Lymphatic vessel: Origin, heterogeneity, biological functions and therapeutic targets

Lymphatic vessels, comprising the secondary circulatory system in human body, play a multifaceted role in maintaining homeostasis among various tissues and organs. They are tasked with a serious of responsibilities, including the regulation of lymph absorption and transport, the orchestration of immune surveillance and responses. Lymphatic vessel development undergoes a series of sophisticated regulatory signaling pathways governing heterogeneous-origin cell populations stepwise to assemble into the highly specialized lymphatic vessel networks. Lymphangiogenesis, as defined by new lymphatic vessels sprouting from preexisting lymphatic vessels/embryonic veins, is the main developmental mechanism underlying the formation and expansion of lymphatic vessel networks in an embryo. However, abnormal lymphangiogenesis could be observed in many pathological conditions and has a close relationship with the development and progression of various diseases. Mechanistic studies have revealed a set of lymphangiogenic factors and cascades that may serve as the potential targets for regulating abnormal lymphangiogenesis, to further modulate the progression of diseases. Actually, an increasing number of clinical trials have demonstrated the promising interventions and showed the feasibility of currently available treatments for future clinical translation. Targeting lymphangiogenic promoters or inhibitors not only directly regulates abnormal lymphangiogenesis, but improves the efficacy of diverse treatments. In conclusion, we present a comprehensive overview of lymphatic vessel development and physiological functions, and describe the critical involvement of abnormal lymphangiogenesis in multiple diseases. Moreover, we summarize the targeting therapeutic values of abnormal lymphangiogenesis, providing novel perspectives for treatment strategy of multiple human diseases.


INTRODUCTION
The lymphatic system is a vital component of the circulatory system and plays a crucial role in maintaining fluid homeostasis, lipid absorption and the immune response in the body.Comprising a vast network of lymphatic vessels, this intricate lymphatic system is a conduit for the transportation of lymph fluid, immune cells, and various macromolecules.Lymphatic vessels are lined with lymphatic endothelial cells (LECs) with distinct structures and functions in the hierarchical lymphatic network. 1 Additionally, it is becoming increasingly clear that adult lymphatic vessels exposed to different organ-specific environments acquire distinct characteristics and in turn execute multiple tissue-specific functions.Abnormal lymphangiogenesis can be induced under pathological conditions, where it becomes an active player in the pathogenesis of several diseases, such as lymphedema, obesity and cancer. 2ecently, molecular and genetic techniques have propelled the identification of potential therapeutic targets to modulate lymphangiogenesis.In this review, we provide a comprehensive summary of lymphatic vessels, addressing their origin, heterogeneity, biological functions, and related therapeutic targets.

HISTORICAL RESEARCH AND MILESTONE EVENTS OF LYMPHANGIOGENESIS Milestone events of lymphatic vessel anatomy and function
The anatomy and function of lymphatic vessels have been investigated for more than 2000 years, and many researchers have contributed numerous landmark discoveries that have led to the gradual clarification of the structure and physiological function of lymphatic vessels. 3,4The earliest record of the lymphatic system is the finding of lymph nodes.In the 5th century B.C., Hippocrates first coined the term chylos (chyle) and observed lymphatic glands (lymph nodes) located in the armpits, near the ears, around jugular vessels, and spread through diverse locations in the abdominal cavity.Moreover, Hippocrates described a milky fluid, termed ichor (lymph fluid), flowing in the lumen of some vessels.Then, Aristotle (384-322 B.C.) identified some unique fibers between blood vessels and nerves that were filled with fluid, thereby first describing the anatomy of general lymphatic vessels. 5As interest increased, lymphatic vessels were clearly described in a variety of tissues.Herophilus (335-280 B.C.) and Erasistratus (304-250 B.C.) successively found chyliferous vessels inside the mesentery. 6,7n 1536, Massa (1485-1569) found some vessels (lymphatics) in fat tissue near kidneys (renal lymphatic vessels). 8Eustachi (1520-1574) found the vena alba thoracis (thoracic duct) during horse dissection but failed to identify the extended structure and function. 9In 1627, Gaspare Aselli found the venae albae aut lacteae (the gut lacteal, a specialized capillary lymphatics with a blind end that absorbs chylomicron from intestinal villi) in a dog in 1627. 10Immediately afterward, in 1628, Fabrice de Peiresc described lacteals in the human body. 11hen, researchers went beyond anatomical studies and began to investigate the role of lymphatic vessels in lymph drainage.Jean Pecquet (1624-1674) described the cisterna chyli (reservoir of the chyle) and thoracic duct and explained that lymph drained into the left subclavian vein via the thoracic duct not the liver. 12At approximately the same time, another lymphatic vessel that converge with the thoracic duct was also described.Olaus Rudbeck (1630-1702) found ducti hepatici aquosi (watery hepatic ducts), now known as hepatic lymphatic vessels.Rudbeck also found cardiac, renal, pulmonary, and peripheral lymphatic vessels in 1653. 13,14In the same year, another researcher, Thomas Bartholin (1616-1680), coined the term vasae lymphatica (lymphatics or lymphatic vessels) to describe the ducts conveying lymph fluid and distinguished mesenteric lymphatic vessels from hepatic lymphatic vessels, confirming that the lymph fluid from two different sources flows into the thoracic duct. 15Niels Stensen (1638-1686) specifically described that both the thoracic duct and left jugular lymphatic vessel delivered lymph into the angle between the duct of the left subclavian and internal jugular veins. 4Simultaneously, in 1675, Stensen also discovered cervical lymphatic vessels and lymph nodes. 4Subsequently, in 1701, Frederik Ruysch explored the morphology and function of lymphatic valves, which ensure the unidirectionality of lymph flow. 16Paolo Mascagni described lymphatic vessels in the human dura mater (meningeal lymphatic vessels) and lymph node-related lymphatic vessels in 1787. 17,18espite the lack of advanced microscopy imaging techniques and specific lymphatic markers to stain, the striking findings and continued exploration laid the foundation for modern anatomy and knowledge about the function of lymphatic vessels.Herein, we clearly present the early research events and critical timepoints of lymphatic vessel discoveries in Fig. 1.
Milestone events of lymphatic vessel origins and development Early studies revealed the anatomy and function of mature lymphatic vessels, while modern research has been focused on the embryonic events of lymphatic vessel formations comprising origins and development (the specific events and timepoints of their discoveries are presented in Fig. 2).In 1902, Florence Sabin discovered the origin and development of lymphatic vessels by injecting India ink into pig embryos and then proposed the venous-origin theory of lymphatic vessels, which suggests that LECs sprout from veins and form the lymph sacs involved in general lymphatic vessel development. 19This researcher was the first to visualize the origin of lymphatic vessels and the development process.In contrast, in 1910, Huntington, McClure, and Kampmeier separately proposed a nonvenous theory of lymphatic vessel origin, suggesting that lymphatic vessels concentrically grow from isolated mesenchymal lymphangioblasts, coalesce into lymphatic sacs, and then connect to the venous system. 20These origin theories have been explored and verified for nearly a century.With the application of lineage tracing and other techniques in different animal models, the diversity of lymphatic vessel origins has been gradually revealed.
Martin Schneider and Annelii Ny supported the theory that lymphatic vessels originate from nonvenous cells and found that lymphangioblasts participate in the development of lymphatic vessels in avian wing bud and Xenopus laevis tadpole models in 1999 and 2005, respectively. 21,22The zebrafish is an optimal vertebrate model owing to its fast reproduction rate and ability of researchers to visualize their internal structures.In 2006, Axel M Küchler and Karina Yaniv respectively reported development and regulatory factors of lymphatic vessels in zebrafish models and supported the theory that lymphatic vessels are derived from embryonic veins. 23,24Additionally, mice are a proper mammalian models and have been used to show the process of lymphatic vessel development in different embryonic stages.In 2007, Sathish Srinivasan demonstrated that lymphatic vessels originated from venous endothelial cells (VeECs) by establishing prospero homeobox protein 1 (PROX1)-creERT2 model mice, PROX1 mainly drives the direct reprogramming of VeECs that form the functional lymphatic system that lasts a lifetime. 25,26René Hägerling showed the detailed process of embryonic lymphangiogenesis by applying ultramicroscopy to the study of whole-mount immunostained murine embryos in 2013. 27Hägerling found that lymphatic Fig. 1 Milestone events of lymphatic vessel anatomy and function.Since the first discovery of chyle and lymph fluid at 5th B.C., some milestone findings have gradually revealed lymphatic vessel network and function in mammals.Created with Adobe Illustrator endothelial progenitor cells were selectively located on the dorsolateral wall of the cardinal vein, indicating that specific VeECs participate in lymphangiogenesis.Using lineage tracing and whole-mount immunostaining on different embryonic days, Oliver A. Stone found that the general lymphatic endothelium was derived mainly from paraxial mesoderm not lateral plate mesoderm.He further indicated that paraxial mesoderm-derived PAX3 + VeECs transdifferentiated into PROX1 + lymphatic endothelial progenitor cells in the cardinal veins and intersomitic veins.PAX3 is a marker for identifying myogenic progenitors in a subset of the somatic paraxial mesoderm, which could differentiate into muscular tissue and endocardium. 28Genetic lineage tracing in the past decade revealed the nonvenous cellular origins of a variety of organ-specific lymphatic vessels.Ines Martinez-Corral identified an isolated cell population involved in the formation of murine lumbar and dorsal midline dermal lymphatic vessels, showing another origin of dermal lymphatic vessels in 2015. 29Three years later, by applying genetic lineage tracing, Cathy Pichol-Thievend demonstrated that this progenitor cell population originated from a blood capillary plexus. 30Moreover, in 2015, Lukas Stanczuk found a population of hemogenic endothelium-derived c-Kit + progenitor cells that may be involved in mesenteric lymphatic vessel development was discovered. 31Cardiac lymphatic vessels have also been shown to be derived from diverse cellular sources.In 2015, by using multiple Cre-loxp system-based lineage tracing, Linda Klotz determined that multiple populations of hemogenic endothelium-derived VAV1 + /PDGFRB + /CSF1R + progenitor cell contributed to cardiac lymphatic vessel development. 32Additionally, Kazuaki Maruyama and Ghislaine Lioux separately in 2019 and 2020 identified a population of second heart field-derived ISL1 + progenitor cells that participated in the formation of ventral cardiac lymphatic vessels. 33,34Two years later, Kazuaki Maruyama found that these ISL1 + progenitor cells originating from the cardiopharyngeal mesoderm differentiated into craniofacial and cardiac LECs. 35n the 1990s, a large number of studies on the regulatory factors and markers of lymphatic vessel have begun to emerge in the research field.In 1995, Kaipainen et al. discovered FLT4 gene (encoding vascular endothelial growth factor receptor 3, VEGFR3) becomes restricted in lymphatic endothelium during embryonic development. 36Subsequently, Kari Alitalo and Vladimir Joukov were the first researchers to isolate the ligand vascular endothelial growth factor C (VEGFC), the ligand for VEGFR2/VEGFR3 and a key factor in regulating LECs sprouting by activating VEGFR3 signaling, as proven by follow-up studies. 37,38In 1999, Guillermo Oliver and Jeffrey T Wigle demonstrated that PROX1 is the master regulator of lymphatic fate and regulates the expression of other transcription factors during embryonic lymphangiogenesis. 39At the same year, Silvana Breiteneder-Geleff discovered a transmembrane glycoprotein in podocytes, podoplanin (PDPN, encoded by T1α), which was specifically expressed in the endothelium of capillary lymphatics and was, therefore, the first lymphatic marker for immunolocalization and distinguishing the blood from lymphatic vessels. 40Simultaneously, Suneale Banerji determined that lymphatic vessel endothelial hyaluronan receptor 1 (LYVE1) is another specific lymphatic marker. 41hese historical studies and milestone events reveal the diversity and heterogeneity of lymphatic vessel anatomy, function, and development and demonstrate the enthusiasm of these researchers for lymphatic vessel research.

LYMPHATIC VESSEL DEVELOPMENT AND RELATED REGULATORY SIGNALING PATHWAYS
Lymphatic vessels in embryos undergo a stepwise developmental process, including lymphatic endothelial progenitor cell specification, LEC migration, and lymphatic vessel assembly and maturation. 42Lymphatic vessel development involves lymphangiogenesis and lymphvasculogenesis.Lymphangiogenesis, sprouting from preexisting lymphatic vessels/embryonic veins to form new lymphatic vessels, is the main developmental mechanism underlying the formation and expansion of lymphatic networks in an embryo. 43,44Another mechanism, termed lymphvasculogenesis, is the process by which various populations of nonvenous cells de novo express lymphatic markers and directly incorporated into new lymphatic vessels. 43,45Lymphatic vessel development is a highly conserved process across multiple species and relies on a stepwise and precise regulatory program. 468][49] However, few studies have recorded the complete process of lymphatic vessel development.Due to ethical issues in using human fetuses, most studies of lymphatic vessel development and function have been carried out with other vertebrate animals, such as mice and zebrafish, and with contributions from these studies, the regulatory map of lymphatic vessel development is gradually being completed. 50,51rine lymphatic vessel development and regulatory signaling pathways General lymphatic vessel development and signaling pathways.Based on diverse studies with murine embryos, the timing and processes of lymphatic vessel development have been revealed. 27On approximately embryonic day 9.5-10.5 (E9.5-E10.5),a portion of VeECs located in the cardinal vein and intersomitic veins gradually transdifferentiate into lymphatic endothelial progenitor cells, which is the initial event in lymphatic vessel development. 52SRY-box transcription factor 18 (SOX18) and the chicken ovalbumin upstream promoter transcription factor 2 (COUP-TFII, encoded by NR2F2) are initially expressed in VeECs, which could synergistically activate PROX1 expression. 53,54Furthermore, COUP-TFII cooperates with PROX1 to upregulate the expression of VEGFR3, Neuropilin 2 (NRP2, a coreceptor with VEGFR3), and LYVE1. 55,56In turn, activated VEGFR3 contributes to the consistent expression of PROX1.The regulatory feedback loop further promotes lymphatic phenotype differentiation. 57t E10.5-E15.5,VEGFR3-expressing lymphatic endothelial progenitor cells sprout and form lymph sacs in response to extracellular VEGFC signaling, which triggers tip cells to leave veins and autonomously enter the surrounding mesenchyme. 58uring this period, lymphatic endothelial progenitor cells differentiate into LECs and acquire migration and tube formation abilities.VEGFC is necessary and sufficient for prompting lymphatic endothelial progenitor cell budding and directed migration. 38At this stage, collagen and calcium binding EGF domains 1 (CCBE1) and a disintegrin and metallopeptidase with thrombospondin motifs 3 (ADAMTS3) are essential for the proteolytic cleavage of the active form of VEGFC. 59,60Moreover, NRP2 and VEGFR3 can jointly respond to VEGFC binding to regulate LEC migration. 562][63] In addition to biochemical pathways, mechanical force can activate lymphangiogenesis in this stage.The expression of the zinc-finger transcription factor GATA-binding protein 2 (GATA2) enhances VEGFR3 signaling in response to changes in tissue stiffness. 64Moreover, increased fluid volume could stimulate β1 integrin-mediated VEGFR3 signaling. 65Subsequently, lymph sacs separate from the cardinal vein via the action of platelet aggregation in response to c-type lectin-like receptor 2/PDPN signaling. 66Interestingly, platelet also maintain the homeostasis of lymphovenous valves. 67Lymphovenous valves, as the only connections between the blood and lymph circulatory systems, which have been gradually characterized, maintain unidirectional lymph drainage into veins.Especially, VEGFC activates the expression of YAP and TAZ to maintain PROX1 expression, which promote the lymphovenous valves and lymphatic valves development. 68rom E15.5 to the early postnatal period, the primary lymphatic plexus gradually remolds into hierarchical lymphatic vessels with different features, and these vessels are classified into capillary lymphatic vessels, pre-collecting lymphatic vessels, and collecting lymphatic vessels.The transition of intercellular junctions and changes in cell morphology are fundamental to the initial functionality of lymphatic vessels (described "Capillary lymphatics").Additionally, the maturation of collecting lymphatic vessels involves lymphatic valve morphogenesis and smooth muscle cell recruitment, which are the structural foundations for lymph transport. 69The constant shear stress caused by lymph flow can stimulate the LEC-expressed mechanosensory receptors, such as PECAM, VEcadherin, PIEZO1, β1 integrin, VEGFR2, and VEGFR3. 702][73] In addition to lymphatic valves, collecting lymphatic vessels transport lymph fluid by the action of coverage of smooth muscle cells.Smooth muscle cell recruitment is regulated by the expression of platelet-derived growth factor B (PDGFB), Reelin and MCP1 in LECs. 74,75Moreover, FOXC2 and Angiopoietin 2 (ANG2) could Fig. 2 Milestone events of lymphatic vessels origins and development.In modern research (from 1902 to now), numerous researchers have gradually discovered the diverse origins and molecules of the lymphatic vessel development.These studies have doubtless initiated the understanding of heterogeneous development processes and regulatory mechanism of lymphatic vessels.VEGFR3 vascular endothelial growth factor receptor 3, PROX1 prospero homeobox protein 1, LYVE1 lymphatic vessel endothelial hyaluronan receptor 1, PDPN podoplanin, LEC lymphatic endothelial cell, FHF first heart field, SHF second heart field, ISL1 Islet 1, VAV1 vav guanine nucleotide exchange factor 1, PDGFRB platelet-derived growth factor receptor B, CSF1R colony-stimulating factor 1 receptor.Created with Adobe Illustrator activate downstream signaling to maintain the normal pattern of smooth muscle cell coverage of vessels. 73,76In contrast, the Sema3A/NRP1/PlexinA1 axis prevents smooth muscle cells from covering valve-forming endothelial cells. 77We depict the developmental process of general lymphatic vessels in Fig. 3.
Organ-specific lymphatic vessel development and signaling pathways.Lymphatic vessels undergo a general development process mediated through biochemical and mechanical signaling pathways and gradually form a specialized lymphatic vessel network.To adapt to the physiological needs of different organs, lymphatic vessel development involves heterogeneous processes and responses to lymphangiogenic signaling. 78Therefore, we summarize the development process of organ-specific lymphatic vessels and regulatory signaling in Table 1.We also depict schematic diagrams of the murine organ-specific lymphatic vessel anatomy in Figs.4-6.
Zebrafish lymphatic vessel development and related signaling pathways Because of their relatively transparent body, large number of progeny, and short developmental cycle, zebrafish have become an optimal animal model for observing the dynamic development of lymphatic vessels. 79,80Through the combined application of high-resolution imaging techniques and identification of lymphatic markers, the heterogeneous processes underlying lymphatic vessel development in zebrafish have been gradually elucidated in the past decade. 79Although the main lymphangiogenic signaling network is conserved across mammals, lymphatic vessel development is regulated by specific molecules and signaling pathways in zebrafish.Therefore, we summarize the heterogeneous development processes of lymphatic vessels (Fig. 7) and the significant molecules and signaling pathways in zebrafish (Table 2).
Early lymphatic vessel development occurs during the first day 5 postfertilization (dpf).Similar to mammals, the posterior cardinal     Pulmonary lymphatic vessels E11.5-E14.5:LECs migrate in a proximal-to-distal manner into the developing lung lobes, and then the primary lymphatic plexus expands along the bronchovascular bundles.
E18.5-P0:The pulmonary lymphatic vessel network has been widely distributed in the airways and lower respiratory bronchioles, as well as existing abut intralobular arterioles and small veins.Around birth, pulmonary lymphatic vessels rapidly function in response to the surge generation of interstitial fluid along the change of button-like junctions.1. VEGFC/VEGFR3 signaling mediates pulmonary lymphatic vessel development from the embryonic to the neonatal period.2. At birth, transient expression of c-JUN can induce CDH13 and ATF3 expression, remodeling the conformation of the actin cytoskeleton and initiating lymphatic vessel drainage in response to high shear stress.
P8-P21: The lymphatic vessels continuously sprout deeply and terminally distribute at the portal vein region, the hepatic vein region, and the hepatic capsule region.
1. Heterozygous mutations of VEGFC/VEGFR3 delay hepatic lymphatic vessel development and disrupt the lymphatic vessel structure.
2. CHD4 raises the transcriptional activity of uPAR to activate plasmin, maintaining the development and structure of hepatic lymphatic vessels and lymphovenous valves.vein is the origin of lymphangiogenesis. 81Between hour 30 and 34 postfertilization (hpf), a population of bipotential progenitor cells (also known as lymphangioblasts) generates two kinds of endothelial cells, VeECs and PROX1-expressing lymphatic endothelial progenitor cells. 82In particular, VEGFC is the key factor that regulates the division of cell identity, and it also triggers PROX1 expression. 82Moreover, the role of PROX1 in initiating the transdifferentiation of VeECs into lymphatic endothelial progenitor cells is conserved in both zebrafish and mammals. 82At 1.5 dpf-2 dpf, LECs dorsally sprout toward the horizontal myoseptum, forming a population of LECs known as parachordal lymphangioblasts (or parachordal line).CCBE1/ VEGFC/VEGFR3 signaling regulates LEC sprouting and migration. 83,84t 2.5 dpf-4 dpf, lymphatic vessel sprouts from the parachordal lymphangioblasts begin to migrate dorsally and ventrally along arterial intersegmental vessels not venous intersegmental vessels, forming intersegmental lymphatic vessels. 85,86Subsequently, LECs on the dorsal and ventral sides of the intersegmental vessels migrate rostrally and caudally and ultimately interconnect, forming the two trunk lymphatic vessels, namely, the dorsal longitudinal lymphatic vessel (abutting the dorsal longitudinal anastomotic vessel) and thoracic duct (abutting the posterior cardinal vein). 87,88We show the process of mainly trunk lymphatic vessel development in Fig. 7 and describe the related regulatory signaling pathways involved in LEC sprouting and migration in Table 2.
Between 5 dpf and 7 dpf, LECs begin to emerge from the intersegmental lymphatic vessels (the third trunk lymphatic vessel) and extend rostrally and caudally along the horizontal myoseptum to gradually form parachordal lymphatic vessels. 80ubsequently, parachordal lymphatic vessels continue to expand laterally during zebrafish development and form intercostal lymphatic vessels at approximately 15 dpf. 80Parachordal lymphatic vessels and intercostal lymphatic vessels become lateral lymphatic vessels in zebrafish.Through sophisticated signaling mechanisms, VEGFC/VEGFR3 is the key interaction that triggers the signaling cascade to activate LECs continuously.Interestingly, the homeobox transcription factor HOXC9 supports the expression of stabilin 2 to maintain the normal formation of thoracic duct and parachordal lymphangioblasts, and another homologous protein, stabilin 1, plays a similar role in promoting zebrafish lymphangiogenesis in a HOXC9-independent manner. 89n this developmental period, organ-specific lymphatic vessel development simultaneously occurs in the head and intestine of zebrafish. 80,90We depict the process of organ-specific lymphatic vessels by development stages in Fig. 7. Further studies should be conducted to verify the specific function of lymphangiogenic signaling pathways in organ-specific lymphatic vessel development and biological capacity.

BIOLOGICAL FUNCTIONS OF LYMPHATIC VESSELS AND RELATED REGULATORY SIGNALING PATHWAYS
Anatomy and structure of the lymphatic vessel network The lymphatic system includes primary lymphoid organs (the bone marrow and thymus), secondary lymphoid organs (the lymph nodes, spleen, and mucosal-associated lymphoid tissue), and lymphatic vessels that connect all lymphoid organs. 91The lymphatic vessel network is composed of capillary lymphatics, pre-collecting and collecting lymphatics. 92Additionally, the cellcell junctions (button-and zipper-like junctions) are important for functionally specialized capillary and collecting lymphatics (Fig. 8).
Capillary lymphatics.Capillary lymphatics (also called initial lymphatics) consist of a single layer of loosely connected LECs without a continuous basement membrane and are covered by pericytes or smooth muscle cells. 93They are blind-ended vessels  The button-like junctions of the capillary lymphatics are formed by adherens junction proteins, including VE-cadherin, 94 p120catenin, and catenin, which bind to each other and the actin cytoskeleton.Tight junctions are formed by transmembrane proteins, such as claudin-5 and occludin, and the cytoplasmic protein ZO-1, which regulate paracellular permeability, 91 and junctional adhesion molecule and endothelial cell-selective adhesion molecule, which are involved in leukocyte transmigration.The ANG/tunica interna endothelial cell kinase 2 (TIE2) signaling pathway is indispensable for the formation of button-like junctions within capillary lymphatics. 95In lacteals, VEGFC-VEGFR2/ 3-delta-like 4 (DLL4)-NOTCH signaling is crucial for constant regeneration and maintenance of button junctions. 96llecting lymphatics.Capillary lymphatics drain into precollecting lymphatic vessels and merge with larger collecting lymphatics.Collecting lymphatic vessels contain valves that regulate the unidirectional flow of lymph with the coordinated contraction of smooth muscle cells facilitating the transport of lymph into the bloodstream. 97Tissue fluid transported by collecting lymphatics ultimately drains into the thoracic duct and right lymphatic duct, which discharge lymph into the common opening of the jugular and subclavian veins known as the venous angle. 98n collecting lymphatics, LECs are continuously connected through zipper-like junctions and are enveloped by specialized smooth muscle cells that contract to assist lymph flow. 93During mouse embryonic development, the transformation from continuous zipper-like junctions (formed at E12.5-E16.5) to button-like junctions begins at E17.5 and is mostly complete by postnatal day (P) 28. 99Therefore, zipper-like junctions are regulated in a manner similar to that of button-like junctions, however, some mechanisms that specifically regulate zipper-like junctions are described below.RhoA/ROCK signaling is essential for LEC junction formation in lacteals, lymphatic valves, and collecting vessels.Transcription factors FOXC1 and FOXC2 are required for maintaining LEC junction integrity in lymphatic valves, collecting vessels, and dermal lymphatics. 92Recent studies identified several other major signaling pathways that control tight junction localization and lymphatic vessel integrity, including EphrinB2/EphB4 and S1PR1. 91ological functions of lymphatic vessels The general functions of lymphatic vessels in fluid absorption and transport, as well as immunosurveillance, are well understood.However, accumulating evidence indicates that lymphatic vessels play active and versatile roles in an organ-specific manner during homeostasis and multiple disease processes. 100e provide a brief overview of the novel discoveries of organspecific functions of adult mammalian lymphatic vessels, including immunosurveillance after pathogen invasion, transport of dietary fat, and drainage of cerebrospinal fluid and aqueous humor.
Lymph absorption and transport.Lymphatic vessels play crucial roles in the uptake and transport of multiple substances to maintain tissue fluid homeostasis, such as lipids, proteins, and immune cells in the body, which present diverse characteristics in different organs. 101Studies have suggested that both passive paracellular and active transcellular transport mechanisms may contribute to lymph absorption. 102Moreover, lymphatic vessels have an active role in draining excess interstitial fluid from organs and serving as conduits for immune cell trafficking to lymph nodes.The lymphatic pump undergoes phasic contractions Lymph absorption and transport in meningeal lymphatic vessels.Although the brain parenchyma is devoid of lymphatic vessels, the rapid clearance of cellular debris and metabolic products in the central nervous system is attributable to the glymphatic system and meningeal lymphatic vessels. 103The glymphatic system is composed of three essential components: the para-arterial cerebrospinal fluid influx channel, the para-venous interstitial fluid efflux channel, and the water channel aquaporin-4 in astrocytes that connect these channels. 103Cerebrospinal fluid flows into the brain through the para-arterial space and exchanges with interstitial fluid via aquaporin-4; this type of exchange drives metabolite and interstitial fluid into the para-venous space and then into the cerebrospinal fluid circulatory system or directly through the capillary lymphatics into the cervical lymphatics.In particular, the glymphatic system transports lipids within the brain.Excess cholesterol in the brain is eliminated through hydroxylation to 24-hydroxycholesterol by Apolipoprotein E concentrated in astrocytes.
In addition to the glymphatic system, meningeal lymphatic vessels are involved in the elimination of cellular debris and waste products.Dorsal meningeal lymphatic vessels transport macromolecules and cells along the superior sagittal and transverse sinuses.Basal meningeal lymphatic vessels possess lymphatic valves without smooth muscle cells, thereby acquiring a precollector phenotype. 104Dysfunction of meningeal lymphatic vessels potentially contributes to the onset and progression of Alzheimer's disease by disrupting the clearance of pathological proteins such as amyloid-β and tau protein, which we will discuss in "Abnormal lymphangiogenesis in human diseases".
Lymph absorption and transport in ocular lymphatic vessels.The ocular surface lymphatic system and Schlemm's canal regulate lymph absorption and transport in ocular lymphatic vessels.Regarding the ocular surface lymphatic system, lymphatic vessels have been identified in the corneal limbus and conjunctiva of mice and humans. 105Ocular surface lymphatic vessels are characterized by button-like junctions, an oak leaf-like shape, and luminal valves with features similar to those of capillary lymphatics and pre-collecting lymphatic vessels. 106chlemm's canal is an endothelial cell-lined vessel encircling the cornea and abutting the juxtacanalicular region of the trabecular meshwork. 107As a special structure regulating intraocular Fig. 5 The lymphatic vessels in heart, lung, liver, kidney, and intestine.a Cardiac lymphatic vessels develop from the extracardiac region and follow the basal-to-tip manner along the developing coronary arteries to the ventricles; b Pulmonary lymphatic vessels consists of interlobular, intralobular and pleural lymphatic vessels, and develop surround airway, blood vessels and developing alveoli; c Capillary lymphatic vessels of the portal tract region mainly absorb the lymph secreted into the Disse space and eventually drain through collecting lymphatic vessels into thoracic duct; d Capsular lymphatic vessels are located near the renal surface.Cortical capillary lymphatic vessels accompany the renal tubules, glomeruli and small arteries and run along the medullary collecting lymphatic network and are finally excluded from the kidney via the hilar lymphatic vessels; e The intestinal lymphatic vessels consist of mesenteric collecting lymphatic vessels, mucosal, submucosal, muscle lymphatic vessels, and lacteals.Created with Adobe Illustrator pressure, Schlemm's canal drains aqueous humor into aqueous and episcleral veins. 108Yang et al. described a luminal structure called the lymphatic bridge that connects Schlemm's canal to ocular surface lymphatic vessels, which allows aqueous humor outflow to the conjunctival lymphatic pathway.This finding suggested, for the first time, that the two lymphatic drainage systems are physically connected, expanding the knowledge of the aqueous humor pathway. 109mph absorption and transport in intestinal lymphatic vessels.Intestinal lymphatic vessels mediate distinct functions in fat absorption, intestinal homeostasis, and peripheral fat transport.Lymphatics continuously deliver nutrients to tissues.Dietary lipids are packaged into chylomicrons in the small intestines and transported via lacteals (capillary lymphatics in the small intestine), where they mix with lymph to become chyle.Mesenteric lymphatic vessels and cisterna chyli carry chyle through the thoracic duct and into the venous circulation. 110Defects in lacteals can cause problems with lipid uptake in the intestine.VEGFR2/ VEGFR3 signaling, which is mediated through DLL4/NOTCH, is important for lacteal function maintenance.The deletion of DLL4 in lymphatics led to lacteal atrophy and an increase in the number of zipper junctions, resulting in the inability of the tissues to take up chylomicrons. 111Interestingly, VEGFA/VEGFR2 signaling also leads to a shift from the establishment of button-like junctions to that of zipper-like junctions in lacteals. 112Notably, lacteal atrophy caused by postnatal deletion of VEGFC impaired the absorption of lipids and led to steatorrhea. 113lthough the small intestine is generally considered an absorptive organ, it can be induced to secrete fluids, causing diarrhea, under certain conditions. 114Intestinal lymphatics are important for fluid absorption, especially after a meal.Lymphatics also appear to participate in peripheral tissue lipid balance, and recent studies have shown that they are critical for reverse cholesterol transport.When high-density lipoprotein transports cholesterol out of cells and into peripheral tissues, lymphatic vessels conduct the particles into the bloodstream and back to the liver for excretion through feces. 115In mice, obstruction of Fig. 6 The lymphatic vessels in skin, ovary, and bone.a Skin lymphatic vessels, consisting of superficial and deep lymphatic vessel networks, are mainly located in the dermis and partly accompanied by dermal blood vessels.During E13.5 to E15.5, the primitive lymphatic plexus of the dorsally cervical region of skin begins to develop from the bilateral sides toward the midline of the back; b Ovarian lymphatic vessels develop along established blood vessels in the interstitium, which happened during the period of the first wave of follicular development; c Skeletal lymphatic vessels could develop at the sternum, femur, and tibia.And this part shows the skeletal lymphatic vessels go along the bone marrow of the long bones.Ex embryonic day x.Created with Adobe Illustrator lymphatic vessels impaired reverse cholesterol transport 116 and led to increased atherosclerotic plaque formation. 117

Lymphatic vessels in immunity
Lymph node lymphatic vessels in coordinating immune responses.Peripheral lymphatic vessels transport antigens and immune cells to draining lymph nodes, fostering an immune response. 100In mature lymph nodes, lymphatic vessels and specialized high endothelial venules that are indispensable for the trafficking of naïve lymphocytes into the paracortex of the lymph node, 118 contributing to the adaptive immune response. 119Lymph node LECs contribute to immune response directly by antigen archiving and presentation.Antigen archiving in proliferating lymph node LECs can be directly transferred to other cells, for example, to migratory CD11c + dendritic cells. 120Antigens can also be released from dying LECs and subsequently transferred to Batf3-dependent   migratory dendritic cells.Antigens can be presented by LECs to immune cells through the MHC (comprising MHCI and MHCII). 121ECs in different regions can guide immune cell trafficking and positioning within lymph nodes by expressing specific molecules. 122For instance, LECs create a chemokine (C-C motif) ligand 21 (CCL21) gradient that facilitates the migration of dendritic cells into the lymph node medulla. 123Additionally, S1P gradients, formed by medullary LECs, are necessary for B and T-cell egress into efferent lymphatics and subsequent lymphocyte recirculation.LECs establish a niche for subcapsular sinus and medullary macrophage homing and maintenance.Lymph node LECs serve as major sources of the macrophage pro-survival factor colonystimulating factor-1, with RANK receptor-expressing LECs inducing colony-stimulating factor-1 expression by interacting with CCL19 + marginal reticular cells, producing RANKL (Fig. 10). 124mphatic vessels in central nervous system immunity.Recent studies of meningeal lymphatic vessels revealed an intersection between the immune system and central nervous system. 125eningeal lymphatic vessels may provide a route for central nervous system-derived immune cell and antigen delivery to cervical lymph nodes and thus prevent central nervous system from infection or injury.Meningeal lymphangiogenesis plays an active role in immune surveillance to protect the central nervous system.In the context of glioblastoma, VEGFC-induced meningeal lymphangiogenesis recruited CD8 + T cells into the tumor and induced a long-lasting antitumor memory response. 126In response to spinal cord injury, VEGFC/VEGFR3 signaling activation-mediated spinal lymphangiogenesis enhanced the immune response by increasing the T cell infiltration rate. 127owever, studies have shown that meningeal lymphatic vessels potentially promote pathological processes under autoimmune neuroinflammatory conditions.In the multiple sclerosis context, blocking meningeal lymphatic vessels reduced disease severity and alleviated the inflammatory response, likely by interfering with the trafficking and activation of CCR7 + T cells in draining lymph nodes. 128mphatic vessels in gut immunity.Intestinal lymphatic vessels are important components of the gut immunosurveillance system, which promotes the mucosal immune response and tolerance.Intestinal dendritic cells present antigens in response to LECderived CCL21 production, which is essential for the establishment of oral tolerance. 129Intestinal dendritic cells also drive the apoptosis of intestinal epithelial cells in mesenteric lymph nodes by transmitting critical signals that induce Treg cell activation. 129,130In addition, different parts of the intestine drain to distinct mesenteric lymph nodes that are immunologically specific to the functional gut segment that they drain.Proximal small intestine-draining mesenteric lymph nodes induce tolerogenic  131 The capillary lymphatics in the intestine (also known as lacteals) function as a secondary barrier defending against potential bacterial infections while simultaneously serving as the primary conduit for the dissemination of pathogens, pathogen-derived toxins, and subsequently tissue-derived proinflammatory mediators.DLL4-specific deletion led to lacteal regression and weakened the local immune response, leading to susceptibility to infection and impaired dietary fat uptake. 111Additionally, lymphatic drainage can influence the composition of the gut microbiota, with increased drainage potentially promoting a healthier microbiota profile and reducing the incidence of colitis.In contrast, reduced drainage may impede pathogen dissemination and reduce proinflammatory factor levels.

ABNORMAL LYMPHANGIOGENESIS IN HUMAN DISEASES
In the above sections, we provided a detailed account of lymphatic vessels in physiological conditions, encompassing lymphatic vessel development and physiological functions.Furthermore, lymphatic vessels actively participate in pathological processes in human diseases.As the comprehension of lymphangiogenesis in diseases improves, the underlying molecular mechanisms have been elucidating.In this section, we provide a comprehensive elucidation of the pivotal roles of lymphangiogenesis in various prevalent diseases and associated regulatory signaling pathways.Meanwhile, lymphangiogenesis in other diseases is concisely presented in Table 3.

Lymphedema and lymphatic malformation
Lymphedema.Lymphedema is a chronic, progressive accumulation of protein-rich fluid in the interstitium due to lymphatic vessel deficiency, resulting in inflammation, fat deposition, and fibrosis.Lymphedema is classified into primary disease caused by congenital abnormalities or secondary disease caused by the injury of iatrogenesis, trauma, and infection.Primary lymphedema, a rare inherited autosomal dominant disorder, is initially characterized by mutations in FLT4 (which encodes VEGFR3).Germline mutations responsible for primary lymphedema have been identified in 28 genes that encode proteins mainly involved in VEGFR3 signaling and these encoded proteins include transcription factors such as GATA2, FOXC2, and SOX18.The majority of mutations result in reduced activation of the VEGFR3 pathway. 110Secondary lymphedema arises as a result of infection, trauma or surgery. 132Current treatment strategies include mainly physical or surgical interventions to alleviate edema and these treatments include decongestive therapy, intermittent pneumatic compression and liposuction. 133In addition, recent studies have revealed the efficacy of pharmacotherapy and cell-based therapies in the treatment of lymphedema. 134,135mphatic malformation.Lymphatic malformation is a benign congenital vascular disease characterized by abnormal lymphatic vessel development.It is caused by single somatic mutations, most of which are in genes encoding components of oncogenic growth factor-activated signal transduction pathways. 136The classification of lymphatic malformations is based primarily on clinical manifestations.Cystic lymphatic malformation is the most prevalent type of congenital lymphatic malformation, presenting as solitary lesions of variable sizes.Based on appearance, it is classified into macrocystic, microcystic, or mixed cystic lymphatic malformation. 136Most cystic lymphatic malformations are caused by a causative mutation in PIK3CA.Most PIK3CA mutations causing cystic lymphatic malformation activate the phosphatidylinositol-3-kinase (PI3K)/AKT/mTOR signaling cascade. 137Complex lymphatic malformations are characterized as multifocal lesions or defection occurring in central collecting lymphatic vessels and show overlapping and variable clinical features.These features include generalized lymphatic anomaly, Gorham-Stout disease, Kaposiform lymphangiomatosis, and central conducting lymphatic anomaly. 138Similar to the cause of cystic lymphatic malformation, a causative somatic PIK3CA mutation (His1047Arg) has been reported in generalized lymphatic anomaly. 139In other types of complex lymphatic malformations, mutations in genes encoding components of the RAS/MAPK pathway have been reported, including mutations in NRAS and ARAF. 140,141Furthermore, germline heterozygous kinase-dead mutations in the gene encoding EPHB4 could activate MAPK signaling in cases of central conducting lymphatic anomaly. 142he choice of therapy is based on the location and size of the malformation, and the affected tissues.Pharmacotherapy, surgical resection, sclerotherapy, and thermal ablation can be used to b Collecting lymphatics have a period of brisk contraction (systole) and a period of relaxation (diastole) between each phasic contraction.Each lymphangion, defined as the segment between two valves, can typically exhibit systole and diastole.When a lymphangion is relaxed, the inflow (or upstream) valve will open (given sufficient inflow pressure).During systole, the phasic contraction pushes the lymph, but the inflow valve closes, so that lymph is forced forward through the outflow valve.LECs lymphatic endothelial cells.Created with Adobe Illustrator control and relieve symptoms of recurrent effusions, infection, and pain in lymphatic malformations. 136mphangiogenesis in cancer In the past, cancer-associated lymphatic vessels were considered passive transporters of cancer cells.However, recent studies revealed that lymphatic vessels actively participate in the process of cancer metastasis through their dynamic changes, mostly mediated via lymphangiogenesis.Lymphangiogenesis requires the coordination of complex cellular events, including proliferation, sprouting, migration, and tube formation. 46Tumorassociated lymphangiogenesis, with its resultant increased permeability and enlargement of lymphatic vessels, synergistically promotes cancer metastasis. 143Depending on the type and site of a tumor, the signaling pathways for lymphangiogenesis vary.Moreover, targeting lymphangiogenesis to inhibit cancer metastasis has been proven to be a valuable therapeutic strategy.In this section, we summarize the abnormal lymphangiogenesis in various cancers (Figs.11, 12).

Nervous system cancer
Glioma.Malignant glioma is the most common primary cancer of the central nervous system.The expression levels of lymphangiogenic factors (PDPN, VEGFC/D, VEGFR3) are increased in high-grade gliomas, with their expression significantly higher at relapse than it was in the primary tumor. 144In addition, microenvironmental stress, including hyperthermia and oxidative stress, has been reported to enhance LEDGF activity, which increases the transcription and expression of VEGFC, thereby promoting lymphangiogenesis. 145However, Hu et al. found that meningeal lymphangiogenesis mediated by VEGFC enhanced the efficacy of anti-PD-1/CTLA-4 combination therapy, which was abolished by CCL21/CCR7 blockage. 146uroblastoma.Neuroblastoma is one of the most common cancers in children.Lymphangiogenesis in neuroblastoma is associated with upregulated VEGFC, VEGFD, and VEGFR3, which promotes lymph node metastasis and leads to poor prognosis. 147ndogenous soluble VEGFR2 inhibits the activation of VEGFR3 by binding to VEGFC, thereby inhibiting LEC proliferation.In the context of advanced neuroblastoma, the downregulation of sVEGFR2 is correlated with the disease progression. 148Furthermore, an anti-VEGFD monoclonal antibody, cVE199, specifically binds VEGFD to inhibit the binding of VEGFD to VEGFR3, thereby significantly reducing the lymphangiogenesis in the context of primary lesions. 149oracic cancer Non-small cell lung cancer.The presence of lymphangiogenesis promoting lymph node metastasis is a crucial determinant for unfavorable prognosis in patients with non-small cell lung cancer.Lymphangiogenesis, indicated by an elevated density of PDPNpositive peritumoral lymphatic vessels, has been demonstrated to be associated with cancer progression and unfavorable prognosis in patients with non-small cell lung cancer. 150Watari et al. found that highly metastatic human lung cancer cells have the capability to secrete IL-1, which induces the M2-type polarization of macrophages, augmenting VEGFC expression and subsequently increasing the lymphangiogenesis. 151In addition, the overexpression of ITGA6 enhanced the tube formation capacity of LECs, thereby promoting lymphangiogenesis and accelerating subsequent lymph node metastasis in the lung adenocarcinoma context. 152Moreover, estrogens in females promoted lymphangiogenesis through an estrogen receptor alpha-dependent pathway in Lewis lung cancer. 153Additionally, Hu's team found that miR-128, functioning as a cancer suppressor, directly targeted VEGFC and subsequently inhibited extracellular signal-regulated  kinase (ERK), AKT, and p38 signaling pathway activation to impede lymphangiogenesis in the non-small cell lung cancer context. 154east cancer.The dissemination of breast cancer cells is primarily mediated through lymphatic vessels.Increased lymphatic vessel density has been associated with lymph node metastasis and poorer survival in patients with breast cancer. 155The interaction between PDPN and LEC-derived galectin-8 contributed to the activation of promigratory integrin β1, thereby augmenting PDPN-expressing macrophages proximal to lymphatics, which subsequently stimulated local matrix remodeling and promoted lymphangiogenesis. 156Weichand et al. revealed that S1PR1 on tumor-associated macrophages promoted lymphangiogenesis and metastasis via NLRP3/IL-1β. 157In addition, Zheng et al. found that the hypomethylation of the long noncoding RNA (lncRNA) HUMT promoted lymphangiogenesis and metastasis by enhancing FOXK1 transcription to activated the AKT/mTOR and VEGFC signaling pathways in breast cancer cells. 158A recent study conducted by Li et al. revealed that the transcription factor ZKSCAN5 directly interacted with SETD7, forming a complex at the VEGFC promoter.This interaction effectively regulated the expression of VEGFC, inducing tube formation of LECs and promoting lymphangiogenesis. 159Furthermore, NADPH oxidase 4 promoted lymphangiogenesis via the ROS/ERK/CCL21 signaling pathway and providing the entry for metastasis of CCR7expressing breast cancer cells. 160Nectin-4 induced chemotactic interactions between CXCR4-expressing cancer cells and CXCL12expressing LECs, which stimulated VEGFC and LYVE1 expression to promote LEC proliferation and migration, ultimately promoting lymphangiogenesis. 161Additionally, heat shock protein 90α significantly enhanced the migration and tube formation abilities of LECs to promote lymphangiogenesis via the LRP1/AKT/ CXCL8 signaling pathway. 162Chemotherapy remains an effective treatment for breast cancer, although its efficacy may be influenced by lymphangiogenesis.Harris and colleagues found that lymphangiogenesis induced by platinum chemotherapy increased the rate of lymph node metastasis in breast cancer, which was prevented by adjuvant anti-VEGFR3 therapy. 163gestive system cancer Hepatocellular cancer.Hepatocellular cancer is the most common type of liver cancer. 164High lymphatic vessel density has been associated with reduced survival and disease-free survival of patients with hepatocellular cancer. 165VEGFD-overexpressing hepatocellular carcinoma cells promote lymphangiogenesis, resulting in an increased rate of lymph node metastasis. 166urthermore, lncRNA HANR, which regulates exosomal miR-296 secretion, may induce lymphangiogenesis via the EAG1/VEGFA axis in LECs. 167Targeting lymphangiogenesis has been proposed as a promising approach for suppressing hepatocellular cancer metastasis.An IgG-like fusion protein molecule (VEGF receptor 31immunoglobulin, VEGFR31-Ig) binding VEGFC has been developed to inhibit lymphangiogenesis, thereby suppressing cancer growth and metastasis. 168trahepatic cholangiocarcinoma.Intrahepatic cholangiocarcinoma is an aggressive and lethal type of primary liver cancer. 169ymphangiogenesis has been correlated with an increased risk of lymph node metastasis and reduced overall survival in patients with intrahepatic cholangiocarcinoma. 170Carpino et al. found that THB1, THBS2, and PEDF released into the intrahepatic cholangiocarcinoma stroma induced lymphangiogenesis, which contributed to preferential lymph node metastasis of intrahepatic cholangiocarcinoma. 171Furthermore, cholangiocarcinoma-derived PDGFD activated LEC-adjacent fibroblasts, which secreted VEGFC and VEGFA, resulting in lymphangiogenesis to promote cancer cell intravasation. 172Moreover, PDGF-BB secreted by cancerassociated fibroblasts activated the receptor PDGFR-β and downstream ERK1/2-JNK signaling pathways in LECs to promote lymphangiogenesis. 173ncreatic cancer.The high lethality of pancreatic cancer stems from its propensity for rapid dissemination in the lymphatic system and distant organs, and lymph node metastasis may occur early in the course of pancreatic cancer development. 174Similar to its effect on other cancer types, VEGFC may mediate lymphangiogenesis in the context of pancreatic cancer.Under hypoxic conditions, BANCR is overexpressed in pancreatic cancer and promotes lymphangiogenesis by upregulating the HIF-1α/VEGFC/VEGFR3 pathway. 175In contrast, circular RNA (circRNA) circNFIB1 exerts a suppressive effect on lymphangiogenesis by downregulating the effect of miR-486-5p and upregulating PIK3R1 expression to inhibit VEGFC signaling. 176VEGFC could be secreted from cells in extracellular vesicles to facilitate lymphangiogenesis.Wang et al. reported that the downregulation of DUSP2 in pancreatic cancer enhanced extracellular vesicle-associated secretion of VEGFC.Thus, VEGFC enhances lymphangiogenesis and cancer cell invasion into lymphatic vessels through paracrine and autocrine mechanisms, ultimately leading to lymph node metastasis. 177Additionally, based on the aforementioned mechanism, Wang et al. reported a selective inhibitor B390 of HDAC1/2 that effectively suppressed lymphangiogenesis by reinstating DUSP2 expression. 178Other studies have been aimed at understanding lymphangiogenesis independent of VEGFC action.KRAS(G12D)-mutated pancreatic cancer cells maintained the secretion of extracellular vesicles carrying hnRNPA1 in a SUMOylation-dependent manner, thereby promoting lymphangiogenesis through the stabilization of PROX1 mRNA in vesicle-recipient LECs. 179Furthermore, Zhou et al. demonstrated that exosomes derived from pancreatic cancer cells exerted a stimulating effect on the proliferation and migration of LECs via the downregulating ABHD11-AS1 expression, to promote lymphangiogenesis. 180With the recent development of the "medicine-industry combination", Shen et al. utilized three-dimensional imaging technology to observe the relationship between primary pancreatic cancer and lymphatic vessel networks, revealing peritumoral lymphangiogenesis, laying a technological and morphological foundation for future systematic detection and three-dimensional analysis of lymphatic invasion in tumor microenvironment (TME). 181stric cancer.Lymph node metastasis represents the predominant pattern of gastric cancer dissemination, with lymphangiogenesis emerging as a pivotal contributing factor.The evidence suggests that gastric cancer cells stimulate lymphangiogenesis through the secretion of VEGFC, a process typically facilitated by other regulatory factors, such as transforming growth factor β1 (TGFβ1) and MACC1, in the TME. 182,183Our recent study reported that CRIP1 reshaped the gastric TME to increase the lymphangiogenesis and lymphatic vessel permeability by increasing the amount of secreted VEGFC and CCL5. 184dditionally, tumor-associated lymphangiogenesis and lymph node metastasis is influenced by metabolic factors.Yang et al. demonstrated that the elevation of oxLDL levels in plasma induced the activation of the nuclear factor (NF)-κB pathway through binding with LOX-1, leading to the upregulation of VEGFC expression and subsequently facilitating lymphangiogenesis. 185The rate-limiting enzyme SOAT1 in the cholesterol metabolic pathway exerts effect by upregulating the SREBP1 and SREBP2 expression. 186Furthermore, recent studies have also reported several factors that impede lymphangiogenesis in gastric cancer.Among them, kallistatin exerts its inhibitory effects on lymphangiogenesis and lymphatic node metastasis by downregulating the expression and secretion of VEGFC through the LRP6/IKK/IκB/NF-κB pathway. 187[190] Colorectal cancer.Colorectal cancer, a prevalent gastrointestinal malignancy, frequently progresses to lymph node metastasis.Lymphangiogenesis indicates a higher risk of local recurrence and poorer prognosis in patients with colorectal cancer. 191Metastasisassociated protein 1 has been demonstrated to induce VEGFC expression and promote lymphangiogenesis in colorectal cancer. 192Moreover, Xiang's team found that colorectal cancerderived exosomes promoted lymphangiogenesis in sentinel lymph nodes through IRF-2, which induced VEGFC expression in macrophages. 193CCBE1, expressed and secreted by colorectal cancer cells and cancer-associated fibroblasts, facilitated lymphangiogenesis through the promotion of VEGFC proteolysis and maturation, while its activity was negatively regulated by TGFβ signaling. 194The development of therapeutic approaches targeting lymphangiogenesis for the treatment of colorectal cancer is currently ongoing.Qingjie Fuzheng Granule and Pien Tze Huang exhibit inhibitory effects on tumor growth and lymphangiogenesis via the PI3K/AKT/VEGFC pathway. 195,196In addition, an ethanol extract of Hedyotis diffusa Willd suppresses VEGFC-stimulated LEC migration and tube formation while concurrently downregulating the expression of downstream molecules involved in the VEGFC/ VEGFR3 signaling pathway, such as MMP2, MMP9, cyclin D1, and CDK4. 197nitourinary cancer Bladder cancer.Bladder cancer is a highly prevalent malignancy in the genitourinary system. 164Higher lymph vessel density has been correlated with decreased metastasis-free survival of patients with bladder cancer. 198Changhao Chen and colleagues found that the lncRNA LINC01296, termed LNMAT1, epigenetically induced CCL2 expression in bladder cancer cells, recruiting macrophages to the TME, which induced lymphangiogenesis via VEGFC secretion. 199Afterward, the team identified another lncRNA known as LNMAT2 in exosomes secreted by bladder cancer cells that stimulated LEC tube formation and migration via epigenetically acting on the PROX1 promoter to upregulate the expression. 200Subsequently, Chen et al. discovered that EV-mediated ELNAT1 also promoted lymphangiogenesis via the transcriptional upregulation of SOX18 expression in human LECs via SUMOylation motification. 201In addition, overexpression of the lncRNA BLACAT2 stimulated lymphangiogenesis by binding WDR5, the core subunit of human H3K4 methyltransferase complexes, to increase the expression of VEGFC. 202The novel circRNA circEHBP1 mediated TGFβR1 overexpression and activated the TGFβ/ SMAD3 signaling pathway in bladder cancer cells, thereby promoting the secretion of VEGFD to drive lymphangiogenesis. 203he inhibition of lymphangiogenesis is a promising therapeutic Prostate cancer.The incidence of prostate cancer is highest among all the malignancies affecting the male reproductive system.Previous studies have demonstrated that elevated lymphatic vessel density in conjunction with increased VEGFC expression was indicative of metastasis and unfavorable prognosis in patients diagnosed with prostate cancer. 205Lysophosphatidic acid increased the expression of VEGFC and promoted lymphangiogenesis by upregulating calreticulin in prostate cancer cells. 206elevant studies are currently ongoing to investigate the potential of targeted lymphangiogenesis therapy in managing lymph node metastasis and distant metastasis of prostate cancer.The administration of a VEGFC ligand trap (soluble VEGFR3) or anti-VEGFR3 antibody (mF4-31C1) resulted in a significant reduction in the lymphangiogenesis, as well as metastasis to regional lymph nodes and distant organs. 207Yano et al. revealed that glucocorticoids suppressed lymphangiogenesis by downregulating the expression of VEGFC. 208arian cancer.Ovarian cancer is one of the most aggressive gynecological cancers and is associated with poor prognosis.High lymphatic vessel density has been found to be significantly associated with lymph node metastasis and recurrence in patients with ovarian cancer. 209Sapoznik et al. found that folliclestimulating hormone enhanced the interaction between LEDGF and the VEGFC promoter, thereby increasing VEGFC expression and promoting lymphangiogenesis. 210Additionally, the overexpression of Her-2/NEU increased the endothelial permeability and facilitated lymph node metastasis by upregulating the expression of VEGFC. 211Cheng and his colleagues found that hypoxia-induced secretion of HIF-1α facilitated lymphangiogenesis and expedited metastasis through the ALKBH5/m6A-ITGB1/ FAK signaling pathway. 212Other factors modulate lymphangiogenesis to influence the rate of lymph node metastasis in ovarian cancer.For example, SPARC, a Ca 2+ -binding matricellular glycoprotein, has been demonstrated to inhibit lymphangiogenesis by downregulating VEGFC and VEGFD expression. 213rvical cancer.Patients with cervical cancer and lymph node metastasis face a dismal prognosis, and lymphangiogenesis promotes the dissemination of cervical cancer cells to regional lymph nodes.Chen et al. found that TNFα promoted lymphangiogenesis by VEGFC-mediated activation of the AKT and ERK pathways, which was suppressed by MAZ51, a VEGFR3 inhibitor. 214PTPRM, which has been identified as an independent prognostic factor of patients with cervical cancer, can induce VEGFC-dependent lymphangiogenesis. 215Upregulated expression of FASN and FABP5, which both play important roles in lipid metabolism, has been positively correlated with the lymph node metastasis of cervical cancer. 216,217As a pivotal enzyme in lipid metabolism, FASN stimulated the secretion of PDGF-AA and IGFBP3 by cervical cancer cells, thereby facilitating lymphangiogenesis and promoting metastasis. 216Furthermore, the upregulation of FABP5 reprogrammed fatty acid metabolism, leading to an increase in intracellular fatty acids that activated the NF-κB pathway, resulting in lymphangiogenesis in cervical cancer. 217dditionally, exosomal miR-221-3p secreted by cervical cancer cells was transferred to LECs, thereby activating the ERK and AKT pathways through downregulation of VASH1 and promoting lymphangiogenesis. 218A recent study reported that circVPRBP interacted with RACK1 and shielded the S122 O-GlcNAcylation site, thereby inducing RACK1 degradation, which subsequently suppressed galectin 1-mediated lymphangiogenesis and lymph node metastasis in cervical cancer. 219pillary thyroid cancer.Lymphangiogenesis has been demonstrated to facilitate lymph node metastasis in papillary thyroid cancer.Choi et al. found that increased lymphatic vessel density, as assessed by high PDPN and VEGFR3 expression, was significantly associated with the incidence of lymph node metastasis in the papillary thyroid cancer context. 220Additionally, recurrent papillary thyroid cancer exhibited higher peritumoral lymphatic vessel density than nonrecurrent thyroid cancer. 221oreover, lncRNA MFSD4A-AS1 functioned as a competing endogenous RNA to disrupt miRNA-mediated VEGFA/C repression and activated TGFβ signaling, thereby promoting lymphangiogenesis. 222lanoma.Melanoma is an extremely malignant cutaneous cancer with a high propensity for metastasis, predominantly through lymph node metastasis.The prognostic significance of lymphatic vessel density in melanoma has been documented, with higher densities associated with a poorer prognosis. 223elanoma-derived melanosomes facilitate the transfer of let-7i to LECs, thereby triggering type I IFN signaling and promoting lymphangiogenesis. 224Moreover, melanoma cells secrete extracellular vesicles enriched with NGFR, which promotes lymphangiogenesis and facilitate cancer cell adhesion through the induction of ERK kinase activity, activation of NF-κB, and upregulation of ICAM-1 expression in LECs. 225The high expression of CD147 within melanoma cells has been reported to stimulate lymphangiogenesis through the upregulation of PROX1 expression. 226Additionally, both Adrenomedullin and Apelin have been demonstrated to enhance lymphangiogenesis in melanoma. 227,228n the context of melanoma, claudin-3 exerted an inhibitory effect on lymphangiogenesis through the downregulation of VEGFC and PI3K signaling pathways. 229Additionally, various inhibitors targeting lymphangiogenesis have been documented, including rapamycin and a novel 2-aminobenzimidazole derivative called MFB, which effectively suppressed lymphangiogenesis by downregulating VEGFs. 230,231Interestingly, Sasso et al. demonstrated that the induction of lymphangiogenesis through VEGFC increased the efficacy of immunotherapy, thereby presenting a novel therapeutic strategy for cancer treatment targeting lymphangiogenesis. 232zheimer's disease Alzheimer's disease is the most common form of dementia, in which impaired amyloid-β clearance from the brain is the core etiology.233 Meningeal lymphatics are involved in the clearance of molecules, including amyloid-β (as explained in "Lymph absorption and transport in meningeal lymphatic vessels"), and their dysfunction is an aggravating factor in Alzheimer's disease pathology.234 Modulation of lymphatic vessel function might be a novel therapeutic strategy for Alzheimer's disease.Recent studies have shown that VEGFC treatment promoted meningeal lymphangiogenesis in transgenic mice, which decreased the level of soluble amyloid-β in cerebrospinal fluid.234,235 Moreover, the therapeutic delivery of VEGFC enhanced meningeal lymphatic function to increase the clearance rate of amyloid-β by monoclonal antibodies.236 Ocular hypertension and glaucoma Glaucoma is the foremost cause of irreversible blindness, with elevated intraocular pressure being the most crucial risk factor.Ocular lymphatic vessels and Schlemm's canal play pivotal roles in regulating intraocular pressure under the physiological condition (as outlined in "Lymph absorption and transport in ocular lymphatic vessels").VEGFC/VEGFR3 plays a crucial role in the development and maintenance of Schlemm's canal. Theapplication of recombinant VEGFC resulted in the promotion of Schlemm's canal growth in mice and led to a tendency toward decreased intraocular pressure.237 Kim et al. found that Schlemm's canal integrity was maintained via the interconnected and coordinated functions of ANG/TIE2 signaling, aqueous humor outflow and PROX1 activity.Deletion of ANG1/ANG2 or TIE2 severely impaired the integrity of Schlemm's canal, resulting in elevated intraocular pressure, retinal neuron damage, and impaired retinal ganglion cell function, all hallmarks of primary open-angle glaucoma.238 Recently, SVEP1 was identified as a modifier of TEK expression during Schlemm's canal development and affected the penetrance and severity of primary congenital glaucoma disease.239 However, the underlying mechanism through which ocular lymphatic dysfunction contributes to the pathogenesis of glaucoma remains unclear, and further investigations are needed to gain a comprehensive understanding.

Obesity and lipedema
Obesity is characterized by excessive adipose tissue accumulation resulting from an imbalance between energy intake and expenditure. 240Adipose tissue is no longer considered solely an energy storage depot but has been recognized as an active endocrine organ that secretes numerous adipokines and proinflammatory cytokines. 241Obesity is widely acknowledged to be a significant clinical risk factor for the development of lymphedema.Obesity-induced chronic inflammation, fibrosis, and increased adipose tissue deposition detrimentally impact lymphatic vessel function, thereby exacerbating the inflammatory response and precipitating the development of lymphedema. 242A decrease in lymphatic vessel density has also been observed in murine models of obesity. 243Therefore, maintaining a normal number and function lymphatic vessels may potentially ameliorate the metabolic disruption in obese patients.The study conducted by Chakraborty et al. substantiated this possibility, demonstrating that an increased VEGFD-induced lymphangiogenesis in adipose tissue mitigated the obesity-related immune accumulation and increased the metabolism. 244Subsequently, they observed that VEGFD-induced lymphangiogenesis in adipose tissue resulted in a decrease in the macrophage populations and accelerated systemic fatty acid utilization, thereby facilitating the remodeling of the inflammatory response. 245ipedema, often misidentified as lymphedema or obesity, is a chronic progressive disease characterized by disproportional adipose tissue distribution and limb pain, predominantly in women.Patients with lipedema present with features of lymphedema, particularly in advanced stages, which may arise from the synergistic effects of lymphatic abnormalities and lipid accumulation.Amann et al. employed fluorescence microlymphography and thus identified beadlike dilated lymphatic vessels in individuals with lipedema. 246In addition, Lohrmann et al. revealed functional and morphological aberrations in the lymphatic vessels of lower extremities in lipedema patients. 247In terms of lymphatic abnormalities as potential etiologies for lipedema, the leakage of lymph fluid has been shown to promote adipocyte proliferation significantly. 248However, imbalanced and prolonged adipose tissue expansion may contribute to abnormal contraction of collecting lymphatic vessels, as observed by Blum et al. in mice chronically fed a high-fat diet. 249Expanded adipocytes secreted certain lymphangiogenic factors, such as VEGFC, VEGFD and ANG2. 250In light of these findings, further investigations are warranted to elucidate the intricate association between lipedema and lymphatic vessel impairment.

Diabetes mellitus
Diabetes mellitus is a chronic metabolic disorder characterized by hyperglycemia and abnormal carbohydrate, fat, and protein metabolism. 251Impaired lymphangiogenesis is a complication of diabetes mellitus.Wenstedt et al. observed that saltsensitive increases in blood pressure in individuals with Type 1 diabetes may be linked to the absence of macrophages and thus reduced lymphangiogenesis. 252Wu et al. demonstrated that diabetes-induced ROS-activated c-Src-dependent phosphorylation of VEGFR3 and upregulation of epsin expression, causing VEGFR3 degradation via the interaction between epsin and VEGFR3, ultimately leading to impaired lymphangiogenesis. 253In patients with Type 2 diabetes, increased lymphatic permeability has been demonstrated to lead to lymphatic vessel dysfunction.Scallan et al. initially identified increased permeability in the collecting lymphatic vessels in individuals with Type 2 diabetes, leading to lymphatic leakage.This outcome was attributed to the diminished bioavailability of NO, which was rectified by inhibiting the action of the NOdegrading enzyme phosphodiesterase 3. 254 Similarly, Cifarelli et al. observed that the downregulation of VEGFC/VEGFR2/AKT after CD36 silencing resulted in VE cadherin degradation and subsequently increased lymphatic vessel permeability in individuals diagnosed with Type 2 diabetes. 255The prolonged hyperglycemia associated with diabetes can cause oxidative stress, advanced glycation end-product formation, and inflammation, which can lead to significant damage to various organs, such as the kidneys and eyes. 256Recent studies have demonstrated the involvement of lymphatic vessels in the pathogenesis of these complications.
Diabetic kidney disease.Hyperglycemia and other metabolic abnormalities in diabetes can lead to ultrastructural and functional changes in the glomeruli and tubules, eventually causing diabetic kidney disease. 257A study by Kim et al. showed that inhibiting lymphangiogenesis alleviated lipid overload induced by diabetic kidney disease and relieved symptoms. 258Mechanistically, this outcome was caused by lymphangiogenesis in diabetic kidney disease, which promoted tubulointerstitial fibrosis in the kidneys. 259Subsequently, Hwang et al. demonstrated that the mitigation of kidney damage in diabetic kidney disease was achievable through targeted inhibition of lymphangiogenesis using a specific VEGFR3 inhibitor. 260Collectively, these studies indicated that targeting lymphangiogenesis-related factors may be a viable therapeutic strategy for diabetic kidney disease.Diabetic retinopathy.Diabetic retinopathy is a common ocular complication of diabetes that can eventually lead to vision loss. 261berrant lymphangiogenesis has been observed to be involved in the pathogenesis of diabetic retinopathy. 262,263Gucciardo et al. observed that the microenvironment of diabetic retinopathy can promote pathological lymphangiogenesis. 264Korhonen et al. identified significant enrichment of genes and signaling pathways associated with lymphatic vessel development in tissues obtained from patients diagnosed with diabetic retinopathy through mRNA sequencing and Gene Ontology and pathway enrichment analyses. 265However, the mechanisms underlying pathological lymphangiogenesis contributions to the pathogenesis of diabetic retinopathy are currently unknown, and further investigation is required.
Diabetic wound healing.Lymphatic dysfunction in diabetes mellitus may lead to the impaired transport of immune cells, growth factors, and other molecules involved in tissue regeneration, resulting in delayed wound healing. 266Several studies have shown that the activation of lymphangiogenesis facilitates diabetic wound healing. 267,2680][271] In addition, some lncRNAs have also been shown to promote diabetic wound healing by promoting lymphangiogenesis. 272,273Considering these findings, researchers engineered a new tissue material to induce lymphangiogenesis, paving the way for the development of novel strategies to facilitate diabetic wound healing. 274und healing Wound healing is a complex and dynamic process that involves a series of overlapping stages to restore tissue integrity and function.It encompasses revascularization, inflammation, innervation, and remodeling.275 Activation of lymphangiogenesis pathways is considered an effective strategy to facilitate healing of chronic wounds and alleviate tissue inflammation, which is mainly induced by VEGFC/VEGFR3 signaling.276 During the wound healing process, platelets promote the release of VEGFC, thereby facilitating lymphangiogenesis.Immune cells, proteins, and fluids are transported out of the wound area through newly formed lymphatic vessels.277 Stabilized expression of HIF-1α in a wound also promotes the expression of VEGFC, thereby regulating lymphangiogenesis.278 Hosono et al. found increased expression of COX-2 and mPGES-1 at wound sites and showed that these proteins promoted the expression of VEGFC and induced lymphangiogenesis.279 Notably, impaired or insufficient lymphangiogenesis may result in hindered or incomplete wound healing.280 In addition, lymphatic vessels form a specific niche for the regeneration of diverse tissues.Dermal capillary lymphatic vessels regulate the regeneration of hair follicles by dynamically interacting with stem cells.Mechanically, activated hair follicle stem cells express ANG-like protein 4 to promote capillary lymphatic vessel remodeling and reduce lymph drainage to initiate hair follicle regeneration.281,282 Skeletal lymphatic vessels mediate the regeneration of bone and hematopoietic stem cells under genotoxic stress conditions. Bisas et al. recently found that skeletal lymphangiogenesis specifically recruited and enhanced the proliferation of mature Myh11 + CXCR4 + pericytes via secreting CXCL12, inducing their differentiation into osteoblasts and contributing to bone regeneration.283 Moreover, they found through experiments that inhibition of skeletal lymphangiogenesis reduced the proportion of hematopoietic stem cells, indicating a particularly potent regenerative function of lymphatic vessels.283 Additionally, lymphatic vessels have been shown to be indispensable for heart regeneration after myocardial infarction.Gancz et al. found that the lack of cardiac lymphatic vessels impaired heart regeneration by preventing VEGFC/ VEGFR3 signaling in zebrafish.284 Epicardium-derived Adrenomedullin signaling in mice stimulated regenerative cardiac lymphangiogenesis via lateralization of CX43, which is a potential therapeutic target for cardiac regeneration.285 Transplant rejection Types of transplant rejection include host-versus-graft disease (HVGD) and graft-versus-host disease (GVHD). HVG is an immune-mediated response wherein the recipient's immune system discerns the transplanted organ as an exogenous entity and subsequently initiates an immunological assault against it.286 Lymphatic vessels play crucial roles as conduits for antigenpresenting cells and soluble antigens, thereby facilitating their transport.Surgical intervention resulting in disrupted lymphatic vessel integrity can lead to impaired lymphatic drainage, consequently impacting both acute and chronic rejection responses after transplantation.Moreover, lymphangiogenesis exhibits heterogeneity in transplant rejection among organs.287 During ischemia-reperfusion injury in rat heart allografts, activation of the VEGFC/VEGFR3 axis induced lymphangiogenesis and subsequently exacerbated allograft inflammation.288 After the transplantation of minor antigen sex-mismatched murine heart grafts, an increase in the lymphatic flow index was associated with higher lymphatic vessel density and inflammatory infiltration of T cells and macrophages.289 VEGFR3 is involved in the trafficking of immune cells from peripheral tissues to secondary lymphoid organs by regulating the production of CCL21 in allogeneic lymphatic vessels.Adenovirus VEGFR3-Ig inhibited lymphangiogenesis and attenuated cardiac allograft rejection by reducing the number of transported and activated antigen-presenting cells. 290Additionally, Kerjaschki et al. demonstrated that lymphangiogenesis contributed to nodular mononuclear infiltration while also played a role in sustaining a potentially detrimental alloreactive immune response in hosts after renal transplant.291 Mechanistically, the nodular infiltrates contained a significant number of CCR7-positive immune cells, which appeared to be attracted by SLC/CCL21 produced and released by LECs.291 However, it has been suggested that lymphangiogenesis plays a pivotal role in enhancing the survival of allografts.Hyaluronic acid has been identified to induce inflammation and contribute to the development of chronic allograft rejection. 292Cui et al. found that stimulation of lymphangiogenesis using VEGF-C156S, a mutant form of VEGFC selectively binding to VEGFR3, resulted in the attenuation of an established rejection response and increased the clearance of hyaluronic acid from lung allografts.293 Pedersen et al. found that lymphangiogenesis in a mouse model of renal transplant rejection extended the lifespan of the recipients, which may have been related to immune tolerance promoted by lymphangiogenesis.294 GVHD is an immune response of immunocompetent cells in the graft against histocompatibility antigens in the host, resulting in damage to the host.Acute GVHD is triggered by alloreactive T cells that damage peripheral tissues and lymphoid organs.295 Gehlsen et al. found that lymphangiogenesis is involved in the pathogenesis of ocular GVHD.296 In addition, Mertlitz et al. found that acute GVHD was associated with lymphangiogenesis in murine allo-HSCT models and in intestinal tissue biopsy samples taken from patients, while the administration of anti-VEGFR3 antibodies suppressing lymphangiogenesis ameliorated GVHD and prolonged the survival in murine models.297

THERAPEUTIC INTERVENTIONS AND CLINICAL RESEARCH PROGRESS OF LYMPHANGIOGENESIS
Many past and present efforts have been made to study and reveal the interventions of lymphangiogenesis under physiological and pathological conditions.In the following section, we summarize the known promoters and inhibitors of lymphangiogenesis, list therapeutic interventions, and describe the progress in their clinical applications.

Interventions of lymphangiogenesis VEGFs
Agonistic effects of VEGFs.Among VEGF family members, VEGFC and VEGFD are the best-characterized and specific growth factors for lymphatic vessels.Generally, VEGFC and VEGFD function as ligands that bind receptors on the LEC membrane and then activate downstream signaling cascades to promote lymphangiogenesis.VEGFC and VEGFD both bind to the receptor VEGFR3, which is commonly expressed by LECs. 298,299After binding of VEGFC or VEGFD, VEGFR3 dimerizes and is phosphorylated, leading to the activation of its cytoplasmic tail tyrosine kinase activity.The phosphorylation of VEGFR3 leads to the recruitment of some important proteins, such as GRB2, CRK, and SHC, which mediate the activation of downstream signaling pathways, including the conserved PI3K/AKT, MAPK/ERK, and MAPK/JNK pathways, etc. 300,301 Activation of these molecular signaling cascades promotes the initiation of a series of cellular biological behaviors, such as LEC proliferation and migration and vessel sprouting (Fig. 13).VEGFA has been identified as the angiogenic factor acting via VEGFR1 and VEGFR2.3][304][305] On one hand, VEGFA could function on VEGFR1/2 expressed by LECs and promote lymphanigongenesis. 304,305On the other hand, VEGFA could indirectly induce lymphangiogenesis via recruitment of VEGFR1 + bone marrow-derived macrophages which in turn release both hemangiogenic and lymphangiogenic growth factors. 302,303rgeted inhibitors of VEGF signaling.Antibody drugs: Bevacizumab is a well-characterized monoclonal antibody of VEGFs and is used as an anti-angiogenic drug for various types of cancer.Moreover, some clinical trials have been carried out to evaluate its anti-lymphangiogenic effects. 306Dumond et al. reported a new VEGFC antibody named 1E9 that significantly inhibited VEGFR3 signaling activation in LECs. 307Similarly, VGX-100, another highly specific monoclonal antibody, targeted VEGFC and impaired VEGFC-VEGFR2/3 signaling activation. 308A soluble fusion protein VEGFR3-immunoglobulin that bound VEGFC and inhibited VEGFR3 signaling has also been reported, and their effects in inhibiting tumor lymphangiogenesis and metastasis were remarkable. 309To target VEGFRs, blocking VEGFR3 signaling with VEGFR3 antagonist antibodies effectively inhibited angiogenesis, lymphangiogenesis, and tumor growth in an orthotopic spontaneous breast cancer metastasis model. 310mall-molecule inhibitors: The FDA has approved several small-molecule inhibitors of VEGFRs because they significantly prolong the survival of cancer patients.For instance, pazopanib is an orally available small-molecule inhibitor of VEGFRs, including VEGFR1, VEGFR2, and VEGFR3.Pazopanib showed favorable inhibitory effects on tumor growth, lymph node metastasis, and tumor lymphangiogenesis in an orthotopic colorectal cancer model. 311Sunitinib is a small-molecule inhibitor that targets VEGFRs, PDGFRs, and c-Kit. 312Sunitinib treatment markedly reduced pathological corneal lymphangiogenesis and angiogenesis. 313However, Dufies et al. reported that sunitinib treatment also induced lymphangiogenesis in the renal cell carcinoma context by activating VEGFC transcription and stabilizing VEGFC mRNA. 314her inhibitors: Previous studies revealed that inhibition of VEGFC with specific siRNAs reduced the lymphangiogenesis in a murine mammary tumor model. 315,316Additionally, treatment with VEGFC siRNA effectively reduced lymphangiogenesis and significantly increased the survival rate of tumor-bearing mice.Fucoxanthin, a multifunctional natural non-pro-vitamin A carotenoid, has been shown to decrease tumor-associated lymphangiogenesis, indicating a potential anti-lymphangiogenic agent for use in cancer therapy. 317Shikonin, another natural compound isolated from the traditional Chinese medicinal herb Lithospermum erythrorhizon, inhibited lymphangiogenesis in a dose-and time-dependent manner. 318Curcumin, a natural dietary compound derived from turmeric, also inhibited lymphangiogenesis in vitro and in vivo by inhibiting the expression of VEGF receptors (Table 4). 319G Agonistic effects of ANG.ANG and its receptors were first found to be important modulators in blood vessel growth, maturation, and stability.The two ANG receptors, called TIE1 and TIE2, were also reported to be expressed in LECs.After interaction with TIE on LECs, ANG induced the formation of TIE receptor complexes and then mediated cell behavior via activation of the PI3K/AKT pathway.AKT subsequently phosphorylated FOXO1, causing its nuclear exclusion and reducing the expression of FOXO1 downstream genes.320 Some findings revealed that ANG1 promoted lymphangiogenesis dependent on VEGFR3, indicating a difference in effects between ANG proteins.321 Interestingly, a recent study revealed that VEGFC induced ANG2 secretion from LECs and then stabilized VEGFR3 expression via the activation of ANG2/TIE/PI3K signaling, revealing cross-talk between the VEGFC and ANG2 signaling pathways.322 Additionally, ANG2 also functioned independent of its binding to TIE receptors.In this scenario, ANG2 bound β1 integrin and activated Src and FAK, leading to RhoA activation.The activation of RhoA led to the phosphorylation of the Fig. 13 Lymphangiogenesis-mediating proteins ligands and their receptors.Schematic diagram showing the main promoters of lymphangiogenesis with soluble ligands or interacting proteins present outside the cell and the transmembrane receptors expressed by lymphatic endothelial cells (LECs) at 7the cell surface.VEGFC vascular endothelial growth factor C, VEGFD vascular endothelial growth factor D, VEGFR3 vascular endothelial growth factor receptors 3, ANG angiopoietin, TIE, tunica interna endothelial cell kinase, EGF epidermal growth factor, EGFR epidermal growth factor receptor, FGF fibroblast growth factor, FGFR fibroblast growth factor receptor, HGF hepatocyte growth factor, PDGF platelet-derived growth factor, PDGFR platelet-derived growth factor receptor, IGF insulin-like growth factor, IGFR insulin-like growth factor receptor, AM adrenomedullin.Created with BioRender.comdownstream effectors ROCK and formins, thereby regulating lymphangiogenesis.323 Targeted inhibitors of ANG signaling.Antibody drugs: Considering the effects of ANG2 on angiogenesis and lymphangiogenesis, several neutralizing antibodies for this signaling pathway have been designed and synthesized.These antibodies include trebananib, CVX-060, AMG 780, MEDI3617, Nesvacumab, Aflibercept, CVX-241, AZD5180, and 18E5.Among these neutralizing antibodies, MEDI3617, AZD5180, and 18E5 have been reported to show significant inhibitory effects on lymphangiogenesis.324,325 Small-molecule inhibitors: Regorafenib is a novel oral multikinase inhibitor that can inhibit various kinases, including VEGFRs, TIE, PDGFRs, c-Kit, BRAF, etc. 326 In orthotopic colon tumor models, regorafenib treatment significantly decreased the density of lymphatic vessels in tumors.327 Other inhibitors: A previous study showed that siRNAmediated ANG2 knockdown markedly inhibited corneal lymphangiogenesis. 76 ecently, some multifunctional siRNA nanocapsules have been developed to deliver siRNA for targeting ANG in glioblastoma, 328,329 which may provide a new direction for delivering siRNA for the treatment of abnormal lymphangiogenesis (Table 4).

Epidermal growth factor (EGF)
Agonistic effects of EGF.EGF belongs to a group of growth factors that specifically bind EGFR and activate EGFR signaling, 330 which has been reported to participate in regulating skin lymphangiogenesis.EGF notably facilitated pathological lymphangiogenesis in melanoma, thus supporting the lymph node metastasis of melanoma. 331n summary, the effects of EGF on lymphangiogenesis have been relatively less studied than the effects of other factors and remain to be further investigated in the future.Targeted inhibitors of EGF signaling.Antibody drugs: Some preclinical evidence has shown that monoclonal antibodies targeting EGF signaling could attenuate angiogenesis during cancer progression. 332,333However, evidence showing the inhibitory role of these monoclonal antibodies on lymphangiogenesis is lacking and further exploration is needed.Small-molecule inhibitors: Afatinib, erlotinib, gefitinib, lapatinib, and vandetanib are representative small-molecule inhibitors of EGFR that prevent signal transduction after ligand-receptor binding and EGFR dimer formation.Among these drugs, lapatinib has been reported to attenuate tumor lymphangiogenesis and angiogenesis (Table 4). 334F2.FGF2 has been reported to exert a profound effect on lymphangiogenesis.In the mouse cornea, FGF2 promoted lymphangiogenesis in a dose-dependent manner and enhanced the secretion of VEGFC from vascular endothelial and perivascular cells to facilitate lymphangiogenesis. 335Additionally, FGF2 functions by binding the cell membrane LYVE1 with high affinity, which subsequently induces lymphangiogenesis. 336patocyte growth factor (HGF).HGF is a heparin-binding glycoprotein that was first shown to mediate liver regeneration.HGF functions by interacting with HGFR (also known as c-Met) to regulate lymphangiogenesis.Supplementation of HGF into the LEC culture medium promoted lymphangiogenesis, while inhibition of HGFR with an antagonist reduced the lymphangiogenesis. 337GF.PDGFs are secreted dimeric glycoprotein ligands with biological activities mediated by three forms of tyrosine kinase receptors encoded by two gene products, PDGFR-α and PDGFRβ. 338,339PDGF-BB functions as a lymphangiogenic factor and directly binds PDGFR-β expressed on LECs to induce lymph vessel growth. 340e insulin growth factor (IGF).IGF signaling pathway is composed mainly of IGFs (IGF1 and IGF2), IGFRs (IGFR1, and IGFR2), and IGF-binding proteins (IGFBPs). 341,342IGFs bind IGFRs to initiate their effects, while IGFBPs interact with IGFs to modulate IGF stability and activity.IGFRs are expressed by LECs in both humans and mice.In vivo, administration of IGFs stimulated lymph vessel network expansion, while in vitro treatment with IGFs increased the lymphangiogenesis via activation of downstream ERK and PI3K/AKT signaling. 343In the future, the development of IGFs, IGFRs or IGFBPs antagonists may be an important approach for treating abnormal lymphangiogenesis.
WNT.Among the WNT family members, WNT5A and WNT5B have been reported to exert a positive effect on lymphangiogenesis. 344,345WNT5A regulates dermal lymphangiogenesis mainly through the noncanonical β-catenin-independent signaling pathway. 346Cancer cell-derived WNT5B modulated lymphangiogenesis and lymphatic permeability through the activation of both canonical and noncanonical WNT signaling pathways. 344hrinB2.EphrinB2, a transmembrane ligand of the Eph receptor EphB4, controls cell migration and cytoskeletal organization in many different cell types and tissues. 347,348Evidence has shown that EphrinB2 and EphB4 are simultaneously expressed by endothelial cells and promote sprouting behavior to induce angiogenesis and lymphangiogenesis. 349,350Mechanistically, the binding of EphrinB2 to EphB4 promoted the activation of the small GTPases Rac1, AKT, and ERK and promoted VEGFC/VEGFR3 downstream signaling.In capillary lymphatic vessels of adult mouse corneas, the EphrinB2/EphB4 axis functioned in the formation and maintenance of funnel-shaped valves, indicating that this axis might be an ideal target for regulating corneal lymphangiogenesis. 351renomedullin.Adrenomedullin, a well-known vasodilator, is also an important regulator of lymphangiogenesis.Adrenomedullin functions by binding its specific receptor, CALCRL.Ablation of Adrenomedullin/CALCRL signaling impedes the activation of ERK signaling, leading to the formation of abnormal jugular lymphatic vessels. 63Blockade of Adrenomedullin/CALCRL signaling after normal lymphatic vessel formation resulted in impaired permeability and function in intestinal, corneal, and dermal lymphatic vessels. 352In several types of cancers, Adrenomedullin significantly increased tumor-associated lymphangiogenesis. 353,354oactive lipids.Bioactive lipids are important regulators in the body; they include 1) arachidonic acid (AA) and its metabolites, such as prostaglandins (PGs), thromboxane (TXA), and leukotrienes (LTs); 2) S1P, a metabolic product of sphingolipids; and 3) lysophosphatidic acid (LPA).These bioactive lipids have been shown to regulate lymphangiogenesis under certain pathological conditions.We summarize the function of these common bioactive lipids in lymphangiogenesis (Fig. 14).
PGs. PGs are common metabolites of AA generate through the action of phospholipase A2, cyclooxygenases (COXs), and the respective prostanoid synthases.PGs function by binding their specific receptors, which are often transmembrane G proteincoupled receptors. 355,356In an LPS-induced model of inflammation, COX2-derived PGs enhanced lymphangiogenesis. 357Similarly, in acute colitis induced by DSS, PGE2/PGE receptor (EP) 4 signaling stimulates lymphangiogenesis to repair damaged mucosa.PGE2-EP4 activation on tumor cells and TAMs increased the amount of VEGFC and VEGFD secreted from these cells and then stimulated LEC lymphangiogenesis. 358Tumor-derived PGE2 also directly acted on LECs to activate EP4 and VEGFR3 and ultimately induced lymphangiogenesis. 359A2.TXA2 is an unstable metabolite of AA produced by the reciprocal action of COX and TX synthase. 360,361TXA2 plays a regulatory role by binding thromboxane prostanoid (TP), a transmembrane G protein-coupled receptor.TXA2-TP signaling facilitates lymphangiogenesis by acting on macrophages and T cells during inflammation.TP-positive macrophages and T cells infiltrate inflamed tissue and produce VEGFC and VEGFD after stimulation with TXA2.These macrophage-and T-cell-derived VEGFC/D promoted lymphangiogenesis and drainage function in mice with inflammatory stress. 362s.LTs constitute a class of bioactive lipids derived from AA by 5-lipoxygenase (LOX5) and LOX5-activating protein. 363,364LTs also function by binding G protein-coupled receptors.Two G proteincoupled receptors, BLT1 and BLT2, are receptors for LTB4 and are expressed in macrophages, leukocytes, epidermal keratinocytes, and epithelial cells.Evidence from a lymphedema model showed that macrophages are important sources of LTB4 and that inhibition of LTB4 signaling effectively prevents edema. 365,366P.S1P is the phosphorylated form of sphingosine that is formed through the action of sphingosine kinase 1 (SphK1) and SphK2.S1P not only functions intracellularly as a second messenger, but also can be exported extracellularly to serve as a ligand for a family of S1P receptors. 367S1P promotes lymphangiogenesis both in vitro and in vivo through the S1P/Gi/ phospholipase C/Ca 2+ signaling pathways. 368In breast cancer, SphK1-mediated S1P production induced lymphangiogenesis, indicating that SphK1-S1P signaling may be a potential therapeutic target for controlling lymphangiogenesis. 369A.LPA is a low-molecular-weight lipid growth factor that functions by binding to Edg family members. 370LPA is generated through enzymatic cleavage of membrane phosphatidic acid.A series of studies have revealed that LPA lymphangiogenesis by increasing the expression of the important prolymphangiogenic factor VEGFC in targeted cells such as tumor cells and endothelial cells. 371,372RNA.NcRNA transcripts constitute a recently described type of RNA that has been extensively explored in recent decades.Some ncRNAs have been reported to play a clear role in lymphangiogenesis, especially in tumor-associated lymphangiogenesis (Fig. 14).
LncRNAs.LncRNAs are RNA transcripts longer than 200 bases with low protein-coding potential. 373Some lncRNAs play a prolymphangiogenic role intracellularly to enhance the expression of VEGFC, thereby promoting lymphangiogenesis. 374,375Cancer cells also deliver lncRNA-containing exosomes to LECs.The lncRNA cargo internalized by LECs induced lymphangiogenesis both in vitro and in vivo. 376These pieces of evidence implicate lncRNAs as important therapeutic targets for controlling abnormal lymphangiogenesis in patients with cancer (Fig. 14).
CircRNAs.CircRNAs represent a type of novel ncRNA with a covalently circular structure generated from the splicing of pre-mRNAs and interlacing of the 5′ caps and 3′ poly-A tails and are specific messenger RNAs. 377,378The role of circRNAs in lymphangiogenesis was investigated recently.For instance, circEHBP1 served as a miRNA sponge for miR-130a-3p to regulate the TGFβR1/VEGFD axis, leading to increased levels of VEGFD and lymph vessel density in the context of bladder cancer. 203dditionally, some circRNAs are transported from cancer cells to LECs via exosomes.In this manner, cancer cell-derived circRNAs can directly function as intra-LECs to contribute to lymphangiogenesis. 379inical trials of treatments for lymphangiogenesis-related diseases We conducted an electronic search for relevant clinical trials of lymphangiogenesis-related diseases in PubMed.Additionally, relevant clinical trial registration sites, such as ClinicalTrials.govand Netherlands Trial Registry, were comprehensively examined.Literature retrieval was performed in duplicate by two Fig. 14 The role of bioactive lipids and ncRNAs on lymphangiogenesis.a The bioactive lipids derived from the metabolism of arachidonic acid, Sphingosine, phosphatidic acid could regulate lymphangiogenesis through binding their specific GPCRs; b The function model of ncRNAs on lymphangiogenesis.Some ncRNAs were reported to have evident role on lyphangiogenesis, especially in tumor associatedlymphangiogenesis.These ncRNAs could be potential therapeutic targets for controlling abnormal lymphangiogenesis in cancer.GPCRs G Protein-Coupled Receptors, COX cyclooxygenase, PLA2 phospholipase A2, PS prostanoid synthases, TXA thromboxane, LOX5 5-lipoxygenase, S1P sphingosine 1-phosphate, LPA lysophosphatidic acid, ncRNAs noncoding RNAs, lncRNAs long noncoding RNAs, circRNAs circular RNAs, RBPs, RNA binding proteins.Created with BioRender.comindependent reviewers.A total of ten published clinical trials were included in the analysis, among these, seven studies mainly examined the effects of different interventions on lymphangiogenesis-related diseases in human samples, one study focused on evaluating stem cell therapy in lymphedema, 380 one study focused on circulating angiogenic factors in pulmonary tuberculosis in which angiogenesis and lymphangiogenesis were classical features, 381 and one study mainly examined whether PDPN expression correlated with sentinel lymph node metastasis in early squamous cell carcinomas of the oral cavity and oropharynx. 382The characteristics of these studies are listed in Supplementary Table 1.
The ten selected clinical trials had enrolled participants with eight different diseases and conditions.4][385] A few studies recruited participants with other diseases, including lung adenocarcinoma, 386 early squamous cell carcinomas of the oral cavity and oropharynx, Type 1 diabetes, 252 tongue cancer, 387 lower limb lymphedema, lymphangioleiomyomatosis (LAM) 388 and pulmonary tuberculosis.The study with the largest number of participants enrolled patients with centrally located squamous cell carcinoma with cavitary features, and those with brain metastases that were uncontrolled or controlled for less than 2 months were excluded (n = 440).The patients were randomly assigned in a 2to-1 ratio to receive either 12 mg/day of anlotinib (n = 294) or a matched placebo (n = 146).
With regard to the intervention/comparison in the studies, over half of the studies (n = 5) focused on drug (anlotinib treatment for lung adenocarcinoma) and stem cell therapy (using bone marrowderived mononuclear cells in the treatment of lower limb lymphedema), and 1 study focused on dietary interventions such as salt intake.Salt-sensitive blood pressure increases in Type 1 diabetes patients is accompanied by disturbed skin macrophage influx and lymphatic dilation.In an evaluation of the medical treatment of patients with breast cancer, two clinical trials demonstrated that treatment with sunitinib showed favorable effects on tumor vessel modulation and lymphangiogenesis and significantly decreased lymphatic vessel density, as assessed via immunohistochemistry.To assess a lung adenocarcinoma medical treatment, one clinical trial demonstrated that anlotinib suppressed lymphangiogenesis and lymphatic metastasis through a process potentially involving VEGFR3 signaling.Another clinical trial showed that in patients with lymphangioleiomyomatosis, sirolimus stabilized lung function and reduced the level of serum VEGFD, which is a lymphangiogenic growth factor implicated in the pathophysiology of LAM and was associated with a reduction in symptoms and improvement in quality of life.A study of patients with chronic lymphedema showed that cell therapy led to reduced limb circumference and increased pain relief and improved walking ability compared with the results in the control group.
Approximately 40.0%(n = 4) of published clinical trials explored the effects of lymphangiogenesis activators under pathological conditions.One study showed that HER2/neu expression correlated with VEGFC and lymphangiogenesis in lymph node-positive breast cancer patients.Another study demonstrated that pulmonary tuberculosis was associated with elevated circulating levels of VEGFA, VEGFC, and VEGFR2, and angiogenesis and lymphangiogenesis were shown to be classical features of granuloma formation.Recently, the expression of PDPN in cancer cells was demonstrated to promote tumor cell motility and tumor lymphangiogenesis in vitro, and one supplementary clinical trial showed that PDPN expression correlated with sentinel lymph node metastasis in early squamous cell carcinomas of the oral cavity and oropharynx.NRP2 plays an important role in regulating lymphangiogenesis, and findings from a clinical trial for patients with early-stage tongue cancer showed that cytoplasmic NRP2 was associated with metastasis and a poor prognosis.
Although several published clinical trials showed consistent findings and most studies suggested that drug interventions targeting activators or inhibitors suppressed lymphangiogenesisrelated signaling, lymphangiogenesis activators played an important role in attenuating the pathological state.Given the substantial impact of lymphangiogenesis progression on health and disease, a larger sample, longer intervention period, and multicenter clinical trials are needed to examine the safety and efficacy of targeted interventions.

CONCLUSION
Since the discovery of lymphatic vessels exists in organisms, an increasing number of studies have revealed the mapping of lymphatic vessel anatomy and development.In this review, we described the general lymphatic vessel development and regulatory signaling pathways.Meanwhile, organ-specific lymphatic vessel development has also shown heterogeneous processes and signaling regulation catering to tissue development and physiological functions.However, the lymphangiogenic regulatory landscape remains a puzzle.Therefore, further mechanism studies are required to determine the phenotypic differences of lymphatic vessels in diverse developmental stages and tissues, including the key transcriptome and epigenome function.The robust lymph absorption and transport capacity of lymphatic vessels contribute to fluid homeostasis.In addition, lymphatic vessels directly or indirectly participate in immunosurveillance and immune response within diverse tissues and organs.
Lymphatic vessels are actively involved in multiple diseases in humans and alleviate or exacerbate local pathological progression through lymphangiogenesis.Notably, many studies have great interest in exploring lymphangiogenesis in tumors, which actively participates in the process of lymph node metastasis and affects the tumor prognosis and treatment.Moreover, LECs are involve in the regulation of tumor-specific immune response by affecting migration, function, and survival of immune cells.Exploration of crosstalk between LECs and immune cells may be a powerful target to enhance immunosurveillance for tumors in humans.In the future, exploration of the specific markers for tumorassociated lymphangiogenesis assists clinical tracing of metastatic lymph nodes, which may provide the specification for accurate lymph node resection.Targeting lymphangiogenesis is a potential and powerful intervention for restoring lymphatic vessel function and improving disease treatment.Based on these, we systematically review the lymphangiogenic signaling pathways, with specific inhibitors known till now.Moreover, multi-center clinical trials are being carried out to further demonstrate the feasibility and broad prospects of targeting abnormal lymphangiogenesis in a variety of diseases.
In conclusion, we have summarized the heterogeneous characteristics and functions of lymphatic vessels in health and disease conditions and expect to provide comprehensive knowledge for future research to realize translational therapy.

Fig. 3
Fig. 3 The schematic diagram of embryonic lymphatic vessel development.a Beginning at E9.5, VeECs, located at CV and ISVs, transdifferentiate into LEPCs.During E10.5-E15.5, the lymphatic plexus continues to sprouting and migrating, and expanding the primary lymphatic vessel network.Continuing from E15.5 until the early postnatal stage, the primary lymphatic plexus undergoes the maturation events to remodel into the hierarchical lymphatic vessels, comprising of capillary lymphatic vessels, pre-collecting lymphatic vessels, and collecting lymphatic vessels.Capillary lymphatic vessels sense interstitial pressure changes by anchoring filaments to control the opening of button-like junctions.The formation of pre-collecting and collecting lymphatic vessels requires for lymphatic valves morphogenesis and SMCs recruitment to drive lymph drainage; b At E10.5, upregulated VEGFR3 and NRP2 mediate LEPCs sprouting and LECs migration in response to VEGFC stimulation.VEGFC/VEGFR3 is an irreplaceable signaling regulates lymphatic vessel development; c The lymphovenous valve serves as the only connection of the lymphatic-venous system to prevent blood backflow.Platelet dynamically regulated lymphovenous hemostasis via interacting with LECs to activate CLEC2/PDPN signaling pathway to maintain platelet aggregation; d Under the stimulation of OSS, the differentiation of valve-forming cells prepares to proliferation, elongation, and protrusion.Moreover, ECM deposition and selective SMCs coverage further promote lymphatic vessel maturation.Ex embryonic day x, VeECs venous endothelial cells, CV cardinal vessel, ISVs intersomitic veins, LECs lymphatic endothelial cells, LEPCs lymphatic endothelial progenitor cells, VEGFC vascular endothelial growth factor C, VEGFR3 vascular endothelial growth factor receptor 3, NRP1/2 neuropilin 1/2, CLEC2 c-type lectin-like receptor 2, PDPN podoplanin, OSS oscillatory shear stress, MCP1 monocyte chemotactic protein 1, PDGFB platelet-derived growth factor B, ECM extracellular matrix, SMCs smooth muscle cells.Created with Adobe Illustrator : The right subcardinal veins-derived LECs outgrow ventrolaterally to form retroperitoneal lymph sacs.Subsequently, mesenteric lymphatic vessels gradually sprout from retroperitoneal lymph sacs and go along the established mesenteric blood vessels at the left region of the dorsal mesentery.E13.5:A population of the hemogenic endothelium-derived c-Kit + progenitor cells incorporates into mesenteric lymphatic vessels via lymphvasculogenesis.E14.5-E15.5:The mesenteric lymphatic vessels continue expanding and forming intestinal wall lymphatic vessels, filling the submucosa along the branch trail of the arteries.E17.5-P10:The mesenteric lymphatic vessels sprout into the majority of the villus and form the mature lacteals.
and are connected by anchoring filaments to the interstitial tissue.Overlapping endothelial cells build flap-like mini-valves, ensuring one-way interstitial fluid, macromolecule, and immune cells flow into the vessels.These capillary lymphatics in the most tissues are interconnected through discontinuous button-like junctions.Additionally, the integrity of LEC junctions is regulated by two different types of cell-cell junctions: adherens junctions and tight junctions.

Fig. 4
Fig. 4 The lymphatic vessels in meninge and eyes.a The meningeal lymphatic vessels are mainly located at the dural region abut to the cranium, and developing along the cerebral vessels and nerves.Meningeal lymphatic vessels enter the nasal submucosal interstitium traveling through cribriform plate and form nasal lymphatic vessels extracranially, partly participating in the extracranial CSF drainage; b The meningeal lymphatic vessels exchange CSF with glymphatic system at subarachnoid space and eventually drain it into dcLNs; c SC abuts juxtacanalicular region of the TM, consisting of inner and outer wall constituted by heterogeneous endothelial cells.The inner wall could sense flow and transport aqueous humor into the SC and further drain to downstream episcleral veins; d The ocular surface lymphatic vessels originate from the nasal canthus and encircle laterally along the corneal limbus and the bulbar conjunctiva.CSF cerebrospinal fluid, dcLNs deep cervical lymph nodes, SC Schlemm's canal, TM trabecular meshwork.Created with Adobe Illustrator

Fig. 7
Fig. 7 The schematic of lymphatic vessels development in zebrafish.a Zebrafish possess an extensive lymphatic vessel network throughout the body.Specialized lymphatic vessels development in zebrafish includes facial lymphatic vessel development (b), intestinal lymphatic vessel development (c), and trunk lymphatic vessel development (d); b The facial lymphatic vessels of zebrafish undergo a step-wise assembly from 1.5 dpf to 4 dpf.The FLS are derived from the CCV beginning to form along the PHS.Subsequently, a group of ETV2-expressing cells, known as VAL, begin to fuse with the lymphatic sprouts to form the LFL along the PHS.The LFL then begins to bud out to form a complex facial lymphatic vessels including the OLV, LAA, and MFL; c The development of intestinal lymphatic vessels proceeds from 3 dpf-15 dpf.At 3 dpf-4 dpf, LECs sprout from the PCV to the ventral and bilateral sides, respectively to form segmental lymphatic vessels, which subsequently interconnect to form L-SIL, R-SIL.The SILs first bud toward the right side of the abdomen along the vascular network to form UR-IL and IR-IL.Finally, the lymphatic vessel network continues to expand follow the left vascular track to form UL-IL and LL-IL and take up intestinal lymph; d The formation of trunk lymphatic vessels is the earliest event of embryonic lymphatic vessel development in zebrafish, budding from the PCV to form the ISLV along the trajectory of the ISVs, and subsequently sprouting ventrally and dorsally to form the DLLV and TD, respectively.Dpf day postfertilization, CCV common cardinal vein, PHS primary head sinus, FLS facial lymphatic sprouting, VAL ventral aorta lymphangioblast, LFL lateral facial lymphatic vessel, OLV otolithic lymphatic vessel, ETV2 ETS variant transcription factor 2, LAA lymphatic branchial arches, MFL medial facial lymphatic vessels, PCV posterior cardinal vein, L-SIL the left supraintestinal vessel, R-SIL the right supraintestinal vessels, UR-IL upper-right intestinal lymphatics, LR-IL lower-right intestinal lymphatics, UL-IL upper-left intestinal lymphatics, LL-IL lower-left intestinal lymphatics, ISLV intersegmental lymphatic vessel, aISV arterial intersegmental vessels, vISV venous intersegmental vessel, PAC parachordal line, DA dorsal aorta, DLAV dorsal longitudinal anastomotic vessel, HM horizontal myoseptum, DLLV dorsal longitudinal lymphatic vessel, TD thoracic duct.Created with Adobe Illustrator

Fig. 8
Fig.8Anatomy of the lymphatic system.a The lymphatic system includes the primary and secondary lymphoid organs and lymphatic vessels, providing a one-way drainage route from all tissues back ultimately to the blood circulation via the great veins in the neck.In the primary lymphoid organs (bone marrow and thymus), immune cell production and maturation takes place, whereas secondary lymphoid organs (lymph nodes, spleen, and mucosa-associated lymphoid organs such as Peyer's patch, tonsils, and adenoids) are the sites for lymphocyte activation; b The thoracic duct is responsible for the lymph drainage coming from most of the body with the exception of the right side of the head and neck, the right side of the thorax and the right upper limb where drain lymph primarily into the right lymphatic duct; c-e The spleen, the Peyer's patch and lymph nodes are highly organized structures with segregated B-cell and T-cell zones to optimize the induction of adaptive immune responses; f The capillary lymphatics drain downstream into the collecting lymphatics.Capillary LECs are interconnected via discontinuous junctions allowing the fluid to enter the system passively.Collecting LECs present with continuous junctions.Collecting lymphatics differ from capillary lymphatics by possessing intraluminal valves, LSMCs and a continuous basement membrane.LSMCs lymphatic smooth muscle cells, LECs lymphatic endothelial cells, GC germinal center.Created with Adobe Illustrator

Fig. 9
Fig. 9 Lymph absorption and transport.a Capillary lymphatics comprise a single layer of loosely connected LECs lacking a continuous basement membrane and perivascular mural cells.LECs within capillary lymphatics are interconnected through discontinuous button-like junctions that facilitate the uptake of interstitial fluid, macromolecules and immune cells which are released by the blood capillary; b Collecting lymphatics have a period of brisk contraction (systole) and a period of relaxation (diastole) between each phasic contraction.Each lymphangion, defined as the segment between two valves, can typically exhibit systole and diastole.When a lymphangion is relaxed, the inflow (or upstream) valve will open (given sufficient inflow pressure).During systole, the phasic contraction pushes the lymph, but the inflow valve closes, so that lymph is forced forward through the outflow valve.LECs lymphatic endothelial cells.Created with Adobe Illustrator

Fig. 10
Fig. 10 Compartmentalized functions of LN LECs. a Decoy CCL21 receptor CCRL1 produced by cLECs creates a CCL21 gradient and regulates intranodal migration of CCR7-expressing DCs; b The expression of CSF1 in LECs is maintained by RANK expressed on LECs, which is activated by RANKL produced by MRCs; c Medullary LN LECs express CD209 to retain neutrophils, which may be important in clearing lymph-borne pathogens.cLEC ceiling lymphatic endothelial cell, fLEC floor lymphatic endothelial cell, LN lymph node, LEC lymphatic endothelial cell, CCL21 chemokine (C-C motif) ligand 21, CCRL1 chemokine (C-C motif) receptor like 1, CSF1 colony-stimulating factor 1, RANK receptor activator of nuclear factor-kappaB, RANKL receptor activator of nuclear factor-kappaB ligand, DCs dendritic cells, S1P sphingosine 1 phosphate, SCS subcapsular sinus, SSM subcapsular sinus macrophage, MM medullary macrophage, MRC marginal reticular cell.Created with Adobe Illustrator

Fig. 11
Fig. 11 Lymphangiogenesis in cancers.Lymphangiogenesis plays a crucial role in lymph node metastasis, which is associated with poor prognosis and overall survival in a range of malignancies.The molecular mechanisms underlying lymphangiogenesis exhibit diversity across different cancer contexts, potentially suggesting targeted therapeutic strategies for cancers.Created with BioRender.com

Fig. 12
Fig. 12 Lymphangiogenesis and lymph node metastasis in cancer.a Lymphatic vessels undergo sprouting, filopodia formation, and lymphatic vessel enlargement; b The disruption of lymphatic vessels and augmented permeability contribute to the intravasation of cancer cells into lymphatic vessels; c An increased coverage by LSMCs and a higher innervation present in the dilated collecting lymphatic vessels, which coordinately enhances collecting lymphatic vessel contractility and pumping frequency; d LECs forming the boundaries of the SCS create and maintain chemokine gradients that direct cancer cells to arrive in the SCS of MLN.Furthermore, LECs within the MLN upregulate adhesion molecules, that further support cancer cell colonization.LV lymphatic vessel, LSMC lymphatic smooth muscle cell, LEC lymphatic endothelial cell, SCS subcapsular sinus, MLN metastatic lymph node.Created with BioRender.com

Table
. Organ-specific lymphatic vessel development and regulatory signaling pathways in mouse

Table 2 .
Molecules and related signaling pathways of lymphatic vessel development in zebrafish

Table 3 .
Lymphangiogenesis in other diseases

Table 4 .
Inhibitors of lymphangiogenesis and applications