Thank you for visiting nature.com. You are using a browser version with limited support for CSS. To obtain
the best experience, we recommend you use a more up to date browser (or turn off compatibility mode in
Internet Explorer). In the meantime, to ensure continued support, we are displaying the site without styles
and JavaScript.
Research on stem cells provides critical insights into our understanding of development, genetics/epigenetics, physiology, reprogramming, regeneration, and disease, and is finding applications ranging from drug screening methods to cell transplantation. Here, we highlight work focusing on the basic biology and diverse applications of stem cells.
Stem cell quiescence is generally considered as an inactive state with poised potential. Here, Khoa et al. find that quiescent embryonic stem cells actively maintain a dynamic reservoir of cells with unrestricted cell fate that converges on S-adenosylmethionine and H3K27me3 status.
The role of nucleolar phase separation in stem cell fate decision is not well understood. Here, the authors show that the nucleolus-localized LIN28A protein undergoes LLPS in mESCs and in vitro, and that pluripotency state conversion depends on this phase separation capacity.
Authors report that VGLL1 regulates cell fate determination and self-renewal of human pluripotent stem cell-derived trophectoderm-like cells and trophoblast stem cells via modulation of chromatin accessibility in cooperation with TEAD4.
Blastoids are emerging models for early embryo development exploration in vitro. Here, authors found self-renewing human naïve PSCs spontaneously and efficiently give rise to blastoids upon three-dimensional suspension culture.
Authors report that long-term intestinal tissue maintenance in naked mole rats is achieved by having an expanded pool of slow-dividing adult stem cells while a higher proportion of differentiated cells confer enhanced function and protection to the intestinal mucosa.
How the neural crest gains its pluripotency-like stem cell potential is unclear. Here, the authors show that the entire post-gastrula ectoderm maintains expression of pluripotency genes, leading to the high stem cell capacity in the neural crest.
Hunt et al. identify the protein sets that are modulated by RNAi for each E2 ubiquitin-conjugating enzyme in human cells. By analyzing the UBA1/E2-sensitive proteome, they report an adaptive stress response that preserves peroxisomal protein import in cells with decreased ubiquitination capacity.
The contribution of cell-extrinsic factors during cellular reprogramming to human induced pluripotent stem cells has long been overlooked. Here, the authors show functional protein communication between reprogramming intermediates and the re-shaping of a permissive extracellular environment.
Normal limb development relies on synchronized formation of cartilage and bone. Here, the authors show that in salamander limb regeneration these processes are decoupled: ossification occurs after the final size of regenerating cartilage is reached, allowing fast regeneration and leading to bulky bones.
Stem cell models of organogenesis are a valuable tool for the study of human development, but often lack the context of tissue-tissue interaction. Here they generate human multi-lineage organoids comprising pro-epicardium, septum transversum, and liver bud, which they co-culture with heart organoids to generate a physiologically relevant model of organogenesis.
The TYK2 gene is associated with development of type 1 diabetes. Here the authors show that TYK2 regulates β-cell development, but at the same time TYK2 inhibition in the islets prevents IFNα responses and enhances their survival against CD8+ T-cell cytotoxicity; representing a potent therapeutic target to halt T1D progression.
Proximal nephron in pluripotent stem cell derived kidney organoids are immature with limited support for functional solute channels. Vanslambrouck et al report improved metanephric specification, generating enhanced kidney organoids with superior proximal tubules, spatially arranged nephrons, and applications for disease research, and drug screening.
How ribosomes differ in composition and function to regulate gene expression is poorly understood. Here, the authors show that ribosome composition changes during stem cell differentiation and identify a ribosomal protein that regulates production of the mesoderm lineage.
The development of safe preservation methods for genetic resources is important. Here, the authors successfully produce cloned mice from freeze-dried somatic cells, demonstrating the possibility of safe and low-cost preservation of genetic resources.
Relatively little is known about the first hematopoietic stem and progenitor cells to arrive in the fetal bone marrow. Here they characterize the frequency, function, and molecular identity of fetal BM HSPCs and their bone marrow niche, and show that most BM HSPCs have little hematopoietic function until birth.
Lipid metabolism regulates stem cell states and differentiation. Here, the authors demonstrate a requirement in planarians for Apolipoprotein B-mediated neutral lipid transport from intestinal stores to stem cells and their progeny during differentiation and whole-body regeneration.
The growth plate cartilage supports long bone growth. Here the authors identify FoxA2+ long term stem cells in the growth plate that are stratified with short term PTHrP+ cells, participate in production of hyaline cartilage, expand in response to trauma, and whose ablation impairs cartilage regeneration.
Many regenerative animals form an outgrowth at wound sites called a blastema. Here the authors identify equinox, which is expressed in the planarian wound epidermis and essential to initiate positional information regeneration and blastema formation.
Somitogenesis has been well characterized in model organisms, resulting in detailed description of the somite segmentation clock. Here they generate somitogenic organoids from human pluripotent stem cells that recapitulate somitogenesis, periodic segmentation, and proper polarity.
The mesothelium supports homeostasis and regeneration, yet its development origins remain unclear. Here, the authors uncovered the earliest mesothelium progenitor cells in zebrafish, linking Hand2 gene function to mesothelium formation and its re-activation to mesothelioma tumors.
Organs consist of parenchyma and stroma. Nishinakamura and colleagues induce renal stromal progenitors from mouse pluripotent stem cells (PSCs), and generate completely PSC-derived organoids that reproduce complex kidney structure.
N6-methyladenosine (m6A) plays important role in lineage specifications of embryonic stem cells, but its role at specific sites has not been assessed. Here the authors develop an adenine editor-based strategy, and systematically identify functional m6A sites that control lineage decisions in human embryonic stem cells.
Synthetic embryo models have arisen as an approach to probe early development in vitro, facilitating the study of difficult to access stages. Here the authors present a simple system for generating embryo-like structures that resemble peri-implantation mouse embryos.
Studying morphogen gradient formation and reception in mammalian development is challenging. Here, the authors show with human gastruloids that Nodal activity in live cells spreads via a relay mechanism with timing that is locally controlled by Lefty, which dictates mesoderm differentiation timing.
Mammary morphogenesis is a complex process. Here the authors describe how stem cells build a three-dimensional self-organizing multi-lineage tissue by showing that positional signals from the extracellular matrix through the collagen receptor DDR1 lead stem cells to differentiate into multi-lineage committed multi-layered progeny.
While the role of smooth muscle in peristalsis has been studied extensively, little is known about its other functions in the intestine. Here the authors identify MMP17, expressed by smooth muscle cells, as a modulator of intestinal epithelial regeneration and the intestinal stem cell niche.
Current protocols to generate cholangiocytes from human pluripotent cells produce immature cells. Here the authors identify retinoic acid, BMP, cAMP and Rho kinase pathways as regulators of cholangiocyte maturation, and generate ciliated cholangiocytes expressing high levels of CFTR that form ductal structures in vivo.
Human and murine embryonic development has disparities, highlighting the need for primate systems. Here, the authors construct a post-implantation transcriptional atlas from non-human primate embryos and show ISL1 controls a gene regulatory network in the amnion required for mesoderm formation.
Cells in the developing embryo interpret WNT signalling with context-dependence, but the mechanism decoding these cues is unclear. Here, the authors show that combinatorial TALE/HOX activity destabilizes nucleosomes at WNT-responsive regions to activate paraxial mesodermal genes.
Investigations of human cardiac disease involving human pluripotent stem cell-derived cardiomyocytes are limited by the disorganized presentation of biomechanical cues resulting in cell immaturity. Here the authors develop a platform of micron-scale 2D cardiac muscle bundles to precisely deliver physiologic cues, improving reproducibility and throughput.
Biomechanical mechanisms orchestrating stem cell dynamics in development remain unclear. Here the authors show that guidance receptor Plexin-B2 organizes actomyosin contractility, cytoskeletal tension and adhesion during multicellular development of human embryonic stem cells and neuroprogenitor cells.
The dogma is that limb muscle cells originate from somite, while connective tissue fibroblasts derive from lateral plate mesoderm. Here the authors identify a fibroblast population that undergoes myoblast conversion in response to BMP and contributes nuclei to myotubes at the myotendinous junction.
Classically, myogenic precursor cells derive from somites, and connective tissues derive from lateral plate mesoderm (LPM). Here the authors identify LPM derived fibroblasts that turn on a myogenic program and fuse to muscle fibers at muscle-tendon junctions, introducing fibroblast transcripts into myofibers.
X-chromosome inactivation (XCI) ensures dosage compensation between the sexes. Here the authors perform allele-specific single-cell RNA sequencing in differentiating mouse embryonic stem cells to provide a detailed profile of the onset of XCI.
Cardiomyocytes of heart ventricles consist of subpopulations of trabecular and compact subtypes. Here the authors describe the generation of structurally, metabolically and functionally mature compact ventricular cardiomyocytes as well as mature atrial cardiomyocytes from human pluripotent stem cells.
Short term systemic expression of the reprogramming factors Oct-3/4, Sox2, Klf4, c-Myc (OSKM) rejuvenates aging cells and promotes tissue regeneration. Here the authors show that myofiber-specific expression of OSKM accelerates muscle regeneration by reducing secretion of muscle stem cell quiescence promoting Wnt4.
Both A/B compartments and TADs are thought to be absent from the inactive X chromosome, but to be re-established with transcriptional reactivation and chromatin opening during X-reactivation. Here, the authors characterise gene reactivation, chromatin opening and chromosome topology during X-reactivation, observe A/B-like compartments on the inactive X that guide TAD formation independently of transcription during X-reactivation.
How neural stem cells can transition between states of proliferation and quiescence is unclear. Here, the authors identify Lrig1 as a specific marker for the primed quiescent state and demonstrate that Lrig1 maintains cells in a quiescent state via modulation of the EGFR pathway.
The differentiation of neural stem cells (NSCs) into neurons is a critical part in devising potential cell-based therapeutic strategies for central nervous system diseases but NSCs fate determination and prediction is problematic. Here, the authors present a deep neural network model for predictable reliable identification of NSCs fate.
Bone regeneration involves activation of tissue resident stem cells. Here the authors show that mesenchymal progenitors from skeletal muscle mediate the fibrotic response to bone injury and also contribute to bone repair; processes that are impaired when both muscle and bone are injured.
The role of transcriptional enhancers and 3D chromatin organisation in coordinating the transition from naive to primed pluripotency remains poorly understood. Here the authors generate a high-resolution atlas of gene regulatory interactions, chromatin profiles and transcription factor occupancy in naive and primed human pluripotent stem cells to provide insights into these developmental processes.
Epidermal cultures can treat skin diseases, such as Junctional Epidermolysis Bullosa, but the signature of stem cells is unclear. By single cell RNAseq analyses on human keratinocytes, the authors identify the molecular profile of holoclones and the role of FOXM1 in regulating the proliferative potential of epidermal stem cells.
RALYL is a liver progenitor cell-specific gene but its role in hepatocellular carcinoma (HCC) remains unknown. Here, the authors demonstrate that RALYL regulates HCC stemness through upregulation of TGF-β2 mRNA stability by decreasing N6-methyladenosine modification.
The cell source and dynamics of Notch ligands during the regulation of muscle stem cells is unclear. Here, the authors show that the Notch ligand Dll1 has to oscillate in order to control the balance between self-renewal and differentiation of muscle stem cells, with Hes1 acting as transcriptional pacemaker for the oscillatory network.