Abstract
Wnt signaling regulates a broad variety of processes in both embryonic development and various diseases. Recent studies indicated that some genetic variants in Wnt signaling pathway may serve as predictors of diseases. Low-density lipoprotein receptor protein 6 (LRP6) is a Wnt co-receptor with essential functions in the Wnt/β-catenin pathway, and mutations in LRP6 gene are linked to many complex human diseases, including metabolic syndrome, cancer, Alzheimer’s disease and osteoporosis. Therefore, we focus on the role of LRP6 genetic polymorphisms and Wnt signaling in complex diseases, and the mechanisms from mouse models and cell lines. It is also highly anticipated that LRP6 variants will be applied clinically in the future. The brief review provided here could be a useful resource for future research and may contribute to a more accurate diagnosis in complex diseases.
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Introduction
The Wnt1 gene was identified in 1982. Ensuing studies in Drosophila and Xenopus unveiled a highly conserved Wnt/β-catenin pathway, namely, canonical Wnt signaling. With the identification of Wnt transcription factors, receptors and co-receptors, the Wnt/β-catenin pathway has become a hot topic in molecular biology studies. Considering its essential role in certain physiological process, including embryonic development, insulin secretion, stem cell homeostasis, bone formation and neurogenesis, abnormal signaling through this pathway has a serious effect on cell growth and function, leading to a plethora of debilitating and life-threatening disorders. Low-density lipoprotein receptor-related protein 6 (LRP6) acts as an essential co-receptor of Wnt/β-catenin signaling and has recently become ‘a star molecule’.
In recent years, the question of whether and how LRP6 variants influence the development and progression of various diseases has attracted much interest. Many researchers have demonstrated that in different populations, specific mutations in LRP6 and Wnt pathway-related genes are associated with increased risk of disease. In addition to clinical evidence, results from genetically engineered transgenic mouse models and cell lines support this conclusion. In this review, we present the most recent evidences regarding the role of LRP6 and Wnt signaling in various human diseases, discuss the newly discovered mutations, and address the potential of innovative diagnostics for complex diseases.
Overview of LRP6
LRP6 structure
The low-density lipoprotein receptor (LDLR) family comprises cell surface receptors, and several members are involved in numerous signaling pathways and expressed in various target organs.1 LDLR-related proteins 5/6 (LRP5/6) belong to this large family and function as co-receptors of the Wnt/β-catenin pathway. These proteins are structurally related, with ~71% homology at the nucleotide level,2 and are broadly expressed in humans, including in the hippocampus, rental tubular cells, hepatocytes, intestinal epithelial cells, osteoblasts and osteoclasts. Nonetheless, previous studies highlighted that LRP5 and LRP6 mediated distinct actions due to differences in tissue distribution and affinity for individual Wnt ligands.3 In contrast, murine models suggested incomplete functional redundancy between the two receptors.4 Although both have a crucial role in the regulation of bone mass,5 LRP6 is closely related to glucose and lipid metabolism signaling pathways6, 7, 8 and plays a more important role than LRP5 in developmental processes.9
The human LRP6 gene (hLRP6), which is located on chromosome 12p13.2, is 150 kb in length and contains 23 exons. hLRP6 is highly conserved evolutionarily, with almost no species differences;7, 10 for instance, hLRP6 is highly conserved among Drosophila, Xenopus and Mus. The protein encoded by hLRP6 is 1613 amino acids and is a type I signal transmembrane protein that contains a signal peptide and a transmembrane domain. The LRP6 receptor possesses extracellular and intracellular domains, and the structure of the former is essential for regulating interaction with Wnt ligand, Dickkopf-related protein 1 (Dkk1), and Sclerostin (Sost)11 (Figure 1). The extracellular domain contains four YWTD (Tyr-Trp-Thr-Asp)-type β propellers, four epidermal growth factor (EGF)-like domains, and three LDLR type A domains; the intracellular domain harbors PPPSP (Pro-Pro-Pro-Ser-Pro) motifs. According to the crystal structure of an LDLR that contains a single propeller, the YWTD β propeller comprises six YWTD repeats that form a six-bladed β-propeller structure.12 An EGF-like domain of ~40 bases follows every YWTD-type β propeller motif.7 Although LRP6 belongs to the LDLR family, it differs from other LDLR family members; for example, the cytoplasmic C-terminal domain of LRP6 contains at least one copy of a PPPSP motif in place of the NPxY (Asn-Pro-any amino acid (x)-Tyr) domain7 (Figure 1). Some variants of LRP6 might have altered protein function, so understanding the structure of LRP6 is essential for studying signal transduction and the discovery of novel therapeutic targets.
Structure of low-density lipoprotein receptor (LDLR) and LDLR-related 5 and 6 (LRP5/6). LDLR is an extraordinarily multifunctional subgroup, which includes LRP5/6. Both of LDLR and LRP6 share the common domains structurally, including LDLR type A domain, EGF-like domain, YWTD-type β propeller, transmembrane domain and a cytoplasmic domain. There is a NPxY motif in the cytoplasmic domain of LDLR, while a PPPSP motif is in the cytoplasmic domain of LRP6. EGF, epidermal growth factor; LDLR, low-density lipoprotein receptor; NPxY, Asn-Pro-any amino acid (x)-Tyr; PPPSP, Pro-Pro-Pro-Ser-Pro; YWTD, Tyr-Trp-Thr-Asp.
Overview of Wnt/β-catenin signaling
The Wnt/β-catenin pathway mainly consists of Wnt, Frizzled (Fz), LRP5/6, disheveled (Dvl), β-catenin, glycogen synthase kinase-3β (GSK-3β), axis inhibition protein 1 (Axin), adenomatous polyposis coli (APC), casein kinase 1 (CK1) and nuclear T-cell transcription factor/lymphatic enhancement factor (TCF/LEF; Figure 2). In the absence of upstream signal, the Wnt/β-catenin pathway is inactive, and with the Wnt ligands, the pathway is active (Figure 2). In addition to Wnt/β-catenin pathway, Wnt can also signal through protein kinase C, Rho or c-Jun N-terminal kinase, namely non-canonical Wnt signaling pathway.13 A considerable number of basic and clinical studies confirm that Wnt ligands, APC, LRP6 and TCF7L2 play crucial roles in the synthesis and secretion of triglyceride (TG), LDL and very low-density lipoprotein.14, 15 Moreover, these genes are shown to be related in cancer,16, 17 AD18 and osteoporosis.19
Canonical Wnt pathway (namely Wnt/β-catenin siganling pathway). Inactivate pathway: the absence of Wnt ligand results in the cytoplasmic pool of β-catenin being recruited into a multiprotein destruction complex that includes APC, CK1, Axin (axis inhibition protein 1) and GSK-3β. This destruction complex facilitates the GSK-3β-dependent phosphorylation of β-catenin and subsequent ubiquitinylation, leading to the degradation of β-catenin via the proteasome (the left panel). Active pathway: Wnt ligands combine with Fz (Frizzled) and LRP5/6, forming a Wnt-Fz-LRP5/6 ternary complex, which accelerates phosphorylation of LRP5/6 intracelluar region, attracting Axin complex, generating the inhibition of β-catenin, while the LRP5/6 phosphorylation protein inhibits the phosphorylation and degradation of β-catenin from GSK-3β, so that β-catenin in the cytoplasm is stable freely, and β-catenin combines with TCF/LEF (nuclear T-cell transcription factor/lymphatic enhancement factor) in the nucleus with activation of downstream target genes (the right panel). APC, adenomatous polyposis coli; CK1, casein kinase 1; Dvl, disheveled; GSK-3β, glycogen synthase kinase-3β; Ub, ubiquitylation; βTrCP, β-transducin-repeat-containing protein.
LRP6 genetic polymorphisms and metabolic syndrome
Metabolic syndrome is a comprehensive disease typical of metabolic disorder that comprises dysglycemia, dyslipidemia, hypertension and the procoagulant state.20 According to the surveys, the morbidity of metabolic syndrome among American and Chinese is 34 and 23.3%, respectively.21, 22 Indeed, numerous reports confirmed that mutants of LRP6 and TCF7L2 caused atherosclerosis,23 diabetes,24 hyperlipidemia23, 25 and hypertension.26 Recently, attenuation of Wnt-mediated transcription resulting from mutations in LRP6 has been genetically linked to coronary artery disease (CAD) as well as several features of metabolic syndrome including hyperlipidemia, hypertension and diabetes but not obesity.13 In an effort to clarify the correlation of LRP6 gene polymorphisms and metabolic syndrome, we provide a complete and up-to-date summary of the reported LRP6 genetic mutations in metabolic disorders and the regulatory mechanisms in Table 1.
Type 2 diabetes mellitus (T2DM)
T2DM is characterized by insulin resistance or insulin secretion deficiency. However, the etiology of T2DM is complicated, with involvement of genetic background, lifestyle and the environment.27 In 2007, Mani et al.10 found a missense mutation of a cysteine for arginine substitution at a highly conserved position of an EGF-like domain of LRP6 that impaired Wnt signaling in vitro. The article attracted the attention of investigators to the interrelationship between LRP6 variants and various human disorders. Furthermore, a number of investigators have confirmed that LRP6 is associated with the insulin pathway. For example, Masako et al.28 indicated that three single-nucleotide polymorphisms (SNPs) of LRP6 (rs7136900, rs10743980 and rs2417086) were associated with T2DM in Japanese patients in the initial study, but this association was not confirmed in the replication panel. Thereafter, Singh et al.29 reported that the LRP6 R611C mutation impaired glucose tolerance and activity of the insulin pathway; the study also found that LRP6 enhanced glucose metabolism by promoting TCF7L2-dependent insulin receptor expression and the mTOR pathway.29
Hyperlipidemia
Hyperlipidemia, which is characterized by a state in which blood has abnormally high levels of lipids, including cholesterol and TGs, is a major risk factor for CAD, the leading cause of death in the world.30, 31 It is reported that the risk of early CAD, hyperlipidemia, hypertension and diabetes in LRP6 R611C crowd is markedly higher than the normal.10 Singh et al.32 found three new missense mutations (that is, 1418G>A, 1079G>A and 1298T>C) of LRP6 in the Caucasian subjects, and all mutation carriers had hyperlipidemia, diabetes, or impaired glucose tolerance and hypertension. In addition, Wang et al.33 demonstrated that LRP6 rs11054731 was associated with the risk of CAD (P=0.001) in the Chinese population.
Based on the fact that there is an association between LRP6 variants and hyperlipidemia or CAD, many researchers are taking an effort to explain this phenomenon. On the one hand, some studies implicated that LRP6 influenced activity of the mTOR pathway via Wnt/β-catenin signaling, and that overactivation of mTOR may up-regulate the lipid synthesis process.29, 34 Moreover, Go et al.35 highlighted the effect of LRP6 on lipid synthesis in the liver, resulting in increased serum TC and TGs through insulin-like growth factor 1, mTOR and sterol regulatory element-binding protein 1/2 (SREBP1/2), namely, the IGF1-mTOR-SREBP1/2 pathway.35 On the other hand, Wang et al.36 found increased activity of non-canonical Wnt signaling in homozygous LRP6R611C (LRP6mut/mut) mice, with both steatohepatitis and steatofibrosis. Besides that, some studies also reported that LRP6 was essential for normal LDL clearance and that gain- or loss-of-function mutations of LRP6 may induce hyperlipidemia or other diseases.37, 38 Xu et al.39 showed that LRP6 regulated lipid metabolism mainly through human umbilical vein endothelial cell proliferation and migration. In conclusion, it is possible that LRP6 is a regulatory factor in lipid metabolism via multiple pathways.
Atherosclerosis
Atherosclerosis refers to a vascular inflammatory disorder characterized by shrinking of the blood vessel lumen due to the accumulation of lipids, inflammatory cells, vascular smooth muscle cells and platelets.40, 41, 42 In humans, expression of LRP6 in atherosclerotic coronary arteries is markedly increased, and the protein colocalizes with platelet-derived growth factor receptor β.43 Further investigation showed that wild-type LRP6 inhibited, but LRP6 R611C promoted, vascular smooth muscle cell proliferation in response to platelet-derived growth factor.43 In the clinical, Sarzani et al.23 demonstrated that LRP6 I1062V (rs2302685) was associated with carotid artery atherosclerosis and speculated that LRP6 rs2302685 was likely to be an independent risk factor of atherosclerotic plaque formation through retrospective analysis of 334 hypertensive patients. In addition, Cheng et al.44 studied the role of LRP6 in atherosclerosis in the SM22-Cre;LRP6(fl/fl);LDLR−/− animal model, conditionally depleting LRP6 in the VSM lineage in male LDLR-null mice; the authors discovered that the conditional knockout of LRP6 enhanced aortic calcification and vessel stiffening. One explanation may be that non-canonical Wnt signals promoted mature tissue calcification, whereas LRP6 restrained this pathway in part by sequestering certain Fz receptors.45 Thus, LRP6 might play a uniquely important role in bone-vascular interactions.46 In conclusion, changes in Wnt/LRP6/β-catenin signaling pathway activity may be a main cause of atherosclerotic plaque formation, and LRP6 genetic polymorphism is possibly to be a predictor of atherosclerosis.
LRP6 genetic polymorphisms and cancers
The Wnt/β-catenin signaling pathway is a key modulator of cellular proliferation due to its regulation of stem cell homeostasis, and candidate gene approaches have investigated associations between genetic variants in Wnt pathway genes and susceptibility to cancers.47 As an indispensable Wnt co-receptor, LRP6 is overexpressed in several types of cancer and malignant tissues,48, 49 and altered LRP6 expression leads to abnormal Wnt protein activation, cell proliferation and tumorigenesis.
Recently, Pierzynski et al. conducted a study including a cohort of 803 bladder cancer cases and an equal number of healthy controls, and showed that LRP6 rs10743980 was associated with a decreased risk of bladder cancer (OR=0.76, 95% CI=0.58–0.99, P=0.039), with the findings validated in a genome-wide association study using a bladder microarray.50 A recent study involving 500 non-small cell lung cancer (NSCLC) patients and 500 healthy controls implicated that LRP6 rs10845498 contributed to a reduced risk of lung squamous cell carcinoma and that the LRP6 rs6488507 increased the risk of NSCLC in tobacco smokers.51 LRP6 was overexpressed in human breast tumors,49 and down-regulation of LRP6 inhibited breast cancer tumorigenesis.52 Based on the known genetic predisposition for some diseases, Richarda et al. identified that LRP6 rs141458215 as a novel candidate risk factor for early-onset colorectal cancer using whole-exome sequencing.53 Lemieux et al.54 found that Wnt/β-catenin pathway showed increased activity through LRP6 in colorectal cancer through KARS signaling. In addition to its role in the development of the cancers mentioned above, LRP6 is also necessary for the proliferation of prostate cancer cells.55
Over the past decade, mutations in LRP6 have been linked to a wide variety of cancers, and its critical role in Wnt signaling pathway has made LRP6 a hot topic of research. It has been confirmed that the LRP6 variants are related to the risk of cancer and tumor progression; accordingly, this gene may be used as a biomarker to predict the risk of cancer.
LRP6 genetic polymorphisms and AD
AD, the most common form of age-associated dementia affecting a growing population of elderly individuals, is a progressive neurodegenerative disorder characterized by a deficit in cognitive processes that manifest as alterations in memory, judgment and reasoning.56 Understanding the exact pathogenesis of AD and finding more effective biomarkers and accurate gene variants would contribute to therapy for this disorder and benefit patients. It is well established that Wnt signaling activity is linked to the pathogenesis of AD, leading researchers to examine whether the LRP6 gene, is associated with this disease.
Genome-wide linkage studies involving a multicenter case–control series as well as a large family-based series defined a broad susceptibility region for late-onset AD on chromosome 12, a region that contains the LRP6 gene.57 Moreover, De Ferrari et al.57 found a significant association between a synonymous SNP in exon 18 (18e, rs1012672, C→T) and AD in combined multiple samples (Zurich/U.K/U.S series). Individuals carrying the minor T allele had 69–80% greater risk of developing AD compared with CC homozygote individuals.57 In addition, haplotype tagging of SNPs identified a putative risk haplotype that included a SNP in LRP6 14e (rs2302685; T→C). Interestingly, the LRP6 I1062V caused reduced activation of a β-catenin-responsive reporter gene in HEK293T/STF recombinant cells, suggesting that reduced signaling through the canonical pathway may predispose people toward AD.57, 58 Except the common SNPs of genes, altered posttranscriptional metabolism has recently become a hot topic. To date, several key genes of the Wnt/β-catenin pathway have been demonstrated to be alternatively spliced, such as TCF7L2 in colorectal, gastric and endometrial carcinomas,59 β-catenin, axin and the homologous LRP5 in human colorectal tissue.60 A recent study evaluated posttranscriptional metabolism of the LRP6 messenger RNA by sequentially scanning 23 exons in human tissues and reported that a novel LRP6 isoform that completely skipped exon 3 was present in all tissues. In addition, the messenger RNA level was significantly increased in AD brains compared with controls (1.6-fold; P=0.037) and other pathological samples (2-fold; P=0.007).61 As shown in these clinical studies, LRP6 is linked to the risk of AD, and plays a pivotal role in AD development and progression.
To confirm that LRP6 deficiency may lead to AD and to elucidate the mechanism by which LRP6 regulates levels of Aβ, researchers conditionally deleted the LRP6 gene in neurons, generating LRP6 conditional knockout (LRP6 CKO) and corresponding littermate control mice.62 This study showed that neuronal LRP6 deficiency contributed to significant memory impairment, impaired long-term potentiation induction, correlating with learning and memory, and increased expression of glial fibrillary acidic protein and ionized calcium-binding adaptor molecule 1 (Iba1), markers for astrocyte and microglia activation, respectively.62 Furthermore, the study reported that LRP6 deficiency significantly increased mouse endogenous Aβ40 and Aβ42 levels in the brain compared with control mice.62 Despite evidence demonstrating the relevance between LRP6 and Aβ levels, the researchers designed in vitro experiments in human neuroblastoma SH-SY5Y cells overexpressing human APP (SHSY5Y-APP) to confirm the in vivo results. They found that LRP6 regulated APP trafficking and processing to Aβ62 and also reported that LRP6 levels and Wnt signaling were down-regulated in AD brains in comparison with controls.62 All these studies showed that LRP6 deficiency contributed to the development of AD.62
LRP6 genetic polymorphisms and osteoporosis
Osteoporosis is a major health problem in western societies, affecting up to half of the elderly female population. The condition is characterized by low body bone mineral density (BMD) and bone fragility and fractures.63 Heritability studies show that genetic factors may account for 50–80% of the variance in BMD.64, 65 The canonical Wnt pathway is critical for skeletal development and maintenance, though the precise roles of Wnt co-receptors LRP5/6 are not entirely clear. Approximately a decade ago, the identification of causal mutations in LRP5 involved in two rare bone disorders propelled research in the bone area into completely new directions.66
Mani et al.10 found that individuals with LRP6 mutations developed many abnormalities including diabetes, hypertension, CAD and osteoporosis. Moreover, van Meurs et al.67 discovered an association of LRP6 rs2302685 with height (P=0.04) and lumber spine bone area (P=0.01) in healthy white individuals. The authors went on to analyze fracture risk and found that LRP6 I1062V carriers also had a 60% increased risk for fragility fractures.67 In analyses of the interaction between polymorphisms in LRP5 and LRP6, the researchers observed that men carrying both LRP5 A1330V and LRP6 I1062V risk alleles had a 90% higher risk of vertebral fracture (P=0.08) compared to all other individuals.67 Furthermore, LRP6 rs1181334 was also associated with decreased total hip BMD (P=0.014) in 425 postmenopausal woman of an urban Mexican population.68 These data support previously reported associations of LRP6 with BMD.69
In the past years, it has been established that LRP6 controls osteoblast differentiation in mice models. A study more than a dozen years ago reported genetic enhancement of a Wnt mutant phenotype in mice lacking one functional copy of LRP6 and found that this type of mouse displayed defects in both limb and axial development.70 Numerous studies in mice also showed that a point mutation in LRP6 contributed to abnormal formation of the axial skeleton and a low bone mass phenotype.5, 71 Furthermore, a mouse in which LRP6 was selectively disrupted in the osteoblast was generated, with a significant reduction in BMD, and deficiencies in bone structure were evident much earlier in the development.72 Moreover, the LRP6 mutant mice failed to attain peak trabecular bone volume, accompanied by a profound decrease in osteoblasts and significant reductions in mineral apposition and bone formation rates.72 Another group generated mice carrying a collagen2a1-Cre-mediated deletion of LRP6 to examine the function of this gene in both developing and adult mouse skeletons; they found that mutation in LRP6 within the osteochondral lineage caused reductions in bone mass.73 These studies proved that LRP6 had a pivotal role in the modulation of BMD and influenced skeletal development in mice.
Several lines of evidence suggest that LRP6 may be a key determinant of bone mass. Indeed, loss-of-function mutations in LRP6 may increase the risk of osteoporosis. Gaining insight into the relationship between LRP6 mutations and BMD will provide insight into utilizing LRP6 as a therapeutic target for osteoporosis and other bone-related diseases. A summary of the relevance between currently known LRP6 genetic variants and complex diseases is listed in Table 2.
Wnt signaling and diagnostics
Besides the LRP6 genetic polymorphisms, many other genetic variants in Wnt signaling pathway may also serve as predictors of some complex diseases. Kanazawa et al.74 found a SNP in the Wnt5B gene to be strongly associated with T2DM in the Japanese population. A meta-analysis by Tong et al.75 implicated IVS3C>T and IVS4G>T of TCF7L2 as risk factors for T2DM. Stewart DJ et al.76 showed that Wnt inhibitory factor 1 rs10878232 may be related to NSCLC survival. Wnt16 rs2536182 was found to influence NSCLC recurrence, and Fz4 rs10898563 gene was found to be associated with both recurrence-free and overall survival in Caucasian patients.77 Many researchers focused on the complex associations between mutations in Wnt pathway genes and bladder cancer, such as secreted frizzled-related protein 1 rs3242.78 Wang JY et al.79 discovered that Dkk1 rs2241529 correlated to baseline BMD. As emerging molecular biomarkers, some variants of Wnt siganaling pathway genes are in the process of translation to the clinic to help clinical diagnosis and treatment. And we discriminate the phase of the translational phase and the clinical annotation levels of evidence according to the pharmgkb website. A summary of mutations in Wnt pathway-related genes and their predicting functions in various diseases is shown in Table 3. And the location of known LRP6 SNPs in various diseases is shown in Figure 3.
Diagram of known LRP6 SNPs in various diseases. Orange arrow represents transcriptional direction, and the blue columns are representative of exons. The LRP6 variants and possibly related diseases are noted in the genecard. AD, Alzheimer’s disease; CAA, carotid artery atherosclerosis; CAD, coronary artery disease; Ileal CD, the early ileal Crohn’s disease; I1: intron1; I2: intron 2; I3: intron 3; E14: exon 14; E18: exon 18; LRP6, lipoprotein receptor-related protein 6; NSCLC, non-small cell lung cancer; SNP, single-nucleotide polymorphism; T2DM, type 2 diabetes mellitus.
Concluding remarks and future perspectives
It is clear that the Wnt pathway has a functional role in metabolic regulation, cell proliferation, synaptic maintenance and function and bone mass regulation. Accordingly, Wnt pathway genes are good candidate genes for susceptibility to various diseases. As an indispensable co-receptor of the Wnt/β-catenin pathway, LRP6 has recently gained much attention. Such strong attention to the gene network of LRP6 has provided an opportunity to illustrate the importance of LRP6 mutations in the prediction of various diseases. Here, we summarized that variations in LRP6 and Wnt genes may affect the formation or progression of metabolic diseases, cancers, AD and osteoporosis.
Based on the fact that the majority of the published data were preliminary, further investigations are deserved to validate the currently reported biomarkers in LRP6 and Wnt pathway genes. However, it is highly anticipated that LRP6 variants will be applied clinically in the future. For instance, LRP6 rs2302685 has the potential to become one of the most useful and powerful biomarkers of accelerated atherosclerosis. Thus, hypertensive patients with this mutation may need some clinical checkment to detect subclinical atherosclerosis.23 Besides, LRP6 rs2302685, predisposing people toward early-onset ileal Crohn’s disease, may also turn into an attractive therapeutic target as an alternative to the current anti-inflammatory approaches in the therapy of Crohn' diseases.80 Another variant, LRP6 rs6488507, may be associated with the increased risk of NSCLC in tobacco smokers, and thus the clinical diagnostic testing may be necessary for carriers with smoking history.51 Hence, it is expected that further research in this field means a lot to the prediction or treatment of complex diseases.
Although previous studies have shown that LRP6 is associated with a variety of diseases, there are many problems demanding prompt resolution. (1) The existing results are frequently conflicting because of racial differences. Thus, expanding sample sizes in different ethnic populations needs to be addressed. (2) Many aspects of LRP6 and the Wnt pathway remain eclusive (for example, knowledge about the contributions of LRP6 in different cancer types). Undoubtedly, such knowledge will be crucial to support more accurate diagnosis. (3) There are important issues in translational science, namely, how to translate findings from bench to clinical application. A possible solution to this problem is to begin an investigation into the regulation of LRP6 in various cells and tissues to broaden our knowledge of the roles of genes. Such an approach will contribute to address the unmet demands of molecular development, both diagnostics and therapeutic targets, to improve the clinical management of these diseases' diagnosis.
References
Dieckmann M, Dietrich MF, Herz J . Lipoprotein receptors—an evolutionarily ancient multifunctional receptor family. Biol Chem 2010; 391: 1341–1363.
Brown SD, Twells RC, Hey PJ, Cox RD, Levy ER, Soderman AR et al. Isolation and characterization of LRP6, a novel member of the low density lipoprotein receptor gene family. Biochem Biophys Res Commun 1998; 248: 879–888.
Kelly OG, Pinson KI, Skarnes WC . The Wnt co-receptors Lrp5 and Lrp6 are essential for gastrulation in mice. Development 2004; 131: 2803–2815.
Bejsovec A . Wnt signaling: an embarrassment of receptors. Curr Biol 2000; 10: R919–R922.
Holmen SL, Giambernardi TA, Zylstra CR, Buckner-Berghuis BD, Resau JH, Hess JF et al. Decreased BMD and limb deformities in mice carrying mutations in both Lrp5 and Lrp6. J Bone Miner Res 2004; 19: 2033–2040.
Joiner DM, Ke J, Zhong Z, Xu HE, Williams BO . LRP5 and LRP6 in development and disease. Trends Endocrinol Metab 2013; 24: 31–39.
Cheng Z, Biechele T, Wei Z, Morrone S, Moon RT, Wang L et al. Crystal structures of the extracellular domain of LRP6 and its complex with DKK1. Nat Struct Mol Biol 2011; 18: 1204–1210.
MacDonald BT, Tamai K, He X . Wnt/beta-catenin signaling: components, mechanisms, and diseases. Dev Cell 2009; 17: 9–26.
Zhong Z, Baker JJ, Zylstra-Diegel CR, Williams BO . Lrp5 and Lrp6 play compensatory roles in mouse intestinal development. J Cell Biochem 2012; 113: 31–38.
Mani A, Radhakrishnan J, Wang H, Mani A, Mani MA, Nelson-Williams C et al. LRP6 mutation in a family with early coronary disease and metabolic risk factors. Science 2007; 315: 1278–1282.
Bourhis E, Tam C, Franke Y, Bazan JF, Ernst J, Hwang J et al. Reconstitution of a frizzled8.Wnt3a.LRP6 signaling complex reveals multiple Wnt and Dkk1 binding sites on LRP6. J Biol Chem 2010; 285: 9172–9179.
Rudenko G, Henry L, Henderson K, Ichtchenko K, Brown MS, Goldstein JL et al. Structure of the LDL receptor extracellular domain at endosomal pH. Science 2002; 298: 2353–2358.
Manolagas SC, Almeida M . Gone with the Wnts: beta-catenin, T-cell factor, forkhead box O, and oxidative stress in age-dependent diseases of bone, lipid, and glucose metabolism. Mol Endocrinol 2007; 21: 2605–2614.
Perez-Martinez P, Perez-Caballero AI, Garcia-Rios A, Yubero-Serrano EM, Camargo A, Gomez-Luna MJ et al. Effects of rs7903146 variation in the Tcf7l2 gene in the lipid metabolism of three different populations. PLoS ONE 2012; 7: e43390.
Scott CC, Vossio S, Vacca F, Snijder B, Larios J, Schaad O et al. Wnt directs the endosomal flux of LDL-derived cholesterol and lipid droplet homeostasis. EMBO Rep 2015; 16: 741–752.
Lu XP, Hu GN, Du JQ, Li HQ . TCF7L2 gene polymorphisms and susceptibility to breast cancer: a meta-analysis. Genet Mol Res 2015; 14: 2860–2867.
Wood LD, Parsons DW, Jones S, Lin J, Sjoblom T, Leary RJ et al. The genomic landscapes of human breast and colorectal cancers. Science 2007; 318: 1108–1113.
Blom ES, Wang Y, Skoglund L, Hansson AC, Ubaldi M, Lourdusamy A et al. Increased mRNA levels of TCF7L2 and MYC of the Wnt pathway in Tg-ArcSwe mice and Alzheimer's disease brain. Int J Alzheimers Dis 2010; 2011: 936580.
Makitie RE, Haanpaa M, Valta H, Pekkinen M, Laine CM, Lehesjoki AE et al. Skeletal Characteristics of WNT1 Osteoporosis in Children and Young Adults. J Bone Miner Res 2016; 31: 1734–1742.
Steinberger J, Daniels SR, Eckel RH, Hayman L, Lustig RH, McCrindle B et al. Progress and challenges in metabolic syndrome in children and adolescents: a scientific statement from the American Heart Association Atherosclerosis, Hypertension, and Obesity in the Young Committee of the Council on Cardiovascular Disease in the Young; Council on Cardiovascular Nursing; and Council on Nutrition, Physical Activity, and Metabolism. Circulation 2009; 119: 628–647.
Ford ES, Giles WH, Dietz WH . Prevalence of the metabolic syndrome among US adults: findings from the third National Health and Nutrition Examination Survey. JAMA 2002; 287: 356–359.
Yan F, Liu J, Zhao X, Hu X, Wang S, Ma Z et al. Association of the number of years since menopause with metabolic syndrome and insulin resistance in Chinese urban women. J Womens Health (Larchmt) 2015; 24: 843–848.
Sarzani R, Salvi F, Bordicchia M, Guerra F, Battistoni I, Pagliariccio G et al. Carotid artery atherosclerosis in hypertensive patients with a functional LDL receptor-related protein 6 gene variant. Nutr Metab Cardiovasc Dis 2011; 21: 150–156.
Liu PH, Chang YC, Jiang YD, Chen WJ, Chang TJ, Kuo SS et al. Genetic variants of TCF7L2 are associated with insulin resistance and related metabolic phenotypes in Taiwanese adolescents and Caucasian young adults. J Clin Endocrinol Metab 2009; 94: 3575–3582.
Huertas-Vazquez A, Plaisier C, Weissglas-Volkov D, Sinsheimer J, Canizales-Quinteros S, Cruz-Bautista I et al. TCF7L2 is associated with high serum triacylglycerol and differentially expressed in adipose tissue in families with familial combined hyperlipidaemia. Diabetologia 2008; 51: 62–69.
Bonnet F, Roussel R, Natali A, Cauchi S, Petrie J, Laville M et al. Parental history of type 2 diabetes, TCF7L2 variant and lower insulin secretion are associated with incident hypertension. Data from the DESIR and RISC cohorts. Diabetologia 2013; 56: 2414–2423.
Zimmet P, Alberti KG, Shaw J . Global and societal implications of the diabetes epidemic. Nature 2001; 414: 782–787.
Zenibayashi M, Miyake K, Horikawa Y, Hirota Y, Teranishi T, Kouyama K et al. Lack of association of LRP5 and LRP6 polymorphisms with type 2 diabetes mellitus in the Japanese population. Endocr J 2008; 55: 699–707.
Singh R, De Aguiar RB, Naik S, Mani S, Ostadsharif K, Wencker D et al. LRP6 enhances glucose metabolism by promoting TCF7L2-dependent insulin receptor expression and IGF receptor stabilization in humans. Cell Metab 2013; 17: 197–209.
Ballantyne C, Arroll B, Shepherd J . Lipids and CVD management: towards a global consensus. Eur Heart J 2005; 26: 2224–2231.
Go GW . Low-density lipoprotein receptor-related protein 6 (LRP6) is a novel nutritional therapeutic target for hyperlipidemia, non-alcoholic fatty liver disease, and atherosclerosis. Nutrients 2015; 7: 4453–4464.
Singh R, Smith E, Fathzadeh M, Liu W, Go GW, Subrahmanyan L et al. Rare nonconservative LRP6 mutations are associated with metabolic syndrome. Hum Mutat 2013; 34: 1221–1225.
Wang H, Liu QJ, Chen MZ, Li L, Zhang K, Cheng GH et al. Association of common polymorphisms in the LRP6 gene with sporadic coronary artery disease in a Chinese population. Chin Med J (Engl) 2012; 125: 444–449.
Liu W, Singh R, Choi CS, Lee HY, Keramati AR, Samuel VT et al. Low density lipoprotein (LDL) receptor-related protein 6 (LRP6) regulates body fat and glucose homeostasis by modulating nutrient sensing pathways and mitochondrial energy expenditure. J Biol Chem 2012; 287: 7213–7223.
Go GW, Srivastava R, Hernandez-Ono A, Gang G, Smith SB, Booth CJ et al. The combined hyperlipidemia caused by impaired Wnt-LRP6 signaling is reversed by Wnt3a rescue. Cell Metab 2014; 19: 209–220.
Wang S, Song K, Srivastava R, Dong C, Go GW, Li N et al. Nonalcoholic fatty liver disease induced by noncanonical Wnt and its rescue by Wnt3a. FASEB J 2015; 29: 3436–3445.
Ye ZJ, Go GW, Singh R, Liu W, Keramati AR, Mani A . LRP6 protein regulates low density lipoprotein (LDL) receptor-mediated LDL uptake. J Biol Chem 2012; 287: 1335–1344.
Liu W, Mani S, Davis NR, Sarrafzadegan N, Kavathas PB, Mani A . Mutation in EGFP domain of LDL receptor-related protein 6 impairs cellular LDL clearance. Circ Res 2008; 103: 1280–1288.
Xu Y, Gong W, Peng J, Wang H, Huang J, Ding H et al. Functional analysis LRP6 novel mutations in patients with coronary artery disease. PLoS ONE 2014; 9: e84345.
Karki R, Kim SB, Kim DW . Magnolol inhibits migration of vascular smooth muscle cells via cytoskeletal remodeling pathway to attenuate neointima formation. EXP. Cell Res 2013; 319: 3238–3250.
Paudel KR, Panth N, Kim DW . Circulating endothelial microparticles: a key hallmark of atherosclerosis progression. Scientifica (Cairo) 2016; 2016: 8514056.
Tolle M, Reshetnik A, Schuchardt M, Hohne M, van der Giet M . Arteriosclerosis and vascular calcification: causes, clinical assessment and therapy. Eur J Clin Invest 2015; 45: 976–985.
Keramati AR, Singh R, Lin A, Faramarzi S, Ye ZJ, Mane S et al. Wild-type LRP6 inhibits, whereas atherosclerosis-linked LRP6R611C increases PDGF-dependent vascular smooth muscle cell proliferation. Proc Natl Acad Sci USA 2011; 108: 1914–1918.
Cheng SL, Ramachandran B, Behrmann A, Shao JS, Mead M, Smith C et al. Vascular smooth muscle LRP6 limits arteriosclerotic calcification in diabetic LDLR-/- mice by restraining noncanonical Wnt Signals. Circ Res 2015; 117: 142–156.
Albers J, Schulze J, Beil FT, Gebauer M, Baranowsky A, Keller J et al. Control of bone formation by the serpentine receptor Frizzled-9. J Cell Biol 2011; 192: 1057–1072.
Demer L, Tintut Y . The bone-vascular axis in chronic kidney disease. Curr Opin Nephrol Hypertens 2010; 19: 349–353.
Anastas JN, Moon RT . WNT signalling pathways as therapeutic targets in cancer. Nat Rev Cancer 2013; 13: 11–26.
Lindvall C, Zylstra CR, Evans N, West RA, Dykema K, Furge KA et al. The Wnt co-receptor Lrp6 is required for normal mouse mammary gland development. PLoS ONE 2009; 4: e5813.
Liu CC, Prior J, Piwnica-Worms D, Bu G . LRP6 overexpression defines a class of breast cancer subtype and is a target for therapy. Proc Natl Acad Sci USA 2010; 107: 5136–5141.
Pierzynski JA, Hildebrandt MA, Kamat AM, Lin J, Ye Y, Dinney CP et al. Genetic variants in the Wnt/beta-catenin signaling pathway as indicators of bladder cancer risk. J Urol 2015; 194: 1771–1776.
Deng D, Zhang Y, Bao W, Kong X . Low-density lipoprotein receptor-related protein 6 (LRP6) rs10845498 polymorphism is associated with a decreased risk of non-small cell lung cancer. Int J Med Sci 2014; 11: 685–690.
Zhang J, Li Y, Liu Q, Lu W, Bu G . Wnt signaling activation and mammary gland hyperplasia in MMTV-LRP6 transgenic mice: implication for breast cancer tumorigenesis. Oncogene 2010; 29: 539–549.
de Voer RM, Hahn MM, Weren RD, Mensenkamp AR, Gilissen C, van Zelst-Stams WA et al. Identification of novel candidate genes for early-onset colorectal cancer susceptibility. PLoS Genet 2016; 12: e1005880.
Lemieux E, Cagnol S, Beaudry K, Carrier J, Rivard N . Oncogenic KRAS signalling promotes the Wnt/beta-catenin pathway through LRP6 in colorectal cancer. Oncogene 2015; 34: 4914–4927.
Park E, Kim EK, Kim M, Ha JM, Kim YW, Jin SY et al. Androgen receptor-dependent expression of low-density lipoprotein receptor-related protein 6 is necessary for prostate cancer cell proliferation. Korean J Physiol Pharmacol 2015; 19: 235–240.
Hardy J, Selkoe DJ . The amyloid hypothesis of Alzheimer's disease: progress and problems on the road to therapeutics. Science 2002; 297: 353–356.
De Ferrari GV, Papassotiropoulos A, Biechele T, Wavrant DF, Avila ME, Major MB et al. Common genetic variation within the low-density lipoprotein receptor-related protein 6 and late-onset Alzheimer's disease. Proc Natl Acad Sci USA 2007; 104: 9434–9439.
Inestrosa NC, Arenas E . Emerging roles of Wnts in the adult nervous system. Nat Rev Neurosci 2010; 11: 77–86.
Duval A, Iacopetta B, Ranzani GN, Lothe RA, Thomas G, Hamelin R . Variable mutation frequencies in coding repeats of TCF-4 and other target genes in colon, gastric and endometrial carcinoma showing microsatellite instability. Oncogene 1999; 18: 6806–6809.
Pospisil H, Herrmann A, Butherus K, Pirson S, Reich JG, Kemmner W . Verification of predicted alternatively spliced Wnt genes reveals two new splice variants (CTNNB1 and LRP5) and altered Axin-1 expression during tumour progression. BMC Genomics 2006; 7: 148.
Alarcon MA, Medina MA, Hu Q, Avila ME, Bustos BI, Perez-Palma E et al. A novel functional low-density lipoprotein receptor-related protein 6 gene alternative splice variant is associated with Alzheimer's disease. Neurobiol Aging 2013; 34: 1709.
Liu CC, Tsai CW, Deak F, Rogers J, Penuliar M, Sung YM et al. Deficiency in LRP6-mediated Wnt signaling contributes to synaptic abnormalities and amyloid pathology in Alzheimer's disease. Neuron 2014; 84: 63–77.
Stevenson JC, Whitehead MI . Postmenopausal osteoporosis. Br Med J (Clin Res Ed) 1982; 285: 585–588.
Evans RA, Marel GM, Lancaster EK, Kos S, Evans M, Wong SY . Bone mass is low in relatives of osteoporotic patients. Ann Intern Med 1988; 109: 870–873.
Pocock NA, Eisman JA, Hopper JL, Yeates MG, Sambrook PN, Eberl S . Genetic determinants of bone mass in adults. A twin study. J Clin Invest 1987; 80: 706–710.
Lara-Castillo N, Johnson ML . LRP receptor family member associated bone disease. Rev Endocr Metab Disord 2015; 16: 141–148.
van Meurs JB, Rivadeneira F, Jhamai M, Hugens W, Hofman A, van Leeuwen JP et al. Common genetic variation of the low-density lipoprotein receptor-related protein 5 and 6 genes determines fracture risk in elderly white men. J Bone Miner Res 2006; 21: 141–150.
Velazquez-Cruz R, Garcia-Ortiz H, Castillejos-Lopez M, Quiterio M, Valdes-Flores M, Orozco L et al. WNT3A gene polymorphisms are associated with bone mineral density variation in postmenopausal mestizo women of an urban Mexican population: findings of a pathway-based high-density single nucleotide screening. Age (Dordr) 2014; 36: 9635.
Sims AM, Shephard N, Carter K, Doan T, Dowling A, Duncan EL et al. Genetic analyses in a sample of individuals with high or low BMD shows association with multiple Wnt pathway genes. J Bone Miner Res 2008; 23: 499–506.
Pinson KI, Brennan J, Monkley S, Avery BJ, Skarnes WC . An LDL-receptor-related protein mediates Wnt signalling in mice. Nature 2000; 407: 535–538.
Kokubu C, Heinzmann U, Kokubu T, Sakai N, Kubota T, Kawai M et al. Skeletal defects in ringelschwanz mutant mice reveal that Lrp6 is required for proper somitogenesis and osteogenesis. Development 2004; 131: 5469–5480.
Riddle RC, Diegel CR, Leslie JM, Van Koevering KK, Faugere MC, Clemens TL et al. Lrp5 and Lrp6 exert overlapping functions in osteoblasts during postnatal bone acquisition. PLoS ONE 2013; 8: e63323.
Schumacher CA, Joiner DM, Less KD, Drewry MO, Williams BO . Characterization of genetically engineered mouse models carrying Col2a1-cre-induced deletions of Lrp5 and/or Lrp6. Bone Res 2016; 4: 15042.
Kanazawa A, Tsukada S, Sekine A, Tsunoda T, Takahashi A, Kashiwagi A et al. Association of the gene encoding wingless-type mammary tumor virus integration-site family member 5B (WNT5B) with type 2 diabetes. Am J Hum Genet 2004; 75: 832–843.
Tong Y, Lin Y, Zhang Y, Yang J, Zhang Y, Liu H et al. Association between TCF7L2 gene polymorphisms and susceptibility to type 2 diabetes mellitus: a large Human Genome Epidemiology (HuGE) review and meta-analysis. BMC Med Genet 2009; 10: 15.
Stewart DJ, Chang DW, Ye Y, Spitz M, Lu C, Shu X et al. Wnt signaling pathway pharmacogenetics in non-small cell lung cancer. Pharmacogenomics J 2014; 14: 509–522.
Coscio A, Chang DW, Roth JA, Ye Y, Gu J, Yang P et al. Genetic variants of the Wnt signaling pathway as predictors of recurrence and survival in early-stage non-small cell lung cancer patients. Carcinogenesis 2014; 35: 1284–1291.
Rogler A, Hoja S, Socher E, Nolte E, Wach S, Wieland W et al. Role of two single nucleotide polymorphisms in secreted frizzled related protein 1 and bladder cancer risk. Int J Clin Exp Pathol 2013; 6: 1984–1998.
Wang JY, Zhou PR, Liu Y, Xu XJ, Ma DD, Xia WB et al. The analysis of DKK1 polymorphisms in relation to skeletal phenotypes and bone response to alendronate treatment in Chinese postmenopausal women. Pharmacogenomics 2016; 17: 209–217.
Koslowski MJ, Teltschik Z, Beisner J, Schaeffeler E, Wang G, Kubler I et al. Association of a functional variant in the Wnt co-receptor LRP6 with early onset ileal Crohn's disease. PLoS Genet 2012; 8: e1002523.
Acknowledgements
This work was supported by grants from the National Key Research and Development Program (No. 2016YFC0905000, 2016YFC0905001), National High Technology Research and Development Program of China, ‘863’ Project (No. 2012AA02A518), National Scientific Foundation of China (No. 81522048, 81573511 and 81273595) and Innovation Driven Project of Central South University (No. 2016CX024).
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Wang, ZM., Luo, JQ., Xu, LY. et al. Harnessing low-density lipoprotein receptor protein 6 (LRP6) genetic variation and Wnt signaling for innovative diagnostics in complex diseases. Pharmacogenomics J 18, 351–358 (2018). https://doi.org/10.1038/tpj.2017.28
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DOI: https://doi.org/10.1038/tpj.2017.28
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