ABSTRACT
Wilms' tumor 1 (WT1) is essential for the development and homeostasis of multiple mesodermal tissues. Despite evidence for post-transcriptional roles, no endogenous WT1 target RNAs exist. Using RNA immunoprecipitation and UV cross-linking, we show that WT1 binds preferentially to 3' untranslated regions (UTRs) of developmental targets. These target mRNAs are down-regulated upon WT1 depletion in cell culture and developing kidney mesenchyme. Wt1 deletion leads to rapid turnover of specific mRNAs. WT1 regulates reporter gene expression through interaction with 3' UTR-binding sites. Combining experimental and computational analyses, we propose that WT1 influences key developmental and disease processes in part through regulating mRNA turnover.
Subject(s)
3' Untranslated Regions/physiology , Gene Expression Regulation, Developmental/genetics , RNA, Messenger/genetics , Wilms Tumor/genetics , Wilms Tumor/metabolism , Animals , Cell Line , Down-Regulation , Gene Deletion , Kidney/cytology , Mesoderm/metabolism , Mice , Mouse Embryonic Stem Cells , RNA, Messenger/metabolismABSTRACT
The significant heterogeneity of Wilms' tumors between different patients is thought to arise from genetic and epigenetic distortions that occur during various stages of fetal kidney development in a way that is poorly understood. To address this, we characterized the heterogeneity of alternative mRNA splicing in Wilms' tumors using a publicly available RNAseq dataset of high-risk Wilms' tumors and normal kidney samples. Through Pareto task inference and cell deconvolution, we found that the tumors and normal kidney samples are organized according to progressive stages of kidney development within a triangle-shaped region in latent space, whose vertices, or "archetypes", resemble the cap mesenchyme, the nephrogenic stroma, and epithelial tubular structures of the fetal kidney. We identified a set of genes that are alternatively spliced between tumors located in different regions of latent space and found that many of these genes are associated with the epithelial-to-mesenchymal transition (EMT) and muscle development. Using motif enrichment analysis, we identified putative splicing regulators, some of which are associated with kidney development. Our findings provide new insights into the etiology of Wilms' tumors and suggest that specific splicing mechanisms in early stages of development may contribute to tumor development in different patients.
Subject(s)
Alternative Splicing , Epithelial-Mesenchymal Transition , Kidney Neoplasms , Wilms Tumor , Wilms Tumor/genetics , Wilms Tumor/pathology , Humans , Kidney Neoplasms/genetics , Kidney Neoplasms/pathology , Epithelial-Mesenchymal Transition/genetics , Gene Expression Regulation, Neoplastic , Kidney/metabolism , Kidney/pathologyABSTRACT
Wilms' tumor, or nephroblastoma, is the most common pediatric renal cancer. The tumors morphologically resemble embryonic kidneys with a disrupted architecture and are associated with undifferentiated metanephric precursors. Here, we discuss genetic and epigenetic findings in Wilms' tumor in the context of renal development. Many of the genes implicated in Wilms' tumorigenesis are involved in the control of nephron progenitors or the microRNA (miRNA) processing pathway. Whereas the first group of genes has been extensively studied in normal development, the second finding suggests important roles for miRNAs in general-and specific miRNAs in particular-in normal kidney development that still await further analysis. The recent identification of Wilms' tumor cancer stem cells could provide a framework to integrate these pathways and translate them into new or improved therapeutic interventions.
Subject(s)
Gene Expression Regulation, Developmental , Kidney Neoplasms/genetics , Kidney/embryology , Organogenesis/genetics , Wilms Tumor/genetics , Animals , Epigenesis, Genetic/genetics , Gene Expression Regulation, Neoplastic , Humans , Kidney/pathology , MicroRNAs/geneticsABSTRACT
Wilms' tumors are pediatric malignancies that are thought to arise from faulty kidney development. They contain a wide range of poorly differentiated cell states resembling various distorted developmental stages of the fetal kidney, and as a result, differ between patients in a continuous manner that is not well understood. Here, we used three computational approaches to characterize this continuous heterogeneity in high-risk blastemal-type Wilms' tumors. Using Pareto task inference, we show that the tumors form a triangle-shaped continuum in latent space that is bounded by three tumor archetypes with "stromal", "blastemal", and "epithelial" characteristics, which resemble the un-induced mesenchyme, the cap mesenchyme, and early epithelial structures of the fetal kidney. By fitting a generative probabilistic "grade of membership" model, we show that each tumor can be represented as a unique mixture of three hidden "topics" with blastemal, stromal, and epithelial characteristics. Likewise, cellular deconvolution allows us to represent each tumor in the continuum as a unique combination of fetal kidney-like cell states. These results highlight the relationship between Wilms' tumors and kidney development, and we anticipate that they will pave the way for more quantitative strategies for tumor stratification and classification.
Subject(s)
Kidney Neoplasms , Wilms Tumor , Child , Humans , Kidney Neoplasms/pathology , Unsupervised Machine Learning , Kidney/pathologyABSTRACT
The proliferation, differentiation, and survival of cells of the mononuclear phagocyte system (MPS; progenitors, monocytes, macrophages, and classical dendritic cells) are controlled by signals from the M-CSF receptor (CSF1R). Cells of the MPS lineage have been identified using numerous surface markers and transgenic reporters, but none is both universal and lineage restricted. In this article, we report the development and characterization of a CSF1R reporter mouse. A FusionRed (FRed) cassette was inserted in-frame with the C terminus of CSF1R, separated by a T2A-cleavable linker. The insertion had no effect of CSF1R expression or function. CSF1R-FRed was expressed in monocytes and macrophages and absent from granulocytes and lymphocytes. In bone marrow, CSF1R-FRed was absent in lineage-negative hematopoietic stem cells, arguing against a direct role for CSF1R in myeloid lineage commitment. It was highly expressed in marrow monocytes and common myeloid progenitors but significantly lower in granulocyte-macrophage progenitors. In sections of bone marrow, CSF1R-FRed was also detected in osteoclasts, CD169+ resident macrophages, and, consistent with previous mRNA analysis, in megakaryocytes. In lymphoid tissues, CSF1R-FRed highlighted diverse MPS populations, including classical dendritic cells. Whole mount imaging of nonlymphoid tissues in mice with combined CSF1R-FRed/Csf1r-EGFP confirmed the restriction of CSF1R expression to MPS cells. The two markers highlight the remarkable abundance and regular distribution of tissue MPS cells, including novel macrophage populations within tendon and skeletal muscle and underlying the mesothelial/serosal/capsular surfaces of every major organ. The CSF1R-FRed mouse provides a novel reporter with exquisite specificity for cells of the MPS.
Subject(s)
Biomarkers/metabolism , Mononuclear Phagocyte System/metabolism , Receptors, Granulocyte-Macrophage Colony-Stimulating Factor/metabolism , Animals , Cell Differentiation/physiology , Dendritic Cells/metabolism , Hematopoietic Stem Cells/metabolism , Macrophage Colony-Stimulating Factor/metabolism , Macrophages/metabolism , Mice , Mice, Inbred C57BL , Mice, Transgenic , Monocytes/metabolism , Muscle, Skeletal/metabolism , RNA, Messenger/metabolism , Receptor, Macrophage Colony-Stimulating Factor/metabolism , Tendons/metabolismABSTRACT
In this issue of Genes & Development, Urbach and colleagues (pp. 971-982) provide compelling data suggesting a role for LIN28 in the pathogenesis of a significant percentage of Wilms tumors. These data extend our insights in the genetics underlying Wilms tumor development and emphasize the importance of stemness and microRNA-mediated processes in the origins of these tumors.
Subject(s)
Cell Differentiation , Kidney Neoplasms/genetics , Kidney Neoplasms/physiopathology , RNA-Binding Proteins/genetics , Stem Cells/cytology , Wilms Tumor/genetics , Wilms Tumor/physiopathology , Animals , HumansABSTRACT
BACKGROUND: During mammalian kidney development, nephron progenitors undergo a mesenchymal-to-epithelial transition and eventually differentiate into the various tubular segments of the nephron. Recently, Drop-seq single-cell RNA sequencing technology for measuring gene expression from thousands of individual cells identified the different cell types in the developing kidney. However, that analysis did not include the additional layer of heterogeneity that alternative mRNA splicing creates. METHODS: Full transcript length single-cell RNA sequencing characterized the transcriptomes of 544 individual cells from mouse embryonic kidneys. RESULTS: Gene expression levels measured with full transcript length single-cell RNA sequencing identified each cell type. Further analysis comprehensively characterized splice isoform switching during the transition between mesenchymal and epithelial cellular states, which is a key transitional process in kidney development. The study also identified several putative splicing regulators, including the genes Esrp1/2 and Rbfox1/2. CONCLUSIONS: Discovery of the sets of genes that are alternatively spliced as the fetal kidney mesenchyme differentiates into tubular epithelium will improve our understanding of the molecular mechanisms that drive kidney development.
Subject(s)
Kidney/embryology , Mesoderm/embryology , Organogenesis/genetics , Urothelium/embryology , Animals , Cell Culture Techniques , Mice , RNA Isoforms , Sequence Analysis, RNAABSTRACT
The Wilms' tumor suppressor gene, WT1, encodes a zinc finger protein that regulates podocyte development and is highly expressed in mature podocytes. Mutations in the WT1 gene are associated with the development of renal failure due to the formation of scar tissue within glomeruli, the mechanisms of which are poorly understood. Here, we used a tamoxifen-based CRE-LoxP system to induce deletion of Wt1 in adult mice to investigate the mechanisms underlying evolution of glomerulosclerosis. Podocyte apoptosis was evident as early as the fourth day post-induction and increased during disease progression, supporting a role for Wt1 in mature podocyte survival. Podocyte Notch activation was evident at disease onset with upregulation of Notch1 and its transcriptional targets, including Nrarp. There was repression of podocyte FoxC2 and upregulation of Hey2 supporting a role for a Wt1/FoxC2/Notch transcriptional network in mature podocyte injury. The expression of cleaved Notch1 and HES1 proteins in podocytes of mutant mice was confirmed in early disease. Furthermore, induction of podocyte HES1 expression was associated with upregulation of genes implicated in epithelial mesenchymal transition, thereby suggesting that HES1 mediates podocyte EMT. Lastly, early pharmacological inhibition of Notch signaling ameliorated glomerular scarring and albuminuria. Thus, loss of Wt1 in mature podocytes modulates podocyte Notch activation, which could mediate early events in WT1-related glomerulosclerosis.
Subject(s)
Glomerulonephritis/metabolism , Podocytes/metabolism , Receptor, Notch1/metabolism , Repressor Proteins/metabolism , Albuminuria/genetics , Albuminuria/metabolism , Animals , Apoptosis , Apoptosis Regulatory Proteins/genetics , Apoptosis Regulatory Proteins/metabolism , Basic Helix-Loop-Helix Transcription Factors/genetics , Basic Helix-Loop-Helix Transcription Factors/metabolism , Cells, Cultured , Disease Models, Animal , Epithelial-Mesenchymal Transition , Forkhead Transcription Factors/genetics , Forkhead Transcription Factors/metabolism , Gene Expression Regulation , Glomerulonephritis/genetics , Glomerulonephritis/pathology , Intracellular Signaling Peptides and Proteins , Mice, Inbred C57BL , Mice, Knockout , Podocytes/pathology , Proteins/genetics , Proteins/metabolism , Receptor, Notch1/genetics , Repressor Proteins/deficiency , Repressor Proteins/genetics , Signal Transduction , Transcription, Genetic , WT1 ProteinsABSTRACT
BACKGROUND: During murine kidney development, new cortical blood vessels form and pattern in cycles that coincide with cycles of collecting duct branching and the accompanying splitting of the cap mesenchyme (nephron progenitor cell populations that "cap" collecting duct ends). At no point in the patterning cycle do blood vessels enter the cap mesenchyme. We hypothesized that the exclusion of blood vessels from the cap mesenchyme may be controlled, at least in part, by an anti-angiogenic signal expressed by the cap mesenchyme cells. RESULTS: We show that semaphorin-3f (Sema3f), a known anti-angiogenic factor, is expressed in cap mesenchymal cells and its receptor, neuropilin-2 (Nrp2), is expressed by newly forming blood vessels in the cortex of the developing kidney. We hypothesized that Sema3f/Nrp2 signaling excludes vessels from the cap mesenchyme. Genetic ablation of Sema3f and of Nrp2, however, failed to result in vessels invading the cap mesenchyme. CONCLUSIONS: Despite complementary expression patterns, our data suggest that Sema3f and Nrp2 are dispensable for the exclusion of vessels from the cap mesenchyme during kidney development. These results should provoke additional experiments to ascertain the biological significance of Sema3f/Nrp2 expression in the developing kidney. Developmental Dynamics 246:1047-1056, 2017. © 2017 Wiley Periodicals, Inc.
Subject(s)
Gene Expression Regulation, Developmental/physiology , Kidney , Membrane Proteins/biosynthesis , Mesoderm , Models, Biological , Neovascularization, Physiologic/physiology , Nerve Tissue Proteins/biosynthesis , Neuropilin-2/biosynthesis , Animals , Kidney/blood supply , Kidney/embryology , Membrane Proteins/genetics , Mesoderm/blood supply , Mesoderm/embryology , Mice , Nerve Tissue Proteins/genetics , Neuropilin-2/geneticsABSTRACT
The transmembrane glycoprotein E11/Podoplanin (Pdpn) has been implicated in the initial stages of osteocyte differentiation. However, its precise function and regulatory mechanisms are still unknown. Due to the known embryonic lethality induced by global Pdpn deletion, we have herein explored the effect of bone-specific Pdpn knockdown on osteocyte form and function in the post-natal mouse. Extensive skeletal phenotyping of male and female 6-week-old Oc-cre;Pdpnflox/flox (cKO) mice and their Pdpnflox/flox controls (fl/fl) has revealed that Pdpn deletion significantly compromises tibial cortical bone microarchitecture in both sexes, albeit to different extents (p < 0.05). Consistent with this, we observed an increase in stiffness in female cKO mice in comparison to fl/fl mice (p < 0.01). Moreover, analysis of the osteocyte phenotype by phalloidin staining revealed a significant decrease in the dendrite volume (p < 0.001) and length (p < 0.001) in cKO mice in which deletion of Pdpn also modifies the bone anabolic loading response (p < 0.05) in comparison to age-matched fl/fl mice. Together, these data confirm a regulatory role for Pdpn in osteocyte dendrite formation and as such, in the control of osteocyte function. As the osteocyte dendritic network is known to play vital roles in regulating bone modeling/remodeling, this highlights an essential role for Pdpn in bone homeostasis.
Subject(s)
Cell Differentiation , Cell Shape , Gene Deletion , Membrane Glycoproteins/metabolism , Osteocytes/metabolism , Osteogenesis , Tibia/metabolism , Animals , Female , Genotype , Male , Membrane Glycoproteins/deficiency , Membrane Glycoproteins/genetics , Mice, Knockout , Osteocytes/pathology , Phenotype , Signal Transduction , Tibia/diagnostic imaging , Tibia/pathology , X-Ray MicrotomographyABSTRACT
In recent years there has been an increase in the number of studies into the role of stromal cells and microRNAs (miRNAs) in kidney development. Nakagawa et al. combine the two in a study of a stromal cell-specific knockout of Dicer1. The work identifies many important roles for miRNAs in these cells and kidney development in general, partially through their modification of the ß-catenin signaling cascade.
Subject(s)
Cell Differentiation/genetics , DEAD-box RNA Helicases/physiology , Neovascularization, Physiologic/genetics , Nephrons/embryology , Ribonuclease III/physiology , Animals , FemaleABSTRACT
This report presents a novel mechanism for remodelling a branched epithelial tree. The mouse renal collecting duct develops by growth and repeated branching of an initially unbranched ureteric bud: this mechanism initially produces an almost fractal form with young branches connected to the centre of the kidney via a sequence of nodes (branch points) distributed widely throughout the developing organ. The collecting ducts of a mature kidney have a different form: from the nephrons in the renal cortex, long, straight lengths of collecting duct run almost parallel to one another through the renal medulla, and open together to the renal pelvis. Here we present time-lapse studies of E11.5 kidneys growing in culture: after about 5 days, the collecting duct trees show evidence of 'node retraction', in which the node of a 'Y'-shaped branch moves downwards, shortening the stalk of the 'Y', lengthening its arms and narrowing their divergence angle so that the 'Y' becomes a 'V'. Computer simulation suggests that node retraction can transform a spread tree, like that of an early kidney, into one with long, almost-parallel medullary rays similar to those seen in a mature real kidney.
Subject(s)
Kidney Tubules, Collecting/embryology , Models, Biological , Morphogenesis/physiology , Animals , Cell Culture Techniques , Cells, Cultured , Computer Simulation , Mice , Mice, Transgenic , Time-Lapse ImagingABSTRACT
BACKGROUND: Glandular organs require the development of a correctly patterned epithelial tree. These arise by iterative branching: early branches have a stereotyped anatomy, while subsequent branching is more flexible, branches spacing out to avoid entanglement. Previous studies have suggested different genetic programs are responsible for these two classes of branches. RESULTS: Here, working with the urinary collecting duct tree of mouse kidneys, we show that the transition from the initial, stereotyped, wide branching to narrower later branching is independent from previous branching events but depends instead on the proximity of other branch tips. A simple computer model suggests that a repelling molecule secreted by branches can in principle generate a well-spaced tree that switches automatically from wide initial branch angles to narrower subsequent ones, and that co-cultured trees would distort their normal shapes rather than colliding. We confirm this collision-avoidance experimentally using organ cultures, and identify BMP7 as the repelling molecule. CONCLUSIONS: We propose that self-avoidance, an intrinsically error-correcting mechanism, may be an important patterning mechanism in collecting duct branching, operating along with already-known mesenchyme-derived paracrine factors.
Subject(s)
Kidney/embryology , Ureter/embryology , Anaplastic Lymphoma Kinase , Animals , Body Patterning , Bone Morphogenetic Protein 7/physiology , Computer Simulation , Kidney/anatomy & histology , Mice, Transgenic , Models, Biological , Receptor Protein-Tyrosine Kinases , Signal Transduction , Tissue Culture TechniquesABSTRACT
The WT1 gene was originally identified through its involvement in the development of Wilms tumours. The gene is characterized by a plethora of different isoforms with, in some cases, clearly different functions in transcriptional control and RNA metabolism. Many different mouse models for Wt1 have already been generated, and these are increasingly providing new information on the molecular roles of Wt1 in normal development and disease. In this review we discuss the different models that have been generated and what they have taught us about the role of Wt1 in the kidney.
Subject(s)
Kidney Neoplasms/genetics , WT1 Proteins/genetics , Wilms Tumor/genetics , Animals , Disease Models, Animal , Humans , MiceABSTRACT
There is much interest in the mechanisms that regulate adult tissue homeostasis and their relationship to processes governing foetal development. Mice deleted for the Wilms' tumour gene, Wt1, lack kidneys, gonads, and spleen and die at mid-gestation due to defective coronary vasculature. Wt1 is vital for maintaining the mesenchymal-epithelial balance in these tissues and is required for the epithelial-to-mesenchyme transition (EMT) that generates coronary vascular progenitors. Although Wt1 is only expressed in rare cell populations in adults including glomerular podocytes, 1% of bone marrow cells, and mesothelium, we hypothesised that this might be important for homeostasis of adult tissues; hence, we deleted the gene ubiquitously in young and adult mice. Within just a few days, the mice suffered glomerulosclerosis, atrophy of the exocrine pancreas and spleen, severe reduction in bone and fat, and failure of erythropoiesis. FACS and culture experiments showed that Wt1 has an intrinsic role in both haematopoietic and mesenchymal stem cell lineages and suggest that defects within these contribute to the phenotypes we observe. We propose that glomerulosclerosis arises in part through down regulation of nephrin, a known Wt1 target gene. Protein profiling in mutant serum showed that there was no systemic inflammatory or nutritional response in the mutant mice. However, there was a dramatic reduction in circulating IGF-1 levels, which is likely to contribute to the bone and fat phenotypes. The reduction of IGF-1 did not result from a decrease in circulating GH, and there is no apparent pathology of the pituitary and adrenal glands. These findings 1) suggest that Wt1 is a major regulator of the homeostasis of some adult tissues, through both local and systemic actions; 2) highlight the differences between foetal and adult tissue regulation; 3) point to the importance of adult mesenchyme in tissue turnover.
Subject(s)
Glomerulonephritis/genetics , Homeostasis/genetics , Multiple Organ Failure/genetics , WT1 Proteins/physiology , Animals , Atrophy/genetics , Atrophy/pathology , Cell Lineage/genetics , Epithelial-Mesenchymal Transition/genetics , Female , Gene Deletion , Gene Expression Regulation , Glomerulonephritis/pathology , Gonads/embryology , Gonads/metabolism , Gonads/pathology , Hematopoiesis/genetics , Insulin-Like Growth Factor I/genetics , Insulin-Like Growth Factor I/metabolism , Kidney Glomerulus/embryology , Kidney Glomerulus/metabolism , Kidney Glomerulus/pathology , Male , Membrane Proteins/genetics , Membrane Proteins/metabolism , Mesenchymal Stem Cells/metabolism , Mice , Mice, Transgenic , Multiple Organ Failure/pathology , Pancreas, Exocrine/embryology , Pancreas, Exocrine/metabolism , Pancreas, Exocrine/pathology , Podocytes/metabolism , Podocytes/pathology , Spleen/embryology , Spleen/metabolism , Spleen/pathology , Tamoxifen/pharmacology , WT1 Proteins/geneticsABSTRACT
Congenital anomalies of the kidney and urinary tract (CAKUTs) are common disorders of human development affecting the renal parechyma, renal pelvis, ureter, bladder and urethra; they show evidence of shared genetic aetiology, although the molecular basis of this remains unknown in the majority of cases. Breakpoint mapping of a de novo, apparently balanced, reciprocal translocation associated with bilateral renal agenesis has implicated the gene encoding the nuclear steroid hormone receptor ESRRG as a candidate gene for CAKUT. Here we show that the Esrrg protein is detected throughout early ureteric ducts as cytoplasmic/sub-membranous staining; with nuclear localization seen in developing nephrons. In 14.5-16.5 dpc (days post-conception) mouse embryos, Esrrg localizes to the subset of ductal tissue within the kidney, liver and lung. The renal ductal expression becomes localized to renal papilla by 18.5 dpc. Perturbation of function was performed in embryonic mouse kidney culture using pooled siRNA to induce knock-down and a specific small-molecule agonist to induce aberrant activation of Esrrg. Both resulted in severe abnormality of early branching events of the ureteric duct. Mouse embryos with a targeted inactivation of Esrrg on both alleles (Esrrg(-/-)) showed agenesis of the renal papilla but normal development of the cortex and remaining medulla. Taken together, these results suggest that Esrrg is required for early branching events of the ureteric duct that occur prior to the onset of nephrogenesis. These findings confirm ESRRG as a strong candidate gene for CAKUT.
Subject(s)
Kidney Medulla/embryology , Receptors, Estrogen/metabolism , Ureter/embryology , Ureter/metabolism , Animals , Congenital Abnormalities/embryology , Congenital Abnormalities/genetics , Congenital Abnormalities/metabolism , Gene Expression Regulation, Developmental , Humans , Kidney/abnormalities , Kidney/embryology , Kidney/metabolism , Kidney Diseases/congenital , Kidney Medulla/metabolism , Mice , Mice, Knockout , Organogenesis , Receptors, Estrogen/geneticsABSTRACT
WT1 is a versatile gene that controls transitions between the mesenchymal and epithelial state of cells in a tissue-context dependent manner. As such, WT1 is indispensable for normal development of many organs and tissues. Uncontrolled epithelial to mesenchymal transition (EMT) is a hallmark of a diverse array of pathologies and disturbance of mesenchymal to epithelial transition (MET) has been associated with a number of developmental abnormalities. It is therefore not surprising that WT1 has been linked to many of these. Here we review the role of WT1 in proper control of the mesenchymal-epithelial balance of cells and discuss how far these roles can explain the role of WT1 in a variety of disease states.
Subject(s)
Epithelial-Mesenchymal Transition/genetics , Epithelium/pathology , Genes, Wilms Tumor/physiology , Kidney Neoplasms/genetics , Mesoderm/pathology , Wilms Tumor/genetics , Animals , Cardiovascular Diseases/genetics , Disease Models, Animal , Embryonic Development/genetics , Gonadal Dysgenesis, 46,XY/genetics , Humans , Kidney/embryology , Kidney Neoplasms/pathology , Mice , Mutation/genetics , Oncogenes/physiology , Regeneration/genetics , Wilms Tumor/pathologyABSTRACT
ErbB4 receptor tyrosine kinase contributes to the development of the heart, the central nervous system, and the lactating mammary gland, but whether it has a role in the development of the kidney epithelium is unknown. Here, we found that expression of Erbb4 isoforms JM-a CYT-1 and JM-a CYT-2 was first detectable around embryonic day 13 in the mouse, mainly in the collecting ducts and both the proximal and distal tubules. In vitro, overexpression of a relevant ErbB4 isoform promoted proliferation and disturbed polarization of kidney epithelial cells when cultured as three-dimensional structures. We examined ErbB4 function in developing kidney tubules in vivo with Pax8-Cre-mediated conditional overexpression of Rosa26 locus-targeted ERBB4 and with conditional Erbb4 knock-out mice. The Pax8-Cre-driven ERBB4 overexpression enhanced proliferation in the collecting ducts, reduced the size of epithelial duct lumens, and promoted formation of cortical tubular cysts. These defects were associated with changes in the subcellular distribution of markers of epithelial cell polarity. Similarly, the Pax8-Cre-mediated Erbb4 knock-out mice manifested dysfunctional kidneys with larger duct lumens and epithelial cell mispolarization. Taken together, these data suggest that ErbB4 signaling modulates proliferation and polarization, cellular functions critical for the development of epithelial ducts in the kidney.
Subject(s)
Cell Polarity , ErbB Receptors/metabolism , Kidney Tubules/embryology , Animals , Cell Proliferation , Dogs , Epithelial Cells/physiology , ErbB Receptors/genetics , Humans , Isoenzymes/metabolism , Kidney Tubules/cytology , Kidney Tubules/metabolism , Mice , Mice, Inbred C57BL , Mice, Knockout , Organogenesis , Receptor, ErbB-4ABSTRACT
Sex determination in mammals depends on the differentiation of the supporting lineage of the gonads into Sertoli or pregranulosa cells that govern testis and ovary development, respectively. Although the Y-linked testis-determining gene Sry has been identified, the ovarian-determining factor remains unknown. In this study, we identified -KTS, a major, alternatively spliced isoform of the Wilms tumor suppressor WT1, as a key determinant of female sex determination. Loss of -KTS variants blocked gonadal differentiation in mice, whereas increased expression, as found in Frasier syndrome, induced precocious differentiation of ovaries independently of their genetic sex. In XY embryos, this antagonized Sry expression, resulting in male-to-female sex reversal. Our results identify -KTS as an ovarian-determining factor and demonstrate that its time of activation is critical in gonadal sex differentiation.
Subject(s)
Ovary , Sex Determination Processes , WT1 Proteins , Animals , Female , Male , Mice , Ovary/growth & development , Sex Determination Processes/genetics , Sex-Determining Region Y Protein/genetics , Sex-Determining Region Y Protein/metabolism , Testis/growth & development , WT1 Proteins/genetics , WT1 Proteins/metabolism , Protein IsoformsABSTRACT
Immune checkpoint therapy (ICT) has the power to eradicate cancer, but the mechanisms that determine effective therapy-induced immune responses are not fully understood. Here, using high-dimensional single-cell profiling, we interrogate whether the landscape of T cell states in the peripheral blood predict responses to combinatorial targeting of the OX40 costimulatory and PD-1 inhibitory pathways. Single-cell RNA sequencing and mass cytometry expose systemic and dynamic activation states of therapy-responsive CD4+ and CD8+ T cells in tumor-bearing mice with expression of distinct natural killer (NK) cell receptors, granzymes, and chemokines/chemokine receptors. Moreover, similar NK cell receptor-expressing CD8+ T cells are also detected in the blood of immunotherapy-responsive cancer patients. Targeting the NK cell and chemokine receptors in tumor-bearing mice shows the functional importance of these receptors for therapy-induced anti-tumor immunity. These findings provide a better understanding of ICT and highlight the use and targeting of dynamic biomarkers on T cells to improve cancer immunotherapy.