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The Hippo pathway directs cell differentiation during organogenesis, in part by restricting proliferation. How Hippo signaling maintains a proliferation-differentiation balance in developing tissues via distinct molecular targets is only beginning to be understood. Our study makes the unexpected finding that Hippo suppresses nuclear factor kappa-light-chain-enhancer of activated B cells (NFκB) signaling in pancreatic progenitors to permit cell differentiation and epithelial morphogenesis. We find that pancreas-specific deletion of the large tumor suppressor kinases 1 and 2 (Lats1/2PanKO) from mouse progenitor epithelia results in failure to differentiate key pancreatic lineages: acinar, ductal, and endocrine. We carried out an unbiased transcriptome analysis to query differentiation defects in Lats1/2PanKO. This analysis revealed increased expression of NFκB activators, including the pantetheinase vanin1 (Vnn1). Using in vivo and ex vivo studies, we show that VNN1 activates a detrimental cascade of processes in Lats1/2PanKO epithelium, including (1) NFκB activation and (2) aberrant initiation of epithelial-mesenchymal transition (EMT), which together disrupt normal differentiation. We show that exogenous stimulation of VNN1 or NFκB can trigger this cascade in wild-type (WT) pancreatic progenitors. These findings reveal an unexpected requirement for active suppression of NFκB by LATS1/2 during pancreas development, which restrains a cell-autonomous deleterious transcriptional program and thereby allows epithelial differentiation.

The kidney vasculature facilitates the excretion of wastes, the dissemination of hormones, and the regulation of blood chemistry. To carry out these diverse functions, the vasculature is regionalized within the kidney and along the nephron. However, when and how endothelial regionalization occurs remains unknown. Here, we examine the developing kidney vasculature to assess its 3-dimensional structure and transcriptional heterogeneity. First, we observe that endothelial cells (ECs) grow coordinately with the kidney bud as early as E10.5, and begin to show signs of specification by E13.5 when the first arteries can be identified. We then focus on how ECs pattern and remodel with respect to the developing nephron and collecting duct epithelia. ECs circumscribe nephron progenitor populations at the distal tips of the ureteric bud (UB) tree and form stereotyped cruciform structures around each tip. Beginning at the renal vesicle (RV) stage, ECs form a continuous plexus around developing nephrons. The endothelial plexus envelops and elaborates with the maturing nephron, becoming preferentially enriched along the early distal tubule. Lastly, we perform transcriptional and immunofluorescent screens to characterize spatiotemporal heterogeneity in the kidney vasculature and identify novel regionally enriched genes. A better understanding of development of the kidney vasculature will help instruct engineering of properly vascularized ex vivo kidneys and evaluate diseased kidneys.

Mammals achieve the highest urine concentrations of any vertebrate, a feat that hinges on generating steep osmotic gradients within the renal medulla. Interestingly, the region with the highest osmolality, the inner medulla, is unique to mammals. Among the nephron’s segments, the ascending thin limb (aTL) is the sole element exclusive to this zone and is thought to mediate passive salt reabsorption. However, the architecture and functional impact of the aTL have remained obscure. Here we uncover an unexpected morphogenetic program in the aTL, characterized by extensive apical-junctional interdigitations that greatly increase cell-to-cell contact area. Integrating single-nucleus transcriptomics with high-resolution imaging, we identify claudin-10b, a tight junction protein and paracellular cation pore, as a central driver of this architecture. Inducible deletion of claudin-10b specifically in the aTL abolishes membrane interdigitations and markedly reduces urine-concentrating ability, thereby establishing a direct link between segment-specific epithelial morphology and whole-organ function. Claudin-10b proves necessary for interdigitation formation, acting through transcellular adhesion and interaction with the tight-junction scaffold ZO1. These findings offer definitive evidence that the inner medulla and aTL are essential for maximal urinary concentration, while revealing a non-canonical, morphogenetic role for claudin-10b. This study identifies extensive lateral interdigitations in the kidney’s ascending thin limb and demonstrates that Claudin-10b regulates both epithelial architecture and urine-concentrating function in this distinct nephron segment.

The Hippo pathway directs cell differentiation during organogenesis, in part by restricting proliferation. How Hippo signaling maintains a proliferation-differentiation balance in developing tissues via distinct molecular targets is only beginning to be understood. Our study makes the unexpected finding that Hippo suppresses nuclear factor kappa-light-chain-enhancer of activated B cells (NF[kappa]B) signaling in pancreatic progenitors to permit cell differentiation and epithelial morphogenesis. We find that pancreas-specific deletion of the large tumor suppressor kinases 1 and 2 (Lats1/2.sup.PanKO) from mouse progenitor epithelia results in failure to differentiate key pancreatic lineages: acinar, ductal, and endocrine. We carried out an unbiased transcriptome analysis to query differentiation defects in Lats1/2.sup.PanKO . This analysis revealed increased expression of NF[kappa]B activators, including the pantetheinase vanin1 (Vnn1). Using in vivo and ex vivo studies, we show that VNN1 activates a detrimental cascade of processes in Lats1/2.sup.PanKO epithelium, including (1) NF[kappa]B activation and (2) aberrant initiation of epithelial-mesenchymal transition (EMT), which together disrupt normal differentiation. We show that exogenous stimulation of VNN1 or NF[kappa]B can trigger this cascade in wild-type (WT) pancreatic progenitors. These findings reveal an unexpected requirement for active suppression of NF[kappa]B by LATS1/2 during pancreas development, which restrains a cell-autonomous deleterious transcriptional program and thereby allows epithelial differentiation.

Single-ventricle congenital heart disease (SV-CHD) is a uniformly lethal condition requiring the Glenn surgery, which as a side effect eliminates arterial pulsatility and contributes to pulmonary vascular complications. In Glenn patients, we quantified pulsatility loss in each dimension of force (flow, pressure, and stretch) using cardiac catheterization and MRI. To model and investigate the individual impact of each dimension of pulsatility loss on the pulmonary vasculature, we applied isolated pulsatile and non-pulsatile mechanical stimuli to pulmonary artery endothelial cells (ECs) in vitro. We found that each dimension of force triggered distinct transcriptional responses, revealing force-specific regulation of structural and signaling pathways. Pulsatile stretch uniquely stimulated EC secretion of PDGFB, a key driver of vascular smooth muscle cell (vSMC) recruitment. In a rat Glenn model, loss of pulsatility led to vascular wall thinning, loss of EC PDGFB, and reduced activation of smooth muscle PDGFBRβ, confirming in vivo relevance. Our findings uncover a mechanistic link between endothelial stretch sensing and PDGFB-mediated EC-vSMC crosstalk, essential for maintaining pulmonary artery architecture. Clinically, these insights suggest that restoring or mimicking pulsatile forces may help preserve vascular integrity and prevent remodeling in patients with SV-CHD.

Single ventricle congenital heart disease (SV-CHD) is a uniformly lethal condition. Survival depends upon the Glenn surgery, which shunts venous blood directly to the pulmonary arteries without the support of a pumping ventricle. In the context of this altered circulation (loss of cardiac-driven pulsatility), diverse pulmonary vascular complications develop, severely limiting survival. To date, the relationship between loss of arterial pulsatility and pulmonary vascular changes has not yet been investigated at the cellular level. Using combined cardiac catheterization and cardiac MRI, we defined pulsatility loss in three dimensions (flow, pressure, and stretch) in the pulmonary arteries of SV-CHD patients in the Glenn stage. To assess the impact of pulsatility loss on endothelial cells (ECs), we exposed cultured human pulmonary artery endothelial cells to individual dimensions of force. We used bulk RNA sequencing, GSEA, ELISA, and immunofluorescent staining to investigate cellular changes. A rat model of the Glenn circulation was used to further assess the cellular adaptation of pulmonary arteries to non-pulsatile hemodynamic forces. We identify and quantify pulsatility loss in Glenn patients, occurring in all three dimensions of hemodynamic force. We show unique transcriptional signatures of pulsatility within each dimension of force, affecting key structural and signaling pathways in ECs. We identify pulsatile stretch as a critical stimulus for endothelial secretion of PDGFB-a known driver of vascular smooth muscle cell (vSMC) proliferation and vascular wall recruitment. Moreover, we show that loss of arterial pulsatility leads to thinning of the vascular wall and reduction of VSMCs. This work identifies a novel and critical role for blood flow pulsatility in maintenance of the pulmonary vascular architecture. Our study provides a mechanistic understanding of the role of pulsatile, arterial forces in maintaining normal pulmonary vascular architecture through EC-SMC crosstalk. Arterial pulsatility is sensed by stretch of endothelial cells and relayed via PDGFB to the vascular smooth muscle, thus maintaining a vascular structure that can support arterial hemodynamic force.

Kidney formation requires the coordinated growth of multiple cell types including the collecting ducts, nephrons, vasculature and interstitium. There has been a long-held belief that interactions between the progenitors of the collecting ducts and nephrons are primarily responsible for kidney development. However, over the last several years, it has become increasingly clear that multiple aspects of kidney development require signaling from the interstitium. How the interstitium orchestrates these multiple roles is still poorly understood. We show that during development, the interstitium is a highly heterogeneous, patterned population of cells that occupies distinct positions correlated to the adjacent parenchyma. Our analysis indicates that the heterogeneity is not a mere reflection of different stages in a linear developmental trajectory but instead represents several novel differentiated cell states. Further, we find that beta-catenin has a cell autonomous role in the development of a medullary subset of the interstitium and that this non-autonomously affects the development of the adjacent epithelia. These findings suggest the intriguing possibility that the different interstitial subtypes may create microenvironments that play unique roles in development of the adjacent epithelia and endothelia.

Single ventricle congenital heart disease (SV-CHD) is a uniformly lethal condition requiring the Glenn surgery, which as a side effect eliminates arterial pulsatility and contributes to pulmonary vascular complications. In Glenn patients, we quantified pulsatility loss in each dimension of force (flow, pressure, and stretch) using cardiac catheterization and MRI. To model and investigate the individual impact of each dimension of pulsatility loss on the pulmonary vasculature, we applied isolated pulsatile and non-pulsatile mechanical stimuli to pulmonary arterial endothelial cells (ECs) in vitro. We found that each dimension of force triggered distinct transcriptional responses, revealing force-specific regulation of structural and signaling pathways. Pulsatile stretch uniquely stimulated EC secretion of PDGFB, a key driver of vascular smooth muscle cell (vSMC) recruitment. In a rat Glenn model, loss of pulsatility led to vascular wall thinning, confirming in vivo relevance. Our findings uncover a mechanistic link between endothelial stretch sensing and PDGFB-mediated EC-vSMC crosstalk, essential for maintaining pulmonary artery architecture. Clinically, these insights suggest that restoring or mimicking pulsatile forces may help preserve vascular integrity and prevent remodeling in SV-CHD patients.

The kidney is a complex organ requiring tightly coordinated interactions between epithelial, endothelial, and mesenchymal cells during development. Congenital kidney defects can result in kidney disease and renal failure, highlighting the importance of understanding kidney formation mechanisms. Advances in RNA sequencing have revealed remarkable cellular heterogeneity, especially in the kidney stroma, though relationships between stromal, epithelial, and endothelial cells remain unclear. This study presents a comprehensive gene expression atlas of embryonic and postnatal kidneys, integrating single-nucleus and in situ RNA sequencing data. We developed the Kidney Spatial Transcriptome Analysis Tool (KSTAT), enabling researchers to identify cell locations, predict cell-cell communication, and map gene pathway activity. KSTAT revealed significant heterogeneity among embryonic kidney pericytes, providing a critical resource for hypothesis generation and advancing knowledge of kidney development and disease.Competing Interest StatementThe authors have declared no competing interest.

The James Webb Space Telescope (JWST) is a large, infrared space telescope that has recently started its science program which will enable breakthroughs in astrophysics and planetary science. Notably, JWST will provide the very first observations of the earliest luminous objects in the universe and start a new era of exoplanet atmospheric characterization. This transformative science is enabled by a 6.6 m telescope that is passively cooled with a 5 layer sunshield. The primary mirror is comprised of 18 controllable, low areal density hexagonal segments, that were aligned and phased relative to each other in orbit using innovative image-based wave front sensing and control algorithms. This revolutionary telescope took more than two decades to develop with a widely distributed team across engineering disciplines. We present an overview of the telescope requirements, architecture, development, superb on-orbit performance, and lessons learned. JWST successfully demonstrates a segmented aperture space telescope and establishes a path to building even larger space telescopes.