Project description:Developing gut in mice undergoes rapid elongation during late embryogenesis, yet significantly slows down after birth. Precise regulatory mechanism of this dynamic morphogenetic process remains unknown. Utilizing single-cell RNA-sequencing analysis, we show that YAP activity in Cxcl13high intestinal fibroblasts is the major molecular contributor to gut elongation. To determine how mesenchymal YAP activity is controlled, we identified canonical Sarcolemma membrane-associated protein (SLMAP) as its critical regulator during embryonic gut morphogenesis. Deleting Slmap in gut mesenchyme impairs YAP activity, leading to short gut and a significant decrease in intestinal epithelial cell proliferation. Mechanistically, SLMAP activates YAP by directly regulating MST3 kinase. Physiologically, MST3 levels prominently increase over the developmental time, reaching their peak on postnatal day P14, when gut elongation in mice slows down. Depleting Mst3 in mesenchyme results in increased gut length at P14 accompanied by enhanced YAP activity. Importantly, short gut phenotype in mesenchyme-specific Slmap mutant mice is partially compensated by concomitant deletion of mesenchymal Mst3. Taken together, our findings demonstrate that SLMAP interacts with MST3 kinase to dynamically regulate mesenchymal YAP activity that governs dynamic gut elongation across its embryonic and postnatal development.

Project description:Developing gut in mice undergoes rapid elongation during late embryogenesis, yet significantly slows down after birth. Precise regulatory mechanism of this dynamic morphogenetic process remains unknown. Utilizing scRNA-seq analysis, we show that YAP activity in Cxcl13high intestinal fibroblasts is the major molecular contributor to gut elongation. To determine how mesenchymal YAP activity is controlled, we identified canonical Sarcolemma membrane-associated protein (SLMAP) as its critical regulator during embryonic gut morphogenesis. Deleting Slmap in gut mesenchyme impairs YAP activity, leading to short gut and a significant decrease in intestinal epithelial cell proliferation. Mechanistically, Slmap activates YAP by directly regulating Mst3 kinase. Physiologically, Mst3 levels prominently increase over the developmental time, reaching their peak on postnatal day P14, when gut elongation in mice slows down. Depleting Mst3 in mesenchyme results in increased gut length at P14 accompanied by enhanced YAP activity. Importantly, short gut phenotype in SlmapcKO mice is partially compensated by concomitant deletion of mesenchymal Mst3. Taken together, our findings demonstrate that Slmap interacts with Mst3 kinase to dynamically regulate mesenchymal YAP activity that governs gut elongation across its embryonic and postnatal development.

Project description:Mesenchymal SLMAP coordinates with MST3 to govern gut elongation during development

Project description:Mesenchymal SLMAP coordinates with MST3 to govern gut elongation during development [RNAseq_TL]

Project description:Mesenchymal SLMAP coordinates with MST3 to govern gut elongation during development (scRNA-Seq)

Project description:Aberrant mtROS release in response to mitochondrial stress are considered to be a major novel feature of neoplastic transformation. However, the molecular mechanisms by which mtROS contribute to CRC development have not been fully elucidated. In this study, we showed that upon sensing the mtROS signal, the mitochondrially localized phosphatase PGAM5 undergoes cleavage in the mitochondrial transmembrane domain, and then the Cleaved PGAM5 is released into the cytoplasm. Subsequently, Cleaved PGAM5 binds to the kinase MST3 in the cytoplasm to promote MST3 dephosphorylation, resulting in a decrease in MST3 activity. Importantly, MST3 inactivation failed to regulate YAP phosphorylation, leading to YAP translocation into the nucleus, consequently promoting CRC proliferation and metastasis. Collectively, our findings identified the PGAM5-MST3-YAP axis as an important molecular mechanism through which mtROS promotes CRC development.

Project description:Aberrant mtROS release in response to mitochondrial stress are considered to be a major novel feature of neoplastic transformation. However, the molecular mechanisms by which mtROS contribute to CRC development have not been fully elucidated. In this study, we showed that upon sensing the mtROS signal, the mitochondrially localized phosphatase PGAM5 undergoes cleavage in the mitochondrial transmembrane domain, and then the Cleaved PGAM5 is released into the cytoplasm. Subsequently, Cleaved PGAM5 binds to the kinase MST3 in the cytoplasm to promote MST3 dephosphorylation, resulting in a decrease in MST3 activity. Importantly, MST3 inactivation failed to regulate YAP phosphorylation, leading to YAP translocation into the nucleus, consequently promoting CRC proliferation and metastasis. Collectively, our findings identified the PGAM5-MST3-YAP axis as an important molecular mechanism through which mtROS promotes CRC development.

Project description:Recent studies identified FoxL1+-Telocytes (TCFoxL1+) as key players in gut epithelial-mesenchymal interactions impacting the microenvironment. Disruption of BMP-signaling in TCFoxL1+ alters the physical and cellular microenvironment leading to gut pathophysiology, suggesting a role for TCFoxL1+ in stromagenesis. However, profiling studies from whole tissue can be misleading when analyzing the specific contribution of TCFoxL1+. We performed an ex vivo deconstruction of control and BmpR1a△FoxL1+ colons, isolated the mesenchyme-enriched fractions and determined the protein composition of in vivo ECM to compare the microenvironment. Matrisomic analysis of mesenchyme fractions revealed modulations in ECM proteins with functions associated to innate immunity, epithelial wound healing and collagen network. These results show that TCFoxL1+ have a critical role in orchestrating the colon ECM biodynamics. Dysfunctional TCFoxL1+ reprogram the microenvironment driving the epithelium toward pathologies. This method allows to truthfully investigate how TCFoxL1+ impacts matrix dynamics leading to a comprehensive ECM profiling in diseases.

Project description:Mesenchymal-epithelial interactions play a critical role in organ development, stem cells and disease. During intestinal development, pseudostratified epithelia undergo dramatic morphogenesis called villification, to form finger-like projections, in which mesenchymal cell clustering and muscle layers play a key role. In the adult, the gut mesenchyme is proposed as a key intestinal stem cell niche providing essential niche signals such as Wnt ligands, while the TGF beta signaling mediated gut stromal program is critical for cancer progression. However, how these signals are produced is currently unknown. In the gut, Hedgehog (Hh) signaling acts strictly in a paracrine manner: Hh ligands are expressed in the epithelium and activate signaling exclusively in the mesenchyme. Notably, Hh signaling is not only essential for mesenchymal clustering and muscle differentiation, it is also involved in intestinal tumorigenesis. To investigate Hh mediated mechanisms, we analyzed mice deleted for key Hh negative regulators, Sufu and/or Spop in the gut mesenchyme, and demonstrated their dosage dependent role in the negative regulation of Hh signaling. Although these mutants exhibit abnormal mesenchymal cell growth and functionally defective muscle layers, villification is completed with proper mesenchymal clustering, implying a permissive role for Hh signaling. These mesenchymal defects are partially rescued by Gli2 reduction, demonstrating the significance of its transcriptional regulation. Surprisingly, in contrast to its known inhibitory role in epithelial proliferation, abnormal Hh activation in the gut mesenchyme leads to increased epithelial proliferation. Corroborating this data, Sufu reduction is sufficient to promote intestinal tumorigenesis, while Gli2 heterozygosity suppresses it. To define GLI2-mediated downstream mechanisms, we mapped its binding sites and analyzed gene expression genome-wide, identifying one of the most robust Hh direct targetome data sets ever reported. This work reveals the GLI2 transcriptional regulation of Wnt and TGF beta pathways in stem cell proliferation and muscle differentiation, providing mechanistic insight into the intestinal stem cell niche in development and tumorigenesis.

Project description:Mesenchymal-epithelial interactions play a critical role in organ development, stem cells and disease. During intestinal development, pseudostratified epithelia undergo dramatic morphogenesis called villification, to form finger-like projections, in which mesenchymal cell clustering and muscle layers play a key role. In the adult, the gut mesenchyme is proposed as a key intestinal stem cell niche providing essential niche signals such as Wnt ligands, while the TGF beta signaling mediated gut stromal program is critical for cancer progression. However, how these signals are produced is currently unknown. In the gut, Hedgehog (Hh) signaling acts strictly in a paracrine manner: Hh ligands are expressed in the epithelium and activate signaling exclusively in the mesenchyme. Notably, Hh signaling is not only essential for mesenchymal clustering and muscle differentiation, it is also involved in intestinal tumorigenesis. To investigate Hh mediated mechanisms, we analyzed mice deleted for key Hh negative regulators, Sufu and/or Spop in the gut mesenchyme, and demonstrated their dosage dependent role in the negative regulation of Hh signaling. Although these mutants exhibit abnormal mesenchymal cell growth and functionally defective muscle layers, villification is completed with proper mesenchymal clustering, implying a permissive role for Hh signaling. These mesenchymal defects are partially rescued by Gli2 reduction, demonstrating the significance of its transcriptional regulation. Surprisingly, in contrast to its known inhibitory role in epithelial proliferation, abnormal Hh activation in the gut mesenchyme leads to increased epithelial proliferation. Corroborating this data, Sufu reduction is sufficient to promote intestinal tumorigenesis, while Gli2 heterozygosity suppresses it. To define GLI2-mediated downstream mechanisms, we mapped its binding sites and analyzed gene expression genome-wide, identifying one of the most robust Hh direct targetome data sets ever reported. This work reveals the GLI2 transcriptional regulation of Wnt and TGF beta pathways in stem cell proliferation and muscle differentiation, providing mechanistic insight into the intestinal stem cell niche in development and tumorigenesis.