Project description:The chronic inflammation of Crohns disease frequently leads to fibrosis and muscular hypertrophy of the intestinal wall. This often culminates in strictures, a serious condition lacking directed therapy. Severe pathological changes occur in the submucosa and muscularis propria intestinal wall layers of strictures, yet stricture-associated proteome changes in these layers is unexplored. We perform unbiased proteomics on submucosa and muscularis propria microdissected from transmural sections of strictured and non-strictured ileum. Proteome changes in stricture submucosa reflect a transition from homeostasis to tissue remodeling, inflammation and smooth muscle alterations. Top submucosa features include reduced vascular components and lipid metabolism proteins accompanied by increased proteins with immune-, matrix- or stress functions including CTHRC1, TNC, IL16, MZB1 and TXNDC5. In parallel, predominant changes in stricture muscularis propria include increased matrix (POSTN) and immune (mast cell CPA3) proteins alongside decreased proteins with lipid metabolic, mitochondrial or key muscle functions. Finally, trends of differentially expressed proteins along non-stricture submucosa suggest progressive profibrotic tissue remodeling and muscle expansion as proximity to stricture increases. The comprehensive proteome map presented here offers unique layer-resolved insight into the stricture microenvironment and potential drivers of fibrotic disease, providing a unique resource to fuel research toward new biomarkers and therapeutic targets.

Project description:The intestinal muscle layers execute various gut wall movements to achieve controlled propulsion and mixing of intestinal content. Engineering intestinal muscle layers with complex contractile function is critical for developing bioartificial intestinal tissue to treat patients with short bowel syndrome. A living intestinal muscle patch is created for the first time in vitro to generate three distinct motility patterns and display multiple digesta manipulations. Developing such intestinal muscle patches combines a differentiation medium and a 3D scaffold. Next-generation RNA sequencing was performed across primary cells isolated from the intestinal muscle layers that were further cultured with/without the differentiation medium or with/without the 3D scaffold to characterize the effect of the medium and the scaffold on the transcriptomic profile of the cells. We found that the successful generation of the contracting intestinal muscle patch relies on both biological factors in the medium and environmental cues from the scaffold. In cooperation, the medium and the scaffold both greatly enhance the differentiation and maturity of the enteric neurons. Separately, the medium profoundly impacts ion transport activities. The scaffold markedly reshapes cell communication and protein binding.

Project description:Skeletal muscle is a highly adaptive tissue that changes with many physiological stimuli and is composed of many cell types. Upon muscle injury, the concerted action of these cells is required to proceed through the process of inflammation, extracellular matrix remodeling, and restoration of function. To uncover novel genes and molecular pathways important for skeletal muscle remodeling and regeneration, we used a mouse hindlimb unloading and reloading protocol, and performed transcriptomics analysis. This study focuses on the microprotein Mustn1 (Musculoskeletal embryonic nuclear protein 1, also known as Mustang), whose gene expression is increased in muscle at the onset of hindlimb reloading, exercise, and injury. We generated a whole-body Mustn1 knockout mouse model and performed proteomics analysis of muscle and aorta.

Project description:Smooth muscle is an essential component of the intestine, both to maintain its structure and produce peristaltic and segmentation movements. However, very little is known about other putative roles that smooth muscle may have. Here, we show that smooth muscle is the dominant supplier of BMP antagonists, which are niche factors that are essential for intestinal stem cell maintenance. Furthermore, muscle-derived factors can render epithelium reparative and fetal-like, which includes heightened YAP activity. Mechanistically, we find that the matrix metalloproteinase MMP17, which is exclusively expressed by smooth muscle, is required for intestinal epithelial repair after inflammation- or irradiation-induced injury. Furthermore, we provide evidence that MMP17 affects intestinal epithelial reprogramming indirectly by cleaving the matricellular protein PERIOSTIN, which itself is able to activate YAP. Together, we identify an important signaling axis that firmly establishes a role for smooth muscle as a modulator of intestinal epithelial regeneration and the intestinal stem cell niche.

Project description:Smooth muscle is an essential component of the intestine, both to maintain its structure and produce peristaltic and segmentation movements. However, very little is known about other putative roles that smooth muscle may have. Here, we show that smooth muscle is the dominant supplier of BMP antagonists, which are niche factors that are essential for intestinal stem cell maintenance. Furthermore, muscle-derived factors can render epithelium reparative and fetal-like, which includes heightened YAP activity. Mechanistically, we find that the matrix metalloproteinase MMP17, which is exclusively expressed by smooth muscle, is required for intestinal epithelial repair after inflammation- or irradiation-induced injury. Furthermore, we provide evidence that MMP17 affects intestinal epithelial reprogramming indirectly by cleaving the matricellular protein PERIOSTIN, which itself is able to activate YAP. Together, we identify an important signaling axis that firmly establishes a role for smooth muscle as a modulator of intestinal epithelial regeneration and the intestinal stem cell niche.

Project description:Anterior vaginal prolapse, as the most common form of POP, severely affect women’s physical and mental health. However, the cellular profiles of vaginal wall and molecular mechanism in pathological process of POP remain unclear. Here, we built the first single-cell transcriptomic atlas of prolapsed vaginal wall. We further revealed prolapse induced aberrant gene expression and transcriptional regulatory networks in cell-type specific manner in POP. Besides extracellular matrix dysregulation, dysfunction of immune cells and immune response were involved with prolapse occur. Computational prediction demonstrated that the abnormal cell-cell communication patterns present among fibroblasts, smooth muscle cells and macrophages in POP, with interplay in extracellular matrix remodeling and regulation of immune reaction. Taken together, our work provides the first comprehensive single-cell transcriptomic atlas for deciphering gene expression landscapes of heterogeneous cell types in prolapsed anterior vaginal wall, broadens our understanding of cell identities and cell-type-specific gene changes in POP and demonstrated the vital role of enhanced interplay between non-immune cells and immune cells in prolapsed vaginal wall.

Project description:Anterior vaginal prolapse, as the most common form of POP, severely affect women’s physical and mental health. However, the cellular profiles of vaginal wall and molecular mechanism in pathological process of POP remain unclear. Here, we built the first single-cell transcriptomic atlas of prolapsed vaginal wall. We further revealed prolapse induced aberrant gene expression and transcriptional regulatory networks in cell-type specific manner in POP. Besides extracellular matrix dysregulation, dysfunction of immune cells and immune response were involved with prolapse occur. Computational prediction demonstrated that the abnormal cell-cell communication patterns present among fibroblasts, smooth muscle cells and macrophages in POP, with interplay in extracellular matrix remodeling and regulation of immune reaction. Taken together, our work provides the first comprehensive single-cell transcriptomic atlas for deciphering gene expression landscapes of heterogeneous cell types in prolapsed anterior vaginal wall, broadens our understanding of cell identities and cell-type-specific gene changes in POP and demonstrated the vital role of enhanced interplay between non-immune cells and immune cells in prolapsed vaginal wall.

Project description:Aging of skeletal muscle tissue is characterized by loss of metabolic and contractile competence. It is thought that this phenomenon is driven via extrinsic and intrinsic factors. In order to identify age-dependent changes intrinsic to the muscle cell, microarray transcriptional profiles and measurements of glucose metabolism were performed in primary cultured human myotubes at different time points over seven weeks. Aging in culture tended to reduce myotube glucose metabolism, oxidative and storage capacities, despite elevation of glucose transport. The mitochondrial membrane potential slightly increased, whereas peroxidation of cell membrane lipids declined and membrane integrity was preserved. Transcriptional analysis revealed a fall in genes involved in glucose metabolism and oxidative phosphorylation, while stress defense genes were elevated. Expression of numerous genes coding for muscle contractile proteins and calcium-regulating proteins, was gradually decreased during aging of cultured myotubes. Transcripts of genes involved in cell growth, matrix and motility markedly rose while those involved in cell adhesion dropped. In conclusion, aging myotubes in culture exhibit a loss of glucose metabolic capacity. They are characterized by a shift from a contractile to a growth-survival, matrix-remodeling phenotype. This pattern of changes, linked to intrinsic factors, displays significant similarities with aging of muscle from primates and human subjects.

Project description:Diverse functions of the homeodomain transcription factor BARX1 include Wnt-dependent, non-cell autonomous specification of the stomach epithelium, tracheo-bronchial septation, and Wnt-independent expansion of the spleen primordium. Tight spatio-temporal regulation of Barx1 levels in the mesentery and stomach mesenchyme suggests additional roles. To determine these functions, we forced constitutive BARX1 expression in the Bapx1 expression domain, which includes the mesentery and intestinal mesenchyme, and also examined Barx1-/- embryos in further detail. Transgenic embryos invariably showed intestinal truncation and malrotation, in part reflecting abnormal left-right patterning. Ectopic BARX1 expression did not affect intestinal epithelium, but intestinal smooth muscle developed with features typical of the stomach wall. BARX1, which is normally restricted to the developing stomach, drives robust smooth muscle expansion in this organ by promoting proliferation of myogenic progenitors at the expense of other sub-epithelial cells. Undifferentiated embryonic stomach and intestinal mesenchyme showed modest differences in mRNA expression and BARX1 was sufficient to induce much of the stomach profile in intestinal cells. However, limited binding at cis-regulatory sites implies that BARX1 may act principally through other transcription factors. Genes expressed ectopically in BARX1+ intestinal mesenchyme and reduced in Barx1-/- stomach mesenchyme include Isl1, Pitx1, Six2 and Pitx2, transcription factors known to control left-right patterning and influence smooth muscle development. The sum of evidence suggests that potent BARX1 functions in intestinal rotation and stomach myogenesis occur through this small group of intermediary transcription factors.

Project description:Diverse functions of the homeodomain transcription factor BARX1 include Wnt-dependent, non-cell autonomous specification of the stomach epithelium, tracheo-bronchial septation, and Wnt-independent expansion of the spleen primordium. Tight spatio-temporal regulation of Barx1 levels in the mesentery and stomach mesenchyme suggests additional roles. To determine these functions, we forced constitutive BARX1 expression in the Bapx1 expression domain, which includes the mesentery and intestinal mesenchyme, and also examined Barx1-/- embryos in further detail. Transgenic embryos invariably showed intestinal truncation and malrotation, in part reflecting abnormal left-right patterning. Ectopic BARX1 expression did not affect intestinal epithelium, but intestinal smooth muscle developed with features typical of the stomach wall. BARX1, which is normally restricted to the developing stomach, drives robust smooth muscle expansion in this organ by promoting proliferation of myogenic progenitors at the expense of other sub-epithelial cells. Undifferentiated embryonic stomach and intestinal mesenchyme showed modest differences in mRNA expression and BARX1 was sufficient to induce much of the stomach profile in intestinal cells. However, limited binding at cis-regulatory sites implies that BARX1 may act principally through other transcription factors. Genes expressed ectopically in BARX1+ intestinal mesenchyme and reduced in Barx1-/- stomach mesenchyme include Isl1, Pitx1, Six2 and Pitx2, transcription factors known to control left-right patterning and influence smooth muscle development. The sum of evidence suggests that potent BARX1 functions in intestinal rotation and stomach myogenesis occur through this small group of intermediary transcription factors. To investigate how Barx1 regulates gut smooth muscle development in a cell-autonomous manner, we used Affymetrix arrays to profile genes enriched in wild-type stomach and BARX1-overexpressing intestinal mesenchyme, compared to wild-type intestinal mesenchyme.