Project description:We performed molecular phenotyping of RV remodeling, using transcriptome analysis of RV tissue obtained from MCT-induced rats (of both male and female animals). The clustering approach along with precise hemodynamics assessments identified “early" and "late" subgroups of decompensated state in rat RV. Further molecular characterization of these subgroups identified distinct molecular genes and pathways within different stages of RV remodeling. This study provided a resource to comprehensively compare human RV remodeling with the current animal model of PH (MCT), and led to validation of state-specific biomarkers and potential therapeutic targets for RV dysfunction.

Project description:Human cardiac tissue (Apex, LV, RV), whole tissue and isolated cardiomyocyte, processed by s-trap, with and without high pH fractionation, DDA of non-fractionated and fractionated and DIA of non-fractionated

Project description:Insulin-producing beta cells become dedifferentiated during diabetes progression. An impaired ability to select substrates for oxidative phosphorylation, or metabolic inflexibility, sets the stage for progression from beta cell dysfunction to beta cell dedifferentiation. In this study, we sought to isolate and functionally characterize failing beta cells, as a preliminary step to identify pathways to reverse dedifferentiation. Using various experimental models of diabetes, we found a striking enrichment in the expression of aldehyde dehydrogenase 1 isoform A3 (ALDH+) as beta cells become dedifferentiated. Flow-sorted ALDH+ islet cells demonstrate impaired glucose-induced insulin secretion, are depleted of Foxo1 and MafA, and include a Neurogenin3-positive subset. RNA sequencing analysis demonstrates that ALDH+ cells are characterized by: (i) impaired oxidative phosphorylation and mitochondrial complex I, IV, and V; (ii) activated RICTOR; and (iii) progenitor cell markers. We propose that impaired mitochondrial function marks the progression from metabolic inflexibility to dedifferentiation in the natural history of beta cell failure. RNA-Sequencing analysis of 2 different cell types in 2 different genotype categories.

Project description:Bone marrow mesenchymal stem cells (MSC) were adipogenically differentiated followed by dedifferentiation. We are interested to know the new fat markers, adipogenic signaling pathways and dedifferentiation signaling pathways.Furthermore we are also intrested to know that how differentiated cells convert into dedifferentiated progenitor cells. To address these questions, MSC were adipogenically differentiated, followed by dedifferentiation. Finally these dedifferentiated cells were used for adipogenesis, osteogenesis and chondrogenesis. Histology, FACS, qPCR and GeneChip analyses of undifferentiated, adipogenically differentiated and dedifferentiated cells were performed. Regarding the conversion of adipogenically differentiated cells into dedifferentiated cells, gene profiling and bioinformatics demonstrated that upregulation (DHCR24, G0S2, MAP2K6, SESN3) and downregulation (DST, KAT2, MLL5, RB1, SMAD3, ZAK) of distinct genes play a curcial role in cell cycle to drive the adipogenically differentiated cells towards an arrested state to narrow down the lineage potency. However, the upregulation (CCND1, CHEK, HGF, HMGA2, SMAD3) and downregulation (CCPG1, RASSF4, RGS2) of these cell cycle genes motivates dedifferentiation of adipogenically differentiated cells to reverse the arrested state. We also found new fat markers along with signaling pathways for adipogenically differentiated and dedifferentiated cells, and also observed the influencing role of proliferation associated genes in cell cycle arrest and progression. We have differentiated bone marrow derived mesenchymal stem cells(MSC) into adipogenically differentiated cells followed by dedifferentiation. We are intrested to know new fat markers, signaling pathways for adipogenically differentiated and dedifferentiated cells, along to observe the genes associated with cell cycle arrest and progression. Results are also provide molecular insight into the process of adipogenesis and dedifferentiation. To study the adipogenic differentiation and dedifferentiation process along with "how adipogenically differentiated cells convert into dedifferentiated cells" on the molecular level, gene expression profiling with genome-wide Affymetrix HG-U133 Plus 2.0 olgonucleotide microarrays (Affymetrix, Santa Clara, CA, USA) was applied. In total, 12 GeneChips were performed for n=3 donors and 4 times (3x4=12): 3x P4 MSC (undifferentiated state), 3x adipogenically differentiated cells at day 15 (differentiated state), 3x dedifferentiated cells at day 7 (dedifferentiated state) and 3x dedifferentiated cells at day 35 (dedifferentiated state)

Project description:Pulmonary arterial hypertension (PAH) is a progressive disease characterized by pulmonary vascular remodeling leading to increased pulmonary vascular resistance and right ventricular (RV) hypertrophy, resulting in RV failure. RV dysfunction is a complex process that leads to cardiomyocyte hypertrophy, fibrosis, inflammation, angiogenesis, and metabolic changes. In patient with PAH, the adaptation of the RV to high pulmonary arterial pressures is the most important determinant of prognosis. However, the underlying molecular mechanism of adverse RV remodeling and dysfunction is poorly understood, and there are no currently approved therapies that improve RV function. Chrysin (5,7-dihydroxyflavone) is a phytochemical, which is a flavonoid widely present in plant sources. In various experimental models chrysin has shown to exert cardio-protective effects through its antioxidant and anti-inflammatory effects. In this study, we performed a comprehensive analysis of gene expression changes in heart tissues of rats under hypoxic conditions with chrysin treatment using RNA sequencing (RNA-seq).

Project description:Right ventricular (RV) failure is the major determinant of outcome in pulmonary hypertension (PH). Calves exposed to 2-wks environmental hypoxia develop severe PH and unlike rodents, chronic hypoxia-induced PH in this species can lead to right heart failure. We therefore sought to examine the molecular and structural changes in the RV in calves with hypoxia-induced PH, hypothesizing that we could identify mechanisms underlying compensated physiological function in the face of developing severe PH. Calves were exposed to 14d of hypobaric hypoxia (PB=430 mm Hg, equivalent to 4570m elevation, n=29) or ambient normoxia (1525m, n=25). Cardiopulmonary function was evaluated by right heart catheterization and pressure volume loops. Molecular and cellular determinants of RV remodeling were analyzed by cDNA microarrays, RealTime PCR, proteomics and immunochemistry. Hypoxic exposure induced robust PH, with increased RV contractile performance and preserved cardiac output, yet evidence of dysregulated RV-pulmonary artery mechanical coupling consistent with advanced PH. Analysis of gene expression revealed cellular processes associated with structural remodeling, cell signaling, and survival. We further identified specific clusters of gene expression associated with (i) hypertrophic gene expression and pro-survival mechanotransduction through YAP-TAZ signaling, (ii) ECM remodeling, (iii) inflammatory cell activation and (iv) angiogenesis. A potential transcriptomic signature of cardiac fibroblasts in RV remodeling was detected. Proteomic and immunohistochemical analysis confirmed RV myocyte hypertrophy, together with localization of ECM remodeling, inflammatory cell activation, and endothelial cell proliferation within the RV interstitium. In conclusion, hypoxia and hemodynamic load initiate coordinated processes of protective and compensatory RV remodeling to withstand the progression of PH.

Project description:Insulin-producing beta cells become dedifferentiated during diabetes progression. An impaired ability to select substrates for oxidative phosphorylation, or metabolic inflexibility, sets the stage for progression from beta cell dysfunction to beta cell dedifferentiation. In this study, we sought to isolate and functionally characterize failing beta cells, as a preliminary step to identify pathways to reverse dedifferentiation. Using various experimental models of diabetes, we found a striking enrichment in the expression of aldehyde dehydrogenase 1 isoform A3 (ALDH+) as beta cells become dedifferentiated. Flow-sorted ALDH+ islet cells demonstrate impaired glucose-induced insulin secretion, are depleted of Foxo1 and MafA, and include a Neurogenin3-positive subset. RNA sequencing analysis demonstrates that ALDH+ cells are characterized by: (i) impaired oxidative phosphorylation and mitochondrial complex I, IV, and V; (ii) activated RICTOR; and (iii) progenitor cell markers. We propose that impaired mitochondrial function marks the progression from metabolic inflexibility to dedifferentiation in the natural history of beta cell failure.

Project description:Right ventricular (RV) failure plays a critical role in any type of heart failure. However, there is no specific therapy developed for RV failure. To understand RV failure, we focused on the RV specific genes. Global gene expression analysis showed that alternative complement pathway-related genes including C3 and Cfd were significantly upregulated in right ventricle in murine heart. We generated the RV failure by right ventricle-specific pressure overload model mice, pulmonary artery constriction (PAC), which induces RV failure around 14 days. After administration of C3a receptor (C3aR) antagonist, RV function was dramatically improved PAC-induced RV dysfunction in wild type mice. To investigate the role of C3a to cardiomyocyte, C3a recombinant protein was administerd to neonatal rat ventricular myocytes (NRVMs), the results that several MAP kinesis were phosphorylated by C3a. In turn, to identify the key expressed genes as downstream of C3a in NRVMs, global gene expression analysis was performed in vitro.

Project description:Bone marrow mesenchymal stem cells (MSC) were adipogenically differentiated followed by dedifferentiation. We are interested to know the new fat markers, adipogenic signaling pathways and dedifferentiation signaling pathways.Furthermore we are also intrested to know that how differentiated cells convert into dedifferentiated progenitor cells. To address these questions, MSC were adipogenically differentiated, followed by dedifferentiation. Finally these dedifferentiated cells were used for adipogenesis, osteogenesis and chondrogenesis. Histology, FACS, qPCR and GeneChip analyses of undifferentiated, adipogenically differentiated and dedifferentiated cells were performed. Regarding the conversion of adipogenically differentiated cells into dedifferentiated cells, gene profiling and bioinformatics demonstrated that upregulation (DHCR24, G0S2, MAP2K6, SESN3) and downregulation (DST, KAT2, MLL5, RB1, SMAD3, ZAK) of distinct genes play a curcial role in cell cycle to drive the adipogenically differentiated cells towards an arrested state to narrow down the lineage potency. However, the upregulation (CCND1, CHEK, HGF, HMGA2, SMAD3) and downregulation (CCPG1, RASSF4, RGS2) of these cell cycle genes motivates dedifferentiation of adipogenically differentiated cells to reverse the arrested state. We also found new fat markers along with signaling pathways for adipogenically differentiated and dedifferentiated cells, and also observed the influencing role of proliferation associated genes in cell cycle arrest and progression. We have differentiated bone marrow derived mesenchymal stem cells(MSC) into adipogenically differentiated cells followed by dedifferentiation. We are intrested to know new fat markers, signaling pathways for adipogenically differentiated and dedifferentiated cells, along to observe the genes associated with cell cycle arrest and progression. Results are also provide molecular insight into the process of adipogenesis and dedifferentiation.

Project description:Background: Current mammalian model for heart regeneration research is limited in apex amputation or myocardium infarction, both of which are controversy. Moreover, RNAseq demonstrated there were a very limited set of differential expressed genes between sham and operation heart in the myocardium infarction model. Here we investigated whether pressure overload in the right ventricle(RV), a common phenomenon in congenital heart disease children, could be a better animal model for heart regeneration study when consider cardiomyocyte(CM) proliferation as the most important index. Methods and results: Pressure overload was induced by pulmonary artery banding (PAB) on day1 and confirmed by echocardiography and hemodynamic measurements at postnatal day 7(P7). RNAseq analyses of purified RVCM at P7 from PAB and sham-operated rats revealed there were 5469 differential expressed genes between these two groups. GO and KEGG analysis showed that these genes mainly mediated mitosis and cell division. Cell proliferation assay indicates a continuous over-proliferation of RVCM after PAB, in particular for P3. In addition, there were ~2 times-fold increase of Ki67/Phh3 -positive CM in human overload RV compared to non-overload RV. Other features about this model included CM hypotrophy and no fibrosis.. Conclusions: Pressure overload profoundly promotes RVCM proliferation in the neonatal stage both in rats and human beings, activated a regeneration-specific gene program, and may offer a better alternative animal model for heart regeneration research..