Project description:The gastrointestinal tract is covered by a single layer of epithelial cells that, together with the mucus layers, protect the underlying tissue from bacterial invasion. The epithelium has one of the highest turnover rates in the body, renewing every 4-5 days. Using stable isotope labelling, high-resolution mass spectrometry and computational analysis, we report here a comprehensive dataset of the turnover rate of 3041 and the expression of 5012 intestinal epithelial cell proteins, analyzed under conventional and germ-free conditions across five different segments in mouse intestine. The median protein half-life was shorter in small intestine compared to colon, ranging from 3.5 to 4.2 days. Differences in protein turnover rates along the intestinal tract can be explained by distinct physiological functions and site-specific immune responses between the small and large intestine. Absence of microflora resulted in increased protein half-life by approximately one day.

Project description:Profiling of chromosomal gains and losses in a genomic complement of stem cells from human exfoliated deciduous teeth comparing control undifferentieated SHED with hepatocyte differentiated SHED.

Project description:Phenotypic evolution can result from gains and losses of genes, mutations in coding sequences, or regulatory mutations affecting gene expression. While the relative importance of these mechanisms is debated, regulatory evolution is recognized as a key driver of phenotypic diversity. In this study, we applied a phylogenetic model to discretized gene expression states (active or inactive) to investigate the evolutionary turnover of organ-specific transcriptomes, which we define as instances where gene expression is activated or deactivated in a particular organ. We focus on transcriptome turnover in two male reproductive organs in 11 species of the Drosophila melanogaster species group. Using the Bayesian inference method zigzag (Thompson et al. 2020), we estimate that testes express a higher proportion of the genome (65--75% of genes, depending on the species) compared to accessory glands (46--64%), with background expression noise producing less than 1% of transcripts in both organs. We find that many conserved genes have gained or lost expression in testes and accessory glands. Our model of joint transcriptome evolution, applied to 8,660 genes conserved as single copy families in all species (singleton genes), revealed similar turnover rates but distinct evolutionary trajectories in the two organs. We estimate that the genes in our data set transition between active and inactive expression states at rates on the order of 10^-9 yr^-1. The two organs experienced accelerated transcriptome turnover on different branches of the Drosophila phylogeny. The accessory glands exhibit greater variation in turnover rates among lineages, suggesting a lower baseline rate with bursts of rapid evolution in a subset of branches on the phylogeny. We do not observe significant differences in turnover rates between X-linked and autosomal genes. Genes that encode transcription factors transition between active and inactive states slower than non-TF genes in the accessory gland, but slightly faster in the testis. The results are robust to the choice of probability cut-offs used to discretize gene expression states, and there is good agreement between the estimates of expression states from zigzag and the inferences from the phylogenetic model. Overall, our study highlights the complex dynamics of transcriptome evolution in male reproductive organs. We discuss the benefits and challenges associated with investigating the evolution of gene expression as a binary trait and suggest potentially fruitful avenues for further methodological development.

Project description:The effects of fasting have been studied extensively, predominantly on isolated processes, within a specific organ. No comprehensive study of the adaptations was available for different organs, let alone interrelating them, which left the understanding of the body’s orchestration of fasting response limited. The gene expression profiles of brain, small intestine, kidney, liver and skeletal muscle were therefore studied in mice subjected to short, moderate and prolonged fasting. Functional category enrichment, network, and text-mining analyses were employed to scrutinize the overall adaptive response, aiming to identify responsive pathways, processes and networks, and their regulation. The implicated processes did not follow the accepted carbohydrate-lipid-protein succession of energy substrates expenditure. Instead, they were activated simultaneously in different organs during the whole duration of fasting. The most prominent changes occurred in lipid and steroid metabolism, especially in the liver and kidney, which showed biochemically similar, orchestrated responses. They were accompanied by suppression of the immune response and cell turnover, particularly in the small intestine, tied in with increased proteolysis in the muscle. Enhanced defence against oxidative damage, obvious in all the organs, was the top reaction of the brain, otherwise shown to be extremely well protected from starvation. The major transcription regulators of fasting response in different organs were FoxO transcription factors, AP-1, p53, cMyc, Sp1, EGF and HNF4α. The revealed interorgan interactions between metabolic, inflammatory and cell turnover responses are essential when designing strategies to treat the starvation affected individuals, while stressing the significance of using complimentary bioinformatics tools in the high-throughput data analysis. 6 week-old male FVB mice were fasted for 0, 12, 24, 48 or 72 hours before sacrifice (N = 5 per group). From each mouse total RNA was isolated from five organs - liver, small intestine, kidney, brain, and calf muscle. Five microarrays per experimental condition (five tissues, five timepoints) were performed. We used a common reference design. The single common-reference sample was a pool of equal amounts of RNA from all the samples investigated, including additional samples from 5 mice that were fasted for 48 hours and supplemented with vitamin B complex after 24 and 36 hours of fasting.

Project description:The effects of fasting have been studied extensively, predominantly on isolated processes, within a specific organ. No comprehensive study of the adaptations was available for different organs, let alone interrelating them, which left the understanding of the body’s orchestration of fasting response limited. The gene expression profiles of brain, small intestine, kidney, liver and skeletal muscle were therefore studied in mice subjected to short, moderate and prolonged fasting. Functional category enrichment, network, and text-mining analyses were employed to scrutinize the overall adaptive response, aiming to identify responsive pathways, processes and networks, and their regulation. The implicated processes did not follow the accepted carbohydrate-lipid-protein succession of energy substrates expenditure. Instead, they were activated simultaneously in different organs during the whole duration of fasting. The most prominent changes occurred in lipid and steroid metabolism, especially in the liver and kidney, which showed biochemically similar, orchestrated responses. They were accompanied by suppression of the immune response and cell turnover, particularly in the small intestine, tied in with increased proteolysis in the muscle. Enhanced defence against oxidative damage, obvious in all the organs, was the top reaction of the brain, otherwise shown to be extremely well protected from starvation. The major transcription regulators of fasting response in different organs were FoxO transcription factors, AP-1, p53, cMyc, Sp1, EGF and HNF4α. The revealed interorgan interactions between metabolic, inflammatory and cell turnover responses are essential when designing strategies to treat the starvation affected individuals, while stressing the significance of using complimentary bioinformatics tools in the high-throughput data analysis.

Project description:We conducted transcriptional profiling of laser-captured stamen abscission zone cells over five developmental stages from prepollination to organ shed.

Project description:A key feature in intestinal immunity is the dynamic intestinal barrier, which separates the host from resident and pathogenic microbiota through a mucus gel impregnated with antimicrobial peptides. The mechanisms underlying the maintenance and function of this intestinal barrier are not completely understood. Using a mouse forward genetic screen for defects of intestinal homeostasis, we have found a mutation in Tvp23b, which conferred susceptibility to chemically induced and infectious colitis. Golgi apparatus membrane protein TVP23 homolog B (TVP23B) is a transmembrane protein conserved from yeast to humans. In the intestine, the protein is localized to the epithelium and its deficiency in the hematopoietic extrinsic compartment was essential to the colitis phenotype. We found that TVP23B controls the homeostasis of Paneth cells and function of goblet cells in vivo, leading to a decrease in antimicrobial peptides as well as a more penetrable mucus layer. As a result, Tvp23b-/- mice displayed decreased barrier function and a loss of host-microbe separation. TVP23B-deficient colonocytes have a loss of core-3 O-glycosylation of colonic proteins, which is the major O-glycosylation present on gel forming mucins. TVP23B binds with another Golgi protein, YIPF6, which is similarly critical for intestinal homeostasis. The Golgi proteomes of YIPF6 and TVP23B-deficient colonocytes have a common deficiency of several critical glycosylation enzymes, including those necessary for core-3 glycosylation of mucins. TVP23B is necessary for the formation of the sterile mucin layer of the intestine and its absence disturbs the balance of host and microbe in vivo.

Project description:Comparison of whole genome gene expression profiles of stem cells from exfoliated decidous teeth (SHEDs) ,Hepatocyte like-cells derived SHEDs (SHED-Hep cells), and human primary hepatocytes. We showed that the profile of three different donors of MSC-Hep cells was close to that of human hepatocytes, but separate from that of three different donors of undifferentiated MSCs

Project description:POSITIONAL TRANSCRIPTOMICS SHED LIGHT ON SITE-SPECIFIC PATHOLOGIES OF THE AORTA

Project description:Transcriptomic analysis of neural-induced SHED cells with/without HCMV infection