Project description:PURPOSE: To provide a detailed gene expression profile of the normal postnatal mouse cornea. METHODS: Serial analysis of gene expression (SAGE) was performed on postnatal day (PN)9 and adult mouse (6 week) total corneas. The expression of selected genes was analyzed by in situ hybridization. RESULTS: A total of 64,272 PN9 and 62,206 adult tags were sequenced. Mouse corneal transcriptomes are composed of at least 19,544 and 18,509 unique mRNAs, respectively. One third of the unique tags were expressed at both stages, whereas a third was identified exclusively in PN9 or adult corneas. Three hundred thirty-four PN9 and 339 adult tags were enriched more than fivefold over other published nonocular libraries. Abundant transcripts were associated with metabolic functions, redox activities, and barrier integrity. Three members of the Ly-6/uPAR family whose functions are unknown in the cornea constitute more than 1% of the total mRNA. Aquaporin 5, epithelial membrane protein and glutathione-S-transferase (GST) omega-1, and GST alpha-4 mRNAs were preferentially expressed in distinct corneal epithelial layers, providing new markers for stratification. More than 200 tags were differentially expressed, of which 25 mediate transcription. CONCLUSIONS: In addition to providing a detailed profile of expressed genes in the PN9 and mature mouse cornea, the present SAGE data demonstrate dynamic changes in gene expression after eye opening and provide new probes for exploring corneal epithelial cell stratification, development, and function and for exploring the intricate relationship between programmed and environmentally induced gene expression in the cornea. Keywords: other

Project description:Cellular binary fate decisions require the progeny to silence genes associated with the alternative fate. The major subsets of alpha:beta T cells have been extensively studied as a model system for fate decisions. While the transcription factor RUNX3 is required for the initiation of Cd4 silencing in CD8 T cell progenitors, it is not required to maintain the silencing of Cd4 and other helper T lineage genes. The other runt domain containing protein, RUNX1, silences Cd4 in an earlier T cell progenitor, but this silencing is reversed whereas the gene silencing after RUNX3 expression is not reverse. Therefore, we hypothesized that RUNX3 and not RUNX1 recruits other factors that maintains the silencing of helper T lineage genes in CD8 T cells. To this end, we performed a proteomics screen of RUNX1 and RUNX3 to determine candidate silencing factors.

Project description: Not available

Project description:Gene expression analysis of hematopoetic progenitors

Project description: Not available

Project description:Fetal and adult progenitors give rise to unique populations of CD8+ T cells

Project description:Expression analysis of GATA1s murine megakaryocyte progenitors from bone marrow and fetal Liver

Project description:Expression analysis of BL6 murine megakaryocyte progenitors from bone marrow and fetal Liver

Project description:Gene expression analysis of early haematopoietic progenitors

Project description:Development of red blood cells from progenitors requires profound reshaping of both gene expression and metabolism. How these processes are coupled is unclear. Nprl3, an inhibitor of mTORC1, has remained in synteny with the -globin genes for >500 million years, and harbours most of the -globin enhancers. However, whether Nprl3 itself serves an erythroid role is unknown. While hematopoietic progenitors rely on tonic expression of baseline Nprl3, erythroblasts experience ‘boosted’ Nprl3 expression. Using Nprl3-deficient fetal liver and adult competitive bone marrow - fetal liver chimaeras, we show that NprI3 is required for sufficient erythropoiesis. Loss of Nprl3 elevates mTORC1 signalling, suppresses autophagy and disrupts erythroblast glycolysis. Human NPRL3-knockout erythroid progenitors produce fewer enucleated cells and demonstrate dysregulated mTORC1 signalling in response to nutrient availability and erythropoietin. Thus, Nprl3 is a key regulator of erythroid metabolism. Finally, we show that the alpha-globin enhancers upregulate erythoid NprI3 expression, and that this activity supports optimal erythropoiesis.