Project description:Here we show that the T-box transcription factor encoded by Tbx1 positively regulates monomethylation of histone 3 lysine 4 (H3K4me1) at a significant number of regions that it occupies throughout the genome, often located at the 3' end of target genes. Treatment of cells with Tranylcypromine (TCP), an inhibitor of histone demethylases, rescues the expression of approx. one third of the genes dysregulated by Tbx1 suppression and it rebalances H3K4me1 levels at many Tbx1 occupied sites. In addition, TCP treatment of mouse models of the 22q11.2DS ameliorates substantially the cardiovascular phenotype.

Project description:To assess the influence of Tbx1 on gene expression profile within the developing palate we performed a microarray screen using RNA isolated from dissected secondary palate shelves of E13.5 wild type, Tbx1+/- and Tbx1-/- mice. Significant differences were identified between genotypes, with a total of 67 genes demonstrating at least a 2-fold change (p<0.05) in expression. These were clustered into 5 groups, including those downregulated in mutant compared to wild type and heterozygote (n=36); those progressively downregulated from wild type to mutant (n=12); those upregulated in heterozygote and downregulated in mutant compared to wild type (n=2); those progressively upregulated from wild type to mutant (n=12) and those downregulated in heterozygote and upregulated in mutant compared to wild type (n=5). High-throughput real time quantitative RT-PCR confirmed a total of 18 genes significantly changed between wild type and mutant and 24 between heterozygote and mutant. Amongst these, 15 were present in both groups and all except 1 were downregulated in the mutant. There were no significant differences in gene expression between wild type and heterozygous palatal shelves. Secondary palatal shelf pairs were carefully microdissected from E13.5 Tbx1+/+; Tbx1+/- and Tbx1-/- embryos (3 embryos per genotype as biological replicates). RNA was extracted from each pooled shelf pair generating nine RNA samples in total, each one analysed using a single microarray.

Project description:Expression data from rat vocal fold at different periods after vocal fold injury

Project description:Auxin regulates functional gene groups in a fold-specific manner in Arabidopsis root

Project description:Expression data from rat vocal fold at different periods after vocal fold injury (miRNA)

Project description:To assess the influence of Tbx1 on gene expression profile within the developing palate we performed a microarray screen using RNA isolated from dissected secondary palate shelves of E13.5 wild type, Tbx1+/- and Tbx1-/- mice. Significant differences were identified between genotypes, with a total of 67 genes demonstrating at least a 2-fold change (p<0.05) in expression. These were clustered into 5 groups, including those downregulated in mutant compared to wild type and heterozygote (n=36); those progressively downregulated from wild type to mutant (n=12); those upregulated in heterozygote and downregulated in mutant compared to wild type (n=2); those progressively upregulated from wild type to mutant (n=12) and those downregulated in heterozygote and upregulated in mutant compared to wild type (n=5). High-throughput real time quantitative RT-PCR confirmed a total of 18 genes significantly changed between wild type and mutant and 24 between heterozygote and mutant. Amongst these, 15 were present in both groups and all except 1 were downregulated in the mutant. There were no significant differences in gene expression between wild type and heterozygous palatal shelves.

Project description:To understand the extent that Heat shock protein 90 (Hsp90) regulated its target proteins at the transcription level, transcriptomic change was profiled in yeast cells upon Hsp90 compromising. We genetically modified the R1158 strain (resulting genotype of mutant strain: TETp-HSC82 hsp82Δ arg4Δ lys5Δ car2Δ::URA3) and then reduced the Hsp90 amount with doxycycline treatment. Fold change of mRNA from untreated to treated cells indicated the transcriptomic change. Totally, we identified 1104 genes mis-regulated with a fold change of no less than 1.5 (P <0.05) upon Hsp90 compromising.

Project description:To understand the extent that Heat shock protein 90 (Hsp90) regulated its target proteins at the transcription level, transcriptomic change was profiled in yeast cells upon Hsp90 compromising. We genetically modified the R1158 strain (resulting genotype of mutant strain: TETp-HSC82 hsp82Δ arg4Δ lys5Δ car2Δ::URA3) and then reduced the Hsp90 amount with doxycycline treatment. Fold change of mRNA from untreated to treated cells indicated the transcriptomic change. Totally, we identified 1104 genes mis-regulated with a fold change of no less than 1.5 (P <0.05) upon Hsp90 compromising. Two-condition experiment, treated vs. untreated cells. Biological duplicates, independently grown and harvested. Technical triplicates for RNA isolation.

Project description:T reg frequency, activation and function was studied in ESN individuals. Between the subjects with a HIV-specific T cell response, we identified two groups, one, where the T regs were able to suppress T cell proliferation and one where they lacked this capability. Sorted T regs from this two groups were analysed for their expression pattern.

Project description:Purpose: The goal of this study is to compare the expression profile of wild type and Tbx1-nmf219/nmf219 mice with NGS-derived inner ear transcriptome profiling (RNA-seq) Methods: inner ear mRNA profiles of E16.5 wild-type (WT) and Tbx1-nmf219/nmf219mice were generated by RNA-seq Results: Using an optimized data analysis workflow, we mapped about 30 million sequence reads per sample to the mouse genome and identified transcripts in the inner ear of WT and Tbx1nmf219/nmf219 mice. Approximately 10% of the transcripts showed differential expression between the WT and Tbx1nmf219/nmf219 inner ear, with a fold change ≥1.5 and p value <0.05. Conclusions: Our study represents the detailed analysis of inner ear transcriptomes, with biologic replicates, generated by RNA-seq technology.