Project description:We have used RNA-seq to examine long non-coding RNA (lncRNA) and mRNA from rRNA depleted in chicken leg musle of three different development stages (11 embryo age, 16 embryo age, and 1 days post hatch). Our study reveals the prevalence of lncRNA in chicken, and has identified lncRNA differentially abundant in different stage of embryonic skeletal muscle, suggesting its important functions during poultry muscle development.

Project description:Identification of long non-protein coding RNAs in chicken skeletal muscle by Solexa sequencing

Project description:Global identification of growth-related long non-coding RNAs in breast muscle of chicken

Project description:RNA-seq of RNase R treated and ribo- RNAs from leg muscle of Xinghua Chickens

Project description:The long non-coding RNA(lncRNA) expression profiles in human aortic vascular smooth muscle cells (HAVSMCs)

Project description:Long non-coding RNAs (LncRNAs) in hypertensives and their mechanisms in regulating blood pressure still remain unexplored. The aim of present study is to construct the profiles of LncRNAs in blood of patients with essential hypertension and healthy controls. Methods and results, LncRNA microarray identified up-regulated, anddown-regulated LncRNAs, in hypertensives compared to their healthy controls. Among them, one vascular smooth muscle (VSM)-specific LncRNA AK096656 (LncVSM) was quantitated in plasma of patients with hypertension and their healthy controls using the real-time qRT-PCR. LncVSM shows specific expression in human arterial vascular smooth muscle cells (HASMCs) and promote its proliferation and migration. Expression profiles and Ingenuity Pathway Analysis (IPA) revealed that LncVSM activated Renin-Angiotensin Signaling (RAS). the overexpression of LncVSM would result hypertension related complications. LncVSM (AK098656) transfection

Project description:A deletion mutation in the growth hormone receptor (GHR) gene results in the inhibition of skeletal muscle growth and fat deposition in dwarf chickens. In this study, microarray techniques were used to detect the miRNA and mRNA expression profiles of 14-day-old embryo and 7-week-old chicken skeletal muscle of deletion-type dwarf chickens and normal-type chickens. Skeletal muscle tissues of Dwarf recessive White Rock chickens and normal recessive White Rock chickens were used to make the microarray assay. Results show the expression of miR-1623 and miR-181b in 14-day-old embryos and of let-7b and miR-128 in 7-week-old chickens. let-7b was the only miRNA found to be completely complementary to its target in the 3'UTR of GHR and inhibited GHR gene expression. KEGG (Kyoto Encyclopaedia of Genes and Genomes) pathway analysis and RT-PCR verified that there were three main signalling pathways regulating the skeletal muscle growth and fat deposition of chickens influenced by the let-7b-regulated GHR gene. The suppression of the cytokine signalling 3 (SOCS3) gene was found to be involved in the signalling pathway of adipocytokines. We found that let-7b is the critical miRNA involved in the regulation of the GHR gene. SOCS3 plays a critical role in the network regulating skeletal muscle growth and fat deposition via let-7b-mediated GHR gene expression. Two groups were analyzed in the array assay: one group consisted of normal recessive White Rock 14-day-old embryo leg muscle tissues, and the other group consisted of dwarf recessive White Rock 14-day-old embryo leg muscle tissues. The control samples were labeled as A1, A2, A3, and the dwarf chicken samples were labeled as B1, B2, and B3. 9 total embryos per breed, 3 embryos used per breed for each sample. 523 mature miRNA sequences were assembled and integrated into the LC miRNA microarray design, and different expression miRNAs were measured on the 7000HT Fast Real-Time PCR system. This submission represents the miRNA profiling component of the study.

Project description:A deletion mutation in the growth hormone receptor (GHR) gene results in the inhibition of skeletal muscle growth and fat deposition in dwarf chickens. In this study, microarray techniques were used to detect the miRNA and mRNA expression profiles of 14-day-old embryo and 7-week-old chicken skeletal muscle of deletion-type dwarf chickens and normal-type chickens. Skeletal muscle tissues of Dwarf recessive White Rock chickens and normal recessive White Rock chickens were used to make the microarray assay. Results show the expression of miR-1623 and miR-181b in 14-day-old embryos and of let-7b and miR-128 in 7-week-old chickens. let-7b was the only miRNA found to be completely complementary to its target in the 3'UTR of GHR and inhibited GHR gene expression. KEGG (Kyoto Encyclopaedia of Genes and Genomes) pathway analysis and RT-PCR verified that there were three main signalling pathways regulating the skeletal muscle growth and fat deposition of chickens influenced by the let-7b-regulated GHR gene. The suppression of the cytokine signalling 3 (SOCS3) gene was found to be involved in the signalling pathway of adipocytokines. We found that let-7b is the critical miRNA involved in the regulation of the GHR gene. SOCS3 plays a critical role in the network regulating skeletal muscle growth and fat deposition via let-7b-mediated GHR gene expression. Two groups were analyzed in the array assay: one group consisted of normal recessive White Rock 7-week-old chicken leg muscle tissues, and the other group consisted of dwarf recessive White Rock 7-week-old chicken leg muscle tissues. The control samples were labeled as A1b, A2b, A3b, and the dwarf chicken samples were labeled as B1b, B2b, and B3b. 9 total chickens per breed, 3 chickens used per breed for each sample. 523 mature miRNA sequences were assembled and integrated into the LC miRNA microarray design, and different expression miRNAs were measured on the 7000HT Fast Real-Time PCR system. REPLACE This submission represents the miRNA profiling component of the study.

Project description:miRNA-seq for leg muscles of Jinghai yellow female chickens at 300 days

Project description:Omics analysis of transgenic chickens compared with non-transgenic chickens [gender]