Project description:metagenome of duck fecal sample Metagenome

Project description:Duck tissue metagenome

Project description:duck sample metagenome

Project description:Fecal virome composition of migratory wild duck species

Project description:We deep sequenced and analyzed miRNAs using deep RNA sequencing (RNA-seq) in cage rearing and traditional breeding duck's duodenum sample of Nonghu NO.2 duck. 21 differentially expressed miRNA were identified in the duodenum. 6 miRNAs were upregulated and 15 were downregulated in the cage rearing duck's duodenum of the Nonghu NO.2 duck compared to their expression in the control group. These findings provided insights into the expression profiles of miRNAs in duck duodenum, and deepened our understanding of miRNAs in oxidative injury of duck.

Project description:We aim to study the unusual TMA metabolism mechanism of ducks, and further explore the hidden reasons that led to the weakening TMA metabolism ability.To achieve this, transcriptome, proteome, and metagenome analyses were integrated based on the constructed duck populations with high TMA metabolism ability and low TMA metabolism ability.

Project description:We deep sequenced and analyzed miRNAs using deep RNA sequencing (RNA-seq) in transported and control duck's duodenum sample of Jingjiang duck. We analyzed the miRNA data with 9467248 reads and 9808143 million reads, obtained 9338224 and 9677777 clean reads in transported and control duck's by high-throughput sequencing, respectively. we respectively gained 4636135 and 4759049 miRNAs sequences in two groups by filtering the known non-miRNA reads, such as rRNA, tRNA, snRNA, and snoRNA by screening against ncRNA deposited in the GenBank and Rfam databases. These findings provided insights into the expression profiles of miRNAs in duck duodenum, and deepened our understanding of miRNAs in transportation injury of duck.

Project description:Genome sequencing and assembly of mock sample

Project description:duck intestinal sample sequencing

Project description:We aim to study the unusual TMA metabolism mechanism of ducks, and further explore the hidden reasons that led to the weakening TMA metabolism ability. To achieve this, transcriptome, proteome, and metagenome analyses were integrated based on the constructed duck populations with high TMA metabolism ability and low TMA metabolism ability. In addition, further experiments were followed to validate the hypothesis on the limited flavin-containing monooxygenase 3 (FMO3) metabolism ability of ducks. The study demonstrated that both cecal microbe, including Akkermansia and Mucispirillum, and liver FMO3 participated in the TMA metabolism process of ducks. The limited oxidation ability of FMO3 explained the weakening TMA metabolism ability of ducks. Nevertheless, it contributed to the duck’s survival and reproduction during the evolutional adaption process.