Project description:RNA-seq of the copepod Pseudocalanus newmani using rRNA-depletion approach

Project description:18S metabarcoding of the copepod Pseudocalanus newmani and environment seawaters

Project description:MIG-seq analysis of Pseudocalanus spp.

Project description:Pseudocalanus newmani overview

Project description:Pseudocalanus acuspes Transcriptome or Gene expression

Project description:To identificate long noncoding RNAs in maize, we profiled transcriptome of shoots and roots using stranded single-end RNA-seq based on poly(A) selection.

Project description:To identificate long noncoding RNAs in maize, we profiled transcriptome of shoots and roots using non-directional paired-end RNA-seq based on poly(A) selection.

Project description:To identificate long noncoding RNAs in rice, we profiled transcriptome of various organs at different developmental stages using stranded single-end RNA-seq based on poly(A) selection.

Project description:To identificate long noncoding RNAs in rice, we profiled transcriptome of various organs at different developmental stages using nondirectional paired-end RNA-seq based on poly(A) selection.

Project description:The Poly(A)-Tail focused RNA-seq, or PAT-seq approach, is an affordable and efficient tool for the measure of 3’UTR dynamics. We show here that PAT-seq returns (i) digital gene expression, (ii) polyadenylation site usage within and between samples, including alternative adenylation, and (iii) the polyadenylation-state the transcriptome. PAT-seq differs from previous 3’ focused RNA-seq methods in that it strictly depends on native 3’ adenylation within total RNA samples and thus removes the need for ribosome depletion and, that the full native poly(A)-tail is included in the sequencing libraries. Limited RNase digestion combined with size selection and directional sequencing mean that deep-sequencing reads map to within ~50-100 bases of adenylation sites and run from unique sequence into adenosine homopolymers. Here, total RNA samples from budding yeast cells were analyzed to highlight the changes in gene expression and adenylation-state of the transcriptome in response to loss of the deadenylase Ccr4. Furthermore, concordant changes to gene expression and adenylation-state were demonstrated in a classic Crabtree-Warburg metabolic shift. Because all adenylated RNA are interrogated by the PAT-seq approach, alternative adenylation sites, long noncoding RNA and other non-coding RNA and RNA decay intermediates were also identified.