Project description:UNC13A contains a novel cryptic exon which is expressed upon TDP-43 knockdown. However, it also features TDP-43 regulated intron retention of a downstream intron. To investigate the correlation of these two events, we performed Nanopore sequencing of amplicons from SHSY5Y cells with inducible TDP-43 knockdown, and FTD patient RNA samples
Project description:Through splicing analysis of a publicly available RNA-Seq dataset, we discovered TDP-43 represses a cryptic exon splicing event in UNC13A, a gene that had been associated with FTD/ALS through GWA studies. To confirm the sequences of the cryptic exons, we used shRNA to reduce TDP-43 levels in iPSC-derived motor neurons (iPSC-MNs) and by amplicon sequencing the RT-PCR product, we observed the insertion in cells with TDP-43 depletion but not in control shRNA-treated cells. Through sequence alignment, we verified the sequences of the cryptic exons.
Project description:Long-read nanopore sequencing is capable of continuously reading thousands of base pairs. Here, we report the application of nanopore sequencing technology for analysing hypoxia-specific transcriptomes in normal liver and liver cancer cell lines, which help us to better understand the mechanism of cell survival and metastasis under hypoxia. We conducted transcriptomic sequencing of normal liver and liver cancer cell lines under normoxia or hypoxia, founding that long-read sequencing could detect thousands of hypoxia-specific isoforms and unannotated novel genes. At the cellular level, we have verified that the novel gene 644 is most up-regulated novel gene under hypoxic conditions. We observed that the novel gene 644 possesses classical mRNA characteristics, with its CDS region encoding 91 amino acids. Through protein structure predictions, we discovered that the novel gene 644 contains a transmembrane domain. Experimental validation confirmed that the novel gene 644 is a membrane protein, and knockdown of the novel gene 644 significantly suppresses the proliferative capacity of liver cancer cells under hypoxic conditions. Furthermore, we revealed the protein structure alteration of hypoxia specific isoforms with molecular dynamics simulation. The results indicate that our hypoxic dataset can serve as a foundation for the structural simulation of hypoxic-specific proteins. In summary, we have presented a hypoxic-specific third-generation sequencing dataset for further analysis, which provides sufficient details on cellular transcriptomes and is particularly valuable for understanding the survival and metastasis of tumor under hypoxic conditions. From this dataset, we have validated the importance of novel gene 644 for tumor survival under hypoxia and identified alterations in hypoxic-specific protein structures. These discoveries can bring us new knowledge about hypoxia, leading to the identification of potential tumor treatment targets and biomarkers.
Project description:Custom Agilent 8 x 15K microarray interrogating exon level expression of a set of genes previously known to be involved in oncogenic rearrangements. The goal of this study was to discover novel gene fusions by screening for exonic expression transitions within individual genes. Sixteen cancer samples and cell lines, including eight positive controls with known gene fusions and eight sarcoma specimens, where gene fusions have yet to be discovered, were hybridized against a common reference mRNA control (pooled from 11 diverse cell lines)
