Loading...
Publication
Integrative network approach to identify new players involved in NMD or its regulation
| Name: | Description: | Size: | Format: | |
|---|---|---|---|---|
| 2.6 MB | Adobe PDF |
Advisor(s)
Abstract(s)
Nonsense-mediated mRNA decay (NMD) is a surveillance pathway that recognizes and
selectively degrades mRNAs carrying premature translation-termination codons (PTCs). The
physiological importance of NMD is manifested by the fact that about one third of all genetic
diseases and some forms of cancer are caused by nonsense or frameshift mutations that
introduce PTCs, and NMD can modulate the clinical phenotype of these diseases. Noteworthy,
in total, genetic diseases attributable to PTCs affect millions of patients worldwide. Recent
studies have shown that NMD also targets mRNAs transcribed from a large subset of wild-type
genes, shaping their levels. NMD is a complex process where several proteins interact with
each other and cooperate to induce degradation of a given transcript. Although this pathway
has been extensively studied, the interactions and connectivity among these components is only
partly elucidated. Aiming to expand the knowledge about the NMD pathway, we are combining
bioinformatics, network analysis and experimental work to identify new proteins involved in NMD
or its regulation. Our work, begins with a network analysis approach that integrates publicly
available data regarding different types of interactions: 1) protein-protein, 2) kinase-target, 3)
phosphatase-target, 4) miRNA-target, 5) transcription factor-target, 6) gene co-expression and
7) ubiquitination-target. Additionally, our network include data regarding known NMD-targets
and NMD-triggering features. The generated network will be used to find novel NMD-associated
proteins, prioritizing candidates with simultaneous interactions with different mRNA processing
pathways (mRNA splicing, mRNA transport, mRNA translation and mRNA decay). Following
data integration, we will develop a scoring algorithm to select the most central proteins in the
generated network, which can be essential to further understand NMD and its regulation. The
predicted candidates will be experimentally validated and their role in NMD will be tested. Due
to the diversity of regulatory links integrated in this workflow, we propose it can be applied to
find molecular bridges between related biological processes and generate novel hypotheses
about the molecular mechanisms co-regulating these phenomena.
Description
Keywords
Nonsense-mediated mRNA Decay (NMD) Expressão Génica Genómica Funcional e Estrutural