AI Article Synopsis
- HNF4alpha is a crucial liver transcription factor linked to various diseases, but its complete DNA-binding profile and target genes were previously unknown.
- The study utilized protein binding microarrays to identify around 1400 new binding sequences and developed a model to predict an additional 10,000 unique binding sites for HNF4alpha, revealing new rules for its DNA interaction.
- The research discovered approximately 240 new direct target genes for HNF4alpha in humans, broadening its functional scope to include roles in cell cycle, immune responses, and cancer, along with introducing a web tool for identifying HNF4alpha-binding sites.
Article Abstract
Unlabelled: Hepatocyte nuclear factor 4 alpha (HNF4alpha), a member of the nuclear receptor superfamily, is essential for liver function and is linked to several diseases including diabetes, hemophilia, atherosclerosis, and hepatitis. Although many DNA response elements and target genes have been identified for HNF4alpha, the complete repertoire of binding sites and target genes in the human genome is unknown. Here, we adapt protein binding microarrays (PBMs) to examine the DNA-binding characteristics of two HNF4alpha species (rat and human) and isoforms (HNF4alpha2 and HNF4alpha8) in a high-throughput fashion. We identified approximately 1400 new binding sequences and used this dataset to successfully train a Support Vector Machine (SVM) model that predicts an additional approximately 10,000 unique HNF4alpha-binding sequences; we also identify new rules for HNF4alpha DNA binding. We performed expression profiling of an HNF4alpha RNA interference knockdown in HepG2 cells and compared the results to a search of the promoters of all human genes with the PBM and SVM models, as well as published genome-wide location analysis. Using this integrated approach, we identified approximately 240 new direct HNF4alpha human target genes, including new functional categories of genes not typically associated with HNF4alpha, such as cell cycle, immune function, apoptosis, stress response, and other cancer-related genes.
Conclusion: We report the first use of PBMs with a full-length liver-enriched transcription factor and greatly expand the repertoire of HNF4alpha-binding sequences and target genes, thereby identifying new functions for HNF4alpha. We also establish a web-based tool, HNF4 Motif Finder, that can be used to identify potential HNF4alpha-binding sites in any sequence.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC3581146 | PMC |
| http://dx.doi.org/10.1002/hep.23357 | DOI Listing |
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