AI Article Synopsis
- The study highlights a significant interaction between key regulatory pathways that control cell function, particularly focusing on the VEGF and p53 pathways.
- A specific genetic variation (C-->T SNP) in the VEGFR-1 promoter has been discovered, leading to a new insight into how these pathways might influence various diseases.
- The research identifies a new regulatory mechanism where estrogen receptors (ERs) and p53 work together to enhance the expression of Flt1, showing a complex interplay among the three pathways, which may also apply to other genes in master regulatory networks.
Article Abstract
Interactions between master regulatory pathways provide higher-order controls for cellular regulation. Recently, we reported a C-->T single-nucleotide polymorphism (SNP) in the vascular endothelial growth factor receptor 1 (VEGFR-1/Flt1) promoter that merges human VEGF and p53 pathways. This finding suggested a new layer in environmental controls of a pathway relevant to several diseases. The Flt1-T SNP created what appeared to be a half-site p53 target response element (RE). The absence of information about p53 gene responsiveness mediated by half-site REs led us to address how it influences Flt1 expression. We now identify a second regulatory sequence comprising a partial RE for estrogen receptors (ERs) upstream of the p53 binding site. Surprisingly, this provides for synergistic stimulation of transcription specifically at the Flt1-T allele through the combined action of ligand-bound ER and stress-induced p53. In addition to demonstrating direct control of Flt1 expression by ER and p53 proteins acting as sequence-specific transcription factors at half-site REs, we establish a new interaction between three master regulatory pathways, p53, ER, and VEGF. The mechanism of joint regulation through half-sites is likely relevant to transcriptional control of other targets and expands the number of genes that may be directly controlled in master regulatory networks.
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|---|---|
| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC1899907 | PMC |
| http://dx.doi.org/10.1128/MCB.01742-06 | DOI Listing |
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