Abstract
Proteins that promote angiogenesis, such as vascular endothelial growth factor (VEGF), are major targets for cancer therapy. Accordingly, proteins that specifically activate expression of factors like VEGF are potential alternative therapeutic targets and may help to combat evasive resistance to angiogenesis inhibitors. VEGF mRNA contains two internal ribosome entry sites (IRESs) that enable selective activation of VEGF protein synthesis under hypoxic conditions that trigger angiogenesis. To identify novel regulators of VEGF IRES-driven translation in human cells, we have developed a high-throughput screening approach that combines siRNA treatment with transfection of a VEGF-IRES reporter mRNA. We identified the kinase MAPK3 as a novel positive regulator of VEGF IRES-driven translation and have validated its regulatory effect on endogenous VEGF. Our automated method is scalable and readily adapted for use with other mRNA regulatory elements. Consequently, it should be a generally useful approach for high-throughput identification of novel regulators of mRNA translation.
Highlights
MRNA translation by the ribosome is the ultimate step in the expression of the,20,000 human genes that encode proteins
To identify potential regulators of vascular endothelial growth factor (VEGF) internal ribosome entry sites (IRESs)-dependent translation we developed a general RNAi screening approach integrated with mRNA transfections
We have chosen to perform the screen in the HeLa human cell line because: I) the established siRNA treatment procedure is optimized for these cells; II) the VEGF IRES is active (Fig. S1A) and III) and responds to low oxygen tension
Summary
MRNA translation by the ribosome is the ultimate step in the expression of the ,20,000 human genes that encode proteins. Translation initiates via a ‘cap-dependent’ mode, in which recruitment of the small ribosomal subunit to the mRNA involves the 7-methylguanosine (‘cap’) structure, located at the 59 end of cellular mRNAs [3,4]. This interaction is mediated by the cytoplasmic cap-binding complex eIF4F, which enables recruitment of other translation initiation factors, scanning to the start codon, and joining of the large ribosomal subunit for translational elongation and protein synthesis [3,4,5]. Translation initiation occurs efficiently independent of the cap structure and many of the associated translation initiation factors [6]
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