Nucleotide sequence of the mouse VEGF 3'UTR and quantitative analysis of sites of polyadenylation.

Sequencing of rat and human vascular endothelial growth factor (VEGF) cDNA clones has previously identified a 3' untranslated region of approximately 1.9 kb, although the apparent site of polyadenylation differed in the two species, despite a high degree of sequence conservation in the region. Neither site is preceded by a canonical AAUAAA polyadenylation signal, a situation frequently found in genes that are subject to alternative polyadenylation. We have sequenced 2.25 kb of the 3' region of the mouse VEGF gene and mapped the usage of potential polyadenylation sites in fibroblasts cultured under both normoxic and hypoxic conditions. We find that two sites for polyadenylation are present in the mouse VEGF gene but the majority of transcripts contain the longer form of the 3'UTR and that their usage is not effected by environmental oxygen tension.

Hypoxic regulation of vascular endothelial growth factor mRNA stability requires the cooperation of multiple RNA elements.

Vascular endothelial growth factor (VEGF) is a key regulator of developmental, physiological, and tumor angiogenesis. Upregulation of VEGF expression by hypoxia appears to be a critical step in the neovascularization of solid cancers. The VEGF mRNA is intrinsically labile, but in response to hypoxia the mRNA is stabilized. We have systematically analyzed the regions in the VEGF mRNA that are responsible for its lability under normoxic conditions and for stabilization in response to hypoxia. We find that the VEGF mRNA not only contains destabilizing elements in its 3' untranslated region (3'UTR), but also contains destabilizing elements in the 5'UTR and coding region. Each region can independently promote mRNA degradation, and together they act additively to effect rapid degradation under normoxic conditions. Stabilization of the mRNA in response to hypoxia is completely dependent on the cooperation of elements in each of the 5'UTR, coding region, and 3'UTR. Combinations of any of two of these three regions were completely ineffective in responding to hypoxia, whereas combining all three regions allowed recapitulation of the hypoxic stabilization seen with the endogenous VEGF mRNA. We conclude that multiple regions in the VEGF mRNA cooperate both to ensure the rapid degradation of the mRNA under normoxic conditions and to allow stabilization of the mRNA in response to hypoxia. Our findings highlight the complexity of VEGF gene expression and also reveal a mechanism of gene regulation that could become the target for strategies of therapeutic intervention.

The vascular endothelial growth factor mRNA contains an internal ribosome entry site.

Vascular endothelial growth factor (VEGF), an essential regulator of angiogenesis during early development as well as during the growth of solid tumours, bears an unusually large 5' untranslated region (5'-UTR) in the mRNA of over 1000 nucleotides. We found that the VEGF 5'-UTR, despite being GC-rich and containing an upstream short open reading frame, promotes efficient translation of a luciferase reporter. The VEGF 5'-UTR also allowed translation of luciferase from a dicistronic mRNA when placed between the two cistrons, demonstrating that it contains an internal ribosome entry site. Deletion analysis indicated that the IRES resides towards the 3' end of the 5'-UTR.

The use of oriC-dependent phage infection to characterize the ultra violet (UV)-induced inhibition of initiation of DNA replication in Escherichia coli.

The oriC transducing phage lambda poriCc is a pseudovirulent phage capable of forming plaques on a lambda lysogen. This phenotype is dependent upon the presence of the oriC insert. The ability of lambda poriCc to form plaques on a lambda lysogen represents a potential phage assay system for studying aspects of oriC function. In the present study we establish that lambda poriCc infection of a lambda lysogen is a legitimate assay for oriC function. We use this assay to confirm the previously reported observation that initiation of DNA replication from oriC is transiently inhibited in a ultra violet (UV) irradiated cell at doses greater than 60 J/m2. We further demonstrate using this assay that the UV induced inhibition of initiation of DNA replication from oriC is not a SOS function nor a heat shock function. In the course of these studies, we found that lambda poriCc infection of a non-lysogenic cell is extremely sensitive to pre-irradiation of the Escherichia coli host. We postulate that the sensitivity of lambda poriCc replication to host cell pre-irradiation reflects in some way the transient inhibition of initiation of DNA replication from oriC following UV irradiation.

Chaperone-mediated reduction of RepA dimerization is associated with RepA conformational change.

RepA, the initiator protein of plasmid P1, binds to multiple sites (iterons) in the origin. The binding normally requires participation of chaperones, DnaJ, DnaK and GrpE. When purified, RepA appears dimeric and is inactive in iteron binding. On reaction with chaperones, a species active in iteron binding is formed and found to be monomeric. To test whether the chaperones can reduce dimerization, RepA was used to replace the dimerization domain of the lambda repressor. The hybrid protein repressed the lambda operator efficiently, indicating that RepA can dimerize in vivo. A further increase in repressor activity was seen in dnaJ mutant cells. These results are consistent with a chaperone-mediated reduction of RepA dimerization. We also found that RepA mutants defective in dimerization still depend on DnaJ for iteron binding. Conversely, RepA mutants that no longer require chaperones for iteron binding remain dimerization proficient. These results indicate that the chaperone dependence of RepA activity is not solely owing to RepA dimerization. Our results are most simply explained by a chaperone-mediated conformational change in RepA protomer that activates iteron binding. This conformational change also results in reduced RepA dimerization.

Dissociation kinetics of RepA dimers: implications for mechanisms of activation of DNA binding by chaperones.

BACKGROUND: The replication initiator of plasmid P1, RepA, binds DNA as monomer. The binding is stimulated by the chaperones DnaJ, DnaK and GrpE of Escherichia coli. Two models of chaperone action have been proposed. (i) Chaperones dissociate RepA dimers, which are inactive in DNA binding, into active monomers. (ii) The dissociation occurs spontaneously but the monomeric products require the chaperones for refolding into the active form. The latter model was based on the observation that RepA diluted 1000-fold below the K(D) for dimer dissociation, still required the chaperones for DNA binding. RESULTS: We have confirmed that under the condition of DNA binding experiments, the RepA dimers dissociate reversibly into monomers with a K(D) value of 1.1 +/- 0.1 microM. In the vicinity of this concentration, the sedimentation coefficient of RepA was concentration dependent, allowing estimation of s(20,w) coefficients for the RepA monomer (2.95 S) and dimer (4.01 S). Dynamic light scattering experiments indicated an increase of the monomer fraction within 5 min of RepA dilution. Circular dichroism (CD) measurements were consistent with these results. CONCLUSION: RepA monomerization is efficient without the mediation of chaperones. They are required to activate RepA most likely because they are needed to re-fold RepA monomers.

Control of gene expression in the temperate coliphage 186. IX. B is the sole phage function needed to activate transcription of the phage late genes.

Using plasmid clones we have determined that the late control function B is the only phage function that is needed to activate a late promoter of coliphage 186, and we predict that it functions as an auxiliary factor to RNA polymerase in the activation of late transcription. We have also shown that a high concentration of B will activate late transcription from a prophage, and we conclude that replicating DNA is not a template requirement for B to function. The original demonstration of a need for the replication gene A in late transcription can be explained by the fact that replication leads to an increase in B gene dosage, with the consequent increase in B concentration leading to the efficient activation of the late promoters.

Control of gene expression in the temperate coliphage 186. X. The cI repressor directly represses transcription of the late control gene B.

We have found that the repressor of 186 lytic transcription, CI, represses transcription of the late control gene B, with no involvement of the B protein itself. In clone studies we showed that CI repressed transcription from the B promoter and that temperature inactivation of CIts led to B derepression. We conclude that CI repressor directly represses transcription of the B gene and, with prophage induction, it is probable that the inactivation of the CI repressor not only derepresses early lytic transcription, but also derepresses B gene transcription, leading to the activation of transcription from the late promoters.