The replication activation potential of selected RNA polymerase II promoter elements at the simian virus 40 origin

Interference of the simian virus 40 origin of replication by the cytomegalovirus immediate early gene enhancer: evidence for competition of active regulatory chromatin conformation in a single domain

Replication origins are often found closely associated with transcription regulatory elements in both prokaryotic and eukaryotic cells. To examine the relationship between these two elements, we studied the effect of a strong promoter-enhancer on simian virus 40 (SV40) DNA replication. The human cytomegalovirus (CMV) immediate early gene enhancer-promoter was found to exert a strong inhibitory effect on SV40 origin-based plasmid replication in Cos-1 cells in a position- and dose-dependent manner. Deletion analysis indicated that the effect was exerted by sequences located in the enhancer portion of the CMV sequence, thus excluding the mechanism of origin occlusion by transcription. Insertion of extra copies of the SV40 origin only partially alleviated the inhibition. Analysis of nuclease-sensitive cleavage sites of chromatin containing the transfected plasmids indicate that the chromatin was cleaved at one of the regulatory sites in the plasmids containing more than one regulatory site, suggesting that only one nuclease-hypersensitive site existed per chromatin. A positive correlation was found between the degree of inhibition of DNA replication and the decrease of P1 cleavage frequency at the SV40 origin. The CMV enhancer was also found to exhibit an inhibitory effect on the CMV enhancer-promoter driving chloramphenicol acetyltransferase expression in a dose-dependent manner. Together these results suggest that inhibition of SV40 origin-based DNA replication by the CMV enhancer is due to intramolecular competition for the formation of active chromatin structure.

Interaction of the transcription factor TFIID with simian virus 40 (SV40) large T antigen interferes with replication of SV40 DNA in vitro

Simian virus 40 (SV40) large tumor (T) antigen is the major regulatory protein that directs the course of viral infection, primarily by interacting with host cell proteins and modulating their functions. Initiation of viral DNA replication requires specific interactions of T antigen bound to the viral origin of DNA replication with cellular replication proteins. Transcription factors are thought to stimulate initiation of viral DNA replication, but the mechanism of stimulation is poorly understood. Since the transcription factor TATA-binding protein (TBP) binds to sequences within the origin of replication and interacts specifically with T antigen, we examined whether TBP complexes stimulate SV40 DNA replication in vitro. On the contrary, we found that depletion of TBP complexes from human cell extracts increased their ability to support viral DNA replication, and readdition of TBP complexes to the depleted extracts diminished their activity. We have mapped the sites of interaction between the proteins to residues 181 to 205 of T antigen and 184 to 220 of TBP. Titration of fusion proteins containing either of these peptides into undepleted cell extracts stimulated their replication activity, suggesting that they prevented the T antigen-TBP interaction that interfered with replication activity. TBP complexes also interfered with origin DNA unwinding by purified T antigen, and addition of either the T antigen or the TBP fusion peptide relieved the inhibition. These results suggest that TBP complexes associate with a T-antigen surface that is also required for origin DNA unwinding and viral DNA replication. We speculate that competition among cellular proteins for T antigen may play a role in regulating the course of viral infection.

Initiation of baculovirus DNA replication: early promoter regions can function as infection-dependent replicating sequences in a plasmid-based replication assay

From the results of transient plasmid-based replication assays, it has been postulated that homologous regions (hrs) of Autographa californica nuclear polyhedrosis virus (AcMNPV) function as origins of viral DNA replication. However, these assays vary in specificity according to the methodology used and may not be dependent solely on the presence of hr sequences. To determine the role that hrs and other sequences might play in the replication process, a series of plasmids containing specific deletions of various hrs was generated and tested in a standardized replication assay. Deletion of the AcMNPV hr2 and hr5 sequences abolished the ability of plasmids to replicate in the standard infection-dependent replication assay, while deletion of hr1, hr3, and hr4a sequences decreased but did not eliminate plasmid replication in this assay. Plasmids carrying the complete ie-2 and pe38 genes, the ie-1 gene upstream region, or a variety of baculovirus genes including 11 early promoter regions were also able to replicate in virus-infected cells, suggesting that early viral promoter sequences could also function as putative origins of replication. These data suggest that the standard infection-dependent replication assay may identify a broad range of infection-dependent replicating sequences, only one or a few of which may represent genuine viral origins used by the virus in vivo. We propose a model suggesting that the selection of replication initiation sites may be imposed directly by chromatin structure and indirectly by primary sequence and that the process of viral DNA replication may be linked with viral transcription.

A link between increased transforming activity of lymphoma-derived MYC mutant alleles, their defective regulation by p107, and altered phosphorylation of the c-Myc transactivation domain

The c-Myc protein is a transcription factor with an N-terminal transcriptional regulatory domain and C-terminal oligomerization and DNA-binding motifs. Previous studies have demonstrated that p107, a protein related to the retinoblastoma protein, binds to the c-Myc transcriptional activation domain and suppresses its activity. We sought to characterize the transforming activity and transcriptional properties of lymphoma-derived mutant MYC alleles. Alleles encoding c-Myc proteins with missense mutations in the transcriptional regulatory domain were more potent than wild-type c-Myc in transforming rodent fibroblasts. Although the mutant c-Myc proteins retained their binding to p107 in in vitro and in vivo assays, p107 failed to suppress their transcriptional activation activities. Many of the lymphoma-derived MYC alleles contain missense mutations that result in substitution for the threonine at codon 58 or affect sequences flanking this amino acid. We observed that in vivo phosphorylation of Thr-58 was absent in a lymphoma cell line with a mutant MYC allele containing a missense mutation flanking codon 58. Our in vitro studies suggest that phosphorylation of Thr-58 in wild-type c-Myc was dependent on cyclin A and required prior phosphorylation of Ser-62 by a p107-cyclin A-CDK complex. In contrast, Thr-58 remained unphosphorylated in two representative mutant c-Myc transactivation domains in vitro. Our studies suggest that missense mutations in MYC may be selected for during lymphomagenesis, because the mutant MYC proteins have altered functional interactions with p107 protein complexes and fail to be phosphorylated at Thr-58.

The region encompassing the procyclic acidic repetitive protein (PARP) gene promoter plays a role in plasmid DNA replication in Trypanosoma brucei

We have previously reported the construction and characterization of an autonomously replicating plasmid in Trypanosoma brucei. In this plasmid the procyclic acidic repetitive protein (PARP) gene promoter drives the transcription of a selectable marker. Deletion of this promoter incapacitates the plasmid, suggesting its utilization as a promoter-trap. Three independent libraries were created by inserting variously digested T.brucei genomic DNA into this promoterless construct. Transfection of these libraries into procyclic T.brucei and the subsequent isolation of episomes led only to the reisolation of the PARP promoter. Additionally, a ribosomal RNA promoter failed to keep the construct as an episome, although it can sustain mRNA transcription in T.brucei and was shown to be an efficient promoter in this construct. Finally, by using a transient replication assay involving the methylation-sensitive restriction endonuclease DpnI to distinguish between input and replicated DNA, we showed that the PARP promoter-bearing construct could replicate autonomously in procyclic T.brucei, but the corresponding construct with the rRNA promoter could not. The close association between elements that sustain transcription and DNA replication in T.brucei mirrors results observed in several higher eukaryotes and their viruses and suggests an ancient origin of this feature.

A critical role for chromatin in mounting a synergistic transcriptional response to GAL4-VP16

The role of chromatin in mounting a synergistic transcriptional response to GAL4-VP16 was investigated. Strong synergy was observed when chromatin templates were used in vitro. The synergy was severely reduced when naked DNA templates were transcribed. In vivo synergy was strong when nonreplicating templates were used. However, the use of replicating templates, which involved transient disruptions of chromatin, led to strong reductions in synergy. In both of these low-synergy responses, transcription levels were high. We infer that strong synergy has a requirement for chromatin that may be understood in terms of the competition between multiple activator molecules and histone cores for promoter DNA.

A critical role for chromatin in mounting a synergistic transcriptional response to GAL4-VP16

The role of chromatin in mounting a synergistic transcriptional response to GAL4-VP16 was investigated. Strong synergy was observed when chromatin templates were used in vitro. The synergy was severely reduced when naked DNA templates were transcribed. In vivo synergy was strong when nonreplicating templates were used. However, the use of replicating templates, which involved transient disruptions of chromatin, led to strong reductions in synergy. In both of these low-synergy responses, transcription levels were high. We infer that strong synergy has a requirement for chromatin that may be understood in terms of the competition between multiple activator molecules and histone cores for promoter DNA.