Role of Middle T-small T in the Lytic Cycle of Polyomavirus: Control of the Early-to-late Transcriptional Switch and Viral DNA Replication

Overview

Journal J Virol

Publisher American Society for Microbiology

Date 2001 Aug 17

PMID 11507183

Citations 9

Authors

L Chen

M M Fluck

Affiliations

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Abstract

A comparative analysis of the lytic cycle of wild-type polyomavirus and middle T and small T defective mutants was carried out in the A2 genetic background. The results contrast with those obtained in comparisons between the hr-t type and their middle-T small-T-producing partners as previously described (20). The A2-derived mutants were found to share the maturation defect previously described for the hr-t mutants. However, their defect in DNA replication was more acute, resulting in a 5- to 100-fold decrease in the accumulation of viral genomes. Furthermore, their gene expression pattern was affected. A2-derived mutants displayed an early defect resulting in a 4- to 16-h delay in the expression of large T, and an alteration of the early-to-late transcriptional switch. In wild-type A2 infection, this switch is characterized by a large increase in the accumulation of early transcripts followed by late transcripts after the appearance of middle T and small T proteins and the onset of viral DNA replication (L. Chen and M. M. Fluck, J. Virol. 75: 8368-8379, 2001). In the mutant infection, increases in both classes of transcripts were delayed and reduced, but the effect on early transcripts was more pronounced. As has been described previously for the hr-t mutants (E. Goldman, J. Hattori, and T. Benjamin, Cell 13:505-513, 1979), the magnitude of these defects depended upon experimental conditions. Experiments using cytosine beta-arabinofuranoside to reduce genome amplification suggest that the effect of middle T-small T on the transcriptional switch is not solely mediated by the effect of these protein(s) on increasing the number of templates. These data provide the first direct demonstration of an effect of middle T and/or small T in the viral transcription pattern during viral infection. The results agree with previous results obtained with plasmid reporters and with our understanding that the downstream targets of the middle T signaling pathway include three transcription factors that have binding sites in the enhancer domain that play a key regulatory role in the expression of the viral genes.

Citing Articles

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Cellular transformation by Simian Virus 40 and Murine Polyoma Virus T antigens.

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Lessons from polyoma middle T antigen on signaling and transformation: A DNA tumor virus contribution to the war on cancer.

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Polyomavirus small T antigen controls viral chromatin modifications through effects on kinetics of virus growth and cell cycle progression.

Dahl J, Chen H, George M, Benjamin T J Virol. 2007; 81(18):10064-71.

PMID: 17626093 PMC: 2045420. DOI: 10.1128/JVI.00821-07.

Independent contributions of polyomavirus middle T and small T to the regulation of early and late gene expression and DNA replication.

Chen L, Wang X, Fluck M J Virol. 2006; 80(15):7295-307.

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