Janice L. Williams scite author profile

A simian virus 40 late replacement vector encoding human immunodeficiency virus type 1 (HIV-1) gp120 (pGP120) was used to define a region within the HIV-2 genome that could work as a rev-responsive element (RRE). Our previous work showed that gp120 expression in this system required a functional RRE in cis and required the rev protein in trans (M.-L. Hammarskjöld, J. Heimer, B. Hammarskjöld, I. Sangwan, L. Albert, and D. Rekosh, J. Virol. 63:1959-1966, 1989). Using pGP120, we first mapped an RRE to a 1,042-base-pair (bp) Sau3a fragment in the env region of HIV-2. Both HIV-1 rev (rev1) and HIV-2 rev (rev2) could work in conjunction with this fragment. Further mapping showed that a 272-bp subfragment within the 1,042-bp region was sufficient as an RRE. Surprisingly, the smaller fragment worked only with the rev1 protein and not with its homologous rev2 protein. In addition, the rev2 protein failed to function together with the RRE from HIV-1. We also utilized this system to examine the ability of the rex genes of human T-cell leukemia virus types I and II to functionally substitute for rev. These experiments showed that complementation by both the rexI and rexII proteins required the presence of an RRE. The rex proteins worked well in conjunction with either the HIV-1 or the HIV-2 RRE (the 1,042-bp as well as the 272-bp fragment).

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Lymphoid specific gene expression of the adenovirus early region 3 promoter is mediated by NF-kappa B binding motifs.

Williams¹,

Garcia²,

Harrich³

et al. 1990

The EMBO Journal

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A primary site of infection by human adenoviruses is lymphoid cells. However, analysis of the viral control elements and the cellular factors that regulate adenoviral gene expression in lymphocytes has not been reported. The adenovirus early region 3 (ES) gene products are involved in the maintenance of viral persistence by complexing with the class I MHC antigens, thus preventing their cell surface expression with a resultant decrease in host immunologic destruction. To determine whether different cellular factors were involved in E3 regulation in lymphocytes as compared with HeLa cells, both DNA binding and transfection analysis with the E3 promoter in both cell types were performed. These studies detected two novel domains referred to as L1 and L2 with a variety of lymphoid but not HeLa extracts. Each of these domains possessed strong homology to motifs previously found to bind the cellular factor NF‐kappa B. Transfections of E3 constructs linked to the chloramphenicol acetyltransferase gene revealed that mutagenesis of the distal NF‐kappa B motif (L2) had minimal effects on promoter expression in HeLa cells, but resulted in dramatic decreases in expression by lymphoid cells. In contrast, mutagenesis of proximal NF‐kappa B motif (L1) had minimal effects on gene expression in both HeLa cells and lymphoid cells but resulted in a small, but reproducible, increase in gene expression in lymphoid cells when coupled to the L2 mutation. Reversing the position and subsequent mutagenesis of the L1 and L2 domains indicated that the primary sequence of these motifs rather than their position in the E3 promoter was critical for regulating gene expression.(ABSTRACT TRUNCATED AT 250 WORDS)

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HTLV x Gene Mutants Exhibit Novel Transcriptional Regulatory Phenotypes

Wachsman

Cann

Williams

et al. 1987

Science

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The human T-cell leukemia viruses, HTLV-I and HTLV-II, contain a gene, termed x, with transcriptional regulatory function. The properties of the x proteins were analyzed by constructing mutant genes containing site-directed deletions and point mutations. The results demonstrate that the amino terminal 17 amino acids of the x protein constitute part of a functional domain that is critical for the transcriptional activating properties of the protein. Within this region, substitution of a leucine residue for a proline residue results in major changes in the trans-activation phenotype of the protein. The mutant HTLV-II x protein, though incapable of activating the HTLV-II long terminal repeat, will block trans-activation of the HTLV-II long terminal repeat by the wild-type protein. The altered phenotype of this mutant suggests a potential negative regulatory function of the x protein.

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Studies of heterologous promotertrans-activation by the HTLV-IItaxprotein

Williams¹,

Cann²,

Leff³

et al. 1989

Nucl Acids Res

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The tax protein of HTLV-II increases the level of steady-state mRNA produced from the HTLV-II long terminal repeat (LTR) and also activates heterologous promoters. We have previously shown that the adenovirus E3 promoter, which is trans-activated by the adenovirus E1a protein, is also trans-activated by the tax protein. To investigate the mechanism of trans-activation by tax, we analyzed E3 promoter deletion mutants to determine nucleotide sequence requirements for activation of this promoter. Our results show that removal of different upstream regions within the promoter does not result in loss of trans-activation, indicating that tax does not appear to interact with a single DNA binding protein to activate the E3 promoter. In addition, tax and E1a together activate the E3 promoter in a greater than additive fashion, suggesting that these proteins function differently. Possible mechanisms of activation by the tax protein are discussed.

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