A sensitive promoter assay based on the transcriptional activator Tat of the HIV-1 virus.

We developed a sensitive vector system for the analysis of weak promoter activities. This promoter assay is based on the transcriptional activator protein, Tat, of human immunodeficiency virus type 1 (HIV-1). High-level expression of HIV requires activation in trans by Tat of the promoter in the long terminal repeat (LTR). Here we describe the construction of a promoterless pTat vector. Foreign promoter elements can be inserted upstream from the tat gene, and expression of Tat protein is measured in trans on a co-transfected LTR-CAT reporter plasmid. We show that this binary system is more sensitive than standard pCAT reporter assays.

Intracellular analysis of in vitro modified HIV Tat protein.

Human immunodeficiency viruses HIV-1 and HIV-2 encode a Tat protein that specifically activates transcription from the viral long terminal repeat. To characterize the properties of the Tat proteins, we have expressed them in Escherichia coli. The purified Tat protein was biochemically analyzed and tested for activity upon electroporation into human cell lines. This protein electroporation was used for the intracellular analysis of in vitro modified Tat protein. Our results indicate that the transcriptionally active form of the Tat protein is a monomer. Furthermore, we found that Tat activity is dramatically inhibited by preincubation of the protein with strongly reducing agents. In contrast, no inhibitory effect was measured upon incubation with metal-chelating reagents. These results suggest that the cysteine residues of Tat are involved in the formation of intramolecular disulfide bonds.

Functional Analysis of the ACTGCTGA Sequence Motif in the Human Immunodeficiency Virus Type-1 Long Terminal Repeat Promoter.

The ACTGCTGA sequence (CTG motif) is located immediately upstream of the NF-kappaB enhancer in the human immunodeficiency virus type-1 (HIV-1) long terminal repeat (LTR). We previously reported on the frequent duplication of this motif in HIV-1-infected individuals. In this study we further characterized the role of the CTG element in transcription and its interaction with cellular proteins. We analyzed the biological activity of LTR promoters with dimeric, monomeric or deleted CTG motifs. Our results indicate that LTRs containing the monomeric CTG motif are the most active transcriptional promoters. Furthermore, mutant viruses with dimeric or deleted CTG motif were consistently out-competed by the wild-type virus in co-culture experiments. Gel mobility shift assays were used to identify a nuclear protein of approximately 68 kD that specifically interacts with this DNA sequence. Copyright 1994 S. Karger AG, Basel

Human immunodeficiency virus uses tRNA(Lys,3) as primer for reverse transcription in HeLa-CD4+ cells.

Significant amounts of different tRNA molecules are present in retroviral particles, but one specific tRNA species functions as primer in reverse transcription. It is generally believed that the HIV-1 virus uses the tRNA(Lys,3) molecule as primer. This is based on sequence complementarity between the 3' end of tRNA(Lys,3) and the primer-binding site (PBS) on HIV-1 genomic RNA. Recent biochemical analyses indicated that tRNA(LYs,3) is indeed incorporated into viral particles. Interestingly, tRNA(Lys,3) could not be detected in virions produced by HeLa-CD4+ cells [(1992) Biochem. Biophys. Res. Commun. 185, 1105-1115]. In order to test whether alternative tRNA molecules can function as primer in HIV replication, we performed a series of experiments based on the observation that tRNA primer sequences are inherited by the viral progeny. We cultured HIV-1 for prolonged periods of time in HeLa-CD4+ cells, but did not detect sequence changes in the PBS region. Furthermore, we found PBS-mutants to be replication-incompetent, again suggesting that HIV-1 solely uses tRNA(Lys,3) as primer. Most importantly, we obtained revertants of one such PBS-mutant, which had restored a wild-type PBS sequence. This tRNA(Lys,3)-mediated repair demonstrates a general requirement for this primer in HIV-1 reverse transcription.

Natural variants of the HIV-1 long terminal repeat: analysis of promoters with duplicated DNA regulatory motifs.

Sequence variation in the long terminal repeat (LTR) region of HIV-1 was analyzed in viral isolates of 17 infected individuals. Two classes of LTR size variants were found. One HIV-1 variant was detected containing an additional binding site for the transcription factor Sp1. Another LTR size variation was observed in four patients in a region just upstream of the NF-kappa B enhancer. This variation was the result of a duplication of a short DNA sequence (CTG-motif). Cell culture experiments demonstrated that the natural variant with four Sp1 sites had a slightly higher promoter activity and viral replication rate than the isogenic control LTR with three Sp1 sites. No positive effect of the duplicated CTG-motif could be detected. In order to measure small differences in virus production more accurately, equal amounts of a size variant and the wild-type plasmid were cotransfected into T-cells. The virus with four Sp1 sites did outgrow the three Sp1 virus in 35 days of culture and CTG-monomer virus outcompeted the CTG-dimer virus in 42 days. Based on these results we estimate a 5-10% difference in virus production of the LTR variants when compared to that of wild-type.