Anne Caumont

Functional Interactions of Human Immunodeficiency Virus Type 1 Integrase with Human and Yeast HSP60

ABSTRACT Integration of human immunodeficiency virus type 1 (HIV-1) proviral DNA in the nuclear genome is catalyzed by the retroviral integrase (IN). In addition to IN, viral and cellular proteins associated in the high-molecular-weight preintegration complex have been suggested to be involved in this process. In an attempt to define host factors interacting with IN, we used an in vitro system to identify cellular proteins in interaction with HIV-1 IN. The yeast Saccharomyces cerevisiae was chosen since (i) its complete sequence has been established and the primary structure of all the putative proteins from this eucaryote has been deduced, (ii) there is a significant degree of homology between human and yeast proteins, and (iii) we have previously shown that the expression of HIV-1 IN in yeast induces a lethal phenotype. Strong evidences suggest that this lethality is linked to IN activity in infected human cells where integration requires the cleavage of genomic DNA. Using IN-affinity chromatography we identified four yeast proteins interacting with HIV-1 IN, including the yeast chaperonin yHSP60, which is the counterpart of human hHSP60. Yeast lethality induced by HIV-1 IN was abolished when a mutated HSP60 was coexpressed, therefore suggesting that both proteins interact in vivo. Besides interacting with HIV-1 IN, the hHSP60 was able to stimulate the in vitro processing and joining activities of IN and protected this enzyme from thermal denaturation. In addition, the functional human HSP60-HSP10 complex in the presence of ATP was able to recognize the HIV-1 IN as a substrate.

High affinity interaction of HIV-1 integrase with specific and non-specific single-stranded short oligonucleotides

Retroviral integrase (IN) catalyzes the integration of double‐stranded viral DNA into the host cell genome. The reaction can be divided in two steps: 3′‐end processing and DNA strand transfer. Here we studied the effect of short oligonucleotides (ODNs) on human immunodeficiency virus type 1 (HIV‐1) IN. ODNs were either specific, with sequences representing the extreme termini of the viral long terminal repeats, or non‐specific. All ODNs were found to competitively inhibit the processing reaction with K i values in the nM range for the best inhibitors. Our studies on the interaction of IN with ODNs also showed that: (i) besides the 3′‐terminal GT, the interaction of IN with the remaining nucleotides of the 21‐mer specific sequence was also important for an effective interaction of the enzyme with the substrate; (ii) in the presence of specific ODNs the activity of the enzyme was enhanced, a result which suggests an ODN‐induced conformational change of HIV‐1 IN.

Expression of functional HIV-1 integrase in the yeastSaccharomyces cerevisiae leads to the emergence of a lethal phenotype: potential use for inhibitor screening

The integrase of the human immunodeficiency virus type 1 (HIV-1) has been expressed in yeast in order to investigate its potential lethal effect mediated by DNA damage. To this end, we have constructed an expression plasmid containing the retroviral integrase gene under the control of the inducible promotor ADH2/GAPDH which is regulated by the glucose concentration of the medium. Haploid yeast strain W303-1A did not appear to be clearly sensitive to HIV-1 integrase expression. However, disruption of theRAD 52 gene, which is involved in the repair of double-strand DNA breaks, strongly increased the deleterious effects of the retroviral enzyme in this yeast strain. The diploid strain constructed with W303-1A and an isogenic strain of the opposite mating type also showed a strong sensitivity to the HIV-1 integrase. Under yeast culture conditions allowing moderate integrase synthesis, the deleterious effect was totally abolished by missense integrase mutations, which are known to abolish HIV-1 integrase activities in vitro. We conclude that the lethal phenotype due to HIV-1 integrase expression in yeast may be closely related to the HIV-1 integration reaction in infected human cells, and that yeast may be a useful tool to study the HIV-1 integration process and to screen drugs capable of inhibiting HIV-1 integration in vivo.

Inactivation of the SNF5 transcription factor gene abolishes the lethal phenotype induced by the expression of HIV-1 integrase in yeast.

The ubiquitous human transcription factor Ini1 has been shown to interact with HIV-1 integrase (IN) and to stimulate in vitro the reactions catalyzed by this enzyme. We have previously used a yeast model to study the effect of HIV-1 IN expression (Caumont, A.B., Jamieson, G.A., Pichuantes, S., Nguyen, A.T., Litvak, S., Dupont, C. -H., 1996. Expression of functional HIV-1 integrase in the yeast Saccharomyces cerevisiae leads to the emergence of a lethal phenotype: potential use for inhibitor screening. Curr. Genet. 29, 503-510). Here, we describe the effect of the inactivation of the gene encoding for SNF5, a yeast transcription factor homologous to Ini1, on the lethality induced by the expression of HIV-1 IN in yeast. We observed that the retroviral IN was unable to perform its lethal activity in cells where the SNF5 gene has been disrupted, suggesting that SNF5 may play a role in the lethal effect induced by IN in yeast. SNF5 inactivation affects neither yeast viability nor expression of HIV-1 IN. Given the homology between SNF5 and its human counterpart Ini1, our results suggest that this factor may be important for IN activity in infected cells. Moreover, given the important role proposed for this transcription factor in the integration step and the fact that it is dispensable for cell viability, the interaction between Ini1/ySNF5 and HIV-1 IN should become a potential target in the search for new antiretroviral agents.

Inhibition of HIV-1 integrase-catalysed reaction by new DNA minor groove ligands: the oligo-1,3-thiazolecarboxamide derivatives

Human immunodeficiency virus type 1 (HIV-1) integrase (IN) is an essential enzyme in the life cycle of the retrovirus, responsible for catalysing the insertion of the viral genome into the host cell chromosome. For this reason it provides an attractive target for antiviral drug design. We synthesized a series of novel thiazole (Tz)-containing oligopeptides (TCOs; oligo-1,3-thiazolecarboxamides), specifically interacting within the minor groove of DNA. The oligocarboxamide derivatives contained 1-4 Tz rings and different N- and C-terminal groups. The effect of these oligocarboxamides on the HIV-1 IN-catalysed reaction was investigated. Some of the compounds were able to inhibit the reaction. The inhibitory effect of the TCOs increased with the number of Tz units. The structure of various additional positively and/or negatively charged groups attached to the N- and C-termini of TCOs had a pronounced effect on their interaction with the DNA substrate complexed to IN. Modified TCOs having a better affinity for this complex should provide a rationale for the design of drugs targeting the integration step.