Interaction of C-terminal sequences of human immunodeficiency virus reverse transcriptase with template primer

Multiple pathways of amino terminal processing produce two truncated variants of RANTES/CCL5

The CC chemokine regulated on activation, normal T cell expressed and secreted (RANTES)/CC chemokine ligand 5 (CCL5) is expressed by macrophages, endothelial cells, keratinocytes, and T cells during a wide variety of immune responses. Post-translational proteolysis is expected to play an important role in regulating such broad-based expression; however, the rates and modes of RANTES processing by primary cell systems remain poorly understood. Here, we show that peripheral blood mononuclear cells (PBMC) secrete RANTES as an intact molecule that is subject to three post-translational processing pathways. One occurs in the presence of serum or plasma and rapidly generates a RANTES variant lacking two N-terminal residues (3-68 RANTES). Such processing is mainly attributable to soluble CD26. A second pathway, which is evident in the absence of serum or plasma, generates 3-68 RANTES in concert with the expression of cell-surface CD26. The third pathway is unique and generates a novel variant lacking three N-terminal residues (4-68 RANTES). This variant binds CC chemokine receptor 5, exhibits reduced chemotactic and human immunodeficiency virus (HIV)-suppressive activity compared with 1-68 and 3-68 RANTES, and is generated by an unidentified enzyme associated with monocytes and neutrophils. Overall, these results indicate that the production of RANTES by primary cells is regulated by multiple processing pathways which produce two variants with different functional properties. Such findings have important implications for understanding the immunological and HIV-suppressive activities of native RANTES.

Identification of the primer binding domain in human immunodeficiency virus reverse transcriptase

We have labeled the primer binding domain of HIV1-RT with 5'-32P-labeled (dT)15 primer using ultraviolet light energy. The specificity of the primer cross-linking to HIV1-RT was demonstrated by competition experiments. Both synthetic and natural primers, e.g., p(dA)15, p(dC)15, and tRNA(Lys), inhibit p(dT)15 binding and cross-linking to the enzyme. The observed binding and cross-linking of the primer to the enzyme were further shown to be functionally significant by the observation that tRNA(Lys) inhibits the polymerase activity on poly(rA).(dT)15 template-primer as well as the cross-linking of p(dT)15 to the enzyme to a similar extent. At an enzyme to p(dT)15 ratio of 1:3, about 15% of the enzyme can be cross-linked to the primer. To identify the domain cross-linked to (dT)15, tryptic peptides were generated and purified by a combination of HPLC on a C-18 reverse-phase column and DEAE-Sephadex chromatography. A single peptide cross-linked to p(dT)15 was identified. This peptide corresponded to amino acid residues 288-307 in the primary sequence of HIV1-RT as judged by amino acid composition and sequence analyses. Further, Leu(289)-Thr(290) and Leu(295)-Thr(296) of HIV1-RT appear to be the probable sites of cross-linking to the primer p(dT)15.

Generation of HIV-1/HIV-2 cross-reactive peptide antisera by small sequence changes in HIV-1 reverse transcriptase and integrase immunizing peptides

We have generated peptide antisera against selected regions in HIV-1 and HIV-2 reverse transcriptase (RT) and integrase (IN) to investigate the specificity of determinants governing the immune response. Peptides representing homologous regions (>50%) in the N- and C-termini and central portions of these proteins were synthesized and injected into rabbits. HIV-1 and HIV-2 IN peptide antisera inhibited IN-mediated cleavage of an HIV-1 DNA oligonucleotide substrate in a 3' processing assay, while anti-RT or normal sera had no effect. None of the RT sera inhibited RT activity. In Western blots, HIV-2 antisera directed against RT or IN peptides recognized HIV-2 RT and IN proteins, respectively, as expected, but also cross-reacted with the corresponding HIV-1 proteins. By contrast, corresponding HIV-1 antisera were type-specific. In some cases, HIV-1 cross-reactive antisera could be generated by immunization with HIV-1 chimeric peptides with as few as two residues in the HIV-1 sequence changed to the corresponding HIV-2 amino acids. The finding that a type-specific response can be converted to a cross-reactive response suggests alternate strategies for developing new diagnostic reagents which detect HIV-1 and HIV-2. In addition, our results provide a general model for generating HIV peptide vaccines with dual specificity against HIV-1 and HIV-2.

Immunogenic properties of reverse transcriptase of HIV type 1 assessed by DNA and protein immunization of rabbits

Genetic immunization may be one way to prime individuals for a subsequent broad anti-HIV-1 immune response. Reverse transcriptase of HIV-1 (RT) presents a selective target for attempts to arrest replication of HIV-1. Rabbits immunized with a plasmid carrying the gene for reverse transcriptase HIV-1 (RT DNA) developed potent antibody and cellular responses to the gene product. The immunogenic properties of RT DNA and recombinant reverse transcriptase were compared in rabbits. The specific immune responses were similar to those reported previously for HIV-1 infected humans. The array of B and T cell epitopes recognized in RT DNA-immunized rabbits was broader than in rabbits immunized with the recombinant RT. We localized seven novel B and T cell epitopes and concordance between B cell and helper T cell epitopes was observed. B cell epitopes of RT induced proliferation of peripheral blood mononuclear cells and were active as helper T cell epitopes. T cell-proliferative responses to the epitopes of RT preceded or paralleled the production of antibodies of the same specificity. Subdomains of reverse transcriptase involved in the enzymatic activity of RT were highly immunogenic. Anti-RT IgG partially inhibited reverse transcription in vitro.

Inhibition of HIV-1 replication using a mutated tRNALys-3 primer

Cellular tRNALys-3 serves as the primer for reverse transcription of human immunodeficiency virus, type 1 (HIV-1). tRNALys-3 interacts directly with HIV-1 reverse transcriptase, is packaged into viral particles and anneals to the primer-binding site (PBS) of the HIV-1 genome to initiate reverse transcription. Therefore, the priming step of reverse transcription is a potential target for antiviral strategies. We have developed a mutant tRNALys-3 derivative with mutations in the PBS-binding region such that priming specificity was re-directed to the highly conserved TAR stem-loop region. This mutant tRNA retains high-affinity binding to HIV-1 reverse transcriptase, viral encapsidation, and is able to prime at both the targeted TAR sequence and at the viral PBS. Constitutive expression of mutant tRNA in T-cells results in marked inhibition of HIV-1 replication, as determined by measurements of viral infectivity, syncytium formation, and p24 production. Inhibition of retroviral replication through interference with the normal process of priming constitutes a new anti-retroviral approach and also provides a novel tool for dissecting molecular aspects of priming.

Mechanism of enzyme inhibition mediated by anti-reverse transcriptase antibodies from HIV type 1-infected individuals

We have examined the mechanisms of reverse transcriptase (RT) inhibition mediated by anti-RT antibodies, isolated by affinity chromatography, from four HIV-1-positive individuals. In kinetics assays, anti-RT immunoglobulin (Ig) obtained from three of the sera mediated a noncompetitive type of inhibition against template primer; two of these three also mediated noncompetitive inhibition with respect to deoxyribonucleoside triphosphate. Such inhibition did not require that the Ig be preincubated with RT prior to the addition of reaction components. In contrast, a more complicated pattern of inhibition was exhibited by anti-RT Ig from the fourth serum. Preincubation of this Ig with enzyme markedly enhanced the inhibition. The results demonstrate that the specificities of RT-inhibiting antibodies vary among HIV-1-infected individuals, but that one prevalent mechanism of inhibition involves interactions with epitopes outside of the enzyme active site.

Characterization of HIV-1 reverse transcriptase with antibodies indicates conformational differences between the RNAse H domains of p 66 and p 15

Antibody binding to the p 66 and p 15 RNase H regions of HIV-1 reverse transcriptase was compared using a polyclonal rabbit immune serum raised against a synthetic peptide from the RNase H region of reverse transcriptase (aa 511-527) and six monoclonal antibodies binding to discontinuous epitopes in the RNase H region of p 66. The antigens used in Western blot analysis included recombinantly expressed homodimeric p 66 digested with the HIV-1 protease for generation of the p 51 and p 15 polypeptides and two different length RNase H domains expressed as Trp E fusion proteins (aa 410-560 and aa 441-560). The polyclonal rabbit antibody binding to a continuous epitope recognized both the Trp E-fusion proteins and also the polypeptides p 66 and p 15 generated by processing of homodimeric p 66 with the viral protease. Two additional cleavage products with estimated molecular weights of 9 and 11 kDa were also detected. The anti-RNase H MAbs binding to discontinuous epitopes recognized only the RNase H domain of the p 66 polypeptide and the Trp E-RNase H fusion protein when this was expressed together with the C-terminal part of the polymerase domain. The results indicate conformational differences between the RNase H domain of the p 66 subunit and the RNase H p 15 polypeptide.

Purification and partial characterization of equine infectious anemia virus reverse transcriptase

Previously we raised a rabbit monospecific antibody (C2003) against a synthetic peptide derived from a sequence within the C-terminal portion of the reverse transcriptase (RT) of the human immunodeficiency virus type 1 (HIV-1). This sequence is found to be conserved in the predicted amino acid sequence of a related lentivirus, the equine infectious anemia virus (EIAV). It was previously determined that the C2003 antibody could cross-react with native EIAV RT and directly inhibit the DNA polymerase activity of the enzyme. We have now fractionated EIAV RT by immunoaffinity chromatography with immobilized C2003 antibody. The procedure yielded an equimolar mixture of two proteins of 66 and 51 kDa associated with both DNA polymerase and RNase H activities. When the EIAV RT proteins were examined by in situ activity gel assays, polymerase activity was found to be principally associated with the 66-kDa component. The fidelity of DNA synthesis by EIAV RT was found to be equivalent to that of HIV-1 RT and lower than that of AMV RT. These observations indicate that the RTs of EIAV and HIV-1 share similar structural and functional properties.