A hybridoma producing human monoclonal antibody specific for glycoprotein 120 kDa of human immunodeficiency virus (HIV-1

Human antibody variable region gene usage in HIV-1 infection

Human antibody variable region gene usage during human immunodeficiency virus type 1 (HIV-1) infection is examined in the following review, and several hypotheses are presented to account for the distinct patterns of antibody gene expression associated with infection. Evidence supporting qualitatively biased antibody gene expression has been derived from analysis of the human humoral immune response by isoelectric focusing (IEF) and serological and molecular studies of immunoglobulin (Ig) from different lymphoid compartments of HIV-1-infected patients. Preferential usage of heavy-chain variable region (VH) gene families 1 and 4 is supported by serological studies of serum Ig and molecular characterization of anti-HIV-1 human monoclonal antibodies derived from infected patients. Negative biases against VH3 family gene usage are detected by polymerase chain reaction (PCR) studies of peripheral blood lymphocytes from AIDS patients but not by combinatorial phage display library techniques. Biased antibody gene usage and expression during HIV-1 infection may be related to HIV-1 pathogenesis by limiting the available HIV-1 neutralizing repertoire. Further molecular characterization of anti-HIV-1 antibodies and in vivo expression of V-region genes during HIV-1 infection should provide important information regarding antibody gene expression and its relationship to HIV-1 pathogenesis.

Variable region genes of anti-HIV human monoclonal antibodies: non-restricted use of the V gene repertoire and extensive somatic mutation

The extent of the expressed human V gene repertoire for the most part has been derived from fetal cDNA libraries, autoantibodies, and myeloma proteins. In order to continue to explore the utilization of the VH and VL gene repertoire in response to exogenous viral antigens, the heavy and light chain cDNAs from four human anti-HIV monoclonal antibodies were PCR amplified from human-mouse heterohybridomas, cloned, and nucleotide sequence analysis performed. Of the monoclonals analyzed, three were directed against gp120 and one reacted with gp41. Three of the antibodies were of the IgG1 lambda isotype and one was an IgG1 kappa. Three of the four heavy chains were derived from VHI gene segments and one VHII was observed. D segments showed evidence of D-D joining and three JH4 and one JH5 gene were utilized. Two V lambda II lambda chains and one from the V lambda III gene family were observed and the single kappa chain sequenced was from the V kappa III family. DNA sequence comparison with known germline gene segments identified putative precursor V gene segments for one of the heavy chains and two light chains. Comparison of the expressed amino acid sequences with the predicted germline sequences indicated that changes were clustered in the CDRs and FR3 regions of the V gene segments. We reported previously the nucleotide sequences of five human monoclonal antibodies from HIV-infected individuals, three of which utilized VHIV, one VHV and one a VHI gene segment and also found extensive evidence of somatic mutation. Collectively, our results indicate that an antigen driven response is functioning following HIV infection and, surprisingly, to date we have not encountered a VHIII gene segment. Since VHIII is the largest human VH gene family, it may well be that this under-representation has both functional and clinical implications.

B cell responses to HIV and the development of human monoclonal antibodies

In this review B cell responses in HIV-infected individuals are summarized together with the techniques used to date to produce human monoclonals to HIV and the properties of these antibodies. Profound disturbances in B cell responses are apparent both in vivo and in vitro. While there is evidence in vivo of marked polyclonal B cell activation, primary and secondary antibody responses are impaired. Similarly these cells exhibit spontaneous immunoglobulin secretion upon in vitro culture but do not readily respond to B cell mitogens and recall antigens including HIV. Furthermore, certain of these defects can be reproduced in normal B cells in vitro by incubation with HIV or HIV coded peptides. Individuals infected with HIV develop antibodies to HIV structural proteins (e.g. p17, p24, gp41 and gp120) and regulatory proteins (e.g. vif, nef, RT). Autoantibodies against a number of immunologically important molecules are also frequently observed. The anti-HIV antibodies are predominantly of the IgG1 isotype and exhibit a variety of effects on the virus in vitro. To date, using conventional immortalization strategies, an appreciable number of human monoclonals to HIV have been developed. These have been specific for gp41, gp120 and gag with antibodies of the former specificity predominating. The majority of these antibodies have been of the IgG1 isotype. Only a small number of the antibodies neutralize virus in vitro and most of these react with gp120. The neutralizing antibodies recognize conformational and carbohydrate epitopes or epitopes in amino acid positions 306-322. The predominant epitopes recognized by the anti-gp41 antibodies were in amino acid positions 579-620 and 644-662. A high percentage (congruent to 25%) of these antibodies enhance viral growth in vitro. The problems relating to the production of human monoclonals to HIV are discussed together with strategies that could be used in the future.

Homotypic antibody responses to fresh clinical isolates of human immunodeficiency virus

Human immunodeficiency virus type 1 (HIV-1) exhibits extensive genomic and antigenic diversity, which is thought to contribute to the failure of the host's immune response to control infection and prevent clinical progression. Part of this failure may be due to utilization by the virus of antigenic variation as a means to escape protective immune responses. Antibody-escape variants of HIV-1 were studied here using fresh clinical isolates and autologous plasmas. HIV-1 was isolated from the plasma of seven people who were all seropositive for at least 2 years, and symptomatic sometime during that period. Isolated viruses were confirmed as HIV-1 by the presence of reverse transcriptase activity in infected culture supernatants, and by positive immunofluorescence using human monoclonal antibody to HIV-1 core protein. Plasma from these people were positive by Western immunoblot (DuPont) for most major HIV-1 (strain IIIB) antigens. These plasmas neutralized three laboratory strains of HIV-1 (i.e., IIIB, RF, and MN) but did not neutralize the homotypic strain in five cases, and had greatly reduced neutralizing titers against the homotypic strain in two cases. Homotypic neutralizing antibodies were absent in autologous plasma obtained 3 months later. When antibody titers were measured by fixed-cell indirect immunofluorescence assays (IFAs), high titers of IgG (1:6400 to 1:25,600) were detected against HIV-1 IIIB, while low titers of only 1:20 to 1:160 were detected against homotypic viral antigens at the time of virus isolation, and remained low 12 and 16 weeks later. No class IgA, IgD, IgE, or IgM antibodies to homotypic viral antigens, as possible IgG-blocking antibodies, were detected by fixed-cell IFAs. Cross-reactions with heterologous donor's plasmas were observed in some cases, and in these cases the cross-reactions were unidirectional. Live-cell IFAs detected IgG in patient's plasma to HIV-1 IIIB-infected cells but not to cells infected with homotypic isolates. These results suggest that it is common for neutralization-resistant HIV-1 variants to appear during the course of infection, and that all or most antigens of these variants are capable of escaping antibody recognition.