Martin Purtscher

A Potent Cross-Clade Neutralizing Human Monoclonal Antibody against a Novel Epitope on gp41 of Human Immunodeficiency Virus Type 1

We have established a panel of human monoclonal antibodies against human immunodeficiency virus type 1 (HIV-1). The antibodies 2F5 and 2G12 have been identified to be two of the most potently in vitro neutralizing antibodies against HIV-1. Here we report on a further antibody, 4E10, of similar in vitro neutralizing potency. 4E10 binds to a novel epitope C terminal of the ELDKWA sequence recognized by 2F5, which has been so far the only described broadly neutralizing anti-gp41 antibody. Both 4E10 and 2F5 bind only weakly to infected cells compared with gp120-specific 2G12 and polyclonal anti-HIV-1 immunoglobulin (HIVIG), but show potent in vitro neutralizing properties. 4E10 neutralizes potently not only tissue culture-adapted strains but also primary isolates of different clades, including A, B, C, D, and E. Viruses that were found to be resistant to 2F5 were neutralized by 4E10 and vice versa; none of the tested isolates was resistant to both anti-gp41 antibodies. This confirms that the region recognized by 2F5 and 4E10 is essential for viral infectivity and may be important for vaccine design. Moreover, our results suggest that 4E10 should be further investigated for passive anti-HIV immunotherapy.

Restricted antigenic variability of the epitope recognized by the neutralizing gp41 antibody 2F5.

Objective To investigate whether variations of the conserved gp41 amino-acid sequence ELDKWA affect its binding or neutralization by monoclonal antibody (MAb) 2F5. Design and methods Neutralization assays were performed with primary isolates from different HIV-1 subtypes and the sequences corresponding to the 2F5 epitope region were analysed. Studies of MAb 2F5 peptide reactivity were performed by spot analysis, using peptides immobilized on cellulose. The frequency of emergence of neutralization-resistant virus variants was determined by immune selection experiments in the presence of MAb 2F5. Results Primary isolates from clades A, B and E were neutralized by MAb 2F5. Neutralization sensitivity correlated with the presence of the LDKW motif. A K-to-N change in the core sequence was identified in a neutralization-resistant patient isolate. Neutralization resistant virus variants that were selected in the presence of MAb 2F5 were found to contain D-to-N, D-to-E, or K-to-N changes within the LDKW sequence. Neither in natural isolates nor in variants obtained under immune selection conditions in the laboratory were changes in the L and W positions observed. Studies of MAb 2F5 binding to variations of the ELDKWA peptide confirmed that the changes at the first and last positions did not significantly reduce binding capacity, whereas amino-acid changes from D to N, D to E, and K to N almost completely abrogated binding of MAb 2F5. Conclusion Sequence analysis of a variety of primary isolates suggests that the major determinant of MAb 2F5 binding corresponds to the amino-acid sequence LDKW. Naturally occurring and in vitro selected neutralization-resistant viruses contained changes in the D and K positions of the ELDKWA motif.

Immunogenic presentation of a conserved gp41 epitope of human immunodeficiency virus type 1 on recombinant surface antigen of hepatitis B virus.

In view of the high antigenic variability of human immunodeficiency virus type 1 (HIV-1), a vaccine against AIDS must induce an immune response to epitopes as invariable as possible among the various virus strains and clones. Previously the highly conserved six amino acid sequence Glu-Leu-Asp-Lys-Trp-Ala (ELDKWA) from gp41, defining the epitope of the human MAb 2F5, was shown to elicit HIV-1-neutralizing antibodies when presented on haemagglutinin of influenza virus. We investigated the immunogenic potential of the MAb 2F5 epitope and two of its major escape epitopes as internal fusions to the hepatitis B virus (HBV) surface antigen (HBsAg). Recombinant HBsAg-HIV proteins produced in the methylotrophic yeast Pichia pastoris self-assembled into 22 nm lipoprotein particles. Mice immunized with these particles developed an anti-HBsAg immune response in a range that is considered to be protective against HBV infection in humans. More importantly, antisera had extremely high titres of antibodies reactive with a structurally flexible form of the HIV-1 epitope, whereby strong cross-reactivity with the escape variants of the epitope was observed. Although HIV-1 gp 160 and the ectodomain of gp41 containing the epitope were significantly recognized, the antisera failed to neutralize HIV-1 in vitro. These data, together with those on the haemagglutinin-ELDKWAS fusion suggest that the ability of the MAb 2F5 epitope to induce neutralizing antibodies depends on the molecular context in which it is presented. Therefore, further characterization of secondary and tertiary structure requirements of the epitope is indispensable for the full exploitation of its potential as a vaccine component.

Stable recombinant expression of the anti HIV‐1 monoclonal antibody 2F5 after IgG3/IgG1 subclass switch in CHO cells

The human monoclonal antibody (humAb) 2F5 is a potent candidate for immunotherapy of HIV-1. The xenohybridoma derived humAb 2F5 is of IgG3 kappa isotype. Generally, IgG1 isotype has a longer half-life (beta-clearance) in humans than IgG3. Therefore the isotype was switched to an IgG1 by ligation of the 2F5 heavy chain variable region to an IgG1 constant region and expressed as IgG1 kappa in CHO cells. CHO clones have been established, which stably express humAb 2F5 at high levels. The specificity, affinity and in vitro function of both isotypes were identical.

Comparison of protein A, protein G and copolymerized hydroxyapatite for the purification of human monoclonal antibodies

Protein A Superose, protein G Sepharose fast flow and copolymerized hydroxyapatite were used for the purification of human monoclonal antibodies against HIV 1. Both desalted culture supernatant and a prepurified protein solution were used as starting materials. The different runs were compared with respect to yield and recovery of biological activity. The biological activity (specific reactivity) was checked by antigen enzyme-linked immunosorbent assay with recombinant antigen. The human monoclonal antibodies could not be selectively eluted from the hydroxyapatite but elution could be effected from the protein A Superose at pH 4.0 and from protein G at pH 3.0. The eluted immunoglobulin G was distributed over a broad pH range when protein G Superose was used. Biologically active material could be obtained from protein A Superose and protein G Sepharose fast flow.

A simple and robust method for the complete dissociation of HIV-1 p24 and other antigens from immune complexes in serum and plasma samples

Accuracy of antigen determination in human plasma samples is often adversely affected by immune complex formation between antigens (e.g., HIV-1 p24 protein) and specific antibodies. In this study we describe an optimized method for complete immune complex dissociation (ICD) in plasma. This method is based on heat denaturation of antibodies and utilizes a defined solution of sodium dodecyl sulfate (SDS) and diethylenetriaminepentaacetic acid (DTPA) as diluent. The efficiency of this procedure for ICD was compared with those of published methods, employing heat denaturation alone and acidification. Plasma samples from patients participating in anti-retroviral treatments and samples reconstituted in vitro were treated and analyzed in parallel. HIV-1 p24 antigen was determined by quantitative enzyme-linked immunosorbent assay (ELISA). In 312 samples from 97 patients, antigenemia was found in 44.9% when measured directly and in 87.2% after this treatment. In a subset of 56 samples, 21.4% tested positive prior to treatment, while after either novel treatment, heat denaturation or acidification, these samples tested positive in 80.4%, 62.5% and 60.7%, respectively. In 94% of cases viral RNA was detected. This improved procedure for ICD provides a reliable and convenient method for complete and accurate p24 antigen detection in human plasma and is applicable to commercially available test kits.

Pilot scale production of a human monoclonal antibody against human immunodeficiency virus HIV-1

Human monoclonal antibodies against the transmembrane protein gp41 of HIV-1 were isolated and purified on a pilot scale. A purification scheme was established for the production of human monoclonal antibodies on the gram scale. 50 1 of culture supernatant can be treated in one purification cycle. The hybridomas were mass cultured in an airlift fermenter. The culture broth was clarified by microfiltration and chromatographed on CM-Sepharose fast flow and protein A Superose. Scale up of the high performance affinity chromatography from 1 ml protein A Superose up to 40 ml is described. All desalting steps were performed by gel filtration on Sephadex G-25 coarse. The yield of the whole purification procedure is in the range of 50-60%. The purity is higher than 99.9%. DNA and reverse transcriptase could not be detected. The whole method is designed as a basis for scale up to industrial scale. Results from quality control assays have proven the validity of this approach.

Isolation of isoproteins from monoclonal antibodies and recombinant proteisn by chromatofocusing

A fast protein liquid chromatographic method for the preparative separation of the various isoproteins is described. Highly purified human monoclonal antibodies, recombinant human superoxide dismutase and human superoxide dismutase from erythrocytes were used as starting material. The isoproteins were separated by chromatofocusing on Mono P columns. A very narrow pH gradient was applied to achieve complete separation of the isoproteins. The prepurification steps and the pretreatment of the samples to achieve optimum resolution are described in detail. The method is also applicable to extremely basic monoclonal antibodies (pI = 9). The successful separation was checked by isoelectric focusing in immobilized pH gradients (Immobilines). The future of these methods is discussed, because for many different biochemical and biophysical investigations pure and homogeneous isoproteins are necessary.