Bioactive CD4 ligands as pre- and/or postbinding inhibitors of HIV-1

In Silico Selection of Gp120 ssDNA Aptamer to HIV-1

Nucleic acid aptamers that specifically bind to other molecules are mostly obtained through the systematic evolution of ligands by exponential enrichment (SELEX). Because SELEX is a time-consuming procedure, the in silico design of specific aptamers has recently become a progressive approach. HIV-1 surface glycoprotein gp120, which is involved in the early stages of HIV-1 infection, is an attractive target for RNA and DNA aptamer selection. In this study, four single-stranded DNA aptamers, referred to as HD2, HD3, HD4, and HD5, that had the ability of HIV-1 inhibition were designed in silico. In a proposed non-SELEX approach, some parts of the B40 aptamer sequence, which interacted with gp120, were isolated and considered as a separate aptamer sequence. Then, to obtain the best docking scores of the HDOCK server and Hex software, some modifications, insertions, and deletions were applied to each selected sequence. Finally, the cytotoxicity and HIV inhibition of the selected aptamers were evaluated experimentally. Results demonstrated that the selected aptamers could inhibit HIV-1 infection by up to 80%, without any cytotoxicity. Therefore, this new non-SELEX approach could be considered a simple, fast, and efficient method for aptamer selection.

Recombinant anti-CD4 antibody 13B8.2 blocks membrane-proximal events by excluding the Zap70 molecule and downstream targets SLP-76, PLC gamma 1, and Vav-1 from the CD4-segregated Brij 98 detergent-resistant raft domains

The biological effects of rIgG(1) 13B8.2, directed against the CDR3-like loop on the D1 domain of CD4, are partly due to signals that prevent NF-kappaB nuclear translocation, but the precise mechanisms of action, particularly at the level of membrane proximal signaling, remain obscure. We support the hypothesis that rIgG(1) 13B8.2 acts by interfering with the spatiotemporal distribution of signaling or receptor molecules inside membrane rafts. Upon cross-linking of Jurkat T lymphocytes, rIgG(1) 13B8.2 was found to induce an accumulation/retention of the CD4 molecule inside polyoxyethylene-20 ether Brij 98 detergent-resistant membranes at 37 degrees C, together with recruitment of TCR, CD3zeta, p56 Lck, Lyn, and Syk p70 kinases, linker for activation of T cells, and Csk-binding protein/phosphoprotein associated with glycosphingolipid adaptor proteins, and protein kinase Ctheta, but excluded Zap70 and its downstream targets Src homology 2-domain-containing leukocyte protein of 76 kDa, phospholipase Cgamma1, and p95(vav). Analysis of key upstream events such as Zap70 phosphorylation showed that modulation of Tyr(292) and Tyr(319) phosphorylation occurred concomitantly with 13B8.2-induced Zap70 exclusion from the membrane rafts. 13B8.2-induced differential raft partitioning was epitope, cholesterol, and actin dependent but did not require Ab hyper-cross-linking. Fluorescence confocal imaging confirmed the spatiotemporal segregation of the CD4 complex inside rafts and concomitant Zap70 exclusion, which occurred within 10-30 s following rIgG(1) 13B8.2 ligation, reached a plateau at 1 min, and persisted until the end of the 1-h experiment. The differential spatiotemporal partitioning between the CD4 receptor and the Zap70-signaling kinase inside membrane rafts interrupts the proximal signal cross-talk leading to subsequent NF-kappaB nuclear translocation and explains how baculovirus-expressed CD4-CDR3-like-specific rIgG(1) 13B8.2 acts to induce its biological effects.

In Vitro Antitumoral Activity of Baculovirus-expressed Chimeric Recombinant Anti-CD4 Antibody 13B8.2 on T-cell Lymphomas

A baculovirus-expressed chimeric recombinant IgG1 (rIgG1) antibody, with Cgamma1 and Ckappa human constant domains, was derived from the murine monoclonal antibody 13B8.2, which is specific for the CDR3-like loop of the CD4 molecule. The recombinant IgG1 antibody 13B8.2 was previously shown to inhibit HIV-1 replication and to abrogate the one-way mixed-lymphocyte reaction and block proliferation of CD3-stimulated peripheral blood CD4 lymphocytes from healthy donors. Before testing this recombinant anti-CD4 antibody in in vivo preclinical trials, in vitro mechanisms of action of rIgG1 13B8.2 were assessed using various CD4 T-cell lymphomas. The baculovirus-expressed rIgG1 13B8.2 antibody led to 14% to 40% proliferation inhibition of the lymphoblastic leukaemia-derived SUP-T1, the acute T lymphoma-derived CCRF-CEM and Jurkat, and the cutaneous T-Cell lymphoma-derived HUT-78 cell lines, but it did not affect the cell cycle nor induce cell apoptosis. rIgG1 antibody 13B8.2 bound the C1q fraction, leading to 9% to 17% complement-mediated lysis of the HUT-78, H9, Sup-T1, and the CCRF-CEM cell lines. No correlation was observed between cell sensitivity to rIgG1 13B8.2-triggered complement-dependent lysis and CD35-, CD46-, CD55-, and CD59-surface expression on T lymphoma cells. Using fluorescence-activated cell sorter analysis, the antibody was shown to bind to FcgammaRI/CD64-transfected IIA1.6, FcgammaRII/CD32-transfected CDw32L, and FcgammaRIII/CD16-transfected Jurkat CD16 cell lines. In correlation with these findings, rIgG1 13B8.2 induced 11% to 31% antibody-dependent cell-mediated cytotoxicity of the CCRF-CEM, SUP-T1, A2.01 CD4, and Jurkat cell lines. These convincing results on the activity of the recombinant chimeric anti-CD4 antibody 13B8.2 have led us to perform in vivo preclinical study in a murine xenograft model of CD4 lymphomas.

PIN-bodies: a new class of antibody-like proteins with CD4 specificity derived from the protein inhibitor of neuronal nitric oxide synthase

By inserting the CB1 paratope-derived peptide (PDP) from the anti-CD4 13B8.2 antibody binding pocket into each of the three exposed loops of the protein inhibitor of neuronal nitric oxide synthase (PIN), we have combined the anti-CD4 specificity of the selected PDP with the stability, ease of expression/purification, and the known molecular architecture of the phylogenetically well-conserved PIN scaffold protein. Such "PIN-bodies" were able to bind CD4 with a better affinity and specificity than the soluble PDP; additionally, in competitive ELISA experiments, CD4-specific PIN-bodies were more potent inhibitors of the binding of the parental recombinant antibody 13B8.2 to CD4 than the soluble PDP. The efficiency of CD4-specific CB1-inserted PIN-bodies was confirmed in biological assays where these constructs showed higher potencies to block antigen presentation by inhibition of IL-2 secretion and to inhibit the one-way and two-way mixed lymphocyte reactions, compared with soluble anti-CD4 PDP CB1. Insertion of the PDP into the first exposed loop (position 33/34) of PIN appeared to be the most promising scaffold. Taken together, our findings demonstrate that the PIN molecule is a suitable scaffold to expose new peptide loops and generate small artificial ligand-binding products with defined specificities.

Mapping the paratope of anti-CD4 recombinant Fab 13B8.2 by combining parallel peptide synthesis and site-directed mutagenesis

We analyzed antigen-binding residues from the variable domains of anti-CD4 antibody 13B8.2 using the Spot method of parallel peptide synthesis. Sixteen amino acids, defined as Spot critical residues (SCR), were identified on the basis of a 50% decrease in CD4 binding to alanine analogs of reactive peptides. Recombinant Fab 13B8.2 mutants were constructed with alanine residues in place of each of the 16 SCR, expressed in the baculovirus cell system, and purified. CD measurements indicated that the mutated proteins were conformationally intact, with a beta-sheet secondary structure similar to that of wild-type Fab. Compared with the CD4-binding capacity of wild-type Fab 13B8.2, 11 light (Y32-L, W35-L, Y36-L, H91-L, and Y92-L) and heavy chain (H35-H, R38-H, W52-H, R53-H, F100K-H, and W103-H) Fab single mutants showed a decrease in CD4 recognition as demonstrated by enzyme-linked immunosorbent assay, BIAcore, and flow cytometry analyses. The five remaining Fab mutants showed antigen-binding properties similar to those of wild-type Fab. Recombinant Fab mutants that showed decreased CD4 binding also lost their capacity to inhibit human immunodeficiency virus promoter activation and the antigen-presenting ability that wild-type Fab displays. Molecular modeling of the 13B8.2 antibody paratope indicated that most of these critical residues are appropriately positioned inside the putative CD4-binding pocket, whereas the five SCR that were not confirmed by mutagenesis show an unfavorable positioning. Taken together, these results indicate that most of the residues defined by the Spot method as critical matched with important residues defined by mutagenesis in the whole protein context. The identification of critical residues for CD4 binding in the paratope of anti-CD4 recombinant Fab 13B8.2 provides the opportunity for the generation of improved anti-CD4 molecules with more efficient pharmacological properties.

Efficient CD4 binding and immunosuppressive properties of the 13B8.2 monoclonal antibody are displayed by its CDR-H1-derived peptide CB1

A systematic exploration of the V(H)2/V(kappa)12-13 variable domains of the anti-CD4 monoclonal antibody (mAb) 13B8.2 was performed by the Spot method to screen for paratope-derived peptides (PDPs) demonstrating CD4 binding ability. Nine peptides, named CB1 to CB9, were identified, synthesized in a cyclic and soluble form and tested for binding to recombinant soluble CD4. Among them, CB1, CB2 and CB8 showed high anti-CD4 activity. Competition studies for CD4 binding indicated that PDPs CB1, CB8, and the parental mAb 13B8.2 recognized the same complementarity determining region (CDR)3-like loop region. PDP CB1 was shown to mimic the biological properties of 13B8.2 mAb in two independent cellular assays, demonstrating inhibitory activities in the micromolar range on antigen presentation and human immunodeficiency virus promoter activation. Our results indicate that the bioactive CDR-H1 PDP CB1 has retained a significant part of the parental 13B8.2 mAb properties and might be a lead for the design of anti-CD4 peptidomimetics of clinical interest.