Fucosylated lactosamines participate in adhesion of HIV-1 envelope glycoprotein to dendritic cells.

Carbohydrates expressed on HIV-1 gp160 are purported to bind to several receptor types that affect virus pathophysiology. Here, we define a potential role for fucosylated glycans involved in the adhesion of cells expressing anchored HIV-1 glycoprotein or HIV virions to human dendritic cells (DCs). We observe that a monoclonal antibody (FH6), with reactivity toward an extended dimeric form of a fucosyl lactosamine, binds to gp120 transfectants, blocking adhesion of these cells and virus particles to human DCs. We observe that serum antibodies induced by peptide mimetic of fucosylated carbohydrate core structures emulate the monoclonal antibody reactivity pattern, showing enhanced reactivity to HIV-1 envelope-expressing cell line and blocking the adhesion of these cells to human DCs. These results suggest a potential role for initial adherence of virally infected cells or virions mediated by fucosylated lactosamines expressed on the envelope protein. As these carbohydrates function as adhesion molecules associated with homing and dissemination processes, such interactions may contribute to the HIV infection process.

Peptide mimotopes as prototypic templates of broad-spectrum surrogates of carbohydrate antigens.

Peptide mimetics of carbohydrate antigens can function as templates to exploit immune mechanisms to augment vaccine design strategies as they are T cell dependent antigens. In this study we evaluate a peptide mimetic (peptide 105) of the Pneumococcal capsular polysaccharide type 14 (Pn14) as a model antigen to explore differences in antigenicity and immunogenicity of peptide mimotopes. The multiple antigenic peptide (MAP) form, by ELISA, competes with native Pn14 in a concentration-dependent manner for binding to an anti-Pn14 monoclonal antibody. It was observed that peptide priming with a conjugated form (105-BSA) and boosting with Pn14 produced higher levels of Pn14-reactive IgG1, IgG2a, IgG2b and IgG3 than priming and boosting with Pn14. This serum also displayed reactivity with multiple serotypes, as assessed by ELISA. However, when compared with serum from humans immunized with the 23-valent pneumococcal vaccines, mimetic-induced mouse serum did not display a significant ability to mediate opsonophagocytic killing of pneumococci. These results suggest the feasibility of designing mimotopes to render effective humoral responses not only to a single serotype of Streptococcus pneumoniae, but to multiple serotypes at once. Such peptides would simplify currently available vaccine approaches, yet highlights the requirement of more extensive polymerization to fully emulate native antigen.

Immunization with a carbohydrate mimicking peptide augments tumor-specific cellular responses.

The metastatic potential of some tumor cells is associated with the expression of the neolactoseries antigens sialyl-Lewis x (sLex) and sialyl-Lewis a (sLea) as they are ligands for selectins. We have recently shown that peptide mimetics of these antigens can potentiate IgG2a antibodies, which are associated with a Th1-type cellular response. As L-selectin is preferentially expressed on CD4+ Th1 and CD8+ T cell populations, specific induction of these phenotypes could augment a response to L-selectin ligand-expressing tumor cells. Here we demonstrate that immunization with a multiple antigen peptide (MAP) mimetic of sugar constituents of neolactoseries antigens induces a MHC-dependent peptide-specific cellular response that triggers IFN-gamma production upon peptide stimulation, correlating with IgG2a induction. Surprisingly, T lymphocytes from peptide-immunized animals were activated in vitro by sLex, also triggering IFN-gamma production in a MHC-dependent manner. Stimulation by peptide or carbohydrate resulted in loss of L-selectin on CD4+ T cells confirming a Th1 phenotype. We also observed an enhancement in cytotoxic T lymphocyte (CTL) activity in vitro against sLex-expressing Meth A cells using effector cells from Meth A-primed/peptide-boosted animals. CTL activity was inhibited by both anti-MHC class I and anti-L-selectin antibodies. These results further support a role for L-selectin in tumor rejection along with the engagement by the TCR for most likely processed tumor-associated glycopeptides, focusing on peptide mimetics as a means to induce carbohydrate reactive cellular responses.

Directing the immune response to carbohydrate antigens.

Peptide mimetics may substitute for carbohydrate antigens in vaccine design applications. At present, the structural and immunological aspects of antigenic mimicry, which translate into immunologic mimicry, as well as the functional correlates of each, are unknown. In contrast to screening peptide display libraries, we demonstrate the feasibility of a structure-assisted vaccine design approach to identify functional mimeotopes. By using concanavalin A (ConA), as a recognition template, peptide mimetics reactive with ConA were identified. Designed peptides were observed to compete with synthetic carbohydrate probes for ConA binding, as demonstrated by enzyme-linked immunosorbent assay and isothermal titration calorimetry (ITC) analysis. ITC measurements indicate that a multivalent form of one particular mimetic binds to ConA with similar affinity as does trimannoside. Splenocytes from mimeotope-immunized mice display a peptide-specific cellular response, confirming a T-cell-dependent nature for the mimetic. As ConA binds to the Envelope protein of the human immunodeficiency virus, type 1 (HIV-1), we observed that mimeotope-induced serum also binds to HIV-1-infected cells, as assessed by flow cytometry, and could neutralize T-cell line adapted HIV-1 isolates in vitro, albeit at low titers. These studies emphasize that mimicry is based more upon functional rather than structural determinants that regulate mimeotope-induced T-dependent antibody responses to polysaccharide and emphasize that rational approaches can be employed to develop further vaccine candidates.

Exploiting molecular mimicry to broaden the immune response to carbohydrate antigens for vaccine development.

Peptide mimetics of carbohydrates represent an alternative approach to induce anti-carbohydrate responses. Depending on their formulation, peptide mimetics can mediate T-independent or T-dependent responses. Multivalent peptide mimeotopes can induce high IgM/IgG ratios, as non-conjugated carbohydrates do. Here we observe that immunization with multivalent peptide mimeotope conjugated to BSA enhances carbohydrate reactive antibodies in Balb/c mice and xid mice, with IgG1 greater than IgG2a, in xid mice. These results suggest that mimeotope-conjugate formulations might augment carbohydrate-specific immune responses in immuno-compromised hosts.

Exploiting molecular mimicry: defining rules of the game.

Molecular mimicry has been touted as a mean to develop new generation of vaccines to target carbohydrate antigens on pathogens and on tumor cells. Structural and immunological rules governing molecular mimicry require definition for its successful exploitation. Of interest are the kinds of structures that peptides adopt as carbohydrate mimics, the extent to which topological or sequence similarities among peptide mimeotopes define serum cross-reactivity to carbohydrate antigens and the extent to which peptide mimeotopes affect T-cell responses. Rational design concepts can be applied to define how a peptide may mimic carbohydrate antigens, similarities in binding affinities of antibodies for carbohydrate and for peptides, how peptides can mimic core structures on otherwise dissimilar carbohydrate antigens, and how peptide mimeotopes can be used to manipulate cellular responses not achievable by carbohydrate antigens.

Immunological characterization of peptide mimetics of carbohydrate antigens in vaccine design strategies.

Targeting antigens which cannot be readily addressed by genetic vectors is a major challenge in vaccine design. The inter-conversion of carbohydrate antigens into peptide mimetic forms provides a means to broaden the immune response to carbohydrate antigens. Peptides that mimic carbohydrate antigens offer new possibilities to augment immune responses to such antigens that include inducing carbohydrate reactive T-cell responses. Peptide mimeotopes can be formulated in a variety of ways that include multiple antigen peptides (MAP) and as DNA vaccines that prime for different antibody isotypes. On the immunological side we observe that: (i) depending on the immunogen formulation peptide mimetics can be processed by either CD5+ or CD5-B cells; (ii) peptide mimeotope immunization can induce cross-reactive responses to multiple carbohydrate forms; (iii) priming with peptide mimeotopes can enhance carbohydrate immune responses upon boosting and (iv) immunization with peptide mimeotopes can induce carbohydrate reactive T cells.

A molecular basis for functional peptide mimicry of a carbohydrate antigen.

Peptides may substitute for carbohydrate antigens in carbohydrate-specific immunological reactions. Using the recognition properties of an anti-Lewis Y (LeY) antibody, BR55-2, as a model system, we establish a molecular perspective for peptide mimicry by comparing the three-dimensional basis of BR55-2 binding to LeY with the binding of the same antibody to peptides. The peptides compete with LeY, as demonstrated by enzyme-linked immunosorbent assay and Biacore analysis. The computer program LUDI was used to epitope map the antibody-combining site, correlating peptide reactivity patterns. This approach identified amino acids interacting with the same BR55-2 functional residue groups that recognize the Fucalpha(1-3) moiety of LeY. Molecular modeling indicates that the peptides adopt an extended turn conformation within the BR55-2 combining site, serving to overlap the peptides with the LeY spatial position. Peptide binding is associated with only minor changes in BR55-2, relative to the BR55-2-LeY complex. Anti-peptide serum distinguishes the Fucalpha(1-3) from the Fucalpha(1-4) linkage, therefore differentiating difucosylated neolactoseries antigens. These results further confirm that peptides and carbohydrates can bind to the same antibody-binding site and that peptides can structurally and functionally mimic salient features of carbohydrate epitopes.

Evidence that immunoglobulin specificities of AIDS-related lymphoma are not directed to HIV-related antigens.

Chronic B-cell stimulation may be a predisposing event in the early pathogenesis of the acquired immunodeficiency syndrome (AIDS)-related lymphoma (ARL). ARL-derived immunoglobulin (Ig) genes are significantly diversified from germline, suggesting that antigenic stimulation via Ig receptors may occur prior to malignant transformation. We have evaluated 6 ARL-derived antibodies for binding to human immunodeficiency virus (HIV) and cell surface epitopes. Five cases expressed IgM, and 1 case expressed IgG. Expressed V genes were significantly diversified (3%-15%) from known germline V genes. A non-Ig producing mouse myeloma cell line was transfected with expression vectors containing the lymphoma-derived V genes. By enzyme-linked immunosorbent assay and Western blot assay, the lymphoma-derived Ig's showed no reactivity against HIV recombinant proteins. Also, no specific HIV reactivity was observed by flow cytometry with lymphoma-derived Ig's against the T-cell line infected with T-tropic HIV-1 or peripheral blood mononuclear cells infected with M-tropic HIV strains, indicating lack of binding to native HIV epitopes. However, 2 of the lymphoma-derived Ig's (ARL-7 and ARL-14) bound strongly to non-HIV-infected cells of various tissue origins. Thus, these findings suggest that the transformed B cells of AIDS-associated lymphomas may not arise from the pool of anti-HIV specific B cells but, rather, may develop from B cells responding to other antigens, including self-antigens. (Blood. 2000;95:1393-1399)