Williams Wv

Restricted heterogeneity of T cell receptor transcripts in rheumatoid synovium.

RA is characterized by massive proliferation of synovial tissue, accompanying infiltration of the tissue with CD4+ T lymphocytes, and a genetic linkage to the MHC antigen HLA-DR4. Since T cells are restricted by class II MHC molecules such as DR4, this suggests a direct role for these CD4+ cells in pathogenesis. To investigate T cell receptor (TCR) usage in RA, we used oligonucleotide primers specific for each of the major alpha and beta TCR subfamilies to amplify cDNA derived from whole synovium or synovial tissue T cell lines in a family-specific manner. Detection of amplified DNA was facilitated by utilizing oligonucleotide probes derived from the constant regions of the TCRs. The TCR repertoire present in the synovial T cell lines was quite heterogeneous, with an average of 15 alpha chains and 15.8 beta chains detected. When synovial tissue was analyzed, the predominant TCR subfamilies detected tended to be more restricted, with an average of 4.6 alpha chains and 8.6 beta chains detected. This compared with an average of six alpha chains and 12 beta chains in nonrheumatoid synovial samples. The average percentage of synovia positive per TCR beta family was significantly lower for RA versus non-RA specimens (46.1 vs 65.6%, P = 0.034). These findings indicate that while a polyclonal population of T cells is present in RA synovium, the predominant patterns of TCR transcript expression may be somewhat more restricted, suggesting that TCR-based therapy of RA is possible.

Vertical transmission of human immunodeficiency virus (HIV) infection. Reactivity of maternal sera with glycoprotein 120 and 41 peptides from HIV type 1.

The observation that approximately 70% of HIV-infected pregnant women do not transmit infection vertically suggests that antibody therapy may be effective in the prevention of transmission of HIV infection from mother to child. Currently, there is an incomplete understanding of the processes involved in vertical transmission of HIV infection. The elucidation of the serological basis of maternal immunity as it relates to protection from vertical transmission is the goal of this study. We have screened 20 maternal sera from HIV+ individuals of known vertical transmission status for reactivity with 31 peptides spanning the entire envelope glycoprotein of HIV-1. Of interest was reactivity to regions outside of the V3 loop of gp120. The findings have been examined in relationship to transmission status, as well as to in vitro anti-HIV-1 biological activity. Our results indicate that lack of vertical transmission is correlated with high viral neutralization activity, but not with antisyncytial activity nor with binding to the V3 peptides examined in this study. Also, the transmission group bound to fewer gp41 peptides when compared with the nontransmission group, suggesting that immune responses to gp41 may be important in preventing transmission. These findings may provide insights into the design of passive immunotherapies.

Binding of type 3 reovirus by a domain of the sigma 1 protein important for hemagglutination leads to infection of murine erythroleukemia cells.

The recognition of cellular receptors by the mammalian reoviruses is an important determinant of cell and tissue tropism exhibited by reovirus strains of different serotypes. To extend our knowledge of the role of reovirus-receptor interactions in reovirus tropism, we determined whether type 1 and type 3 reovirus strains can infect cells derived from erythrocyte precursors. We found that reovirus type 3 Dearing (T3D), but not type 1 Lang, can grow in murine erythroleukemia (MEL) cells. This difference in growth was investigated by using reassortant viruses and we found that the capacity of T3D to infect MEL cells is determined by the viral cell-attachment protein, sigma 1. In experiments using murine monoclonal antibodies (mAbs) that bind to different sigma 1 regions, we show that T3D binding to MEL cells is inhibited by a mAb that identifies a domain important for hemagglutination (HA). We also determined that type 3 strains that can infect murine L cells but do not produce HA do not infect MEL cells. These results suggest that type 3 reovirus binds to and infects erythrocyte precursor cells via a sigma 1 domain important for HA. Moreover, this study suggests that different domains of some viral cell-attachment proteins are used to initiate productive infections of different types of cells.

Rational Design of Granulocyte-Macrophage Colony-stimulating Factor Antagonist Peptides

Granulocyte-macrophage colony-stimulating factor (GM-CSF) is a member of the four-helix bundle family of cytokines/growth factors which exhibit several activities. It is a hematopoietic growth factor, a cytokine involved in inflammatory and immune processes, an adjunct for cancer therapy, and an anti-tumor immunomodulator. Studies of interactions between GM-CSF and its receptor and identification of small peptides presenting binding capacity to the receptor are important goals for the development of GM-CSF analogs. Here we describe the study of two cyclic peptides, 1785 and 1786, developed based on structural analysis of the GM-CSF region mimicked by anti-anti-GM-CSF recombinant antibody 23.2. These peptides were designed to structurally mimic the positions of specific residues on the B and C helices of human GM-CSF implicated in receptor binding and bioactivity. Both 1785 and 1786 were specifically recognized by polyclonal anti-GM-CSF antibody (stronger for 1786 than 1785). 1786 also competitively inhibited binding of GM-CSF to the GM-CSF receptor on HL-60 cells and demonstrated antagonist bioactivity, as shown by its reversal of GM-CSFs ability to inhibit apoptosis of the GM-CSF-dependent cell line MO7E. These studies support the role of residues on the GM-CSF B and C helices in receptor binding and bioactivity and suggest strategies for mimicking binding sites on four-helix bundle proteins with cyclic peptides.

Vaccination Against Pathogenic Cells by DNA Inoculation

The goal of vaccination is to induce immunity to protect the host from disease. Vaccines should generate long-term protective immune responses which perform immune surveillance against specific antigens. Currently, a wide spectrum of vaccines are under development against not only infectious diseases, but also against cancers as well as allergic and autoimmune diseases. The mechanisms by which vaccines elicit protective immune responses against tumor growth have not been completely understood. Costimulatory molecule activation and strong cytolytic T cells (CTLs) have been implicated in the control of tumor cell growth or metastasis. Specific monoclonal antibodies have been also shown to control tumor cell growth to some degree. To achieve protective immune responses against tumor cells, we need to understand the context of the different cellular, humoral and molecular functions of the immune system.

Synthetic Cyclodextrin Derivatives Inhibit HIV Infection in vitro

The AIDS pandemic has stimulated the search for safe potent antiviral agents. To date, only AZT has been approved as a therapeutic agent for the treatment of HIV infection. It is likely that a large number of antiviral compounds would be necessary to control a life-long infection. We have utilized the rigid structure of the cyclodextrin molecule to determine the minimal components necessary for anti-HIV activity. Utilizing this targeted approach to drug design, we demonstrate the antiviral effects of candidate compounds from the family of cyclodextrins. We report that polysulfated cyclodextrins mediate significant anti-HIV effects which include blocking infectivity and syncytia formation mediated by the HIV viruses. Several other substituted forms of cyclodextrins did not mediate significant antiviral effects. Further results demonstrate that the polysulfated cyclodextrins mediated no specific antiviral effects against already infected human cells. These results demonstrate that the antiviral activities of this class of compounds are centered around early events in the viral life cycle. These in vitro results suggest that such molecules may be of importance in antiretroviral therapeutic regimes.

Synovial T Cell Receptor Heterogeneity in Early Arthritis

Rheumatoid arthritis (RA) has been postulated to result from a synovial immune response to an unidentified antigen(s), which should be mirrored by the T cell response. Here we investigate the T cell receptor (TCR) repertoire in the synovial tissue of patients with arthritis of early to moderate duration. We developed a nested polymerase chain reaction (PCR) technique to examine the TCR repertoire of small biopsy specimens, and show that the method is highly sensitive. We apply this technique to synovial biopsies obtained from the knee joints of patients with early to moderate duration arthritis (average duration of arthritis 1 year, range 0.02–2.75 years). We examined biopsies from 5 normal individuals, 32 RA patients, 7 patients with seronegative spondyloarthropathy (Sp), and 12 patients with undifferentiated arthritis (UA). TCR message was detectable in 4/5 normals, 15/32 RA, 5/7 Sp, and 8/11 UA biopsies, with sampling error likely accounting for most negative biopsies. The average numbers of TCR Vβs detected per TCR-positive biopsy were 5.0 ± 3.7 for normals, 12.7 ± 8.4 for RA, 18.0 ± 7.4 for Sp patients, and 14.4 ± 10.2 for UA. Examination of TCR messages by single-stranded conformational polymorphism analysis showed similar proportions of dominant clones in the normals compared with the patients with inflammatory arthritis. Sequence analysis was performed on 33 dominant clones from 16 patients. Sequence alignment of the third hypervariable regions showed some evidence of disease-specific sequence clustering for Sp, while some RA sequences showed similarity to previously described motifs. These data indicate greater TCR heterogeneity in early Sp and UA compared with normal synovium. Disease-specific TCR sequences may occur in early RA and Sp.

Immunological Characteristics of the Putative CD4-Binding Site of the HIV-1 Envelope Protein

As an extension of previous studies demonstrating the immunosuppressive properties of gp120, we have analyzed the immunological characteristics of gp120 peptides, derived principally from its putative CD4-binding site. Our studies indicate that peptides derived from this region do not stimulate proliferation of lymphocytes from HIV-seropositive donors with relatively normal numbers of CD4+ lymphocytes. No significant proliferation was observed in response to various concentrations of peptide, even in the presence of interleukin-2 (IL-2). Significant proliferation of these lymphocytes was observed in response to two recall antigens, cytomegalovirus (CMV) and tetanus toxoid (TT), and these responses were augmented by IL-2. Peripheral blood mononuclear cells from HIV-seronegative donors were cultured in the presence of TT and CMV and the peptides derived from gp120. Proliferation in the presence of these recall antigens was inhibited by these peptides in a dose-dependent manner. These studies demonstrate that at high concentrations, peptides from the putative CD4-binding site can inhibit proliferation of lymphocytes from normal donors in response to a recall antigen. The apparent immunosuppressive properties of this region highlight the pathogenic role played by HIV-1 envelope protein interactions with host cells.

Anti-idiotype Modeled Peptides with Biologic Activity

We have developed synthetic peptides modeled after the hypervariable region of an anti-idiotypic/anti-receptor antibody. These peptides exhibit biologic properties identical to those of the antibody, including inhibition of DNA synthesis.

Characterization of Immune Responses Elicited by an Experimental Facilitated-DNA Vaccine for Human Immunodeficiency Virus Type-1 (HIV-1)

Vaccination has proved to be among the most successful methods developed for protecting humans and domestic animals from infectious diseases. Vaccines operate by inducing immune responses in the host that limit and ultimately clear infections; they typically do not prevent infections from occurring. Vaccine efficacy is therefore, dependent on the induction of appropriate types of immune responses and on the establishment of immunological memory.