Faculty Bibliography

The CD2 glycoprotein has been implicated in both positive and negative regulation of T-cell mitogenesis. To study the involvement of CD2 in T-lymphocyte development and immune responses, we have analyzed two lines of CD2-null mice, each expressing a distinct class I major histocompatibility complex (MHC)-restricted T-cell receptor (TCR). In both situations, the absence of CD2 appeared to promote the positive selection of cells in a manner that is similar to that which occurs in the absence of CD5. Consistent with this, compound homozygotes that lacked both CD2 and CD5 showed evidence of enhanced positive selection even in the absence of a transgenic TCR. Despite the observed enhancement of positive selection, the lack of CD2 was associated with defects in proliferative responses and interferon-gamma production when transgenic thymocytes and mature T lymphocytes were stimulated with the appropriate antigens. These findings raise the possibility that impaired sensitivity to selecting ligands in the thymus may provide a selective advantage that improves the efficiency of positive selection for certain TCRs. Furthermore, the results highlight the potential for a differential role for CD2 in thymocyte selection and T-cell immune responses

Studies of human T-cell leukemia virus type 1 (HTLV-1) have been hampered by the difficulty of achieving high cell-free and cell-associated infectious titers. Current retroviral pseudotyping systems using the HTLV-1 envelope generate titers of less than 200 infectious particles per ml. We describe here an improved system for pseudotyping using a defective human immunodeficiency virus (HIV) type 1 genome in combination with HTLV-1 env in 293T producer cells. Introduction of additional copies of rev and treatment of cells with sodium butyrate resulted in a cell-associated titer of 10(5)/ml and cell-free titers of greater than 10(4)/ml . By using this system, we found that the host range of HTLV-1 is even greater than previously suspected. Earlier studies which assigned a chromosomal location for the HTLV-1 receptor may therefore reflect cell-to-cell variation in receptor number rather than the absolute presence or absence of a receptor. The generation of higher-titer HIV(HTLV-1) may facilitate identification of the cellular receptor and investigations of the pathophysiology of HTLV-1 infection

Entry of HIV-1 into target cells requires cell-surface CD4 and additional host cell cofactors. A cofactor required for infection with virus adapted for growth in transformed T-cell lines was recently identified and named fusin. However, fusin does not promote entry of macrophage-tropic viruses, which are believed to be the key pathogenic strains in vivo. The principal cofactor for entry mediated by the envelope glycoproteins of primary macrophage-tropic strains of HIV-1 is CC-CKR-5, a receptor for the beta-chemokines RANTES, MIP-1alpha and MIP-1beta

OBJECTIVE: To study HIV envelope glycoprotein (Env)-mediated entry using a sensitive fusion assay. DESIGN AND METHODS: CD4+ lymphocytes or T-cell lines were labelled with fluorescent cytoplasm or membrane markers. Fusion with Env-expressing adherent cells was monitored by observing dye transfer from CD4+ cells to Env cells. RESULTS: Cell-cell fusion began 20-30 min after co-cultivation at 37 degrees C. Pre-binding at 4 degrees C was observed not to decrease the lag phase before fusion. Cells expressing envelope glycoproteins from non-syncytium-inducing (NSI) HIV strains showed dye transfer between two cells without progression to syncytia. A glycosylphosphatidylinositol anchored Env was found to be incapable of mediating membrane fusion, as measured either by lipid or cytoplasm contents mixing. Primary mouse cells expressing human CD4 and mouse 3T3 cells stably expressing both human CD4 and human CD26 did not support fusion with our Env-expressing cells. CONCLUSIONS: Env-mediated cell-cell fusion is a relatively slow process, probably reflecting a multi-step process occurring after CD4 binding and requiring the transmembrane domain of gp41. Env proteins are able to mediate cell-cell fusion at least under some experimental conditions, indicating that lack of a syncytia phenotype does not rule out the possibility of fusion occurring between only two or a few cells

The T cell receptor (TCR) recognizes antigenic peptide presented by major histocompatibility complex (MHC) molecules. Analogs of antigenic peptides have been shown to inhibit antigen-specific T cell responses, a phenomenon described as TCR antagonism. We have examined the effect of a natural variant of an antigenic peptide and a synthetic peptide analog, on the responses of mature T cells and immature thymocytes from an alpha-beta TCR-transgenic mouse (F5), the TCR of which recognizes a nonamer peptide from the nucleoprotein (NP) of influenza virus in the context of the H-2Db MHC molecule. Both peptides were shown to antagonize specifically the T cells cytolytic response without being able directly to stimulate mature T cells from these transgenic mice. Furthermore, a negative selection assay in vitro was used to demonstrate for the first time that antagonistic peptides are capable of antagonizing thymocyte deletion induced by antigenic peptides. These data suggest that the final selection of a T cell could be the result of a balance between the positive and negative influences of endogenous peptide ligands

The data reviewed in this chapter suggest that the primary developmental function of the CD4 and CD8 coreceptors is to improve the efficacy by which a thymocyte recognizes peptide/MHC. During positive selection, DP thymocytes down-regulate expression of either CD4 or CD8 in response to signals that originate from the TCR/coreceptor complex. Experiments with transgenic and MHC-null mice have shown that coreceptor down-regulation and lineage commitment can occur stochastically in a manner that is independent of TCR specificity for MHC. Nevertheless, the positive selection of a given thymocyte is contingent on sustained expression of the coreceptor that is appropriate for the MHC specificity of its TCR. In most cases, loss of the required coreceptor blocks developmental progression and results in thymocyte apoptosis. CD4 expression is controlled by both positive and negative regulatory sequences embedded in the CD4 gene and it is likely that similar sequences regulate the CD8 gene. The down-regulation of coreceptor expression is coupled to a functional commitment which ensures that mature CD4+ T cells have a helper phenotype and CD8+ T cells have a cytotoxic phenotype. The molecular basis for this coupling and the identity of the switching mechanism which governs coreceptor regulation remain to be determined

CD4 assists in T cell recognition of peptides bound to MHC class II molecules by binding to a non-polymorphic region on class II and stabilizing TCR recognition of the peptide-class II complex. Overexpression of CD4 in transgenic mice expressing a class II-restricted TCR resulted in a dramatic loss of thymocytes that became evident soon after the TCR and CD4 were co-expressed. Both the thymus and lymph nodes of the double-transgenic mice had reduced numbers of CD4 lineage T cells. A large proportion of the remaining CD4 lineage T cells lost either the transgenic TCR alpha or beta chains. The double-transgenic mice continued to generate thymocytes and T cells that expressed the transgenic TCR, but these cells did not express endogenous CD4. Overexpression of CD4 thus severely disrupts the normal developmental pathway of these thymocytes, supporting a model in which avidity of the TCR complex for self class II molecules determines the outcome of thymocyte development