A simple method for the radioactive iodination of CD4 molecules

Loss of N-terminal charged residues of mouse CD3 epsilon chains generates isoforms modulating antigen T cell receptor-mediated signals and T cell receptor-CD3 interactions

The antigen T cell receptor (TCR)-CD3 complexes present on the cell surface of CD4(+) T lymphocytes and T cell lines express CD3 epsilon chain isoforms with different isoelectric points (pI), with important structural and functional consequences. The pI values of the isoforms fit the predicted pI values of CD3 epsilon chains lacking one, two, and three negatively charged amino acid residues present in the N-terminal region. Different T cells have different ratios of CD3 epsilon chain isoforms. At a high pI, degraded CD3 epsilon isoforms can be better recognized by certain anti-CD3 monoclonal antibodies such as YCD3-1, the ability of which to bind to the TCR-CD3 complex is directly correlated with the pI of CD3 epsilon. The abundance of CD3 epsilon isoforms can be modified by treatment of T cells with the proteinase inhibitor phenanthroline. In addition, these CD3 epsilon isoforms have functional importance. This is shown, first, by the different structure of TCR-CD3 complexes in cells possessing different amounts of isoforms (as observed in surface biotinylation experiments), by their different antigen responses, and by the stronger interaction between low pI CD3 epsilon isoforms and the TCR. Second, incubation of cells with phenanthroline diminished the proportion of degraded high pI CD3 epsilon isoforms, but also the ability of the cells to deliver early TCR activation signals. Third, cells expressing mutant CD3 epsilon chains lacking N-terminal acid residues showed facilitated recognition by antibody YCD3-1 and enhanced TCR-mediated activation. Furthermore, the binding avidity of antibody YCD3-1 was different in distinct thymus populations. These results suggest that changes in CD3 epsilon N-terminal chains might help to fine-tune the response of the TCR to its ligands in distinct activation situations or in thymus selection.

Crry/p65, a membrane complement regulatory protein, has costimulatory properties on mouse T cells

It is known that certain type I membrane molecules (complement receptors type 1 and 2) belonging to the regulators of complement activation (RCA) family are involved in the regulation of B lymphocyte activation. In contrast, only GPI-anchored RCA molecules (CD55) have been described to be involved in T lymphocyte activation. In this study, we describe a novel function for the mouse RCA type I membrane protein Crry/p65 as a costimulatory molecule in CD4+ T cell activation. This is shown by increased anti-CD3-induced proliferation of CD4+ spleen T lymphocytes in the presence of the Crry/p65-specific mAb P3D2. Furthermore, Ab-induced coligation of Crry/p65 and CD3 favors IL-4 rather than IFN-gamma secretion in these cells. Crry/p65 signaling was also observed regardless of additional Ca2+, protein kinase C, or CD28-mediated costimuli. Analysis of intracellular intermediaries shows that Crry/p65-CD3 coligation enhances certain TCR/CD3-mediated signals, producing increased early tyrosine phosphorylation of many substrates and enhanced activation of the mitogen-activated protein kinase, extracellular signal-related kinase. These data fit well with the association of Crry/p65 with the tyrosine kinase Lck found in T cell lysates. The epitope recognized by the mAb P3D2 interferes with the protective role of Crry/p65 on C3 deposition. The relationship between protective function and costimulation by Crry/p65 is discussed. Our results support a multifunctional role for Crry/p65 in T cells and suggest new links between the natural and adaptive immune responses.

Construction and characterization of a radio-iodinatable mutant of recombinant human CD4

Recombinant soluble human CD4 (rsCD4) has been used in iodinated form to study the interaction of CD4 with its ligands. However, the utility of [125I]-rsCD4 is limited because rsCD4 is inefficiently iodinated and the iodinated protein is poorly active. The iodination properties of rsCD4 most likely reflect the poor accessibility of the tyrosine residues, apparent from the available X-ray structures. We have generated an iodinatable mutant of rsCD4 by substituting Tyr for Phe(179) in the flexible, solvent-exposed C-terminal region of rsCD4(183), a truncated form of CD4 that consists of the first 183 residues of CD4 and includes the binding sites for HIV-1 gp120 and MHC class II molecules. When F179Y rsCD4(183) is iodinated under trace-labeling conditions, the efficiency of 125I incorporation and the percentage of iodinated molecules that are active are much enhanced compared with WT rsCD4. Moreover, trace-labeled [125I]-F179Y rsCD4(183) has the same affinity for HIV-1 rgp120 as unlabeled WT rsCD4. The improved activity of trace-labeled [125I]-F179Y rsCD4(183) appears to be due to effective competition by Y179 for reactive iodine species that, in WT rsCD4, react with traces of denatured protein and/or with residues critical for activity or conformational integrity. The incorporation of accessible tyrosine residues may improve the iodinatibility of a protein both by introducing a readily iodinatable residue and by protecting sensitive proteins from adverse reactions.

Identification of a T lineage antigen in the catfish

A murine monoclonal antibody produced against catfish thymocytes and immunoglobulin-negative lymphocytes in the blood identified a catfish T cell antigen designated CfT1. The CfT1 antigen was found to be expressed on thymocytes, a subpopulation of the lymphoid cells in blood and other lympho-hemopoietic tissues, and a T cell line, but was not expressed by erythrocytes, thrombocytes, myeloid cells, B cells or macrophage cell lines. Stimulation of blood mononuclear cells with the T cell mitogen, concanavalin A, resulted in an increased frequency of CfT1+ cells. Conversely, lipopolysaccharide stimulation increased the number of IgM+ B cells and decreased the frequency of CfT1+ cells. The CfT1 antigen was defined as a single chain protein of M(r) 35,000 lacking N- and O-linked sugars. The CfT1 molecule thus provides a T lineage-specific marker in this bony fish representative.

Tyrosine phosphorylation of a human killer inhibitory receptor recruits protein tyrosine phosphatase 1C

Natural killer (NK) cells express killer inhibitory receptors that mediate negative regulation of NK cell cytotoxicity upon binding to MHC class I molecules on target cells. Unrelated inhibitory receptors on B cells have recently been shown to function through recruitment of phosphotyrosine phosphatase 1C (PTP-1C). Here, we show that a human killer inhibitory receptor specific for HLA-C also recruits PTP-1C after phosphorylation induced either by the pharmacological agent phenylarsine oxide or by conjugation with target cells. This recruitment is mediated by the binding of specific cytoplasmic phosphotyrosine-containing sequences to PTP-1C. These results implicate PTP-1C as a cytosolic component of the negative signaling pathway through NK cell inhibitory receptors.

Isoforms of the transmembrane tyrosine phosphatase CD45 differentially affect T cell recognition

Activation of T cells has been shown to require CD45. CD45 is expressed on T cells as distinct isoforms and these isoforms are expressed differentially on subsets of CD4 T cells. We have generated T cell lines expressing a T cell receptor (TCR) of known specificity, with or without CD4, and examined the effect of different CD45 isoforms on stimulation through the antigen receptor. We find that isoforms differ in their ability to participate in antigen recognition, with the null isoform that is predominantly found on memory CD4 T cells being the most effective. The ability of the CD4 T cells being the most effective. The ability of the CD45 ectodomain to differentially affect sensitivity to specific ligands represents a novel way of regulating the efficacy of signaling through a receptor without altering its specificity. It may play a crucial role both in immunological memory and during intrathymic maturation of T cells.

Epitope-specific differential modulations within the T-cell antigen receptor complex

The feeding of cloned helper T cells by irradiated spleen cells results in the modulation of T-cell antigen receptors (TCRs) as detected by FACS. When two groups of anti-TCR antibodies--anti-idiotypic and anti-V beta--are compared, time-dependent patterns of modulation of TCR are drastically different. Whereas up to 80% of the idiotypic determinants disappear within 2 days after stimulation, almost no change is observed for the determinants recognized by V beta-specific antibodies within the same period. Sequential immunoprecipitations clearly showed that anti-idiotypic and anti-V beta antibodies recognize the same population of TCR. Moreover, surface labelling followed by immunoprecipitation of TCR did not show rapid and drastic changes in the amount of specifically precipitated material. The modulation is not significantly affected by the addition of specific antigen, but is specific for the clone's MHC restriction element. Functionally, the modulation of TCR epitopes affects the ability of anti-TCR antibody but not of the MHC/antigen complex to stimulate T cells. We conclude that the observed modulation of fluorescence intensity in the TCR complex after MHC recognition (1) is epitope specific, (2) is independent of the presence of nominal antigen and (3) does not affect the efficiency of antigen-specific stimulation.

A monoclonal antibody which blocks infection with feline immunodeficiency virus identifies a possible non-CD4 receptor

Monoclonal antibody vpg15 detects a 24-kDa cell surface protein on feline cells permissive for infection with feline immunodeficiency virus (FIV). The antibody blocks infection of FIV-susceptible cells, and expression of the vpg15 marker is decreased in FIV-infected cells in vitro. These results suggest that the antibody may recognize an FIV receptor distinct from CD4.

Generation and characterization of monoclonal antibodies against rabbit CD4, CD5 and CD11a antigens

We describe in this report the production and characterization of monoclonal antibodies (mAb) to the rabbit homologues of CD4, CD5 and CD11a antigens, and their use for phenotypic analysis of rabbit lymphoid cell lines. All the mAbs were produced by immunizing mice with rabbit thymocytes. mAb KEN-4 apparently identified rabbit CD4, precipitated two bands of 42 and 50 kDa under reducing and non-reducing conditions and markedly inhibited allo-MLR. The distribution of antigen-positive cells were restricted to the thymus and classical T-dependent areas in peripheral lymphoid tissues. mAb KEN-5 apparently identified rabbit CD5, precipitated a single polypeptide of 67 kDa similar to other anti-CD5 mAb in the human and mouse. The use of this mAb revealed that CD5+ B cells were infrequent in this species. mAb KEN-11 apparently identified rabbit CD11a and precipitated a heterodimer of 150/95 kDa by selectively recognizing the 150 kDa moiety. It blocked cation-dependent aggregation of phorbol ester-induced rabbit Con A blasts and also allo-MLR in a similar manner to other anti-CD11a mAb in various animal species. Phenotypic examination of HTLV-1 transformed rabbit lymphoid cell lines using these mAb clearly indicated that most of them were CD4+, CD5+ and CD11a+, and hence derived from CD4+ T cells. These mAb will be useful tools for the study of the cellular immune system in the rabbit.

Biochemical evidence of the physical association of the majority of CD3 delta chains with the accessory/co-receptor molecules CD4 and CD8 on nonactivated T lymphocytes

The association of components of the CD3 complex with the accessory molecules CD4 and CD8 was studied by immunoprecipitation experiments followed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) analysis. Enhanced surface iodination was achieved by a water-soluble derivative of the Bolton-Hunter reagent. Using freshly isolated nonactivated splenic T cells, we find that antibodies to CD4 and to CD8 strongly co-precipitate a 28-30-kDa band identical in mobility to the delta chain of the CD3 complex. Components corresponding in mobility to the epsilon and gamma chains of the CD3 complex are also co-precipitated but to a much lesser extent. The identity of the co-precipitated 28-30-kDa material with the CD3 delta chain was ascertained by two-dimensional nonreducing/reducing SDS-PAGE, by two-dimensional non-equilibrium pH gradient electrophoresis/SDS-PAGE and by one-dimensional peptide mapping with three different proteases. The co-precipitated 28-30-kDa material was identical to the CD3 delta chain by all these criteria. Quantitative analyses by densitometric gel tracing revealed that the amounts of CD3 delta co-precipitated with anti-CD4 and anti-CD8 add up to those in anti-V beta precipitates and to an average of 90% of those in anti-CD3 epsilon precipitates. We conclude that the majority of CD3 delta chains are associated with the accessory/co-receptor molecules CD4 or CD8 on resting T cells, and that this association is independent of antigen-specific recognition by the T cell receptor.