Cutting edge: thymic selection and autoreactivity are regulated by multiple coreceptors involved in T cell activation.
(17/601)
Immune responses are shaped by several processes that promote responses to pathogens and hinder responses to self. One mechanism that contributes to this polarization in response is negative selection, in which thymocytes that can respond to self-peptide/MHC complexes are deleted from the T cell repertoire. I found here that several coreceptors known to contribute to mature T cell activation also participate in negative selection. Interestingly, these molecules appeared to act in a cooperative fashion. Blocking the contribution of these molecules in fetal thymus organ culture not only prevented negative selection in the CD4+ lineage, but also induced the appearance of autoreactive thymocytes. This is the first demonstration that blocking coreceptor interactions during thymic development can produce autoreactive T cells. The contribution of negative selection to the mature T cell repertoire and to autoimmunity is discussed in light of these results. (+info)
CD2 and CD3 associate independently with CD5 and differentially regulate signaling through CD5 in Jurkat T cells.
(18/601)
In T lymphocytes, the CD2 and CD5 glycoproteins are believed to be involved in the regulation of signals elicited by the TCR/CD3 complex. Here we show that CD2 and CD3 independently associate with CD5 in human PBMC and Jurkat cells. CD5 coprecipitates with CD2 in CD3-deficient cells and, conversely, coprecipitates with CD3 in cells devoid of CD2. In unstimulated CD2+ CD3+ Jurkat cells, CD5 associates equivalently with CD2 and CD3 and is as efficiently phosphorylated in CD2 as in CD3 immune complexes. However, upon activation the involvement of CD5 is the opposite in the CD2 and CD3 pathways. CD5 becomes rapidly tyrosine phosphorylated after CD3 stimulation, but is dephosphorylated upon CD2 cross-linking. These opposing effects correlate with the decrease in the activity of the SH2 domain-containing protein phosphatase 1 (SHP-1) following CD3 activation vs an enhanced activity of the phosphatase after CD2 triggering. The failure of CD5 to become phosphorylated on tyrosine residues in the CD2 pathway has no parallel with the lack of use of zeta-chains in CD2 signaling; contrasting with comparable levels of association of CD2 or CD3 with CD5, zeta associates with CD2 only residually and is nevertheless slightly phosphorylated after CD2 stimulation. The modulation of CD5 phosphorylation may thus represent a level of regulation controlled by CD2 in signal transduction mechanisms in human T lymphocytes. (+info)
Human hematopoietic stem/progenitor cells generate CD5+ B lymphoid cells in NOD/SCID mice.
(19/601)
The nonobese diabetic/severe combined immunodeficient (NOD/SCID) xenotransplantation model is increasingly utilized to study both human lymphohematopoietic stem/progenitor cells and committed cell types. Human B lymphoid cells develop and proliferate in this model. We found high numbers of CD19+CD5+ B lymphoid cells in the bone marrows and spleens of NOD/SCID mice transplanted with human CD34+ stem/progenitor cells. The CD5+ cells accounted for a particularly large percentage of the B lymphoid cells in the spleens of chimeras analyzed three months after transplantation. CD19+CD5+ cells from all the analyzed chimeras coexpressed HLA-DR, surface IgM, CD20, CD38, CD43, and CD45. However, CD19+CD5+ cells were negative for kappa light chain, CD10, CD11a, CD11b, CD15, CD21, CD22, CD23, CD25, CD34, CD35, CD44, CD62L, CD69, and CD71. Cell surface expression of the lambda light chain, surface IgD, CD9, and CD40 antigens was detected in some but not all chimeras. Thus, the CD19+CD5+ cell population detected in our study has the phenotype of previously described CD5+ B lymphoid cells in humans and other species. The origin and role of the B lymphoid cells which express CD5 cell surface glycoprotein are poorly understood. The malignant cells in B lymphoid chronic lymphocytic leukemia express CD5, and the numbers of CD5+ B lymphoid cells are elevated in several autoimmune conditions. The human-NOD/SCID chimera system may provide an in vivo model to investigate the maturation and development of this cryptic human CD5+ B lymphoid cell subpopulation. (+info)
Theileria annulata in CD5(+) macrophages and B1 B cells.
(20/601)
Theileria parasites infect and transform bovine leukocytes. We have analyzed laboratory-established Theileria sp.-infected leukocyte lines and observed that transformed macrophages express CD5. Low-level expression of CD5 by macrophages was further confirmed on three independent Theileria annulata clinical isolates from Tunisia. Interestingly, the fourth CD5(+) clinical isolate (MB2) was morphologically different, expressed surface immunoglobulin M (IgM) and BoLA class II, and had rearranged Ig light-chain genes. To demonstrate that MB2 did indeed contain CD5(+) B cells, individual clonal lines were obtained by limiting dilution, and CD5 expression and Ig gene rearrangement were confirmed. This suggests that in natural infections T. annulata can invade and transform CD5(+) B cells. (+info)
Negative regulation of CD4 lineage development and responses by CD5.
(21/601)
CD5 deficiency results in a hyper-responsive phenotype to Ag receptor stimulation. Here we show that the development and responses of CD4 lineage T cells are regulated by the function of CD5. Thymocytes expressing the I-Ad-restricted DO11.10 TCR undergo abnormal selection without CD5. In H-2d mice, the absence of CD5 causes deletion of double-positive thymocytes, but allows for efficient selection of cells expressing high levels of the DO11.10 clonotype. By contrast, there is enhanced negative selection against the DO11.10 clonotype in the presence of I-Ab. T cell hybridomas and DO11.10 T cells are more responsive to TCR stimulation in the absence of CD5. Such hypersensitivity can be eliminated by expression of wild-type CD5, but not by a form of CD5 that lacks the cytoplasmic tail. Finally, CD5 deficiency partially suppresses the block of CD4 lineage development in CD4-deficient mice. Taken together, the data support a general role for CD5 as a negative regulator of Ag receptor signaling in the development and immune responses of CD4 lineage T cells. (+info)
Association of a tetraspanin CD9 with CD5 on the T cell surface: role of particular transmembrane domains in the association.
(22/601)
CD9 is a member of the tetraspanin superfamily which is characterized by four transmembrane (TM) domains and associates with other surface molecules. This tetraspanin was recently found to be expressed on mature T cells. Here, we investigated which molecules associate with CD9 on T cells and which CD9 domains are required for the association. Immunoprecipitation of T cell lysates with anti-CD9 mAb followed by immunoblotting with mAb against various T cell molecules showed the association of CD9 with CD3, CD4, CD5, CD2, CD29 and CD44. Because association with CD5 was most prominent, we determined the role of CD9 TM or extracellular (EC) domains in the association with CD5. CD9 mutant genes lacking each domain were constructed and introduced into EL4 thymoma cells deficient in CD9 but expressing CD5. Among various types of stable EL4 transfectants, EL4 transfected with the mutant gene lacking TM domains (TM2/TM3) between two EC domains expressed a small amount of the relevant protein without showing association with CD5. CD9(-)CD5(-) monkey COS-7 cells transfected with this mutant gene and the CD5 gene expressed both transfected gene products, but the association of these was not detected. EL4 cells transfected with a CD9/CD81 chimera gene (the CD9 gene containing TM2/TM3 of CD81) expressed the chimeric protein on the cell surface and showed association with CD5. These results suggest an essential role of particular CD9 TM domains in the surface expression of the CD9 molecule as well as the association with CD5. (+info)
The pseudo-immunoreceptor tyrosine-based activation motif of CD5 mediates its inhibitory action on B-cell receptor signaling.
(23/601)
Genetic studies revealed that CD5 could be a negative regulator of the B-cell antigen receptor (BCR). We explore here the effect of human CD5 on BCR-triggered responses. B cells were obtained expressing a chimera composed of extracellular and transmembrane domains of Fcgamma type IIB receptor fused to CD5 cytoplasmic domain (CD5cyt). Coligation of the chimera with the BCR induces CD5cyt tyrosine phosphorylation. A rapid inhibition of BCR-induced calcium response is observed, as well as a partial but delayed inhibition of phospholipase Cgamma-1 phosphorylation. Activation of extracellular regulated kinase-2 is also severely impaired. Moreover, at the functional level, interleukin-2 production is abolished. Src homology 2 domain-bearing tyrosine phosphatase SHP-1 and Src homology 2 domain-bearing inositol 5'-phosphatase SHIP usually participate in negative regulation of the BCR. We show that they do not associate with the phosphorylated CD5 chimera. We finally demonstrate that the pseudo-immunoreceptor tyrosine based activation motif present in CD5cyt is involved because its deletion eliminates the inhibitory effect of the chimera, both at biochemical and functional levels. These results demonstrate the inhibitory role of CD5 pseudo-immunoreceptor tyrosine based activation motif tyrosine phosphorylation on BCR signaling. They further support the idea that CD5 uses mechanisms different from those already described to negatively regulate the BCR pathway. (+info)
Non-CD28 costimulatory molecules present in T cell rafts induce T cell costimulation by enhancing the association of TCR with rafts.
(24/601)
While CD28 functions as the major T cell costimulatory receptor, a number of other T cell molecules have also been described to induce T cell costimulation. Here, we investigated the mechanisms by which costimulatory molecules other than CD28 contribute to T cell activation. Non-CD28 costimulatory molecules such as CD5, CD9, CD2, and CD44 were present in the detergent-insoluble glycolipid-enriched (DIG) fraction/raft of the T cell surface, which is rich in TCR signaling molecules and generates a TCR signal upon recruitment of the TCR complex. Compared with CD3 ligation, coligation of CD3 and CD5 as an example of DIG-resident costimulatory molecules led to an enhanced association of CD3 and DIG. Such a DIG redistribution markedly up-regulated TCR signaling as observed by ZAP-70/LAT activation and Ca2+ influx. Disruption of DIG structure using an agent capable of altering cholesterol organization potently diminished Ca2+ mobilization induced by the coligation of CD3 and CD5. This was associated with the inhibition of the redistribution of DIG although the association of CD3 and CD5 was not affected. Thus, the DIG-resident costimulatory molecules exert their costimulatory effects by contributing to an enhanced association of TCR/CD3 and DIG. (+info)