The B-cell transmembrane protein CD72 binds to and is an in vivo substrate of the protein tyrosine phosphatase SHP-1

BACKGROUND

Signals from the B-cell antigen receptor (BCR) help to determine B-cell fate, directing either proliferation, differentiation, or growth arrest/apoptosis. The protein tyrosine phosphatase SHP-1 is known to regulate the strength of BCR signaling. Although the B-cell co-receptor CD22 binds SHP-1, B cells in CD22-deficient mice are much less severely affected than those in SHP-1-deficient mice, suggesting that SHP-1 may also regulate B-cell signaling by affecting other signaling molecules. Moreover, direct substrates of SHP-1 have not been identified in any B-cell signaling pathway.

RESULTS

We identified the B-cell transmembrane protein CD72 as a new SHP-1 binding protein and as an in vivo substrate of SHP-1 in B cells. We also defined the binding sites for SHP-1 and the adaptor protein Grb2 on CD72. Tyrosine phosphorylation of CD72 correlated strongly with BCR-induced growth arrest/apoptosis in B-cell lines and in primary B cells. Preligation of CD72 attenuated BCR-induced growth arrest/death signals in immature and mature B cells or B-cell lines, whereas preligation of CD22 enhanced BCR-induced growth arrest/apoptosis.

CONCLUSIONS

We have identified CD72 as the first clear in vivo substrate of SHP-1 in B cells. Our results suggest that tyrosine-phosphorylated CD72 may transmit signals for BCR-induced apoptosis. By dephosphorylation CD72. SHP-1 may have a positive role in B-cell signaling. These results have potentially important implications for the involvement of CD72 and SHP-1 in B-cell development and autoimmunity.

Coexistence of Fabry's disease and systemic lupus erythematosus

This report describes a case of a female with systemic lupus erythematosus, who was subsequently diagnosed with Fabry's disease. Due to similarities in the organs involved by these two multisystem disorders, difficulties were encountered in establishing a prompt diagnosis of Fabry's disease. That and subsequent management of this patient are discussed. A literature review of the coexistence of the two disorders along with the potential pathogenic mechanisms explaining this association are explored.

Tolerance is overcome in beef insulin-transgenic mice by activation of low-affinity autoreactive T cells

To gain insight into the factors controlling the maintenance or loss of T cell self tolerance we produced beef insulin (BI)-transgenic BALB/c mice. Transgenic mice express BI under control of the human insulin promoter and secrete physiological amounts of beef insulin. Although these mice are tolerant to BI, as evidenced by the lack of insulin-specific IgG antibody production following intraperitoneal immunization, tolerance is not complete. Footpad immunization results in a weak antigen-specific T cell proliferative response, indicating the presence of self-reactive BI-specific T cell in the periphery. These T cells are functional in vivo, providing support for IgG1, IgG2a, and IgG2b BI-specific antibody production, but require higher higher concentrations of antigen than nontransgenic T cells (both in vivo and following recall responses in vitro) to become activated. In vitro, BI-specific T cell proliferation in BI-transgenic mice can be largely restored by addition of interleukin-2, indicating that a significant component of T cell tolerance is mediated by anergy. To characterize the autoreactive T cells that become activated when tolerance is broken, BI-specific T cell hybridomas were generated from transgenic mice and compared to a panel of hybridomas previously derived from nontransgenic BALB/c mice. The majority of BI-transgenic hybridomas recognized the immunodominant A1-14 beef insulin peptide but with lower avidity than BALB/c hybridomas. Consistent with this, none of the dominant T cell receptor rearrangements found in the BALB/c BI-specific T cell receptor repertoire were found in the transgenic hybridomas. These results indicate that, despite evidence for clonal inactivation of many BI-specific T cells in BI-transgenic mice, loss of tolerance results from activation of low-affinity antigen-specific T cells that appear to have escaped this process.

Both MHC and background gene heterozygosity alter T cell receptor repertoire selection in an antigen-specific response

Many autoimmune diseases are associated with specific class II MHC alleles; however, this association is not complete. One explanation for the variable expression of disease in susceptible individuals is that variability in the TCR repertoire may alter the potential to generate pathogenic autoreactive T cells. The current study was undertaken to examine the possibility that MHC and background heterozygosity, which is the norm in the outbred human population, alters the expressed TCR repertoire and, if so, whether this has an impact on peptide recognition and antigenic specificity. We, therefore, systematically analysed the beef insulin-specific TCR repertoire in inbred BALB/c mice before and after introduction of MHC heterozygosity (BALB/c x BALB.K)F1 mice, or MHC and background gene heterozygosity (BALB/c x A/J)F1 mice. We show that T cells from all three repertoires are predominantly Ad-restricted and recognize the same immunodominant peptide. Despite this, the beef insulin-specific TCR repertoires in F1 mice differ from those seen in BALB/c mice with the most dramatic changes seen in (BALB/c x A/J)F1 mice. These changes are accompanied by subtle differences in the antigenic specificity of the T cells. The results demonstrate that both MHC and background gene heterozygosity affect TCR repertoire selection, suggesting that the variable expression of autoimmune disease in individuals with a susceptible MHC allele may result, in part, from variability in the TCR repertoire introduced by this heterozygosity.

Clinical utility and specificity of anticardiolipin antibodies

Established solid phase assays for anticardiolipin antibodies (aCL) are often characterized by high levels of nonspecific binding. As a result, only very high levels of aCL have been reported to be associated with a variety of clinical conditions including systemic lupus erythematosus (SLE), recurrent intravascular thrombosis and unexplained recurrent fetal loss. We have developed an ELISA replacing direct evaporation of soluble cardiolipin with cardiolipin micelles in physiological saline as the antigen binding step in the assay. Levels of IgG aCL were detected in various sera at dilutions of 1/100 to 1/3200, showing improved assay sensitivity. Assay specificity was determined using double stranded DNA and ovalbumin as irrelevant binding antigens and no crossreactivity was found. The controversial use of Tween 20 in the assay was investigated and results showed it decreases nonspecific binding without interfering in antibody detection. This assay has enabled us to identify differences in the prevalence and level of aCL antibodies in sera from healthy nonpregnant controls (0/25 positive), healthy pregnant controls (5/47 positive for IgG and 8/47 positive for IgM) and from women with unexplained recurrent fetal loss (16/62 and 14/62 positive, respectively). We support the observation that aCL are not normally distributed, and therefore nonparametric methods of statistical analysis are necessary to determine population prevalence. We confirm that aCL IgM are a relatively nonspecific finding, and extreme caution must be used in basing any clinical decisions on the presence of this antibody alone.

Amino acid residues in the T cell receptor CDR3 determine the antigenic reactivity patterns of insulin-reactive hybridomas

We examined TCR gene usage in a panel of beef insulin/I-Ad-restricted T cell hybrids obtained from BALB/c mice. These hybrids demonstrated several distinct patterns of reactivity defined by their ability to respond to species variants of insulin. Correlation of TCR-alpha and -beta-gene usage with these patterns of reactivity demonstrated that TCR gene usage was restricted within Ag reactivity groups. In particular, V-J junctional regions (CDR3 equivalent) were restricted with conserved junctional amino acid motifs present in both TCR-alpha- and -beta-chains. Comparison of TCR gene usage in hybrids expressing identical V alpha and V beta gene segments but demonstrating different patterns of reactivity revealed that changes in either J alpha and/or J beta gene segment usage could alter antigenic reactivity. Indeed, single or limited amino acid differences within the CDR3 region were sufficient to markedly alter fine specificity. These data demonstrate the critical role for CDR3 in determining antigenic reactivity in beef insulin-reactive hybrids and are compatible with the current model of TCR/peptide/MHC interaction.

Amino acid residues in the T cell receptor CDR3 determine the antigenic reactivity patterns of insulin-reactive hybridomas

We examined TCR gene usage in a panel of beef insulin/I-Ad-restricted T cell hybrids obtained from BALB/c mice. These hybrids demonstrated several distinct patterns of reactivity defined by their ability to respond to species variants of insulin. Correlation of TCR-alpha and -beta-gene usage with these patterns of reactivity demonstrated that TCR gene usage was restricted within Ag reactivity groups. In particular, V-J junctional regions (CDR3 equivalent) were restricted with conserved junctional amino acid motifs present in both TCR-alpha- and -beta-chains. Comparison of TCR gene usage in hybrids expressing identical V alpha and V beta gene segments but demonstrating different patterns of reactivity revealed that changes in either J alpha and/or J beta gene segment usage could alter antigenic reactivity. Indeed, single or limited amino acid differences within the CDR3 region were sufficient to markedly alter fine specificity. These data demonstrate the critical role for CDR3 in determining antigenic reactivity in beef insulin-reactive hybrids and are compatible with the current model of TCR/peptide/MHC interaction.

Long-term expression of a T-cell receptor beta-chain gene in mice reconstituted with retrovirus-infected hematopoietic stem cells

To determine the feasibility of retrovirus-mediated gene transfer into stem cells for studying T-cell development, we constructed a high-titer retrovirus vector containing the neomycin phosphotransferase (neo) gene and a murine T-cell receptor (TCR) beta-chain gene with the V beta 6 variable segment. The TCR gene was placed under the control of the human beta-actin promoter and enhancer. Bone marrow cells pretreated with 5-fluorouracil were infected by coculturing with psi-2 virus-producing cells in the presence of recombinant interleukins 1, 2, 4, and 6 as well as interleukin 3 from WEHI-3 conditioned medium. The infected cells were transplanted into irradiated mice, and expression of the exogenous V beta 6 gene was examined with a V beta 6-specific monoclonal antibody, RNase protection, and polymerase chain reaction amplification. Three of seven mice expressed the retroviral TCR gene on the surface of a significant proportion of mature T cells 5-6 months after transplantation. In mice analyzed less than 1 month after transplantation, up to 30% of mature T cells expressed V beta 6 TCRs, an increase of at least 20% above the level of endogenous V beta 6 expression. DNA analysis revealed that pluripotent hematopoietic stem cells were infected by the retroviral vector in a long-term reconstituted mouse that showed increased V beta 6 expression.