J Quintáns

Monoclonal antibody GK1.5 recognizes a previously undescribed murine T cell surface molecule, designated L3T4, which migrates on SDS-PAGE under reducing conditions as a single band with an apparent m.w. of 52,000. L3T4 is expressed by approximately 80% of thymocytes and by approximately 20% of spleen cells. There appears to be poor correlation between expression of L3T4 by functional T cell clones and expression of Lyt-2, expression of the cytolytic phenotype, and class I MHC antigen reactivity. On the other hand, both a class II MHC antigen-reactive HTL clone and an Lyt-1- Mls-reactive HTL clone express L3T4. Analysis of the effect of mAb GK1.5 on PFC responses in adoptive transfer suggests that L3T4 is expressed by the helper/inducer subset of murine T cells. Expression of L3T4 by murine T cells, however, may correlate primarily with class II MHC antigen reactivity rather than with functional phenotype; mAb GK1.5 profoundly blocks antigen-specific cytolysis by the cloned class II MHC antigen-reactive CTL line A15-1.17. Antigen-specific cytolysis by A15-1.17 is blocked by mAb GK1.5 at a step before the lethal hit. Collectively, the flow cytometric, functional, and biochemical data indicate that L3T4 is similar to the human Leu-3/T4 molecule.

Cyclosporin A, FK-506, and rapamycin are immunosuppressants often used as pharmacological probes to study lymphocyte activation and physiological cell death (PCD). Because cyclosporin A and FK-506 are known to prevent PCD in T-cell hybridomas and thymocytes, we used these reagents, as well as rapamycin, to determine whether they alter the pathway leading to apoptosis in murine WEHI-231 cells following surface IgM cross-linking. We observed that the immunosuppressants themselves induced PCD in WEHI-231 cells, but only in sublines susceptible to anti-IgM-mediated apoptosis. PCD was preceded by growth arrest and characterized by the DNA fragmentation pattern typical of apoptosis. In B-cell lines resistant to anti-immunoglobulin- and immunosuppressant-induced PCD, cyclosporin A, FK-506, and rapamycin caused growth arrest. PCD was also induced by inhibitors of protein synthesis in WEHI-231 cells but not in the mature B-cell line BAL-17. Immunosuppressant-induced and protein synthesis inhibitor-induced PCD, but not growth arrest, could be prevented by the overexpression of bcl-xL, while transfection with bcl-2 did not affect PCD or cell cycle arrest. These results suggest that bcl-2 and bcl-xL may control partially independent systems to inhibit PCD in lymphoid cells and that PCD in B and T cells may be differentially regulated.

RESEARCH on the cause of autoimmune thyroid disease (AITD) has in the past focused on potentially unique and specific abnormalities that could provide a unitary explanation for these illnesses [Graves' disease (GD), Hashimoto's thyroiditis (HT), and primary thyroid failure]. Evolving knowledge of the human immune system and results of studies on thyroid autoimmunity have suggested to us for many years (1) that the cause of autoimmunity is instead multifactorial. We believe that some level of self-reactivity is a normal—indeed, necessary—aspect of immune function. The development of autoimmune disease involves genetic and environmental influences that amplify normal self-reactivity and which evolve over a lifetime. The course is not always unidirectional, since activation of autoregulatory responses can apparently reverse it. In this article we first provide an abbreviated summary of immune function and then review contemporary research on autoimmunity as related to the thyroid gland, including studies that begin to explain immune responses in molecular terms. Last, we offer a construction of AITD as a multifactorial process evolving through recognizable stages over years and attempt to integrate the experimental findings into this scheme.

Ionizing radiation mediates cell death, in part, through chromosomal damage following one or more cell divisions. X-rays also induce programmed cell death (apoptosis) in some cell types both in vitro and in vivo. Both neutral and acidic sphingomyelinases, which generate the lipid second messenger ceramide, are reported to induce apoptosis following ionizing radiation and other death signals such as tumor necrosis factor alpha and Fas ligand. Herein we report that a loss of ceramide production from a neutral sphingomyelinase generates a radioresistant phenotype as measured by a marked decrease in apoptosis. A WEHI-231 subline made deficient in ceramide production was found to be resistant to apoptosis compared with the parental subline following treatment with X-rays. The resistant subline underwent two to three subsequent cell divisions following X-irradiation, confirming that X-rays induce cell death through both mitotic and apoptotic mechanisms. These data suggest that loss of ceramide production following X-rays represents an extranuclear mechanism for the development of radioresistance. Modulation of extranuclear signals may increase tumor cell killing following radiation and represent new cellular targets for cancer therapy.