Physiological T-cell death: susceptibility is modulated by activation, aging, and transformation, but the mechanism is constant.

It is not surprising that the recent explosion of interest in physiological cell death has been centered particularly on lymphocytes. Physiological cell death responses are singularly important in the biology of T lymphocytes, especially in the establishment and maintenance of a diverse, non-autoreactive, and self-limiting repertoire. Cell death responses can be triggered in T cells by a variety of stimuli; sensitivity to these inducers is altered as a function of differentiation, activation, aging, and transformation. The elimination of autoreactive T cells occurs by a process that involves comitogenic stimulation at high dose with antigenic and/or mitogenic agents. The control of susceptibility to this activation-driven cell death with differentiation and with prior activation provides a mechanistic explanation for the development of central and peripheral tolerance. Enhanced lymphocyte activation with aging also leads to an augmented activation-driven cell death response. However, aging does not alter cell death responses generally, and aging-associated changes in cell death responses cannot account for aging-associated immunopathology. Oncogenic transformation also alters the activation-driven cell death response by supplanting one of the required signals for activation-driven cell death. This difference provides a rationale for selective anti-tumor therapy. A single mechanism underlies all cases of physiological cell death and involves out-of-phase mitotic activity. We now know that of the two hallmarks of cell death, genome digestion is dispensable and mitotic-like events associated with cell cycle arrest are critical. T cells triggered to undergo physiological cell death arrest in a post-mitotic compartment of the cell cycle and die when they attempt a precocious and abortive mitosis.

Target cell death triggered by cytotoxic T lymphocytes: a target cell mutant distinguishes passive pore formation and active cell suicide mechanisms.

The role of the target cell in its own death mediated by cytotoxic T lymphocytes (CTL) has been controversial. The ability of the pore-forming granule components of CTL to induce target cell death directly has been taken to suggest an essentially passive role for the target. This view of CTL-mediated killing ascribes to the target the single role of providing an antigenic stimulus to the CTL; this signal results in the vectoral degranulation and secretion of pore-forming elements onto the target. On the other hand, by a number of criteria, target cell death triggered by CTL appears fundamentally different from death resulting from membrane damage and osmotic lysis. CTL-triggered target cell death involves primary internal lesions of the target cell that reflect a physiological cell death process. Orderly nuclear disintegration, including lamin phosphorylation and solubilization, chromatin condensation, and genome digestion, are among the earliest events, preceding the loss of plasma membrane integrity. We have tested directly the involvement of the target cell in its own death by examining whether we could isolate mutants of target cells that have retained the ability to be recognized by and provide an antigenic stimulus to CTL while having lost the capacity to respond by dying. Here, we describe one such mutant, BW87. We have used this CTL-resistant mutant to analyze the mechanisms of CTL-triggered target cell death under a variety of conditions. The identification of a mutable target cell element essential for the cell death response to CTL provides genetic evidence that target cell death reflects an active cell suicide process similar to other physiological cell deaths.

Susceptibility to cell death is a dominant phenotype: triggering of activation-driven T-cell death independent of the T-cell antigen receptor complex.

The failure of Thy-1 and Ly-6 to trigger interleukin-2 production in the absence of surface T-cell antigen receptor complex (TCR) expression has been interpreted to suggest that functional signalling via these phosphatidylinositol-linked alternative activation molecules is dependent on the TCR. We find, in contrast, that stimulation of T cells via Thy-1 or Ly-6 in the absence of TCR expression does trigger a biological response, the cell suicide process of activation-driven cell death. Activation-driven cell death is a process of physiological cell death that likely represents the mechanism of negative selection of T cells. The absence of the TCR further reveals that signalling leading to activation-driven cell death and to lymphokine production are distinct and dissociable. In turn, the ability of alternative activation molecules to function in the absence of the TCR raises another issue: why immature T cells, thymomas, and hybrids fail to undergo activation-driven cell death in response to stimulation via Thy-1 and Ly-6. One possibility is that these activation molecules on immature T cells are defective. Alternatively, susceptibility to activation-driven cell death may be developmentally regulated by TCR-independent factors. We have explored these possibilities with somatic cell hybrids between mature and immature T cells, in which Thy-1 and Ly-6 are contributed exclusively by the immature partner. The hybrid cells exhibit sensitivity to activation-driven cell death triggered via Thy-1 and Ly-6. Thus, the Thy-1 and Ly-6 molecules of the immature T cells can function in a permissive environment. Moreover, with regard to susceptibility to Thy-1 and Ly-6 molecules of the immature T cells can function in a permissive environment. Moreover, with regard to susceptibility to Thy-1 and Ly-6 triggering, the mature phenotype of sensitivity to cell death is genetically dominant.