Changing immunodominance patterns in antiviral CD8 T-cell responses after loss of epitope presentation or chronic antigenic stimulation.

The H-2(b)-restricted CD8 T-cell response against lymphocytic choriomeningitis virus is directed against at least 10 dominant and subdominant epitopes, including two newly identified epitopes in the nucleoprotein. We have used this set of epitopes to characterize the plasticity of the hierarchy under different experimental circumstances, i.e., loss of MHC class I molecules, loss of specific epitopes (CTL escape), and prolonged antigenic stimulation (chronic infection). We found that loss of epitope-specific responses was almost inevitably associated with compensatory responses against other, subdominant, epitopes. Multiple epitope loss was required to change the hierarchy. Persistent viral infection was associated with a loss of not only the dominant response against the NP396 epitope, but also a loss of subdominant responses against nucleoprotein epitopes. In contrast, responses against glycoprotein epitopes, dominant and subdominant, survived under chronic infection conditions, and even dominated the response (GP118). Our results suggest that the fate of each specific T-cell response during chronic infection is in part determined by the origin of the cognate epitopes, i.e, the proteins from which they are processed, or, more specifically, nucleoprotein versus glycoprotein. A model in which recruitment time plays a role in the longevity of antiviral T-cell responses during persistent infection is discussed.

Heterologous immunity provides a potent barrier to transplantation tolerance.

Many strategies have been proposed to induce tolerance to transplanted tissue in rodents; however, few if any have shown equal efficacy when tested in nonhuman primate transplant models. We hypothesized that a critical distinction between specific pathogen-free mice and nonhuman primates or human patients is their acquired immune history. Here, we show that a heterologous immune response--specifically, virally induced alloreactive memory--is a potent barrier to tolerance induction. A critical threshold of memory T cells is needed to promote rejection, and CD8(+) "central" memory T cells are primarily responsible. Finally, treatment with deoxyspergualin, an inhibitor of NF-kappa B translocation, together with costimulation blockade, synergistically impairs memory T cell activation and promotes antigen-specific tolerance of memory. These data offer a potential explanation for the difficulty encountered when inducing tolerance in nonhuman primates and human patients and provide insight into the signaling pathways essential for memory T cell activation and function.

Mitochondrial potential and reactive oxygen intermediates in antigen-specific CD8+ T cells during viral infection.

Following many viral infections, there are large expansions of Ag-specific CD8(+) T cells. After viral clearance, mechanisms exist to ensure that the vast majority of effector cells undergo apoptosis. In studies of thymocyte apoptosis, loss of mitochondrial potential (deltapsi(m)) and excess production of reactive oxygen intermediates have been implicated as key events in cellular apoptosis. The purpose of the experiments presented in this work was to determine these parameters in Ag-specific CD8(+) T cells during a physiological response such as viral infection. Using lymphocytic choriomeningitis virus infection of mice, we found that Ag-specific CD8(+) effector T cells that had undergone recent TCR stimulation had an increased deltapsi(m). These cells also had increased levels of superoxide. As these cells progressed through the contraction of the immune response, their potential decreased, but superoxide levels remained similar to naive cells. One of the consequences of reduced mitochondrial potential is membrane permeability and subsequent caspase activation. We examined both the enzymatic activity and levels of cleaved caspase 3, an effector caspase, and could only detect increased levels in Ag-specific CD8(+) T cells on day 5 postinfection, a time point in which virus was still present. This contrasts with Ag-specific effector cells examined during the contraction phase that had no detectable caspase activity directly ex vivo. These data suggest that the apoptotic program begins earlier than previously expected on day 5, during the expansion phase.

Differential sensitivity of naive and memory CD8+ T cells to apoptosis in vivo.

Apoptosis is a critical regulator of homeostasis in the immune system. In this study we demonstrate that memory CD8(+) T cells are more resistant to apoptosis than naive cells. After whole body irradiation of mice, both naive and memory CD8(+) T cells decreased in number, but the reduction in the number of naive cells was 8-fold greater than that in memory CD8(+) T cells. In addition to examining radiation-induced apoptosis, we analyzed the expansion and contraction of naive and memory CD8(+) T cells in vivo following exposure to Ag. We found that memory CD8(+) T cells not only responded more quickly than naive cells after viral infection, but that secondary effector cells generated from memory cells underwent much less contraction compared with primary effectors generated from naive cells (3- to 5-fold vs 10- to 20-fold decrease). Increased numbers of secondary memory cells were observed in both lymphoid and non-lymphoid tissues. When naive and memory cells were transferred into the same animal, secondary effectors underwent less contraction than primary effector cells. These experiments analyzing apoptosis of primary and secondary effectors in the same animal show unequivocally that decreased downsizing of the secondary response reflects an intrinsic property of the memory T cells and is not simply due to environmental effects. These findings have implications for designing prime/boost vaccine strategies and also for optimizing immunotherapeutic regimens for treatment of chronic infections.