T cell apoptosis and reactive oxygen species

T cells respond to antigen stimulation through a process of activation, division, and differentiation to generate a large pool of activated effector T cells. Regulated induction of apoptosis of these expanded T cells avoids several problems for the host, including increased metabolic cost, disruption of lymphoid homeostasis, and predisposition to autoimmunity and lymphoid neoplasia. On the other hand, it is essential that some activated T cells survive apoptotic death to become memory T cells. Thus, an understanding of why most expanded T cells die, while some survive, will shed light on how autoimmunity and lymphoid cancer are prevented, and how immunity is acquired. Recent studies have identified the molecular details of this apoptotic process that operate in vivo. It is now becoming clear that two separate pathways — activation-induced cell death (AICD) and activated T cell–autonomous death (ACAD) — control the fate of antigen-specific T cells. Interestingly, reactive oxygen species (ROS) can control both pathways through reciprocal modulation of the main effector molecules FasL and Bcl-2. This review will focus on the role played by ROS in the determination of activated T cell fate.

The kinetics of T cell responses in vivo

The endogenous T cell response to many different antigens follows a remarkably similar pattern. Following antigen administration, T cells proliferate vigorously and reach a peak of expansion (Figure 1). This peak does not have a predetermined upper limit, since it can be further increased by certain adjuvants (i.e., LPS or stimulating antibodies to OX40, CD40, or 4-1BB) or by manipulation of the antigen dose. However, the number of activated T cells at this stage cannot, of course, exceed the capacity of the animal to support them. It is thought that few antigen-specific T cells die during the expansion phase, because of the obvious impairment of expansion that this would cause, although little has been done to explore this possibility. After the T cells reach their peak of expansion, their numbers begin to decline rather rapidly, a process that has been referred to as contraction (1). Recent reports have shown that during this decline, some of the T cells appear to migrate to nonlymphoid tissues and to reside there as effector memory T cells (2, 3). However, the numbers of T cells that migrate to nonlymphoid tissues cannot account for the total number of cells that exist at the peak of the response, and most of the activated cells disappear because they apoptose (4). Recent research has uncovered two separate pathways responsible for the death of activated, antigen-specific T cells in vivo. One of these pathways, AICD, is driven by signals delivered exogenously to the cell. The other pathway, ACAD, is driven by signals that are intrinsic to the activated T cell.

Figure 1

Graph of the kinetics of the T cell response to antigenic stimulation in vivo. Following stimulation with antigen, antigen-specific T cells proliferate vigorously to reach peak numbers during the expansion phase. They then decline in number rapidly, a process referred to as the contraction phase. Importantly, both the peak-expansion phase and the contraction phase can be independently modulated by stimulators of innate immunity (adjuvants) (53, 54).

Activation increases the levels of ROS in T cells: ROS may play a role in activated T cell death

Activation increases the amount of ROS in T cells (5–7), although it is unclear how these extra ROS are created. T cells lack the conventional NADPH oxidase enzymes used by granulocytes for oxidative bursts. However, other mechanisms for producing ROS have been described and might occur in T cells. One such mechanism could be driven by the increased demands for ATP production imposed on T cells by their conversion from a resting condition to the state of rapid cell division that accompanies activation. This is exemplified by experiments in which thymocytes are stimulated with phorbol myristate acetate and ionomycin, leading to rapid glucose consumption followed by increased oxidative phosphorylation and a subsequent increase in ROS production (8). This production of ROS probably occurs as a consequence of direct interaction of electrons shed from the respiratory chain with molecular oxygen, resulting in the formation of superoxide (9). Increased demands on mitochondrial electron transport for energy can therefore lead to the increased levels of superoxide within cells. For T cells this is evidenced by increased alkalinization of the cell cytosol (which is indicative of increased respiratory activity) rather than increased acidification (which would be evidence of increased glycolytic activity) (10). Thus, mitochondria can be a major source of ROS within cells, and increased energy demands, such as those seen with rapid T cell proliferation, can increase levels of mitochondrially derived ROS.

One group has reported that ROS levels increase within 15 minutes of T cell activation, a time that is too short for production of ROS via increased mitochondrial activity (6). Thus, it may be that reactions that are more immediate than increased mitochondrial activity are responsible for at least the initial increases in ROS levels in activated T cells. A well-known pathway for certain receptors to induce ROS involves Ras/Rac/PI3K signaling to activate NADPH oxidase enzymes. However, as mentioned previously, because T cells do not express these enzymes, it is unlikely that this pathway plays a role.

Another putative source of ROS might be peroxisomal enzymes; however, no studies of the role peroxisomes play in the generation of ROS in T cells have been reported. Interestingly, agonists of PPARγ cause significant apoptosis of activated T cells (11), and although the authors of this study did not examine ROS generation by this agonist, a recent report has shown that agonists of PPARγ can induce rapid superoxide generation in myoblast cells (12).

Some have suggested that bystander neutrophils might be the source of the increased ROS levels in activated T cells. In this instance, it is postulated that activated neutrophils produce the ROS and that these ROS then diffuse into neighboring T cells (13). However, under most circumstances the ROS are produced by the T cells themselves (5–7).

Regardless of their origin, the detoxification of these ROS by antioxidant enzymes can influence their levels as well. For example, superoxide dismutases (SODs) convert two superoxide molecules into one oxygen and one hydrogen peroxide (H₂O₂) molecule (9). In turn, H₂O₂ is detoxified by glutathione peroxidase and/or catalase (9). While SOD converts superoxide into another toxic ROS, H₂O₂, it is important to note that the reaction of superoxide with iron- and sulfur-containing proteins such as aconitase produces H₂O₂ as well (14). Furthermore, dismutation of superoxide radicals by SOD produces half the amount of H₂O₂ produced by direct interaction of superoxide with oxidizable molecules such as aconitase and prevents the release of damaging iron (14, 15). In addition, the levels and/or activities of glutathione peroxidase and/or catalase are critical, because interactions of H₂O₂ with transition metals can lead to the highly reactive hydroxyl radical via Fenton or Haber-Weiss chemistry (9). Thus, the outcome of ROS damage is ultimately dependent upon the levels and type of ROS made, both of which are dependent upon the levels and activities of endogenous antioxidant enzymes. Unfortunately, little work has been done to examine the activities of the endogenous antioxidant enzymes before and during T cell activation in vivo. One report has shown that T cells are deficient in both their ability to synthesize and their ability to take up glutathione precursors, possibly causing decreases in glutathione peroxidase activity (16). Clearly, much more work needs to be done to determine the relationship between T cell activation and activities of endogenous antioxidant enzymes.

Despite the fact that very little is known about the molecular events that lead to ROS production and ROS detoxification within T cells, several studies have shown that activated T cells can be killed by these entities (6, 7). We demonstrated that T cells that have been activated in vivo and isolated just before they would have started to die in the animal, die very rapidly in culture. This rapid death is markedly slowed by addition of a synthetic, catalytic manganese superoxide dismutase mimetic, manganese (III) tetrakis 5, 10, 15, 20 benzoic acid porphyrin (MnTBAP) (7). Results of this nature have led to interest in the roles that ROS might pay in the various pathways of T cell death, as discussed below.

AICD

Ashwell and colleagues made the initial observation that, instead of causing proliferation, T cell receptor (TCR) stimulation of T cell hybridomas resulted in decreased growth and a block in the cell cycle (17). Green’s group further investigated this phenomenon and showed that anti-CD3–treated T cell hybridomas and thymocytes underwent significant apoptosis, a process they referred to as AICD (18). Since these initial in vitro observations, the molecular details of AICD have been worked out. It is generally well accepted that AICD is mediated predominantly by signaling through the death receptor Fas and, in certain instances, by signaling through TNF-α receptors. Mice with functional defects in either Fas or FasL (lpr and gld, respectively) were used to determine whether AICD plays a role in termination of T cell responses in vivo. A few reports showed that T cell responses were prolonged in lpr or gld mice, leading many in the field to believe that Fas signaling is required for the death of all activated T cells in vivo (19, 20).

Molecular control of AICD

In vitro activation of T cells results in increased expression of FasL, which, upon binding to and oligomerization of Fas, results in the direct activation of caspase enzymes via their recruitment to a death-inducing signaling complex (DISC) (reviewed in ref. 20). Once these upstream caspases are activated in the DISC, the apoptotic program is initiated, and downstream caspases and other endogenous substrates are then proteolytically cleaved, resulting in the demise of the cell by classical apoptosis.

In theory, T cell death caused by AICD could be controlled in several ways: by control of Fas expression, by control over the pathways downstream of Fas engagement that lead to cell death, or by control of FasL expression. While Fas can be upregulated following T cell activation, T cells express significant amounts of Fas to begin with, so expression of this molecule is probably not a controlling factor (21).

Modulation of Fas signaling after engagement by FasL is mainly achieved by the expression of an enzymatically inert homologue of caspase-8 called FLIP (22). Resting primary T cells express high levels of FLIP, are resistant to AICD, and require downregulation of FLIP by IL-2 to acquire sensitivity to Fas-driven death (23). cFLIP transcription has been reported to be induced by MEK1, though it is unclear whether this is the mechanism by which resting T cells maintain high levels of FLIP (24). Alternatively, TGF-β may be involved, since it is known to induce FLIP, and since TGF-β–deficient mice and T cells from these mice display increased sensitivity to Fas-driven AICD (25, 26). In any case, levels of FLIP probably affect induction of AICD in cells, but a role for ROS in FLIP expression is currently not suspected.

Control of FasL expression by ROS

Along with FLIP expression, FasL expression is the major means by which AICD is controlled. Engagement of the TCR increases FasL expression on T cells (27). A fairly coherent pathway can be proposed to account for such induction, although all the pieces of the pathway have not been fully established in T cells. TCR engagement leads to increased Ca²⁺ levels in the cytoplasm of the cell. This may occur via two routes; one is well known and involves phospholipase Cγ, production of inositol 1,4,5-trisphosphate, and release of Ca²⁺ from intracellular stores (28). The other route may involve TCR-induced production of ROS through increased mitochondrial activity consequent to T cell activation. ROS, in turn, increase cytoplasmic Ca²⁺ levels via pathways that are not fully understood (29).

Increased levels of intracellular Ca²⁺ activate the phosphatase calcineurin. Once activated, calcineurin dephosphorylates nuclear factor of activated T cells (NFAT) (Figure 2). Dephosphorylated NFAT translocates to the nucleus and mediates gene transcription. While active NFAT sites have been mapped within the FasL promoter, optimal NFAT-mediated regulation of FasL now appears to occur through NFAT-driven upregulation of the early growth response transcription factors Egr2 and/or Egr3 (30).

Figure 2

Control of AICD by ROS. T cell activation via TCRs leads to rapid generation of both superoxide and H₂O₂. TCR activation also leads to FasL induction. This occurs because TCR activation raises intracellular Ca²⁺ levels, thus activating the phosphatase calcineurin. Calcineurin dephosphorylates NFAT, and the now activated NFAT can migrate to the nucleus and contribute to FasL transcription directly via the NFAT-binding sites upstream of the gene. NFAT can also stimulate FasL transcription indirectly, by increasing transcription of the genes for the early growth response proteins Egr2 and Egr3, which in turn can themselves induce transcription of FasL. Another pathway that may be involved in FasL induction by ROS may involve signaling through NF-κB, via activation of IκB by H₂O₂. NFATp, phosphorylated NFAT.

Support for the idea that ROS are intermediates in the induction of FasL after TCR engagement stems from two reports that the induction is inhibited by antioxidants (6, 31). One group showed that, in addition to antioxidants, inhibitors of mitochondrial function also blocked TCR-induced FasL mRNA induction, suggesting a possible role for mitochondrially derived ROS (31). They also showed that, in the absence of TCR stimulation, exogenously added H₂O₂ could induce FasL mRNA and that this was modestly inhibited by a dominant negative version of IκBα. Their results suggest that, at least for Jurkat cells, H₂O₂ activation of NF-κB may be responsible for FasL mRNA induction. Another group more closely assessed the nature of the ROS produced very early after TCR stimulation (6). They found that both superoxide and H₂O₂ were produced following TCR stimulation but suggested that superoxide and not H₂O₂ was responsible for upregulation of FasL after TCR stimulation. However, this study is confounded by the fact that the authors used electroporation as a means of introducing plasmids that encode antioxidant cDNAs into T cells, and that this process not only kills cells but also induces large amounts of ROS (32). The results of these studies point to the possibility that FasL upregulation is controlled by ROS; however, this effect is likely to be cell type–specific, since we have observed that antioxidants do not prevent FasL-driven death of DO11.10 T cell hybridomas following anti-CD3 stimulation (data not shown). Thus, while the aforementioned studies point to a possible role for ROS in controlling the induction of FasL after TCR stimulation, it will be of interest to determine where these ROS mediate their effects in the physiologic regulation of FasL following normal TCR activation of primary T cells.

ACAD and the role of Bcl-2–related proteins

While Fas signaling contributes to the death of some activated T cells, it certainly does not control the death of all, or even most, activated T cells in vivo, since several reports have shown that activated T cells die almost equally well in the presence or absence of Fas signaling (7, 19, 33, 34).

The Fas- and TNF-α–independent pathway for T cell death has been referred to as passive cell death or death by neglect, implying that it is mediated by cytokine or antigen withdrawal. However, we prefer to use the term ACAD (35), because the former terms are inadequate in describing what now appears to be a programmed and regulated event. This is illustrated by experiments from numerous groups (for example, refs. 1, 36) that show that T cell contraction occurs prior to antigen depletion, and suggest that contraction of the T cell response is a preprogrammed event set in place very early after TCR stimulation in vivo, not simply the consequence of the lack of a stimulus.

Several experiments suggest that ACAD is controlled by various members of the Bcl-2 family of proteins. This family consists of pro- and antiapoptotic members that control the fate of cells by protection or destruction of mitochondria (37). Three main classes of Bcl-2–related proteins exist. Class 1 Bcl-2–like proteins are antiapoptotic and contain Bcl-2 homology (BH) domains 1–4. Class 2 proteins are proapoptotic and Bax-like and contain BH domains 1–3. Class 3 proteins are included in a large family of proapoptotic BH3-only proteins that are expressed in a relatively tissue-specific manner. These BH3-only proteins contain a short stretch of 9 amino acids termed the BH3 domain but do not contain other regions of homology with Bcl-2. The Bcl-2–like proteins function partly by interacting physically with one another. How this interaction specifically results in induction of or protection from apoptosis is still only vaguely understood. However, Thompson, and their colleagues have shown that the class 3 proteins require a class 2 protein (either Bax or Bak) to execute their apoptotic signals, at least in higher vertebrates (38).

Regardless of how these molecules interact, their induction of apoptosis involves the release of cytochrome c and other apoptogenic factors from mitochondria (37, 39). Besides the depolarization and inactivation of the mitochondria by Bcl-2–like proteins, the factors released by these damaged mitochondria can activate caspases in the cytosol as well as directly damage DNA in a caspase-independent manner. While T cells express several different kinds of Bcl-2–like molecules, the role they play in T cell apoptosis has only recently been investigated.

Bcl-2 itself certainly plays a role in ACAD. ACAD is inhibited by increased expression of the antiapoptotic protein Bcl-2 in T cells, a property that distinguishes it from the Fas-driven AICD pathway (19, 40). More physiologically, levels of Bcl-2 mRNA and protein drop as activated T cells approach the stage at which they will die (33, 41). This fall in Bcl-2 is common to all the activated cells. The few activated T cells that are destined to survive also contain low levels of Bcl-2, suggesting that the signal that prevents death of surviving, memory cells acts via a pathway that does not involve Bcl-2. The idea that the decrease in Bcl-2 contributes to ACAD is supported by experiments in which Bcl-2 levels are increased in activated T cells via retroviral transduction, an event that prevents T cell apoptosis both in vitro and in vivo (33, 42).

Bcl-2 is not the only member of the family that affects ACAD. Recent publications have shown that the death of activated T cells in vivo and in vitro and, to a certain extent, the death of thymocytes requires expression within the cell of the proapoptotic BH3-only protein Bim (33, 43). Levels of Bim protein are similar in resting and activated T cells; however, Bim drives rapid death only in the latter (33). Although the state of Bim might change between resting and activated cells, perhaps via changes in its phosphorylation state, its ability to drive activated T cell death is certainly not controlled by the amount of Bim protein expressed. Therefore, it is likely that the changes in levels of the Bim antagonist Bcl-2 are important, and an understanding of the molecular mechanisms that control these changes are of critical importance to our understanding of ACAD.

ROS and Bcl-2 expression

As mentioned earlier, apoptosis of activated T cells can be inhibited by culture with the antioxidant MnTBAP, indicating that ROS are somehow involved in ACAD (7). To find out whether the ROS caused T cell death by affecting gene transcription, we activated T cells in vivo, isolated the cells just before they were to die, and cultured them for a short time in the presence or absence of MnTBAP. mRNA was then isolated from the cells and its content compared using Affymetrix gene chips (Affymetrix Inc., Santa Clara, California, USA). The expression of many genes was changed by the presence of MnTBAP (data not shown). Interestingly, while expression of mRNA for Fas, FasL, and many of the proapoptotic Bcl-2 family members was unchanged, expression of the mRNA for Bcl-2 itself was markedly increased by MnTBAP treatment (data not shown). These data strongly suggest that ROS can drive Bcl-2 downregulation within activated T cells.

The transcription factor cAMP response element–binding protein (CREB) is a potential target of these ROS, since ROS can decrease CREB function in other cell types (44) and CREB controls Bcl-2 levels in lymphoid cells (45) (Figure 3). In fact, a recent report has shown that, in neuronal cells, hypoxia (which can decrease ROS) can induce Bcl-2, and that the cAMP response element is required for this inducibility (46). We are currently testing the possibility that ROS inactivation of CREB occurs in activated T cells and is responsible for the observed decrease in Bcl-2.

Figure 3

Control of ACAD by ROS. TCR activation leads to increased mitochondrial production of superoxide that is converted to H₂O₂ either via reactions with endogenous substrates (not shown) or via manganese superoxide dismutase (MnSOD). These ROS may have effects on various transcription factors, such as CREB, that may play a role in the downregulation of Bcl-2 and in subsequent sensitivity of T cells to the effects of ACAD.

CREB may not be the only intermediate between ROS and loss of Bcl-2 mRNA. ROS affect the activity of NF-κB, and NF-κB has been reported to increase mRNA levels of both Bcl-2 and its antiapoptotic relative Bcl-x_L (47). However, the reported effects of ROS on NF-κB activity are confusing and contradictory. For example, ROS induce NF-κB activity by increasing degradation of IκB and consequently facilitating migration of NF-κB to the nucleus (48). On the other hand, ROS cause oxidation of a crucial cysteine residue at the DNA-binding site of NF-κB, thereby inhibiting the action of the transcription factor (49). Whether ROS activate or inhibit NF-κB activity is perhaps controlled by the amount and/or cellular location of the ROS.

Taken together, our results suggest a two-step model of ACAD. Signal one is provided by ROS-driven Bcl-2 downregulation and is necessary, but not sufficient, for apoptosis. Evidence supporting this comes from the demonstration that activated T cells from Bim-deficient mice still have decreased levels of Bcl-2 but do not die in vivo (33). Also, restoration of Bcl-2 levels via retrovirus can inhibit Bim-mediated apoptosis (33). Signal two, therefore, is provided by Bim. Since the levels of Bim do not change following T cell activation in vivo, factors underlying ROS-driven Bcl-2 downregulation are of considerable interest.

Other targets of ROS that might affect ACAD

A huge number of papers have addressed the problem of which molecules are targets of the stress induced in cells by ROS. Besides the effects on Bcl-2 levels mentioned above, ROS may affect many other molecules potentially involved in ACAD. For example, ROS certainly oxidize membrane lipids, and these molecules, either in the cell or in mitochondrial membranes, could affect the ability of the cell to resist death. However, in preliminary experiments conducted in association with the laboratory of Robert Murphy, we have not found changes in lipid oxidation when comparing the membranes of resting, long-lived T cells with those of activated T cells that are destined to die rapidly. Thus, it appears that the amount of ROS produced by T cells after activation is too small to mediate such lipid peroxidation and membrane destruction (data not shown).

ROS also act on proteins within the cell. Among these are many transcription factors. Loss of CREB and NF-κB activity might reduce transcription of genes important to cell survival, in addition to those for Bcl-2 and Bcl-x_L, discussed above. Other targets of ROS, such as inhibitor-of-apoptosis proteins, SODs, and A1, may also be important. Changes in the activities of other transcription factors, including AP-1, nuclear factor 1, Sp1, and various members of the forkhead and Stat families, may also be crucial (50, 51).

ROS also affect signal-transducing proteins. As discussed above, a number of groups have shown that PI3K and proteins downstream of the enzyme, such as Akt/protein kinase B, are activated in cells treated with H₂O₂ or inducers of ROS. In the chicken pre-B cell line DT40, externally applied H₂O₂ increases intracellular Ca²⁺ levels via a pathway that includes Syk, Btk, the B cell linker protein BLNK, and phospholipase Cγ2 (52). Evidence suggests that Syk and/or Btk are the most upstream enzymes in this pathway. However, it is not known whether these proteins are the actual targets of chemical modification by H₂O₂. Obviously the downstream products, increased Ca²⁺ levels, and PI3K/Akt activation have many affects on lymphocytes, including, in the case of increased Ca²⁺, induction of FasL and increased sensitivity to AICD. Since Akt is often thought to act as a prosurvival rather than a death-inducing enzyme, it is not obvious how this portion of the ROS/PI3K pathway could contribute to the death of activated T cells, unless the effects of Akt are outweighed by increased levels of Ca²⁺ in some undetermined way.

Other signal transduction proteins affected by ROS include the extracellular signal–regulated kinases (ERKs) 1 and 2, and although ROS-induced activation of ERK2 is thought to be required for cell cycle progression (5), ROSmay also affect Bcl-2 expression, as a cell cycle–inhibitory effect of Bcl-2 has been described (12).

Summary

Thousands of studies of ROS and their effects on cells have been reported. Therefore it is not surprising that these powerful biological mediators play a role in the phenomena associated with T cell activation and death. Even though activated T cells can die in two different ways, driven by external stimuli via AICD or by processes that are intrinsic to the cell via ACAD, evidence suggests that ROS are involved in both pathways. Although much of the signaling mediated by ROS in T cells remains unclear, the abundance of data on ROS signaling in nonlymphoid cell types should aid in the elucidation of ROS-driven signaling within T cells. Furthermore, since ROS are so crucial in determining the fates of activated T cells, an understanding of how ROS achieve their effects may suggest therapeutic targets for the destruction of autoimmune T cells, and for the improvement of substandard vaccines — the twin goals of modern applied immunology.

Note added in proof.

Reusch and colleagues recently showed that ROSspecifically downregulated CREB-dependent Bcl-2 promoter activity in primary neurons. (Pugazhenthi, S. et al. 2003. Oxidative stress-mediated down-regulation of Bcl-2 promoter in hippocampal neurons. J. Neurochem. In press.)

Acknowledgments

This work was supported by US Public Health Service grants AI-17134, AI-18785, AI-22295, and AI-52225.

Footnotes

Conflict of interest: The authors have declared that no conflict of interest exists.

Nonstandard abbreviations used: activation-induced cell death (AICD); activated T cell autonomous death (ACAD); reactive oxygen species (ROS); superoxide dismutase (SOD); manganese (III) tetrakis 5, 10, 15, 20 benzoic acid porphyrin (MnTBAP); T cell receptor (TCR); nuclear factor of activated T cells (NFAT); Bcl-2 homology (BH); cAMP response element–binding protein (CREB).

References

1. Badovinac, VP, Porter, BB, Harty, JT. Programmed contraction of CD8(+) T cells after infection. Nat. Immunol. 2002. 3:619-626.
   View this article via: PubMed Google Scholar
2. Masopust, D, Vezys, V, Marzo, AL, Lefrancois, L. Preferential localization of effector memory cells in nonlymphoid tissue. Science. 2001. 291:2413-2417.
   View this article via: PubMed CrossRef Google Scholar
3. Reinhardt, RL, Khoruts, A, Merica, R, Zell, T, Jenkins, MK. Visualizing the generation of memory CD4 T cells in the whole body. Nature. 2001. 410:101-105.
   View this article via: PubMed CrossRef Google Scholar
4. Kawabi, Y, Ochi, A. Programmed cell death and extrathymic reduction of Vbeta8+ CD4+ T cells in mice tolerant to Staphylococcus aureus enterotoxin B. Nature. 1991. 349:245-248.
   View this article via: PubMed CrossRef Google Scholar
5. Goldstone, SD, Hunt, NH. Redox regulation of the mitogen-activated protein kinase pathway during lymphocyte activation. Biochim. Biophys. Acta. 1997. 1355:353-360.
   View this article via: PubMed Google Scholar
6. Devadas, S, Zaritskaya, L, Rhee, SG, Oberley, L, Williams, MS. Discrete generation of superoxide and hydrogen peroxide by T cell receptor stimulation: selective regulation of mitogen-activated protein kinase activation and fas ligand expression. J. Exp. Med. 2002. 195:59-70.
   View this article via: PubMed CrossRef Google Scholar
7. Hildeman, DA, et al. Reactive oxygen species regulate activation-induced T cell apoptosis. Immunity. 1999. 10:735-744.
   View this article via: PubMed CrossRef Google Scholar
8. Aulwurm, UR, Brand, KA. Increased formation of reactive oxygen species due to glucose depletion in primary cultures of rat thymocytes inhibits proliferation. Eur. J. Biochem. 2000. 267:5693-5698.
   View this article via: PubMed CrossRef Google Scholar
9. Halliwell, B., and Gutteridge, J.M.C. 1985. Free radicals in biology and medicine. Oxford University Press. Oxford, United Kingdom. 189 pp.
10. Gerson, DF, Kiefer, H, Eufe, W. Intracellular pH of mitogen-stimulated lymphocytes. Science. 1982. 216:1009-1010.
    View this article via: PubMed CrossRef Google Scholar
11. Harris, SG, Phipps, RP. The nuclear receptor PPAR gamma is expressed by mouse T lymphocytes and PPAR gamma agonists induce apoptosis. Eur. J. Immunol. 2001. 31:1098-1105.
    View this article via: PubMed CrossRef Google Scholar
12. Huang, WC, Chio, CC, Chi, KH, Wu, HM, Lin, WW. Superoxide anion-dependent Raf/MEK/ERK activation by peroxisome proliferator activated receptor gamma agonists 15-deoxy-delta(12, 14)-prostaglandin J(2), ciglitazone, and GW1929. Exp. Cell Res. 2002. 277:192-200.
    View this article via: PubMed CrossRef Google Scholar
13. Cauley, LS, Miller, EE, Yen, M, Swain, SL. Superantigen-induced CD4 T cell tolerance mediated by myeloid cells and IFN-gamma. J. Immunol. 2000. 165:6056-6066.
    View this article via: PubMed Google Scholar
14. Gardner, PR. Superoxide-driven aconitase Fe-S recycling. Biosci. Rep. 1997. 17:33-42.
    View this article via: PubMed CrossRef Google Scholar
15. Gardner, R, Salvador, A, Moradas-Ferreira, P. Why does SOD overexpression sometimes enhance, sometimes decrease, hydrogen peroxide production? A minimalist explanation. Free Radic. Biol. Med. 2002. 32:1351-1357.
    View this article via: PubMed CrossRef Google Scholar
16. Droge, W, Eck, HP, Gmunder, H, Mihm, S. Modulation of lymphocyte functions and immune responses by cysteine and cysteine derivatives. Am. J. Med. 1991. 91(Suppl. 3C):140S-144S.
    View this article via: PubMed Google Scholar
17. Ashwell, JD, Cunningham, RE, Noguchi, PD, Hernandez, D. Cell growth cycle block of T cell hybridomas upon activation with antigen. J. Exp. Med. 1987. 165:173-194.
    View this article via: PubMed CrossRef Google Scholar
18. Shi, YF, Sahai, BM, Green, DR. Cyclosporin A inhibits activation-induced cell death in T-cell hybridomas and thymocytes. Nature. 1989. 339:625-626.
    View this article via: PubMed CrossRef Google Scholar
19. Van Parijs, L, Peterson, DA, Abbas, AK. The Fas/Fas ligand pathway and Bcl-2 regulate T cell responses to model self and foreign antigens. Immunity. 1998. 8:265-274.
    View this article via: PubMed CrossRef Google Scholar
20. Peter, ME, Krammer, PH. Mechanisms of CD95 (APO-1/Fas)-mediated apoptosis. Curr. Opin. Immunol. 1998. 10:545-551.
    View this article via: PubMed CrossRef Google Scholar
21. Tucek-Szabo, CL, Andjelic, S, Lacy, E, Elkon, KB, Nikolic-Zugic, J. Surface T cell Fas receptor/CD95 regulation, in vivo activation, and apoptosis. Activation-induced death can occur without Fas receptor. J. Immunol. 1996. 156:192-200.
    View this article via: PubMed Google Scholar
22. Tschopp, J, Irmler, M, Thome, M. Inhibition of fas death signals by FLIPs. Curr. Opin. Immunol. 1998. 10:552-558.
    View this article via: PubMed CrossRef Google Scholar
23. Refaeli, Y, Van Parijs, L, London, CA, Tschopp, J, Abbas, AK. Biochemical mechanisms of IL-2-regulated Fas-mediated T cell apoptosis. Immunity. 1998. 8:615-623.
    View this article via: PubMed CrossRef Google Scholar
24. Yeh, JH, Hsu, SC, Han, SH, Lai, MZ. Mitogen-activated protein kinase kinase antagonized fas-associated death domain protein-mediated apoptosis by induced FLICE-inhibitory protein expression. J. Exp. Med. 1998. 188:1795-1802.
    View this article via: PubMed CrossRef Google Scholar
25. Chen, W, et al. Requirement for transforming growth factor beta1 in controlling T cell apoptosis. J. Exp. Med. 2001. 194:439-453.
    View this article via: PubMed CrossRef Google Scholar
26. Schlapbach, R, et al. TGF-beta induces the expression of the FLICE-inhibitory protein and inhibits Fas-mediated apoptosis of microglia. Eur. J. Immunol. 2000. 30:3680-3688.
    View this article via: PubMed CrossRef Google Scholar
27. Ramsdell, F, et al. Differential ability of Th1 and Th2 T cells to express Fas ligand and to undergo activation-induced cell death. Int. Immunol. 1994. 6:1545-1553.
    View this article via: PubMed CrossRef Google Scholar
28. Williamson, JR. Role of inositol lipid breakdown in the generation of intracellular signals. State of the art lecture. Hypertension. 1986. 8:II140-II156.
    View this article via: PubMed Google Scholar
29. Schieven, GL, et al. ZAP-70 tyrosine kinase, CD45, and T cell receptor involvement in UV- and H2O2-induced T cell signal transduction. J. Biol. Chem. 1994. 269:20718-20726.
    View this article via: PubMed Google Scholar
30. Rengarajan, J, et al. Sequential involvement of NFAT and Egr transcription factors in FasL regulation. Immunity. 2000. 12:293-300.
    View this article via: PubMed CrossRef Google Scholar
31. Bauer, MK, et al. Role of reactive oxygen intermediates in activation-induced CD95 (APO-1/Fas) ligand expression. J. Biol. Chem. 1998. 273:8048-8055.
    View this article via: PubMed CrossRef Google Scholar
32. Maccarone, M, Rosato, N, Agro, AF. Electroporation enhances cell membrane peroxidation and luminescence. Biochem. Biophys. Res. Commun. 1995. 206:238-245.
    View this article via: PubMed CrossRef Google Scholar
33. Hildeman, DA, et al. Activated T cell death in vivo mediated by pro-apoptotic Bcl-2 family member Bim. Immunity. 2002. 16:759-767.
    View this article via: PubMed CrossRef Google Scholar
34. Gonzalo, JA, et al. A single injection of Staphylococcus aureus enterotoxin B reduces autoimmunity in MRL/lpr mice. Clin. Immunol. Immunopathol. 1994. 71:176-182.
    View this article via: PubMed CrossRef Google Scholar
35. Hildeman, DA, Zhu, Y, Mitchell, T, Kappler, J, Marrack, P. Molecular mechanisms of activated T cell death in vivo. Curr. Opin. Immunol. 2002. 14:354-359.
    View this article via: PubMed CrossRef Google Scholar
36. Zajac, AJ, et al. Viral immune evasion due to persistence of activated T cells without effector function. J. Exp. Med. 1998. 188:2205-2213.
    View this article via: PubMed CrossRef Google Scholar
37. Newton, K, Strasser, A. The Bcl-2 family and cell death regulation. Curr. Opin. Genet. Dev. 1998. 8:68-75.
    View this article via: PubMed CrossRef Google Scholar
38. Zong, WX, Lindsten, T, Ross, AJ, MacGregor, GR, Thompson, CB. BH3-only proteins that bind pro-survival Bcl-2 family members fail to induce apoptosis in the absence of Bax and Bak. Genes Dev. 2001. 15:1481-1486.
    View this article via: PubMed CrossRef Google Scholar
39. Martinou, JC, Green, DR. Breaking the mitochondrial barrier. Nat. Rev. Mol. Cell Biol. 2001. 2:63-67.
    View this article via: PubMed CrossRef Google Scholar
40. Strasser, A, Harris, AW, Huang, DC, Krammer, PH, Cory, S. Bcl-2 and Fas/APO-1 regulate distinct pathways to lymphocyte apoptosis. EMBO J. 1995. 14:6136-6147.
    View this article via: PubMed Google Scholar
41. Akbar, AN, et al. The significance of low bcl-2 expression by CD45O T cells in normal individuals and patients with acute viral infections. The role of apoptosis in T cell memory. J. Exp. Med. 1993. 178:427-438.
    View this article via: PubMed CrossRef Google Scholar
42. Mitchell, TC, et al. Immunological adjuvants promote activated T cell survival via induction of Bcl-3. Nat. Immunol. 2001. 2:397-402.
    View this article via: PubMed Google Scholar
43. Bouillet, P, et al. BH3-only Bcl-2 family member Bim is required for apoptosis of autoreactive thymocytes. Nature. 2002. 415:922-926.
    View this article via: PubMed CrossRef Google Scholar
44. Watson, PA, Nesterova, A, Burant, CF, Klemm, DJ, Reusch, JE. Diabetes-related changes in cAMP response element-binding protein content enhance smooth muscle cell proliferation and migration. J. Biol. Chem. 2001. 276:46142-46150.
    View this article via: PubMed CrossRef Google Scholar
45. Wilson, BE, Mochon, E, Boxer, LM. Induction of bcl-2 expression by phosphorylated CREB proteins during B-cell activation and rescue from apoptosis. Mol. Cell. Biol. 1996. 16:5546-5556.
    View this article via: PubMed Google Scholar
46. Freeland, K, Boxer, LM, Latchman, DS. The cyclic AMP response element in the Bcl-2 promoter confers inducibility by hypoxia in neuronal cells. Brain Res. Mol. Brain Res. 2001. 92:98-106.
    View this article via: PubMed CrossRef Google Scholar
47. Bureau, F, et al. Constitutive nuclear factor-kappaB activity preserves homeostasis of quiescent mature lymphocytes and granulocytes by controlling the expression of distinct Bcl-2 family proteins. Blood. 2002. 99:3683-3691.
    View this article via: PubMed CrossRef Google Scholar
48. Majumdar, S, Lamothe, B, Aggarwal, BB. Thalidomide suppresses NF-kappa B activation induced by TNF and H2O2, but not that activated by ceramide, lipopolysaccharides, or phorbol ester. J. Immunol. 2002. 168:2644-2651.
    View this article via: PubMed Google Scholar
49. Ginis, I, et al. Tumor necrosis factor and reactive oxygen species cooperative cytotoxicity is mediated via inhibition of NF-kappaB. Mol. Med. 2000. 6:1028-1041.
    View this article via: PubMed Google Scholar
50. Hirota, K, et al. AP-1 transcriptional activity is regulated by a direct association between thioredoxin and Ref-1. Proc. Natl. Acad. Sci. U. S. A. 1997. 94:3633-3638.
    View this article via: PubMed CrossRef Google Scholar
51. Waris, G, Huh, KW, Siddiqui, A. Mitochondrially associated hepatitis B virus X protein constitutively activates transcription factors STAT-3 and NF-kappa B via oxidative stress. Mol. Cell. Biol. 2001. 21:7721-7730.
    View this article via: PubMed CrossRef Google Scholar
52. Qin, S, Chock, PB. Bruton’s tyrosine kinase is essential for hydrogen peroxide-induced calcium signaling. Biochemistry. 2001. 40:8085-8091.
    View this article via: PubMed CrossRef Google Scholar
53. Maxwell, JR, Weinberg, A, Prell, RA, Vella, AT. Danger and OX40 receptor signaling synergize to enhance memory T cell survival by inhibiting peripheral deletion. J. Immunol. 2000. 164:107-112.
    View this article via: PubMed Google Scholar
54. Mitchell, T, Kappler, J, Marrack, P. Bystander virus infection prolongs activated T cell survival. J. Immunol. 1999. 162:4527-4535.
    View this article via: PubMed Google Scholar