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Nuclear Factor-B Regulates ß-Cell Death

A Critical Role for A20 in ß-Cell Protection

¹ Arthritis and Inflammation Program, Garvan Institute for Medical Research, Darlinghurst, New South Wales, Australia
² Biology and Chemistry Section, CombiMatrix Corporation, Mukilteo, Washington

Address correspondence and reprint requests to Dr. Shane T Grey,Gene Therapy & Autoimmunity Group, Arthritis and Inflammation Program, Garvan Institute of Medical Research, 384 Victoria Street, Darlinghurst, NSW 2010 Australia. E-mail: s.grey{at}garvan.org.au

Abbreviations: FACS, fluorescence-activated cell sorter; FADD, Fas-associated death domain; FADD-DN, FADD dominant negative inhibitor; ß-gal, ß-galactosidase; IL, interleukin; IFN, interferon; IB, inhibitor of NF-B; NF-B, nuclear factor-B; NIK, NF-B-inducing kinase; PKD, protein kinase D; Th, T-helper; TLR, Toll-like receptor; TNF, tumor necrosis factor; TNF-R, TNF receptor; TRAF, TNF receptor–associated factor

	ABSTRACT

TOP ABSTRACT RESEARCH DESIGN AND METHODS RESULTS DISCUSSION REFERENCES

 
Apoptotic ß-cell death is central to the pathogenesis of type 1 diabetes and may be important in islet graft rejection. Despite this, genetic control of ß-cell apoptosis is only poorly understood. We report that inhibition of gene transcription sensitized ß-cells to tumor necrosis factor (TNF)-–induced apoptosis, indicating the presence of a regulated antiapoptotic response. Using oligonucleotide microarrays and real-time PCR, we identified TNFAIP3/A20 as the most highly regulated antiapoptotic gene expressed in cytokine-stimulated human and mouse islets. Cytokine induction of A20 mRNA in primary islets and insulinoma cells was rapid and observed within 1 h, consistent with A20 being an immediate early response gene in ß-cells. Regulation of A20 was nuclear factor-B (NF-B)–dependent, two NF-B sites within the A20 promoter were found to be necessary and sufficient for A20 expression in ß-cells. Activation of NF-B by TNF receptor–associated factor (TRAF) 2, TRAF6, NF-B–inducing kinase, or protein kinase D, which transduce signals downstream of Toll-like receptors, TNF receptors, and free radicals, respectively, were all potent activators of the A20 promoter. Moreover, A20 expression was induced in transplanted islets in vivo. Finally, A20 expression was sufficient to protect ß-cells from TNF-induced apoptosis. These data demonstrate that A20 is the cardinal antiapoptotic gene in ß-cells. Further, A20 expression is NF-B dependent, thus linking islet proinflammatory gene responses with protection from apoptosis.

Apoptosis or programmed cell death is a genetically controlled response of the cell to commit suicide (1,2). Apoptosis is the physiological process for cell deletion in normal, reorganizing, or involuting tissue and is required for shaping of the endocrine pancreas (3,4). Aside from its role in normal cell biology, ß-cell apoptosis has been implicated in the pathophysiology of type 1 diabetes, both at its initiation phase and as the final effector mechanism (5,6). Evidence from the NOD mouse (a widely studied model of autoimmune diabetes) (7) indicates that autoreactive cytolytic T-cells (8), as well as soluble mediators including proinflammatory cytokines and free radicals, contribute to increased ß-cell apoptotic destruction during the pathogenesis of type 1 diabetes (6,9). Transplantation of islets is considered to be one potential approach that could restore normal metabolic control for the cure of type 1 diabetes. However, multiple obstacles are faced in islet transplants, including cellular rejection akin to the mechanisms involved in autoimmune destruction of ß-cells, and also primary nonfunction, a phenomena related to lack of nutrients, hypoxia, and nonspecific inflammatory mediators (10–12).

Despite the importance of apoptosis in the pathophysiology of ß-cell death, the genetic control of apoptosis in islets is poorly understood. Determining the molecular basis of ß-cell susceptibility to apoptosis would increase our understanding of the mechanisms underscoring ß-cell loss, as well as reveal potential gene therapy candidates for the creation of "death-defying" islets (13), capable of resisting immune and nonimmune insults. With this goal in mind, we generated a custom microarray, a so-called "death-CHIP," to map the immediate early antiapoptotic gene expression profile of cytokine-activated islets. Though later changes in islet gene expression after cytokine activation have been mapped in a number of studies (14,15), we focused only on the immediate early response, as it is this response that determines cell fate after inflammatory insult (16–19). Surprisingly, we found that in contrast to other cell types, primary islets have a highly restricted immediate early antiapoptotic gene response, with TNFAIP3/A20 being the most highly regulated antiapoptotic gene. Significantly, we demonstrate that A20 is regulated at the level of gene transcription in pancreatic ß-cells by the proinflammatory transcription factor nuclear factor-B (NF-B), thus linking islet inflammatory gene responses with protection from apoptosis. Together, with our previous studies demonstrating an anti-inflammatory and antiapoptotic function for A20 (13,20–22), these present data indicate that A20 is a critical component of the islet-regulated response to inflammatory stress and injury. Thus, we demonstrate that loss of A20 expression renders ß-cells susceptible to apoptotic death; conversely, enhancing A20 expression in ß-cells may improve their survival in the face of inflammatory and autoimmune insults (13,21).

	RESEARCH DESIGN AND METHODS

TOP ABSTRACT RESEARCH DESIGN AND METHODS RESULTS DISCUSSION REFERENCES

 
BALB/c and C57BL/6 mice were purchased from ARC (Perth, WA, Australia). NOD mice were purchased from The Walter and Eliza Hall Institute (Melbourne, VIC, Australia). Procedures complied with the Australian Code of Practice for the Care and Use of Animals for Scientific Purposes.

Cell death assays.
Assays were performed using a modified crystal violet method (23,24). Briefly, ß-insulinoma (ß-TC₃) cells were pretreated (30 min) with 0.01 µmol/l actinomycin D (Calbiochem, Kilsyth, Australia) before the addition of 100, 500, or 1000 units/ml of recombinant mouse tumor necrosis factor (TNF)- (R&D Systems, Minneapolis, MN). Twenty-four hours later, cell death was determined as described (23).

Cytokine stimulation.
Human primary islets, provided by Prof. Phillip O’Connell (Westmead Hospital, Sydney, NSW, Australia), were isolated from cadaveric organ donors and cultured as described (25). Mouse islets were isolated and cultured as we have described (13,26). For cytokine stimulation, islets (150–200 islets/treatment) were stimulated with 200 units/ml of the appropriate cytokine for the indicated times. Human and mouse recombinant T-helper (Th) 1 cytokines interleukin (IL)-1ß, TNF-, or -interferon (IFN), and the Th2 cytokines IL-4, IL-13, or IL-15 (R&D Systems). ß-TC₃ and Min6 cells were cultured as described (27). Cells were stimulated with 200 units/ml of mouse recombinant IL-1ß or TNF- for the indicated time points. In some cases islets were first pretreated with 100 µmol/l of the pharmacological NF-B inhibitor, pyrrolidine dithiocarbamate (Sigma, St. Louis, MO) as described (28).

Gene expression in ß-cells sorted with a fluorescence-activated cell sorter.
For cell sorting, primary mouse islets were first stimulated with cytokines as above and then washed (4% EDTA-PBS), and dispersed into single cells by a brief incubation with 0.05% trypsin-EDTA (Invitrogen). Dispersed islets were then washed free of trypsin and resuspended in 1% BSA-PBS and sorted in a fluorescence-activated cell sorter (FACS) based upon autofluorescence (FL-1) as described (29). Sorted cells were then analyzed for A20 expression as described below. The percentage of insulin-positive ß-cells in the FL-1^Hi and FL-1^Lo sorted populations was determined by insulin (mouse anti-insulin; Zymed Laboratories, South San Francisco, CA) and glucagon (rabbit anti-glucagon; ICN Immunologicals, Lisle, IL) specific labeling on cytospun cells.

Real-time PCR.
mRNA was extracted as described (26); we obtained 3–5 µg mRNA per 200 islets. cDNA was produced from 0.5 µg of RNA using the SuperScript III Reverse Transcriptase Kit (Invitrogen, Australia). Reactions were performed on the RG300 Real Time PCR System (Rotorgene), using SYBR green chemistry (JumpStart, Sigma, Castle Hill, Australia). A20 primers were human (F: AAAGCCCTCATCGACAGAAA; R: CAGTTGCCAGCGGAATTTA) and mouse (F: TGGTTCCAATTTTGCTCCTT; R: CGTTGATCAGGTGAGTCGTG). Human and mouse samples were normalized with glyceraldehyde-3-phosphate dehydrogenase (F: CACATCAAGAAGGTGGTG; R: TGTCATACCAGGAAATGA) or CPH2, respectively (F: TGGACCAAACACAAACGGTTCC; R: ACATTGCGAGCAGATGGGGTAG). Fold change was calculated following the 2^CT method.

Microarray.
Before hybridization, total RNA was amplified and labeled using the MessageAmp II aRNA Amplification Kit (Ambion, Austin, TX). Amplified RNA quality was evaluated by capillary electrophoresis using an Agilent 2100 Bioanalyzer (Agilent Technologies, Palo Alto, CA). Samples were hybridized on a custom-designed death-CHIP, a CustomArray 12K-Microarray platform (CombiMatrix, Mukilteo, WA). Genes were selected for inclusion on the microarray based upon their reported role in the regulation of cell death (Table 1). The microarray probe design and feature layout, hybridization and scanning protocol, data normalization, and quality control data will be reported elsewhere (D. Liuwantara, S.T. Grey, unpublished data). All data were first normalized and background corrected, then log (base 2) transformed. For each experiment, islets were isolated from 10 mice, pooled, and treated with cytokines, and RNA was harvested as described. Each experiment was performed on three (NOD) or four (BALB/c) independent islet preparations. All samples were run on duplicate arrays; 42 arrays were run in total. The mean coefficients of variation (CVs) based on replicate features on the microarrays were 20%.

Islet transplantation.
Islet transplantation into diabetic (blood glucose 300 mg/dl) recipients was performed essentially as described (13). Islets (isolated from three donor mice per recipient) from BALB/c mice were transplanted either into diabetic BALB/c recipients (syngeneic model) or into diabetic C57BL/6 mice (allogeneic model). To harvest the transplanted islets, nephrectomy was performed on postoperative day 5. The islet graft was collected by carefully peeling off the kidney capsule; mRNA was then isolated as described above. In some cases the graft was prepared for histological assessment as described (13).

	RESULTS

TOP ABSTRACT RESEARCH DESIGN AND METHODS RESULTS DISCUSSION REFERENCES

 
ß-Cells have an inducible antiapoptotic response.
Despite the importance of cell death in pathological ß-cell loss, little is known about the genetic control of apoptosis in these cells. Cell death is a highly regulated event, controlled in a proinflammatory setting by an inducible set of antiapoptotic genes rapidly upregulated in response to this same inflammatory stress and/or injury (16–19). We were particularly interested in determining whether ß-cells could also generate a rapid and inducible antiapoptotic response after exposure to inflammatory cytokines as has been described for other cell types (16–18). We first tested this concept by stimulating ß-TC₃ cells with TNF- in the presence or absence of the general transcription inhibitor, actinomycin D. Blockade of de novo gene transcription in combination with TNF- stimulation sensitized ß-TC₃ cells to cell death, whereas either treatment alone had minimal effect upon cell survival (Fig. 1). Cell survival decreased from 100% in control cells to 53% when cells were treated with 1000 units of TNF- and actinomycin D (P 0.005). These data demonstrate that blockade of de novo gene transcription sensitizes ß-cells to TNF-–induced cell death, consistent with the notion that TNF- triggers a proapoptotic death cascade that can be prevented by gene induction (16–18). Thus, ß-cells do have a cytokine-dependent regulated antiapoptotic response as has been demonstrated for other cell types.

View larger version (12K): [in this window] [in a new window]   FIG. 1. ß-Cells have an inducible antiapoptotic response. Survival of ß-TC3 cells treated with increasing concentrations of TNF- with () or without () Actinomycin D. Data represent mean ± SD percentage survival from four independent experiments, performed in duplicate. Data with 500 and 1,000 units are significant (**P 0.005).

Of the 63 antiapoptotic genes represented on the death-CHIP, we found that islets constitutively expressed a broad selection of antiapoptotic genes over a range of expression levels (Table 1). To confirm the findings of the death-CHIP, the basal expression of selected genes (Table 1) was established by Western blot and/or PCR analysis in primary human and rodent islets and ß-insulinoma cell lines (data not shown). Of the genes confirmed to be expressed in all three tissue samples, highly expressed genes (10,000 mean intensity units) including heat shock protein 70, HSPA1A/HSP70, and SOD1/CuZnSOD; moderately expressed genes (1–10,000 mean intensity units) including Heme oxygenase 1 and SOD2/MnSOD; and genes including the cellular inhibitors of apoptosis, BIRC2/c-IAP1, BIRC3/c-IAP2, BIRC4/XIAP, and the BCL family genes BCL2, BCL2L1/BCLXL, BCL2A1A/Bfl-1/A1, and TNFAIP3/A20 were expressed at relatively low constitutive basal levels (1,000 mean intensity units). In contrast, examination of the expression profile after cytokine stimulation indicated that islets have a relatively sparse immediate early antiapoptotic gene response (Fig. 2A and B). Establishing a twofold cutoff for statistical significance, only two genes were determined to be upregulated, namely, TNFAIP3/A20 and BIRC3/c-IAP-2, of which A20 was consistently the most highly regulated antiapoptotic gene (Fig. 2C). These data contrast islets with other tissues such as endothelial cells, which express a broad range of antiapoptotic genes under similar conditions (19,38,39).

View larger version (98K): [in this window] [in a new window]   FIG. 2. Islets have a limited antiapoptotic response. A: Hierarchical cluster analysis of 63 antiapoptotic genes. Each column represents change in gene expression (log2) from an individual array experiment. Red, upregulation; green, downregulation. B: Top 10 most highly expressed antiapoptotic genes. Data represent mean ± SD average fold change (log2 ratios) from at least three independent experiments. C: Fold changes in gene expression for A20 and Birc3; each column represents an individual array. Only A20 and Birc3 were significant (P 0.001).

View larger version (28K): [in this window] [in a new window]   FIG. 3. A20 is an immediate early response gene in ß-cells. A: A20 expression in BALB/c or NOD islets treated with IL-1ß or TNF-. Data represents means ± SD from three independent experiments. B: A20 expression in male or female NOD islets stimulated with IL-1ß or TNF- for 1 h. Data represents means ± SD from three independent experiments. C: A20 expression in primary human islets treated with IL-1ß or TNF-. Data represent means ± SD from four independent experiments. All differences are significant (P 0.05).

ß-Cell–specific expression of A20 in islets.
Islets of Langerhans are a heterogeneous tissue comprising not only insulin-secreting ß-cells but also additional hormone-secreting cells including - and -cells. ß-Cells from freshly isolated islets are autofluorescent due to intracellular flavin adenine dinucleotide levels and can be FACS-purified on this basis (29). To determine the cellular source of A20 expression in intact primary islets, we next examined A20 expression in FACS-purified primary ß-cells and non–ß-cells (Fig. 4A). We found that inducible A20 expression was restricted to insulin-positive ß-cells (approximately threefold induction P 0.05) as A20 expression was not induced by IL-1ß in glucagon-positive cells (Fig. 4B). We also examined inducible A20 expression in the insulinoma cell line, Min6. Stimulation of Min6 cells with IL-1ß or TNF- resulted in a rapid and marked induction of A20, with kinetics similar to that seen for primary human and rodent islets (Fig. 4C). Thus, these data demonstrate ß-cell–specific regulation of A20 expression within pancreatic islets.

View larger version (33K): [in this window] [in a new window]   FIG. 4. A20 is expressed in insulin-producing ß-cells. A: A20 expression in FACS-sorted primary ß-cells. Primary islets were stimulated with IL-1ß for 1 h, dispersed into single cells, and FACS-sorted based on autofluorescence into FL-1Hi (insulin-positive and glucagon-negative) and FL-1Lo (insulin-negative and glucagon-positive) cells. B: A20 expression was induced by IL-1ß in FL-1Hi cells (*P 0.05) but not in FL-1Lo cells. RT, real-time; CTL, control. C: A20 expression in Min6 cells following IL-1ß or TNF- stimulation. Data represents means ± SD from four independent experiments. All differences were significant (P 0.05).

View larger version (18K): [in this window] [in a new window]   FIG. 5. A20 is regulated at the level of transcription by NF-B. A: A20 expression in BALB/c islets treated with IL-1ß for 1 h with or without actinomycin D (AcD). Data represent means ± SD from two independent experiments. B: A20 promoter sequence indicating deleted NF-B binding sites used for reporter studies. C: Induction of the native or NF-B A20 reporter in ß-TC3 by IL-1ß or TNF-. Data are means ± SD from a representative experiment of three independent experiments. All differences are significant (**P 0.001).

NF-B is both necessary and sufficient to initiate transcriptional activation of the A20 promoter.

We next utilized an alternative approach to confirm the importance of NF-B in the regulation of de novo transcription of the A20 promoter. We achieved this by overexpressing the p65/RelA subunit of NF-B (39) in ß-TC₃ cells and examined whether this change would result in induction of the A20 promoter. As shown in Fig. 6B, forced expression of p65/RelA resulted in a marked dose-dependent activation of the A20 promoter, showing an 19-fold increase (P 0.001) at the highest concentration tested. Importantly, forced expression of p65/RelA also resulted in a fivefold induction (P 0.005) in endogenous A20 mRNA levels, indicating that NF-B was sufficient to drive the endogenous A20 promoter (Fig. 6A). Finally, inhibition of NF-kB activity using the chemical inhibitor, pyrrolidine dithiocarbamate (28), abolished IL-1ß–stimulated A20 mRNA (>90%, P 0.01) expression in islets (Fig. 6C.) Together these data demonstrate that NF-B is both necessary and sufficient to initiate transcriptional activation of the A20 promoter and drive expression of A20 mRNA. These data are consistent with our finding that A20 is regulated by the NF-B–activating cytokines IL-1ß and TNF-, but not cytokines such as -IFN, IL-4, IL-13, and IL-15, which do not activate NF-B.

View larger version (16K): [in this window] [in a new window]   FIG. 6. NF-B is necessary and sufficient to drive de novo A20 expression. A: Induction of the A20 reporter in ß-TC3 by p65/RelA. Data represent means ± SD from a representative experiment of three independent experiments. B: Induction of endogenous A20 mRNA in ß-TC3 by p65/RelA. Data represent means ± SD from a representative experiment of three independent experiments conducted. C: A20 expression in BALB/c islets treated with IL-1ß for 1 h with or without pyrrolidine dithiocarbamate. Data represent means ± SD of three independent experiments. All differences are significant (*P 0.05; **P 0.01; ***P 0.001). RLA, relative light activity; PDTC, pyrrolidine dithiocarbamate.

A20 transcription is regulated by multiple NF-B signaling pathways.

View larger version (23K): [in this window] [in a new window]   FIG. 7. A20 expression is NF-B dependent in ß-cells. Induction of the A20 reporter in ß-TC3 by (A) TRAF6, (B) TRAF2, (C) NIK, and (D) PKD. Data represent means ± SD from one representative experiment of four to six independent experiments conducted. All differences are significant (*P 0.05; **P 0.001). RLA, relative light activity.

Expression of A20 in stressed islets in vivo.
Transplanted islets are exposed to a hyperglycemic environment, nonspecific inflammatory reactions (i.e., including cytokines and free radicals), and immune-mediated rejection as well as stresses relating to hypoxia and lack of adequate nutrients (10,11). Many of these factors are able to induce NF-B. Having identified A20 as a major NF-B–regulated gene in ß-cells, we hypothesized that A20 expression should be heavily regulated in islets in vivo after exposure to inflammatory stress. To assess this directly, we examined A20 expression levels in islets after transplantation into either diabetic syngeneic or diabetic allogeneic hosts. As shown in Fig. 8, already at day 5 after transplantation, there were significant approximately threefold (P 0.05) and approximately fourfold (P 0.05) increases in A20 steady-state mRNA expression in islets transplanted into either syngeneic or allogeneic recipients, respectively. These data demonstrate that transplanted islets do have a regulated antiapoptotic stress response and that A20 is a critical component of this stress response in vivo.

View larger version (13K): [in this window] [in a new window]   FIG. 8. A20 is upregulated in islets in vivo. Islet A20 expression at postoperative day 5. Data represent means ± SD from three independent experiments. All differences are significant (*P 0.05). Non Tx, nontransplanted; Syn, syngeneic; Allo, allogeneic.

A20 is sufficient to protect ß-cells from TNF-–induced cell death.

Activation of the TNF receptor by its cognate ligand results in the recruitment of FADD, which subsequently recruits and activates procaspase 8/FLICE, triggering apoptosis (1,39). For this experiment, ß-TC₃ cells were transiently cotransfected with a FADD expression vector to induce apoptosis in the presence or absence of an A20 expression plasmid. Controls cells were transfected with a vector expressing a FADD dominant negative inhibitor (FADD-DN) or the empty vector pcDNA₃. All groups were transiently cotransfected with a cytomegalovirus-driven ß-gal reporter, which was used to determine the percentage of viable cells for each group (22). As shown in Fig. 9, forced expression of FADD resulted in the rapid destruction of ß-TC₃ cells as evidenced by the decrease in ß-gal reporter activity (60%, P 0.005) compared with baseline levels observed in control groups (e.g., pcDNA₃ or FADD-DN), whereas expression of FADD-DN had little effect upon cell viability (P = 0.132). In contrast, A20 expressing cells were completely protected from the proapoptotic effect of FADD (P 0.05). These data demonstrate for the first time that A20 is sufficient to protect ß-cells from TNF-–induced apoptosis; thus, loss of A20 expression by transcriptional blockade sensitizes ß-cells to apoptotic cell death.

View larger version (16K): [in this window] [in a new window]   FIG. 9. A20 rescues ß-cells from FADD-induced cell death. Cell survival in ß-TC3 cells expressing pcDNA3, FADD-DN, FADD, or FADD plus A20. Data represent mean ± SD percentage survival from four independent experiments. Differences between FADD and FADD plus A20 are significant (**P 0.05). RLA, relative light activity.

	DISCUSSION

TOP ABSTRACT RESEARCH DESIGN AND METHODS RESULTS DISCUSSION REFERENCES

In this present study we demonstrate that this paradigm is true for ß-cells, as ß-cells were sensitized to TNF-–induced death by inhibition of de novo gene transcription. Our microarray-based approach revealed that TNFAIP3/A20 is one potential candidate gene providing a molecular basis for this protective response. A20 is a zinc finger–containing, immediate early-response gene with a potent antiapoptotic and anti-inflammatory function (20,40,45). This essential antiapoptotic and anti-inflammatory function of A20 is preserved in islets (13,21). Once expressed, A20 binds to and targets TNF receptor interacting protein for proteosomal degradation, thereby preventing TNF-–induced NF-B activation (46). The antiapoptotic mechanism of A20 is less well understood but may also involve inhibition of key proximal signaling events, as A20 inhibits activation of initiator caspases after death receptor ligation (22), consistent with our data demonstrating that A20 protects ß-cells from FADD-induced apoptosis.

The transcription factor NF-B regulates multiple proinflammatory genes that can contribute to islet destruction. NF-B can promote T-cell–mediated killing and the generation of ß-cell toxins through the induction of molecules such as Fas (47,48), inducible nitric oxide synthase (48,49) and cyclooxygenase-2 (50), respectively. In addition, the promoters of other proinflammatory genes induced in ß-cells, including chemokines (i.e., monocyte chemoattractant protein-1) and adhesion molecules (i.e., intercellular adhesion molecule-1), also possess binding elements for NF-B (43). The importance of NF-B in ß-cell inflammatory responses is underscored by the fact that blockade of NF-B in in vitro models, by means of an inhibitor of NFB (IB) super-repressor or via A20 overexpression, prevents IL-1ß–and -IFN–induced ß-cell dysfunction and death (21,48,49,51). Collectively these data implicate NF-B as a major player in cytokine-dependent ß-cell dysfunction and indicate that targeting NF-B may have therapeutic utility as a means to improve islet function in the face of inflammatory insults.

However, aside from its important proinflammatory role, NF-B is a major regulator of cellular apoptosis through its ability to control the expression of multiple antiapoptotic genes including the c-IAPs, caspase-8-c-FLIP, Bfl-1/A1 (39), and A20 (20,42). In cells that lack the NF-B family member p65/RelA, exposure to TNF- will induce apoptosis (16). Furthermore, blockade of NF-B activation, by nonspecifically inhibiting transcription with actinomycin D (52) or specifically via the use of an IB super-repressor (17,18), also sensitizes cells to TNF-–mediated apoptosis. Importantly blockade of NF-B in ß-cells by means of an IB super-repressor (53) or via actinomycin D as we demonstrate here, also sensitizes cells to TNF-–dependent apoptotic death. We propose that this sensitization was due to blockade of NF-B activation and, at least in part, the subsequent loss of A20 expression. Consistent with this, prevention of A20 induction in vitro sensitizes endothelial cells to TNF-dependent apoptosis (20). Thus in ß-cells, as has been demonstrated for other cell types, NF-B activation governs both proinflammatory responses and protection from apoptosis (39). Therefore, targeting NF-B activation in an in vivo setting in which multiple factors are at play may sensitize ß-cells to apoptosis (53). In light of this, we propose that more sophisticated approaches than mere blanket blockade of NF-B are warranted if one aims to prevent the unwanted proinflammatory effects of NF-B activation without incurring the associated risk of sensitizing ß-cells to apoptotic death. Alternative strategies might include expressing genes such as A20 (13,20) or targeting specific upstream regulators of NF-B activation (54).

In conclusion, we demonstrate that primary islets upregulated a relatively small set of antiapoptotic genes in response to inflammatory stress, of which TNFAIP3/A20 was the most highly regulated. Here we demonstrate that A20 is regulated at the level of gene transcription in pancreatic ß-cells, under the control of the transcription factor NF-B; thus, tightly linking islet proinflammatory gene responses with protection from apoptosis. Together with our previous studies demonstrating an anti-inflammatory and antiapoptotic function for A20 in islets (13,21), these present data indicate that A20 is a critical component of the islet-regulated response to inflammatory stress and injury. Thus, pathologic loss of A20 expression may render ß-cells susceptible to apoptotic death; conversely, enhancing A20 expression in ß-cells may improve their survival in the face of inflammatory and autoimmune insults. Importantly, our data indicate that blockade of NF-B, as a means to prevent islet inflammatory responses in vivo, may have the unwanted side effect of sensitizing ß-cells to apoptosis by preventing the upregulation of antiapoptotic genes such as A20 (16,17,20).

	ACKNOWLEDGMENTS

 
This work was supported by the Juvenile Diabetes Foundation International (JDRF 2-2000-719) and a BioFirst Award from the New South Wales Ministry for Science and Medical Research (to S.T.G.).

The authors thank Drs. J. Gunton and R. Laybutt for critical reading of this manuscript and T. Shukri, L. Choi, J. Chan, Jerome Darakdjian, and the Biological Testing Facility staff for technical assistance.

	FOOTNOTES

 
The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

Received for publication January 31, 2006 and accepted in revised form June 1, 2006

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