Evasion of Cytotoxic T Lymphocyte (CTL) Responses by Nef-dependent Induction of Fas Ligand (CD95L) Expression on Simian Immunodeficiency Virus-infected Cells

By Xiao-Ning Xu,* Gavin R. Screaton,* Frances M. Gotch,Dagger Tao Dong,* Rusung Tan,* Neil Almond,§ Barry Walker,§ Richard Stebbings,§ Karen Kent,§ Shigekazu Nagata,par Jim E. Stott,§ and Andrew J. McMichael*

From the * Molecular Immunology, Institute of Molecular Medicine, John Radcliffe Hospital, Oxford OX3 9DU, United Kingdom; the Dagger   Dept of Immunology, Chelsea and Westminster Hospital, London SW10 9NH, United Kingdom; the § AIDS Collaborating Centre, National Institute for Biological Standards and Control, Hertfordshire EN6 3QG, United Kingdom; the par  Department of Genetics, Osaka University Medical School, Osaka 565, Japan

Summary
Materials and Methods
Results
Discussion
Footnotes
Acknowledgements
References


Summary

Inoculation of macaques with live attenuated SIV strains has been shown to protect against subsequent challenge with wild-type SIV. The protective mechanism(s) remain obscure. To study the effect in more detail, we have investigated the role of virus-specific CTL responses in macaques infected with an attenuated SIV strain (pC8), which has a four-amino acid deletion in the nef gene, as compared with the wild-type SIVmac32H clone (pJ5). Cynomolgus macaques infected with pC8 were protected against subsequent challenge with pJ5 and did not develop any AIDS-like symptoms in the 12 months after infection. The pC8-induced protection was associated with high levels of virus-specific CTL responses to a variety of viral antigens. In contrast, pJ5-infected macaques had little, if any, detectable CTL response to the viral proteins after three months. The latter group of macaques also showed increased Fas expression and apoptotic cell death in both the CD4+ and CD8+ populations. In vitro, pJ5 but not pC8 leads to an increase in FasL expression on infected cells. Thus the expression of FasL may protect infected cells from CTL attack, killing viral-specific CTLs in the process, and providing a route for escaping the immune response, leading to the increased pathogenicity of pJ5. pC8, on the other hand does not induce FasL expression, allowing the development of a protective CTL response. Furthermore, interruption of the Fas-FasL interaction allows the regeneration of viral-specific CTL responses in pJ5-infected animals. This observation suggests an additional therapeutic approach to the treatment of AIDS.


Live attenuated SIV1 or HIV with a deletion of the nef gene exhibits reduced pathogenicity and does not cause an AIDS-like illness (1). Moreover, macaques immunized with the nef-mutant SIV are protected against superinfection with wild-type pathogenic SIV (2, 4). However, the mechanism(s) of protection induced by the attenuated virus are not known.

Accumulated evidence suggests that CTL play a critical role in controlling HIV replication (5). HIV-specific CTL activity has been observed at different stages of the disease in infected individuals. In particular, the early induction of an HIV-specific CTL response has been associated with the initial control of viremia and may influence the subsequent clinical outcome (6). However during disease progression the fall in CD4+ T cells is associated with a decrease in CD8+ T cell numbers and an associated reduction in the virus-specific CTL activity (9). Although several mechanisms are known to cause depletion of CD4+ T cells in HIV infection (12), less is known about the mechanisms leading to the fall in numbers and dysfunction of CD8+ T cells, which probably result from several factors in addition to the reduction of CD4+ T cell help. In particular, HIV-associated programmed cell death (apoptosis) has been well documented in infected individuals (16). Interestingly, these apoptotic cells include not only uninfected CD4+ cells but also CD8+ (bystander) cells (18, 19).

Apoptosis of lymphocytes can be triggered by several cell surface receptors including TNF-R1, Fas, and a newly cloned molecule WSL-1/DR3 (20, 21). Each of these molecules will trigger apoptosis when it contacts its counter- receptor or ligand, TNF and FasL for TNF-R1 and Fas, respectively (22). Interaction between Fas and FasL plays a important role in the homeostatic regulation of normal immune responses (23). The expression of Fas is quite diffuse being found on a variety of extra-lymphoid tissues such as liver, ovary, and heart. The expression of FasL on the other hand is much more tightly controlled being restricted to activated lymphocytes and selected sites enjoying immune privilege (24, 25).

Fas is upregulated on both CD4+ and CD8+ cells from HIV-infected individuals (26, 27). However Fas expression per se does not lead to cell death as ligation of Fas by FasL is required to trigger apoptosis. There are therefore two crucial questions relating to the death of CD8+ cells in HIV infection, first where is FasL expressed, and secondly what induces its expression.

To address this question, we have investigated CTL responses and apoptosis in macaques infected with the attenuated SIV strain pC8 compared with the pathogenic wild-type pJ5. Our results indicate that the mechanisms of protection induced by the nef-mutant SIV involves the induction of a viral-specific CTL response. The failure of pC8-infected CD4+ cells to upregulate FasL expression may allow the generation of an efficient antiviral response. In contrast the pJ5-infected CD4+ cells upregulate FasL expression which can induce death of SIV-specific lymphocytes, including CTL expressing Fas. This results in a failure to check viral replication and a consequent progression to AIDS.


Materials and Methods

Antibodies, Fusion Protein, and Cells

Antibodies. Anti-human Fas monoclonal IgM was obtained from UBI (Lake Placid, New York); anti-human Fas ligand monoclonal antibodies, 4A5 and 4H9, were described previously (28). Biotin-conjugated anti-human FasL mAb (NOK1) was purchased from PharMingen (San Diego, CA). mAbs to SIV-nef or env protein were made by NIBSC (London, UK). PE-conjugated anti-CD4 and CD8 mAbs were purchased from Beckton Dickinson (Mountain View, CA) and Dako Corp. (Carpinteria, CA), respectively.

Fas-Fc Fusion Protein. PCR primers F Fas Kpn AAT GCG GTA CCT AGA TTA TCG TCC AAA AGT GTT AAT GCC C and R Fas Bcl GCA CTT TGA TCA GAT CTG GAT CCT TCC TCT TTG CAC TT were used to amplify sequences encoding the extracellular region of the Fas protein from PHA blasted PBMC cDNA. After digestion with the appropriate restriction enzymes the fragment was cloned into a CMV driven expression vector forming a fusion with the Fc region of human IgG1. The plasmid DNA was then used for transient transfection of COS cells by DEAE dextran (29). 4-5 d after transfection the Fas-Fc fusion protein was passed over a protein A-Sepharose column and eluded with 0.1 M citric acid (pH 3.0).

Cells. CEM or Jurkat CD4+ T-lymphoblastoid cell lines were obtained from the American Type Culture Collection (Gaithersburg, MD). Macaque PBMCs were isolated on Ficoll-Hypaque and cultured in a R10H medium (RPMI containing 10% human AB serum) as indicated.

Infection of Macaques or T Lymphocytes with SIVmac 32H Clones

Two SIVmac 32H clones, pC8 and pJ5, were originally isolated from rhesus macaque 32H inoculated with a SIVmac251 virus pool (1). The pC8 clone differs from the pJ5 clone by a four- amino acid deletion in the nef open reading frame and expresses an attenuated phenotype in vivo (4). Four cynomolgus macaques were infected intravenously with pC8 (104 TCID50) for 12 mo and then challenged with a pathogenic SIVmac32H clone, pJ5 (50 MID50) for an additional 3 mo. Another group of four naive macaques was infected with pJ5 (50 MID50) only.

In vitro infection of PBMCs or CEM cells. PBMC (1 × 106) were stimulated with Con A (5 µg/ml) for 12 h and superinfected with 200 µl of pC8 or pJ5 supernatant containing 5 × 104 TCID50 for 2 h at 37°C under 5% CO2. After washing three times with RPMI 1640, cells were adjusted to a concentration of 2.0 × 105/ml and incubated in R10H medium for another 48 h. For infection of CEM cells, 1 × 106 cells were infected with 400 µl of pC8 or pJ5 supernatant containing 5 × 104 TCID50 for 2 h and incubated in R10H for another 24 h. Mock infection was performed under the same conditions using a supernatant generated from Con A-stimulated or unstimulated uninfected cells. Infectivity of SIV was analyzed by staining intracytoplasmic nef expression or cell surface env expression using flow cytometry.

Detection of Virus Infection in Macaques

The presence of SIV-specific DNA sequences in the blood of SIV challenged macaques was performed as described previously (4). In brief, this involves the amplification of a region of the SIV nef gene. Restriction analyses of PCR products using the enzyme Rsa I allows the differentiation of products derived from pJ5 or pC8 virus.

Detection of Virus-specific CTL Activities

SIV-specific CTL activity was measured in bulk cultures as previously described (30). In brief, PBMC were isolated on Ficoll-Hypaque and one-tenth of the autologous PBMC were stimulated with Con A (5 µg/ml) for 24 h. Cells were infected with 100 µl SIV pC8 supernatant for 2 h, washed and then added back to the remaining cells. Infected cells were then cultured in R10H medium for 3 d and maintained for another 7-14 d in medium supplemented with 10 U/ml IL-2. H. papio-transformed autologous B cell lines infected with recombinant vaccinia viruses carrying the SIV mac nef, gag/pol, env, RT, rev, tat, or control (influenza NP) gene were used as target cells. In some experiments soluble Fas-Fc fusion protein (5 µg/ml) was added initially in bulk cultures and the cells were then washed before using as effector cells in CTL assay. Cytotoxicity was determined by culturing 51Cr-labeled target cells with effector cells at various E/T ratios for 4 h in 96-well U-bottomed plates. Maximum and spontaneous release were determined by incubating target cells with 5% Triton X-100 or media, respectively. Percentage lysis was calculated as ([experimental release - spontaneous release]/ [maximum release - spontaneous release]) × 100. Spontaneous release varied from 10% to 25%. Specific lysis was calculated by subtracting background killing of influenza NP-infected target cells.

Detection of Apoptotic cells by DNA Fragmentation

PBMC were cultured in R10H media for 4 or 16 h and fragmented DNA was extracted according to the method previously described (31). In brief, pelleted cells (0.5-1 × 106 cells) were lysed with 100 µl lysis buffer (1% NP-40, 20 mM EDTA, 50 mM Tris-HCL, pH 7.5) for 1 min and centrifuged at 1,600 g for 5 min. The supernatant was collected and treated with 1% SDS and RNAseA (5 µg/ml) at 56°C for 2 h. After digestion with proteinase K (2.5 µg/ml) for 2 h at 37°C, the DNA was precipitated by adding 1/2 volume of 10 M ammonium acetate and 2.5 vol of cold ethanol, and then analyzed by electrophoresis on 1.5% agarose gels. To quantitate the percentage DNA fragmentations Southern blot was hybridized with 32P-labeled probe generated by random priming of whole monkey genomic DNA. The percentage DNA fragmentation was calculated by dividing the total counts by the counts found on DNA fragments below 23,000 bp (32). DNA extracted from naive controls had <20% of the counts as determined by this method.

Flow Cytometry

For analysis of Fas expression, PBMCs (5 × 105 ) were incubated first with anti-Fas IgM monoclonal antibody and then with a secondary FITC-conjugated rabbit anti-mouse IgM (Sigma Chem. Co., St. Louis, MO). Fas stained cells were then counterstained with a PE-conjugated anti-CD4 or CD8 mAbs. For intracytoplasmic staining of SIV nef antigen, the infected cells were incubated with the anti-SIV nef mAb together with 0.3% saponin (Sigma) and then stained with a secondary FITC-conjugated rabbit anti- mouse Ig (Sigma). Labeled cells were analyzed on a FACScan®. Isotype-specific mAbs of irrelevant specificity were used as negative controls (Dako Corp.).

Analysis of FasL Expression

Functional FasL was assessed using a bioassay for FasL (33). SIV-infected cells were cocultured with 51Cr-labeled Fas-sensitive Jurkat cells at various E/T ratios in the presence or absence of the human Fas-Fc fusion protein (10 µg/ml) or blocking anti-FasL mAbs (5 µg/ml) for 12-16 h. The level of chromium release into the supernatant was determined using a beta -plate counter.

To determine the level of FasL expression on the cell surface, SIV-infected cells were incubated with 20 µl of biotin-conjugated anti-human FasL mAb (NOK-1; PharMingen), followed by 5 µl of PE-conjugated streptavidin (Sigma). Negative controls were either infected cells stained with PE-streptavidin only or uninfected cells stained with anti-FasL mAb and PE-streptavidin.


Results

Protective Effects of pC8 on Challenge of the Macaques with pJ5.

After infection with the attenuated strain of SIV pC8, all macaques became infected but did not develop the characteristic clinical manifestations of AIDS over the subsequent 12 mo. These pC8-infected macaques and four naive animals were then challenged with pJ5. After 8 wk, the viral load was assessed. The virus was recovered from all naive animals after challenge but not from the animals that had been preinfected with pC8 (Table 1), indicating that the attenuated clone pC8 protects against subsequent challenge with pJ5.

Table 1. >Challenge with Wild-type SIV pJ5 in pC8-infected and Naive Macaques


Group* Before challenge After challenge
Abs to SIV gp140Dagger Virus detected by V/P§ Abs to SIV gp140 Virus detected by V/P

pC8-infected
  N113 4.0  -/? 4.0  -/pC8
  N114 3.5  -/pC8 3.0  -/pC8
  N115 3.6  -/pC8 3.6  -/?
  N116 3.6  -/pC8 3.9  -/pC8
Naive
  N174 <1.5  -/ND 3.7 +/pJ5
  N175 <1.5  -/ND 3.5 +/pJ5
  N176 <1.5  -/ND 3.5 +/pJ5
  N177 <1.5  -/ND 3.3 +/pJ5

*  Monkeys N113-116 were infected intravenously with 104 TCID50 of SIVpC8 for 35 mo and then together with naive N174-177 monkeys challenged intravenously with 50 MID50 SIV pJ5 clone.
Dagger  Antibody to SIV gp140 was determined by ELISA using anti-SIV gp140 mAbs and data is end point titers expressed as log10.
§  V, virus detected by virus isolation; P, virus detected by PCR. + indicates virus recovered from 5 × 106 PBMCs; - indicates no virus recovered from 5 × 106 PBMCs; pC8 or pJ5 indicates PCR product with characterization of pC8 or pJ5 respectively; ? indicates indeterminate PCR product unlike pJ5; ND indicates not determined.

SIV-specific CTL Activities.

To investigate the mechanism of protection induced by pC8, SIV-specific CTL responses were measured in PBMC bulk cultures 3 mo after challenge with pJ5. All pC8-infected macaques showed multiple virus-specific CTL responses to nef, gag/pol, env, RT, rev, and/or tat, (Table 2). By contrast, no detectable virus-specific CTL activity was observed in PBMC from pJ5-infected animals, at an E/T of 30:1, although a weak CTL response was found in a lymph node from one of these animals.

Table 2. >SIV-specific CTL Responses after SIVpJ5 Challenge in pC8-infected and Naive Macaques


Target cell infectionDagger SIV pJ5 challenge on* (% specific lysis at E/T = 30:1)
pC8-infected Naive
N113 N114 N115 N116 N174 N175 N177

rVV-nef 7.2§ <1.0 19.3 19.4 <1.0 <1.0 <1.0
   (3.9)par      (7.4)par
rVV-gag/pol <1.0     11.8 <1.0 17.8 2.0 <1.0 <1.0
   (2.4)par (11.2)par
rVV-env 22.9 <1.0 12.5 16.6 <1.0 <1.0 <1.0
     (9.1)par
rVV-RT <1.0 <1.0 <1.0 25.5 <1.0 <1.0 <1.0
rVV-rev <1.0    18.7 13.6 <1.0 <1.0 <1.0 <1.0
rVV-tat <1.0    31.5 <1.0 9.1 <1.0 <1.0 <1.0

*  pC8-infected (N113-N116) or naive (N14, N175, and N177) macaques were intravenously injected with 50 MID50 SIV pJ5 clone as shown in Table 1 and bulk cultured CTL activities were determined at 3 mo after infection.
Dagger  Herpes papio-transformed autologous B cell lines were infected with recombinant vaccinia viruses (10 PFU/cell) expressing SIV proteins for 2 h at 37°C. After washing the cells were cultured in RPMI 10% FCS for 12 h and then used as target cells.
§  Specific lysis was calculated by subtracting the background killing of rVV fluNP-infected target.
par  CTL activities in lymph nodes.

Induction of Apoptosis In Vivo by SIV pJ5 Compared with pC8.

To characterize the loss of CTL responses in pJ5-infected animals further, we analyzed the viability of PBMCs in both groups. Freshly isolated PBMCs were cultured for 4 or 16 h in R10H medium at 37°C and apoptosis was assessed by DNA fragmentation (Fig. 1). Spontaneous apoptosis was significantly higher in pJ5-infected macaques than in pC8-infected animals after 16 h (47.2% vs. 18.1%, P <0.001). Apoptosis was more profound in the CD8+ population (CD4 vs. CD8: 28.3% vs. 41.4%, P <0.05, respectively) (Fig. 2). Thus T cells, in particular CD8+ T cells, from pJ5-infected animals are more vulnerable to apoptosis than those from pC8-infected animals.


Fig. 1. Spontaneous DNA fragmentation of PBMCs from pC8-induced protected (N113-N114) or pJ5-infected (N174-N177) macaques. Fresh isolated PBMCs (1 × 106) were cultured in medium containing 10% human AB serum for 4 or 16 h. Fragmented DNA was extracted as described in Materials and Methods. (A) DNA was analyzed by electrophoresis on 1.5% agarose gels; (B) Southern blot analysis of the DNA by hybridization with 32P-labeled genomic macaque DNA; (C) The percentage of DNA fragmentation in B was calculated as dividing the total counts of each sample by the number of counts in the bottom 85-90% of the gel (below 23,000 bp). The percentage of DNA fragmentation of PBMCs from naive macaques was always <20% (data not shown). P value for the two groups <0.005 after 16 h.
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Fig. 2. Spontaneous DNA fragmentation of CD4 and CD8 subpopulations from pJ5-infected control (N174-N177) macaques. PBMCs were cultured in the medium for 16 h and CD4+ or CD8+ T cells was then purified by positive selection using anti-CD4 or CD8 magnetic beads, respectively. The purity of each subset was >95% as assessed by flow cytometry. After extracting the DNA, Southern blot was performed (A) and analyzed as described in Fig. 1 (B). P value for CD4 vs CD8 <0.05. These data are representative of three separate experiments.
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To explain this increased susceptibility to apoptosis we analyzed Fas expression on lymphocyte subsets obtained from pJ5 and pC8-infected animals (Fig. 3). Although Fas expression was significantly increased in both infected groups (pJ5: 36.9 ± 12.7%, pC8: 17.6 ± 4.2%) compared with naive animals (6.2 ± 1.2%), pJ5 induced a significantly higher level of Fas expression than pC8 (P <0.05) (Fig. 3 A). Moreover, while Fas expression was found to be upregulated on both CD4+ and CD8+ T cells in the pJ5 group, it was significantly higher in the CD8+ T cells (P <0.05).


Fig. 3. Expression of Fas antigen on SIV-infected macaques. (A) Representative histograms of Fas expression on PBMCs. The percentage of Fas positive cells (mean fluorescent intensity >13 units): naive 6.2 ± 1.2% (n = 4), C8+J5-infected 17.6 ± 4.2% (n = 4), or pJ5-infected 36.9 ± 12.7% (n = 4) macaques (C8+J5 vs J5 P <0.05). (B) Fas expression on fractionated CD4+ or CD8+ T cells from pC8- and pJ5-infected groups (P = 0.08 for CD4+ cells and P <0.05 for the CD8+ cells).
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Upregulation of Fas Ligand Expression on SIV-infected Cells.

Engagement of FasL is required for Fas-induced apoptosis, so to search for the source of FasL we used a sensitive bioassay. The assay exploits the sensitivity of Jurkat cells to Fas-mediated killing which can be blocked by the addition of an excess of soluble Fas-Fc fusion protein or anti-FasL mAbs.

PBMC or CEM cells were infected in vitro with either pC8 or pJ5 and then cocultured with 51Cr-labeled Jurkat cells (Fig. 4). The results for PBMC and CEM are equivalent, and demonstrate that pJ5-infected but not pC8- infected cells induce killing of Jurkat cells which is abrogated by Fas-Fc fusion protein, implying upregulation of FasL in the pJ5-infected cells. To confirm the results of the bioassay we analyzed FasL expression on infected CEM cells, 24 h after infection, with an anti-FasL mAb. As expected FasL was upregulated in the pJ5 infected cells to a greater degree than cells infected with pC8 (Fig. 5 A).


Fig. 4. SIV-infected cells kill Fas-sensitive target via FasL-Fas interaction. Naive monkey PBMCs (A) or CEM cells (B) were superinfected with SIV pC8 or pJ5 as indicated in Materials and Methods. SIV-infected cells were cocultured with 51Cr-labeled Fas-sensitive Jurkat cells in the presence or absence of Fas-Fc fusion proteins (10 µg/ml) for 12-16 h. Chromium release was determined by a beta -plate counter. Specific lysis was calculated by subtracting the killing of Jurkat cells by mock-infected cells. Infectivity of SIV pC8 or pJ5 in CEM cells.
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Fig. 5. (A) Comparison of FasL induction by infection with pC8 or pJ5 as assessed by staining with the anti-FasL mAb. 24 h after infection cells were stained with biotinylated anti-human FasL mAb (NOK-1) plus PE-streptavidin (solid lines). Dotted lines indicate background staining with PE-streptavidin alone. (B) Staining of infected cells (solid lines) with anti-nef mAb demonstrates equal infectivity of pC8 and pJ5 infection. Dotted lines indicate background staining with control mAb.
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This phenomenon does not result from a difference in the infectivity of the two viral strains. The percentage of infected cells at 3 d, pC8 (98.3%; 76.5 MFI) and pJ5 (98.1%; 78.8 MFI), are equivalent when assessed with anti- nef (Fig. 5 B). A similar result was obtained with anti-env mAb (data not shown). Moreover, the lysis of Jurkat cells is not due to direct viral invasion as Jurkat cells are resistant to SIV infection (our unpublished observation and others [34]). Similar results were also made with fresh PBMC isolated from macaques 3 mo after infection with pJ5 (Fig. 6). Fractionation of T cells from these macaques demonstrates that although the CD8+ population expresses more Fas, the majority of FasL activity resides in the CD4+ population, probably on SIV-infected cells.


Fig. 6. PBMCs from SIV pJ5-infected macaques kill Fas-sensitive target are CD4-dependent. PBMCs from pJ5-infected or uninfected macaques (n = 2 in each group) were stimulated with Con A (5 µg/ml) for 12 h. After washing three times with RPMI, CD4+ or CD8+ T cells were depleted by using anti-CD4 or CD8 magnetic beads, respectively. Cells were then cocultured with 51Cr-labeled Jurkat cells in the presence or absence of fusion proteins (10 µg/ml) or anti-human FasL mAbs (5 µg/ml) for 12-16 h. Specific lysis was assayed as described in Fig. 4.
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CTL Responses Can Be Restored by Blocking Fas-FasL Interactions.

One explanation for the poor CTL responses mounted by the pJ5-infected macaques is that SIV-infected CD4+ cells, which we have demonstrated to express FasL, paradoxically kill cognate cytotoxic T cells. If this is the case we should be able to restore CTL responses by blocking the interaction of FasL expressed on infected CD4+ T cells with Fas expressed on CTL.

We tested this hypothesis with a bulk culture CTL assay in the presence or absence of Fas-Fc fusion protein. No CTL responses were elicited from cells cultured with medium alone or soluble CD4 protein, in agreement with our previous results on the pJ5-infected macaques. However, in the presence of soluble Fas-Fc fusion protein a nef-specific CTL response was established (Fig. 7).


Fig. 7. Soluble Fas-Fc fusion protein regenerates CTL response from SIV pJ5-infected macaques. PBMCs were isolated from macaques (P93) 6 mo after infection and set up for bulk culture CTL in the presence or absence of either Fas-Fc fusion protein (10 µg/ml) or soluble CD4 (5 µg/ml) for 14 d. After washing the cells, the virus-specific CTL activities were determined as described in Materials and Methods. The data are representative of three seperate experiments.
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Discussion

Loss of functional immune cells is a hallmark of AIDS. This was initially thought to result from direct viral cytotoxicity on CD4+ T cells with a consequent loss of T cell help (35). However, it is now clear that a considerable loss of uninfected bystander lymphocytes occurs in HIV-infected individuals. Much of this loss is due to apoptosis occurring in both CD4+ and CD8+ T cells (18, 26, 32, 36). Why this happens is not understood.

To date, the most effective vaccination strategy in macaques has been the use of live attenuated nef mutant SIV such as pC8 (2, 4). Our results show that one possible contributing mechanism to such protection is the induction of strong virus-specific CTL responses with multiple specificities. Some CTL responses can be elicited from pJ5-infected macaques within 8 wk of infection (37), but at 3 mo these appear to be lost revealing a striking difference in the responses of the animals to challenge with pC8 and pJ5. In addition, the strong CTL activity observed in the protected animals correlates with a lower frequency of apoptotic cell death of both CD4+ and CD8+ T cells. Fas, which is upregulated in T cells from HIV+ patients is a candidate for the induction of apoptosis seen in the uninfected cells (26, 32). Our study in SIV corroborates these results showing increased expression of Fas in both CD4+ and CD8+ T cells. Interestingly, animals infected with nef-attenuated SIV express less Fas antigen on their cell surface. The mechanism by which uninfected T cells overexpress Fas antigen is unknown, but this may reflect the generalized state of immune activation seen in SIV/HIV infection.

FasL expression is tightly regulated being confined to activated lymphocytes, Sertoli cells, stromal cells of the anterior chamber of the eye, and neurons (22). The expression at these nonlymphoid sites of immune privilege suggests that FasL may play a role in protection from immunological attack (38). Indeed, it has recently been shown that allogeneic transplanted testes from gld mice that lack FasL expression are rapidly rejected (39). Tumor cells may also express FasL, gaining immune privilege and escaping an anti-tumor immune response (25, 40, 41). HIV has been shown to upregulate FasL expression on macrophages (42) and HIV tat/gp120 can enhance anti-CD3-induced apoptosis by increasing the expression of FasL on CD4+ cells (43). In our studies we have assessed the effects of FasL upregulation upon apoptosis and the course of infection in vivo. We demonstrate that freshly isolated PBMC show increased FasL expression and kill Fas-sensitive targets which is blocked by soluble Fas-Fc fusion protein or anti-FasL mAb. The activity of FasL is contained within the CD4+ population, possibly SIV-infected cells. Our demonstration at the protein level of FasL induction by SIV infection is consistent with the demonstration of FasL induction on HIV-infected CD4+ cells shown by RT-PCR (44). On the other hand, nef mutant SIV-infected cells do not upregulate FasL expression. The nef gene codes for a protein that is not essential for viral growth in vitro, but which is essential to the development of AIDS (45). Nef leads to the downregulation of CD4 expression and is believed to increase the state of T cell activation through interactions with proteins involved in cellular activation and signaling such as Src family tyrosine kinases (46). T cell activation via several modalities leads to an increase in FasL expression (33), so nef through enhancing T cell activation may similarly lead to the expression of FasL. The mechanisms underlying the failure of the nef-mutant SIV pC8 to induce FasL expression require clarification. In preliminary experiments, we have shown that full-length nef expression by vaccinia does not upregulate FasL. This may be due to either counter-activity induced by vaccinia gene products or other HIV/SIV genes may be involved.

We propose that the increased expression of FasL is the cause for the increased pathogenicity of wild-type SIV pJ5. The FasL expression by infected CD4+ cells can trigger apoptosis of virus-specific CTL, which themselves express Fas. This situation thus mimics the expression of FasL at sites of immune privilege, or the upregulation of FasL by certain tumors. In this way the virus can evade the immune response by preventing the development of an effective CTL response. The effective CTL response developed by macaques infected with pC8, which does not cause FasL expression in CD4+ cells, suggests that inhibition of the FasL activity on infected cells may restore CTL responses. This is indeed the case; our results show that incubation of cells from the infected macaque with soluble Fas leads to the generation of an efficient anti-nef CTL response. These results suggest a new therapeutic intervention in the treatment of SIV/HIV which we are testing on infected macaques in vivo.


Footnotes

Address correspondence to Xiao-Ning Xu, Molecular Immunology, Institute of Molecular Medicine, John Radcliffe Hospital, Oxford OX3 9DU, UK. Phone: 44-1865-222334; FAX: 44-1865-222502.

Received for publication 30 January 1997 and in revised form 24 March 1997.

   X.-N. Xu is a CARG Research Fellow supported by Australian Government, G.R. Screaton is a Clinician Scientist Fellow supported by Welcome Trust and Arthritis and Rheumatism Council, and R. Tan is a Samuel F. McLaughlin Fellow of Canada.
   1 Abbreviations used in this paper: FasL, Fas ligand; MID50, half-maximal macaque infectious dose; R10H, RPMI 1640 containing 10% fetal calf serum; SIV, simian immunodeficiency virus; TCID50, half-maximal tissue culture infectious dose.

We thank Peter Silvera, Rebecca Sangster, Jame Rose, Kirsty Silvera, Jenny Lines, and Caroline Arnold for technical assistance, Drs. Erling Rud and Martin Cranage for the SIV viruses, and Dr. David Jackson and Ulrich Gerth for expert help in preparation of Fas-Fc fusion protein. This study was supported by the MRC AIDS directed Programs.


References

1. Rud, E.W., M. Cranage, J. Yon, J. Quirk, L. Ogilvie, N. Cook, S. Webster, M. Dennis, and B.E. Clarke. 1994. Molecular and biological characterization of simian immunodeficiency virus macaque strain 32H proviral clones containing nef size variants. J. Gen. Virol. 75: 529-543 [Abstract].
2. Daniel, M.D., F. Kirchhoff, S.C. Czajak, P.K. Sehgal, and R.C. Desrosiers. 1992. Protective effects of a live attenuated SIV vaccine with a deletion in the nef gene. Science (Wash. DC). 258: 1938-1941 [Medline].
3. Deacon, N.J., A. Tsykin, A. Solomon, K. Smith, M. Ludford, Menting, D.J. Hooker, D.A. McPhee, A.L. Greenway, A. Ellett, C. Chatfield, et al . 1995. Genomic structure of an attenuated quasi species of HIV-1 from a blood transfusion donor and recipients. Science (Wash. DC). 270: 988-991 [Abstract].
4. Almond, N., K. Kent, M. Cranage, E. Rud, B. Clarke, and E.J. Stott. 1995. Protection by attenuated simian immunodeficiency virus in macaques against challenge with virus-infected cells. Lancet 345: 1342-1344 [Medline].
5. Rowland-Jones, S., R. Tan, and A. McMichael. 1997. The role of cellular immunity in protection against HIV infection. Adv. Immunol. In press.
6. Yasutomi, Y., K.A. Reimann, C.I. Lord, M.D. Miller, and N.L. Letvin. 1993. Simian immunodeficiency virus-specific CD8+ lymphocyte response in acutely infected rhesus monkeys. J. Virol. 67: 1707-1711 [Abstract].
7. Koup, R.A., J.T. Safrit, Y. Cao, C.A. Andrews, G. McLeod, W. Borkowsky, C. Farthing, and D.D. Ho. 1994. Temporal association of cellular immune responses with initial control of viremia in primary human immunodeficiency virus type 1 syndrome. J. Virol. 68: 4650-4655 [Abstract].
8. Borrow, P., H. Lewicki, B.H. Hahn, G.M. Shaw, and M.B. Oldstone. 1994. Virus-specific CD8+ cytotoxic T-lymphocyte activity associated with control of viremia in primary human immunodeficiency virus type 1 infection. J. Virol. 68: 6103-6110 [Abstract].
9. Carmichael, A., X. Jin, P. Sissons, and L. Borysiewicz. 1993. Quantitative analysis of the human immunodeficiency virus type 1 (HIV-1)-specific cytotoxic T lymphocyte (CTL) response at different stages of HIV-1 infection: differential CTL responses to HIV-1 and Epstein-Barr virus in late disease. J. Exp. Med. 177: 249-256 [Abstract].
10. Roederer, M., J.G. Dubs, M.T. Anderson, P.A. Raju, L.A. Herzenberg, and L.A. Herzenberg. 1995. CD8 naive T cell counts decrease progressively in HIV-infected adults. J. Clin. Invest. 95: 2061-2066 [Medline].
11. Rinaldo, C.J., L.A. Beltz, X.L. Huang, P. Gupta, Z. Fan, and D.R. Torpey. 1995. Anti-HIV type 1 cytotoxic T lymphocyte effector activity and disease progression in the first 8 years of HIV type 1 infection of homosexual men. Aids Res. Hum. Retroviruses 11: 481-489 [Medline].
12. Pantaleo, G., C. Graziosi, and A.S. Fauci. 1993. The immunopathogenesis of human immunodeficiency virus infection. N. Engl. J. Med. 328: 327-335 [Free Full Text].
13. Finkel, T.H., and N.K. Banda. 1994. Indirect mechanisms of HIV pathogenesis: how does HIV kill T cells? Curr. Opin. Immunol. 6: 605-615 [Medline].
14. Zinkernagel, R.M., and H. Hengartner. 1994. T-cell-mediated immunopathology versus direct cytolysis by virus: implications for HIV and AIDS. Immunol. Today. 15: 262-268 [Medline].
15. Nardelli, B., C.J. Gonzalez, M. Schechter, and F.T. Valentine. 1995. CD4+ blood lymphocytes are rapidly killed in vitro by contact with autologous human immunodeficiency virus-infected cells. Proc. Natl. Acad. Sci. USA. 92: 7312-7316 [Abstract].
16. Ameisen, J.C.. 1992. Programmed cell death and AIDS: from hypothesis to experiment. Immunol. Today. 13: 388-391 [Medline].
17. Estaquier, J., T. Idziorek, F. de Bels, F. Barre, Sinoussi, B. Hurtrel, A.M. Aubertin, A. Venet, M. Mehtali, E. Muchmore, P. Michel, et al . 1994. Programmed cell death and AIDS: significance of T-cell apoptosis in pathogenic and nonpathogenic primate lentiviral infections. Proc. Natl. Acad. Sci. USA. 91: 9431-9435 [Abstract/Free Full Text].
18. Meyaard, L., S.A. Otto, R.R. Jonker, M.J. Mijnster, R.P. Keet, and F. Miedema. 1992. Programmed death of T cells in HIV-1 infection. Science (Wash. DC). 257: 217-219 [Medline].
19. Finkel, T.H., G. Tudor, Williams, N.K. Banda, M.F. Cotton, T. Curiel, C. Monks, T.W. Baba, R.M. Ruprecht, and A. Kupfer. 1995. Apoptosis occurs predominantly in bystander cells and not in productively infected cells of HIV- and SIV-infected lymph nodes. Nature. Med. 1: 129-1134 [Medline].
20. Chinnaiyan, A.M., K. Orourke, G.L. Yu, R.H. Lyons, M. Garg, D.R. Duan, L. Xing, R. Gentz, J. Ni, and V.M. Dixit. 1996. Signal transduction by DR3, a death domain-containing receptor related to TNFR-1 and CD95. Science (Wash. DC). 274: 990-992 [Abstract/Free Full Text].
21. Kitson, J., T. Raven, Y.-P. Jiang, D.V. Goeddel, K.M. Giles, K.-T. Pun, C.J. Grinham, R. Brown, and S.N. Farrow. 1996. A death-domain-containing receptor that mediates apoptosis. Nature (Lond.). 384: 372-375 [Medline].
22. Nagata, S., and P. Golstein. 1995. The Fas death factor. Science (Wash. DC). 267: 1449-1456 [Medline].
23. Lynch, D.H., F. Ramsdell, and M.R. Alderson. 1995. Fas and FasL in the homeostatic regulation of immune responses. Immunol. Today 16: 569-574 [Medline].
24. Abbas, A.K.. 1996. Die and let live: eliminating dangerous lymphocytes. Cell 84: 655-657 [Medline].
25. Nagata, S.. 1996. Fas ligand and immune evasion. Nature. Med. 2: 1306-1307 [Medline].
26. Katsikis, P.D., E.S. Wunderlich, C.A. Smith, L.A. Herzenberg, and L.A. Herzenberg. 1995. Fas antigen stimulation induces marked apoptosis of T lymphocytes in human immunodeficiency virus-infected individuals. J. Exp. Med. 181: 2029-2036 [Abstract].
27. Silvestris, F., P. Cafforio, M.A. Frassanito, M. Tucci, A. Romito, S. Nagata, and F. Dammacco. 1996. Overexpression of Fas antigen on T cells in advanced HIV-1 infection: differential ligation constantly induces apoptosis. AIDS (Phila.). 10: 131-141 .
28. Tanaka, M., T. Suda, K. Haze, N. Nakamura, K. Sato, F. Kimura, K. Motoyoshi, M. Mizuki, S. Tagawa, S. Ohga, et al . 1996. Fas ligand in human serum. Nature. Med. 2: 317-322 [Medline].
29. Tanaka, M., T. Suda, T. Takahashi, and S. Nagata. 1995. Expression of the functional soluble form of human fas ligand in activated lymphocytes. EMBO (Eur. Mol. Biol. Organ.) J. 14: 1129-3115 [Abstract].
30. Gotch, F.M., R. Hovell, M. Delchambre, P. Silvera, and A.J. Mcmichael. 1991. Cytotoxic T-cell response to simian immunodeficiency virus by cynomolgus macaque monkeys immunized with recombinant vaccinia virus. AIDS (Phila.). 5: 317-320 .
31. Herrmann, M., H.-M. Lorenz, R. Voll, M. Grunke, W. Woith, and J.R. Kalden. 1994. A rapid and simple method for the isolation of apoptotic DNA fragments. Nucleic Acids Res. 22: 5506-5507 [Medline].
32. Lewis, D.E., D.S. Tang, A. Adu, Oppong, W. Schober, and J.R. Rodgers. 1994. Anergy and apoptosis in CD8+ T cells from HIV-infected persons. J. Immunol. 153: 412-420 [Abstract/Free Full Text].
33. Alderson, M.R., T.W. Tough, T. Davis, Smith, S. Braddy, B. Falk, K.A. Schooley, R.G. Goodwin, C.A. Smith, F. Ramsdell, and D.H. Lynch. 1995. Fas ligand mediates activation-induced cell death in human T lymphocytes. J. Exp. Med. 181: 71-77 [Abstract].
34. Agy, M.B., K. Foy, M.J. Gale, R.E. Benveniste, E.A. Clark, and M.G. Katze. 1991. Viral and cellular gene expression in CD4+ human lymphoid cell lines infected by the simian immunodeficiency virus, SIV/Mne. Virology 183: 170-180 [Medline].
35. Cohen, D.I., Y. Tani, H. Tian, E. Boone, L.E. Samelson, and H.C. Lane. 1992. Participation of tyrosine phosphorylation in the cytopathic effect of human immunodeficiency virus 1.  Science (Wash. DC). 256: 542-545 [Medline].
36. Groux, H., G. Torpier, D. Monte, Y. Mouton, A. Capron, and J.C. Ameisen. 1992. Activation-induced death by apoptosis in CD4+ T cells from human immunodeficiency virus-infected asymptomatic individuals. J. Exp. Med. 175: 331-340 [Abstract].
37. Gallimore, A., M. Cranage, N. Cook, N. Almond, J. Bootman, E. Rud, P. Silvera, M. Dennis, T. Corcoran, J. Stott, et al . 1995. Early suppression of SIV replication by CD8+ nef-specific cytotoxic T cells in vaccinated macaques. Nature. Med. 1: 1167-1173 [Medline].
38. Griffith, T.S., X.H. Yu, J.M. Herndon, D.R. Green, and T.A. Ferguson. 1996. CD95-induced apoptosis of lymphocytes in an immune privileged site induces immunological tolerance. Immunity 5: 7-16 [Medline].
39. Bellgrau, D., D. Gold, H. Selawry, J. Moore, A. Franzusoff, and R.C. Duke. 1995. A role for CD95 ligand in preventing graft rejection. Nature (Lond.). 377: 630-632 [Medline].
40. Hahne, M., D. Rimoldi, M. Schroter, P. Romero, M. Schreier, L.E. French, P. Schneider, T. Bornand, A. Fontana, D. Lienard, et al . 1996. Melanoma cell expression of Fas (Apo-1/CD95) ligand: implications for tumor immune escape. Science (Wash. DC). 274: 1363-1366 [Abstract/Free Full Text].
41. Strand, S., W.J. Hofmann, H. Hug, M. Muller, G. Otto, D. Strand, S.M. Mariani, W. Stremmel, P.H. Krammer, and P.R. Galle. 1996. Lymphocyte apoptosis induced by CD95 (APO-1/Fas) ligand-expressing tumor cells-A mechanism of immune evasion. Nature. Med. 2: 1361-1366 [Medline].
42. Badley, A.D., J.A. McElhinny, P.J. Leibson, D.H. Lynch, M.R. Alderson, and C.V. Paya. 1996. Upregulation of Fas ligand expression by human immunodeficiency virus in human macrophages mediates apoptosis of uninfected T lymphocytes. J. Virol. 70: 199-206 [Abstract].
43. Westendorp, M.O., R. Frank, C. Ochsenbauer, K. Stricker, J. Dhein, H. Walczak, K.M. Debatin, and P.H. Krammer. 1995. Sensitization of T cells to CD95-mediated apoptosis by HIV-1 Tat and gp120. Nature (Lond.). 375: 497-500 [Medline].
44. Mitra, D., M. Steiner, D.H. Lynch, L. Staiano, Coico, and J. Laurence. 1996. HIV-1 upregulates Fas ligand expression in CD4+ T cells in vitro and in vivo: association with Fas-mediated apoptosis and modulation by aurintricarboxylic acid. Immunology. 87: 581-585 [Medline].
45. Trono, D.. 1995. HIV accessory proteins: leading roles for the supporting cast. Cell 82: 189-192 [Medline].
46. Lee, C.-H., K. Saksela, U.A. Mirza, B.T. Chait, and J. Kuriyan. 1996. Crystal structure of the conserved core of HIV-1 nef complexed with a Src family SH3 domain. Cell 85: 931-942 [Medline].

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