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Journal of Virology, March 2005, p. 3748-3757, Vol. 79, No. 6
0022-538X/05/$08.00+0     doi:10.1128/JVI.79.6.3748-3757.2005
Copyright © 2005, American Society for Microbiology. All Rights Reserved.

Enhanced Cellular Immunity in Macaques following a Novel Peptide Immunotherapy

S. Chea,^1, C. J. Dale,^1, R. De Rose,¹ I. A. Ramshaw,² and S. J. Kent^1*

Department of Microbiology and Immunology, University of Melbourne, Victoria,¹ John Curtin School of Medical Research, Australian National University, Canberra, Australia²

Received 29 August 2004/ Accepted 21 October 2004

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

 
Advances in treating and preventing AIDS depend on understanding how human immunodeficiency virus (HIV) is eliminated in vivo and on the manipulation of effective immune responses to HIV. During the development of assays quantifying the elimination of fluorescent autologous cells coated with overlapping 15-mer simian immunodeficiency virus (SIV) or HIV-1 peptides, we made a remarkable observation: the reinfusion of macaque peripheral blood mononuclear cells, or even whole blood, pulsed with SIV and/or HIV peptides generated sharply enhanced SIV- and HIV-1-specific T-cell immunity. Strong, broad CD4⁺- and CD8⁺-T-cell responses could be enhanced simultaneously against peptide pools spanning 87% of all SIV- and HIV-1-expressed proteins—highly desirable characteristics of HIV-specific immunity. De novo hepatitis C virus-specific CD4⁺- and CD8⁺-T-cell responses were generated in macaques by the same method. This simple technique holds promise for the immunotherapy of HIV and other chronic viral infections.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

 
Control of persistent intracellular pathogens such as human immunodeficiency virus type 1 (HIV-1) requires cell-mediated immunity. CD8⁺ cytotoxic T lymphocytes (CTL) eliminate virus-infected cells by recognizing and lysing cells presenting viral peptides on cell surface major histocompatibility complex (MHC) class I molecules. HIV-1-specific CD8⁺-T-cell responses temporally correlate with reduced viremia during acute infection prior to the appearance of virus-specific antibodies (6, 20). Depletion of CD8⁺ T cells in macaques chronically infected with simian immunodeficiency virus (SIV) results in brisk rises in viremia (31). CD4⁺-T-helper-cell responses are required to maintain effective virus-specific CD8⁺-T-cell immunity. The generation of T-cell immune responses correlates with the control of viremia following challenge of macaques with chimeric SIV/HIV-1 (5, 22).

Measuring broad functional T-cell immunity in outbred subjects of unknown MHC genotype generally relies on the detection of antigen-specific gamma interferon (IFN-) production from T cells (17). In addition to secreting IFN-, an important cytokine mediator of cell-mediated immunity, T cells undergo proliferation and migration and release other effector molecules that facilitate their critical function during a viral infection: clearance of virus-infected cells in vivo. Previous murine studies have utilized fluorescent syngeneic splenocytes pulsed with known T-cell epitopes to sensitively measure virus-specific elimination in vivo (1, 7, 12, 25). No assessment of in vivo T-cell recognition and clearance of SIV/HIV-1 in nonhuman primates has previously been undertaken.

There is an urgent need to induce or enhance HIV-specific T-cell immunity to prevent or control HIV disease. Safely inducing SIV- or HIV-1-specific CD4⁺ and CD8⁺ T cells in outbred nonhuman primates or in humans by vaccination generally requires DNA and/or live vaccine vectors that express foreign antigens within cells (2, 5, 19, 33). Peptide or protein approaches to induce CD8⁺-T-cell responses in primates have previously required ex vivo expansion of sterile antigen-presenting cell fractions such as monocyte-derived dendritic cells (26, 34). Although monocyte-derived dendritic cells loaded with inactivated SIV virions show promise for the control of SIV infection in macaques, such techniques will not be widely applicable since prolonged sterile culture is required (23). More feasible immunotherapy methods are needed.

In this study, we describe a novel in vivo killing (IVK) assay using overlapping 15-mer peptide pools pulsed onto autologous fluorescently labeled peripheral blood mononuclear cells (PBMC) to measure SIV/HIV-1 vaccine-specific T-cell immunity in outbred pigtail macaques. When we analyzed SIV/HIV-1-specific immunity by standard techniques in the weeks following the IVK assays, a marked enhancement of virus-specific CD8⁺- and CD4⁺-T-cell immunity was induced.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

 
Animals. Colony-bred simian retrovirus type D-negative pigtail macaques (Macaca nemestrina, aged 2 to 4 years) were studied. Animals were anesthetized with ketamine (10 mg/kg of body weight, intramuscularly) prior to all procedures. Conditions and protocols were approved by a University of Melbourne animal ethics committee.

Preimmunizations. T-cell responses were induced in macaques by administering 1-mg doses of a DNA vaccine expressing HIV-1 or SIV Gag and Pol genes twice followed by a single 5 x 10⁷ PFU fowlpox virus (FPV) vaccine boost expressing similar HIV-1/SIV genes intramuscularly at 4-weekly intervals as previously described (8, 19).

Overlapping peptide pools. Next, 15-mer peptides (>80% purity) overlapping by 11 amino acids spanning the entire Gag (125 peptides), Pol (263 peptides), and Nef (21 peptides) proteins of SIV_mac239; Env (212 peptides) protein of HIV-1_MN; and Tat (23 peptides), Rev (21 peptides), and Vpu (19 peptides) proteins of HIV-1 consensus subtype B were pooled for each protein by solubilizing each 1 mg of peptide in 10 to 40 µl of dimethyl sulfoxide (DMSO; Sigma, St. Louis, Mo.). Following that, 18-mer peptides (>80% purity) overlapping by 11 amino acids encoding the entire protein length of hepatitis C virus (HCV) type 1a H77 were solubilized similarly into two pools of structural (peptides 1 through 116, encoding Core, E1, E2, and p7) and nonstructural (peptides 117 through 441, encoding NS2, NS3, NS4a, NS4b, NS5a, and NS5b) proteins. All peptides were kindly provided by the AIDS Research and Reference Reagent Program, Division of AIDS, National Institute of Allergy and Infectious Diseases, National Institutes of Health (NIH).

IVK assays. PBMC were isolated over Ficoll-Hypaque from 40 to 50 ml of blood. A total of 25 ml of sterile injectable saline was infused into the animals immediately after blood sampling. PBMC were resuspended in phosphate-buffered saline and divided into 0.5 ml containing 1 x 10⁷ to 2 x 10⁷ PBMC two or three times. Cells were pulsed with peptide pools (10 µg/ml) or an equivalent volume of DMSO for 60 to 90 min in a 37°C water bath with regular mixing. Each population was labeled with either 5-(and-6)-carboxyfluorescein diacetate, succinimidyl ester (CFSE^lo 0.5 µM, CFSE^hi 5 µM; Molecular Probes, Eugene, Ore.) or 5-(and-6)-chloromethyl SNARF-1-acetate (SNARF; 5 µM; Molecular Probes). Cells were mixed thoroughly and stained for 10 min at 37°C and washed twice. All peptide-pulsed labeled cells for each animal were pooled in saline and reinfused into the femoral vein on the same day. Prior to infusion, blood was sampled to confirm the absence and/or account for the presence of previously fluorescent-labeled cells in peripheral blood.

To quantitate the selective killing of peptide-pulsed cells in vivo, 3 ml of blood was sampled from the opposite femoral vein 5 min following infusion (to confirm equal numbers of recirculating labeled cells) and at 4 h and/or 16 to 20 h afterward. Red blood cells were lysed with fluorescence-activated cell sorter (FACS) lysing solution (Becton Dickinson, San Diego, Calif.), and 10⁶ gated lymphocytes were analyzed by flow cytometry (FACSort, CellQuest software; Becton Dickinson) for the presence of CFSE- or SNARF-labeled circulating cells. Lymph node mononuclear cells were studied following biopsy and isolation of cells 36 h following PBMC infusion. Killing of peptide-pulsed labeled cells was expressed as the proportion or percentage of target versus control-labeled cells relative to events analyzed 5 min following infusion.

For later experiments using peptide-pulsed autologous whole blood to stimulate immune responses, 9 ml of acid citrate dextrose-anticoagulated blood was collected, centrifuged to remove 3 to 4 ml of plasma, and pulsed with overlapping peptide pools (5 µg/peptide/ml) for 1 h at 37°C prior to intravenous reinfusion.

IFN- ELISPOT assay. Enumeration of antigen-specific IFN--secreting cells was assessed using a monkey IFN- enzyme-linked immunospot (ELISPOT) commercial kit (U-CyTech, Utrecht, The Netherlands) as previously described (10). All assays were performed in duplicate on fresh PBMC. Briefly, PBMC were stimulated with SIV or HIV-1 peptide pools (solubilized in DMSO at 1 µg/ml) or control wells with DMSO or with whole inactivated SIV or control microvesicles (5 µg/ml; kindly provided by Jeff Lifson, AIDS Vaccine Program, National Cancer Institute, Bethesda, Md.) for 18 h and then transferred to anti-IFN- monoclonal antibody-coated flat-bottomed 96-well plates and restimulated with antigen for 5 h. Positive control wells were stimulated with Staphylococcus enterotoxin B (Sigma). Cells were lysed, and wells were incubated with biotinylated anti-IFN- polyclonal rabbit antibody, followed by incubation with a gold-labeled antibiotin immunoglobulin G antibody. IFN- spots were developed and counted on an automated reader (AID, Strassberg, Germany). Results were normalized to antigen-specific IFN--secreting precursor frequency per 10⁶ PBMC, with positive results identified as >50 spot-forming cells/10⁶ PBMC and three or more times the background (30).

IFN- intracellular cytokine staining (ICS). Phenotyping and quantitation of antigen-specific intracellular IFN- expression in CD8⁺ or CD4⁺ T cells was assessed by flow cytometry as previously described (10, 24). Briefly, whole blood was stimulated with SIV, HIV-1, or HCV peptides (1 µg/ml) with costimulatory antibodies to human CD28 and CD49d (1 µg/ml; Becton Dickinson) for 7 h. Brefeldin A (10 µg/ml; Sigma) was added during the last 5 h of stimulation. T cells were phenotyped with anti-CD3-phycoerythrin, anti-CD4-fluorescein isothiocyanate, and anti-CD8-PerCP (SP34, L200, and Leu-2a, respectively; Becton Dickinson) by incubation for 20 to 30 min. Red blood cells were lysed, and the remaining cells were permeabilized with FACS Permeabilizing Solution 2 (Becton Dickinson), followed by incubation with anti-human IFN--allophycocyanin antibody (B7; Becton Dickinson). A total of 10⁵ gated lymphocytes were analyzed by flow cytometry. The percentage of antigen-specific gated cells expressing IFN- was assessed in both the CD3⁺ CD4⁺- and CD3⁺ CD8⁺-lymphocyte subsets.

HIV-1/SHIV infection of macaques. Macaques were infected with either (i) nonpathogenic HIV-1_LAI (10⁶ 50% tissue culture infective doses [TCID₅₀]) intravenously as previously described (9, 19), (ii) SHIV_mn229 intrarectally in two 0.5-ml doses over 2 days (total, 10⁵ TCID₅₀) as previously described (8, 10), or (iii) SHIV_SF162P3 atraumatically, intravaginally, in 1 ml twice over 2 days (total, 6 x 10³ TCID₅₀). SHIV_SF162P3 was obtained from the NIH AIDS Research and Reference Reagent Program and expanded on human PBMC as described previously (15, 16). SHIV viremia was quantified by reverse transcriptase-real-time PCR, and depletion of peripheral CD4⁺ T cells by flow cytometry was quantified as previously described (10).

In vivo CD8 depletion. To phenotype cells mediating the in vivo elimination of SHIV peptide-coated cells, the anti-CD8 cM-T807 monoclonal antibody (provided as a generous gift by Keith A. Reimann, Harvard Medical Center, Boston, Mass., obtained from the National Cell Culture Center) was administered subcutaneously (10 mg/kg) on day 0 and intravenously (5 mg/kg) on days 3 and 7 as previously described (31). CD8 T-cell depletion was confirmed and monitored by whole-blood staining with anti-CD8-fluorescein isothiocyanate (DK25; Dako Inc., Carpentaria, Calif.) and anti-CD3-phycoerythrin antibodies as previously described (10). Lack of binding interference between the two CD8 antibodies (cM-T807 and the DK25) was confirmed in vitro on pigtail PBMC (data not shown).

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

 
In vivo CTL killing. Initial experiments studied pigtail macaques (M. nemestrina) vaccinated with HIV-1 Gag-encoding DNA and attenuated FPV and subsequently challenged with nonpathogenic HIV-1_LAI. We and others have shown by ex vivo assays that this general immunization and challenge method generates high-level T-cell immunity in macaques (2, 8, 9, 14, 19, 27).

Virus-specific CTL effector activity is generally measured by the standard ex vivo chromium release assay, an insensitive, indirect measurement of the ability of T cells to clear virus in vivo. By infusing fluorescent autologous macaque PBMC pulsed with large pools of SIV and HIV-1 overlapping peptides, we were able to directly measure the clearance of HIV-1- or SHIV-peptide-expressing cells in vivo.

Equivalent numbers of circulating fluorescent cells were detected by flow cytometry 5 min after intravenous infusion (prior to potential in vivo elimination) (Fig. 1A). In an animal previously primed for HIV-1-specific immunity by sequential DNA and FPV vaccination, a 96% elimination of Gag-peptide-pulsed cells, in comparison to non-peptide-pulsed cells, was detected the following day—direct evidence of the elimination of Gag-expressing cells. In six animals not administered DNA and FPV vaccines, there was no significant killing of Gag-pulsed cells (data not shown).

View larger version (31K): [in this window] [in a new window]   FIG. 1. IVK of HIV-1 Gag-pulsed cells. Equal numbers of autologous PBMC pulsed either with a pool of overlapping HIV-1 Gag peptides (SNARF, red) or without Gag peptides (CFSE, green; control population) were infused intravenously. Circulating labeled cell numbers in the peripheral blood were identified by flow cytometry at various time points thereafter and are expressed as values relative to those of the control population. (A) Similar numbers of circulating Gag-pulsed and control cells are identified 5 min following infusion but selective depletion of the Gag-pulsed population occurs 20 h following infusion in an HIV-1 immune macaque. (B) Lymph node mononuclear cells examined for the loss of Gag-pulsed cells 36 h following infusion in an unimmunized macaque and a preimmune macaque are shown.

To examine the virus-specific cytotoxicity generated by DNA and FPV vaccines during a virulent lentivirus infection, we studied vaccinated animals subsequently challenged with SHIV_mn229, a highly pathogenic chimeric HIV-1_IIIB/SIV_mac239 virus (8, 10). T-cell immunity was again induced by immunization of animals with DNA and FPV vaccines expressing the shared SIV_mac239 gag and pol genes (8). Elimination of both Gag- and Pol-peptide-labeled cells was examined by infusing 3 populations of autologous cells: one labeled with SNARF (5 µM, pulsed with SIV Pol peptides), one labeled with a low concentration of CFSE (0.5 µM, pulsed with SIV Gag peptides), and a control population labeled with a high concentration of CFSE (5 µM, pulsed with either DMSO alone or SIV Nef peptides, an irrelevant peptide pool not expressed by the vaccines).

Immediately following infusion, all three labeled, equivalent-cell populations were distinctly identified (Fig. 2A). In a macaque (macaque H20) previously immunized with DNA and FPV vaccines encoding SIV gag and pol, elimination of Gag-pulsed cells (27%) was detected as early as 4 h after infusion (Fig. 2A). By 16 h, 76% elimination of Gag-pulsed cells was detected in this macaque. No IVK of Pol-labeled targets was observed in vaccinated macaques. No killing of Gag- or Pol-pulsed cells was detected in unvaccinated macaques.

View larger version (43K): [in this window] [in a new window]   FIG. 2. In vivo SHIV-specific killing after immunization and pathogenic SHIV infection. Flow cytometric analysis of macaque peripheral blood following infusion of PBMC pulsed with sets of overlapping SIV peptides: Pol (SNARF, red); Gag (CFSElo, green), and Nef or DMSO (CFSEhi, green; control population). Cell numbers are expressed as values relative to those of the control population. (A) Progressive elimination of Gag-pulsed cells in a DNA- and FPV-immunized animal was detected 4 and 16 h following infusion; no Gag or Pol-specific cytotoxicity was detected in an unimmunized naïve animal. (B) At 14 days after SHIV challenge, near-complete elimination of Gag- and Pol-pulsed cells in a previously immunized animal occurred.

View this table: [in this window] [in a new window]   TABLE 1. IVK of Gag- and Pol-pulsed cells after SHIV challenge and correlation with IFN- ELISPOT and ICS

View larger version (32K): [in this window] [in a new window]   FIG. 3. IVK mediated by CD8+ cells. (A) Depletion of CD8+ T cells () following administration of a CD8 depleting monoclonal antibody over 7 days (arrows) in immunized and SHIVmn229-challenged macaque H21 led to a brisk rise in SHIV viremia (). Repletion of CD8+ T cells correlated temporally with recontrol of viremia, in association with strong T-cell immunity as measured by ICS (bars) to Gag (CD4+ [] and CD8+ []) and Pol (CD4+ [] and CD8+ [hatched]). No Pol responses were assayed between weeks 18 and 33 post-SHIV challenge, and no Gag or Pol responses were assayed at week 8 post-SHIV challenge and between days 10 and 19 post-CD8+-T-cell depletion. (B) Flow cytometric analysis of IVK of infused PBMC pulsed with SIV peptides: Pol (SNARF, red); Gag (CFSElo, green), and DMSO (CFSEhi, green; control population) was performed on macaque H21 on day 9 of CD8 depletion. A similarly immunized and SHIVmn229-challenged but non-CD8-depleted macaque, H20, was assayed concurrently. Cell numbers are expressed as values relative to those of the control population.

Immunogenicity of peptide-pulsed autologous cells. We have previously shown that our DNA and FPV vaccines express Pol at low levels and do not induce the strong Pol-specific immune responses measured by ELISPOT and ICS (8), which correlated with the lack of Pol-specific killing observed by IVK following vaccination alone shown above. Interestingly, the three animals that generated very high levels of Pol-specific killing (H20, H21, and E22) early after SHIV challenge were the only animals that received an infusion of Pol-pulsed PBMC twice previously. We reasoned that immune recognition of the infused peptide-pulsed PBMC could stimulate or boost T-cell immunity. SHIV-specific immunity was therefore studied before and after cell infusion, first by measuring SHIV-specific IFN- secretion by ELISPOT assays (Fig. 4A).

View larger version (60K): [in this window] [in a new window]   FIG. 4. T-cell immunity measured by IFN- ELISPOT. (A) IFN- spot-forming cells responding to SIV Gag, Pol, and DMSO (control antigen) antigens in each well from naïve and SHIV-immunized macaques before and after infusion of Gag- and Pol-peptide-pulsed autologous PBMC. Numbers of positive spots in actual ELISPOT wells are shown. (B) T cells secreting IFN- in response to either SIV Gag peptides or whole inactivated SIV prior to () and 1 week following () infusion of peptide-pulsed autologous cells in two unimmunized macaques (E20 and E22) and four macaques previously immunized with DNA and FPV vaccines (B00, H8, H20, and H21).

To our surprise, T-cell immune responses to SIV Pol were also detected in a naïve animal (E22) not previously exposed to any vaccinations or SHIV infection following infusions of peptide-pulsed PBMC. This suggested that priming of responses can also be induced with this method.

Induction of CD4⁺- and CD8⁺-T-cell immunity. We next studied whether the infusion of peptide-pulsed autologous cells could enhance both CD4⁺- and CD8⁺-T-cell immune responses by ICS analysis in SHIV-infected macaques. Two macaques with vaccine-induced partial control of SHIV_mn229 37 weeks following challenge were restudied. Nonfluorescent PBMC pulsed with Gag and Pol peptides were infused, and SHIV-specific immunity was subsequently analyzed by ICS (Fig. 5A). A brisk rise in both CD4⁺ and CD8⁺ SHIV-specific T lymphocytes was observed following infusion with a mean peak increase of 8.5% Gag-specific and 1.3% Pol-specific CD4⁺ T lymphocytes (Fig. 5B). A mean peak increase of 1.1% Gag-specific and 0.27% Pol-specific CD8⁺ T lymphocytes was also observed following infusion.

View larger version (39K): [in this window] [in a new window]   FIG. 5. Induction of CD4+- and CD8+-T-cell immunity. SHIV-specific T-cell responses measured by IFN- ICS after infusion of SIV Gag- and Pol-peptide-pulsed PBMC and whole blood is shown. (A) Flow cytometric analysis of increased CD8+ and CD8– (CD4+) SIV Gag-specific T cells before (day 0) and after (day 17) infusion of peptide-pulsed PBMC in a previously immunized and SHIV-infected macaque. Percents CD3+ CD8+ and CD3+ CD4+ SIV Gag-specific lymphocytes are indicated in upper right and left quadrants, respectively. (B) Kinetic analysis of CD4+- and CD8+-T-cell responses to SIV Gag and Pol following infusion of Gag- and Pol-peptide-pulsed PBMC into two macaques previously immunized and challenged with SHIVmn229 (H8 [] and H20 []). (C) Analysis of T-cell responses following infusion of Gag- and Pol-peptide-pulsed whole blood in three macaques previously infected with SHIVsf162P3 (9E [], 23E [], and 24E [•]).

Multiple infusions of peptide-pulsed whole blood in SHIV viremic animals. These initial results suggest that multiple infusions of overlapping peptide-pulsed autologous cells might contribute to a greater rise in T-cell immunity. Further, since both Gag- and Pol-specific responses could be induced, we postulated that broad responses to additional structural and regulatory proteins could also be simultaneously elicited.

We then infused an animal chronically infected with SHIV_mn229 for 47 weeks with sustained but low-level viremia (3.9 log₁₀ RNA copies/ml) with fresh autologous SHIV-peptide-pulsed whole blood three times. Separate 9-ml aliquots of blood were pulsed with 15-mer peptide pools spanning (i) SIV Gag, (ii) SIV Pol, and (iii) HIV-1 Env, Tat, Rev, Vpu, and SIV Nef proteins (covering >87% of all SHIV proteins). A sequential boosting of both CD4⁺- and CD8⁺-T-cell immunity to all of the peptide pools infused was detected by ICS (Fig. 6A), with higher SHIV-specific responses consistently detected in the CD4⁺-T-cell subset. The immunogenicity was greatest for Gag, Pol, and Env proteins (each 125 peptides/pool) and less for the regulatory proteins Rev, Tat, Vpu, and Nef (84 peptides), which may reflect the smaller number of epitopes in this pool recognized by this animal.

View larger version (25K): [in this window] [in a new window]   FIG. 6. T-cell immunity to induced SHIV and HCV. Multiple infusions of SHIV- or HCV-peptide-pulsed whole blood were administered to chronically SHIVmn229-infected macaques. (A) Increased SIV Gag, Pol, HIV-1 Env, and HIV-1 Tat-Rev-Vpu-SIV-Nef-specific CD4+ (•)- and CD8+ ()-T-cell responses by ICS following three monthly infusions of SHIV peptide-pulsed whole blood (arrows) in a macaque with partial control of SHIVmn229 viremia. (B) Correlation between baseline plasma SHIV viral load (prior to infusion) and induction of total SHIV-specific CD4+-T-cell responses following SHIV-peptide-pulsed whole-blood infusion in five macaques previously infected with SHIVmn229. (C) Induction of CD4+ (•)- and CD8+ ()-T-cell responses to both structural and nonstructural HCV proteins following three monthly infusions of HCV-peptide-pulsed whole blood (arrows) in a macaque with controlled SHIVmn229 viremia.

Induction of HCV-specific T-cell immunity with peptide-pulsed whole blood. Last, we asked whether de novo T-cell immunity to HCV, another important chronic viral pathogen, could be generated utilizing peptide-pulsed whole blood. A macaque chronically infected with SHIV_mn229 with controlled SHIV viremia prior to infusion (<3.2 log₁₀ RNA copies/ml) was administered three doses of fresh autologous whole blood pulsed with two HCV 18-mer peptide pools spanning (i) structural proteins Core, E1, E2, and p7 (116 total peptides) and (ii) nonstructural proteins NS2-5b (325 total peptides). Induction of new CD4⁺- and CD8⁺-T-cell responses to both structural and nonstructural HCV proteins was detected (Fig. 6C). HCV-specific responses were highest in the CD4⁺-T-cell subset and were greater for the structural HCV peptide pool than those for the larger nonstructural peptide pool. This may be due to a greater number of epitopes present in the structural pool or the potential for antigenic competition within the very large nonstructural peptide pool. These results should be interpreted cautiously, as only one macaque with a low SHIV viral load and thought likely to respond to the peptide-pulsed cell immunizations was available to study.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

 
This series of macaque studies had three important findings. First, we found that an IVK assay can be utilized in outbred macaques to directly measure CTL responses by clearance of HIV-1- or SIV-peptide-pulsed fluorescent autologous cells. Soon after SHIV challenge, near-complete clearance of Gag- and Pol-labeled cells was demonstrated in previously vaccinated macaques. Interestingly, despite such very high levels of virus elimination, latent lentiviral infection is still established in macaques challenged with SHIV. Taken together with the observed recrudescence of viremia following CD8 depletion, these findings illustrate the potential difficulties of the long-term control of primate lentiviral infection by T-cell responses alone.

Second, we demonstrated that infusion of autologous PBMC or whole blood pulsed for 1 h with large sets of overlapping SHIV 15-mer peptides boosts broadly reactive SHIV-specific immunity in outbred macaques primed for SHIV-specific immunity by vaccination or SHIV infection. Both CD4⁺ and CD8⁺ SHIV-specific T-cell immune responses were highly elevated following the infusion of peptide-pulsed cells, even in SHIV-infected animals. These findings were repeated in four separate macaque experiments involving 16 animals. Not surprisingly, SHIV viremia levels inversely correlated with the ability to boost SHIV-specific T-cell responses, providing parameters with which to approach human studies.

Third, we demonstrated that autologous PBMC or whole blood pulsed with either 15-mer SHIV or 18-mer HCV peptides can, at least in the small numbers of animals studied in this report, prime broad de novo CD4⁺- and CD8⁺-T-cell responses in immunocompetent macaques. Taken together, these studies suggest that the use of a relatively simple and safe procedure of pulsing whole blood for 1 h with pools of overlapping peptides spanning whole proteins or indeed the entire protein sequence of a pathogen, is a useful immunotherapy technology. Large numbers of fresh antigen-loaded cells are delivered widely to immune compartments. Minimal or no antigen processing is required, circumventing many virus-specific strategies to avoid effective antigen presentation. The short incubation period, lack of requirement to isolate cell subpopulations and/or extensive ex vivo culture (23), and lack of requirement to define the MHC genotypes of the host or epitope specificity of the pathogen are significant, practical advantages of this immunotherapy approach. We have termed this immunotherapy technology overlapping peptide-pulsed autologous cells.

Although HIV-1- or HCV-specific CD4⁺- and CD8⁺-T-cell responses assist the control of these chronic virus infections, assessing the utility of manipulating T-cell immunity by infusing overlapping-peptide-pulsed cells for controlling viral replication requires larger nonhuman primate or human studies. Many of the animals studied to date have had low or undetectable viral loads, with no power to detect significant reduction in viremia. The animals studied with high viral loads have had poor induction of immunity, reflecting their immunodeficiency and consistency with other vaccine studies in SIV/HIV-infected monkeys or HIV-1-infected humans (13). It was of interest that early, complete control of SHIV viremia was observed in one DNA- and FPV-vaccinated animal (H21) boosted twice with Gag- and Pol-labeled cells. The control of viremia in this animal was mediated primarily by CD8⁺ T cells, rather than neutralizing antibodies (2), since high-level SHIV viremia reemerged promptly following CD8 depletion. Recontrol of viremia was associated with CD8⁺-T-cell repletion and dramatically high levels of both CD4⁺ and CD8⁺ SHIV-specific T-cell immunity.

Several additional studies are immediately suggested by these results. First, we are endeavoring to adapt the IVK assay to measure the clearance of SHIV-infected, rather than SHIV-peptide-pulsed, cells. Although technically challenging, such studies could dissect additional important roles of non-CD4 and -CD8 T-cell components, such as natural killer cells, natural killer T cells, neutrophils, and antibody in the clearance of SHIV-infected cells. Second, it was of interest that a higher proportion of CD4⁺ T cells than that of CD8⁺ T cells was stimulated by this immunotherapy technique using 15- to 18-mer overlapping peptides. The preponderance of CD4 over CD8 T-cell responses was consistent across multiple antigens and time points in all seven animals studied by ICS in this report. Although potentially highly desirable in HIV-1- and HCV-infected subjects where virus-specific CD4⁺ T cells are commonly absent or dysfunctional (11), other pathogens may require a more balanced or predominant CD8⁺-T-cell response. Utilizing smaller peptides or pulsing for longer time periods may facilitate more efficient binding with MHC class I molecules and CD8⁺-T-cell stimulation. Third, we are planning studies to compare the administration of peptide-pulsed PBMC, peptide-pulsed whole blood, and peptide-pulsed-expanded-dendritic-cell populations for their ability to assist the clearance of acute SIV viremia in macaques. The very high levels of antigen-specific responses expanded by the use of PBMC or whole blood (up to 13.1 and 2.3% of all CD4⁺ and CD8⁺ T cells, respectively) suggest the responses induced could be at least equivalent to employing more complicated and less accessible modalities of expanding antigen-presenting cell populations extensively ex vivo.

Last, immunotherapy clinical trials for HIV and HCV by using autologous whole blood pulsed with overlapping viral peptides are suggested by these studies. Since T-cell responses are associated with the control of HIV-1 and clearance (and cure) of HCV (21), the ability to induce and expand CD4⁺- and CD8⁺-T-cell populations across most or all virus proteins could be highly advantageous. Our results, consistently demonstrating sharply enhanced T-cell immunity in macaques with controlled SHIV viremia, suggest the testable hypothesis that the enhancement of T-cell immunity in humans with HIV-1 viremia controlled by antiretroviral therapy could facilitate improved control upon withdrawal of drug therapy (28).

	ACKNOWLEDGMENTS

 
We thank J. Medveczky, I. Stratov, C. Fernandez, M. Smith, and S. Grueninger for technical assistance; R. Sydenham, A. Sydenham, L. Protyniak, and K. Szalnowski for animal care; K. Reimann for providing the depleting CD8 antibody (produced under NIH award R24 RR16001); M. Law for statistical analyses; and F. Carbone, S. Mueller, R. Coles, J. McCluskey, K. Walsh, W. Kimpton, and R. Cahill for helpful discussions.

	FOOTNOTES

 
* Corresponding author. Mailing address: Department of Microbiology and Immunology, University of Melbourne, Victoria 3010, Australia. Phone: 61383449939. Fax: 61383443846. E-mail: skent{at}unimelb.edu.au.

S.C. and C.J.D. contributed equally to this work.

	REFERENCES

Top Abstract Introduction Materials and Methods Results Discussion References

 

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