The Simian Immunodeficiency Virus {Delta}nef Vaccine, after Application to the Tonsils of Rhesus Macaques, Replicates Primarily within CD4+ T Cells and Elicits a Local Perforin-Positive CD8+ T-Cell Response

Deletion of the nef gene from simian immunodeficiency virus(SIV) strain SIVmac239 yields a virus that undergoes attenuatedgrowth in rhesus macaques and offers substantial protectionagainst a subsequent challenge with some SIV wild-type viruses.We used a recently described model to identify sites in whichthe SIV ${Delta}$ nef vaccine strain replicates and elicits immunity invivo. A high dose of SIV ${Delta}$ nef was applied to the palatine andlingual tonsils, where it replicated vigorously in this portalof entry at 7 days. Within 2 weeks, the virus had spread andwas replicating actively in axillary lymph nodes, primarilyin extrafollicular T-cell-rich regions but also in germinalcenters. At this time, large numbers of perforin-positive cells,both CD8⁺ T cells and CD3-negative presumptive natural killercells, were found in the tonsil and axillary lymph nodes. Thenumber of infected cells and perforin-positive cells then fell.When autopsy studies were carried out at 26 weeks, only 1 to3 cells hybridized for viral RNA per section of lymphoid tissue.Nevertheless, infected cells were detected chronically in mostlymphoid organs, where the titers of infectious virus couldexceed by a log or more the titers in blood. Immunocytochemicallabeling at the early active stages of infection showed thatcells expressing SIV ${Delta}$ nef RNA were CD4⁺ T lymphocytes. A majorityof infected cells were not in the active cell cycle, since 60to 70% of the RNA-positive cells in tissue sections lacked theKi-67 cell cycle antigen, and both Ki-67-positive and -negativecells had similar grain counts for viral RNA. Macrophages anddendritic cells, identified with a panel of monoclonal antibodiesto these cells, were rarely infected. We conclude that the attenuatedgrowth and protection observed with the SIV ${Delta}$ nef vaccine straindoes not require that the virus shift its characteristic siteof replication, the CD4⁺ T lymphocyte. In fact, this immunodeficiencyvirus can replicate actively in CD4⁺ T cells prior to beingcontained by the host, at least in part by a strong killer cellresponse that is generated acutely in the infected lymph nodes.

INTRODUCTION

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Introduction

The simian immunodeficiency virus (SIV), when deleted of itsnef gene (SIV ${Delta}$ nef), exhibits two major features in the rhesusmacaque. First, virus replication is greatly attenuated in mostmonkeys (5, 18–20). Second, infection with the ${Delta}$ nef strainof SIVmac239 protects most monkeys against challenge with SIVmac239and -251 (7, 8, 19, 30). Nevertheless, the SIV ${Delta}$ nef vaccine strainhas considerable replicative potential. In vitro, the vaccinestrain replicates similarly to wild-type SIV in activated Tcells and T cells that are cocultured with mature dendriticcells (17, 22). In vivo, upon vaccination with SIV ${Delta}$ nef, the virusreaches infectious titers that are 1 to 10% of those found withwild-type SIV; these titers then subside to a low set point(5).

We have now investigated the cellular sites of acute and chronicinfection with SIV ${Delta}$ nef in vivo to better understand its lowerlevel of replication relative to the wild type and its capacityto act as a vaccine. We wanted to determine if the absence ofthe nef gene alters the site of SIV replication in vivo fromCD4⁺ T cells to dendritic cells and macrophages and whetherthis resulted in less active virus replication but more effectiveimmune stimulation. SIV-specific CD4⁺ (11, 30) and CD8⁺ (38)immune responses have been documented in the blood during chronicinfection with SIV ${Delta}$ nef, and furthermore, temporary depletionof CD8⁺ T cells results in a rapid increase in viral RNA inthe plasma (23). Therefore, infection with this attenuated vaccinestrain most likely represents a "battleground" in which thereis ongoing virus replication and immune-based resistance, butwhere is the virus replicating? Chakrabarti et al. showed thatinfected cells are found in lymphoid tissues (5), but thesecells remain to be defined.

To pursue these questions, we have used a recently describedsystem in which infection is initiated by atraumatic applicationof SIV to the oral mucosa-associated lymphoid tissue (MALT),both the palatine and lingual tonsils (31). It is known thatSIV is highly infectious via the oral route (3, 27). By applyingvirus directly to the tonsil, it becomes feasible to directlyanalyze the site of primary infection and its spread to otherlymphoid organs. Application of vaccines to the oral MALT mayalso facilitate vaccination of adult and pediatric populations,with the potential to produce stronger mucosal immunity. Elsewhere(unpublished data) we will show that tonsillar application ofSIV ${Delta}$ nef in fact provides protection against a subsequent tonsillarchallenge with SIVmac251.

Here we studied two animals at early time points, 4 and 7 daysafter tonsillar application of SIV ${Delta}$ nef, and three animals atboth 2 and 26 weeks to identify sites in which the vaccine virusreplicates and spreads. During acute infection and spread, manyinfected cells were evident in lymphoid tissues. CD4⁺ T cellswere clearly the dominant sites for vaccine replication, butin these infected lymph nodes, there was a marked expansionof perforin-positive, cytolytic lymphocytes. Chronically, infectiousvirus was recovered from most lymphoid tissues, and infectedcells were observed in tissue sections. These findings add tothe evidence that an infected host can contain a significantlevel of virus replication in T cells, even after an initialperiod of active acute SIV replication and spread.

MATERIALS AND METHODS

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Materials and Methods

Animals and virus inoculation. Juvenile and young adult rhesus monkeys (Macaca mulatta) ofIndian origin were bred at the German Primate Centre (DeutschesPrimatenzentrum) or imported from the United States (LaboratoryAnimal Breeder & Services, Yemassee, N.C.). Animal carewas in accordance with guidelines of the German Primate Centre.Monkeys were of either sex, had a body weight of 4.5 to 6 kg,and were antibody negative for simian T-lymphotropic virus type1, simian D-type retrovirus, and SIV. Animals were caged individuallyand monitored as described (30).

Virus inoculation, physical examination, and bleeding were performedunder ketamine anesthesia, while removal of peripheral lymphnodes used deeper anesthesia via a combined injection of ketamine,xylazine, and atropine. The infecting virus was the attenuatedSIV nef deletion mutant SIV ${Delta}$ NU, in which 513 bp had been deletedfrom the nef gene and the U3 region of SIVmac239 (15). For thepreparation of our virus stock, supernatant from freshly transfectedCEMx174 cells was harvested and used to infect fresh monkeyperipheral blood mononuclear cells (PBMCs). The virus stockhad an in vitro titer of 10^6.3 median tissue culture infectiousdoses (TCID₅₀) in the human T-cell line C81-66. Applicationof SIV ${Delta}$ NU to the palatine and lingual tonsils was performed asdescribed (31), using ${approx}$ 10⁵ TCID₅₀.

Determination of virus load and serology. Cell-associated virus loads were determined in a limiting dilutioncoculture assay with mononuclear cells from blood and lymphoidorgans as described before (30, 31). Viral RNA in plasma wasdetermined by a quantitative RNA-PCR (33). The detection limitof this assay is 40 RNA equivalents per ml of plasma. SIV-specificserum antibodies were detected by Western blotting (32).

In situ hybridization. The in situ hybridization was performed on either paraffin orcryostat sections as described previously (34). Briefly, 5-µmsections were cut onto slides coated with 3-aminopropyltriethosilane.Frozen sections were fixed in 4% paraformaldehyde for 30 minand subjected to in situ hybridization. Dewaxed paraffin sectionswere either boiled in a domestic pressure cooker in citratebuffer (pH 6.0) for 5 min or treated with proteinase K (0.01mg/ml) for 8 min at room temperature and subjected to in situhybridization to detect viral RNA.

We used a ³⁵S-labeled, single-stranded antisense RNA probe ofSIVmac239 (Lofstrand Labs, Gaithersburg, Md.). The probe wascomposed of fragments of 1.4 to 2.7 kb, which collectively representapproximately 90% of the SIV genome. The specific activity ofthe probe was 2 x 10⁶ dpm of probe/ml. The hybridization wasperformed overnight at 45°C in a moist chamber. The slideswere washed, digested with RNase (Boehringer Mannheim GmbH,Mannheim, Germany) at 37°C for 40 min, and washed again.Then the slides were dipped into photo emulsion (NTB2; Kodak,Rochester, N.Y.), exposed for 3 to 7 days, developed, counterstainedwith Hemalaun, and mounted. As a positive control, cytospinpreparations of SIV-infected PBMCs were used. As a negativecontrol, sections were hybridized with a ³⁵S-labeled sense probe.The sections were examined with a microscope equipped with epiluminescentillumination (Axiophot; Carl Zeiss Inc., Jena, Germany). Cellswere considered positive for viral gene expression if the graincount was more than six times the background.

Immunocytochemistry. Immunocytochemistry was performed by the alkaline phosphatase-anti-alkalinephosphatase (APAAP) and peroxidase methods. Paraffin-treatedor frozen sections were incubated with primary antibodies todefined cellular antigens and perforin as summarized in Table1. The immunolabeling was performed before in situ hybridization.To identify the perforin-positive cells, immunohistochemicaldouble labeling was made on paraffin-treated or frozen sections.Dewaxed paraffin sections were placed in a domestic pressurecooker containing 1 mM EDTA (pH 8), boiled for 7 min, and chilledto room temperature. The sections were incubated with the primaryantibody, anti-CD4 (Novocastra), anti-CD3, or Ki-67, overnight.Binding of anti-CD3 was detected with the peroxidase-antiperoxidasetechnique, and binding of the other antibodies was detectedwith the APAAP method using either New Fuchsin as the red chromogenor Fast Blue salt, giving a blue reaction product. The sectionswere than heat treated again for 15 min and incubated with antibodyto perforin overnight, followed by visualization with the APAAPmethod.

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TABLE 1. Antibodies used in the present study

The perforin-containing CD8⁺ T-cell subset was detected on frozensections. These were fixed in acetone and treated with a ready-to-useperoxidase blocking reagent (Dako) for 10 min. After rinsingin phosphate-buffered saline, the sections were incubated witha mixture of mouse anti-CD8 and rat antiperforin antibodies.The sections were fixed in 4% paraformaldehyde and incubatedwith a biotinylated rabbit anti-mouse immunoglobulin (Ig) (Dako).After incubation with the StreptAB complex/horseradish peroxidase(Dako), the CD8⁺ cells were visualized with 3-amino-9-ethylcarbazole(Sigma-Aldrich, St. Louis, Mo.). To detect binding of antiperforin,the sections were incubated with an anti-rat Ig secondary antibodyfollowed by the tertiary antibody (rat APAAP; Dako) and visualizedwith Fast Blue salt.

RESULTS

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Results

Recovery of infectious virus from the lymphoid tissues of monkeys vaccinated with SIV ${Delta}$ nef via the tonsillar route. A high dose of SIV ${Delta}$ nef ( ${approx}$ 10⁵ infectious units) was applied tothe palatine tonsils and the back of the tongue (lingual tonsils)of five animals. Three of five animals underwent peripherallymph node biopsies (axillary lymph nodes) at 2 weeks and bloodsampling at several time points, and the animals were euthanizedat 26 weeks. In these monkeys, we observed an acute burst ofvirus replication (Fig.. 1A), peaking at a level that was similarto the amount of infectious cell-associated virus found in animalsinfected with wild-type virus. By contrast, peak levels of viralRNA in plasma were about 10% of those measured in SIV wild-type-infectedanimals (Fig.. 1B). The results with the tonsillar route ofvaccination were similar to those observed after intravenousSIV ${Delta}$ nef infection, i.e., a burst of replication followed by adecay in viremia to a low set point (5, 8).

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FIG. 1. Virus load over time in the blood of rhesus macaques after tonsillar infection with SIV ${Delta}$ nef. (A) Cell-associated virus in PBMCs was determined by a limiting-dilution coculture technique, and the endpoint was calculated. Virus loads are expressed as the number of infectious cells per 10⁶ PBMCs. (B) Levels of viral RNA in plasma measured by quantitative reverse transcription-PCR and expressed as RNA equivalents per ml. The detection limit of this assay is 40 RNA equivalents per ml. Individual monkeys are indicated by four-digit numbers.

The lymphoid tissues were examined from the three chronicallyinfected animals as well as two monkeys euthanized acutely 4and 7 days after infection (Fig. 2). In the latter animals,the highest titers of infectious virus were measured primarilyat the portal of entry, the tonsils (Fig. 2). Actually, theinfection of the tonsils was focal in nature, since separateportions of the tonsil could have very different extents ofinfection, as assessed by virologic and histologic (in situhybridization of viral RNA) criteria (not shown). For the chronicallyinfected monkeys assayed at 26 weeks, infectious virus was foundin almost all peripheral lymphoid tissues (Fig. 2). The titersof virus in chronically infected animals varied considerablyfrom one organ to another, but it was evident that infectioncould be comparably active in the tonsillar site of entry andthe sites to which the virus had spread. Furthermore, the titersin lymphoid tissues were generally much higher than in blood(compare Fig. 2 with Fig. 1A). We conclude that a high doseof the SIV ${Delta}$ nef vaccine strain undergoes active replication acutely,spreads from one lymphoid organ to another, and replicates chronicallyat low levels in lymphoid tissues. However, the extent of replicationof the vaccine is much greater in lymphoid tissues than in blood.

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FIG. 2. Cell-associated virus load in lymphoid organs and blood of rhesus macaques during acute infection (4 and 7 days postinfection, upper two panels) with attenuated SIV ${Delta}$ nef and in the chronic stage (26 weeks, lower three panels). Mononuclear cell suspensions from each organ and the blood were prepared, and infectious units were determined as described for Fig. 1. Missing bars mean that no virus could be isolated; nd means the organ was not obtained; ne means the culture could not be evaluated because of contamination; the asterisks indicate that the endpoint was not reached. dpi, days postinfection; wpi, weeks postinfection; Ln, lymph node; tons, tonsil; cervic, cervical; retrophar, retropharyngeal; submand, submandibular; axill, axillary; mesent, mesenteric; Peyer’s, Peyer’s patches. Individual monkeys are indicated on the right of each panel by Mm (for Macaca mulatta) and four-digit numbers.

Tempo and spread of the SIV ${Delta}$ nef vaccine strain in sections of lymphoid tissues. (i) Studies at 4 and 7 days. Following in situ hybridization of tonsil sections with radiolabeledantisense RNA probes, the day 4 animal showed only a few infectedcells (Table 2). In contrast, prior studies with much lowerdoses (about 2%) of wild-type SIV showed active infection atthe portal of entry by day 4 (31) (Table 2). This is consistentwith the fact that SIV ${Delta}$ nef exhibits attenuated growth propertiesin vivo (15) even in the highly permissive tonsil. At day 7,extensive infection (19 SIV RNA⁺ cells/mm² of tissue) with thevaccine strain was evident both in the germinal centers of thetonsil and in extrafollicular regions (Table 2, Fig.. 3A). Sinceday 7 is well before the time of seroconversion (3 to 4 weeks),germinal center cells can be infected in the absence of antibody-trappedvirus.

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TABLE 2. Frequency of SIV ${Delta}$ nef or SIVmac251 RNA-positive cells in lymphoid tissue

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FIG. 3. Active replication and spread of SIV ${Delta}$ nef following infection via the tonsil. Lymphoid tissues were examined by in situ hybridization with ³⁵S-labeled antisense probes (labeled cells were not found with the control sense probe; not shown). Cells expressing viral RNA appear black (A, B, and D) or green (C). (A) The tonsil during acute infection, 1 week after infection with SIV ${Delta}$ nef. Many RNA -positive cells (black) are in the extrafollicular T-cell-rich regions but are also found in germinal centers (GC). (B) Axillary lymph nodes, to which infection has spread at 2 weeks, contain many infected cells, including in the germinal centers. (C and D) Mesenteric node and auxiliary node 26 weeks after infection contain a few but clear-cut (arrows) RNA-positive cells, typically in the germinal centers.

We observed some spread of SIV ${Delta}$ nef to lymph nodes as early asday 4 by histology and also with the virus isolation coculturetechnique. However, 10-fold-less virus, based on the numberof positive cells by in situ hybridization, was present in theretropharyngeal lymph nodes that drain the tonsil than at theportal of virus entry. More distant lymph nodes, the spleen,and MALT showed either no signs of virus replication or onlyminimal virus production (<0.1 cell/mm²).

(ii) Studies at 2 weeks. For the three long-term-infected animals, we took axillary lymphnode biopsies at 2 weeks to look for the early spread of infectionprior to seroconversion. All three axillary nodes were infected,with two of them having numerous RNA-positive cells by in situhybridization (Table 2, Fig. 3B). The replication was similarin magnitude to that observed in the tonsil at day 7 (Table2).

(iii) Studies at 26 weeks. At autopsy at 26 weeks, infected cells were noted in many peripherallymphoid tissues, including the spleen and gut. These cellswere mainly found in the germinal centers (Table 2 and Fig.3C and D, arrows). One chronically infected monkey even replicatedinfectious virus in the thymus at a low level. This animal presentedwith the highest virus load in lymphoid tissue compared to thatobserved in the others. No infection was found in the liver,kidneys, or lamina propria of the intestine. The frequency ofinfected cells in the lymph nodes was much less than that observedacutely at the site of entry (tonsils) or spread (axillary lymphnodes) (compare Fig. 3C and D with Fig. 3A and B). Morphologically,every virus-positive cell resembled a lymphocyte. The remarkabledrop in infected CD4⁺ T cells means that, following applicationof SIV ${Delta}$ nef, the replication and spread of virus from CD4⁺ lymphocyteswere successfully contained by the host.

Of interest was the nearly complete absence of virus or RNAtrapping by follicular dendritic cells. Bound SIV ${Delta}$ nef RNA wasabsent in the three animals studied at 26 weeks and extensivelysampled (tonsils, lymph nodes, spleen, and MALT; Fig. 3C and D).The absence of trapping was in part unexpected, since allanimals seroconverted and remained persistently seropositiveduring the course of this study. Also, plasma virus levels wereabove the limit of detection (Fig. 1B), and a low level of virusreplication was evident in some of the germinal centers (Fig.3C and D).

Another feature of infection with the SIV ${Delta}$ nef vaccine strainwas its focal nature in chronically infected lymph nodes. Occasionalgerminal centers could have several infected cells, while mostothers in the field had none (Fig. 3D). This is consistent withprior data that immunodeficiency viruses seed germinal centersunder limiting dilution conditions, and then virus spreads toother cells locally within the environment of the germinal center(6).

Identification by immunolabeling of the types of cells infected with SIV ${Delta}$ nef. Tissue sections were immunolabeled with a panel of monoclonalantibodies (Table 1) prior to in situ hybridization for SIVRNA. The antibodies recognized T cells (CD4), macrophages (sialoadhesin/CD169and macrosialin/CD68), and dendritic cells (Langerin/CD207,DC-LAMP/CD208, CD1a, and CD83). At the site of entry, i.e.,the crypt lymphoepithelium of the tonsils, the infected cellswere CD4⁺ and had lymphoid morphology (Fig. 4A), which was alsothe case in the lymph nodes to which the infection had spreadacutely at 2 weeks (Fig. 4B and C).

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FIG. 4. SIV ${Delta}$ nef primarily replicates in CD4⁺ T cells in lymphoid nodes. Tissue sections from lymph node (LN) and tonsil were labeled with the indicated monoclonal antibodies using an immunoperoxidase method (red color) and by in situ hybridization (black) to visualize RNA-positive cells. (A) Two infected CD4⁺ cells (arrows) in the lymphoepithelium of the acutely infected tonsil at 1 week. (B and C) Low- and high-power views of peripheral lymph nodes at 2 weeks to show labeling of infected cells for the CD4 T-cell marker (arrows). (D to F) Double labeling for CD1a (D), DC-LAMP/CD208 (E), and CD68 (F). Most infected cells are negative. Infected T cells can be found close to noninfected dendritic cells (E, arrows). An occasional CD68-positive cell is infected (F, arrow).

As illustrated in Fig. 4D to F, it was difficult to identifyinfected cells that were labeled with antibodies to dendriticcells and macrophages, although in rare instances infected cellswere found to be labeled for either CD1a, CD68 (Fig.. 4F, arrow)or CD169. Interestingly, infected cells could be juxtaposedto noninfected, more mature dendritic cells carrying the DC-LAMPmarker (Fig.. 4E, arrows), consistent with in vitro data thatmature dendritic cells are able to drive the replication ofSIV ${Delta}$ nef in T cells (17, 22). In summary, the predominant sitefor replication at the portals of entry and spread of the SIVvaccine strain is the CD4⁺ T cell, much the same as wild-typeSIV (31).

Majority of infected CD4⁺ T cells do not express the Ki-67 cell cycle antigen. It has been suggested that the nef gene product facilitatesvirus replication by increasing the state of cellular activation(1, 14). We explored the activation status of the infected Tcells by double labeling the specimens for the cell cycle antigenKi-67 (13, 28). This antigen produces a strong and discretenuclear stain. However, wild-type SIV replicated primarily incells that were not double labeled for Ki-67 (Fig. 5A and B).This confirms prior data with HIV-1 infection (37). The samefinding was observed with SIV ${Delta}$ nef. 65 to 70% of the RNA positivecells were not labeled for Ki-67 (Fig. 5C and D) and thereforenot clearly in cell cycle at all. In both Ki-67-positive and-negative T cells, the grain counts generated from the ³⁵S-labeledprobe ranged from 60 to 300 per cell (white and black arrows,respectively, in Fig.. 5D), indicating that the levels of virusproduction per infected cell were similar in cycling and noncyclingcells. Thus, the absence of a nef gene does not substantiallyalter the capacity of SIV to replicate in noncycling T cells.

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FIG. 5. SIV wild type (A and B) and SIV ${Delta}$ nef (C and D) often replicate in cells that do not immunolabel for the cell cycle antigen Ki-67 (red). Black arrows indicate Ki-67-negative RNA-infected cells, while white arrows indicate Ki-67-positive infected cells.

Marked expansion of perforin-positive, CD3⁺, and CD3^- cells in acutely infected lymph nodes. It is known that significant antiviral, CD8⁺ T-cell responsesdevelop during infection with SIV ${Delta}$ nef (23). To gain evidencefor such a response in vivo, we stained the specimens for lysosomalgranules containing the pore-forming protein perforin, a keycomponent of CD8⁺ cytolytic T lymphocytes and natural killer(NK) cells. Perforin-positive lymphocytes were rare in the lymphnode and the tonsil of uninfected macaques. In contrast, perforin-positivelymphocytes were abundant (7 to 14 cells per field with a 40xobjective) in the acutely infected tonsil (day 7, Fig. 6A) butnot in the poorly infected retropharyngeal lymph node at thattime (Fig. 6B). When the lymph nodes became infected (week 2),perforin-positive cells were abundant, including in germinalcenters (Fig. 6C). At later time points (26 weeks), perforin-positivecells were difficult to detect (Fig. 6D). Therefore, it appearsthat lytic cells are most abundant early in response to thevaccine strain.

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FIG. 6. Detection of perforin-positive lymphocytes in tissue sections following tonsillar infection of rhesus macaques with SIV ${Delta}$ nef. Single-color immunolabeling (red) at 1 week in the heavily infected tonsil (A) and weakly infected retropharyngeal lymph node (B) and at 2 weeks (C) and 26 weeks (D) in strongly infected and weakly infected nodes. Two-color immunolabeling, with perforin in blue, shows the cells to be CD4 negative (red color in E and F), either CD3⁺ (arrows, G) or CD3^- (arrowheads, G), or CD8⁺ (arrows, H).

We assessed the lineage of the perforin-positive cells by immunohistochemicaldouble labeling. The majority of perforin-positive cells inthe acutely infected tonsil (Fig. 6E) and lymph nodes (Fig.6F) did not display CD4. However, a significant percentage (25to 32%) were CD3⁺ (arrows, Fig. 6G), suggesting that they werecytolytic T lymphocytes. Likewise, about 30% of the perforin-positivecells double labeled for the CD8 killer T-cell marker (arrows,Fig. 6H). Most perforin-positive cells were CD3 negative andwere most likely NK cells (Fig. 6G).

Additional findings that are not shown are as follows. Perforin-positivecells were similarly abundant in the infected lymphoid tissuesof animals given wild-type SIVmac251 through the tonsillar route(31), again within CD3-negative and CD3⁺ lymphocyte subsets.In both wild-type- and SIV ${Delta}$ nef vaccine strain-infected monkeys,some of the perforin-positive cells were double labeled forKi-67, the cell cycle antigen. We found many perforin-positivecells in the lumen of the high endothelial venules of the T-dependentzone as well as the medullary sinuses, indicating that the killercells were able to migrate out of the lymphoid tissues intothe blood. These results indicate that there is a strong cytolyticcell response in the acutely infected lymphoid tissues, withboth T cells and NK cells participating.

DISCUSSION

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Discussion

The SIV ${Delta}$ nef vaccine strain has limited but clear replicativepotential in vivo, as assessed by measurements of infectiousunits and viral RNA in blood. By applying the SIV ${Delta}$ nef vaccinestrain directly to the tonsils of rhesus macaques, we demonstratedsignificant virus replication at the site of inoculation at1 week and shortly thereafter in peripheral lymph nodes. Thenthe virus is brought under control, though it continues to replicateat lower levels in most lymphoid tissues.

Here we stress two new findings. First, the vaccinated animalsare containing a substantial primary and spreading infectionwith SIV ${Delta}$ nef in the CD4⁺ T-cell compartment. The SIV ${Delta}$ nef vaccinestrain therefore is not less virulent, because it shifts itssite of infection from T cells to non-T cells, such as macrophagesor dendritic cells. Second, there is a major expansion of perforin-positivekiller cells, including CD8⁺ and CD3⁺ T cells, in lymph nodesthat are supporting viral replication. The SIV ${Delta}$ nef vaccine straintherefore seems to elicit a strong local immune response, eventhough killer cells can be difficult to detect in the bloodstream(38). SIV-specific CD8⁺ T-cell responses become more evidentwhen one challenges the vaccinated animals with wild-type SIV(38).

In designing this study, we wanted to explore the possibilitythat the efficacy of the SIV ${Delta}$ nef vaccine strain reflected a relativeincrease in virus replication in dendritic cells, leading tomore effective antigen presentation and antiviral immunity.However, we could not demonstrate viral RNA by in situ hybridizationin cells that were double labeled with dendritic cell markers.These included Langerin/CD207, a constituent of the Birbeckgranules of Langerhans cells (35, 36); DC-LAMP/CD208, a lysosome-associatedmembrane protein of more mature dendritic cells (9); CD1a, amarker for Langerhans cells as well as dendritic cells in theexternal and crypt epithelia of the tonsils (31); and CD83 (39).Also, we only rarely found RNA-positive cells that were doublelabeled for sialoadhesin/CD169 (16) and macrosialin/CD68 (25),two markers that are abundant in resident and inflammatory macrophages.

Instead, the site for virus replication in vivo, acutely andchronically, proved to be the CD4⁺ T cell. More than half ofthe infected cells were not in cell cycle at the time of examination,as indicated by Ki-67 staining. This also occurs with infectionwith human immunodeficiency virus (HIV) and wild-type SIV (37).These findings might be explained as a composite of severalelements in the virus-host interaction. Initially SIV ${Delta}$ nef isable to replicate in T cells that are interacting with maturedendritic cells, as occurs in tissue culture (22), perhaps throughthe aegis of the HIV-1 and SIV binding lectin DC-SIGN (12, 24).DC-SIGN is proposed to mediate the known capacity of dendriticcells to capture virus and transmit infection in trans to Tcells. In contrast, replication of SIV ${Delta}$ nef is compromised whenimmature dendritic cells are carrying the vaccine (22). Whenan immune response develops, especially a CD8⁺ T-cell responsethat is known to dampen the levels of infection in vivo (23),virus replication is contained.

The new data in this paper on the number and types of infectedcells in SIV ${Delta}$ nef-vaccinated monkeys indicate that the host cancontain or resist a substantial early infection of CD4⁺ T cellswith an immunodeficiency virus. Elsewhere we will document thatmonkeys vaccinated via the tonsillar route are indeed protectedagainst a challenge with the pathogenic SIVmac251. Perhaps infectionwith SIV ${Delta}$ nef has some parallels with what takes place when SIVagminfects its natural African green monkey host.

During acute infection with SIVagm, there are abundant infectedcells in lymphoid tissues, and then viral RNA and DNA levelsfall to a low set point (10). The resistance that the host canmount to infected T cells also is reminiscent of individuals(26) and of macaques (21, 29) treated with highly active antiretroviraltherapy early in acute infection with HIV-1 or SIV. In theseindividuals, the virus does take hold initially, but early treatmentseems to allow the immune system or other defenses to controlthe infection. Conceivably, the initial virus infection interferesor retards further progression of infection, although our observationsraise the possibility that T-cell and NK cell activity in thelymphoid tissue, especially at the portal of virus entry, maybe playing a containment role. These lines of evidence are consistentwith recent SIV-HIV hybrids results in macaques (2, 4), concludingthat vaccines for immunodeficiency viruses need not providesterilizing immunity against infection of CD4⁺ T cells, butrather need to contain the infection, allowing the host to establisha low viral set point compatible with immunocompetence.

ACKNOWLEDGMENTS

This work was supported by grant QLRT-PL 1999-01215 from theEuropean Community and by grants AI40045 and AI40874 from theNIH and Direct Effect.

We thank Gudrun Grossschupff, Petra Mayer, and Birgit Raschdorfffor excellent technical assistance.

FOOTNOTES

* Corresponding author. Mailing address: Bernhard Nocht Institute for Tropical Medicine, Bernhard-Nocht-Str. 77, 20359 Hamburg, Germany. Phone: 49 40 42818 499. Fax: 49 40 42818 544. E-mail: racz{at}bni.uni-hamburg.de.

REFERENCES

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