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Journal of Virology, April 2003, p. 4169-4180, Vol. 77, No. 7
0022-538X/03/$08.00+0     DOI: 10.1128/JVI.77.7.4169-4180.2003
Copyright © 2003, American Society for Microbiology. All Rights Reserved.

nef Gene Is Required for Robust Productive Infection by Simian Immunodeficiency Virus of T-Cell-Rich Paracortex in Lymph Nodes

Chie Sugimoto,1 Kei Tadakuma,1 Isao Otani,2 Takashi Moritoyo,3 Hirofumi Akari,1 Fumiko Ono,4 Yasuhiro Yoshikawa,5 Tetsutaro Sata,6 Shuji Izumo,3 and Kazuyasu Mori1,7*

Tsukuba Primate Center for Medical Sciences, National Institute of Infectious Diseases,1 Corporation for Production and Research of Laboratory Primates, Tsukuba 305-0843,4 Department of Veterinary Medicine, College of Bioresource Sciences, Nihon University, Fujisawa 252-8510,2 Center for Chronic Viral Disease, Faculty of Medicine, Kagoshima University, Kagoshima 890-0075,3 Department of Biomedical Science, Faculty of Agriculture, University of Tokyo, Tokyo 113-8657,5 AIDS Research Center,7 Department of Pathology, National Institute of Infectious Diseases, Tokyo 162-8640, Japan6

Received 30 September 2002/ Accepted 19 December 2002


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ABSTRACT
 
The pathogenesis of AIDS virus infection in a nonhuman primate AIDS model was studied by comparing plasma viral loads, CD4+ T-cell subpopulations in peripheral blood mononuclear cells, and simian immunodeficiency virus (SIV) infection in lymph nodes for rhesus macaques infected with a pathogenic molecularly cloned SIVmac239 strain and those infected with its nef deletion mutant ({Delta}nef). In agreement with many reports, whereas SIVmac239 infection induced AIDS and depletion of memory CD4+ T cells in 2 to 3 years postinfection (p.i.), {Delta}nef infection did not induce any manifestation associated with AIDS up to 6.5 years p.i. To explore the difference in SIV infection in lymphoid tissues, we biopsied lymph nodes at 2, 8, 72, and 82 weeks p.i. and analyzed them by pathological techniques. Maximal numbers of SIV-infected cells (SIV Gag+, Env+, and RNA+) were detected at 2 weeks p.i. in both the SIVmac239-infected animals and the {Delta}nef-infected animals. In the SIVmac239-infected animals, most of the infected cells were localized in the T-cell-rich paracortex, whereas in the {Delta}nef-infected animals, most were localized in B-cell-rich follicles and in the border region between the paracortex and the follicles. Analyses by double staining of CD68+ macrophages and SIV Gag+ cells and by double staining of CD3+ T cells and SIV Env+ cells revealed that SIV-infected cells were identified as CD4+ T cells in either the SIVmac239 or the {Delta}nef infection. Whereas the many functions of Nef protein were reported from in vitro studies, our finding of SIVmac239 replication in the T-cell-rich paracortex in the lymph nodes supports the reported roles of Nef protein in T-cell activation and enhancement of viral infectivity. Furthermore, the abundance of SIVmac239 infection and the paucity of {Delta}nef infection in the T-cell-rich paracortex accounted for the differences in viral replication and pathogenicity between SIVmac239 and the {Delta}nef mutant. Thus, our in vivo study indicated that the nef gene enhances SIV replication by robust productive infection in memory CD4+ T cells in the T-cell-rich region in lymphoid tissues.


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INTRODUCTION
 
The importance of the nef gene of simian immunodeficiency virus (SIV) for persistent active viral replication has been demonstrated in a macaque AIDS model (26). Defects in the nef gene not only lowered the magnitude of SIV infection but also allowed the host immune system to induce protective immunity against pathogenic SIVs (12, 24, 25). Findings of defective nef alleles in human immunodeficiency virus (HIV) isolates from infected individuals who have been categorized as long-term nonprogressors were the driving force behind studies on protective immunity against the AIDS virus (28). Based on those studies, the nef gene is generally accepted to play a key role in the pathogenesis of HIV/SIV (primate AIDS virus) infection (13). The functions of the nef gene in primate AIDS virus replication in vitro or ex vivo have been reported; they include enhancement of viral infectivity (20, 33), mediation of T-cell activation (4, 15, 32, 48), and down-regulation of cell surface molecules such as CD4 (1, 18), major histocompatibility complex (MHC) class I (21, 30), and CD28 in CD4+ T cells (52). However, the functions of the nef gene in the primate AIDS virus in vivo still remain unclear (for reviews, see references 17, 25, and 41).

The importance of early events in AIDS virus infection in terms of viral replication, host immune response, and disease progression has been reported from HIV type 1 (HIV-1) clinical studies (45) and studies of animal AIDS models (34). In particular, due to considerations of feasibility in study design, early events of SIV infection in macaques were extensively investigated by examination of various tissues, viral strains, and infection routes (9, 10, 23, 29, 39, 44, 50, 51, 54-57). Reimann et al., using SIVmac251, reported that SIV-infected cells localized predominantly in T-cell-rich extrafollicular regions in lymph nodes (LNs) at primary infection (44). Lackner et al. performed extensive analyses of the spleen and thymus and reported similar results for SIVmac239 infection. They also found that cells infected with an attenuated strain, SIVmac1A11, were localized in follicles (29). The results of Chakrabarti et al. with SIVmac251 were relatively consistent with those of Reimann et al. and Lackner et al., but they also noted SIV+ cells scattered in the cortex (corresponding to follicles) at day 4 postinfection (p.i.) (9). Chakrabarti et al. found productive infection by a SIVmac251 nef mutant in germinal centers (GC) at day 7 p.i. and subsequent trapping of SIV virions in GC at day 15 p.i. (10). Stahl-Henning et al. examined localization of SIV-infected cells in tonsils at day 4 p.i. for macaques infected with SIVmac251 by an oral mucosal route (50); they found that whereas SIV-infected cells were observed in all compartments of the tonsils, the majority were CD4+ T cells in extrafollicular lymphoid tissue equivalent to the paracortex in LNs. Taken together, the results from these five studies show that pathogenic SIVmac251 and SIVmac239 infection occurred in both the T-cell-rich paracortex and follicles and that {Delta}nef mutants and an attenuated strain, SIVmac1A11, replicated in follicles in LNs. Thus, early events after SIV infection are assumed to determine the outcome of AIDS virus infection, that is, whether the infected host controls the infection or not. Furthermore, we assumed that the nef gene plays an important role in determining these early events after primate AIDS virus infection.

In this study, to clarify the role of the nef gene in SIV replication in vivo, we infected rhesus macaques with a molecularly cloned SIVmac239 with a functional nef gene as a wild-type virus or with its nef deletion mutant ({Delta}nef). SIVmac239 infection induced AIDS in two of the three animals by 3 years p.i., and {Delta}nef mutant infection was suppressed to low viral loads without any manifestation associated with AIDS except a gradual decline in naïve CD4 T cells. We examined SIV infection in the LNs at weeks 2, 8, 72, and 82 p.i. At the peak of the primary infection, SIV-infected cells were observed in different locations in the LNs: for the SIVmac239-infected animals, most of the infected cells were localized in the T-cell-rich paracortex, whereas for the {Delta}nef-infected animals, most were localized in B-cell-rich follicles. Our in vivo study indicated that the nef gene enhances SIV replication by robust productive infection in memory CD4+ T cells in the T-cell-rich paracortex in lymphoid tissues.


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MATERIALS AND METHODS
 
Viruses. Proviral DNAs of wild-type SIVmac239 nef+ (SIVmac239) and a mutant with a 183-bp deletion in the nef gene ({Delta}nef) were provided by Ronald C. Desrosiers (New England Regional Primate Research Center, Harvard Medical School, Southborough, Mass.) (26). Stocks of SIVmac239 and {Delta}nef were produced by DNA transfection of the respective infectious DNAs into COS1 cells (34, 35). For SIV infection of monkeys, these virus stocks were propagated in phytohemagglutinin (PHA)-stimulated peripheral blood mononuclear cells (PBMCs) from rhesus macaques, and their titers (50% tissue culture infective doses [TCID50]) were determined on CEMx174 cells (34, 35).

Animal infection studies. Eight juvenile rhesus macaques of Burmese or Laotian origin that were seronegative for SIV, simian T-lymphotropic virus, B virus, and type D retroviruses were used. All animals were housed in individual cages and maintained according to the National Institute of Infectious Diseases rules and guidelines for experimental animal welfare. Animals were infected intravenously with 100 TCID50 of SIVmac239 (animals Mm18, Mm24, Mm27, Mm06, and Mm22) or {Delta}nef (animals Mm14, Mm16, and Mm29).

Determination of plasma viral loads by real time PCR. SIV infection was monitored by measuring the plasma viral load. Viral RNA was isolated from plasma from infected animals by using a commercial viral RNA isolation kit (Roche Diagnostics, Tokyo, Japan). SIV gag RNA was amplified and quantified by using a commercial RNA reverse transcription-PCR kit (TaqMan EZ RT-PCR; Perkin-Elmer Applied Biosystems, Urayasu, Japan) with two gag primers, namely, the forward primer 1224F (5'-AATGCAGAGCCCCAAGAAGAC-3') and the reverse primer 1326R (5'-GGACCAAGGCCTAAAAAACCC-3'), and with the TaqMan probe 1272T (FAM-5'-ACCATGTTATGGCCAAATGCCCAGAC-3'-TAMRA). Purified viral RNA (10 µl) was reverse transcribed and amplified in a MicroAmp optical 96-well reaction plate (Perkin-Elmer Applied Biosystems) according to the manufacturer's instructions and with the following thermal cycle conditions: 1 cycle of three sequential incubations (50°C for 2 min, 60°C for 30 min, and 95°C for 5 min), followed by 50 cycles of amplification (95°C for 5 s and 62°C for 30 s) in a 7700 prism sequence detection system (Perkin-Elmer Applied Biosystems). In vitro RNA transcripts were quantified by measurement of optical density at 260 nm and a branched-DNA assay for SIV viral RNA (Bayer Diagnostics, Tarrytown, N.Y). RNA equivalent to 10 to 107 copies per reaction was used as a standard for each assay. The detection sensitivity of plasma viral RNA by this method was 103 copies/ml.

Flow cytometry. CD4 depletion was monitored by measuring the absolute number (or count) of CD4+ T cells in the blood and the percentages of memory and naïve CD4+ T cells in PBMCs. PBMC samples were purified from citrate-anticoagulant-containing blood by standard Ficoll-Hypaque gradient centrifugation. For flow cytometry, 2 x 105 PBMCs were reacted with fluorescein isothiocyanate (FITC)- or phycoerythrin (PE)-labeled antibodies (anti-human CD4 antibody Nu-Th/I [Nichirei, Tokyo, Japan], anti-human CD8 antibody Leu2a [Becton Dickinson, San Jose, Calif.], anti-human CD29 antibody 4B4 [Coulter, Miami, Fla.], anti-monkey CD3 antibody FN-18 [Biosource, Camarillo, Calif.], and anti-human CD20 antibody Leu16 [Becton Dickinson]) as previously described (2). PBMC counts in blood samples were determined by using an automated blood cell counter (Sysmex, Kobe, Japan). Absolute CD4 counts were calculated by multiplying the PBMC count in blood by the percentage of CD4+ T cells.

Tissue collection. In the first experiment, biopsies of inguinal or axillary LNs of all six infected monkeys (Mm18, Mm24, and Mm27 infected with SIVmac239; Mm14, Mm16, and Mm29 infected with the {Delta}nef mutant) were carried out at 2, 8, and 72 weeks p.i. (for Mm14, Mm16, Mm29, and Mm27) or 82 weeks p.i. (for Mm18 and Mm24). In the second experiment, two rhesus macaques (Mm06 and Mm22) infected with SIVmac239 were biopsied at days 4 and 7 p.i. and autopsied at day 11 p.i. (Mm06) or day 14 p.i. (Mm22). Collected LNs were fixed with 4% paraformaldehyde for 24 h and then embedded in paraffin. For routine histopathological examination, tissues were stained with hematoxylin-eosin.

Immunohistochemistry. We analyzed the phenotypes of the cells by immunohistochemical methods with fluorescein or regular 3,3'-diamidebenzidine (DAB) as a chromogen. Detailed information on the antibodies used in this study is given in Table 1. Paraffin-treated sections were dewaxed and pretreated by appropriate methods for each antibody (Table 1).


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  		TABLE 1. Antibodies used in immunohistochemistry study

For double staining (combination of anti-p27 Gag and anti-CD68, anti-p27 Gag and anti-CD35, or anti-Env gp160/gp32 and anti-CD3), sections were incubated with both primary antibodies either at 4°C overnight or at 37°C for 1 h. After a wash with Tris-buffered saline and blocking with TNB (0.1 M Tris-HCl [pH 7.5]-0.15 M NaCl-0.5% blocking reagent), sections were incubated at room temperature for 1 h with Envision+ rabbit, a peroxidase-labeled anti-rabbit immunoglobulin (Ig) polymer (Dako, Kyoto, Japan), for the rabbit polyclonal antibody and with a biotin-conjugated anti-mouse IgG (Dako) for monoclonal antibodies. After a wash, the immobilized peroxidase-labeled Ig on the sections was visualized with fluorescein tyramide by using a Tyramide Signal Amplification (TSA) kit (Perkin-Elmer Life Science, Boston, Mass.). Subsequently, sections were incubated with Alexa 594-conjugated streptavidin (Molecular Probes, Eugene, Oreg.) for visualization of immobilized biotin-conjugated IgG.

For single staining (anti-SIV Env gp160/gp32, anti-SIV Nef, anti-CD4, anti-CD20, anti-CD3, TIA1, and PCNA), sections were incubated first with the primary antibody and then with Envision+ rabbit or mouse (Dako) as the secondary antibody. Sections were visualized by TSA or a metal-enhanced DAB substrate (Pierce, Rockford, Ill.).

Finally, sections were mounted with VECTASHIELD mounting medium and 4',6'-diamidino-2-phenylindole (DAPI) (Vector Laboratories, Burlingame, Calif.) for immunofluorescein staining or with MOUNT QUICK for DAB staining. Sections were examined with a fluorescence microscope system (BX50 + BX-FLA; Olympus, Tokyo, Japan) equipped with a digital camera (DP50) and a personal computer.

To examine the location specificity of SIV replication in LNs, SIV protein-containing (Gag+ or Env+) cells in the paracortex, B-cell-rich follicles, and border region (region containing scattered B cells) were counted by using the serial sections stained with antibodies against SIV proteins and with an anti-CD20 antibody.

In situ hybridization. For in situ hybridization, we used riboprobes that were complementary to SIV gag, pol, and nef regions and were labeled by incorporation of digoxigenin-UTP (Roche Diagnostics). SIV RNA was detected in tissue sections by in situ hybridization as previously described (36, 39). Briefly, dewaxed sections were pretreated with 0.2 N hydrochloric acid for 20 min, digested with 20 µg of proteinase K/ml at 37°C for 15 min, and acetylated. For hybridization, 2 µg of SIV probe mixture/ml in 50% deionized formamide-10% dextran sulfate-600 mM NaCl-10 mM Tris (pH 7.5)-1 mM EDTA-200 µg of yeast RNA/ml-0.25% sodium dodecyl sulfate-1x Denhardt's solution was annealed at 50°C overnight in a humid chamber. After a wash in 2x SSC (1x SSC is 0.15 M NaCl plus 0.015 M sodium citrate) at 55°C for 1 h and another in 0.2x SSC at 50°C for 40 min, the sections were incubated with a sheep anti-digoxigenin antibody conjugated with alkaline phosphatase (Roche Diagnostics). Bound probes were finally visualized with the alkaline phosphatase substrate nitroblue tetrazolium (NBT)-5-bromo-4-chloro-3-indolylphosphate (BCIP) in the substrate buffer. Sections were counterstained with Kernechtrot solution.


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RESULTS
 
Plasma viral loads in rhesus macaques infected with either SIVmac239 or {Delta}nef. Three rhesus macaques were intravenously infected with 100 TCID50 of SIVmac239 with a functional nef gene (SIVmac239), and three were infected with a mutant virus with a 183-bp deletion in the nef gene ({Delta}nef). Two patterns of infection were seen in the three rhesus macaques infected with SIVmac239 (Fig. 1). During the first 4 weeks p.i., SIV replicated synchronously in all three animals; a peak in the primary infection was seen at 2 weeks p.i. for all three (2 x 107, 9 x 106, and 1.3 x 107 SIV RNA copies/ml for Mm18, Mm24, and Mm27, respectively). However, the set points and viral loads diverged into two paths thereafter. Incomplete suppression of primary infection with a set point of 104 copies/ml was seen for two of the three animals (Mm18 and Mm24). For these two animals, viral loads continued to increase to the end points; Mm18 died of AIDS at 106 weeks p.i., and Mm24 was euthanized due to AIDS symptoms at 133 weeks p.i. In contrast, for the other animal (Mm27), SIV infection was suppressed after the primary infection with a set point below 103 copies/ml, and even in the chronic phase, the viral load remained on the order of 103 copies/ml up to 330 weeks p.i. (Fig. 1).



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  		FIG. 1. Replication of SIVmac239 and {Delta}nef in rhesus macaques based on plasma viral RNA load after intravenous inoculation with 100 TCID50 of the respective virus. {dagger}, animals Mm18 and Mm24 died of AIDS at 106 and 133 weeks (w) p.i., respectively.

For the three rhesus macaques infected with {Delta}nef, primary infections occurred with kinetics similar to those observed for the monkeys with the SIVmac239 infection, as described in the preceding paragraph. Peak viral loads were detected for all three animals (2 x 105, 3 x 106, and 4 x 105 copies/ml for Mm14, Mm16, and Mm29, respectively) at 2 weeks p.i. Despite the differences in the peak viral loads among the three animals, each viral load decreased sharply to below the detection sensitivity (103 copies/ml) by 8 weeks p.i. In the chronic phase, viral loads remained below 104 copies/ml in all three animals (Fig. 1).

CD29high and CD29low subpopulations in CD4+ T cells. Subpopulations of CD4+ CD29high T cells and CD4+ CD29low T cells, which are closely related to memory and naïve CD4+ T cells, respectively, have been used to monitor disease progression in HIV-infected individuals and in an SIV AIDS animal model (8, 31, 37). Therefore, we monitored these CD4+ T-cell subpopulations in SIV-infected animals. In the two animals that developed AIDS (Mm18 and Mm24), the CD4+ CD29high subpopulation dropped below 5% after 80 weeks p.i. By contrast, in the other four animals, which maintained low viral loads for more than 6 years, the CD4+ CD29high subpopulation remained at preinfection levels (Fig. 2A). Thus, longitudinal changes in the levels of CD4+ CD29high T cells in PBMCs correlated well with disease progression in SIVmac239-infected animals (Fig. 2A).



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  		FIG. 2. CD4+ T cells in rhesus macaques infected with {Delta}nef or SIVmac239. (A) Percentage of CD4+ CD29high T cells in PBMCs; (B) percentage of CD4+ CD29low T cells in PBMCs; (C) absolute CD4+ T-cell counts in blood.

In contrast to the CD4+ CD29high subpopulation, less-drastic decreases in the CD4+ CD29low subpopulation were detected at the time of autopsy or euthanasia for the two animals that developed AIDS (Mm18 and Mm24). In addition, this subpopulation (CD4+ CD29low) decreased gradually after 1.5 years p.i. in three of the four animals (Mm27, Mm14, and Mm29) that maintained low viral loads for more than 6 years (Fig. 2B). Only for one animal (Mm16) did both CD29high and CD29low CD4+ T-cell subpopulations remain at preinfection levels for more than 6 years.

Because of the distinct kinetics of CD29high and CD29low populations, blood CD4+ T-cell counts did not correlate with pathogenic development and viral load for the SIVmac239-infected animals. Only one animal (Mm24) exhibited a sharp drop in CD4+ T-cell counts, partly due to lymphocytopenia, at the time of euthanasia at 133 weeks p.i., although the CD4 count had increased at 109 weeks p.i. (Fig. 2C). Another disease progressor (Mm18) also showed an increase in the CD4 count near the time of death at 99 weeks p.i.

The CD29 marker does not accurately define memory and naïve CD4+ T cells: whereas CD4+ CD29low T cells correspond to naïve CD4+ T cells, CD4+ CD29high T cells contain both memory and naïve CD4+ T cells (42; L. J. Picker, personal communication). Nevertheless, these results indicated that different extents of SIV replication in the chronic phase influenced different CD4 subpopulations in PBMCs: whereas high SIV replication was associated with depletion of memory CD4+ T cells, long-term low-level SIV infection was associated with a decline in naïve CD4+ T cells.

Histology and CD4+ cell depletion in surface LNs from SIVmac239- and {Delta}nef-infected animals. AIDS virus infection is well known to occur predominantly in CD4+ T cells and macrophages in lymphatic tissue in vivo. Therefore, we examined the histology and distribution of CD4+ cells and SIV infection in biopsied surface LNs. Activated GC were observed at 2 weeks p.i. in LNs from {Delta}nef-infected animals (Fig. 3A), and moderately activated follicles were observed in those from SIVmac239-infected animals (Fig. 3B); however, this histological difference was reversed at chronic infection (72 or 82 weeks p.i.). Whereas only a small GC was observed in {Delta}nef-infected animals, many large GC were observed in SIVmac239-infected animals (Fig. 3C and D). Consistent with plasma viral loads, many SIV Gag+ cells were detected in LNs taken at 2 weeks p.i. from {Delta}nef-infected animals (Fig. 3E) and SIVmac239-infected animals (Fig. 3F). SIV Gag+ cells localized differently in LNs in the two infected groups. Many SIV+ cells were inside and around the GC in {Delta}nef-infected animals (Fig. 3A and E), whereas most of the SIV-infected cells were outside the follicles in SIVmac239-infected animals (Fig. 3B and F). As the viral load decreased at 72 weeks p.i. (Fig. 1), few SIV+ cells were detected in {Delta}nef-infected animals (Fig. 3G). In SIVmac239-infected animals with high viral loads (Mm24 [Fig. 1]), SIV+ signals were densely accumulated in GC in LNs taken at 82 weeks p.i. (Fig. 3H). These signals were found to be SIV virions trapped on follicular dendritic cells (FDC), because of the nature of diffused Gag+ signals and the overlap with CD35+ (a C3b receptor which is an FDC marker) signals (Fig. 3I, J, and M). In addition, CD4 cell depletion was also evident in LNs from SIVmac239-infected animals (Fig. 3L) but not in LNs from {Delta}nef-infected animals (Fig. 3K).



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  		FIG. 3. Histology and immunohistochemical staining of LN samples taken at 2 weeks p.i. and at 72 or 82 weeks p.i. from a rhesus macaque (Mm16) infected with {Delta}nef or from rhesus macaques (Mm18 and Mm24) infected with SIVmac239. (A through D) Hematoxylin-eosin staining of LN sections from Mm16 at 2 weeks p.i. (A), Mm18 at 2 weeks p.i. (B), Mm16 at 72 weeks p.i. (C), and Mm24 at 82 weeks p.i. (D). (E through H) Immunostaining of SIV p27 Gag protein in sections from Mm16 at 2 weeks p.i. (E), Mm18 at 2 weeks p.i. (F), Mm16 at 72 weeks p.i. (G), and Mm24 at 82 weeks p.i. (H). (I, J, and M) Immunostaining of FDC network in GC of Mm24 at 82 weeks p.i. (I) SIV p27 Gag; (J)CD35+ cells (FDC); (M) double staining of SIV p27 Gag and CD35. (K and L) Immunostaining of CD4+ cells from Mm16 at 72 weeks p.i. (K) and Mm24 at 82 weeks p.i. (L). The following combinations of panels represent staining of serial sections: A and E; B and F; C, G, and K; and D, H, and L.

{Delta}nef-infected cells preferentially localized in follicles of LNs at primary infection. Using serial sections from LNs biopsied at 2 weeks p.i., we stained SIV RNA+ cells by in situ hybridization and stained B cells with an anti-CD20 antibody by immunohistochemistry. SIV RNA+ cells were localized inside B-cell-rich follicles in {Delta}nef-infected animals but were localized in the paracortex in SIVmac239-infected animals (Fig. 4). Furthermore, we examined multiple sections from multiple LNs from each of the six animals by immunohistochemistry with antibodies against SIV proteins (Fig. 5). For both groups of infected animals, the most distinct localization was seen in sections with many SIV+ cells (Table 2). However, in both groups, some SIV-infected cells were in border regions between the follicles and the paracortex (Fig. 5; Table 2). We estimated the proportions of SIV-infected cells in the paracortex, B-cell-rich follicles, and border region in LNs at 2 weeks p.i. for each of the six animals (Table 2). Eighty percent of the SIV+ cells were localized in the T-cell-rich paracortex in SIVmac239-infected animals, whereas less than 10% of the SIV+ cells were detected in the same region, and the majority of the remaining cells were in B-cell-rich follicles or the border region, in {Delta}nef-infected animals. Because the frequency of SIV+ cells in SIVmac239-infected animals was higher than that in {Delta}nef-infected animals, we concluded that the difference in localization of SIV+ cells could be explained by the paucity of SIV replication in the paracortices of {Delta}nef-infected animals.



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  		FIG. 4. SIV RNA+ cells in LN samples taken at 2 weeks p.i. from a {Delta}nef-infected (Mm16) and a SIVmac239-infected (Mm18) rhesus macaque. (A and B) Mm16; (C and D) Mm18. Serially sectioned tissue specimens were stained either by in situ hybridization with antisense SIVmac239 RNA (A and C) or with an anti-CD20 antibody (B and D) to stain B cells. SIV RNA+ cells (blue) were localized in a region rich in CD20+ B cells (brown) in LNs of rhesus macaques infected with {Delta}nef. By contrast, SIV RNA+ cells were localized outside a region rich in CD20+ B cells in LNs of rhesus macaques infected with SIVmac239.



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  		FIG. 5. SIV Env+ cells in LNs at 2 weeks p.i. Serially sectioned tissue specimens were stained either with an anti-SIV gp32 Env antibody (A, C, E, G, I, and K) or with an anti-CD20 antibody (B, D, F, H, J, and L) to stain B cells. (Left panels) LNs of rhesus macaques infected with {Delta}nef: Mm16 (A and B), Mm14 (E and F), and Mm29 (I and J). (Right panels) LNs of rhesus macaques infected with SIVmac239: Mm18 (C and D), Mm24 (G and H), and Mm27 (K and L).


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  		TABLE 2. Localization of SIV+ cells in LNs

The majority of SIV+ cells were CD68- CD3+ cells in both {Delta}nef-infected and SIVmac239-infected animals. CD4+ T cells and macrophages are the major cell types in rhesus macaques infected with pathogenic SIVs (9, 10, 23, 29, 50, 54, 55). We therefore examined if the differential localization of infected cells is due to localization of target cells in LNs at 2 weeks p.i. Using an anti-CD68 monoclonal antibody and an anti-SIV Gag p27 rabbit antibody, we did double staining of SIV+ cells and CD68+ macrophages. As shown in Fig. 6, SIV+ cells (green) and macrophages (red) did not overlap in LNs from either {Delta}nef-infected or SIVmac239-infected animals (Fig. 6A, E, I, and M). Using serial sections, we stained CD4+ T cells to examine the cell type of SIV+ cells (Fig. 6B and J). Because many CD4+ cells coexisted with SIV+ cells, most of the SIV+ cells in both SIVmac239-infected and {Delta}nef-infected animals were likely CD4+ T cells. Next, we did double staining of SIV Env+ cells (red) and CD3+ T cells (green) by using an anti-SIV Env mouse monoclonal antibody and an anti-CD3 rabbit antibody. Most SIV Env+ cells overlapped with CD3+ cells (Fig. 6F, G, H, N, O, and P). Thus, SIV productively infected CD4+ T cells in LNs in both {Delta}nef-infected and SIVmac239-infected animals.



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  		FIG. 6. Identification of SIV+ cells in LN samples taken from the {Delta}nef-infected rhesus macaque Mm16 (A through H) and the SIVmac239-infected rhesus macaque Mm18 (I through P) at 2 weeks p.i. (A, E, I, and M) Double staining with an anti-SIV p27 Gag antibody (green) and an anti-CD68 (macrophage marker) monoclonal antibody (red). Panels E and M are enlarged photos of panels A and I. (B and J) Staining with an anti-CD4 antibody; (C and K) staining with an anti-CD20 (B-cell marker) antibody; (D and L) staining with an anti-TIA1 (CTL and NK marker) antibody; (F and N) double staining with an anti-SIV Env gp160/gp32 monoclonal antibody (red) and an anti-CD3 (T-cell marker) antibody (green); (G and O) staining with the anti-CD3 antibody (green) alone; (H and P) staining with the anti-SIV Env antibody (red) alone. The following combinations of panels represent staining of serial sections: A, B, C, and D; I, J, K, and L.

Using another serial section, we stained CD20+ B cells to define B-cell-rich follicles and the paracortex (Fig. 6C and K). The location of SIV+ cells in LNs was confirmed. We also stained for TIA1, a marker of effector cells (cytotoxic T lymphocytes [CTL] or natural killer [NK] cells). Whereas many TIA1+ cells localized proximal to SIV-infected cells in the paracortex of a SIVmac239-infected animal, apparently fewer TIA1+ cells localized in the B-cell-rich follicles of a {Delta}nef-infected animal (Fig. 6D and L).

SIV-infected cells in LNs at day 7 p.i. At 2 weeks p.i, the peak of primary infection, SIV-infected cells localized differentially depending on the function of the nef gene. SIVmac239-infected cells predominantly localized in the T-cell-rich paracortex. One question arises: does this distinctive localization of SIV productive infection occur only at the peak of the primary infection? SIV infection might move into an LN depending on the susceptibility of the target cells to SIV replication. For example, the initial infection takes place in the most susceptible cells, fully activated CD4+ T cells, and then infection spreads to resting memory CD4+ T cells. To examine this hypothesis, we biopsied LNs from two SIVmac239-infected animals at days 4 and 7 p.i. and examined the SIV infection. In LNs from autopsies at days 11 and 14 p.i., SIV Env+ cells were predominantly detected in the paracortex, as with the three animals infected with SIVmac239 in the first experiment (Mm18, Mm24, and Mm27). At day 4 p.i., no SIV Env+ cells were detected by fluorescent-staining immunohistochemistry. At day 7 p.i., the earliest time at which SIV Env+ cells were detected, 60 to 70% of productively infected cells were localized in the border region between B-cell-rich follicles and the T-cell-rich paracortex (Fig. 7; Table 2). These results indicate that T cells in the border region were highly susceptible to SIV infection in LNs. These results also suggest that SIVmac239 infection then spread to many T cells in the paracortex, whereas {Delta}nef infection spread to T cells in the B-cell-rich follicles.



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  		FIG. 7. SIV Env+ cells in LN biopsy samples taken at day 7 p.i. from rhesus macaques infected with SIVmac239. Serially sectioned tissue specimens were stained with either an anti-SIV Env gp160/gp32 antibody or an anti-CD20 antibody. The color of anti-CD20 antibody staining was digitally changed and combined with the image of anti-SIV Env antibody staining. The combined images indicate that SIV Env+ cells (green) were in the border region between the paracortex and B-cell-rich follicles (red). (A) Mm06; (B) Mm22.

Development of GC and anti-SIV antibody titer. As described in the preceding section, we observed larger GC in LNs in the {Delta}nef infection than in the SIVmac239 infection (Fig. 3A and B). To see the difference in the development of the B-cell-rich follicles in the two groups, we stained CD20+ cells and PCNA (a marker of proliferating cells)-positive cells in LN specimens taken at 2 weeks p.i. from SIVmac239- and {Delta}nef-infected animals. Greater numbers of GC and B-cell-rich follicles were observed for {Delta}nef-infected animals than for SIVmac239-infected animals (Fig. 8).



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  		FIG. 8. GC of LNs at 2 weeks p.i. Serial sections of LNs were stained with an anti-CD20 antibody (A through F) or an anti-PCNA (proliferating-cell marker) antibody (G through L) to visualize the GC. (A and G) Mm14; (B and H) Mm16; (C and I) Mm29; (D and J) Mm18; (E and K) Mm24; (F and L) Mm27.

To examine whether the difference in GC formation influenced the development of an anti-SIV humoral response in SIV-infected animals, we assayed anti-SIV enzyme-linked immunosorbent assay (ELISA) titers for SIVmac239- and {Delta}nef-infected animals. We detected anti-SIV IgG 1 week earlier in the animals with SIVmac239 infection (at 3 weeks p.i.) than in those with {Delta}nef infection (Fig. 9). As expected from the difference in plasma viral loads, anti-SIV antibody titers in SIVmac239-infected animals were higher than those in {Delta}nef-infected animals throughout the infection (Fig. 9). Collectively we observed more-extensive development of GC in {Delta}nef infection than in SIVmac239 infection. However, the difference in GC development did not correlate with the difference in the anti-SIV IgG antibody response between SIVmac239 infection and {Delta}nef infection.



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  		FIG. 9. Anti-SIV ELISA. The optical density at 490 nm was used as a relative measure of antibody titer. Shown are results for 1:100-diluted (top left) and 1:600-diluted (bottom left) plasma from {Delta}nef-infected animals and for 1:100-diluted (top right) and 1:600-diluted (bottom right) plasma from SIVmac239-infected animals. w, weeks.


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DISCUSSION
 
Because we compared infections with wild-type SIVmac239 and its {Delta}nef mutant in LNs, the paucity of SIV infection in the T-cell-rich paracortex must have been due to a defect in the nef gene. Thus, Nef protein did play an important role in facilitating SIV replication in CD4+ T cells in the paracortex. Conversely, why did the {Delta}nef mutant preferentially infect CD4+ T cells in B-cell-rich follicles rather than in the paracortex, despite the fact that there are more CD4+ T cells in the paracortex? The answer is probably related to the requirement of CD4+ T-cell properties for productive infection by primate AIDS virus. HIV preferentially replicates in memory CD4+ T cells in vitro (47, 49). For SIV-infected animals, depletion of memory CD4 T cells during the primary infection in gut lymphoid tissues (54, 55) and PBMCs (3) has been reported. Because of the predominant use of CCR5 as a viral receptor for SIV infection, CCR5 expression is another requirement for productive SIV infection in vivo (56). From these reports, CCR5+ memory CD4+ T cells are the major target cells for SIV infection in vivo. Then, for productive infection by {Delta}nef, what is the subpopulation of CD4+ T cells that resides in B-cell-rich follicles but not in the paracortex? This subpopulation is likely the activated helper CD4+ T cells that have migrated to GC from the paracortex. CD4+ T cells in GC reportedly are major cells involved in HIV replication in early infection (53). In a human tonsil study, CD57+ CXCR5+ T cells were localized only in GC (and thus are referred to as GC helper T cells) and expressed the surface markers CD45RO (memory marker) and CD69 (early activation marker) (27). Therefore, such CD4+ T cells might be the major target cells for {Delta}nef as well as the initial targets for SIVmac239.

The next question is what cells are productively infected with SIVmac239 but not with {Delta}nef at the peak of primary infection (2 weeks p.i.). We considered a well-described nef function, activation of resting memory CD4+ T cells. From an immunological viewpoint, secondary lymphatic tissues, such as LNs and spleen, contain central memory T cells that localize in the T-cell-rich paracortex (46). Because highly activated memory CD4+ T cells are the initial targets of SIV infection in vivo (55), the resting memory CD4+ T cells in the paracortex might subsequently be productively infected by SIVmac239 after the cells are fully activated with the help of the Nef protein.

In vitro studies on Nef function indicated that Nef enhances viral replication by increasing infectivity (33). The findings of Miller et al. (33) and of a study on replication of HIV-1 strain NL4-3 and its {Delta}nef mutant in human tonsil lymphoid histoculture (20) were mostly consistent with the results of our study. Thus, the difference in SIV infection in LNs might be due to the difference in the infectivities of SIVmac239 and {Delta}nef for the resting memory CD4+ T cells in the paracortex. Furthermore, replication of HIV-1 strain NL4-3 but not of its {Delta}nef mutant was efficiently enhanced by addition of interleukin-2 to the culture. Thus, this study appeared to support a role for Nef in T-cell activation, suggesting a common in vivo function of the Nef proteins of HIV-1 and SIVmac239.

Other nef functions also might account for SIV replication in the T-cell-rich paracortex. These infected cells might evade an anti-SIV immune response by CTL via MHC class I (MHC-I) down-modulation, which is caused by Nef protein in infected cells (for a review, see reference 13). Relevant to this function, we observed higher numbers of TIA1+ effector (CTL or NK) cells in the paracortex in than in the follicles at 2 weeks p.i. in both SIVmac239 infection and {Delta}nef infection (Fig. 6D and L; also data not shown). Therefore, the difference in the number of SIV-infected cells in the paracortex may be due to MHC-I down-regulation in SIVmac239 infection. Munch et al. reported that Nef-mediated MHC-I down-modulation provided a selective advantage for viral replication in SIVmac239 nef mutant-infected macaques (37). However, in vivo studies on MHC-I down-regulation by Nef were controversial. Patel et al. reported that Nef-mediated regulation of MHC-I expression does not appear to be critical for the increased replicative ability of pathogenic SIVmne variants (40). Furthermore, the emergence of CTL escape mutants during primary infection also raised questions on the role of MHC-I down-regulation for immune evasion against CTL (38). Thus, the relevance of Nef function for MHC-I down-regulation in vivo still remains to be elucidated.

In the spread of SIV infection, the initial target cells might be the activated helper CD4+ T cells, as mentioned. Garside et al. visualized migration and interaction of antigen-specific T cells and B cells in LNs (19), revealing that T cells were initially activated in the T-cell-rich paracortex and then migrated to the border region between the paracortex and the follicles, where specific T cells and B cells interacted through binding of CD40 ligand (CD40L) in T cells to CD40 on B cells. In our study, the earliest detected SIV-infected cells were at the border region at day 7 p.i. in SIVmac239 infection (Fig. 7). Many SIV-infected cells were also located in nearly the same regions in the {Delta}nef-infected animals at 2 weeks p.i. (Fig. 5 and Table 2). Therefore, SIV infection may influence the helper T-cell function required for the proper immune response. Poudrier et al. observed impaired CD40L expression in CD4+ T cells and discussed the association with impaired helper T-cell functions in HIV-1 transgenic mice. They reported similar impairment of GC formation in transgenic mice that harbored HIV-1 with a functional nef gene but not with a mutated nef allele (43). They also demonstrated the impairment of Ig isotype switching from IgM to IgG in the transgenic mice. Relevant to these results, SIV-infected macaques that succumbed rapidly to AIDS often lacked a SIV-specific IgG antibody (16). However, an anti-SIV IgG response occurred in slow disease progressors, as we observed in SIVmac239-infected animals (Mm18 and Mm24) (16) (Fig. 9). Thus, the extent of impairment of helper T-cell function may determine the disease course in SIV/HIV infection. Fewer and smaller GC in SIVmac239 infection than in {Delta}nef infection might imply a delay in the development of the humoral response, but this delay might be compensated for by strong antigen stimulation due to vigorous viral replication in SIVmac239 infection (Fig. 9). Indeed, we observed similar extensive development of GC in both groups at 8 weeks p.i. (data not shown).

After the primary infection, a SIV-specific immune response suppressed viral infection in both groups, as seen by viral load results (Fig. 1). However, the difference in viral replication in the T-cell-rich paracortex led to different paths of viral replication and host immune response for the two groups: the {Delta}nef mutant infected fewer memory CD4+ T cells in the paracortex, and therefore helper T-cell functions might have been impaired to a lesser extent than in SIVmac239 infection. In fact, high numbers of SIV-specific CD8+ T cells and CD4+ T cells were maintained in the {Delta}nef mutant infection (C. Sugimoto and K. Mori, unpublished data). Therefore, these SIV-specific cellular immune responses might play an important role in control of SIV infection in the chronic phase (Fig. 1). In contrast, presumably due to destruction of SIV-specific CD4+ T cells as reported for HIV-1 infection (14), SIV-specific CD8+ T cells were depleted in SIVmac239-infected animals (Sugimoto and Mori, unpublished). As SIV-specific cellular responses decreased, a second increase in viral replication resulted in AIDS in two of the three animals infected with SIVmac239 (Fig. 1). Hence, the extent of SIV replication in the T-cell-rich regions in lymphatic tissue during primary infection might determine the pathogenic outcome of SIV infection.

{Delta}nef mutants of SIV have been used as prototype viruses for attenuated vaccine virus and have been found to induce protective immunity against pathogenic SIVs (12, 24). However, the pathogenic potential of SIV attenuated vaccine strains was reported for newborn macaques and adult macaques (6, 7). Our results provide evidence of the pathogenic potential of a {Delta}nef mutant for juvenile macaques. Relatively high viral loads were noted in {Delta}nef-infected animals compared with those in animals infected with other attenuated SIVs (11, 24). Our results also revealed a gradual decline in the naïve CD4+ T-cell population in two of the three animals (Mm14 and Mm29), despite a stable presence of the memory CD4+ T-cell population (Fig. 2A and B). Because depletion of naïve CD4+ T cells occurs during HIV infection (22), these two animals need to be monitored for the development of AIDS-related symptoms.

Animals infected with attenuated SIVs in testing for vaccine development exhibit nearly sterilizing immunity against pathogenic SIVs (12, 24, 34). On the other hand, safer vaccine regimens, such as DNA priming and modified vaccinia virus Ankara boosting, successfully controlled chronic infection but failed to control primary infection, thus allowing dissemination of SIV-infected cells throughout the body (5). Therefore, further study is needed to elucidate the mechanisms of nearly sterilizing immunity and of the underlying pathogenicity in attenuated-SIV infection in order to develop a safe vaccine.


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ACKNOWLEDGMENTS
 
We thank Ronald C. Desrosiers and Andrew A. Lackner for reviewing the manuscript before submission. We also thank Karen Kent for providing the monoclonal antibody to SIV gp160/gp32 through the EU Programme EVA/MRC Centralised Facility for AIDS Reagents, NIBSC, United Kingdom (grants QLK2-CT-1999-00609 and GP828102).

This work was supported by AIDS research grants from the Health Sciences Research Grants, from the Ministry of Health, Labour, and Welfare of Japan, and from the Ministry of Education, Culture, Sports, Science and Technology of Japan.


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FOOTNOTES
 
* Corresponding author. Mailing address: Tsukuba Primate Center for Medical Science, National Institute of Infectious Diseases, 1 Hachimandai, Tsukuba 305-0843, Japan. Phone: 81-298-37-2121. Fax: 81-298-37-0218. E-mail: mori{at}nih.go.jp. Back


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Journal of Virology, April 2003, p. 4169-4180, Vol. 77, No. 7
0022-538X/03/$08.00+0     DOI: 10.1128/JVI.77.7.4169-4180.2003
Copyright © 2003, American Society for Microbiology. All Rights Reserved.



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