Plasmacytoid Dendritic Cell Dynamics and Alpha Interferon Production during Simian Immunodeficiency Virus Infection with a Nonpathogenic Outcome

We addressed the role of plasmacytoid dendritic cells (PDC)in protection against AIDS in nonpathogenic simian immunodeficiencyvirus (SIVagm) infection in African green monkeys (AGMs). PDCwere monitored in blood and lymph nodes (LNs) starting fromday 1 postinfection. We observed significant declines in bloodduring acute infection. However, PDC then returned to normallevels, and chronically infected AGMs showed no decrease ofPDC in blood. There was a significant increase of PDC in LNsduring acute infection. Blood PDC displayed only weak alphainterferon (IFN- ${alpha}$ ) responses to TLR9 agonist stimulation beforeinfection. However, during acute infection, both blood and LNPDC showed a transiently increased propensity for IFN- ${alpha}$ production.Bioactive IFN- ${alpha}$ was detected in plasma concomitant with the peakof viremia, though levels were only low to moderate in someanimals. Plasma interleukin 6 (IL-6) and IL-12 were not increased.In conclusion, PDC were recruited to the LNs and displayed increasedIFN- ${alpha}$ production during acute infection. However, increases inIFN- ${alpha}$ were transient. Together with the lack of inflammatorycytokine responses, these events might play an important rolein the low level of T-cell activation which is associated withprotection against AIDS in nonpathogenic SIVagm infection.

INTRODUCTION

Top

INTRODUCTION

During primary and chronic human immunodeficiency virus type1 (HIV-1) infection, both subsets of dendritic cells (DC), i.e.,myeloid dendritic cells (MDC) and plasmacytoid dendritic cells(PDC), are decreased in the blood (20, 36, 46). The capacityof PDC to produce IFN- ${alpha}$ is impaired in acute and chronic HIV-1infection (13, 23, 29). Long-term nonprogressors display highernumbers of PDC and a higher capacity for their PDC to produceIFN- ${alpha}$ than progressors (46). Early profound and persistent depletionsof PDC have also been observed in macaques infected with themacaque strain of simian immunodeficiency virus (SIVmac) (4,40). Different mechanisms have been proposed to explain DC declines,including cell death and homing to lymph nodes (LNs) (4, 32,40, 50).

Here, we investigated the dynamics and function of PDC in bloodand LNs during a nonpathogenic infection, i.e., SIVagm infectionin African green monkeys (AGMs). AGMs, like other African nonhumanprimates, such as mandrills and mangabeys, are natural hostsfor SIV and generally do not progress to AIDS despite displayinghigh levels of plasma and intestinal viral load (VL) (21). Naturalhosts for SIV display low levels of T-cell activation, in contrastto HIV-infected humans and SIVmac-infected macaques (6). Exacerbatedchronic T-cell activation might drive CD4 T-cell depletion andAIDS (19, 22). An immunologic activation set point is establishedearly after HIV-1 infection, and this set point is predictiveof the rate at which CD4⁺ T cells are lost over time (11, 49).Innate immune responses acting at the early time points arecrucial for T-cell activation profiles. In the present study,we studied whether PDC are recruited to LNs in response to SIVagmand analyzed early cytokine profiles, including alpha interferon(IFN- ${alpha}$ ) production by blood and LN PDC.

MATERIALS AND METHODS

Top

MATERIALS AND METHODS

Animals and infections. AGMs of the species Chlorocebus sabaeus were housed at InstitutPasteur in Dakar (Senegal) according to institutional and ethicalguidelines. The study included 12 noninfected AGMs (00017, 00021,02001, 02004, 02010, 02015, 02024, 02026, 03005, 03006, 03007,and Thyaliss), 8 naturally infected AGMs (89046, 92017, 93035,00015, 00018, 01016, 02017, and 03002), and 9 AGMs experimentallyinfected with SIVagm.sab92018, of which three were studied exclusivelyin the chronic phase (96030, 97005, and 98011) and the othersix were monitored prospectively. The latter were between 2and 5 years old and consisted of three females (97008, 00020,and 01013) and three males (98013, 01015, and 02003). Threeof these AGMs (97008, 98013, and 00020) were sacrificed at day120 postinfection (p.i.). The inoculum, VLs, and CD4 cell countsof the SIVagm.sab92018-infected monkeys were published previously(26).

SIVagm.sab plasma VL. Plasma viral RNA was quantified using real-time PCR based onamplification of long terminal repeat RNA as previously described(26).

Preparation of cells. Whole blood was collected in EDTA-K2 and heparinized Vacutainer(BD) tubes. Biopsies of peripheral LNs were performed by excision.After careful removal of adhering connective and fat tissues,the LN fragments were mechanically disrupted on a sterile nylonmesh and the cells treated with 20 IU/ml of collagenase typeVII (Sigma) and 20 IU/ml of DNase I (Sigma). Peripheral bloodmononuclear cells (PBMC) and LN mononuclear cells (LNMC) wereisolated by Ficoll-Paque (Pharmacia Biotech AB) density gradientcentrifugation.

Flow cytometry. Flow cytometric analyses were performed on freshly isolatedcells. CD4⁺ T cells were quantitated as previously described(26). For PDC quantification, cells were stained with the followingmonoclonal antibodies: fluorescein isothiocyanate-labeled anti-Lineage(Lin) panel: anti-CD3 (FN18; Biosource)/CD14 (Tük4; Miltenyi)/CD16(3G8; BD)/CD20 (2H7, BD), peridin chlorophyll protein-labeledanti-HLA-DR (L243; BD), and anti-CD123 (7G3; BD). Cross-reactivityof the anti-human MAb had been validated on AGM monocyte-deriveddendritic cells (33, 39). For each sample, 50,000 to 200,000events were acquired. PDC were defined as Lin^– HLA-DR⁺CD123⁺ (Fig. 1) (20, 36).

View larger version (26K):
[in this window]
[in a new window]

FIG. 1. Flow cytometric analysis of AGM PDC. PBMC or LNMC were selected in the R1 gate, excluding debris and polynuclear cells. Lin^– cells (CD3^– CD20^– CD16^– CD14^–) were selected in the R2 gate. CD123⁺ HLA-DR⁺ events were quantified in R3 from R1 x R2 gated events. (A) Blood; (B) LN.

Quantification of bioactive IFN- ${alpha}$ . Plasma IFN- ${alpha}$ titers were determined using a functional assaybased on protection of Madin-Darby bovine kidney (MDBK) cellsagainst the cytolytic effect of vesicular stomatitis virus (37).MDBK are more sensitive to IFN- ${alpha}$ than to IFN-β and are notsensitive to the IFN- ${gamma}$ antiviral effect. The titers were expressedin international units based on the reference standard for humanIFN- ${alpha}$ (G-023-901-527; NIH, Bethesda, MD). This test measuresall subtypes of human IFN- ${alpha}$ (37). The detection limit of thisassay corresponded to 4 IU/ml, which was 7.75 times lower thana multisubtype human IFN- ${alpha}$ enzyme-linked immunosorbent assaykit formulated for serum or plasma (PBL Biomedical Laboratories),at least for AGM plasma IFN- ${alpha}$ (data not shown).

In order to assess IFN- ${alpha}$ production by blood and LN PDC, freshmononuclear cells were exposed to herpes simplex virus type1 (HSV-1) at a multiplicity of infection of 1 (37). Stimulationwith HSV-1 generally occurs through TLR9, which is expressedby PDC. It has been shown that after stimulation of human ormacaque PBMC with HSV-1, PDC are the major producers of IFN- ${alpha}$ (8, 28). We verified that HSV-1 also induces IFN- ${alpha}$ productionby AGM PDC by flow cytometric intracellular staining (data notshown). After 20 h of culture in the presence of HSV-1, viruswas UV inactivated, and IFN- ${alpha}$ activity in the supernatants wasquantified as described above.

Quantification of IL-6 and IL-12. The cytokines IL-12 (p40+p70) and IL-6 in the plasma were measuredby using monkey enzyme-linked immunosorbent assay kits (U-Cytech).The detection limits were 10 and 2.5 pg/ml for IL-12 and IL-6,respectively.

Statistical analysis. Statistical analysis was done with one-way analysis of varianceor with Kruskal-Wallis analysis of variance when assumptionsof normality of the distribution or homogeneity of varianceswere not verified using R (http://www.R-project.org). The assumptionsand the normality of the distribution and variance homogeneitywere, respectively, tested with a Shapiro and a Bartlett test.Data were considered significant when P values were <0.05.For each data set, the procedure analysis was as follows. (i)Determine if the values before infection could be pooled byan analysis of homogeneity of the mean. If the means of differenttime points were not significantly different, all preinfectionvalues could be pooled and constituted the baseline, the lattercorresponding to the mean of all preinfection values. (ii) Determineif the values after infection display a significant varianceby the methods described above. If the postinfection phase isnot homogeneous (at least two time points have different means),determine for each day after infection if the mean is significantlydifferent than the baseline (for each day after infection, H₀:µ_before = µ_day; H₁: µ_before $!=$ µ_day) bya nonparametric Wilcoxon-Mann-Whitney test (or a Student t testwhen the data are normally distributed and when the varianceswere homogenous).

The Spearman rank test was used to assess the correlation betweentwo continuous variables. Multiple regression was used to evaluatethe effect of more than two independent continuous variableson one dependent continuous variable.

RESULTS

Top

RESULTS

Blood PDC levels in uninfected AGMs. Our goal was to study the dynamics and function of PDC in bloodand LNs early after infection in a model of nonpathogenic SIVinfection. PDC were quantified by the method used for humancells (20, 36). PDC numbers were first determined in the bloodof 18 uninfected AGMs (Table 1). The mean number of blood PDCwas 8,703/ml (median, 7,672), and the mean percentage amongPBMC was 0.26% (median, 0.25). The levels were generally inthe same range as those reported for naïve macaques (4,9, 25, 40, 47) and healthy humans (7, 13, 14, 20, 46).

View this table:
[in this window]
[in a new window]

TABLE 1. PDC levels in blood of AGMs

Early but transient declines of blood PDC during primary SIVagm infection. Six of the 18 AGMs described above were then randomly selectedfor a prospective study. They were infected with wild-type SIVagm.sab92018.As described in previous studies, plasma VLs peaked around day8 p.i. (Fig. 2A) (26).

View larger version (21K):
[in this window]
[in a new window]

FIG. 2. VL and T CD4⁺ cell dynamics. (A) Plasma VL in SIVagm-infected AGMs. (B) Blood CD4⁺ T cell counts before and after SIVagm infection.

Blood CD4⁺ T cells significantly declined between days 8 and28 p.i. (P $≤$ 0.007), as previously reported (26). Afterwards,they recovered and reached their preinfection baseline levelsat day 120 p.i. (Fig. 2B).

The mean percentage of PDC before infection in these six AGMswas 0.26% and is thus representative of the uninfected animalsdescribed above. In order to get a robust baseline, we carriedout four to seven measurements for each animal before infection(Fig. 3A). In addition, in order to ensure that the samplingkinetics used did not affect homeostasis, for four of the sixanimals (00020, 01013, 02003, and 98013) we used exactly thesame time intervals for blood collection before infection asbetween days 1 and 13 p.i.

View larger version (32K):
[in this window]
[in a new window]

FIG. 3. PDC dynamics in blood and LNs of AGMs before and after SIVagm infection. (A) Absolute numbers of PDC in blood; (B) PDC percentages in LN. In order to study narrow intervals, LN were collected from three AGMs (97008, 98013, and 00020) at days 1, 3, 8, 13, 28, 42, 63, 91, and 120 p.i. and from three other AGMs (01013, 01015, and 02003) at days 1, 6, 10, 16, 28, and 42 p.i.

We then evaluated the absolute numbers of PDC in blood. Beforeinfection, we observed large fluctuations in the PDC counts;however, the variance was not significant (P = 0.74). PDC countssignificantly declined at days 6, 8, and 10 p.i. (P = 0.0002at day 10 p.i.) and at weeks 4 and 5 p.i. (P = 0.02 and 0.0004,respectively) (Fig. 3A). The levels of PDC then progressivelyincreased again to reach baseline levels starting from day 42p.i. (P = 1). Similar results were observed with percentagesof circulating PDC (data not shown).

We then evaluated PDC counts in the chronic phase of infection.Three of the six AGMs (01013, 01015, and 02003) were studiedat 1 year p.i. (the other three AGMs were sacrificed at day120 p.i.; see below), and we extended the analysis to 11 additionallong-term SIVagm-infected AGMs. The latter consisted of threeexperimentally and eight naturally infected AGMs (1 to 14 yearsof infection; median, 4 years; mean, 6.1 years). We detectedno significant difference in the frequency or the absolute numbersof PDC in a cross-sectional comparison of the 14 chronicallySIVagm-infected AGMs to all noninfected AGMs (Table 1). Therewas no significant difference between the six experimentallyand the eight naturally infected animals regarding the frequencyand the absolute numbers of PDC in blood (data not shown).

There was no correlation between the absolute numbers of PDCwith CD4⁺ T cells during the early phase of infection (days1 to 42 p.i.). During the chronic phase of infection (days 63to 430 p.i.), however, PDC were positively correlated with CD4⁺-T-cellcounts (rho = 0.60, P = 0.003). By multiple regression analysis,PDC counts were predictive for CD4 T cell counts (P = 0.01).

There was no correlation between PDC counts and VL throughoutthe follow-up. Nevertheless, when only the first week p.i. wasconsidered, PDC counts were negatively correlated with VL (rho= –0.55, P < 0.009).

Altogether, we observed early declines of PDC in blood. Thesewere transient, and no depletion was detected in the chronicphase of SIVagm infection. PDC counts were negatively correlatedwith VL during the first week p.i. and positively correlatedwith CD4⁺ counts during the chronic phase of SIVagm infection.

Increased frequencies of PDC in LN during primary SIVagm infection. We wondered whether the transient declines of circulating PDCduring the early stages of SIVagm infection could be linkedwith migration to secondary lymphoid organs. We therefore longitudinallymonitored PDC dynamics in the LNs. For each of the six AGMs,one LN biopsy was performed before infection. For four of thesix animals (98013, 00020, 01013, and 02003), we performed asecond biopsy in order to get the most robust possible preinfectionintraindividual baseline (Fig. 3B). Before infection, the meanpercentages of PDC among mononucleated cells in LNs of the sixAGMs were 0.08% (range, 0.01 to 0.11%) (Fig. 3B). Such levelsare consistent with some reports on rhesus macaques (30). Thevariance among the values before infection was not significant.We then determined LN PDC levels after SIVagm infection startingfrom day 1 p.i. The PDC showed a significant increase at day28 p.i. (P = 0.001) (Fig. 3B). The increases at days 6 and 16were not significant (P = 0.088); however, we sampled only threeanimals for these time points. These increased proportions werefound to have a temporal association with decreases in bloodcounts. There was indeed a trend toward a significant negativecorrelation between LN and blood PDC (rho = –0.28, P =0.09).

During the chronic phase of infection (days 42 to 120 p.i.),no significant increase of PDC was observed in LNs.

Because of the suggested potential important role of the gutin AIDS pathogenesis, we also evaluated DC frequencies in mesentericLN for three animals (97008, 98013, and 00020) that were sacrificedat day 120 p.i. The mean percentages of PDC in mesenteric LNcorresponded to 0.08% and were thus similar to those in peripheralLNs (data not shown).

Altogether, our longitudinal study revealed a significant increaseof PDC in LN during primary SIVagm infection.

Increased IFN- ${alpha}$ production during primary SIVagm infection. Since PDC were increased in LNs at early stages of SIVagm infection,we addressed the question of the functionality of these cells.One major function of PDC in the setting of a viral infectionis the production of large amounts of IFN- ${alpha}$ (44). We quantifiedthe levels of bioactive IFN- ${alpha}$ in the plasma of the six AGMs.The quantification method was the same as that previously usedfor humans and in the SIVmac251/rhesus macaque model (23, 24).Plasma IFN- ${alpha}$ increased as early as day 1 p.i. in two of six AGMs(02003 and 01015) and was increased in all animals at days 8and 10 p.i. (Fig. 4A). Plasma IFN- ${alpha}$ reached levels of 2,500 IU/mlat day 8 p.i. The peak of IFN- ${alpha}$ was coincident with the peakof VL. IFN- ${alpha}$ titers then decreased, and from day 35 p.i. on,they remained below detection level in all animals. We analyzedwhether plasma IFN- ${alpha}$ levels correlate with VL during primaryinfection (day 1 to day 35 p.i.). There was a significant positivecorrelation (rho = 0.61, P < 0.0001).

View larger version (18K):
[in this window]
[in a new window]

FIG. 4. Levels and production of bioactive IFN- ${alpha}$ . (A) IFN- ${alpha}$ levels in plasma. The detection level of the assay was 2 IU/ml. (B) IFN- ${alpha}$ concentrations in supernatants of PBMC stimulated with HSV-1 in vitro. Cells were collected before and after infection from all six animals until day 120 p.i. For day 330 p.i., three of six animals were studied (01013, 01015, and 02003). (C) IFN- ${alpha}$ production by LN PDC. LNMC were collected from the six longitudinally monitored AGMs at four time points before infection and at seven time points during primary infection. LNMC were stimulated with HSV-1 in vitro, and the concentrations of IFN- ${alpha}$ in the supernatants were quantified. Data are ratios of the IFN- ${alpha}$ concentration and the percentage of LN PDC before infection and during primary infection.

In order to address the question of whether PDC might contributeto the heightened IFN- ${alpha}$ levels in plasma, we analyzed the capacityof AGM blood and LN PDC to produce IFN- ${alpha}$ . We quantified IFN- ${alpha}$ production after stimulation with a TLR9 agonist. In order tohave a robust baseline, we measured eight time points beforeinfection (Fig. 4B). Without stimulation, IFN- ${alpha}$ levels were <6IU/ml (data not shown). After stimulation, the median valuesranged from 34 to 350 IU/ml. Two AGMs (00020 and 01015) displayedstrong intraindividual variation and occasionally produced highlevels (between 800 and 1,400 IU/ml) at two preinfection timepoints (Fig. 4B). Overall, stimulation with the TLR9 agonistresulted in significantly increased IFN- ${alpha}$ production. However,the levels produced were four times lower than those of humancontrols (23).

After infection, median values of IFN- ${alpha}$ produced by blood AGMPDC ranged from 200 to 1,750 IU/ml. Compared to preinfectionlevels, IFN- ${alpha}$ production was significantly increased during primarySIVagm infection between days 3 and 21 p.i. (P $≤$ 0.017 for eachtime point) (Fig. 4B). When days –55 and –48 wereomitted from the baseline values, days 1 and 28 p.i. also showedsignificant increases (P $≤$ 0.001). The highest levels of production(peak values up to 4,000 IU/ml) were observed around 1 weekafter the peak of plasma viremia and of plasma IFN- ${alpha}$ . There wasno correlation between PDC numbers and their IFN- ${alpha}$ productioncapacity, but there was a significant positive correlation betweenVL and IFN- ${alpha}$ production by PDC (rho = 0.57, P < 0.0001).

We then quantified the ability of LN PDC to produce IFN- ${alpha}$ . Themedian values of IFN-production were 62.5 IU/ml before infectionand 525 IU/ml after infection (data not shown). Again, cellscollected during primary infection were more prone to produceIFN- ${alpha}$ than those obtained before infection (P = 0.01). To investigatewhether the increases in IFN- ${alpha}$ production by LN PDC are due totheir increases in percentages, we plotted the ratio of IFN- ${alpha}$ production per PDC percentages in LN (Fig. 4C). The differencein the ratios between cells from before and during primary infectionwas again significant (P = 0.0065). There was no correlationbetween levels of PDC and IFN- ${alpha}$ production (P = 0.6).

In summary, SIVagm-infected AGMs showed increased levels ofIFN- ${alpha}$ in plasma during primary infection. Moreover, both bloodand LN PDC were capable of producing IFN- ${alpha}$ in response to a TLR9agonist in vitro, and the propensity for IFN- ${alpha}$ production wassignificantly increased during primary SIVagm infection.

No detectable increase of IL-6 and IL-12 in plasma. Like IFN- ${alpha}$ , many other cytokines are secreted by antigen-presentingcells and involved in the early orientation of T-cell responses.We previously measured tumor necrosis factor alpha (TNF- ${alpha}$ ) andIL-10 in the plasma of these monkeys (26). Here, we also measuredIL-12 and IL-6 because of their respective roles in Th1 inductionand Treg inhibition (10, 41). Although there was a trend towarda significant change in plasma IL-12 at 16 p.i. (P = 0.052),overall the levels of plasma IL-12 did not increase during acuteSIVagm infection (Fig. 5A). IL-6 in plasma from AGMs did notincrease at any time point in response to SIVagm infection (Fig.5B).

View larger version (21K):
[in this window]
[in a new window]

FIG. 5. IL-6 and IL-12 plasma levels during primary SIVagm infection. (A) IL-12_p40+p70 concentrations in plasma; (B) IL-6 concentrations in plasma.

DISCUSSION

Top

DISCUSSION

We show here that AGMs display a decline of PDC in blood duringprimary SIVagm infection. We detected two nadirs. The possibilitythat such oscillations also occur in HIV-1 and SIVmac infectionsand might have been previously undetected because previous studieswere not performed with such early and narrow intervals as thisone can not been excluded. The blood PDC levels showed a trendtoward a negative correlation with PDC levels in LNs. The PDCdepletion in blood might thus be explained, at least in part,by recruitment to lymphoid organs. It is likely that PDC migrateto LN also during early HIV-1 infection, since the density ofCD123⁺ cells in T-cell zones increases in LN from asymptomaticHIV-1-infected patients (16).

During chronic SIVagm infection, we did not observe any signof PDC depletion. The restoration of PDC to normal levels afterthe acute phase of SIVagm infection is in sharp contrast withpathogenic HIV/SIVmac infections, where the levels are onlypartially restored after primary infection (7, 23, 40). Duringthe chronic phase of SIVagm infection, PDC counts were positivelycorrelated with CD4⁺ T cell counts. Thus, our study supportsprevious observations in humans suggesting that the degree ofrecovery of PDC after the primary infection has good prognosticvalue regarding disease outcome (7, 36, 46).

AGMs may maintain a better ability to generate DC precursors.In line with this, it was reported that SIV-infected sooty mangabeysexhibited preserved functions of bone marrow, at least regardingtheir T-lymphocyte-regenerative capacity, whereas macaques didnot (45, 48). Another possibility is better survival. PDC aresusceptible to HIV-1 and SIVmac infection in vivo (15, 40).Interestingly, though, viral replication in PDC occurs onlyfollowing maturation as induced with CD40L or TNF- ${alpha}$ , and celldeath of HIV-infected human PDC occurs only when the PDC havecontact with activated CD4⁺ cells (15, 43). Chronically infectedAGMs display lower levels of activated lymphocytes and TNF- ${alpha}$ than SIVmac-infected macaques (26), and DC might thus be lesssusceptible to death in AGMs. Finally, the depletions in HIV-1infections may also be explained by continuous recruitment intolymphoid organs (2, 31).

The proinflammatory cytokines IL-6 and IL-12 were not increasedin plasma. These data are in line with our previous resultsin AGMs, showing no or only weak increases of proinflammatorycytokine (TNF- ${alpha}$ , IFN- ${gamma}$ , and MIP-1 ${alpha}$ ) and Th1 transcription factor(t-bet) expressions (26, 38). In contrast, macaques generallyshow increases in proinflammatory cytokines such as IL-6 andTNF- ${alpha}$ (1, 3, 17, 35). Plasma IFN- ${alpha}$ levels were significantly increasedduring primary SIVagm infection and strongly correlated withVL, as is also the case in SIVmac infection (18, 24). However,the increases were very transient, and high levels (above 1,000IU/ml) were detected at only one time point, which correspondedto the peak of viremia (day 8 p.i.). Moreover, in a recent studythat we performed using the same quantification method, thepeak IFN- ${alpha}$ levels were generally higher in SIVmac-infected macaquesthan in AGMs (C. Butor, unpublished data). In line with this,PDC from noninfected AGMs produced lower levels of IFN- ${alpha}$ afterTLR9 stimulation than cells from humans (23).

During primary SIVagm infection, PDC were prone to produce IFN- ${alpha}$ .The levels were significantly increased, the highest levelsbeing observed after the peak of plasma IFN- ${alpha}$ , which is mostlikely related to a positive feedback loop of IFN- ${alpha}$ (28). Thecapacity of AGM PDC to produce IFN- ${alpha}$ was not correlated withthe PDC counts, similar to what has been reported for HIV-1,where a correlation was detected in chronic but not primaryinfection (36). In both cases, this might be explained eitherby the presence of other cellular sources of IFN- ${alpha}$ or by variableIFN- ${alpha}$ production among PDC cells. We do not know whether AGMPDC would also show increased IFN- ${alpha}$ production after stimulationwith SIV or TLR-7 agonists in vitro. However, plasma IFN- ${alpha}$ levelsare increased, and the strong correlation with the VL suggestsa role for the virus in IFN- ${alpha}$ induction in vivo.

TLR9 stimulated PDC are able to induce CD4⁺ and CD8⁺ Treg (34).Human MDC treated with IFN- ${alpha}$ and IL-10 have been shown to becometolerogenic and able to induce regulatory CD4⁺ T cells in vitro(5, 27, 42). On the other hand, IL-6, which is increased inmacaques but not in AGMs, can prevent CD4⁺ CD25⁺ Treg regulatoryfunctions (12). It is thus possible that, due to the particularcytokine environments during early SIVagm infection, MDC donot migrate massively to LNs and/or that the DC are conditionedto preferentially induce regulatory T cells. In fact, our previousdata suggested the presence of CD4⁺ and CD8⁺ regulatory T cellsduring SIVagm infection (26).

In summary, our study reveals declines in levels of PDC in bloodduring primary SIVagm infection. The declines are only transient,as normal levels are maintained afterwards. Conversely to blood,PDC frequencies were increased in AGM LNs during primary SIVagminfection. Blood and LN PDC showed a heightened propensity toproduce IFN- ${alpha}$ during primary infection. Plasma IFN- ${alpha}$ levels wereincreased during primary infection, but the peak levels wereoften low and always transient. The preservation of functionalPDC in the absence of strong proinflammatory responses mightbe at the origin of control of generalized T-cell activationand AIDS.

ACKNOWLEDGMENTS

We thank M. Ndiaye and M. Touré for assistance with animalcare. We are indebted to Anne Badel and Anne Camproux for theirexpert contributions in statistical analysis. We thank LisaAn for help with VL assays, Sandrine Kahi and Lene Vimeux forhelp with DC flow cytometry setups, Véronique Mayau forhelp with data analysis and editing, Jamie Robinson for revisionof the English, D. Scott-Algara for critical reading of themanuscript, and all members of the Dendritic Cells Working Groupfrom the ANRS (AC19) for helpful discussions.

This study was supported by grants from the French Agency forAIDS Research (ANRS). M.J.-Y.P. received scholarships from theMNERT and Sidaction, and L.M. and D.K. received fellowshipsfrom ANRS.

FOOTNOTES

* Corresponding author. Mailing address: Unité de Régulation des Infections Rétrovirales, 25, rue du Dr Roux, Institut Pasteur, 75015 Paris, France. Phone: 33140613969. Fax: 33145688957. E-mail: mmuller{at}pasteur.fr

Published ahead of print on 2 April 2008.

^# Present address: Department of Microbiology and Molecular Immunology,Brown University, Providence, RI.

Present address: University of Insubria, Department of Clinicaland Biological Sciences, Varese, Italy.

REFERENCES

Top