Naive T-Cell Dynamics in Human Immunodeficiency Virus Type 1 Infection: Effects of Highly Active Antiretroviral Therapy Provide Insights into the Mechanisms of Naive T-Cell Depletion

Both naïve CD4⁺ and naïve CD8⁺ T cells are depletedin individuals with human immunodeficiency virus type 1 (HIV-1)infection by unknown mechanisms. Analysis of their dynamicsprior to and after highly active antiretroviral therapy (HAART)could reveal possible mechanisms of depletion. Twenty patientswere evaluated with immunophenotyping, intracellular Ki67 staining,T-cell receptor excision circle (TREC) quantitation in sortedCD4 and CD8 cells, and thymic computed tomography scans priorto and $~$ 6 and $~$ 18 months after initiation of HAART. NaïveT-cell proliferation decreased significantly during the first6 months of therapy (P < 0.01) followed by a slower decline.Thymic indices did not change significantly over time. At baseline,naïve CD4⁺ T-cell numbers were lower than naive CD8⁺ T-cellnumbers; after HAART, a greater increase in naïve CD4⁺T cells than naïve CD8⁺ T cells was observed. A greaterrelative change (n-fold) in the number of TREC⁺ T cells/µlthan in naïve T-cell counts was observed at 6 months forboth CD4⁺ (median relative change [n-fold] of 2.2 and 1.7, respectively;P < 0.01) and CD8⁺ T cell pools (1.4 and 1.2; P < 0.01).A more pronounced decrease in the proliferation than the disappearancerate of naïve T cells after HAART was observed in a secondgroup of six HIV-1-infected patients studied by in vivo pulselabeling with bromodeoxyuridine. These observations are consistentwith a mathematical model where the HIV-1-induced increase inproliferation of naïve T cells is mostly explained by afaster recruitment into memory cells.

INTRODUCTION

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Introduction

The mechanisms leading to CD4⁺ T-cell depletion during humanimmunodeficiency virus (HIV) infection and CD4⁺ T-cell restorationduring therapy with highly active antiretroviral therapy (HAART)remain undefined. Direct viral cytopathogenicity or redistributionof lymphocytes between lymphoid tissues and the circulationcan account only in part for these changes (28, 32, 41). Characterizinglymphocyte turnover in HIV-infected patients can potentiallylead to a better understanding of these mechanisms.

A number of studies utilizing indirect methods (2, 21, 31, 40,48) and, more recently, direct methods using deuterated glucose(25, 36) or 5-bromo-2'-deoxyuridine (BrdU) (29) to measure CD4cell dynamics have shown that CD4 cell turnover is increasedduring chronic HIV type 1 (HIV-1) infection. Moreover, whilepreliminary cross-sectional studies described an increase inCD4 cell turnover in patients following initiation of HAART,suggesting a defect in CD4 cell production secondary to HIVinfection (12, 25), longitudinal studies have clearly demonstrateda rapid and persistent decrease in CD4 cell proliferation followinginitiation of HAART, suggesting that the increase in CD4 cellturnover itself may be an important pathogenic mechanism ofCD4 depletion (21, 29, 36). While this increased turnover wasinitially postulated to represent a homeostatic response toCD4 depletion (11, 12), such a hypothesis is inconsistent withthe rapid reduction in proliferation of CD4⁺ as well as CD8⁺T cells after viral suppression with HAART, prior to normalizationof CD4 cell numbers (2, 29, 31, 36). These observations ledto alternative hypotheses proposing that either HIV-directedor nonspecific immune activation drives increased turnover.Moreover, based in part on studies demonstrating that levelsof immune activation in T cells, especially CD8 cells, are independentpredictors of CD4 depletion and disease progression, immuneactivation is currently felt by many investigators to play adirect role in HIV-associated CD4 depletion (17, 34, 43).

An increase in turnover has been demonstrated in naïveT cells (24, 26) as well as memory T cells during pathogeniclentiviral infection. Whereas memory CD4⁺ but not memory CD8⁺T cells decrease in number during chronic HIV infection, bothnaïve CD4⁺ as well as naïve CD8⁺ T cells are depletedduring such infection (5, 22, 39). This observation led to theconclusion that naïve T-cell depletion is one of the hallmarksof HIV infection. While infection of naïve T cells hasbeen documented, this appears to be a relatively rare eventthat cannot quantitatively explain the loss of naïve CD4⁺T cells. The observation that both naïve CD4⁺ and naïveCD8⁺ T cells decrease during HIV infection led to the hypothesisthat persistent hyperactivation of the immune system leads toerosion of naïve T cells by their increased recruitmentinto memory cells (20), probably through antigen- and nonantigen-specificstimulation, as has been shown in animal models (18, 37).

Because the thymus is the source of new T cells, examining thymicfunction during HIV infection and therapy is critical to studiesof T-cell dynamics (14, 19). Due to the difficulties in directlystudying thymic function, quantitation of T-cell receptor excisioncircles (TRECs) has been utilized as a surrogate of thymic function.Early studies measuring the number of TRECs per naïve Tcell suggested that HIV infection leads to a decrease in thymicfunction and that improved thymic function contributes to immunereconstitution following HAART (9). More recently, studies usingmathematical modeling showed that the observed changes in TRECcontent cannot be explained solely by changes in thymic function(21) or by redistribution of T lymphocytes from lymphoid tissuesto the blood (32); the observed TREC dynamics were more consistentwith changes in peripheral proliferation and disappearance ratesof T-lymphocytes.

In the current study we undertook a detailed examination ofthe relationship between T-cell turnover, thymic function, andimmune activation in HIV-1-infected patients to better understandthe contribution of these various parameters to the immunologicchanges seen during HIV infection and therapy.

MATERIALS AND METHODS

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Materials and Methods

Patient characteristics. Twenty-three HIV-1-infected patients who were initiating HAART(n = 20), starting HAART after a 6- and 24-month treatment interruption(n = 2), or switching from an ineffective to an effective HAARTregimen (n = 1) were studied. Twenty previously untreated (orwith limited nucleoside analogue exposure) HIV-1-infected patients(group 1) enrolled between 1997 and 2000 in a study to identifyviral reservoirs in patients receiving antiretroviral therapy.These patients initiated therapy with indinavir, nevirapine,lamivudine, and zidovudine (or stavudine [one patient]). Drugchanges were permitted for intolerance; for 14 patients, zidovudinewas replaced by stavudine, and for 6 patients, indinavir wasreplaced by nelfinavir. After at least 1 year on study, additionalchanges were permitted at the patient's and referring physician'sdiscretion; seven patients made such changes, usually for simplificationof the regimen. All patients ultimately demonstrated a virologicresponse, with declines in plasma viral loads to levels belowbranched DNA assay limits (<50 copies/ml, 18 patients; <500copies/ml, 2 patients) and all but 2 patients had an increasein CD4 cell numbers of at least 100 cells/mm³. Group 1 patientshad immunophenotyping analysis and evaluation of thymic functionby TREC analysis and thymic computed tomography (CT) scans atthe following time points: 0 (pre-HAART), 1 (5 to 8 months,median of 6 months after start of therapy), and 2 (13 to 42months, median of 18 months after start of therapy). Naïvecell labeling kinetics were analyzed for six HIV-1-infectedpatients (group 2) who had undergone in vivo pulse labelingwith BrdU prior to and 3 to 6 months after the initiation ofan effective HAART regimen. Three of these patients are alsoincluded in group 1; the remaining three received stavudine,lamivudine, indinavir, and nevirapine (one patient); stavudine,lamivudine, and efavirenz (1 patient); and abacavir, amprenavir,nelfinavir, and efavirenz (one patient). Results for CD4 andCD8 cell labeling, but not naïve cell labeling, have beenpreviously reported for this group (29). Baseline characteristicsfor group 1 and pre- and post-HAART parameters for group 2 areshown in Tables 1 and 2.

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TABLE 1. Baseline patient characteristics for group 1

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TABLE 2. Pre- and post-HAART viral loads and CD4⁺ and CD8⁺ T cell counts for group 2

Viral load. HIV-1 RNA levels were determined using a modification of theRoche Amplicor HIV Monitor assay kit (Indianapolis, IN) (27)or a branched DNA assay (Bayer Diagnostics, Tarrytown, NY) (3).Each assay had a lower limit of detection of 50 copies/ml; fortwo patients enrolled early in the study, the limit of detectionwas 500 copies/ml.

Immunophenotyping and intracellular staining for Ki67. Immunophenotypic analysis of cryopreserved peripheral bloodmononuclear cells was performed using four-color immunofluorescenceas previously described (42). Naïve cells were definedas CD45RO^– CD27⁺, central memory were defined as CD45RO⁺CD27⁺, and effector memory were defined as CD45RO⁺ CD27^–for CD4 T cells and as CD27^– (CD45RO⁺ or CD45RO^–)for CD8 T cells. Cells were stained intracellularly with Ki67-phycoerythrin(clone B56) or isotype (mouse immunoglobulin G1-phycoerythrin;clone MOPC-21) from BD/Pharmingen. T-cell proliferation wasdefined as the percentage of cells expressing Ki67 (15).

TREC determination. Signal joint TRECs (Sj-TRECs) in purified cell subsets werequantitated by real-time PCR by the cell lysis method as describedpreviously (38). The consistency of the DNA content of the celllysate was checked by real-time PCR using a ribosomal proteingene and a TaqMan gene expression assay kit from Applied Biosystems,Inc. (Foster City, CA). Because no more than one Sj-TREC canbe produced per cell, the number of TRECs per unit volume ofblood also represents the number of TREC⁺ T cells in the sameunit volume.

Thymic CT scans. CT scans of the thymus were obtained prior to and at a medianof 6 and 18 months after starting HAART. Scans were graded aspreviously described on a 0 (no thymic tissue) to 5 (thymicmass) scale by two independent radiologists blinded to clinicaland laboratory results (35). In addition, computer-based densityand volume analysis of the thymus was performed by transferringCT data to a GE Advantage Windows workstation (versions 2.1and 4.0; GE Medical Systems, Advanced Windows Workstation TrainingProgram, Milwaukee, WI). Contours of the anterior mediastinumwere outlined by a radiologist-trained technician and corroboratedby a radiologist (13).

BrdU infusion and flow cytometry. The fractions of BrdU⁺ CD4⁺ CD45RO^– and BrdU⁺ CD8⁺ CD45RO^–T cells were analyzed by flow cytometry as previously described(29).

Statistics. Changes in median values for each variable were tested for significanceby the permutation test with paired samples computed with anexact method (44). Tests were performed using StatXact software.Association between variables was determined by the Spearmanrank correlation test. Adjustment of P values for multiple testingwas done by the Bonferroni method. Occasional data points weremissing for group 1; however, all paired analyses were testedwith n values that were $≥$ 15.

The relative change (n-fold) of a variable H between time (t)points (e.g., t₀ and t₁) is defined as the ratio between thevalue of H at t₁ versus t₀: H(t₁)/H(t₀).

Modeling. Differential equations were solved using Labview 7.0 (NationalInstruments, Austin, TX). The data were fitted to the differentialequations using the Levenberg-Marquardt method (16).

Mathematical model for TREC analysis. To help interpret the data obtained in this study, we proposea slight generalization of a mathematical model originally describedby Hazenberg et al. (21). The number of naïve T cells/µl(T) and the number of TREC⁺ T cells/µl (T⁺) are governedby the following equations:

Formula 1 (1)

Formula 1

Naïve CD4⁺ or CD8⁺ T cells, T, in the periphery receivea constant input from the thymus, ${sigma}$ , proliferate at rate p (day^–1)and disappear at a rate d (day^–1). TREC⁺ T cells, T⁺,appear at a lower rate of thymic production (f ${sigma}$ ) and disappearfrom the same compartment as naïve T cells at a rate d.We assume that naïve T cells can proliferate without losingtheir naïve phenotype as has been reported (45-47). SinceTRECs do not replicate during cell mitosis (9), proliferationof TREC⁺ T cells decreases the fraction of TREC⁺ T cells pernaïve T cell (T⁺/T).

Since changes in T and T⁺ occur very slowly, the steady-statevalues obtained by equation 1 can be used to analyze how changesin the parameters ( ${sigma}$ , d, p, and f) would affect changes in thenumber of naïve cells, T, the number of TREC⁺ cells, T⁺,and the fraction of TREC⁺ T cells per naïve T cell (T⁺/T):

Formula 2 (2)

Formula 2

Formula 2
For the generalization in equation1, we assume that the disappearance rate, d, is a compositeof two different factors: d = ${delta}$ _A + ${delta}$ _R, where ${delta}$ _A represents thedeath rate of naïve cells and ${delta}$ _R is the rate of primingof naïve cells into memory cells (7, 23). We also assumethat the increase in the proliferation rate of naïve Tcells during chronic HIV-1 infection (p $->$ p + ${Omega}$ ) is largely explainedby the increase in the rate of priming of naïve T cellsinto memory cells ( ${delta}$ _R $->$ ${delta}$ _R + ${Omega}$ ). Thus, the generalized model hasbeen simulated to predict the changes in naïve T-cell counts,TREC⁺ T cells, and the fraction of TRECs per naïve T cellafter HAART, when the perturbation of the quasi-steady stateinduced by the administration of HAART is described mathematicallyby the reduction of ${Omega}$ .

Mathematical model for the kinetics of BrdU-labeled naïve T cells. To describe the in vivo kinetics of BrdU-labeled naïveT cells in the blood after a 30-min BrdU infusion, we used thefollowing semiempirical equation (29):

Formula 3 (3)

Formula 3

The pool of labeled cells in the blood, L, is refilled at aconstant rate s until time ${tau}$ , and labeled cells disappear fromthe pool of naïve T cells in the blood with a disappearancerate d*. In developing this semiempirical model, it is assumedthat lymphoid tissue serves as an effective source of labeledcells that are distributed to the blood until equilibrationis reached (time ${tau}$ ), at which point the effective source ceasesto affect changes in the concentration of labeled cells (29).Because BrdU⁺ chromosomes segregate independently into daughtercells, labeled cells that have divided will still be countedas BrdU⁺ cells, as long as the intensity of BrdU in each cellis higher than the threshold of flow cytometric detection. Inhuman lymphocytes we estimate that the BrdU intensity decreasesbelow the detection threshold after two to three divisions (datanot shown). Thus, for highly proliferating cells equation 3is approximately similar to a model where d* consists only ofthe disappearance rate of labeled cells (29). For more slowlyproliferating cells, such as naïve T cells, a possiblecontribution of proliferation can be taken into account by replacingd* with d – p, which is similar to an equation proposedby Debacq and colleagues (4). When d* is small (<<1) thesolution of equation 3 for t $≤$ ${tau}$ is given by , or the fraction of labeled cells increasesapproximately linearly over time with a rate s. Thus, the solutionof equation 3 used in this analysis is given by

Formula 4 (4)

Formula 4
Moreover,if the peak of labeling is reached at similar times betweenrecipients, the value of the fraction of BrdU-labeled cellsat the peak will correlate with s and, thus, with proliferationrates (4).

For BrdU labeling, naïve CD4 cells are defined as CD45RO^–,as additional markers were not utilized in these analyses. ForCD4 cells, this is a good approximation of true naïve cells(6, 30).

RESULTS

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Results

Effect of HAART on viral load, T-cell counts, and T-cell proliferation. Sixteen of 20 group 1 patients had suppression of viral loadsto <50 copies/ml at time point 1, and 18 of 20 had the sameresult at time point 2. Subjects had a mean CD4 count increasecompared to a baseline of 144 cells/µl (range, 33 to 515cells/µl) at time point 1 ( $~$ 6 months) and 286 cells/µl(range, 17 to 643 cells/µl) at time point 2 ( $~$ 18 months;P < 0.01) (Table 3).

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TABLE 3. Flow cytometry parameters and thymic indices for group 1 patients during the study period

Statistically significant increases in naïve CD4⁺ T cellswere observed at both time points 1 and 2 compared to baseline(from 87 to 127 and 164 cells/µl, respectively; P <0.01), while statistically significant increases in naïveCD8⁺ T cells were only observed at time point 2 (from 114 to175 cells/µl; P < 0.05) (Table 3). At baseline, naïveCD4⁺ T-cell numbers were lower than naïve CD8 T-cell numbers(P < 0.05) but not at time point 1 or time point 2. Thus,the increase in naïve T cells from baseline was higherfor naïve CD4⁺ T cells than naïve CD8⁺ T cells attime point 1 (mean increase, 55 versus 24 cells/µl; P< 0.05) and at time point 2 (mean increase, 104 versus 68cells/µl; P < 0.05). The additional changes betweentime points 1 and 2 in naïve T-cell numbers did not differbetween naïve CD4⁺ and naïve CD8⁺ T cells.

Significant inverse Spearman rank correlations were observedbetween baseline naïve T-cell counts and the relative change(n-fold) in naïve T cells for both CD4⁺ and CD8⁺ T cellsat time point 1 ( ${rho}$ = –0.53, P < 0.05 for CD4; ${rho}$ = –0.48,P < 0.05 for CD8) and time point 2 ( ${rho}$ = –0.82, P <0.01 for CD4; ${rho}$ = –0.64, P < 0.01 for CD8).

Significant declines in Ki67 expression were observed in bothCD4⁺ and CD8⁺ naïve and central memory T cells at timepoint 1 (P < 0.01) (Table 3). Before HAART, a median of 3.8%of naïve CD4 cells and 5% of naïve CD8 cells wereKi67⁺, with the difference between the means reaching borderlinestatistical significance (P = 0.05). At time point 1 these numbersdecreased to 1.7 and 2.3%, respectively (P < 0.01). The additionalobserved declines at time point 2 to 1.4% and 1.3%, respectively,were not statistically significant (P > 0.05, between timepoints 1 and 2). Moreover, the relative change (n-fold) in percentKi67⁺ naïve CD4⁺ T cells between time point 0 to time point1 inversely correlated with the corresponding relative changein CD4⁺ naïve T-cell counts at the same time points (Spearmanrank correlation, ${rho}$ = –0.54, P = 0.017). No similar correlationwas observed between time points 1 and 2 or between any timepoints for naïve CD8⁺ T cells.

Greater relative change (n-fold) in TRECs/µl than naïve T cells/µl in CD4⁺ and CD8⁺ T cells after HAART. A statistically significant increase in TRECs/µl fromtime point 0 to time point 1 (P < 0.01) was seen for bothnaïve CD4⁺ T cells and naïve CD8⁺ T cells (Fig. 1).A greater relative increase (n-fold) was seen in the numberof TRECs/µl than in the naïve T-cell counts in bothCD4⁺ (median relative increases of 2.2- and 1.7-fold, respectively,P < 0.01) and CD8⁺ T-cell pools (1.4- and 1.2-fold, respectively,P < 0.01) at time point 1. This observation is equivalentto an increase in the fraction of TRECs, i.e., TRECs per millionnaïve T cells, after initiation of HAART (Fig. 1), consistentwith previously reported data (21, 32). The relative increasewas observed to be lower for TRECs/µl than for naïveT-cell counts from time point 1 to time point 2, with this differencebeing statistically significant for CD4⁺ T cells (P < 0.05)but not for CD8⁺ T cells. No significant correlations were observedbetween the relative change in percent Ki67⁺ naïve CD4⁺T cells at time point 1 to time point 0 and the relative changein TREC⁺ cells at the same time points (for CD4⁺, n = 14, ${rho}$ =–0.03, and P = 0.47; for CD8⁺, n = 16, ${rho}$ = –0.05,and P = 0.41). The lack of correlation between changes in theproliferation of naïve T cells and the change in the fractionof TREC⁺ cells per naïve T cell suggests that it is notthe extent of reduction in proliferation per se that can explainthe greater relative change in TRECs/µl versus naïveT-cell counts, but the latter does probably depend on changesin both the proliferation and disappearance rate of the naïvepool after the initiation of HAART.

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FIG. 1. Naïve T-cell counts, TRECs per microliter of blood, and fraction of TREC⁺ T cells per 10⁶ naïve T cells for CD4 and CD8⁺ T cells at the three time points of the study. Values are the means ± standard errors of the means. *, P < 0.05; **, P < 0.01 (versus time point 0).

Thymic indices did not significantly change during HAART and did not correlate with changes in TRECs. CT scoring was carried out by two radiologists blinded to clinicaland laboratory data. The median baseline score was 1.5 (0.5to 3.0). Median scores remained constant at time point 1 (1.5;range, 0.5 to 4) and at time point 2 (1.5; range, 0.5 to 4),with a median change for both time points of 0 (Table 3). Whenscores were clustered according to subjects with greater thanand less than or equal to the median CD4 increase of 96 cells/µlat time point 1 and 257 cells/µl at time point 2, differencesagain were not significant. By volumetric analysis, the medianscore prior to initiating HAART was 1.58 cm³ (0.75 to 11.9).At time point 1 there was a median increase of 0.17 cm³ (–4.24to 9.33); an additional period of approximately 12 months ofHAART resulted in a median change of –0.04 cm³ (range,–5.27 to 6.5). None of these changes was statisticallysignificant (Table 3). Baseline naïve CD4⁺, but not naïveCD8⁺, T-cell counts positively correlate with thymic volume(data not shown). An inverse statistically significant correlationwas observed between the relative change (n-fold) in naïveT cell counts and baseline CT scores for naïve CD4⁺ T cells( ${rho}$ = –0.52, P < 0.05) but not for naïve CD8⁺ Tcells ( ${rho}$ = –0.08, P > 0.05). Partial Spearman rank correlationanalysis that included age or baseline naïve T-cell countsdid not qualitatively change the statistical significances ofthe above correlations. Similar patterns of correlations wereobserved when CT scores were replaced by thymic volumes. Inaddition, thymic volume changes did not correlate with changesin any TREC parameters.

Analysis of the model. A possible explanation for the greater relative change in TRECs/µlversus naïve T-cell counts can be provided by a model ofnaïve T-cell dynamics similar to the one described in equation1 with the disappearance rate, d, a composite of two differentfactors: d = ${delta}$ _A + ${delta}$ _R, where ${delta}$ _A represents the death rate of naïvecells and ${delta}$ _R is the rate of priming of naïve cells intomemory cells (7, 23). Assuming that the increase in the proliferationrate of naïve T cells during chronic HIV-1 infection (p $->$ p + ${Omega}$ ) is mostly explained by the increase in the rate of primingof naïve T cells into memory cells ( ${delta}$ _R $->$ ${delta}$ _R + ${Omega}$ ) (Fig. 2A),naïve T-cell counts will not substantially change, sincethe increased recruitment of naïve T cells into memorycells is counterbalanced by the simultaneous increase in theproliferation rate of naïve T cells (without losing theirphenotypes). Conversely, if the main effect of HAART consistsof reducing the rate of priming ( ${Omega}$ $->$ 0, with time), again, naïveT-cell counts will be only marginally affected since the consequentdecrease in recruitment (and consequent loss) of naïveT cells is now counterbalanced by the simultaneous decreasein the proliferation rate. However, the reduction in proliferationwill lead to an increase of the naïve T-cell (and thusTREC⁺ T cell) life span or, equivalently, the decrease in disappearancerate d. This leads to an increase in TREC⁺ T cells/µl,and since the naïve T-cell counts are only marginally affected,the fraction of TREC⁺ T cells per naïve T cell is alsopredicted to increase.

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FIG. 2. (A) Diagram of the model used to describe the changes in naïve T-cell counts and TREC⁺ T cells/µl during HIV infection and after initiation of HAART. The proliferation rate of naïve T cells is increased during HIV-1 infection by a factor ${Omega}$ as a result of the increase in the rate of priming into memory cells. (B) HAART-induced changes in the fraction of TREC⁺ T cells per naïve T cell (left) and TREC⁺ cells/µl and naïve T-cell counts (right) predicted by a model that assumes that the HIV-1-induced increase in proliferation of naïve T cells is largely explained by the increase in rate of priming: Formula 4 = ${sigma}$ + [p + ${Omega}$ (t)]T – [ ${delta}$ _A + ${delta}$ _R + ${Omega}$ (t)]T and = f ${sigma}$ – [ ${delta}$ _A + ${delta}$ _R + ${Omega}$ (t)]T⁺, where ${sigma}$ = 1 cell · µl^–1 · day^–1, f = 0.1, p = 0.01 day^–1, and d = ${delta}$ _A + ${delta}$ _R = 0.03 day^–1. Here, ${Omega}$ (t) is modeled as a single exponential decaying function from the administration of HAART: ${Omega}$ (t) = ${Omega}$ ₀e^–^t, with ${Omega}$ ₀ = 0.02 day^–1 and ${lambda}$ = 0.05 day^–1. The graphs show the ratio of the value of the individual parameters at time t to the value at time zero. The dynamics predicted by this model are similar to the dynamics observed for CD8⁺ naïve T cells in this study. (C) HAART-induced changes for the same variables when the death rate, ${delta}$ _R, is also enhanced by a factor ${Psi}$ (t) during chronic HIV-1 infection due to activation-induced cell death. Here, ${Psi}$ (t) is modeled as a single exponential decaying function from the administration of HAART: ${Psi}$ (t) = ${Psi}$ ₀e^–^t, with ${Psi}$ ₀ = 0.025 day^–1 and ${gamma}$ = 0.005 day^–1. Other parameters are as follows: ${Omega}$ ₀ = 0.045 day^–1, ${lambda}$ = 0.05 day^–1, ${sigma}$ = 1 cell · µl^–1 · day^–1, f = 0.1, p = 0.01 day^–1, and d = ${delta}$ _A + ${delta}$ _R = 0.02 day^–1. The dynamics predicted by this model are similar to the dynamics observed for CD4⁺ naïve T cells in this study.

With ${sigma}$ values of >0 this generalization predicts a greaterdecrease in the proliferation than the disappearance rate whena new quasi-steady state is reached following initiation ofHAART (data not shown). The dynamics of naïve CD8⁺ T cellsobserved in this study are consistent with this: a significantincrease in the number of TREC⁺ T cells/µl is accompaniedby a limited increase in naïve T-cell counts after initiationof HAART (Table 3 and Fig. 1 and 2B). This model also predictsthat the decrease in the proliferation rate after HAART is notexpected to correlate with the increase in naïve T-cellcounts, since the latter will be only marginally affected regardlessof the rate at which naïve T-cell proliferation normalizes.Again, our data are consistent with this: there is no significantcorrelation between the increase of CD8⁺ naïve T-cell countsand the decrease of percent Ki67⁺ CD8⁺ naïve T cells betweentime points 0 and 1 or later.

For CD4⁺ naïve T cells, the above model is inadequate toexplain the observed dynamics. However, the transient increasein the fraction of TREC⁺ T cells per naïve T cell and thefollowing new steady state reached after 18 months of antiretroviraltherapy can be explained by assuming that the death rate, ${delta}$ _A,is also enhanced ( ${delta}$ _A $->$ ${delta}$ _A + ${Psi}$ ) during HIV-1 infection due to activation-inducedcell death. The effect of HAART is again to normalize the proliferationrate and the disappearance rate of the CD4⁺ naïve T cells.However, the latter now includes both the death rate and thepriming rate, which demonstrate differential dynamics relatedto changes in ${Omega}$ and ${Psi}$ , respectively. A HAART-induced normalizationof the death rate that is approximately 10-fold slower thanthe normalization of the proliferation rate adequately accountsfor the changes in both TREC fractions and TREC⁺ T cells/µlthat are observed for CD4⁺ naïve T cells (Fig. 2C).

Previous reports have identified a positive correlation betweenbaseline percentages of proliferating and apoptotic (terminaldeoxynucleotidyltransferase-mediated UTP nick end labeling-positivecells) T cells (36). If the HIV-1-induced increases in proliferationand death rates of naïve T cells ( ${Omega}$ and ${Psi}$ ) are similarlyproportionally related, then the model also predicts an inversecorrelation between the HAART-induced decrease in proliferationof naïve T cells and the recovery of naïve T-cellcounts (data not shown) which we observed for CD4⁺ naïveT cells. Thus, HIV-1-infected patients with higher proliferationand death rates of naïve T cells during chronic infectionwould demonstrate a faster recovery of naïve T-cell countsafter HAART, with most of the recovery explained by normalizationof the death rate rather than by normalization of the proliferationrate, which, as in the earlier model, is still counterbalancedby the simultaneous reduction in the rate of priming.

Kinetics of BrdU-labeled naïve T cells prior to and after HAART. To further evaluate the effects of HAART on the proliferationand disappearance rates of naïve T cells, we analyzed thekinetics of BrdU-labeled naïve T cells prior to and afterinitiation of HAART in six HIV-1-infected patients. Figure 3shows the theoretical curves obtained by best fitting equation3 to the fraction of BrdU-labeled naïve CD4⁺ T cells foreach patient, before and after initiation of therapy. Becausethe percentages of BrdU-labeled cells within the naïveT-cell population are relatively small, and thus closer to thedetection threshold, this analysis resulted in a weak convergenceof the nonlinear best-fitting procedure using equation 3. Thus,equation 4 was used to estimate the slope s from the time ofinfusion to the peak of labeling, and a single exponential decayfunction has been used to estimate d* from the time of peaklabeling. As shown in Table 4, this modeling predicts a decayin s greater than a decay in d* for naïve CD4⁺ T cellsafter initiation of HAART (median relative decrease [n-fold]in s of 2.3 and median relative decrease in d* of 1.5; P = 0.03).Since changes in s imply changes in mean proliferation rates,a greater decay in s than d* implies a more dramatic decreasein proliferation than disappearance rates of naïve T cellsafter HAART, whether d* represents the apoptotic death rateplus the rate of priming into memory T cells or the differencebetween the disappearance rate in the blood, d, and the proliferationrate in the blood, p (data not shown).

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FIG. 3. Comparison of experimental data with modeling of the kinetics of BrdU incorporation and decay by CD4⁺ naïve T cells for each patient. Lines represent the modeling, and symbols represent the actual data points (red, pre-HAART; blue, post-HAART).

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TABLE 4. Parameter estimates for the dynamics of BrdU-labeled naïve CD4⁺ T cells before and after HAART in group 2 patients

DISCUSSION

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Discussion

In this study we have analyzed the relationship between T-cellturnover, thymic function, and immune activation in HIV-1-infectedpatients, focusing on naïve CD4⁺ and naïve CD8⁺ Tcells, to better understand the contribution of these variousparameters to the immunologic changes seen during HIV infectionand therapy. We specifically targeted a broad range of baselineviral load and CD4⁺ T-cell counts in order to highlight thedynamics across the spectrum of HIV infection. At baseline,naive T-cell numbers were lower in the CD4 pool compared tothe CD8 pool, but no difference between the two groups was observedin the percentages of proliferating naïve T cells or inthe number of TRECs. Even though a dramatic decrease in proliferationis observed for both naïve CD4⁺ and CD8⁺ T cells afterthe first 6 months of therapy, we found that naïve CD4⁺T-cell numbers significantly increased after initiation of HAART,but naïve CD8⁺ T-cell numbers were only marginally affected.Baseline naïve T-cell counts inversely correlated withthe relative changes in naïve T cells in both subpopulationsof cells, and TRECs/µl increased in both subsets of cells.We also observed an increase in the fraction of TREC⁺ T cellsper naïve T cell, which is equivalent to a faster growthof TREC⁺ T cells versus total naïve T cells, for both CD4and CD8 cells following initiation of HAART. We did not observesignificant changes of thymic volumes during time or statisticallysignificant correlations between changes in thymic volumes andchanges in naïve T-cell numbers or TRECs/µl.

To provide a unified description of the concomitant changesin naïve T cells (TRECs/µl and the percentage ofproliferating naïve T cells during HAART) that can explainthe observed differences in the dynamics of these variablesin the CD4 and CD8 subpopulations of T lymphocytes, we developeda mathematical model based on a generalization of a model originallydescribed by Hazenberg et al. (21). We have generalized thedisappearance rate of naïve T cells as the sum of the ratesof naïve cells priming into memory cells and naïvecell death and assumed that the increase in proliferation ofnaïve T cells during chronic infection is primarily explainedby the increase in the rate of priming of naïve T cellsinto memory cells. This simple theoretical framework is sufficientto predict the simultaneous increases in the fraction of TREC⁺T cells per naïve T cell and the number of TREC⁺ T cellsin the periphery after initiation of HAART. The model explainsthe dynamics of naïve CD8⁺, but not CD4⁺, T cells afterinstitution of HAART. To explain the dynamics of naïveCD4⁺ T cells, we postulate that there is an increase in theapoptotic death rate of naïve T cells during HIV-1 infectionrelated to immune activation or to the increase in proliferationrate and that there is delayed normalization of the apoptoticdeath rate compared to the proliferation rate, as has been reportedfor total CD4⁺ T cells in lymph node samples of HIV-1-infectedpatients before and after initiation of HAART (48). This modeldoes not require (or exclude) changes in thymic output or redistributionof T lymphocytes from the lymphoid tissue as additional mechanismscontributing to naïve T-cell recovery.

The normalization of the death rates can also account for theinverse correlation between baseline naïve T-cell countsand the relative change in naïve T-cell counts after initiationof HAART. However, the increase in naïve T cells appearsto be lower for naïve CD8 T cells than for the naïveCD4⁺ T cells, which suggests independent mechanisms of peripheralnormalization for the different populations. This dichotomy,observed in the dynamics of naïve CD4⁺ T cells comparedto naïve CD8⁺ T cells after HAART, as well as the presenceof an inverse correlation between baseline thymic scores andthe relative change (n-fold) in naïve T-cell numbers forCD4⁺ but not CD8⁺ T cells is difficult to explain solely asa result of changes in thymic output rates or trafficking effects,since these should not have differential effects on the twopopulations of naïve T cells. Moreover, based on this model,the observed inverse correlation between baseline counts andthe relative change in naïve T-cell counts after HAARTfor both naïve CD4⁺ and naïve CD8⁺ T cells suggeststhat increases in the death rate affect both populations. However,the greater baseline depletion of naïve CD4⁺ T cells comparedto naïve CD8⁺ T cells, together with the concomitant increasein TRECs per microliter in both compartments following therapy,suggests, as highlighted by the model, that similar mechanismsdrive both naïve CD4⁺ and naïve CD8⁺ T cells to beprimed into memory cells, but for unknown reasons the increasein the death rate is more pronounced in the CD4⁺ than in theCD8⁺ naïve T-cell populations. Interestingly, Li et al.have recently shown that, at least in the settings of acutesimian immunodeficiency virus infection, higher levels of Fas-and Fas ligand-mediated apoptosis are observed within CD4⁺ butnot CD8⁺ T lymphocytes in the lamina propria, which may resultfrom massive exposure of CD4⁺ T cells to virion gp120 (33).Our data suggest that during chronic infection, the differentialability to tolerate similar increases in proliferation, ${Omega}$ , isan intrinsic property of each subpopulation of naïve Tcells. An alternative scenario in which ${Omega}$ is different betweenthe two subpopulations would require that naïve CD4 T cellshave a higher proliferation rate than naïve CD8 T cellsto account for the relative loss in naïve CD4 T cells.However, this was not observed in our data when we looked atthe baseline fractions of proliferating naïve CD4 and CD8T cells.

It is important to note that this model represents an idealizedsituation and that deviations from this model, resulting, forinstance, from the presence of nonlinear contributions of traffickingof lymphocytes or of replenishment of the peripheral pool bythymic output, might result in a situation that is far fromthe quasi-steady-state condition assumed in equation 1. In thelatter circumstances, TREC content after initiation of HAARTcan potentially be affected in an unpredictable manner.

The hypothesis of a more pronounced decrease in the proliferationrate than the disappearance rate of naïve T cells afterHAART is supported by the kinetics of BrdU-labeled naïveT cells studied longitudinally (pre- and post-HAART) that weobserved in a smaller group of HIV-1-infected patients.

In principle, changes in the fraction of naïve T cellscarrying TRECs upon exiting the thymus (f in equation 1) mightalso explain a greater relative change in TREC⁺ T cells/µlthan naïve T-cell counts after initiation of HAART (32).Among the four parameters discussed in this analysis (d, p, ${sigma}$ , and f), f is the least investigated. Dion and colleagues (8)have recently shown an increase of the ratio ${alpha}$ -TRECs/ß-TRECsafter initiation of HAART, which suggests that the newly producednaïve T cells undergo more intrathymic divisions beforeentering the peripheral pool. Since ß-TRECs are producedbefore ${alpha}$ -TRECs, this would lead to a decrease, not an increase,in f after initiation of HAART, thus excluding changes in fas a major factor affecting the dynamics of the fraction ofTREC⁺ T cells after initiation of HAART.

This analysis provides evidence that changes in peripheral proliferationand disappearance rates of naïve T cells, rather than changesin thymic output, explain the observed dynamics of TRECs andthe fraction of proliferating T cells during HAART. But whatis the mechanism that drives naïve T cells to proliferatefaster during chronic infection? The first pathogenic effectof HIV-1 infection might consist of an increase in the rateof priming of naïve T cells due to a generalized stateof chronic immune activation. In this scenario, the HIV-1-inducedincrease in the proliferation rate could serve as a compensatory(homeostatic) mechanism aimed at maintaining the naïveT-cell count constant, in response to the loss of naïveT cells that have been primed into memory cells. Alternatively,the p(t) expression of the proliferation rate of our model couldalso be modeled as a function of the number of cells, T(t),for instance, following a density-dependent law (10). Underthis scenario, changes in thymic output and consequent (homeostatic)changes in peripheral proliferation of naïve T cells couldalso explain the observed TREC dynamics, as suggested by Dutilhet al. to explain the changes of TREC content during aging (10).However, given the relatively short time frame (a few weeks)in which significant changes of proliferation and disappearancerates are seen (36) and the negligible contribution by the thymusseen in thymectomy studies (as recently described for nonhumanprimates by Arron et al. [1]), as well as our thymic CT data,we feel that peripheral mechanisms (including homeostatic mechanisms)leading to changes in proliferation and disappearance ratesare the major factors affecting the dynamics of TRECs. The observeddichotomy in the dynamics of naïve CD4⁺ and naïveCD8⁺ T cells is difficult to explain by invoking changes inthymic output as the sole mechanism responsible for changesin peripheral (homeostatic) proliferation rates of naïveT cells.

If a homeostatic mechanism governs the proliferation of naïveT cells, we would expect, as has been previously suggested forthe entire population of T cells (24), an inverse correlationbetween relative change (n-fold) in naïve T-cell countsafter HAART and the relative changes in the percentages of proliferatingnaïve T cells. In our study we do observe such an inversecorrelation for naïve CD4⁺ but not naïve CD8⁺ T cells.Alternatively, the first effect of activation might consistof inducing naïve T cells to proliferate faster withoutlosing their phenotype (45-47), bringing these cells closerto the priming activation threshold which leads to an increaseddisappearance rate of naïve T cells. In this scenario,the increase in the proliferation rate is primarily explainedby the increase in the rate of priming during chronic infection.The simultaneous decrease in both the proliferation and primingrates after initiation of HAART should generate a lack of correlationbetween the recovery of naïve T-cell counts (only marginallyaffected) and the decrease in the percentage of proliferatingnaïve T cells. This latter paradigm would explain the observedlack of such correlation for naïve CD8⁺ T cells. The additionalassumption that higher levels of proliferation are associatedwith higher levels of apoptosis is required to explain the presenceof this inverse correlation for CD4⁺ naïve T cells. Bothscenarios show consistency with a differential change in theproliferation and disappearance rates of naïve T-cells.Based on current available data, it is difficult to make conclusivearguments in support of either hypothesis. Thus, further investigationsare required to clarify the mechanisms responsible for the increasedproliferation of naïve T cells induced by HIV-1.

ACKNOWLEDGMENTS

We thank the patients for their willingness to participate inthese studies, the physicians, nurses, and other members ofthe National Institute of Allergy and Infectious Diseases-ClinicalCenter HIV/AIDS Program for their support of these studies,and Betty Wise for performing the quantitative thymic measurements.

This research was supported in part by the Intramural ResearchProgram of the National Institutes of Health, National Instituteof Allergy and Infectious Diseases, and Warren Grant MagnusonClinical Center.

FOOTNOTES

* Corresponding author. Mailing address: National Institute of Allergy and Infectious Diseases, National Institutes of Health, 6700 B Rockledge Drive, MSC 7609, Bethesda, MD 20892. Phone: (301) 451-5135. Fax: (301) 480-0912. E-mail: mdimascio{at}niaid.nih.gov.

REFERENCES

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