CD4+ T Cells Are Required for the Priming of CD8+ T Cells following Infection with Herpes Simplex Virus Type 1

The role of CD4⁺ helper T cells in modulating the acquired immuneresponse to herpes simplex virus type 1 (HSV-1) remains illdefined; in particular, it is unclear whether CD4⁺ T cells areneeded for the generation of the protective HSV-1-specific CD8⁺-T-cellresponse. This study examined the contribution of CD4⁺ T cellsin the generation of the primary CD8⁺-T-cell responses followingacute infection with HSV-1. The results demonstrate that theCD8⁺-T-cell response generated in the draining lymph nodes ofCD4⁺-T-cell-depleted C57BL/6 mice and B6-MHC-II^–/–mice is quantitatively and qualitatively distinct from the CD8⁺T cells generated in normal C57BL/6 mice. Phenotypic analysesshow that virus-specific CD8⁺ T cells express comparable levelsof the activation marker CD44 in mice lacking CD4⁺ T cells andnormal mice. In contrast, CD8⁺ T cells generated in the absenceof CD4⁺ T cells express the interleukin 2 receptor ${alpha}$ -chain (CD25)at lower levels. Importantly, the CD8⁺ T cells in the CD4⁺-T-cell-deficientenvironment are functionally active with respect to the expressionof cytolytic activity in vivo but exhibit a diminished capacityto produce gamma interferon and tumor necrosis factor alpha.Furthermore, the primary expansion of HSV-1-specific CD8⁺ Tcells is diminished in the absence of CD4⁺-T-cell help. Theseresults suggest that CD4⁺-T-cell help is essential for the generationof fully functional CD8⁺ T cells during the primary responseto HSV-1 infection.

INTRODUCTION

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INTRODUCTION

Infection due to herpes simplex virus type 1 (HSV-1) resultsin a wide spectrum of clinical presentations depending on thehost's age, the host's immune status, and the route of inoculation(47). HSV-1 typically causes mild and self-limited lesions onthe orofacial areas or genital sites. However, the disease canbe life-threatening, as in the case of neonatal and centralnervous system infections (18). The host's immune responses,particularly CD8⁺ T cells, play an important role in determiningthe outcome of HSV infections in both the natural human host(18, 19, 28) and experimental murine models (11, 43). Immunodepletionand adoptive transfer studies have demonstrated the role ofCD8⁺ T cells in reducing viral replication, resolving cutaneousdisease, and providing overall protection upon rechallenge (6,25, 26). CD8⁺ T cells play a particularly important role inpreventing infection of the peripheral nervous system (PNS)and the reactivation of latent virus from neurons in the sensoryganglia of infected mice (21, 24, 36). The mechanisms that CD8⁺T cells employ include gamma interferon (IFN- ${gamma}$ ) production andfunctions associated with cytolytic granule content at the sitesof primary infection (23, 31, 38). In the PNS of infected mice,the mechanisms primarily involve IFN- ${gamma}$ secretion (16, 20, 29),particularly against infected neurons expressing surface Qa-1(41). Histopathological evidence from HSV-1-infected human ganglionsections show a large CD8⁺-T-cell infiltrate and the presenceof inflammatory cytokines, suggesting that the presence of activated,effector memory cells within the PNS is important for maintainingHSV-1 latency in the natural human host (10, 42).

The generation of a robust CD8⁺-T-cell response is essentialfor the control of various infectious pathogens. Some studiessuggest that a brief interaction with antigen-presenting cells(APCs) is sufficient for CD8⁺-T-cell activation and expansioninto functional effectors (44). However, the magnitude and qualityof the overall CD8⁺-T-cell response generated may be dependenton additional factors (49). Recent evidence suggests that CD4⁺T cells facilitate the activation and development of CD8⁺-T-cellresponses either directly through the provision of cytokinesor indirectly by the conditioning of dendritic cells (DC) (8,48, 51). Those studies suggested that the latter mechanism isthe dominant pathway, wherein CD4⁺ T cells assist CD8⁺-T-cellpriming via the engagement of CD40 ligand (CD154) on CD4⁺ Tcells and CD40 expressed on DC (4, 30, 33). This interactionresults in the activation and maturation of DC, making themcompetent to stimulate antigen-specific CD8⁺-T-cell responses(35, 37).

The requirement for CD4⁺-T-cell help in the generation of primaryand secondary CD8⁺-T-cell responses to antigen varies. PrimaryCD8⁺-T-cell responses to infectious pathogens, such as Listeriamonocytogenes, lymphocytic choriomeningitis virus (LCMV), influenzavirus, and vaccinia virus, can be mounted effectively independentlyof CD4⁺-T-cell help (3, 12, 22, 34). In contrast, primary CD8⁺-T-cellresponses to nonmicrobial antigens display an absolute dependenceon CD4⁺-T-cell help (4, 5, 30, 33, 46). This observed differencein the requirement for CD4⁺-T-cell help may ultimately be aproduct of the initial inflammatory stimulus generated followingimmunization (49). Microbial antigens trigger an inflammatoryresponse that can lead to the direct activation and primingof APCs, such as DC, thereby bypassing the need for CD4⁺-T-cellhelp. Nonmicrobial antigens, however, trigger an attenuatedinflammatory response that does not directly activate and primeDCs. In the absence of this inflammation, CD4⁺ T cells are thoughtto condition and license DC functions through CD154/CD40 interactions,which leads to the subsequent activation of antigen-specificCD8⁺-T-cell responses (5, 49). Even in the case of pathogenswhere primary CD8⁺-T-cell responses were independent of CD4⁺-T-cellhelp, the secondary responses to these pathogens were foundto be defective in the absence of CD4⁺-T-cell help (3, 12, 34,40).

The requirement for CD4⁺-T-cell help in priming CD8⁺-T-cellresponses against HSV-1 infection is not well defined. Earlierstudies with HSV-1 suggested that CD4⁺ T cells play an importantrole in the generation of primary CD8⁺-T-cell responses, detectedin vitro, to acute infection with HSV-1 (14), principally throughthe provision of interleukin 2 (IL-2) for optimal CD8⁺-T-celldifferentiation and proliferation. Subsequent studies, utilizingan in vivo approach, indicated that CD4⁺ T cells were not requiredfor CD8⁺-T-cell-mediated cytolytic function (23). CD4⁺ T cellsare thought to provide help by conditioning DC in a cognate,antigen-specific manner, thereby making them competent to stimulateHSV-1-specific CD8⁺-T-cell responses (37). By contrast, findingsfrom other studies show that CD4⁺-T-cell-depleted mice wereable to fully recover from acute infection with HSV-1 (38).These studies imply that the absence of CD4⁺ T cells does notprevent priming of CD8⁺ T cells in vivo.

Studies from this laboratory have identified two distinct HSV-1-specificCD8⁺-T-cell subpopulations generated during the primary response,based upon the ability to synthesize IFN- ${gamma}$ following antigenicstimulation in vitro (1). To better understand the need forCD4⁺-T-cell help, we examined the functional characteristicsand phenotypes of these CD8⁺-T-cell populations generated duringa primary response to acute infection with HSV-1 in mice lackingCD4⁺ T cells. Our findings show that primary CD8⁺-T-cell responsesto HSV-1 are compromised in the absence of CD4⁺-T-cell help.Specifically, the HSV-1 gB-specific CD8⁺ T cells produced inthe absence of CD4⁺ T cells were found to be active with regardto cytolysis in vivo but were functionally impaired in the productionof IFN- ${gamma}$ and TNF- ${alpha}$ compared with intact C57BL/6 mice. Virus-specificCD8⁺ T cells were also reduced in number in CD4-depleted miceand in B6 mice lacking major histocompatibility complex (MHC)class II expression (B6-MHC-II^–/–) compared to wild-type(WT) mice. In addition, our data showed higher virus burdensin the infectious tissues obtained from mice lacking CD4⁺ Tcells than in those from intact mice. Collectively, these findingsdemonstrate that CD4⁺-T-cell help is essential for the generationof primary CD8⁺-T-cell responses following acute cutaneous infectionwith HSV-1.

MATERIALS AND METHODS

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MATERIALS AND METHODS

Mice. Three- to five-week-old male C57BL/6 mice and B6-MHC-II^–/–(C57BL/6-A^bβ^–/–) were purchased from JacksonLaboratories (Bar Harbor, ME) and Taconic (Germantown, NY),respectively. The animals were maintained in pathogen-free animalfacilities at the Louisiana State University Health SciencesCenter (LSUHSC), Shreveport, LA, and Drexel University Collegeof Medicine, Philadelphia, PA. Mice were used between 6 and10 weeks of age.

Virus. HSV-1 strain Patton, originally obtained from Richard Tenser,Pennsylvania State University College of Medicine, Hershey,PA, was plaque purified four times on Vero cell monolayers andestablished as a stock by infection of Vero cells at a multiplicityof infection of 0.01. Virus present in culture supernatant andvirus released from infected cells by a freeze-thaw cycle werepooled, titrated on Vero cell monolayers, and stored at –80°Cbefore use.

HSV-1 immunization of mice. Mice were anesthetized by intraperitoneal (i.p.) injection of60 mg/kg of sodium pentobarbital (Butler, Columbus, OH). Micewere then injected subcutaneously in each hind footpad (FP)with 2 x 10⁶ PFU HSV-1 in 50 µl of phosphate-bufferedsaline (PBS). Mice were sacrificed 5 days following infection,and the draining popliteal lymph nodes (PLN) were isolated foranalysis.

Quantification of virus in the FP tissue. Levels of infectious virus were determined in FP tissues asdescribed previously (38). Briefly, mice were sacrificed 5 dayspostinfection (p.i.) with HSV-1, the FP surface was cleanedwith 70% alcohol, and the tissue was removed with a 21-gaugescalpel. Tissues were homogenized in 1-ml glass tissue grinders(Wheaton, Millville, NJ) and centrifuged, and the cell-freehomogenate was assayed at various dilutions on Vero cell monolayersin 12-well tissue culture plates overlaid with 0.5% methylcellulose.Plaques were visualized following fixation of the monolayerswith 10% buffered formalin and staining with 0.5% crystal violet.

Antibodies and reagents used for staining. The following panel of monoclonal antibodies (MAbs) and reagentswas used for phenotypic analysis of lymphocytes in the PLN:phycoerythrin (PE)-conjugated anti-CD8 ${alpha}$ (clone 53-6.7; eBioscience,San Diego, CA), PE-TXR anti-CD8 ${alpha}$ (5H10; Caltag, Burlingame, CA),fluorescein isothiocyanate (FITC)-conjugated anti-CD44 (IM7;eBioscience), biotin-conjugated anti-CD25 (PC 61; eBioscience),and allophycocyanin-Cy7-conjugated anti-CD25 (PC61; BD Biosciences,San Diego, CA). Flow-cytometric analysis was performed on aFACSVantage SE (Becton Dickinson [BD], San Jose, CA) in theresearch Core Facility at LSUHSC, Shreveport, LA, and a FACSCalibur(BD, San Jose, CA) in the Flow Cytometry Core Facility of theDepartment of Microbiology and Immunology, Drexel UniversityCollege of Medicine. The data were analyzed using Flow Jo software(Tree Star, Ashland, OR).

CD4⁺-T-cell depletion. B6 mice were depleted of CD4⁺ T cells by administering 300 µgof anti-CD4 GK1.5 MAb i.p. at 3 days and 1 day before infectionwith HSV-1. Depletion of CD4⁺ T cells was confirmed using flow-cytometricanalysis (data not shown).

CD8⁺-T-cell depletion. B6 mice were depleted of CD8⁺ T cells by administering 300 µgof anti-CD8 ${alpha}$ 2.43 MAb i.p. at 3 days and 1 day before infectionwith HSV-1. Depletion was confirmed using flow-cytometric analysis(data not shown).

Intracellular staining. Lymphocytes were cultured for 5 h in 96-well U-bottom microtiterplates (Costar, Cambridge, MA) at a concentration of 1 x 10⁶cells/well in 200 µl of Iscove's modified Dulbecco's medium(American Type Culture Collection) supplemented with 10% fetalcalf serum, 20 mM HEPES, 2 mM L-glutamine, 50 µM β-mercaptoethanol,20 µg gentamicin sulfate (complete medium), and 1 µl/mlbrefeldin A (Golgi Plug; BD) in the presence of 10^–5 MHSV-1 glycoprotein B (gB) (⁴⁹⁸SSIEFARL⁵⁰⁵) peptide or 10^–5M vesicular stomatitis virus (VSV) nucleoprotein (⁵²RGYVYGQL⁵⁹)(LSUHSC Core Laboratories, New Orleans, LA). After 5 h, thecells were washed and surface stained with PE-conjugated anti-CD8 ${alpha}$ ,FITC-conjugated anti-CD44, and allophycocyanin-Cy7-conjugatedanti-CD25 MAbs. After the unbound antibodies had been washed,intracellular cytokine staining was performed using a Cytofix/Cytopermkit as per the manufacturer's instructions (BD). For IFN- ${gamma}$ /TNF- ${alpha}$ staining, the cells were stained with allophycocyanin-conjugatedrat anti-mouse IFN- ${gamma}$ MAb (XMG 1.2; BD) and FITC-conjugated ratanti-mouse TNF- ${alpha}$ MAb (MP6-XT22; BD). For perforin and granzymeB intracellular staining, lymphocytes were surface stained forCD8 expression. Cells were then washed, fixed, permeabilized,and stained for perforin and granzyme B using PE-conjugatedrat anti-mouse perforin (JAW246; eBioscience) and FITC-conjugatedrat anti-mouse granzyme B (16G6; eBioscience).

In vivo cytolytic assay. To prepare target cells for measurement of in vivo cytolysis,erythrocytes were removed from spleen cell suspensions fromnaive B6 mice using a lysis buffer (Pharm Lyse; BD, San Diego,CA). The cells were then washed and split into two populations.One population was pulsed with 10^–5 M HSV-1 gB viral peptidefor a period of 75 min at 37^°C and then labeled with 5.0µM carboxy fluorescein succinimidyl ester (CFSE) (MolecularProbes, Eugene, OR) (CFSE^hi). The other population was pulsedwith a nonspecific control VSV peptide and labeled with 0.5µM CFSE (CFSE^lo). For intravenous (i.v.) injection, equalnumbers of cells from each population were mixed together suchthat each mouse received a total of 15 x 10⁶ cells in 300 µlof PBS. Cells were injected into mice that had been infected5 days earlier with HSV-1, as described above. The mice weresacrificed 4 h after adoptive transfer for their PLN. Lymphnode cell suspensions were analyzed by flow cytometry, and eachpopulation was detected by its differential fluorescence intensities.The percent specific lysis was calculated by the following formula,as previously described (38): [1 – (ratio uninfected/ratioinfected)] x 100, where ratio is percent CFSE^lo cells/percentCFSE^hi cells.

Quantitative in vivo cytolytic assay. To prepare target cells to measure in vivo cytolysis, erythrocyteswere removed from spleen cell suspensions from naive B6 miceusing a lysis buffer (Pharm Lyse; BD, San Diego, CA). Cellswere washed and separated into four populations. Cells werepulsed with either 10^–6 M gB peptide or 10^–10 MgB peptide for 60 min at 37°C and then labeled with 5.0µM of either red fluorescent dye PKH26 (Sigma) or CFSE(Molecular Probes, Eugene, OR), respectively. The other populationswere pulsed with a nonspecific control VSV peptide at 10^–6M or 10^–10 M, and labeled with 0.5 µM of PKH26 orCFSE. For i.v. injection, equal numbers of cells from each populationwere mixed together such that each mouse received a total of20 x 10⁶ cells in 300 µl of PBS. Cells were injected intomice that had been infected 5 days earlier with HSV-1. The micewere sacrificed 3.5 h after adoptive transfer for their PLN.Lymph node cell suspensions were analyzed by flow cytometryand specific lysis was calculated as given above. This experimentwas repeated at 10^–14 M and 10^–18 M peptide concentrationsas well.

Statistical analysis. Statistical analyses were performed using unpaired Student'st test unless otherwise mentioned. Analyses were made usingPrism 3 software, (Graph Pad, San Diego, CA). Probability (P)values of <0.05 are considered significant. Unless otherwisestated, plotted data are means ± standard errors of themean (SEM).

RESULTS

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RESULTS

The absence of CD4⁺ T cells reduces the overall HSV-1-specific CD8⁺-T-cell response. The primary response to cutaneous HSV-1 infection results inthe activation and expansion of two phenotypically defined CD8⁺-T-cellsubpopulations, based upon the surface expression of CD25 (1).To determine the impact of the absence of CD4⁺ T cells on eachof the subpopulations, the characteristics of the CD8⁺-T-cellresponse in B6 mice subjected to depletion of CD4⁺ T cells priorto infection and in B6 mice lacking class II MHC expressiondue to genetic knockout of the H-2Aβ gene within the classII MHC locus (B6-MHC-II^–/–) were examined. The drainingPLN of CD4-depleted B6 mice, harvested on day 5 of infection,which corresponds to the peak of the response in WT B6 mice(9), were reduced in total cellularity compared to control HSV-1-infectedB6 mice (Fig. 1C; P < 0.0001). Essentially identical resultswere obtained for B6-MHC-II^–/– mice (Fig. 1D; P< 0.0001). The reduced cellularity likely reflected not onlythe absence of CD4⁺ T cells themselves but also a reductionin the expansion of CD8⁺ T cells. A comparison of absolute CD8⁺-T-cellnumbers in CD4-deficient mice to those in WT B6 control miceconfirmed a significant reduction in CD4-depleted mice (Fig.1E; P < 0.0001). While there was a reduction of total CD8⁺T cells in B6-MHC-II^–/– mice, this was not significantcompared to WT B6 mice (Fig. 1F; P < 0.2). However, whenthe absolute numbers of CD8⁺ T cells specific for the immunodominantH-2K^b-binding epitope derived from gB (⁴⁹⁸SSIEFARL⁵⁰⁵) recognizedin B6 mice were determined, a significant reduction was observedin both CD4-depleted (Fig. 1A; P < 0.04) and B6-MHC-II^–/–(Fig. 1B, P < 0.03) mice. These results indicated that theprimary expansion of HSV-1 gB-specific CD8⁺ T cells was reducedin the absence of CD4⁺-T-cell help.

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FIG. 1. Lymphocyte cellularity in the draining PLN following acute infection with HSV-1. C57BL/6 (WT) mice, CD4-depleted B6 mice, or B6-MHC-II^–/– mice were infected in each hind FP with 2 x 10⁶ PFU HSV-1. Mice were sacrificed 5 days p.i., and the draining PLN cells were analyzed by flow cytometry. (A) Absolute number of HSV-1 gB-specific CD8⁺ T cells (four mice/group; *, P = 0.03). (B) Absolute number of HSV-1 gB-specific CD8⁺ T cells (three mice/group; *, P = 0.04). (C) Absolute number of total cells per PLN (four mice/group; *, P < 0.0001). (D) Absolute number of total cells per PLN (three mice/group; *, P = 0.0001). (E) Absolute number of CD8⁺ T cells per PLN (four mice/group; *, P < 0.0001). (F) Absolute number of CD8⁺ T cells per PLN (three mice/group; P = 0.2). For panels A and B, lymph node cells were simultaneously stained with anti-CD8 ${alpha}$ and H-2K^b-gB_498-505 tetramers to identify HSV-1-specific CD8⁺ T cells. Data are representative results from one of two independent experiments for each group (means ± SEM).

The phenotype of HSV-1-specific CD8⁺ T cells in the CD4-deficient environment. The expression of CD44 and CD25 on HSV-1 gB-specific CD8⁺ Tcells was quantified to determine the role of CD4⁺ T cells inthe generation of each subpopulation. CD44 expression was similarin CD4-depleted B6 and B6-MHC-II^–/– mice, comparedto control B6 mice (Fig. 2A and B). In contrast, the expressionof CD25 was substantially reduced in both CD4-depleted B6 andB6-MHC-II^–/– mice compared to control B6 mice (Fig.2C and D). These findings indicated that the absence of CD4⁺-T-cellhelp shifted the primary HSV-1 gB-specific CD8⁺ T cells towardthe CD8⁺ CD25^lo T-cell response as a consequence of a pronouncedreduction in the CD8⁺ CD25^hi T-cell subpopulation.

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FIG. 2. Analysis of expression of activation markers on HSV-1 gB-specific CD8⁺ T cells in CD4-depleted, B6-MHC-II^–/–, and WT mice in response to acute infection with HSV-1. Draining PLN cells were obtained from WT, CD4-depleted, or B6-MHC-II^–/– mice 5 days following infection of each hind FP with HSV-1 and stained using anti-CD8 ${alpha}$ , anti-CD44, anti-CD25, and H-2K^b-gB tetramers. (A and B) Expression of CD44 on HSV-1 gB-specific CD8⁺ T cells in WT compared to CD4-depleted B6 mice (A) and WT compared to B6-MHC-II^–/– mice (B). (C and D) Expression of CD25 in WT compared to CD4-depleted B6 mice (C) and WT compared to B6-MHC-II^–/– mice (D). Solid lines, WT; dotted lines, CD4-depleted or B6-MHC-II^–/– mice. Data are representative of two independent experiments for each group.

The absence of CD4⁺ T cells reduces HSV-1-specific CD8⁺-T-cell cytokine synthesis. The functional capacity of HSV-1-specific CD8⁺ T cells, generatedin the presence or absence of CD4⁺ T cells in vivo, was examinedthrough the determination of IFN- ${gamma}$ (Fig. 3) and TNF- ${alpha}$ (Fig. 4)synthesis in response to stimulation in vitro with a syntheticpeptide corresponding to the immunodominant HSV-1 gB peptide,compared to a control, H-2K^b-binding peptide derived from VSVNP. It was found that the absence of CD4⁺ T cells did not preventIFN- ${gamma}$ synthesis by HSV-1 gB-specific CD8⁺ T cells (Fig. 3A) butresulted in a 50 to 60% downward shift in the mean fluorescenceintensity (MFI) of the IFN- ${gamma}$ signal in both CD4-deficient environments(Fig. 3B, lower panels). The absolute number of HSV-1 gB-specificCD8⁺ T cells able to synthesize IFN- ${gamma}$ was also significantlyreduced in CD4-depleted and B6-MHC-II^–/– mice comparedto control B6 mice (Fig. 3B, upper panels). Importantly, thesynthesis of IFN- ${gamma}$ by HSV-1 gB-specific CD8⁺ T cells was almostentirely due to CD8⁺ CD25^lo T cells in both CD4-deficient environments,compared to control B6 mice (Fig. 3C). These results indicatedthat the absence of CD4⁺ T cells resulted not only in a reductionin the absolute numbers of IFN- ${gamma}$ synthesizing HSV-1 gB-specificCD8⁺ T cells, but also in a pronounced shift in the phenotypeof the major CD8⁺-T-cell subpopulation responsible for IFN- ${gamma}$ synthesis. The analysis was expanded to include TNF- ${alpha}$ synthesisby HSV-1 gB-specific CD8⁺ T cells. These results indicated thatCD4 depletion caused a profound reduction in the detection ofTNF- ${alpha}$ synthesis by CD8⁺ T cells (Fig. 4A), which correspondedto a decrease in both the absolute numbers of TNF- ${alpha}$ synthesizingCD8⁺ T cells and the MFI of the TNF- ${alpha}$ signal detected in HSV-1gB-specific CD8⁺ T cells (Fig. 4B). In control B6 mice, themajority of HSV-1 gB-specific CD8⁺ T cells synthesized bothIFN- ${gamma}$ and TNF- ${alpha}$ (Fig. 4C, left). Depletion of CD4⁺ T cells appearedto have a greater impact upon TNF- ${alpha}$ synthesis by CD8⁺ T cellsthan upon IFN- ${gamma}$ , resulting in a higher percentage of CD8⁺ T cellsproducing IFN- ${gamma}$ alone and a pronounced reduction in TNF- ${alpha}$ synthesis,compared to control B6 mice (Fig. 4C, right). Taken together,these findings demonstrated an important role for CD4⁺ T cellsin the optimal cytokine synthetic response to acute cutaneousHSV-1 infection.

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FIG. 3. Assessment of IFN- ${gamma}$ -producing HSV-1 gB-specific CD8⁺ T cells during acute infection with HSV-1 in CD4-depleted, B6-MHC-II^–/–, and WT mice. Mice were infected with HSV-1 in the hind FP, and the draining PLN were harvested on day 5 p.i. The lymph node cells were stimulated in vitro with gB peptide or control (VSV) peptide in the presence of brefeldin A for 5 h. The stimulated lymphocytes were then surface stained for the expression of CD8 and CD25, fixed, permeabilized, and stained for intracellular expression of IFN- ${gamma}$ . (A) Representative dot plots show the frequency of CD8⁺ IFN- ${gamma}$ ⁺ T cells in the draining lymph nodes. Numbers in the gated regions are the percentages of CD8⁺ IFN- ${gamma}$ ⁺ T cells. Numbers beside the boxed area indicate the MFI for IFN- ${gamma}$ staining within the gated region. (B) (Top panels) Absolute numbers of IFN- ${gamma}$ producing CD8⁺ T cells (four mice/group; *, P = 0.01 [left]; three mice/group; *, P = 0.002 [right]). (Bottom panels) MFI of IFN- ${gamma}$ staining by gB-specific CD8⁺ T cells in the gated region (four mice/group; *, P = 0.004 [left]; three mice/group; *, P = 0.01 [right]). (C) Representative histograms showing expression of IFN- ${gamma}$ and CD25 on gated CD8⁺ T cells. Numbers in the quadrants are percentages of CD8⁺ cells which are IFN- ${gamma}$ ⁺ CD25^– (quadrant 1) or IFN- ${gamma}$ ⁺ CD25⁺ (quadrant 2). Numbers in parentheses are the MFI for IFN- ${gamma}$ staining. Data are representative of two independent experiments (means ± SEM). P values of <0.05 were considered significant.

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FIG. 4. Analysis of TNF- ${alpha}$ -producing HSV-1 gB-specific CD8⁺ T cells following acute infection with HSV-1. WT and CD4-depleted mice were infected with HSV-1 in the FP, and draining PLN cells were harvested on day 5 p.i. and stimulated in vitro with gB peptide in the presence of brefeldin A for 5 h. The stimulated lymphocytes were then surface stained for the expression of CD8 and CD25, fixed, permeabilized, and stained for intracellular expression of TNF- ${alpha}$ and IFN- ${gamma}$ . (A) Representative dot plots show the frequency of CD8⁺ TNF- ${alpha}$ ⁺ T cells in the draining lymph nodes. Numbers are the percentages of CD8⁺ TNF- ${alpha}$ ⁺ T cells. Numbers in parentheses are the MFI for TNF- ${alpha}$ staining. (B) (Left) Absolute number of TNF- ${alpha}$ -producing CD8⁺ T cells (three mice/group; *, P = 0.02). (Right) MFI of TNF- ${alpha}$ staining by CD8⁺ T cells (three mice/group; *, P < 0.0001). Data shown are representative of two independent experiments (means ± SEM). (C) Representative histograms show percentages of gated CD8⁺ T cells which express IFN- ${gamma}$ only (upper left quadrant), IFN- ${gamma}$ and TNF- ${alpha}$ (upper right quadrant), or TNF- ${alpha}$ only (lower right quadrant). P values of <0.05 were considered significant.

The absence of CD4⁺ T cells does not impair CD8⁺-T-cell-mediated CTL function in vivo. In addition to cytokine synthesis, CD8⁺ T cells utilize directtarget cell recognition and lysis to control virus infection.Therefore, the in vivo cytolytic capacity of CD8⁺ T cells fromCD4-depleted and B6-MHC-II^–/– mice was assessedusing a CFSE-based assay to determine the requirement of CD4⁺T cells for the induction of the primary HSV-1-specific cytotoxic-T-lymphocyte(CTL) responses. In these experiments, B6 spleen cells pulsedwith HSV-1 gB peptide expressed high levels of CFSE (CFSE^hi),while B6 spleen cells pulsed with control H-2K^b-binding VSVpeptide expressed low levels of CFSE (CFSE^lo). In an assay assessingin vivo lysis 4 h after injection of the labeled target cells,it was found that little target cell lysis was observed in uninfectedB6 mice, while HSV-1 gB-pulsed targets were completely lysedin HSV-1-infected B6 mice (Fig. 5A). Similar levels of HSV-1gB-pulsed target lysis were observed in both CD4-depleted andB6-MHC-II^–/– mice (Fig. 5A). Depletion of both CD4⁺and CD8⁺ T cells eliminated the lysis of HSV-1 gB-pulsed targetcells (Fig. 5B), which confirmed that the lysis of the peptide-pulsedtarget cells was mediated entirely by the CD8⁺-T-cell subpopulation.These findings indicated that the expression of HSV-1-specificCTL activity in vivo was independent of functional CD4⁺ T cells.While this finding is consistent with other studies that haveanalyzed the lysis of HSV-1 gB-pulsed target cells in vivo (37),our results differ from previous studies analyzing the cytolyticactivity of HSV-1-specific CTL cultured in vitro (14). Becausetarget cell lysis was essentially 100% by 4 h after introductionof the target cells into the infected animals, differences betweenthe control and CD4-deficient mice may have been overlooked.However, while the lysis of HSV-1 gB-pulsed target cells waslower in both control and CD4-depleted B6 mice at 1 and 2 hcompared to 4 h posttransfer (Fig. 6), there was no significantdifference in the levels of lysis between the two groups. Therefore,it was concluded that CD4⁺ T cells were not required for theoptimal expression of HSV-1-specific CTL function in vivo.

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FIG. 5. Analysis of in vivo cytolytic activity in WT, CD4-depleted, and B6-MHC-II^–/– mice. WT, CD4-depleted, and B6-MHC-II^–/– mice were infected in each hind FP with 2 x 10⁶ PFU HSV-1 and examined for HSV-1-specific cytolytic function in vivo using a 4-h CFSE-based assay as described in Materials and Methods. For acute responses to HSV-1 infection, cytolytic activity was measured on day 5 p.i., which corresponds to the peak of the response in the draining PLN. (A) Representative histogram plots of lymph node cells obtained from naïve control and day 5 infected WT, CD4-depleted, and B6-MHC-II^–/– mice 4 h after transfer of CFSE-labeled target cells. Numbers in the plots are percent specific lysis of target cells. (B) Histograms show lysis of CFSE-labeled target cells in naïve control and day 5 infected WT and CD4/CD8-depleted mice 4 h after transfer. Numbers in the plots are percent specific lysis of target cells.

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FIG. 6. Kinetic analysis of in vivo cytolytic activity in WT and CD4-depleted mice. WT, CD4-depleted, and B6-MHC-II^–/– mice were infected in each hind FP with 2 x 10⁶ PFU HSV-1 and examined for HSV-1-specific cytolytic function in vivo using a CFSE-based assay as described in Materials and Methods. The presence of CFSE^hi and CFSE^lo cells remaining 1, 2, and 4 h after i.v. transfer of target cells was determined. No significant difference was apparent between the two experimental groups at any time point examined.

A second possibility is that high surface density of the H-2K^b-bindingHSV-1 gB peptide may mask a potential role for CD4⁺ T cellsin the generation of the optimal HSV-1-specific CD8⁺-T-cellresponse. In this scenario, even if the CD4-independent CTLresponse is qualitatively inferior, this would be offset bythe potential of a lower-avidity CTL to interact with the targetcells due to the artificially high surface density of the MHC-peptidetarget structure. To address this question, the CFSE-based invivo CTL assay was modified to include two distinct lipophilicdyes. This method enabled the simultaneous examination of targetcells pulsed with two peptide concentrations. Briefly, targetcells were pulsed with different concentrations of the immunodominantHSV-1 gB peptide. Pulsed cells were then labeled with the lipophilicdye CFSE or the PKH26 red fluorescent cell linker dye (gB-CFSE^hiand gB-PKH26^hi, respectively). VSV-pulsed control target populationswere labeled with a lower concentration of the appropriate dyes(VSV-CFSE^lo and VSV-PKH26^lo). Target cells were then mixed ata ratio of 1:1:1:1 and injected into B6 mice such that eachanimal received a total of 2 x 10⁷ cells. Using this approach,no difference in killing capacity was detected between CD4-depletedand nondepleted mice at any of the peptide concentrations examined(Fig. 7A and B), which further supported the conclusion thatCD4⁺-T-cell help was not necessary for optimal CTL functions.Notably, it was observed that killing of cells pulsed with HSV-1gB-peptide was detected at concentrations of 10^–6 M and10^–10 M. Lysis was reduced at a gB peptide concentrationof 10^–14 M, and no lysis was observed at 10^–18 M.(Fig. 7B). Therefore, it was possible to modify the surfacedensity of H-2K^b-binding gB peptide to demonstrate that a criticalthreshold of target density was required for recognition andlysis of the target cells, but no difference was detected whetherCD4⁺ T cells were present or absent.

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FIG. 7. CD4 depletion does not affect CTL activity in vivo. (A) Representative histograms from the PLN of naïve, CD4-depleted, and nondepleted B6 mice, 5 days post-HSV-1 infection. (B) Percent specific lysis as a function of peptide concentration (means ± SEM). Percent specific lysis was calculated as described in the text. Squares, naïve mice; triangles, CD4-depleted mice; circles, nondepleted mice. Statistical analysis using the Wilcoxon sum of ranks test revealed no significant differences in the percentage of HSV-1-specific lysis between CD4-depleted and nondepleted mice at any of the concentrations examined.

Synthesis of perforin and granzyme B is not affected in CD8⁺ T cells in the absence of the absence of CD4⁺-T-cell help. The perforin-granzyme B pathway is considered the primary lyticmechanism utilized by CD8⁺ T cells to kill virus infected cells.Therefore, intracellular straining was employed to determinethe influence of CD4⁺ T cells on the synthesis of lytic granulesby CD8⁺ T cells from WT mice, CD4-depleted B6 mice and MHC classII^–/– mice infected with HSV-1 (5 days p.i.). Theresults showed a comparable level of perforin (Fig. 8A) andgranzyme B (Fig. 8B) expression in the CD8⁺-T-cell populationsfrom CD4-depleted, MHC class II^–/– and intact WTmice. These results further confirm that CD8⁺-T-cell cytolyticactivity is not dependent on CD4⁺-T-cell help.

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FIG. 8. Perforin and granzyme B levels in CD8⁺ T cells were not affected in mice lacking CD4⁺ T cells during primary responses to HSV-1 infection. Draining cells from CD4-depleted B6, MHC class II^–/–, and WT mice were harvested on day 5 p.i. with HSV-1 and stained for expression of CD8, perforin, and granzyme B as described in Materials and Methods. Expression of perforin (A) and granzyme B (B) on CD8⁺ T cells is shown. Data are representative of two independent experiments for each group.

Higher virus levels in B6-MHC-II^–/– and CD4-depleted mice. Because efficient HSV-1 clearance from the infected tissuesis dependent on competent CD8⁺-T-cell responses (38), the levelsof the infectious virus in the FP tissues of mice were determined5 days following cutaneous infection with HSV-1. The resultsshowed significantly higher levels of infectious virus in theFP tissues in CD4-depleted (P < 0.01) and B6-MHC-II^–/–(P < 0.03) mice than in control B6 mice (Fig. 9). Taken together,these findings suggest that the ability of HSV-1-specific CD8⁺T cells to produce optimal levels of antiviral cytokines ismore important than their ability to recognize and kill infectedcells in the control of HSV-1 infection in the skin.

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FIG. 9. Increased viral titers in CD4-depleted and B6-MHC-II^–/– mice. Virus levels in the FP tissues of WT, CD4-depleted, and B6-MHC-II^–/– mice were determined by virus plaque assay of samples from five to seven mice per group at 5 days after infection with HSV-1. *, P = 0.01 (n = 5) for CD4-depleted versus WT mice and 0.03 (n = 7) for B6-MHC-II^–/– versus WT mice. Each symbol represents one individual animal. Horizontal bars indicate means. A P value of <0.05 is considered significant.

DISCUSSION

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DISCUSSION

In this study, we examined the functions and phenotypes of CD8⁺T cells generated in the absence of CD4⁺-T-cell help followingacute infection with HSV-1. The findings show that CD4⁺-T-cellhelp is required for the efficient induction of primary CD8⁺-T-cellresponses to HSV-1. Our results suggest that phenotypicallydistinct populations of CD8⁺ T cells develop in the absenceof CD4⁺-T-cell help. CD8⁺ T cells produced in CD4-depleted orCD4-deficient mice (B6-MHC-II^–/–) expressed levelsof CD44 similar to those in WT B6 mice. In contrast, expressionof CD25 (the IL-2 receptor alpha [IL-2R ${alpha}$ ]) was significantlyreduced in CD4-depleted and B6-MHC-II^–/– mice comparedto WT mice. The lower expression of CD25 on CD8⁺ T cells inCD4-depleted mice and B6-MHC-II^–/– mice is likelya reflection of decreased levels of IL-2 (51) or the absenceof optimal DC activation (30, 37). Specifically, studies usingshort-term in vitro assays suggest that DCs isolated from HSV-1-infectedB6-MHC-II^–/– mice are compromised in their abilityto stimulate CD8⁺-T-cell proliferation and induce the upregulationof IL-2R (37). It is entirely possible that the reduction ofthe CD25^hi CD8⁺ T cells within the lymphoid tissues of micelacking CD4⁺ T cells, as defined in this study, may be due toan enhanced migration of this subpopulation into the infectedcutaneous tissues or to enhanced apoptosis of the subpopulationas it develops in the absence of sufficient IL-2. These possibilitieswill be addressed in future studies.

At the peak of the primary response to HSV-1, the numbers ofHSV-1-specific CD8⁺ T cells were lower in mice lacking CD4⁺T cells compared with WT mice. Furthermore, the absence of CD4⁺T cells reduced the frequency of IFN- ${gamma}$ producing HSV-1 gB-specificCD8⁺ T cells during the primary response. These results areconsistent with a recent study (37). Importantly, our studiesrevealed that CD8⁺ T cells from CD4⁺-T-cell-depleted mice andB6-MHC-II^–/– mice produced much less IFN- ${gamma}$ on a per-cellbasis than their WT counterparts. Our findings also indicatelower levels of TNF- ${alpha}$ -producing CD8⁺ T cells in CD4-depletedB6 mice than in WT mice. These results show that CD4⁺-T-cellhelp is crucial for the proliferation and function of virus-specificCD8⁺ T cells during the primary phase of response to HSV-1.This is in sharp contrast to acute infection with infectiouspathogens such as Listeria and LCMV, where a significant proportionof antigen-specific CD8⁺ T cells retained their capability toproduce IFN- ${gamma}$ in the absence of CD4⁺-T-cell help during the primaryphase of infection (12, 40, 45). It is likely that additionalfactors or stimulatory signals provided by CD4⁺ T cells arerequired for optimal IFN- ${gamma}$ synthesis in the case of HSV-1 infection.It is interesting to note that a higher percentage of CD8⁺ CD25^–cells produced IFN- ${gamma}$ in CD4-depleted and B6-MHC-II^–/–mice than in WT mice. Although CD8⁺ CD25^–-T-cell populationsare capable of producing IFN- ${gamma}$ (1), our findings suggest thatthey have a lower capacity to produce this cytokine than theCD8⁺ CD25⁺-T-cell subpopulation. These results suggest a closecorrelation between CD25 expression and IFN- ${gamma}$ production on aper-cell basis.

An interesting point arising from these and other studies (37)is the apparent dichotomy between the CD4⁺-T-cell independenceof HSV-1-specific CTL function in vivo and the CD4⁺-T-cell dependenceof HSV-1-specific CTL function in vitro (14). This suggeststhe possibility of two distinct CTL populations being measuredin each of these circumstances. It has long been known thatthe expression of HSV-1-specific CTL activity in vitro requiresex vivo culture for 2 to 3 days (27). However, CD8⁺ T cellsfrom immunologically intact B6 mice expressing high levels ofCD25 mediate CTL activity directly ex vivo (23), indicatingthat this T-cell subpopulation has become fully activated invivo. It was argued that CD8⁺ T cells, programmed to becomecytolytic, were likely to emigrate rapidly from the lymph node(23). The in vitro culture period may have retained these cellsand allowed them to complete their activation, and the completionof the activation process was dependent upon functional CD4⁺T cells, presumably through the continued availability of IL-2in culture (23). It is possible that the latter population isidentical to the "armed" CD8⁺ T cells that leave the lymph nodeand take up residence in the spleen following cutaneous HSV-1infection (9). This population is likely to retain the CD25^–phenotype within the spleen (1). The fact that CD4⁺ T cellsare not an absolute requirement for HSV-1-specific CTL functionin vivo suggests that alternative sources of IL-2, such as NKcells, play a more important role in vivo. Alternatively, HSV-1-specificCD8⁺ T cells may respond to cytokines other than IL-2 in vivoto achieve optimal CTL activity. Finally, the in vivo CTL assaymay measure a wider range of cytolytic functions than the invitro assay. With respect to the latter point, our studies havedemonstrated that the in vitro assay detected perforin-dependentcytolytic functions only, while the in vivo assay detected bothperforin-dependent and -independent cytolytic functions (N.K. Rajasagi et al., unpublished data). It should be noted thatthe measurement of cytokine synthesis is performed upon lymphocytespresent within the regional lymph nodes, while the cytolyticactivity is determined by the ability of effector cells to recognizethe target cells that have migrated into the lymphoid tissues.Therefore, the apparent requirement for CD4⁺ T cells in thegeneration of cytokine synthesis in CD8⁺ T cells, as opposedto their requirement for cytolytic function in vivo, may reflectdifferences in the location of the effector cells at the timeof assay and their ability to traffic in vivo.

A key observation from these studies is that low expressionof IL-2R did not affect cytolysis in vivo or the intracellularexpression of perforin and granzyme B, suggesting that the expressionof cytolytic function in vivo may not be tightly regulated byCD25 expression. This observation is supported by the fact thatgB-specific cytolytic activity was found in the spleen in theabsence of CD25 expression on HSV-1-specific CD8⁺ T cells, indicatingthat the continued expression of CD25 is not required for theexpression of cytolytic function in vivo (9). By contrast, reportsof in vitro studies advocate an important role for IL-2 andIL-2R signaling in the expression of perforin and granzyme Bgenes (13, 52). On the other hand, our data suggest the possibleinvolvement of other mechanisms in vivo in the regulation oflytic granule levels in response to viral infections, whichmay become more important in the absence of CD4⁺-T-cell help.

The findings also show higher viral loads in CD4⁺-T-cell-depletedmice and B6-MHC-II^–/– mice than in WT mice. It isimportant to note that mice selectively depleted of CD4⁺ T cellswere able to recover from cutaneous HSV-1 infection, with aslight delay in the total clearance of the virus (38). Thesestudies also suggest that the clearance of the virus in CD4-depletedmice is CD8⁺-T-cell mediated, as in vivo depletion of CD4⁺ andCD8⁺ T cells resulted in the inability of these mice to clearthe virus. Therefore, despite the reduced primary CD8⁺-T-cellresponse to HSV-1 infection, the phenotypically different poolsof HSV-1-specific CD8⁺ T cells that are generated in the absenceof CD4⁺-T-cell help seem to be sufficient to resolve the cutaneousinfection, even though their functional quality is reduced.The expression of cytolytic function at the sites of infectionmust be considered an important mechanism in clearing the infectiousvirus. On the other hand, previous studies suggest that IFN- ${gamma}$ plays an important role, both in the resolution of cutaneousinfection (38) and preventing reactivation of the latent virus(21, 16). Therefore, it is important to address the potentialeffects of reduced IFN- ${gamma}$ production in the recovery process,especially in preventing dissemination of the virus to the PNS.

It is not known why primary CD8⁺-T-cell responses to HSV-1 showa greater dependence on CD4⁺-T-cell help than responses to virusessuch as LCMV, influenza virus, vaccinia virus, ectromelia virus,or murine gammaherpesvirus 68, which can generate robust primaryCD8⁺-T-cell responses in the absence of CD4⁺-T-cell help (2,3, 7, 12, 34). There are several plausible reasons for the differentialrequirement of CD4⁺-T-cell help, including the ability of thepathogen to directly activate APCs through pathogen-derivedstimuli (5). Studies by Smith et al. suggest that in the caseof HSV-1, CD4⁺-T-cell help is essential for the activation ofDC, thereby making them competent to stimulate CD8⁺-T-cell responses(37). Nonetheless, as the bulk of expansion of the HSV-1-specificCD8⁺ T cells takes place outside the lymphoid compartment (9),cytokines such as IL-2 produced by CD4⁺ T cells may play animportant role in improving the magnitude of the CD8⁺-T-cellresponse to viral infections (15, 51). Also, IL-2 was foundto be important for promoting IFN- ${gamma}$ production by CD8⁺ T cells(15). In addition, a more recent study suggests that IL-2 signalsduring the priming stage are required for the secondary expansionof memory CD8⁺ T cells (50). Data presented here suggest thatCD4⁺ T cells most likely provide help through the provisionof IL-2, since they are the main source of IL-2 in vivo (32,39, 50). Furthermore, our recent studies demonstrate an importantrole for IL-2 in the induction of primary CD8⁺-T-cell responsesfollowing infection with HSV-1 (Rajasagi et al., unpublished).

Overall, these findings suggest that CD8⁺-T-cell populationsthat develop in the absence of CD4⁺-T-cell help are phenotypicallydifferent from the CD8⁺ T cells produced in normal WT mice duringprimary response to acute infection with HSV-1. The data showdiminished primary CD8⁺-T-cell responses to HSV-1 in mice lackingCD4⁺ T cells. Notably, CD8⁺ T cells produced in the absenceof CD4⁺-T-cell help expressed normal cytolytic activity in vivobut were functionally impaired in the production of IFN- ${gamma}$ andTNF- ${alpha}$ . Although the unhelped CD8⁺ T cells appear to resolve acuteHSV-1 infection (38), it is important to examine whether theCD8⁺ T cells maintained in the absence of CD4⁺-T-cell help willbe able to provide long-term protection in the case of a persistentvirus like HSV-1. This aspect is particularly important, asrecent studies suggest that the formation of memory CD8⁺-T-cellprecursors is affected in the absence of CD4⁺ T cells (37).

ACKNOWLEDGMENTS

This work was supported by Public Health Service grant AI-49428from the National Institute of Allergy and Infectious Diseases(S.R.J.).

We gratefully acknowledge Deborah Chervenak and Lijia Yin atLSUHSC and Yvonne Mueller at Drexel University College of Medicinefor their excellent technical assistance and advice with flowcytometric analysis.

FOOTNOTES

* Corresponding author. Mailing address: Department of Microbiology and Immunology (Room 18107), Drexel University College of Medicine, 245 N. 15th Street, Philadelphia, PA 19102. Phone: (215) 762-3719. Fax: (215) 762-1955. E-mail: stephen.jennings{at}drexelmed.edu

Published ahead of print on 11 March 2009.

We dedicate this paper to our late colleague, Patrick MitchellSmith (1956 to 2007).

Present address: Department of Microbiology, University of Tennessee,Knoxville, TN 37996.

Present address: Gene Therapy Program, University of PennsylvaniaSchool of Medicine, Philadelphia, PA 19104.

REFERENCES

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