CD4+-T-Cell Effector Functions and Costimulatory Requirements Essential for Surviving Mucosal Infection with Citrobacter rodentium

Citrobacter rodentium causes an attaching and effacing infectionof the mouse colon. Surprisingly, protective adaptive immunityagainst this mucosal pathogen requires a systemic T-cell-dependentantibody response. To define CD4⁺ T-cell effector functionspromoting this systemic defense of infected epithelial surfaces,studies were undertaken in weaning-age mice lacking costimulatorymolecules CD28 or CD40L or cytokines gamma interferon (IFN- ${gamma}$ )or interleukin-4 (IL-4). Adoptive transfer of CD4⁺ T cells fromwild-type, CD28^–/–, CD40L^–/–, or IFN- ${gamma}$ ^–/–donors to CD4^–/– recipients delineated functionsof these CD4⁺ T-cell-expressed molecules on the outcome of infection.Wild-type and IL-4^–/– mice successfully resolvedinfection, while 70% of IFN- ${gamma}$ ^–/– mice survived. Incontrast, all CD28^–/– mice succumbed during acuteinfection. While fewer than half of CD40L^–/– micesuccumbed acutely, surviving mice failed to clear infection,resulting in progressive mucosal destruction, polymicrobialsepsis, and death 1 to 2 weeks later than in CD28^–/–mice. Downstream of CD28-mediated effects, CD4⁺ T-cell-expressedCD40L proved essential for generating acute pathogen-specificimmunoglobulin M (IgM) and early IgG, which reduced pathogenburdens. However, deficiency of CD4⁺ T-cell-expressed IFN- ${gamma}$ didnot adversely impact survival or development of protective antibodyin adoptively transferred CD4^–/– recipients, thoughit impacted Th1 antibody responses. These findings demonstratethat CD4⁺ T-cell-expressed CD40L promotes the rapid productionof protective systemic antibody during acute infection, whiledeficiencies of IL-4 or of CD4⁺ T-cell-expressed IFN- ${gamma}$ can beovercome. These findings have important implications for understandingthe role of T-helper-cell responses during infections involvingmucosal surfaces.

INTRODUCTION

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Introduction

Citrobacter rodentium serves as the mouse model for studyingthe pathogenesis and host responses to attaching and effacingpathogens. These pathogens cause significant morbidity and mortalityamong infants and children in the developing world and amonganimals of agricultural significance. As with related pathogens,including the enteropathogenic Escherichia coli, C. rodentiumcauses a self-limited infection of the apical surface of thegut epithelium (2, 14, 16). The noninvasive nature of this infectionprovides a model for dissecting events associated with infectionsof mucosal surfaces, including the host responses needed toresolve them. This infection also serves as the primary mousemodel of infectious colitis, providing a rigorous system forunderstanding microbial contributions to gut inflammation andpathways involved in its successful resolution.

Primary infection with C. rodentium progresses through threedistinct phases, a useful schema for defining points at whichelements of innate and adaptive immunity impact host defense.First, colonization and proliferation of the pathogen startwith successful introduction of C. rodentium into the colon.After initial adhesion (4), attaching and effacing lesions form,mediated by the bacterial adhesin intimin and type III secretedbacterial proteins, including the translocated intimin receptor,Tir (7, 8, 18). Innate defenses, including epithelial-producedß-defensins, affect early colonization and proliferationof C. rodentium in the colon (13, 24). The presence of mucosalantibody also appears to impact the initial kinetics of bacterialgrowth (2, 15, 28). Second, by the onset of symptomatic infection7 to 10 days after inoculation, the developing pathogen burdenhas triggered a number of epithelial responses, including thehallmark hyperplastic response and production of antimicrobialfactors (14, 24). Previous studies have also demonstrated protectiveroles for proinflammatory cascades resulting in secretion ofgamma interferon (IFN- ${gamma}$ ) and tumor necrosis factor alpha membercytokines in the colon (9, 10, 24, 26). Interestingly, acuteinfection primarily recruits CD4⁺ T cells into the colon, thoughabscess formation in proximity to densely colonized areas intermittentlydisrupts epithelial integrity, creating the potential for polymicrobialsepsis as C. rodentium and lesser numbers of commensals gainentrance to host tissues (2). While adult immunocompetent hostscontrol this aspect of the infection, it contributes to thelethality and morbidity seen in immature animals and populationswith defects in B cells and CD4⁺ T cells (2, 25). Third, mostmice resolve infection within 4 weeks after initial inoculation.Immunocompetent hosts clear the pathogen, with resolution ofinflammation and return of epithelial proliferation to a baselinestate.

The development of T-cell-dependent serum antibody proved thecritical adaptive response needed to survive and resolve thisprimary infection of a mucosal surface (2). This response consistsof CD4⁺ T-cell-dependent serum immunoglobulin M (IgM) and evolvingIgG predominated by the Th1-biased isotype IgG2c, the IgG2aallotype produced in C57BL/6 mice. Surprisingly, this responsedid not require CD4⁺ T-cell or B-cell responses in mucosal tissues,as evidenced by survival and resolution of infection in micelacking ß₇-integrins, adhesion molecules facilitatingbinding of lymphocytes to the mucosal addressing cell adhesionmolecule (MAdCAM) that permits entry into mucosal sites, includingthe GALT (2). These findings indicate that protective adaptiveresponses against attaching and effacing pathogens do not needto occur in the same tissue compartment as the primary siteof infection.

Activation of naïve T cells through costimulatory moleculessuch as CD28 or ICOS leads to the expression of downstream effectorcostimulatory molecules, including CD40L, OX40, and CD27, eachof which impacts Th1/Th2 differentiation, cytokine production,and end effects on B-cell stimulation, germinal center formation,and antibody production (1, 11, 12, 21, 29, 30).

However, when framed in the context of infection with a noninvasivemucosal pathogen, we know remarkably little regarding how theseCD4⁺ T-cell effector functions facilitate host survival andresolution of infection. We thus undertook infection studieswith mice lacking CD28, CD40L, IFN- ${gamma}$ , or interleukin-4 (IL-4),molecules with potential impact on host defense against C. rodentium.Adoptive transfer of wild-type CD28^–, CD40L^–, orIFN- ${gamma}$ ^– CD4⁺ T cells into CD4^–/– recipientssubsequently elucidated the functional roles of these CD4⁺ T-cell-expressedmolecules on the generation of protective antibody, controlof pathogen burdens, and resolution of infection. We found thatCD28 and CD40L were dominant in providing T-cell help for protectiveantibody responses, while single deficiency of IL-4 or of CD4⁺T-cell-expressed IFN- ${gamma}$ did not produce an appreciable impactupon successful resolution of infection.

MATERIALS AND METHODS

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Materials and Methods

Bacterial strains. Citrobacter rodentium strain DBS 100 and mouse commensal E.coli cells were cultured on MacConkey agar (Remel Inc.) or inLuria-Bertani (LB) broth (2).

Mouse strains. CD45.1⁺ and CD45.2⁺ wild-type and CD45.2⁺ CD28^–/–,CD40L^–/–, IFN- ${gamma}$ ^–/– IL-4^–/–,and CD4^–/– C57BL/6 mice were obtained from JacksonLaboratories (Bar Harbor, ME), housed as previously described(2). All methods and procedures were carried out in accordancewith Animal Care and Use Committee-approved protocols.

Infection of mice. Weaning-age mice were fasted 8 h prior to oral inoculation with5 x 10⁸ CFU of C. rodentium. Animals were allowed access tofood after inoculation. All manipulations were performed inBL-2 biosafety cabinets. During infection, moribund animalsor those showing unalleviated distress were euthanized.

Survival studies. A least six mice of each C57BL/6 strain were analyzed in a minimumof two independent experiments. Log rank and chi-square analyseswere carried out in Prism 4.0 to determine median survival timeand statistical significance. A P value of <0.05 was consideredsignificant.

Tissue collection, histology, and immunofluorescence. Samples of spleen, liver, mesenteric lymph node (MLN), smallintestine, and colon were placed in 10% Formalin in phosphate-bufferedsaline (PBS), or in tissue blocks containing OCT (Tissue-Tek)and snap-frozen. The colon was dissected to the anal canal andremoved en bloc. Five-micrometer sections were stained withhematoxylin and eosin. Immunofluorescent staining was performedon frozen sections fixed in cold methanol for 5 min, washedin PBS, and blocked for 10 min in PBS plus 5% mouse serum priorto staining with rat anti-mouse E-cadherin (Zymed) and recognizedwith rabbit anti-rat Ig conjugated to AMCA (Jackson Immunochemical),hamster anti-mouse CD3 ${varepsilon}$ conjugated to fluorescein isothiocyanate(FITC) (Caltag), rat anti-mouse CD4 conjugated to phycoerythrin(PE; Caltag), rat anti-mouse CD45.1-FITC (eBiosciences), andHoechst nuclear dye (bis-benzimide; Sigma Chemical; 1 mg/mlstock solution diluted 1:10,000).

Colony counts. Distal colon, spleen, and liver were weighed, homogenized, seriallydiluted, and plated in triplicate to MacConkey agar. C. rodentiumand E. coli colonies were counted after 24 h of incubation at37°C to determine log₁₀ CFU per gram of tissue. Lower detectionlimits were 20 CFU/gram spleen (log₁₀ = 1.3), 8 CFU/gram liver(log₁₀ = 0.9), and 12 CFU/gram colon or fecal pellets (log₁₀= 1.1).

Preparation of serum and fecal lysates. Serum prepared from whole blood was collected by periorbitaleye bleed from sevoflurane-anesthetized mice. For preparationof fecal lysates, fecal pellets were collected from mice, weighed,and subjected to two sequential extractions in fecal lysateextraction buffer (0.1% Tween 20 plus 10 µl Sigma proteaseinhibitors/ml); 0.5 ml of buffer was added per 0.1 g of materialfor each extraction. Material was vortexed for 20 min and spunfor 10 min at 12,000 rpm, and supernatant was passed over a0.22-µm-filter spin tube (Corning). Sequentially collectedsupernatants from the same sample were pooled to result in 1ml of lysate per 0.1 g of fecal material.

Immunoglobulin enzyme-linked immunosorbent assays. Antibody enzyme-linked immunosorbent assays were performed bycoating 96-well plates with heat killed C. rodentium. Plateswere incubated overnight washed with PBS plus 0.05% Tween 20,blocked in 10% soy milk (8th Continent) plus PBS plus 0.05%Tween 20 and washed prior to addition of serially diluted serumor fecal lysates. Samples were incubated for 2 h at room temperatureand washed, and bound antibody was detected with goat anti-mouseIgA, IgM, IgG1, IgG2b, IgG2c, or IgG3 (Southern BiotechnologyAssociates) conjugated to alkaline phosphatase. After 1 h ofincubation at room temperature, washed plates were developedwith p-nitrophenyl phosphate (PNPP; Sigma), read in a MolecularDevices reader, and analyzed in SoftMAX 4.0 with a four-parameterfit of mean absorbance at an optical density of 405 nm of eachsample versus the reciprocal of the dilution. Interpolationwith the resulting equation was used to define the relativeendpoint titer yielding an optical density of 405 nm of 0.15.The minimum detectable titer was 50.

Serum transfers. Adoptive transfer of serum from mice was performed as previouslydescribed (2). Briefly, wild-type, CD40L^–/–, orIFN- ${gamma}$ ^–/– donors were infected 2 weeks prior to CD4^–/–recipients. On days 3, 4, and 5 after inoculation of CD4^–/–recipients with C. rodentium, whole blood was collected fromacutely infected donors, allowed to clot, and filter sterilizedprior to immediate administration of 0.25 ml serum to each recipient.Each CD4^–/– recipient received serum only from wild-type,CD40L^–/–, or IFN- ${gamma}$ ^–/– donors to assessthe protective capacity of the acute antibody responses in donormice. Survival of CD4^–/– recipients was monitoredfor 6 weeks after infection with C. rodentium.

T-cell purification. Spleen and mesenteric lymph node were harvested from naïve5-week-old CD45.1⁺ or CD45.2⁺ wild-type mice or CD45.2⁺ CD28^–/–,CD40L^–/–, or IFN- ${gamma}$ ^–/– C57BL/6 mice. Tissueswere macerated through a 70-µm mesh filter (Becton Dickinson)into 10 ml of RPMI plus 10% calf serum (R10; Gibco). Cells werespun for 5 min at 1,500 rpm at 4°C, and red cells were lysed.Preparations were spun and washed with R10, and the cell concentrationwas determined. Control preparations were suspended to deliver20 million unfractionated cells to recipient mice. Remainingcells were suspended to 2.5 x 10⁸ cells/ml for purificationwith CD4⁺ or CD8⁺ T-cell magnetic bead purification kits, performedper the manufacturer's specifications (Miltenyi). Purified cellswere stained with rat anti-mouse CD4, CD8 ${alpha}$ , CD19, GR1, F4/80,or rat isotype control conjugated to phycoerythrin (Caltag)and analyzed on a Becton-Dickinson fluorescence-activated cellsorter (FACS) Scan device. CD4⁺ T-cell preparations gave $≥$ 96%CD4⁺ T cells, $≤$ 1% CD19⁺ B cells, <1% CD8⁺ T cells, <1%F4/80⁺ macrophages, or GR1⁺ neutrophils and $≤$ 1% dead cells. Theresulting suspensions were passed over a 40-µm mesh filterand suspended in RPMI to deliver $~$ 5 million cells per recipientmouse at 23 days of age. Recipients were orally inoculated withC. rodentium as described 2 days after adoptive transfer. Administrationof 5 million purified CD4⁺ T cells conferred a significant survivalphenotype in CD4^–/– recipients infected with C.rodentium, but administration of 20 million unfractionated cells,5 million CD8⁺ T cells, or 500,000 CD4⁺ T cells did not.

FACS analysis of tissues from adoptively transferred mice. Tissues from wild-type, control, and adoptively transferredCD4^–/– recipients were obtained at day 15 postinoculation(day 17 posttransfer). Spleen and MLN were macerated through70-µm filters. Distal colon was opened and flushed withcold Hanks buffered saline solution (Gibco) and placed on parafilm,and the mucosa was gently scraped with a sterile razor blade.Scraped material was placed in cold HBSS, pelleted at 1,500rpm prior to two 15-min incubations at 37°C in HBSS plus10% fetal calf serum (FCS) plus antibiotics plus 2 mM EDTA torelease epithelial cells from stromal cells. Material was resuspendedin R10 plus type IV collagenase (dispase) plus 10 U/ml of DNase(Pierce) and underwent two 20-min incubations at 37°C. Collectedfractions were passed over 40-µm Nytex mesh filters, spun,washed twice in R10, and resuspended for staining with speciesand isotype-specific controls (Caltag), hamster anti-mouse CD3e-cychrome(Pharmingen), CD4-PE or -FITC, CD8 ${alpha}$ -PE or -FITC, CD19-PE, F4/80-PE,and FITC-conjugated anti-mouse CD45.1 or CD45.2 (eBiosciences).In mice receiving purified CD45.1⁺ CD4⁺ T cells, CD8⁺, CD19⁺,or other CD45.1⁺ cells remained at <0.5% at 15 days aftertransfer. By FACS analysis, cells within the lymphocyte gatewere gated by CD3 positivity in FL-3 and analyzed for CD4 orCD8 ${alpha}$ expression in FL-1 to determine the percentages of CD4⁺and CD8⁺ T cells from these locations. Mice adoptively transferredwith CD45.1⁺ cells were gated on CD45.1⁺ in the FL-1 channeland analyzed in FL-2 for CD4 expression and FL-3 for CD3 expressionto determine the phenotype of the transferred cell populations.

RESULTS

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Results

IFN- ${gamma}$ , CD28, and CD40L impact survival of infection with C. rodentium. Survival studies with wild-type, CD28^–/–, CD40L^–/–,IFN- ${gamma}$ ^–/–, and IL-4^–/– mice defined criticaljunctures during infection requiring expression of these molecules.Animals were infected at 21 days of age, a time during whichmice are more susceptible to infection with C. rodentium andone modeling the development of symptomatic infections causedby attaching-and-effacing pathogens in susceptible populations,including human children and young animals. Whereas all wild-type(Fig. 1A) and IL-4-deficient (Fig. 1B) mice survived infection,100% of CD28^–/– mice succumbed during acute infection(Fig. 1C). While 40% of CD40L^–/– animals succumbedduring acute infection (Fig. 1D), the remaining 60% succumbedover the next 2 weeks, during the time that wild-type mice clearedC. rodentium from the colon. IFN- ${gamma}$ ^–/– mice demonstrated30% lethality during acute infection with survival of remaininganimals (Fig. 1E). These findings indicated that costimulatoryevents mediated by CD28 impacted necessary host responses duringacute infection. Surprisingly, costimulation mediated by CD40Limpacted events associated with both acute and resolution stagesof infection, while deficiency of IFN- ${gamma}$ demonstrated a milderbut still important contribution toward survival of acute infection.

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FIG. 1. Survival among mice lacking CD28, CD40L, IL-4, or IFN- ${gamma}$ . Mice were orally inoculated with 5 x 10⁸ CFU of C. rodentium at day 21 of age. (A) Wild-type C57BL/6 mice (n = 12 mice). (B) IL-4^–/– mice (n = 6 mice). (C) CD28^–/– mice (n = 6 mice). (D) CD40L^–/– mice (n = 9 mice). (E) IFN- ${gamma}$ ^–/– mice (n = 7 mice).

Deficiency of CD28 or CD40L leads to development of polymicrobial sepsis, damage to colon and internal organs, and defects in bacterial clearance. Wild-type mice characteristically develop peak pathogen burdens2 weeks into infection, with numbers exceeding 1 x 10⁸ CFU ofC. rodentium per gram of colon (Fig. 2A). In spite of this pathogenburden, the colonic epithelium remains grossly intact with rarebreaks associated with abscess formation and efflux of neutrophilsinto the lumen (Fig. 3A) (2). The pathogen burden declines 3to 4 logs over the next week, with the majority of animals clearingC. rodentium within 4 weeks (Fig. 2A and 3E). The same patternwas found in mice lacking IL-4 (data not shown).

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FIG. 2. Pathogen burden in colon and spleen. The x axis denotes the number of days into infection. The y axis denotes log₁₀ CFU of C. rodentium/gram of colon (A to D) or spleen (E to H) or E. coli in spleen (I to L). Lower limits of detection are 20 CFU/gram spleen and 12 CFU/gram colon. An asterisk indicates no surviving mice at those time points for analysis. Squares, CFU of C. rodentium; open circles, CFU of E. coli.

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FIG. 3. Tissue pathology in infected mouse strains. Shown are hematoxylin and eosin stains at a x200 magnification unless otherwise noted. (A) Colon of C57BL/6 mouse at day 15 of infection showing adherent C. rodentium (arrows) and lymphocytic infiltrate near the epithelial crypts (arrowheads). The epithelium remains intact. (B) Adherent C. rodentium (arrow) in a CD28^–/– mouse. (C) CD40L^–/– mouse at day 15. (D) Area of disrupted epithelium in a CD28^–/– mouse at 15 days into infection. Asterisks indicate microcolonies of C. rodentium in the lamina propria. Arrows point to abscesses and epithelial disruptions. (E) Colon of wild-type mouse 28 days into infection. C. rodentium cells have been cleared, and epithelial hyperplasia has largely resolved, though remnants of the crypt-associated inflammatory infiltrate remain. (F) Colon of CD40L^–/– mouse at 28 days showing mucin-engorged crypts, epithelial disruptions (arrows), and microcolonies of C. rodentium contacting the mucosa (asterisk). (G) Colon from IFN- ${gamma}$ ^–/– mouse (similar to panel E). (H) Rare lamina propria microabscess in IFN- ${gamma}$ ^–/– mouse 28 days into infection with sloughed cells in the crypt lumen (asterisk). (I to L) Liver at x400. (I) Clear hepatic sinusoid from wild-type mouse at day 15 of infection. The top of the image shows the central vein. (J) Sinusoids from CD28^–/– mouse demonstrating abscess formation. Arrows point to an area of ballooning degeneration. (K) Section from CD40L^–/– mouse similar to panel I, but demonstrating a small microabscess (arrow). (L) A x100 image of liver from a CD40L^–/– mouse at day 28 showing widespread geographic necrosis (arrows) extending from regions supplied by the portal circulation.

All knockout strains demonstrated colonic burdens of C. rodentiumsimilar to those of wild-type mice during initial colonizationand proliferation (Fig. 2A to D). By 15 days of infection, CD28^–/–mice demonstrated a half-log-higher colonic burden of C. rodentiumthan wild-type or other knockout strains of mice (Fig. 2B).Histologically, the distal colon of CD28^–/– micealso demonstrated more frequent focal abscesses and breaks inepithelial integrity than those found in wild-type or IFN- ${gamma}$ -or CD40L-deficient mice (Fig. 3A to D) (data not shown). However,while pathogen burdens in wild-type mice dropped >3 logsbetween 15 and 21 days of infection (Fig. 2A), the pathogenburden remained constant or rose in surviving CD40L^–/–mice (Fig. 2C). This failure to clear the colonic infectionwas associated with increasing destruction of the gut mucosa(Fig. 3F). The pathogen burden in IFN- ${gamma}$ ^–/– mice remainedcomparable to that in wild-type mice, except for a mean 10-daylag in clearance of colonic C. rodentium and delayed resolutionof mucosal inflammation (Fig. 2D and 3G and H).

Investigation of CFU in liver and spleen revealed key defects.Prior studies in mice lacking CD4⁺ T cells demonstrated worseningpolymicrobial sepsis by day 15 of infection, characterized bysystemic spread of C. rodentium and lesser numbers of commensalspecies (2), events that were infrequent in wild-type mice (Fig.2E and I). CD28^–/– mice demonstrated a similar septicpicture characterized by the presence of C. rodentium and commensalE. coli in spleen and liver (Fig. 2F and J). The liver in particulardemonstrated frequent focal abscesses and hepatocyte damage(Fig. 3J). CD40L^–/– mice developed a milder septicpicture (Fig. 2G and K) with less damage to internal organsby day 15 of infection (Fig. 3K). However, at later time points,numbers of C. rodentium and E. coli increased in CD40L^–/–mice (Fig. 2G and K) as did damage to internal organs, liverin particular (Fig. 3L). In contrast, IFN- ${gamma}$ ^–/– micedisplayed milder sepsis acutely that resolved in surviving animals(Fig. 2H and L).

T-cell costimulation mediated by CD28 and CD40L is required for development of protective antibody responses against C. rodentium. We next determined the effect of CD28, CD40L, or IFN- ${gamma}$ deficiencyon acute antibody responses against C. rodentium. Wild-typemice infected with C. rodentium characteristically develop strongpathogen-specific serum IgM responses that peak approximately2 weeks after oral inoculation (Fig. 4A, squares). IgG responsesrise above baseline and peak over subsequent weeks (2). TheIgG responses at day 15 of infection in wild-type mice demonstraterising production of IgG2b (Fig. 4C) and Th1-dependent IgG2c(Fig. 4D).

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FIG. 4. Anti-C. rodentium serum and mucosal Ig responses: the x axis denotes mouse strains, and the y axis shows relative endpoint titers. Bars indicate mean values. Squares, wild-type C57BL/6 mice; triangles, CD28^–/– mice; inverted triangles, CD40L^–/– mice; diamonds, IFN- ${gamma}$ ^–/– mice. (A to E) Serum antibody responses against C. rodentium at day 15 of infection. (A) IgM. (B) IgG1. (C) IgG2b. (D) IgG2c. (E) IgG3. (F to J) Mucosal antibody responses against C. rodentium at day 15. (F) Fecal IgM. (G) IgA. (H) IgG2b. (I) IgG2c. (J) IgG3. The minimum detectable titer is 50.

In contrast to the early antibody profile seen in wild-typemice, CD28-deficient mice failed to mount significant pathogen-specificantibody at 15 days of infection (Fig. 4A to E, triangles).Lack of CD40L impaired the production of acute-pathogen-specificIgM (Fig. 4A, triangles) and IgG, with the exception of minimaltiters of IgG2b at day 15 (Fig. 4D). This lack of significantIgG reactivity persisted in CD40L^–/– mice survivingbeyond day 15 of infection (data not shown). IFN- ${gamma}$ ^–/–mice developed total pathogen-specific Ig responses comparableto those of wild-type mice, with IgG2b (Fig. 4D, diamonds) and/orIgG3 (Fig. 4E) developing in the absence of IgG2c (Fig. 4C).

Analyses of immunoglobulin titers in feces demonstrated a similarstriking impact on the development of C. rodentium-specificantibody that reached the bowel lumen. At day 15 of infection,wild-type and IFN- ${gamma}$ ^–/– mice demonstrated comparabletiters of reactive fecal IgM, IgA, and IgG2b, the primary IgGisotype detected. In contrast, CD28^–/– mice demonstratedlimited fecal IgA responses, in the absence of detectable anti-CitrobacterIgG (Fig. 4F to J). Likewise, titers of reactive fecal IgM,IgA, and IgG were significantly reduced in CD40L^–/–mice. Though CD40L^–/– mice produced detectable IgG2bagainst C. rodentium (Fig. 4H), these titers were 10-fold lowerthan those found in wild-type or IFN- ${gamma}$ ^–/– mice.

We next assessed the protective capacity of the acute-phaseserum Ig responses produced in CD40L- and IFN- ${gamma}$ -deficient mice.Previous studies demonstrated that administration of serum orpurified serum Ig from infected wild-type donors to highly susceptibleCD4^–/– mice protected recipients from infectionwith C. rodentium (2). As shown in Fig. 5A, transfer of wild-typeacute-phase serum protected 100% of CD4^–/– recipients,as did transfer of serum from IFN- ${gamma}$ ^–/– donors. Whileserum transfer from CD40L^–/– mice provided a survivaladvantage of 7.45 days, it failed to protect CD4^–/–recipients. These data indicate that the limited pathogen-specificIg response produced in CD40L^–/– mice extends survivalof CD4^–/– recipients but fails to provide completeprotection. Though IFN- ${gamma}$ impacts the profile of reactive IgG,its production was not required to generate protective antibody.

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FIG. 5. Transfer of acute-phase serum to CD4^–/– recipients. Shown are results from CD4^–/– mice receiving saline (squares; 5 mice), preimmune serum from naïve C57BL/6 mice (triangles; 5 mice), or serum from acutely infected wild-type (crosses; 5 mice), CD40L^–/– (inverted triangles; 7 mice), or IFN- ${gamma}$ ^–/– mice (diamonds; 5 mice). The crosses (representing wild type) and diamonds (representing IFN- ${gamma}$ ^–/– donors) overlap.

Adoptive transfer of CD4⁺ T cells protects CD4^–/– recipients against infection with C. rodentium. To determine the specific contributions of CD4⁺ T-cell-expressedCD28, CD40L, and IFN- ${gamma}$ , we adoptively transferred 5 million wild-typeor specifically deficient CD4⁺ T cells into CD4^–/–recipients subsequently infected with C. rodentium. Transferof CD45.1⁺ CD4⁺ T cells to CD45.2⁺ CD4^–/– donorsassessed the degree of reconstitution in uninfected and infectedrecipient mice 2 weeks after transfer (Table 1). Subsequenttransfers used CD45.2⁺ CD4⁺ T cells from wild-type, CD28^–/–,CD40L^–/–, or IFN- ${gamma}$ ^–/– donors. Recipientsreceiving CD4⁺ CD28^– T cells demonstrated poor reconstitutionof the CD4⁺ T-cell compartment in spleen, MLN, and colon 2 weeksafter transfer (Table 1), while recipients of CD4⁺ CD40L^–T cells demonstrated slightly improved reconstitution of thespleen and MLN but limited reconstitution of the colon (Table1).

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TABLE 1. Percent CD3⁺ CD4⁺ T cells per total CD3⁺ T cells in adoptively transferred CD4^–/– recipients

Adoptive transfer produced profound phenotypic effects uponsurvival of C. rodentium infection. Eighty percent of CD4^–/–recipients receiving wild-type CD4⁺ T cells successfully resolvedinfection (Fig. 6A). Transfer of CD4⁺ CD28^– T cells producedsurvival comparable to that with control CD4^–/–mice receiving media (14.8 days; Fig. 6B and E), while transferof CD4⁺ CD40L^– T cells extended the mean survival to 20.7days (Fig. 6C). Surprisingly, transfer of CD4⁺ IFN- ${gamma}$ ^– Tcells (Fig. 6D) produced survival comparable to that of micereceiving wild-type CD4⁺ T cells.

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FIG. 6. Survival of CD4^–/– mice adoptively transferred with CD4⁺ T cells from wild-type or CD28-, CD40L-, or IFN- ${gamma}$ -deficient donors. (A) Mice receiving wild-type CD4⁺ T cells (n = 10 mice). (B) CD4⁺ CD28^– T cells (n = 5 mice). (C) CD4⁺ CD40L^– T cells (n = 6 mice). (D) CD4⁺ IFN- ${gamma}$ ^– T cells (n = 5 mice). (E) CD4^–/– recipients receiving media (n = 8 mice).

The differences in survival were associated with developmentof a protective profile of acute-phase serum antibody. Recipientstransferred with wild-type CD4⁺ T cells demonstrated acute pathogen-specificserum IgM comparable to that with wild-type mice and near-normallevels of IgG2b and IgG2c (Fig. 7, inverted triangles). Micereceiving CD4⁺ CD28^– T cells demonstrated poor pathogen-specificresponses (Fig. 7, diamonds). Though transfer of CD4⁺ CD40L^–T cells produced a mild elevation in pathogen-specific IgM (Fig.7, circles) and IgG2b (Fig. 7, circles), pathogen-specific IgMremained >5-fold lower and pathogen-specific IgG 10-foldlower than the titers found in mice receiving wild-type CD4⁺T cells (Fig. 7). Transfer of CD4⁺ IFN- ${gamma}$ ^– T cells resultedin comparable titers of total pathogen-specific serum IgM andIgG with compensatory titers of IgG2b (Fig. 7B, asterisks) andIgG3 (Fig. 7D, asterisks) in the absence of detectable IgG2c(Fig. 7C).

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FIG. 7. Acute antibody responses in adoptively transferred CD4^–/– mice. Shown are pathogen-specific IgM (A), IgG2b (B), IgG2c (C), and IgG3 (D) antibody responses. The x axis indicates antibody responses in wild-type, CD4^–/–, or adoptively transferred CD4^–/– recipients; The y axis indicates the relative endpoint titer. The minimum detectable titer is 50. Squares, wild-type C57BL/6 mice; triangles, CD4^–/– recipients receiving medium only; inverted triangles, CD4^–/– recipients receiving wild-type CD4 T cells; diamonds, CD4^–/– recipients receiving CD28^–/– CD4⁺ T cells; circles, CD4^–/– recipients receiving CD40L^–/– CD4⁺ T cells; asterisks, CD4^–/– recipients receiving IFN- ${gamma}$ ^–/– CD4⁺ T cells.

These titers correlated with lower pathogen burdens at day 15of infection in internal organs. Transfer of wild-type CD4⁺T cells or CD4⁺ IFN- ${gamma}$ ^– T cells produced a $≥$ 2-log decreasein the number of pathogenic bacteria found in the spleen whencompared with CD4^–/– mice receiving CD4⁺ CD28^–T cells or media (Fig. 8A; P < 0.01). Though recipients receivingCD4⁺ CD40L^– T cells developed lower mean burdens in spleenthan CD4^–/– mice, this difference was not significant(log₁₀ CFU of C. rodentium/gram of tissue of 3.6 versus 4.3;P = 0.06).

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FIG. 8. Burden of C. rodentium in adoptively transferred CD4^–/– mice. Shown are colonic (A) and splenic (B) CFU of C. rodentium at 15 days of infection. The y axis denotes log₁₀ CFU of C. rodentium per gram of tissue. The x axis indicates the mouse strain and cell populations transferred to CD4^–/– mice. Squares, wild-type C57BL/6 mice; triangles, CD4^–/– recipients receiving medium only; inverted triangles, CD4^–/– recipients receiving wild-type CD4 T cells; diamonds, CD4^–/– recipients receiving CD28^–/– CD4⁺ T cells; circles, CD4^–/– recipients receiving CD40L^–/– CD4⁺ T cells; asterisks, CD4^–/– recipients receiving IFN- ${gamma}$ ^–/– CD4⁺ T cells.

DISCUSSION

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Discussion

Our findings have further elucidated the complicated interplaybetween mucosal and systemic adaptive immunity in controllinga primary infection of a mucosal surface. Unlike phylogeneticallyrelated members of the Enterobacteriaceae including Salmonellaenterica serovar Typhimurium, Shigella, and enteric Yersiniaspecies, C. rodentium does not establish a primarily invasiveor intracellular infection. However, the infections caused byeach of these pathogens involve contact with epithelial surfacesand the potential for direct microbial or host-mediated damageto the mucosa (3, 23). The adherence of high bacterial burdensof enteropathogenic E. coli or of C. rodentium to mucosal surfacesmakes this process all the more important in the pathogenesisof infections caused by attaching and effacing pathogens. Epithelialdisruptions provide passive portals through which pathogenicand commensal species may enter, creating the potential forpolymicrobial sepsis. This microbiologial "bystander effect"remains an underappreciated pathological mechanism that canoccur with any process damaging the gut epithelial barrier andcan contribute to the morbidity and mortality of mucosal infectionsin immature and immunocompromised populations (2, 6).

Adaptive immunity to C. rodentium requires development of asystemic and CD4⁺ T-cell-dependent antibody response. This responseis necessary in mice infected at the weaning transition or atolder ages (2, 25). As demonstrated in mice lacking ß₇-integrins,these responses need not occur in proximity to the primary mucosalsite of infection

During primary infection with C. rodentium, CD28 clearly affectsthe in vivo survival and proliferation of CD4⁺ T-helper cells,impacting downstream effector functions and development of protectiveantibody. More significantly, CD4⁺ T-cell-expressed CD40L providesa key costimulatory effector function needed to develop protectiveantibody responses. While more than half of CD40L^–/–mice, or CD4^–/– mice receiving serum from CD40L^–/–donors, survived the normal period of acute infection, animalsfailed to resolve colonic infection and ultimately succumbedto profound polymicrobial sepsis. As systemic IgG responseshave been implicated in the clearance of colonic C. rodentium(15), the lack of reactive IgG in CD40L^–/– micecould explain this protracted course of infection among CD40L^–/–mice and CD4^–/– mice receiving serum or CD4⁺ CD40L^–T cells from CD40L^–/– donors.

Surprisingly, deficiency of IL-4 or of CD4⁺ T-cell-producedIFN- ${gamma}$ did not adversely impact the host's ability to developprotective antibody and survive infection. The roles playedby IL-4 or CD4⁺ T-cell-expressed IFN- ${gamma}$ in the resolution of thisinfection may thus be small, or alternatively they may be overcomethrough other mechanisms in the deficient host. Furthermore,IFN- ${gamma}$ produced by populations other than CD4⁺ T cells, includingNK cells, neutrophils, macrophages, or dendritic cells, maypromote key effector functions needed for host defense, includingmacrophage activation, neutrophil recruitment, and aspects ofepithelial defense, including the induction of antimicrobialdefensins (19, 24).

However, the profile of protective antibody generated in wild-typemice indicates the development of IFN- ${gamma}$ and other cytokine responsesin a normal host. The dependence of the IgG2c response on CD4⁺T-cell-expressed IFN- ${gamma}$ demonstrates that immunocompetent micegenerate Th1 responses during mucosal infection with C. rodentium.The codevelopment of Citrobacter-specific IgG2b, an IgG isotypepromoted by transforming growth factor ß1 (5, 17),further suggests contributions of regulatory cytokine responses.Dissecting the manner and locations in which these responsesdevelop may be key to discerning how the normal host evolvesand controls proinflammatory responses generated during mucosalinfections.

Protective serum antibody responses in acute infection consistedof pathogen-specific IgM with evolving IgG2b/IgG2c or IgG2b/IgG3responses. These profiles are consistent with complement-fixingantibodies and convalescent IgG responses that bind with highaffinity to myeloid Fc ${gamma}$ R1 receptors and Fc ${gamma}$ RII/III receptors (20).Whereas pathogen-specific IgM develops during the point in infectionwhen a naïve host is most susceptible to the developmentof sepsis, pathogen-specific IgG, and not mucosal IgA, has beendemonstrated to help clear the colonic infection (15). Our datademonstrate that reactive IgG, IgG2b in particular, enters thelumen through an ill-defined mechanism, whether through damagedor leaky epithelium, FcRn-mediated epithelial transport, oruptake and release via the hepatobiliary system (22, 27). Effectorfunctions of reactive antibody could thus include a combinationof complement-mediated, phagocytic and direct antimicrobialfunctions, acting in systemic and mucosal locations.

We have defined key effector functions of CD4⁺ T cells duringinfection with the attaching and effacing pathogen C. rodentium.CD4⁺ T-cell-expressed CD28 and CD40L promote the developmentof protective humoral immunity during this primary infectionof a mucosal surface, while deficiency of IL-4 or CD4⁺ T-cell-expressedIFN- ${gamma}$ have limited functional effects. These systemic adaptiveimmunological responses are essential for control of infectionspreviously thought to be localized to the gastrointestinal tract.The development of a CD4⁺ T-cell adoptive transfer model witha robust survival phenotype provides a powerful tool to furtherdissect the evolution of differential Th responses in mucosaland systemic locations and to study CD4⁺ T-cell and antibody-mediatedprocesses leading to successful resolution of mucosal infectionsand associated inflammation.

ACKNOWLEDGMENTS

We thank Shannon Bowes and Monica Wang for technical assistanceand Terry and David Bowman for histological processing.

This work was supported by funding from NIH grants R01 AI38578,K08 AI051734, and R21 AI059628. L.B. is a recipient of a K08Career Development Award from the National Institutes of Health.

FOOTNOTES

* Corresponding author. Mailing address: 4226-EBRC, Department of Pathology, Brigham & Women's Hospital, Harvard Medical School, Boston, MA 02115. Phone: (617) 732-7763. Fax: (617) 264-6898. E-mail: lbry{at}partners.org.

Editor: A. D. O'Brien

REFERENCES

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