Analysis of the Immune Response to Mycobacterium avium subsp. paratuberculosis in Experimentally Infected Calves

Johne's disease of cattle is widespread and causes significanteconomic loss to producers. Control has been hindered by limitedunderstanding of the immune response to the causative agent,Mycobacterium avium subsp. paratuberculosis, and lack of aneffective vaccine and sensitive specific diagnostic assays.The present study was conducted to gain insight into factorsaffecting the immune response to M. avium subsp. paratuberculosis.A persistent proliferative response to M. avium subsp. paratuberculosispurified protein derivative and soluble M. avium subsp. paratuberculosisantigens was detected in orally infected neonatal calves 6 monthspostinfection (p.i.) by flow cytometry (FC). CD4⁺ T cells witha memory phenotype (CD45R0⁺) expressing CD25 and CD26 were thepredominant cell type responding to antigens. Few CD8⁺ T cellsproliferated in response to antigens until 18 months p.i. ${gamma}$ ${delta}$ Tcells did not appear to respond to antigen until 18 months p.i.The majority of WC1⁺ CD2^– and a few WC1^– CD2⁺ ${gamma}$ ${delta}$ Tcells expressed CD25 at time zero. By 18 months, however, subsetsof ${gamma}$ ${delta}$ T cells from both control and infected animals showed anincrease in expression of CD25, ACT2, and CD26 in the presenceof the antigens. Two populations of CD3^– non-T non-B nullcells, CD2⁺ and CD2^–, proliferated in cell cultures fromsome control and infected animals during the study, with andwithout antigen. The studies clearly show multicolor FC offersa consistent reliable way to monitor the evolution and changesin the immune response to M. avium subsp. paratuberculosis thatoccur during disease progression.

INTRODUCTION

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Introduction

Johne's disease, paratuberculosis, is a chronic wasting diseaseof the intestine caused by Mycobacterium avium subsp. paratuberculosis.It causes significant economic loss to producers, especiallythe dairy industry, due to increase in forage consumption, decreasedmilk production, and early culling due to poor health of affectedanimals (reviewed in reference 51). The disease has been difficultto control because of the lack of sensitivity and specificityof available diagnostic assays (5) and the lack of an efficaciousvaccine (4, 33, 37). Available assays, such as M. avium subsp.paratuberculosis antigen enzyme-linked immunosorbent assays(ELISAs) and the gamma interferon (IFN- ${gamma}$ ) assays, vary in theircapacity to detect infected animals in the early stages of thedisease (reviewed in reference 51). Available vaccines havebeen shown to reduce the severity of pathology but not stopshedding of bacteria (reviewed in reference 33). Consequently,there is both a need to develop better diagnostic assays anda vaccine that, at a minimum, stops shedding during the productivelife of dairy cattle. At this juncture, information remainslimited on the factors affecting the immune response to M. aviumsubsp. paratuberculosis, and it is unlikely that it will bepossible to make progress on the development of a vaccine untilthe immune response to M. avium subsp. paratuberculosis is betterunderstood. Studies to date have shown the time course of diseaseis characterized by a long latency period (2 to 5 years) withno clinical signs of disease. No defined time point has beendetermined during this latency period when immune control ofinfection begins to deteriorate and animals begin shedding bacteria.It is thought that loss of immune control is associated witha depression of cell-mediated immunity (CMI) and an increasein the antibody response to M. avium subsp. paratuberculosisantigens. Comparison of the tissue distribution and functionalstatus of lymphocyte subsets in animals at different stagesof disease supports this supposition (38). Peripheral and intestinalCMI responses were decreased in symptomatic compared to asymptomaticanimals (38). Disease progression appeared to be associatedwith local loss of CD4⁺ T cells and an increase in ${gamma}$ ${delta}$ T cells(11, 38). The underlying defect that could be associated witha depression in CMI is dysregulation of macrophage functionmediated by M. avium subsp. paratuberculosis (56, 61, 65). Disruptionof gene activation and signaling through genes encoding tumornecrosis factor alpha (TNF- ${alpha}$ ), interleukin-1 (IL-1), IL-12, andIFN- ${gamma}$ and their receptors could lead to a breakdown in the immuneresponse controlling infection (27, 36, 46). Studies with geneticallysusceptible and knockout mice with defects in ${alpha}$ ß and ${gamma}$ ${delta}$ T-cell receptors and defects in CD4 and CD8 coreceptors haveshown that CD4⁺ T cells with a type 1 cytokine profile (8) playa critical role in maintenance of protection (38). The effectormechanisms used by CD4⁺ T cells include secretion of IFN- ${gamma}$ , whichactivates bactericidal activity in macrophages, and secretionof lymphotoxin, perforin, and granulysin (10, 52). Disruptioncould also affect effector activity of CD8⁺ T cells (10).

To gain further insight into the factors affecting the immuneresponse to M. avium subsp. paratuberculosis, it will be essentialto use experimentally infected cattle where the evolution ofan immune response can be monitored from the time of first exposureto the time of shedding and progression to clinical disease.One question that must be answered to make this approach successful,however, is whether animals can be uniformly infected by theoral route or whether it will be necessary to directly inoculateanimals to ensure they become infected. An initial study hasclearly shown direct inoculation of a large dose of M. aviumsubsp. paratuberculosis into the tonsils leads to infectionand the appearance of humoral and lymphoproliferative responsesto M. avium subsp. paratuberculosis antigens (60). An antibodyresponse was detected to two proteins ( $~$ 50 and $~$ 60 kDa) within7 to 14 days of exposure and by 134 days of exposure to lipoarabinomannan(LAM). A persistent lymphoproliferative response to LAM andsoluble M. avium subsp. paratuberculosis antigens was evidentby 5 to 6 months. CD4⁺ T cells with a memory phenotype (CD45R0⁺)that expressed an activation molecule (CD26) were the predominantcell type responding to both antigens. IFN- ${gamma}$ response above controlvalues was evident by 194 days, while a nitric oxide responsein macrophages was evident by 160 days.

The present study was conducted to determine if animals canalso be uniformly infected by the oral route and whether flowcytometry (FC) can be used, in conjunction with commercial M.avium subsp. paratuberculosis antibody ELISAs, IFN- ${gamma}$ assays,and fecal sampling, to monitor the evolution of the immune responseto M. avium subsp. paratuberculosis antigens during the earlyand late stages of infection. As reported here, high-dose exposureby the oral route also leads to uniform infection and the appearanceof a lymphoproliferative response to M. avium subsp. paratuberculosisantigens with similar kinetics to those noted in animals directlyinoculated with M. avium subsp. paratuberculosis. The commercialELISAs remained negative during the course of the study. TheIFN- ${gamma}$ assay yielded inconsistent results. Fecal shedding wasnot detected at the time of writing of this report.

MATERIALS AND METHODS

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Materials and Methods

Animals. Three newborn Holstein calves were obtained from the WashingtonState University M. avium subsp. paratuberculosis-free dairyherd for the present study. The five newborn calves experimentallyinfected with M. avium subsp. paratuberculosis were obtainedfrom a dairy in the middle of the state. The calves were givendaily doses of M. avium subsp. paratuberculosis (10⁷ bacteria)by the oral route for 7 days, starting at 24 to 48 h after birth.The calves were housed and maintained according to the InstitutionalAnimal Care and Use committee guidelines and the Associationfor Assessment and Accreditation of Laboratory Animal Care.The three M. avium subsp. paratuberculosis-free animals werehoused separately and served as controls.

MHC typing. Major histocompatibility complex (MHC) typing was performedby hybridization of biotinylated, genomic PCR products fromMHC class I, DRB3, and DQA genes to short, 15- to 22-bp, oligonucleotidemicroarrays as previously described (47). The only significantmodification from our previously published procedure was thatinstead of using heminested PCR for the class I and DRB3 genes,all of the biotinylated PCR products were generated by single-roundamplification. Data were interpreted using Cytofile matrix analysissoftware (15). Although the class I typing was performed bymicroarray hybridization, the serological names have been usedto denote the haplotypes (Table 1). The class II haplotypesare indicated using the D-region haplotype nomenclature (16,42, 47, 53). The official allele names assigned by the BovineLeukocyte Antigen Nomenclature Committee of the InternationalSociety for Animal Genetics were used for the class II allelespresent in each haplotype (14, 54).

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TABLE 1. BoLA typing results

Blood processing for tissue culture and FC. Peripheral blood mononuclear cells (PBMC) used in cultures wereobtained from buffy coat fractions of blood collected in acidcitrate dextrose (ACD) separated by density gradient centrifugationwith Accu-Paque (density, 1.086; Accurate Chemical & ScientificCorp., Westbury, N.Y.). Residual erythrocytes were lysed withH₂O. Dead cells and debris were removed from cultured cellsby density gradient centrifugation before use in FC.

For analysis of the composition of peripheral blood at the initiationof culture, 10 ml of blood was collected in ACD and lysed inTris-buffered NH₄Cl to remove erythrocytes. The resultant cellswere washed several times in phosphate-buffered saline (PBS)containing 20% ACD (PBS-ACD) to remove excess platelets andthen used in FC as described elsewhere (18).

Antigens. M. avium subsp. paratuberculosis purified protein derivative(PPD) Johnin was obtained from the National Veterinary ServiceLaboratory. Live bacteria used in the study and soluble antigen(SAg) were prepared from a field isolate (8544) used in previousstudies (29). M. avium subsp. paratuberculosis was grown aspreviously described (60) and harvested by centrifugation at1,500 x g for 10 min at 4°C, washed three times in PBS,suspended in PBS (pH 7.4) containing 0.01% Tween 80, and irradiatedwith exposure to a ⁶⁰Co source for 26 h, using the fixed tubeat a distance of 5.5 in. from base, in a Plexiglas rack (2.5Mrad). The mycobacterial concentration was determined spectrophotometricallyas that producing an optical density at 600 nm of 0.2 of M.avium subsp. paratuberculosis cells, approximately 10⁸/ml. Irradiatedcells were sonicated at the settings of output control 6, dutycycle 60 continuous, using a cup sonicator three times for 3min, and with a 3-min rest on ice between rounds of sonication.Soluble M. avium subsp. paratuberculosis antigen was preparedby vortexing M. avium subsp. paratuberculosis cells mixed withthe same amount (vol/vol) of zirconia-silica beads (BiospecProducts, Inc., Bartlesville, Okla.) with three to five cyclesof 2 min, with 1 min rest on ice in between cycles, and harvestingsupernatant following centrifugation at 4°C at maximum speed.Phenylmethylsulfonyl fluoride was added to soluble M. aviumsubsp. paratuberculosis antigen at a final concentration of1 mM to prevent protein degradation. Protein concentration ofSAg was calculated by measuring the optical density at 280 nm.

Cell culture and IFN- ${gamma}$ ELISA. PBMC were resuspended in RPMI 1640 medium supplemented with13% bovine calf serum, 2-mercaptoethanol, and antibiotics andthen distributed in T75 tissue culture flasks (3 x 10⁶ cells/ml).Two flasks each were stimulated with M. avium subsp. paratuberculosisPPD (20 µg/ml; RPMI 1640 complete medium) or SAg (4 µg/ml).Two additional flasks were cultured without stimulation. At6 or 7 days poststimulation, the cultures were collected andsubjected to density gradient centrifugation to remove deadcells and then labeled for FC as described elsewhere (18). Mediumfrom the cultures was collected after 1, 3, and 6 days of cultureto assay for the presence of IFN- ${gamma}$ .

Whole blood cultures were set up with fresh heparinized bloodaccording to the protocol recommended in the BOVIGAM IFN- ${gamma}$ testkit (CSL Veterinary, Parkville, Victoria, Australia) to testfor the presence of IFN- ${gamma}$ after 24 h of culture. Two millilitersof blood was dispensed into each well of a 24-well tissue cultureplate. Antigen (40 µg of commercial Johnin PPD) was addedto triplicate wells for stimulation. Wells without antigen wereused as controls. At 24 h, 100 µl of supernatant plasmaor cultured medium was collected by centrifugation and testedfor the presence of IFN- ${gamma}$ by using the BOVIGAM bovine IFN- ${gamma}$ testkit according to the protocols recommended by the manufacturer.

ELISA for antibody to M. avium subsp. paratuberculosis. Serological responses were evaluated by using commercially availablePARACHEK Johne's absorbed ELISA (CSL Veterinary) with absorbedserum and HerdChek M. paratuberculosis according to the protocolsrecommended by the manufacturer.

Serum samples were also submitted to the diagnostic laboratoryfor evaluation with an antibody ELISA (IDEXX Labs., Westbrook,Maine).

Detection of M. avium subsp. paratuberculosis with RT-PCR. Cecal lymph nodes were obtained at 1 year postinfection to testfor the presence of M. avium subsp. paratuberculosis by reversetranscription-PCR (RT-PCR). Total RNA from bovine cecal lymphnodes was prepared using TRIzol reagent (Invitrogen, Carlsbad,Calif.) according to the manufacturer's instructions. The first-strandcDNA was prepared using the SuperScript first-strand synthesissystem for RT-PCR (Invitrogen) with oligo(dT)_12-18 as a primer.The PCR mixture contained 1x PCR buffer, a 0.2 mM concentrationof each deoxynucleoside triphosphate, a 0.1 µM concentrationeach of the IS900-specific forward (5'-CCGCTAATTGAGAGATGCGATTGG-3')and reverse (5'-AATCAACTCCAGCAGCGCGGCCTCG-3') primers, 1.25U of Taq DNA polymerase (Invitrogen), and 1 µl of first-strandcDNA template. Thermocycler conditions included 35 cycles of95°C for 30 s, 58°C for 30 s, and 72°C for 1 min.Amplification of the 229-bp PCR product was confirmed by electrophoresisin 2% agarose gel.

FC. The monoclonal antibodies (MAbs) used in the present study areshown in Table 2. The combinations of MAbs used in the three-and four-color analyses are shown in Fig. 1. In some combinations,two MAbs of the same specificity and isotype were used to increasethe intensity of the fluorescent signal. MAbs specific for the ${delta}$ chain of the ${gamma}$ ${delta}$ T-cell receptor were used in combination withMAbs to CD3 and CD2 to distinguish ${alpha}$ ß T cells fromthe CD2⁺ WC1^– and CD2^– WC1⁺ ${gamma}$ ${delta}$ T-cell subsets. WC1(workshop cluster 1) is a unique molecule expressed on a subsetof ${gamma}$ ${delta}$ T cells only found in Artiodactyla (20). Previous studieshave shown the WC1^– subset is the same as the ${delta}$ chain⁺CD2⁺ WC1^– subset and that the WC1⁺ subset is the sameas the ${delta}$ chain⁺ CD2^– subset (17). WC1 is used in the textwith CD2 when describing results obtained on the CD2⁺ WC1^–and CD2^– WC1⁺ populations of ${gamma}$ ${delta}$ T cells. All MAbs were usedat 15 µg/ml. The same combinations of MAbs were used throughoutthe study. In brief, 10⁶ cells were incubated for 15 min in96-well conical bottom assay plates in the respective cocktailsof MAbs (50 µl of each MAb) in a final concentration of250 µl of first wash buffer (PBS-20% ACD containing 0.5%horse serum, 0.09% azide, and 0.1% phenol red), washed threetimes, and then incubated for an additional 15 min in cocktailsof isotype-specific second-step reagents conjugated with fluorescein,phycoerythrin, phycoerythrin-Cy5 (Tricolor), or Cy5 (Caltag,Burlingame, Calif., and Southern Biotechnology Associates, Birmingham,Ala.). Following incubation, the cells were washed two timesin PBS-ACD without phenol red, fixed in 2% PBS-buffered formaldehyde,and kept in the refrigerator until examined.

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TABLE 2. MAbs used to determine the composition of PBMC at time zero and after 6 to 7 days of culture with antigens

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FIG. 1. Summary of MAb combinations used to analyze the composition of PBMC following culture with PPD and M. avium subsp. paratuberculosis SAg.

A FACSort flow cytometer equipped with argon and red lasers,a Macintosh Quadra computer, and Cell Quest software (BectonDickinson Immunocytometry Systems, San Jose, Calif.) was usedto collect data. FCS Express software (De Novo Software, Thornton,Ontario, Canada) was used to analyze the data.

Analysis of the proliferative response to M. avium subsp. paratuberculosis antigens. Following oral inoculation, blood was collected every 2 weeksfor 2 months, once a month to 14 months, and every 2 monthsthereafter and processed for cell culture, the IFN- ${gamma}$ assay, andFC. Sera were collected at each time point for later analysis.In the first year, three-color FC was used to collect data usingthe primary panel of MAbs shown in Fig. 1A. In subsequent studies,four-color FC was used to collect data, using the primary panelof MAbs shown in Fig. 1B. A secondary panel of MAbs was usedat 50 weeks postexposure to determine if additional moleculeswere upregulated on CD4⁺ T cells stimulated with M. avium subsp.paratuberculosis antigens (Fig. 1C). Selective gating was usedto obtain results on specific subpopulations of lymphocytes.For time zero (T0), data were collected on 20,000 cells (seeFig. 2 and 3, below). Granulocytes and nonspecific signal wereexcluded at the time of data acquisition. Gate 1 was used todefine small lymphocytes. Gate 2 was used to define monocytesand large lymphocytes at the start of culture and large lymphocytesundergoing blastogenesis and proliferation on days 6 and 7 ofculture (see Fig. 2). For analysis of cultured cells, data werecollected with and without additional gates. An additional gatewas placed on CD3⁺ cells at the time of analysis to analyzethe composition of ${alpha}$ ß and ${gamma}$ ${delta}$ T cells. In the first monthsof the study, gates were placed on CD4⁺ and CD8⁺ T cells atthe time of data acquisition because of the low frequency ofthese subpopulations in unstimulated cultures. A gate was placedon ${gamma}$ ${delta}$ T cells at the time of analysis. Exclusion gates were placeon CD3 and CD5 T cells to analyze null cells present in gate2 (see Fig. 4, below). MAbs specific for CD25 and CD26 wereused to monitor the activation status of ${alpha}$ ß and ${gamma}$ ${delta}$ Tcells and other cells in the cultures (23, 40). An additionalMAb was used to monitor the upregulation of a molecule, ACT2,uniquely expressed on activated ${gamma}$ ${delta}$ T cells (Table 2; Fig. 1) (23).Figures 2, 3, and 5 to 7 (below) are representative FC dot plotprofiles of cells obtained from an animal that had been infectedfor 18 months. Figure 4 is a representative set of profilesfrom a control animal showing the characteristics of CD3^–CD2⁺ and CD3^– CD2^– populations of null cells thatwere present in some cultures of cells from control and infectedanimals. Summary data on the response of control and infectedanimals to PPD and SAg are shown below in Fig. 8 to 10.

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FIG. 2. Representative dot plot profiles of PBMC labeled with four MAbs (Fig. 1B, MAb set 1) before (T0) and after 6 days of culture in RPMI alone or with M. avium subsp. paratuberculosis SAg. The phenotypes of cell subsets present in each quadrant in the dot plot profiles are shown in boxes above columns A to E. In profiles A, F, and K, the quadrants show the division between small lymphocytes in gate 1 and large cells in gate 2 and the relative frequencies of cells in each gate before and after culture. The profiles B, G, and L, with gates placed only on 1 and 2, show the frequency of CD3⁺ cells at each time point. The profiles in C, H, and M, with gates placed only on 1 and 2, show the frequency of CD3^– CD2^– null cells, CD3⁺ CD2^– ${gamma}$ ${delta}$ ⁺ T cells, CD2⁺ ${alpha}$ ß and CD2⁺ ${gamma}$ ${delta}$ T cells, and CD3^– CD2⁺ null cells. At T0, the CD3^– CD2^– null population contains CD3^– CD2^– null cells, B cells, monocytes, and dendritic cells. After 6 to 7 days of culture, this double negative population includes residual B cells and CD3^– CD2^– null cells. The profiles D, I, and N, with gates on 1, 2, and CD3⁺ cells, show the frequency of CD3⁺ ${alpha}$ ß T cells, CD2⁺ WC1^– ${gamma}$ ${delta}$ T cells, and CD2^– WC1⁺ ${gamma}$ ${delta}$ T cells. The profiles E, J, and O, with gates on 1, 2, and CD3⁺ cells, show the frequency of CD2^– CD25^– ${gamma}$ ${delta}$ T cells, CD2⁺ CD25^– ${alpha}$ ß T cells plus CD2⁺ WC1^– ${gamma}$ ${delta}$ T cells, CD2⁺ CD25⁺ ${alpha}$ ß T cells plus CD2⁺ WC1^– ${gamma}$ ${delta}$ T cells, and CD2^– WC1⁺ CD25⁺ ${gamma}$ ${delta}$ T cells.

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FIG. 3. Representative dot plot profiles of PBMC labeled with four MAbs at the start of culture (T0) (Fig. 1B, MAb set 5). Data were collected in gates 1 and 2. Profile A, anti-CD172a versus anti-B-B2, shows the frequency of CD172a⁺ monocytes in the upper left quadrant, CD172a⁺ B-B2⁺ cells in the upper right quadrant, and CD172a^– B-B2⁺ cells in the lower right quadrant. Profile B, anti-CD5 versus anti-B-B2, shows the frequency of CD5⁺ T cells in the upper left quadrant, CD5⁺ B-B2⁺ B cells in the upper right quadrant, and CD5^– B-B2⁺ B cells in the lower right quadrant. Profile C, anti-CD6 versus anti-B-B2, shows the frequency of CD6⁺ T cells in the upper left quadrant, CD6⁺ B-B2⁺ cells in the upper right quadrant, and CD6^– B-B2⁺ cells in the lower right quadrant. Profile D, anti-CD5 versus anti-CD172a, shows CD5⁺ T cells in the upper left quadrant, CD5⁺ CD172a⁺ cells in the upper right quadrant, and CD172a⁺ monocytes in the lower right quadrant.

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FIG. 4. Representative dot plot profiles of PBMC from a control animal labeled with four MAbs after 6 days of culture in RPMI (Fig. 1B, MAb sets 1 [A to D] and 5 [E to H]). Dot plot profiles A to D, with selective and exclusion gates on 2 and CD3, show that null cells comprise two unique phenotypically distinct CD3^– CD2^– and CD3^– CD2⁺ populations of cells. Profile A shows the frequency of CD3^– and CD3⁺ cells present in gate 2. Profile B shows that the cells in gate 2 comprise four populations: CD3^– CD2^– null cells in the lower left quadrant, CD3⁺ CD2^– ${gamma}$ ${delta}$ T cells in the upper left quadrant, CD3⁺ CD2⁺ ${alpha}$ ß and ${gamma}$ ${delta}$ T cells in the upper right quadrant, and CD3^– CD2⁺ null cells in the lower right quadrant. Profile C, with an exclusion gate on CD3, shows the frequency of CD3^–, CD2^– CD3^–, and CD2⁺ populations of null cells in gate 2. Profile D, with an exclusion gate on CD3, shows that both null cell populations, CD3^– CD2⁺ cells in the upper right quadrant and CD3^– CD2^– cells in the lower right quadrant, express CD25. Dot plot profiles E to H, with selective and exclusion gates on 2 and CD5, show that the two null cell populations do not express CD5 and that a subset of the null cells expresses CD6. Profile E shows the frequency of CD5^– and CD5⁺ cells in gate 2. Profile F shows the cells in gate 2 comprise four populations: CD5^– CD6^– null cells in the lower left quadrant, CD5⁺ ${gamma}$ ${delta}$ T cells in the upper left quadrant, CD2⁺ CD6⁺ T cells in the upper right quadrant, and CD5^– CD6⁺ null cells in the lower right quadrant. Profile G, with an exclusion gate on CD5, shows the frequency of CD6^– and CD6⁺ null cells in gate 2. Profile H, with an exclusion gate on CD5, shows the frequency of residual B-B2⁺ B cells present in the culture.

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FIG. 5. Representative dot plot profiles of CD4⁺ T cells from an infected animal labeled with four MAbs at T0 and after 6 days of culture in RPMI alone or with SAg (Fig. 1B, MAb set 2). A gate was placed on CD4⁺ T cells to analyze the expression of CD25 and CD26 on naïve and memory T cells present in gates 1 and 2. Profiles A, D, and G, SSC versus anti-CD4, show the frequency of CD4⁺ cells in the cell preparations in gates 1 and 2. Profiles B, E, and H, anti-CD25 versus anti-CD45R0, with a gate on CD4, show the frequency of CD25^– naïve (lower left quadrant), CD25⁺ naïve (upper left quadrant), CD25⁺ memory (upper right quadrant), and CD25^– memory (lower right quadrant) T cells. Profiles C, F, and I, anti-CD26 versus anti-CD45R0, with a gate on CD4, show the frequency of CD26^– naïve (lower left quadrant), CD26⁺ naïve (upper left quadrant), CD26⁺ memory (upper right quadrant), and CD26^– memory (lower right quadrant) T cells.

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FIG. 7. Representative dot plot profiles of ${gamma}$ ${delta}$ ⁺ T cells from an infected animal labeled with four MAbs at T0 and after 6 days of culture in RPMI alone or with SAg (Fig. 1B, MAb set 4). A gate was placed on ${gamma}$ ${delta}$ ⁺ T cells to analyze the expression of ACT2, CD25, and CD26 on ${gamma}$ ${delta}$ T cells present in gates 1 and 2. Previous studies have shown these cells are CD45R0 positive (data not shown). Profiles A, E, and I, SSC versus anti- ${gamma}$ ${delta}$ T cells, show the frequency of ${gamma}$ ${delta}$ T cells present in gates 1 and 2. Profiles B, F, and J, anti-ACT2 versus anti-CD26, with a gate on ${gamma}$ ${delta}$ T cells, show the frequency ACT2^– CD26^– (lower left quadrant), ACT2⁺ CD26^– (upper left quadrant), ACT2⁺ CD26⁺ (upper right quadrant), and ACT2^– CD26⁺ (lower right quadrant) ${gamma}$ ${delta}$ T cells. Profiles C, G, and K, anti-ACT2 versus anti-CD25, with a gate on ${gamma}$ ${delta}$ T cells, show the frequency of ACT2^– CD25^– (lower left quadrant), ACT2⁺ CD25^– (upper left quadrant), ACT2⁺ CD25⁺ (upper right quadrant), and ACT2^– CD25⁺ (lower right quadrant) ${gamma}$ ${delta}$ T cells. Profiles D, H, and I, anti-CD26 versus anti-CD25, with a gate on ${gamma}$ ${delta}$ T cells, show the frequency CD26^– CD25^– (lower left quadrant), CD26⁺ CD25^– (upper left quadrant), CD26⁺ CD25⁺ (upper right quadrant), and CD26⁺ CD25^– (lower right quadrant) ${gamma}$ ${delta}$ T cells.

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FIG. 8. Summary of FC analysis of CD25 and CD26 expressed on CD4⁺ CD45R0⁺ T cells stimulated with PPD and M. avium subsp. paratuberculosis SAg. Significant differences were noted between control animals and animals infected with M. avium subsp. paratuberculosis as indicated in the figure (a, P < 0.01; b, 0.01 < P < 0.05).

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FIG. 10. Summary of FC analysis of CD25 and CD26 expressed on CD8⁺ CD45R0⁺ T cells stimulated with PPD and M. avium subsp. paratuberculosis SAg. The significant differences between control animals and animals infected with M. avium subsp. paratuberculosis are as indicated in the figure (a, P < 0.01; b, 0.01 < P < 0.05).

Statistics. Data were analyzed by either repeated-measures, one-way analysisof variance followed by a Tukey-Kramer multiple comparison testor with Student's t test.

RESULTS

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Results

FC analysis of the proliferative response to M. avium subsp. paratuberculosis antigens. At the initiation of culture, CD4⁺ and CD8⁺ T cells comprised,on average, $~$ 16 and 10%, of the ungated cells, respectively.CD2⁺ ${alpha}$ ß⁺ T cells comprised $~$ 42% of the CD3 gated cells.CD2⁺ ${gamma}$ ${delta}$ ⁺ and CD2^– ${gamma}$ ${delta}$ ⁺ T cells comprised $~$ 4 and 47% of the CD3⁺gated cells, respectively (Fig. 2). CD3^– CD2⁺ cells comprised $~$ 1 to 3% of the ungated population of cells. The CD3^– CD2^–cells—B cells, monocytes, dendritic, and null cells includedin the CD3^– CD2^– population—comprised $~$ 38%of the ungated cells (Fig. 2). B cells, both CD5⁺ and CD5^–populations, comprised a variable proportion of cells at thestart of culture (Fig. 3).

The composition of cultured cells changed with time followinginfection with M. avium subsp. paratuberculosis. Based on sideand forward light scatter, lymphocytes were small and fell intogate 1 at the start of culture. Up to 5 to 6 months, both ${alpha}$ ßand ${gamma}$ ${delta}$ T cells remained small in cultures of unstimulated andstimulated cells from control and infected animals culturedfor 7 days. Only 6 to 10% of lymphocytes fell into the largelymphocyte gate (i.e., gate 2 in Fig. 2). In cultures from somecontrol and infected animals, however, populations of CD3^–CD2^– and CD3^– CD2⁺ null cells increased in sizeand proliferated. These cells proliferated in the presence andabsence of antigen. As shown in representative profiles in Fig.4, examination of cells present in the large lymphocyte gate(i.e., gate 2) with an exclusion gate on CD3 revealed that bothCD3^– CD2^– and CD3^– CD2⁺ null cell populationsexpressed CD25. Analysis of the CD172A, CD5, CD6, and B-cellcombination showed that in cultures where few CD3^– CD2^–and CD3^– CD2⁺ cells proliferated, persisting B cells accountedfor most of the null cells present in the culture. An exclusiongate on CD5, used with cultures where these populations proliferated,showed that the CD3^– CD2^– CD5^– cells did notexpress B-B2, a marker of B cells. A subset, however, expressedCD6 (Fig. 4). Together, these findings demonstrated that a populationof non-T, non-B cells from mononuclear cell cultures of youngcalves proliferate and express CD25 without specific stimulation.Thus, selective gates were placed on CD3, CD4, CD8, and ${gamma}$ ${delta}$ T cellsto exclude null cells when analyzing the response of CD4⁺, CD8⁺,and ${gamma}$ ${delta}$ T cells to M. avium subsp. paratuberculosis antigens.

Up to 5 months, there was little difference in the compositionof cultures of unstimulated and stimulated PBMC taken from controland infected animals. The majority of CD4⁺, CD8⁺, and ${gamma}$ ${delta}$ T cellswere present in the small lymphocyte gate (i.e., gate 1 in Fig.2). By 5 months a response to M. avium subsp. paratuberculosisantigens was evident in some infected animals. At 6 months,cells from all infected animals proliferated in the presenceof M. avium subsp. paratuberculosis PPD and SAg. After 6 to7 days of culture in the presence of antigens, 70 to 80% ofthe T cells were present in the large lymphocyte gate (i.e.,gate 2 in Fig. 2). Analysis of gated CD4⁺ T cells showed thatthe majority of CD4⁺ T cells fell into the large lymphocytegate and that they were CD45R0⁺, CD25⁺, and CD26⁺ (Fig. 5).CD45R0^– cells were present in the small lymphocyte gate(i.e., gate 1 in Fig. 2) and were negative for CD25 and CD26.As shown below in Fig. 8, the proportion of CD45R0⁺ CD25⁺ andCD26⁺ T cells from infected animals was significantly higherat 24 and 50 weeks than in respective samples from control animals.Further examination at 50 weeks showed additional activationmolecules were also upregulated in response to stimulation withM. avium subsp. paratuberculosis PPD and SAg (see Fig. 9).

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FIG. 9. Summary of FC data on nine activation molecules upregulated on CD4⁺ CD45R0⁺ T cells 50 weeks following stimulation with PPD and M. avium subsp. paratuberculosis SAg. The significant differences between control animals and animals infected with M. avium subsp. paratuberculosis are as indicated in the figure (a, P < 0.01; b, 0.01 < P < 0.05).

The proliferative response of CD8⁺ T cells was minimal to 50weeks postexposure to M. avium subsp. paratuberculosis. Theycomprised less than 10% of cells in stimulated and unstimulatedcultures from control and infected animals. At 50 weeks, someCD8⁺ T cells from infected animals were beginning to respondto antigen (see Fig. 10). Although their frequency in cultureswas still low at 18 months, examination of CD8⁺ cells from infectedanimals showed some cells were responding to antigens (Fig.6). Selective gating showed the responding cells were increasedin size, CD45R0⁺, CD25⁺, and CD26⁺. Small cells in gate 1 wereCD45R0^–, CD25^–, and CD26^–.

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FIG. 6. Representative dot plot profiles of CD8⁺ T cells from an infected animal labeled with four MAbs at T0 and after 6 days of culture in RPMI alone or with SAg (Fig. 1B, MAb set 3). A gate was placed on CD8⁺ T cells to analyze the expression of CD25 and CD26 on naïve and memory T cells present in gates 1 and 2. Profiles A, D, and G, SSC versus anti-CD8, show the frequency of CD8⁺ cells in the cell preparations in gates 1 and 2. Profiles B, E, and H, anti-CD25 versus anti-CD45R0, with a gate on CD8, show the frequency of CD25^– naïve (lower left quadrant), CD25⁺ naïve (upper left quadrant), CD25⁺ memory (upper right quadrant), and CD25^– memory (lower right quadrant) T cells. Profiles C, F, and I, anti-CD26 versus anti-CD45R0, with a gate on CD8, show the frequency of CD26^– naïve (lower left quadrant), CD26⁺ naïve (upper left quadrant), CD26⁺ memory (upper right quadrant), and CD26^– memory (lower right quadrant) T cells.

As noted in Fig. 2, ${gamma}$ ${delta}$ T cells comprised a large proportion ofcells present at the initiation and after 6 to 7 days of culture.The majority of the ${gamma}$ ${delta}$ T cells were CD2^– WC1⁺. The frequencyof this subset varied from 40 to 50% of the total T-cell populationin both control and infected animals. The CD2⁺ WC1^– populationvaried from 5 to 10%. The relative proportions of these subsetsdid not change in unstimulated cultures. The frequencies ofboth populations were lower in antigen-stimulated cultures frominfected animals containing proliferating CD4⁺ T cells (Fig.2). ${gamma}$ ${delta}$ T cells expressed CD25 and ACT2 at low levels (Fig. 7).They did not express CD26. Eighteen months postinfection, ${gamma}$ ${delta}$ Tcells in cultures from control and infected animals exhibitedan activated phenotype in the presence of PPD and SAg (Fig.2 and 7). Selective gating on small and large cells with a gateon the CD2⁺ WC1^– populations showed 10% of the cells inthe small lymphocyte gate expressed CD25 at T0, 6% expressedCD25 after 6 days of culture without antigen, and 13% expressedCD25 6 days after culture with antigen, respectively. At thesame time points, 50, 64, and 84% of the ${gamma}$ ${delta}$ T cells in the largelymphocyte gate expressed CD25 (Fig. 2). Selective gating onsmall and large cells with a gate on CD2^– WC1⁺ cells showed70% of the cells in the small lymphocyte gate expressed CD25at T0, 52% expressed CD25 after 6 days of culture without antigen,and 81% expressed CD25 at 6 days after culture with antigen.At the same time points, 86, 96, and 98% of the cells in thelarge lymphocyte gate expressed CD25 (Fig. 2). In the presenceof antigen, subsets coexpressing ACT2 and CD26 or CD26 alonewere readily distinguished. Selective gating showed that thecells expressing higher levels of ACT2 and CD26 were presentin the large lymphocyte gate, indicating that they were activatedand proliferating.

IFN- ${gamma}$ and ELISA assays. As noted in a previous study (5), IFN- ${gamma}$ responses did not yieldconsistent results over time (data not shown). Some infectedanimals tested positive at some time points and negative atother time points during the course of the study. No positiveresults were obtained with the absorbed ELISA for M. avium subsp.paratuberculosis-specific antibody with infected animals (datanot shown). Serum samples submitted to the Washington StateDiagnostic Laboratory and examined by HerdChek ELISA (IDEXXLabs) were also negative. M. avium subsp. paratuberculosis wasnot detected in any of the fecal samples submitted to the diagnosticlaboratory throughout the period of investigation.

Detection of M. avium subsp. paratuberculosis in tissue biopsies. To determine if M. avium subsp. paratuberculosis could be detectedin infected animals responding to M. avium subsp. paratuberculosisantigens, PCR was performed on cecal lymph node tissue takenat 12 months postexposure from the control and infected animals.Similar to findings in previous studies, M. avium subsp. paratuberculosiswas not detected in tissues from every animal (60). Lymph nodesfrom two of the infected animals were positive by RT-PCR (datanot shown).

Effect of MHC haplotype on the immune response to M. avium subsp. paratuberculosis. At the time of writing of this report, no clear differenceswere detected in the immune response of cattle with differentMHC genotypes (Table 1) to M. avium subsp. paratuberculosisas analyzed by FC. Therefore, data were combined for statisticalanalysis of the response of individual subpopulations of cellsto M. avium subsp. paratuberculosis antigens.

DISCUSSION

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Discussion

The results presented here extend previous observations andreveal the importance of using multicolor FC for in vitro analysisof the immune response to M. avium subsp. paratuberculosis.Using the intratonsillar inoculation model, we were able toshow animals can be uniformly infected and used to examine theevolution of an immune response to M. avium subsp. paratuberculosis(60). Fecal culture and IS900 RT-PCR confirmed the animals wereinfected. Light shedding was detected between 146 to 271 dayspostinoculation (one to four colonies/agar slant). At the terminationof the study at 320 days, M. avium subsp. paratuberculosis wasisolated from tonsil, duodenum, ileum, and jejunum and the ileal,jejunal, and spiral colon lymph nodes. M. avium subsp. paratuberculosiswas not obtained from some tissues in each of the animals examined,similar to the findings of Koets et al. (38). Sequential samplingand culture of PBMC with LAM and SAg revealed a recall proliferativeresponse to M. avium subsp. paratuberculosis was detectableby 6 months after infection by tritiated thymidine incorporationand FC. Phenotypic analysis by FC showed CD4⁺ T cells expressingCD45R0 and an activation molecule, CD26, were the predominantcell type present in the cultures responding to antigen. TheIFN- ${gamma}$ ELISA demonstrated the presence of IFN- ${gamma}$ in culture supernatants.Intracellular staining showed CD4⁺ T cells were the main celltype positive for IFN- ${gamma}$ .

Infection by the oral route yielded similar results with thekinetics of appearance of a proliferative response to M. aviumsubsp. paratuberculosis antigens occurring in the same timeframe. In contrast to the variable results observed with theIFN- ${gamma}$ and serological ELISAs, a persistent strong cellular recallresponse to M. avium subsp. paratuberculosis antigens was observedwith PBMC from all five infected animals at all time pointstested 6 months after infection. This is the first consistentindication of infection in animals still fecal culture negativeand inconsistently positive in the IFN- ${gamma}$ and antibody-based diagnosticELISAs. This finding would be expected in animals where theimmune response to M. avium subsp. paratuberculosis is stillcontrolling but not eliminating M. avium subsp. paratuberculosis,as suggested in the recent National Academy of Science reporton Johne's disease (51).

FC analysis confirmed CD4⁺ T cells are the predominant populationof cells responding to antigens in the first year of infectionand, further, revealed the complexity of cultures maintainedover a 6- to 7-day period in the absence and presence of antigen.Analysis of CD4⁺ and CD8⁺ T cells showed each population canbe divided into three subpopulations based on expression ofCD45R0, a marker for memory T cells (6, 28), and CD25 and CD26,markers used to determine the state of cell activation (Fig.5 and 6) (9, 32). CD4⁺ CD45R0⁺ T cells comprised $~$ 50% of CD4⁺T cells at the start of culture; $~$ 4 to 10% expressed CD25 atlow levels; 10 to 20% expressed CD26 at levels similar to thevalues obtained in animals 13 to 302 days of age. Followingstimulation, the CD4⁺ memory T cells increased in size and beganto proliferate. By 6 to 7 days, the majority of CD4⁺ T cellsexpressed CD25 and CD26 at high levels (Fig. 5 and 8). Theyalso expressed nine additional activation molecules (Fig. 9).After 6 to 7 days of culture, few naïve CD4⁺ T cells werepresent in the culture. As noted at the beginning of the culture,the naïve cells were small and negative for CD25 or CD26,indicating they had not been activated. Analysis of CD8⁺ T cellsshowed CD8⁺ CD45R0⁺ T cells comprised $~$ 30% of the CD8⁺ T cellsat the start of culture, $~$ 1% expressed CD25 at low levels, and $~$ 10% expressed CD26. Up to a year, there appeared to be littlechange in size or composition of the CD8⁺ T-cell populationin stimulated cultures (Fig. 10). However, by 18 months, antigen-stimulatedCD8⁺ T cells showed an increase in size and expression of CD25and CD26, suggesting that a progressive change in the immuneresponse to M. avium subsp. paratuberculosis was beginning tooccur (Fig. 6). Selective gating on large cells in gate 2 showedit was the CD45R0⁺ memory T cells that increased in size andexpressed CD25 and CD26.

The response of ${gamma}$ ${delta}$ T cells to M. avium subsp. paratuberculosisantigens was not clearly defined in the present study. Analysisof the frequency and activation status of ${gamma}$ ${delta}$ T cells in the firstmonths of the study showed the two major subpopulations of ${gamma}$ ${delta}$ T cells comprised a large proportion of the cells in culturein the presence and absence of M. avium subsp. paratuberculosisantigens at all time points during the study. The CD2⁺ ${gamma}$ ${delta}$ ⁺ populationcorresponds to the CD2⁺ WC1^– population, and the CD2^– ${gamma}$ ${delta}$ ⁺ population corresponds to the CD2^– WC1⁺ population.These populations are distinct (17). They have different patternsof trafficking in blood and tissues (26, 62-64). The frequencyof CD2^– WC1⁺ cells is high in blood and low in intestinalepithelial and lymphoid tissues and skin. CD2^– WC1⁺ cellsexpress CD62L (L selectin) at high levels, whereas the CD2⁺WC1^– population expresses a low level of CD62L. The latterpopulation is present at a low frequency in blood and most tissuesbut high in the spleen. The relative proportions of these twopopulations of ${gamma}$ ${delta}$ T cells remained similar in unstimulated andantigen-stimulated cultures of cells. At the initiation of culture,CD2^– WC1⁺ ${gamma}$ ${delta}$ T cells were the predominant population expressingCD25. The majority of these cells were present in the smalllymphocyte gate, indicating they were not activated. CD2⁺ WC1^– ${gamma}$ ${delta}$ T cells expressing CD25 were found mainly in the large lymphocytegate, suggesting they were activated. There appeared to be minimalexpression of ACT2 or CD26 on either population of cells incultures prepared during the first year of the study. However,at 18 months, subsets of ${gamma}$ ${delta}$ T cells in cultures of cells fromboth control and infected animals either coexpressed ACT2 andCD26 or expressed CD26 alone. Cells expressing these moleculeswere present in the large lymphocyte gate, indicating they wereproliferating.

Of particular interest, the study revealed the presence of twopopulations of null cells: one, CD3^– CD2⁺, consideredto be NK cells and one that was CD3^– CD2^–. The latterpopulation has not been previously reported. The appearanceof these two populations of cells in unstimulated and antigen-stimulatedcultures from control and infected animals was not anticipated.The predominant population in most cultures where proliferationoccurred was CD3^– CD2^–. It was also CD5^– B-B2^–,and a subset expressed CD6. Culture conditions promoting proliferationof these populations of cells are not known, but it is clearthat the random appearance of this population in cultures ofPBMC could account for the high background noted in studieswhere tritiated thymidine has been used to detect cell proliferation.The data obtained in this study would have been difficult tointerpret based on tritiated thymidine incorporation. The useof exclusion gating permitted us to analyze the antigen-specificresponses of lymphocyte subsets in all cultures.

Limited information is available on whether there is any associationof disease resistance or susceptibility to M. avium subsp. paratuberculosislinked to a given MHC haplotype. The data obtained here didnot reveal any difference in the time of appearance or magnitudeof the proliferative response to PPD or SAg. Further studiesare needed with additional infected animals with different MHChaplotypes to determine if there are MHC-linked associationsaffecting the rate of disease progression.

Elucidation of how M. avium subsp. paratuberculosis modulatesthe immune response and evades immune elimination is crucialto understanding what strategies need to be employed to developan effective vaccine. The general view is that protection ismediated through CMI against M. avium subsp. paratuberculosisand that disease progression correlates with an apparent shiftin the dominant immune response to M. avium subsp. paratuberculosisfrom a strong CMI response to a humoral response. Cumulativedata from studies of Mycobacterium tuberculosis and M. aviumsubsp. paratuberculosis indicate that CD4⁺ T cells with a type1 cytokine profile and CD8⁺ T cells are the primary cells mediatingprotection against intracellular pathogens. The role of ${gamma}$ ${delta}$ T cellsremains unclear, especially in Artiodactyla, where two phenotypicallydistinct complex subpopulations exist. As mentioned, the subsetsdiffer in tissue distribution and patterns of trafficking. Theeffector mechanisms of CD4⁺ cells are associated with secretionof IFN- ${gamma}$ , which activates bactericidal activity in macrophages,lymphotoxin, perforin, and granulysin (10). The effector mechanismsof CD8⁺ T cells and ${gamma}$ ${delta}$ T cells are less clear, but there is evidencethat CD8⁺ and ${gamma}$ ${delta}$ T cells also secrete granulysin (10, 55). Theirpresence in M. tuberculosis lesions has suggested they may synergizewith CD4⁺ T cells in mediating protection. Dysregulation couldinvolve disruption of cell signaling essential for maintenanceof CMI at multiple steps, beginning with the first encounterand uptake of the pathogen by dendritic cells and macrophages(25, 58). Uptake and sequestration of M. avium subsp. paratuberculosiscould involve the same receptors as described for M. tuberculosisand associated disruption in phagosome lysosome fusion. Retentionof TACO (tryptophan-aspartate-containing coat protein) in thephagosome appears to retard fusion with lysosomes and protectsreplicating bacteria from bactericidal oxygen and nitrous oxideintermediates produced by activated macrophages (49, 50). Alterationsin the cytokine and chemokine profiles could affect innate immunityand the way antigens are processed and presented to T cells(27, 36, 46, 58). Progressive changes attributable to disseminationand spread of M. avium subsp. paratuberculosis and increasedantigenic load could induce alterations in signaling mediatedthrough cytokines and chemokines that modulate the responseto M. avium subsp. paratuberculosis antigens. Recent gene profilinghas revealed changes in gene expression that could account foralterations in cell signaling mediated through cell receptorsand altered patterns of cytokine and chemokine secretion (12,13). Significant changes were noted in expression of multiplegenes in cultures of PBMC from infected animals incubated withlive M. avium subsp. paratuberculosis. Some genes exhibitedincreased expression in cells from infected animals, while othersexhibited a decrease in expression. Of particular interest,changes were noted in the expression of IFN- ${gamma}$ , IL-10, and CD154(CD40L). M. avium subsp. paratuberculosis-mediated arrest ofphagosome maturation also appears to involve members of therab family of small GTPases, which confer fusion competencein the endocytic pathway (30, 56, 59). More specific changesthat might be associated with M. avium subsp. paratuberculosis-mediatedchanges in gene expression and potential mechanisms of pathogenesishave been found in tissue samples taken from the ileum of M.avium subsp. paratuberculosis-infected animals. A large increasein expression of IL-1 ${alpha}$ and TNF receptor-associated factor 1 werefound in tissues from infected animals (1). Increases in secretionof IL-1 ${alpha}$ could lead to local toxicity and reduced proinflammatorysignaling mediated by TNF- ${alpha}$ . Whether specific changes in geneexpression can be associated with functional changes in CMIand humoral responses to M. avium subsp. paratuberculosis arenot yet clear. Comparative analysis using single-fluorescenceFC did not reveal any statistically significant differencesin blood lymphocyte and monocyte populations between infectedand uninfected animals (12). However, a more comprehensive studyby Koets et al. (38) has shown that progressive changes in thefrequency of CD4⁺ T cells and ${gamma}$ ${delta}$ T cells might correlate withchanges in gene activation. Using immunohistochemistry and single-fluorescenceFC, their studies with (i) normal animals, (ii) animals at theasymptomatic but shedding stage of disease, (iii) symptomaticanimals at the end stage of disease, and (iv) animals vaccinatedwith a live vaccine showed differences exist in the frequencyof CD4⁺ T cells and ${gamma}$ ${delta}$ T cells in the lesional areas of the ileallamina propria in symptomatic compared to asymptomatic animals.Using tritiated thymidine incorporation, they also showed anoverall lower proliferative response to M. avium subsp. paratuberculosisheat shock protein 70, PPD, whole bacteria, and concanavalinA in symptomatic compared to normal, asymptomatic shedders andto vaccinated animals.

These recent observations are beginning to provide insight intothe immune response to M. avium subsp. paratuberculosis andpotential mechanisms by which M. avium subsp. paratuberculosismodulates the response during the course of disease. With thehigher resolution obtained with multicolor FC combined withgene profiling, it should be possible to elucidate how M. aviumsubsp. paratuberculosis affects immune recognition at the levelof antigen-presenting cells and the events during immune recognitionand development of an immune response to M. avium subsp. paratuberculosis.The finding that a proliferative response to M. avium subsp.paratuberculosis is not readily detected until 5 months afterinfection by direct inoculation or the oral route suggests M.avium subsp. paratuberculosis interferes with pathways of activationassociated with antigen uptake by antigen-presenting cells.It will be important to determine if M. avium subsp. paratuberculosisuses DC-SIGN (CD209) similar to M. tuberculosis to dysregulateantigen processing and/or disrupt toll-like receptor-mediatedsignaling (31, 58).

ACKNOWLEDGMENTS

This study was funded in part by grants USDA-NRICGP 2002-35204-11688and 2003-05165, USDA-APHIS-VS 03-9100-0788-GR, and 03-9100-07-GR,intramural support USDA Animal Health WNV-00150. Hye CheongKoo was supported in part by the Research Institute of VeterinaryScience, College of Veterinary Medicine, Seoul National University,the Brain-Korea 21 Project in Agricultural Biotechnology, andthe Washington State University Monoclonal Antibody Center.

FOOTNOTES

* Corresponding author. Mailing address: Department of Veterinary Microbiology and Pathology, CVM, Washington State University, Pullman, WA 99164-7040. Phone: (509) 335-6051. Fax: (509) 335-8328. E-mail: davisw{at}vetmed.wsu.edu.

Editor: J. D. Clements

REFERENCES

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