Role of CD40 Ligand in Mycobacterium avium Infection

This Article

	Abstract
	Full Text (PDF)
	Alert me when this article is cited
	Alert me if a correction is posted

Services

	Similar articles in this journal
	Similar articles in PubMed
	Alert me to new issues of the journal
	Download to citation manager
	Reprints and Permissions
	Copyright Information
	Books from ASM Press
	MicrobeWorld

Citing Articles

	Citing Articles via HighWire
	Citing Articles via Google Scholar

Google Scholar

	Articles by Hayashi, T.
	Articles by Catanzaro, A.
	Search for Related Content

PubMed

	PubMed Citation
	Articles by Hayashi, T.
	Articles by Catanzaro, A.

Previous Article | Next Article

Infection and Immunity, July 1999, p. 3558-3565, Vol. 67, No. 7
0019-9567/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.

Role of CD40 Ligand in Mycobacterium avium Infection

Tomoko Hayashi, Savita P. Rao, Pascal R. Meylan, Richard S. Kornbluth, and Antonino Catanzaro^*

Department of Medicine, University of California San Diego, San Diego, California

Received 29 January 1999/Returned for modification 2 March 1999/Accepted 14 April 1999

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

Mycobacterium avium is a common opportunistic pathogen in immunocompromised patients such as those infected with human immunodeficiencyvirus. Although M. avium is an intracellular organism replicatingpredominantly in macrophages, disseminated M. avium infectionis seen in AIDS patients with CD4⁺ cell counts of <50 cells/µl, suggesting a possible involvementof a T cell-macrophage interaction for the elimination of M. avium.To determine whether CD40-CD40 ligand (CD40L) interactions playa role in M. avium infection, we studied the ability of CD40Lto restrict M. avium replication in human monocyte-derived macrophages(MDM) in vitro. MDM were infected with M. avium and coculturedwith CD40L-transfected 293 cells for 7 days. Intracellular growthof M. avium in these MDM was assessed by colony counting. CD40L-expressingcells inhibited growth of M. avium in MDM by 86.5% ± 4.2% comparedto MDM cultured with control cells. These findings were verifiedby assays using purified, soluble recombinant human CD40L (CD40LT).CD40LT (5 µg/ml) inhibited intracellular growth of M. avium by76.9% ± 18.0% compared to cells treated with medium alone. Inhibitionby CD40LT was reduced by monoclonal antibodies (MAbs) againstCD40 and CD40L. The inhibitory effect of CD40LT was not accompaniedby enhancement of interleukin-12 (IL-12) production by M. avium-infectedMDM, while CD40L-expressing cells stimulated IL-12 productionby these cells. Treatment of M. avium-infected mice with MAb againstmurine CD40L resulted in recovery of larger numbers of organisms(0.8 to 1.0 log) from the spleens, livers, and lungs of theseanimals compared to infected mice which received normal immunoglobulinG. These results indicate that CD40-CD40L signaling may be animportant step in host immune response against M. aviuminfection.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

Mycobacterium avium infection is one of the most commonly encountered opportunistic infections in human immunodeficiency virus(HIV)-infected individuals (26). It remains difficult to treatand can be a significant cause of morbidity. M. avium predominantlyinfects and multiplies within macrophages (17). This organismis known to attach and enter macrophages with the help of specificreceptors expressed on the surface of these cells (7, 37,39). In vitro studies have shown that macrophages secrete severalcytokines such as tumor necrosis factor alpha (TNF- $alpha$ ), interleukin-1 $beta$ (IL-1 $beta$ ), IL-6, granulocyte-macrophage colony-stimulating factor(GM-CSF), and granulocyte colony-stimulating factor (19, 33)in response to infection with this organism. Some cytokines, suchas TNF- $alpha$ and GM-CSF, have also been shown to activate infectedmacrophages to kill this organism. Healthy individuals are ableto control this infection easily. However, AIDS patients, particularlythose who have CD4⁺ T-cell counts of less than 50 cells/µl, are at increased riskof developing disseminated infection due to M. avium (26). Thefact that infection due to M. avium is seen predominantly in immunocompromisedindividuals with low CD4⁺ T cells suggests that T cells are critically important in controllingthis infection and that a T-cell interaction with macrophagesmay play a role in preventing M. avium infection in healthyhosts.

T-cell products such as gamma interferon (IFN- $gamma$ ) and IL-12 are known to be important for antimycobacterial activity of macrophages(20). In recent years it has been shown that T cells can stimulatemacrophages by a non-cytokine-mediated, direct cell-cell contact-dependentpathway through CD40 ligand (CD40L). CD40L, also known as CD154,is expressed transiently on the surface of activated T cells andbinds to surface CD40 molecules on antigen-presenting cells, includingB cells, macrophages, and dendritic cells (5). CD40-CD40L signalingis essential for several immunoregulatory pathways, includingcell-mediated host immune response against pathogens (24). Ligationof CD40L to CD40 on B cells has been shown to inhibit immunoglobulin(Ig) isotype switching (5) as well as primary and secondaryhumoral immune response to thymus-dependent (TD) antigens butnot thymus-independent (TI) type II antigens (22). CD40-CD40Linteractions are known to activate antigen-presenting cells, suchas macrophages and dendritic cells (24). Ligation of CD40 withCD40L is also required for the microbicidal activity of macrophages.CD40-CD40L interactions have been reported to be important inresolution of infections by pathogens such as Leishmania major(10), Leishmania amazonensis (42), Cryptosporidium parvum(14), and Pneumocystis carinii (47). Patients suffering fromhyper-IgM syndrome, who have a defect in their CD40L gene, arehighly susceptible to intracellular pathogens such as Pneumocystis,Cryptococcus, and Histoplasma species (9, 35).

In this study, we examined the role of CD40L in M. avium infection, both in vitro and in vivo. We have determined whetherCD40L plays a role in inhibiting intracellular growth of M. aviumin human macrophages in vitro. Further, we evaluated the roleof CD40-CD40L interactions in vivo, using monoclonal antibodies(MAbs) against CD40L to block this interaction in mice infectedwith M. avium.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Reagents. RPMI 1640 and Iscove's modified Dulbecco's medium were purchased from BioWhittaker (Walkersville, Md.). Fetal bovine serum(FBS) and normal human serum (NHS) were purchased from IrvineScientific (Santa Ana, Calif.). Minimal essential medium withEagle's salts and FBS for culture of 293 cells were purchasedfrom Quality Biological (Gaithersburg, Md.) and Summit Biotechnology(Fort Collins, Colo.), respectively. Murine MAbs against humanCD40 (clone M3) (31) and recombinant human IFN- $gamma$ were purchasedfrom Genzyme (Cambridge, Mass.). Control mouse IgG $kappa$ chain waspurchased from PharMingen (San Diego, Calif.). Goat anti-mouseIgG-fluorescein isothiocyanate conjugate was obtained from BectonDickinson (San Jose, Calif.). Purified recombinant soluble humantrimeric CD40L (CD40LT) and murine MAb against human CD40L (cloneM90) (4) were provided by Immunex Corporation (Seattle, Wash.).MR1 (hamster MAb specific for mouse CD40L) was purified from culturesupernatants of hybridoma cells (HB-11048; American Type CultureCollection, Manassas, Va.) by Immunodynamics Inc. (San Diego,Calif.). Control hamster IgG was purchased from Pierce ChemicalCo. (Rockford, Ill.). Alkaline phosphate-conjugated anti-mouseIgG was obtained from Sigma Chemical Co. (St. Louis, Mo.).

Culture of M. avium. The previously studied M. avium strain 13 (32), isolated from an AIDS patient at the University of California, San Diego,was used in all experiments. It was cultured on Middlebrook 7H11agar (Difco Laboratories, Detroit, Mich.) with oleic acid-albumin-dextrosecomplex (OADC) enrichment at 37°C in the presence of 5% CO₂ for2 weeks. Transparent colonies were selectively picked and furthercultured on Middlebrook 7H11 plates for 2 more weeks. The resultingcolonies, which were predominantly transparent (>90%), were thencollected and washed two times with phosphate-buffered saline(PBS). The bacteria were finally resuspended in Middlebrook 7H11broth (Difco Laboratories), and the optical density at 600 nmof the suspension was adjusted to 0.15 to 0.2. The suspensionwas aliquoted and stored at $-$ 70°C until use. The number of organismsper milliliter of this suspension was determined by the colony-formingunit (CFU)assay.

Isolation of human monocytes. Monocytes were isolated from normal human buffy coats obtained from the San Diego Blood Bank by Ficoll-Hypaque and Percollgradient centrifugation (25). Purity of the monocytes by thismethod was greater than 70%. The monocytes thus isolated werecultured for 5 to 7 days in Iscove's modified Dulbecco's mediumsupplemented with 10% NHS, 2 mM L-glutamine, and 50 U of penicillin-streptomycinper ml in Teflon beakers to yield monocyte-derived macrophage(MDM). MDM were further enriched by adherence to the wells oftissue culture plates before use in experiments. Purity of MDMafter the second adherence as assessed by esterase staining was>95%. Viability determined by trypan blue exclusion was >97%.

Transfection of 293 cells with CD40L. 293 (human embryonic kidney) cells were transfected as described previously (31). Briefly, the cDNA for human CD40L wasprepared by reverse transcription of mRNA isolated from peripheralblood mononuclear cells which were stimulated with an anti-CD-3MAb and IL-2 and selected for surface CD40L expression by usingan anti-CD40L MAb. This cDNA was amplified by PCR, and the PCRproduct was cloned into the expression vector pcDNA3.1(+) (Invitrogen,San Diego, Calif.). This plasmid, referred to as pcDNA3.1-CD40L,was transfected into 293 cells and selected in medium containingG418 (Genectin; GIBCO BRL, Grand Island, N.Y.). The CD40L-positivecells (CD40L-293 cells) were further selected by repeated cellsorting using a CD40L-specific antibody. The control 293 cellsused in this study were prepared by transfection of 293 cellswith the empty expression vector, pcDNA3.1(+) (pcDNA-293 cells).The ability of M. avium to infect 293 cells when added at a cell/bacteriumratio of 1:10 was tested; 0.37% ± 0.8% of the total number ofM. avium added to the wells attached and/or invaded these cells.However, the organism did not replicate in 293cells.

Infection of MDM with M. avium. MDM were adhered to wells of a 48-well (2 × 10⁵/well) or 96-well (6 × 10⁴/well) tissue culture plate for 2 h, and nonadherent cells wereremoved by washing with serum-free RPMI 1640. After washing, adherentMDM were infected with M. avium at a multiplicity of infectionof 10:1 for 2 h at 37°C. After 2 h, MDM were extensively washedwith prewarmed RPMI 1640 to remove extracellular organisms. Todetermine whether priming of MDM with IFN- $gamma$ alters the effectof CD40L on intracellular growth of M. avium, in some experimentsadherent MDM were incubated with IFN- $gamma$ (0.3 µg/ml; Genzyme) inRPMI 1640 containing 10% NHS for 3 days prior to infection withM. avium.

Treatment of M. avium-infected MDM with CD40L-293 cells or CD40LT. CD40L-293 cells and pcDNA-293 cells were harvested and resuspended in RPMI 1640 containing 5% heat-inactivated FBS in theabsence of antibiotics. Live CD40L-293 or pcDNA-293 cells wereadded to M. avium-infected MDM at a ratio of 0.5:1. M. avium-infectedcells cultured with medium alone served as the untreated control.In experiments designed to study the effect of CD40LT, M. avium-infectedMDM were incubated with CD40LT at 1 and 5 µg/ml. Infected cellscultured with medium alone served ascontrols.

On days 1, 3, and 7 postinfection, the supernatant was collected and set aside and the adherent cells were lysed. To accountfor all the mycobacteria in each well, corresponding lysates andsupernatants were combined and used to determine the number ofCFU (described below). Experiments were done in triplicate, andresults were expressed as mean CFU per well ± standard deviation(SD).

In some experiments, infected MDM were treated with CD40L-293 cells or CD40LT in the presence of MAb against CD40L (10 µg/ml)or CD40 (10 µg/ml) in order to prevent ligation of CD40L withCD40. In these experiments, total CFU in each well was determinedonly on day 7. Comparisons were made between M. avium-infectedMDM treated with CD40L-293 cells and M. avium-infected MDM treatedwith pcDNA-293 cells or M. avium-infected MDM treated with CD40LTand mediumalone.

CFU assay. CFU were determined by colony counting as we described previously (36). Serial 10-fold dilutions of total cell lysates wereperformed in PBS; 10 µl of each dilution was plated on Middlebrook7H11 plates supplemented with OADC enrichment, and plates wereincubated up to 14 days at 37°C. The number of colonies were countedevery alternate day from day 10 onward until no new colonies appear;this yields the number of CFU/10 µl. The number of CFU in eachwell was thencalculated.

Measurement of IL-12 production by M. avium-infected MDM treated with CD40L-293 cells or CD40LT. MDM infected with M. avium and uninfected MDM were cultured with CD40L-293 or pcDNA-293 cells in RPMI 1640 containing 5% heat-inactivatedFBS in the absence of antibiotics. In some experiments, infectedMDM were treated with 5 µg of CD40LT per ml. Cells treated withmedium alone served as controls. On days 1, 3, and 7 postinfection,culture supernatant was collected and IL-12 (p70) was measuredby enzyme-linked immunosorbent assay (ELISA) using human IL-12ELISA kits (Endogen, Inc., Woburn, Mass.). Experiments were donein triplicate, and results are expressed as mean ±SD.

Infection of mice and administration of MAb against CD40L. Seven- to eight-week-old, female C57BL/6 mice (Simonsen Laboratories, Gilroy, Calif.) were infected with 10⁶ M. avium in 0.1 ml of PBS by intravenous tail vein injectionand then divided into two groups of five each. Immediately afterinfection (day 0), as well as on days 2, 4, 6, 10, 13, 17, 20,24, 27, 31, and 34, one group of mice received 250 µg of MAb againstmurine CD40L (MR1) intraperitoneally. The control group received250 µg of normal hamster IgG at the same time points. On day 35(5 weeks), all mice were euthanized and dissected. The liver,spleen, and lungs were collected and weighed. All procedures wereperformed under a biosafety cabinet in a biosafety level 2 facility.The organs were minced and homogenized for 30 s with 0.25% sodiumdodecyl sulfate in PBS (1 ml/100 mg of tissue). The number ofCFU in the tissue homogenates was determined by the CFU assay,and the results were expressed as CFU perorgan.

As mentioned earlier, CD40-CD40L signaling is required for the generation of a humoral immune response against TD antigens.Anti-CD40L MAb treatment has been shown to inhibit the generationof an antibody response to these antigens (18). We used thisobservation as a tool to determine whether MR1 effectively blocksCD40L in our in vivo experiments. We therefore examined the humoralresponse against MR1, a hamster anti-mouse CD40L antibody whichitself is a TD antigen (13). Serum IgG and IgM levels againstMR1 in anti-CD40L-treated mice were compared with those of micetreated with control hamster IgG. Murine IgG specific for hamsterIgG and IgM was assayed by ELISA. Blood samples were collectedfrom each mouse on day 35 after infection with M. avium. ELISAplates (Nunc-Immuno Plate MaxiSorp plates; Nunc Inc., Naperville,Ill.) were coated overnight at 4°C with 10 µg of hamster IgG perml. After blocking, 10-fold serial dilutions of the serum wereperformed and added into the wells. Mouse IgG or IgM specificfor hamster IgG was detected by using alkaline phosphate-conjugatedanti-mouse IgG or IgM,respectively.

Histologic examination. Tissue sections of the spleen, liver, and lungs collected from each of the experimental and control mice were fixed overnightin 10% buffered formalin at room temperature and embedded in paraffin.The paraffin-embedded tissue was further sectioned (5-µm thickness),stained with Ziehl-Neelsen reagent, which specifically stainsacid-fast bacilli, and also stained with hematoxylin-eosin. Thesections were observed under an Olympus microscope. At least threespecimens from each organ of each of the experimental and controlmice were evaluated, and representative fields were photographedwith Olympus microphotographic equipment (Olympus Optical Co.,Lake Success, N.Y.) or a Zeiss Axiophot microscope (Carl ZeissInc., Thornwood, N.Y.) equipped with a Sony DKC5000 charge-coupleddevice camera. The images were captured and processed for presentationwith Adobe Photoshop 4.0 and printed on a dye sublimationprinter.

Statistical analysis. Results were expressed as mean ± SD. Statistical differences were determined by Student's t test. A P value below 0.05 wasconsidered to be statisticallysignificant.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

In vitro effect of CD40L against growth of M. avium in MDM. To assess the effect of CD40-CD40L interaction on intracellular growth of M. avium in MDM, we treated M. avium-infected MDMwith CD40L-293 cells and determined the number of CFU on days1, 3, and 7 after infection (Fig. 1A). CD40L-293 cells were foundto inhibit the intracellular growth of M. avium in MDM by 86.5%± 4.2% compared to MDM treated with pcDNA-293 cells, which servedas the control (P < 0.05). However, pcDNA-293 cells themselveswere found to substantially inhibit intracellular growth of M.avium in MDM compared to infected MDM treated with medium alone.To confirm that the inhibitory effect observed with CD40L-293cells was indeed due to CD40L and not merely the cells themselves,MAb specific for CD40L or CD40 was used to block ligation of CD40with CD40L (Fig. 1B). The antimycobacterial effect of CD40L-293cells was inhibited by 65% ± 23% (P < 0.05) in the presence ofMAb against CD40L and by 90% ± 14% (P < 0.001) in the presenceof MAb against CD40.

View larger version (24K):
[in this window]
[in a new window]

FIG. 1. Effect of CD40L-293 cells and CD40LT on intracellular growth of M. avium in MDM. M. avium-infected MDM were cocultured with CD40L-293 cells or CD40LT in the presence and absence of MAbs against CD40L and CD40 for up to 7 days. Intracellular growth of M. avium was assessed by the CFU assay on days 1, 3, and 7 after infection. Each condition was tested in triplicate, and results are expressed as mean CFU per well ± SD. (A) M. avium-infected MDM cultured with CD40L-293 cells; (B) M. avium-infected MDM cultured with CD40L-293 cells or control pcDNA-293 cells in the presence and absence of MAb against CD40L (10 µg/ml), CD40 (10 µg/ml), or control mouse IgG $kappa$ chain (10 µg/ml); (C) M. avium-infected MDM cultured with recombinant CD40LT at 1 or 5 µg/ml or medium alone; (D) M. avium-infected MDM cultured with CD40LT in the presence and absence of MAb against CD40L (10 µg/ml), CD40 (10 µg/ml), or control mouse IgG $kappa$ chain (10 µg/ml). Results shown are representative of three experiments.

These data were further validated in assays using CD40LT. Intracellular growth of M. avium in MDM was assessed on days 1,3, and 7 after infection in the presence and absence of CD40LT(Fig. 1C). On day 7, CD40LT at 1 and 5 µg/ml was found to inhibitintracellular growth of M. avium by 61.2% ± 9.6% (P < 0.001) and65.0% ± 10.3% (P < 0.001), respectively, compared to growth ofM. avium in MDM treated with medium alone. This inhibitory effectof CD40LT on the intracellular growth of M. avium was blockedby 49% ± 8% (P < 0.05) in the presence of MAb against CD40L and82% ± 18% (P < 0.02) in the presence of MAb against CD40 (Fig.1D). These findings clearly demonstrate that ligation of CD40Lwith CD40 inhibits intracellular growth of M. avium in infectedMDM.

IFN- $gamma$ , an important T-cell product, is known to be a stimulant of antimycobacterial activity in macrophages (3). Further,IFN- $gamma$ is known to increase CD40 expression on MDM (1). We thereforedetermined whether priming of MDM with IFN- $gamma$ further enhancesthe inhibitory effect of CD40L. MDM were incubated with IFN- $gamma$ for 3 days prior to infection with M. avium and then exposed toCD40L-293 cells or CD40LT. Priming MDM with IFN- $gamma$ did not appearto modify the inhibitory effect of CD40L-293 cells or CD40LT onM. avium growth within these cells (data notshown).

CD40L-293 cells, but not CD40LT, enhance IL-12 production by M. avium-infected MDM. CD40-CD40L interaction is known to stimulate the production of IL-12 by macrophages (40). To determine whether IL-12 isresponsible for the antimycobacterial effect of CD40L, culturesupernatants of M. avium-infected MDM were assayed for IL-12 inthe presence and absence of CD40L-293 cells or CD40LT. MDM wereinfected with M. avium and cultured with CD40L-293 cells or CD40LT.Cells incubated with pcDNA-293 cells and medium alone served ascontrols. On days 1, 3, and 7 after infection, IL-12 (p70) inthe culture supernatant was measured by ELISA (Fig. 2).

View larger version (47K):
[in this window]
[in a new window]

FIG. 2. IL-12 (p70) production by M. avium-infected MDM cocultured with CD40L-293 cells. M. avium-infected MDM and uninfected MDM were cultured with medium alone, pcDNA-293 cells, or CD40L-293 cells. On days 1, 3, and 7 after infection, culture supernatants were collected and assayed for IL-12 (p70) by ELISA. Experiments were done in triplicate, and results are expressed as mean ± SD. *, P < 0.03 compared to M. avium-infected MDM cultured with pcDNA-293 cells.

CD40L-293 cells were found to significantly enhance production of IL-12 by M. avium-infected MDM on days 1, 3, and 7 postinfection(P < 0.03) compared to MDM treated with medium only or pcDNA-293cells. However, CD40L-293 cells did not affect IL-12 productionby uninfected MDM (data not shown). These results indicate thatCD40-CD40L ligation enhances IL-12 production by M. avium-infectedMDM but not by uninfected MDM. In contrast, CD40LT did not enhancethe production of IL-12 by infected or uninfected MDM. Pretreatmentof MDM with IFN- $gamma$ did not alter the IL-12 response of MDM (datanotshown).

In vivo effect of CD40L against M. avium infection in mice. (i) Assessment of bacterial load. To study the role of CD40-CD40L interaction in vivo, growth of M. avium in the livers, spleens, and lungs of mice that receivedMAbs against CD40L was analyzed and compared with that of micewhich received control hamster IgG. Mice were infected with M.avium and treated with 250 µg of MR1 or control hamster IgG intraperitoneallyfor 35 days as described previously by Wiley and Harmsen for miceinfected with P. carinii (47). Based on their studies, administrationof MAbs at this concentration was found to be sufficient to inhibitresolution of P. carinii infection in mice by blocking CD40-CD40Lligation.

The spleens, livers, and lungs were collected from M. avium-infected mice at 5 weeks, homogenized, and used to determine thenumber of CFU as described in Materials and Methods. The numberof viable bacteria recovered from the livers, lungs, and spleensof mice treated with MR1 was 0.8 to 1.0 log higher than that recoveredfrom mice treated with the control antibody (P < 0.01) (Fig. 3).Measurement of the immune response (serum IgG and IgM levels)of these mice to hamster IgG indicated that mice receiving MR1had significantly lower serum IgG and IgM levels compared to micethat received control hamster IgG (data not shown). These resultsindicate that the MAb MR1 administered to the mice in our studywas sufficient to block CD40L function in vivo and that the inhibitionof M. avium growth observed in the spleens, livers, and lungsof mice was indeed due to blockade of CD40L by this antibody.

View larger version (19K):
[in this window]
[in a new window]

FIG. 3. M. avium growth in mice treated with anti-CD40L MAb. Mice were infected with 10⁶ M. avium and treated with MR1 (anti-CD40L MAb) or control IgG. M. avium growth in the spleen, liver, and lungs was determined by the CFU assay on day 35. Results shown are mean of CFU per organ ± SD. *, P < 0.01 compared to CFU in the organs of M. avium-infected mice treated with control hamster IgG.

(ii) Histological examination. Tissue sections from the spleens of M. avium-infected mice treated with MR1 and control IgG were fixed and stained with Ziehl-Neelsenreagent (Fig. 4). The number of acid-fast bacilli observed insections of the spleen from MR1-treated mice was higher than thatobserved in the sections from mice treated with control IgG (Fig.4). These findings correlate with the CFU data described earlier.

View larger version (103K):
[in this window]
[in a new window]

FIG. 4. Mycobacterial burden in tissue from M. avium-infected mice treated with anti-CD40L MAb. Mice were infected with M. avium and treated with anti-CD40L MAb or control IgG. Mice from both groups were sacrificed on day 35. The spleen was collected from each mouse, sectioned (5 µm), and stained with Ziehl-Neelsen acid-fast stain to visualize mycobacteria. The sections were viewed at a magnification of ×630. Shown are spleen sections from M. avium-infected mice treated with control IgG (A) and anti-CD40L MAb (B). Arrowheads indicate acid-fast bacilli.

Tissue sections of the spleen and liver from M. avium-infected mice treated with MR1 as well as normal IgG were stained withhematoxylin-eosin and compared with tissue sections prepared fromuninfected mice of comparable age (Fig. 5). The white pulp ofthe spleen appeared to be disrupted in M. avium-infected mice(Fig. 5B and C) but not in the uninfected mice (Fig. 5A). However,there were no significant pathological differences between MR1-treatedmice (Fig. 5C) and control IgG-treated M. avium-infected mice(Fig. 5B). The livers from uninfected mice did not show any granulomas(Fig. 5D), in contrast to livers from M. avium-infected mice (Fig.5E and F). The sizes and numbers of granulomas in the liver fromMR1-treated and control IgG-treated mice were similar (Fig. 5Eand F). Although there do not appear to be significant pathologicaldifferences between the two groups of mice, blockade of CD40-CD40Linteraction in M. avium-infected mice with MAb abrogates the controland restriction of this organism in vivo. The size and numberof granulomas in the liver do not appear to reflect bacterialload in this organ.

View larger version (121K):
[in this window]
[in a new window]

FIG. 5. Histopathology of tissue sections from liver and spleen of M. avium-infected mice. Mice were infected with M. avium and treated with anti-CD40L MAb or control IgG. Mice from both groups were sacrificed on day 35. The spleen and liver was collected from each mouse, sectioned (5 µm), and stained with hematoxylin-eosin. The sections were viewed at a magnification of ×100. (A) Spleen from uninfected mouse showing intact white pulp; (B) spleen from M. avium-infected mouse treated with control IgG showing the disrupted white pulp; (C) spleen from M. avium-infected mouse treated with anti-CD40L MAb also showing disrupted white pulp; (D) liver from uninfected mouse; (E) liver from control IgG-treated M. avium-infected mouse showing granulomas; (F) liver from anti-CD40L treated M. avium-infected mouse showing granulomas.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

CD40-CD40L interactions are known to mediate host immune responses and T-cell-mediated effector functions (24). Bindingof CD40L to CD40 on MDM is critical in the interaction of antigenpresenting cells with T cells and during infections due to intracellularpathogens such as Leishmania and P. carinii (24). In this study,we have shown that CD40-CD40L interactions also play an importantrole in host immune response against M. avium infection. Ligationby CD40L of CD40 on the surface of M. avium-infected macrophagesreduced intracellular growth of this organism in vitro. Thesestudies used two different forms of human CD40L, CD40L-expressingcells and recombinant soluble human CD40L. Both forms of CD40Lwere found to inhibit M. avium growth in MDM. To confirm thatthe inhibitory effect of CD40L-293 cells was indeed due to CD40Land not merely the transfected cells themselves, we used MAb specificfor CD40L or CD40 to block ligation of CD40 with CD40L. The antimycobacterialeffects of CD40L-expressing cells was significantly reduced, suggestingthat this effect was partially due to CD40L on the surface ofthe cells. It is likely that the inhibition observed in the caseof the control cells transfected with the empty vector is dueto the rapid growth of these cells in culture or due to the secretionof other cytokines by the cells. To further substantiate thisfinding, we performed studies using CD40LT, the soluble form ofCD40L. CD40LT was found to significantly inhibit intracellulargrowth of M. avium compared to control cells treated with mediumalone.

The in vitro experiments with CD40L (either on the membrane of 293 cells or as a soluble trimeric protein) suggest that thismolecule acts directly on cultured human macrophages by inducingthem to restrict the growth of M. avium in vitro. The mechanismof this effect is not yet clear and will require further study.For example, nitric oxide can be induced in murine macrophagesby CD40L (27). Ligation of CD40L on T cells to CD40 on macrophageshas been shown to induce nitric oxide production (45), and nitricoxide generation by macrophages is known to be a major pathwayby which CD40L mediates immunity against L. amazonensis (42).Yet, it has been reported that nitric oxide has no antimycobacterialeffects against M. avium either in murine macrophages in vitroor in mice in vivo (16).

Ligation of CD40L with CD40 has been reported to induce IL-12 production by IFN- $gamma$ -primed murine peritoneal macrophages (28,40). IL-12 is a multifunctional cytokine which is produced mainlyby macrophages and monocytes, which in turn stimulate productionof IFN- $gamma$ , GM-CSF, and TNF- $alpha$ by T cells. All of these cytokinesare known to stimulate macrophages to restrict intracellular growthof M. avium (3, 15). IFN- $gamma$ has been shown to be criticalfor the control of mycobacterial infections. Mice with deletionsof the IFN- $gamma$ gene or mice treated with anti-IFN- $gamma$ antibody arehighly susceptible to infection by M. avium (2, 16, 21),and humans with genetic defects of the IFN- $gamma$ receptor are vulnerableto infection by M. avium (34). Consequently, it is understandablethat mice with deletions of the IL-12 gene or treated with anti-IL-12antibody are also susceptible to infection by M. avium (12).IL-12 alone, however, is not sufficient to induce cultured humanmacrophages to control M. avium (8). TNF- $alpha$ is another cytokinewhich is important in controlling M. avium replication in vitroin macrophages (15) and in vivo in mice (16). CD40L also inducesTNF production by both mouse (43) and human (1, 29) monocytesand macrophages. Further studies are needed to elucidate the possibleinvolvement of TNF- $alpha$ in the antimycobacterial activity inducedin macrophages byCD40L.

IL-12 production is known to be essential for effective clearance of M. avium (12, 30). We analyzed IL-12 production byM. avium-infected MDM in the presence of CD40L-expressing cellsand CD40LT. Interestingly, the antimycobacterial effects of CD40L-expressingcells were accompanied with enhancement of IL-12 production byM. avium-infected MDM. On the contrary, CD40LT, which is the solubleform of CD40L, failed to enhance IL-12 production by M. avium-infectedMDM in conjunction with inhibition of intracellular M. avium growth.Previous studies by Fanslow et al. (18) have shown that thebiological function of membrane-associated CD40L is differentfrom that of soluble CD40L. This may account for the lack of stimulationof IL-12 production by M. avium-infected MDM treated with solubleCD40L in our study. Although we do not have direct evidence, itappears that IL-12 may be partly involved in the antimycobacterialactivity of CD40L in vivo. In the case of L. major (10), cell-mediatedimmunity has been shown to be due to production of IL-12 by infectedmacrophages. In this study, which used CD40L-knockout (KO) mice,it was also shown that T cells from these mice are unable to induceIL-12 production bymacrophages.

Our studies using direct contact between M. avium-infected human macrophages and CD40L-expressing 293 cells model the cell-cellcontact pathway of macrophage activation by activated T cells.Direct contact with activated T cells has been shown to be importantfor the control of mycobacterial infection in macrophages fromboth mice (44) and humans (41). CD40L on the membranes ofactivated T cells is the major factor in the cell-cell contactpathway of macrophage activation in a variety of systems (43).Consequently, it is plausible that some of the reversal of antimycobacterialimmunity that we found after administering anti-CD40L antibodyto M. avium-infected mice results from blocking CD40L-macrophageinteractions.

In vivo, however, the administration of anti-CD40L antibody could affect other parts of the immune system. Blockade of CD40-CD40Linteraction by anti-CD40L MAbs is known to suppress humoral immunityagainst TD antigen (46) and in turn against pathogens such asP. carinii, where host response is predominantly mediated by humoralimmune responses (47). Humoral immunity against mycobacteriawas reevaluated by Glatman-Freedman and coworkers, who demonstratedthat antibody responses do play a role in modulating the courseof mycobacterial infection (23). Low levels of antibody productionagainst M. avium in M. avium-infected mice injected with MAbsagainst CD40L may have some role to play in elevated bacterialburden in thesemice.

In in vivo experiments described in the present study, M. avium-infected mice treated with anti-murine CD40L were found tohave higher number of organisms in the spleen, liver, and lungscompared to control M. avium-infected mice which received a controlantibody. Our results suggest that development of granulomas duringmycobacterial infection, which is the result of a series of complexinflammatory events, is independent of mycobacterial burden. Althoughthe bacterial burden in organs harvested from M. avium-infectedmice which received anti-CD40L MAbs was significantly higher thanthat in organs from mice treated with control IgG, there wereno significant differences in the histopathological response betweenthe two groups. There were no significant differences in the weightsof the livers and spleens collected from the two groups of mice.Further, the size and number of granulomas in the liver were similarin the twogroups.

While the CD40-CD40L pathway has been reported to be critical in elimination of infection due to pathogens such as Leishmaniaand P. carinii (10, 42, 47), Campos-Neto et al. (11) reportedthat resistance to Mycobacterium tuberculosis infection is achievedindependently of CD40L. Their studies were carried out with CD40L-KOmice. In addition, the number of organisms injected were lowerthan that used in our study. However, they report that when micewere infected with 10⁶ organisms as in the case of our study, and followed for longerperiods of time, there was a significant difference between CD40L-KOand control mice with respect to the bacterial burden in the spleenand liver. This disparity between their findings and ours maybe due to differences in the strain of mice used (C57BL/6 versusCD40L-KO) and size of the inoculum. CD40L-KO mice are known tohave slight increases in the percentage of CD4⁺ T cells and slight decreases in the percentage of double-positivethymocytes compared to the wild-type mice. Although mice usedin our study as well as the CD40L-KO mice have similar humoraland cellular immune responses against TD and TI antigens (38,48), it is possible that host immune responses to M. tuberculosisand M. avium are quite different. For example, in humans, M. aviuminfection is commonly seen in HIV-infected individuals with meanCD4⁺ T-cell counts of less than 50 cells/µl (26), while M. tuberculosisinfection occurs in all stages of HIV infection (6).

In summary, we have shown that ligation of CD40-CD40L plays a role in intracellular growth of M. avium in vitro, and treatmentof mice with anti-CD40L MAb increased M. avium growth in the lungs,livers, and spleens of mice. We propose that interaction of CD40with CD40L is an important pathway involved in the restrictionof M. avium growth in mice. These results are highly consistentwith the observation that interaction of T cells with M. avium-infectedmacrophages is required for resistance to M. avium infection inHIV-infected individuals. These findings suggest that administrationof CD40L may serve as an alternate therapeutic means to inhibitM. avium infection in individuals who have low T-cell counts.Further studies to establish the mechanism of CD40L-mediated signalingleading to the restriction of M. avium infection arerequired.

	ACKNOWLEDGMENTS

This research was supported by funds from the Universitywide AIDS Research Program, University of California, grant R97-SD-057to A. Catanzaro, and NIH grants AI35258 and HL57911 to RichardS.Kornbluth.

We thank Immunex Corp for providing recombinant soluble human trimeric CD40L and E. K. Thomas and W. C. Fanslow (Immunex Corp.)for valuable suggestions during the course of the study and manuscriptpreparation. We also thank J. Yi and N. Varki for assistance withthe histologystudies.

	FOOTNOTES

^* Corresponding author. Mailing address: University of California San Diego Medical Center, 200 W. Arbor Dr., San Diego, CA92103-8374. Phone (619) 543-5550. Fax: (619) 543-3276. E-mail:acatanzaro{at}ucsd.edu.

Editor: S. H. E. Kaufmann

	REFERENCES

Top Abstract Introduction Materials and Methods Results Discussion References

1.	Alderson, M. R., R. J. Armitage, T. W. Tough, L. Strockbine, W. C. Fanslow, and M. K. Spriggs. 1993. CD40 expression by human monocytes: regulation by cytokines and activation of monocytes by the ligand for CD40. J. Exp. Med. 178:669-674[Abstract/Free Full Text].
2.	Appelberg, R. 1994. Protective role of interferon gamma, tumor necrosis factor alpha and interleukin-6 in Mycobacterium tuberculosis and M. avium infections. Immunobiology 191:520-525[Medline].
3.	Appelberg, R., A. G. Castro, J. Pedrosa, R. A. Silva, I. M. Orme, and P. Minóprio. 1994. Role of gamma interferon and tumor necrosis factor alpha during T-cell-independent and -dependent phases of Mycobacterium avium infection. Infect. Immun. 62:3962-3971[Abstract/Free Full Text].
4.	Armant, M., R. Armitage, N. Boiani, G. Delespesse, and M. Sarfati. 1996. Functional CD40 ligand expression on T lymphocytes in the absence of T cell receptor engagement: involvement in interleukin-2-induced interleukin-12 and interfering production. Eur. J. Immunol. 26:1430-1434[Medline].
5.	Armitage, R. J., C. R. Maliszewski, M. R. Alderson, K. H. Grabstein, M. K. Spriggs, and W. C. Fanslow. 1993. CD40L: a multi-functional ligand. Semin. Immunol. 5:401-412[Medline].
6.	Barnes, P. T., A. B. Bloch, P. T. Davidson, and D. E. Snider, Jr. 1991. Tuberculosis in patients with human immunodeficiency virus infection. N. Engl. J. Med. 324:1644-1650[Medline].
7.	Bermudez, L. E., L. S. Young, and H. Enkel. 1991. Interaction of Mycobacterium avium complex with human macrophages: roles of membrane receptors and serum proteins. Infect. Immun. 59:1697-1702[Abstract/Free Full Text].
8.	Bermudez, L. E., M. Wu, and L. S. Young. 1995. Interleukin-12-stimulated natural killer cells can activate human macrophages to inhibit growth of Mycobacterium avium. Infect. Immun. 63:4099-4104[Abstract].
9.	Callard, R. E., R. J. Armitage, W. C. Fanslow, and M. K. Spriggs. 1993. CD40 ligand and its role in X-linked hyper-IgM syndrome. Immunol. Today 14:559-564[Medline].
10.	Campbell, K. A., P. J. Ovendale, M. K. Kennedy, W. C. Fanslow, S. G. Reed, and C. R. Maliszewski. 1996. CD40 Ligand is required for protective cell-mediated immunity to Leishmania major. Immunity 4:283-289[Medline].
11.	Campos-Neto, A., P. Ovendale, T. Bement, T. A. Koppi, W. C. Fanslow, M. A. Rossi, and M. R. Alderson. 1998. CD40 ligand is not essential for the development of cell-mediated immunity and resistance to Mycobacterium tuberculosis. J. Immunol. 160:2037-2041[Abstract/Free Full Text].
12.	Castro, A. G., R. A. Silva, and R. Appelberg. 1995. Endogenously produced IL-12 is required for the induction of protective T cells during Mycobacterium avium infections in mice. J. Immunol. 155:2013-2019[Abstract].
13.	Cohn, M., and B. Blomburg. 1975. The self-nonself discrimination: a one- or two signal mechanism? Scand. J. Immunol. 4:1-24[Medline].
14.	Cosyns, M., S. Tsirkin, M. Jones, R. Flavell, H. Kikutani, and A. R. Hayward. 1998. Requirement for CD40-CD40 ligand interaction for elimination of Cryptosporidium parvum from mice. Infect. Immun. 66:603-607[Abstract/Free Full Text].
15.	Denis, M. 1991. Tumor necrosis factor and granulocyte macrophage-colony stimulating factor stimulate human macrophages to restrict growth of virulent Mycobacterium avium and to kill avirulent M. avium: killing effector mechanism depends on generation of reactive nitrogen intermediates. J. Leukoc. Biol. 49:380-387[Abstract].
16.	Doherty, T. M., and A. Sher. 1997. Defects in cell-mediated immunity affect chronic, but not innate, resistance of mice to Mycobacterium avium infection. J. Immunol. 158:4822-4831[Abstract].
17.	Edwards, D., and C. H. Kirkpatrick. 1986. The immunology of mycobacterial diseases. Am. Rev. Respir. Dis. 134:1062-1071[Medline].
18.	Fanslow, W. C., S. Srinivasan, R. Paxton, M. G. Gibson, M. K. Spriggs, and R. J. Armitage. 1994. Structural characteristics of CD40 ligand that determine biological function. Semin. Immunol. 6:267-278[Medline].
19.	Fattorini, L., Y. Xiao, B. Li, C. Santoro, F. Ippoliti, and G. Orefici. 1994. Induction of IL-1 $beta$ , IL-6, TNF- $alpha$ , GM-CSF, and G-CSF in human macrophages by smooth transparent and smooth opaque colonial variants of Mycobacterium avium. J. Med. Microbiol. 40:129-133[Abstract].
20.	Flesch, I. E., J. H. Hess, S. Huang, M. Aguet, J. Rothe, H. Bluethmann, and S. H. Kaufmann. 1995. Early interleukin 12 production by macrophages in response to mycobacterial infection depends on interferon $gamma$ and tumor necrosis factor $alpha$ . J. Exp. Med. 181:1615-1621[Abstract/Free Full Text].
21.	Florido, M., R. Appelberg, I. M. Orme, and A. M. Cooper. 1997. Evidence for a reduced chemokine response in the lungs of beige mice infected with Mycobacterium avium. Immunology 90:600-606[Medline].
22.	Foy, T. M., D. M. Shepherd, F. H. Durie, A. Aruffo, J. A. Ledbetter, and R. J. Noelle. 1993. In vivo CD40-gp39 interactions are essential for thymus-dependent humoral immunity. II. Prolonged suppression of the humoral immune response by an antibody to the ligand for CD40, gp39. J. Exp. Med. 178:1567-1575[Abstract/Free Full Text].
23.	Glatman-Freedman, A., and A. Casadevall. 1998. Serum therapy for tuberculosis revisited: reappraisal of the role of antibody-mediated immunity against Mycobacterium tuberculosis. Clin. Microbiol. Rev. 11:514-532[Abstract/Free Full Text].
24.	Grewal, I. S., and R. A. Flavell. 1997. The CD40 ligand. At the center of the immune universe? Immunol. Res. 16:59-70[Medline].
25.	Hayashi, T., A. Catanzaro, and S. P. Rao. 1997. Apoptosis of human monocytes and macrophages by Mycobacterium avium sonicate. Infect. Immun. 65:5262-5271[Abstract].
26.	Horsburgh, C. R., Jr. 1991. Mycobacterium avium complex in the acquired immunodeficiency syndrome (AIDS). N. Engl. J. Med. 324:1332-1338[Medline].
27.	Kamanaka, M., P. Yu, T. Yasui, K. Yoshida, T. Kawabe, T. Horii, T. Kishimoto, and H. Kikutani. 1996. Protective role of CD40 in Leishmania major infection at two distinct phases of cell-mediated immunity. Immunity 4:275-281[Medline].
28.	Kennedy, M. K., K. S. Picha, W. C. Fanslow, K. H. Grabstein, M. R. Alderson, K. N. Clifford, W. A. Chin, and K. M. Mohler. 1996. CD40/CD40 ligand interactions are required for T cell-dependent production of interleukin-12 by mouse macrophages. Eur. J. Immunol. 26:370-378[Medline].
29.	Kiener, P. A., P. Moran-Davis, B. M. Rankin, A. F. Wahl, A. Aruffo, and D. Hollenbaugh. 1995. Stimulation of CD40 with purified soluble gp39 induces proinflammatory responses in human monocytes. J. Immunol. 155:4917-4925[Abstract].
30.	Kobayashi, K., T. Kasama, J. Yamazaki, M. Hosaka, T. Katsura, T. Mochizuki, K. Soejima, and R. M. Nakamura. 1995. Protection of mice from Mycobacterium avium infection by recombinant interleukin-12. Antimicrob. Agents Chemother. 39:1369-1371[Abstract].
31.	Kornbluth, R. S., K. Kee, and D. D. Richman. 1998. CD40 ligand (CD154) stimulation of macrophages to produce HIV-1-suppressive $beta$ -chemokines. Proc. Natl. Acad. Sci. USA 95:5205-5210[Abstract/Free Full Text].
32.	Meylan, P. R., D. D. Richman, and R. S. Kornbluth. 1990. Characterization and growth in human macrophages of Mycobacterium avium complex strains isolated from the blood of patients with acquired immunodeficiency syndrome. Infect. Immun. 58:2564-2568[Abstract/Free Full Text].
33.	Newman, G. W., H. X. Gan, P. L. McCarthy, Jr., and H. G. Remold. 1991. Survival of human macrophages infected with Mycobacterium avium intracellulare correlates with increased production of tumor necrosis factor- $alpha$ and IL-6. J. Immunol. 147:3942-3948[Abstract].
34.	Newport, M. J., C. M. Huxley, S. Huston, C. M. Hawrylowicz, B. A. Oostra, R. Williamson, and M. Levin. 1996. A mutation in the interferon-gamma-receptor gene and susceptibility to mycobacterial infection. N. Engl. J. Med. 335:1941-1949[Abstract/Free Full Text].
35.	Notarangelo, L. D., M. Duse, and A. G. Ugazio. 1992. Immunodeficiency with hyper-IgM (HIM). Immunodefic. Rev. 3:101-122[Medline].
36.	Ogata, K., B. A. Linzer, R. I. Zuberi, T. Ganz, R. I. Lehrer, and A. Catanzaro. 1992. Activity of defensins from human neutrophilic granulocytes against Mycobacterium avium-Mycobacterium intracellulare. Infect. Immun. 60:4720-4725[Abstract/Free Full Text].
37.	Rao, S. P., K. Ogata, and A. Catanzaro. 1993. Mycobacterium avium-M. intracellulare binds to the integrin receptor $alpha$ V $beta$ 3 on human monocytes and monocyte-derived macrophages. Infect. Immun. 61:663-670[Abstract/Free Full Text].
38.	Renshaw, B. R., W. C. Fanslow III, R. J. Armitage, K. A. Campbell, D. Liggitt, B. Wright, B. L. Davison, and C. R. Maliszewski. 1994. Humoral immune responses in CD40 ligand-deficient mice. J. Exp. Med. 180:1889-1900[Abstract/Free Full Text].
39.	Roecklein, J. A., R. P. Swartz, and H. Yeager, Jr. 1992. Nonopsonic uptake of Mycobacterium avium complex by human monocytes and alveolar macrophages. J. Lab. Clin. Med. 119:772-781[Medline].
40.	Shu, U., M. Kiniwa, C. Y. Wu, C. Maliszewski, N. Vezzio, J. Hakimi, M. Gately, and G. Delespesse. 1995. Activated T cells induce interleukin-12 production by monocytes via CD40-CD40 ligand interaction. Eur. J. Immunol. 25:1125-1128[Medline].
41.	Silver, R. F., Q. Li, W. H. Boom, and J. J. Ellner. 1998. Lymphocyte-dependent inhibition of growth of virulent Mycobacterium tuberculosis H37Rv within human monocytes: requirement for CD4+ T cells in purified protein derivative-positive, but not in purified protein derivative-negative subjects. J. Immunol. 160:2408-2417[Abstract/Free Full Text].
42.	Soong, L., J. Xu, I. S. Grewal, P. Kima, J. Sun, B. J. Longley, Jr., N. H. Ruddle, D. McMahon-Pratt, and R. A. Fravell. 1996. Disruption of CD40-CD40 ligand interactions results in an enhanced susceptibility to Leishmania amazonensis infection. Immunity 4:263-273[Medline].
43.	Stout, R. D., J. Suttles, J. Xu, I. S. Grewal, and R. A. Flavell. 1996. Impaired T cell-mediated macrophage activation in CD40 ligand-deficient mice. J. Immunol. 156:8-11[Abstract].
44.	Sypek, J. P., S. Jacobson, A. Vorys, and D. J. Wyler. 1993. Comparison of gamma interferon, tumor necrosis factor, and direct cell contact in activation of antimycobacterial defense in murine macrophages. Infect. Immun. 61:3901-3906[Abstract/Free Full Text].
45.	Tian, L., R. J. Noelle, and D. A. Lawrence. 1995. Activated T cells enhance nitric oxide production by murine splenic macrophages through gp39 and LFA-1. Eur. J. Immunol. 25:306-309[Medline].
46.	Van den Eertwegh, A. J. M., R. J. Noelle, M. Roy, D. M. Shepherd, A. Aruffo, J. A. Ledbetter, W. J. A. Boersma, and E. Claassen. 1993. In vivo CD40-gp39 interactions are essential for thymus-dependent humoral immunity. I. In vivo expression of CD40 ligand, cytokines, and antibody production delineates sites of cognate T-B cell interaction. J. Exp. Med. 178:1555-1565[Abstract/Free Full Text].
47.	Wiley, J. A., and A. G. Harmsen. 1995. CD40 ligand is required for resolution of Pneumocystis carinii pneumonia in mice. J. Immunol. 155:3525-3529[Abstract].
48.	Xu, J., T. M. Foy, J. D. Laman, E. A. Elliott, J. J. Dunn, T. J. Waldschmidt, J. Elsemore, R. J. Noelle, and R. A. Flavell. 1994. Mice deficient for the CD40 ligand. Immunity 1:423-431[Medline].

This article has been cited by other articles:

Miles, D. J. C., van der Sande, M., Crozier, S., Ojuola, O., Palmero, M. S., Sanneh, M., Touray, E. S., Rowland-Jones, S., Whittle, H., Ota, M., Marchant, A. (2008). Effects of Antenatal and Postnatal Environments on CD4 T-Cell Responses to Mycobacterium bovis BCG in Healthy Infants in The Gambia. CVI 15: 995-1002 [Abstract] [Full Text]
Filipe-Santos, O., Bustamante, J., Haverkamp, M. H., Vinolo, E., Ku, C.-L., Puel, A., Frucht, D. M., Christel, K., von Bernuth, H., Jouanguy, E., Feinberg, J., Durandy, A., Senechal, B., Chapgier, A., Vogt, G., de Beaucoudrey, L., Fieschi, C., Picard, C., Garfa, M., Chemli, J., Bejaoui, M., Tsolia, M. N., Kutukculer, N., Plebani, A., Notarangelo, L., Bodemer, C., Geissmann, F., Israel, A., Veron, M., Knackstedt, M., Barbouche, R., Abel, L., Magdorf, K., Gendrel, D., Agou, F., Holland, S. M., Casanova, J.-L. (2006). X-linked susceptibility to mycobacteria is caused by mutations in NEMO impairing CD40-dependent IL-12 production. J. Exp. Med. 203: 1745-1759 [Abstract] [Full Text]
Subauste, C. S., Wessendarp, M. (2006). CD40 Restrains In Vivo Growth of Toxoplasma gondii Independently of Gamma Interferon. Infect. Immun. 74: 1573-1579 [Abstract] [Full Text]
Andrade, R. M., Wessendarp, M., Portillo, J.-A. C., Yang, J.-Q., Gomez, F. J., Durbin, J. E., Bishop, G. A., Subauste, C. S. (2005). TNF Receptor-Associated Factor 6-Dependent CD40 Signaling Primes Macrophages to Acquire Antimicrobial Activity in Response to TNF-{alpha}. J. Immunol. 175: 6014-6021 [Abstract] [Full Text]
Andrade, R. M., Wessendarp, M., Subauste, C. S. (2003). CD154 Activates Macrophage Antimicrobial Activity in the Absence of IFN-{gamma} through a TNF-{alpha}-Dependent Mechanism. J. Immunol. 171: 6750-6756 [Abstract] [Full Text]
Majorov, K. B., Lyadova, I. V., Kondratieva, T. K., Eruslanov, E. B., Rubakova, E. I., Orlova, M. O., Mischenko, V. V., Apt, A. S. (2003). Different Innate Ability of I/St and A/Sn Mice To Combat Virulent Mycobacterium tuberculosis: Phenotypes Expressed in Lung and Extrapulmonary Macrophages. Infect. Immun. 71: 697-707 [Abstract] [Full Text]
Larkin, R., Benjamin, C. D., Hsu, Y.-M., Li, Q., Zukowski, L., Silver, R. F. (2002). CD40 Ligand (CD154) Does Not Contribute to Lymphocyte-Mediated Inhibition of Virulent Mycobacterium tuberculosis within Human Monocytes. Infect. Immun. 70: 4716-4720 [Abstract] [Full Text]
Hayashi, T., Rao, S. P., Takabayashi, K., Van Uden, J. H., Kornbluth, R. S., Baird, S. M., Taylor, M. W., Carson, D. A., Catanzaro, A., Raz, E. (2001). Enhancement of Innate Immunity against Mycobacterium avium Infection by Immunostimulatory DNA Is Mediated by Indoleamine 2,3-Dioxygenase. Infect. Immun. 69: 6156-6164 [Abstract] [Full Text]
Hogan, L. H., Markofski, W., Bock, A., Barger, B., Morrissey, J. D., Sandor, M. (2001). Mycobacterium bovis BCG-Induced Granuloma Formation Depends on Gamma Interferon and CD40 Ligand but Does Not Require CD28. Infect. Immun. 69: 2596-2603 [Abstract] [Full Text]
Kornbluth, R. S. (2000). The emerging role of CD40 ligand in HIV infection. J. Leukoc. Biol. 68: 373-382 [Abstract] [Full Text]
Samten, B., Thomas, E. K., Gong, J., Barnes, P. F. (2000). Depressed CD40 Ligand Expression Contributes to Reduced Gamma Interferon Production in Human Tuberculosis. Infect. Immun. 68: 3002-3006 [Abstract] [Full Text]
Hwang, Y.-i., Nahm, M. H., Briles, D. E., Thomas, D., Purkerson, J. M. (2000). Acquired, but Not Innate, Immune Responses to Streptococcus pneumoniae Are Compromised by Neutralization of CD40L. Infect. Immun. 68: 511-517 [Abstract] [Full Text]

This Article

	Abstract
	Full Text (PDF)
	Alert me when this article is cited
	Alert me if a correction is posted

Services

	Similar articles in this journal
	Similar articles in PubMed
	Alert me to new issues of the journal
	Download to citation manager
	Reprints and Permissions
	Copyright Information
	Books from ASM Press
	MicrobeWorld

Citing Articles

	Citing Articles via HighWire
	Citing Articles via Google Scholar

Google Scholar

	Articles by Hayashi, T.
	Articles by Catanzaro, A.
	Search for Related Content

PubMed

	PubMed Citation
	Articles by Hayashi, T.
	Articles by Catanzaro, A.

J. Bacteriol.	J. Virol.	Eukaryot. Cell

Microbiol. Mol. Biol. Rev.	Clin. Vaccine Immunol.	All ASM Journals