Production of Matrix Metalloproteinases in Response to Mycobacterial Infection

doi:10.1128/IAI.69.9.5661-5670.2001

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Infection and Immunity, September 2001, p. 5661-5670, Vol. 69, No. 9
0019-9567/01/$04.00+0 DOI: 10.1128/IAI.69.9.5661-5670.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.

Production of Matrix Metalloproteinases in Response to Mycobacterial Infection

Marianne Quiding-Järbrink,^* Debbie A. Smith, and Gregory J. Bancroft

Department of Infectious and Tropical Diseases, London School of Hygiene and Tropical Medicine, London WC1E 7HT, United Kingdom

Received 17 August 2000/Returned for modification 22 November 2000/Accepted 29 May 2001

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

Matrix metalloproteinases (MMPs) constitute a large family of enzymes with specificity for the various proteins of the extracellularmatrix which are implicated in tissue remodeling processes andchronic inflammatory conditions. To investigate the role of MMPsin immunity to mycobacterial infections, we incubated murine peritonealmacrophages with viable Mycobacterium bovis BCG or Mycobacteriumtuberculosis H37Rv and assayed MMP activity in the supernatantsby zymography. Resting macrophages secreted only small amountsof MMP-9 (gelatinase B), but secretion increased dramaticallyin a dose-dependent manner in response to either BCG or M. tuberculosisin vitro. Incubation with mycobacteria also induced increasedMMP-2 (gelatinase A) activity. Neutralization of tumor necrosisalpha (TNF- $alpha$ ), and to a lesser extent interleukin 18 (IL-18),substantially reduced MMP production in response to mycobacteria.Exogenous addition of TNF- $alpha$ or IL-18 induced macrophages to expressMMPs, even in the absence of bacteria. The immunoregulatory cytokinesgamma interferon (IFN- $gamma$ ), IL-4, and IL-10 all suppressed BCG-inducedMMP production, but through different mechanisms. IFN- $gamma$ treatmentincreased macrophage secretion of TNF- $alpha$ but still reduced theirMMP activity. Conversely, IL-4 and IL-10 seemed to act by reducingthe amount of TNF- $alpha$ available to the macrophages. Finally, infectionof BALB/c or severe combined immunodeficiency (SCID) mice witheither BCG or M. tuberculosis induced substantial increases inMMP-9 activity in infected tissues. In conclusion, we show thatmycobacterial infection induces MMP-9 activity both in vitro andin vivo and that this is regulated by TNF- $alpha$ , IL-18, and IFN- $gamma$ .These findings indicate a possible contribution of MMPs to tissueremodeling processes that occur in mycobacterialinfections.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

Infection with virulent mycobacterial species results in a granulomatous disease of the affected organs. Granuloma formationand activation of macrophages and T cells are crucial parts ofa protective cellular immune response (28, 31, 39). T-cellimmunity is mainly mediated by secretion of gamma interferon (IFN- $gamma$ ),which induces effective macrophage killing of ingested bacteria.Macrophages also secrete cytokines and chemokines important forcontaining the infection. Among these, tumor necrosis factor alpha(TNF- $alpha$ ) is important for granuloma formation and host resistance(8, 15, 45), but if it is produced in excess, or late inthe infection, the effects can be detrimental (3, 32, 49).Thus, the same effector mechanisms can result in both protectiveimmune responses and pathology, depending on their strength andkinetics (11). These pathological processes are often associatedwith tissue remodeling and breakdown of the extracellular matrix(ECM).

Matrix metalloproteinases (MMPs) constitute a large family of Zn²⁺- and Ca²⁺-dependent endopeptidases, implicated in tissue remodeling andchronic inflammation. They possess broad and overlapping specificitiesand collectively have the capacity to degrade all the componentsof the ECM (42, 52). MMPs are produced by many cell types,including lymphocytes and granulocytes, but in particular by activatedmacrophages (17). MMPs are secreted as proenzymes, which areactivated by proteolytic cleavage and regulated by a family ofinhibitors called the tissue inhibitors of matrix metalloproteinases(TIMPs), which are constitutively produced by a variety of cells.Changes in actual MMP activity are thus dependent on the balancebetween production and activation of MMPs and the local levelsof TIMPs. In rheumatoid arthritis, pulmonary emphysema, periodontaldisease, and inflammatory bowel disease, MMPs are believed tobe responsible for much of the associated tissue destruction (4,35, 43, 50). In addition to their direct effects on ECMproteins, MMPs can exacerbate inflammation by activating the proinflammatorycytokine interleukin-1 $beta$ (IL-1 $beta$ ) or releasing cytokines such asTNF- $alpha$ and IL-6 from cell surfaces (1, 21, 23). Their generationof chemotactic fragments from ECM proteins may also contributeto the recruitment of inflammatory cells (22, 40).

Little is known about MMP production during bacterial infections and the contribution they make to immunity versus pathology.Systemic Escherichia coli infection, acute Lyme neuroborreliosis,and pneumococcal meningitis can all lead to secretion of significantamounts of MMP-9 (25, 29, 34), and in the last infectionMMP-9 is suggested to contribute to destruction of the blood-brainbarrier and to neuronal injury. In cell culture, MMP productionis induced by bacterial products such as lipopolysaccharide (LPS),phospholipase C, and clamydial heat shock proteins (10, 14,26, 54). Several proinflammatory cytokines produced in responseto bacterial infections, including TNF- $alpha$ , IL-1, and granulocyte-macrophagecolony-stimulating factor (GM-CSF), have also been shown to up-regulatemonocyte and macrophage MMP production in vitro (38, 55).Significantly, a recent report has demonstrated increased levelsof MMP-9 in bronchoalveolar lavage fluids from tuberculosis patientsand that heat-killed Mycobacterium tuberculosis as well as mycobacterialcell wall components increase MMP-9 mRNA production by a myelomonocyticcell line (7).

In order to investigate the regulation of MMP expression by live mycobacteria in more detail, we have compared the effectsof Mycobacterium bovis BCG and M. tuberculosis on MMP expressionby purified macrophages in culture and also in the lungs, livers,and spleens of infected mice. We now show that mycobacteria induceextensive production of the gelatinases MMP-9 and MMP-2 both invivo and in vitro and that this process is regulated by both macrophage-and T-cell-derivedcytokines.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Animals. CB-17/ICR severe combined immunodeficiency (SCID) mice were bred under aseptic conditions and maintained in microisolatorcages at the London School of Hygiene and Tropical Medicine. BALB/cmice were purchased from Harlan (Oxon, United Kingdom). Femaleanimals between 8 and 15 weeks of age wereused.

Bacterial strains and infections. M. tuberculosis strain H37Rv was obtained from the American Type Culture Collection (ATCC 25618), and M. bovis BCG was obtainedfrom Statens Seruminstitut (Copenhagen, Denmark). Bacteria weregrown to mid-log phase, washed twice in phosphate-buffered saline,and kept frozen at $-$ 70°C, and a fresh aliquot was thawed for eachexperiment. Mice were infected with 10⁶ CFU of M. tuberculosis H37Rv or BCG in 200 µl of normal saline,via a lateral tail vein. The multiplicity of infection was calculatedfrom mycobacterial stocks which were stored at $-$ 70°C and regularlyconfirmed by plating the bacterial input at the time of experimentation.In the case of M. tuberculosis, the multiplicity of infectionwas confirmed by direct plating of the inoculum in each experiment.Sham-infected mice received saline only. For in vitro experiments,thawed aliquots of bacteria were kept at 4°C for up to 3 weekswithout loss ofactivity.

Stimulation of macrophage MMP expression in vitro. Peritoneal exudate cells were collected 3 to 4 days following intraperitoneal injection of 10% Proteose Peptone into naivemice by injection and retrieval of 10 ml of ice-cold RPMI mediumcontaining 1% fetal calf serum. Isolated cells were washed inmedium and plated at 2 × 10⁶ cells/well in 24-well tissue culture plates in RPMI containing2.5% fetal calf serum, 100 IU of penicillin per ml, 100 µg ofstreptomycin per ml, and 100 mM L-glutamine (Life Technologies,Paisley, United Kingdom). Two hours later, plates were washedextensively with room temperature RPMI to remove nonadherent cells,and the remaining adherent cells were subsequently cultured in0.5 ml of macrophage serum-free medium (MØ-SFM; Life Technologies)supplemented with penicillin and streptomycin as above. In theexperiments comparing BCG and M. tuberculosis, no antibioticswere used. Recombinant IL-12, IL-18 (both from Genzyme, Cambridge,Mass.), TNF- $alpha$ (Life Technologies), or thawed and gently resuspendedviable mycobacteria were added and incubated at 37°C for up to4 days. Input bacterial concentrations ranged between 0.001 and30 bacteria per macrophage. Culture medium was collected, centrifugedat 10,000 rpm for 10 min in an Eppendorf centrifuge, aliquoted,and stored at $-$ 20°C until analysis of MMP activity. In some experiments,neutralizing antibodies to TNF- $alpha$ (clone TN3, a kind gift fromR. D. Schreiber, Washington University School of Medicine, St.Louis, Mo.), IL-12 (clone C17.8, a kind gift from G. Trinchieri,Wistar Institute, Philadephia, Pa.) (53), IL-18 (MBL Co., Ltd.,Nagoya, Japan), GM-CSF (clone MPI.22E9.11, a kind gift from J.Abrams, DNAX, Palo Alto, Calif.), blocking antibodies to the IL-1 $beta$ receptor (Pharmingen, San Diego, Calif.), or 5 µg of indomethacin(Sigma, St. Louis, Mo.) per ml were added to the macrophage culturesimmediately prior to addition of bacteria or cytokines. In othercultures, recombinant IL-4 (Life Technologies), IL-10 (R&D, Abingdon,United Kingdom), or IFN- $gamma$ (Life Technologies) either were addedfor 20 h and then washed off before BCG stimulation or were addedat the same time as the BCG. Macrophage-conditioned medium wasgenerated by incubating naive peritoneal macrophages preparedas above with 10 BCG bacteria per macrophage. The supernatantwas removed after 18 h and sterile filtered through a 22-µm-pore-sizefilter. Conditioned medium was added to uninfected macrophagesfor 18 h and removed by washing the macrophages twice in freshmedium, and MMP activity was assessed in the supernatants aftera further 24 or 72 h ofincubation.

Specimen collection and extraction of MMP activity from tissues. Mice infected intravenously (i.v.) with BCG or M. tuberculosis H37Rv were killed at various time points after infection, andlungs, spleens, and livers were collected for analysis of histology,bacterial burden, and protein extraction. For determination ofpathology and granuloma formation in M. tuberculosis-infectedmice, approximately 200 mg from each organ was fixed in formalin,embedded in paraffin, and subsequently used for routine hematoxylinand eosin staining for morphology and Ziehl-Neelsen staining todetect mycobacteria. The bacterial burden in each tissue was assessedin organs homogenized by passage through 100-µm nylon membranesin water containing 0.05% Tween 80. Serial 10-fold dilutions ofthe homogenate in 7H10 medium were plated on Middlebrook 7H11agar plates supplemented with oleic acid, albumin, dextrose, andcatalase (all from Difco, Detroit, Mich.) and incubated for 3to 4 weeks at 37°C before the counting of CFU. The remaining homogenizedtissue was incubated for 2 h at 4°C, centrifuged at 10,000 rpmin an Eppendorf centrifuge, and sterile filtered. The proteinconcentration was determined using the BCA kit (Pierce, Rockford,Ill.), and the protein extract was frozen in aliquots at $-$ 20°Cuntil analysis of MMP activity. The organs of BCG-infected micewere prepared as above and used directly for CFU determinationand formalin fixation, and the remaining snap-frozen tissue waskept at $-$ 70°C until used for protein extraction in water-Tween80 asabove.

Detection of MMPs using zymography. The MMP activity in tissue extracts and supernatants was analyzed using substrate gel sodium dodecyl sulfate-polyacrylamidegel electrophoresis (SDS-PAGE) zymography (20). Tissue extractswere adjusted to the same protein concentration (see below) andmixed with an equal volume of nonreducing SDS-PAGE sample buffer(0.2 M Tris-HCl, 20% glycerol, 6% SDS, 0.05% bromophenol blue,pH 6.7), and 40 µl of this mixture was loaded per lane. Cell culturemedium was mixed with an equal volume of sample buffer, and 40µl was loaded per lane. In some assays, the supernatants wereconcentrated 20 times using Centricon tubes with a 10-kDa cutoff(Millipore Corporation, Bedford, Mass.) before analysis. The sampleswere separated in 7.5% polyacrylamide gels containing 1 mg ofgelatin (type B, 225 Bloom; Sigma) per ml or 0.5 mg of $alpha$ -casein(Sigma) per ml at 120 V (gelatin gels) or 60 V (casein gels).The gels were then incubated for 30 min on a rotating platformin Tris-buffered saline (10 mM Tris-HCl, 0.15 M NaCl, pH 7.6 [TBS])containing 2.5% Triton X-100. They were washed three times inTBS and then incubated for 20 h at 37°C in TBS containing 5 mMCaCl₂, 1% Triton X-100, and 0.02% NaN₃. Coomassie blue stainingrevealed the presence of gelatinolytic or caseinolytic activityas clear bands against the blue background. Recombinant murineMMP-9 or purified murine MMP-3 (both from Chemicon, Harrow, UnitedKingdom) were used as positive controls, and the sensitivity ofthe assays was >50 pg. Inclusion of 10 mM EDTA in assay bufferscompletely inhibited all MMP activity in the samples, and theidentity of MMP-9 in macrophage cultures stimulated with BCG wasfurther confirmed by Western blotting, using a polyclonal goatantibody reacting with murine MMP-9 (Santa Cruz Biotechnology,Santa Cruz, Calif.).

To estimate the amount of active MMPs in a certain sample, the intensity of the lytic bands was determined using Phoretix1d software. Data are presented as relative enzymatic activityobtained by dividing the optical density of the experimental samplewith that resulting from the activity of 2 ng of rMMP-9 separatedon the same gel. The procedure was validated by analyzing serialdilutions of rMMP-9 by zymography, which yielded a straight-linerelationship between MMP concentration and optical density forsamples containing between 0.5 and 8 ng of MMP-9 (relative enzymaticactivities between 0.25 and 3). The total amount of tissue-extractedprotein that was loaded onto the gel was adjusted to fall withinthis range, resulting in 3, 40, and 20 µg of total spleen, liver,and lung proteins, respectively, being loaded in individuallanes.

Cytokine detection. The concentration of TNF- $alpha$ in culture supernatants was determined by enzyme-linked immunosorbent assay (ELISA). Ninety-six-wellplates were coated with 5 µg of anti-murine TNF- $alpha$ monoclonal antibodyTN3 per ml. Captured TNF- $alpha$ was detected by stepwise addition ofa polyclonal rabbit serum raised against murine TNF- $alpha$ , horseradishperoxidase-labeled goat anti-rabbit antibodies (Kirkegaard & PerryLaboratories, Inc., Gaithersburg, Md.), 1 mg of 2,2'-azinobis(3-ethylbenzthiazolinesulfonicacid) (ABTS), and 0.04% H₂O₂ substrate. Standard curves were constructedusing recombinant mouse TNF- $alpha$ , and the sensitivity of the assaywas >1 ng/ml.

Statistical evaluation. Differences in enzymatic activity between groups of mice were evaluated using the two-tailed t test for independentsamples.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

Stimulation with BCG induces macrophage secretion of MMPs. To determine if mycobacteria can induce secretion of MMPs from macrophages, peritoneal macrophages were incubated with 10live M. bovis BCG bacteria per macrophage, and culture supernatantswere collected at various time points. Zymography analyses showeda low but consistent secretion of MMP-9 (gelatinase B) in mediafrom unstimulated cells cultured for 48 h. Stimulation with BCGincreased MMP-9 expression within 6 h, and it rose progressively,reaching a maximum after 48 h (Fig. 1A). The identity of MMP-9was further confirmed by Western blotting. In contrast, productionof MMP-2 (gelatinase A) was not detected until after 48 h of incubationwith BCG, and maximal MMP-2 activity was consistently less thanthat of MMP-9. Neither MMP-2 nor MMP-9 production was influencedby addition of the PGE₂ synthase inhibitor indomethacin (datanot shown).

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FIG. 1. M. bovis BCG induces gelatinase activity in macrophages. Macrophage monolayers were incubated with either medium alone or 10 BCG bacteria per macrophage for various times (A) or for 48 h with 0.01 to 30 BCG bacteria per macrophage (B). Cell culture supernatants were analyzed for gelatinase activity using zymography. Data presented are representative of four independent experiments.

Reproducible induction of MMP-9 activity was observed with 0.01 BCG bacterium per macrophage and increased in a dose-dependentmanner at least up to 30 BCG bacteria per macrophage (Fig. 1B).Our results indicate that upregulation of MMP activity by mycobacteriaoccurs equally well in response to live and dead bacteria. Thus,the presence (Fig. 1; see also Fig. 2, 3, and 5) or absence (seeFig. 7) of streptomycin in the culture media has no effect onthe magnitude of the response observed under these conditions.Production of other gelatinolytic enzymes, particularly MMP-3or MMP-7, was not observed under these conditions or in caseinzymograms, even after concentrating the culture supernatants 20times. Together these results demonstrate that BCG is a relativelyselective inducer of MMP-9, and to a lesser extent MMP-2, expressionby murine macrophages invitro.

The role of macrophage-derived cytokines in MMP induction by BCG. Under the culture conditions we used, BCG is readily phagocytosed (13), which induces the secretion of a range of macrophage-derivedcytokines. To compare the role of ingestion per se versus cytokinesecretion in MMP induction, macrophages were incubated with BCGand neutralizing antibodies to selected proinflammatory cytokinesknown to be produced after BCG ingestion (12, 13, 46, 51),and the resulting supernatants were assayed by zymography. Whenlow numbers of BCG bacteria were incubated with the macrophages(0.1 BCG bacterium per macrophage), neutralization of TNF- $alpha$ abolishedMMP-9 induction (Fig. 2), while antibodies to IL-18 partiallyreduced MMP-9 secretion. When higher bacterial burdens were used(10 BCG bacteria per macrophage), the effect of anti-TNF- $alpha$ antibodieswas still evident, whereas antibodies to IL-18 had no detectableeffect. In the latter setting, however, the combination of antibodiesto TNF- $alpha$ and IL-18 resulted in a further decrease in MMP activity,compared to the effect of anti-TNF- $alpha$ alone (data not shown). Incontrast, addition of antibodies to IL-12 or GM-CSF, or blockingof the IL-1 $beta$ R, did not affect the MMP response (Fig. 2).

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FIG. 2. Neutralization of TNF- $alpha$ or IL-18 inhibits M. bovis BCG-induced MMP secretion by macrophages. Macrophage monolayers were incubated with either medium alone (MØ) or with 0.1 BCG bacterium per macrophage (MØ BCG) in the absence or presence of neutralizing antibodies to TNF- $alpha$ , IL-18, IL-12, GM-CSF, or the IL-1 $beta$ receptor CD121a (MØ BCG Ab), or relevant isotype control antibodies (MØ BCG control). Cell culture supernatants were harvested after 72 h and analyzed for gelatinase activity using zymography. Data presented are representative of two to four independent experiments.

In order to determine if cytokines alone could induce MMP secretion to the same extent as BCG, macrophages were cultured withpurified recombinant TNF- $alpha$ or IL-18 in the absence of mycobacteria.TNF- $alpha$ induced a dose-dependent production of MMP-9, with concentrationsas low as 1 ng/ml resulting in increased levels of MMP-9 after24 h of stimulation (Fig. 3A). In contrast, 10 ng of TNF- $alpha$ perml was needed to induce MMP-2, which was not detected until after72 h of stimulation (Fig. 3B). When macrophages were culturedwith IL-18, only $>=$ 30 ng of IL-18 per ml induced increased productionof MMP-9, but not until 72 h after stimulation (Fig. 3C). Additionof TNF- $alpha$ plus IL-18 did not induce any further MMP productionthan that observed with either cytokine alone (data not shown).We have no evidence to suggest that the MMP activity induced byIL-18 results from increased TNF- $alpha$ secretion, since this cytokinecould not be detected in supernatants from IL-18-stimulated macrophages,and neutralization of TNF- $alpha$ in these cultures did not inhibitthe IL-18-induced MMP production. Furthermore, the ability ofsecreted products from BCG-stimulated macrophages to influenceMMP production was tested using conditioned media from BCG-stimulatedmacrophages, which induced a slightly increased MMP-9 activity,but not to the same extent as did infection with BCG (data notshown). Together, these results indicate that TNF- $alpha$ and IL-18produced by macrophages in response to mycobacterial infectioninduce MMP activity in an autocrine fashion.

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FIG. 3. Recombinant TNF- $alpha$ and IL-18 induce macrophage MMP activity. Macrophage monolayers were incubated in medium alone or with increasing concentrations of recombinant murine TNF- $alpha$ for 24 h (A) or 72 h (B) or with recombinant murine IL-18 for 72 h (C). Cell culture supernatants were analyzed for gelatinase activity using zymography. No MMP activity could be detected in IL-18-stimulated cultures by 24 h. Data presented are representative of three to five independent experiments.

Effects of immunoregulatory cytokines on macrophage MMP production. In granulomas, macrophages are subjected to the effects of several immunomodulatory cytokines, some of the more prominentbeing the activating cytokine IFN- $gamma$ and the inhibitory cytokinesIL-10 and IL-4 (19, 33). To examine if BCG-induced MMP productioncould be further modulated by these cytokines, macrophages werepreincubated with any one of these cytokines and then stimulatedwith BCG as described above. In parallel experiments, the cytokineswere added at the same time as BCG, and all cell cultures wereanalyzed by zymography. Addition of IFN- $gamma$ inhibited MMP-9 productioneither when the macrophages were pretreated for 20 h before additionof BCG or when IFN- $gamma$ was added at the same time (Fig. 4). Paradoxically,IFN- $gamma$ treatment resulted in reduced MMP production despite increasinglevels of TNF- $alpha$ in the cultures compared to the MMP productionof those with BCG alone (Fig. 4).

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FIG. 4. IFN- $gamma$ regulates macrophage production of MMP-9. Macrophage monolayers were incubated with medium alone or with 1 to 100 IU of IFN- $gamma$ per ml either for 20 h prior (pretreated) or at the time of addition of 10 M. bovis BCG bacteria per macrophage (IFN- $gamma$ in culture). Cell culture supernatants were harvested 48 h later, assayed for gelatinase activity using zymography, and analyzed for TNF- $alpha$ content in ELISA. Variation between duplicates in ELISA was consistently <5%. Data presented are representative of three independent experiments, with the TNF- $alpha$ concentrations from the same cultures given above each zymogram lane.

We also examined the effect of IL-10, a cytokine with inhibitory effects on macrophage effector function, on BCG-induced MMP-9activity. Minimal effect was seen on MMP activity when macrophageswere pretreated with different concentrations of IL-10 and thenstimulated with BCG (Fig. 5). On the other hand, addition of IL-10at the same time as BCG resulted in a clear reduction in the amountof MMP-9 secreted by the macrophages. In contrast to what wasobserved with IFN- $gamma$ , the inhibitory effect of IL-10 on MMP-9 expressioncorrelated with reduced TNF- $alpha$ levels (Fig. 5) and could be overcomeby addition of exogenous TNF- $alpha$ to the cultures (data not shown).Treatment with IL-4 resulted in a modest reduction of MMP-9 activityin both assay protocols. As with IL-10, the reduction in MMP-9activity correlated with reduced levels of TNF- $alpha$ in the culturesupernatants (data not shown).

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FIG. 5. IL-10 regulates macrophage production of MMP-9. Macrophage monolayers were incubated with medium alone or with 1 to 100 IU of IL-10 per ml either for 20 h prior to (pretreated) or at the time of addition of 10 M. bovis BCG bacteria per macrophage (IL-10 in culture). Cell culture supernatants were harvested 48 h later, assayed for gelatinase activity using zymography, and analyzed for TNF- $alpha$ content in ELISA. Variation between duplicates in ELISA was consistently <5%. Data presented are representative of three independent experiments, with the TNF- $alpha$ concentrations from the same cultures given above each zymogram lane.

In vivo production of MMPs during BCG infection. To determine if increased MMP activity was also a feature of mycobacterial infections in vivo, MMP levels were assayed intissue homogenates prepared from spleens, livers, and lungs ofBALB/c mice during the course of infection with BCG. The baselineMMP activity in uninfected or saline-treated mice differed betweenthe organs but was consistent between animals. The spleen hadthe highest baseline MMP-9 activity (relative enzyme activity,0.85 ± 0.17 [mean ± standard deviation] in 20 µg of total proteins),whereas the lung activity was lower (0.38 ± 0.11 in 20 µg) andthe liver activity was almost undetectable in naive animals (0.13± 0.03 in 40 µg). The MMP-9 activity in extracts from spleensincreased over the first 4 weeks after infection compared to thatof uninfected controls, and then it remained elevated (Fig. 6).MMP-9 activity in the lungs and livers of BCG-infected mice wasalso increased compared to that of controls, particularly at day78 postinfection (data not shown). A low, constitutive MMP-2 activitywas observed in all uninfected tissues tested and did not increaseover the time course of the experiment. No MMP-3 or MMP-7 activitycould be detected in spleens, livers, or lungs collected 5, 29,and 78 days after infection.

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FIG. 6. Infection with M. bovis BCG increased spleen MMP-9 activity in vivo. Sham-infected BALB/c mice (white bars) and mice infected i.v. with 10⁶ BCG bacteria (black bars) were killed at various time points after infection. Tissue homogenates from spleens were analyzed by gelatin zymography. Data are presented as the relative enzymatic activity in pooled samples consisting of 1 µg of total protein per animal from spleen homogenates from three mice per group. When representative samples were assayed from individual mice, the standard deviations of relative MMP activity ranged from 5 to 19% of the means.

The course of infection followed a classical pattern for BCG in immunocompetent mice. The bacterial load rose from 5.4 × 10⁵ ± 0.03 × 10⁵ CFU in the spleen to the highest seen in the organs (2.7 × 10⁶ ± 0.01 × 10⁶ CFU/spleen) 22 days after infection. After this initial replication,the bacterial growth was controlled and CFU numbers returned tothe level seen at the beginning of theexperiment.

Infection with M. tuberculosis induces MMP production in vivo and in vitro. We next asked how virulent M. tuberculosis affected macrophage MMP production in comparison to BCG. In peritoneal macrophages,M. tuberculosis induced a vigorous MMP-9 response that was dosedependent and of at least the same magnitude as that induced byBCG (Fig. 7).

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FIG. 7. M. tuberculosis induces gelatinase activity in macrophages in vitro. Macrophage monolayers were incubated either with medium alone or with 0.1 or 10 M. tuberculosis H37Rv or M. bovis BCG bacteria per macrophage. Cell culture supernatants were collected after 48 h and analyzed for gelatinase activity using zymography. Data presented are representative of two independent experiments.

The presence of MMPs in protein extracts from spleens, livers, and lungs was then determined in BALB/c mice infected i.v.with 10⁶ M. tuberculosis H37Rv organisms for 5 months. At this time point,there was substantial inflammation and mature organized granulomaswere seen in the livers. In the lungs, granulomas correspondedto lesions of categories 3 to 4 as defined by Rhoades et al. (37),i.e., focal lesions of epithelioid macrophages with some scatteredlymphocytic foci. In this experiment, spleen, liver, and lungtissues from infected animals all had levels of MMP-9 which weresignificantly increased compared to those of age-matched sham-infectedcontrols (Fig. 8A).

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FIG. 8. Infection with M. tuberculosis induces increased MMP-9 activity in vivo. (A) BALB/c mice were infected i.v. with 10⁶ M. tuberculosis H37Rv bacteria, and homogenates were prepared from spleens, livers, and lungs of sham-infected age-matched controls (white bars) and of infected mice (black bars) 5 months later and analyzed by gelatin zymography. (B) SCID mice were infected i.v. with 10⁶ M. tuberculosis H37Rv bacteria, and homogenates were prepared from spleens, livers, and lungs of sham-infected age-matched controls (white bars) and of infected mice 8 days (grey bars) and 22 days (black bars) later and analyzed by gelatin zymography. Data are presented as means + standard deviations of the relative enzymatic activity in samples from individual mice (three per group) with the same total protein content loaded (lungs, 20 µg; spleens, 3 µg; and liver, 40 µg of total protein/lane). *, P < 0.05; **, P < 0.01; ***, P < 0.001 when comparing with the uninfected animals.

In order to assess MMP activity in vivo in a situation without the T-cell-dependent control of mycobacterial growth, gelatinaseactivity was determined in organs from M. tuberculosis-infectedSCID mice on a BALB/c background. These mice were infected withM. tuberculosis H37Rv, and tissues were collected both early (8days) and relatively late (22 days) after infection. The lackof T cells resulted in an accelerated pathology with necrosisand a large influx of neutrophils in the late stage of the infection.Bacterial replication was not controlled in any of the organsstudied. Mean bacterial numbers were as high as 1.4 × 10⁹ in the spleens, 3.0 × 10⁸ in the livers, and 5.0 × 10⁸ in the lungs, and the mice died about 35 days postinfection.Eight days after infection, no effects on the MMP levels of theSCID mice were seen. In contrast, 2 weeks later a fourfold increasein MMP-9 could be seen in the livers and lungs of these animals(Fig. 8B). These experiments demonstrate that M. tuberculosisis a potent inducer of gelatinase activity both in vivo and invitro.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

In this article we show that mycobacterial infection is a powerful stimulus for production of MMP-9 (gelatinase B) and MMP-2(gelatinase A) by murine macrophages. The mycobacterial inductionof MMPs was mediated by macrophage secretion of TNF- $alpha$ and IL-18and was regulated by the T-cell-associated cytokines IFN- $gamma$ andIL-4, as well as by IL-10. Infection of both immunocompetent andSCID mice with M. tuberculosis or BCG also resulted in increasedMMP-9 activity in severalorgans.

In order to study MMP responses from normal, nontransformed macrophages after interaction with mycobacteria, we used an invitro model in which peritoneal macrophages were stimulated withBCG or M. tuberculosis. In this system, small numbers of bacteriafrom both species were able to induce prominent production ofMMP-9. Preliminary experiments also showed that stimulation withMycobacterium avium induced comparable levels of MMP-9 activityin macrophages, and therefore, MMP-9 induction seems to be a commonfeature of mycobacterial infection. Apart from MMP-9 and MMP-2,no other MMPs could be detected after stimulation with BCG, anMMP profile that is in agreement with the range of MMPs inducedby in vitro stimulation of macrophages with LPS or in vitro infectionwith Borrelia spp. (25, 54). A previous study (7) alsodemonstrated that inactivated M. tuberculosis induced increasedMMP-9 production in a myelomonocytic cell line. We have now extendedthese findings by demonstrating the effects of both live and inactivatedmycobacteria on freshly isolated macrophages and have also characterizedthe cytokine network regulating mycobacterium-induced macrophageMMP-production.

Several observations indicate that the most important factor contributing to MMP production after BCG stimulation in vitrois the cytokine response which the mycobacteria induce. Thus,blocking of TNF- $alpha$ inhibited BCG-induced MMP production, and additionof recombinant TNF- $alpha$ to untreated macrophages induced MMP-9 activityto the same extent as live BCG bacteria. Indeed, the concentrationof recombinant TNF- $alpha$ needed to induce MMP-9 activity was similarto the levels of TNF- $alpha$ induced in macrophage cultures by stimulationwith BCG. Finally, conditioned, sterile-filtered media from BCG-infectedmacrophages induced increased levels of MMP activity. Previousstudies have demonstrated the ability of TNF- $alpha$ to induce MMP productionby different cell types in vitro (24, 38, 50, 51, 55),but this study is the first to demonstrate the involvement ofTNF- $alpha$ in MMP production induced by a pathogenic bacterium. Inaddition to the effect of TNF- $alpha$ neutralization, antibodies toIL-18 also had a reproducible, but less pronounced, inhibitoryeffect and stimulation with recombinant IL-18 also enhanced MMP-9activity. This effect of IL-18 on MMP production has not beendocumented before, and the previously reported effects of IL-18on macrophages have mainly been inhibitory, such as attenuatingLPS-induced IL-12 and TNF- $alpha$ secretion (6, 36). Other proinflammatorycytokines produced by macrophages in response to ingestion ofmycobacteria, such as IL-1 $beta$ and GM-CSF (12, 51), have beenshown to promote MMP secretion in vitro, alone or in synergy withTNF- $alpha$ (38, 55). However, the BCG-induced secretion of MMP-9and MMP-2 shown here was not influenced by neutralization of IL-1,IL-12, or GM-CSF. Taken together, these results indicate the existenceof an autocrine loop involving key cytokines (among them TNF- $alpha$ and IL-18) which induce macrophage production of MMPs in responseto mycobacteria. Indomethacin treatment did not affect macrophageMMP production, suggesting that the BCG-induced MMP productionis largely independent of prostaglandin E₂. This again supportsthe view that a major part of BCG-induced MMP production is mediatedby macrophage cytokines produced in response to the infection,since cytokine- but not LPS-induced MMP-9 production is independentof prostaglandin E₂ (41, 55).

Macrophage function and activation stage are dependent on the net effect of the regulatory cytokines that the macrophage encounters(48). TNF- $alpha$ and IL-18 are produced during mycobacterial infectionand are important for containing the infection, presumably bypromoting IFN- $gamma$ secretion from T cells and NK cells (2, 15,16, 30). TNF- $alpha$ and IFN- $gamma$ often act in synergy to enhance macrophageeffector functions, partly since IFN- $gamma$ induces expression of TNF-Rand increases the activation of NF- $kappa$ B induced by TNF- $alpha$ stimulation(5, 18). Nevertheless, IFN- $gamma$ and TNF- $alpha$ have opposing effectson macrophage MMP secretion induced by mycobacteria. In supportof this finding, IFN- $gamma$ has previously been shown to down-regulateLPS- and cytokine-induced MMP production (38, 54), but theintracellular signaling events resulting in decreasing MMP productionin IFN- $gamma$ -containing cultures are presently unknown. We cannotdetermine if IFN- $gamma$ binding results in a direct decrease in theamounts of MMPs produced in our system or rather in increasedTIMP production. Earlier studies suggest, however, that the potentialof IFN- $gamma$ to down-regulate macrophage gelatinase activity in cytokine-or LPS-stimulated macrophages does not result from increased TIMPsynthesis (44, 47). NO has been suggested to decrease MMPsecretion from macrophages (27), and IFN- $gamma$ -induced NO productionmight therefore be one of the mechanisms resulting in decreasedMMP-9activity.

In addition to IFN- $gamma$ , the immunomodulatory cytokines IL-10 and IL-4 also down-regulate BCG-induced MMP activity. However,in this case the effects seem to be indirect, accomplished byreducing the amount of TNF- $alpha$ available to the macrophages. Itseems, therefore, that macrophage MMP production can be modulatedin two ways by regulatory cells, either directly by IFN- $gamma$ or indirectlyby altering the magnitude of the TNF- $alpha$ response with macrophage-deactivatingcytokines such as IL-10 and IL-4.

Increased MMP activity in response to mycobacterial infection was not only an in vitro phenomenon, since infection with BCGor M. tuberculosis results in significantly increased MMP-9 activityin several tissues in immunocompetent mice. These observationsare consistent with the finding of increased MMP levels in bronchoalveolarlavage specimens from patients with active tuberculosis (7)and now provide an experimental model in which to dissect theircontribution to immunopathology versus resistance in vivo. Thus,we could monitor the different kinetics of induction of MMP-9activity in several organs after infection withBCG.

The increased tissue MMP activity in SCID mice after infection with M. tuberculosis is of particular interest. Vigorous MMP-9responses were seen during the late stage of the infection inlungs and livers of SCID mice infected with M. tuberculosis. Atthis time point, the infection is characterized by extensive tissuedamage combined with a large neutrophil infiltration, especiallyin the lungs. The excessive MMP production in SCID mice may partlyresult from a reduced level of the T-cell-associated cytokineIFN- $gamma$ , which would down-regulate MMP activity in an immunocompetentmouse. The influence of large bacterial loads in the tissues mayalso be one of the reasons for the high MMP-9 activity, and thelarge number of infiltrating neutrophils may also contribute tothe tissue content of MMP-9, since neutrophils harbor preformedMMP-9 in their granulae (43).

The implications of increased MMP activity in the various organs during mycobacterial infections are still unclear, but wespeculate that the breakdown of the extracellular matrix is necessaryfor cell recruitment and efficient granuloma formation. Thus,MMP production may be essential for the development of protectiveimmune responses to mycobacteria. However, MMP activity may alsoplay an important role in the pathology of mycobacterial infectionsby destroying the tissue integrity. Dysregulation of MMP productionat late stages of the infection could be one of the factors resultingin tissue damage. The generation of chemotactic fragments fromthe ECM may also contribute to cell recruitment to inflammatoryfoci (22, 40). In view of recent in vitro data demonstratingthat M. avium-induced MMP activity promotes human immunodeficiencyvirus replication and spread in T cells, MMP production in vivoduring mycobacterial infections is probably a contributing factorto the mutual exacerbation of both diseases in patients coinfectedwith M. tuberculosis and human immunodeficiency virus type 1 (9).

In conclusion, we show that mycobacterial infections induce increased MMP-9 activity both in vitro and in vivo and that thisactivity is regulated by TNF- $alpha$ , IL-18, and IFN- $gamma$ . These findingsindicate possible contributions of these enzymes to tissue remodelingprocesses in tuberculous lesions invivo.

	ACKNOWLEDGMENTS

M.Q.J. was supported by a grant from the Swedish Foundation for International Cooperation in Research and HigherEducation.

We are grateful for the technical assistance of Helen Counihan and the staff of the Biological Services Facility at the LondonSchool of Hygiene and Tropical Medicine. We thank Paul Kaye forhelpful comments on themanuscript.

	FOOTNOTES

^* Corresponding author. Present address: Dept. of Medical Microbiology & Immunology, Box 435, Göteborg University, SE-405 30Göteborg, Sweden. Phone: 46-31-342 4492. Fax: 46-31-826976. E-mail:marianne.quiding{at}microbio.gu.se.

Editor: S. H. E. Kaufmann

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