Tumor Necrosis Factor-alpha -induced Proteolytic Activation of Pro-matrix Metalloproteinase-9 by Human Skin Is Controlled by Down-regulating Tissue Inhibitor of Metalloproteinase-1 and Mediated by Tissue-associated Chymotrypsin-like Proteinase

doi:10.1074/jbc.M202842200

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Tumor Necrosis Factor- $alpha$ -induced Proteolytic Activation of Pro-matrix Metalloproteinase-9 by Human Skin Is Controlled by Down-regulating Tissue Inhibitor of Metalloproteinase-1 and Mediated by Tissue-associated Chymotrypsin-like Proteinase^*

Yuan-Ping Han, Yih-Dar Nien, and Warren L. Garner

From the Division of Plastic and Reconstructive Surgery, Department of Surgery, The Keck School of Medicine, University of Southern California, Los Angeles, California 90033

Received for publication, March 25, 2002, and in revised form, April 30, 2002

ABSTRACT

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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

The proteolytic activation of pro-matrix metalloproteinase (MMP)-9 by conversion of the 92-kDa precursor into an 82-kDa activeform has been observed in chronic wounds, tumor metastasis, andmany inflammation-associated diseases, yet the mechanistic pathwayto control this process has not been identified. In this report,we show that the massive expression and activation of MMP-9 inskin tissue from patients with chronically unhealed wounds couldbe reconstituted in vitro with cultured normal human skin by stimulationwith transforming growth factor- $beta$ and tumor necrosis factor (TNF)- $alpha$ .We dissected the mechanistic pathway for TNF- $alpha$ induced activationof pro-MMP-9 in human skin. We found that proteolytic activationof pro-MMP-9 was mediated by a tissue-associated chymotrypsin-likeproteinase, designated here as pro-MMP-9 activator (pM9A). Thisunidentified activator specifically converted pro-MMP-9 but notpro-MMP-2, another member of the gelatinase family. The tissue-boundpM9A was steadily expressed and not regulated by TNF- $alpha$ , whichindicated that the cytokine-mediated activation of pro-MMP-9 mightbe regulated at the inhibitor level. Indeed, the skin constantlysecreted tissue inhibitor of metalloproteinase-1 at the basalstate. TNF- $alpha$ , but not transforming growth factor- $beta$ , down-regulatedthis inhibitor. The TNF- $alpha$ -mediated activation of pro-MMP-9 wastightly associated with down-regulation of tissue inhibitor ofmetalloproteinase-1 in a dose-dependent manner. To establish thislinkage, we demonstrate that the recombinant tissue inhibitorof metalloproteinase-1 could block the activation of pro-MMP-9by either the intact skin or skin fractions. Thus, these studiessuggest a novel regulation for the proteolytic activation of MMP-9in human tissue, which is mediated by tissue-bound activator andcontrolled by down-regulation of a specificinhibitor.

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Matrix metalloproteinases (MMPs)¹ are essential for remodeling of the extracellular matrix in physiologic and pathologic conditions(1, 2). Within the MMP family, MMP-9 (gelatinase B; EC 3.4.24.35)is particularly important, because it has a documented role inmany human diseases. Like most MMPs, MMP-9 is secreted as a latentzymogen that is maintained by the interaction between a cysteinein the N-terminal pro-domain and the active-site zinc atom. Proteolyticcleavage of the pro-domain is a common control mechanism for MMPactivation, which triggers a conformational change of the enzymeand is termed the "cysteine switch" (3). The conversion ofpro-MMP-9 with an apparent molecular mass of 92-kDa to the 82-kDaactive MMP-9 has been commonly observed in the pathogenesis ofmany diseases (4).

Metastasis is a multistep process, including detachment of cancer cells from a primary site, invasion into surrounding tissuethrough breakdown matrix, spreading through circulation, and proliferationin distant organs. Breakdown of the basement membrane zone (BMZ)is necessary to allow malignant cells to migrate from the primarylocation. MMP-9 is not normally expressed in developed tissues,yet it is highly expressed in many cancers (5-7). During theearly phase of breast cancer, only pro-MMP-9 is increased. Asthe cancer stage increases, evidenced by skin invasion or lymphovascularpermeation, active MMP-9 is found (8). Similarly, sequentialexpression and activation of pro-MMP-9 has been observed in livermetastasis (9). An interesting pattern of MMP-9 expressionhas also been documented in wound healing. In the normal repairof acute trauma or burn wound, pro-MMP-9 is transiently expressedand declines with the progress of healing (10, 11). On theother hand, persistent expression of a larger amount of MMP-9,especially the active 82-kDa MMP-9, has been repeatedly documentedin chronic wounds (12-14). Given the proteolytic function of MMP-9in the digestion of BMZ components such as type IV collagen, thepathogenesis of these diseases could be due to the activity ofMMP-9.

A critical unanswered question regarding MMP-associated disease pathogenesis is the identification of specific factors controllingthe expression and activation of the proteinase. MMP activitiesare regulated at multiple levels from their expression to activationby cleavage of the inhibitory domain as well as blockage by tissueinhibitors. Although the proteolytic activation of MMP-9 has beenwell documented in many diseases, the mechanism for the proteolyticconversion is not established. In this report, we show for thefirst time that the increased expression and activation of MMP-9found in patients with chronic wounds could be reconstituted incultured normal human skin by treatment with specific cytokines.Furthermore, we found that activation of pro-MMP-9 was mediatedby a tissue-associated chymotrypsin-like proteinase. The TNF- $alpha$ -mediatedactivation of pro-MMP-9 is controlled by down-regulation of theMMP inhibitor, TIMP-1. These findings provide a novel model toexplain the MMP-9 activation in the pathogenesis of chronic woundsand tumor metastasis through the action of specific proinflammatorycytokines.

EXPERIMENTAL PROCEDURES

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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Materials and Reagents-- Cytokines were purchased from R & D Systems (Minneapolis, MN). The antibodies against TIMP-1 (MAB13437) and the purified recombinantTIMP-1 protein (CC3328) were purchased from Chemicon International(Temecula, CA). The antibody for mast cell chymase (MS-1217) wasfrom NeoMarkers (Fremont, CA). Aprotinin, L-1-chloro-3-(4-tosylamido)-7-amino-2-heptanone-HCl(TLCK), and L-1-chloro-3-(4-tosylamido)-4-phenyl-2-butanone (TPCK)were purchased from Roche Molecular Biochemicals. MMP-3 inhibitorII (N-isobutyl-n-(4-methoxyphenylsulfonyl)-glycylhydroxamic acid)was from Calbiochem. The Immobilon-P was purchased from MilliporeCorp. (Bedford, MA). ECL was purchased from Amersham Biosciences.The gelatin was from Sigma. Gelatin-Sepharose 4B was purchasedfrom Amersham Biosciences AB (Uppsala,Sweden).

Organ Culture and Cytokine Stimulation of Human Skin-- Normal human skin was obtained as discarded tissue from patients undergoing reconstructive or aesthetic surgery (Universityof Southern California Internal Review Board no. 999061). Thefull thickness skin was decontaminated by incubation in DMEM containing2× antibiotic (200 units/ml penicillin G sodium, 200 units/mlstreptomycin sulfate, and 0.5 mg/ml amphotericin B) at 4 °C overnightbefore all subsequent procedures. Then the skin was cut into squaresof equal sizes with 0.5 cm in each side and incubated in DMEMat 37 °C with 5% CO₂ for 6 h. To decrease the effects of endogenoussoluble factors in the skin induced by the harvesting process,the medium was changed three times during the 6-h incubation.Finally, the explant was floated in 2 ml of DMEM with specificcytokines and was maintained at 37 °C with 5% CO₂.

Preparation and Culture of Human Dermal Fibroblasts and Keratinocytes-- Dermal fibroblasts and keratinocytes were isolated from normal full thickness or partial thickness human skin (15, 16).The isolated fibroblasts were cultivated in DMEM containing 10%fetal bovine serum and with penicillin (100 units/ml) and streptomycinsulfate (100 µg/ml). The keratinocytes were cultivated with completekeratinocyte growth medium. Before exposure to cytokines, themedium was replaced with serum- and antibiotic-free DMEM for fibroblastsand keratinocyte basal medium forkeratinocytes.

Preparation of Pro-MMP-9-- The transformed human keratinocytes (kindly provided by Dr. David T. Woodley at USC) were grown in keratinocyte growth mediumto confluence. The cells were treated by 2 ng/ml TNF- $alpha$ in keratinocytebasal medium for 72 h in standard culture condition. In this condition,most of the gelatinase secreted in the medium is the 92-kDa pro-MMP-9.The conditioned medium from 20 10-cm dishes was collected andcleared by centrifugation at 4000 × g. The conditioned mediumwas then passed to a 5-ml gelatin-Sepharose 4B column followedby washing with 400 mM NaCl, 0.5% Triton X-100 in 50 mM Tris,pH 7.5. The bound gelatinase was eluted by 6 M urea followed bydialysis against buffer containing 100 mM NaCl and 50 mM Trisat pH 7.5. The identity of pro-MMP-9 was confirmed by Westernblot with antibody against MMP-9 as reported previously (17).

Preparation of Pro-MMP-2-- Human dermal fibroblasts were grown as monolayers in DMEM with 10% fetal bovine serum. To generate pro-MMP-2, the medium wasreplaced by serum-free DMEM. After culturing for 74 h, the conditionedmedium was cleared by centrifugation. The gelatinase was purifiedby gelatin-Sepharose 4B as described above. In this preparation,most of the gelatinase is pro-MMP-2 (18). The identity was confirmedby Western blot with antibody against MMP-2.

Assay of Tumor Necrosis Factor from Skin Biopsies-- 6-mm punch biopsies were taken from each patient at the site of an unhealed burn wound, healed wound, and normal skin (Universityof Southern California Internal Review Board no. 999061). Theskin biopsies were briefly washed by phosphate-buffered salineand immersed in 0.5 ml of DMEM with proper antibiotics. The tissueswere incubated at 37 °C with 5% CO₂ for 18 h. The conditionedmedium and tissue were stored at $-$ 80 °C before assay. Bioactivityof TNF- $alpha$ was determined as previously described (15, 19).

Extraction of Pro-MMP-9 Activator (pM9A) from Human Skin-- The skin tissue was minced and ground in liquid nitrogen by a mechanic miller. The skin powder was washed by NT buffer containing100 mM NaCl and 50 mM Tris at pH 7.5. Then the tissue powder wasextracted by 2.5% Triton X-100, 2 M NaCl, and 6 M urea, respectively.The extracts were subjected to dialysis against NT buffer, andthe insoluble fractions were washed using the samebuffer.

pM9A Activity Assay-- For each assay, 80 µl of tissue extracts were incubated with 15 µl of pro-MMP-9 together with 5 µl of 100 mM CaCl₂. The reactionwas carried at 37 °C for 16 h followed by gelatinolytic zymogramanalysis. For the inhibition experiments, 2.5 µl of inhibitorsand 2.5 µl of 200 mM CaCl₂ were added to the system beforeincubation.

Gelatinolytic Zymogram-- The conditioned medium was mixed with SDS-PAGE sample buffer in the absence of reducing agent and electrophoresed in 10% polyacrylamidegel containing 0.1% (w/v) gelatin. Electrophoresis was carriedout at 4 °C with 120 V for 16 h. After electrophoresis, SDS inthe gel was removed by incubation with 2.5% Triton X-100. Gelatinolyticactivities were developed in buffer containing 5 mM CaCl₂, 150mM NaCl, and 50 mM Tris at pH 7.5 for 16 h at 37 °C. The gelatinolyticactivities were visualized by staining with Coomassie Blue R-250.

Western Blot-- The conditioned medium or skin extracts were resolved by reducing SDS-PAGE (15%). The protein was transferred to Immobilon-P(Millipore Corp.). The membrane was exposed to antibodies againsthuman TIMP-1 or mast cell chymase followed by blot with peroxidase-conjugatedsecondary antibodies, which were subsequently detected by enhancedchemiluminescence.

RESULTS

TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

The Excessive Expression and Activation of MMP-9 in the Tissue from Patients with Chronic Unhealed Wounds Can Be Reconstituted by Cultured Human Skin with Specific Cytokines-- Massive expression and activation of MMP-9 have been extensively reported in the tissue fluid of chronic wounds (12-14). Tofind the causal factors that induce expression and activationof MMP-9, we measured the gelatinase profile and cytokine concentrationfrom the tissue of patients' unhealed wounds, and then we attemptedto reconstitute the results in vitro by using cultured normalhuman skin. Here we show a typical gelatinase profile from a patientwith a chronic wound. Biopsies from the unhealed wound, healedwound, and the surrounding normal skin were taken from a 19-year-oldpatient 60 days after partial graft loss during treatment fora thermal burn. The unhealed wound was a small area of graft loss(<2 cm²) that would normally be expected to heal within 2-3 weeks. Thebiopsies were immersed in DMEM with antibiotics and incubatedat culture condition for 6 h. This short term culture was designedto allow the diffusion of the soluble factors produced by thetissue. The conditioned medium was resolved by a gelatinolyticzymogram. As shown in Fig. 1, substantial gelatinase activitieswith apparent molecular masses of 92 and 82 kDa, representingthe pro-MMP-9 and active MMP-9, respectively, were found. Conversely,little gelatinase activities were secreted from the normal skinand healed wound.

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Fig. 1. The expression and activation of pro-MMP-9 in chronic patients can be reconstituted by cultured human skin with specific cytokines. A, biopsies from unhealed wound, healed wound, and surrounding normal skin were taken from a 19-year-old patient 60 days after partial graft loss during treatment for a thermal burn. The biopsies were immersed in 0.5 ml of DMEM with antibiotics and incubated for 6 h. The conditioned medium was resolved by gelatinolytic zymogram. B, TNF- $alpha$ level in biopsies from normal skin and healed and chronic wounds was measured as described under "Experimental Procedures." C, the cytokine-induced expression and activation of MMP-9 by human skin. Normal human skin was cultured in 2 ml of DMEM with cytokines as indicated for 64 h. The gelatinase activities from the conditioned medium were analyzed by gelatin zymogram.

To identify the potential factors that cause the expression and activation of MMPs in human skin, we initially tested a panelof cytokines that have been found elevated in chronic wounds andat metastatic tumor sites. Single or combinations of cytokineswere added to normal human full thickness skin floating in DMEM(1 ng/ml for TGF- $beta$ and 10 ng/ml for the other cytokines). Afterculture for 64 h, the conditioned media were resolved by zymogram.As shown in Fig. 1, among this panel of cytokines only TGF- $beta$ inducesthe expression of 92-kDa pro-MMP-9, and only TNF- $alpha$ promotes theformation of 82-kDa MMP-9. The TNF- $alpha$ -mediated formation of 82-kDaMMP-9 is sequentially processed by induction of the 92-kDa formfollowed by conversion to the 82-kDa form (17). As expected,combination of TNF- $alpha$ with TGF- $beta$ leads to greater expression andactivation of MMP-9 than either factor alone. Other cytokines,such as platelet-derived growth factor, interleukin-6, and interleukin-8(data not shown), were without effect alone or in combination.The identity of 92- and 82-kDa MMP-9 were confirmed by Westernblot as demonstrated in our previous report (17). To confirmthis result, we measured the cytokine levels produced by biopsiesof chronically unhealed wound, healed wound, and normal skin tissues.In a comparison of unhealed, healed, and normal skin in nine patients,the TNF- $alpha$ level was found to be significantly higher in chronicwound tissue (Fig. 1). The concentration of TNF- $alpha$ found in chronicwound tissue (6 ± 2 ng/ml) is comparable with the cytokine concentrationnecessary to promote the proteolytic conversion of pro-MMP-9 innormal skin. Taken together, we identified TGF- $beta$ and TNF- $alpha$ ascausal factors for induction and activation of MMP-9, respectivelyin chronic wounds. These results indicate that the induction andactivation of MMP-9 observed in chronic wounds and tumors areprobably mediated through thesecytokines.

Human Skin Steadily Expresses the Pro-MMP-9 Activator, Which Is Not Regulated by TNF- $alpha$ -- Initially, we thought that the TNF- $alpha$ -mediated activation of pro-MMP-9 might be regulated through the increase of pM9A activity,perhaps through an increase in synthesis of pM9A. To address thisquestion, we performed the following two experiments. In the firstexperiment, we examined whether pM9A activity was enhanced bycytokines. Normal human skin was stimulated with TNF- $alpha$ and TGF- $beta$ individually or simultaneously. After culturing for 64 h, theconditioned medium and skin tissue were separated. The skin tissueswere washed by phosphate-buffered saline and ground in liquidnitrogen. The tissue powder was then extracted by 2% Triton X-100for 16 h, and the resulting insoluble fractions were further washedto remove the detergent. To assay pM9A activities, purified pro-MMP-9was incubated with the skin fractions for 16 h followed by zymogramanalysis. As shown in Fig. 2A, 92-kDa pro-MMP-9 was convertedto the 82-kDa form by the tissue fractions under all conditions.Notably, TNF- $alpha$ did not increase the pM9A activity.

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Fig. 2. Human skin-associated pM9A is not regulated by TNF- $alpha$ . A, a scheme for the experiment design. Normal human skin was stimulated by TNF- $alpha$ and TGF- $beta$ individually or simultaneously. After culture for 64 h, the conditioned medium and skin tissue were separated. B, the skin tissues were washed and then ground in liquid nitrogen. The resulting tissue powder was then extracted by 2% Triton X-100 followed by separation into soluble and insoluble fractions. To assay pM9A activities, purified pro-MMP-9 was incubated with these insoluble fractions followed by zymogram analysis. C, measurement of the pM9A activities in the conditioned medium. The original conditioned medium and the gelatinase-depleted medium were incubated with or without purified pro-MMP-9 followed by zymogram analysis.

We also tested whether pM9A activity was secreted into the conditioned medium. We measured the pM9A activities in the originalconditioned medium as well as the conditioned medium that hadbeen depleted of gelatinase in order to lower the background.In the untreated conditioned media, there was cytokine-inducedMMP-9 that came from the organ culture, and the exogenous addedpro-MMP-9 was not converted (Fig. 2B). Similarly, as shown inFig. 2C, the added pro-MMP-9 failed to be converted into the 82-kDaform in the depleted conditioned media. Thus, either the tissue-boundpM9A is not secreted or there is a specific inhibitor that isalso secreted with theactivator.

Because the organ culture technique utilized in our experiments might lead to the expression of pM9A, we performed a timecourse experiment. Normal human skin was cut into small pieces.Some were immediately frozen in liquid nitrogen, as day 0 samples.Other pieces were cultured in DMEM for 24 and 72 h. Then the skintissues were ground, followed by Triton X-100 extraction. Purifiedpro-MMP-9 was added to these tissue fractions for pM9A assay.The data show that the tissue-associated pM9A activity is clearlydetectable in the day 0 sample and increased slightly during thesubsequent 3-day culturing (Fig. 3A).

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Fig. 3. The pM9A is steadily expressed in human skin. A, normal human skin was cut into small pieces, and some were immediately stored at $-$ 80 °C and regarded as day 0 samples. Others were cultured in DMEM for an additional 24 or 72 h. Tissue samples were ground, followed by Triton X-100 extraction. The pM9A activities were assayed by incubation with purified pro-MMP-9 followed by zymogram analysis. B, cycloheximide inhibited the expression of pM9A by human skin. Normal human skin was cultured in DMEM with or without cycloheximide (40 µg/ml) and with or without TNF- $alpha$ (10 ng/ml) for 46 h. The tissue-bound pM9A activities were assayed by incubation with pro-MMP-9.

We then asked whether de novo protein synthesis in the skin was required for the expression of pM9A. Normal human skin wascultured in DMEM with or without TNF- $alpha$ (10 ng/ml) in the presenceor absence of cycloheximide (40 µg/ml). Then skin tissue was extractedwith Triton X-100, and the insoluble fractions were assayed forpM9A activities by incubation with purified pro-MMP-9. The reactionwas resolved by zymogram (Fig. 3B). The results show that cycloheximidetreatment decreases the pM9A activities in the skin tissue. Again,TNF- $alpha$ did not alter the cycloheximide-induced inhibition. Theremaining pM9A activities from the cycloheximide-treated skinwere probably derived from the skin prior to the treatment. Thus,pM9A is constitutively synthesized in skin, and its level is notregulated by TNF- $alpha$ .

Tissue-associated pM9A Is a Chymotrypsin-like Proteinase-- We then characterized this unidentified proteinase by its sensitivity to various proteinase inhibitors. The Triton-insolublefractions of human skin and purified pro-MMP-9 were incubatedwith pepstatin (aspartic proteinase inhibitor), aprotinin (serineproteinase inhibitor), and MMP-3 inhibitor II. The results showthat aprotinin but not other inhibitors can block the skin tissue-mediatedconversion of pro-MMP-9. This indicates that pM9A is a serineproteinase (Fig. 4A). We further investigated the inhibition specificityof pM9A through a pair of serine proteinase inhibitors, TLCK,a specific inhibitor for trypsin-like proteinase and TPCK, a specificinhibitor for chymotrypsin-like proteinase. The results show thatthe tissue-associated pM9A activity is inhibited by TPCK at 50µM and completely blocked by the inhibitor at 250 µM, which iswithin the normal concentration to block typical chymotrypsin(Fig. 4B). In contrast, TLCK has no inhibitory effect, even at500 µM. Thus, the tissue-associated pM9A represents an as yetunidentified chymotrypsin-like proteinase.

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Fig. 4. Tissue-associated pM9A is a chymotrypsin-like proteinase. A, the Triton-insoluble fractions of human skin were incubated with purified pro-MMP-9 together with pepstatin (100 µM), aprotinin (50 µM), and MMP-3 inhibitor II (3 µM). After a 16-h incubation, the reaction products were resolved by zymogram. B, the tissue-bound pM9A is inhibited by TPCK, a specific inhibitor for chymotrypsin-like proteinase but not TLCK, the inhibitor for trypsin-like proteinase. The inhibitors at the indicated concentration were incubated with the Triton X-100 fractions followed by zymogram analysis.

Extraction of the Tissue-associated pM9A-- Our next aim was to extract pM9A from the skin tissue for identification. For this purpose, a serial extraction was performed.As shown previously, Triton X-100 was inefficient to extract thepM9A even at quite high concentration (17). We then tried saltextraction. The full thickness skin was ground in liquid nitrogenfollowed by extraction with either 2 M NaCl or 6 M urea. The extractswere subsequently dialyzed and assayed for pM9A activities byincubation with purified pro-MMP-9. As shown in Fig. 5A, 2 M NaClefficiently extracted pM9A activity, whereas urea at 6 M failedto do so. In analysis of the debris, 2 M NaCl removed almost allpM9A activities, leaving no significant pro-MMP9-converting activityin the insoluble fraction. Conversely, most pM9A activity remainedin the urea-insoluble fractions. In addition, the pM9A could alsobe extracted by SDS and retained its activity (data not shown).We conclude that the failure of extraction of pM9A by either ureaor Triton X-100 was not due to denaturation or inactivation ofpM9A but rather the incapability of these agents to dissociatethe proteinase from the skin tissue.

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Fig. 5. Extraction of the tissue-associated pM9A and mast cell chymase. A, the full thickness skin was ground in liquid nitrogen followed by extraction with either 2 M NaCl or 6 M urea. The soluble fractions were subsequently dialyzed, and the insoluble fractions were washed. The fractions were assayed for pM9A activities by incubation with pro-MMP-9. B, the fractions were analyzed for the mast cell $alpha$ -chymase by Western blot.

Human Pro-MMP-9 Activation Is Probably Not through the Mast Cell Chymase-- Mast cells play important roles in skin inflammation by secretion of histamine and proteinases, including a chymotrypsin-likeproteinase, $alpha$ -chymase. Whether $alpha$ -chymase can convert pro-MMP-9is a subject of debate. Mast cell $alpha$ -chymase prepared from dogmastocytoma cells was shown to be unable to activate human pro-MMP-9(20), whereas another group showed that the dog mast cell chymasecould activate the dog pro-MMP-9 by cleaving at the Phe⁸⁸-Gln⁸⁹ and Phe⁹¹-Glu⁹² (21). To clarify whether the human skin mast $alpha$ -chymase is pM9A,we compared the extraction behavior of $alpha$ -chymase versus pM9A activities.Results show that NaCl at 2 M could extract pM9A activity butfailed to extract the mast cell chymase as measured by Westernblot (Fig. 5B). Conversely, urea at 6 M failed to extract pM9Aactivity but could extract $alpha$ -chymase. Thus, these two lines ofevidence indicate that the mast cell $alpha$ -chymase is not likely tobe pM9A in humanskin.

The Cytokine-induced MMP-3 Is Not Sufficient to Activate Pro-MMP-9-- Based on in vitro constitution experiments, MMP-3 has been previously suggested as a potential activator for pro-MMP-9 (22).However, in the mice with homozygous knockout of MMP-3 (MMP-3^/), the activation of MMP-9 was found to be normal, which suggestsan MMP-3-independent pathway (23). To test this possibility,we examined whether TNF- $alpha$ can regulate MMP-3. Normal human skinand primary dermal fibroblasts and keratinocytes were stimulatedby TNF- $alpha$ and TGF- $beta$ . After culture for 64 h, the conditioned mediumwas analyzed by zymogram for MMP-9 activation and Western blotfor MMP-3 protein (Fig. 6). As expected, the 92-kDa MMP-9 wasinduced by TGF- $beta$ , and the active 82-kDa was generated by TNF- $alpha$ stimulation in human skin, whereas pro-MMP-9 was induced but noactivation was observed in either dermal fibroblasts or epidermalkeratinocytes. A small amount of MMP-3 was found expressed byhuman skin at basal state, and the protein level was significantlyincreased by TNF- $alpha$ stimulation. Similarly, MMP-3 protein was inducedby TNF- $alpha$ in dermal fibroblasts and keratinocytes, where no activationof pro-MMP-9 was found. In addition, most of the MMP-3 is secretedas a soluble factor, whereas pM9A is tissue-bound. As shown inFig. 4A, the specific inhibitor for MMP-3 failed to inhibit theactivation of pro-MMP-9. All of these results suggest that expressionof MMP-3 is not sufficient to activate pro-MMP-9.

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Fig. 6. The cytokine-induced MMP-3 is not sufficient to activate pro-MMP-9. Normal human skin, primary dermal fibroblasts embedded in collagen matrix, and keratinocytes on monolayers were stimulated by TNF- $alpha$ and TGF- $beta$ individually or combined. After culture for 64 h, the conditioned media were collected. A, conditioned media were analyzed by zymogram for MMP-9 induction and activation. B, MMP-3 protein in the conditioned medium was analyzed by Western blot.

Specificity of pM9A-- The specificity of pM9A as an activator was determined by testing its ability to activate MMP-2, another member of the gelatinasefamily. Pro-MMP-2 activation is generally thought to be mediatedthrough the membrane type MMP with the participation of TIMP-2(24). We asked whether the tissue-associated pM9A could alsoactivate pro-MMP-2. The Triton X-100-insoluble and NaCl-solublefractions from normal human skin were incubated with purifiedpro-MMP-2 and pro-MMP-9, respectively, and the products were resolvedby zymogram. As shown, pro-MMP-9 but not the pro-MMP-2 is convertedby the skin fractions (Fig. 7). Note that some 62-kDa active MMP-2was derived from the original preparation, and that amount wasnot increased by incubation with the skin fractions, whereas mostof the pro-MMP-9 was converted to the 82-kDa form. Therefore,pM9A is specific for pro-MMP-9 activation.

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Fig. 7. Specificity of pM9A. The Triton X-100-insoluble and NaCl-soluble fractions from normal human skin were incubated with purified pro-MMP-2 or pro-MMP-9. The products were resolved by zymogram. Some active 62-kDa MMP-2 was present in the preparation, and that amount was not increased by incubation with the skin fractions.

Correlation of TNF- $alpha$ -mediated Down-regulation of TIMP-1 with the Cytokine-induced Activation of Pro-MMP-9-- As shown in Figs. 2 and 3, pM9A activity is steadily expressed in human skin, and TNF- $alpha$ seemingly has no additional regulatoryeffect on it. On the other hand, TNF- $alpha$ can induce the conversionof pro-MMP-9. Since the activator was not regulated by TNF- $alpha$ ,we hypothesized that the regulation might be at the inhibitorlevel. An important hint came from the effects of TGF- $beta$ , as shownin Fig. 1. TGF- $beta$ induced expression of pro-MMP-9 in normal skinbut has little effect on conversion of pro-MMP-9. However, theTGF- $beta$ -primed skin was capable of proteolytically processing thepro-MMP-9 once the soluble factors were removed (Fig. 2). Thissuggests that skin secrets a pM9A inhibitor and that TNF- $alpha$ , butnot TGF- $beta$ , may down-regulate it, resulting in the activation ofpro-MMP-9. Initially, we considered TIMP-1, because it has beendemonstrated that TIMP-1 can form a complex with pro-MMP-9 throughtheir carboxyl terminus (25, 26). Specifically, we determinedwhether TNF- $alpha$ could regulate TIMP-1. The conditioned medium fromskin stimulated by TNF- $alpha$ and TGF- $beta$ was resolved by Western blotwith monoclonal antibody against human TIMP-1. As expected, TIMP-1protein was steadily expressed at the basal state, and the proteinlevel was decreased by TNF- $alpha$ . TGF- $beta$ alone or in combination withTNF- $alpha$ had no additional effect on the decrease of TIMP-1 (Fig.8A). This profile of TNF- $alpha$ -mediated down-regulation of TIMP-1correlates well with the cytokine-mediated conversion of pro-MMP-9as shown in Fig. 6. In addition, like the putative pro-MMP-9 activationinhibitor, TIMP-1 is mostly distributed as a secreted factor.To further characterize this correlation, we examined the effectsof increasing concentrations of TNF- $alpha$ on both the activation ofpro-MMP-9 and TIMP-1 protein level. Normal human skin was stimulatedwith a range of concentrations of TNF- $alpha$ for 64 h, and the conditionedmedium was analyzed for MMP-9 activation and TIMP-1 protein. Asshown in Fig. 8B, TNF- $alpha$ caused a dose-dependent activation ofpro-MMP-9 with efficient action at 2 nM. The TIMP-1 protein levelwas simultaneously down-regulated by TNF- $alpha$ . Importantly, the cytokine-mediatedactivation of pro-MMP9 and down-regulation of TIMP-1 occurredat similar concentrations. To determine the specificity of thisresult, we also tested for TIMP-2, the inhibitor for MMP-2, andfound that TNF- $alpha$ has no effect on its expression (data not shown).Thus, the experimental evidence indicates that TNF- $alpha$ -mediateddown-regulation of TIMP-1 may participate in the conversion ofpro-MMP-9.

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Fig. 8. Correlation of TNF- $alpha$ -mediated down-regulation of TIMP-1 with the cytokine-induced activation of pro-MMP-9 by human skin. A, normal human skin was cultured in DMEM with TNF- $alpha$ and TGF- $beta$ as indicated. The conditioned medium was resolved by Western blot with monoclonal antibody against human TIMP-1. B, normal human skin was cultured in DMEM with TNF- $alpha$ at the indicated concentration. After culturing for 64 h, the conditioned medium was subjected to zymogram analysis. The conditioned medium and SDS-extracted skin tissue were resolved by Western blot for TIMP-1.

Recombinant TIMP-1 Blocks the Tissue-mediated Activation of Pro-MMP-9-- To confirm the role of TIMP-1 in the activation of pro-MMP-9, we tested whether the purified recombinant TIMP-1 could inhibitthe conversion of pro-MMP-9. To simulate the environment in whichactivation of pro-MMP-9 was initially observed, we added the TIMP-1protein directly to the skin culture together with purified pro-MMP-9as substrate. As shown in Fig. 9A, the skin-mediated activationof pro-MMP-9 was blocked by TIMP-1. At 9 nM, most of the activationwas blocked (Fig. 9A). Further, Triton X-100-insoluble fractionswere incubated with human TIMP-1 together with pro-MMP-9 as substrate.As expected, the TIMP-1 blocked the tissue-bound pM9A-mediatedactivation of pro-MMP-9 (Fig. 9B). These results confirm our hypothesisthat TIMP-1 blocks pro-MMP-9 activation and support our conclusionthat TNF- $alpha$ -induced pro-MMP-9 activation is mediated by down-regulationof TIMP-1.

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Fig. 9. Recombinant TIMP-1 blocks pM9A activity. A, normal human skin was incubated in DMEM with purified pro-MMP-9 as substrate together with the bovine TIMP-1 protein at the indicated concentration. After incubation for 16 h, the product was resolved by zymogram and Western blot. B, normal human skin was extracted by 2% Triton X-100 and the insoluble fractions were incubated with pro-MMP-9 and the recombinant human TIMP-1 at the indicated concentration. After 16 h, the reaction was resolved by zymogram.

	DISCUSSION

TOP ABSTRACT INTRODUCTION EXPERIMENTAL PROCEDURES RESULTS DISCUSSION REFERENCES

In this paper we present for the first time a novel model for the proteolytic activation of pro-MMP-9 in human skin. As shownschematically in Fig. 10, multiple factors, including specificcytokines, a tissue-secreted inhibitor, and a tissue-bound proteinaseparticipate in the regulation of pro-MMP-9 activation in humanskin. In quiescent tissue, very little MMP-9 is expressed, andthe proteinase inhibitor, TIMP-1, is constantly expressed. Duringany inflammatory process, TGF- $beta$ induces the expression of pro-MMP-9.The MMP retains its latency by forming a complex with TIMP-1,which prevents its access to the tissue-associated activator,pM9A. When TNF- $alpha$ is also present, it down-regulates TIMP-1. Thenpro-MMP-9 can be converted by the tissue-associated chymotrypsin-likepM9A. We believe that this model can be extended to the pathogenesisof many inflammation-associated human diseases. Because thesecytokines are present in significant concentrations in diseasessuch as chronic wounds (27-29) and metastatic cancer (30-33), webelieve that these cytokines may be the causal factors for MMP-9expression and activation in these conditions and may ultimatelylead to basement membrane remodeling.

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Fig. 10. A proposed model for pro-MMP-9 activation in human tissue. Based on the evidence presented here and reported previously, we propose a model to explain the induction and activation of pro-MMP-9 in human tissue. A, at basal state, MMP-9 is not expressed in most developed tissues. Conversely, the inhibitor pM9AI, presumably TIMP-1, is constitutively expressed and secreted. B, during inflammation, including wound repair and tumor metastasis, TGF- $beta$ induces the expression of pro-MMP-9. The pro-MMP-9 forms a complex with TIMP-1, and that prevents access to the pM9A, the tissue-associated chymotrypsin-like proteinase. When TNF- $alpha$ is present, it down-regulates the pM9AI/TIMP-1 and thereafter releases pro-MMP-9. The free pro-MMP-9 is converted into 82-kDa enzyme through the tissue-associated pM9A.

MMP-9 has been implicated in the pathogenesis of several different types of diseases. A major biological function for MMP-9has been suggested in the remodeling of the BMZ of the skin, whichis based on its substrate preference for type IV collagen, themajor component in BMZ and type VII collagen, which anchors theBMZ to the dermis (34). The association between nonhealing woundsand MMP-9 is thought to be related to a breakdown of the matrixupon which keratinocytes migrate to reepithelialize the tissue.The best evidence for a role for MMP-9 in BMZ remodeling comesfrom the study of a skin disease called bullous pemphigoid (BP),which is characterized by the separation of the epidermis fromthe dermis at the BMZ and is caused by autoantibodies and complements(35). BP has been reconstituted in a mouse model through injectionof antibodies against BP180, a transmembrane protein anchoringthe basal keratinocytes to BMZ (36). The linkage of MMP-9 toBP has been established by showing the in vitro cleavage of BP180(37). Conclusive evidence for this model comes from the MMP-9-deficientmice, which are resistant to experimentally induced bullous pemphigoid(38).

Our model proposes two distinct components in the biochemical control of MMP-9 activation. One is the tissue-associated chymotrypsin-likeproteinase, the unidentified pM9A. We have characterized muchabout this enzyme, although its specific identity is not yet determined.Based on the inhibition by TPCK and other inhibitors for chymotrypsin,² pM9A is a chymotrypsin-like proteinase. The tight tissue/cellassociation of pM9A suggests interesting possibilities about itsnature. We found that ionized salt such as NaCl can easily dissociatepM9A from tissue, while the nonionized components such as ureaand Triton X-100 failed to do so. This suggests that pM9A maybind to a charged component in skin, which is likely to be anextracellular matrix. The inhibition of aprotinin on pM9A alsosuggests a potential way to purify this protein through the inhibitor-conjugatedchromatography. We anticipate that the initial biochemical characterizationof pM9A presented here will provide the basis for the purificationof this enzyme in the future. Under "Results," we provide compellingevidence showing that candidate proteinases for the pM9A, MMP-3and mast cell chymase, are not likely to be pM9A. We consideredmast cell $alpha$ -chymase as a candidate for pM9A because mast cellsare strongly associated with skin inflammation. At the basal state,this chymase is located intracellularly in granules, and it isreleased by IgE-mediated stimulation. The best evidence to ruleout this chymase as pM9A comes from the extraction experiment;NaCl can extract pM9A but not the chymase, and conversely, ureacan extract the chymase but not pM9A. Two other groups have studieddog mast cell chymase on MMP-9 activation. These studies gavecontradictory conclusions (20, 21, 39). We believe thatthe difference may be due to the nature of substrates used inthose experiments. Taken together, the work presented in thispaper indicates that the mast cell $alpha$ -chymase is not likely tobe the pM9A. Based on in vitro reconstitution experiments, MMP-3was shown to convert pro-MMP-9 (40). In this study, we testedthe role of MMP-3 in pro-MMP-9 activation in human skin and providea clear finding that expression of MMP-3 is not sufficient forMMP-9 activation. In addition, the inhibitor for MMP-3 does notaffect the skin-mediated pro-MMP-9 activation. Finally, MMP-3and pM9A are distributed differently; MMP-3 is secreted, and pM9Ais tissue-bound. Although we believe that we have excluded thesetwo candidates as pM9A, the final conclusive evidence must waituntil the molecular identification of pM9A, which will be thesubject of our futurework.

Initially, we assumed that TNF- $alpha$ -mediated activation of pro-MMP-9 by human skin was through induction of its activator. Toour surprise, the pM9A activities are steadily expressed and notregulated by the cytokines. This led us to a notion that TNF- $alpha$ -mediatedactivation of pro-MMP-9 is probably governed at the inhibitorlevel. We believe that we have identified this inhibitor as TIMP-1.The most compelling single piece of evidence for a pM9A inhibitorcomes from the effects of TGF- $beta$ . In the organ explant experiments,TGF- $beta$ potently induces pro-MMP-9 but fails to promote its activation.However, once the conditioned medium was removed from the explanttissue, the remaining skin tissue could activate pro-MMP-9. Thisindicates that the skin secretes an inhibitor, which in turn preventsthe tissue-associated pM9A from processing pro-MMP-9. This putativepM9A inhibitor should satisfy the following criteria. First, itshould be expressed at basal state and not down-regulated by TGF- $beta$ .Second, it must be down-regulated or sequestrated by TNF- $alpha$ . Third,it must be secreted as a soluble factor. Fourth, down-regulationof the pM9A inhibitor should be linked to the activation of pro-MMP-9,and finally, the accumulation of the inhibitor should block theactivation of pro-MMP-9. We provide evidence in this report thatTIMP-1 meets all of these demands: 1) TIMP-1 is steadily expressedby skin; 2) most of TIMP-1 is secreted as a soluble factor; 3)TNF- $alpha$ down-regulates TIMP-1, and this down-regulation correlateswith activation of pro-MMP-9 in a dose-dependent manner; and 4)when exogenous TIMP-1 is added to skin explant culture, it blocksthe activation of pro-MMP-9. However, whether TIMP-1 is the onlyinhibitor regulated by TNF- $alpha$ is currently unknown to us. Thispossibility will be examined by depletion of TIMP-1 from the conditionedmedium and testing whether the pM9A inhibitor function is alsoeliminated. An additional question we have not yet addressed isthe nature of TNF- $alpha$ -induced down-regulation of TIMP-1; it couldbe achieved at the level of transcriptional suppression or atthe post-transcriptional level such as protein degradation. Thecytokine-induced down-regulation of TIMP-1 is unlikely to occurthrough the sequestration or translocation of the protein, becausewe measured both the secreted and tissue-associated fractions,and the total amount of the inhibitor is down-regulated.

The findings we have reported here show that multiple factors, including specific cytokine, tissue-bound proteinase, and solublefactor, together participate in the activation of pro-MMP-9 inhuman skin. This complexity, with the simultaneous involvementof multiple factors, may explain why others failed to observeMMP-9 activation when utilizing the homogenous cell culture. Infact, we also failed to measure the proteolytic activation byculturing the keratinocytes and dermal fibroblasts (17). Thisis noteworthy in comparison with the activation of pro-MMP-2,which has been demonstrated to involve the membrane type MMP,MT1-MMP (24). A comparison of the primary sequences betweenpro-MMP-9 and pro-MMP-2 shows that they are different at theirN-terminal regions, where the presumed activation cleavage sitesare located. This also indicates that there is a different mechanismfor the activation of these two gelatinases, allowing for differencesin control andregulation.

Finally, we believe that the model we have presented here may be extended to other human tissues besides skin. This modelmay also provide targets for pathophysiological responses in manyinflammation-associated diseases. Blocking the potential linkagebetween inflammation and tumor metastasis by preventing the inductionand activation of MMP-9 may prevent BMZ breakdown, limiting tumorcell migration. Acute liver failure induced by viral hepatitis,alcohol, or other hepatotoxic drugs has been reconstituted byinjection of TNF- $alpha$ into mice (41). In these TNF- $alpha$ -treated mice,MMP-9 was massively induced and proteolytically activated in theliver. However, the cytokine-induced liver failure could be preventedby either knockout of mmp genes or administration of MMP inhibitor.Thus, TNF- $alpha$ -regulated factors such as TIMP-1 and the pM9A, aswe show in this article, may also participate in the liver failure.Taken together, identification of the factors involved in MMP-9expression and activation in human tissue may provide useful targetsfor potential therapeutic treatment of the diseases that involvematrixdegradation.

ACKNOWLEDGEMENTS

We gratefully acknowledge the determination of TNF levels in tissue biopsies by Dr. Dan Remick (University of Michigan). Wethank Dr. Ronald A. Kohanski (Mount Sinai School of Medicine)for valuable comments and editing of this manuscript. We thankDr. Susan Downey (USC) for supplying the humanskin.

	FOOTNOTES

^* This work was supported in part by the Plastic Surgery Education Society and the Wound Healing Foundation (to Y. P. H.) andNational Institutes of Health Grant GM 50967 (to W. L. G.).Thecosts of publication of this article were defrayed in part bythe payment of page charges. The article must therefore be herebymarked "advertisement" in accordance with 18 U.S.C. Section 1734solely to indicate thisfact.

To whom correspondence should be addressed: 1450 San Pablo St., Suite 2000, Division of Plastic and Reconstructive Surgery,Los Angeles, CA 90033. Tel.: 323-442-3856; Fax: 323-442-6477;E-mail: yhan@surgery.usc.edu.

Published, JBC Papers in Press, May 9, 2002, DOI 10.1074/jbc.M202842200

² Y.-P. Han, Y.-D. Nien, and W. L. Garner, unpublisheddata.

ABBREVIATIONS

The abbreviations used are: MMP, matrix metalloproteinase; BMZ, basement membrane zone; TLCK, L-1-chloro-3-(4-tosylamido)-7-amino2-heptanone-HCl; TPCK, L-1-chloro-3-(4-tosylamido)-4-phenyl-2-butanone; DMEM, Dulbecco's modified Eagle's medium; TNF, tumor necrosis factor; TGF, transforming growth factor; pM9A, pro-MMP-9 activator; TIMP, tissue inhibitor of metalloproteinase; BP, bullous pemphigoid.

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Tumor Necrosis Factor--induced Proteolytic Activation of Pro-matrix Metalloproteinase-9 by Human Skin Is Controlled by Down-regulating Tissue Inhibitor of Metalloproteinase-1 and Mediated by Tissue-associated Chymotrypsin-like Proteinase*

Tumor Necrosis Factor- $alpha$ -induced Proteolytic Activation of Pro-matrix Metalloproteinase-9 by Human Skin Is Controlled by Down-regulating Tissue Inhibitor of Metalloproteinase-1 and Mediated by Tissue-associated Chymotrypsin-like Proteinase^*