Tumor Necrosis Factor Receptor Deficiency Alters Matrix Metalloproteinase 13/Tissue Inhibitor of Metalloproteinase 1 Expression in Murine Silicosis

Tumor Necrosis Factor Receptor Deficiency Alters Matrix Metalloproteinase 13/Tissue Inhibitor of Metalloproteinase 1 Expression in Murine Silicosis

LUIS A. ORTIZ, JOSEPH LASKY, EVELYNE GOZAL, VICTOR RUIZ, GIUSEPPE LUNGARELLA, ELEONORA CAVARRA, ARNOLD R. BRODY, MITCHELL FRIEDMAN, ANNIE PARDO, and MOISES SELMAN

Section of Pulmonary Diseases, Critical Care, and Environmental Medicine, Department of Pathology, and the Lung Biology Program, Tulane University Medical Center, New Orleans, Louisiana; Instituto Nacional de Enfermedades Respiratorias, Mexico City, Mexico; Facultad de Ciencias, Universidad Nacional Autónoma de México, Mexico City, Mexico; and Istituto di Patologia Generale, Università di Siena, Siena, Italy

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

Murine exposure to silica is associated with enhanced tumor necrosis factor $alpha$ (TNF- $alpha$ ) expression and matrix deposition. Theregulation of TNF is mediated through TNF receptor (TNFR) activationof transcription factors. In the present work we have studiedthe importance of the individual TNFR in silica-induced lung inflammationand matrix deposition in mice. We studied RNA expression of TNF, $alpha$ 1(I) collagen, interstitial collagenase (MMP-13), and its inhibitor(TIMP-1) in the lungs of silica-treated mice. Furthermore, wecorrelated MMP-13/TIMP-1 RNA abundance with activation of thetranscription factors AP-1 and NF- $kappa$ B in the lungs of C57BL/6 mice,and of mice deficient in one of the two types of TNFR (p55^/ or p75^/), exposed to silica (0.2 g/kg) or saline by intratracheal instillation.Animals were killed 28 d after exposure and lung hydroxyproline(HP), TNF, $alpha$ 1(I) collagen, MMP-13, and TIMP-1 RNA abundance wasmeasured. AP-1 and NF- $kappa$ B activation was studied by gel-shift assays.Compared with C57BL/6 mice, p55^/ and p75^/ mice significantly (*p < 0.05) decreased lung HP accumulationin response to silica. All murine strains enhanced TNF and $alpha$ 1(I)collagen mRNA in response to silica. Enhanced (p < 0.05) MMP-13RNA expression was also observed in all murine strains in responseto silica. Enhanced (p < 0.05) TIMP-1 RNA expression was observedin C57BL/6 mice, but not in p55^/ or p75^/ mice, in response to silica. NF- $kappa$ B activation was observed inall murine strains, whereas AP-1 activation was observed onlyin C57BL/6 mice after silica treatment. These data suggest thatTNFR deletion modifies MMP-13/ TIMP-1 expression in favor of matrixdegradation.

	INTRODUCTION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Murine exposure to silica results in the development of lung inflammation and accumulation of extracellular matrix with characteristicssimilar to the fibroproliferative changes observed in humans afteroccupational exposure (1, 2). The mechanisms responsiblefor the development of silica-induced fibrotic lung injury arenot fully understood but may involve the upregulated expressionof cytokines in the lung (1, 2). Tumor necrosis factor $alpha$ (TNF) has been shown to play an important role in the pathogenesisof silicosis (1, 2). Mice exposed to silica overexpresslung TNF mRNA and show increased TNF production in the lung (3,4). This enhanced TNF expression precedes the onset of fibroblastproliferation and subsequent collagen deposition in the lung (3,4). Neutralization of TNF with anti-TNF antibodies or the administrationof soluble TNF receptors can prevent or diminish the developmentof silica-induced lung fibrosis in mice (3, 5).

The mechanisms by which TNF promotes the accumulation of collagen in the lung of silica-treated mice are not completely understoodand a controversial body of information regarding the effectsof TNF on collagen expression is available (6, 7). In vitrodata suggest that TNF regulates collagen transcription, and TNFhas been shown to induce collagen mRNA expression in culturedhuman fibroblasts (6, 7). However, the effects of TNF oncollagen transcription may be mediated indirectly by upregulatingthe expression of cytokines such as transforming growth factor $beta$ (8).

Although these findings support a profibrotic role for TNF, data also suggest that TNF is capable of inducing matrix remodelingby enhancing the expression of metalloproteinases (9). Silica-exposedrats demonstrate enhanced lung expression of collagenase 3 (MMP-13),a matrix metalloproteinase that degrades mainly fibrillar collagens,and gelatinases A and B (MMP-2 and MMP-9), which are known todegrade type IV basement membrane collagen (10). Therefore,it is possible that TNF can induce extracellular matrix remodelingaffecting both matrix deposition and degradation in response tosilica.

TNF transduces its biologic activities by binding to two receptors of 55 and 75 kDa (11, 12). The trimeric occupationof the TNF receptor by the ligand results in the recruitment ofreceptor-specific proteins that activate kinases and promote theactivation of transcription factors, such as NF- $kappa$ B and AP-1, thatwill induce transcription of TNF-sensitive genes (11, 12).The importance of the TNF receptors in the pathogenesis of silica-inducedlung fibrosis is demonstrated by the fact that mice in which bothof these receptors have been deleted are protected from the inflammatoryand fibrotic effects of silica (13). The contribution of theindividual TNF receptors during silicosis is not wellunderstood.

To study the role of TNF and its receptors in the pathogenesis of lung fibrosis, we evaluated the effect that deletion ofeither TNF receptor (p55 or p75) has on $alpha$ 1(I) collagen, interstitialcollagenase (MMP-13), and tissue inhibitor of metalloproteinases1 (TIMP-1) mRNA expression after silica exposure in mice. We alsocharacterized the activation of the NF- $kappa$ B and AP-1 transcriptionfactors in the lungs of wild-type (silica-sensitive C57BL/6) andTNF receptor-deficient mice, and correlated this activation withchanges in MMP-13 and TIMP-1 mRNA expression in murinelung.

	METHODS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Chemicals

Silica particles were crystalline ( $alpha$ -quartz) and had an average particle size of 1 µm. These particles were filtered and sterilizedat 200° C as previously described (13). Silica suspension wasmade by adding sterile 0.9% NaCl and sonicating immediately beforeintratrachealinstillation.

Animals

Specific pathogen-free female C57BL/6 mice (Charles River Laboratories, Kingston, NY) weighing 20 to 25 g (6-10 wk old) werehoused in pathogen-free cabinets and provided with food, and waterad libitum. Mice deficient in either p55 (p55^/) or p75 (p75^/) TNF receptors were generated at Immunex (Seattle, WA) on a C57BL/6background and have been previously described (Peschon and coworkers[13-15]).

Silica Treatment

Animals were anesthetized with tribromoethanol and then exposed to silica as previously described (13). Briefly, silica(0.2 g/kg; approximately 5 mg per animal) in 0.06 ml of 0.9% NaClwas slowly instilled into the tracheal lumen. Control mice receivedthe same volume of sterile saline. Twenty-eight days after silicaexposure animals were anesthetized, the descending aorta was severed,and the left lungs were removed and stored at $-$ 80° C for RNA andhydroxyprolineanalysis.

Morphology

Right lungs were fixed in situ for 2 h by the intratracheal instillation of 10% neutral formalin at a constant pressure of20 cm H₂O. Lung tissues were then sectioned sagittally and embeddedin paraffin. Sections 4 µm thick were stained with hematoxylin-eosinor Masson trichrome for light microscopicexamination.

Lung Hydroxyproline Content

Lung hydroxyproline concentration was determined spectrophotometrically as previously described (13, 16, 17). Hydroxyprolinecontent was computed as micrograms of hydroxyproline per wholeleftlung.

Northern Analysis

Total RNA was extracted from the lung by a cesium chloride method and Northern analysis was performed as previously described(13, 18). Murine TNF (pMuTNF) and 18S cDNAs were obtainedfrom the American Type Culture Collection (Rockville, MD) andhave been described elsewhere (17, 19). The murine $alpha$ 1(I) procollagenplasmid (pMColla1-I) was graciously provided by E. Vuorio (TurkuUniversity, Turku, Finland) (20).

RT-PCR for MMP-13 and TIMP-1

One microgram of RNA was treated with 1 U of DNase (GIBCO-BRL, Rockville, MD). First-strand cDNA was synthesized by reversetranscriptase (RT). Primers used for polymerase chain reactions(PCRs) were custom synthesized (GIBCO-BRL), and are summarizedbelow.

The set of primers used for the glyceraldehyde-3-phosphate dehydrogenase (GAPDH) PCR was as follows: 5'-CCCCTTCATTGACCTCAACT-3'and 5'-TTGTCATGGATGACCTTGGC-3' with an amplified product of 395bp. MMP-13 nucleotides 5'-CATCCATCCCGTGACCTTAT-3' and 5'-GCATGACTCTCACAATGCGA-3'were used as primers to amplify a 383-bp segment. For TIMP-1 amplificationthe primers 5'-GACCACCTTATACCAGCGTT-3' and 5'-GTCACTCTCCAGTTTGCAAG-3'were used for a fragment size of 333 bp. To quantify the housekeepinggene GAPDH, a competitor was constructed by cutting with NcoIan internal fragment of 155 bp from a GAPDH cDNA. The competitor(cGAPDH) sequence was obtained by PCR amplification of the modifiedplasmid, using the primers for GAPDH. The competitor size was240 bp. Fourfold serial dilutions of the standard competitor (5,20, 50, and 100 pg) were coamplified with a constant amount ofcellular cDNA (1 pg/µl). Cycling conditions were as follows: 95°C/10 min for 1 cycle; 95° C/30 s, 58° C/30 s, and 72° C/ 120 sfor 40 cycles; and a final incubation at 72° C for 7 min. Aliquots(5 µl) of the PCR product were resolved on a 1.5% agarose gelcontaining ethidium bromide. Scanning densitometry (Kodak digitalanalysis system 120; Eastman Kodak, Rochester, NY) quantitatedband intensities. The logarithm of the GAPDH-to-cGAPDH ratio wasplotted as a function of the logarithm of known cGAPDH amount.The point of equivalence represents the concentration of GAPDHin the cDNA sample. For collagenase amplification 5 pg of GAPDHwas used in 35 cycles, and TIMP-1 was amplified with 3 pg of GAPDHin 40cycles.

In Situ Hybridization for MMP-13 and TIMP-1

Riboprobes for in situ hybridization were generated as previously described (21). Rat collagenase cDNA was kindly providedby C. O. Quinn (St. Louis University, St. Louis, MO). Mouse TIMP-1cDNA was provided by D. Edwards (University of East Anglia, Norwich,UK). In situ hybridization was performed on 4-µm sections as previouslyreported, using digoxigenin-labeled riboprobes (21, 22).

Electrophoretic Mobility Shift Assay

Nuclear extracts from the lungs of silica-treated mice were prepared as previously described (23). For retardation assays,NF- $kappa$ B consensus oligonucleotide 5'-GGGGACTTTCCC-3' and AP-1 consensusoligonucleotide 5'-CGCTTGATGACTCAGCCGGAA-3' (Santa Cruz Biotechnology,Santa Cruz, CA) were end labeled with [ $gamma$ -³²P]ATP and T4 polynucleotide kinase (GIBCO-BRL Life Technologies,Gaithersburg, MD). Five micrograms of protein from the crude nuclearextract was mixed with the labeled probe. DNA-protein complexeswere separated on a 6% polyacrylamide gel. Competition assayswere performed with a 400-fold excess of unlabeled probe or NF- $kappa$ Bor AP-1 mutant oligonucleotide (Santa Cruz Biotechnology). Supershiftswere performed by adding to the binding mixture antibodies top50, p65, or c-Jun/AP-1 (Santa Cruz Biotechnology). Densitometricanalysis of the gels was performed with the use of a Gel Doc 2000(Bio-Rad, Hercules,CA).

Statistics

All values are expressed as means + SEM. Differences between murine strains were analyzed by analysis of variance (ANOVA)with the Fisher protected least-squares differences (PLSD) testfor pairwise comparison (StatView 4; Abacus Concept, Berkeley,CA). A p value of < 0.05 was consideredsignificant.

	RESULTS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Silica-induced Lung Injury in Wild-type and Individual TNF Receptor-deficient Mice

Histologic evidence of lung injury was evaluated by light microscopy 28 d after the intratracheal exposure of mice to eithersilica or saline (Figure 1). Saline-exposed wild-type or TNF receptor-deficientmice (either p55^/ or p75^/) demonstrated normal lung histology (not shown). In contrast,silica exposure resulted in the development of peribronchiolarareas of inflammation in the lungs of C57BL/6 mice (Figure 1A).These areas of inflammation formed well-defined nodules consistingof hystiocytes and lymphocyte aggregates that surrounded the terminalbronchioles and vessels (Figure 1B). In contrast to C57BL/6 mice,p55 TNF receptor-deficient mice reacted to silica exposure withan accumulation of acellular, proteinaceous material that filledmany alveolar spaces of the lung (Figure 1C). This proteinaceousmaterial stained positive with periodic acid-Schiff (data notshown) and contained few polymorphonuclear cells (Figure 1D).However, the granuloma-like lesions that were clearly identifiedin C57BL/6 mice (Figure 1A) were largely absent in the lungs ofp55^/ mice (Figure 1C). Well-organized nodules were observed in thelungs of p75 TNF receptor-deficient mice in response to silicaexposure (Figure 1E). However, in contrast to the lesions observedin the lungs of C57BL/6 mice, these were predominantly locatedin perivascular areas of the lung (Figure 1F).

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Figure 1. Silica-induced lung injury in mice. Representative low-power (original magnification, ×100), and high-power (original magnification, ×400) photomicrographs of lungs obtained from wild-type and TNF receptor-deficient mice (p55^/ or p75^/) 28 d after silica exposure: C57BL/ 6 (A and B), p55^/ (C and D), p75^/ (E and F ) (n = 10 mice per murine strain and treatment). Silica-induced granulomatous inflammation is peribronchiolar in C57BL/6 mice and perivascular in p75^/ TNF receptor deficient mice. P55^/ mice demonstrate alveolar filling with proteinaceous material. TB = terminal bronchiole; PL = pleural surface; V = vein. Scale bars: 20 µm.

Lung Collagen Content after Silica Exposure

Lung collagen content was assessed by measuring hydroxyproline from each murine strain 28 d after silica exposure. As depictedin Figure 2, silica exposure significantly increased the hydroxyprolinecontent in the lungs of all groups. There was a 105 ± 3% increasein lung hydroxyproline in C57BL/6 mice (201 ± 14 µg/left lung)compared with saline-treated mice (98 ± 8 µg/left lung) (p < 0.05).Compared with saline-treated animals (80 ± 8 µg/left lung in p55^/ mice and 83 ± 5 µg/left lung in p75^/ mice, respectively) silica exposure also induced significantincreases in the lung hydroxyproline content of TNF receptor-deficientmice (132 ± 5 µg/left lung in p55^/ mice and 118 ± 11 µg/left lung in p75^/ mice, respectively). However, the increases in lung hydroxyprolinecontent in p55^-/- and p75^/ mice were significantly less (66 ± 2 and 42 ± 3%) than in C57BL/6mice (p < 0.05).

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Figure 2. Lung collagen content after silica exposure. Lung hydroxyproline was measured 28 d after a single endotracheal injection of silica. The values are expressed as micrograms of hydroxyproline per left lung. The data represent the mean ± SEM obtained from five animals for each group. *Strains were significantly (p < 0.05) different compared with saline-treated mice. Strains were significantly different (p < 0.05) compared with silica-treated C57BL/6 mice.

$alpha$ 1(I) Collagen and TNF mRNA Expression after Silica Exposure

We studied the possibility that the decreased levels of collagen accumulation in the lungs of TNF receptor-deficient micewere the result of decreased gene transcription. Therefore, westudied, by Northern analysis, the expression of TNF and $alpha$ 1(I)procollagen mRNA in the lungs of C57BL/6 and TNF receptor-deficientmice 28 d after silica exposure. Silica exposure resulted in anenhanced expression of TNF and $alpha$ 1(I) procollagen mRNA in the lungsof both C57BL/6 and individual TNF receptor-deficient mice (datanotshown).

Interstitial Collagenase 3 and TIMP-1 RNA Expression in Murine Lung after Silica Exposure

Lung expression of interstitial collagenase MMP-13 mRNA and its inhibitor (TIMP-1) mRNA was studied by PCR 28 d after silicaexposure (Figure 3A). Figure 3B illustrates the densitometricanalysis (measured in arbitrary units) of the expression of interstitialcollagenase mRNA in the lungs of C57BL/6 and individual TNF receptordeficient mice exposed to silica. Compared with saline-treatedmice (C57BL/6, 1.5 ± 0.95 AU × 10⁴; p55^/, 1.1 ± 0.9 AU × 10⁴; p75^/, 1.7 ± 0.9 AU × 10⁴), silica exposure significantly (p < 0.05) increased the expressionof interstitial collagenase in the lungs of all the murine strains(C57BL/6, 3.1 ± 0.4 AU × 10⁴; p55^/, 2.6 ± 0.7 AU × 10⁴; p75^/, 3.3 ± 0.7 AU × 10⁴) (p < 0.05). However, no differences were found in MMP-13 expressionbetween the wild-type and both strains of TNF receptor-deficientmouse.

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Figure 3. Collagenase 3 (MMP-13) and TIMP-1 mRNA expression in murine lung after silica exposure. (A) Agarose gel electrophoresis of PCR products. Total lung RNA was isolated, reverse transcribed, and amplified in 35 (MMP-13) and 40 (TIMP-1) PCR cycles (as described in METHODS) from mouse lung 28 d after silica exposure. (B) A significant increase in collagenase 3 mRNA expression was observed in all silica exposed mice. *Strains were significantly different (p < 0.05) when compared with control-treated mice. (C) Silica induced significant increases in TIMP-1 mRNA expression only in wild-type (C57BL/6) mice. *Strain was significantly different (p < 0.01) when compared with TNF receptor-deficient mice.

Figure 3C illustrates the expression of TIMP-1 mRNA in the lungs of C57BL/6 and individual TNF receptor-deficient mice exposedto silica. Compared with control mice (C57BL/6, 4.2 ± 0.3 AU ×10⁴; p55^/, 5 ± 1.1 AU × 10⁴; p75^/, 3.2 ± 0.6 AU × 10⁴) silica exposure resulted in significant increases (p < 0.05)in TIMP-1 mRNA expression in the lungs of C57BL/ 6 mice (8.2 ±1.6 AU × 10⁴; p < 0.05), but not in the lungs of p55^/ (6.2 ± 1.2 AU × 10⁴) or p75^/ (4.5 ± 0.7 AU × 10⁴)mice.

In Situ Hybridization for Interstitial Collagenase (MMP-13) and TIMP-1 in Murine Lungs

We studied the localization of MMP-13 and TIMP-1 mRNAs in the lungs of silica-treated C57BL/6 and individual TNF receptor-deficient,mice using digoxigenin-labeled riboprobes. Figure 4 illustratesthe hybridization signal for MMP-13 mRNA in the lungs of saline-and silica-treated mice. Silica exposure resulted in overexpressionof MMP-13 in the lungs of C57BL/6 mice (Figure 4A), and in bothstrains of TNF receptor-deficient mice (Figures 4B and 4C). Insidesilicotic nodules, MMP-13 signal was primarily observed in thecytoplasm of macrophages (Figure 4E). In addition, alveolar epithelialcells and alveolar macrophages located in the neighborhood ofthe granulomatous lesions showed intense cytoplasmic labeling(Figures 4F and 4G). In saline-treated mice the expression ofMMP-13 was limited to bronchiolar cells and scattered free alveolarmacrophages (Figures 4H-4J). The specificity of the hybridizationsignal was demonstrated by the absence of signal with the useof a sense riboprobe (Figure 4D).

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Figure 4. In situ hybridization for MMP-13 in murine silicosis. (A-J) Light photomicrographs of C57BL/6 and TNF receptor-deficient (p55^/ or p75^/) mouse tissue after hybridization with digoxigenin-labeled MMP-13 riboprobe. (A) Collagenase 3 transcript signal was detected in silicotic nodules and surrounding parenchyma in C57BL/6 mice (original magnification, ×10). (B and C ) Silica also upregulated MMP-13 expression in both TNF receptor-deficient mice (B, p55^/; C, p75^/) (original magnification, ×10). (D) No signal was observed when lungs were hybridized with sense riboprobe (original magnification, ×10). (E ) Higher magnification showing positive macrophages inside a silicotic nodule (original magnification, ×100). (F and G) In the neighborhood of silicotic nodules, alveolar epithelial cells (F ) and alveolar macrophages (G) showed intense labeling (arrows; ×100). (H ) Saline-exposed wild-type mouse tissue showing positive bronchiolar epithelial cells (arrowhead; original magnification, ×40). (I ) Saline-treated p55^/ mouse tissue exhibiting labeled bronchiolar cells (arrowhead ) and macrophages (arrow; original magnification, ×40). ( J ) Saline-treated p75^/ mouse tissue showing some positive free alveolar macrophages (double arrowhead; original magnification, ×40). Slides were counterstained with hematoxylin.

Figure 5 depicts the localization, by in situ hybridization, of TIMP-1 mRNA in the lungs of C57BL/6 and individual TNF receptor-deficientmice. Silica exposure resulted in TIMP-1 mRNA expression in granuloma-likelesions in wild-type and both strains of TNF receptor-deficientmice (Figures 5A-5C). An intense staining was noticed in the silicoticnodules as well as in epithelial and inflammatory cells of theneighboring areas of C57BL/6 mouse lungs (Figure 5A). In saline-treatedmice, expression of TIMP-1 mRNA was primarily observed in bronchiolarepithelial cells (Figures 5E-5G). Control experiments using senseriboprobe displayed no reactivity (Figure 5D).

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Figure 5. In situ hybridization for TIMP-1 in murine silicosis. (A-G) Light photomicrographs of C57BL/6 and TNF receptor-deficient (p55^/ or p75^/) mouse tissue after in situ hybridization with a digoxigenin-labeled riboprobe for TIMP-1. (A) Silica exposure enhanced TIMP-1 mRNA expression in granulomatous-like lesions of C57BL/6 mice. (B and C ) TIMP-1 hybridization signal in the lungs of TNF receptor-deficient mice (B, p55^/; C, p75^/). The specificity of the hybridization signal was demonstrated by the absence of signal with the use of a sense riboprobe (D). (E ) Saline-exposed wild-type mouse tissue showing labeled bronchiolar epithelial cells and macrophages (original magnification, ×40). (F ) Saline-treated p75^/ mouse exhibiting stained bronchiolar cells (original magnification, ×40). (G) No signal was observed in the alveolar epithelia and septa as exemplified in this lung section from a p55^/ mouse. Slides were counterstained with hematoxylin.

Transcription Factor Activation in Murine Lung after Silica Exposure

To further understand the mechanisms involved in the modification of silica-induced MMP-13 and TIMP-1 mRNA upregulation inTNF receptor-deficient mice, we studied the activation of thetranscription factors NF- $kappa$ B (Figure 6) and AP-1 (Figure 7) inthe lungs of C57BL/6 and individual TNF receptor-deficient mice.Silica exposure resulted in significantly enhanced (p < 0.05)NF- $kappa$ B activation in the lungs of C57BL/6 and in both p55 and p75TNF receptor-deficient mice 28 d after exposure (Figures 6A and6B, respectively). The observed NF- $kappa$ B binding could be competedby a nonlabeled NF- $kappa$ B oligonucleotide. The use of an antibodyspecific to the p50, but not the p65, subunit of NF- $kappa$ B causeda shift of the NF- $kappa$ B complexes. In contrast, silica exposure resultedin significant (p < 0.05) AP-1 activation in the lungs of C57BL/6mice. This response was significantly decreased in the lungs ofindividual TNF receptor deficient mice (Figures 7A and 7B). Useof antibodies against AP-1 depleted the corresponding AP-1 band,confirming AP-1-binding specificity.

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Figure 6. NF- $kappa$ B activation in murine lung after silica exposure. (A) DNA-binding activity of NF- $kappa$ B in crude nuclear extracts from whole lung isolated from C57BL/6, and individual TNF receptor-deficient, mice 28 d after silica exposure. Cold $kappa$ B represents NF- $kappa$ B binding in lung nuclear extract of a C57BL/6 silica-treated mouse, assayed in the presence of excess unlabeled oligonucleotide as a competitor. Antibody supershifts were performed with the nuclear extract of a C57BL/6 silica-treated mouse as described in METHODS. (B) Densitometry analysis of gel shifts as described in METHODS. Values represent means ± SEM. Gel is representative of four experiments. *Significantly different (p < 0.05) compared with saline-treated animals.

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Figure 7. AP-1 activation in murine lung after silica exposure. (A) DNA-binding activity of AP-1 in crude nuclear extracts from whole lung isolated from C57BL/6, and individual TNF receptor-deficient, mice 28 d after silica exposure. Cold AP-1 represents AP-1 binding in lung nuclear extract of a C57BL/6 silica-treated mouse, assayed in the presence of excess unlabeled oligonucleotide as a competitor. Antibody supershifts were performed with the nuclear extract of a C57BL/6 silica-treated mouse as described in METHODS. (B) Densitometry analysis of gel shifts as described in METHODS. Values represent means ± SEM. Gel is representative of four experiments. *Significantly different (p < 0.05) compared with saline-treated animals. Significant different (p < 0.05) compared with silica-treated C57BL/6 mice.

	DISCUSSION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

TNF and its receptors play a fundamental role in the pathogenesis of silicosis (3, 5). Silica induces oxidative stressin the lung, with an enhanced production of reactive oxygen speciesthat upregulates the TNF promoter (24, 25). Once produced,TNF mediates its biologic activities by binding to its two knownreceptors (11, 12). The 55-kD receptor contains a cytoplasmicdeath domain that signals cytotoxic effects and triggers NF- $kappa$ Bactivation (26, 27). The 75-kD receptor similarly mediatesNF- $kappa$ B activation, triggers cell proliferation, and in murine modelsof lung injury modulates TNF-mediated inflammation (11, 15,26). The importance of the TNF receptors in the pathogenesisof fibrogenic lung disease has been demonstrated in mice in whichboth of these receptors have been deleted. These animals are protectedfrom the inflammatory and fibroproliferative effects of silica(13). However, the contribution of the individual receptorsto the pathogenesis of the disease process is poorlyunderstood.

In the present work we found that deletion of either one of the TNF receptors (p55 or p75) modifies the nature of the inflammatoryresponse observed in the lungs of wild-type (C57BL/6) mice. C57BL/6mice are silica sensitive, demonstrating enhanced TNF expressionin their lungs, and developing inflammation and fibrosis in responseto silica (4, 13). The characteristic lesion observed inthe lungs of silica-treated C57BL/6 mice is the development ofwell-formed nodules of peribronchiolar predominance (Figure 1B).In the present work it was found that deletion of either one ofthe TNF receptors (p55 or p75) resulted in histologic differencesin the formation of these lesions. Thus, the characteristic nodularlesion was observed less frequently in p55 TNF receptor-deficientmice, and although p75 receptor-deficient animals did form granuloma-likenodules in response to silica, their location were predominantlyperivascular (Figure 1D). These data suggest a possible role forthe p55 TNF receptor in the formation of granulomas in responseto silica. Similar results have been observed in the liver ofBCG-challenged p55 TNF receptor-deficient mice. In these micea decreased granulomatous response to BCG was demonstrated (28).

An important observation of the present work is that the deletion of TNF receptors significantly decreased the accumulationof collagen in comparison with the lungs of C57BL/6 silica-treatedmice. This result should be the consequence of changes in collagenturnover either by decreased collagen production and/or increasedcollagen degradation. The effects of TNF on collagen expressionare complex and TNF has been shown both to promote and inhibitcollagen production in vitro (6, 7). Alveolar macrophages,retrieved from the lungs of asbestos-exposed patients, releaseTNF that promote upregulation of the collagen gene when addedto human fibroblasts (6, 7). In vivo studies have demonstratedthat overexpression of TNF in the lungs of rats (transfer of TNFcDNA via adenovirus infection) or mice (transgenic mice overexpressingTNF) is followed by the development of inflammation and the accumulationof collagen in the lung (8, 29). However, these studies didnot evaluate in a direct manner the impact of TNF on collagenaccumulation and, therefore, it is not clear whether TNF overexpressionenhanced lung collagen synthesis or decreased collagen degradation.Interestingly, Piguet and associates demonstrated that the administrationof anti-TNF antibodies to normal adult mice decreased lung andbone collagen content without altering collagen mRNA levels (30).In addition, these authors reported that treatment of mice withanti-TNF antibodies or soluble TNF receptors can prevent the depositionor promote the resorption of collagen in the lungs of silica-treatedmice (3, 5). Our finding of decreased lung collagen accumulationin response to silica in TNF receptor-deficient mice cannot beexplained by changes in lung collagen transcription, because nodifferences in $alpha$ 1(I) procollagen mRNA were found. In contrast,our data strongly suggest that the observed reduction in collagendeposition in the lungs of individual TNF receptor-deficient micecould be better explained by an enhanced degradation of lungcollagen.

Matrix metalloproteinases (MMPs) are a family of secreted or transmembrane zinc-dependent endopeptidases that are capableof degrading virtually all extracellular matrix and basement membranescomponents. On the basis of their substrate affinity and structuraldomains, MMPs have been classified as collagenases, gelatinases,stromelysins, and membrane-type metalloproteinases (31). MMPproduction and activity are highly regulated at different levels.In general, basal transcription in normal adult tissues is lowbut MMPs are upregulated by a variety of factors at transcriptional,posttranscriptional, and posttranslational levels as well as bythe interaction of the secreted enzymes with their tissue inhibitors(TIMPs) (33, 34).

Silica has been shown to upregulate MMP expression both in vitro and in vivo (9, 10). Pérez-Ramos and coworkers showedin a rat model of silicosis that early silicotic granulomas exhibitedintense staining for collagenase 3 and gelatinases A and B, andfor TIMP-1 and TIMP-2. However, in late, highly fibrotic nodulesMMP signals were scarce. As TIMPs showed only a moderate reductionin late silicotic nodules, compared with MMPs, the findings suggestedthat an imbalance in the expression of MMPs and TIMPs might beimplicated in extracellular matrix remodeling and basement membranedisruption during experimental lung silicosis (10). However,in this study, MMP and TIMP levels were notquantified.

In the present study, we found an enhanced gene expression of MMP-13, which degrades mainly fibrillar collagens, and its inhibitorTIMP-1 in the lungs of silica-sensitive C57BL/6 mice. Most importantly,TIMP-1, but not collagenase, mRNA expression was significantlylower in the lungs of both types of TNF receptor-deficient micecompared with wild-type mice. Because collagenase activity dependson a tight balance between the expression of the active enzymeand its inhibitors, these data suggest that the absence of eitherof the TNF receptors promotes matrix degradation by effectivelydecreasing the overexpression of TIMP-1.

TIMP-1 is a multifunctional molecule that inhibits matrix metalloproteinase activity and promotes the proliferation of receptivecells. Thus, any reduction in TIMP expression is likely to leadto a higher level of collagenase activity, thus facilitating collagenbreakdown, but also may influence fibroblast proliferation. Themechanisms responsible for the regulation of MMPs and their inhibitorsin silicosis are not well known. TNF induces collagenase productionby fibroblasts and endothelial and leukemic cells (9, 35).This effect of TNF on MMP expression appears to be transduced,at least in human dermal fibroblasts, by the p55 TNF receptor(37, 38).

The TNF-mediated signal transduction pathways involved in the regulation of MMPs and TIMPs in silicosis are unknown at thistime. Studies looking at the transcription level of the MMPs andtheir inhibitors suggest that the predominant regulation of theirrespective promoters is mediated by AP-1 (39- 41). Most publisheddata regarding TNF activation of AP-1 indicate that it is mediatedvia the p55 TNF receptor, whereas NF- $kappa$ B activation can be signaledby either of the TNF receptors (26). Our results demonstratedthat each type of TNF receptor is competent to induce overexpressionof MMP-13 RNA in mouse lung in response to silica exposure. Wealso found that in response to silica exposure wild-type (C57BL/6)mice enhanced the activation of both transcription factors, NF- $kappa$ Band AP-1. In contrast to C57BL/6 mice, TNF receptor-deficientanimals demonstrated only enhanced activation of NF- $kappa$ B, and exhibiteda greatly decreased activation of AP-1 in their lungs in responseto silica exposure. These data may suggest a role for NF- $kappa$ B inthe regulation of MMP-13. Interestingly, in collagen-induced arthritisin mice, the expression of both AP-1 and NF- $kappa$ B increased collagenase3 gene expression, although a better correlation was observedwith NF- $kappa$ B activation (42).

Murine TIMP-1 gene is expressed by most cells at a low basal level, and during acute remodeling its transcription is activatedby a variety of stimuli. TIMP-1 has also been shown to be upregulatedby TNF. A nonconsensus AP-1-binding site (5'-TGAGTAA-3') thatis conserved in mammalian TIMP-1 genes has been shown to be acritical element in basal and serum-stimulated transcription (43).In our findings, the decreased AP-1 activation observed in thelungs of individual TNF receptor-deficient mice correlates wellwith their decreased TIMP-1 lung RNA expression, suggesting thatAP-1 may play a role in the regulation of TIMP-1 expression. However,these results might be the reflection of altered populations ofinflammatory cells in the lungs from the different murine strainsrather than specific changes in the level of activation of AP-1.Therefore, further analyses performed in specific lung cell populationsin which the changes in both AP-1 activity and TIMP-1 transcriptioncan be localized to the same cell type are necessary to establishthis regulation. Further studies evaluating the transcriptionregulation of MMPs and their inhibitors in the lungs of TNF receptor-deficientmice are necessary to understand the importance of TNF receptorsin lunginjury.

	Footnotes

Correspondence and requests for reprints should be addressed to Luis A. Ortiz, M.D., Section of Pulmonary Diseases, Critical Care, and Environmental Medicine, Department of Medicine SL9, Tulane University Medical Center, New Orleans, LA 70112-2699. E-mail: lortiz{at}mailhost.tcs.tulane.edu

(Received in original form February 23, 2000 and in revised form July 26, 2000).

Acknowledgments: The authors thank Drs. J. Peschon, A. Holian, O. Quinn, and D. Edwards for their generous gift of TNF receptor-deficient mice,silica particles, MMP-13, and TIMP-1 cDNA, respectively, and Mrs.Mary Chelles and Boioang Tonthat, respectively, for technicalassistance in the preparation of lung tissues and Northernanalysis.

Supported by NIH grants HL 03569 (to L. A. Ortiz), HL 03374 (to J. A. Lasky), and ES 08663 (to M.Friedman).

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