Collagenase production by primary cultures of rat uterine cells. Partial purification and characterization of the enzyme

Serotonin-induced MMP-13 production is mediated via phospholipase C, protein kinase C, and ERK1/2 in rat uterine smooth muscle cells

Serotonin (5-hydroxytryptamine; 5-HT), acting via the 5-HT(2A) receptor, up-regulates the transcription and production of interstitial collagenase (matrix metalloproteinase-13; MMP-13), a critical enzyme responsible for maintaining the integrity of the uterus, after parturition. Serotonin treatment of rat uterine myometrial smooth muscle cells induced inositol phosphate (IP) turnover, which was abolished by the 5-HT(2A) receptor-specific antagonists ketanserin and spiperone. The phospholipase C (PLC) inhibitors and D609 attenuated serotonin-mediated-IP turnover with a corresponding inhibition of MMP-13 protein production. Subsequent recovery of both MMP-13 protein expression and IP generation was seen following the removal of D609. Protein kinase C (PKC) activators, the diacylglycerol analogue 1,2-dioctanoyl-sn-glycerol and phorbol myristate acetate (PMA), mimicked the effect of serotonin on MMP-13 protein expression; prolonged PMA treatment (which down-regulates PKC) lowered MMP-13 protein levels. The PKC-specific inhibitors bisindolylmaleimide I, calphostin C, CGP 41251, and the PKCdelta-selective inhibitor rottlerin were able to suppress serotonin up-regulation of MMP-13. Furthermore, the mitogen-activated protein kinase kinase (MEK) inhibitor PD98059 blocked serotonin-dependent activation of p44/42 MAPK (pERK1/2), a downstream effector of PKC and also down-regulated MMP-13 protein expression. Similarly, calphostin C and rottlerin depressed activation of p44/42 MAPK. From these studies, serotonin, binding through the 5-HT(2A) receptor, initiates a signaling cascade whereby stimulation of PLC leads to the activation of PKC and subsequently the ERK1/2 pathway, which ultimately results in MMP-13 production.

Localization and regulation of IL-1alpha in rat myometrium during late pregnancy and the postpartum period

Interleukin-1 (IL-1) has been implicated as a participant in preterm labor that is induced by bacterial infection. Previously, we showed that serotonin-induced production of IL-1alpha by myometrial smooth muscle cells in vitro is also essential for the synthesis of interstitial collagenase. It is therefore likely that IL-1alpha production in uterine tissues has implications for both the normal physiology of involution and for the pathophysiological mechanisms of preterm labor. The objective of this study was to characterize the serotonin-induced production of IL-1alpha by myometrial cultures in vitro and to assess the production of IL-1alpha and its relationship to collagenase production in vivo during pregnancy and the postpartum period. Immunohistochemistry demonstrated IL-1alpha protein in the nuclei and cytoplasm of serotonin-treated myometrial cells. IL-1alpha levels were decreased by treatment with progesterone or IL-1-receptor antagonist but were unaffected by lipopolysaccharide. Western analysis of myometrium from pregnant rats showed low levels of IL-1alpha during midpregnancy with increased concentrations at days 21 and 22 and postpartum. IL-1alpha mRNA levels also increased from days 15 to 22. Levels of mRNA for IL-1beta also increased, although to a lesser degree than IL-1alpha. Both mRNAs decreased postpartum. Conversely, mRNA for interstitial collagenase was barely detectable at term but increased postpartum. Together, these data show that serotonin stimulates IL-1alpha production in vitro and indicate that normal myometrium from pregnant rats is an identifiable source of IL-1 during late pregnancy. The findings are consistent with the possibility that myometrial IL-1alpha participates in normal labor as well as the postpartum production of interstitial collagenase.

Progesterone mediates decreases in uterine smooth muscle cell interleukin-1alpha by a mechanism involving decreased stability of IL-1alpha mRNA

The regulation, by progesterone, of serotonin-induced interleukin-1alpha production was studied in primary cultures of rat uterine smooth muscle cells. Prior reports from this laboratory have demonstrated that these cells produce IL-1alpha and IL-1beta mRNAs in response to the hormonal action of serotonin. Results of the present study indicate that treatment of myometrial smooth muscle cells with medroxyprogesterone acetate (MPA) results in a marked decrease in IL-1alpha protein as measured by western blot analysis. These decreases occur even in the presence of maximally-inducing concentrations of serotonin. MPA-mediated changes in IL-1alpha protein are characterized by a rapid decline in IL-1alpha mRNA levels. This inhibition by medroxyprogesterone also occurs when cells are stimulated to produce IL-1alpha by PMA rather than serotonin. Thus, when cells are cultured in the presence of both inducer and inhibitor, the inhibitor, progesterone, clearly dominates in the control of IL-1alpha expression. This effect is concentration-dependent, can be mimicked by native progesterone or glucocorticoids, but is unaffected by estradiol. The ability of progestins to decrease IL-1alpha mRNA is blocked by both inhibitors of transcription and translation and by treatment with RU-486. Progesterone had no effect on chloramphenicol acetyl transferase (CAT) transcription from two different IL-1alpha promoter constructs, indicating that progesterone's action appears to be dependent on post-transcriptional rather than transcriptional regulation. Conversely, progesterone accelerated the normal rate of decay of IL-1alpha mRNA that occurs following the removal of serotonin from the cultures. These results suggest that progesterone decreases IL-1alpha levels by stimulating the production of an intracellular intermediate that decreases the stability of IL-1alpha mRNA.

Serotonin-inducible transcription of interleukin-1alpha in uterine smooth muscle cells requires an AP-1 site: cloning and partial characterization of the rat IL-1alpha promoter

Interleukin-1 has been shown to contribute to infection-induced inflammatory processes during pregnancy. Prior work from this laboratory has demonstrated that serotonin-induced IL-1alpha also is required for the in-vitro production of collagenase in uterine smooth muscle cells, a normal, non-inflammatory process that occurs in-vivo during post-partum uterine involution. To understand the molecular mechanisms that regulate transcription of the IL-1alpha gene in these cells, we isolated and characterized 1.6 kilobases of the 5'-flanking region of the rat IL-1alpha gene. Sequencing and primer extension identified a single transcription start site and multiple potential regulatory elements, including a TATA box at - 30 bp, a CAAT box at - 74 bp, and a conserved AP-1 site at - 9 bp. This 5'-flanking DNA exhibited low basal promoter activity that was inducible by serotonin. Serotonin-induced promoter activity was unaffected or induced by either medroxyprogesterone or IL-1 receptor antagonist. This occurred despite the ability of both of these hormones to markedly decrease IL-1alpha mRNA. Deletional analysis revealed a strong repressor in the region between - 147 and - 98 bp; removal of this sequence resulted in a fivefold higher basal promoter activity that was still serotonin responsive. Constitutive promoter activity appeared to reside between - 97 and - 22 bp. Deletion of this promoter region, which contained the TATA and CAAT boxes and an NF-IL-6/PEA-3 site, resulted in decreased basal transcriptional activity to the low level seen in larger constructs. Mutational analysis showed that serotonin-inducible transcriptional activity was mediated, at least in part, by the conserved AP-1 site at - 9 bp. This site is located within a larger extended palindromic region: 5'-AAGCCTGACTCAGACTT-3', that together effects both the basal and serotonin-inducible expression of the IL-1alpha gene.

Serotonin-mediated production of interstitial collagenase by uterine smooth muscle cells requires interleukin-1alpha, but not interleukin-1beta

The activation of the gene for interstitial collagenase in myometrial smooth muscle cells is absolutely dependent upon the presence of serotonin. Our previous studies investigating the mechanisms of this induction demonstrated that the mRNAs of both interleukin-1 (IL-1) isoforms, IL-1alpha and IL-1beta, are induced by serotonin and that the induction of IL-1 is required for the subsequent induction of collagenase. These data provided compelling evidence that serotonin-induced IL-1 acts via an autocrine loop in activating the collagenase gene. The experiments described here were designed to examine the potential role of each IL-1 isoform in collagenase production by using neutralizing antisera specific to each isoform of the cytokine. The antisera were examined for their ability to inhibit the serotonin-dependent production of the mRNA for collagenase and of the cytokines themselves. Neutralizing antiserum against IL-1alpha, but not against IL-1beta, inhibited the induction of the mRNA for collagenase and of the mRNAs for both IL-1alpha and IL-1beta. Western analysis indicated that detectable levels of IL-1alpha protein, but not that of IL-1beta, are produced at the time of serotonin-dependent collagenase induction. In contrast, significant levels of IL-1beta protein are detected only when bacterial lipopolysaccharide is added to the cells. Taken together, the results of our study indicate that IL-1alpha, but not IL-1beta, plays an obligatory role in multiple serotonin-mediated gene regulations in the myometrial smooth muscle cell. In addition, the data suggest that IL-1beta production has the potential for modifying myometrial function in pathological settings, particularly that of uterine infection.

Serotonin regulates the expression of the gene for alpha2-macroglobulin in myometrial smooth muscle cells

Serotonin (5-hydroxytryptamine (5-MT)) has been shown to be a regulator of gene expression in rat myometrial smooth muscle cells (SMC). Serotonin activates the genes for interstitial collagenase, interleukin-1alpha, -1beta and interleukin-6, among others. On the other hand, serotonin down-regulates the genes for types I and III collagen and fibronectin. Here we show that serotonin is also a negative regulator of the expression of anti-protease alpha2-macroglobulin (alpha2M) in SMC. The serotonin-dependent repression occurs at both the mRNA and protein levels, and is mediated by the 5-HT2A receptor subtype. The inhibitory effect is prevented by cycloheximide, indicating the requirement for the synthesis of one or more proteins. Interleukin-1 (IL-1), which is induced by serotonin in SMC and is required for subsequent interstitial collagenase induction, appears not to be one of these intermediates. On the other hand, progesterone, the major steroid hormone of pregnancy, is capable of reversing the serotonin-mediated inhibition of alpha2M. The phorbol myristate acetate (PMA), which mimics the induction of interstitial collagenase by serotonin, fails to affect the inhibition of alpha2M production. The cell-permeable cyclic AMP analogue 8-bromoadenosine 3':5'-cyclic monophosphate sodium salt (8-bromo-cAMP), is, however, capable of fully reproducing the action of serotonin on alpha2M. These results further speak to the ability of serotonin to regulate gene expression in the myometrial SMC, both positively and negatively. In addition, although all the effects of serotonin so far identified are mediated by the 5-HT2A receptor, different post-receptor pathways appear to mediate the positively and negatively regulated genes.

Serotonin regulation of gene expression in uterine extracellular matrix: reciprocal effects on collagens and collagenase

The regulation of collagen gene expression by serotonin was investigated in rat uterine smooth muscle cells. Serotonin treatment of myometrial cells caused decreases of up to 10-fold in levels of type I collagen mRNA. Decreases in secreted type 1 collagen protein paralleled decreases in collagen mRNA. The effective half-life of collagen mRNA in serotonin-treated cells was approximately 1.7 days. Selective 5-HT2 receptor agonists mimicked the effects of serotonin, while the effects of serotonin were blocked by 5-HT2 antagonists. Nuclear run-on analysis showed that serotonin-dependent decreases in collagen mRNA are accompanied by decreased transcription. Progesterone analogs, which inhibit the serotonin-dependent activation of the gene for interstitial collagenase, had no effect on the ability of serotonin to decrease collagen mRNA. Conversely, the cell-permeable cAMP analog, 8-bromo-cAMP, mimicked the effects of serotonin on type I collagen mRNA and protein. Serotonin also decreased levels of the mRNAs for type III collagen and fibronectin, but had no effect on the mRNAs for type IV collagen. These results indicate that serotonin, previously shown to upregulate the interstitial collagenase gene, downregulates the gene for type I collagen and other extracellular matrix proteins, possibly by a novel mechanism of action downstream of 5-HT2 receptor binding.

Regulation of uterine collagenase gene expression: interactions between serotonin and progesterone

This report seeks to further define the requirements for the previously established induction of collagenase gene expression by serotonin and inhibition by progesterone in primary cultures of rat uterine smooth muscle cells. Detectable increases in collagenase production were observed after as little as 3 h exposure of cells to 5 microM serotonin, with maximal induction occurring after approximately 8 h of exposure. The apparent half-life of collagenase mRNA upon removal of serotonin was estimated to be approximately 12 h, and was not dependent on the duration of induction. Inhibition by either cycloheximide or progesterone showed similar half lives for collagenase mRNA, however a much shorter half-life (6 h) was obtained in the presence of actinomycin D. These experiments suggest that neither serotonin induction nor progesterone inhibition of collagenase synthesis represents a primary effect on collagenase gene transcription. Rather they appear to be secondary to changes that occur at one or more primary intermediate genes whose induction or decay must occur prior to changes in collagenase transcription. The progesterone receptor antagonist, RU-486, abrogates the ability of progesterone to inhibit serotonin-induced collagenase gene expression, indicating that the effects of progestins in this system likely are receptor-mediated. Finally, the present studies demonstrate that pretreatment of cells for times as long as 5 days with medroxyprogesterone in the absence of serotonin is unable to prevent subsequent serotonin-induced collagenase mRNA increases. These data suggest the possibility of a unique interaction between the molecular pathways of inducer and inhibitor, one in which serotonin may help mediate the progesterone-dependent repression of the levels of collagenase mRNA.

Serotonin: an inducer of collagenase in myometrial smooth muscle cells

Rat myometrial smooth muscle cells in culture actively produce collagenase in medium containing fetal bovine serum, but not in medium containing newborn bovine serum or containing fetal serum adsorbed with dextran-coated charcoal. A dialyzable molecule has been isolated from fetal bovine serum, which restores the ability of the smooth muscle cells to produce collagenase. The molecule has been purified and identified as serotonin (5-hydroxytryptamine). Cells cultured in medium depleted of serotonin for 3 days fail to produce collagenase, as assessed both enzymatically and immunologically. Addition of serotonin promptly restores the ability of the cells to produce the enzyme. The EC50 for serotonin is approximately 2 microM; maximum stimulation of collagenase production is observed at 5 microM. The response is specific for serotonin: a wide variety of compounds tested, either related to serotonin or of potential reproductive significance, were without effect in the induction of collagenase production by the cells. No changes in DNA content, general protein synthesis, or cellular collagen production were observed as a consequence of serotonin depletion or restoration, suggesting a selective effect of the compound on collagenase production. The effect of serotonin was also selective to myometrial smooth muscle cells; collagenase-producing fibroblasts from skin and cervix displayed no serotonin requirement for enzyme production. Studies using specific agonists or antagonists for a variety of serotonin receptor subtypes suggest that the 5-HT-2 receptor mediates the serotonin induction of collagenase in these cells. Preliminary evidence indicates that cultured human myometrial smooth muscle cells are also dependent upon serotonin for collagenase production. The evidence in this study suggests the possibility that serotonin serves as a signal to begin the massive collagen degradation that occurs in the postpartum uterus.

Collagenase activity in the normal rat myocardium. An immunohistochemical method

Fibrillar collagen in the myocardium provides a supportive framework for myocytes and capillaries. Disruption of this organized framework has been observed in certain pathological states. Collagen degradation is primarily mediated by the specific enzyme collagenase, which has been found to exist in various tissues including the myocardium. In this report we describe a method that detects collagenase activity in sections of cardiac tissue. This method is on the basis of degradation of collagen by collagenase on one hand and the visualization of disrupted collagen fibers by immunofluorescence on the other. Frozen rat heart sections were incubated under optimal conditions for collagenase activity (37 degrees C in the presence of 0.1 M calcium at pH 7.4) for 24 h and 48 h. Subsequently, immunofluorescence staining with antibody to type I collagen was performed and the collagenous structures were visualized by immunofluorescence light microscopy. As control, untreated rat heart sections and sections incubated in the absence of calcium were similarly treated with antibody. After the 24 h of incubation, we found no change in the structural integrity of collagen fibers. Marked disruption of the type I collagen fibers was observed 48 h after incubation. No evidence of collagen fiber disruption was found in control sections. Experiments with exogenous collagenase resulted in similar collagen fiber disruption in the frozen rat heart sections. We conclude that the disruption of collagen type I fibers after 48 h of incubation, under optimal conditions for collagenolytic digestion, is the result of collagen degradation by intrinsic collagenase of the myocardium.

Cleavage site specificity of vertebrate collagenases

A series of synthetic peptide substrates for vertebrate collagenase having the structure Ac-Pro-Leu-Gly-X-Leu-Gly-OC2H5, where X is Leu, Ile, Val, Phe and Ala, have been prepared. Collagenolytic enzymes from various sources cleave these substrates with differing relative rate patterns. This series of peptides should be valuable for characterization of collagenases.

Proactivator-dependent activation of procollagenase induced by treatment with EGTA

A new mechanism for activation of the proactivator of procollagenase [Vater, Nagase & Harris (1983) J. Biol. Chem. 258, 9374-9382] has been found. Collagenolytic and other proteolytic enzyme activities in the medium of cultured rabbit synovial fibroblasts were found to be activated by a new mechanism: short-term incubation at 37 degrees C performed in the presence of EGTA followed by replacement of Ca2+ during enzyme assay. The crucial event in procollagenase activation is the production of a functional activator enzyme. Activation of procollagenase in the culture medium did not occur when proactivator was removed by immunoprecipitation. Proteolytic activity of proactivator was fully activated, whereas procollagenase alone could not be activated by the same sequence. EGTA treatment of the culture medium at 0 degrees C did not result in enzyme activation if Ca2+ was replaced before incubation at 37 degrees C. Certain other bivalent metal ions (e.g. Sn2+, Cd2+, Zn2+ and Mn2+) could substitute for Ca2+ to stabilize the proactivator as a zymogen and therefore prevent the appearance of proteolytic activity in culture medium. Isolation of proactivator and procollagenase from EGTA-treated radiolabelled culture medium by immunoprecipitation and subsequent analyses by fluorography revealed that a time-dependent proteolysis of both molecules occurred after replacement of Ca2+ and incubation at 37 degrees C. However, comparison of enzyme activity with fluorographic analyses showed that the maximal activation of both enzymes was achieved before any detectable decrease in Mr. The results suggest that the activation of proactivator and the subsequent activation of procollagenase may be initiated by conformational changes in structure of the proactivator molecule produced by removal of stabilizing bivalent metal ions.

Purification and properties of rat uterine procollagenase

A procollagenase from monolayer cultures of postpartum rat uterine cells has been purified. The crucial step in the purification is the binding of the procollagenase from crude, fetal bovine serum-containing culture medium to heparin-Sepharose, followed by elution with extremely low concentrations (5-10 nM) of dextran sulfate. Resultant eluates contain 8-10% procollagenase. Purification is completed by ion-exchange chromatography on DEAE-Sepharose, gel filtration on AcA-44, and chromatography on blue-Sepharose. Rat uterine procollagenase appears as a protein doublet of Mr approximately 58,000, as indicated by two polyacrylamide gel electrophoresis systems, by AcA-44 chromatography, and by equilibrium sedimentation ultracentrifugal analysis. The proenzyme forms are converted by trypsin to an active enzyme doublet of Mr approximately 48,000. Small amounts of active enzyme, which are often generated during the purification, are electrophoretically indistinguishable from trypsin-activated collagenase. Active collagenase can be separated from the zymogen forms by DEAE-Sepharose chromatography. The two forms of the proenzyme doublet can be partially separated by gel filtration on AcA-44 and preliminary analysis indicates each has equal collagenolytic activity. The amino acid analysis of rat uterine collagenase reveals it to be markedly different from two other vertebrate collagenases whose composition is known. The uterine proenzyme is unusually rich in glycine and in the hydroxy amino acids and is considerably more acidic than the human skin fibroblast collagenase, consistent with the different ion-exchange behavior of the two molecules. The specific activity of rat uterine collagenase at 37 degrees C is approximately 3000 micrograms collagen/min/mg, using native reconstituted guinea pig skin type I collagen fibrils as substrate. The enzyme cleaves denatured collagen, but fails to attack a variety of noncollagen proteins.