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

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

J. Andres Melendez, James M. Vinci, John J. Jeffrey, and Brian D. Wilcox

Department of Biochemistry and Molecular Biology, Albany Medical College, Albany, New York 12208

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

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-1 $alpha$ by myometrialsmooth muscle cells in vitro is also essential for the synthesisof interstitial collagenase. It is therefore likely that IL-1 $alpha$ production in uterine tissues has implications for both the normalphysiology of involution and for the pathophysiological mechanismsof preterm labor. The objective of this study was to characterizethe serotonin-induced production of IL-1 $alpha$ by myometrial culturesin vitro and to assess the production of IL-1 $alpha$ and its relationshipto collagenase production in vivo during pregnancy and the postpartumperiod. Immunohistochemistry demonstrated IL-1 $alpha$ protein in thenuclei and cytoplasm of serotonin-treated myometrial cells. IL-1 $alpha$ levels were decreased by treatment with progesterone or IL-1-receptorantagonist but were unaffected by lipopolysaccharide. Westernanalysis of myometrium from pregnant rats showed low levels ofIL-1 $alpha$ during midpregnancy with increased concentrations at days21 and 22 and postpartum. IL-1 $alpha$ mRNA levels also increased fromdays 15 to 22. Levels of mRNA for IL-1 $beta$ also increased, althoughto a lesser degree than IL-1 $alpha$ . Both mRNAs decreased postpartum.Conversely, mRNA for interstitial collagenase was barely detectableat term but increased postpartum. Together, these data show thatserotonin stimulates IL-1 $alpha$ production in vitro and indicate thatnormal myometrium from pregnant rats is an identifiable sourceof IL-1 during late pregnancy. The findings are consistent withthe possibility that myometrial IL-1 $alpha$ participates in normal laboras well as the postpartum production of interstitialcollagenase.

uterus; smooth muscle; parturition; cytokine; collagenase

	INTRODUCTION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

INTERLEUKIN-1 (IL-1) COLLECTIVELY refers to a gene family of three related cytokines that are involved in a variety of cellularprocesses. The family consists of the two agonist molecules, designatedIL-1 $alpha$ and IL-1 $beta$ , and a naturally occurring IL-receptor antagonist(IL-1ra). These cytokines are produced by numerous cell typesin a diverse array of tissues and exert their biological activitiesby binding to the same membrane receptors. Although originallystudied as proinflammatory mediators that are involved in immuneresponses, it is now known that these molecules exert a vast arrayof tissue- and cell-specific biological activities (9, 10).

The majority of the scientific interest in IL-1, both clinical and experimental, has been in the roles of these cytokinesin proinflammatory settings, especially in response to infection.This interest is derived mainly from the original identificationof IL-1 as an acute leukocytic product capable of inducing fever.In agreement with this proinflammatory role, there is a growingbody of evidence linking the production of IL-1 with labor-inducinginflammatory processes that occur within the mammalian uterus(15, 31, 34). Both IL-1 $alpha$ and -1 $beta$ , presumably the productsof macrophages and lymphocytes, are detected in the amniotic fluidof women experiencing preterm labor due to uterine infection (17,32). Similarly, the human decidua also produces IL-1 isoformsin response to bacterial products or infection (35). Once present,these cytokines have been shown to cause the synthesis and releaseof stimulatory prostaglandins, notably PGE₂ and PGF₂ $alpha$ , from thedecidua and fetal membranes (24, 26, 30), an observationconsistent with their participation in premature labor associatedwith infection. Causative support for the participation of IL-1in preterm labor is given by the observation that exogenouslyadministered IL-1 abruptly stimulates premature labor and deliveryin pregnant mice (33).

Whereas the contribution of IL-1 to infection-induced preterm labor has been well studied, work from this laboratory has demonstratedthat uterine myometrial cells themselves can produce IL-1 in responseto hormonal stimulation by serotonin (13, 43). These studieswere the first to demonstrate that IL-1 could be produced by cellsderived from the myometrium in response to a hormone that is presentand possibly increasing during late pregnancy (11). Interestingly,the induction of IL-1 mRNA in the myometrium is potently blockedby progesterone, an effect that may prevent the untimely inductionof IL-1 before parturition (22, 43). More importantly, theproduction of IL-1 by these cells is a crucial component of anormal noninflammatory process that occurs within the uterus,that being the induction of interstitial collagenase synthesisthat occurs after delivery (43). Although both IL-1 $alpha$ and -1 $beta$ are produced by myometrial cells, we recently observed that IL-1 $alpha$ is the single IL-1 isoform that is specifically required for theproduction of collagenase (13). These studies are importantbecause they demonstrate the necessity of the hormonal inductionof a specific IL-1 isoform for a defined biological purpose ina normal uterine cell population in the absence ofinfection.

The requirement for serotonin-induced IL-1 $alpha$ in the production of collagenase raises the possibility that myometrial-derivedIL-1 may be involved in other events occurring in the uterus,including the initiation of normal labor or in uninfected or otherwiseidiopathic preterm labor. With this in mind, we are continuingto explore the mechanisms whereby serotonin and progesterone regulateIL-1 synthesis in myometrial smooth muscle cells. Both the pathologicalimplications of IL-1-induced preterm labor and the requirementfor IL-1 in collagenase production make the regulation of uterineIL-1 $alpha$ a pivotal area for further research. In the studies presentedhere, we investigate the localization and regulation of IL-1 proteinsin primary cultures of uterine smooth muscle cells and in thenormal rat uterus during pregnancy and the postpartumperiod.

	MATERIALS AND METHODS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Cell cultures. All experiments using cultured cells were conducted on primary isolates of rat uterine smooth muscle cells derived from 4-daypostpartum uteri. Uteri were obtained, and cultures were preparedas described in detail previously (16). For all experiments,cells were plated in 75-cm² culture flasks and allowed to reach confluence in DMEM supplementedwith 30 mM HEPES and 10%(vol/vol) fetal bovine serum (FBS) thathad been adsorbed with dextran-coated charcoal to remove serotonin[CS-FBS (20, 38)]. Other additions to medium are describedin detail for eachexperiment.

Immunohistochemistry for IL-1 $alpha$ . Cell cultures for immunohistochemistry were plated directly onto 20 × 20-mm glass coverslips and treated as described in detailfor each experiment (see RESULTS). Uterine tissue for immunohistochemistrywas rapidly frozen in optimum cutting temperature embedding compound(Triangle Biomedical, Durham, NC) and stored at $-$ 70^oC until cryosections (~10 µm) were collected on gelatinized slides.All slides/coverslips were washed twice in PBS and then incubatedin 3.7% formaldehyde at 37^oC for 10 min. Adherent cells/tissue were washed and incubatedfor 5 min in 0.5% (vol/vol) Triton X-100, washed again, then incubatedfor 10 min in PBS containing 10 mg/ml glycine. Slides were againwashed three times, then they were incubated at room temperaturefor 20 min with 8% (vol/vol) goat serum. Excess goat serum wasremoved by gentle blotting followed by incubation for 30 min ina 1:200 dilution of rabbit anti-rat IL-1 $alpha$ antibody (Endogen) in0.1% goat serum. Slides were washed twice with PBS, then incubatedfor 30 min with a 1:200 dilution of biotinylated goat anti-rabbitIgG (Vector Laboratories, Burlingame, CA). Slides were then washedthree times with PBS and incubated for 30 min in VECTASTAIN EliteABC reagent (Vector Laboratories). Slides were washed and incubatedin 3,3'-diaminobenzidine peroxidase substrate for color developmentfollowed by distilled water. Photomicrographs were taken throughan Olympus IMT-2 microscope on Kodak Royal Goldfilm.

Tissue extracts. For in vivo experiments, rats were euthanized by exposure to carbon dioxide, and the uterus was quickly removed. After theremoval of the uterine contents, the endometrium was removed bygentle scraping with a fresh scalpel, and the myometrium was carefullydissected free from the underlying stroma, finely minced, andsuspended in two volumes (wt/vol) of PBS containing 2 mM EDTAand protease inhibitors (Complete Mini, Boehringer-Mannheim, Mannheim,Germany). The tissue was then homogenized with a motor-drivenhomogenizer for 1 min at 4°C followed by sonication for 10 s at4°C. Homogenates were centrifuged at 15,000 g for 15 min. Supernatantswere aliquoted and stored at $-$ 70°C. Proteins in the pellet fractionswere further solubilized in PBS containing 0.1% SDS, recentrifuged,and supernatants were stored at $-$ 70°C.

Western blot analysis. Western blot analysis on tissue extracts was performed exactly as described previously (13, 22). The anti-rat IL-1 $alpha$ polyclonalantibody was obtained from Endogen (Cambridge, MA) and was usedat a dilution of 1:200. The anti-rat IL-1 $beta$ polyclonal antibodywas obtained from R&D Systems (Minneapolis, MN) and was used ata dilution of 1:500. Alkaline phosphatase-conjugated secondaryantibodies were from Sigma (St. Louis,MO).

RT-PCR analysis of IL-1 $alpha$ RNA. Total RNA from rat myometrial tissue was isolated using the RNA Isolator reagent (Genosys Biotechnologies, The Woodlands,TX) as described in detail previously (22). Poly(dT)-primedcDNA synthesis was carried out on 2 µg of RNA using SuperscriptII RT (Life Technologies, Gaithersburg, MD). Reactions (30 µl)contained 1× reverse transcriptase buffer (50 mM Tris · HCl, pH8.3, 10 mM MgCl₂, 60 mM KCl, 10 mM 1,4-dithiothreitol), 0.5 µlof RNase inhibitor (Promega, Madison, WI), 0.5 µg/µl of oligodT, 0.5 mM dNTPs, and 0.1 mg/ml BSA and were carried out for 1h at 42^oC. Oligonucleotide primers for PCR amplification were designedusing the OLIGO primer analysis software (National Biosciences,Plymouth, MN) and are shown in Table 1. All primers were designedto span introns so as to detect possible contamination of theRNA samples with genomic DNA. The PCR mixture (50 µl) consistedof 5 µl of cDNA from the RT reaction, 2.5 µl of each PCR primer(final concentration 1 µM), 2.5 mM dNTPs, 1× PCR buffer (50 mMKCl, 10 mM Tris · HCl, pH 8.3, 1.5 mM MgCl₂, 0.01% Gelatin), and1.25 units of Taq DNA polymerase (Perkin-Elmer, Branchburg, NJ).Amplification was carried out for three cycles of 94°C for 60s, 60°C for 2 min, 72°C for 2 min, followed by 27 cycles of 94°Cfor 15 s, 60°C for 30 s, and 72°C for 15 s unless otherwise specified.After 30 cycles, the temperature was held at 72°C for 3 min. Theproducts of PCR amplification were analyzed by electrophoresison 1.5% agarose gels. Under these conditions, PCR amplificationboth of IL-1 $alpha$ and -1 $beta$ remains in the linear range. RT-PCR analysisof GAPDH mRNA levels was modified to remain in the linear rangeof amplification by reducing the total number of PCR cycles from30 to 18. The identity of a representative PCR sample for eachamplified product was confirmed by bidirectional sequencing usingthe Taq DyeDeoxy terminator cycle-sequencing kit and an ABI model310 DNA sequencer (Applied Biosystems).

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Table 1. Primer pairs used for RT-PCR of mRNAs for rat IL-1 $alpha$ , IL-1 $beta$ , and GAPDH

Northern blot analysis. Total RNA from rat uterine tissues was isolated as described above for RT-PCR. RNA samples were electrophoresed on 1.3% agarosegels containing 0.66 M formaldehyde and blotted to nitrocellulose,as described in detail previously (8). Probes were radiolabeledwith [ $alpha$ -³²P]dCTP (3,000 Ci/mmol) using the Random Primer Plus ExtensionLabeling System (New England Nuclear, Boston, MA). Autoradiographicsignals were quantified by video capture and digital image processingusing the BioImage system (BioImage/Millipore, Ann Arbor, MI).The IL-1 $alpha$ probe is a 2-kb cDNA to mouse IL-1 $alpha$ cloned from mouseDBA/2 P388D1 cells [pmIL1AcDNA; (23)]. It was obtained throughthe American Type Culture Collection (Rockville, MD). The cDNAprobe for rat collagenase is a 2.6-kb clone isolated from a ratosteoblast cDNA library and contains the entire coding regionfor the active enzyme (UMRcase 54, see Ref. 29).

	RESULTS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Immunolocalization of IL-1 $alpha$ in myometrial smooth muscle cells. Previous studies from this laboratory demonstrated that IL-1 $alpha$ mRNA production in myometrial cells is clearly induced by treatmentwith serotonin [5-hydroxytryptamine (5-HT)] alone or in combinationwith lipopolysaccharide (LPS) (19, 43). Recently, we alsodemonstrated that IL-1 $alpha$ protein is readily detected by Westernblot analysis of myometrial smooth muscle cells (13, 22).To further characterize the localization and regulation of IL-1 $alpha$ in myometrial smooth muscle cells, we performed immunohistochemicaldetection of IL-1 $alpha$ protein. As depicted in Fig. 1, intense immunoreactivenuclear and cytoplasmic staining was observed in cells treatedwith either 5-HT alone or with a combination of 5-HT and LPS.In contrast, untreated cells showed only very faint cytosolicor nuclear staining. Because our prior studies showed that serotonin-inducedIL-1 $alpha$ mRNA was blocked by treatment with progesterone or the IL-1-receptorantagonist, we also used immunohistochemistry to examine thisregulation in more detail. As depicted in Fig. 2A, chronic treatmentwith either progesterone or the IL-1ra decreased both the nuclearand cytosolic levels of IL-1 $alpha$ immunoreactive protein induced byserotonin. In addition, progesterone and IL-1ra were able to blockand reverse the serotonin-mediated induction of IL-1 $alpha$ protein(Fig. 2, B and C). These findings demonstrate that IL-1 $alpha$ proteinis readily detected both in the nucleus and cytoplasm of serotonin-treatedcells but is inhibited in the presence of either progesteroneor IL-1ra.

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Fig. 1. Immunohistochemical detection of interleukin (IL)-1 $alpha$ in serotonin-treated and lipopolysaccharide (LPS)-treated rat myometrial smooth muscle cells in vitro. Primary cultures of rat myometrial smooth muscle cells were plated and allowed to reach confluence as described in MATERIALS AND METHODS. At confluence (~day 7), cells were treated as indicated until day 21 of culture, then they were analyzed for the presence of IL-1 $alpha$ protein as described. Light micrographs shown are representative of the appearance of cultures at ×10 and ×20 magnification after immunohistochemical detection. Concentrations used were serotonin (5-HT), 5 µM; LPS, 100 ng/ml.

Fig. 2. Effects of treatment with medroxyprogesterone acetate (Prog.) and IL-1-receptor antagonist (IL-1ra) on serotonin-stimulated production of IL-1 $alpha$ . A: primary cultures of myometrial smooth muscle cells were chronically treated as indicated from days 7 to 21 of culture as described in Fig. 1. B and C: cells were treated in either serotonin-containing (+5-HT) or serotonin-free ( $-$ 5-HT) medium until day 21 of culture, then they received the indicated treatments for 48 h. Light micrographs shown are representative of the appearance of cultures at ×20 magnification after immunohistochemical detection of IL-1 $alpha$ . Concentrations used were 5-HT, 5 µM; Prog., 10⁷ M; IL-1ra, 500 ng/ml.

Western blot analysis of IL-1 $alpha$ and -1 $beta$ in the pregnant and postpartum rat uterus. Numerous studies both in humans and animals have implicated the involvement of IL-1 isoforms in endotoxin-induced abortionand in premature labor caused by infection. Our present findings,however, indicate that myometrial cells can produce IL-1 $alpha$ in responseto hormonal stimuli in the absence of endotoxin or infection.For this reason, we next chose to characterize the levels of IL-1protein in apparently normal, noninfected rat uterine tissue isolatedfrom rats at various times during pregnancy. Our results are depictedin Fig. 3. Western blot analysis with an IL-1 $alpha$ -specific antibodydemonstrated a faint immunoreactive band that was first observedon day 16 and was markedly increased in tissue isolated at day21 of pregnancy and 2 days postpartum (Fig. 3A). IL-1 $alpha$ was onlydetected in cell supernatants and was not observed in the solubilizedparticulate fraction. Figure 3B shows the results of two otherseparate experiments conducted with cell supernatants from differentanimals. In these experiments, IL-1 $alpha$ protein was undetectableat days 5 and 10 of pregnancy but was readily detected at day15. As in the previous experiment, IL-1 $alpha$ protein in tissue supernatantsappeared to increase during late pregnancy and the postpartumperiod. Although an IL-1 $beta$ -specific antibody could readily detecta purified IL-1 $beta$ standard, no IL-1 $beta$ was detected in any tissuehomogenates at any stage of pregnancy. These data indicate thatIL-1 $alpha$ is the predominant resident IL-1 isoform produced in therat myometrium during normal pregnancy and show that levels ofIL-1 $alpha$ increase before parturition.

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Fig. 3. Western blot analysis of IL-1 $alpha$ and -1 $beta$ in rat myometrial tissue during pregnancy and the postpartum period. A: myometrial tissues were isolated from rat uteri on days 16 and 21 of pregnancy and at 2 days postpartum as described in MATERIALS AND METHODS. Extracts from cell supernatants (s) and resolubilized pellet fractions (p) were analyzed separately. The blot was probed with a rabbit anti-rat IL-1 $alpha$ antibody as described in MATERIALS AND METHODS. B: two separate experiments in which only cell supernatants were analyzed from myometrial tissue isolated on days 5, 10, 15, 20, and 21 of pregnancy and at 2 days postpartum (P-P). Blots were probed with a rabbit anti-rat IL-1 $alpha$ antibody and with goat anti-rat IL-1 $beta$ antibody as described in MATERIALS AND METHODS. Standards shown for size comparisons are purified mouse IL-1 $alpha$ and rat IL-1 $beta$ .

Immunolocalization of IL-1 $alpha$ in the pregnant and postpartum rat uterus. We next used immunohistochemistry to further define the tissue distribution and temporal regulation of IL-1 $alpha$ in the nonpregnant,pregnant, and postpartum rat uterus (Fig. 4). IL-1 $alpha$ -specific immunoreactivitywas weak or absent in the myometrium of nonpregnant uteri butwas clearly observed in the myometrium of both pregnant and postpartumanimals. This immunoreactivity was evident in tissues isolatedat day 15 of pregnancy and was noticeably increased at day 21of pregnancy and postpartum. In general, immunoreactive stainingwas much greater in the outer, longitudinal myometrium, especiallyat day 21 and postpartum. In contrast, IL-1 $alpha$ immunoreactivityin the endometrium and uterine glands was present in most tissuesexamined but was not observed to undergo noticable changes duringpregnancy. Control experiments that used normal rabbit serum inplace of primary antibody (or secondary antibody alone) showedno immunoreactive staining. These data are in agreement with theresults of Western blotting depicted in Fig. 3 and indicate thata significant portion of the uterine IL-1 $alpha$ detected during latepregnancy is produced by the longitudinal myometrium.

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Fig. 4. Immunolocalization of IL-1 $alpha$ in rat uterine tissues isolated during pregnancy and the postpartum period. Intact uteri were isolated from nonpregnant, pregnant, and postpartum animals at the times indicated, and immunohistochemistry with rabbit anti-rat IL-1 $alpha$ was performed as described in MATERIALS AND METHODS. IL-1 $alpha$ was localized in both the circular (C) and longitudinal (L) myometrial smooth muscle and in the luminal endometrium (E). Lower panels show a negative control in which normal rabbit serum was used in place of primary antibody and a normal hematoxylin and eosin (H&E) stain of tissue from a postpartum animal. All micrographs (×35 magnification) shown are representative of the distribution of IL-1 $alpha$ in 1 of 3 animals at each time point.

Characterization of IL-1 mRNA levels from rat myometrial tissue in vivo. We next sought to determine whether the production of IL-1 was correlated with changes in IL-1 mRNA and whether the productionof IL-1 $alpha$ mRNA was altered before parturition. RT-PCR analysisshowed that IL-1 $alpha$ mRNA was essentially undetectable in myometriumisolated on day 10 of pregnancy but steadily increased duringlate pregnancy (Fig. 5A). Peak levels of IL-1 $alpha$ mRNA were observedon days 21 and 22 of pregnancy, and a noticeable decrease in IL-1 $alpha$ mRNA occurred postpartum. IL-1 $beta$ mRNA, on the other hand, was detectableearly in pregnancy (day 10), also peaked at days 21 and 22, andwas also detectable during the postpartum period. Overall, therelative levels of IL-1 $alpha$ mRNA were observed to undergo more significantchanges than those of IL-1 $beta$ mRNA (Fig. 5B). These data demonstratethat the mRNAs for both IL-1 $alpha$ and -1 $beta$ are significantly inducedin the rat myometrium before parturition.

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Fig. 5. Expression of IL-1 $alpha$ and -1 $beta$ mRNAs in rat myometrial tissue isolated during pregnancy and the postpartum period. Total RNA was isolated from myometrial tissue at days 10, 15, 21, and 22 of pregnancy and at 2 days postpartum. Relative amounts of mRNAs for IL-1 $alpha$ , IL-1 $beta$ , and GAPDH were measured using RT-PCR as described in MATERIALS AND METHODS. A: photographs of agarose gels showing the relative intensities of amplified cDNAs after RT-PCR. Each lane contains 5 µl of RT-PCR product from a separate animal. B: relative band intensities of the data shown in A after analysis using Molecular Dynamics IMAGEQUANT software. Bands for IL-1 $alpha$ or -1 $beta$ were normalized to the level of GAPDH for each individual sample. The values shown are the means ± SE for each time period (days 21 and 22 are represented as 1 group). Statistically significant differences from day 10 (*P < 0.05, **P < 0.01) were determined using the 2-sided Student's t-test.

Characterization of collagenase mRNA from rat myometrium in vivo. Previous studies from this laboratory have focused on the ability of IL-1 isoforms to induce the production of interstitialcollagenase from myometrial smooth muscle cells in vitro (13,43). Our results presented here indicate that the rat myometriumin vivo can also synthesize IL-1 $alpha$ and that levels of IL-1 $alpha$ increaseduring late pregnancy. We, therefore, sought to determine whethercollagenase mRNA is also produced by the rat myometrium in vivo.We used Northern blot analysis in these experiments because wehave not yet undertaken a careful analysis of RT-PCR conditionsthat accurately represent quantitative changes in collagenasemRNA. We also reasoned that Northern blotting would representa reasonable revalidation of the RT-PCR data obtained for IL-1 $alpha$ and -1 $beta$ in Fig. 5. Northern blots of RNA isolated from pregnantand postpartum rats showed detectable collagenase mRNA as earlyas day 10 of pregnancy (Fig. 6). The amount of mRNA increasedslightly before parturition but was markedly increased in thepostpartum period. In general, the qualitative pattern of expressionof IL-1 $alpha$ mRNA detected by Northern blotting was similar to thatobserved with RT-PCR with the exception that the method was notablyless sensitive. We do not believe that differences in the twodetection methods are due to differences in mRNA loading, becauseethidium bromide staining of the gels before blotting demonstratedthat all samples contained equivalent amounts of total RNA (datanot shown).

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Fig. 6. Northern blot analysis of IL-1 $alpha$ and interstitial collagenase mRNAs in rat myometrial tissue in vivo. Total RNA was isolated from the myometrium of pregnant and postpartum animals at the times indicated and was subjected to Northern blot analysis. All RNA samples are from the same animals depicted in Fig. 5 with the exception of 1 postpartum sample in which no RNA remained after RT-PCR. A: the actual autoradiographs after Northern blot analysis. B: the relative image intensity after video capture and digital analysis. The values shown are the means ± SE for each time period (days 21 and 22 are represented as 1 group). Statistically significant differences from day 10 (*P < 0.05) were determined using the 2-sided Student's t-test.

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Recent work from this laboratory has focused on defining the hormonal regulation of IL-1 $alpha$ production in primary cultures ofuterine smooth muscle cells. IL-1 $alpha$ is crucial in these cells asan intermediate in the production of interstitial collagenase(13). We first demonstrated that the ability of myometrial cellsto produce IL-1 $alpha$ mRNA in vitro was dependent on stimulation byserotonin (43). Conversely, serotonin-stimulated increases inIL-1 $alpha$ mRNA were readily blocked by simultaneous treatment witheither progesterone or the IL-1-receptor antagonist (22, 43).This work was intriguing in that it provided a paradigm wherebyinflammatory cytokines could be produced for a specific purposeby resident uterine cells in a noninflammatory setting. WhereasIL-1 production by macrophages and lymphocytes has long been implicatedas a participant in uterine pathologies caused by infection andischemia, these data provided evidence that cytokines could havea distinctly physiological role when induced by hormonal stimuliin vitro. The data presented in this paper expand on this modelin two important ways. First, we demonstrate that IL-1 $alpha$ proteincan indeed be detected in myometrial smooth muscle cells in vitroand that its levels correlate with our previous studies on theregulation of its mRNA. Second, we provide evidence, for the firsttime, that the resident myometrial cells of the noninfected ratcan be a source of IL-1 in vivo and that levels of this cytokineincrease before the onset of labor and the postpartum increasein collagenaseproduction.

The results of our first experiments, using primary cell cultures, demonstrate that IL-1 $alpha$ protein is indeed produced by ratmyometrial cells and that the production of IL-1 $alpha$ protein mimicsthe previously reported regulation of its mRNA. IL-1 $alpha$ proteinwas undetectable in cultures treated without serotonin but wasreadily detected in its presence. Interestingly, simultaneoustreatment with bacterial LPS had neither a positive nor negativeeffect on IL-1 $alpha$ levels, in agreement with our previous studieson IL-1 $alpha$ mRNA in similarly treated cells (43). This observationis of interest because of the well-studied implication of IL-1isoforms as participants in preterm labor that is induced by bacterialinfection. We previously showed that IL-1 $alpha$ mRNA can be stimulatedby LPS but that LPS treatment is not necessary for its productionin the presence of serotonin (43). Our current results showthat the hormonal stimulation of IL-1 $alpha$ protein by serotonin alsorepresents a maximal induction that is not augmented by the presenceof bacterialproducts.

The repressive actions of progesterone and IL-1ra on -1 $alpha$ mRNA have also been demonstrated in vitro (43). In the studiespresented here, we show that these effects are also borne outat the level of IL-1 $alpha$ protein. Simultaneous treatment with eitherprogesterone or IL-1ra inhibits or reverses the ability of serotoninto stimulate IL-1 $alpha$ -protein production. Therefore, in the presenceof both a repressor and an inducer of IL-1 production, the repressorclearly dominates over expression of the protein. For IL-1ra,this repression indicates the importance of autocrine stimulationof IL-1 for the continued production of IL-1 protein by myometrialcells in vitro. Similarly, the repression mediated by progesteronecould have profound implications on the production of IL-1 bythe myometrium in vivo during mid- to late pregnancy, when progesteroneis maintained at high levels. Previously, we demonstrated thatthe ability of progesterone to repress IL-1 $alpha$ mRNA production isreceptor mediated and likely involves a protein-dependent increasein the instability of IL-1 $alpha$ mRNA (22). We are actively engagedin further defining this mechanism and determining whether a similareffect of progestins exists invivo.

Immunohistochemical analysis of IL-1 $alpha$ in rat myometrial cell cultures demonstrated prominent serotonin-dependent increasesin both nuclear and cytosolic staining. The reason why this stainingpattern is distinctly heterogeneous, however, is not entirelyclear. Prior immunohistochemical studies with anti-smooth muscleactin have demonstrated that our cultures are essentially entirelyof smooth muscle origin (6). It is possible that the combinednuclear and cytosolic staining pattern is therefore linked tocell-cycle progression and, in a nonsynchronous culture system,results in a heterogeneous pattern of expression. This is in agreementwith numerous other studies that have demonstrated cytoplasmicand nuclear localization of IL-1 $alpha$ (7, 25, 27, 42). Mizelet al. (27) demonstrated rapid internalization of 17 kDa IL-1 $alpha$ from the culture medium of murine fibroblasts or lymphoma cellsand showed that it localized to the nucleus within 2-6 h. Otherstudies (25, 42) demonstrated that pro-IL-1 $alpha$ (28-35 kDa) alsolocalizes to the nucleus, possibly due to a specific signal thatis present within the first 115 amino acids of the IL-1 $alpha$ propiece.Although our studies did not differentiate pro-IL-1 $alpha$ from matureIL-1 $alpha$ in the nucleus, it is clear from our results that IL-1 $alpha$ was at least partially directed to the nucleus. Prior work fromour lab also showed that IL-1 $alpha$ production from myometrial cellswas crucial for the autocrine induction of both collagenase andIL-1 mRNAs (13). Although speculative, it is possible that itis in the nucleus that IL-1 $alpha$ participates in the hormonal inductionof collagenase gene expression or the expression of its ownmRNA.

The results of Western blot analysis of crudely fractionated myometrial tissue indicate that IL-1 $alpha$ is predominantly freelysoluble and varies in molecular weight from ~17 to 28 kDa. Althoughnumerous studies have demonstrated immunoreactive IL-1 $alpha$ in cellmembranes (5, 21), we failed to detect IL-1 $alpha$ immunoreactivityin resolubilized membrane fractions. Previously, we also failedto detect IL-1 $alpha$ in conditioned medium from serotonin-treated myometrialcells, even after that medium was concentrated up to 100-fold(13). Thus our findings indicate that IL-1 $alpha$ is predominantlylocated in a soluble intracellular pool within these cells. Indeed,most cells do not process and secrete IL-1 $alpha$ . Rather, the 17-kDa"processed" form is thought to derive from cleavage of the 30-kDapro-IL-1 $alpha$ by extracellular proteases after its release from damagedcells (9, 18, 41). It is also interesting to note thatwe failed to detect the presence of IL-1 $beta$ protein in these studies,although we previously demonstrated IL-1 $beta$ mRNA in vitro (43).In many cell lines, pro-IL-1 $beta$ is rapidly cleaved by the IL-1 $beta$ -convertingenzyme and secreted. This may explain our failure to detect IL-1 $beta$ immunoreactive protein in crude myometrial extracts (9).

Western blot analysis of myometrial tissue from pregnant rats showed that IL-1 $alpha$ protein was present as early as day 15 ofpregnancy and increased in concentration during late pregnancyand the postpartum period. This observation is intriguing becausethe initial rise in IL-1 concentration occurs during midpregnancywhen progesterone concentrations should inhibit IL-1 expression.During this stage of pregnancy in the rat, the uterus is undergoingdramatic structural and morphological changes to accommodate therapidly developing embryo. It is possible that at day 15, theproduction of IL-1 $alpha$ may be regulated by mechanisms that are, asyet, undefined or are restricted to defined regions of the uterus.In support of this hypothesis, preliminary studies from our laboratoryindicate that IL-1 $alpha$ production at day 15 is more pronounced inthe intervening regions of uterine tissue between implantationsites (unpublished observations). Interestingly, the IL-1 $alpha$ immunoreactivebands observed by Western blot also appeared to vary somewhatin molecular weight with an increase in size during late pregnancy.This increase was observed in three separate experiments (seeFig. 3). Despite this variation in size, the specificity of theseantibody interactions was demonstrated by competition experimentsusing purified mouse IL-1 $alpha$ . When purified, IL-1 $alpha$ was added tothe primary antibody solution; detection of all immunoreactivebands was abolished (data not shown). A study by Hojo et al. (18)in rat bladder cancer cells also demonstrated the appearance ofnumerous IL-1 $alpha$ reactive bands at 10, 17, 28, and 31 kDa. Presumably,these proteins represented different cleavage products from maturepro-IL-1 $alpha$ . Although removal of the IL-1 $alpha$ propiece is generallythought to yield a fragment of 17 kDa, analysis of the IL-1 $alpha$ proteinsequence also identifies a trypsin digestion site that would producea 25- to 28-kDa fragment from the precursor molecule (28). Thedefinitive identity of the different immunoreactive species ofIL-1 $alpha$ in rat myometrium awaits microsequencing of the variousfragments. Given that the molecular weight of IL-1 $alpha$ appeared tobe consistently altered during late pregnancy, it will be interestingto assess whether these different forms of IL-1 $alpha$ have differingfunctions in theuterus.

The results of immunohistochemistry and Northern analysis of uterine tissue from pregnant rats indicate that IL-1 $alpha$ is predominantlylocalized to the outermost longitudinal myometrium and that IL-1 $alpha$ levels appear to increase throughout late pregnancy. These resultsare in agreement with the results of Western blot analysis ondissected myometrial tissue and together indicate that the myometriumis a significant source of IL-1 $alpha$ during normal pregnancy in therat. Previously, investigators definitively showed that the myometriumis also the principal source of uterine collagenase in vivo (6).Given that collagenase production in myometrial cells in vitrorequires the presence of IL-1 $alpha$ , these results are also consistentwith a role for IL-1 $alpha$ in the production of collagenase in vivo.Results from Northern blot analysis were consistent with thispossibility and showed that increases in IL-1 $alpha$ mRNA at least precedethe production of collagenase mRNA in myometrial tissue. Our Northerndata are in contrast to those of Balbin et al. (4), who wereunable to detect a signal for rat interstitial collagenase inthe postpartum uterus. It is possible that these differences occurredbecause of rapid degradation of collagenase mRNA in the nuclease-richenvironment of the postpartum uterus, an outcome that was avoidedin the present study by rapid, immediate processing of uterinetissues for RNA extraction. Interestingly, concentrations of mRNAboth for IL-1 $alpha$ and -1 $beta$ were observed to decrease after delivery,possibly indicating that these molecules are indeed tightly regulatedthroughout late pregnancy and the postpartum period. Whether IL-1 $alpha$ regulates collagenase production in vivo remains to be establishedand is the focus of our currentinvestigations.

Our previous studies on the regulation of IL-1 $alpha$ in vitro have concentrated on the upregulation of IL-1 $alpha$ transcription by serotonin(13, 19). In myometrial cell cultures, increased IL-1 $alpha$ proteinand IL-1 $alpha$ gene expression occurs at serotonin concentrations thatare found in the rat uterus, placenta, and maternal circulationduring pregnancy (1, 14). Serotonin is also present at similarconcentrations in the plasma of women during pregnancy and possiblyincreases before labor (11). Thus serotonin exists in vivo duringpregnancy at levels that stimulate IL-1 $alpha$ expression in vitro.Given that a significant amount of serotonin circulates withinplatelet granules that are only released on platelet activation,locally elevated levels of serotonin are typically encounteredin tissues during physiological or pathological responses thatinvolve coagulation. This is mentioned because of the implicationof placental bleeding, either gross or microscopic, in the genesisof preterm labor (36). Placental vascular abnormalities andischemia have been noted to occur at significantly higher frequenciesduring preterm birth (37) and represent a subset of pretermdeliveries that occur in the absence of bacterial colonization(3). It is therefore interesting to hypothesize that a subsetof preterm deliveries might involve the induction of myometrialcytokines that are, in part, induced by elevated serotonin. Weare currently at work on studies designed to test these hypothesesin humanpatients.

In summary, the results presented here show that resident myometrial cells of the uninfected rat uterus can be a significantsource of cytokines during pregnancy. In doing so, this studyis one of several that have recently shown that inflammatory cytokinesare produced in uterine tissues in the absence of infection. Forexample, Steinborn et al. (40) showed that concentrations ofIL-1 $alpha$ , IL-1 $beta$ , and tumor necrosis factor- $alpha$ were elevated in thecervicovaginal secretions of women during normal term deliveryin the absence of infection. Other recent studies (2, 12,39) also showed that decidual and placental IL-1 $beta$ and -6 werereadily detected in women in labor regardless of gestational agebut were rarely detected in women undergoing cesarean sectionin the absence of labor. Taken together, these results suggestthat common but temporally distinct pathways for both term andpreterm labor may include increased levels of uterine-derivedcytokines. In a normal, physiological setting, the productionof IL-1 appears to be tightly regulated and to precede the onsetof delivery. It is tempting to speculate that during at leasta small percentage of preterm deliveries, increased serotoninmay lead to the premature production of IL-1, a process that isdesigned to induce collagenase production and return the uterusto reproductive competence in the postpartumperiod.

Perspectives

The findings reported in this study provide evidence for an extended role of IL-1 $alpha$ in the tremendously complex processes involvedin the normal termination of pregnancy and the onset of postpartumregression. Numerous studies have given rise to the notion thatIL-1 plays a major role in preterm labor, particularly in thecontext of uterine infection. The possibility that the cytokineis involved in normal myometrial function during pregnancy hasbeen suggested by numerous in vitro studies. These studies showedthat the induction of the gene for interstitial collagenase, amongothers, is mediated by IL-1 $alpha$ in primary cultures of myometrialsmooth muscle cells. Interstitial collagenase is a crucial enzymefor the removal of collagen of the uterus during postpartum involution.The current studies serve to bridge the gap between the in vitrofindings and the situation in vivo; clearly, IL-1 $alpha$ levels riseduring late pregnancy, preceding the appearance of interstitialcollagenase in the tissue. Although a causal relationship hasnot been demonstrated, the temporal relationships are consistentwith a role for the cytokine in collagenase induction. In anyevent, it seems clear from these studies that IL-1 plays a rolein late pregnancy distinct from its more classical proinflammatoryfunctions.

	ACKNOWLEDGEMENTS

This work was supported by National Institutes of Health HD-32585 (to B. D. Wilcox), HD-05291 (to J. J. Jeffrey), and CA-77068(to J. A.Melendez).

	FOOTNOTES

During the early stages of this work, J. A. Melendez was supported by a National Institute of Child Health and Human Development-sponsoredsupplement to HD-32585 for the support of underrepresented minoritiesin postdoctoraltraining.

Address for reprint requests and other correspondence: B. D. Wilcox, Dept. of Biochemistry and Molecular Biology, Mail Code165, Albany Medical College, 47 New Scotland Ave., Albany, NY12208 (E-mail: wilcoxb{at}mail.amc.edu).

The costs of publication of this article were defrayed in part by the payment of page charges. The article must thereforebe hereby marked "advertisement" in accordance with 18 U.S.C.Section 1734 solely to indicate thisfact.

Received 3 January 2000; accepted in final form 25 October 2000.

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

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