Differential expression of uterine NO in pregnant and nonpregnant rats with intrauterine bacterial infection

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Differential expression of uterine NO in pregnant and nonpregnant rats with intrauterine bacterial infection

L. Fang¹^,², B. Nowicki¹^,³, and C. Yallampalli¹^,²

¹ Department of Obstetrics and Gynecology, ² Anatomy and Neuroscience, and ³ Microbiology and Immunology, The University of Texas Medical Branch, Galveston, Texas 77555 - 1062

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIAL AND METHODS
RESULTS
DISCUSSION
REFERENCES

Previous studies have demonstrated that nitric oxide (NO) is involved in the uterine host defense against bacterial infection.In nonpregnant rats, NO production in the uterus was shown tobe lower, and inducible NO synthase (NOS) expression was undetectable.However, studies in pregnant rats show abundant expression ofinducible NOS with significant elevation in NO production in theuterus. We have recently reported that intrauterine Escherichiacoli infection caused a localized increase in uterine NO productionand inducible NOS expression in the nonpregnant rat. In our presentstudy, we examined whether the uterine NO production, NOS expression,and uterine tumor necrosis factor- $alpha$ protein are increased in pregnantrats with intrauterine pathogenic Escherichia coli infection.Unlike the nonpregnant state, the NO production in the infecteduterine horn of pregnant rats was not significantly elevated afterbacterial inoculation compared with the contralateral uterinehorn. The expression of uterine NOS (types II and III) also didnot show significant upregulation in the infected horn. This isin contrast to that in nonpregnant animals, in which type II NOSwas induced in the uterus on infection. Moreover, intrauterineinfection induced an elevated expression of tumor necrosis factor- $alpha$ protein in the infected horn both of nonpregnant and of pregnantrats. These data suggest that the sequential stimulation of NOSexpression, especially the inducible isoform, and generation ofuterine NO are lacking during pregnancy despite an elevated tumornecrosis factor- $alpha$ after infection. In summary, NO synthesis responsemay be maximal at pregnancy, and infection may not further inducethe NO system. Present studies, together with our previous reportthat intrauterine infection-induced lethality in pregnancy ratswas amplified with the inhibition of NO, suggest that pregnancyis a state predisposed for increased complications associatedwith intrauterine infection and that the constitutively elevateduterine NO during pregnancy may help contain or even reduce therisk of infection-relatedcomplications.

cytokines; Escherichia coli; gestation; Dr fimbriae; nitric oxide

	INTRODUCTION

TOP ABSTRACT INTRODUCTION MATERIAL AND METHODS RESULTS DISCUSSION REFERENCES

INTRAUTERINE INFECTION DURING pregnancy is a serious problem with significant neonatal morbidity and mortality, includinglow birth weight, high-risk pregnancy, fetal growth retardation,and septicemia (1, 11, 14, 20, 33). The underlyingpredisposition to intrauterine infection during pregnancy is poorlyunderstood. Suggested mechanisms include a decrease in the immuneresponse during pregnancy and pregnancy-induced hormonal changes(19). Recently, much emphasis has been placed on the role ofinflammatory cytokines interleukin-1 $beta$ (IL-1 $beta$ ) and tumor necrosisfactor- $alpha$ (TNF- $alpha$ ), prostaglandins, and nitric oxide (NO) in thepathophysiology of intrauterine infection and infection associatedwith uterine immune response (1, 14, 15, 22, 26, 31,33).

NO, a simple gas molecule, is generated from L-arginine by NO synthase (NOS) and was found to be involved in a variety ofphysiological functions, including neurotransmission, vasodilation,and infection (9, 10, 24). Three different isoforms ofNOS (I, II, and III) have been identified in mammalian cells (9,24, 41). Types I and III NOS are constitutive isoforms originallyisolated from neurons and endothelial cells, respectively. NOSII is an inducible form originally found in mouse macrophagesthat has been shown to participate in the immune response to infection(9, 24). Several reports indicate that NOS III, but not II,is expressed in nonpregnant rat uterus, whereas both NOS II andIII are expressed in pregnant rat uterus (4, 41, 42). UterineNO production is substantially elevated during pregnancy (41-43).Furthermore, the inhibition of NO synthesis with nitro-L-argininemethyl ester (L-NAME; an inhibitor of NOS) increased the bacterialinvasion and the infection-induced lethality in pregnant rats(26, 28). NOS II is upregulated in the nonpregnant rat uteruson intrauterine bacterial inoculation, and the NOS II expressionis restricted to uterine macrophages and natural killer (NK) cells(7).

Several lines of evidence indicate that NO may be involved in the host defense mechanisms against infection (6, 29).Inhibition of NOS activity significantly decreased the survivaltime of mice infected with Salmonella typhimurium or Escherichiacoli (6). Furthermore, the mortality rate was increased inendotoxemic rats from 33% to 74% when NO synthesis was inhibited(38). In addition, NO was considered to be a crucial effectorin the host defense in Leishmania-infected mice (5, 36).The microbicidal and microbiostatic activity of NO has been demonstratedagainst a number of protozoa, viruses, and bacteria (6, 12,29). Furthermore, an increased NO production induced by infectionand endotoxin via cytokines such as TNF- $alpha$ and IL-6 could alsoplay a role in these host defense mechanisms (33).

Maternal intrauterine infections have been related to several adverse outcomes of pregnancy in human and experimental animalsincluding intrauterine fetal death, premature labor, prematurerupture of membranes, and abortion (3, 13, 32). Comparedwith nonpregnant, pregnant women are more susceptible to the infectiousdiseases caused by viruses, bacteria, fungi, and protozoa; oncewomen are infected, these diseases tend to become severe. Thepathophysiology of the gestation-associated infections is thoughtto correlate with pregnancy-altered systemic and local host responses.Maternal host defense against these pathogens is primarily cellmediated, and so it is believed that maternal cell-mediated immunityis downregulated to avoid immunological rejection of the fetus.The amount of immunosuppression increases with the duration ofthe gestation (39).

It is well accepted that the pregnant state is associated with a reduced host response to infection, which may be differentfrom the nonpregnant state. Therefore, the present study was undertakento evaluate the responsiveness of uterine NOS expression and NOproduction in pregnant rats with intrauterine pathogenic E. coliinfection compared with those from the nonpregnant rat uterus.The levels of uterine TNF- $alpha$ , a well-known proinflammatory cytokinethat can stimulate the upregulation of inducible NOS and highoutput of NO (21, 24), were also measured in the infectedpregnant and nonpregnant animals to assess whether differentialuterine NO generation is a consequence of altered proinflammatorycytokineresponse.

	MATERIAL AND METHODS

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Animals and Treatment

Infected pregnant rat model. Adult timed-pregnant Sprague-Dawley rats were purchased from Harlan Sprague Dawley (Houston, TX). All experiments were approvedby the Animal Care and Use Committee at The University of TexasMedical Branch and performed in accordance with the National Institutesof Health Guide for the Care and Use of Laboratory Animals. Twodays before experimental infection, each animal received one doseof streptomycin (7.0 mg/g body wt) to eliminate possible infectionsin the urogenital tract that may have occurred naturally. An inoculumof pathogenic E. coli 075:K5:H that express the virulence factor Dr fimbriae (strain IH11128)in a volume of 200 µl of PBS (5 × 10⁹ bacterial cells/ml) was placed through the cervical os into thecavity of the left uterine horn of pregnant rats on day 18 ofgestation using a blunted 16-gauge stainless steel animal feedingneedle. For control experiments, the same amount of PBS was placedin the right uterine horn. During this procedure, animals wereplaced under ketamine (45 mg/kg body wt; Parker-Davis, MorrisPlains, NJ)/xylazine (5 mg/kg body wt; Phoenix Scientific, St.Joseph, MO) anesthesia. Infected animals were randomly killedin groups of five using a CO₂- inhalation chamber at 12 and 24h after bacterial infection, and tissues were collected for furtherstudy. We used an E. coli strain (IH11128) that expresses Dr fimbriae,a virulent factor that mediates adherence to the mucosal surface,in our experiments because of its association with gestationalinfections and its capacity to colonize epithelial cells (27)through the attachment to its tissuereceptors.

Infected nonpregnant rat model. Adult female nonpregnant Sprague-Dawley rats, without regard to the stage of estrus cycle, were bilaterally ovariectomized(OVX) while they were under anesthesia and treated as describedabove. Similar to pregnant animal protocol, 2 days before experimentalinfection, each animal received one dose of streptomycin (7.0mg/g of weight). Because it was impossible to pass the blunt needlethrough the cervix in nonpregnant rats, we used laparotomy toinoculate bacteria into the uterine lumen of these animals. Underanesthesia, a laparotomy exposing both uterine horns was performedand an inoculum of Dr+ E. coli in a volume of 200 µl of PBS (5× 10⁹ bacterial cells/ml) was injected into the lumen of the exposedleft uterine horn through an 18-gauge needle. The cervical endof the horn was ligated to prevent loss of inoculum through theinjection site. The right uterine horn, which was injected withthe same amount of PBS followed by ligation of the cervical end,served as the control within each animal. The laparotomy incisionwas closed, and the animals were randomly killed in groups offive using a CO₂ inhalation chamber at specific times afterinfection.

Tissue collection. The uterine tissues from all animals were removed for assessment of nitrite production or were either immediately snap frozenin liquid nitrogen or placed in Tissue-Tek OCT embedding compoundand frozen in liquid nitrogen. Frozen specimens were stored at $-$ 70°C until they were sectioned for immunofluorescence-stainingstudies and immunoblottinganalysis.

Evaluation of nitrite production by rat uterine tissue with HPLC. Uterine tissues were cut into 2-mm strips (~100 mg), placed in minimum essential medium (GIBCO, Gaithersburg, MD) containing1% penicillin and 1% streptomycin, and placed in a CO₂ incubatorwith humidified chamber at 37°C for an initial 1-h equilibrationperiod to eliminate the effect of cutting. Media was replacedwith fresh media, and incubation continued for 24 h. Because NOspontaneously autooxidizes to form the stable metabolites nitriteand nitrate, measurement of these products provides an indirectassay for NO production. Nitrates were converted to nitrites,and these were measured as the final product of NO metabolism.We used a novel and highly sensitive HPLC method for the measurementof nitrites released into media from infected and noninfectedrat uterus (7).

Nitrite concentrations in the media were measured in triplicate by the HPLC method as described earlier (7). Briefly, analiquot of media was injected into a spectrophotometric nitrite(NO₂) and nitrate (NO₃) analyzer, which consists of HPLC pumps,a cadmium-reducing column, a postcolumn reactor, and an ultravioletdetector (Beckman System Bold 126, Beckman, Fullerton, CA). Thesamples were carried through the analyzer in a 0.3% aqueous ammoniumchloride buffer containing 0.07% EDTA (pH 8.0). Nitrates werereduced to nitrites on the cadmium-reducing column. The ultraviolet-absorbingderivative was formed by postcolumn reaction with a solution containing0.1% N-(1-naphthyl) ethylenediamine dihydrochloride and 1% HCl.The areas of the absorbance peak at 546 nm were determined withanintegrator.

Western immunoblotting analysis for NOS II and III in rat uterine tissue. Western blot was performed as previously described (7). Full-thickness uterine tissues containing both endometrium andmyometrium were homogenized in 50 mM Tris buffer (pH 7.4) containing0.1 mmol EGTA, 0.14 µl $beta$ -mercaptoethanol, 100 nmol phenylmethylsulfonylfluoride, and 0.2 mg/ml trypsin inhibitor. The homogenate wascentrifuged at 1,000 g for 15 min at 4°C, and the supernatantwas used for immunoblotting. The concentration of proteins inthe supernatant fraction was measured with the bicinchoninic acid(BCA) kit (Pierce, Rockford, IL). As positive controls for NOSisoforms, proteins obtained from cytosolic fractions of cytokine-stimulatedRAW264.7 cells (NOS II) and membrane fraction of human endothelialcells (NOS III) were used. Equal amounts of protein (40 µg) weresize fractionated on 7.5% (wt/vol) SDS-PAGE and transferred toa polyvinylidene difluoride membrane. The blots were allowed todry in air and placed in blocking buffer [1% BSA (wt/vol) in 10mM Tris buffer with 100 mmol NaCl, 0.1% Tween 20 (vol/vol)] atpH 7.5, for 1 h at room temperature. The blots were incubatedwith specific monoclonal antibodies of NOS III and II (TransductionLaboratories Lexington, KY) for 1 h at room temperature. The blotswere washed three times for 30 min each with buffer [10 mM Tris,100 mmol NaCl, 0.1% Tween 20 (vol/vol), pH 7.5] incubated withhorseradish peroxidase-conjugated goat antimouse antibody (TransductionLaboratories). The membranes were washed, and proteins were visualizedusing the enhanced chemiluminescence kit (Amersham, ArlingtonHeights, IL). The intensity of specific immunoreactive bands onautoradiographic film was quantified using a densitometric image-scanningsystem (PDI, Huntinton Station,NY).

Immunofluorescent staining for the distribution of NOS II in pregnant rat uterus. The immunofluorescent staining method was performed by a modified immunofluorescence protocol (7, 41). Cryosections of5 µm from rat uterus were cut and fixed in 70% acetone. Five percentnormal goat serum and Avidin-Biotin blocking buffer were appliedto slides to reduce nonspecific binding. Because polyclonal antibodiesagainst NOS II (Upstate Biotechnology, Lake Placid, NY) and III(Transduction Laboratories) appeared to work better for immunofluroscentstudies (7, 41); these antibodies in PBS buffer were addedto the sections and incubated for 90 min. After slides were washedin PBS, they were incubated with biotinylated goat anti-rabbitIgG (Vector Lab, Burlingame, CA) for 45 min at 25°C. After washesin PBS, the detection step was performed with fluorescein avidin-D(Vector Lab) for 1 h at room temperature. Slides were then washedfour times in PBS, counterstained with propidium iodide to visualizenuclei, and mounted with Vectashield mounting media (Vector Lab),then they were viewed under a Nikon fluorescent microscope (Nikon,Mellville, NY). For negative control sections, rabbit IgG wasused in place of primaryantibodies.

Western immunoblotting analysis for TNF- $alpha$ in pregnant and nonpregnant OVX rat uterus. Full-thickness uterine tissues from OVX rats were homogenized as described above. Because TNF- $alpha$ has a molecular weight of18, the homogenates of uterine tissue were size fractionated on10%-20% (wt/vol) gradient SDS-PAGE gels. The polyclonal antibodyof TNF- $alpha$ raised against purified recombinant rat TNF- $alpha$ was usedat a dilution of 1:10,000. Both the antibody and the rat TNF- $alpha$ for positive control were from Biosource International (Carmarillo,CA) and horseradish peroxidase-conjugated goat anti-rabbit antibodywas from Santa Cruz Biotech (Santa Cruz, CA). The procedures forblotting were similar to that describedabove.

Statistical analysis. One-way ANOVA or Student's t-test was used to evaluate differences between various treatments. Differences were consideredsignificant at P < 0.05.

	RESULTS

TOP ABSTRACT INTRODUCTION MATERIAL AND METHODS RESULTS DISCUSSION REFERENCES

Nitrite production by uterine tissue from rats with intrauterine infection. Analysis of HPLC absorbence peaks of nitrite generated by the uterine tissue from nonpregnant and pregnant rats, a quantitativeindicator of NO production, is presented in Fig. 1. In nonpregnantrats, increases in nitrite production by the infected uterinehorn 12 or 24 h after bacterial inoculation were observed (P >0.05) compared with those from the noninfected uterine horn. Theseresults are similar to our previous report (7). Interestingly,NO production in the noninfected uterine horns of pregnant ratswas significantly higher (3.5-fold) compared with that of nonpregnantOVX rats (Fig. 1). However, in the infected horn of pregnant ratuterus, a significant induction after intrauterine infection wasnot demonstrable (Fig. 1). Moreover, the baseline uterine NO levelsin pregnant rats are similar to the infection-stimulated uterineNO levels in nonpregnant rats. This indicates that the uterineNO production may be at near maximum in pregnant rats and thatthere is a lack of uterine NO production increase on intrauterineinfection in pregnant rats.

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Fig. 1. Nitrite generated by uterine tissues from infected and noninfected horns of nonpregnant (NP) ovariectomized (OVX) rats and pregnant (P) rats at different time points after infection. Uterine tissues were obtained from rats killed at 12 and 24 h after bacterial inoculation. Data are presented as µmol/100 mg uterus, calculated from absorbance area. Results are means ± SE (n = 4) for both infected and noninfected horns. *P < 0.05.

Western immunoblotting analysis for NOS II of experimental rats. NOS II protein was undetectable in nonpregnant OVX animals, whereas it is expressed abundantly during pregnancy (Fig. 2A).Protein from murine macrophages was used as a control for NOSII. Densitometric analysis (Fig. 2B) indicated that intrauterineinfection of nonpregnant rats caused a significant elevation inthe expression of NOS II protein in infected uterine horn butnot in the noninfected horn when examined at 12 and 24 h afterinoculation (P < 0.05). In pregnant animals, however, no significantchanges were found in NOS II contents between the infected andnoninfected horns.

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Fig. 2. Western immunoblotting of protein for nitric oxide synthase (NOS) II using a monoclonal antibody in the tissue homogenate of uterus from P and NP OVX rats at 12 and 24 h after intrauterine infection. A: specific bands in the homogenates of the infected horn and noninfected horn from 2 representative rats in each group. B: relative densitometric changes in NOS II expression in the uterus. Data in each group are presented relative to the values from NP OVX rats at 12 h (100%). Values are the means ± SE from 4 animals in each group. M, mouse macrophage. *P < 0.05.

Western immunoblotting analysis for NOS III in rat uterine tissue. A specific band corresponding to the size of NOS III protein was present in the homogenate of all uterine horns from everytested group whether or not they received the bacterial inoculum.Densitometric analysis demonstrates that no significant differencesare apparent in the homogenates of infected and noninfected uterinehorns, either in pregnant or nonpregnant rats (Fig. 3B). Proteinfrom human endothelial cells was used as a control for NOS III.

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Fig. 3. Western immunoblotting of protein for NOS III using a monoclonal antibody in the tissue homogenate of uterus from P and NP OVX rats at 12 and 24 h after intrauterine infection. A: specific bands in the homogenates of infected horn and noninfected horn from 2 representative rats in each group. B: relative densitometric changes in NOS III expression in the uterus. Data in each group are presented relative to the values from NP OVX rats at 12 h (100%). Values are means ± SE from 4 animals in each group. E, human endothelial cells.

Immunofluorescent staining for the distribution of NOS II in pregnant rat uterus. Abundant staining for NOS II was detected in the uterine stromal layer and in the connective tissue area between myometrialbundles (Fig. 4a) in the infected uterine horn. No detectablestaining was visualized in epithelial and smooth muscle cells(Fig. 4a). A similar pattern of immunoreactivity for NOS II wasfound in sections from the noninfected horn of pregnant rats (Fig.4c). In the nonpregnant rat uterus, abundant staining for NOSII was detected in the uterine stromal layer in the infected horn,and no detectable staining was visualized in any cells in thenoninfected horn (see Ref. 7 for details).

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Fig. 4. Immunohistochemical localization of NOS II protein in cross sections from infected horn and noninfected horn from P rats at 24 h after intrauterine infection. Green fluorescence indicates NOS II-containing cells. E, epithelial cells; M, myometrium. No significant change in NOS-II staining is detectable in the infected and noninfected horn. All sections were counterstained with propidium iodide for nuclear viewing (red immunofluoresence). a: infected horn with NOS II antibody; b: infected horn without NOS II antibody; c: noninfected horn with NOS II antibody; d: infected horn without NOS II antibody. Arrows indicate NOS II-positive cells.

Western immunoblotting analysis for TNF- $alpha$ in rat uterine tissues. With the use of a similar immunoblotting method, the expression of TNF- $alpha$ protein was demonstrable in the uterine tissues ofnonpregnant OVX and pregnant rats, irrespective of infection (Fig.5A). However, the intensity of TNF- $alpha$ expression was greater inthe infected uterine horn compared with noninfected horn at 12and 24 h after infection, either in nonpregnant or pregnant rats.In addition, the levels of expression of uterine TNF- $alpha$ in responseto infection were greater in pregnant rats compared with thosefrom nonpregnant OVX rats (Fig. 5, P < 0.05).

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Fig. 5. Western immunoblotting of protein for tumor necrosis factor (TNF)- $alpha$ using a polyclonal antibody in the tissue homogenate of uterus from P and NP OVX rats at 12 and 24 h after intrauterine infection. A: specific bands in the homogenates of infected horn and noninfected horn from 2 representative rats in each group. B: relative densitometric changes in uterine TNF- $alpha$ expression in the uterus. Data in each are expressed relative to the values from NP OVX rats at 12 h (100%). Values are the means ± SE from 4 animals in each group. *P < 0.05. TNF- $alpha$ +, positive control band.

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIAL AND METHODS RESULTS DISCUSSION REFERENCES

Previous studies have suggested that the uterus is capable of NO generation and that NO may have a role in maintaining uterinequiescence during pregnancy (8, 17, 25, 34, 40-42). InducibleNOS (NOS II) expression is detectable in the pregnant rat uterusby Western blot and immunofluorescence microscopy (41) as wellas the presence of mRNA for NOS II (4). Constitutive NOS (NOSIII) expression is present both in the nonpregnant (2, 41)and in pregnant rat uterus (41). Furthermore, uterine NO andNOS expression may be important host-response factors to intrauterineinfection both in pregnant human and in experimental animals (7,16, 26).

The major finding of this study is that the pattern of the responsiveness of NOS II to intrauterine bacterial infection inpregnant rats is different from nonpregnant animals. Unlike thenonpregnant rats challenged with bacteria, there was no significantelevation in uterine NO production or NOS II protein expressionin pregnant rats (Fig. 1A, Fig. 2). Lack of changes in uterineNOS II protein expression due to infection observed in pregnantrats was also confirmed by immunofluorescence methods, i.e., noapparent changes in the pattern of distribution of NOS II-expressingcells (Fig. 4). This may be suggestive of a lack of response ofthe NO system (both NO production and inducible NOS II expression)to intrauterine bacterial infection in the pregnant state. Thislack of response could be due to saturation of NOS II expressionand NO generation during pregnancy to function as an endogenoussmooth muscle relaxation factor. Thus infection cannot inducefurther NOS II or NO production in the pregnant rat uterus. However,pregnancy appeared to be a state predisposed for increased complicationsassociated with intrauterine infection (1, 11, 14, 20,33). An elevated uterine NO production (constitutively) duringpregnancy may help contain or even reduce the infection-relatedcomplications. Therefore, if NO production is reduced during pregnancy,the infection-related complications may become more pronounced.This is further supported by our previous report in which inhibitionof NO with L-NAME increased the lethality of pregnant rats onintrauterine infection (26).

In this study, immunoblotting for NOS III demonstrated that intrauterine infection did not change the amount of this constitutiveNOS isoform (Fig. 3). This phenomenon was also observed in theuterus of infected nonpregnant OVX rats. This result further confirmsthat NOS III is a constitutive isoform in rat uterine tissue.In the absence of infection, both uterine NO production and NOSII protein expression were significantly higher in the pregnantrat uterus compared with those from nonpregnant rats (Figs. 1and 2). These observations are similar to our previous reports(4, 41, 42).

In our previous study, the uterine macrophage and NK cells in nonpregnant uterine tissues were shown to be the NOS II-expressingcells after infection (7). The distribution of NOS II-expressingcells in the current study is similar to our previously publisheddata in pregnant rats (41). No apparent differences were detectablein the distribution of NOS II-expressing cells between infectedand noninfected horns in pregnant rats. Together, immunolocalization(Fig. 4) and immunoblotting data (Fig. 2) in pregnant rats indicatethat infection did not induce NOS II expression when comparedwith the noninfectedhorn.

We found a significant increase in the expression of uterine TNF- $alpha$ protein after bacterial infection both in nonpregnant OVXrats and in pregnant rats. TNF- $alpha$ is a cytokine associated withinflammation and infection. The presence of bioactive TNF- $alpha$ inhuman amniotic fluid and placental culture supernatants indicatesits possible involvement in normal pregnancy (19). Intrauterineinfection-induced increases in TNF- $alpha$ both in pregnant and in nonpregnantrats observed in the current study are similar to the changesin uterine TNF- $alpha$ both in humans and in experimental animals withintrauterine infection (11). Several studies have shown thatlipopolysaccharide (LPS) stimulates TNF- $alpha$ protein in uterine macrophageand NK cells (18), cultured human fetal membranes, and decidualexplants (1). Furthermore, high levels of TNF- $alpha$ during gestationare associated with intrauterine infection and preterm labor (23,33).

TNF- $alpha$ has been shown to induce NOS II expression and subsequently increase NO production during infection. In nonpregnantrats, infection caused elevations in the levels of both TNF- $alpha$ and NOS II proteins and NO production in the uterus (Figs. 1 and2). In pregnant rats, however, infection stimulated the expressionof TNF- $alpha$ (Fig. 5) without changes in NOS II protein and NO production(Figs. 1 and 2). This may indicate that the NOS II expressionin pregnant rat uterus is no longer inducible by the increasedTNF- $alpha$ after infection, because the levels of this enzyme are alreadymaximally induced (Fig. 5). When pregnancy-associated elevationsin uterine NO are reduced by an inhibitor of NO, L-NAME, the severityof infection is increased resulting in higher lethality to infection(26). Moreover, NO presumably derived from tissue-associatedmacrophages and NK cells in the uterus may be an important antimicrobialcompound, and high local concentrations of NO may independentlyhave bacteriostatic or bactericidal effects during pregnancy.Thus perhaps the elevated NOS II expression may compensate forother potential immunological defects duringpregnancy.

Hirsch's laboratory (14) observed that the increased uterine TNF- $alpha$ levels in a mouse model with intrauterine E. coli infectionwere concomitant with the upregulation of inducible cyclooxengenaseenzyme. As a major gram-negative bacterial product, LPS activatestranscription of TNF- $alpha$ gene and stimulates massive productionof bactericidal molecules such as NO by macrophages and NK cells.Previous experiments from Hunt's lab (18) suggest that LPS maybe capable of stimulating TNF- $alpha$ production by nonlymphocytes aswell as by lymphocytes. For example, the human Jar cell (choriocarcinomacell) was reported to produce TNF- $alpha$ after the stimulation withLPS (44). In addition, the release of uterine TNF- $alpha$ and NO inuterine tissue was observed in the LPS-injected rat model. Theresults from our current study also suggest that uropathogenicE. coli is a strong stimulator for induction of TNF- $alpha$ and NOSII expression in nonpregnant rat uterine tissue. Previous studieson uropathogenic E. coli with P or type 1 fimbriae also indicatethat the fimbrial protein could activate the cytokine network(TNF- $alpha$ and IL-1 $beta$ ) of local mucosal epithelial cells and immunecells, either with LPS or alone (37). The E. coli strain, IH11128,that we used in this study expresses LPS and two types of fimbriae(type 1 and Dr); together, these factors may serve to induce TNF- $alpha$ and the NOsystem.

In summary, we used uropathogenic Dr+ E. coli to initiate an intrauterine bacterial infection in nonpregnant and pregnantrats and observed the responsiveness of the NO system and TNF- $alpha$ .We found that both NO production and NOS II expression in theuterus were increased in nonpregnant but not in pregnant rats.These studies suggest that the uterine NO system may be maximallyactivated during pregnancy to function as an endogenous relaxationfactor as well as a local antimicrobial agent to protect againstuterine infection. This upregulated NO system in the uterus cannotbe stimulatedfurther.

Perspectives

Intrauterine infection during pregnancy can result in increased neonatal morbidity and mortality, fetal growth retardation,and septicemia. It is suggested that immunological responses aredampened during pregnancy to accommodate the fetus. This reducedimmunological host-response state could provide ample opportunityfor amplification of the severity of potential infection. NO,a gas molecule, has been implicated as an important modulatorof infection and immunity through its antimicrobial activity.Our current study provides evidence that local NO synthesis andexpression of inducible NOS (NOS II) are increased on intrauterineinfection in the nonpregnant rat. However, in pregnant rats, thereis a lack of further increase in the NO system indicating thatthis system is functioning at maximum during pregnancy to protectagainst infection and also to provide smooth muscle relaxation.When pregnancy-associated elevations in uterine NO are reducedby an inhibitor (L-NAME), the severity of uterine infection isincreased, resulting in higher lethality (26). The elevatedlocal concentrations of NO in the uterus may have a bactericidalfunction, and thus perhaps the increased NOS II expression duringpregnancy may be compensatory for other potential immunologicaldeficiencies. Therefore, the uterine NO system during pregnancymay play an important role in maintaining host defense againstinfection, and disturbance of this system could result in infection-relatedcomplications.

	ACKNOWLEDGEMENTS

For editorial and graphic assistance, we thank Obstetrics/Gynecology Publications director and staff: R. G. McConnell, KristiBarrett, John Helms, and TraciSmith.

	FOOTNOTES

We gratefully acknowledge support received through grants from the National Institutes of Health: HD-30273 and HL-58144 toC. Yallampalli and DK-42029 to B. J.Nowicki.

Address for reprint requests and other correspondence: C. Yallampalli, Dept. of Obstetrics & Gynecology, 301 Univ. Blvd.,Medical Research Bldg., Rm. 11.138, Galveston, TX 77555-1062 (E-mail:chyallam{at}utmb.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 21 March 2000; accepted in final form 8 January 2001.

	REFERENCES

TOP ABSTRACT INTRODUCTION MATERIAL AND METHODS RESULTS DISCUSSION REFERENCES

1. Casey, ML, Cox SM, Beutler B, Milewich L, and MacDonald PC. Cachectin/tumor necrosis factor-alpha formation in human decidua. Potential role of cytokines in infection-induced preterm labor. J Clin Invest 83: 430-436, 1989.

2. Chatterjee, S, Gangula PR, Dong YL, and Yallampalli C. Immunocytochemical localization of nitric oxide synthase-III in reproductive organs of female rats during the oestrous cycle. Histochem J 28: 715-723, 1996[ISI][Medline].

3. Dammann, O, and Leviton A. Maternal intrauterine infection, cytokines, and brain damage in the preterm newborn. Pediatr Res 42: 1-8, 1997[ISI][Medline].

4. Dong, YL, Fang L, Gangula PR, and Yallampalli C. Regulation of inducible nitric oxide synthase messenger ribonucleic acid expression in pregnant rat uterus. Biol Reprod 59: 933-940, 1998[Abstract/Free Full Text].

5. Evans, TG, Thai L, Granger DL, and Hibbs JB, Jr. Effect of in vivo inhibition of nitric oxide production in murine leishmaniasis. J Immunol 151: 907-915, 1993[Abstract].

6. Fang, FC. Perspectives series: host/pathogen interactions. Mechanisms of nitric oxide-related antimicrobial activity. J Clin Invest 99: 2818-2825, 1997[ISI][Medline].

7. Fang, L, Nowicki BJ, Dong YL, and Yallampalli C. Localized increase in nitric oxide production and the expression of nitric oxide synthase isoforms in rat uterus with experimental intrauterine infection. Am J Obstet Gynecol 181: 601-609, 1999[ISI][Medline].

8. Figueroa, JP, and Massmann GA. Estrogen increases nitric oxide synthase activity in the uterus of nonpregnant sheep. Am J Obstet Gynecol 173: 1539-1545, 1995[ISI][Medline].

9. Forstermann, U, and Kleinert H. Nitric oxide synthase: expression and expressional control of the three isoforms. Naunyn Schmiedebergs Arch Pharmacol 352: 351-364, 1995[ISI][Medline].

10. Fukatsu, K, Saito H, Fukushima R, Inoue T, Lin MT, Inaba T, and Muto T. Detrimental effects of a nitric oxide synthase inhibitor (N-omega-nitro-L-arginine-methyl-ester) in a murine sepsis model. Arch Surgery 130: 410-414, 1995[Abstract].

11. Gomez, R, Ghezzi F, Romero R, Munoz H, Tolosa JE, and Rojas I. Premature labor and intra-amniotic infection. Clinical aspects and role of the cytokines in diagnosis and pathophysiology. Clin Perinatol 22: 281-342, 1995[ISI][Medline].

12. Granger, DL. Macrophage production of nitrogen oxides in host defense against microorganisms. Res Immunol 142: 570-572, 1991[ISI][Medline].

13. Hill, LV, Luther ER, Young D, Pereira L, and Embil JA. Prevalence of lower genital tract infections in pregnancy. Sex Transm Dis 15: 5-10, 1988[ISI][Medline].

14. Hirsch, E, Saotome I, and Hirsh D. A model of intrauterine infection and preterm delivery in mice. Am J Obstet Gynecol 172: 1598-1603, 1995[ISI][Medline].

15. Hsu, CD, Aversa K, Meaddough E, Lee IS, and Copel JA. Elevated amniotic fluid nitric oxide metabolites and cyclic guanosine 3',5'-monophosphate in pregnant women with intraamniotic infection. Am J Obstet Gynecol 177: 793-796, 1997[ISI][Medline].

16. Hsu, CD, Meaddough E, Lu LC, Chelouche A, Liang RI, Copel JA, and Parkash V. Immunohistochemical localization of inducible nitric oxide synthase on human fetal amnion in intra-amniotic infection. Am J Obstet Gynecol 179: 1271-1274, 1998[ISI][Medline].

17. Huang, PL, Huang Z, Mashimo H, Bloch KD, Moskowitz MA, Bevan JA, and Fishman MC. Hypertension in mice lacking the gene for endothelial nitric oxide synthase. Nature 377: 239-242, 1995[Medline].

18. Hunt, JS, Chen HL, and Miller L. Tumor necrosis factors: pivotal components of pregnancy. Biol Reprod 54: 554-562, 1996[Abstract].

19. Jaattela, M, Kuusela P, and Saksela E. Demonstration of tumor necrosis factor in human amniotic fluids and supernatants of placental and decidual tissues. Lab Invest 58: 48-52, 1988[ISI][Medline].

20. Krohn, MA, Hillier SL, Nugent RP, Cotch MF, Carey JC, Gibbs RS, and Eschenbach DA. The genital flora of women with intraamniotic infection. Vaginal Infection and Prematurity Study Group. J Infect Dis 171: 1475-1480, 1995[ISI][Medline].

21. Lowenstein, CJ, Alley EW, Raval P, Snowman AM, Snyder SH, Russell SW, and Murphy WJ. Macrophage nitric oxide synthase gene: two upstream regions mediate induction by interferon gamma and lipopolysaccharide. Proc Natl Acad Sci USA 90: 9730-9734, 1993[Abstract/Free Full Text].

22. Mitchell, MD, Edwin S, and Romero RJ. Prostaglandin biosynthesis by human decidual cells: effects of inflammatory mediators. Prostaglandins Leukot Essent Fatty Acids 41: 35-38, 1990[ISI][Medline].

23. Mussalli, GM, Blanchard R, Brunnert SR, and Hirsch E. Inflammatory cytokines in a murine model of infection-induced preterm labor: cause or effect? J Soc Gynecol Invest 6: 188-195, 1999[ISI][Medline].

24. Nathan, C, and Xie QW. Nitric oxide synthases: roles, tolls, and controls. Cell 78: 915-918, 1994[ISI][Medline].

25. Natuzzi, ES, Ursell PC, Harrison M, Buscher C, and Riemer RK. Nitric oxide synthase activity in the pregnant uterus decreases at parturition. Biochem Biophys Res Commun 194: 1-8, 1993[ISI][Medline].

26. Nowicki, B, Fang L, Singhal J, Nowicki S, and Yallampalli C. Lethal outcome of uterine infection in pregnant but not in nonpregnant rats and increased death rate with inhibition of nitric oxide. Am J Reprod Immunol 38: 309-312, 1997.

27. Nowicki, B, Martens M, Hart A, and Nowicki S. Gestational age-dependent distribution of Escherichia coli fimbriae in pregnant patients with pyelonephritis. Ann NY Acad Sci 730: 290-291, 1994[ISI][Medline].

28. Nowicki, B, Singhal J, Fang L, Nowicki S, and Yallampalli C. Inverse relationship between severity of experimental pyelonephritis and nitric oxide production in C3H/HeJ mice. Infect Immun 67: 2421-2427, 1999[Abstract/Free Full Text].

29. Payen, D, Bernard C, and Beloucif S. Nitric oxide in sepsis. Clin Chest Med 17: 333-350, 1996[ISI][Medline].

30. Polan, ML, Loukides J, Nelson P, Carding S, Diamond M, Walsh A, and Bottomly K. Progesterone and estradiol modulate interleukin-1 beta messenger ribonucleic acid levels in cultured human peripheral monocytes. J Clin Endocrinol Metab 69: 1200-1206, 1989[Abstract].

31. Rivera, DL, Olister SM, Liu X, Thompson JH, Zhang XJ, Pennline K, Azuero R, Clark DA, and Miller MJ. Interleukin-10 attenuates experimental fetal growth restriction and demise. FASEB J 12: 189-197, 1998[Abstract/Free Full Text].

32. Robb, JA, Benirschke K, and Barmeyer R. Intrauterine latent herpes simplex virus infection. I. Spontaneous abortion. Hum Pathol 17: 1196-1209, 1986[ISI][Medline].

33. Romero, R, Sirtori M, Oyarzun E, Avila C, Mazor M, Callahan R, Sabo V, Athanassiadis AP, and Hobbins JC. Infection and labor. V. Prevalence, microbiology, and clinical significance of intraamniotic infection in women with preterm labor and intact membranes. Am J Obstet Gynecol 161: 817-824, 1989[ISI][Medline].

34. Sladek, SM, Regenstein AC, Lykins D, and Roberts JM. Nitric oxide synthase activity in pregnant rabbit uterus decreases on the last day of pregnancy. Am J Obstet Gynecol 169: 1285-1291, 1993[ISI][Medline].

35. Spitzer, JA. Gender differences in nitric oxide production by alveolar macrophages in ethanol plus lipopolysaccharide-treated rats. Nitric Oxide 1: 31-38, 1997[ISI][Medline].

36. Stenger, S, Donhauser N, Thuring H, Rollinghoff M, and Bogdan C. Reactivation of latent leishmaniasis by inhibition of inducible nitric oxide synthase. J Exp Med 183: 1501-1514, 1996[Abstract/Free Full Text].

37. Svanborg, C, Godaly G, and Hedlund M. Cytokine responses during mucosal infections: role in disease pathogenesis and host defence. Curr Opin Microbiol 2: 99-105, 1999[ISI][Medline].

38. Tiao, G, Rafferty J, Ogle C, Fischer JE, and Hasselgren PO. Detrimental effect of nitric oxide synthase inhibition during endotoxemia may be caused by high levels of tumor necrosis factor and interleukin-6. Surgery 116: 332-337, 1994[ISI][Medline].

39. Weinberg, ED. Pregnancy-associated immune suppression: risks and mechanisms. Microb Pathog 3: 393-397, 1987[ISI][Medline].

40. Yallampalli, C, Byam-Smith M, Nelson SO, and Garfield RE. Steroid hormones modulate the production of nitric oxide and cGMP in the rat uterus. Endocrinology 134: 1971-1974, 1994[Abstract].

41. Yallampalli, C, Dong YL, Gangula PR, and Fang L. Role and regulation of nitric oxide in the uterus during pregnancy and parturition. J Soc Gynecol Invest 5: 58-67, 1998[ISI][Medline].

42. Yallampalli, C, Garfield RE, and Byam-Smith M. Nitric oxide inhibits uterine contractility during pregnancy but not during delivery. Endocrinology 133: 1899-1902, 1993[Abstract].

43. Yallampalli, C, Izumi H, Byam-Smith M, and Garfield RE. An L-arginine: nitric oxide-cGMP system exists in the uterus and inhibits contractility during pregnancy. Am J Obstet Gynecol 170: 175-85, 1994[ISI][Medline].

44. Yang, Y, Yelavarthi KK, Chen HL, Pace JL, Terranova PF, and Hunt JS. Molecular, biochemical, and functional characteristics of tumor necrosis factor-alpha produced by human placental cytotrophoblastic cells. J Immunol 150: 5614-5624, 1993[Abstract].

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