The rate of cervical change and the phenotype of spontaneous preterm birth.

OBJECTIVE: Preterm birth is classified by the presence of uterine contractions and/or amniorrhexis at clinical presentation. This classification does not include prior cervical change. We hypothesized that the rate of cervical shortening before preterm birth would not differ according to clinical presentation. STUDY DESIGN: We analyzed data from a completed study of paired cervical ultrasound measurements to test our hypothesis. Cervical ultrasound measurements obtained 4 weeks apart in the second trimester were related to gestational age and clinical presentation at birth. RESULTS: Of 2521 eligible women, 128 were delivered after preterm labor and 106 after preterm membrane rupture; 89 delivered preterm for a medical or obstetrical indication; 2198 delivered at term. The rate of change was similar in women who presented with preterm labor (-0.96 mm/week) and preterm ruptured membranes (-0.82 mm/week). CONCLUSION: Cervical shortening occurs at the same rate before spontaneous preterm birth, regardless of presentation.

Beta-2 adrenoceptor genotype and progress in term and late preterm active labor.

OBJECTIVE: We sought to evaluate whether beta-2 adrenoceptor (ß2AR) genotype at a functional polymorphic site encoding for amino acid residue 16 influences rate of cervical dilatation in term and late preterm active labor. STUDY DESIGN: Subjects who underwent vaginal delivery at ≥34 weeks' gestational age from May 2006 through August 2007 were identified. Each subject had provided venous blood from which DNA was extracted for ß2AR genotyping. Digital cervical examinations with paired examination times were collected from intrapartum records. Rate of cervical dilatation in active labor was determined using linear regression. Rates were compared between genotype groups. RESULTS: Among 401 subjects with satisfactory genotype and intrapartum data, overall rate of active labor was 0.76±0.01 cm/h. When labor was compared by genotype, homozygous Arg/Arg16 subjects progressed at a slower rate (0.64±0.03 cm/h) than all other pooled genotypes (0.8±0.02 cm/h, P<.001). CONCLUSION: Homozygous ß2AR genotype encoding for Arg/Arg16 was associated with slower progress in active labor.

Pro-inflammatory and anti-inflammatory cytokines in human preterm and term cervical ripening.

Cervical ripening is necessary for successful delivery. Since cytokines are believed to be involved in this process, the aim of this study was to investigate possible changes in the mRNA and protein expression of pro-inflammatory cytokines (interleukin (IL)-1alpha, IL-1beta, IL-12, IL-18) and anti-inflammatory cytokines (IL-4, IL-10, IL-13) in the human cervix during pregnancy, term and preterm labor. Cervical biopsies were taken from 59 women: 21 at preterm labor, 24 at term labor, 10 at term not in labor and 4 from non-pregnant women. mRNA was analyzed with real-time RT-PCR and protein expression and/or secretion with immunohistochemistry and ELISA. There was an upregulation of mRNA for IL-10, IL-13, IL-1alpha and IL-1beta in the laboring groups, while mRNA for IL-12 and IL-18 was downregulated. IL-4 mRNA was detected more frequently, while IL-12 mRNA expression was lower, in the preterm labor group than in the term labor group. The protein levels of IL-4 and IL-12 were lower and IL-18 tended to be higher in the labor groups, while IL-10 protein levels were unaffected by labor. IL-4 protein levels were significantly higher in the preterm subgroup with bacterial infection than in the non-infected group. IL-10 had higher expression in squamous epithelium at preterm labor than at term. In conclusion, the major changes in pro-inflammatory and anti-inflammatory cytokine mRNA and protein expression in cervix occur during the labor process irrespective of the length of gestation. Our results indicate that dysregulation of anti-inflammatory cytokines in the human cervix could be involved in the pathogenesis of preterm labor.

The transcriptome of cervical ripening in human pregnancy before the onset of labor at term: identification of novel molecular functions involved in this process.

OBJECTIVE: The aim of this study was to identify changes in the cervical transcriptome in the human uterine cervix as a function of ripening before the onset of labor. STUDY DESIGN: Human cervical tissue was obtained from women at term not in labor with ripe (n = 11) and unripe (n = 11) cervices and profiled using Affymetrix GeneChip HGU133Plus2.0 arrays. Gene expression was analyzed using a moderated t-test (False Discovery Rate 5%). Gene ontology and pathway analysis were performed. Quantitative reverse transcription-polymerase chain reaction (qRT-PCR) was used for confirmation of selected differentially expressed genes. RESULTS: (1) Ninety-one genes were differentially expressed between ripe and unripe groups. (2) Cervical ripening was associated with enrichment of specific biological processes (e.g. cell adhesion, regulation of anatomical structure), pathways and 11 molecular functions (e.g. extracelluar matrix (ECM)-structural constituent, protein binding, glycosaminoglycan binding). (3) qRT-PCR confirmed that 9 of 11 tested differentially expressed genes (determined by microarray) were upregulated in a ripe cervix (e.g. MYOCD, VCAN, THBS1, COL5A1). (4) Twenty-three additional genes related to ECM metabolism and adhesion molecules were differentially regulated (by qRT-PCR) in ripe cervices. CONCLUSION: (1) This is the first description of the changes in the human cervical transcriptome with ripening before the onset of labor. (2) Biological processes, pathways and molecular functions were identified with the use of this unbiased approach. (3) In contrast to cervical dilation after term labor, inflammation-related genes did not emerge as differentially regulated with cervical ripening. (4) Myocardin was identified as a novel gene upregulated in human cervical ripening.

Preterm and term cervical ripening in CD1 Mice (Mus musculus): similar or divergent molecular mechanisms?

Premature cervical ripening is believed to contribute to preterm birth (PTB). Preterm cervical ripening may be due to an aberrant regulation in timing of the same processes that occur at term, or may result from unique molecular mechanisms. Using mouse models of PTB, this study sought to investigate if the molecular mechanisms that govern cervical ripening were similar between preterm and term. Lipopolysaccharide (LPS) is infused into the uterine horn to create a mouse model of inflammation-induced PTB. For a noninfectious model of PTB, RU486 was administered. Both models result in delivery of pups in 8-24 h. Cervical tissues were collected from these models, as well as throughout gestation. Cervical tissues from E15 (preterm), E15 LPS (preterm inflammation), and E18.5 (term) were used for microarray analysis (n = 18). Additional experiments using gestational time course specimens were performed to confirm microarray results. Specific gene pathways were differentially expressed between the groups. Genes involved in immunity and inflammation were increased in the cervix in inflammation-induced PTB; term labor was not associated with differential expression of immune pathways. Cytokine expression was not increased in cervices during term labor, but was increased in the pospartum period. Epithelial cell differentiation pathway was significantly altered in term, but not preterm, labor. Activation of immune pathways may be sufficient for cervical ripening, but does not appear necessary. Differential expression of the epithelial cell differentiation pathway appears necessary in the process of cervical repair. Our results indicate that the molecular mechanisms governing preterm and term cervical ripening are distinctly different.

Preventing cervical ripening: the primary mechanism by which progestational agents prevent preterm birth?

OBJECTIVE: Recent clinical trials suggest that progestational agents may prevent preterm birth, specifically in women with short cervices. These studies sought to assess novel pathways by which progestational agents (PAs) may modify signal transduction pathways that are involved in cervical ripening. STUDY DESIGN: A microarray analysis was performed on pregnant mouse cervix that was exposed to a MPA. Appropriate microarray and cluster analyses were performed. Target genes of interest were investigated in both PA- and inflammation-exposed cervices by quantitative polymerase chain reaction and immunohistochemistry. RESULTS: Microarray analysis identified both the previously recognized and novel pathways that are involved in cervical ripening. PAs differentially regulate expression of claudin-2, hyaluronan synthase 2, and lipocalin 2. Claudin expression is significantly decreased by inflammation, which is prevented by PAs. CONCLUSION: PAs significantly modulate gene expression in the cervix in the presence and absence of inflammation. The regulation of these pathways, specifically claudin proteins, may be a critical mechanism by which PAs prevent preterm birth, especially in women with premature cervical shortening.

Androgen-regulated cervical ripening: a structural, biomechanical, and molecular analysis.

OBJECTIVE: Androgens regulate biomechanical responses in load-bearing tissues. Evidence suggests that androgens may play a role in the cervix. We hypothesized that androgens directly regulate cervical remodeling by altering both collagen structure and proteoglycan composition. STUDY DESIGN: Cervical resistance was evaluated using the cervical creep method after the administration of intravaginal dihydrotestosterone or oral flutamide. Microstructural changes in collagen were evaluated by transmission electron microscopy and polarized light birefringence. Proteoglycan expression was evaluated by reverse transcription-polymerase chain reaction for the core proteins (decorin, biglycan, fibromodulin, aggrecan, versican) and fluorophore-assisted carbohydrate analysis. RESULTS: Dihydrotestosterone decreased cervical resistance, whereas flutamide inhibited the decline in cervical resistance, compared with vehicle controls. Flutamide was associated with higher levels of organized collagen and increased aggrecan expression with a greater proportion of chondroitin/dermatan sulfate glycosaminoglycans. Flutamide inhibited the increase in hyaluronan. CONCLUSION: Androgens appear to play a role in regulating cervical resistance by altering proteoglycan content. Structural analysis indicates that flutamide may alter collagen fibril organization and/or structure.

Parturition and recruitment of macrophages in cervix of mice lacking the prostaglandin F receptor.

Parturition does not occur in transgenic mice lacking the prostaglandin F receptor (Ptgfr(-/-)) because luteolysis is forestalled and progesterone production persists. Ovariectomy of pregnant Ptgfr(-/-) mice leads to a decline in circulating progesterone and delivery of live pups. The objective of the present study was to test the hypothesis that immigration of macrophages and increased innervation of the cervix of Ptgfr(-/-) mice was associated with ripening and parturition. The cervix of pregnant Ptgfr(-/-) mice was studied on Days 15-21 after breeding; additional groups were ovariectomized on Day 19 of pregnancy, and the cervix obtained on Day 20 of pregnancy before birth or the next day at about 24 h after birth. On Days 18-19 of pregnancy, macrophage numbers and nerve fiber density increased more than 3-fold compared with findings in nonpregnant or Day 15 or 21 pregnant Ptgfr(-/-) mice. The magnitude and time course of these changes were comparable to those found in wild-type controls that delivered on Day 19 after breeding. Thus, the mechanism regulating macrophage immigration, innervation, and cervical remodeling in Ptgfr(-/-) mice with delayed parturition is similar to wild-type controls that deliver at term. By contrast, ovariectomy forestalled the decrease in cervical macrophages in Ptgfr(-/-) mice. By Day 21 after breeding, macrophage numbers more than double those after ovariectomy, relative to those found in pregnant Ptgfr(-/-) mice, whereas nerve fiber density was the same regardless of birth. Density of collagen structure in these mice directly matched macrophage traffic in the cervix. The findings indicate that the prostaglandin F(2alpha) receptor and progesterone withdrawal are a necessary part of the final common pathway for ripening of the cervix and the process of parturition.

Processes regulating cervical ripening differ from cervical dilation and postpartum repair: insights from gene expression studies.

A greater understanding of the processes that regulate cervical remodeling during pregnancy, parturition, and the postpartum period is required to understand causes of preterm and posterm birth in which abnormal cervical function is the primary culprit. In the current study, gene expression patterns unique to cervical ripening as compared with cervical dilation and/or postpartum repair are identified in a mouse model. Genes differentially regulated from gestation day 15 to late day 18 reveal processes important for cervical ripening. Genes differentially regulated from late day 18 to 2 hours after birth reveal processes that could be important during cervical dilation or the postpartum recovery period. Based on expression patterns, cervical ripening requires a downregulation of collagen assembly genes; increased synthesis of glycosaminoglycans that disrupt the matrix, such as hyaluronan; increased metabolism of progesterone; and changes in epithelial barrier properties. The latter phases of dilation and postpartum recovery are associated with increased assembly of mature collagen, synthesis of matrix proteins that promote a dense connective tissue, activation of inflammatory responses, prostaglandin synthesis, and further changes in epithelial barrier properties and differentiation. Processes/gene expression required for cervical ripening are distinct from those important in latter phases of cervical remodeling and highlight the importance of timing of tissue collection for understanding the molecular mechanisms of cervical ripening.

Signaling via the type I IL-1 and TNF receptors is necessary for bacterially induced preterm labor in a murine model.

OBJECTIVE: We have shown previously that interleukin 1 (IL-1) signaling is not necessary for bacterially induced preterm delivery in mice. We now test whether combined signaling of IL-1 and tumor necrosis factor (TNF) is critical for this process. STUDY DESIGN: Female mice lacking the type I receptors for IL-1 and TNF (Il1r1/Tnfrsf1a double-knockouts) and normal controls underwent intrauterine inoculation with killed Escherichia coli bacteria on day 14.5 of a 19- to 20-day gestation. Preterm delivery rates within 48 hours were recorded and gene expression was analyzed by reverse transcription-polymerase chain reaction (RT-PCR). RESULTS: Il1r1/Tnfrsf1a double-knockout mice had significantly lower rates of preterm delivery than controls (8% vs 69% with 7 x 10(7) bacteria, P = .002, and 52% vs 81% with 1.4 x 10(8) bacteria, P = .003) and significantly lower myometrial levels of cyclooxygenase (COX)-2, but not COX-1 mRNA. There were no genotype- or treatment-related differences in cervicovaginal and lower uterine expression of mRNAs for a variety of genes associated with cervical ripening. CONCLUSION: The combination of IL-1 and TNF signaling plays a critical role in bacterially induced labor and myometrial COX-2 production in the mouse. Cervical gene expression patterns during bacterially induced preterm labor suggest fundamental differences from spontaneous term labor in the cervical ripening process.

Impaired nipple development and parturition in LGR7 knockout mice.

LGR7 is a G-protein coupled receptor with structural homology to the gonadotrophin and thyrotrophin receptors. Recently, LGR7 was deorphanized, and it was shown that relaxin is the ligand for LGR7. To further study the function of this receptor, mice deficient for LGR7 were generated by replacing part of the transmembrane-encoding region with a LacZ reporter cassette. Here we show that LGR7 is expressed in various tissues, including the uterus, heart, brain, and testis. Fertility studies using female LGR7-/- mice showed normal fertility and litter size. However, some females were incapable of delivering their pups, and several pups were found dead. Moreover, all offspring died within 24 to 48 h after delivery because female LGR7-/- mice were unable to feed their offspring due to impaired nipple development. In some male LGR7-/- mice, spermatogenesis was impaired, leading to azoospermia and a reduction in fertility. Interestingly, these phenomena were absent in mutant mice at older ages or in later generations. Taken together, results from LGR7 knockout mice indicate an essential role for the LGR7 receptor in nipple development during pregnancy. Moreover, a defect in parturition was observed, suggesting a role for LGR7 in the process of cervical ripening.