Abnormal extracellular matrix remodelling in the cervix of pregnant relaxin-deficient mice is not associated with reduced matrix metalloproteinase expression or activity.

Relaxin regulates cervical extracellular matrix (ECM) remodelling during pregnancy by modifying collagen and other ECM molecules by unknown mechanisms. We hypothesised that abnormal collagen remodelling in the cervix of pregnant relaxin-deficient (Rln1-/-) mice is due to excessive collagen (Col1a1 and Col3a1) and decreased matrix metalloproteinases (Mmp2, Mmp9, Mmp13 and Mmp7) and oestrogen receptors (Esr1 and Esr2). Quantitative polymerase chain reaction, gelatinase zymography, MMP activity assays and histological staining evaluated changes in ECM in pregnant wildtype (Rln1+/+) and Rln1-/- mice. Cervical Col1a1, Col3a1 and total collagen increased in Rln1-/- mice and were higher at term compared with Rln1+/+ mice. This was not correlated with a decrease in gelatinase (Mmp2, Mmp9) expression or activity, Mmp7 or Mmp13 expression, which were all significantly higher in Rln1-/- mice. In late pregnancy, circulating MMP2 and MMP9 were unchanged. Esr1 expression was highest in Rln1+/+ and Rln1-/- mice in late pregnancy, coinciding with a decrease in Esr2 in Rln1+/+ but not Rln1-/- mice. The relaxin receptor (Rxfp1) decreased slightly in late-pregnant Rln1+/+ mice, but was significantly higher in Rln1-/- mice. In summary, relaxin deficiency results in increased cervical collagen in late pregnancy, which is not explained by a reduction in Mmp expression or activity or decreased Rxfp1. However, an imbalance between Esr1 and Esr2 may be involved.

Evolution of the CDKN1C-KCNQ1 imprinted domain.

BACKGROUND: Genomic imprinting occurs in both marsupial and eutherian mammals. The CDKN1C and IGF2 genes are both imprinted and syntenic in the mouse and human, but in marsupials only IGF2 is imprinted. This study examines the evolution of features that, in eutherians, regulate CDKN1C imprinting. RESULTS: Despite the absence of imprinting, CDKN1C protein was present in the tammar wallaby placenta. Genomic analysis of the tammar region confirmed that CDKN1C is syntenic with IGF2. However, there are fewer LTR and DNA elements in the region and in intron 9 of KCNQ1. In addition there are fewer LINEs in the tammar compared with human and mouse. While the CpG island in intron 10 of KCNQ1 and promoter elements could not be detected, the antisense transcript KCNQ1OT1 that regulates CDKN1C imprinting in human and mouse is still expressed. CONCLUSION: CDKN1C has a conserved function, likely antagonistic to IGF2, in the mammalian placenta that preceded its acquisition of imprinting. CDKN1C resides in synteny with IGF2, demonstrating that imprinting of the two genes did not occur concurrently to balance maternal and paternal influences on the growth of the placenta. The expression of KCNQ1OT1 in the absence of CDKN1C imprinting suggests that antisense transcription at this locus preceded imprinting of this domain. These findings demonstrate the stepwise accumulation of control mechanisms within imprinted domains and show that CDKN1C imprinting cannot be due to its synteny with IGF2 or with its placental expression in mammals.

Mechanisms of relaxin action in the reproductive tract: studies in the relaxin-deficient (Rlx-/-) mouse.

The major functions of relaxin (RLX) are associated with female reproductive tract physiology, namely, the regulation of biochemical processes involved in remodeling of extracellular matrix components in the cervix and vagina at term. Studies in RLX-deficient mice (Rlx-/-) demonstrate that although females give birth to live young without apparent dystocia, the pubic symphysis is not elongated, and they have abnormal cervical and vaginal morphology. The current study examined phenotypic differences in collagen, matrix metalloproteinases (MMP), and estrogen receptors (ERs) in the cervix and vagina of pregnant Rlx+/+ and Rlx-/- mice. Neither collagen nor TGFbeta1 mRNA levels in the cervix and vagina differed significantly between Rlx+/+ and Rlx-/- at any stage of gestation, except on gestation day 18.5, with an increase in alpha(1)-I collagen and TGFbeta1 expression in Rlx-/- mice. MMP gene expression was also increased in Rlx-/- mice, especially at term. Administration of recombinant H2 RLX (0.05 microg/microL/h) to Rlx-/- mice for 6 d from gestation day 12.5 caused a significant decrease in alpha1-I collagen and MMP-13 gene expression in the cervix and vagina, but it had no effect on TGFbeta1. There was also a significant reduction in ERbeta expression in RLX-treated Rlx-/- mice. Interestingly, RLX treatment caused a significant decrease in LGR7 expression in these reproductive tissues. In summary, these data show increases in MMP gene expression in Rlx-/- mice that are not correlated with changes in collagen expression. Furthermore, we report a novel ER phenotype in the cervix and vagina of Rlx-/- mice.

Oxytocin and estrogen receptor expression in the myometrium of pregnant relaxin-deficient (Rlx-/-) mice.

Relaxin decreases oxytocin-stimulated rat myometrial contractions in vitro. This study used pregnant relaxin-deficient (Rlx-/-) mice to investigate the interaction between relaxin, oxytocin receptor (OTR), and estrogen receptor (ER) expression in the myometrium. Myometrial OTRs were significantly decreased on gestation day 18.5 in Rlx-/- mice than in Rlx+/+ mice. An increase in ERalpha in Rlx+/+ mice at term was correlated with a decrease in ERbeta, which was not observed in Rlx-/- mice. Treatment of Rlx-/- mice with relaxin had no effect on OTR, LGR7, or ERalpha expression, but it caused a significant decrease in ERbetas.

Effects of the sucking stimulus on relaxin receptor (LGR7) expression in the mammary apparatus of the tammar wallaby (Macropus eugenii).

Macropodid marsupials suckle young of different ages simultaneously, a phenomenon known as asynchronous lactation. The growth of the mammary glands supporting young of different ages varies considerably. This study investigates relaxin receptor (LGR7) expression in different mammary glands and nipples during early lactation in the wallaby. LGR7s were upregulated in the nipple and mammary gland supporting the neonate 5-11 d postpartum. LGR7 mRNA concentrations were also significantly higher in the gland supporting the newborn young than the older young. These data suggest that a local stimulus, that is, continuous sucking by the neonate, may influence LGR7 expression in the mammary apparatus.

Increased expression of the relaxin receptor (LGR7) in human endometrium during the secretory phase of the menstrual cycle.

This study investigated localization and expression of relaxin and its receptor, LGR7, in the human endometrium during the proliferative and secretory phases of the menstrual cycle. H2 relaxin binding was identified in endometrium, but not myometrium, and particularly in the epithelium of the endometrial glands and uterine lumen. Binding sites increased in the early secretory phase of the menstrual cycle and were paralleled by similar increases in LGR7 mRNA measured by Q-PCR. The increase in LGR7 expression and H2 relaxin binding in the secretory phase of the menstrual cycle suggests a specific role for relaxin after ovulation in the human uterus.

Increased expression of the relaxin receptor (LGR7) in human endometrium during the secretory phase of the menstrual cycle.

Relaxin (RLX) is a structural homolog of insulin that is the ligand for the LGR7 receptor. Although the 6k peptide is produced by the ovaries to cause connective tissue remodeling of the rodent and pig reproductive tracts to facilitate parturition, in human reproduction, the role of RLX is less well understood. Binding of human gene 2 (H2) [(33)P]-RLX, expression of RLX peptides and the LGR7 receptor was examined in the human uterus at different stages of the menstrual cycle. A significant increase in RLX receptor binding in endometrium was identified by quantitative autoradiography in the secretory compared with the proliferative phase. H2RLX competed with [(33)P]-H2RLX binding with higher affinity than porcine RLX during both the proliferative and secretory phases. Increased LGR7 receptor gene expression during the secretory phase paralleled the changes in [(33)P]-H2RLX binding. Human gene 1 RLX transcripts were not detected in the uterus, and H2RLX gene expression was low and not influenced by the stage of the menstrual cycle. The studies show that binding to and gene expression of the LGR7 RLX receptor changes markedly with the phases of the menstrual cycle, suggesting a specific role for the hormone in the physiology of the human uterus.

Inhibition of oxytocin receptor and estrogen receptor-alpha expression, but not relaxin receptors (LGR7), in the myometrium of late pregnant relaxin gene knockout mice.

This study used relaxin (RLX) gene knockout mice (Rlx-/-) to investigate the effects of RLX on myometrial oxytocin receptor (OTR) and estrogen receptor (ER)-alpha gene expression in late gestation. We also characterized the temporal expression of the RLX receptor (LGR7) and demonstrated gene transcripts in the myometrium of Rlx+/+ and Rlx-/- mice. There was a significant (P < 0.05) decrease in myometrial LGR7 gene expression on d 17.5 and 18.5 post coitum (pc) compared with earlier stages of gestation, but no differences between Rlx+/+ and Rlx-/- mice. Myometrial OTR mRNA levels increased at the end of gestation in Rlx+/+ but not Rlx-/- mice. ERalpha gene expression was up-regulated on d 14.5 pc in Rlx+/+ mice, with mRNA levels remaining high throughout late gestation. In contrast, ERalpha mRNA levels were significantly lower in Rlx-/- mice on d 14.5 and 18.5 pc. These data show that the increases in myometrial OTR and ERalpha expression in late pregnant Rlx+/+ mice were attenuated in Rlx-/- mice. The effects of RLX on OTRs are probably mediated via activation of ERalpha. Finally, RLX receptor expression in the myometrium of Rlx-/- mice did not differ from wild-type mice, implying that RLX does not influence expression of its receptor.

Effects of fetectomy on oxytocin receptors in the myometrium of the tammar wallaby.

Mesotocin, an oxytocin-like peptide, stimulates uterine contractions during marsupial parturition. Female marsupials have two separate uteri, and in monovular species, the uterus with the conceptus is gravid, whereas the contralateral uterus is nongravid. Marsupials are unique because systemic and feto-placental factors in the regulation of uterine function can be differentiated. In pregnant tammar wallabies, a marked increase in myometrial mesotocin receptors (MTRs) occurs on Day 23 of the 26-day gestation, but only in the gravid uterus. The objective of this study was to investigate the effects of removing the conceptus on this MTR up-regulation. Complete fetectomy on Day 20 of gestation resulted in significantly lower MTR mRNA and receptor concentrations on Day 23 compared with sham-operated controls. In contrast, there was no significant difference in MTR expression between controls and partially fetectomized animals in which uterine distension was maintained in the absence of a conceptus. In a related study, we examined MTRs in the myometrium of animals that appeared to be pregnant with a large, distended uterus. However, these uteri contained an abnormally developed fetus and avascular placenta. In these animals, MTR levels were significantly higher in the distended uterus compared with the nondistended uterus, and did not differ from controls. These data demonstrate that uterine occupancy is essential for the marked increase in uterine MTRs observed on Day 23 gestation. It also appears that distension may be one of the key factors involved.

Up-regulation of mesotocin receptors in the tammar wallaby myometrium is pregnancy-specific and independent of estrogen.

The oxytocin-like peptide of most Australian marsupials is mesotocin, which stimulates uterine contractions and is important for normal birth in the tammar wallaby. Female marsupials have two uteri and, in monovular species such as the tammar, one uterus is gravid with a single fetus, whereas the contralateral uterus is nongravid. A significant increase in myometrial mesotocin receptor concentrations occurs only in the gravid uterus on Day 23 of the 26-day gestation. This study examined whether or not mesotocin receptors are present in the myometrium and are up-regulated at the equivalent stage of the luteal phase in unmated tammars. In contrast to the marked increase in mesotocin receptor mRNA and protein concentrations in the myometrium of the gravid uterus during pregnancy, receptors did not increase in the unmated animals. There were also no significant differences between the two uteri, except on Day 27. Plasma profiles of peripheral estradiol-17beta and progesterone did not differ significantly between pregnant and nonpregnant cycles. However, progesterone concentrations were significantly lower on Day 1 postpartum compared with Day 27 of the nonpregnant cycle. In pregnant tammars, the molar ratio of circulating estradiol-17beta to progesterone increased significantly between Day 25 of gestation and 1 day postpartum, but was not correlated with an increase in mesotocin receptor concentrations in either uterus. The data confirm that a local fetal influence is more important than systemic factors, such as estrogen, in the regulation of uterine mesotocin receptors in the tammar wallaby.