Endoplasmic reticulum stress response and the regulation of endometrial interferon-beta production.

Objective: To gain an understanding of the potential role of endoplasmic reticulum (ER) stress in the endometrial compartment during early pregnancy, a highly understudied area.

Design: This study examined the regulation of interferon-β (IFNβ) in response to ER stress in human decidualized and nondecidualized endometrial cells (human endometrial stromal cells [HESCs]) in vitro. In vivo, we examined ER stress and the IFNβ levels locally in the mouse endometrium before and after implantation at embryonic day (E)1, E3, and E6.

Preimplantation apoptotic endometrial caspase-3-mediated phospholipase A2 activation: a potential component in programming uterine receptivity.

Objective: To examine the activation and consequence of uterine apoptotic caspase-3 action on 1 day after coitus (dpc) in the pregnant mouse. We have previously demonstrated that in a pregnant uterus, caspase-3 activation from mid to late gestation isolated to the myometrial compartment is largely nonapoptotic and controls uterine quiescence. Additionally, we had demonstrated that apoptotic caspase-3 activation isolated to the endometrial compartment at term regulated endometrial prostaglandin synthesis.

Steroidogenic Factor 1 (Nr5a1) is Required for Sertoli Cell Survival Post Sex Determination.

The elevated level of Steroidogenic Factor 1 (Nr5a1, Sf-1) expression in the male gonadal development pathway, post sex determination, implies a vital role in testis gonadal differentiation. In this study we generated Sertoli cell-specific Nr5a1 KO mice (SC-SF-1) at E14.5, which coincides with testis development post sex determination, using the Amh-Cre mouse model.

Estrogen receptor alpha isoform ERdelta7 in myometrium modulates uterine quiescence during pregnancy.

Background: Circulating estrogen (E2) levels are high throughout pregnancy and increase towards term, however its local tissue specific actions vary across gestation. For example, myometrial E2 regulated uterotonic action is disabled until term, whereas it's proliferative function is maintained in the breast. We have identified gestationally regulated splicing events, mediated by hnRNPG and modulated by E2 that generate alternatively spliced estrogen receptor alpha (ERα) variants (ERΔ7 and ERα46) in the myometrium.

Preconditioning the uterine unfolded protein response maintains non-apoptotic Caspase 3-dependent quiescence during pregnancy.

The prevention of apoptotic caspase 3 activation through biological preconditioning, mediated through the modulation of the unfolded protein response has been demonstrated to ameliorate multiple pathophysiologies. The maintenance of non-apoptotic caspase 3 activity by the unfolded protein response within the pregnant uterus has previously been proven to be critical in inhibiting uterine myocyte contractility during pregnancy. Here we report that the pregnant uterus utilizes an unfolded protein response-preconditioning paradigm to conserve myometrial caspase 3 in a non-apoptotic state in order to effectively inhibit uterine contractility thereby preventing the onset of preterm labor.

Thinking Outside the Box.

A broad definition of preconditioning is "the preparation for a subsequent action." Mounting evidence demonstrates that novel remote preconditioning paradigms, in which protective stimuli experienced locally can capacitate systemic tolerance and enhanced cell viability upon exposure to ensuing cellular insults, have been largely successful in the field of cardiovascular ischemia/reperfusion injury. To ensure successful protective preconditioning, some models (including the uterus) have been demonstrated to activate the unfolded protein response (UPR), which is a cellular stress response controlled at the level of the endoplasmic reticulum.

The Unfolded Protein Response Regulates Uterine Myocyte Antioxidant Responsiveness During Pregnancy.

There is considerable evidence that implicates oxidative stress in the pathophysiology of human pregnancy complications. However, the role and the mechanism of maintaining an antioxidant prosurvival uterine environment during normal pregnancy is largely unresolved. Herein we report that the highly active uterine unfolded protein response plays a key role in promoting antioxidant activity in the uterine myocyte across gestation.

Steroid receptor coactivators 1 and 2 mediate fetal-to-maternal signaling that initiates parturition.

The precise mechanisms that lead to parturition are incompletely defined. Surfactant protein-A (SP-A), which is secreted by fetal lungs into amniotic fluid (AF) near term, likely provides a signal for parturition; however, SP-A-deficient mice have only a relatively modest delay (~12 hours) in parturition, suggesting additional factors. Here, we evaluated the contribution of steroid receptor coactivators 1 and 2 (SRC-1 and SRC-2), which upregulate SP-A transcription, to the parturition process.

Cross-species withdrawal of MCL1 facilitates postpartum uterine involution in both the mouse and baboon.

A successful postpartum involution permits the postnatal uterus to rapidly regain its prepregnancy function and size to ultimately facilitate an ensuing blastocyst implantation. This study investigates the molecular mechanisms that govern the initiation of the involution process by examining the signaling events that occur as the uterus transitions from the pregnant to postnatal state. Using mouse and baboon uteri, we found a remarkable cross-species conservation at the signal transduction level as the pregnant uterus initiates and progresses through the involution process.

MicroRNA-200a serves a key role in the decline of progesterone receptor function leading to term and preterm labor.

During pregnancy, uterine quiescence is maintained by increased progesterone receptor (PR) activity, but labor is facilitated by a series of events that impair PR function. Previously, we discovered that miR-200 family members serve as progesterone (P(4))-modulated activators of contraction-associated genes in the pregnant uterus. In this study, we identified a unique role for miR-200a to enhance the local metabolism of P(4) in myometrium and, thus, decrease PR function during the progression toward labor.

Antiapoptotic signaling via MCL1 confers resistance to caspase-3-mediated apoptotic cell death in the pregnant human uterine myocyte.

Our group has previously identified elevated levels of nonapoptotic active caspase 3 (CASP3) accompanied by increased prosurvival, antiapoptotic signaling in the pregnant mouse uterus during late gestation. We speculated that increased antiapoptotic signaling desensitized the pregnant uterine myocyte to the apoptotic action of uterine CASP3. This current study examines the mechanism by which the pregnant myocyte gains resistance to the apoptotic effects of increased uterine CASP3.

Elevated levels of uterine anti-apoptotic signaling may activate NFKB and potentially confer resistance to caspase 3-mediated apoptotic cell death during pregnancy in mice.

Preserving the uterus in a state of relative quiescence is vital to the maintenance of a successful pregnancy. Elevated cytoplasmic levels of uterine caspase 3 during pregnancy have been proposed as a potential regulator of uterine quiescence through direct targeting and disabling of the uterine contractile architecture. However, despite highly elevated levels of uterine caspase 3 during pregnancy, there is minimal evidence of apoptosis.

Progesterone-regulated caspase 3 action in the mouse may play a role in uterine quiescence during pregnancy through fragmentation of uterine myocyte contractile proteins.

The appropriate timing of the onset of labor is critical to a successful pregnancy, with potentially devastating consequences resulting to both the mother and child with the onset of preterm labor. In this study, we tested the central hypothesis that progesterone maintains uterine quiescence through regulation of active uterine caspase 3. Using the mouse as our model system, we examined, by Western blot analysis, levels of active caspase 3 and its association with the degradation of uterine contractile proteins during pregnancy.

Up-regulation of the progesterone receptor (PR)-C isoform in laboring myometrium by activation of nuclear factor-kappaB may contribute to the onset of labor through inhibition of PR function.

Progesterone acting via the progesterone receptor (PR) plays a critical role in maintaining uterine quiescence during pregnancy. In the present study, we tested the hypothesis that the transactivating capability of the PR is down-regulated in the myometrium at term by a change in uterine PR isoform ratio resulting from local activation of the nuclear factor (NF)-kappaB pathway. Overexpression of the truncated PR-C isoform in human myometrial cells inhibited PR-B transactivation.

New insights into the molecular endocrinology of parturition.

The signals that lead to the initiation of parturition have remained a mystery. We postulate that in humans and other mammals, uterine quiescence is maintained by increased progesterone receptor (PR) transcriptional activity, and spontaneous labor is initiated or facilitated by a concerted series of biochemical events that negatively impact PR function. In recent studies, we have obtained compelling evidence to suggest that the fetus signals the initiation of labor by secretion into amniotic fluid of major lung surfactant protein, SP-A.

Surfactant protein secreted by the maturing mouse fetal lung acts as a hormone that signals the initiation of parturition.

Parturition is timed to begin only after the developing embryo is sufficiently mature to survive outside the womb. It has been postulated that the signal for the initiation of parturition arises from the fetus although the nature and source of this signal remain obscure. Herein, we provide evidence that this signal originates from the maturing fetal lung.

A decline in the levels of progesterone receptor coactivators in the pregnant uterus at term may antagonize progesterone receptor function and contribute to the initiation of parturition.

The molecular events that lead to the onset of labor in humans and in other mammalian species remain unclear. We propose that a decline in coactivators containing histone acetylase activity in myometrium may contribute to the onset of labor by impairing the function of the progesterone-progesterone receptor (PR) complex. As assessed by semiquantitative and real-time RT-PCR, immunohistochemistry, and immunoblotting, expression of the PR coactivators cAMP-response element-binding protein (CREB)-binding protein and steroid receptor coactivators 2 and 3 was decreased in fundal uterine tissue of women in labor.

Calmodulin-dependent kinase I regulates adrenal cell expression of aldosterone synthase.

Aldosterone synthase (CYP11B2) is expressed in the adrenal glomerulosa and controls the capacity of the adrenal glomerulosa to produce aldosterone. Herein, human NCI-H295R (H295R) adrenocortical cells were used to define the calcium-dependent mechanisms regulating CYP11B2 gene transcription using reporter constructs containing CYP11B2 gene 5'-flanking DNA. Treatment of H295R cells with calcium/calmodulin-dependent protein kinase (CaMK) inhibitor (KN93) or calmodulin inhibitor (calmidazolium) blocked angiotensin II and potassium (K(+)) stimulation of CYP11B2 reporter gene expression.