Nuclear estrogen receptor binding in microdissected brain regions of female rats during pregnancy: implications for maternal and sexual behavior

A Scientometric Approach to Review the Role of the Medial Preoptic Area (MPOA) in Parental Behavior

Research investigating the neural substrates underpinning parental behaviour has recently gained momentum. Particularly, the hypothalamic medial preoptic area (MPOA) has been identified as a crucial region for parenting. The current study conducted a scientometric analysis of publications from 1 January 1972 to 19 January 2021 using CiteSpace software to determine trends in the scientific literature exploring the relationship between MPOA and parental behaviour. In total, 677 scientific papers were analysed, producing a network of 1509 nodes and 5498 links. Four major clusters were identified: “C-Fos Expression”, “Lactating Rat”, “Medial Preoptic Area Interaction” and “Parental Behavior”. Their content suggests an initial trend in which the properties of the MPOA in response to parental behavior were studied, followed by a growing attention towards the presence of a brain network, including the reward circuits, regulating such behavior. Furthermore, while attention was initially directed uniquely to maternal behavior, it has recently been extended to the understanding of paternal behaviors as well. Finally, although the majority of the studies were conducted on rodents, recent publications broaden the implications of previous documents to human parental behavior, giving insight into the mechanisms underlying postpartum depression. Potential directions in future works were also discussed.

Low doses of 17α-ethinyl estradiol alter the maternal brain and induce stereotypies in CD-1 mice exposed during pregnancy and lactation

Maternal care is critical for the survival, development and long-term success of offspring. Despite our current understanding of the role of endogenous estrogen in both maternal behavior and the maternal brain, the potential effects of exogenous estrogens on these endpoints remain poorly understood. Here, pregnant CD-1 mice were exposed to low doses of 17α-ethinyl estradiol (EE2), commonly used as a positive control in studies of other xenoestrogens, from day 9 of pregnancy until weaning. Using traditional maternal behavior assays, we document no significant changes in maternal behavior throughout the lactational period. However, EE2 induced increases in repetitive tail retrieval, which may indicate a stereotypy or obsessive compulsive (OCD)-like behavior. We also observed a significant reduction in tyrosine hydroxylase (TH) immunoreactivity in the ventral tegmental area (VTA), a region important for maternal motivation. These results suggest that pregnant adult females are not immune to the effects of this compound.

Bisphenol S (BPS) Alters Maternal Behavior and Brain in Mice Exposed During Pregnancy/Lactation and Their Daughters

Estrogenic endocrine disrupting chemicals have been shown to disrupt maternal behavior in rodents. We investigated the effects of an emerging xenoestrogen, bisphenol S (BPS), on maternal behavior and brain in CD-1 mice exposed during pregnancy and lactation (F0 generation) and in female offspring exposed during gestation and perinatal development (F1 generation). We observed different effects in F0 and F1 dams for a number of components of maternal behavior, including time on the nest, time spent on nest building, latency to retrieve pups, and latency to retrieve the entire litter. We also characterized expression of estrogen receptor α in the medial preoptic area (MPOA) and quantified tyrosine hydroxylase immunoreactive cells in the ventral tegmental area, 2 brain regions critical for maternal care. BPS-treated females in the F0 generation had a statistically significant increase in estrogen receptor α expression in the caudal subregion of the central MPOA in a dose-dependent manner. In contrast, there were no statistically significant effects of BPS on the MPOA in F1 dams or the ventral tegmental area in either generation. This work demonstrates that BPS affects maternal behavior and brain with outcomes depending on generation, dose, and postpartum period. Many studies examining effects of endocrine disrupting chemicals view the mother as a means by which offspring can be exposed during critical periods of development. Here, we demonstrate that pregnancy and lactation are vulnerable periods for the mother. We also show that developmental BPS exposure alters maternal behavior later in adulthood. Both findings have potential public health implications.

Hormonal and non-hormonal bases of maternal behavior: The role of experience and epigenetic mechanisms

This article is part of a Special Issue "Parental Care". Though hormonal changes occurring throughout pregnancy and at the time of parturition have been demonstrated to prime the maternal brain and trigger the onset of mother-infant interactions, extended experience with neonates can induce similar behavioral interactions. Sensitization, a phenomenon in which rodents engage in parental responses to young following constant cohabitation with donor pups, was elegantly demonstrated by Rosenblatt (1967) to occur in females and males, independent of hormonal status. Study of the non-hormonal basis of maternal behavior has contributed significantly to our understanding of hormonal influences on the maternal brain and the cellular and molecular mechanisms that mediate maternal behavior. Here, we highlight our current understanding regarding both hormone-induced and experience-induced maternal responsivity and the mechanisms that may serve as a common pathway through which increases in maternal behavior are achieved. In particular, we describe the epigenetic changes that contribute to chromatin remodeling and how these molecular mechanisms may influence the neural substrates of the maternal brain. We also consider how individual differences in these systems emerge during development in response to maternal care. This research has broad implications for our understanding of the parental brain and the role of experience in the induction of neurobiological and behavior changes.

Activation and circuitry of uterine-cervix-related neurons in the lumbosacral dorsal root ganglia and spinal cord at parturition

Stimulation of the uterine cervix at parturition activates neural circuits involving primary sensory nerves and supraspinally projecting neurons of the lumbosacral spinal cord, resulting in output of hypothalamic neurohormones. Dorsal root ganglia (DRG) and spinal neurons of these circuits are not well-characterized. The objectives of this study were to detail the activation of DRG and spinal neurons of the L6/S1 levels that are stimulated at late pregnancy, verify hypothalamic projections of activated spinal neurons, and determine whether activated neurons express estrogen receptor-alpha (ERalpha). Expression of phosphorylated cyclic-AMP response element-binding protein (PCREB) and Fos immunohistochemistry were used to "mark" activated DRG and spinal neurons, respectively. Retrograde tracing identified uterine-cervix-related and spinohypothalamic neurons. Baseline PCREB expression in the DRG increased during pregnancy and peaked during the last trimester. Some PCREB-expressing neurons contained retrograde tracer identifying them as cervix-related neurons. Fos-expressing neurons were few in spinal cords of nonpregnant and day 22 pregnant rats but were numerous in parturient animals. Some Fos-expressing neurons located in the dorsal half of the spinal cord contained retrograde tracer identifying them as spinohypothalamic neurons. Some DRG neurons expressing PCREB also expressed ERalpha, and some spinal neurons activated at parturition projected axons to the hypothalamus and expressed ERalpha. These results indicate that DRG and spinal cord neurons are activated at parturition; that those in the spinal cord are present in areas involved in autonomic and sensory processing; that some spinal neurons project axons to the hypothalamus, ostensibly part of a neuroendocrine reflex; and that sensory and spinal neurons can respond to estrogens. Moreover, some activated sensory neurons may be involved in the animal's perception of labor pain.

Neural steroid hormone receptor gene expression in pregnant rats

Estrogen and progesterone play important roles during pregnancy in stimulating the onset of maternal behavior at parturition. The status of receptor expression of these hormones during pregnancy in neural regions that regulate maternal behavior is unclear. The objective of the present study is to characterize changes in neural gene expression of the estrogen receptors alpha and beta (ERalpha and ERbeta) and the progesterone receptor (PR) during the latter part of pregnancy. Brains from primigravid Sprague-Dawley rats were collected on days 15 and 21 of pregnancy. Micropunches of the olfactory bulb (OB), medial preoptic area (MPOA), bed nucleus of the stria terminalis (BnST), hypothalamus (HYP), medial amygdala (MeA), and the temporal cortex (TCx) were analyzed by real-time RT-PCR (Taqmantrade mark) for levels of gene expression. No changes in either ERalpha or ERbeta mRNA levels were detected in any brain region between days 15 and 21 of pregnancy: however, the MPOA had higher levels of both ERalpha and ERbeta than other brain regions. Progesterone receptor mRNA levels, in contrast, declined significantly in the MPOA, HYP, and TCx, between days 15 and 21 of pregnancy (P < 0.05). In addition, the levels of PR mRNA were significantly higher in the HYP and TCx compared to both the OB and MeA. These data indicate that there is a downregulation of PR prepartum and suggest that this decrease may play a role in the disinhibition of maternal behavior at parturition.

Estrogen receptor beta messenger ribonucleic acid expression in the forebrain of proestrous, pregnant, and lactating female rats

Estrogen receptor (ER)beta is present in hypothalamic and limbic neurons of female rat brains, but little is known about its regulation under physiological conditions. To determine whether ER beta expression varies during physiological conditions in which sex steroid hormone profiles are significantly different, we used in situ hybridization to assess ER beta mRNA expression in the periventricular preoptic area, bed nucleus of stria terminalis, paraventricular nucleus, supraoptic nucleus, and the posterodorsal medial amygdala of female rats on proestrus, on d 22 of pregnancy, or on d 10 of lactation (L10). In the periventricular preoptic area, d-22 pregnant females had fewer ER beta-mRNA-expressing cells than did females at proestrus, but the level of ER beta mRNA expression per cell in pregnant females was higher than in the two other groups. In the paraventricular nucleus, no changes in ER beta mRNA expression were observed; whereas in the supraoptic nucleus, proestrous females had fewer ER beta-mRNA-expressing cells than L10 females. In the posterodorsal medial amygdala, proestrous females had a greater number of ER beta-mRNA-expressing cells than did L10 females. These results demonstrate that ER beta mRNA expression is differentially regulated in a brain-region-specific and temporal manner under physiological conditions and suggest that ER beta may participate in the regulation of estrogen-sensitive reproductive functions in female rats.

Estrogen Receptors in the Spinal Cord, Sensory Ganglia, and Pelvic Autonomic Ganglia

Until relatively recently, most studies of the effects of estradiol in the nervous system focused on hypothalamic, limbic, and other brain centers involved in reproductive hormone output, feedback, and behaviors. Almost no studies addressed estradiol effects at the spinal cord or peripheral nervous system level. Prior to the mid-1960s-1970s, few studies examined neural components of reproductive endocrine organs (e.g., ovary or testis) or the genital organs (e.g., uterus or penis) because available data supported endocrine regulation of these structures. Over the last two decades interest in and studies on the innervation of the genital organs have burgeoned. Because of the responsiveness of genital organs to sex steroid hormones, these neural studies seeded interest in whether or not autonomic and sensory neurons that innervate these organs, along with their attendant spinal cord circuits, also are responsive to sex hormones. From the mid-1980s there has been a steady growth of interest in, and studies of the neuroanatomy, neurochemistry, neural connectivity, and neural functional aspects in reproductive organs and the response of these parameters to sex steroids. Thus, with the growth of probes and techniques, has come studies of anatomy, neurochemistry, and circuitry of sex hormone-responsive neurons and circuits in the spinal cord and peripheral nervous system. This review focuses on estrogen receptors in sensory, autonomic, and spinal cord neurons in locales that are associated with innervation of female reproductive organs.

Estrogen receptor-alpha and neural circuits to the spinal cord during pregnancy

Estrogen receptor immunoreactivity and mRNAs are present in spinal cord neurons in locations that are associated with sensory and autonomic innervation of female reproductive organs. The present study was undertaken to examine the expression of estrogen receptor-alpha in the spinal cord during different stages of pregnancy and to determine whether estrogen receptor-alpha-expressing neurons are related to uterine afferent nerves bringing information to the spinal cord at parturition. Immunohistochemistry showed estrogen receptor-alpha-immunoreactive neurons in the dorsal one-half of the spinal cord, i.e., dorsal horn, dorsal intermediate gray areas (dorsal commissural nucleus), and around the central canal and sacral parasympathetic autonomic nucleus of the lumbosacral spinal cord. Neurons in these areas corresponded topographically to the distribution of central processes of visceral primary afferent neurons (e.g., containing calcitonin gene-related peptide and substance P) that innervate and activate second-order spinal cord neurons (evidenced by their expression of Fos) at parturition. Western blots showed that estrogen receptor-alpha increases in the spinal cord, with a peak at day 20 of gestation, followed by a slight decrease by 2 days postpartum. These studies show that estrogen receptor-alpha is expressed by neurons in autonomic and sensory areas of the lumbosacral spinal cord that have connections with the female reproductive system and that the level of estrogen receptor-alpha changes over the course of pregnancy, which may follow profiles of steroid hormones. Many of these neurons may be involved in processing information related to reproductive organ function, changes during pregnancy, and relays to other CNS centers.

Estrogen, progesterone, and pregnancy termination alter neural activity in brain regions that control maternal behavior in rats

Estrogen stimulates maternal behavior in rats, but does so most potently when its administration is temporally coupled with the termination of pregnancy. In contrast, this effect of estrogen is blocked when subjects are administered a large dose of progesterone concurrent with estrogen. The current study was performed to examine the neural circuitry influenced by these treatments and pup presentation during the hormonally-mediated onset and inhibition of maternal behavior. In experiment I, estrogen induced c-Fos immunoreactivity (Fos-IR) in the medial preoptic area (MPOA) in virgin rats, but was much more effective when administered to pregnancy-terminated rats, suggesting that pregnancy termination increases MPOA's susceptibility to the physiological effects of estrogen. In experiment II, administering progesterone concurrently with estrogen in pregnancy-terminated rats strongly inhibited estrogen-stimulated Fos-IR in the MPOA, indicating that the physiological effects of estrogen on the MPOA are blocked if high progesterone levels are maintained. In experiment III, pregnancy-terminated subjects were administered estrogen, progesterone, or both hormones and presented with pups for 2 h. Approximately half of the subjects administered estrogen alone showed maternal behavior, but subjects receiving the other treatments were not maternal. In the MPOA, ventral bed nucleus of the stria terminalis (BSTv), and dorsal and intermediate lateral septum (LSd,i), maternal subjects showed the highest levels of Fos-IR, whereas subjects treated with progesterone alone or progesterone in combination with estrogen showed low levels of Fos-IR. These experiments suggest that estrogen could promote maternal behavior by enhancing pup-stimulated activity in the MPOA, BSTv, and LSd,i, regions believed to constitute the neural circuit that promotes maternal behavior, whereas progesterone could inhibit maternal behavior by inhibiting neural activity in some of these regions.

Effects of pregnancy hormones on maternal responsiveness, responsiveness to estrogen stimulation of maternal behavior, and the lordosis response to estrogen stimulation

The aim of the study was to determine whether there is an increase in responsiveness to estrogen stimulation of maternal behavior and lordosis responsiveness during pregnancy. Using separate groups of pregnancy-terminated females, we measured the initial maternal responsiveness of hysterectomized-ovariectomized (HO) females and their responsiveness to estrogen stimulation. Maternal behavior latencies were studied in females HO on the 8th, 10th, 13th, 16th, or 19th day of pregnancy (8HO-19HO) and in nonpregnant HO (NPHO) females. Groups were injected sc with estradiol benzoate (EB) in doses ranging from 0 to 200 microgram(s)/kg and tested for maternal behavior (retrieving, crouching, and licking pups). In addition, we investigated whether there is an increase during pregnancy (following HO) in lordosis responsiveness to estrogen stimulation. Lordosis behavior was studied in pregnant HO females (days 8, 16, and 22) and NPHO females given 0 to 200 microgram(s)/kg EB. There was an increase in maternal responsiveness in oil-treated HO females starting around midpregnancy. From early pregnancy on there was also an increase in maternal responsiveness to 20 microgram(s)/kg EB. In late pregnant females (16HO) there was a further increase with 50 microgram(s)/kg EB. There was no increase in lordosis responsiveness to EB stimulation during pregnancy; pregnant and nonpregnant HO females had the same EB threshold for stimulating lordosis behavior. The results of both studies were related to increases during the latter half of pregnancy in nuclear estrogen receptor concentrations in the MPOA, an area that mediates estrogen stimulation of maternal behavior, and the absence of such increases during pregnancy in the VMH, an area that mediates estrogen stimulation of lordosis behavior.

Estrogen implants in the medial preoptic area stimulate maternal behavior in male rats

The present study investigated whether the medial preoptic area (MPOA) mediates estrogen stimulation of maternal behavior in the male as it does in the female. Previous studies have shown that lesions of the medial preoptic area prevent sensitization of maternal behavior in male rats and that in gonadectomized, hormonally primed males, systemically administered estradiol benzoate stimulates short-latency maternal behavior. These findings are similar to those found in females. In the present study adult males were gonadectomized and hormonally primed with subcutaneously implanted capsules of estradiol (Days 1-16) and progesterone (Days 3-15) and then were stereotaxically implanted bilaterally in the MPOA with implants containing 10% estradiol. Tests with young pups were started 48 h later and continued for 10 days (11 tests). Control groups were implanted in the MPOA with cholesterol or were injected subcutaneously with estradiol benzoate (100 microg/kg). Estradiol implanted males had shorter latencies for maternal behavior (retrieving, crouching, licking pups) than cholesterol implanted males, but their latencies were slightly longer than those of estradiol benzoate injected males. The medial preoptic area, therefore, mediates estrogen stimulation of maternal behavior in males as it does in females.

Levels of estrogen receptor immunoreactivity are altered in behaviorally-relevant brain regions in female rats during pregnancy

Pregnancy and parturition are accompanied by unique behavioral changes. Only some of the neural mechanisms behind the dramatic changes in behavior are understood. Estrogen's action within the medial preoptic nucleus (MPN) is necessary for the induction of maternal behavior around the time of parturition, and estrogen acts within the ventromedial nucleus (VMN) to trigger postpartum sexual receptivity shortly after parturition. We have hypothesized that the sensitivity of various brain regions to estrogen may be altered by pregnancy to support these unique behavioral patterns. Using immunocytochemistry, this study examined whether the levels of estrogen receptor (ER) protein, within behaviorally relevant brain regions, differ among females on day 8, day 16, and day 22 of pregnancy, or on postpartum day 1. On day 16 and day 22 of pregnancy, the MPN contained a significantly greater number of cells expressing high levels of ER-ir compared to day 8 or postpartum day 1. In the VMN, the mean amount of ER-ir per cell was significantly higher on day 22 of pregnancy than on day 16 or postpartum day 1. In the bed nucleus of the stria terminalis, ER-ir levels were significantly increased on postpartum day 1 compared to day 22 of pregnancy. There were no significant changes in ER-ir in the medial amygdala. These results demonstrate regionally and temporally specific regulation of ER protein in the brain during pregnancy. Alterations in the levels of ER at critical times in regions such as the MPN and VMN may underlie the unique expression of maternal and sexual behavior that occur during pregnancy and at the time of parturition.

In situ analysis of estrogen receptor mRNA expression in the brain of female rats during pregnancy

Estrogen's action in specific brain regions, particularly the medial preoptic nucleus (MPN), is necessary for the onset of maternal behavior in the pregnant female rat. There is an increase in estrogen binding in the MPN during pregnancy, and it has been hypothesized that this increase is part of the mechanism by which the brain is readied to support estrogen-dependent maternal behavior. This experiment determines whether an alteration in the levels of estrogen receptor mRNA precedes the increase in estrogen binding to its receptor. Using in situ hybridization, estrogen receptor (ER) mRNA levels were measured in specific brain regions in females on day 8, 16 or 22 of pregnancy or on postpartum day 1 or in non-pregnant females. ER mRNA levels are significantly higher in the MPN in females on day 8 of pregnancy compared with non-pregnant females or with females on day 16. In the ventromedial nucleus, which is important for estrogen's role in postpartum sexual receptivity, there was an increase in ER mRNA levels on day 22 of pregnancy compared with day 16 of pregnancy. These results suggest that ER levels may increase in specific, behaviorally relevant brain regions at critical times during pregnancy through regulation of ER mRNA levels.

The psychobiology of parenting in mammals

Parental behavior denotes a variety of genetically programmed activities in which parents help their young to survive to maturity. A highly successful research has been devoted to the psychoneuroendocrine bases of parenting in two species, rat and sheep. As a result empirical data along with conceptual formulations have been obtained which provide a model for generating hypothesis for the study of other species. This review was written to draw the attention to this research because of its enormous potential significance for problems pertaining to human infant care. It discusses the current status of research on the physiological bases of parental behavior.

Hormonal priming and triggering of maternal behavior in the rat with special reference to the relations between estrogen receptor binding and ER mRNA in specific brain regions

Estrogen stimulation of maternal behavior during pregnancy in the rat has been studied at several levels of analysis. These include (a) changes in maternal responsiveness during pregnancy; (b) hormonal stimulation of maternal behavior; and (c) correlation between nuclear binding of estradiol in the medial preoptic area and the stimulation of maternal behavior (i.e., in pregnancy-terminated, ovariectomized females treated with estradiol benzoate). These studies have given rise to the concepts of hormonal priming and triggering of maternal behavior during pregnancy and at parturition. More recently, using in situ hybridization, ER mRNA was measured during pregnancy (also diestrus and postpartum) in brain regions in which binding previously had been studied, to investigate further the regulation of hormonal priming. Steady state levels of ER mRNA per cell and cell densities of ER mRNA produced a measure of total ER mRNA per brain region which was then compared to nuclear estrogen receptor binding. The relation between binding and ER mRNA is presented for one of the brain regions, the rostral medial preoptic nucleus. The results indicate that ER transcription is regulated during pregnancy, but regulation is specific to each brain region and there is no simple relation between ER mRNA and nuclear estrogen receptor binding.