A calcitonin receptor-expressing subregion of the medial preoptic area is involved in alloparental tolerance in common marmosets.

Like humans, common marmoset monkeys utilize family cooperation for infant care, but the neural mechanisms underlying primate parental behaviors remain largely unknown. We investigated infant care behaviors of captive marmosets in family settings and caregiver-infant dyadic situations. Marmoset caregivers exhibited individual variations in parenting styles, comprised of sensitivity and tolerance toward infants, consistently across infants, social contexts and multiple births. Seeking the neural basis of these parenting styles, we demonstrated that the calcitonin receptor-expressing neurons in the marmoset medial preoptic area (MPOA) were transcriptionally activated during infant care, as in laboratory mice. Further, site-specific neurotoxic lesions of this MPOA subregion, termed the cMPOA, significantly reduced alloparental tolerance and total infant carrying, while sparing general health and other social or nonsocial behaviors. These results suggest that the molecularly-defined neural site cMPOA is responsible for mammalian parenting, thus provide an invaluable model to study the neural basis of parenting styles in primates.

Oxytocin and Parental Behaviors.

The oxytocin/vasopressin ancestor molecule has been regulating reproductive and social behaviors for more than 500 million years. In all mammals, oxytocin is the hormone indispensable for milk-ejection during nursing (maternal milk provision to offspring), a process that is crucial for successful mammalian parental care. In laboratory mice, a remarkable transcriptional activation occurs during parental behavior within the anterior commissural nucleus (AC), the largest magnocellular oxytocin cell population within the medial preoptic area (although the transcriptional activation was limited to non-oxytocinergic neurons in the AC). Furthermore, there are numerous recent reports on oxytocin's involvement in positive social behaviors in animals and humans. Given all those, the essential involvement of oxytocin in maternal/parental behaviors may seem obvious, but basic researchers are still struggling to pin down the exact role oxytocin plays in the regulation of parental behaviors. A major aim of this review is to more clearly define this role. The best conclusion at this moment is that OT can facilitate the onset of parental behavior, or parental behavior under stressful conditions.In this chapter, we will first review the basics of rodent parental behavior. Next, the neuroanatomy of oxytocin systems with respect to parental behavior in laboratory mice will be introduced. Then, the research history on the functional relationship between oxytocin and parental behavior, along with advancements in various techniques, will be reviewed. Finally, some technical considerations in conducting behavioral experiments on parental behavior in rodents will be addressed, with the aim of shedding light on certain pitfalls that should be avoided, so that the progress of research in this field will be facilitated. In this age of populism, researchers should strive to do even more scholarly works with further attention to methodological details.

Neural mechanisms of mother-infant bonding and pair bonding: Similarities, differences, and broader implications.

This article is part of a Special Issue "Parental Care". Mother-infant bonding is a characteristic of virtually all mammals. The maternal neural system may have provided the scaffold upon which other types of social bonds in mammals have been built. For example, most mammals exhibit a polygamous mating system, but monogamy and pair bonding between mating partners occur in ~5% of mammalian species. In mammals, it is plausible that the neural mechanisms that promote mother-infant bonding have been modified by natural selection to establish the capacity to develop a selective bond with a mate during the evolution of monogamous mating strategies. Here we compare the details of the neural mechanisms that promote mother-infant bonding in rats and other mammals with those that underpin pair bond formation in the monogamous prairie vole. Although details remain to be resolved, remarkable similarities and a few differences between the mechanisms underlying these two types of bond formation are revealed. For example, amygdala and nucleus accumbens-ventral pallidum (NA-VP) circuits are involved in both types of bond formation, and dopamine and oxytocin actions within NA appear to promote the synaptic plasticity that allows either infant or mating partner stimuli to persistently activate NA-VP attraction circuits, leading to an enduring social attraction and bonding. Further, although the medial preoptic area is essential for maternal behavior, its role in pair bonding remains to be determined. Our review concludes by examining the broader implications of this comparative analysis, and evidence is provided that the maternal care system may have also provided the basic neural foundation for other types of strong social relationships, beyond pair bonding, in mammals, including humans.

Does oxytocin modulate variation in maternal caregiving in healthy new mothers?

BACKGROUND: Maternal sensitivity to infant cues and developmental needs may be pivotal for social and cognitive development. Animal and recent human studies emphasise a major role for Oxytocin (OT) in mediating sensitive caregiving but no study has examined the relationship between OT and extreme variation in human maternal sensitivity. METHODS: From 105 expectant mothers, 80 underwent blind-rating of maternal sensitivity at 4-6 months postpartum through free-play interaction with their infants. At 7-9 months postpartum, 30 mothers at extremes of maternal sensitivity: 15 'sensitive mothers' (high sensitivity mothers - HSMs, mean=4.47; SD=0.74) and 15 'less sensitive mothers' (low sensitivity mothers - LSMs, mean=2.13; SD=0.52) underwent plasma OT measurements before and after 10 min infant play. RESULTS: Baseline and post-interaction plasma OT was higher in LSMs than HSMs [F(1, 26)=8.42; p=0.01]. HSMs showed a trend towards significant reduction in plasma OT [t(14)=2.01; p=0.06] following play-interaction; no change was shown by LSMs [t(13)=-0.14; p=0.89]. Conclusion Higher baseline OT levels in healthy LSMs may imply greater stress responses to the demands of caring for an infant, or past deficiencies in own parenting relationship and act as a biomarker for poor parental sensitivity. OT may be acting to reduce stress and anxiety in LSMs consistent with studies of plasma OT and stress in women. By contrast, in HSMs, play interaction with their infants maybe relaxing as indicated by significant reduction in plasma OT from baseline. Ascertainment of mothers in well-defined sensitivity groups might facilitate examination of distinct coping strategies in parents and better understanding of variation in parental caregiving behaviour and its potential for modulation by OT. This article is part of a Special Issue entitled Oxytocin and Social Behav.

Flexibility and adaptation of the neural substrate that supports maternal behavior in mammals.

Maternal behavior is species-specific and expressed under different physiological conditions, and contexts. It is the result of neural processes that support different forms (e.g. postpartum, cycling sensitized and spontaneous maternal behavior) and modalities of mother-offspring interaction (e.g. maternal interaction with altricial/precocious young; selective/non-selective bond). To understand how the brain adapts to and regulates maternal behavior in different species, and physiological and social conditions we propose new neural models to explain different forms of maternal expression (e.g. sensitized and spontaneous maternal behavior) and the behavioral changes that occur across the postpartum period. We emphasize the changing role of the medial preoptic area in the neural circuitry that supports maternal behavior and the cortical regulation and adjustment of ongoing behavioral performance. Finally, we discuss how our accumulated knowledge about the psychobiology of mothering in animal models supports the validity of animal studies to guide our understanding of human mothering and to improve human welfare and health.

New theoretical and experimental approaches on maternal motivation in mammals.

Maternal behavior is expressed in different modalities, physiological conditions, and contexts. It is the result of a highly motivated brain, that allows the female to flexibily adapt her caring activities to different situations and social demands. To understand how mothers coordinate maternal and other motivated behaviors we discuss the limitations of current theoretical approaches to study maternal motivation (e.g. distinction between appetitive and consummatory behaviors), and propose a different approach (i.e. motorically active vs. passive motivations) and a distinction between maternal motivated state and maternal motivated behaviors. We review the evidence supporting dopamine mediation of maternal motivation and describe how different phases of the dopaminergic response - basal, tonic, and phasic release in the nucleus accumbens - relate to increased salience, invigorating behavior, and behavioral switching. The existing and new experimental paradigms to investigate maternal motivation, and its coexpression and coordination with other social or non-social motivations are also analyzed. An example of how specificity of motivational systems (e.g. maternal and sexual behavior at postpartum estrus) could be processed at the neural level is also provided. This revision offers new theoretical and experimental approaches to address the fundamental question of how mothers flexibly adapt and coordinate the different components of maternal behavior with other motivated behaviors, also critical for the survival of the species.

Functional, anatomical, and neurochemical differentiation of medial preoptic area subregions in relation to maternal behavior in the mouse.

In rodents, previous findings indicate critical involvement of the medial preoptic area (MPOA) in the neural control of maternal behavior. However, the specification of the particular MPOA subregions involved in maternal behavior and the identification of the neurochemical phenotype(s) of the essential neurons demands additional study. Therefore, we investigated the chemical neuroanatomy of the essential MPOA subregion for maternal behavior in C57BL/6J female mice. Using the oxytocinergic neurons in the dorsal MPOA as a primary regional marker, we first assessed the distribution of c-Fos-expressing neurons in the MPOA during maternal behavior using immunohistochemistry. Results showed that non-oxytocinergic neurons in the dorsal and ventral MPOA prominently expressed c-Fos during maternal behavior. Then using excitotoxic lesion studies, we determined the specific MPOA area that is necessary for maternal behavior. Bilateral lesions of the central MPOA, where c-Fos was expressed only moderately, effectively disrupted maternal behavior, although lesions to the dorsal and ventral MPOA regions were ineffective. These centrally lesioned females were highly infanticidal irrespective of their previous maternal experience. Neurochemical investigations showed that more than 75% of the c-Fos-expressing neurons in central MPOA were GABAergic. Many of them also expressed galanin, neurotensin, and/or tachykinin2 mRNAs. Finally, the central MPOA was populated by numerous glutamatergic neurons, although only a small percentage of these neurons colocalized with c-Fos. To conclude, the central MPOA is the indispensable subregion for mouse maternal behavior, and GABAergic and/or peptidergic neurons in this area were transcriptionally activated during maternal behavior.

Neuromolecular basis of parental behavior in laboratory mice and rats: with special emphasis on technical issues of using mouse genetics.

To support the well-being of the parent-infant relationship, the neuromolecular mechanisms of parental behaviors should be clarified. From neuroanatomical analyses in laboratory rats, the medial preoptic area (MPOA) has been shown to be of critical importance in parental retrieving behavior. More recently, various gene-targeted mouse strains have been found to be defective in different aspects of parental behaviors, contributing to the identification of molecules and signaling pathways required for the behavior. Therefore, the neuromolecular basis of "mother love" is now a fully approachable research field in modern molecular neuroscience. In this review, we will provide a summary of the required brain areas and gene for parental behavior in laboratory mice (Mus musculus) and rats (Rattus norvegicus). Basic protocols and technical considerations on studying the mechanism of parental behavior using genetically-engineered mouse strains will also be presented.

Minireview: estrogen receptor-initiated mechanisms causal to mammalian reproductive behaviors.

While estrogen-facilitated changes in gene expression constitute some of the best-analyzed biochemical phenomena in the regulation of transcription, there have been at least two aspects of this topic that have led to much experimental work about estrogen actions on brain and behavior. The first task has required parsing various behavioral and neurochemical functions according to whether they depend on estrogen receptor-α or estrogen receptor-ß. The second task has been the formulation of how nuclear actions of estrogens comport with membrane-initiated actions. With respect to these issues, applications of molecular endocrine approaches to lordosis behavior came first. Currently, the last in the chain of reproductive behaviors, maternal behavior, and an entire range of neural and cognitive functions even more complex in their determinants, must be analyzed using current molecular techniques. This minireview of estrogen actions on the chain of female reproductive behaviors highlights challenging new questions about estrogen actions on cells in the brain, questions that have important practical applications far beyond traditionally studied sex behaviors.

Hypothalamic interaction with the mesolimbic DA system in the control of the maternal and sexual behaviors in rats.

The medial preoptic area (MPOA) of the hypothalamus regulates maternal behavior, male sexual behavior, and female sexual behavior. Functional neuroanatomical evidence indicates that the appetitive aspects of maternal behavior are regulated through MPOA interactions with the mesolimbic dopamine (DA) system; a major focus of this review is to explore whether or not the MPOA participates in the appetitive aspects of sexual behavior via its interaction with the mesolimbic DA system. A second focus of this review is to examine the extent to which estradiol interactions with DA within this circuit regulate all three reproductive behaviors. One mechanism through which estradiol activates male sexual behavior is through the potentiation of DA activity in the MPOA. In the hypothalamus, estradiol has also been found to act in concert with DA, through the activation of similar intracellular signaling pathways, in order to stimulate female sexual behavior. Finally, recent evidence suggests that some effects of estradiol are mediated by direct action of estradiol on the mesolimbic DA system.

Maternity: neural mechanisms, motivational processes, and physiological adaptations.

This review focuses on research on both the neural substrate of maternal responsiveness and on the physiological, behavioral, and motivational adaptations to the maternal state. The female's response to her young is presented as a model motivational system and the mechanisms and neural circuitry through which the medial preoptic area regulates this responsivity is described. This analysis is then used in support of an argument for a greater recognition of the role of hypothalamic nuclei in the stimulation of appetitive behavior. In the subsequent section of the manuscript the adaptations of other motivational systems to the maternal state together with the research investigating the mechanisms that produce these changes are described. Finally, we examine how these multiple adaptations may be coordinated and integrated.

The importance of the basolateral/basomedial amygdala for goal-directed maternal responses in postpartum rats.

A model of the neural regulation of maternal behavior in rats proposes that the basolateral amygdala (BLA) provides pup-related sensory inputs to the nucleus accumbens-ventral pallidum (NA-VP) circuit and that medial preoptic area activation of the mesolimbic dopamine system potentiates the ability of BLA neurons to stimulate goal-directed maternal responses, such as pup retrieval behavior. Previous research using electrical lesions has provided some direct support for the importance of BLA. In the current study, we examined the effects of temporary inactivation of neurons within BLA and the adjoining basomedial nucleus of the amygdala (BMA) on maternal behavior in postpartum rats. For an anatomical control, muscimol was injected into the medial amygdala (MeA). Since research has shown that MeA plays an inhibitory role in maternal behavior, it was predicted that muscimol injections restricted to that site would not disrupt maternal behavior. The results showed that muscimol injections into BLA/BMA, at dosage levels between 100 and 200 ng/side, produced major deficits in retrieval behavior and minor deficits in nursing behavior. In contrast, muscimol injections into MeA left maternal behavior relatively unaffected. These results show that neuron-specific inactivation of BLA/BMA causes severe deficits in what can be considered a goal-directed and appetitive maternal response, pup retrieval, while leaving the consummatory aspect of maternal behavior, nursing, relatively unaffected. Since oxytocin is important for maternal behavior, and since both BMA and MeA neurons contain OT-binding sites, perhaps OT stimulates BMA output and suppresses MeA output to influence aspects of maternal behavior.

Dopamine D(1) receptor activation of adenylyl cyclase, not phospholipase C, in the nucleus accumbens promotes maternal behavior onset in rats.

A body of evidence supports the idea that the mesolimbic dopamine (DA) system modulates the natural increase in responsiveness female rats show toward offspring (biological or foster) at birth. In the absence of the full hormonal changes associated with pregnancy and birth, female rats do not show immediate responsiveness toward foster offspring. Activation of the mesolimbic DA system can produce an immediate onset of maternal behavior in these females. For example, female rats that are hysterectomized and ovariectomized on day 15 of pregnancy (15HO) and presented with pups 48 hours later normally show maternal behavior after 2-3 days of pup exposure, but will show maternal behavior on day 0 of testing after microinjection of the DA D(1) receptor agonist, SKF 38393, into the nucleus accumbens (NA) at the time of pup presentation. DA D(1) receptor stimulation is known to activate cAMP intracellular signaling cascades via its stimulation of adenylyl cyclase (AC). However, some DA D(1) receptors are also linked to phospholipase C (PLC) and are capable of activating phosphatidylinositol signaling cascades. SKF 38393 stimulates both types of D(1) receptors. Here we provide evidence that the facilitatory effects of DA D(1) receptor stimulation in the NA on maternal behavior are mediated by AC-linked DA D(1) receptors. By examining the effects of intra-NA application of SKF 83822, a drug which selectively binds DA D(1)-AC receptors, or SKF 83959, a drug which selectively activates D(1)-PLC-linked receptors, we find that only SKF 83822 facilitates maternal behavior onset.

Temporary inactivation of ventral tegmental area neurons with either muscimol or baclofen reversibly disrupts maternal behavior in rats through different underlying mechanisms.

The purpose of this study was to examine the effects of inactivation of ventral tegmental area (VTA) projection neurons, while sparing fibers of passage, on maternal behavior in rats. Because VTA neurons contain GABA-A and GABA-B receptors, the effects of muscimol or baclofen were studied. Although bilateral injections of either drug into the VTA disrupted maternal behavior, it is likely that they did so through different underlying mechanisms. Muscimol disrupted both retrieval of pups and nursing behavior, while causing stereotyped motor activity. Baclofen disrupted retrieval behavior without affecting nursing behavior, and control injections of baclofen into the region dorsal to VTA were ineffective. The effects of VTA baclofen on maternal behavior are similar to the effects of interference with mesolimbic dopamine (DA) function. The case is made that muscimol probably caused a hyperexcitation of VTA DA neurons through a process of disinhibition. In contrast, baclofen may have depressed the activity of all VTA projection neurons, including VTA DA neurons. Baclofen is a promising tool to explore whether medial preoptic area neurons interact with VTA neurons to control active maternal responses.

A single injection of 17beta-estradiol at the time of pup presentation promotes the onset of maternal behavior in pregnancy-terminated rats.

Female rats that are hysterectomized and ovariectomized on day 15 of pregnancy (15HO) and presented with pups 48 h later show maternal behavior after 2 or 3 days of pup exposure. In contrast, if 15HO females are administered (sc) 20 microg/kg of estradiol benzoate (EB) on day 15 of pregnancy after HO, they show near immediate maternal behavior when pups are presented 48 h later. EB has typically been administered on day 15 because of the underlying assumption that EB exerts genomic effects which require a long duration before being expressed in changes in neuronal phenotype. In light of the more recent evidence that estradiol can generate rapid changes in cellular function, we examined whether injection of a water-soluble form of 17beta-estradiol (E(2)) can facilitate maternal behavior in pregnancy-terminated females when it is administered at the time of pup presentation rather than at the time of HO. Female rats treated with 100 microg/kg of E(2) showed a robust facilitation of maternal behavior, requiring a median of 1 day of pup exposure before showing maternal behavior, compared with 3 days in vehicle-treated rats.

Medial preoptic area interactions with dopamine neural systems in the control of the onset and maintenance of maternal behavior in rats.

The medial preoptic area (MPOA) and dopamine (DA) neural systems interact to regulate maternal behavior in rats. Two DA systems are involved: the mesolimbic DA system and the incerto-hypothalamic DA system. The hormonally primed MPOA regulates the appetitive aspects of maternal behavior by activating mesolimbic DA input to the shell region of the nucleus accumbens (NAs). DA action on MPOA via the incerto-hypothalamic system may interact with steroid and peptide hormone effects so that MPOA output to the mesolimbic DA system is facilitated. Neural oxytocin facilitates the onset of maternal behavior by actions at critical nodes in this circuitry. DA-D1 receptor agonist action on either the MPOA or NAs can substitute for the effects of estradiol in stimulating the onset of maternal behavior, suggesting an overlap in underlying cellular mechanisms between estradiol and DA. Maternal memory involves the neural plasticity effects of mesolimbic DA activity. Finally, early life stressors may affect the development of MPOA-DA interactions and maternal behavior.

Nursing stimulation is more than tactile sensation: It is a multisensory experience.

Novel sensory experiences, particularly those associated with epochal developmental events like nursing alter cortical representation, affecting memory, perception and behavior. Functional MRI was used here to test whether the sensoricortical map of the ventrum is modified during lactation. Three stimuli were used to drive cortical activation in primiparous rats: natural, artificial suckling stimulation and general mechanical rubbing of the skin of the ventrum. These stimuli significantly activated the somatosensory cortex of dams. Of the three stimuli, artificial and pup suckling robustly activated much of the cerebrum, most notably the visual, auditory and olfactory cortices. Surprisingly, activation occurred even in the absence of pups, with artificial suckling. This finding suggests that incoming information from a single modality was sufficient to drive activity of others. Enhanced sensitivity across the cortical mantle during nursing may help the dam to perceive, process, and remember stimuli critical to the care and protection of her young.

Dopamine D1 receptor stimulation of the nucleus accumbens or the medial preoptic area promotes the onset of maternal behavior in pregnancy-terminated rats.

There is good evidence that interference with the mesolimbic dopamine (DA) system results in impaired maternal responding in postpartum female rats. However, whether activation of the mesolimbic DA system is capable of promoting maternal behavior has not been investigated. This study examined whether increasing DA activity in various brain regions of pregnancy-terminated, naive female rats would stimulate the onset of maternal behavior. Experiments 1 and 2 examined the effects of microinjection of various doses (0, 0.2, or 0.5 microg/0.5 microl/side) of a D1 DA receptor agonist, SKF 38393, or a D2 DA receptor agonist, quinpirole, into the nucleus accumbens (NA) on latency to show full maternal behavior, and Experiment 3 determined the effects of SKF 38393 injection into a control site. Finally, because the medial preoptic area (MPOA) is also important for maternal behavior, receives DA input, and expresses DA receptors, the authors examined whether microinjection of SKF 38393 into MPOA was capable of stimulating the onset of maternal behavior. Results indicated that microinjection of SKF 38393 into either the NA or the MPOA facilitates maternal responding in pregnancy-terminated rats.