Abstract
Testosterone is involved in male sexual, parental and aggressive behaviors through the androgen receptor (AR) and estrogen receptor (ER) α expressed in the brain. Although several studies have demonstrated that ERα and AR in the medial preoptic area (MPOA) are required for exhibiting sexual and aggressive behaviors of male mice, the molecular characteristics of ERα- and AR-expressing cells in the mouse MPOA are largely unknown. Here, we performed in situ hybridization for neurotransmitters and neuropeptides, combined with immunohistochemistry for ERα and AR to quantitate and characterize gonadal steroid receptor-expressing cells in the MPOA subregions of male mice. Prodynorphin, preproenkephalin (Penk), cocaine- and amphetamine-related transcript, neurotensin, galanin, tachykinin (Tac)1, Tac2 and thyrotropin releasing hormone (Trh) have distinct expression patterns in the MPOA subregions. Gad67-expressing cells were the most dominant neuronal subtype among the ERα- and AR-expressing cells throughout the MPOA. The percentage of ERα- and AR-immunoreactivities varied depending on the neuronal subtype. A substantial proportion of the neurotensin-, galanin-, Tac2- and Penk-expressing cells in the MPOA were positive for ERα and AR, whereas the vast majority of the Trh-expressing cells were negative. These results suggest that testosterone exerts differential effects depending on both the neuronal subtypes and MPOA subregions.
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Introduction
Androgens such as testosterone play a central role in the regulation of the sexual, parental and aggressive behaviors of male animals through a direct action on androgen receptors (AR) and an indirect action on estrogen receptors (ERs), such as ERα and ERβ after being aromatized into estradiol in the brain1,2,3,4. The medial preoptic area (MPOA), the most anterior part of the hypothalamus, is one of the brain regions with the most abundant expression of AR and ERα5,6,7,8 and regulates the sexual, parental and aggressive behaviors of rodents and humans2, 9,10,11,12,13,14. Importantly, the MPOA abundantly expresses aromatase, which converts testosterone into estradiol15. The local injection of an aromatase inhibitor into the MPOA suppressed male sexual behaviors16.
The MPOA is not a homogeneous structure, and it exhibits regional differences in terms of the neuron density, the distribution of neuron subtypes characterized by gene expression, and the spreading of afferent fibers, such as 5-HT-immunoreactive fibers10, 17,18,19,20. We recently substantiated the functional relevance of the MPOA subregions by showing subregion-specific neuronal activation in response to aggression, ejaculation, paternal behavior and infanticide10, as well as in response to maternal behaviors18.
In addition to ERα and AR, various neuropeptides, such as cocaine- and amphetamine-related transcript (Cart), dynorphin, enkephalin, galanin, neurotensin, substance P (encoded by Tac1), neurokinin B (encoded by Tac2) and thyrotropin releasing hormone (Trh) are expressed in the MPOA17, 18, 21,22,23. A recent report showed that the ablation of galanin-expressing neurons in the MPOA inhibited paternal behaviors, and the optogenetic activation of galanin-expressing neurons enhanced paternal behaviors towards pups24, which suggests that neuronal subtypes characterized by the differential expressions of neuropeptides and neurotransmitters in the MPOA may have a distinct role in sexual and parental behaviors.
To further understand how specific neuronal groups are involved in gonadal steroid-dependent reproductive behaviors, it is crucial to identify the expression of the neurotransmitters and neuropeptides of ERα- and AR-expressing cells in each MPOA subregion. In this study, we quantitated the expression of neurotransmitters and neuropeptides for ERα- or AR-expressing cells in each MPOA subregion of male mice, and the expression was delineated using MPOA subregion markers, such as calbindin, oxytocin neurotensin, preproenkephalin (Penk) and vesicular glutamate transporter2 (Vglut2)17, 18, 25, 26.
Results
MPOA subregions
The MPOA subregions were identified as previously described10, 17,18,19, 22, 26,27,28. Although the brain atlas identified several nuclei in the POA region, such as the medial preoptic nucleus (MPN), posterodorsal preoptic nucleus (PD) and ventrolateral preoptic nucleus (VLPO), the relatively large region outside of these nuclei sandwiched between the anterior commissure and the optic tract remains unnamed or is collectively referred to as the MPOA (Allen brain atlas: http://www.brain-map.org/)29. Thus, in our study, we subdivided this broad MPOA into four regions: the dorsomedial part of the MPOA (dmMPOA), central part of the MPOA (cMPOA), ventral part of the MPOA (vMPOA), and ventrolateral part of the MPOA (vlMPOA). These MPOA subregions were easily identified on Nissl-stained sections and fluorescent images according to the location (Fig. 1).
In general, the subregions and nuclei that were identified on Nissl-stained sections were also easily identified on fluorescent images based on their locations and gene expressions. The central part of the MPN (MPNc) has been shown to predominantly overlapped with the sexually dimorphic nucleus of the preoptic area in rats30, 31, which can be identified by a dense cluster of calbindin-positive cells in rats and mice6, 26, 32 (Fig. 1h). The lateral subdivision of the MPN (MPNl) has a cluster of neurotensin-positive cells17, 18. Since neurotensin was intensely expressed in the ventral part of the MPNl (MPNvl), we assessed for AR- and ERα-positive cells in the MPNvl (Fig. 1g,h). The anterior commissural nucleus (ACN) was characterized by a population of oxytocinergic neurons in the dorsal MPOA25, 29.
In some cases, gene expressions enable us to subdivide Nissl-based MPN structures. The MPNm was further divided into the anterior part (MPNma), which contains a cluster of Penk-expressing cells, and the posterior part (MPNmp), which has a higher density of Cart-expressing cells, arbitrarily at 0.04 mm anterior to the bregma (Figs 1 and 3). The most posterior part of the MPNl (MPNp) was different from the main part of the MPNl in the densities of neurotensin-, Penk-, prodynorphin (Pdyn)- and Tac1-positive cells (Figs 1, 3 and 4).
In addition to the MPOA subregions, we quantitated the AR- and ERα-positive cells in the dorsomedial nucleus of the BNST (BNSTdm), principal nucleus of the BNST (BNSTpr), ventral nucleus of the BNST (BNSTv) and magnocellular nucleus of the BNST (BNSTmg), which are located near the MPOA. We identified BNST nuclei as previously described19, 33, 34 and followed their nomenclature. Similar to the MPOA, the BNST nuclei identified on Nissl-stained sections were easily identified on fluorescent images based on their locations and gene expressions. The BNSTpr was identified by the presence of abundant calbindin-positive neurons in its core area35, 36. The BNSTdm was located ventrally to the anterior commissure and was characterized by moderate oxytocin-ir fibers17. Since the BNSTv and BNSTmg were commonly identified with moderately dense neurotensin-positive cells19, we quantitated for BNSTv and BNSTmg together, subsequently referred to as BNSTv/mg.
Regional differences in ERα-ir and AR-ir cell densities
First, we performed immunostaining for ERα or AR to examine the cell density of gonadal steroid receptor-positive cells in each MPOA subregion. ERα-ir cells were densest in the MPNma, followed by the MPNvl, MPNp and MPNc. ERα-ir cells were sparse in the dmMPOA, vlMPOA and BNSTdm (n = 3, Fig. 2a–c,g). Dense AR-ir cells were found in the ACN, cMPOA, MPNvl, MPNp, MPNma, MPNmp, MPNc, BNSTpr and BNSTv/mg. Similar to ERα-ir cells, AR-ir cells were sparse in the dmMPOA and vlMPOA (n = 3, Fig. 2d–f,h). The largest difference in the cell densities of ERα-ir cells and AR-ir cells was recognized in the BNSTpr, which contains a larger density of AR-ir cells than ERα-ir cells.
To examine the coexpression of ERα and AR, we performed double immunostaining for both receptors. Cells that expressed both ERα and AR were observed throughout the MPOA (n = 3, Fig. 2g,h, Supplementary information Table S2). Double-labeled cells were dense in the MPNma, MPNp, MPNvl and MPNc. In general, approximately half of the ERα-ir cells in the MPOA were immunoreactive for AR. ERα-ir cells in the ACN, cMPOA, MPNp, BNSTpr and BNSTv/mg showed a high proportion of double-labeling (68.0–79.5%). In the MPNma, MPNvl and MPNp, a substantial proportion of AR-ir cells was also immunoreactive for ERα (61.7–74.0%).
Neurotransmitters and neuropeptides in MPOA subregions
Since the MPOA is rich in GABAergic neurons, glutamate decarboxylase 67 (Gad67)-expressing cells were found in the entire MPOA with a high density in the BNSTpr, MPNp and MPNc and a low density in the vlMPOA (Fig. 3a–c). In general, the cell density of Vglut2-expressing cells was lower than that of Gad67-expressing cells in the MPOA (Fig. 3a–h). The Vglut2-expressing cell density was higher in the cMPOA and ventromedial region of the MPOA including the MPNma and MPNmp, and was lower in the dorsal MPOA such as the ACN and dmMPOA, and the BNSTdm, BNSTpr and BNSTv/mg (Fig. 3e–h). A low density of Pdyn-expressing cells was mainly found in the cMPOA and MPNvl (Fig. 3i–l). Penk-positive cells were abundant in the MPNma, cMPOA, dmMPOA and MPNvl (Fig. 3m–p). The highest density of Penk-positive cells was found at the border area between the cMPOA and ACN (Fig. 1). Cart-expressing cell clusters were recognized in the BNSTpr and MPNmp (Fig. 3q–t). The vMPOA and dmBNST contained very few Cart-expressing cells. Neurotensin-expressing cells were abundant in the MPNvl and cMPOA, and they were sparse in the BNSTpr, dmMPOA and MPNmp (Fig. 4a–d). The distribution of neurotensin-expressing cells showed a ventrolateral to dorsomedial gradient. The density of galanin-expressing cells was higher in the MPNma, MPNmp and PVPOA and lower in the dmMPOA, vMPOA, BNSTdm and BNSTpr (Fig. 4e–h). A low density of Tac1-expressing cells was scattered throughout the entire MPOA with the highest density in the BNSTpr (Fig. 4i–l). The distribution of Tac2-expressing cells showed a posterolateral-anteromedial gradient. The BNSTv/mg, cMPOA, ACN and vlMPOA had abundant Tac2-expressing cells whereas very few Tac2-expressing cells were found in the dmMPOA, MPNma, MPNmp or BNSTpr (Fig. 4m–p). Trh-expressing cells were distributed mainly in the periphery of the MPOA with the highest cell density in the vMPOA (Fig. 4q–t).
Neurotransmitters and neuropeptides of ERα-positive cells
In general, approximately half of the Gad67-expressing cells of the MPOA were immunoreactive for ERα. The percentage of ERα-positive cells among Gad67-expressing cells was higher in the MPNma and MPNp, and lower in the vlMPOA, ACN, dmMPOA and BNSTdm (n = 4, Figs 3a–d and 5a,k). The percentage of ERα-positive cells among Vglut2-expressing cells was also highest in the MPNma and lowest in the ACN, dmMPOA and vlMPOA (n = 3, Figs 3e–h, 5b). The density of cells that expressed Pdyn and ERα was higher in the cMPOA and MPNvl (n = 3, Figs 3i–l, 5c). Cells that doubly expressed Penk and ERα were abundant in the MPNma, cMPOA and MPNvl (n = 3, Figs 3m–p, 5d). Of note, a vast majority of Penk-expressing cells were positive for ERα in the MPNma. The percentage of ERα-immunoreactive cells among Cart-positive cells was higher in the MPNma and lower in the vlMPOA (n = 3, Figs 3q–t, 5e). Overall, more than 80% of neurotensin-positive cells were immunoreactive for ERα in the entire MPOA (n = 3, Figs 4a–d, 5f). The MPNma contained the highest density of cells that expressed both ERα and galanin (n = 3, Figs 4e–h, 5g). Overall, less than half of Tac1-expressing cells were ERα-immunoreactive in the MPOA (n = 3, Figs 4i–l, 5h). Seventy to ninety percent of Tac2-expressing cells were positive for ERα in the MPOA except for the vlMPOA (n = 3, Figs 4m–p, 5i). Most Trh-expressing cells did not express ERα (n = 3, Figs 4q–t, 5j).
Neurotransmitters and neuropeptides of ERα cells in MPOA subregions
Next, we quantitated the proportion of neurotransmitter/neuropeptide- and ERα- doubly positive cells in each neurotransmitter/neuropeptide-positive cell and the proportion of the doubly positive cells in ERα-immunoreactive cells for each MPOA subregion (Figs 3–4, Supplementary information Table S3). In the ACN, more than half of the ERα-immunoreactive cells were Gad67, galanin and Tac2 positive cells. In the cMPOA, a large proportion of the ERα-immunoreactive cells expressed Gad67, neurotensin and galanin. In the MPNma, the large proportion of the ERα-immunoreactive cells expressed Gad67 and Vglut2. MPNmp was characterized by the large proportion of Vglut2-expression in ERα-immunoreactive cells. In the MPNvl, the majority of the ERα-positive cells were Gad67- and neurotensin-expressing cells. In the MPNp, MPNc, vMPOA BNSTdm, BNSTpr and BNSTv/mg, most ERα-immunoreactive cells were Gad67-expressing cells. The vlMPOA showed the least proportion of Gad67 expression in ERα-immunoreactive cells among the MPOA subregions. In the MPNp, SDN-POA, vMPOA BNSTdm, BNSTpr and BNSTv/mg, most ERα-immunoreactive cells were Gad67-expressing cells. In the BNSTv/mg, the majority of the ERα-immunoreactive cells were Gad67-expressing cells, followed by galanin- and Tac2-expressing cells.
Neurotransmitters and neuropeptides of AR-positive cells
The proportion of AR-positive cells in Gad67-expressing cells was higher in the MPNvl, MPNp and MPNc, and lower in the dmMPOA, vlMPOA and BNSTdm (n = 3, Figs 6a–d, 8a,k). The proportion of AR-positive cells in Vglut2-expressing cells was highest in the MPNma and lower in the vlMPOA, dmMPOA and BNSTdm (n = 3, Figs 6e–h, 8b). In contrast to low ERα-immunoreactivity (Fig. 4i–l), a high proportion of Pdyn-expressing cells were AR-positive cells in the entire MPOA (n = 3, Figs 6i–l, 8c). The proportion of AR-immunoreactive cells in Penk-expressing cells was higher in the cMPOA, MPNma, MPNmp and MPNp, and lower in the dmMPOA (n = 3, Figs 6m–p, 8d). The proportion of AR-immunoreactive cells in Cart-expressing cells was highest in the MPNp and lowest in the ACN (n = 4, Figs 6q–t, 8e). Similar to ERα (Fig. 4a–d), approximately 80% of neurotensin-expressing cells were immunoreactive for AR in the entire MPOA (n = 3, Figs 7a–d, 8f). Most galanin-expressing cells were immunoreactive for AR in the ACN, cMPOA, MPNma, MPNvl, MPNp, MPNc, vMPOA, BNSTpr and BNSTv/mg (n = 3, Figs 7e–h, 8g). Cells that expressed both AR and Tac1 were abundantly found in the BNSTpr (n = 3, Figs 7i–l, 8h). Similar to ERα (Fig. 4m–p), the proportion of AR-immunoreactive cells in Tac2-expressing cells was higher in the cMPOA and MPNvl, and was lower in the vlMPOA (n = 4, Figs 7m–p, 7i). Among the neurotransmitters and neuropeptides examined, Trh-expressing cells were the lowest proportion of AR-immunoreactive cells in all MPOA subregions (n = 3, Figs 7q–t, 8j).
Neurotransmitters and neuropeptides of AR cells in MPOA subregions
Lastly, we quantitated the proportion of neurotransmitter/neuropeptide- and AR- doubly positive cells in each neurotransmitter/neuropeptide-positive cell and the proportion of the doubly positive cells in AR-immunoreactive cells for each MPOA subregion (Figs 6–7, Supplementary information Table S4). In the cMPOA, a large proportion of AR-positive cells expressed Gad67, galanin and neurotensin. In the MPNma, the majority of AR-positive cells expressed Gad67 and galanin. In the MPNmp, half of the AR-positive cells were Gad67-expressing cells, followed by galanin- and Cart-expressing cells. In the MPNvl, the majority of the AR-positive cells were Gad67- and neurotensin-expressing cells. Since AR-ir cells were sparse in the vlMPOA, the cell density of double-labeled AR-immunoreactive cells was low for all neurotransmitters and neuropeptides examined. In the BNSTv/mg, the majority of ARα-immunoreactive cells expressed Gad67 and neurotensin.
Discussion
The present results show that gonadal steroid receptor-positive cells are not homogeneously distributed throughout the MPOA of male mice. The density of cells that express different neuropeptides and neurotransmitters largely differs among the MPOA subregions. Moreover, the proportions of cells that expressed ERα and AR were different among each neurotransmitter/neuropeptide. In addition to our previous study using female mice10, 18, these results showed the subregion heterogeneity of the MPOA. The current morphological data imply that neurotensin-, galanin-, Tac2- and Penk-expressing cells may be sensitive to gonadal steroid hormones whereas Trh-expressing cells are the least sensitive to AR and ERα.
The quantitation of ERα- and AR-positive cells clearly showed a differential density of gonadal steroid receptor-expressing cells in each MPOA subregion. The highest densities of ERα- and AR-positive cells were found in the MPNma and BNSTpr, respectively. In contrast, the dmMPOA, vlMPOA and BNSTdm contained the lower densities of ERα- and AR-positive cells. Cells doubly positive for ERα and AR were abundantly found throughout the MPOA, as reported for rat MPN37. In general, the density of doubly ERα- and AR-positive cells was greater than that of singly immunoreactive cells for ERα or AR in the MPOA. Especially, a high proportion of doubly ERα- and AR-positive cells was found in the cMPOA, MPNma, MPNp and MPNc, where neurons intensely expressed c-Fos during the parental, sexual and aggressive behaviors10.
Since Vglut1 and Vglut3 expressions are low in the preoptic area, glutamatergic neurons are identified by the expression of Vglut2 mRNA38, 39. Consistent with a general dichotomy between excitatory glutamatergic neurons and inhibitory GABAergic neurons, we previously showed that Gad67-expressing cells were distinct from Vglut2-expressing cells in the MPOA10. In most MPOA subregions, the density of Gad67-expressing neurons was higher than Vglut2-expressing excitatory neurons by at least two-fold, consistent with our previous study in female mice18.
In general, neurons that produce neuropeptides co-release fast neurotransmitters such as glutamate or GABA. For example, 90% of galaninergic neurons in the MPOA are Gad67-positive[24]. Thus, GABAergic neurons in the MPOA may be classified into Gad67(+)-, galanin(+)-neurons and Gad67(+)-, galanin(-)-neurons. Given that the combined density of Gad67-expressing cells and Vglut2-expressing cells is the total density of neurons, there should be a group of neurons that express multiple neuropeptides because the total density of neurons that express neuropeptides surpasses the density of cells that express Gad67 or Vglut2 in the cMPOA, MPNvl and BNSTv/mg. The expression of multiple neuropeptides has been reported for orexin neurons that express dynorphin and amylin40.
The present study showed that the ratio of ERα- and AR-immunoreactivity largely varied depending on neuronal groups in a subregion-specific manner. Among the neuropeptides examined, neurotensin-positive cells showed the highest proportion of ERα- and AR-immunoreactivities throughout the MPOA. Seventy to ninety percent of neurotensin-expressing cells were positive for ERα and AR in the cMPOA, MPNvl, MPNc and BNSTv/mg, which indicates that a large proportion of neurotensin-expressing cells expressed both ERα and AR in these subregions. Estradiol treatment induced neurotensin expression in the MPOA of ovariectomized female rats41, suggesting that ERα is required for the proper expression of neurotensin. Importantly, neurotensin mRNA expression in the rat MPN exhibits a male dominant, sexually dimorphic pattern23. Although the detection methods were not consistent, a larger cluster of neurotensin-expressing cells was found in the male MPNvl, whereas the cluster of neurotensin-expressing cells in the MPNvl of female mice was relatively small18.
Neurotensin-expressing cells positive for both ERα and AR were abundant in the cMPOA and MPNvl, which exhibited c-Fos expression during male sexual behavior and paternal behavior10. Thus, neurotensin-expressing cells in the cMPOA and MPNvl may modulate ERα- and AR-dependent male behaviors. Consistently, most neurotensin-expressing neurons in the MPOA send their fibers to the ventral tegmental area42, 43, and stimulation of neurotensin-expressing neurons increased dopamine release in the nucleus accumbens42. Since the ventral tegmental area-nucleus accumbens system is involved in male sexual behavior44, the current finding of high ERα/AR-positivity of neurotensin-expressing cells suggests that neurotensin-expressing cells incorporate a hormonal milieu to form sexual/social responses. It was recently reported that neurotensin-expressing cells in the MPOA of female mice exhibited an intracellular calcium increase in response to male odor, a social cue with reproductive relevance42. Importantly, estradiol treatment enhanced the response of neurotensin-expressing cells to male urine odor42 suggesting that neurotensin-expressing cells in the MPOA work as a regulatory hub for social behaviors of both male and female mice.
Similar to neurotensin, 70–90% of galanin-expressing cells were positive for ERα and AR in the MPNma, MPNp and MPNc, suggesting a proportion of galanin-expressing cells doubly positive for ERα and AR in these subregions. It is also known that galanin gene expression is regulated by an estrogen responsive element45, 46. Tac2-positive cells also showed very high immunoreactivity for gonadal steroid receptors. For example, approximately 70% of the Tac2-positive cells in the ACN, cMPOA and MPNvl were immunoreactive for ERα and AR, which indicates at least half of the cells were double positive for ERα and AR. Penk-positive cells also showed very high immunoreactivity for gonadal steroid receptors in many MPOA subregions. Thus, androgen may be deeply involved in the MPOA function mediated by cells that express neurotensin, galanin, Tac2 and Penk. Collectively, double-labeled cells of gonadal steroid receptors and neuropeptides were abundantly found in the cMPOA, MPNvl and MPNma, which are involved in sexual behavior, paternal behavior and aggressive behaviors, at least in terms of c-Fos expression10. Further studies are necessary to examine how mouse behaviors are regulated by gonadal steroid receptor-expressing cell clusters found in specific subregions such as Cart-expressing cell clusters in the BNSTpr and MPNmp. The vast majority of Trh-expressing cells were negative for ERα and AR, and Trh-expressing cells are absent in the cMPOA and MPNvl, which are associated with gonadal steroid-related sexual and paternal behaviors10. These findings suggest that the MPOA is incorporated in two neuroendocrine axes for gonadal and thyroid hormones.
In the present study, we quantitated the density of positive cells in brain sections for which single immunostaining or simultaneous staining for protein and mRNA was performed. The sum of the cells doubly positive for Gad67 and ERα and the cells doubly positive for Vglut2 and ERα was similar to the total density of ERα-positive cells identified via double immunostaining of ERα and AR. Similarly, the total number of AR positive cells was consistent between single immunostaining and double immunostaining with in situ hybridization. In addition, the density profiles of ERα and AR among the MPOA subregions were similar between in situ hybridization (ISH) sections and IHC sections (Figs 2, 3, 4, 6, 7). In the preliminary study, we confirmed the expression pattern was similar even when the concentrations of antibodies or riboprobes were changed. These results indicate that our histological procedure and cell counting method are very robust despite technical differences.
In addition to sexual behavior and aggression, the MPOA has multiple roles such as thermoregulation47, 48, sleep49, 50, body weight regulation51 and feeding52, 53. Although most lesion and/or pharmacological studies have targeted the entire MPOA in mice, our report on the role of the cMPOA in paternal behavior supports the idea that each MPOA subregion has a distinct functional role18. Furthermore, galanin neurons of the MPOA have crucial roles in paternal behavior24, and neurotensin neurons of the female MPOA reacted to male odor to activate the reward circuits42. These studies identified each neural subtype as an additional dimension of MPOA functional organization. Therefore, both subregions and neuron subtypes are necessary to fully elucidate the functional organization of the MPOA. In fact, GABAergic neurons in the cMPOA subregion are associated with the action of paternal caring versus infanticide10.
The present study showed a high degree of co-expression of ERα/AR and neurotransmitters/neuropeptides in the MPOA neurons. This finding implies that gonadal hormones may modulate various functions in which the MPOA is involved, in addition to sexual and paternal behaviors. A recent report indicated that hypothalamic Pdyn-expressing neurons expressed amylin, which works synergistically with leptin to inhibit feeding behavior in a sex-dependent manner40. Since amylin expression in the MPOA was high in postpartum dams and undetectable in males54, gonadal hormones may affect amylin expression in the MPOA, resulting in the modulation of food intake and energy metabolism.
One limitation of the present study is that we only examined young adult male C57BL/6 mice. The expressions of gonadal hormone receptors may differ depending on age, mouse strain and sex. Further studies should incorporate female and aged male mice to determine whether the hormonal milieu and aging may alter gene expression in the MPOA. Another limitation is that the differential expressions of mRNAs and proteins detected by ISH and immunostaining do not always reflect biological differences. To elucidate the functional role of MPOA neuron subtypes, it is essential to use an appropriate Cre-driver mouse for optogenetic and pharmacogenetic analyses. Neuropeptide-specific Cre driver mice are also important to determine how gonadal steroid hormones modulate MPOA neuron subtypes and subsequently alter male behaviors as reported in females42. The present study will provide useful information for future studies on the functional anatomy of the MPOA at the subregion level.
Methods
Animals and tissue preparation
All procedures were conducted in accordance with the Guidelines for Animal Experiments of Toho University and were approved by the Institutional Animal Care and Use Committee of Toho University (Approved protocol ID #15-52-254). Breeding pairs of C57BL/6 J mice were obtained from Japan SLC Inc. and CLEA Japan. Mice were raised in our breeding colony under controlled conditions (12 h light/dark cycle; lights on at 8:00 A.M.; 23 ± 2 °C; 55 ± 5% humidity; and ad libitum access to water and food). Mice were weaned at 4 weeks of age and were housed in groups of four or five.
Male mice (10–20-week-old, n = 39) were anesthetized with sodium pentobarbital (50 mg/kg, i.p.), and then transcardially perfused with 4% paraformaldehyde (PFA) in phosphate buffered saline (PBS). The brains were postfixed in 4% PFA at 4 °C overnight, followed by cryoprotection in 30% sucrose in PBS for two days, embedded in Surgipath (FSC22, Leica Biosystems), and stored at −80 °C until use. The brains were cryosectioned coronally at a thickness of 40 μm.
Single or double immunohistochemistry for ERα and AR
For single immunostaining for ERα or AR, brain sections were washed and incubated with rabbit anti-ERα (1:5000, C1355, Millipore) or anti-AR (1:500, sc-816, Santa Cruz biotechnology) antibodies, of which the specificities were verified using gene-deficient mice, shRNA-based gene knockdown or preabsorption with antigen12, 13, 55, 56. The sections were washed and immersed in Alexa568-conjugated donkey anti-rabbit IgG antibody (1:250, A10037, Thermo scientific) and Hoechst 33342 (1 μg/ml).
To examine the coexpression of ERα and AR, we performed double fluorescent immunostaining using two rabbit antibodies for ERα and AR according to a previously published protocol with modifications for multiple labeling with antibodies that were raised in the same host species57,58,59. In our protocol, a dinitrophenyl-conjugated rabbit anti-AR antibody was used after forming a complex of rabbit anti-ERα antibody and anti-rabbit IgG antibody, which prevents anti-rabbit IgG antibody from binding to rabbit anti-AR antibody.
The anti-AR antibody (20 μg/100 μl) was labeled with dinitrophenyl via incubation with 2.6 μg n-succinimidyl 6-(2,4-dinitroanilino) hexanoate in PBS for 2 hours and purified by ultrafiltration using an Amicon Ultra-0.5 (UFC5050, Merck Millipore). The brain sections were washed with PBS that contained 0.2% Triton X-100 (PBST), incubated with methanol for 5 minutes, and washed with PBST. The sections were blocked with 0.8% Block Ace (Dainihon-Seiyaku, Japan) for 30 minutes in PBST, and then incubated at 4 °C overnight in anti-ERα antibody (1:3000) diluted in 0.4% Block Ace/PBST. The sections were washed and incubated in Fab fragment of Alexa488-conjugated donkey anti-rabbit IgG antibody (1:1000, 711-547-003, Jackson Immunoresearch) for 1 hour. The sections were washed and blocked with 0.8% Block Ace for 30 min in PBST, and incubated at 4 °C overnight in the dinitrophenyl-conjugated anti-AR antibody (1:100). The sections were washed and incubated in a goat anti-dinitrophenyl antibody (1:1000, D9781, Sigma Aldrich) for 1 hour, followed by washing and incubation in a cocktail of Alexa568-conjugated donkey anti-goat IgG antibody (1:1000, ab175704, Abcam) and Hoechst 33342 (1 μg/ml). The sections were mounted on a glass slide with Gel/Mount (BioMeda).
In situ hybridization (ISH) combined with immunohistochemistry
To assess the expression of ERα or AR in each neuronal subtype in the MPOA subregions, we performed two different types of histological examination using serial sections: 1) immunostaining for ERα or AR combined with double ISH for two from ten neuronal subtype markers such as Gad67, Vglut2, Pdyn, Penk, Cart, neurotensin, galanin, Tac1, Tac2 and Trh, and 2) double ISH combined with immunostaining for markers that are differentially expressed among the MPOA subregions such as calbindin, neurotensin, oxytocin, Penk and Vglut2.
The complete list of riboprobes used for ISH is available in Supplementary Table S1. All cDNA fragments were amplified, inserted into the pGEM-T plasmid (A3600, Promega) and transformed to DH5α E. coli. The template cDNA was produced using polymerase chain reaction with the specific primers (5′-ATTTAGGTGACACTATAG-3′) and (5′-TAATACGACTCACTATAGGG-3′). The antisense probes were transcribed by SP6 RNA polymerase (P1085, Promega) in the presence of digoxigenin-labeled UTP (Dig labeling mix; Roche Diagnostics,) or fluorescein-labeled UTP (Fluorescein labeling mix; Roche Diagnostics). The sense probes for control staining were transcribed by T7 RNA polymerase (10881767001, Roche Diagnostics) in the same manner.
For immunostaining for ERα or AR combined with double ISH for neuronal subtype markers, the brain sections were processed for ISH as previously described10, 18 with modifications. Briefly, the sections were washed with PBS containing 0.1% Tween-20 (PBT) and postfixed with 4% PFA in PBS for 10 minutes. The sections were immersed in methanol containing 0.3% H2O2 for 10 minutes, followed by acetylation with 0.25% acetic anhydride in 0.1 M triethanolamine (pH 8.0). The hybridization solution contained 50% deionized formamide, 5 × standard saline citrate (SSC, pH 7.0), 5 mM ethylene-diaminetetraacetic acid (pH 8.0), 0.2 mg/ml yeast tRNA, 0.2% Tween-20, 0.2% sodium dodecyl sulfate, 10% dextran sulfate and 0.1 mg/ml heparin. The sections were prehybridized at 58 °C in the mixture of the hybridization solution and PBT (1:1) for 30 minutes, immersed in the hybridization solution for 15 minutes, and then hybridized with the digoxigenin-labeled and fluorescein-labeled riboprobes (1 μg/ml) at 58 °C for 16 hours. After hybridization, the sections were washed twice with 2 × SSC containing 50% formamide at 58 °C for 10 minutes, incubated with RNAse A solution (20 μg/ml, Sigma) and avidin (0.1 μg/ml) at 37 °C for 60 minutes, rinsed twice in 2 × SSC and rinsed four times in 0.2 × SSC at 37 °C (10 minutes each). The sections were incubated in a peroxidase-conjugated anti-digoxigenin antiserum (1:1000, Roche Diagnostics) with biotin (0.5 μg/ml). After two hours of incubation in the antibody solution at room temperature, the sections were washed and immersed in 0.1 M boric buffer (pH 8.5) containing 4 μM biotin-labeled tyramide, 4% dextran sulfate, 0.05 mg/ml iodophenol, and 0.003% H2O2 for 30 minutes, followed by incubation with 10% H2O2/methanol for 30 minutes to quench the peroxidase activity.
The sections were subsequently washed and incubated in a cocktail of anti-ERα (1:5000) or anti-AR (1:500) antibody and peroxidase-conjugated anti-fluorescein antibody (1:1000, Roche Diagnostics) at 4 °C overnight. The sections were washed and immersed in 0.1 M boric buffer (pH8.5) containing 10 μM Alexa488-labeled tyramide, 10% dextran sulfate, 0.05 mg/ml iodophenol and 0.003% H2O2 for 30 minutes. They were subsequently immersed in a cocktail of Alexa647-conjugated streptavidin (1:10000, Life Technologies), Alexa568-conjugated donkey anti-rabbit IgG antibody (1:250, A10037, Thermo scientific) and Hoechst 33342 (1 μg/ml). The sections were mounted on a glass slide with Gel/Mount.
To identify the MPOA subregions, we performed Nissl staining and double ISH combined with immunostaining for regional markers as previously described. The combinations of reginal marker were 1) double ISH for neurotensin and Penk combined with immunostaining for calbindin (1:1000, C9848, Sigma-Aldrich), and 2) ISH for Vglut2 combined with immunostaining for oxytocin (1:5000, #20068, ImmunoStar).
Histological analysis
Detailed histological analyses of the MPOA for ERα and AR were performed using a set of three sections 120 μm apart between bregma + 0.10 mm and bregma −0.14 mm (corresponds to Fig. 1a-c), where abundant AR- and ERα-positive cells are recognized. Each set of three sections was used for double immunostaining for ERα and AR, or ISH combined with immunostaining, and then processed for positive cell counting. To evaluate the cell density of ERα- or AR-positive cells, three or four sets of MPOA sections from different mice were used for ERα- and AR-immunostaining, and then ERα- and AR-positive cells were counted and averaged. The areas quantitated are presented in Fig. 1a-c as shaded areas.
Fluorescent photographs were obtained using a Nikon Eclipse Ni microscope equipped with the A1R confocal detection system under a 20 × objective (Nikon Instruments Inc., Tokyo, Japan). Each image was obtained as a five-layer z-stack of images, and the optical thickness of the sections was 1.0 μm. Experimental controls were prepared in which one or both primary antibodies were omitted from the reaction solution to confirm no detectable signal. In addition, specific staining of each antisense probe was not observed in the sections stained with the sense probes. For the immunostained sections, some non-specific granule-like signals were identified, however, they were easily distinguished from nuclear or cytoplasmic specific staining.
Images were analyzed using ImageJ software (version 1.50i, NIH, USA). The threshold was determined to be above background or nonspecific signals on the control sections, and the same threshold was used through the analysis for all samples. All procedures for brain sampling, ISH and immunohistochemistry were performed in exactly the same time course under a controlled temperature, thus, the fixed threshold worked to evaluate the positive cells of different mice. Singly or doubly positive cells were manually marked on the threshold images and automatically counted. The same contours for the MPOA subregions as shown in Fig. 1a–c were used throughout all samples with positional adjustments along the dorsal-ventral axis between the anterior commissure and optic tract. All histological procedures were conducted under blind conditions. The data in each subregion were presented as the mean ± S.E.M.
Data availability
The datasets generated during and/or analysed during the current study are available from the corresponding author on reasonable request.
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Acknowledgements
We were grateful to Hiroko Arai, Akane Iijima, Kento Suzuki and Arisa Ichikawa for excellent technical assistance for this study.
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Conceived and designed the experiments: Y.T., H.F. Performed the experiments: Y.T., S.Y., S.O., M.K. Analyzed the data: Y.T. Contributed reagents/materials/analysis tools: Y.T., K.T. Wrote the paper: Y.T., S.Y., H.F. This work was supported by JSPS KAKENHI (Grant Number 24780292 to Y.T.; 15K18364 to Y.T.; 26220207 to H.F.; 16K15187 to H.F.; 26507003 to H.F.), MEXT KAKENHI (Grant Number 15H05935 to H.F.), and Takeda Science Foundation (Research Grant to Y.T.).
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Tsuneoka, Y., Yoshida, S., Takase, K. et al. Neurotransmitters and neuropeptides in gonadal steroid receptor-expressing cells in medial preoptic area subregions of the male mouse. Sci Rep 7, 9809 (2017). https://doi.org/10.1038/s41598-017-10213-4
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DOI: https://doi.org/10.1038/s41598-017-10213-4
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