Distribution and Seasonal Variation in Hypothalamic RF‐amide Peptides in a Semi‐Desert Rodent,the Jerboa

The jerboa is a semi‐desert rodent, in which reproductive activity depends on the seasons, being sexually active in the spring–summer. The present study aimed to determine whether the expression of two RF‐amide peptides recently described to regulate gonadotrophin‐releasing hormone neurone activity, kisspeptin (Kp) and RF‐amide‐related peptide (RFRP)‐3, displays seasonal variation in jerboa. Kp and/or RFRP‐3 immunoreactivity was investigated in the hypothalamus of jerboas captured in the field of the Middle Atlas mountain (Morocco), either in the spring or autumn. As in other rodents, the Kp‐immunoreactive (‐IR) neurones were found in the anteroventro‐periventricular and arcuate nuclei. RFRP‐3 neurones were noted within the dorso/ventromedial hypothalamus. A marked sexual dimorphism in the expression of Kp (but not RFRP‐3) was observed. The number of Kp‐IR neurones was nine‐fold higher, and the density of Kp‐IR fibres and terminal‐like elements in the median eminence was two‐fold higher in females than in males. Furthermore, a significant seasonal variation in peptide expression was obtained with an increase in both Kp‐ and RFRP‐3‐IR cell bodies in sexually active male jerboas captured in the spring compared to sexually inactive autumn animals. In the arcuate nucleus, the level of Kp‐IR cells and fibres was significant higher during the sexually active period in the spring than during the autumnal sexual quiescence. Similarly, the number of RFRP‐3‐IR neurones in the ventro/dorsomedial hypothalamus was approximately three‐fold higher in sexually active jerboa captured in the spring compared to sexually inactive autumn animals. Altogether, the present study reports the distribution of Kp and RFRP‐3 neurones in the hypothalamus of a desert species and reveals a seasonal difference in their expression that correlates with sexual activity. These findings suggest that these two RF‐amide peptides may act in concert to synchronise the gonadotrophic activity of jerboas with the seasons.     

Evidence for Changes in Numbers of Synaptic Inputs onto KNDy and GnRH Neurones during the Preovulatory LH Surge in the Ewe

Kisspeptin neurones located in the arcuate nucleus (ARC) and preoptic area (POA) are critical mediators of gonadal steroid feedback onto gonadotrophin‐releasing hormone (GnRH) neurones. ARC kisspeptin cells that co‐localise neurokinin B (NKB) and dynorphin (Dyn), are collectively referred to as KNDy (Kisspeptin/NKB/Dyn) neurones, and have been shown in mice to also co‐express the vesicular glutamate transporter, vGlut2, an established glutamatergic marker. The ARC in rodents has long been known as a site of hormone‐induced neuroplasticity, and changes in synaptic inputs to ARC neurones in rodents occur over the oestrous cycle. Based on this evidence, the the present study aimed to examine possible changes across the ovine oestrous cycle in synaptic inputs onto kisspeptin cells in the ARC (KNDy) and POA, and inputs onto GnRH neurones. Gonadal‐intact breeding season ewes were perfused using 4% paraformaldehyde during either the luteal or follicular phase of the oestrous cycle, with the latter group killed at the time of the luteinising hormone (LH) surge. Hypothalamic sections were processed for triple‐label immunodetection of kisspeptin/vGlut2/synaptophysin or kisspeptin/vGlut2/GnRH. The total numbers of synaptophysin‐ and vGlut2‐positive inputs to ARC KNDy neurones were significantly increased at the time of the LH surge compared to the luteal phase; because these did not contain kisspeptin, they do not arise from KNDy neurones. By contrast to the ARC, the total number of synaptophysin‐positive inputs onto POA kisspeptin neurones did not differ between luteal phase and surge animals. The total number of kisspeptin and vGlut2 inputs onto GnRH neurones in the mediobasal hypothalamus (MBH) was also increased during the LH surge, and could be attributed to an increase in the number of KNDy (double‐labelled kisspeptin + vGlut2) inputs. Taken together, these results provide novel evidence of synaptic plasticity at the level of inputs onto KNDy and GnRH neurones during the ovine oestrous cycle. Such changes may contribute to the generation of the preovulatory GnRH/LH surge.     

Time‐of‐day‐dependent sensitivity of the reproductive axis to RFamide‐related peptide‐3 inhibition in female Syrian hamsters

In spontaneously ovulating rodent species, the timing of the luteinising hormone (LH) surge is controlled by the master circadian pacemaker in the suprachiasmatic nucleus (SCN). The SCN initiates the LH surge via the coordinated control of two opposing neuropeptidergic systems that lie upstream of the gonadotrophin‐releasing hormone (GnRH) neuronal system: the stimulatory peptide, kisspeptin, and the inhibitory peptide, RFamide‐related peptide‐3 (RFRP‐3; the mammalian orthologue of avian gonadotrophin‐inhibitory hormone [GnIH]). We have previously shown that the GnRH system exhibits time‐dependent sensitivity to kisspeptin stimulation, further contributing to the precise timing of the LH surge. To examine whether this time‐dependent sensitivity of the GnRH system is unique to kisspeptin or a more common mechanism of regulatory control, we explored daily changes in the response of the GnRH system to RFRP‐3 inhibition. Female Syrian hamsters were ovariectomised to eliminate oestradiol (E₂)‐negative‐feedback and RFRP‐3 or saline was centrally administered in the morning or late afternoon. LH concentrations and Lhβ mRNA expression did not differ between morning RFRP‐3‐and saline‐treated groups, although they were markedly suppressed by RFRP‐3 administration in the afternoon. However, RFRP‐3 inhibition of circulating LH at the time of the surge does not appear to act via the GnRH system because no differences in medial preoptic area Gnrh or RFRP‐3 receptor Gpr147 mRNA expression were observed. Rather, RFRP‐3 suppressed arcuate nucleus Kiss1 mRNA expression and potentially impacted pituitary gonadotrophs directly. Taken together, these findings reveal time‐dependent responsiveness of the reproductive axis to RFRP‐3 inhibition, possibly via variation in the sensitivity of arcuate nucleus kisspeptin neurones to this neuropeptide.     

Discovery and Evolutionary History of Gonadotrophin‐Inhibitory Hormone and Kisspeptin: New Key Neuropeptides Controlling Reproduction

Gonadotrophin‐releasing hormone (GnRH) is the primary hypothalamic factor responsible for the control of gonadotrophin secretion in vertebrates. However, within the last decade, two other hypothalamic neuropeptides have been found to play key roles in the control of reproductive functions: gonadotrophin‐inhibitory hormone (GnIH) and kisspeptin. In 2000, we discovered GnIH in the quail hypothalamus. GnIH inhibits gonadotrophin synthesis and release in birds through actions on GnRH neurones and gonadotrophs, mediated via GPR147. Subsequently, GnIH orthologues were identified in other vertebrate species from fish to humans. As in birds, mammalian and fish GnIH orthologues inhibit gonadotrophin release, indicating a conserved role for this neuropeptide in the control of the hypothalamic‐pituitary‐gonadal axis across species. Subsequent to the discovery of GnIH, kisspeptin, encoded by the KiSS‐1 gene, was discovered in mammals. By contrast to GnIH, kisspeptin has a direct stimulatory effect on GnRH neurones via GPR54. GPR54 is also expressed in pituitary cells, but whether gonadotrophs are targets for kisspeptin remains unresolved. The KiSS‐1 gene is also highly conserved and has been identified in mammals, amphibians and fish. We have recently found a second isoform of KiSS‐1, designated KiSS‐2, in several vertebrates, but not birds, rodents or primates. In this review, we highlight the discovery, mechanisms of action, and functional significance of these two chief regulators of the reproductive axis.     

Kisspeptin Neurones do not Directly Signal to RFRP‐3 Neurones but RFRP‐3 may Directly Modulate a Subset of Hypothalamic Kisspeptin Cells in Mice

The neuropeptides kisspeptin (encoded by Kiss1) and RFamide‐related peptide‐3 (also known as GnIH; encoded by Rfrp) are potent stimulators and inhibitors, respectively, of reproduction. Whether kisspeptin or RFRP‐3 might act directly on each other's neuronal populations to indirectly modulate reproductive status is unknown. To examine possible interconnectivity of the kisspeptin and RFRP‐3 systems, we performed double‐label in situ hybridisation (ISH) for the RFRP‐3 receptors, Gpr147 and Gpr74, in hypothalamic Kiss1 neurones of adult male and female mice, as well as double‐label ISH for the kisspeptin receptor, Kiss1r, in Rfrp‐expressing neurones of the hypothalamic dorsal‐medial nucleus (DMN). Only a very small proportion (5‐10%) of Kiss1 neurones of the anteroventral periventricular region expressed Gpr147 or Gpr74 in either sex, whereas higher co‐expression (approximately 25%) existed in Kiss1 neurones in the arcuate nucleus. Thus, RFRP‐3 could signal to a small, primarily arcuate, subset of Kiss1 neurones, a conclusion supported by the finding of approximately 35% of arcuate kisspeptin cells receiving RFRP‐3‐immunoreactive fibre contacts. By contrast to the former situation, no Rfrp neurones co‐expressed Kiss1r in either sex, and Tacr3, the receptor for neurokinin B (NKB; a neuropeptide co‐expressed with arcuate kisspeptin neurones) was found in <10% of Rfrp neurones. Moreover, kisspeptin‐immunoreactive fibres did not readily appose RFRP‐3 cells in either sex, further excluding the likelihood that kisspeptin neurones directly communicate to RFRP‐3 neurones. Lastly, despite abundant NKB in the DMN region where RFRP‐3 soma reside, NKB was not co‐expressed in the majority of Rfrp neurones. Our results suggest that RFRP‐3 may modulate a small proportion of kisspeptin‐producing neurones in mice, particularly in the arcuate nucleus, whereas kisspeptin neurones are unlikely to have any direct reciprocal actions on RFRP‐3 neurones.     

Kisspeptin,gonadotrophin‐releasing hormone and oestrogen receptor α colocalise with neuronal nitric oxide synthase neurones in prepubertal female sheep

Puberty is a process that integrates multiple inputs ultimately resulting in an increase in gonadotrophin‐releasing hormone (GnRH) secretion. Although kisspeptin neurones play an integral role in GnRH secretion and puberty onset, other systems are also likely important. One potential component is nitric oxide (NO), a gaseous neurotransmitter synthesised by nitric oxide synthase (NOS). The present study aimed to neuroanatomically characterise neuronal NOS (nNOS) in prepubertal female sheep and determine whether oestradiol exerts effects on this system. Luteinising hormone secretion was reduced by oestradiol treatment in prepubertal ovariectomised ewes. Neurones immunoreactive for nNOS were identified in several areas, with the greatest number present in the ventrolateral portion of the ventromedial hypothalamus, followed by the ventromedial hypothalamus, preoptic area (POA) and arcuate nucleus (ARC). Next, we determined whether nNOS neurones contained oestrogen receptor (ER)α and could potentially communicate oestradiol (E₂) feedback to GnRH neurones. Neuronal NOS neurones contained ERα with the percentage of coexpression (12%‐40%) depending upon the area analysed. We next investigated whether a neuroanatomical relationship existed between nNOS and kisspeptin or nNOS and GnRH neurones. A high percentage of kisspeptin neurones in the POA (79%) and ARC (98%) colocalised with nNOS. Kisspeptin close contacts were also associated with nNOS neurones. A greater number of close contacts were observed in the ARC than the POA. A high percentage of POA GnRH neurones (79%) also expressed nNOS, although no GnRH close contacts were observed onto nNOS neurones. Neither the numbers of nNOS neurones in the POA or hypothalamus, nor the percentage of nNOS coexpression with GnRH, kisspeptin or ERα were influenced by oestradiol. These experiments reveal that a neuroanatomical relationship exists between both nNOS and kisspeptin and nNOS and GnRH in prepubertal ewes. Therefore, nNOS may act both directly and indirectly to influence GnRH secretion in prepubertal sheep.     

Male Effect Pheromone Tickles the Gonadotrophin‐Releasing Hormone Pulse Generator

In sheep and goats, the primer pheromone produced by the male induces out‐of‐seasonal ovulation in anoestrous females, the so‐called ‘male effect.’ Because the initial endocrine event following reception of the pheromone is the stimulation of pulsatile luteinising hormone (LH) secretion, the central target of the pheromone is considered to be the putative gonadotrophin‐releasing hormone (GnRH) pulse generator. Using electrophysiological techniques to record multiple‐unit activity (MUA) in close proximity to kisspeptin neurones in the arcuate nucleus (ARC) of Shiba goats, we found that bursts (volleys) of MUA occur at regular intervals, and repetitive bursts are invariably associated with discrete pulses of LH, suggesting that the ARC kisspeptin neurones may be the intrinsic source of the GnRH pulse generator. A brief exposure of female goats to the pheromone immediately elicited an instantaneous rise in MUA, which is followed by an MUA volley and an accompanying LH pulse, indicating that the pheromone signal is transmitted to a subset of the ARC kisspeptin neurones to activate them. Because it has been suggested that the neurokinin B and dynorphin coexpressed in those neurones play critical roles in generating rhythmic bursts, they may be involved in the intracellular pheromone actions that are responsible for inducing the GnRH pulse.     

Surge‐Like Luteinising Hormone Secretion Induced by Retrochiasmatic Area NK3R Activation is Mediated Primarily by Arcuate Kisspeptin Neurones in the Ewe

The neuropeptides neurokinin B (NKB) and kisspeptin are potent stimulators of gonadotrophin‐releasing hormone (GnRH)/luteinsing hormone (LH) secretion and are essential for human fertility. We have recently demonstrated that selective activation of NKB receptors (NK3R) within the retrochiasmatic area (RCh) and the preoptic area (POA) triggers surge‐like LH secretion in ovary‐intact ewes, whereas blockade of RCh NK3R suppresses oestradiol‐induced LH surges in ovariectomised ewes. Although these data suggest that NKB signalling within these regions of the hypothalamus mediates the positive‐feedback effects of oestradiol on LH secretion, the pathway through which it stimulates GnRH/LH secretion remains unclear. We proposed that the action of NKB on RCh neurones drives the LH surge by stimulating kisspeptin‐induced GnRH secretion. To test this hypothesis, we quantified the activation of the preoptic/hypothalamic populations of kisspeptin neurones in response to POA or RCh administration of senktide by dual‐label immunohistochemical detection of kisspeptin and c‐Fos (i.e. marker of neuronal activation). We then administered the NK3R agonist, senktide, into the RCh of ewes in the follicular phase of the oestrous cycle and conducted frequent blood sampling during intracerebroventricular infusion of the kisspeptin receptor antagonist Kp‐271 or saline. Our results show that the surge‐like secretion of LH induced by RCh senktide administration coincided with a dramatic increase in c‐Fos expression within arcuate nucleus (ARC) kisspeptin neurones, and was completely blocked by Kp‐271 infusion. We substantiate these data with evidence of direct projections of RCh neurones to ARC kisspeptin neurones. Thus, NKB‐responsive neurones in the RCh act to stimulate GnRH secretion by inducing kisspeptin release from KNDy neurones.     

Differential response patterns of kisspeptin and RFamide‐related peptide to photoperiod and sex steroid feedback in the Djungarian hamster (Phodopus sungorus)

Many animals synchronise their reproductive activity with the seasons to optimise the survival of their offspring. This synchronisation involves switching on and off their gonadotrophic axis. Ever since their discovery as key regulators of gonadotrophin‐releasing hormone (GnRH) neurones, the hypothalamic RF‐amide peptides kisspeptin and RFamide‐related peptide (RFRP) have been a major focus of research on the seasonal regulation of the gonadotrophic axis. In the present study, we investigated the regulation of both neuropeptides in the Djungarian hamster, a major animal model for the study of seasonal reproduction. During the long‐day breeding period, kisspeptin neurones in the anteroventral periventricular area are solely controlled by a positive sex steroid feedback and, in the arcuate nucleus, they are subject to a very strong negative sex steroid feedback associated with a minor photoperiodic effect. During short‐day sexual quiescence, the disappearance of this hormonal feedback leads to high levels of kisspeptin in arcuate neurones. Notably, chronic central administration of kisspeptin is able to over‐ride the photoperiodic inhibition of the gonadotrophic axis and reactivate the reproductive function. Therefore, our data suggest that kisspeptin secretion by arcuate neurones during sexual quiescence is inhibited by mechanisms upstream of kisspeptin neurones. RFRP expression is solely controlled by photoperiod, being strongly reduced in short days independently of the sex steroid feedback. Thus, kisspeptin and RFRP display contrasting patterns of expression and regulation. Upstream mechanisms controlling these neurones should be the focus of further studies on the roles of these RFamide neuropeptides in the seasonal control of reproduction.     

Ovarian Regulation of Kisspeptin Neurones in the Arcuate Nucleus of the Rhesus Monkey (Macaca mulatta)

Tonic gonadotrophin secretion throughout the menstrual cycle is regulated by the negative‐feedback actions of ovarian oestradiol (E₂) and progesterone. Although kisspeptin neurones in the arcuate nucleus (ARC) of the hypothalamus appear to play a major role in mediating these feedback actions of the steroids in nonprimate species, this issue has been less well studied in the monkey. In the present study, we used immunohistochemistry and in situ hybridisation to examine kisspeptin and KISS1 expression, respectively, in the mediobasal hypothalamus (MBH) of adult ovariectomised (OVX) rhesus monkeys. We also examined kisspeptin expression in the MBH of ovarian intact females, and the effect of E₂, progesterone and E₂ + progesterone replacement on KISS1 expression in OVX animals. Kisspeptin or KISS1 expressing neurones and pronounced kisspeptin fibres were readily identified throughout the ARC of ovariectomised monkeys but, on the other hand, in intact animals, kisspeptin cell bodies were small in size and number and only fine fibres were observed. Replacement of OVX monkeys with physiological levels of E₂, either alone or with luteal phase levels of progesterone, abolished KISS1 expression in the ARC. Interestingly, progesterone replacement alone for 14 days also resulted in a significant down‐regulation of KISS1 expression. These findings support the view that, in primates, as in rodents and sheep, kisspeptin signalling in ARC neurones appears to play an important role in mediating the negative‐feedback action of E₂ on gonadotrophin secretion, and also indicate the need to study further their regulation by progesterone.     

Nutritional Programming of Accelerated Puberty in Heifers: Involvement of Pro‐Opiomelanocortin Neurones in the Arcuate Nucleus

The timing of puberty and subsequent fertility in female mammals are dependent on the integration of metabolic signals by the hypothalamus. Pro‐opiomelanocortin (POMC) neurones in the arcuate nucleus (ARC) comprise a critical metabolic‐sensing pathway controlling the reproductive neuroendocrine axis. α‐Melanocyte‐stimulating hormone (αMSH), a product of the POMC gene, has excitatory effects on gonadotrophin‐releasing hormone (GnRH) neurones and fibres containing αMSH project to GnRH and kisspeptin neurones. Because kisspeptin is a potent stimulator of GnRH release, αMSH may also stimulate GnRH secretion indirectly via kisspeptin neurones. In the present work, we report studies conducted in young female cattle (heifers) aiming to determine whether increased nutrient intake during the juvenile period (4–8 months of age), a strategy previously shown to advance puberty, alters POMC and KISS1 mRNA expression, as well as αMSH close contacts on GnRH and kisspeptin neurones. In Experiment 1, POMC mRNA expression, detected by in situ hybridisation, was greater (P < 0.05) in the ARC in heifers that gained 1 kg/day of body weight (high‐gain, HG; n = 6) compared to heifers that gained 0.5 kg/day (low‐gain, LG; n = 5). The number of KISS1‐expressing cells in the middle ARC was reduced (P < 0.05) in HG compared to LG heifers. In Experiment 2, double‐immunofluorescence showed limited αMSH‐positive close contacts on GnRH neurones, and the magnitude of these inputs was not influenced by nutritional status. Conversely, a large number of kisspeptin‐immunoreactive cells in the ARC were observed in close proximity to αMSH‐containing varicosities. Furthermore, HG heifers (n = 5) exhibited a greater (P < 0.05) percentage of kisspeptin neurones in direct apposition to αMSH fibres and an increased (P < 0.05) number of αMSH close contacts per kisspeptin cell compared to LG heifers (n = 6). These results indicate that the POMC‐kisspeptin pathway may be important in mediating the nutritional acceleration of puberty in heifers.     

Kisspeptin and the Preovulatory Gonadotrophin‐Releasing Hormone/Luteinising Hormone Surge in the Ewe: Basic Aspects and Potential Applications in the Control of Ovulation

The identification of the neural mechanisms controlling ovulation in mammals has long been a ‘holy grail’ over recent decades, although the recent discovery of the kisspeptin systems has totally changed our views on this subject. Kisspeptin cells are the major link between gonadal steroids and gonadotrophin‐releasing hormone (GnRH) neurones. In the female rodent, kisspeptin cells of the preoptic area are involved in the positive‐feedback action of oestrogen on GnRH secretion, although the picture appears more complicated in the ewe. As in rodents, activation of preoptic kisspeptin neurones accompanies the GnRH surge in the ewe but an active role for arcuate kisspeptin neurones has also been proposed. Experimentally, kisspeptin is able to restore reproductive function when the hypothalamic‐hypophyseal ovarian axis is quiescent. For example, i.v. infusion of a low dose of peptide in anoestrous ewes induces an immediate and sustained release of gonadotrophin, which subsides and then provokes a luteinising hormone (LH) surge a few hours later. This pharmacological intervention induces the same hormonal changes normally observed during the follicular phase of the oestrous cycle, including the secretion of oestrogen and its negative‐ and positive‐feedback actions on the secretion of LH and follicle‐stimulating hormone. Accordingly, a high percentage of kisspeptin‐infused animals ovulated. Although the multiple facets of how the kisspeptin systems modulate GnRH secretion are not totally understood, the demonstration that exogenous kisspeptin administration can induce ovulation in anovulatory animals paves the way for future therapeutic applications aiming to control reproduction.     

Effects of Orchidectomy and Testosterone Replacement on Numbers of Kisspeptin‐, Neurokinin B‐, and Dynorphin A‐Immunoreactive Neurones in the Arcuate Nucleus of the Hypothalamus in Obese and Diabetic Rats

Neurones expressing kisspeptin, neurokinin B and dynorphin A, located in the arcuate nucleus of the hypothalamus (ARC), are important regulators of reproduction. Their functions depend on metabolic and hormonal status. We hypothesised that male rats with high‐fat diet‐induced obesity (DIO) and/or streptozotocin‐induced diabetes mellitus type 1 (DM1) and type 2 (DM2) will have alterations in numbers of immunoreactive (‐IR) cells: kisspeptin‐IR and/or neurokinin B‐IR and dynorphin A‐IR neurones in the ARC in the sham condition. In addition, orchidectomy alone (ORX) and with testosterone treatment (ORX+T) will unmask possible deficits in the response of these neurones in DIO, and/or DM1 and DM2 rats. Rats were assigned to four groups: a control (C) and one diabetic group (DM1) were fed a regular chow diet, whereas the obese group (DIO) and the other diabetic group (DM2) were fed a high‐fat diet. To induce diabetes, streptozotocin was injected. After 6 weeks, each group was divided into three subgroups: ORX, ORX+T and sham. After another 2 weeks, metabolic and hormonal profiles were assessed and immunocytochemistry was performed. We found that: (1) under sham conditions: (i) DM1 and DM2 animals had higher numbers of kisspeptin‐IR cells than controls and (ii) DM2 rats had increased numbers of neurokinin B‐IR and dynorphin A‐IR cells compared to C animals; (2) ORX and ORX+T treatments unmasked deficits of the studied neurones in DM1 and DM2 but not in DIO animals; and (3) DIO, DM1 and DM2 rats had altered metabolic and hormonal profiles, in particular decreased levels of testosterone. We concluded that alterations in numbers of kisspeptin‐IR and neurokinin B‐IR neurones in the ARC and their response to ORX and ORX+T may account for disruptions of metabolic and reproductive functions in diabetic but not in obese rats.     

Visualisation of Kiss1 Neurone Distribution Using a Kiss1‐CRE Transgenic Mouse

Kisspeptin neuropeptides are encoded by the Kiss1 gene and play a critical role in the regulation of the mammalian reproductive axis. Kiss1 neurones are found in two locations in the rodent hypothalamus: one in the arcuate nucleus (ARC) and another in the RP3V region, which includes the anteroventral periventricular nucleus (AVPV). Detailed mapping of the fibre distribution of Kiss1 neurones will help with our understanding of the action of these neurones in other regions of the brain. We have generated a transgenic mouse in which the Kiss1 coding region is disrupted by a CRE‐GFP transgene so that expression of the CRE recombinase protein is driven from the Kiss1 promoter. As expected, mutant mice of both sexes are sterile with hypogonadotrophic hypogonadism and do not show the normal rise in luteinising hormone after gonadectomy. Mutant female mice do not develop mature Graafian follicles or form corpora lutea consistent with ovulatory failure. Mutant male mice have low blood testosterone levels and impaired spermatogenesis beyond the meiosis stage. Breeding Kiss‐CRE heterozygous mice with CRE‐activated tdTomato reporter mice allows fluorescence visualisation of Kiss1 neurones in brain slices. Approximately 80‐90% of tdTomato positive neurones in the ARC were co‐labelled with kisspeptin and expression of tdTomato in the AVPV region was sexually dimorphic, with higher expression in females than males. A small number of tdTomato‐labelled neurones was also found in other locations, including the lateral septum, the anterodorsal preoptic nucleus, the amygdala, the dorsomedial and ventromedial hypothalamic nuclei, the periaquaductal grey, and the mammillary nucleus. Three dimensional visualisation of Kiss1 neurones and fibres by CLARITY processing of whole brains showed an increase in ARC expression during puberty and higher numbers of Kiss1 neurones in the caudal region of the ARC compared to the rostral region. ARC Kiss1 neurones sent fibre projections to several hypothalamic regions, including rostrally to the periventricular and pre‐optic areas and to the lateral hypothalamus.     

Activation of Nesfatin‐1‐Containing Neurones in the Hypothalamus and Brainstem by Peripheral Administration of Anorectic Hormones and Suppression of Feeding via Central Nesfatin‐1 in Rats

Peripheral anorectic hormones, such as glucagon‐like peptide (GLP)‐1, cholecystokinin (CCK)‐8 and leptin, suppress food intake. The newly‐identified anorectic neuropeptide, nesfatin‐1, is synthesised in both peripheral tissues and the central nervous system, particularly by various nuclei in the hypothalamus and brainstem. In the present study, we examined the effects of i.p. administration of GLP‐1 and CCK‐8 and co‐administrations of GLP‐1 and leptin at subthreshold doses as confirmed by measurement of food intake, on nesfatin‐1‐immunoreactive (‐IR) neurones in the hypothalamus and brainstem of rats by Fos immunohistochemistry. Intraperitoneal administration of GLP‐1 (100 μg/kg) caused significant increases in the number of nesfatin‐1‐IR neurones expressing Fos‐immunoreactivity in the supraoptic nucleus (SON), the area postrema (AP) and the nucleus tractus solitarii (NTS) but not in the paraventricular nucleus (PVN), the arcuate nucleus (ARC) or the lateral hypothalamic area (LHA). On the other hand, i.p. administration of CCK‐8 (50 μg/kg) resulted in marked increases in the number of nesfatin‐1‐IR neurones expressing Fos‐immunoreactivity in the SON, PVN, AP and NTS but not in the ARC or LHA. No differences in the percentage of nesfatin‐1‐IR neurones expressing Fos‐immunoreactivity in the nuclei of the hypothalamus and brainstem were observed between rats treated with saline, GLP‐1 (33 μg/kg) or leptin. However, co‐administration of GLP‐1 (33 μg/kg) and leptin resulted in significant increases in the number of nesfatin‐1‐IR neurones expressing Fos‐immunoreactivity in the AP and the NTS. Furthermore, decreased food intake induced by GLP‐1, CCK‐8 and leptin was attenuated significantly by pretreatment with i.c.v. administration of antisense nesfatin‐1. These results indicate that nesfatin‐1‐expressing neurones in the brainstem may play an important role in sensing peripheral levels of GLP‐1 and leptin in addition to CCK‐8, and also suppress food intake in rats.     

Photoperiodic Co‐Regulation of Kisspeptin,Neurokinin B and Dynorphin in the Hypothalamus of a Seasonal Rodent

In many species, sexual activity varies on a seasonal basis. Kisspeptin (Kp), a hypothalamic neuropeptide acting as a strong activator of gonadotrophin‐releasing hormone neurones, plays a critical role in this adaptive process. Recent studies report that two other neuropeptides, namely neurokinin B (NKB) and dynorphin (DYN), are co‐expressed with Kp (and therefore termed KNDy neurones) in the arcuate nucleus and that these peptides are also considered to influence GnRH secretion. The present study aimed to establish whether hypothalamic NKB and DYN expression is photoperiod‐dependent in a seasonal rodent, the Syrian hamster, which exhibits robust seasonal rhythms in reproductive activity. The majority of Kp neurones in the arcuate nucleus co‐express NKB and DYN and the expression of all three peptides is decreased under a short (compared to long) photoperiod, leading to a 60% decrease in the number of KNDy neurones under photo‐inhibitory conditions. In seasonal rodents, RFamide‐related peptide (RFRP) neurones of the dorsomedial hypothalamus are also critical for seasonal reproduction. Interestingly, NKB and DYN are also expressed in the dorsomedial hypothalamus but do not co‐localise with RFRP‐immunoreactive neurones, and the expression of both NKB and DYN is higher under a short photoperiod, which is opposite to the short‐day inhibition of RFRP expression. In conclusion, the present study shows that NKB and DYN display different photoperiodic variations in the Syrian hamster hypothalamus. In the arcuate nucleus, NKB and DYN, together with Kp, are down‐regulated under a short photoperiod, whereas, in the dorsomedial hypothalamus, NKB and DYN are up‐regulated under a short photoperiod.     

The Roles of RFamide‐Related Peptide‐3 in Mammalian Reproductive Function and Behaviour

To maximise reproductive success, organisms restrict breeding to optimal times of the day or year, when internal physiology and external environmental conditions are suitable for the survival of both parent and offspring. To appropriately coordinate reproductive activity, internal and external standing is communicated to the hypothalamic‐pituitary‐gonadal axis via a coordinated balance of stimulatory and inhibitory neurochemical systems. The cumulative balance of these mediators ultimately drives the pattern of gonadotrophin‐releasing hormone secretion, a neurohormone that stimulates pituitary gonadotrophin secretion. Until 2000, a complementary inhibitor of pituitary gonadotrophin secretion had not been identified. At this time, a novel, avian hypothalamic peptide capable of inhibiting gonadotrophin secretion in cultured quail pituitary cells was uncovered and named gonadotrophin‐inhibitory hormone (GnIH). Subsequently, the presence and functional role for the mammalian orthologue of GnIH, RFamide‐related peptide, (RFRP‐3), was examined, confirming a conserved role for this peptide across several rodent species. To date, a similar distribution and functional role for RFRP‐3 have been observed across all mammals investigated, including humans. This overview summarises the role that RFRP‐3 plays in mammals and considers the implications and opportunities for further study with respect to reproductive physiology and the neural control of sexual behaviour and motivation.     

Green light inhibits GnRH‐I expression by stimulating the melatonin‐GnIH pathway in the chick brain

To study the mechanism by which monochromatic light affects gonadotrophin‐releasing hormone (GnRH) expression in chicken hypothalamus, a total of 192 newly‐hatched chicks were divided into intact, sham‐operated and pinealectomy groups and exposed to white (WL), red (RL), green (GL) and blue (BL) lights using a light‐emitting diode system for 2 weeks. In the GL intact group, the mRNA and protein levels of GnRH‐I in the hypothalamus, the mean cell area and mean cell optical density (OD) of GnRH‐I‐immunoreactive (‐ir) cells of the nucleus commissurae pallii were decreased by 13.2%‐34.5%, 5.7%‐39.1% and 9.9%‐17.3% compared to those in the chicks exposed to the WL, RL and BL, respectively. GL decreased these factors related to GnRH‐I expression and the effect of GL was not observed in pinealectomised birds. However, the mRNA and protein levels of hypothalamic gonadotrophin‐inhibitory hormone (GnIH) and GnIH receptor (GnIHR), the mean cell area and mean cell OD of the GnIH‐ir cells of the paraventricularis magnocellularis, and the plasma melatonin concentration in the chicks exposed to GL were increased by 18.6%‐49.2%, 21.1%‐60.0% and 8.6%‐30.6% compared to the WL, RL and BL intact groups, respectively. The plasma melatonin concentration showed a negative correlation with GnRH‐I protein and a positive correlation with GnIH and GnIHR proteins. Protein expression of both GnRH‐I and GnIHR showed a negative correlation in the hypothalamus. After pinealectomy, GnRH‐I expression increased, whereas plasma melatonin concentration, GnIH and GnIHR expression decreased, and there were no significant differences among the WL, RL, GL and BL groups. Double‐labelled immunofluorescence showed that GnIH axon terminals were near GnRH‐I neurones, some GnRH‐I neurones coexpressed with GnIHR and GnIH neurones coexpressed with melatonin receptor subtype quinone reductase 2. These results demonstrate that green light inhibits GnRH‐I expression by increasing melatonin secretion and stimulating melatonin receptor‐GnIH‐GnIH receptor pathway in the chick brain.