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.     

Pituitary Gonadotrophic Hormone Synthesis,Secretion, Subunit Gene Expression and Cell Structure in Normal and Follicle‐Stimulating Hormone β Knockout,Follicle‐Stimulating Hormone Receptor Knockout,Luteinising Hormone Receptor Knockout,Hypogonadal and Ovariectomised Female Mice

To investigate the relationship between gonadotroph function and ultrastructure, we have compared, in parallel in female mice, the effects of several different mutations that perturb the hypothalamic‐pituitary‐gonadal axis. Specifically, serum and pituitary gonadotrophin concentrations, gonadotrophin gene expression, gonadotroph structure and number were measured. Follicle‐stimulating hormone β knockout (FSHβKO), follicle‐stimulating hormone receptor knockout (FSHRKO), luteinising hormone receptor knockout (LuRKO), hypogonadal (hpg) and ovariectomised mice were compared with control wild‐type or heterozygote female mice. Serum levels of LH were elevated in FSHβKO and FSHRKO compared to heterozygote females, reflecting the likely decreased oestrogen production in KO females, as demonstrated by the threadlike uteri and acyclicity. As expected, there was no detectable FSH in the serum or pituitary and an absence of expression of the FSHβ subunit gene in FSHβKO mice. However, there was a significant increase in expression of the FSHβ and LHβ subunit genes in FSHRKO female mice. The morphology of FSHβKO and FSHRKO gonadotrophs was not significantly different from the control, except that secretory granules in FSHRKO gonadotrophs were larger in diameter. In LuRKO and ovariectomised mice, stimulation of LHβ and FSHβ mRNA, as well as serum protein concentrations, were reflected in subcellular changes in gonadotroph morphology, including more dilated rough endoplasmic reticula and fewer, larger secretory granules. In the gonadotophin‐releasing hormone deficient hpg mouse, gonadotrophin mRNA and protein levels were significantly lower than in control mice and gonadotrophs were correspondingly smaller with less abundant endoplasmic reticula and reduced numbers of secretory granules. In summary, major differences in pituitary content and serum concentrations of the gonadotrophins LH and FSH were found between control and mutant female mice. These changes were associated with changes in expression of the gonadotrophin subunit genes and were reflected in the cellular structure and secretory granule appearance within the gonadotroph cells.     

Neuronal Gonadotrophin‐Releasing Hormone (GnRH) and Astrocytic Gonadotrophin Inhibitory Hormone (GnIH) Immunoreactivity in the Adult Rat Hippocampus

Gonadotrophin‐releasing hormone (GnRH) and gonadotrophin inhibitory hormone (GnIH) are neuropeptides secreted by the hypothalamus that regulate reproduction. GnRH receptors are not only present in the anterior pituitary, but also are abundantly expressed in the hippocampus of rats, suggesting that GnRH regulates hippocampal function. GnIH inhibits pituitary gonadotrophin secretion and is also expressed in the hippocampus of a songbird; its role outside of the reproductive axis is not well established. In the present study, we employed immunohistochemistry to examine three forms of GnRH [mammalian GnRH‐I (mGnRH‐I), chicken GnRH‐II (cGnRH‐II) and lamprey GnRH‐III (lGnRH‐III)] and GnIH in the adult rat hippocampus. No mGnRH‐I and cGnRH‐II+ cell bodies were present in the hippocampus. Sparse mGnRH‐I and cGnRH‐II+ fibres were present within the CA1 and CA3 fields of the hippocampus, along the hippocampal fissure, and within the hilus of the dentate gyrus. No lGnRH‐III was present in the rodent hippocampus. GnIH‐immunoreactivity was present in the hippocampus in cell bodies that resembled astrocytes. Males had more GnIH+ cells in the hilus of the dentate gyrus than females. To confirm the GnIH+ cell body phenotype, we performed double‐label immunofluorescence against GnIH, glial fibrillary acidic protein (GFAP) and NeuN. Immunofluorescence revealed that all GnIH+ cell bodies in the hippocampus also contained GFAP, a marker of astrocytes. Taken together, these data suggest that GnRH does not reach GnRH receptors in the rat hippocampus primarily via synaptic release. By contrast, GnIH might be synthesised locally in the rat hippocampus by astrocytes. These data shed light on the sites of action and possible functions of GnRH and GnIH outside of the hypothalamic‐pituitary‐gonadal axis.     

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.     

Effects of Chronic NMDA‐NR2b Inhibition in the Median Eminence of the Reproductive Senescent Female Rat

Gonadotrophin‐releasing hormone (GnRH) neurones of the hypothalamic‐pituitary‐gonadal (HPG) axis drive reproductive function and undergo age‐related decreases in activation during the transition to reproductive senescence. Decreased GnRH secretion from the median eminence (ME) partially arises from attenuated glutamatergic signalling via the NMDA receptor (NMDAR) and may be a result of changing NMDAR stoichiometry to favour NR2b over NR2a subunit expression with ageing. We have previously shown that the systemic inhibition of NR2b‐containing receptors with ifenprodil, an NR2b‐specific antagonist, stimulates parameters of luteinising hormone (used as a proxy for GnRH) release in both young and middle‐aged females. In the present study, we chronically administered ifenprodil, an NR2b‐specific antagonist, at the site of GnRH terminals in the ME or at GnRH perikarya in the preoptic area, in reproductively senescent middle‐aged female rats, aiming to determine whether NR2b antagonism could restore aspects of reproductive functionality. Effects on oestrous cyclicity, serum hormones, and protein expression of GnRH, NR2b and phosphorylated NR2b (Tyr‐1472) in the ME were measured. Chronic ifenprodil treatment in the ME (but not the preoptic area) altered oestrous cyclicity by increasing the percentage of days spent in pro‐oestrus. This was accompanied by increased GnRH fluorescence intensity in the external ME zone and a greater proportion of GnRH terminals that co‐labelled with pNR2b with treatment. We also observed changes in the relationships between protein immunofluorescence, serum hormone levels and other aspects of reproductive physiology in acyclic females, as revealed by bionetwork analysis. Together, these data support the hypothesis that NMDAR‐NR2b expression and phosphorylation state play a role in reproductive senescence and highlight the ME as a major player in reproductive ageing.     

Lack of Pulse and Surge Modes and Glutamatergic Stimulation of Luteinising Hormone Release in Kiss1 Knockout Rats

Kisspeptin, encoded by the Kiss1 gene, has attracted attention as a key candidate neuropeptide in controlling puberty and reproduction via regulation of gonadotrophin‐releasing hormone (GnRH) secretion in mammals. Pioneer studies with Kiss1 or its cognate receptor Gpr54 knockout (KO) mice showed the indispensable role of kisspeptin‐GPR54 signalling in the control of animal reproduction, although detailed analyses of gonadotrophin secretion, especially pulsatile and surge‐mode of luteinising hormone (LH) secretion, were limited. Thus, in the present study, we have generated Kiss1 KO rats aiming to evaluate a key role of kisspeptin in governing reproduction via pulse and surge modes of GnRH/LH secretion. Kiss1 KO male and female rats showed a complete suppression of pulsatile LH secretion, which is responsible for folliculogenesis and spermatogenesis, and an absence of puberty and atrophic gonads. Kiss1 KO female rats showed no spontaneous LH/follicle‐stimulating hormone surge and an oestrogen‐induced LH surge, suggesting that the GnRH surge generation system, which is responsible for ovulation, does not function without kisspeptin. Furthermore, challenge of major stimulatory neurotransmitters, such as monosodium glutamate, NMDA and norepinephrine, failed to stimulate LH secretion in Kiss1 KO rats, albeit they stimulated LH release in wild‐type controls. Taken together, the results of the present study confirm that kisspeptin plays an indispensable role in generating two modes (pulse and surge) of GnRH/gonadotrophin secretion to regulate puberty onset and normal reproductive performance. In addition, the present study suggests that kisspeptin neurones play a critical role as a hub integrating major stimulatory neural inputs to GnRH neurones, using newly established Kiss1 KO rats, which serve as a useful model for detailed analysis of hormonal profiles.     

Evidence of involvement of neurone‐glia/neurone‐neurone communications via gap junctions in synchronised activity of KNDy neurones

Pulsatile secretion of gonadotrophin‐releasing hormone (GnRH)/luteinising hormone is indispensable for the onset of puberty and reproductive activities at adulthood in mammalian species. A cohort of neurones expressing three neuropeptides, namely kisspeptin, encoded by the Kiss1 gene, neurokinin B (NKB) and dynorphin A, localised in the hypothalamic arcuate nucleus (ARC), so‐called KNDy neurones, comprises a putative intrinsic source of the GnRH pulse generator. Synchronous activity among KNDy neurones is considered to be required for pulsatile GnRH secretion. It has been reported that gap junctions play a key role in synchronising electrical activity in the central nervous system. Thus, we hypothesised that gap junctions are involved in the synchronised activities of KNDy neurones, which is induced by NKB‐NK3R signalling. We determined the role of NKB‐NK3R signalling in Ca²⁺ oscillation (an indicator of neuronal activities) of KNDy neurones and its synchronisation mechanism among KNDy neurones. Senktide, a selective agonist for NK3R, increased the frequency of Ca²⁺ oscillations in cultured Kiss1‐GFP cells collected from the mediobasal hypothalamus of the foetal Kiss1‐green fluorescent protein (GFP) mice. The senktide‐induced Ca²⁺ oscillations were synchronised in the Kiss1‐GFP and neighbouring glial cells. Confocal microscopy analysis of these cells, which have shown synchronised Ca²⁺ oscillations, revealed close contacts between Kiss1‐GFP cells, as well as between Kiss1‐GFP cells and glial cells. Dye coupling experiments suggest cell‐to‐cell communication through gap junctions between Kiss1‐GFP cells and neighbouring glial cells. Connexin‐26 and ‐37 mRNA were found in isolated ARC Kiss1 cells taken from adult female Kiss1‐GFP transgenic mice. Furthermore, 18β‐glycyrrhetinic acids and mefloquine, which are gap junction inhibitors, attenuated senktide‐induced Ca²⁺ oscillations in Kiss1‐GFP cells. Taken together, these results suggest that NKB‐NK3R signalling enhances synchronised activities among neighbouring KNDy neurones, and that both neurone‐neurone and neurone‐glia communications via gap junctions possibly contribute to synchronised activities among KNDy neurones.     

Seasonal Effect of Gonadotrophin Inhibitory Hormone on Gonadotrophin‐Releasing Hormone‐induced Gonadotroph Functions in the Goldfish Pituitary

We have shown that native goldfish gonadotrophin inhibitory hormone (gGnIH) differentially regulates luteinsing hormone (LH)‐β and follicle‐stimulating hormone (FSH)‐β expression. To further understand the functions of gGnIH, we examined its interactions with two native goldfish gonadotrophin‐releasing hormones, salmon gonadotrophin‐releasing hormone (sGnRH) and chicken (c)GnRH‐II in vivo and in vitro. Intraperitoneal injections of gGnIH alone reduced serum LH levels in fish in early and mid gonadal recrudescence; this inhibition was also seen in fish co‐injected with either sGnRH or cGnRH‐II during early recrudescence. Injection of gGnIH alone elevated pituitary LH‐β and FSH‐β mRNA levels at early and mid recrudescence, and FSH‐β mRNA at late recrudescence. Co‐injection of gGnIH attenuated the stimulatory influences of sGnRH on LH‐β in early recrudescence, and LH‐β and FSH‐β mRNA levels in mid and late recrudescence, as well as the cGnRH‐II‐elicited increase in LH‐β, but not FSH‐β, mRNA expression at mid and late recrudescence. sGnRH and cGnRH‐II injection increased pituitary gGnIH‐R mRNA expression in mid and late recrudescence but gGnIH reduced gGnIH‐R mRNA levels in late recrudescence. gGnIH did not affect basal LH release from perifused pituitary cells and continual exposure to gGnIH did not alter the LH responses to acute applications of GnRH. However, a short 5‐min GnIH treatment in the middle of a 60‐min GnRH perifusion selectively reduced the cGnRH‐II‐induced release of LH. These novel results indicate that, in goldfish, gGnIH and GnRH modulate pituitary GnIH‐R expression and gGnIH differentially affects sGnRH and cGnRH‐II regulation of LH secretion and gonadotrophin subunit mRNA levels. Furthermore, these actions are manifested in a reproductive stage‐dependent manner.     

Modulation of Gonadotrophin-Releasing Hormone Secretion by an Endogenous Circadian Clock

The mechanisms mediating positive feedback effects of oestradiol on pre-ovulatory gonadotrophin releasing-hormone (GnRH) surge generation in female mammals, although well-explored, are still incompletely understood. In addition to binding to and signalling through classical nuclear receptor-mediated pathways in afferent hypothalamic neurones, recent evidence suggests that ovarian steroids may use membrane-bound receptors or nonclassical signalling pathways to directly influence cell function leading to the generation of GnRH surge secretion. We review recent investigations into the role of the endogenous molecular circadian clock on modulation of GnRH gene expression and neuropeptide secretion, and will explore potential molecular mechanisms by which ovarian steroids may directly induce secretory changes at the level of the GnRH neurone, examining closely whether circadian clock gene oscillations may be involved.     

Differential Expression of RFamide‐Related Peptide,a Mammalian Gonadotrophin‐Inhibitory Hormone Orthologue,and Kisspeptin in the Hypothalamus of Abadeh Ecotype Does During Breeding and Anoestrous Seasons

Gonadotrophin‐inhibitory hormone (GnIH) is a novel hypothalamic neuropeptide that was discovered in birds as an inhibitory factor for gonadotrophin release. RFamide‐related peptide (RFRP) is a mammalian GnIH orthologue that inhibits gonadotrophin synthesis and release in mammals through actions on gonadotrophin‐releasing hormone (GnRH) neurones and gonadotrophs, mediated via the GnIH receptor (GnIH‐R), GPR147. On the other hand, hypothalamic kisspeptin provokes the release of GnRH from the hypothalamus. The present study aimed to compare the expression of RFRP in the dorsomedial hypothalamus and paraventricular nucleus (DMH/PVN) and that of kisspeptin in the arcuate nucleus (ARC) of the female goat hypothalamus during anoestrous and breeding seasons. Mature female Abadeh does were used during anoestrus, as well as the follicular and luteal phases of the cycle. The number of RFRP‐immunoreactive (‐IR) neurones in the follicular phase was lower than in the luteal and anoestrous stages. Irrespective of the ovarian stage, the number of RFRP‐IR neurones in the rostral and middle regions of the DMH/PVN was higher than in the caudal region. By contrast, the number of kisspeptin‐IR neurones in the follicular stage was greater than in the luteal stage and during the anoestrous stage. Irrespective of the stage of the ovarian cycle, the number of kisspeptin‐IR neurones in the caudal region of the ARC was greater than in the middle and rostral regions. In conclusion, RFRP‐IR cells were more abundant in the rostral region of the DMH/PVN nuclei of the hypothalamus, with a greater number being found during the luteal and anoestrous stages compared to the follicular stage. On the other hand, kisspeptin‐IR neurones were more abundant in the caudal part of the ARC, with a greater number recorded in the follicular stage compared to the luteal and anoestrous stages.     

Role of Pituitary Adenylate Cyclase‐Activating Polypeptide in Modulating Hypothalamus‐Pituitary Neuroendocrine Functions in Mouse Cell Models

Pituitary adenylate cyclase‐activating polypeptide (PACAP) was originally identified as a hypothalamic activator of cyclic adenosine monophosphate production in pituitary cells. PACAP and its receptor are expressed not only in the central nervous system, but also in peripheral organs, and function to stimulate pituitary hormone synthesis and secretion as both a hypothalamic‐pituitary‐releasing factor and an autocrine‐paracrine factor within the pituitary. PACAP stimulates the expression of the gonadotrophin α, luteinising hormone (LH) β and follicle‐stimulating hormone (FSH) β subunits, as well as the gonadotrophin‐releasing hormone (GnRH) receptor and its own PACAP type I receptor (PAC1R) in gonadotrophin‐secreting pituitary cells. In turn, GnRH, which is known to be a crucial component of gonadotrophin secretion, stimulates the expression of PACAP and PAC1R in gonadotrophs. In addition, PAC1R and PACAP modulate the functions of GnRH‐producing neurones in the hypothalamus. This review summarises the current understanding of the possible roles of PACAP and PAC1R in modulating hypothalamus and pituitary neuroendocrine cells in the mouse models.     

Intracellular calcium and calmodulin link brain‐derived neurotrophic factor to p70S6 kinase phosphorylation and dendritic protein synthesis

The mammalian target of rapamycin (mTOR)/p70S6 kinase (S6K) pathway plays an important role in brain‐derived neurotrophic factor (BDNF)‐mediated protein synthesis and neuroplasticity. Although many aspects of neuronal function are regulated by intracellular calcium ([Ca²⁺]_i) and calmodulin (CaM), their functions in BDNF‐induced phosphorylation of p70S6K and protein synthesis are largely unknown. Here, we report that BDNF, via TrkB‐dependent activation of mTOR, induces sustained phosphorylation of p70S6K at Thr389 and Thr421/Ser424. BDNF‐induced phosphorylation at Thr389 was dependent on PI3 kinase but independent of ERK‐MAPK. The previously identified MAPK phosphorylation site at Thr421/Ser424 required both PI3K and MAPK in BDNF‐stimulated neurons. Furthermore, we found that the reduction in [Ca²⁺]_i, but not extracellular calcium, blocked the BDNF‐induced phosphorylation of p70S6K at both sites. Inhibition of CaM by W13 also blocked p70S6K phosphorylation. In correlation, W13 inhibited BDNF‐induced local dendritic protein synthesis. Interestingly, sustained elevation of [Ca²⁺]_i by membrane depolarization antagonized the BDNF‐induced p70S6K phosphorylation. Finally, the BDNF‐induced p70S6K phosphorylation did not require the increase of calcium level through either extracellular influx or PLC‐mediated intracellular calcium release. Collectively, these results indicate that the basal level of intracellular calcium gates BDNF‐induced activation of p70S6K and protein synthesis through CaM. © 2009 Wiley‐Liss, Inc.     

Epigenomic control of gonadotrophin‐releasing hormone neurone development and hypogonadotrophic hypogonadism

Mammalian reproductive success depends on gonadotrophin‐releasing hormone (GnRH) neurones to stimulate gonadotrophin secretion from the anterior pituitary and activate gonadal steroidogenesis and gametogenesis. Genetic screening studies in patients diagnosed with Kallmann syndrome (KS), a congenital form of hypogonadotrophic hypogonadism (CHH), identified several causal mutations, including those in the fibroblast growth factor (FGF) system. This signalling pathway regulates neuroendocrine progenitor cell proliferation, fate specification and cell survival. Indeed, the GnRH neurone system was absent or abrogated in transgenic mice with reduced (ie, hypomorphic) Fgf8 and/or Fgf receptor (Fgfr) 1 expression, respectively. Moreover, we found that GnRH neurones were absent in the embryonic olfactory placode of Fgf8 hypomorphic mice, the putative birthplace of GnRH neurones. These observations, together with those made in human KS/CHH patients, indicate that the FGF8/FGFR1 signalling system is a requirement for the ontogenesis of the GnRH neuronal system and function. In this review, we discuss how epigenetic factors control the expression of genes such as Fgf8 that are known to be critical for GnRH neurone ontogenesis, fate specification, and the pathogenesis of KS/CHH.     

Leptin Responsive and GABAergic Projections to the Rostral Preoptic Area in Mice

The adipocyte‐derived hormone leptin plays a critical role in the control of reproduction via signalling in hypothalamic neurones. The drivers of the hypothalamic‐pituitary‐gonadal axis, the gonadotrophin‐releasing hormone (GnRH) neurones, do not have the receptors for leptin. Therefore, intermediate leptin responsive neurones must provide leptin‐to‐GnRH signalling. We investigated the populations of leptin responsive neurones that provide input to the rostral preoptic area (rPOA) where GnRH cell bodies reside. Fluorescent retrograde tracer beads (RetroBeads; Lumafluor Inc., Naples, FL, USA) were injected into the rPOA of transgenic leptin receptor enhanced green fluorescent protein (Lepr‐eGFP) reporter mice. Uptake of the RetroBeads by Lepr‐eGFP neurones was assessed throughout the hypothalamus. RetroBead uptake was most evident in the medial arcuate nucleus (ARC), the dorsomedial nucleus (DMN) and the ventral premammillary nucleus (PMV) of the hypothalamus. The uptake of RetroBeads specifically by Lepr‐eGFP neurones was highest in the medial ARC (18% of tracer‐labelled neurones Lepr‐eGFP‐positive). Because neurones that are both leptin responsive and GABAergic play a critical role in the regulation of fertility by leptin, we next focussed on the location of these populations. To address whether GABAergic neurones in leptin‐responsive hypothalamic regions project to the rPOA, the experiment was repeated in GABA neurone reporter mice (Vgat‐tdTomato). Between 10% and 45% of RetroBead‐labelled neurones in the ARC were GABAergic, whereas uptake of tracer by GABAergic neurones in the DMN and PMV was very low (< 5%). These results show that both leptin responsive and GABAergic neurones from the ARC project to the region of the GnRH cell bodies. Our findings suggest that LEPR‐expressing GABA neurones from the ARC may be mediators of leptin‐to‐GnRH signalling.     

Optogenetic stimulation of kisspeptin neurones within the posterodorsal medial amygdala increases luteinising hormone pulse frequency in female mice

Kisspeptin within the arcuate nucleus of the hypothalamus is a critical neuropeptide in the regulation of reproduction. Together with neurokinin B and dynorphin A, arcuate kisspeptin provides the oscillatory activity that drives the pulsatile secretion of gonadotrophin‐releasing hormone (GnRH), and therefore luteinising hormone (LH) pulses, and is considered to be a central component of the GnRH pulse generator. It is well established that the amygdala also exerts an influence over gonadotrophic hormone secretion and reproductive physiology. The discovery of kisspeptin and its receptor within the posterodorsal medial amygdala (MePD) and our recent finding showing that intra‐MePD administration of kisspeptin or a kisspeptin receptor antagonist results in increased LH secretion and decreased LH pulse frequency, respectively, suggests an important role for amygdala kisspeptin signalling in the regulation of the GnRH pulse generator. To further investigate the function of amygdala kisspeptin, the present study used an optogenetic approach to selectively stimulate MePD kisspeptin neurones and examine the effect on pulsatile LH secretion. MePD kisspeptin neurones in conscious Kiss1‐Cre mice were virally infected to express the channelrhodopsin 2 protein and selectively stimulated by light via a chronically implanted fibre optic cannula. Continuous stimulation using 5 Hz resulted in an increased LH pulse frequency, which was not observed at the lower stimulation frequencies of 0.5 and 2 Hz. In wild‐type animals, continuous stimulation at 5 Hz did not affect LH pulse frequency. These results demonstrate that selective activation of MePD Kiss1 neurones can modulate hypothalamic GnRH pulse generator frequency.