The KiNG of reproduction: kisspeptin/ nNOS interactions shaping hypothalamic GnRH release

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The KiNG of reproduction: kisspeptin/ nNOS interactions shaping hypothalamic GnRH release (2021)
Virginia Delli, Mauro S.B. Silva, Vincent Prévot, Konstantina Chachlaki


Abstract

Gonadotropin-releasing hormone (GnRH) is the master regulator of the hypothalamic-pituitary-gonadal (HPG) axis, and therefore of fertility and reproduction. The release pattern of GnRH by the hypothalamus includes both pulses and surges. However, despite a considerable body of evidence in support of a determinant role for kisspeptin, the mechanisms regulating GnRH pulse and surge remain a topic of debate. In this review, we challenge the view of kisspeptin as an absolute “monarch”, and instead, present the idea of a Kisspeptin-nNOS-GnRH or “KiNG” network that is responsible for generating the “GnRH pulse” and “GnRH surge”. In particular, the neuromodulator nitric oxide (NO) has opposite effects to kisspeptin on GnRH secretion in many respects, acting as the Yin to kisspeptin’s Yang and creating a dynamic system in which kisspeptin provides the “ON” signal, promoting GnRH release, while NO mediates the “OFF” signal, acting as a tonic brake on GnRH secretion. This interplay between an activator and an inhibitor, which is in turn fine-tuned by the gonadal steroid environment, thus leads to the generation of GnRH pulses and surges and is crucial for the proper development and function of the reproductive axis.




1 Introduction

ὁρμῶν (hormôn), “to set in motion, to excite, to stimulate”. Since its introduction by Ernest Starling in 1905 (Starling, 1905), this Greek word has been used to describe the chemical messengers used as a means of communication between different organs in an animal. When the term was introduced, practically nothing was known about the nature or the action of these messengers, which were believed to be produced by only a few specialized organs of the endocrine system (i.e. the glands). We have come a long way since then, with many conceptual changes occurring over the years, the most important of which is possibly the acknowledgment that the nervous and endocrine systems work together to transmit physiological information. The discipline of “Neuroendocrinology” was launched by Geoffrey Harris with his publication in 1955, which not only provided the first proof that the endocrine system could be controlled by the central nervous system (CNS), but also laid the foundations for the notion of the hypothalamic-pituitary-gonadal axis (HPG) (Harris, 1955). In the past two decades, we have come to acknowledge that the field of Neuroendocrinology extends far beyond the traditional neuron-endocrine pathways to encompass the production of hormones by non-traditional cells and tissues, with new and often non-catalytic roles in the regulation of an organism’s development, physiological homeostasis, reproductive capacity, and behavior.

The three components of the HPG axis – the hypothalamus, pituitary gland, and gonads (i.e. the testes and ovaries) – closely interact and depend on each other to allow the complex dialogue between the CNS and the periphery that is indispensable for reproductive function. The hypothalamus is undeniably the single most important brain region integrating vegetative and endocrine signals and controls diverse processes including cardiovascular function, sleep, metabolism, stress, thermoregulation, water and electrolyte balance, growth, and reproduction. Within the hypothalamus, specialized neuronal populations sense moment-to-moment changes in circulating levels of hormones and nutrients, to regulate the neuroendocrine function (Elmquist et al., 2005). Among these hypothalamic neuronal populations are the neurons producing gonadotropin-releasing hormone (GnRH), the main orchestrators of reproductive function, which act as integrators of various signals coming from both the central and the peripheral nervous system.

In spite of their crucial role, GnRH neurons are an extremely small population of cells across mammalian species, counting only 1,000−3,000 neurons in the rodent brain. The GnRH neuronal soma is primarily distributed in the preoptic hypothalamic area (POA) extending their nerve terminals to the pericapillary space of the median eminence (ME), located in the more mediobasal area of the hypothalamus (MBH), releasing the GnRH decapeptide in an episodic manner in both sexes (Sarkar et al., 1976; Moenter et al., 1991; Sarkar & Minami, 1995, Terasawa et al, 1999). Indeed, both immortalized GnRH-secreting GT1 cells and primary GnRH neurons release GnRH in a pulsatile manner, at species-specific intervals (for review see Terasawa, 2019). GnRH is then carried through the pituitary portal circulation for delivery to the anterior pituitary, where it stimulates gonadotropes to synthesize and secrete the gonadotropins, luteinizing hormone (LH), and follicle-stimulating hormone (FSH). These gonadotropins then act on the gonads (i.e. the testes and ovaries) to promote gonadal development and the secretion of sex steroids, which in turn provide positive or negative feedback back to the brain to regulate GnRH release (Prevot, 2015). The pulsatile pattern of GnRH secretion is reflected in the pulsatile secretion of LH during the negative feedback action of sex steroids, while GnRH surge, taking place during the positive feedback action of sex steroids, results in a crucial peak of LH release, triggering ovulation in females (Nett et 79 al., 1974).

Thus, the correct release of LH and FSH depends on the regulation of the frequency and timing of GnRH secretion by sex steroids as well as other neuronal and non-neuronal factors. In turn, the proper development of GnRH neurons, GnRH expression, and GnRH signaling are all essential for the normal functioning of the mammalian HPG axis (Cattanach 84 et al., 1977; Mason et al., 1986; Schwanzel-Fukuda et al., 1989). Justified by the authority of the GnRH system over the regulation of key physiological events, the network surrounding GnRH neurons, ensuring the controlled and timely regulation of their response is complex and multidimensional. To date, kisspeptin neurons have so far been considered the master excitatory driving force behind GnRH/LH release during both positive and negative feedback phases (Navarro et al., 2009; Pielecka-Fortuna et al., 2010; Clarkson et al., 2017).

*In this review, based primarily on research carried out in rodents, we challenge the views of kisspeptin neurons as the sole regulators or supreme “monarchs” of the GnRH network, controlling both GnRH pulse and surge generation. We also explore the implication of the much-overlooked population of neuronal nitric oxide synthase (nNOS) neurons, producing the diffusible messenger nitric oxide (NO), in the control of the GnRH system. Finally, we will discuss how the tripartite Kisspeptin, nNOS, GnRH (KiNG) network could be essential for the regulation of LH pulsatility and LH surge.




2 Milestones during the developmental maturation of the GnRH network in the mouse
2.1 Kisspeptin: the “Yang” of the GnRH network
2.2 NO: the “Yin” of the GnRH network


3 The involvement of ovarian steroid hormones in the GnRH pulse and the GnRH surge generators
3.1 The divergent role of estrogen on the AVPV and ARH kisspeptin populations
3.2 The impact of estrogen on nNOS enzymatic activity


4 The tripartite KiNG network: Could NO be the yin to kisspeptin’s yang?
4.1 The mechanism underlying the ability of nNOS cells to promote the synchronized activity of GnRH neurons
4.2 Interaction of nNOS and kisspeptin neurons as part of the “GnRH pulse” generator
4.3 Interaction of nNOS and kisspeptin neurons as part of the “GnRH surge” generator
4.4 Insights into the involvement of the KiNG interactions controlling reproduction in sheep and primates




5 Concluding remarks and perspectives

Overall, it appears at present that even though kisspeptin neurons undoubtedly play a key role in GnRH secretion, they are not the sole arbiters or “monarchs” of the activation and the function of the HPG axis and that NO, by acting as a brake on GnRH neurons, not only leads to their pulsatility but actually primes them for further stimulation, allowing kisspeptin to instigate the surge in neuropeptide release. Further studies are required to determine how NO and kisspeptin, by acting as the Yin and Yang of the GnRH axis, maintain reproductive homeostasis and the survival and propagation of the species.

 

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Figure 1. Development of GnRH neuronal network. Postnatal development in rodents can be divided into four stages, all marked by developmental events: the neonatal (P0-P7), infantile (P8-P21), juvenile (P22-P30), and peripubertal period, ending with the initiation of puberty. GnRH peptide is already secreted at birth and it increases sharply during the second week of life marking the first postnatal activation of the hypothalamic-pituitary-gonadal (HPG) axis, known as mini puberty. The high levels of circulating estrogens, along with the lack of negative feedback on the neonatal GnRH pulse generator allows for the increase in the FSH levels until the completion of the infantile stage. With the initiation of puberty, the positive feedback action of gonadal steroids eventually results in the GnRH/LH surge. nNOS and kisspeptin neurons also follow distinct maturational patterns. nNOS immunoreactivity (ir) in the preoptic area (POA), within the organum vasculosum laminae terminalis (OV) and the median preoptic nucleus (MePO), is already observed at birth, remaining constant during development. Contrary to the nNOS-ir, the catalytic activity of the nNOS enzyme, marked by the levels of the nNOS phosphorylation on the positive regulatory site serine-1412, significantly increases concomitantly with mini puberty. During adulthood, nNOS phosphorylation significantly increases in proestrus, concomitant with the preovulatory increase in estrogen levels. In the arcuate hypothalamic nucleus (ARH) nNOS-ir appears only after the peak of mini puberty, being visible by the end 4 of the infantile stage. Kisspeptin-ir is already present at birth in the ARH, reaching adult levels before the end of the infantile period. In the POA, within the region of the anteroventral periventricular nucleus (AVPV), the first evidence of kisspeptin-ir is found around mini puberty, with a massive increase in the following days, followed by a steady increase until the end of the juvenile period. Adapted from Messina et al., 2016.

 

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Figure 2. The NO production and downstream signaling cascades (Upper panel) The nNOS-PSD-95- NMDAR ternary complex. nNOS activation and the subsequent production of NO are dependent on the assembly of a ternary complex involving nNOS, the scaffolding protein post-synaptic density-95 (PSD-95), and the N-methyl-D aspartate (NMDA) receptor (NMDAR). The binding of glutamate to the NMDAR enables Ca2+ entry into the neuron activates the nNOS (physically interacting with the NR2B subunit of the NMDAR) via the creation of a Ca2+/calmodulin (CaM) complex. The activation of nNOS results in the production of NO by the enzymatic conversion of L-arginine (L-Arg) to L citrulline (L-Cit). In parallel, membrane-tethered nNOS is also subjected to post-transcriptional modifications, such as phosphorylation via protein kinase AKT at serine-1412, rapidly enhancing nNOS activity.

(Bottom panel) The NO–cGMP signaling pathway. Nitric oxide (NO) is a highly soluble and membrane-permeable neurotransmitter. Once NO is released it stimulates the production of the second messenger cyclic guanosine monophosphate (cGMP) by binding to soluble guanylate cyclase (sGC), inducing a conformational change that results in activation of the enzyme and the subsequent conversion of GTP to cGMP. cGMP interacts with several intracellular targets like cGMP-binding phosphodiesterase (PDE), responsible for catalyzing the hydrolytic destruction of the cGMP to produce 5’-GMP. Considering that the biological and physiological effects of NO are influenced by its ambient concentration, i.e. the balance between its rate of synthesis and its rate of inactivation, the activity of the downstream effectors sGC and PDE is crucial for the cellular function in response to nNOS activation.

 

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Figure 3. Involvement of the KiNG network in shaping GnRH pulsatile and surge release. a) The KiNG network is part of the “GnRH pulse” and “GnRH surge” generators. Within the preoptic area (left panel), kisspeptin neurons (blue) and nNOS neurons communicate with the scattered GnRH neuronal cell bodies (green) located in the organum vasculosum laminae terminalis (OV) and the median preoptic nucleus (MePO). (1) Kisspeptin neurons of the anteroventral periventricular nucleus (AVPV) can both directly excite GnRH neurons (2) and promote the phosphorylation of nNOS in the OV/MePO, inducing its activation and subsequently NO production. Thereupon, NO may diffuse through volume transmission in the vicinity of GnRH neuronal cell bodies (3) acting as a brake to GnRH neurons, which may uphold their synchronous activity at the time of the preovulatory GnRH surge. Within the arcuate nucleus (ARH) (right panel) kisspeptin and nNOS neurons are in close proximity with the GnRH distal dendrites and terminals (green). (1) ARH kisspeptin neurons stimulate GnRH secretion; (2) concomitantly kisspeptin release may promote the activation of the nNOS population in the ARH. Production of NO in the vicinity of GnRH terminals (3) may inhibit GnRH neurons, contributing to the termination of GnRH/LH pulse. Considering ARH kisspeptin neurons can interact with the AVPV kisspeptin population we could also imagine that ARH kisspeptin neurons might indirectly interact with OV/MePO nNOS cells via their AVPV counterparts, hence promoting the action of NO at the level of GnRH neuronal soma.

(b) Proposed mode of action of the nNOS/ kisspeptin microcircuit during GnRH pulse. During the gonadal steroid hormone-mediated negative feedback, (1) ARH kisspeptin neurons activate the GPR54-expressing GnRH neurons promoting GnRH release. Kisspeptin also (2) acts on the GPR54-expressing nNOS neurons, promoting the activation of the nNOS enzyme triggering NO production. In turn, (3) NO acts on the GnRH neurons as the “OFF” signal necessary for GnRH neurons to return to their baseline activity; thus, enabling them to respond to forthcoming stimulus. This dynamic crosstalk driving depolarizing and hyperpolarizing responses in GnRH neurons (1, 2, 3) may give the pulse-like shape of the GnRH/LH release. Therefore, NO may operate as an important messenger for the estrogen-mediated switch from negative to positive feedback according to the sum of responses from the interaction between NO and kisspeptinergic signaling.

 

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Figure 4. nNOS and kisspeptin as the Yin-Yang of the GnRH network. In a concept of dualism, kisspeptin and nNOS neurons integrate and coordinate distinct signals in order to regulate GnRH secretion, driving the “GnRH pulse” and “GnRH surge” generators. The actions of the kisspeptin and nNOS populations seem to be counterbalanced, hence nNOS and kisspeptin could be represented as the Yin-Yang of GnRH network. NO may be synthesized by nNOS neurons in response to a kisspeptinergic drive in these neurons. During the positive feedback, high levels of estrogens stimulate the AVPV kisspeptin population (light blue), promoting the estrogen-induced kisspeptin-mediated phosphorylation of the nNOS enzyme, inducing NO production by the nNOS cells located in the OV/MePO (light red). NO, transduced via volume transmission to the scattered GnRH population (green), restrains the activity of GnRH neurons, enabling their synchronization. With the activity of GnRH neurons being synchronous, the population of GnRH neurons becomes primed for their subsequent activation by kisspeptin, promoting the GnRH surge. During the negative feedback, ARH kisspeptin neurons (dark blue) stimulate GnRH release. Concomitantly kisspeptin also activates nNOS cells, resulting in the production and diffusion of NO that will provide the “OFF” signal for the GnRH neurons simultaneously, enabling them to return to baseline and thus restore their ability to respond to the next stimulatory kisspeptin signal. ARH kisspeptin neurons (dark blue) could interact (1) directly with ARH nNOS neurons (dark red), in turn acting upon GnRH nerve terminals, or (2) indirectly with POA nNOS neurons (light red) via the AVPV kisspeptin population (light blue), that would in turn act upon neighboring GnRH neuronal soma.