Abstract
Inactivating mutations in the melanocortin 4 receptor (MC4R) gene cause monogenic obesity. Interestingly, female patients also display various degrees of reproductive disorders, in line with the subfertile phenotype of MC4RKO female mice. However, the cellular mechanisms by which MC4R regulates reproduction are unknown. Kiss1 neurons directly stimulate gonadotropin-releasing hormone (GnRH) release through two distinct populations; the Kiss1ARH neurons, controlling GnRH pulses, and the sexually dimorphic Kiss1AVPV/PeN neurons controlling the preovulatory LH surge. Here, we show that Mc4r expressed in Kiss1 neurons is required for fertility in females. In vivo, deletion of Mc4r from Kiss1 neurons in female mice replicates the reproductive impairments of MC4RKO mice without inducing obesity. Conversely, reinsertion of Mc4r in Kiss1 neurons of MC4R null mice restores estrous cyclicity and LH pulsatility without reducing their obese phenotype. In vitro, we dissect the specific action of MC4R on Kiss1ARH vs Kiss1AVPV/PeN neurons and show that MC4R activation excites Kiss1ARH neurons through direct synaptic actions. In contrast, Kiss1AVPV/PeN neurons are normally inhibited by MC4R activation except under elevated estradiol levels, thus facilitating the activation of Kiss1AVPV/PeN neurons to induce the LH surge driving ovulation in females. Our findings demonstrate that POMCARH neurons acting through MC4R, directly regulate reproductive function in females by stimulating the “pulse generator” activity of Kiss1ARH neurons and restricting the activation of Kiss1AVPV/PeN neurons to the time of the estradiol-dependent LH surge, and thus unveil a novel pathway of the metabolic regulation of fertility by the melanocortin system.
Introduction
Obesity rates have skyrocketed in Western societies in the last decades, resulting in an alarming rise in comorbidities that place a significant burden on healthcare systems. The increase in obesity correlates with a decrease in fertility rates, leading to conception challenges that are experienced by approximately 15% of couples in the United States currently 1.
The melanocortin 4 receptor (MC4R) binds α-melanocyte stimulating hormone (αMSH), an agonist product of the pro-opiomelanocortin (Pomc) gene, and the inverse agonist of the agouti-related peptide (AgRP) to regulate food intake and energy expenditure 2,3. While the role of MC4R on food intake is largely mediated by neurons located in the paraventricular nucleus of the hypothalamus (PVN) 4, its expression in the brain is widespread 5 with the specific function of the different MC4R-expressing neurons in areas beyond the PVN remaining to be fully explored. Inactivating mutations in MC4R are a leading cause of monogenic obesity in humans and mice 6. Scant evidence in humans shows an association between MC4R mutations and higher incidence of hypogonadotropic hypogonadism (HH) 7, alterations in the timing of puberty onset 8, and polycystic ovary syndrome (PCOS) 9; however, conflicting reports exist 6. Therefore, the role of MC4R signaling in reproductive function in humans remains controversial despite the clear association found in mice. Supporting this role of MC4R, Mc4r null mice display an array of reproductive abnormalities that largely affects females, characterized by irregular estrous cycles, disrupted luteinizing hormone (LH) secretion, reduced corpora lutea and reduced fertility 10–12. Further evidence from mice demonstrates that MC4R agonists robustly increase LH release in a kisspeptin-dependent manner 13.
Kisspeptin is the most potent gonadotropin releasing hormone (GnRH) secretagogue known to date and it is mainly produced in two distinct neuronal populations. Kiss1 neurons of the arcuate nucleus of the hypothalamus (Kiss1ARH), present in both sexes, control the pulsatile (tonic) release of GnRH, and sex steroids attenuate their release of kisspeptin. Kiss1 neurons of the anteroventral periventricular continuum area (Kiss1AVPV/PeN), are predominantly present in females, and are responsible for generating the preovulatory GnRH/LH surge essential for ovulation 14. Despite these critical roles of both populations of Kiss1 neurons for reproduction, the underlying mechanisms that determine how each Kiss1 population responds differently to sex steroids to regulate the GnRH tonic vs surge release remains unresolved.
In rodents, compelling evidence indicates a close interaction between Kiss1 neurons and the melanocortin system: 1) fibers from POMC neurons in the arcuate nucleus (POMCARH) project to and juxtapose Kiss1ARH neurons 13; 2) the melanocortin signaling through MC4R contributes to the permissive role of leptin on puberty onset 13,15,16; and 3) MC4R expression on both Kiss1ARH 17–19 and Kiss1AVPV/PeN17,20. Altogether, this evidence suggests a clear role for MC4R in Kiss1 neurons, in the control of reproductive maturation and fertility.
In this study, we investigated the contribution of MC4R signaling versus obesity per se in the etiology of the reproductive impairments observed in Mc4r null mice, which could explain similar impairments observed in humans. Using genetic mouse models with specific deletion or reinsertion of Mc4r in Kiss1 neurons, we show that MC4R action in Kiss1 neurons is necessary for normal reproductive function in female mice. Whole cell voltage clamp recordings evidenced an excitatory action of MC4R on Kiss1ARH neurons and an estradiol-dependent inhibitory action on Kiss1AVPV/PeN neurons, with important implications for the timing of the preovulatory LH surge.
Results
Mc4r within Kiss1 neurons determines the timing of puberty onset in females
The expression of Mc4r within Kiss1ARH and Kiss1AVPV/PeN neurons has already been described elsewhere 17–20, suggesting a role for MC4R in the regulation of fertility. To further investigate the specific role of MC4R in Kiss1 neurons, we generated a Kiss1-specific MC4R knockout mouse model (Kiss1-MC4RKO). The specific deletion of Mc4r from Kiss1 neurons, as well as the absence of global recombination, were confirmed through RNAscope. While Kiss1 neurons of Kiss1-MC4RKO mice lack Mc4r transcript compared to their control littermates (Figure S1A), Mc4r was detectable in the PVN of all mice, which is a major site of Mc4r expression in the brain in the regulation of metabolism, therefore supporting the specific deletion of Mc4r only within Kiss1 neurons (Figure S1B).
Puberty onset was assessed daily from weaning age through the monitoring of vaginal opening (VO) and first estrus (FE). Kiss1-MC4RKO females showed a significant advancement in the age of VO (P=0.0150, Kiss1-MC4RKO: 24.67± 0.3978 vs controls: 26.32±0.5301) and FE (P=0.0341, Kiss1-MC4RKO: 32.63±1.489 vs controls: 37.84±1.903) compared to their littermate controls (Figure 1A, B). Body weight of Kiss1-MC4RKO females at the age of puberty onset was similar between groups (P=0.2596, Kiss1-MC4RKO: 12.41±0.3041 vs controls: 12.89±0.2631) (Figure 1C). These data suggest that melanocortin signaling on Kiss1 neurons participates in the timing of puberty onset in females. Since the role of the melanocortin system on puberty onset is largely unexplored, we evaluated the expression profile of the main components of this system in the hypothalami of WT female mice at postnatal days (PND) 10, 15, 22 and 30. Interestingly, expressions of Agrp, Mc3r and Mc4r were significantly lower at the time of puberty onset (PND30) compared to earlier developmental ages (Figure 1D). This suggests that a decrease in the hypothalamic melanocortin tone drives puberty onset, in line with the advancement in the age of VO and FE observed in Kiss1-MC4RKO female mice (Figure 1A, B).
MC4R in Kiss1 neurons is required for female reproduction
Because Kiss1-MC4RKO females showed altered puberty onset, we further investigated their reproductive phenotype. Interestingly, Kiss1-MC4RKO female mice displayed normal BW throughout the time of the study (up to PND150) (Figure 2A); however, they presented with irregular estrous cycles with predominantly more time spent in diestrus (P=0.0001) and less time spent in estrus (P<0.0001) than their control littermates (Figure 2B, C). The assessment of the pulsatile release of LH every 10 min over 180 min revealed no change in the total number of pulses between groups but a significant increase in basal LH release (P=0.0368) in Kiss1-MC4RKO female mice (0.426±0.036) compared to controls (0.339±0.026) (Figure 2D-H). The analysis of the gene expression of the “KNDy” systems in the ARH, which control the GnRH pulse generator 14, revealed normal expression levels of Kiss1, Tac2 and Tacr3, but significantly lower expression of Pdyn (P=0.0067, Kiss1-MC4RKO: 0.781±0.0384 vs controls: 1.000±0.0190) (Figure 2I-L). The conserved expression of Kiss1, Tac2 and Tacr3 correlates with the preserved LH pulse frequency and amplitude in Kiss1-MC4RKO mice, while the lower inhibitory tone of dynorphin (Figure 2I) correlates with the higher basal LH levels (Figure 2E). To assess the contribution of MC4R signaling in Kiss1 neurons to the induction of ovulation through the preovulatory LH surge, Kiss1-MC4RKO females and control littermates were submitted to an LH surge induction protocol that showed the LH surge was significantly blunted in the Kiss1-MC4RKO females (P=0.0091), while the protocol clearly evoked the expected afternoon rise of LH in control mice (Figure 2M). In line with these findings, the ovaries of Kiss1-MC4RKO females displayed fewer corpora lutea, markers of recent ovulation (P=0.0054, Kiss1-MC4RKO: 0.800±0.374 vs controls: 2.80±0.374), in addition to increased cystic follicles (P=0.0337, Kiss1-MC4RKO: 1.60±0.400 vs controls: 0.400±0.244) (Figure 2N-P), which correlate with decreased fertility as observed by the extended time to deliver pups (i.e. longer time to get pregnant) (P=0.0030, Kiss1-MC4RKO: 30.30±4.600 vs controls: 20.88±0.2266), and fewer pups per litter (P=0.0095, Kiss1-MC4RKO: 6.667±0.5528 vs controls: 8.444±0.242) (Figure 2S, T).
The increase in serum LH levels and decreased ovulation observed in the Kiss1-MC4RKO females is reminiscent of polycystic ovary syndrome (PCOS) mouse models 21,22. Thus, we investigated whether Kiss1-MC4RKO females display a PCOS-like phenotype. We analyzed circulating levels of testosterone (T) and anti-müllerian hormone (AMH), which are frequently elevated in PCOS models 23. The Kiss1-MC4RKO females expressed normal T and AMH levels compared to control mice in diestrus (Figure 2Q, R). Thus, we can exclude a PCOS-like reproductive phenotype mediated by the lack of melanocortin signaling on Kiss1 neurons.
Re-insertion of MC4R in Kiss1 neurons of MC4RKO mice improves reproductive function
Kiss1-MC4RKO females displayed reproductive abnormalities resembling those described in MC4RKO females 10–12. Thus, we hypothesized that the reproductive defects described for the MC4RKO mice would be, at least in part, due to the absence of MC4R signaling in Kiss1 neurons. To further investigate this hypothesis, we generated mice that do not express Mc4r anywhere (MC4R-LoxTB, i.e. MC4RKO) or that express Mc4r only in Kiss1 neurons (Kiss1-cre:MC4R-loxTB). The specific re-insertion of Mc4r within Kiss1 neurons in the Kiss1-cre:MC4R-loxTB mice was confirmed through RNAscope (Figure S2A). Mc4r expression was not detected in the PVN of these mice (Figure S2B), and it was only detected in Kiss1 neurons in the Kiss1-cre:MC4R-loxTB mice. Puberty onset was assessed daily from weaning age through the monitoring of vaginal opening (VO) and first estrus (FE). MC4R-LoxTB and Kiss1-cre:MC4R-loxTB female mice displayed normal timing of puberty onset compared to their control littermates, as assessed by VO (P=0.104, MC4R-LoxTB: 30.86±1.908 vs Kiss1-cre:MC4R-loxTB: 30.09±1.004 vs controls: 27.57±0.8168), and FE (P=0.8472, MC4R-LoxTB: 35.14±2.463 vs Kiss1-cre:MC4R-loxTB: 34.55±1.648 vs controls: 35.80±0.8406) (Figure 3A), despite displaying significantly higher body weight at the time of puberty onset (P=0.0001, MC4R-LoxTB: 15.49±0.5078 vs Kiss1-cre:MC4R-loxTB: 15.54±0.40 vs Controls: 13.29±0.30) (Figure 3B). As expected, MC4R-LoxTB females (MC4RKO) displayed increased body weight (Figure 3C) and an array of reproductive impairments that included: irregular estrous cycles with significantly more days in diestrus (P=0.0016) and fewer days in estrus (P=0.0317) compared to controls (Figure 3D, E), significantly higher serum LH levels characterized by higher basal (P=0.0882, MC4R-LoxTB: 0.48±0.02 vs Controls: 0.37±0.06) and amplitude levels per LH pulse (P=0.0102, MC4R-LoxTB: 0.73±0.009 vs Controls: 0.58±0.07) (Figure 3F-J), and fewer corporal lutea (P=0.0366, MC4R-LoxTB: 0.80±0.80 vs Controls: 4.20±1.15) (Figure 3K, L), recapitulating the same reproductive phenotype observed in Kiss1-MC4RKO mice despite the differences in BW. Re-introduction of MC4R into Kiss1 neurons in Kiss1-cre:MC4R-loxTB mice completely recovered estrous cyclicity, which was similar to controls (diestrus: P=0.1932, proestrus: P=0.8262, estrus: P=0.0547, compared to controls) (Figure 3D, E) despite Kiss1-cre:MC4R-loxTB mice showing the same degree of obesity as MC4R-LoxTB mice (Figure 3C), indicating that obesity per se was not mediating the irregular estrous cycles in MC4RKO mice. As indicated above, MC4R-LoxTB mice display higher overall circulating LH levels, and this feature was also recovered by the re-insertion of MC4R in Kiss1 neurons of Kiss1-cre:MC4R-loxTB mice (basal LH: 0.32±0.044, LH amplitude: 0.48±0.04, LH pulses/180min: 2.75±0.67 and AUC: 70.62±7.156 compared to controls: 80.36±9.058 compared to controls) (Figure 3G-J), further confirming that the melanocortin action on Kiss1 neurons is required for the normal control of gonadotropin release. Despite these significant improvements in reproductive function, Kiss1-cre:MC4R-loxTB mice presented fewer corpora lutea than controls (0.80±0.80), similar to MC4R-LoxTB mice, suggesting that an ovulatory impairment still persists (Fig. 3K, L). While tonic LH release and estrous cyclicity are predominantly controlled by Kiss1ARH neurons, ovulation is mediated by the induction of the preovulatory LH surge by Kiss1AVPV/PeN neurons. It is possible that the metabolic signals derived from their obese phenotype, and/or the absence of the direct action of MC4R in GnRH neurons 15,24 prevents the complete recovery of ovulation in Kiss1-cre:MC4R-loxTB mice. Both genetic models displayed significantly lower T (MC4R-LoxTB: 28.50±6.20 vs Kiss1-cre:MC4R-loxTB: 31.22±3.90 vs Controls: 62.84±16.53) and AMH (MC4R-LoxTB: 150.6±22.00 vs Kiss1-cre:MC4R-loxTB: 146.9±10.83 vs Controls: 321.8±15.70) levels than control mice in diestrus (Fig. 3M, N). Therefore, we can exclude, once again, a PCOS-like reproductive phenotype mediated by the lack of melanocortin signaling.
Kiss1ARH neurons are excited by MC4R agonists
Based on the expression of Mc4r in Kiss1 neurons and the reproductive impairment found after Mc4r deletion within Kiss1 neurons (Figure 2), we hypothesized that Kiss1ARH neurons are direct targets of melanocortins and would respond to MC4R activation. Initially we did whole-cell, voltage clamp recordings in Kiss1ARH neurons (Figure 4A). Kiss1-Cre x Ai32 or Kiss1-Cre AAV-injected mice underwent ovariectomies (OVX) and were given estradiol (E2) replacement (see Methods). We targeted fluorescent cells for recording which were isolated synaptically by bathing the slices in tetrodotoxin (TTX, 1 μM). Focal application of the high-affinity melanocortin receptor agonist melanotan II (MTII, ∼250 nM) elicited a small inward current in half of the isolated Kiss1ARH cells (10/21) (Figure 4B). Next, we examined if the E2 state affected MTII response by recording from Kiss1ARH neurons from OVX females and found two thirds (6/9 cells) responded, but there was no significant difference in the average current (Figure 4C). Finally, it must be noted that at this concentration MTII is a non-selective MCR agonist, so we followed up using a perfusion of the MC4R-selective agonist THIQ (100 nM) to determine if activation of MC4Rs alone was sufficient to invoke a postsynaptic response in Kiss1ARH neurons from OVX+E2 females. Similar to MTII, THIQ was able to elicit an excitatory inward current in Kiss1ARH neurons (4/5 cells, -7.4±0.5 pA), indicating MC4R activation is sufficient (Figure 4D).
POMC neurons synapse directly with Kiss1ARH neurons
Based on the pharmacological activation of MCRs, we wanted to address whether POMCARH neurons are the source of melanocortins to excite Kiss1ARH neurons directly. To answer this question, we injected an AAV-EF1α-DIO-ChR2:mCherry vector into the ARH of adult Pomc-Cre female mice (Figure 4E) (24). After 2-4 weeks we did whole cell recordings from putative Kiss1ARH neurons and looked for a response to high frequency optogenetic stimulation of POMC fibers in OVX + E2-treated females (Figure 4F). We were able to confirm that these were Kiss1 neurons based on the presence of a persistent sodium current and/or post hoc identification by scRT-PCR (41/69 cells, Figure 4G). While this current is more prevalent in the AVPV Kiss1 population, Kiss1 neurons are the only ARH neurons to display this electrophysiological “fingerprint” of a pronounced INaP paired with a high capacitance and a low input resistance 25. Additionally, while recording from putative Kiss1ARH neurons, we optogenetically stimulated POMC fibers at low frequency (1 Hz, 5 ms, 470 nm light) and recorded fast postsynaptic inward currents. The fast kinetics of the EPSC are also a tell-tale sign of an ionotropic glutamatergic response 26. Previously, CNQX was sufficient to block similar excitatory ESPCs in other postsynaptic targets of POMC neurons 27. While the consistent latency from optogenetic stimulus and current response was indicative of a single synaptic delay, we wanted to establish that it was a direct synaptic connection, as we have previously shown for output of POMC neurons 27 and Kiss1 neurons 28–30. First, we abrogated the optogenetic response with the addition of TTX (1 μM) to the bath, we were able to rescue the postsynaptic glutamate response with the addition of the K+ channel blockers 4-aminopyridine (4-AP; 0.5 mM) and tetraethyl ammonium (TEA; 7.5 mM) (Figure 4H). K+ channel block enables the calcium influx from ChR2 activation in the presynaptic terminals to be sufficient to restore vesicle fusion. Therefore, there appears to be no intervening synapses between POMC and the downstream Kiss1ARH neurons.
Previously we found that E2 increases glutamate release from POMC neurons by increasing Vglut2 27. Therefore, we compared the postsynaptic glutamatergic responses following two optogenetic stimuli (50 ms interval between light flashes) in Kiss1ARH neurons from OVX + vehicle versus OVX + E2-treated female mice (Figure 4I). As anticipated, we found that treatment with E2 increased the probability of glutamate release from POMC neurons onto Kiss1ARH neurons based on the significant decrease in the paired pulse ratio of the two stimuli 31 (Figure 4J). Although in the present study we used an in vivo treatment paradigm, we know from previous studies that this augmentation of glutamate release can happen quite rapidly after a brief exposure to E2 in vitro (within 15 min) 27. Therefore, Kiss1ARH neurons are excited by the glutamatergic input from POMC neurons in an E2-dependent manner.
Finally, given that POMC neurons project directly onto Kiss1ARH neurons, we wanted to show that the evoked slow inward current with high frequency stimulation was mediated by αMSH. Indeed, high frequency stimulation evoked an excitatory inward current (Figure 4K) that was blocked by the selective MC3/4R antagonist SHU 9119 (Figure 4L). The number of high frequency (peptidergic) responses seen in Kiss1 neurons that displayed low frequency postsynaptic (glutamatergic) currents was low (4/16, 25%, mean inward current: -1.4±3.1 pA). However, since these recordings were made in brain slices from E2-treated OVX females and β-endorphin (another product of POMC neurons) expression is enhanced by E2 treatment 32, we were concerned that co-release of this opioid peptide could obscure melanocortin postsynaptic effects. Indeed, there was a notable increase in slow inward currents generated by high frequency stimulation of POMC fibers in slices that were perfused with the non-selective opioid antagonist naloxone (1 μM) (9/23, 40%, mean inward current: -7.6±2.9 pA) (Figure 4M).
Together these optogenetic findings reinforced our pharmacological results showing that Kiss1ARH neurons are excited by MTII, and THIQ. Additional studies would need to be done to identify the cation conductance that is affected by the MC4R signaling cascade in Kiss1ARH neurons, but clearly we have established that there are excitatory glutamatergic and peptidergic inputs from POMC to Kiss1ARH neurons.
Kiss1AVPV/PeN neurons are inhibited by MC4R agonists
Having established a direct, excitatory projection from POMC to Kiss1ARH neurons, we next examined POMC inputs to Kiss1AVPVPeN neurons. First, we used immunocytochemistry to label fibers expressing αMSH to demonstrate that POMC fibers densely innervated the AVPV/PeN area (Figure 5A). Next, we recorded from AVPV neurons in slices taken from OVX+E2, POMC-Cre mice injected with AAV1-DIO-YFP:ChR2 into the ARH (Figure 5B). We targeted cells along the ventricle in the AVPV and PeN, surrounded by YFP terminals, and Kiss1AVPV/PeN neurons were identified based on the expression of several endogenous conductances (INaP, T-type calcium current, h-current) that are unique to these neurons 25,33. We recorded a direct glutamatergic synaptic response following optogenetic stimulation in 5 neurons, which was further verified through pharmacological “rescue” of the synaptic response in 3 out of the 4 neurons tested (Figure 5C), indicating that POMC neurons make direct monosynaptic connections with Kiss1AVPV/PeN neurons. We hypothesized that Kiss1AVPV/PeN neurons would be excited by exogenous application of melanocortins because the receptor is typically Gs-coupled 34,35. We did whole-cell, voltage clamp recordings from Kiss1AVPV/PeN-Cre::Ai32 neurons, which were isolated synaptically by bathing the neurons in TTX (1 μM), from OVX females. For these experiments, we tested the response to the high affinity melanocortin receptor agonist MTII (500 nM). Surprisingly, we consistently measured an outward (inhibitory) current that could be reversed on washout of MTII (Figure 5D). This outward current was associated with an increase in a K+ conductance based on the current-voltage plot (i.e., the outward current reversed at ∼EK+, Figure 5E). Also, the inwardly-rectifying I/V could indicate that MC4R is coupled to activation of inwardly-rectifying K+ channels as has been previously reported for MC4R signaling in pre-autonomic parasympathetic neurons in the brainstem 36. We hypothesized that the coupling could be modulated by E2 via a Gαq-coupled membrane estrogen receptor (Gq-mER) as we have previously demonstrated in POMC neurons 37–39. For these experiments, we again utilized OVX females and targeted Kiss1AVPV/PeN-Cre::Ai32 neurons. Once in the whole-cell voltage-clamp configuration, we perfused the slices with STX (10 nM), a selective ligand for the putative Gq-mER 39, and tested the response to the MTII. Indeed, the outward current (inhibitory) response to MTII was completely abrogated and even reversed by STX (Figure 5F, G). The short-term (bath) treatment with STX ensured that there was no desensitization of the Gq-mER with longer-term (in vivo) treatment with E2. Therefore, estrogen receptor activation can rapidly uncouple (i.e., desensitize) the MC4R inhibitory response in Kiss1AVPV/PeN neurons.
We would predict that the intracellular signaling cascade for the heterologous desensitization is similar to what we have elucidated in POMC neurons 39, but this will need to be determined in future experiments. We next investigated the response in vehicle-treated, OVX females. Indeed, Kiss1AVPV/PeN neurons were even more inhibited by the same MTII exposure (Figure 5G). Therefore, in contrast to Kiss1ARH neurons, the MC4R appears to be coupled to opening of K+ channels in Kiss1AVPV/PeN neurons. To further establish whether the MTII was having pre-or postsynaptic effects, we measured the glutamatergic mEPSCs before and after melanocortin receptor activation. We found there was no significant effect on the frequency (Figure 5H), but there was an effect on the amplitude (Figure 5I). This further supports a postsynaptic locus of STX’s effects. However, posthoc comparisons found STX increased amplitude compared to both OVX and OVX+E. This result hints at a membrane delimited effect as STX is a much more potent agonist for Gq-mER than E2 40.
Discussion
Our findings show that melanocortins act directly on Kiss1 neurons to contribute to the metabolic regulation of fertility, in line with previous reports showing that αMSH stimulates LH release in a kisspeptin-dependent manner 13 and that Kiss1 neurons express the melanocortin receptor MC4R 17–20. Several studies in humans have linked MC4R mutations to reproductive abnormalities, including precocious puberty 8, PCOS 9, and hypogonadism 7. However, a direct association between MC4R mutations and reproductive function, independent from the obese condition of these patients, has not been identified 6. In the current study, we show that the reproductive impairments observed in MC4R deficient mice, which replicate many of the conditions described in humans, are largely mediated by the direct action of melanocortins via MC4R on Kiss1 neurons and not to their obese phenotype. This is because the ablation of MC4R from Kiss1 neurons largely replicated the reproductive impairments observed in MC4RKO female mice without inducing obesity, and the selective reinsertion of MC4R into Kiss1 neurons of MC4RKO mice significantly improved their reproductive function without changing their obese phenotype. Strikingly, puberty onset was advanced in Kiss1-MC4RKO females. Our findings revealed a low melanocortin tone in the hypothalamus of WT females during pubertal development, characterized by lower levels of Agrp, Mc4r and Mc3r expression at the time of puberty onset (∼PND30). This developmental decline in the expression of melanocortin receptors is in line with the advanced timing of puberty onset in females when MC4R is congenitally ablated from Kiss1 neurons. A recent study using whole body MC3RKO mice showed a trend to delayed puberty onset 18, suggesting a larger role of melanocortins in the timing of puberty onset. Here, we show that in females the combination of MC3R and MC4R action may be necessary for pubertal development. Interestingly, the MC4R-LoxTB and Kiss1-cre:MC4R-LoxTB mice do not show an advancement in puberty onset as we observed in Kiss1-MC4RKO mice; however, these mice are obese at the time of puberty onset already, which may affect the timing of sexual maturation independently of MC4R action in Kiss1 neurons. Of note, the findings presented in this study do not rule out the existence of additional sites of action of MC4R in other neuronal populations to regulate reproduction, e.g., GnRH neurons, which also express MC4R 15,24. Indeed, the lack of full recovery of the reproductive function in Kiss1-cre:MC4R-LoxTB mice suggests that MC4R in Kiss1 neurons is necessary but not sufficient to achieve full reproductive capabilities.
In addition to early puberty onset, Kiss1-MC4RKO females displayed an impaired preovulatory LH surge driving ovulation and had fewer corpora lutea in their ovaries compared to control littermates, further supporting a role of MC4R in regulating ovulation. In adulthood, the reproductive phenotype observed in Kiss1-MC4RKO and MC4R-loxTB female mice (increased LH, irregular estrous cycles, oligo-ovulation, increased cystic follicles) correlates with the phenotype observed in PCOS mouse models 21,22. In fact, an association between MC4R mutations and PCOS has been reported 9. However, our mouse models failed to display higher levels of circulating androgens or AMH, two of the hallmarks of PCOS 23, suggesting that melanocortin signaling is unlikely to be a main contributing factor in the development of this syndrome.
Our data revealing early puberty onset and impaired LH pulse and surge driving ovulation support a direct role of MC4R on the two primary Kiss1 populations regulating these functions (ARH and AVPV/PeN). We further investigated this and found that MC4R signaling excites Kiss1ARH neurons and inhibits Kiss1AVPV/PeN neurons in an estradiol-dependent manner. In Kiss1ARH neurons, bath applied or optogenetically-evoked release of melanocortin agonists induce a direct excitatory inward current. Our studies using whole cell voltage clamp in female mice were able to detect a melanocortin-mediated inward current in Kiss1ARH neurons that would increase excitability. Previously, an MCR-activation effect was not detected in cell-attached recordings of diestrus females 13. However, cell-attached recordings do not measure a direct response in isolated Kiss1ARH neurons but rather the summation of multiple synaptic inputs to Kiss1ARH neurons. Most importantly, we did not see a difference in the excitatory response in synaptically isolated Kiss1ARH neurons from E2-treated versus vehicle-treated, ovariectomized females. This emphasizes the importance of doing whole-cell recording from isolated Kiss1 neurons. The modulatory actions of POMCARH neuronal projections to Kiss1ARH neurons can also occur through a) the excitatory action of glutamate in a process that is facilitated in the presence of estradiol, in line with previous publications 41,42, and b) the inhibitory action of β-endorphin, suggesting that POMCARH neurons are able to exert a precise regulatory role of the GnRH pulse generator, i.e. Kiss1ARH neurons, in response to metabolic challenges. In the AVPV/PeN, MC4R agonists inhibited Kiss1AVPV/PeN neurons in an estradiol-dependent manner, which utilized a Gαq-coupled membrane estrogen receptor (STX receptor) to attenuate the inhibitory tone of MC4R in these neurons.
Our pharmacology data clearly demonstrates the estradiol-dependent action of MC4R in Kiss1AVPV/PeN neurons, suggesting that similar to Kiss1ARH neurons, this population is tightly controlled by melanocortins. The effect of MC4R agonists on Kiss1 neurons in the presence of TTX, suggests a direct synaptic effect without the need of channelrhodopsin-2(ChR2)-assisted circuit mapping. Nonetheless, to further demonstrate this interaction, we provide evidence of profound innervation of αMSH fibers and the presence of synaptic contact between POMC and Kiss1AVPV/PeN neurons through the optogenetic stimulation of a glutamatergic response in Kiss1AVPV/PeN neurons after low frequency stimulation of POMC terminals. We intentionally avoided high frequency stimulation of POMC terminals to prevent the co-release of β-endorphins (e.g., Figure 4M) and their possible additive effect on the inhibitory action of MC4R. Future studies will be aimed at the characterization of the endogenous opioid pathways in the induction of the LH surge.
To date, two instances of MC4R-mediated inhibition have been described in the central nervous system: MC4R can Gi,o couple to open K+ (Kir6.2) channels in parasympathetic preganglionic neurons in the brainstem 36, and MC4R can directly couple to K+ (Kv7.1) channels in the hypothalamic paraventricular nucleus neurons 43. Interestingly, our findings describe an inhibitory role of MC4R in the reproductive neuroendocrine axis. This steroid state dependent effect is particularly relevant because in the context of reproduction, the two populations of Kiss1 neurons are strikingly different in their response to estradiol, where peptide expression in Kiss1ARH and Kiss1AVPV/PeN neurons are inhibited or stimulated, respectively, in order to mount the negative versus positive feedback of sex steroids 14. This differential regulation allows for the episodic versus surge release of GnRH; however, the cellular mechanisms underlying these opposing roles of Kiss1 neurons to the same stimulus, i.e. circulating E2 levels, remain unknown. Although there were no differences in the magnitude of the electrophysiological responses to MTII in Kiss1ARH neurons in vehicle-versus E2-treated, ovariectomized females, we cannot rule out that E2 affects other systems activated by the MC4R signaling cascade as recently reported in MC4R expressing neurons of the ventromedial nucleus of the hypothalamus (VMH) 44. Interestingly, puberty onset was advanced in Kiss1-MC4RKO females. This data suggests that the inhibitory tone of MC4R signaling on Kiss1AVPV/PeN neurons might also be involved in the timing of puberty onset, which in turn suggests a role for this female-specific population of Kiss1 neurons in sexual maturation. This phenomenon could explain the earlier age of puberty onset frequently seen in females of most mammalian species compared to their male counterparts 45. Furthermore, our findings suggest that metabolic cues, through the regulation of the melanocortin output onto Kiss1AVPV/PeN neurons, are essential for the timing and magnitude of the GnRH/LH surge. Future studies are warranted to fully elucidate synaptic input and postsynaptic cascades in the POMC-Kiss1AVPV/PeN circuit.
Altogether, our data reveal a differential regulatory action of MC4R in the neural control of GnRH/LH release, participating in both the surge (E2-treated, ovariectomized female) and the pulse-like (ovariectomized female) modes of LH release through the cellular regulation of Kiss1 neurons, which translate into our findings on the conditional knockout of Mc4r from Kiss1 neurons (Figure 6). These findings are important because the reproductive abnormalities often attributed to obesity in MC4R deficient patients may not be caused by the excess in body weight but, at least in part, by a deficiency in MC4R signaling directly at the level of Kiss1 neurons that affects predominantly the ability to mount a preovulatory LH surge.
Materials and methods
In-vivo experimental procedures
Generation of Kiss1-MC4RKO, Kiss1-cre:MC4R-LoxTB and MC4R-LoxTB Transgenic Mice
Kiss1-MC4RKO mice were generated by crossing Kiss1-cre knock-in mice and MC4Rlox/lox mice. Kiss1-cre mice (RRID:MGI:6278139) were obtained from Dr. Richard Palmiter (University of Washington, Seattle, WA) 46 and Mc4rlox/lox (RRID:IMSR_JAX:023720) were a gift from Dr. Brad Lowell (Beth Israel Deaconess Hospital, Boston, MA) 4. These mice were crossed to generate Kiss1-MC4RKO mice lacking Mc4r expression selectively from Kiss1 neurons (Kiss1-cre+/-; MC4Rlox/lox) and their control littermates (MC4Rlox/lox). To generate Kiss1-cre:MC4R-LoxTB and MC4R-LoxTB mice, MC4R-LoxTB mice were purchased from The Jackson Laboratory (MC4R-LoxTB; catalog no. 006414). These mice present with a loxp-flanked transcriptional blocking (LoxTB) sequence preventing normal endogenous gene transcription and translation from the endogenous locus. Homozygous MC4R-loxTB/loxTB mice are devoid of functional MC4R mRNA (MC4RKO mice), while the presence of Cre recombinase on the Kiss1 promotor in Kiss1-cre mice will result in the removal of the transcription blocker and subsequent expression of MC4R in tissue-specific sites (i.e. Kiss1 neurons) therefore resulting in the generation of Kiss1-cre:MC4R-LoxTB (with Mc4r expression restored in Kiss1 neurons), their obese control littermates MC4R-LoxTB mice (MC4RKO), and their WT controls (MC4R+/+). To rule out early embryonic recombination of the MC4RloxTB/loxTB or MC4Rlox/lox alleles, we ran PCR assays on tail DNA designed to detect wild-type allele (MC4R+/+), undeleted lox (MC4Rlox/lox) or loxTB alleles (MC4RloxTB/loxTB). Genotyping was confirmed by sending tissue to Transnetyx, Inc., for testing by real-time polymerase chain reaction. Mice were housed in Harvard Medical School Animal Resources facilities where they were fed standard mouse chow (Teklad F6 Rodent Diet 8664) and were given ad libitum access to tap water under constant conditions of temperature (22–24°C) and light (12 hr light [07:00]/dark [19:00] cycle).
RNAscope in situ hybridization
To validate the Kiss1-MC4RKO, Kiss1-cre:MC4R-LoxTB and MC4R-LoxTB (MC4RKO) mouse models and investigate the co-expression of Kiss1 and Mc4r mRNA in these mice, dual fluorescence ISH was performed using RNAscope (ACD, Multiplex Fluorescent v.2) according to the manufacturer’s protocol using the following probes: Mc4r (319181-C2) and Kiss1 (500141-C1). Brains (n=4/group) from WT OVX (for expression in the ARH) and OVX+E2 (for expression in the AVPV/PeN) mice and OVX Kiss1-MC4RKO, Kiss1-cre:MC4R-LoxTB and MC4RKO were removed fresh frozen on dry ice, and then stored at -80°C until sectioned. Five sets of 20 μm sections in the coronal plane were cut on a cryostat, from the diagonal band of Broca to the mammillary bodies, thaw mounted onto SuperFrost Plus slides (VWR Scientific) and stored at -80°C until use. A single set was used for ISH experiment (adjacent sections 100 mm apart). Images were taken at 20x magnification of the sections containing AVPV, PeN, and the three rostro-to-caudal levels of the ARH, and Kiss1 neurons expressing (Kiss1-cre:MC4R-LoxTB mice) or lacking (Kiss1-MC4RKO mice) Mc4r were identified using ImageJ.
Reproductive maturation of Kiss1-MC4RKO, Kiss1-cre:MC4R-LoxTB and MC4R-LoxTB mice
To assess the reproductive phenotype of mice with selective reinsertion of Mc4r on Kiss1 neurons (Kiss1-cre:MC4R-LoxTB, n=11), selective deletion of Mc4r from Kiss1 neurons (Kiss1-MC4RKO, n=24), global deletion of Mc4r (MC4R-LoxTB, n=7); and their control MC4Rlox/lox littermates (n=14), mice were weaned at post-natal day (PND) 21 and were monitored daily for puberty onset. Females were monitored daily for vaginal opening (VO, indicative of the complete canalization of the vaginal cavity) and for first estrus (first day with cornified cells determined by daily morning vaginal cytology) after the day of VO. Body weight (BW) was measured at the day of puberty onset to determine if changes in puberty onset could be due to differences in BW. Estrous cyclicity was monitored in females by daily vaginal cytology, for a period of 15 days, in 6-month-old mice and their respective control littermates (n=5/group). Cytology samples were obtained every morning (9 am), placed on a glass slide and stained with hematoxylin and eosin for determination of the estrous cycle stage under the microscope.
Fecundity test of Kiss1-MC4RKO females
Adult 6-month-old Kiss1-MC4RKO and control littermate female mice (n=9/group) were placed with adult WT males proven to father litters for 90 days and time to deliver pups and number of pups per litter were monitored.
Characterization of the estradiol-induced luteinizing hormone surge
Kiss1-MC4RKO (n=6) and control MC4Rlox/lox littermate (n=5) adult female mice were subjected to bilateral ovariectomy (OVX) via abdominal incision under light isoflurane anesthesia. Immediately after OVX, capsules filled with E2 (1 ug/20g BW) were implanted subcutaneously via a small mid-scapular incision on the back. Five days later, mice were subcutaneously injected in the morning with estradiol benzoate (1 ug/20g BW) to produce elevated proestrus-like E2 levels (preovulatory LH surge) on the following day 47. Blood samples were collected at 8am and 7pm; LH levels were stored at -80°C until measured via LH ELISA.
Ovarian histology and hormone measurements
Bilateral ovariectomy from 6-month-old Kiss1-MC4RKO (n=4), Kiss1-cre:MC4R-LoxTB, MC4R-LoxTB and their control littermates (n=5/group) was performed under light isoflurane anesthesia. Briefly, the ventral skin was shaved and cleaned, and one small abdominal incision was made. Once the ovaries were identified and excised, the muscle incision was sutured, and the skin was closed with surgical clips. Ovaries were stored in Bouin’s fixative, sectioned, and stained with hematoxylin and eosin at the Harvard Histopathology Core. Corporal lutea were counted in the middle section of each ovary. Serum samples were also collected for analysis of testosterone and anti-müllerian hormone (AMH) levels in these mice. These hormones levels were measured at the University of Virginia Ligand Assay core with the Mouse & Rat Testosterone ELISA assay (reportable average range 10-1600 ng/dL; sensitivity of 10 ng/dL); AMH ELISA assay (reportable average range 0.2 – 15 ng/mL; sensitivity of 0.2 ng/mL).
LH pulsatile secretion profile in gonad intact Kiss1-MC4RKO, Kiss1-cre:MC4R-LoxTB and MC4R-LoxTB female mice
To assess the profile of LH pulses secretion, adult 6 months old gonad intact Kiss1-MC4RKO females (n=6), their control Mc4rlox/lox littermates (n=7); and Kiss1-cre:MC4R-LoxTB (n=5/group), MC4R-LoxTB and their control WT females (n=4/group) were handled daily for 3 weeks to allow acclimation to sampling conditions prior to the experiment. Pulsatile measurements of LH secretion were assessed by repeated blood collection through a single incision at the tip of the tail. The tail was cleaned with saline and 4 μL of blood was taken at each time point from the cut tail with a pipette. We collected sequential blood samples every 10 minutes over a 180-minute sampling period. Samples were immediately frozen on dry ice and stored at −80 °C until analyzed with LH ELISA as previously described 48. The functional sensitivity of the ELISA assay was 0.0039 ng/ml with a CV% of 3.3%.
LH pulses analysis
LH pulses in mice were analyzed using a custom-made MATLAB-based algorithm. The MATLAB code includes a loop that determines LH pulses as any LH peak: (i) whose height is 20% greater than the heights of the 2 previous values; (ii) 10% greater than the height of the following value; and (iii) the peak at the second time interval needs to be 20% greater than the single value that comes before it to be considered a pulse, as we previously described 49.
LH pulsatility was assessed by measuring: (1) the total secretory mass, assessed by area under the curve (AUC); (2) the LH pulse amplitude, calculated by averaging the 4 highest LH values in the samples collection period for each animal; (3) the basal LH, calculated by averaging the 4 lowest LH values in the samples collection period for each animal; and (4) the total number of pulses throughout the 180 minutes sampling period.
Immunohistochemistry
Animals and Treatment
Coronal brain blocks (2 mm each) from adult female C57BL/6 mice (n=4) were fixed by immersion in 4% paraformaldehyde for ∼ 8 hours, cryoprotected in 30% sucrose solution, frozen in isopentane at –55°C, sectioned coronally on a cryostat at 20 μm, and thaw-mounted onto Superfrost Plus slides (Fisher Scientific, Pittsburgh, PA). The 20 µm sections were stored at –20°C until used for immunocytochemistry.
Immunocytochemistry
The sections were rinsed in PB (0.1M phosphate buffer, pH 7.4) for at least 30 min. Next, sections were incubated with normal serum corresponding to the host for the secondary antiserum (5 % normal serum with 0.3% Triton-X100 in PBS for 30 min), rinsed in PB and then incubated for ∼45 h at 4° C with a rabbit polyclonal antiserum against α-MSH (1:2,500). The specificity of this antiserum has been documented 50. After rinsing, sections were first incubated for 2-3 hours at room temperature with biotinylated donkey anti rabbit gamma globulin (IgG; 1:500) and next with streptavidin-Alexa 488 (1:2500). Both the primary and secondary antibodies were diluted in tris-(hydroxymethyl) aminomethane (0.5 %, Jackson ImmunoResearch, Philadelphia, PA) in PB containing 0.7 % seaweed gelatin (Jackson ImmunoResearch, Philadelphia, PA) and 0.5 % Triton X-100 and 3% bovine serum albumin (BSA; Jackson ImmunoResearch, Philadelphia, PA) adjusted to pH 7.6. Following a final rinse overnight, slides were coverslipped with gelvatol containing the anti-fading agent, 1,4-diazabicyclo(2,2)octane (DABCO; Cold Spring Harbor Protocols, 2006).
Imaging
Photomicrographs of labeling were initially acquired using a Nikon E800 fluorescent microscope (Eclipse E800; Nikon Instruments, Melville, NY) equipped with a fiber illuminator (Intensilight C-HGFI; Nikon Instruments) and a high-definition digital microscope camera head (DS-Fi1; Nikon Instruments) interfaced with a PC-based camera controller (DS-U3; Nikon Instruments).
Real time quantitative PCR
i) To investigate the changes in the expression of the melanocortin genes Agrp, Pomc, Mc3r and Mc4r in the MBH during development in prepubertal and pubertal WT females at ages P10 (n=6), P15 (n=6), P22 (n=6), and P30 (n=5), and ii) evaluate the gene expression profile of Pdyn, Kiss1, Tac2, Tacr3, in the ARH of adult intact (in diestrus) female Kiss1-MC4RKO (n=6) and their control MC4Rlox/lox littermates (n=3), the brains were removed and rapidly embedded in Tissue-Tek, frozen in −30°C isopentane solution and stored at −80°C until use. Frozen tissue punches were recovered through MBH with a 1 mm diameter canula 51. These tissue punches encompassed the whole MBH from the WT females and the ARH from the Kiss1-MC4RKO and their control females. The tissues were homogenized, and total RNA was isolated using TRIzol reagent (Invitrogen) followed by chloroform/isopropanol extraction. RNA purity and concentration were measured via an absorbance spectrophotometer (260/280 nm > 1.8; NanoDrop 1000, Thermo Fisher Scientific). Total RNA (1 μg) was reverse transcribed to cDNA using random hexamers (High-Capacity cDNA Synthesis Kit, Life Technologies). Quantitative real-time PCR assays were performed using SYBR Green RT-qPCR master mix (Applied Biosystems) and analyzed using ABI Prism 7000 SDS software (Applied Biosystems). The cycling conditions were: 2 minutes incubation at 95°C (hot start), 45 amplification cycles (95°C for 30 seconds, 60°C for 30 seconds, and 45 seconds at 75°C, with fluorescence detection at the end of each cycle), followed by melting curve of the amplified products obtained by ramped increase of the temperature from 55°C to 95°C to confirm the presence of single amplification product per reaction. PCR specificity was verified by melting curve analysis and agarose gel electrophoresis. Each sample was run in duplicate to obtain an average cycle threshold (CT) value and relative expression of each target gene was determined using the comparative Ct method 52. The data were normalized to Hypoxanthine Guanine Phosphoribosyltransferase (Hprt) expression levels in each sample. Results were expressed as fold differences in relative gene expression with respect to i) P10 for melanocortin genes expression analysis during development in WT mice, and ii) controls for the KNDy genes expression in female Kiss1-MC4RKO mice. The primers used are listed in Table 1.
Data analysis
Statistical data are expressed as means ± SEM, where n represents the number of animals in each study group. The significance of differences between groups was evaluated using unpaired two-tailed Student’s t test, or a one-or two-way ANOVA test (with post hoc comparisons). Significance level was set at p<0.05. All analyses were performed with GraphPad Prism Software, Inc (San Diego, CA).
In-vitro experimental procedures
Animals
All animal procedures described in the electrophysiology studies were performed in accordance with institutional guidelines based on National Institutes of Health standards and approved by the Institutional Animal Care and Use Committees at Oregon Health and Science University and Appalachian State University. Pomc-Cre mice (RRID:IMSR_JAX:005965) 53 were crossed with wildtype C57B6J (RRID:IMSR_JAX:000664) mice. Kiss1-cre(v2) mice 46 were crossed with Ai32 54 or C57B6J mice. All colonies were maintained onsite under controlled temperature (21-23 °C) and photoperiod (12:12-h light-dark cycle 0600 to 1800) while receiving ad libitum food (5L0D; LabDiet, St. Louis, MO) and water access. Following surgeries, mice received a s.c. dose of 4-5 mg/kg carprofen (Rimadyl; Pfizer Animal Health, New York, NY) and given at least 1 week of recovery.
Ovariectomies
At least 7 days prior to each experiment, ovaries were removed as described previously while under isoflurane anesthesia 42. Two days before experiments females received either an injection of sesame oil (50 μl, sc; Sigma-Aldrich, St. Louis, MO) or a priming dose (0.25 μg /50 μl sesame oil, sc) of E2 benzoate (Sigma-Aldrich, St. Louis, MO) in the morning. On the following day, oil or a high (1.5 μg) dose of E2 benzoate, which generates a LH surge, was administered 55. Circulating levels of E2 were verified by the uterine weights (<25 mg for OVX and >95 mg for OVX E2-treated) at the time of euthanasia 55.
AAV Delivery
Bilateral ARH injections of AAV1-Ef1a-DIO-ChR2:mCherry (RRID:Addgene_20297) or AAV1-Ef1a-DIO-ChR2:YFP (RRID:Addgene_20298) were performed on adult Kiss1-cre mice or Pomc-cre mice on a stereotaxic frame under isoflurane anesthesia. ARH injection coordinates were anteroposterior (AP): −1.10 mm, mediolateral (ML): ± 0.30 mm, dorsoventral (DL): −5.80 mm (surface of brain z = 0.0 mm); 400 nl of the AAV (2.0 x 1012 particles/ml) was injected (100 nl/min) into each position. Mice were given carprofen for analgesia and allowed to recover for at least two weeks before euthanasia.
Visualized whole-cell patch recordings
Hypothalamic coronal brain slices (240 um) were made from female mice, using a Leica VT1000S vibratome, in ice cold cutting solution bubbled with O2/C02 (95%/5%). Slices were then transferred to a holding chamber with artificial cerebrospinal fluid bubbled with the same gas mix and allowed to recover for at least 1 hour. For recordings, slices were placed in a perfusion chamber and visualized with a Olympus BX51W1 using either differential infrared contrast or oblique illumination. Kiss1 neurons in the ARH or AVPV/PeN were targeted for electrophysiological recordings as done previously and described below 56,57.
Solutions/drugs
Standard vibratome slicing, external, and internal recording solutions were utilized as previously described 56,57. Tetrodotoxin was purchased from Alomone Labs (Jerusalem, Israel), Melanotan II and αMSH from Tocris (Minneapolis, MN). TEA, 4-AP, 17β-estradiol benzoate, and Naloxone were purchased from Millipore-Sigma. STX was produced by AAPharmaSyn, LLC (Ann Arbor, MI) under contract.
Electrophysiology data analysis
Electrophysiological data were analyzed using Clampfit 10/11 (Molecular Devices) and Prism 7/10 (Dotmatics). All values are expressed as Mean ± SEM. Comparisons between two groups were made using un-paired Student’s t-test or between multiple groups using an ANOVA (with post hoc comparisons) with p-values < 0.05 considered significant. When variances differed significantly, Mann-Whitney U test was used instead.
Targeting of Kiss1 neurons for electrophysiological recordings
For non-optogenetic experiments, brain slices were taken from AAV injected Kiss1-Cre AAV or Kiss1xAi32 female mice. Ai32 mice (RRID:IMSR_JAX:024109, C57BL/6 background) carry the floxed ChR2 (H134R)-EYFP gene in their Gt(ROSA)26Sor Locus 54, allowing its expression in a Cre-dependent manner. Due to concerns of nonspecific expression 58, we previously validated this model using single cell RT-PCR and documented that Kiss1 mRNA was detectable in 99% of individually harvested eYFP cells (n=126). In addition, we have used both AAV injected Kiss1-Cre AAV or Kiss1xAi32 female mice and found no differences in electrophysiological results 56. We used AAV injected POMC-Cre female mice and avoided small soma, high input resistance (>800 MΩ), ventrally located cells that are typically NPY/AgRP neurons. Instead, we targeted larger, more dorsomedial neurons in the ARH while avoiding fluorescent (POMC) cells. Unlike ARH Kiss1 neurons, POMC neurons do not make reciprocal projections, so uninfected POMC neurons do not display monosynaptic EPSCs in response to optogenetic stimulation. Next, we used a ramp IV protocol to probe for the presence of a persistent sodium current (INaP). While this current is more prevalent in the AVPV Kiss1 population, Kiss1 neurons are the only ARH neurons to display this electrophysiological “fingerprint” of a pronounced INaP paired with a high capacitance and low input resistance 25. Finally, we also harvested the cytosol at the end of all recordings and measured the expression of Kiss1. Only cells that expressed a persistent sodium current and/or expressed Kiss1 mRNA were included in final analysis (n = 44).
Acknowledgements
The authors would like to recognize the excellent technical expertise of Ms. Martha A. Bosch (tissue preparation, immunohistochemical procedure and single cell RT-PCR of recorded neurons). In addition, we thank Dr. Rona Carroll for her assistance at Harvard Medical School and Mr. Cole Martinson, a student worker in the Ronnekleiv/ Kelly laboratories, for his assistance with genotyping and care of mouse colonies at OHSU. The University of Virginia Center for Research in Reproduction Ligand Assay and Analysis Core is supported by the Eunice Kennedy Shriver NICHD/NIH (NCTRI) Grant P50-HD28934. This work was supported by PHS MPI grant DK68098 to MJK and OKR; HD090151, HD099084 and DK133760 to VMN, and The Charles A. King Trust Postdoctoral Research Fellowship Award, The Lalor Foundation Postdoctoral Fellowship Award, the Women’s brain initiative Fellowship Award, the ROSA SCORE pilot grant (supported by NIH Research Grant U54 AG062322 funded by The National Institute on Aging (NIA) and Office of Research on Women’s Health (ORWH)) and the IBRO-ISN Research Fellowship Award to RT, and startup funds from Appalachian State University to TLS.
Declaration of interests
The authors declare they have no competing interest.
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