Edinburgh Research Explorer Interactions between neurokinin B and kisspeptin in mediating estrogen feedback in healthy women

Kisspeptin and neurokinin B (NKB) are obligate for normal gonadotropin secretion, but their hierarchy is unexplored in normal women. Objective: To investigate the interaction between kisspeptin and NKB on estrogen-regulated LH secretion. Kisspeptin-10 increased LH secretion during the inhibitory phase, and LH remained elevated be-yondthediscontinuationofkisspeptin-10infusion.NK3RantagonistdecreasedLHpulsefrequency (0.5 (cid:3) 0.2 vs 0.7 (cid:3) 0.2 pulses/hr, p (cid:4) 0.05) and stimulated FSH response to kisspeptin-10 infusion (10.7 (cid:3) 11.0 vs 5.0 (cid:3) 3.6 IU/l, p (cid:4) 0.05) with a non-significant rise in LH. The duration of LH response was blunted, with LH being lower at 48hr (7.5 (cid:3) 4.8vs 15.0 (cid:3) 11.4 IU/l, p (cid:4) 0.05). Conclusions: These data demonstrate that NKB signalling regulates GnRH/LH secretion in normal women,andispredominantlyproximaltokisspeptininmediatingestrogenicpositiveandnegative feedback on LH secretion. ment cycles. To compare the effect of exogenous vs endogenous estrogenonkisspeptin-10response,anothergroupoftenwomenreceivedIVkisspeptin-10(4 (cid:2) g/kg/hr) infusion for 7 hours on cycle day 10–12 without exogenous estrogen treatment, with reproductive hormone measurements at equivalent time points.

tion, culminating in the midcycle LH surge that triggers ovulation. Neuroendocrine mechanisms involved in these pathways and the switch from negative to positive estrogen feedback in the late follicular phase remain unclear.
Kisspeptin and neurokinin B (NKB), neuropeptides partially coexpressed by a population of neurons that also express the opiate, dynorphin, are now recognized as central to the regulation of human reproduction. Patients with loss-of-function mutations in kisspeptin, NKB, or their respective receptors (KISS1R and NK3R) show hypogonadotropic failure of pubertal progression (2)(3)(4)(5), while activating mutations in kisspeptin receptor are associated with precocious puberty (6). Experimental characterization of the relative roles played by kisspeptin and NKB, as well as their functional hierarchy, has been largely carried out in nonhuman models (7)(8)(9)(10)(11). In patients with genetic defects inactivating NKB signaling, exogenous kisspeptin, administered using a regimen shown to be maximally stimulatory in healthy volunteers (12), restored LH pulse frequency to normal (13). This, and concordant data from animal models (7,8), has led to the conclusion that central NKB signaling is functionally upstream of kisspeptin. Data from animal studies of administration of exogenous NKB are discordant, with both stimulatory and inhibitory effects on LH secretion being reported (9 -11), whereas it elicited little effect on gonadotropin secretion in a human study (14).
In women, gonadotropin response to exogenous kisspeptin is dependent on the sex-steroid milieu (15) and is greatest in the late follicular phase of the menstrual cycle (16 -18), suggesting a role for kisspeptin in the preovulatory positive estrogenic drive to GnRH/LH secretion. Exogenous kisspeptin can increase LH secretion sufficiently to induce oocyte maturation following ovarian stimulation (19), but the role of kisspeptin in physiological positive estrogen feedback is unclear. Involvement of kisspeptin in the ovulatory LH surge in rats and sheep is demonstrated by loss the LH surge during kisspeptin receptor antagonist treatment (20,21). The effect of kisspeptin appears largely through an increased frequency of pulsatile GnRH secretion (12,22,23), which preferentially stimulates LH over FSH secretion from gonadotrophs (24). Recent data from animal models indicate that administration of an NKB receptor antagonist can slow LH pulsatility (25), and this has also been demonstrated in women with polycystic ovary syndrome (26) where LH pulse frequency is often increased.
We have investigated the role of kisspeptin and NKB signaling in the regulation of positive estrogen feedback in women by administration of an NKB receptor antagonist and an infusion of kisspeptin-10 during exogenous estrogen administration. We hypothesized that in this model of estrogen-induced LH secretion, kisspeptin would augment LH secretion, and that pharmacological blockade of NKB signaling would reveal the functional hierarchy between kisspeptin and NKB in generating the preovulatory LH surge, and in modulating GnRH/LH pulsatility.

Participants
Twenty healthy women, aged 18 -45 years with regular menstrual cycles (25-35 days) were recruited from the community to this study, which was approved by South East Scotland Research Ethics Committee (Ref: 09/S1101/67); all volunteers provided informed written consent. Subjects were not taking steroidal contraception, had normal physical examination, and full blood count, renal function, electrolytes, liver function and electrocardiogram (ECG) were within normal limits.

Study drugs
Kisspeptin-10 was custom synthesized under GMP standards (Bachem GmBH, Weil am Rhein, Germany) (12). 1 mg kisspeptin-10 was dissolved in 5 ml sterile normal (0.9%) saline immediately before infusion. The syringe and line for infusion were first coated for 30 minutes with kisspeptin-10 to minimize peptide loss from adherence to the plastic. Sterile normal saline was infused as vehicle. The specific neurokinin-3 receptor (NK3R) inhibitor AZD4901, formulated as 20 mg tablets, was gifted by AstraZeneca, UK. Transdermal patches releasing 200 g 17␤ estradiol per 24 hours (Janssen-Cilag Buckinghamshire, UK) were used as exogenous estradiol treatment (27).

Protocol
To standardize estrogen exposure and the onset of increased LH secretion, we used a model of follicular phase administration of transdermal estradiol (200 g/d), which initially suppresses then at 48 hours increases LH secretion (28). In preliminary studies (Supplemental Figure 1) we confirmed that LH secretion at 48 hours is increased to the same extent if the patches were removed at 32 hours or continued till 72 hours: for the main study therefore patches were removed at 32 hours. Sample size was based on previous proof of concept mechanistic studies (12,15). Twenty women were randomly allocated to NK3R antagonist (AZD4901) 40 mg oral twice daily starting from cycle day 4 -6 for 6 days, or no treatment ( Figure 1). Two transdermal estradiol patches were administered after 5 days (time 0 hours), in the late follicular phase (cycle day 9 -11, according to the day of starting AZD4901). At 24 hours of estradiol treatment volunteers attended our clinical research facility for 8 hours. After an hour of baseline sampling, volunteers were randomized (using sealed envelopes) to receive a continuous intravenous (IV) infusion of kisspeptin-10 (4 g/kg/hr) or vehicle for 7 hours. In the NK3R antagonist treatment group, the last dose of AZD4901 was on the morning of kisspeptin-10 or vehicle administration. Estradiol patches were removed at the end of the infusion ie, 32 hours after application. Volunteers attended for further measurement of reproductive hormones at 48 and 72 hours. In a subsequent menstrual cycle, all women returned to receive the alternate infusion of kisspeptin-10 or saline. Those receiving NK3R antagonist had at least one wash out cycle between treat-ment cycles. To compare the effect of exogenous vs endogenous estrogen on kisspeptin-10 response, another group of ten women received IV kisspeptin-10 (4 g/kg/hr) infusion for 7 hours on cycle day 10 -12 without exogenous estrogen treatment, with reproductive hormone measurements at equivalent time points.

Blood sampling and hormone assays
Peripheral venous blood was sampled for LH, FSH and estradiol in the treatment group on the day of commencing NK3R antagonist and in both control and treatment groups before estradiol treatment (0 hour) and then at 24, 32, 48 and 72 hours. During the 8 hour visit, blood samples were collected via an indwelling iv cannula at 10 minutes intervals for assessments of LH pulsatility; FSH was measured hourly. Blood samples were centrifuged at 4°C for 10 minutes at 3000 rpm and serum frozen at -20°C or below until analysis. LH and FSH were determined by ELISA as previously described (12). 17␤-estradiol was measured by ELISA (Demeditec Diagnostics, Kiel, Germany). Interassay and intra-assay coefficient of variation for all hormones was Ͻ 5% at the concentrations measured. Lower detection limit for LH and FSH was 0.1 IU/l and for estradiol 20 pmol/l.

Statistical analysis
Analysis of variance (ANOVA) was used to analyze preliminary data on LH changes with time in the model. For the primary endpoints, hormone concentrations were compared between the four treatment groups at specific time points using ANOVA with repeated measures as appropriate. If there was overall significance, post hoc analysis was performed with Bonferroni's correction for multiple comparisons, comparing all four treatments simultaneously at each time point. The relationship between the timing of peak LH and treatment was assessed by 2 test. Pearson correlation coefficient was computed to assess the relationship between estradiol concentrations and LH response to kisspeptin-10.
The number of LH pulses, secretory mass of LH per pulse, basal (nonpulsatile) and pulsatile (integral of dual amplitude and frequency regulation) LH secretion were identified by an established deconvolutional algorithm with cluster analysis (93% sensitivity and specificity) (29,30) blinded to treatment allocation. Approximate entropy (ApEn), a measure of orderliness, was also estimated for the pattern of LH secretion. Deconvolutional estimates and mean hourly hormone changes were not calculated for one woman in each group, as full 8 hour sampling data were not obtained. ANOVA was used to assess changes in LH pulsatility parameters between the 4 groups, with post hoc testing as above.
Data are presented as mean Ϯ SD. Data not normally distributed were logtransformed prior to statistical analysis, resulting in a distribution that approximated a normal distribution. Differences were regarded as significant at a twosided P Ͻ .05. The statistical software package GraphPad Prism (GraphPad, San Diego, California) was used.

Results
Baseline age, BMI and the menstrual cycle length were comparable between the subjects in the control and the treatment group, as were baseline LH, FSH and estradiol levels in vehicle and kisspeptin-10 cycles within the group (Table 1).

Model validation for estrogen-induced LH secretion
Treatment with exogenous estrogen for 32 hours increased serum estradiol concentrations as expected (P Ͻ .0001) (Supplemental Figure 1). Serum LH was initially suppressed at 32 hours of estrogen treatment, then increased at 48 hours which persisted at 72 hours (all P Ͻ .05 vs 0 hours). FSH concentrations were significantly lower at 24 (P Ͻ .01) and 32 hours (P Ͻ .0001) but were not higher at 48 and 72 hours compared to baseline. This confirms that with this regimen, estrogenic negative feedback is followed by increased LH secretion, thus standardizing estrogen exposure and the time course of changes in LH secretion.

Kisspeptin-10 stimulates gonadotropin secretion
During estrogen administration, kisspeptin-10 stimulated LH secretion to 16.4 Ϯ 12.4 IU/l at the end of infusion vs 2.9 Ϯ 1.0 IU/l following vehicle administration (P Ͻ .0001) (Figure 2A). The time course of this response is shown in Figure 3A. Kisspeptin-10 induced LH secretion persisted beyond the discontinuation of the infusion Ten healthy women were administered NK3R antagonist AZD4901 from cycle day 4 -6 for 6 days, matched to ten women having no treatment. Transdermal estradiol was applied after 5 days. 24 hours later, women were randomized to 7 hour of kisspeptin-10 or vehicle infusion, returning in a subsequent cycle for the alternate infusion. Reproductive hormones were measured throughout the study and LH pulsatility assessed during 10 minute blood sampling for 8 hours.
doi: 10.1210/jc.2016-2132 press.endocrine.org/journal/jcem with higher peak LH compared to controls at 48 hours (9.3 Ϯ 1.9 vs 21.6 Ϯ 13.0 IU/l, P ϭ .007) (Supplemental Table 1). Clarification of the impact of exogenous estradiol on this response was demonstrated in a separate group of women receiving kisspeptin-10 infusion only in the late follicular phase without exogenous estrogen administration, who showed a similar acute increase in LH secretion correlating positively with estradiol concentration (r 2 ϭ0.63, P ϭ .006), but of a shorter duration (48 hours: 6.8 Ϯ 5.8 IU/l vs 15.0 Ϯ 11.4 with estrogen treatment, P Ͻ .01; Supplemental Figure 2). All subjects in the endogenous estrogen group had peak LH at the end of kisspeptin-10 infusion, whereas in exogenous estrogentreated subjects the kisspeptin-10 induced peak LH persisted beyond kisspeptin-10 infusion with 50% of women having peak LH at 32 hours and 50% at 48 hours (P Ͻ .01, Supplemental Table 1). FSH secretion was also significantly higher at the end of kisspeptin-10 infusion compared to vehicle in the control group (P Ͻ .05) but not different to baseline (0 hours; Figure 2B, 3B). As expected with this model of exogenous estradiol administration, estradiol concentrations were similar in kisspeptin-10 and vehicle-infused controls (Figure 2C).

NK3R antagonist has differential effects on LH and FSH secretion
Serum LH levels did not change after 5 days of NK3R antagonist treatment (before the estradiol patches were applied) when compared to either pretreatment concentrations (pre NK3Ra 5.0 Ϯ 1.8 vs 5 days NK3Ra 6.6 Ϯ 4.0 IU/l, ns) or to controls (Figure 2A). Overall there was no difference in LH concentrations and the timing of peak LH in controls vs NK3Ra-treated women (Supplemental Table 1 and Figure 2A). To detect subtle changes in hormone secretion potentially overlooked by single time point blood sampling, analysis of hourly LH for 8 hours post dose showed that overall LH secretion was lower in Table 1. Baseline characteristics of women in the control and the treatment group undergoing vehicle and kisspeptin-10 infusion. Data are shown as mean Ϯ SD; ns, not significant. Note that baseline data on control and treatment groups in lower part of the  NK3Ra-treated women compared to controls (P Ͻ .0001, Figure 3A), although post hoc analysis indicated no significant differences in LH levels at any individual hourly time point. FSH concentrations appeared higher throughout treatment with NK3R antagonist compared to controls ( Figure  2B) and were significantly higher in NK3Ra-treated women throughout the eight-hour period (ie, during saline infusion, P Ͻ .0001) ( Figure 3B). This may reflect that serum estradiol concentrations were significantly lower after 5 days of treatment with NK3R antagonist compared to controls (P Ͻ .05) ( Figure 2C) and comparable to estradiol levels before NK3R antagonist administration (pre NK3Ra: 121 Ϯ 54 vs 145 Ϯ 87 pmol/l after 5 days NK3Ra, ns).
However, NK3Ra blunted the duration of kisspeptin-10 induced LH secretion, with significantly lower LH at 48 hours (15.0 Ϯ 11.4 vs 7.5 Ϯ 4.8 IU/l, P Ͻ .05) when compared to kisspeptin-10 infused controls, whereas FSH showed no significant difference ( Figure 2). There were related changes in the timing of the LH peak (although not statistically significant), which was at 32 hours in 9/10 NK3Ra-treated women in response to kisspeptin-10 infusion, compared with kisspeptin-10 treated controls whose LH peak timing was evenly divided between 32 and 48 hours (Supplemental Table 1).

NK3R antagonist impedes estradiol dependent kisspeptin-10 response
The relationship between LH response to kisspeptin-10 and estradiol exposure, and the influence thereon of NK3Ra treatment, was investigated by analyzing LH concentration at the end of kisspeptin-10 infusion in relation to endogenous estradiol concentrations at 0 hours (ie, before transdermal estradiol application). There was a strong positive correlation in controls (r 2 ϭ0.75, P ϭ .001) (Figure 4). However, in NK3Ra-treated women, the LH response to kisspeptin-10 showed no such relationship (r 2 ϭ0.007, ns). Very similar results were obtained when the analysis was based on estradiol concentrations after 24 hours of patch administration (r 2 ϭ0.65, P ϭ .005 in controls; r 2 ϭ0.03, ns in NK3Ra-treated women).

Interaction between NK3R antagonist and kisspeptin-10 in regulating LH pulsatility
LH pulse frequency increased from 0.7 Ϯ 0.2 pulses/hr in vehicle cycle to 1.0 Ϯ 0.2 pulses/hr during kisspeptin-10 infusion (P Ͻ .01) ( Figure 5A, B). NK3R antagonist reduced LH pulsatility to 0.5 Ϯ 0.2 pulses/hr (P Ͻ .05 vs vehicle-infused controls), but administration of kisspeptin-10 to NK3Ra-treated women restored LH pulse frequency to that observed in kisspeptin-10-infused controls. Thus while NK3Ra slowed LH pulsatility in estrogen treated women, it did not affect the response to kisspeptin-10, indicating that kisspeptin effects are downstream of NKB signaling.
Secretory mass of LH per pulse was increased similarly during infusion of kisspeptin-10 compared with vehicle in both control (P Ͻ .05) and NK3R antagonist treated women (P Ͻ .01) ( Figure 5C). NK3Ra antagonist did not reduce LH secretory mass per pulse.
Consistent with increased LH pulse frequency, basal LH secretion decreased and pulsatile LH secretion in- press.endocrine.org/journal/jcem creased during kisspeptin-10 infusion in the control group (P Ͻ .05 vs vehicle; Figure 5D, E). Basal LH secretion appeared lower in NK3Ra-treated women when compared to controls but there was no effect on pulsatile LH secretion. Kisspeptin-10 induced the same changes in NK3Ra treated women as in controls, with no change in basal and an increase in pulsatile LH secretion (P Ͻ .0001). The regularity of LH secretory pattern was assessed by approximate entopy (ApEn). Both kisspeptin-10 infusion and NK3Ra separately imposed greater orderliness (lower ApEn) in LH secretion (P Ͻ .05; Figure 5F). This was increased further in NK3Ra-treated women during kisspeptin-10 infusion (P Ͻ .0001 vs NK3Ra alone; Figure 5F).

Discussion
In a model of LH modulation by estrogen administration in women, exogenous kisspeptin-10 stimulated LH secretion, the extent of which reflected estradiol concentrations. Pharmacological blockage of NKB-NK3R signaling slowed LH pulsatility and shortened the duration of kisspeptin-mediated LH secretion with 'sharpening' of the LH response, and strikingly abolished the relationship between estradiol and LH response to kisspeptin. Taken to-   secretion (D), pulsatile LH secretion (E) and the relative orderliness/regularity of LH secretory pattern (F) during vehicle and kisspeptin-10 infusion with (n ϭ 9) and without (n ϭ 9) pretreatment with NK3R antagonist. Mean Ϯ SD. * , P Ͻ .05; ** , P Ͻ .01; **** , P Ͻ .0001.

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NKB/kisspeptin interaction in estrogen feedback J Clin Endocrinol Metab gether, these data support a central role for kisspeptin in the modulation of GnRH/LH secretion, and while NKB signaling is largely upstream of kisspeptin as previously reported (13), both pathways interact in determining the timing and characteristics of estrogenic negative and positive feedback on LH secretion. The stimulatory effect of exogenous kisspeptin on LH secretion in women is dependent on the sex steroid environment (15)(16)(17)(18). This response is initially limited but increases markedly in the late follicular phase of the menstrual cycle when estradiol levels are rising (16 -18). For most of the cycle, GnRH and thus LH secretion are inhibited by negative feedback from estradiol (and progesterone in the luteal phase), thus the low responsiveness to kisspeptin administration in previous studies is consistent with endogenous kisspeptin signaling being suppressed by the inhibitory steroidal actions, presumably at the GnRH neuron and/or gonadotroph level. Conversely, the enhanced LH response in the later follicular phase may indicate the development of increased endogenous kisspeptin signaling in the lead up to the midcycle surge. This is supported by animal studies, where kisspeptin expression is highest following an estrogen challenge in the anteroventral periventricular nucleus (the site of positive estrogen feedback in rodents) in ovariectomized mice (31) and at the time of GnRH/LH surge in sheep (32), but is prevented by administration of kisspeptin receptor antagonist (20,21). The present data suggests a role of estradiol in modulating LH response to kisspeptin-10 infusion, which persisted well beyond the pharmacokinetic clearance of the exogenous kisspeptin-10. The striking positive relationship between estradiol concentration in the late follicular phase and the LH response to kisspeptin-10 infusion lends further support for the involvement of kisspeptin in estrogen feedback, as recently demonstrated for kisspeptin-54 (33).
The present data demonstrate that NK3R antagonist treatment, in an environment of high estrogenic negative feedback, reduced LH secretion and pulse frequency, while in the presence of kisspeptin-10 had a stimulatory effect on the secretion of both gonadotropins, but with a shorter duration of LH response. Hitherto, NK3R antagonists have been demonstrated to suppress LH secretion in states of high LH output, such as in women with PCOS (26), or in the ovariectomized ewe and castrate monkeys (25,34), and in intact female monkeys a delay of surge-like but no decrease in basal LH secretion was observed (25). Although it appears that the suppression of LH secretion by the present dose and regimen lasted only a few hours, this was sufficient to significantly lower estradiol concentrations after 5 days of NK3R antagonist treatment (ie, prior to the estrogenic treatment) compared to controls.
While this demonstrates a role of NKB in the regulation of LH secretion, NK3R antagonist had no effect on the timing of peak LH secretion in this model of estrogen administration, which is consistent with a lack of effect of NK3R antagonist on the estrogen induced LH surge seen in ovariectomised ewes (34). The mechanisms critical for progression to positive estrogen feedback therefore appear to be largely independent of NKB but dependent on kisspeptin, consistent with rodent neuroanatomical data (31,35). A recent study using a different NK3R antagonist in normal women also showed a temporary suppression of LH levels lasting few hours post dosing, but no overall decrease in basal LH secretion following treatment throughout the follicular phase (34). NK3Ra did, however, delay LH surge in some women, probably as a consequence of delayed preovulatory estradiol rise, but the study did not assess the effect of neurokinin B antagonism at the time of the switch from negative to positive estrogen feedback, when NKB might be no longer critical (36). Unlike in the present study, no effect of NK3Ra on FSH secretion was observed (35).
We have previously demonstrated that infusion of kisspeptin-10 can restore LH pulsatile secretion in men and women with inactivating mutations in NKB signaling, indicating that kisspeptin is functionally downstream of NKB in LH pulse generation (13). This is supported by the inability of the NK3R agonist senktide to stimulate LH secretion in Kiss1r knockout mice (7). Consistent with this overall hierarchy, NKB antagonism (active during kisspeptin-10 administration as half life of AZD4901 is 8.5 hours (37)) did not prevent the stimulatory effect of kisspeptin-10 infusion on LH secretion. NKB antagonist however shortened the LH response to kisspeptin-10, affecting its timing by reducing the variability of peak LH secretion, and disrupted the relationship between LH response and estradiol concentrations. These findings suggest a more complex interaction than a linear pathway between those neuropeptides at the time of the midcycle LH surge, but are also consistent with NK3R antagonist reducing endogenous kisspeptin stimulation of GnRH as a contribution to the observed effect.
LH pulse frequency increases in the late follicular phase, culminating in the midcycle LH surge (38). Exogenous kisspeptin stimulates pulsatile LH secretion (12,13,22,23,39), but its role as a potential contributor to positive estrogen feedback has not been previously investigated. In this study, the increase in LH secretion during kisspeptin-10 infusion included increased LH pulse frequency and mass-per-secretory pulse. This resulted in a larger proportion of total LH secretion occurring in pulsatile bursts, and the regularity of LH secretory pattern showed greater orderliness in the lead up to the stimula- press.endocrine.org/journal/jcem tory phase of response to estrogen. Deconvolution analysis also indicated changes in the nature of the pulsatile LH secretion following NK3R antagonist administration, with reduced basal secretion and ApEn, indicating a more orderly, slowed pattern of LH and by inference GnRH secretion. The increase in LH pulse frequency resulting from kisspeptin-10 infusion and the slowing in LH pulsatility with NK3R antagonist administration both increased the regularity and orderliness of LH secretion and may be the basis for the reduced variability in the timing of peak LH secretion as well as shortened duration of stimulated LH secretion in response to kisspeptin-10. Consistent with some aspects of our findings, estrogeninduced LH surges were preserved in ovariectomized NK3R antagonist-treated ewes, although the onset-topeak time was delayed (34). In sheep, the NK3R agonist senktide increased LH secretion, resembling 'surge-like' LH levels (9), while in monkeys, NK3R antagonist abolished LH surge, ovulation and subsequent progesterone rise (25). While our data primarily indicate that NKB signaling is largely upstream of kisspeptin signaling in mediating estrogenic positive effects, it clearly has a modulatory role in determining the pattern and duration of GnRH secretion during estrogen positive feedback. A stimulatory effect of kisspeptin alone on FSH has been minimal and inconsistent in previous studies (16 -18, 40), but was robustly demonstrated in this model and was not prevented by NK3R antagonist treatment. NK3R antagonist also increased FSH secretion, and markedly augmented stimulation by kisspeptin-10. These findings are consistent with well-established data from animal models showing that high GnRH pulse frequency favors LH secretion while low pulse frequency favors FSH secretion (24), and that this is the main drive to follicular estrogen production, the reduction in both of which (and presumed reduced inhibin production) is likely to have resulted in the observed increased FSH secretion. The differential effects of NK3Ra on FSH vs LH response to kisspeptin-10 are also similar to the effects in patients with NKB defects (13).
While the present study has clear strengths (the use of specific neurokinin-3 receptor antagonist, detailed LH pulse profiling and blinded pulse analysis), there are weaknesses. The sample size is small, and placebo was not administered to the control group receiving no NK3Ra. The limited LH suppression by the NK3R antagonist might be due to the small sample size and the dose of AZD4901 may be low compared to those used in animal studies, limiting the response (25). Statistical analyses included adjustment for alpha for multiplicity of comparisons but studies such as these should be regarded as mechanistic explorations. Moreover, this model of LH secretion after exogenous estrogen administration may not fully replicate physiological positive estrogen feedback in the preovulatory state.
In summary, using estrogen to standardize LH secretion in women to model the midcycle LH surge, we have shown that the increase in LH secretion by kisspeptin-10 infusion is related to estradiol exposure. We show for the first time that NK3R antagonist reduced LH pulsatility in healthy women. Assessment of the interaction between kisspeptin and NKB showed that the duration of kisspeptin-mediated LH secretion was shortened by the NK3R antagonist, and the quantitative relationship with estradiol exposure abolished. These data thus indicate that NKB pathways regulate GnRH/LH secretion in women, are predominantly upstream of kisspeptin signaling in mediating estrogen feedback, but modify this kisspeptin response. This extends our understanding of these critical events in human reproduction.