A gamma-aminobutyric acidB agonist reverses the negative feedback effect of testosterone on gonadotropin-releasing hormone and luteinizing hormone secretion in the male sheep.

Infusion of baclofen, a GABA(B) agonist, into the medial basal hypothalamus (MBH) of castrated rams rapidly increases LH pulse amplitude without altering pulse frequency. The objectives of this study were to determine whether baclofen infusion increased LH in testosterone (T)-treated and intact rams, the increased LH was due to increased GnRH release, and FSH secretion also was increased. In the first experiment we tested the main effects and interaction of baclofen and T on FSH and LH pulse patterns in castrated rams (n = 7). In the second experiment we determined whether baclofen affected GnRH and LH pulses in intact males. Microdialysis guide cannulae were implanted bilaterally into the MBH. After recovery of the animal from surgery, the MBH was perfused using concentric microdialysis probes (2-mm tip) with artificial cerebrospinal fluid (aCSF) for a 3-h control period followed by either aCSF or 1 mM baclofen for 4 h. Blood samples were taken at 10-min intervals. T suppressed mean LH concentrations (10.4 +/- 1.3 vs. 3.3 +/- 1.3 ng/ml) such that LH pulses were undetectable in some T-treated animals during the control period. The change (control period vs. drug infusion period) in mean LH was greater in response to baclofen than in response to aCSF and was not altered by T. The baclofen x T interaction was nonsignificant. Mean FSH was decreased by T, but was not altered by baclofen. In the second experiment hypophyseal portal blood was collected coincident with microdialysis. Infusion of baclofen into the MBH of intact males (n = 7) resulted within 1 h in the onset of frequent and robust GnRH pulses (0.10/h before baclofen vs. 1.57/h after baclofen) that were followed either immediately or gradually by coincident LH pulses. One interpretation is that baclofen acts downstream of the site of action of T. GABA(B) receptors may regulate pulse amplitude in both the presence and absence of T and regulate pulse frequency by modulating the inhibitory effect of T.

Interactions of photoperiod, testosterone, and naloxone on GnRH and LH pulse parameters in the male sheep.

This study tested the hypothesis that the effects of the opiate antagonist naloxone on GnRH (and LH) secretion is affected by photoperiod length and testosterone (T) concentrations. The effect of infusing naloxone on GnRH and LH pulse patterns was determined in four groups of orchidectomized sheep: long day (LD) photoperiod treated with T, LD without T (LDC), short day photoperiod (SD) with T, SDC (n = 5-7/group). Hypophyseal-portal and jugular blood samples were collected at 10 min intervals for 4 h before and 4 h during naloxone infusion (1 mg/kg/h). Neither photoperiod nor T affected either mean GnRH or LH whereas naloxone (P < 0.01) increased both. LD photoperiod (P < 0.01), T (P < 0.01) and naloxone (P < 0.01) all increased LH pulse amplitude whereas only naloxone increased GnRH pulse amplitude (P < 0.01). There was an interaction (P < 0.01) between steroid and naloxone on LH, but not GnRH, pulse amplitude. Both LD photoperiod and T increased both LH and GnRH (P < 0.01) interpulse-interval (IPI). Naloxone decreased GnRH IPI (P < 0.01). The LH/GnRH pulse amplitude ratio was (P < 0.02) increased by T--likely a secondary response to the T-induced increase in IPI. These results are interpreted as showing that in the ram the endogenous opiate peptides regulate both GnRH pulse frequency and amplitude, but that their specific role is modulated by photoperiod and T. These results do not support the concept that the opiate peptides are the primary mediators of the negative feedback effects of T.

Temporal effects of estradiol (E) on luteinizing hormone-releasing hormone (LHRH) and LH release in castrated male sheep.

We tested the hypothesis that rapidly expressed inhibitory effects of estradiol (E) on luteinizing hormone (LH) release in the male are attributable, in part, to suppression of luteinizing hormone-releasing hormone (LHRH) release. Hypophyseal-portal cannulated, castrated male sheep were infused with E (15 ng/kg/hr) or vehicle. Portal and jugular blood samples were collected at 10-min intervals for 4 hr before, and for either 12 hr (E, n = 4; vehicle, n = 4) or 24 hr (E, n = 8; vehicle, n = 3) after the start of infusion. In animals sampled for 16 hr, temporal changes in both LHRH and LH were assessed. In animals sampled for 28 hr, only LH data were analyzed. Before either the 12-hr or 24-hr infusion, LHRH and/or LH mean concentrations, pulse amplitude and interpulse interval (IPI) did not differ between E- and vehicle-infused animals. In animals sampled for 16 hr, no effects of time or steroid x time interactions were detected for mean LHRH and LHRH pulse amplitude; however, both were greater (P < 0.01) in vehicle-infused than in E-infused males. LHRH IPI was unaffected by infusion. In contrast, both mean LH and LH pulse amplitude declined (P < 0.01) within 4-8 hr after the start of E infusion, whereas mean LH IPI was unaffected. In animals sampled for 28 hr, an effect of time (P < 0.01) and a steroid x time interaction (P < 0.01) was detected for mean LH, and there was an effect of time (P < 0.01) on LH pulse amplitude. Mean LH IPI was not affected. Our results show that in male sheep E rapidly reduces LH release in the absence of a detectable change in LHRH release.

Photoperiod affects the ability of testosterone to alter proopiomelanocortin mRNA, but not luteinizing hormone-releasing hormone mRNA, levels in male sheep.

This study tested the hypothesis that photoperiod affects the ability of testosterone to reduce proopiomelanocortin (POMC) mRNA levels in the arcuate nucleus and luteinizing hormone-releasing hormone (LHRH) mRNA levels in both the preoptic area (POA) or medial basal hypothalamus (MBH). Twenty castrated male sheep were assigned to one of four treatment groups (i): short days (SD; n=5) (ii), short days with testosterone (SD+T; n=5) (iii), long days (LD; n=5), or (iii) long days with testosterone (LD+T; n=5). Blood samples were collected twice weekly for the last 3 weeks of photoperiod treatment and assessed for LH to validate the response to photoperiod. After evaluating LH levels, one animal each from the LD+T and SD+T groups was excluded from the analyses. Mean concentrations of LH were lower (P<0.01) in the LD+T group than in the other treatment groups, which did not differ (P>0.10) from each other. Neither POA nor MBH LHRH mRNA levels were affected (P>0.10) by treatment. Conversely, POMC mRNA levels were suppressed (P<0.01) in the LD+T males compared with the other treatment groups which did not differ (P>0.10) from each other. These observations suggest that photoperiod specific, testosterone-induced alterations in LHRH mRNA levels are not a mechanism whereby testosterone suppresses LHRH release, and that increased beta-endorphin synthesis and release do not mediate testosterone-induced seasonal suppression of LHRH release.

Effects of dialyzing gamma-aminobutyric acid receptor antagonists into the medial preoptic and arcuate ventromedial region on luteinizing hormone release in male sheep.

We investigated the effects of microdialyzing alpha-aminobutyric acid (GABA) receptor antagonists into either the medial preoptic area (mPOA) or the arcuate-ventromedial region (ARC-VMR) on LH secretion. Bicuculline methiodide (BMI, GABA(A) receptor antagonist), and either 2-hydroxysaclofen (SAC) or CGP 55845A (CGP, GABA(B) receptor antagonists) were used. In experiment 1, castrated rams received 4-h dialysis into either the mPOA (n = 5) or ARC-VMR (n = 4) of artificial cerebrospinal fluid (aCSF) followed by 4 h of either BMI (aCSF-BMI, 375 microM in mPOA, 1 mM in the ARC-VMR for 2-1/2 h), or aCSF-SAC (5 mM). In experiment 2, castrated rams received dialysis only in the ARC-VMR (n = 5) of aCSF-aCSF, aCSF-BMI (375 microM), or aCSF-CGP (50 microM). In experiment 3, untreated or testosterone (T)-treated castrated rams (n = 6/group) received dialysis only in the ARC-VMR of aCSF-aCSF, aCSF-BMI (375 microM), or aCSF-CGP (500 microM). Jugular blood was collected at 10-min intervals. In experiment 1, BMI suppressed mean plasma LH (p < 0.05) and increased interpulse interval (IPI, p < 0.05) at both sites. In experiment 2, BMI significantly reduced mean LH and increased IPI (p < 0.01). In experiment 3, BMI reduced mean LH in both the presence (p < 0.05) and absence of T (p < 0.01) and increased IPI (p < 0.01) in the absence of T. SAC, CGP, and aCSF did not affect LH in any experiment. These results show that dialysis of BMI, into either the mPOA or the ARC-VMR of either castrated or T-treated castrated rams decreased LH release, whereas dialysis of GABA(B) antagonists at these sites was without detectable effect.

Effect of infusing gamma-aminobutyric acid receptor agonists and antagonists into the medial preoptic area and ventromedial hypothalamus on prolactin secretion in male sheep.

We investigated the effects of gamma-aminobutyric acid (GABA) agonists muscimol and baclofen (GABA(A) and GABA(B) agonists, respectively) and antagonists bicuculline methiodide (BMI, GABA(A) antagonist) or 2-hydroxysaclofen (SAC) and CGP 55845A (GABA(B) antagonists) on prolactin (PRL) secretion in castrated rams. The drugs were applied by microdialysis into either the medial preoptic area (mPOA) or ventromedial hypothalamus (VMH). Dialysis of baclofen into the mPOA significantly increased mean PRL (p < 0.05), whereas SAC caused a small, but significant decrease (p < 0.01). Dialysis of either muscimol or BMI into the mPOA had no effect on prolactin. In the VMH, baclofen significantly increased (p < 0.01) mean PRL but SAC and CGP 55845A were ineffective, whereas dialysis of either muscimol or BMI increased mean prolactin (p < 0.01). These results show that infusion into the mPOA of drugs that affect GABA(B) receptor alter PRL release, whereas infusion of a GABA(A) agonists and antagonist was without effect on PRL release. In contrast, infusion of both GABA(A) and GABA(B) agonists and a GABA(A) antagonist into the VMH altered PRL secretion. This suggest that GABAergic neurons in both regions participate in regulating PRL secretion, but by different receptor systems.

Hypothalamic sites of action for testosterone, dihydrotestosterone, and estrogen in the regulation of luteinizing hormone secretion in male sheep.

Testosterone (T) inhibits LH secretion partly by acting at unknown sites within the brain to inhibit GnRH secretion. We tested the hypothesis that the preoptic area (POA) and arcuate-ventromedial region (ARC/VMR), areas rich in androgen and estrogen (E) receptors, are neural sites at which T and the T metabolites, dihydrotestosterone (DHT) and estrogen (E), act to suppress LH secretion. Bilateral guide cannulae were surgically implanted into either the POA or ARC/VMR of castrated male sheep. Experiments were conducted under a long day photoperiod to maximize the inhibitory effect of the steroids. In Exp 1, all sheep (n = 6/site) sequentially received bilateral implants of cholesterol (CHOL), T, or E at each site. Jugular blood samples were taken at 10-min intervals for 4 h both immediately before implant insertion and 5 days later. In Exp 2, all sheep (n = 6/site) sequentially received bilateral implants of CHOL, DHT, or E at each site according to a latin square design. Blood samples were taken before and 7 days after implant insertion. In Exp 3, which followed the same design as Exp 2, implants of E, T, or DHT were placed only in the ARC/VMR. In the final experiment, the effects of T and CHOL implants in the ARC/VMR were compared. Neither T, DHT, nor CHOL implants at either site affected LH secretion. In contrast, E treatment in the ARC/VMR suppressed mean plasma LH levels (P < 0.01), primarily due to an increase in interpulse interval (P < 0.01). Estrogen implants in the POA caused a small, but nonsignificant (P > 0.05), decrease in mean LH levels in the first experiment and an increase in LH interpulse interval (P < 0.05) in the second experiment. These results suggest that the ARC/VMR and possibly the POA are sites at which E acts to reduce GnRH secretion in male sheep.

Identification and distribution of neuroendocrine gonadotropin-releasing hormone neurons in the ewe.

The final common pathway controlling reproductive function in vertebrates is the GnRH neuron and its projection to the median eminence (ME), site of peptide release into the pituitary portal system. GnRH neurons are widely distributed; therefore we sought to test the hypothesis that those projecting to the ME are located in specific regions. We used as a model the sheep, a species in which a great deal of information regarding the physiology of GnRH secretion is known. To identify cells projecting to the ME (i.e., neuroendocrine neurons), ewes (n = 10) received injections into the ME of neuronal tract-tracing compounds: cholera toxin-beta subunit (CT-beta) or one of two fluorescent compounds (rhodamine isothiocyanate or fluorescein-conjugated dextran). Forty-eight h later, animals were perfused intracranially and their brains were processed for immunocytochemical localization of GnRH and CT-beta using a dual-immunofluorescent procedure or by single-label immunofluorescent visualization of GnRH combined with direct visualization of fluorescent tracers. Small, well-circumscribed injections into the ME were made successfully in 6 of 10 animals, and these overlapped the location of GnRH terminals and fibers. Neuroendocrine GnRH neurons (those GnRH neurons containing retrogradely transported tracer) were identified throughout their previously reported range: within the diagonal band of the Broca/medial septal region, medial preoptic area (MPOA), anterior hypothalamic area, and medial basal hypothalamus. Although the absolute number of neuroendocrine GnRH neurons varied by region, the percentage of the total GnRH population within each of these areas that was retrogradely labeled did not differ (p > 0.05). Injections placed unilaterally within the ME labeled a similar proportion of GnRH cells both ipsilateral and contralateral to the injection site in all areas except the MPOA, where ipsilaterally labeled cells were approximately twice as numerous as those labeled contralaterally. Injections that missed the ME and were placed either into the third ventricle or into the arcuate nucleus labeled only 0.5% and 4-11% of GnRH neurons, respectively. These results do not support the hypothesis that in the ewe, GnRH neurons projecting to the ME are localized to specific regions. Thus, we postulate that GnRH release into the hypophyseal portal system reflects the output of GnRH neurons located in multiple areas.

Differential regulation of luteinizing hormone release by gamma-aminobutyric acid receptor subtypes in the arcuate-ventromedial region of the castrated ram.

We investigated the effects on LH secretion of infusing gamma-aminobutyric acid (GABA) agonists muscimol and baclofen (GABAA and GABAB receptor agonists, respectively) into either the medial preoptic area (mPOA) or the arcuate-ventromedial region (ARC-VMR) of the hypothalamus of castrated rams during the nonbreeding season. Bilateral microdialysis of artificial cerebrospinal fluid for 4 h followed by treatment with artificial cerebrospinal fluid, baclofen (1 mM), or muscimol (1 mM in the ARC-VMR, 250 microM in the mPOA) for 4 h was carried out on three separate occasions in random order. Simultaneously, jugular venous blood was collected at 10-min intervals, and plasma later was assayed for LH. The estimated dose of baclofen delivered to each unilateral microdialysis site was 7.9 micrograms; for muscimol, it was 1.1 micrograms for the mPOA and 4.5 micrograms for the ARC-VMR. In the mPOA, baclofen had no detectable effect, whereas muscimol had a delayed suppressive effect on mean LH (P < 0.01). In the ARC-VMR muscimol rapidly reduced mean LH (P < 0.01). In contrast, baclofen increased mean LH (P = 0.01) and LH pulse amplitude (P = 0.05) without altering the LH interpulse interval (P > 0.10). These results support the involvement of GABAA receptors in the mPOA in regulating LH secretory patterns. More importantly, both GABAA and GABA(B) receptors in the ARC-VMR appear to differentially modulate LH and, presumably, GnRH release. Whether GABA acts directly on the GnRH neuron or indirectly through other neural systems remains to be determined.

Influence of testosterone on LHRH release, LHRH mRNA and proopiomelanocortin mRNA in male sheep.

The mechanism whereby testosterone (T) reduces pulsatile LHRH and LH release is unknown. We tested the hypothesis that hypothalamic levels of LHRH mRNA decrease and proopiomelanocortin (POMC) mRNA increase coincident with reduced LHRH release induced by either long-term or short-term T treatment in male sheep. Experiment 1 examined the effect of long-term T exposure on LHRH and LH release and LHRH and POMC mRNA levels. Yearling Suffolk rams were castrated and assigned to one of four treatments: 1) castrated (n = 4); 2) castrated, portal cannula (n = 5); 3) castrated+T (n = 4) and 4) castrated+T, portal cannula (n = 4). T-treated males received ten 10-cm silastic T-implants immediately after castration. Surgical placement of devices for collecting hypophyseal-portal blood occurred 2 to 3 months after castration. Seven to 10 days after surgery, blood samples were collected at 10-min intervals for 8 h from portal cannulated males or for 5 h from non-cannulated males to assess pulsatile LHRH and/or LH release. Immediately after blood sample collection, hypothalamic tissue was collected for in situ measurement of LHRH or POMC mRNA. T-treatment decreased (P < 0.01) mean LHRH and LH and decreased (P < 0.01) LHRH and LH pulse frequency. T did not significantly affect (P > 0.10) silver grain area per LHRH neuron, but decreased (P < 0.01) silver grain area per POMC neuron. Portal cannulation tended to decrease (P = 0.057) silver grain area per LHRH neuron without significantly affecting (P > 0.10) LHRH cell numbers while reducing (P < 0.01) silver grain area per POMC neuron and POMC cell numbers. A second experiment examined the effect of 72 h of T-infusion on LHRH and POMC mRNA levels. Castrated yearling males were assigned to receive either vehicle (n = 4) or T (768 ug/kg/day; n = 4). Blood samples were collected at 10 min intervals for 4 h prior to and during the final 4 h of infusion. Infusion of T decreased (P < 0.01) mean LH and LH pulse frequency. T did not significantly affect (P > 0.10) silver grain area per LHRH neuron or LHRH cell numbers. T reduced (P < 0.01) silver grain area per POMC neuron without affecting (P > 0.10) POMC cell number. We reject our hypothesis and conclude that reduced LHRH or heightened POMC gene expression are not mechanisms whereby T reduces pulsatile LHRH release in male sheep.

Disruption of reproductive rhythms and patterns of melatonin and prolactin secretion following bilateral lesions of the suprachiasmatic nuclei in the ewe.

To determine whether the photoperiodic responses of reproductive and prolactin (PRL) rhythms in the ewe requires an intact suprachiasmatic nucleus (SCN) driving the pineal rhythm of melatonin secretion, four groups of ovary-intact ewes over a 6-year period were subjected to bilateral (n = 40) or sham lesions (n = 15) of the SCN. Animals were exposed to an alternating 90-120 day photoregimen of 9L:15D and 16L:8D photoperiods. Blood samples taken twice weekly were assayed for prolactin and for progesterone to monitor oestrous cycles. On several occasions blood samples also were taken at hourly intervals for 24 h and analyzed for melatonin. Melatonin concentrations in sham lesioned ewes were basal during the lights-on period and rose robustly during darkness. Those sheep bearing unilateral lesions of the SCN (n = 13) or where the lesion spared the SCN entirely (n = 8) had patterns of melatonin secretion similar to sham ewes. The remaining ewes, having complete (n = 9) or incomplete bilateral (n = 8) destruction of the SCN, with one exception, had disrupted patterns of melatonin secretion. The nature of this disruption varied from complete suppression to continuously elevated levels. In lesioned ewes where melatonin secretion was not affected the onset and cessation of ovarian cycles were similar to sham ewes; stimulation of oestrous cycles under 9L:15D and cessation of oestrous cycles under 16L:8D. In contrast, 13 of 17 ewes with disrupted melatonin secretion also exhibited disrupted patterns of ovarian activity. In these animals oestrous cycles were no longer entrained by photoperiod but still occurred in distinct clusters, that is, groups of cycles began and ended spontaneously. Sheep with normal melatonin patterns showed low levels of PRL secretion during short days and elevated PRL levels during long days. However, 8 of 13 ewes with disrupted melatonin showed patterns of PRL secretion that were no longer entrained by photoperiod. A minority of ewes with disrupted melatonin patterns still showed reproductive (n = 4) and PRL (n = 5) responses similar to those of sham-lesioned ewes. These results show that bilateral destruction of the SCN in the ewe disrupts the circadian pattern of melatonin secretion and that this disruption usually, but not always, is associated with altered photoperiodic responses. These results strongly suggest that the SCN are important neural elements within the photoperiod time-keeping system in this species. A role for the SCN in the generation of endogenous transitions in reproductive activity (refractoriness) and prolactin secretion is not supported.

Effect of anterior hypothalamic area lesions on photoperiod-induced shifts in reproductive activity of the ewe.

The areas of the brain involved in photoperiodic control of reproduction are not well defined. The objective of this study was to determine whether anterior hypothalamic area (AHA) lesions in the ewe affected the responses of the reproductive system to shifts in the length of the daily photoperiod and development of photorefractoriness to a constant short day photoperiod. Eleven intact ewes received bilateral radiofrequency lesions of the AHA (AHAX), and five received sham lesions (sham). The ewes then were placed in photochambers and exposed alternately to two approximately 90-day periods of long [16 h of light, 8 h of darkness (16L:8D)] and short (10L:14D) days and then to 10L:14D for an additional 165 days. Blood samples were collected twice weekly to monitor plasma profiles of progesterone, PRL, and total T4, and during the second 16L:8D photoperiod, hourly for one 24-h period to assess melatonin release. Lesions increased (P < 0.001) the interval between the start of long days and cessation of estrous cycles during both long day periods, but did not affect the interval between the start of short days and the onset of estrous cycles for either the first (P = 0.08) or second (P > 0.10) short day period. Consequently, the durations of both anestrous periods were shorter (P < 0.001) for AHAX than for sham ewes. AHA lesions did not affect (P > 0.10) diurnal patterns of melatonin release. No effects (P > 0.10) of lesions were evident on plasma patterns of PRL or total T4 for any short or long day photoperiod. Development of photorefractoriness to constant short days either did not occur or was markedly delayed in five of nine AHAX (P < 0.01) ewes, whereas the other four AHAX ewes became refractory at a time similar (P > 0.10) to that in sham ewes. Responses to inhibitory long day photoperiods and constant short days were highly (P < 0.05) correlated (r = 0.74) and appeared dependent upon the extent of the AHA lesion. These results suggest that AHA lesions disrupt neuronal pathways mediating the effects of shifts in photoperiod on reproductive activity and development of photorefractoriness to constant short days. Our results suggest that the effects of AHA lesions are confined to the termination of reproductive activity, and that different neural pathways participate in photostimulation vs. photosuppression or photorefractoriness.

Effect of inhibiting 5 alpha-reductase activity on the ability of testosterone to inhibit luteinizing hormone release in male sheep.

The extent to which inhibitory effects of testosterone (T) on LH secretion in the ram are mediated by its metabolite dihydrotestosterone (DHT) is unknown. Our objective was to determine the effect of inhibiting 5 alpha-reductase activity on pulsatile patterns of LH release in castrated, T-treated male sheep. Nine Dorset and six Hampshire castrated male sheep were allocated equally to one of three treatment groups: 1) infusion of T (768 micrograms/kg/day), 2) infusion of the reductase inhibitor (RI) L-651,723 (0.6 mg/kg/day), and 3) T+RI infusion. Treatments were continuously infused for 3 days. Blood samples were collected via an indwelling jugular catheter at 10-min intervals for 4 h immediately prior to (Day 0) and during the final 4 h of infusion (Day 3). Changes in mean LH, LH pulse amplitude, LH interpulse interval (IPI), T, 17 beta-estradiol (E), and DHT were derived for each animal by subtracting values for Day 0 from Day 3. Data were subjected to one-way analysis of variance. The increase in T and E after infusion of T was similar (p > 0.10) in T- and T+RI-treated males and greater (p < 0.01) than in RI-treated males. The increase of DHT was greater (p < 0.01) in T-treated than either T+RI- or RI-treated males whereas the change was similar (p > 0.10) for T+RI- and RI-treated males. T decreased mean LH more (p < 0.01) than RI. T+RI suppressed mean LH more (p < 0.01) than RI but not as much (p < 0.01) as T alone.(ABSTRACT TRUNCATED AT 250 WORDS)

Time of the sidereal year affects responsiveness to the phase-resetting effects of photoperiod in the ewe.

Two groups of ovary-intact ewes were placed in separate photochambers on the day of the vernal equinox (VE). One group was exposed to a 16 h light:8 h dark (16L:8D) photoperiod and the other to 8L:16D. On the day of the summer solstice (SS) and at 90-91-day intervals thereafter [autumnal equinox (AE), winter solstice (WS), VE and SS], each group was changed to the opposite photoperiod. The latent period between each change and either onset or cessation of cycles, as determined by measuring blood progesterone concentrations, was recorded. The latent period between change to 8L:16D and onset of cycles was shortest after the exposure at AE and longest after exposure at WS (P less than 0.001). The latent period after AE was shorter (P less than 0.001) than after VE. The correlations were small between ambient temperature and interval to onset of cycles. The latent period to cessation of cycles in response to 16L:8D was shorter after SS exposure than after WS exposure (P less than 0.01), but other differences were not significant. There was a strong (r = -0.94, P less than 0.05) negative correlation between interval to cessation of cycles and ambient temperature. Cessation of cycles in response to 16L:8D occurred more rapidly (P less than 0.001) than onset in response to 8L:16D. These results show that responsiveness to the inductive effects of photoperiod varies significantly with time of the sidereal year.