A missense mutation in Katnal1 underlies behavioural, neurological and ciliary anomalies.

Microtubule severing enzymes implement a diverse range of tissue-specific molecular functions throughout development and into adulthood. Although microtubule severing is fundamental to many dynamic neural processes, little is known regarding the role of the family member Katanin p60 subunit A-like 1, KATNAL1, in central nervous system (CNS) function. Recent studies reporting that microdeletions incorporating the KATNAL1 locus in humans result in intellectual disability and microcephaly suggest that KATNAL1 may play a prominent role in the CNS; however, such associations lack the functional data required to highlight potential mechanisms which link the gene to disease symptoms. Here we identify and characterise a mouse line carrying a loss of function allele in Katnal1. We show that mutants express behavioural deficits including in circadian rhythms, sleep, anxiety and learning/memory. Furthermore, in the brains of Katnal1 mutant mice we reveal numerous morphological abnormalities and defects in neuronal migration and morphology. Furthermore we demonstrate defects in the motile cilia of the ventricular ependymal cells of mutants, suggesting a role for Katnal1 in the development of ciliary function. We believe the data we present here are the first to associate KATNAL1 with such phenotypes, demonstrating that the protein plays keys roles in a number of processes integral to the development of neuronal function and behaviour.

Catabolic cytokines disrupt the circadian clock and the expression of clock-controlled genes in cartilage via an NFкB-dependent pathway.

OBJECTIVE: To define how the catabolic cytokines (Interleukin 1 (IL-1) and tumor necrosis factor alpha (TNFα)) affect the circadian clock mechanism and the expression of clock-controlled catabolic genes within cartilage, and to identify the downstream pathways linking the cytokines to the molecular clock within chondrocytes. METHODS: Ex vivo cartilage explants were isolated from the Cry1-luc or PER2::LUC clock reporter mice. Clock gene dynamics were monitored in real-time by bioluminescence photon counting. Gene expression changes were studied by qRT-PCR. Functional luc assays were used to study the function of the core Clock/BMAL1 complex in SW-1353 cells. NFкB pathway inhibitor and fluorescence live-imaging of cartilage were performed to study the underlying mechanisms. RESULTS: Exposure to IL-1ß severely disrupted circadian gene expression rhythms in cartilage. This effect was reversed by an anti-inflammatory drug dexamethasone, but not by other clock synchronizing agents. Circadian disruption mediated by IL-1ß was accompanied by disregulated expression of endogenous clock genes and clock-controlled catabolic pathways. Mechanistically, NFкB signalling was involved in the effect of IL-1ß on the cartilage clock in part through functional interference with the core Clock/BMAL1 complex. In contrast, TNFα had little impact on the circadian rhythm and clock gene expression in cartilage. CONCLUSION: In our experimental system (young healthy mouse cartilage), we demonstrate that IL-1ß (but not TNFα) abolishes circadian rhythms in Cry1-luc and PER2::LUC gene expression. These data implicate disruption of the chondrocyte clock as a novel aspect of the catabolic responses of cartilage to pro-inflammatory cytokines, and provide an additional mechanism for how chronic joint inflammation may contribute to osteoarthritis (OA).

Differential contributions of intra-cellular and inter-cellular mechanisms to the spatial and temporal architecture of the suprachiasmatic nucleus circadian circuitry in wild-type, cryptochrome-null and vasoactive intestinal peptide receptor 2-null mutant mice.

To serve as a robust internal circadian clock, the cell-autonomous molecular and electrophysiological activities of the individual neurons of the mammalian suprachiasmatic nucleus (SCN) are coordinated in time and neuroanatomical space. Although the contributions of the chemical and electrical interconnections between neurons are essential to this circuit-level orchestration, the features upon which they operate to confer robustness to the ensemble signal are not known. To address this, we applied several methods to deconstruct the interactions between the spatial and temporal organisation of circadian oscillations in organotypic slices from mice with circadian abnormalities. We studied the SCN of mice lacking Cryptochrome genes (Cry1 and Cry2), which are essential for cell-autonomous oscillation, and the SCN of mice lacking the vasoactive intestinal peptide receptor 2 (VPAC2-null), which is necessary for circuit-level integration, in order to map biological mechanisms to the revealed oscillatory features. The SCN of wild-type mice showed a strong link between the temporal rhythm of the bioluminescence profiles of PER2::LUC and regularly repeated spatially organised oscillation. The Cry-null SCN had stable spatial organisation but lacked temporal organisation, whereas in VPAC2-null SCN some specimens exhibited temporal organisation in the absence of spatial organisation. The results indicated that spatial and temporal organisation were separable, that they may have different mechanistic origins (cell-autonomous vs. interneuronal signaling) and that both were necessary to maintain robust and organised circadian rhythms throughout the SCN. This study therefore provided evidence that the coherent emergent properties of the neuronal circuitry, revealed in the spatially organised clusters, were essential to the pacemaking function of the SCN.

Cry1 circadian phase in vitro: wrapped up with an E-box.

The circadian timing of gene expression is determined by transcriptional regulation through upstream response elements present throughout the genome. Central to this regulation are the actions of a core group of transcriptional activators and repressors, which act through, and are themselves regulated by, a small set of canonical circadian response elements. Among these, the E-box (CACGTG) is crucial for daytime transcriptional activity. The mammalian Period (Per1-3) and Cryptochrome (Cry1-2) genes are E-box-regulated genes, but in peripheral tissues peak Cry1 mRNA expression is delayed by several hours relative to that of Per. It has been proposed that this delay originates from interactions between the proximal E-box and retinoic acid-related orphan receptor response elements (RORE) present in the Cry1 promoter. By using real-time luciferase reporter assays in NIH3T3 cells the authors show here that a proximal 47-bp E-box containing region of the Cry1 promoter is both necessary and sufficient to drive circadian Cry1 transcription with an appropriate phase delay (around 4 h) relative to Per2. The results therefore suggest that, at least in this in vitro model of the clock, RORE are not necessary for the appropriate circadian regulation of Cry1 expression and rather suggest that sequences surrounding the proximal E-boxes confer gene-specific circadian phasing.

Interacting molecular loops in the mammalian circadian clock.

We show that, in the mouse, the core mechanism for the master circadian clock consists of interacting positive and negative transcription and translation feedback loops. Analysis of Clock/Clock mutant mice, homozygous Period2(Brdm1) mutants, and Cryptochrome-deficient mice reveals substantially altered Bmal1 rhythms, consistent with a dominant role of PERIOD2 in the positive regulation of the Bmal1 loop. In vitro analysis of CRYPTOCHROME inhibition of CLOCK: BMAL1-mediated transcription shows that the inhibition is through direct protein:protein interactions, independent of the PERIOD and TIMELESS proteins. PERIOD2 is a positive regulator of the Bmal1 loop, and CRYPTOCHROMES are the negative regulators of the Period and Cryptochrome cycles.

Differential functions of mPer1, mPer2, and mPer3 in the SCN circadian clock.

The role of mPer1 and mPer2 in regulating circadian rhythms was assessed by disrupting these genes. Mice homozygous for the targeted allele of either mPer1 or mPer2 had severely disrupted locomotor activity rhythms during extended exposure to constant darkness. Clock gene RNA rhythms were blunted in the suprachiasmatic nucleus of mPer2 mutant mice, but not of mPER1-deficient mice. Peak mPER and mCRY1 protein levels were reduced in both lines. Behavioral rhythms of mPer1/mPer3 and mPer2/mPer3 double-mutant mice resembled rhythms of mice with disruption of mPer1 or mPer2 alone, respectively, confirming the placement of mPer3 outside the core circadian clockwork. In contrast, mPer1/mPer2 double-mutant mice were immediately arrhythmic. Thus, mPER1 influences rhythmicity primarily through interaction with other clock proteins, while mPER2 positively regulates rhythmic gene expression, and there is partial compensation between products of these two genes.

Analysis of clock proteins in mouse SCN demonstrates phylogenetic divergence of the circadian clockwork and resetting mechanisms.

The circadian clock in the suprachiasmatic nuclei (SCN) is comprised of a cell-autonomous, autoregulatory transcriptional/translational feedback loop. Its molecular components include three period and two cryptochrome genes. We describe circadian patterns of expression of mPER2 and mPER3 in the mouse SCN that are synchronous to those for mPER1, mCRY1, and mCRY2. Coimmunoprecipitation experiments demonstrate in vivo associations of the SCN mPER proteins with each other and with the mCRY proteins, and of mCRY proteins with mTIM, but no mPER/mTIM interactions. Examination of the effects of weak and strong resetting light pulses on SCN clock proteins highlights a central role for mPER1 in photic entrainment, with no acute light effects on either the mCRY or mTIM proteins. These clock protein interactions and photic responses in mice are divergent from those described in Drosophila.

Central clocking.

The main questions in circadian neurobiology are: how many oscillators are involved; how are their daily oscillations generated and synchronized to the external world; and how do they signal time of day to the organism. The suprachiasmatic nuclei of the hypothalamus (SCN) are well established as the principal circadian oscillator of mammals. Their 10,000 or so 'clock' neurones drive our overt rhythms-the daily patterning we observe in our physiology and behaviour being mirrored perfectly by their spontaneous cycle of neuronal activity. However, they are not our only circadian oscillator, their molecular timekeeping is not understood and they ways in which they communicate with other parts of the brain are more unusual than was previously assumed.

Do corticosteroids damage the brain?

Corticosteroids are an essential component of the body's homeostatic system. In common with other such systems, this implies that corticosteroid levels in blood and, more importantly, in the tissues remain within an optimal range. It also implies that this range may vary according to circumstance. Lack of corticosteroids, such as untreated Addison's disease, can be fatal in humans. In this review, we are principally concerned with excess or disturbed patterns of circulating corticosteroids in the longer or shorter term, and the effects they have on the brain.

The tau mutation in the Syrian hamster differentially reprograms the circadian clock in the SCN and peripheral tissues.

The hypothalamic suprachiasmatic nuclei (SCN), the principal circadian oscillator in mammals, are synchronized to the solar day by the light-dark cycle, and in turn, they coordinate circadian oscillations in peripheral tissues. The tau mutation in the Syrian hamster is caused by a point mutation leading to a deficiency in the ability of Casein Kinase 1epsilon to phosphorylate its targets, including circadian PER proteins. How this accelerates circadian period in neural tissues is not known, nor is its impact on peripheral circadian oscillators established. We show that this mutation has no effect on per mRNA expression nor the nuclear accumulation of PER proteins in the SCN. It does, however, accelerate the clearance of PER proteins from the nucleus to an extent sufficient to explain the shortened circadian period of behavioral rhythms. The mutation also has novel, unanticipated consequences for circadian timing in the periphery, including tissue-specific phase advances and/or reduced amplitude of circadian gene expression. The results suggest that the tau mutation accelerates a specific phase, during mid-late subjective night of the SCN circadian feedback loop, rather than cause a global compression of the entire cycle. This reprogrammed output from the clock is associated with peripheral desynchrony, which in turn could account for impaired growth and metabolic efficiency of the mutant.

Differential resynchronisation of circadian clock gene expression within the suprachiasmatic nuclei of mice subjected to experimental jet lag.

Disruption of the circadian timing system arising from travel between time zones ("jet lag") and rotational shift work impairs mental and physical performance and severely compromises long-term health. Circadian disruption is more severe during adaptation to advances in local time, because the circadian clock takes much longer to phase advance than delay. The recent identification of mammalian circadian clock genes now makes it possible to examine time zone adjustments from the perspective of molecular events within the suprachiasmatic nucleus (SCN), the principal circadian oscillator. Current models of the clockwork posit interlocked transcriptional/post-translational feedback loops based on the light-sensitive Period (Per) genes and the Cryptochrome (Cry) genes, which are indirectly regulated by light. We show that circadian cycles of mPer expression in the mouse SCN react rapidly to an advance in the lighting schedule, whereas rhythmic mCry1 expression advances more slowly, in parallel to the gradual resetting of the activity-rest cycle. In contrast, during a delay in local time the mPer and mCry cycles react rapidly, completing the 6 hr shift together by the second cycle, in parallel with the activity-rest cycle. These results reveal the potential for dissociation of mPer and mCry expression within the central oscillator during circadian resetting and a differential molecular response of the clock during advance and delay resetting. They highlight the indirect photic regulation of mCry1 as a potentially rate-limiting factor in behavioral adjustment to time zone transitions.

Differential regulation of mPER1 and mTIM proteins in the mouse suprachiasmatic nuclei: new insights into a core clock mechanism.

Recent discoveries have identified a framework for the core circadian clock mechanism in mammals. Development of this framework has been based entirely on the expression patterns of so-called "clock genes" in the suprachiasmatic nuclei (SCN), the principal clock of mammals. We now provide data concerning the protein expression patterns of two of these genes, mPer1 and mTim. Our studies show that mPER1 and mTIM are nuclear antigens expressed in the SCN and extensively throughout the forebrain. Expression of mPER1 in the SCN was rhythmic under entrained conditions and with clear circadian cycling under free-running conditions. Expression of mPER1 elsewhere in the mouse forebrain was not rhythmic. In contrast to mPER1, mTIM expression in the SCN did not vary with time in mice housed in either a light/dark cycle or in constant dim red light. The phase relationship between mPer1 RNA and mPER1 cycles in the SCN is consistent with a negative feedback model of the mammalian clock. The invariant nature of nuclear mTIM in the SCN suggests that its participation in negative feedback occurs only after mPER1 has entered the nucleus, and that the abundance of mTIM is not regulated by the circadian clock or the light/dark cycle.

Neuroendocrine rhythms.

Hormones are secreted with circhoral, circadian and seasonal periodicities. Circhoral pulsatility is a temporal code, many chronic and acute changes in neuroendocrine status being mediated by changes in the frequency of circhoral release. The identity of the neuronal circuits controlling circhoral release is not known. Circadian release of hormones occurs with a precise temporal order entrained to the light-dark cycle, synchronized to the activity/rest rhythm and generated by circadian oscillators, of which the suprachiasmatic nuclei are the most important. Seasonal rhythms are driven either by an endogenous circannual clock mechanism or by a process of photoperiodic time measurement which is dependent upon the duration of the nocturnal peak of the pineal hormone melatonin.

A role for the circadian clock of the suprachiasmatic nuclei in the interpretation of serial melatonin signals in the Syrian hamster.

Seasonal rhythms of reproduction in the Syrian hamster are triggered by the pineal hormone melatonin. By varying the parameters of systemic infusions of exogenous melatonin delivered to pinealectomized hamsters, it has been shown that the hypothalamus is sensitive to the duration of individual signals, which serve as an inverse coding of day length. It also has been shown that animals are sensitive to the temporal structure of a series of signals insofar as a series of melatonin infusions of appropriate number and duration may fail to invoke a gonadal response if they are presented at inappropriate frequencies. Although the endogenous circadian pacemaker of the suprachiasmatic nucleus (SCN) is not thought to be involved in the measurement of or response to melatonin signal duration, its contribution to the interpretation of a series of melatonin signals remains to be determined. Syrian hamsters are able to show a short-day-like gonadal response to a series of melatonin signals delivered on a variety of noncircadian schedules, including one in which a "random" pattern of infusions is employed. This study investigated the role of the SCN in the interpretation of such infusion paradigms. Adult male Syrian hamsters received electrolytic lesions of the SCN. Pinealectomized, lesioned, and intact hamsters then were infused with melatonin or saline at one of three different phases of the day in a random pattern such that no signal was predictive of the timing of the next. Other lesioned and intact animals received melatonin or saline at the same time daily. After 6 weeks, control saline-infused animals in both lesioned and intact groups had large testes. However, sham animals receiving melatonin in the random infusion pattern had regressed testes, as did the lesioned animals receiving melatonin at the same phase every day. By contrast, lesioned animals that received melatonin in the random pattern of infusion did not show a short-day gonadal response. These results suggest that although the SCN is not necessary for measurement of the duration of individual signals, it may play a role in the interpretation of a series of melatonin signals in which the number of melatonin signals and the period of time over which they are encountered need to be compared.

Circadian and photoperiodic time measurement in male Syrian hamsters following lesions of the melatonin-binding sites of the paraventricular thalamus.

Autoradiographic studies using [125I]iodomelatonin in several species, including the Syrian hamster, have revealed that the rostral region of the anterior paraventricular nucleus of the thalamus (aPVT) contains a very high density of binding sites for melatonin. In two studies, small or large bilateral electrolytic lesions of the aPVT were made in adult male hamsters maintained on long days (LD 16:8). The hamsters were then transferred to short days (LD 8:16) to test whether testicular regression could occur in response to a decrease in photoperiod. Serum prolactin concentrations were measured as a second photoperiodic response. All unoperated control hamsters showed the typical short-day photoperiodic response: A decrease in serum luteinizing hormone (LH) and prolactin concentrations and testicular regression all occurred within 6 weeks in short days, followed by the development of scotorefractoriness. Lesions of the aPVT did not significantly affect the rate or the degree of the short-day-induced decline in serum levels of LH or prolactin, nor the pattern of testicular regression and the subsequent expression of refractoriness. To enable us to determine whether the aPVT might be involved in the entrainment or the expression of circadian rhythms, locomotor activity was monitored continuously in lesioned and control groups in Experiment 2, prior to and following the switch to short days. The reduction in photoperiod (involving an 8-hr advance in the time of lights-off and an 8-hr extension of the dark phase) caused a decompression of the nocturnal activity bout of control animals, so that after 2 weeks in short days, activity onset had also advanced to regain its phase relationship to the timing of lights-off. A similar pattern of reentrainment was observed in lesioned animals, and no differences were observed between treatment groups in the rate of entrainment and decompression. In addition, both intact controls and animals bearing large bilateral lesions of the aPVT exhibited robust free-running circadian rhythms of locomotor activity when held under constant dim red light. In summary, the integrity of the aPVT is not necessary for the seasonal response of the reproductive axis and prolactin secretion to photoperiod, nor for photic entrainment of activity rhythms, in the Syrian hamster.

Cycle of period gene expression in a diurnal mammal (Spermophilus tridecemlineatus): implications for nonphotic phase shifting.

Ground squirrels, Spermophilus tridecemlineatus, were kept in a 12:12 h light-dark cycle. As expected for a diurnal species, their locomotor activity occurred almost entirely in the daytime. Expression of mPer1 and mPer2 in the suprachiasmatic nucleus was studied at six time points by in situ hybridization. For both these genes, mRNA was highest in the first part of the subjective day (about zeitgeber time 5). This is close to the time when mPer1 and mPer2 expression is maximal in nocturnal rodents. These results have implications for understanding nonphotic phase response curves in diurnal species and thereby for guiding research on nonphotic phase shifting in people.

Differential effects of photoperiodic history on the responses of gonadotrophins and prolactin to intermediate daylengths in the male Syrian hamster.

The effect of photoperiodic history on the neuroendocrine response to intermediate daylengths (11-13.5 hr of light) was investigated in the male Syrian hamster. The duration of the nocturnal peak of pineal melatonin content was inversely proportional to photoperiod and independent of photoperiodic history. Serum levels of prolactin were lower in animals exposed to shorter photoperiods. Photoperiodic history had little effect on the response of serum prolactin to intermediate daylengths. Serum luteinizing hormone (LH) concentrations were also lower in shorter photoperiods, but in addition were sensitive to the direction of photoperiodic change, so that a single photoperiod could be interpreted as either stimulatory or inhibitory to LH secretion. This effect of photoperiodic history was expressed at intermediate photoperiods with 12-13.5 hr of light. The sensitivity of serum follicle-stimulating hormone (FSH) levels to photoperiodic history was masked by an early onset of photorefractoriness. Testicular size and serum testosterone levels revealed weaker effects of photoperiodic history; these were attributed to the dissociation between gonadotrophin and prolactin secretion induced by intermediate daylengths. The contrasting effects of photoperiodic history on the secretion of LH and prolactin may represent the expression of multiple photoperiodic time-measuring systems.

Photoperiodic influences on sexual behavior in male Syrian hamsters.

The effect of photoperiodic conditions on sexual behavior was investigated in male Syrian hamsters that were either gonadally intact, or castrated and treated with low doses of testosterone throughout the experiment. Hamsters were exposed to long (LD 16:8) or short (LD 8:16) days for 7 weeks; for the next 8 weeks, either they were exposed to an intermediate daylength (LD 12:12), or daylength conditions remained unchanged. Sexual behavior was affected by photoperiod conditions in both gonadally intact animals and testosterone-treated castrates, but to different degrees. Intact males exposed to short days for 15 weeks exhibited gonadal regression, and their copulatory performance was impaired. The percentage of animals that intromitted or ejaculated was significantly reduced. Additional measures of sexual performance among the copulating males were also affected. In contrast, among the castrates with testosterone clamped at low but stable levels, the proportion of males that mounted, intromitted, or ejaculated was not affected by photoperiod. However, among the males that continued to copulate, sexual performance changes were present in the short-day castrates that resembled those displayed by the intact males. We infer that these behavioral effects in both hormonal conditions reflect primarily a difficulty in the attainment of intromission. Gonadal regression alone cannot easily account for the behavioral deficits of the intact males, because circulating testosterone levels at the end of the experiment were not significantly different between the gonadally intact hamsters and the castrated, testosterone-treated hamsters exposed continuously to short days. Males transferred from either long or short days to the intermediate-daylength condition responded behaviorally to this photoperiod as if it were a short day, that is, their ejaculatory frequency declined. We conclude that male hamsters exposed to photoinhibitory daylengths exhibit deficits in their sexual behavior, not only because endogenous levels of testosterone decrease, but also because the substrates on which this hormone acts become less responsive. We hypothesize that under physiological conditions, the episodic secretion of testosterone imposes constraints on the maintenance or restoration of copulation, and that the potent behavioral effects achieved by constant-release implants of testosterone may mask the presence of photoperiodically induced alterations in the hamster's sensitivity to this gonadal hormone.

Lesions of the iodomelatonin-binding sites of the mediobasal hypothalamus spare the lactotropic, but block the gonadotropic response of male Syrian hamsters to short photoperiod and to melatonin.

The aim of this study was to determine whether the iodomelatonin-binding sites identified within the preoptic area (POA) or mediobasal hypothalamus (MBH) are essential for the photoperiodic control of seasonal reproduction in male Syrian hamsters. Animals received sham or bilateral electrolytic lesions directed toward either the POA (POA-X; n = 11) or MBH (MBH-X; n = 12) and were then maintained on long days (16 h of light and 8 h of darkness) for at least 4 weeks before transfer to a short photoperiod (SD; 8 h of light and 16 h of darkness). The transscrotal width of the left testis and serum testosterone (Exp 1), PRL, and LH (Exp 2) levels were recorded every 4 weeks in lesioned and intact hamsters to monitor their reproductive state. Lesions of the MBH, but not the POA, abolished the SD-induced gonadal responses (transscrotal width of the left testis after 12 weeks of SD: MBH-X, 10.0 +/- 0.2 mm; sham, 4.6 +/- 0.1 mm; POA-X, 4.0 +/- 0.1 mm; sham, 4.1 +/- 0.1 mm). Similarly, the decrease in serum LH concentrations was prevented by lesions of the MBH (serum LH after 12 weeks SD: MBH-X, 0.74 +/- 0.2 ng/ml; sham, 0.25 +/- 0.1 ng/ml). However, neither lesion prevented the SD-induced decline in serum PRL (serum PRL after 12 weeks SD: MBH-X, 4.7 +/- 1.0 ng/ml; sham, 3.1 +/- 0.1 ng/ml; POA-X, 2.0 +/- 0.1 ng/ml; sham, 2.0 +/- 0.1 ng/ml). To exclude the possibility that the lesion to the MBH prevented gonadal regression through disruption of nocturnal melatonin production, MBH-X animals were switched to a long day photoperiod, pinealectomized, and fitted with a sc cannula for the infusion of either melatonin (500 ng/10 h) or saline (50 microliters/h) once daily for 6 weeks. A group of neurally intact, pinealectomized control animals that received the same infusions showed the expected gonadal regression with melatonin treatment, whereas those receiving saline vehicle had large testes (melatonin, 0.5 +/- 0.1 g; saline, 3.3 +/- 0.3 g. Furthermore, after 6 weeks of infusions, serum LH and PRL concentrations in intact melatonin-infused hamsters were significantly reduced (LH: melatonin, 0.2 +/- 0.04 ng/ml; saline, 1.3 +/- 0.1 ng/ml; PRL: melatonin, 2.2 +/- 0.2 ng/ml; saline, 16.9 +/- 3.1 ng/ml). In contrast to the intact controls, none of the MBH-X animals infused with melatonin exhibited gonadal regression (MBH-X: melatonin, 2.8 +/- 0.5 g; saline, 2.9 +/- 0.5 g).(ABSTRACT TRUNCATED AT 400 WORDS)

Regulation of mitogen-activated protein kinase in the pars tuberalis of the ovine pituitary: interactions between melatonin, insulin-like growth factor-1, and forskolin.

The pars tuberalis (PT) of the anterior pituitary is notable for the expression of levels of melatonin receptors that consistently exceed those in all other tissues in mammals. For this reason and because of its anatomical position, it has been suggested that the PT may play a role in seasonal reproductive responsiveness. However, no data have been forthcoming on the nature of the melatonin-responsive cells in this tissue or on the interaction of melatonin with other hormonal signals in the control of PT cells. A number of recent studies have reported that the tubero-infundibular region of the pituitary in several species contains binding sites for insulin-like growth factor-1 (IGF-1). The present study, therefore, sought to address the question of whether functional receptors for IGF-1 exist in the ovine PT (oPT). Primary cultures of cells from the oPT contained a widespread distribution of cells staining positively with a monoclonal antibody to the human IGF-1 receptor, with the strongest staining occurring over the small phase-bright cells that predominate in this culture system and are thought to constitute the melatonin-responsive cell type. As a functional assay for responsiveness to IGF-1, primary cultures of oPT cells were assayed for activation of mitogen-activated protein kinase (MAPK) using a previously validated phosphotransferase assay. Cytosolic extracts from PT cells treated with IGF-1 (100 pM-10 nM) caused a dose-dependent increase in the rate of phosphorylation of myelin basic protein; in contrast, treatment with melatonin had no significant effect on myelin basic protein phosphorylation. Immunostaining of Western blots of PT cell extracts with a pan-extracellular regulated kinase antibody demonstrated that both p42 and p44 MAPK are strongly expressed in this tissue. To confirm that the effects observed in the cytosol assay were indeed attributable to increased activation of p42/p44, gel renaturation assays of protein kinase activity were performed. These experiments revealed that IGF-1 (10 nM) and forskolin (1 microM) were both potent activators of 42- and 44-kDa moeities; however, neither of these agents had any significant effect on the phosphotransferase activity associated with several other higher molecular weight kinases also detected by the gel-renaturation assay procedure. Melatonin (10 nm) was consistently found to be a highly potent inhibitor of the activation of MAPK induced by forskolin; in contrast, melatonin did not inhibit the activation of MAPK induced by IGF-1.(ABSTRACT TRUNCATED AT 400 WORDS)