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Dive into the research topics where Christopher Scott is active.

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Featured researches published by Christopher Scott.


The Journal of Comparative Neurology | 2003

Evidence for estrogenic regulation of gonadotropin‐releasing hormone neurons by glutamatergic neurons in the ewe brain: An immunohistochemical study using an antibody against vesicular glutamate transporter‐2

Sueli Pompolo; Alda Pereira; Christopher Scott; Fumino Fujiyma; Iain J. Clarke

Gonadotropin‐releasing hormone (GnRH) secretion is controlled by various factors, including the excitatory neurotransmitter glutamate. Estrogen (E) regulates GnRH secretion by means of E‐responsive cells in the brain that relay the feedback effects to the preoptic area (POA). We used an antibody to vesicular glutamate transporter 2 (VGluT2) to label glutamatergic neurons in the areas of the ewe brain that control GnRH secretion. VGluT2‐immunoreactive cells were observed in the arcuate nucleus (ARC)/ventromedial hypothalamic nucleus (VMH) complex, POA, bed nucleus of stria terminalis (BnST), and A1 and A2 cell groups in the brainstem. In three ewes, E receptor‐α was detected in 52–61% of glutamatergic neurons in ARC/VMH, 37–52% of neurons in the POA, and 37–58% of neurons in the BnST. E injection (i.m. or i.v.) increased the percentage of glutamatergic cells that expressed Fos protein in the ARC (P < 0.01 and P < 0.001, respectively). In six ewes, injection of the retrograde tracer Fluoro‐Gold into the POA labeled cells in the ARC and 6–29% of these were also VGluT2‐immunoreactive. Double‐labeling of varicosities in the POA showed colocalization of VGluT2 in 12.5 ± 3% of dopamine β‐hydroxylase–immunoreactive terminals, indicating that a subset of glutamatergic inputs could arise from brainstem noradrenergic neurons cells. In the POA, 60% of GnRH neurons had close appositions that were VGluT2‐immunoreactive. We conclude that E‐responsive glutamatergic neurons arising from the brainstem, the BnST, and ARC/VMH provide input to the POA and may be involved in the regulation of GnRH secretion. J. Comp. Neurol. 465:136–144, 2003.


Steroids | 2006

Steroidogenic alterations and adrenal androgen excess in PCOS

Suhail Abdul Raman Doi; Mona M. Al-Zaid; Philip A. Towers; Christopher Scott; Kamal A.S. Al-Shoumer

BACKGROUND This cross-sectional study was undertaken to improve our understanding of the steroidogenic alterations leading to adrenal hyperandrogenism in polycystic ovarian syndrome (PCOS). METHODS Two-hundred and thirty-four women with clinical and biochemical features suggestive of PCOS underwent metabolic and hormonal evaluation. We used the androstenedione/DHEAS ratio as a surrogate for the level of ovarian 3betaHSD activity. We then selected the 90th percentile for the ratio in those with elevated DHEAS (>9 micromol/l) as the cut-off level beyond which excess DHEAS production will be minimized by excess ovarian 3betaHSD activity. This cut-off level was at a ratio of 1.5 and all PCOS women were then divided into two groups, the higher (>1.5) being the group with excess ovarian 3betaHSD activity. We hypothesized that women with a high ratio would be unlikely to have DHEAS excess due to the rapid conversion of DHEA to androstenedione. Those with a low ratio (concordant ovarian and adrenal steroidogenesis) could then either have high DHEAS or normal DHEAS, depending on whether CYP17 activity was higher or lower respectively. RESULTS Insulin resistance was found to be associated with decreased CYP17 activity while irregular cycles and neuroendocrine dysfunction were determined to be associated with higher ovarian 3betaHSD activity. CONCLUSION Adrenal androgen excess in PCOS seems to be related to insulin sensitivity as well as decreased activity of 3betaHSD, the latter being preferentially present in those women with regular cycles or without neuroendocrine dysfunction.


Neuroscience Letters | 1998

The distribution of estrogen receptors in the brainstem of female sheep.

Christopher Scott; John A. Rawson; Alda Pereira; Iain J. Clarke

Estrogen receptors (ER) have been mapped in the brainstem of the female sheep with immunocytochemistry. A small group of ER-positive cells was found in the lateral and ventrolateral medulla and a larger number in the nucleus of the solitary tract. ER-positive cells were abundant in the area postrema. In the rostral brainstem a small number of ER-positive cells were found in the lateral and dorsal regions of the periaqueductal gray area, and some immediately lateral to the fourth ventricle. Many ER-positive cells were also present in the region around the superior cerebellar peduncle, particularly in the lateral parabrachial nucleus. These results describe for the first time the distribution of ER in the brainstem of the sheep and indicate that the majority of estrogen-containing cells are located in structures involved in the regulation of cardiovascular parameters and fluid balance.


Journal of Neuroendocrinology | 1996

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

Stanley M. Hileman; Laura S. Lubbers; Sandra L. Petersen; David E. Kuehl; Christopher Scott; Gary L. Jackson

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 8h 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 4h 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.


Journal of Neuroendocrinology | 2004

Sex Differences in the Distribution and Abundance of Androgen Receptor mRNA‐Containing Cells in the Preoptic Area and Hypothalamus of the Ram and Ewe

Christopher Scott; Iain J. Clarke; Alexandra Rao; Alan J. Tilbrook

Rams and ewes show a negative‐feedback response to peripheral treatment with testosterone, with both sexes having a similar degree of suppression in luteinizing hormone (LH) secretion during the breeding season. At least part of the action of testosterone to suppress gonadotropin‐releasing hormone/LH secretion is exerted via interaction with an androgen receptor. The distribution of androgen receptor‐containing cells in the hypothalamus has been described for the ram, but similar studies have not been performed in the ewe. In the present study, we tested the hypothesis that levels of androgen receptor mRNA expression in the preoptic area and hypothalamus would be similar in rams and ewes. Perfusion‐fixed brain tissue was obtained from adult Romney Marsh ewes (luteal phase) and rams during the breeding season (n = 4/sex). Androgen receptor mRNA expression was quantified in hypothalamic sections by in situ hybridization using an 35S‐labelled riboprobe and image analysis. Hybridizing cells were found in the medial preoptic area, bed nucleus of the stria terminalis, anterior hypothalamic area, ventromedial nucleus, arcuate nucleus and premamillary nucleus. The level of androgen receptor mRNA expression was higher in rams than ewes in the rostral preoptic area, caudal preoptic area and rostral portion of the bed nucleus of the stria terminalis, with no sex difference in other regions. The preoptic area and bed nucleus of the stria terminalis are important for reproductive behaviour and the sex differences in androgen receptor mRNA expression at these levels may relate to this. The high level of androgen receptor mRNA expression in the basal hypothalamus, with no sex difference, is consistent with the role of this region in the regulation of gonadotropin secretion.


Journal of Neuroendocrinology | 1995

Disruption of Reproductive Rhythms and Patterns of Melatonin and Prolactin Secretion Following Bilateral Lesions of the Suprachiasmatic Nuclei in the Ewe

Christopher Scott; Heiko T. Jansen; Chen-Chih Kao; David E. Kuehl; Gary L. Jackson

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.


Biology of Reproduction | 2003

Neuronal Inputs from the Hypothalamus and Brain Stem to the Medial Preoptic Area of the Ram: Neurochemical Correlates and Comparison to the Ewe

Christopher Scott; Iain J. Clarke; Alan J. Tilbrook

Abstract The retrograde tracer, FluoroGold, was used to trace the neuronal inputs from the septum, hypothalamus, and brain stem to the region of the GnRH neurons in the rostral preoptic area of the ram and to compare these imputs with those in the ewe. Sex differences were found in the number of retrogradely labeled cells in the dorsomedial and ventromedial nuclei. Retrogradely labeled cells were also observed in the lateral septum, preoptic area, organum vasculosum of the lamina terminalis, bed nucleus of the stria terminalis, stria terminalis, subfornical organ, periventricular nucleus, anterior hypothalamic area, lateral hypothalamus, arcuate nucleus, and posterior hypothalamus. These sex differences may partially explain sex differences in how GnRH secretion is regulated. Fluorescence immunohistochemistry was used to determine the neurochemical identity of some of these cells in the ram. Very few tyrosine hydroxylase-containing neurons in the A14 group (<1%), ACTH-containing neurons (<1%), and neuropeptide Y-containing neurons (1–5%) in the arcuate nucleus contained FluoroGold. The ventrolateral medulla and parabrachial nucleus contained the main populations of FluoroGold-containing neurons in the brain stem. Retrogradely labeled neurons were also observed in the nucleus of the solitary tract, dorsal raphe nucleus, and periaqueductal gray matter. Virtually all FluoroGold-containing cells in the ventrolateral medulla and about half of these cells in the nucleus of the solitary tract also stained for dopamine β-hydroxylase. No other retrogradely labeled cells in the brain stem were noradrenergic. Although dopamine, β-endorphin, and neuropeptide Y have been implicated in the regulation of GnRH secretion in males, it is unlikely that these neurotransmitters regulate GnRH secretion via direct inputs to GnRH neurons.


Animal Reproduction Science | 2000

Gonadal steroid receptors in the regulation of GnRH secretion in farm animals

Christopher Scott; Alan J. Tilbrook; John A. Rawson; Iain J. Clarke

The sites of action and mechanisms by which gonadal steroids regulate gonadotrophin-releasing hormone (GnRH) in domestic animals remain largely unknown. This review summarises information gained from sheep regarding the distribution of the gonadal steroid receptors in the brain, the neurochemical identity and the projections of these steroid receptor-containing neurones. The cells in the hypothalamus that contain each of the gonadal steroid receptors (oestrogen receptor alpha (ERalpha), oestrogen receptor beta (ERbeta), progesterone receptor (PR) and androgen receptor (AR)) show a remarkably similar distribution, although the PR and AR-containing cells are less widespread than oestrogen receptors (ERs). There is considerable overlap in the distribution of ERalpha- and ERbeta-containing cells but also some unique sites for each subtype. This suggests differential regulation of the actions of oestrogen. There appears to be little sexual dimorphism in the distribution of the gonadal steroid receptors in the hypothalamus, with the notable exception of the ventromedial nucleus where females appear to have greater numbers of both ERalpha- and ERbeta-containing cells. Neuronal tracing studies have identified projections of some of the ERalpha-containing cells to sites that may allow interaction with the GnRH system. The receptor mapping, neuronal tracing and microimplantation studies suggest that the ventromedial nucleus is likely to be a key hypothalamic nucleus in the steroid regulation of GnRH secretion in sheep.


Journal of Nutritional Biochemistry | 2017

The protective role of plant biophenols in mechanisms of Alzheimer's disease.

Syed Haris Omar; Christopher Scott; Adam S. Hamlin; Hassan K. Obied

Self-assembly of amyloid beta peptide (Aβ) into the neurotoxic oligomers followed by fibrillar aggregates is a defining characteristic of Alzheimers disease (AD). Several lines of proposed hypotheses have suggested the mechanism of AD pathology, though the exact pathophysiological mechanism is not yet elucidated. The poor understanding of AD and multitude of adverse responses reported from the current synthetic drugs are the leading cause of failure in the drug development to treat or halt the progression of AD and mandate the search for safer and more efficient alternatives. A number of natural compounds have shown the ability to prevent the formation of the toxic oligomers and disrupt the aggregates, thus attracted much attention. Referable to the abundancy and multitude of pharmacological activities of the plant active constituents, biophenols that distinguish them from the other phytochemicals as a natural weapon against the neurodegenerative disorders. This review provides a critical assessment of the current literature on in vitro and in vivo mechanistic activities of biophenols associated with the prevention and treatment of AD. We have contended the need for more comprehensive approaches to evaluate the anti-AD activity of biophenols at various pathologic levels and to assess the current evidences. Consequently, we highlighted the various problems and challenges confronting the AD research, and offer recommendations for future research.


Journal of Neuroendocrinology | 2001

Changes in preoptic and hypothalamic levels of progesterone receptor mRNA across the oestrous cycle of the ewe

Christopher Scott; Alda Pereira; Alan J. Tilbrook; John A. Rawson; Iain J. Clarke

We measured the levels of progesterone receptor (PR) mRNA in the hypothalamus and preoptic area (POA) of the ewe across the oestrous cycle. Perfusion‐fixed hypothalamic tissue was collected from sheep killed during the luteal and follicular phases and during behavioural oestrus. Blood samples taken at the time of tissue collection verified that the oestrous ewes were undergoing a preovulatory luteinizing hormone (LH) surge. Matched sections were taken from the POA, periventricular nucleus (PeVN), ventromedial nucleus (VMN) and arcuate nucleus of each animal. In situ hybridization was performed using a sheep specific, 35S‐labelled riboprobe for PR and semiquantitative image analysis was conducted on emulsion‐dipped slides. The number of silver grains per cell was greater in the VMN and arcuate nucleus of oestrous ewes than in luteal and follicular phase ewes; there was no cyclic variation in the level of PR mRNA expression in the cells of the POA and PeVN. The number of labelled cells per mm2 in the VMN was higher in the oestrous ewes than in luteal phase and follicular phase ewes. The number of labelled cells in the PeVN was also higher in the oestrous ewes than in follicular phase ewes, but there was no cyclic variation in the POA and arcuate nucleus. In the ewe, the onset of behavioural oestrus corresponds to the onset of the preovulatory LH surge and increased PR mRNA expression at this time is likely to be due to the high concentrations of circulating oestrogen that precede this period.

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Alan J. Tilbrook

South Australian Research and Development Institute

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Scott Norman

Charles Sturt University

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Adam S. Hamlin

University of Queensland

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Jessica Rose

Charles Sturt University

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Alda Pereira

Prince Henry's Institute of Medical Research

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Cyril Stephen

Charles Sturt University

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Briony McGrath

Charles Sturt University

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