Pauline M. Smith
Queen's University
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Publication
Featured researches published by Pauline M. Smith.
The Journal of Neuroscience | 2006
Mark Fry; Pauline M. Smith; Ted D. Hoyda; Marnie Duncan; Rexford S. Ahima; Keith A. Sharkey; Alastair V. Ferguson
Adiponectin is an adipocyte-derived peptide hormone involved in energy homeostasis and the pathogenesis of obesity, including hypertension. Area postrema (AP) lacks a blood–brain barrier and is a critical homeostatic integration center for humoral and neural signals. Here we investigate the role of AP in adiponectin signaling. We show that rat AP expresses AdipoR1 and AdipoR2 adiponectin receptor mRNA. We used current-clamp electrophysiology to investigate whether adiponectin influenced membrane properties of AP neurons and found that ∼60% of rat AP neurons tested were sensitive to adiponectin. Additional electrophysiology experiments coupled with single-cell reverse transcription-PCR indicated that all neurons that expressed both subtypes of receptor were sensitive to adiponectin, whereas neurons expressing only one subtype were predominantly insensitive. Last, microinjection of adiponectin into AP caused significant increases in arterial blood pressure, with no change in heart rate, suggesting that adiponectin acts at AP to provide a possible link between control of energy homeostasis and cardiovascular function.
Brain Research | 2002
Pauline M. Smith; Barbara C Connolly; Alastair V. Ferguson
Orexin A (OX-A) and orexin B (OX-B), also known as hypocretin-1 and hypocretin-2, have been suggested to play a role cardiovascular control. The nucleus tractus solitarius (NTS), located in the dorsal medulla plays an essential role in neural control of the cardiovascular system. Orexin-immunoreactive axons have been demonstrated within this nucleus suggesting that NTS may be a site through which OX acts to influence cardiovascular control. We report here that microinjection of OX-A into the NTS of urethane anesthetized rats causes increases in blood pressure (10(-9) M, mean AUC=607.1+/-65.65 mmHg s, n=5) and heart rate (10(-9) M, mean AUC=16.15+/-3.3 beats, n=5) which returns to baseline within 90 s. We show that these effects are dose related and site specific. Microinjection of OX-B into NTS elicited similar increases in BP (mean AUC=680.8+/-128.5 mmHg s, n=4) to that of OX-A suggesting specific actions at the OX(2)R receptor. These observations support the conclusion that orexins act as chemical messengers in the NTS likely influencing the excitability of cardiovascular neurons in this region and thus regulating global cardiovascular function.
American Journal of Physiology-regulatory Integrative and Comparative Physiology | 1997
Y. Takahashi; Pauline M. Smith; Alistair Ferguson; Quentin J. Pittman
We have examined the roles of three circumventricular organs, the area postrema, the subfornical organ, and the organum vasculosum of the lamina terminalis (OVLT), as possible access points for circulating pyrogens to cause fever. In conscious, unrestrained rats prepared with telemetry devices, intracerebroventricular cannulas, and intravenous catheters, body temperature was monitored after intravenously administered lipopolysaccharide and, on a different occasion, after intracerebroventricular prostaglandin E1. Lipopolysaccharide-induced fevers in sham control lesioned rats were indistinguishable from those observed in animals with lesions of the area postrema, the OVLT, or the tissue immediately adjacent to this structure (peri-OVLT). In contrast, rats with lesions of the subfornical organ displayed reduced fevers. In none of the groups of lesioned animals were prostaglandin E1 fevers reduced. Thus lesions did not interfere with central thermogenic pathways responsive to prostaglandin. Our results indicate that subfornical organ neurons respond to circulating pyrogens and through their efferent projections activate central pathways involved in fever.We have examined the roles of three circumventricular organs, the area postrema, the subfornical organ, and the organum vasculosum of the lamina terminalis (OVLT), as possible access points for circulating pyrogens to cause fever. In conscious, unrestrained rats prepared with telemetry devices, intracerebroventricular cannulas, and intravenous catheters, body temperature was monitored after intravenously administered lipopolysaccharide and, on a different occasion, after intracerebroventricular prostaglandin E1. Lipopolysaccharide-induced fevers in sham control lesioned rats were indistinguishable from those observed in animals with lesions of the area postrema, the OVLT, or the tissue immediately adjacent to this structure (peri-OVLT). In contrast, rats with lesions of the subfornical organ displayed reduced fevers. In none of the groups of lesioned animals were prostaglandin E1 fevers reduced. Thus lesions did not interfere with central thermogenic pathways responsive to prostaglandin. Our results indicate that subfornical organ neurons respond to circulating pyrogens and through their efferent projections activate central pathways involved in fever.
American Journal of Physiology-regulatory Integrative and Comparative Physiology | 2010
Pauline M. Smith; Alastair V. Ferguson
To maintain homeostasis autonomic control centers in the hypothalamus and medulla must respond appropriately to both external and internal stimuli. Although protected behind the blood-brain barrier, neurons in these autonomic control centers are known to be influenced by changing levels of important signaling molecules in the systemic circulation (e.g., osmolarity, glucose concentrations, and regulatory peptides). The subfornical organ belongs to a group of specialized central nervous system structures, the circumventricular organs, which are characterized by the lack of the normal blood-brain barrier, such that circulating lipophobic substances may act on neurons within this region and via well-documented efferent neural projections to hypothalamic autonomic control centers, influence autonomic function. This review focuses on the role of the subfornical organ in sensing peripheral signals and transmitting this information to autonomic control centers in the hypothalamus.
American Journal of Physiology-regulatory Integrative and Comparative Physiology | 2008
Charles Hindmarch; Mark Fry; Song T. Yao; Pauline M. Smith; David Murphy; Alastair V. Ferguson
We have employed microarray technology using Affymetrix 230 2.0 genome chips to initially catalog the transcriptome of the subfornical organ (SFO) under control conditions and to also evaluate the changes (common and differential) in gene expression induced by the challenges of fluid and food deprivation. We have identified a total of 17,293 genes tagged as present in one of our three experimental conditions, transcripts, which were then used as the basis for further filtering and statistical analysis. In total, the expression of 46 genes was changed in the SFO following dehydration compared with control animals (22 upregulated and 24 downregulated), with the largest change being the greater than fivefold increase in brain-derived neurotrophic factor (BDNF) expression, while significant changes in the expression of the calcium-sensing (upregulated) and apelin (downregulated) receptors were also reported. In contrast, food deprivation caused greater than twofold changes in a total of 687 transcripts (222 upregulated and 465 downregulated), including significant reductions in vasopressin, oxytocin, promelanin concentrating hormone, cocaine amphetamine-related transcript (CART), and the endothelin type B receptor, as well as increases in the expression of the GABA(B) receptor. Of these regulated transcripts, we identified 37 that are commonly regulated by fasting and dehydration, nine that were uniquely regulated by dehydration, and 650 that are uniquely regulated by fasting. We also found five transcripts that were differentially regulated by fasting and dehydration including BDNF and CART. In these studies we have for the first time described the transcriptome of the rat SFO and have in addition identified genes, the expression of which is significantly modified by either water or food deprivation.
American Journal of Physiology-regulatory Integrative and Comparative Physiology | 2009
Pauline M. Smith; Adam P. Chambers; Christopher J. Price; Winnie Ho; Christie Hopf; Keith A. Sharkey; Alastair V. Ferguson
Adipose tissue plays a critical role in energy homeostasis, secreting adipokines that control feeding, thermogenesis, and neuroendocrine function. Leptin is the prototypic adipokine that acts centrally to signal long-term energy balance. While hypothalamic and brain stem nuclei are well-established sites of action of leptin, we tested the hypothesis that leptin signaling occurs in the subfornical organ (SFO). The SFO is a circumventricular organ (CVO) that lacks the normal blood-brain barrier, is an important site in central autonomic regulation, and has been suggested to have a role in modulating peripheral signals indicating energy status. We report here the presence of mRNA for the signaling form of the leptin receptor in SFO and leptin receptor localization by immunohistochemistry within this CVO. Central administration of leptin resulted in phosphorylation of STAT3 in neurons of SFO. Whole cell current-clamp recordings from dissociated SFO neurons demonstrated that leptin (10 nM) influenced the excitability of 64% (46/72) of SFO neurons. Leptin was found to depolarize the majority of responsive neurons with a mean change in membrane potential of 7.3 +/- 0.6 mV (39% of all SFO neurons), while the remaining cells that responded to leptin hyperpolarized (-6.9 +/- 0.7 mV, 25% of all SFO neurons). Similar depolarizing and hyperpolarizing effects of leptin were observed in recordings from acutely prepared SFO slice preparations. Leptin was found to influence the same population of SFO neurons influenced by amylin as three of four cells tested for the effects of bath application of both amylin and leptin depolarized to both peptides. These observations identify the SFO as a possible central nervous system location, with direct access to the peripheral circulation, at which leptin may act to influence hypothalamic control of energy homeostasis.
European Journal of Neuroscience | 1999
David L. S. Washburn; Pauline M. Smith; Alastair V. Ferguson
While most central nervous system (CNS) neurons receive the majority of their input through direct synaptic connections, there is evidence suggesting that they are in fact susceptible to modulation by changes in extracellular ionic composition during both physiological and pathophysiological conditions. In many regions of the CNS, there exists an identified extracellular receptor with the ability to sense levels of cations, most notably calcium. Here we report that activation of this calcium receptor (CaR) in neurons of the subfornical organ (SFO), a forebrain circumventricular structure, results in profound effects on neuronal excitability through metabotropic actions on a non‐selective cation channel. Activation of the CaR by NPS R‐467, an allosteric agonist of the CaR, evoked depolarizing plateau potentials ranging in duration from 5 to 30 s. Similarly, 5 mm CaCl2 caused depolarization and increased action potential frequency. NPS R‐467 was found to activate a non‐selective cation channel with a reversal potential of −48 ± 4 mV, and a slope conductance of 2.54 ± 11 nS. This current could also be elicted by spermine, a known agonist of the CaR. CaR‐mediated activation of this channel was dependent upon both G proteins and intracellular Ca2+ signalling, as disruption of these pathways through inclusion of guanosine 5′‐O‐(2‐thiodiphosphate) (GDP‐β‐S) and 1,2‐bis(2‐aminophenoxy)ethane‐N,N,N ′,N ′‐tetraacetic acid (BAPTA), respectively, in the recording pipette prevented activation of the current. Microinjection of CaR agonists into the SFO of anaesthetized rats resulted in a significant, site‐specific elevation of blood pressure (mean area under curve, 141 ± 50 mmHg.s). Together, these results indicate that the CaR can play an important role in transducing the effects of changes in the extracellular ionic composition, and that these effects have implications for the neural control of fluid balance.
American Journal of Physiology-regulatory Integrative and Comparative Physiology | 2012
Andrea Mimee; Pauline M. Smith; Alastair V. Ferguson
Nesfatin-1 has been identified as one of the most potent centrally acting anorexigenic peptides, and it has also been shown to play important roles in the control of cardiovascular function. In situ hybridization and immunohistochemical studies have revealed the expression of nesfatin-1 throughout the brain and, in particular, in the medullary autonomic gateway known as the nucleus of the solitary tract (NTS). The present study was thus undertaken to explore the cellular correlates and functional roles of nesfatin-1 actions in the medial NTS (mNTS). Using current-clamp electrophysiology recordings from mNTS neurons in slice preparation, we show that bath-applied nesfatin-1 directly influences the excitability of the majority of mNTS neurons by eliciting either depolarizing (42%, mean: 7.8 ± 0.8 mV) or hyperpolarizing (21%, mean: -8. 2 ± 1.0 mV) responses. These responses were observed in all electrophysiologically defined cell types in the NTS and were site specific and concentration dependent. Furthermore, post hoc single cell reverse transcriptase polymerase reaction revealed a depolarizing action of nesfatin-1 on NPY and nucleobindin-2-expressing mNTS neurons. We have also correlated these actions of nesfatin-1 on neuronal membrane potential with physiological outcomes, using in vivo microinjection techniques to demonstrate that nesfatin-1 microinjected into the mNTS induces significant increases in both blood pressure (mean AUC = 3354.1 ± 750.7 mmHg·s, n = 6) and heart rate (mean AUC = 164.8 ± 78.5 beats, n = 6) in rats. Our results provide critical insight into the circuitry and physiology involved in the profound effects of nesfatin-1 and highlight the NTS as a key structure mediating these autonomic actions.
Regulatory Peptides | 1990
Alastair V. Ferguson; Pauline M. Smith
The recently described endothelium derived constricting factor endothelin (ET) is a 21 amino acid peptide which is the most potent endogenous vasoconstrictor yet described. Binding sites for this peptide have been demonstrated within the circumventricular structures of the brain. One of these structures, the area postrema (AP), has been implicated in central cardiovascular control mechanisms. We have therefore examined the effects of AP microinjection of ET on blood pressure in urethane-anaesthetised rats. Such treatment resulted in dose-dependent biphasic changes in arterial blood pressure (increases followed by decreases). Low doses of ET (0.2-1.0 pmol) induced significant increases (P less than 0.01), and high doses (5.0 pmol) significant decreases (P less than 0.01), while at intermediate concentrations (2.0 pmol) ET caused significant increases (P less than 0.05) followed by significant decreases (P less than 0.01) in mean blood pressure. Other vasoconstrictors were found to be without effect following AP administration, suggesting these changes to be the result of specific action of ET. In contrast, both ET and methoxamine had similar cardiovascular actions when microinjected into regions anatomically adjacent to the AP such as the NTS, indicating that vasoconstriction in these areas induces changes in femoral arterial blood pressure. These data suggest a specific role for ET as a chemical messenger involved in central nervous system control of the cardiovascular system within AP.
Developmental Disabilities Research Reviews | 2008
Pauline M. Smith; Alastair V. Ferguson
Hunger is defined as a strong desire or need for food while satiety is the condition of being full or gratified. The maintenance of energy homeostasis requires a balance between energy intake and energy expenditure. The regulation of food intake is a complex behavior. It requires discrete nuclei within the central nervous system (CNS) to detect signals from the periphery regarding metabolic status, process and integrate this information in a coordinated manner and to provide appropriate responses to ensure that the individual does not enter a state of positive or negative energy balance. This review of hunger and satiety will examine the CNS circuitries involved in the control of energy homeostasis as well as signals from the periphery, both hormonal and neural, that convey pertinent information regarding short-term and long-term energy status of the individual.