THE PHYSIOLOGICAL ACTIONS OF ADIPONECTIN IN CENTRAL AUTONOMIC NUCLEI: IMPLICATIONS FOR THE INTEGRATIVE CONTROL OF ENERGY HOMEOSTASIS

HOYDA, TED

13 April 2010

Adiponectin regulates feeding behavior, energy expenditure and autonomic function through the activation of two receptors present in nuclei throughout the central nervous system, however much remains unknown about the mechanisms mediating these effects. Here I investigate the actions of adiponectin in autonomic centers of the hypothalamus (the paraventricular nucleus) and brainstem (the nucleus of the solitary tract) through examining molecular, electrical, hormonal and physiological consequences of peptidergic signalling. RT-PCR and in situ hybridization experiments demonstrate the presence of AdipoR1 and AdipoR2 mRNA in the paraventricular nucleus. Investigation of the electrical consequences following receptor activation in the paraventricular nucleus indicates that magnocellular-oxytocin cells are homogeneously inhibited while magnocellular-vasopressin neurons display mixed responses. Single cell RT-PCR analysis shows oxytocin neurons express both receptors while vasopressin neurons express either both receptors or one receptor. Co-expressing oxytocin and vasopressin neurons express neither receptor and are not affected by adiponectin. Median eminence projecting corticotropin releasing hormone neurons, brainstem projecting oxytocin neurons, and thyrotropin releasing hormone neurons are all depolarized by adiponectin. Plasma adrenocorticotropin hormone concentration is increased following intracerebroventricular injections of adiponectin. I demonstrate that the nucleus of the solitary tract, the primary cardiovascular regulation site of the medulla, expresses mRNA for AdipoR1 and AdipoR2 and mediates adiponectin induced hypotension. Adiponectin has electrical effects on a majority of medial solitary tract neurons and depolarizes those expressing mRNA for the hypotensive neuropeptide Y, revealing a central mechanism to modulate blood pressure. Finally, I show that adiponectin controls paraventricular nucleus neuron excitability by either inhibiting a tetraethyl ammonium-sensitive potassium current thereby depolarizing neurons or activating a glibenclamide-sensitive voltage independent potassium current hyperpolarizing neurons. Therefore, adiponectin differentially modulates potassium current to confer its central effects. These results are the first to show the physiological and electrical actions of adiponectin on individual neurons in blood brain barrier protected central autonomic nuclei. This thesis provides a framework for how adiponectin acts centrally to coordinate whole body energy homeostasis and feeding behavior in the rat. / Thesis (Ph.D, Physiology) -- Queen's University, 2009-09-15 16:50:13.933

adiponectin

paraventricular nucleus

nucleus of the solitary tract

energy homeostasis

autonomic function

Differential activation of brainstem neurons with transcutaneous auricular vagus nerve stimulation and its comparability to cervical vagus nerve stimulation

Owens, Misty, Jacquemet, Vincent, Napadow, Vitaly, Beaumont, Eric

25 April 2023

Non-invasive transcutaneous auricular vagus nerve stimulation (taVNS) is a neuromodulatory technique used to activate vagal afferent fibers located in the concha of the outer ear. Vagal afferents project to the nucleus of the solitary tract (NTS) where information is processed and propagated to higher brain regions. Widespread NTS connections provide a mechanism through which taVNS can be used to influence multiple systems and be a potential treatment for many disorders including heart failure, gastric motility disorders, and migraines. Recent studies are now investigating taVNS as an alternative treatment option to invasive cervical vagus nerve stimulation (cVNS) which is FDA approved to treat drug-resistant epilepsy and depression but has limited patient availability due to the invasiveness of the procedure. Migraine and epilepsy clinical studies have shown therapeutic taVNS benefits and human fMRI studies have demonstrated comparable brain activation between cVNS and taVNS. However, questions remain regarding optimal taVNS parameters, and no study has compared the direct mechanisms responsible for cVNS and taVNS effects. In this study, a high-impedance tungsten electrode was stereotaxically placed into NTS in 10 chloralose-anesthetized rats, and 40-70 neurons were interrogated using electrophysiological methods. Firing rate changes during stimulation on-times were compared to activity levels during stimulation off-times. Neurons were classified as positive responders if they displayed consistent firing rate increases during stimulation, negative responders if they displayed consistent decreases, and non-responders if there was no consistency using a mathematical cosine similarity score. Six taVNS stimulation parameters were investigated using three frequencies (20, 100, 250Hz) at two intensities (0.5, 1.0mA) to identify parameter-specific effects on NTS neurons. Additionally, neuronal activity was evaluated following cVNS at 20 and 250Hz at the bradycardic intensity (lowest intensity to generate a transient 5% decrease in heart rate, BI) and compared to taVNS effects at the corresponding frequencies. Our data shows that taVNS at 20Hz, 1.0mA yields the greatest number of positive responders and 100Hz, 1.0mA yields the greatest number of negative responders (p<0.05) suggesting different taVNS parameters can differentially influence NTS activity. Comparisons between the number of responders generated with cVNS and taVNS revealed significantly fewer negative responders with cVNS at 20Hz compared to taVNS at 20Hz regardless of intensity (p<0.01) but yielded comparable positive responders between cVNS at 20Hz, BI and taVNS at 20Hz, 1.0mA. No significant differences were observed between the number of cVNS and taVNS responders at 250Hz. Interestingly, individual neuronal responses were different between both methods of stimulation, suggesting that they could work through different neuronal pathways.

Vagus nerve

Nucleus of the solitary tract

Vagus nerve stimulation

Neuroscience

Hypothalamic Orexin a-Immunoreactive Neurons Project to the Rat Dorsal Medulla

Harrison, T. A., Chen, C. T., Dun, N. J., Chang, J. K.

24 September 1999

Retrograde tract tracing combined with immunohistochemical techniques were used to identify the origin of orexin A-immunoreactive (OrA-ir) fibers in the rat medulla. One to 5 days following injection of the fluorescent dye Fluorogold into the dorsal medulla, labeled neurons were found in the lateral half of the lateral hypothalamus, paraventricular, perifornical, dorsomedial, dorsal and posterior hypothalamic nuclei. Labeling the same sections with OrA antisera revealed a concentration of OrA-ir neurons in the perifornical and dorsomedial regions of the tuberal hypothalamus. A maximum of 10% of Fluorogold-labeled hypothalamic neurons were OrA-ir and 15% of OrA-ir hypothalamic neurons contained Fluorogold. Our results demonstrate that a fraction of OrA-ir neurons in the tuberal hypothalamus project to areas of the medulla that are involved in autonomic functions.

dorsal motor nucleus of the vagus

fluorogold

hypocretin

lateral hypothalamus

nucleus of the solitary tract

Metastin-Like Immunoreactivity in the Rat Medulla Oblongata and Spinal Cord

Dun, Siok L., Brailoiu, G. Cristina, Parsons, Amy, Yang, Jun, Zeng, Qiang, Chen, Xiangqun, Chang, Jaw Kang, Dun, Nae J.

02 January 2003

Metastin, the product of metastasis suppressor gene KiSS-1, is proposed to be the natural ligand for the G-protein-coupled receptor GPR54, known also as AXOR12. This immunohistochemical study, using a rabbit polyclonal antiserum against the human metastin fragment (45-54)-NH2, showed that in rats metastin-like immunoreactivity (MTS-LI) was present in neurons of the nucleus of the solitary tract and caudoventrolateral reticular nucleus, and in cell processes of the spinal trigeminal tract and lateral reticular nucleus. MTS-LI was confined mainly to neurons and fibers at or caudal to the area postrema. In the spinal cord, MTS-LI cell processes formed a dense plexus in superficial layers I and II of the dorsal horn. The pattern of distribution of MTS-LI in the medulla and spinal cord suggests that this novel peptide may participate in autonomic and sensory neural signaling.

caudoventrolateral reticular nucleus

dorsal horn

nucleus of the solitary tract

rostroventrolateral reticular nucleus

spinal trigeminal tract

KISS-1 Expression and Metastin-Like Immunoreactivity in the Rat Brain

Brailoiu, G. Cristina, Dun, Siok L., Ohsawa, Masahiro, Yin, Deling, Yang, Jun, Jaw, Kang Chang, Brailoiu, Eugen, Dun, Nae J.

17 January 2005

Metastin, the gene product of metastasis suppressor gene KiSS-1, is the endogenous ligand for the G-protein-coupled receptor GPR54 (or AXOR12, or OT7T175). The expression of KiSS-1 gene and peptide and the distribution of metastin were studied in the rat central nervous system by reverse transcriptase-polymerase chain reaction, Western blotting, and immunohistochemical methods. KiSS-1 gene and peptide expression was higher in the hypothalamus than in the brainstem and spinal cord. In the brain, metastin-like immunoreactivity (irMT) was found mainly in three groups of cells: dorsomedial hypothalamic nucleus, nucleus of the solitary tract, and caudal ventrolateral medulla. Immunoreactive fibers of varying density were noted in bed nucleus of stria terminalis, septal nuclei, nucleus accumbens, caudate putamen, diagonal band, amygdala, hypothalamus, zona incerta, thalamus, periaqueductal gray, raphe nuclei, lateral parabrachial nucleus, locus coeruleus, spinal trigeminal tract, rostral ventrolateral medulla, and medullary reticular nucleus. Preabsorption of the antiserum with metastin peptide fragment (45-54)-NH2 (1 μg/ml) resulted in no staining in any of the sections. The biological activity of metastin was assessed by monitoring intracellular calcium [Ca2+]i in cultured hippocampal neurons, which are known to express GPR54. Metastin increased [Ca 2+]i in a population of cultured hippocampal neurons. The results show that metastin is biologically active in rat central neurons, and its anatomical distribution suggests a possible role in nociception and autonomic and neuroendocrine functions.

caudoventrolateral reticular nucleus

dorsal horn

hypothalamus

nucleus of the solitary tract

tyrosine hydroxylase

Distinct Regional Distributions of nk1 and nk3 Neurokinin Receptor Immunoreactivity in Rat Brainstem Gustatory Centers

Harrison, Theresa A., Hoover, Donald B., King, Michael S.

01 March 2004

Tachykinins and their receptors are present in gustatory centers, but little is known about tachykinin function in gustation. In this study, immunohistochemical localization of substance P and two centrally prevalent neurokinin receptors, NK1 and NK3, was carried out in the rostral nucleus of the solitary tract and the caudal parabrachial nucleus to evaluate regional receptor/ligand correspondences. All three proteins showed regional variations in labeling density that correlated with distinct sites in gustatory centers. In the rostral nucleus of the solitary tract, the relative densities of substance P and NK1 receptors varied in parallel across subnuclei, with both being moderate to dense in the dorsocentral, chemoresponsive zone. NK3 receptors had a distinct distribution in the caudal half of this zone, suggesting a unique role in processing taste input from the posterior tongue. In the caudal parabrachial nucleus, substance P and NK1 receptor immunoreactivities were dense in the pontine taste area, while NK3 receptor labeling was sparse. The external medial subnucleus had substantial NK3 receptor and substance P labeling, but little NK1 receptor immunoreactivity. These findings suggest that distinct tachykinin ligand/neurokinin receptor combinations may be important in local processing of information within brainstem gustatory centers.

immunohistochemistry

neurokinin B

pontine taste area

rostral nucleus of the solitary tract

substance P

tachykinin

Biomedical Sciences

Cervical Vagus Nerve Stimulation Augments Spontaneous Discharge in Second-and Higher-Order Sensory Neurons in the Rat Nucleus of the Solitary Tract

Beaumont, Eric, Campbell, Regenia P., Andresen, Michael C., Scofield, Stephanie, Singh, Krishna, Libbus, Imad, Kenknight, Bruce H., Snyder, Logan, Cantrell, Nathan

11 August 2017

Vagus nerve stimulation (VNS) currently treats patients with drug-resistant epilepsy, depression, and heart failure. The mild intensities used in chronic VNS suggest that primary visceral afferents and central nervous system activation are involved. Here, we measured the activity of neurons in the nucleus of the solitary tract (NTS) in anesthetized rats using clinically styled VNS. Our chief findings indicate that VNS at threshold bradycardic intensity activated NTS neuron discharge in one-third of NTS neurons. This VNS directly activated only myelinated vagal afferents projecting to second-order NTS neurons. Most VNS-induced activity in NTS, however, was unsynchronized to vagal stimuli. Thus, VNS activated unsynchronized activity in NTS neurons that were second order to vagal afferent C-fibers as well as higher-order NTS neurons only polysynaptically activated by the vagus. Overall, cardiovascular-sensitive and -insen-sitive NTS neurons were similarly activated by VNS: 3/4 neurons with monosynaptic vagal A-fiber afferents, 6/42 neurons with monosynaptic vagal C-fiber afferents, and 16/21 polysynaptic NTS neurons. Provocatively, vagal A-fibers indirectly activated C-fiber neurons during VNS. Elevated spontaneous spiking was quantitatively much higher than synchronized activity and extended well into the periods of nonstimulation. Surprisingly, many polysynaptic NTS neurons responded to half the bradycardic intensity used in clinical studies, indicating that a subset of myelinated vagal afferents is sufficient to evoke VNS indirect activation. Our study uncovered a myelinated vagal afferent drive that indirectly activates NTS neurons and thus central pathways beyond NTS and support reconsideration of brain contributions of vagal afferents underpinning of therapeutic impacts. NEW & NOTEWORTHY Acute vagus nerve stimulation elevated activity in neurons located in the medial nucleus of the solitary tract. Such stimuli directly activated only myelinated vagal afferents but indirectly activated a subpopulation of second- and higher-order neurons, suggesting that afferent mechanisms and central neuron activation may be responsible for vagus nerve stimulation efficacy.

baroreceptors

blood pressure

echocardiography

nucleus of the solitary tract

rats

vagal primary afferents

vagus nerve stimulation

Biomedical Sciences

Transcutaneous Auricular Vagal Nerve Stimulation (taVNS) as a Potential Treatment for Cardiac, Gastric Motility, and Migraine Disorders

Owens, Misty, Dugan, Laura, Farrand, Ariana, Cooper, Coty, Napadow, Vitaly, Beaumont, Eric

07 April 2022

Transcutaneous auricular vagal nerve stimulation (taVNS) is a non-invasive method of activating axons in the auricular branch of the vagus nerve through the concha of the outer ear. taVNS is under investigation as an alternative treatment option for a wide range of disorders. Vagal afferent fibers terminate in the nucleus of the solitary tract (NTS) where information is processed and relayed to higher brain regions influencing sympathetic and parasympathetic systems. Due to extensive neuronal connections, it is likely that taVNS could serve as a treatment option for many disorders, specifically cardiac, migraine, and gastric motility disorders. Human fMRI studies have indicated that taVNS elicits neuronal responses within NTS and spinal trigeminal nucleus (Sp5c). Studies have indicated that caudal NTS (cNTS) has substantial connections with the cardiac system, rostral NTS (rNTS) is relevant for gastric motility, and Sp5c is likely involved in migraine disorders due to meningeal connections. Aberrant neuronal signaling is likely responsible for the development of these disorders, and taVNS has the potential to modulate neuronal activity to reestablish homeostatic signaling. In this study, electrophysiological methods were used to interrogate neuronal activity of 50-70 neurons within cNTS, rNTS, and Sp5c following taVNS. A high-impedance tungsten electrode was placed stereotaxically in 15 male Sprague-Dawley rats anesthetized with chloralose. Changes in neuronal firing rates were investigated during and immediately following taVNS by comparing changes in neuronal activity to baseline levels using the software Spike 2 v9.14. Neurons were classified as negative responders if activity decreased more than 20%, positive responders if activity increased more than 20%, or non-responders if activity changes were less than 20%. Six different taVNS parameters were investigated using three frequencies (20, 100, 250Hz) at two intensity levels (0.5, 1.0mA). Data from this study suggest that taVNS can modulate neuronal activity in a frequency and intensity-dependent manner. The greatest positive activation for all 3 brain regions occurred at 20Hz, 1.0mA stimulation where an average of 46% ± 9% neurons showed increased firing compared to 29% ± 2% positive responders for other paradigms. The greatest negative activation for all 3 regions occurred at 100Hz, regardless of intensity, where an average of 33% ± 1% neurons showed reduced firing compared to 15% ± 2% negative responders for remaining paradigms. Based on what is known about cardiac, migraine, and gastric motility disorders, it is likely that taVNS can be used to modulate activity in NTS and Sp5c to provide beneficial treatment options to patients. Specifically, using paradigms yielding decreased activity in Sp5c could improve migraine symptoms, and paradigms increasing activity in cNTS and rNTS could improve cardiac and gastric motility disorders, respectively.

Vagus nerve

spinal trigeminal nucleus

heart failure

nucleus of the solitary tract

Neuroscience

Prolactin-Releasing Peptide-Immunoreactivity in A1 and A2 Noradrenergic Neurons of the Rat Medulla

Chen, C. T., Dun, S. L., Dun, N. J., Chang, J. K.

20 March 1999

Distribution of prolactin-releasing peptide-like immunoreactivity (PrRP- LI) was investigated in the rat medulla with the use of a rabbit polyclonal antiserum against the human PrRP-31 peptide. PrRP-positive neurons were noted mainly in two areas of the caudal medulla: ventrolateral reticular formation and commissural nucleus of the nucleus of the solitary tract (NTS), corresponding to the A1 and A2 areas. PrRP-LI neurons were absent in the medulla rostral to the area postrema. Double-labeling the sections with PrRP antisera and tyrosine hydroxylase (TH) monoclonal antibodies revealed extensive colocalization of PrRP- and TH-like immunoreactivity (TH-LI) in neurons of the A1 and A2 areas. Our results show that PrRP-LI is expressed in a population of A1 and A2 noradrenergic neurons of the rat caudal medulla.

A1 and A2 noradrenergic neurons

nucleus of the solitary tract

prolactin

prolactin-releasing peptide

reticular formation

tyrosine hydroxylase

Cocaine- and Amphetamine-Regulated Transcript Peptide Attenuates Baroreflex in the Rat.

Scruggs, Phouangmala C.

03 May 2003

Cocaine- and amphetamine-regulated transcript (CART) was first identified in the rat striatum where levels were upregulated following cocaine or amphetamine administration. A dense plexus of CART-immunoreactive fibers is noted in the nucleus of the solitary tract (NTS). Results from tract-tracing and immunohistochemical studies suggest that the dense network of CARTp-fibers in the NTS may arise from nodose ganglia. The present study was undertaken to evaluate the hypothesis that CARTp may alter baroreceptor function in rats. Rats were intravenously administered phenylephrine every 10 min to elicit a baroreflex. CARTp (0.1- 3 nmol) by intracisternal or bilateral intra-NTS microinjection consistently attenuated the phenylephrineinduced bradycardia. In contrast, CARTp antibody potentiated the bradycardia produced from phenylephrine. Microinjection of saline, normal rabbit serum, or concomitant injection of CARTp and CART antibody into the NTS caused no significant change of phenylephrineinduced baroreflex. The result suggests that CARTp released from primary afferents may modulate baroreflex.

Phenylephrine

Nucleus of the solitary tract

Nodose ganglia

Baroreflex

Medical Sciences

Medicine and Health Sciences