Oxytocin Enhances Cranial Visceral Afferent Synaptic Transmission to the Solitary Tract Nucleus

Peters, James H.; McDougall, Stuart J.; Kellett, Daniel O.; Jordan, David L.; Llewellyn‐Smith, Ida J.; Andresen, Michael

doi:10.1523/jneurosci.3419-08.2008

Cited by 120 publications

(154 citation statements)

References 45 publications

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“…These synchronous EPSCs conform to parabolic variance-mean amplitude relationships indicating that ST axons have a high probability of release (ϳ90% in 2 mM external Ca 2ϩ ) and activate an average of 18 active zone release sites (Bailey et al, 2006b;Andresen and Peters, 2008;Peters et al, 2008). Interestingly, even multiple convergent ST inputs perform independently (Peters et al, 2011;McDougall and Andresen, 2013), which implies that ST synaptic release zones are quite selfcontained with clear spatial delimitations.…”

Section: Cav-sourced Calcium Drives Synchronous Vesicle Releasementioning

confidence: 75%

“…؊ afferents ST afferents lacking TRPV1 have myelinated axons (Jin et al, 2004), are relatively rare, and have indistinguishable synchronous release compared with TRPV1 ϩ afferents (Andresen and Peters, 2008). Neurons receiving these afferents serve as a natural "control" for comparison to the C-fiber TRPV1 ϩ afferent phenotype.…”

Section: Cavs Only Contribute To Synchronous Release On Trpv1mentioning

confidence: 99%

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Distinct Calcium Sources Support Multiple Modes of Synaptic Release from Cranial Sensory Afferents

2016

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Most craniosensory afferents have unmyelinated axons expressing TRP Vanilloid 1 (TRPV1) receptors in synaptic terminals at the solitary tract nucleus (NTS).Neurotransmission from these synapses is characterized by substantial asynchronous EPSCs following action potential-synched EPSCs and high spontaneous rates that are thermally sensitive. The present studies blocked voltage-activated calcium channels (CaV) using the nonselective CaV blocker Cd 2ϩ or the specific N-type blocker -conotoxin GVIA to examine the calcium dependence of the synchronous, asynchronous, spontaneous, and thermally gated modes of release. In rat brainstem slices containing caudal NTS, shocks to the solitary tract (ST) triggered synchronous ST-EPSCs and trailing asynchronous EPSCs. Cd 2ϩ or GVIA efficiently reduced both synchronous and asynchronous EPSCs without altering spontaneous or thermal-evoked transmission. Activation of TRPV1 with either the selective agonist resiniferatoxin (150 pM) or temperature augmented basal sEPSC rates but failed to alter the synchronous or asynchronous modes of release. These data indicate that calcium sourced through TRPV1 has no access to the synchronous or asynchronous release mechanism(s) and conversely that CaV-sourced calcium does not interact with the thermally evoked mode of release. Buffering intracellular calcium with EGTA-AM or BAPTA-AM reduced asynchronous EPSC rates earlier and to a greater extent than synchronous ST-EPSC amplitudes without altering sEPSCs or thermal sensitivity. Buffering therefore distinguishes asynchronous vesicles as possessing a highly sensitive calcium sensor located perhaps more distant from CaV than synchronous vesicles or thermally evoked vesicles from TRPV1. Together, our findings suggest separate mechanisms of release for spontaneous, asynchronous and synchronous vesicles that likely reside in unique, spatially separated vesicle domains.

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Section: Cav-sourced Calcium Drives Synchronous Vesicle Releasementioning

confidence: 75%

Section: Cavs Only Contribute To Synchronous Release On Trpv1mentioning

confidence: 99%

Distinct Calcium Sources Support Multiple Modes of Synaptic Release from Cranial Sensory Afferents

2016

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“…Thus, central vagal afferent endings not only are conduits of signals arriving from the gut, but also may be directly engaged by signals converging onto the NTS from other brain areas. Several anorexic and orexigenic signals have been shown previously to modulate neurotransmission from central vagal afferent endings, including oxytocin (Peters et al, 2008), ghrelin (Cui et al, 2011), and serotonin (Cui et al, 2012). Whether these and other signals also influence food intake by engaging the gut-to-brain circuit via direct activation of central vagal afferent endings merits future investigation.…”

Section: Discussionmentioning

confidence: 95%

Central Vagal Afferent Endings Mediate Reduction of Food Intake by Melanocortin-3/4 Receptor Agonist

Campos

Shiina

Ritter

2014

Journal of Neuroscience

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Injection of the melanocortin-3/4 receptor agonist melanotan-II (MTII) into the nucleus of the solitary tract (NTS) produces rapid and sustained reduction of food intake. Melanocortin-4 receptors (MC4Rs) are expressed by vagal afferent endings in the NTS, but it is not known whether these endings participate in MTII-induced reduction of food intake. In experiments described here, we evaluated the contribution of central vagal afferent endings in MTII-induced reduction of food intake. Examination of rat hindbrain sections revealed that neuronal processes expressing immunoreactivity for the endogenous MC4R agonist ␣-melanoctyte-stimulating hormone course parallel and wrap around anterogradely labeled vagal afferent endings in the NTS and thus are aptly positioned to activate vagal afferent MC4Rs. Furthermore, MTII and endogenous MC4R agonists increased protein kinase A (PKA)-catalyzed phosphorylation of synapsin I in vagal afferent endings, an effect known to increase synaptic strength by enhancing neurotransmitter release in other neural systems. Hindbrain injection of a PKA inhibitor, KT5720, significantly attenuated MTII-induced reduction of food intake and the increase in synapsin I phosphorylation. Finally, unilateral nodose ganglion removal, resulting in degeneration of vagal afferent endings in the ipsilateral NTS, abolished MTII-induced synapsin I phosphorylation ipsilateral to nodose ganglion removal. Moreover, reduction of food intake following MTII injection into the NTS ipsilateral to nodose ganglion removal was significantly attenuated, whereas the response to MTII was not diminished when injected into the contralateral NTS. Altogether, our results suggest that reduction of food intake following hindbrain MC4R activation is mediated by central vagal afferent endings.

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“…Oxytocinergic terminals are evenly distributed throughout the NTS (23,35), and OT-immunoreactive axons are closely apposed, suggesting synaptic contacts, with second-order NTS neurons (35). Peters et al (35) showed that OT released from OTergic axons acts on a subset of second-order NTS neurons to enhance afferent visceral transmission via presynaptic (i.e., increased probability for glutamate release) and postsynaptic (increased inward current by closure of K ϩ channels) mechanisms. Therefore, activation of PVN-NTS OTergic projections causes a slowing of HR via at least two different mechanisms: modulation of afferent signaling and a direct effect of depolarizing and exciting NTS neurons.…”

Section: Discussionmentioning

confidence: 99%

Afferent signaling drives oxytocinergic preautonomic neurons and mediates training-induced plasticity

Cavalleri

Burgi

Cruz

et al. 2011

American Journal of Physiology-Regulatory, Integrative and Comp

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Michelini LC. Afferent signaling drives oxytocinergic preautonomic neurons and mediates training-induced plasticity. Am J Physiol Regul Integr Comp Physiol 301: R958 -R966, 2011. First published July 27, 2011 doi:10.1152/ajpregu.00104.2011.-We showed previously that oxytocinergic (OTergic) projections from the hypothalamic paraventricular nucleus (PVN) to the dorsal brain stem mediate traininginduced heart rate (HR) adjustments and that beneficial effects of training are blocked by sinoaortic denervation (SAD; Exp Physiol 94: 630 -640; 1103-1113). We sought now to determine the combined effect of training and SAD on PVN OTergic neurons in spontaneously hypertensive rats (SHR) and Wistar-Kyoto (WKY) rats. Rats underwent SAD or sham surgery and were trained (55% of maximal capacity) or kept sedentary for 3 mo. After hemodynamic measurements were taken at rest, rats were deeply anesthetized. Fresh brains were frozen and sliced to isolate the PVN; samples were processed for OT expression (real-time PCR) and fixed brains were processed for OT immunofluorescence. In sham rats, training improved treadmill performance and increased the gain of baroreflex control of HR. Training reduced resting HR (Ϫ8%) in both groups, with a fall in blood pressure (Ϫ10%) only in SHR rats. These changes were accompanied by marked increases in PVN OT mRNA expression (3.9-and 2.2-fold in WKY and SHR rats, respectively) and peptide density in PVN OTergic neurons (2.6-fold in both groups), with significant correlations between OT content and training-induced resting bradycardia. SAD abolished PVN OT mRNA expression and markedly reduced PVN OT density in WKY and SHR. Training had no effect on HR, PVN OT mRNA, or OT content following SAD. The chronic absence of inputs from baroreceptors and chemoreceptors uncovers the pivotal role of afferent signaling in driving both the plasticity and activity of PVN OTergic neurons, as well as the beneficial effects of training on cardiovascular control. sinoaortic denervation; exercise training; hypothalamus; paraventricular nucleus; supraoptic nucleus; oxytocin; spontaneous hypertension ACCUMULATING EXPERIMENTAL evidence from our and other laboratories has shown that aerobic training promotes several beneficial cardiovascular effects in normotensive and hypertensive individuals. Training causes remodeling of the heart with a simultaneous stroke volume increase and heart rate (HR) decrease (5, 34, 40), outward eutrophic remodeling of arterioles, capillary angiogenesis, and venule neoformation in the exercised muscles (1-3, 10, 24). Exercise training is also accompanied by a predominance of relaxation over contractile endothelium-derived factors (15, 44). These adaptive mechanisms by improving blood flow and tissue conductance, by reducing vascular resistance, and restoring normal endothelial function favor the amelioration of impaired functions in cardiovascular disease.Training reduces both the activity of the renin-angiotensin system and oxidative stress (13,22,38) and effectively induces neuronal pla...

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Oxytocin Enhances Cranial Visceral Afferent Synaptic Transmission to the Solitary Tract Nucleus

Cited by 120 publications

References 45 publications

Distinct Calcium Sources Support Multiple Modes of Synaptic Release from Cranial Sensory Afferents

Distinct Calcium Sources Support Multiple Modes of Synaptic Release from Cranial Sensory Afferents

Central Vagal Afferent Endings Mediate Reduction of Food Intake by Melanocortin-3/4 Receptor Agonist

Afferent signaling drives oxytocinergic preautonomic neurons and mediates training-induced plasticity

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