Activation of Orexin System Stimulates CaMKII Expression

Hyperactivity of the orexin system within the paraventricular nucleus (PVN) has been shown to contribute to increased sympathetic nerve activity (SNA) and blood pressure (BP) in rodent animals. However, the underlying molecular mechanisms remain unclear. Here, we test the hypothesis that orexin system activation stimulates calcium/calmodulin-dependent kinase II (CaMKII) expression and activation, and stimulation of CaMKII expressing PVN neurons increases SNA and BP. Real-time PCR and/or western blot were carried out to test the effect of orexin-A administration on CaMKII expression in the PVN of normal Sprague Dawley (SD) rats and orexin receptor 1 (OX1R) expressing PC12 cells. Immunostaining was performed to assess OX1R cellular localization in the PVN of SD rats as well as orexin-A treatment on CaMKII activation in cultured hypothalamic neurons. In vivo sympathetic nerve recordings were employed to test the impact of optogenetic stimulation of CaMKII-expressing PVN neurons on the renal SNA (RSNA) and BP. The results showed that intracerebroventricular injection of orexin-A into the SD rat increases mRNA expression of CaMKII subunits in the PVN. In addition, Orexin-A treatment increases CaMKII expression and its phosphorylation in OX1R-expressing PC12 cells. Furthermore, Orexin-A treatment increases CaMKII activation in cultured hypothalamic neurons from neonatal SD rats. Finally, optogenetic excitation of PVN CaMKII-expressing neurons results in robust increases in RSNA and BP in SD rats. Our results suggest that increased orexin system activity activates CaMKII expression in cardiovascular relevant regions, and this may be relevant to the downstream cardiovascular effects of CaMKII.

From Brain to Blood Vessel: Insights From Muscle Sympathetic Nerve Recordings

Multiunit recordings of postganglionic sympathetic outflow to muscle yield otherwise imperceptible insights into sympathetic neural modulation of human vascular resistance and blood pressure. This Corcoran Lecture will illustrate the utility of microneurography to investigate neurogenic cardiovascular regulation; review data concerning muscle sympathetic nerve activity of women and men with normal and high blood pressure; explore 2 concepts, central upregulation of muscle sympathetic outflow and cortical autonomic neuroplasticity; present sleep apnea as an imperfect model of neurogenic hypertension; and expose the paradox of sympathetic excitation without hypertension. In awake healthy normotensive individuals, resting muscle sympathetic nerve activity increases with age, sleep fragmentation, and obstructive apnea. Its magnitude is not signaled by heart rate. Age-related changes are nonlinear and differ by sex. In men, sympathetic nerve activity increases with age but without relation to their blood pressure, whereas in women, both rise concordantly after age 40. Mean values for muscle sympathetic nerve activity burst incidence are consistently higher in cohorts with hypertension than in matched normotensives, yet women’s sympathetic nerve traffic can increase 3-fold between ages 30 and 70 without causing hypertension. Thus, increased sympathetic nerve activity may be necessary but is insufficient for primary hypertension. Moreover, its inhibition does not consistently decrease blood pressure. Despite a half-century of microneurographic research, large gaps remain in our understanding of the content of the sympathetic broadcast from brain to blood vessel and its specific individual consequences for circulatory regulation and cardiovascular, renal, and metabolic risk.

A45 A NOVEL PH-SENSITIVE OPIOID ANALGESIC THAT SELECTIVELY INHIBITS NOCICEPTION IN DSS-INDUCED COLITIS

Background Opioid drugs are used to treat pain in inflammatory bowel disease (IBD) but their side effects can cause serious morbidity. Therefore, we tested a novel opioid analgesic, ±)-N-(3-fluoro-1-phenethylpiperidine-4-yl)-N-phenylpropionamide (NFEPP) which selectively activates peripheral µ-opioid receptors at acidic pH, as occurs in inflamed tissue. Aims Evaluate whether NFEPP causes analgesia in the inflamed colon of DSS-colitis mice using both in vitro and in vivo techniques. Methods To measure the visceral motor reflex (VMR) in response to colorectal distention, EMG electrodes connected to a telemetric transmitter were implanted in mice (c57BL/6), after 10 days recovery acute dextran sodium sulfate (DSS) colitis was induced (5 days 2.5% DSS, 2 days water). VMR was measured 30 min after s.c. injection of vehicle or 0.2 mg/kg of NFEPP or fentanyl. Motility was assessed by fecal pellet count 1 hour after NFEPP. Colonic tissue pH was evaluated using the SNARF-4F-5 carboxylic acid probe. Excitability of mouse dorsal root ganglia (DRG) neurons was measured by recording the rheobase (minimum input current to fire an action potential) after superfusion of NFEPP (300 nM, 10 min) or vehicle at pH 6.5 or 7.4. Colonic afferent nerve responses to probing with a von Frey filament (1 gm) were examined before and after exposure to NFEPP (300 nM, 5 min superfusion) at pH 6.5 and 7.4 respectively. The data was analyzed with Welch’s t-test, 1- or 2-way ANOVA with post hoc Dunnett or Bonferroni or Tukey’s test. Results NFEPP significantly inhibited the VMR in response to distension in mice with colitis compared to vehicle (decreased response by 65%, P<0.001). NFEPP had no effect in control mice. Conversely, fentanyl caused a similar decreased response in both groups (DSS 79% and control 67%, P<0.001). Pelleting was not affected by NFEPP injection in either group compared to vehicle. The pH measurement revealed a more acidic environment in DSS colonic tissue (ΔpH0.37±0.14, P<0.05) compared to controls. In patch-clamp studies, NFEPP decreased DRG excitability at pH 6.5 compared to the baseline and vehicle (increased rheobase 53.84%, P<0.01 and 36.36%, P<0.05 respectively) but had no effect at pH 7.4. In colonic afferent nerve recordings, NFEPP significantly attenuated afferent responses (28.9% P<0.01) to probing at pH 6.5 but also had no effect at pH 7.4. Conclusions This pH-selective opioid agonist significantly inhibits pain at the site of inflammation where the tissue pH is acidic but has no effect in tissues where the pH is in the physiological range. Thus, NFEPP could be an effective opioid analgesic in IBD while being devoid of any unwanted side effects. Funding Agencies CCC

Evidence for sparse C-tactile afferent innervation of glabrous human hand skin

C-tactile (CT) afferents were long-believed to be lacking in humans, but were subsequently shown to densely innervate the face and arm skin, and to a lesser extent the leg. Their firing frequency to stroking touch at different velocities has been correlated with ratings of tactile pleasantness. CT afferents were thought to be absent in human glabrous skin; however, tactile pleasantness can be perceived across the whole body, including glabrous hand skin. We used microneurography to investigate mechanoreceptive afferents in the glabrous skin of the human hand, during median and radial nerve recordings. We describe CTs found in the glabrous skin, with comparable characteristics to those in hairy arm skin, and detail recordings from three such afferents. CTs were infrequently encountered in the glabrous skin and we estimate that the ratio of recorded CTs relative to myelinated mechanoreceptors (1:80) corresponds to an absolute innervation density of around 7 times lower than in hairy skin. This sparse innervation sheds light on discrepancies between psychophysical findings of touch perception on glabrous skin and hairy skin, although the role of these CT afferents in the glabrous skin remains subject to future work.

Cell non-autonomous requirement of p75 in the development of geniculate oral sensory neurons

During development of the peripheral taste system, oral sensory neurons of the geniculate ganglion project via the chorda tympani nerve to innervate taste buds in fungiform papillae. Germline deletion of the p75 neurotrophin receptor causes dramatic axon guidance and branching deficits, leading to a loss of geniculate neurons. To determine whether the developmental functions of p75 in geniculate neurons are cell autonomous, we deleted p75 specifically in Phox2b + oral sensory neurons (Phox2b-Cre; p75fx/fx) or in neural crest-derived cells (P0-Cre; p75fx/fx) and examined geniculate neuron development. In germline p75−/− mice half of all geniculate neurons were lost. The proportion of Phox2b + neurons, as compared to Phox2b-pinna-projecting neurons, was not altered, indicating that both populations were affected similarly. Chorda tympani nerve recordings demonstrated that p75−/− mice exhibit profound deficits in responses to taste and tactile stimuli. In contrast to p75−/− mice, there was no loss of geniculate neurons in either Phox2b-Cre; p75fx/fx or P0-Cre; p75fx/fx mice. Electrophysiological analyses demonstrated that Phox2b-Cre; p75fx/fx mice had normal taste and oral tactile responses. There was a modest but significant loss of fungiform taste buds in Phox2b-Cre; p75fx/fx mice, although there was not a loss of chemosensory innervation of the remaining fungiform taste buds. Overall, these data suggest that the developmental functions of p75 are largely cell non-autonomous and require p75 expression in other cell types of the chorda tympani circuit.

Squalamine Restores the Function of the Enteric Nervous System in Mouse Models of Parkinson’s Disease

Background: Parkinson’s disease (PD) is a progressive neurodegenerative disorder thought to be caused by accumulation of α-synuclein (α-syn) within the brain, autonomic nerves, and the enteric nervous system (ENS). Involvement of the ENS in PD often precedes the onset of the classic motor signs of PD by many years at a time when severe constipation represents a major morbidity. Studies conducted in vitro and in vivo, have shown that squalamine, a zwitterionic amphipathic aminosterol, originally isolated from the liver of the dogfish shark, effectively displaces membrane-bound α-syn. Objective: Here we explore the electrophysiological effect of squalamine on the gastrointestinal (GI) tract of mouse models of PD engineered to express the highly aggregating A53T human α-syn mutant. Methods: GI motility and in vivo response to oral squalamine in PD model mice and controls were assessed using an in vitro tissue motility protocol and via fecal pellet output. Vagal afferent response to squalamine was measured using extracellular mesenteric nerve recordings from the jejunum. Whole cell patch clamp was performed to measure response to squalamine in the myenteric plexus. Results: Squalamine effectively restores disordered colonic motility in vivo and within minutes of local application to the bowel. We show that topical squalamine exposure to intrinsic primary afferent neurons (IPANs) of the ENS rapidly restores excitability. Conclusion: These observations may help to explain how squalamine may promote gut propulsive activity through local effects on IPANs in the ENS, and further support its possible utility in the treatment of constipation in patients with PD.

Solutions to the technical challenges embedded in the current methods for intraoperative peripheral nerve action potential recordings

OBJECTIVEIntraoperative nerve action potential (NAP) recording is a useful tool for surgeons to guide decisions on surgical approaches during nerve repair surgeries. However, current methods remain technically challenging. In particular, stimulus artifacts that contaminate or mask the NAP and therefore impair the interpretation of the recording are a common problem. The authors’ goal was to improve intraoperative NAP recording techniques by revisiting the methods in an experimental setting.METHODSFirst, NAPs were recorded from surgically exposed peripheral nerves in monkeys. For the authors to test their assumptions about observed artifacts, they then employed a simple model system. Finally, they applied their insights to clinical cases in the operating room.RESULTSIn monkey peripheral nerve recordings, large stimulus artifacts obscured NAPs every time the nerve segment (length 3–5 cm) was lifted up from the surrounding tissue, and NAPs could not be recorded. Artifacts were suppressed, and NAPs emerged when “bridge grounding” was applied, and this allowed the NAPs to be recorded easily and reliably. Tests in a model system suggested that exaggerated stimulus artifacts and unmasking of NAPs by bridge grounding are related to a loop effect that is created by lifting the nerve. Consequently, clean NAPs were acquired in “nonlifting” recordings from monkey peripheral nerves. In clinical cases, bridge grounding efficiently unmasked intraoperative NAP recordings, validating the authors’ principal concept in the clinical setting and allowing effective neurophysiological testing in the operating room.CONCLUSIONSTechnical challenges of intraoperative NAP recording are embedded in the current methods that recommend lifting the nerve from the tissue bed, thereby exaggerating stimulus artifacts by a loop effect. Better results can be achieved by performing nonlifting nerve recording or by applying bridge grounding. The authors not only tested their findings in an animal model but also applied them successfully in clinical practice.

A213 A NOVEL PH-SENSITIVE OPIOID ANALGESIC THAT IS SELECTIVELY ACTIVATED IN ACIDIC INFLAMMATORY ENVIRONMENTS

Background Opioids drugs are effective analgesics for inflammatory disorders such as inflammatory bowel disease (IBD) but their effects at non-inflammed sites can cause serious morbidity and even death. Exploiting the knowledge that tissue pH in inflamed tissues is acidic (e.g. 6.5–7.0), a novel opioid analgesic, ±)-N-(3-fluoro-1-phenethylpiperidine-4-yl)-N-phenylpropionamide (NFEPP), with a low acid dissociation constant, was developed that selectively activates peripheral µ-opioid receptor (MOPr) at acidic pH. Thus, pH-sensitive binding of NFEPP could selectively inhibit nociceptive nerves in the inflamed colon and have no effect on non-inflamed tissues outside the GI tract. Aims Evaluate whether NFEPP causes inhibition of colonic nociceptors at acidic pH’s, which mimic the inflamed colon. Methods To evaluate pH sensitive property of NFEPP to activate MOPr, dorsal root ganglia (DRG) neurons from C57BL/6 mice were exposed to the MOPr agonists NFEPP (300nM, 15 min) or DAMGO (100nM, 15 min) or vehicle at pH 6.5 or 6.8 or 7.4. Neuronal excitability was measured by recording the rheobase (minimum current to fire an action potential) using patch clamp recordings of isolated dorsal root ganglia neurons. In parallel ex vivo studies of mouse colon, extracellular recordings were obtained from afferent nerves innervating the distal colon. Afferent responses to probing with von Frey hair (1 gm) were examined before and after exposure to NFEPP (300nM, 5 min superfusion) at pH 6.5 and 7.4 respectively. Oneway ANOVA and post hoc Dunnett and Bonferroni tests were used to analyze the data. Results In patch clamp studies, NFEPP caused a decrease in DRG excitability at pH 6.5 and 6.8 (increased rheobase 21.3%, p<0.05 and 28.9%, p<0.05 respectively compared to vehicle) but had no effect at physiological pH 7.4. DAMGO, a MOPr agonist, caused inhibition of nociceptor excitability at pH 7.4 (increased rheobase 25.2%, p<0.05 compared to vehicle) as shown in previous experiments, but had no effect at pH 6.5 and 6.8. Vehicle had no effect at the different pH’s. In colonic afferent nerve recordings, NFEPP significantly attenuated afferent response (28.9% P<0.01) to probing at pH 6.5 and this effect was reversed after a 15 min washout. At pH 7.4 NFEPP had no effect on afferent nerve firing. Conclusions NFEPP activated MOPr at acidic pH causing inhibition of colonic nociceptors. This pH-selective agonist provides a new strategy to relieve pain at the site of inflammation while being devoid of any of unwanted activity in non-inflamed organs. Funding Agencies CCC