Resting Membrane Potential Modulates Chemoreceptor Sensitivity in Nematocyst Discharge of the Sea Anemone Exaiptasia diaphena.

AbstractExtracellular calcium has been known to be required for in situ nematocyst discharge for more than 60 years, yet calcium's role in nematocyst discharge is poorly understood. Currently, we know that extracellular calcium plays at least two distinct roles in in situ nematocyst discharge. First, calcium plays a role in the triggering of discharge by physical contact, most likely involving transient receptor potential channels. Second, activated L-type calcium channels desensitize nematocyst discharge predisposed to discharge by stimulated chemoreceptors for N-acetylated sugars, such as N-acetylneuraminic acid (NANA). It is not known whether the stimulated NANA signaling pathway activates L-type channels electrogenically through membrane depolarization or directly by phosphorylation of the channel. We hypothesize that the activated NANA signaling pathway initiates desensitization by depolarizing cell membrane potentials to activate voltage-gated L-type calcium channels. Consistent with our hypothesis, we show that depolarization induced by blocking voltage-gated potassium channels with 4-aminopyridine selectively activates Ca2+ influx into tentacle ectodermal cells via L-type channels and inhibits in situ nematocyst discharge from chemosensitized anemones. Furthermore, preventing membrane depolarization with valinomycin or hyperpolarizing resting membrane potentials with low-potassium seawater suppresses NANA-induced Ca2+ influx, prevents desensitization of in situ nematocyst discharge, and enhances NANA sensitivity. Thus, changing resting membrane potentials modulates NANA sensitivity, and NANA-induced depolarization drives desensitization. We suggest that desensitization of the NANA signaling pathway occurs by a feedback pathway involving calcium channels that are activated by NANA-induced depolarization. Elucidating the desensitization pathway may suggest methods to protect or prevent public health cases of nematocyst stinging.

BK Channels Function in Nematocyst Discharge from Vibration-Sensitive Cnidocyte Supporting Cell Complexes of the Sea Anemone Diadumene lineata.

AbstractIntegrated chemo- and mechanosensory pathways, along with activated calcium influxes, regulate nematocyst discharge from sea anemone tentacles. Discharge from vibration-sensitive Type A cnidocyte supporting cell complexes use calcium-conducting transient receptor potential V4-like channels. Because calcium influxes often couple with calcium-activated, large-conductance potassium (BK) channels, we hypothesized that BK channels function in nematocyst discharge. To verify this hypothesis, we first tested five selective BK channel blockers on nematocyst-mediated prey killing in Diadumene lineata (aka Haliplanella luciae). All tested BK channel blockers inhibited prey killing at concentrations comparable to their inhibition of vertebrate BK channels. In addition, the BK channel blocker paxilline selectively inhibited prey killing mediated by vibration-sensitive Type A cnidocyte supporting cell complexes. We queried a mammalian BKα amino acid sequence to the Exaiptasia diaphena database, from which we identified a putative anemone, pore-forming BKα subunit sequence. Using the E. diaphena BKα sequence as a template, we assembled a BKα transcript from our assembled D. lineata transcriptome. In addition, the hydra homolog of D. lineata BKα localizes to nematocytes on the hydra single-cell RNA sequencing map. Our findings suggest that D. lineata expresses BK channels that play a role in vibration-sensitive nematocyst discharge from Type A cnidocyte supporting cell complexes. We believe this is the first functional demonstration of BK channels in nonbilaterians. Because stimulated chemoreceptors frequency tune Type A cnidocyte supporting cell complexes to frequencies matching swimming movements of prey via a protein kinase A signaling pathway and protein kinase A generally activates BK channels, we suggest that D. lineata BK channels may participate in protein kinase A-mediated frequency tuning.

Functional Characterization of TRPV-Like Ion Channels Involved in Nematocyst Discharge from the Sea Anemone Diadumene lineata.

AbstractCnidarians require mechanical stimuli to trigger nematocyst discharge and initiate feeding behaviors. The interval from triggering stimulus to response is tens of microseconds, making it likely that mechanically gated ion channels trigger nematocyst discharge. Because many transient receptor potential channels are mechanically gated, we hypothesized that nematocyst discharge involves transient receptor potential channels. We therefore tested various transient receptor potential channel inhibitors to determine whether they inhibit nematocyst discharge and prey killing in the acontiate sea anemone (Actinaria) Diadumene lineata (a.k.a. Haliplanella luciae). Three types of cnidocyte supporting cell complexes regulate nematocyst discharge in anemones: Types C, B, and A. Discharge from Type Cs is directly triggered by stimulation of contact-sensitive mechanoreceptors, while Type Bs require activation of chemoreceptors from prey-derived N-acetylated sugars to sensitize contact-sensitive mechanoreceptors. In Type As, activated chemoreceptors tune vibration-sensitive mechanoreceptors that predispose contact-sensitive mechanoreceptors for triggering. The non-selective transient receptor potential channel blockers lanthanum and gadolinium dose-dependently inhibited about 80% of prey killing and all nematocyst discharge from Type Bs and Type Cs, but not Type As. The selective transient receptor potential vanilloid 4 (TRPV4) blocker GSK2193874 inhibited Type As and Type Bs. However, the selective TRPV4 blockers HC-067047 and RN-1734 inhibited only Type As. Thus, three TRPV4-selective blockers implicate TRPV-like involvement in discharge from Type As, whereas GSK2193874 also affected Type Bs. Our results suggest that a TRPV-like homolog plays an essential role in nematocyst-mediated prey killing from Type As, whereas other transient receptor potential channels are likely involved in discharge from Type B and C cnidocyte supporting cell complexes.

N-Acetyl Neuraminic Acid (NANA) Activates L-Type Calcium Channels on Isolated Tentacle Supporting Cells of the Sea Anemone (Aiptasia pallida).

AbstractSensory receptors control nematocyst discharge on sea anemone tentacles. Micromolar N-acetylated sugars (e.g., N-acetyl neuraminic acid [NANA]) bind chemoreceptors on ectodermal supporting cells and predispose adjacent nematocyst discharge in response to mechanical contact via a cyclic adenosine monophosphate (cAMP)-dependent sensitization pathway, while higher NANA levels dose-dependently desensitize. Recent evidence implicates L-type calcium channels in desensitizing the pathway in aconitate sea anemones Aiptasia pallida (also known as Exaiptasia diaphana). We, therefore, hypothesize that NANA activates calcium influx via L-type calcium channels. We demonstrate a dose-dependent, NANA-activated 45Ca influx into dissociated ectodermal cells isolated from A. pallida tentacles, with maximal influx occurring at desensitizing concentrations of NANA. The L-type calcium channel inhibitors nifedipine, diltiazem, methoxyverapamil, and cadmium blocked NANA-stimulated 45Ca influx. Elevated extracellular KCl levels dose-dependently increased nifedipine-sensitive 45Ca influx to implicate voltage-gated calcium channels. Forskolin, 8-bromo-cAMP, and the protein kinase A inhibitor H-8 affect NANA-stimulated calcium influx in a manner consistent with activated cAMP-dependent pathway involvement. Because NANA chemoreceptors localize to supporting cells of cnidocyte supporting cell complexes, NANA activation of 45Ca influx into isolated tentacle ectodermal cells suggests that L-type calcium channels and NANA chemoreceptors co-localize to supporting cells. Indeed, a fluorescent marker of L-type calcium channels localizes to the apical ectoderm adjacent to nematocysts of live tentacles. We conclude that supporting cell chemoreceptors activate co-localized L-type calcium channels via a cAMP-dependent mechanism in order to initiate desensitization. We suggest that pathway desensitization may conserve nematocysts from excessive discharge during prey capture.

Cnidocyte Supporting Cell Complexes Regulate Nematocyst-Mediated Feeding Behaviors in the Sea Anemone Diadumene lineata.

AbstractCnidarians, as model animals for studying conserved feeding behavior, possess the simplest nervous and digestive systems. Feeding behavior in cnidarians begins with nematocyst-mediated prey retention, proceeds to coordinated tentacle movements and mouth opening, and then proceeds to release of retained prey for ingestion. Understanding the basis of nematocyst discharge, retention, and release is central to explaining cnidarian feeding. Based on studies using artificial targets, cnidocyte supporting cell complexes (CSCCs) regulate nematocyst discharge, retention, and release in Actinaria (sea anemones); but the relevance of CSCCs to prey retention and ingestion has not yet been established. CSCCs exist as three functional types (Types A, B, and C), with a ratio of Types A∶B∶C of 2∶2∶1 in Diadumene lineata (a.k.a. Haliplanella luciae). We tested the hypothesis that CSCCs control nematocyst-mediated prey killing and ingestion. We used a quantitative feeding assay involving Artemia nauplii (prey) and monoclonal D. lineata. The ratios of Types A∶B∶C involved in prey killing and ingestion were 1∶2.5∶5 and 1∶2∶3, respectively. These findings support the CSCC hypothesis. They also indicate that Type Cs predominate in killing small, hard-surfaced, motile, crustaceous prey. Chemoreceptor-bearing Type Bs and Type As assist in prey killing and assume somewhat greater roles in ingestion. Thus, CSCC types differ with respect to their afferent sensory roles as well as their subsequent efferent roles in killing and ingestion. We conclude that CSCC types perform overlapping and complementary roles during feeding.

Activated L-Type Calcium Channels Inhibit Chemosensitized Nematocyst Discharge from Sea Anemone Tentacles.

Because in vivo nematocyst discharge requires extracellular Ca2+, Ca2+ channels have been suspected to be involved; but their identity and role have not been revealed. The majority of nematocysts that discharge from sea anemone tentacles are under the control of sensitizing chemoreceptors for N-acetylated sugars (e.g., N-acetylneuraminic acid). Activated chemoreceptors predispose contact-sensitive mechanoreceptors to trigger discharge. We show that activating L-type Ca2+ channels inhibits N-acetylneuraminic acid-sensitized discharge, contrary to a previous suggestion. In addition, inhibiting L-type channels increases sensitivity to N-acetylneuraminic acid. Specifically, we show that the L-type Ca2+ channel activator (-)-Bay K 8644 dose-dependently inhibits N-acetylneuraminic acid-sensitized discharge, as does raising ambient Ca2+ levels. We also show that lowering extracellular Ca2+ levels or adding any of several selective and chemically distinct L-type Ca2+ channel blockers, including dihydropyridines, dose-dependently increases N-acetylneuraminic acid sensitivity and broadens the dynamic range of N-acetylneuraminic acid sensitization. Consistent with these functional findings, Aiptasia pallida expresses an L-type Ca2+ channel α subunit transcript that encodes a conserved dihydropyridine-binding site. Phylogenetic analysis confirms a close relationship of the Aiptasia Ca2+ channel α subunit sequence between anemones, anthozoans, and cnidarians that extends into protostomal and deuterostomal bilaterians. We conclude that L-type Ca2+ channel activity modulates N-acetylneuraminic acid-sensitized nematocyst discharge in a push-pull manner depending on channel activity state. Our findings suggest that L-type channel activation promotes chemosensory desensitization, and we predict that N-acetylneuraminic acid chemoreceptor signaling will activate L-type channels.

Long-term hypoxia increases calcium affinity of BK channels in ovine fetal and adult cerebral artery smooth muscle.

Acclimatization to high-altitude, long-term hypoxia (LTH) reportedly alters cerebral artery contraction-relaxation responses associated with changes in K(+) channel activity. We hypothesized that to maintain oxygenation during LTH, basilar arteries (BA) in the ovine adult and near-term fetus would show increased large-conductance Ca(2+) activated potassium (BK) channel activity. We measured BK channel activity, expression, and cell surface distribution by use of patch-clamp electrophysiology, flow cytometry, and confocal microscopy, respectively, in myocytes from normoxic control and LTH adult and near-term fetus BA. Electrophysiological data showed that BK channels in LTH myocytes exhibited 1) lowered Ca(2+) set points, 2) left-shifted activation voltages, and 3) longer dwell times. BK channels in LTH myocytes also appeared to be more dephosphorylated. These differences collectively make LTH BK channels more sensitive to activation. Studies using flow cytometry showed that the LTH fetus exhibited increased BK ß1 subunit surface expression. In addition, in both fetal groups confocal microscopy revealed increased BK channel clustering and colocalization to myocyte lipid rafts. We conclude that increased BK channel activity in LTH BA occurred in association with increased channel affinity for Ca(2+) and left-shifted voltage activation. Increased cerebrovascular BK channel activity may be a mechanism by which LTH adult and near-term fetal sheep can acclimatize to long-term high altitude hypoxia. Our findings suggest that increasing BK channel activity in cerebral myocytes may be a therapeutic target to ameliorate the adverse effects of high altitude in adults or of intrauterine hypoxia in the fetus.

Long-term, progressive, aerobic training increases adiponectin in middle-aged, overweight, untrained males and females.

Adipose tissue secretes the adipokine, adiponectin (ADPN), which increases insulin sensitivity. Because some of the metabolic effects of exercise and ADPN are similar, exercise has been proposed to increase ADPN. However, most short-term (≤3 mos) and constant-effort exercise protocols have not produced increases in ADPN. Furthermore, no direct comparisons of male and female subjects on the effect of exercise on ADPN levels have been reported. We hypothesized that long-term (6 mos), progressive training would increase ADPN levels in both males and females. We recruited middle-aged, untrained males and females to participate in an interventional study employing a marathon training regimen progressing from 9.7 to 88.5 km (6 to 55 miles) per week over 6 mos. At baseline, we matched the mean ages of the male and female groups. We collected and stored fasting plasma samples and recorded body measurements at 0 (baseline) and 6 mos. Stored samples were analysed for insulin, glucose, and ADPN. ADPN increased significantly among both males (from 5.89 ± 2.46 (mean ± SD) to 7.65 ± 3.18 µg/ml; p < 0.05) and females (from 8.48 ± 3.22 to 10.56 ± 4.05 µg/ml; p < 0.05). The extent of the increase in ADPN was similar in the male (40.7 ± 50%; median, 12.1%) and female (27.0 ± 31.1%; median, 22.3%) groups. However, there was no significant reduction in insulin resistance as measured by the HOMA-IR scores in either group. We conclude that long-term, progressive aerobic training increases circulating ADPN levels in middle-aged, untrained males and females.

Effects of satiation and starvation on nematocyst discharge, prey killing, and ingestion in two species of sea anemone.

Studies spanning 60 years with several cnidarian species show that satiation inhibits prey capture and ingestion and that starvation increases prey capture and ingestion. Most have attributed the effects of satiation to inhibition of nematocyst discharge. We hypothesized that satiation inhibits prey capture and ingestion in sea anemones (Haliplanella luciae and Aiptasia pallida) primarily by inhibiting the intrinsic adherence (i.e., holding power) of discharging nematocysts. Using a quantitative feeding assay for H. luciae, we found that satiation completely uncoupled prey killing from prey ingestion, while nematocyst-mediated prey killing was only partially inhibited. Using A. pallida to measure nematocyst discharge and nematocyst-mediated adhesive force, we showed that satiation completely inhibited the intrinsic adherence of discharging nematocysts from Type B and Type C cnidocyte/supporting cell complexes (CSCCs), while only partially inhibiting nematocyst discharge from Type Bs. These inhibitory effects of satiation were gradually restored by starvation, reaching a maximum at 72 h after feeding. Thus, the effects of satiation and starvation on prey killing and ingestion in two species of acontiate sea anemones are primarily due to changes in the intrinsic adherence of nematocysts from both Type B and Type C CSCCs.

The role of nitric oxide in skin blood flow increases due to vibration in healthy adults and adults with type 2 diabetes.

BACKGROUND: We recently demonstrated concomitant increases in skin blood flow and nitric oxide (NO) production in young healthy adults in response to externally applied vibration of the forearm. Research has shown that adults with type 2 diabetes exhibit depressed NO production and vascular responses to NO. We hypothesized that subjects with type 2 diabetes would display lower than normal increases in skin blood flow to externally applied vibration. RESEARCH DESIGN AND METHODS: Therefore, the purpose of this study was to compare 20 male and female, age- and body mass index-matched normal adults and adults with type 2 diabetes in terms of the effects of external vibration of the forearm on skin blood flow and the rate of NO production. Skin blood flow and NO production were measured before vibration, immediately after 5 min of vibration, and 5 min after vibration ceased. RESULTS: Although externally applied vibration significantly increased skin blood flow for both groups (P = 0.0001), those with diabetes had significantly lower (223%; P = 0.003) skin blood flows compared to the healthy older adults (461%). The rate of NO production, expressed as microM NO . flux, also increased significantly in both groups after vibration (healthy group, 374%; diabetes group, 236%) and remained significantly elevated (healthy group, 258%; diabetes group, 177%) for at least 5 min; however, the difference between groups was not significant (P = 0.12). CONCLUSIONS: These findings suggest that subjects with diabetes exhibit a lower skin blood flow and lower NO response to externally applied vibration than matched normal subjects.

Modulation of BK channel calcium affinity by differential phosphorylation in developing ovine basilar artery myocytes.

Large-conductance Ca2+-sensitive K+ (BK) channel activity is greater in basilar artery smooth muscle cells (SMCs) of the fetus than the adult, and this increased activity is associated with a lower BK channel Ca2+ set point (Ca0). Associated PKG activity is three times greater in BK channels from fetal than adult myocytes, whereas associated PKA activity is three times greater in channels from adult than fetal myocytes. We hypothesized that the change in Ca0 during development results from different levels of channel phosphorylation. In inside-out membrane patch preparations of basilar artery SMCs from adult and fetal sheep, we measured BK channel activity in four states of phosphorylation: native, dephosphorylated, PKA phosphorylated, and PKG phosphorylated. BK channels from adult and fetus exhibited similar voltage-activation curves, Ca0 values, and Ca2+ dissociation constants (Kd) for the dephosphorylated, PKA phosphorylated, and PKG phosphorylated states. However, voltage-activation curves of native fetal BK channels shifted significantly to the left of those of the adult, with Ca0 and Kd values half those of the adult. For the two age groups at each of the phosphorylation states, Ca0 and Kd produced linear relations when plotted against voltage at half-maximal channel activation. We conclude that the Ca0 and Kd values of the BK channel can be modulated by differential channel phosphorylation. Lower Ca0 and Kd values in BK channels of fetal myocytes can be explained by a greater extent of channel phosphorylation of fetal than adult myocytes.

Ca2+-activated K+ channel-associated phosphatase and kinase activities during development.

In ovine basilar arterial smooth muscle cells (SMCs), the fetal "big" Ca2+-activated K+ (BK) channel activity is significantly greater and has a lower Ca2+ setpoint than BK channels from adult cells. In the present study, we tested the hypothesis that these differences result from developmentally regulated phosphorylation of these channels. Using the patch-clamp technique and a novel in situ enzymological approach, we measured the rates and extents of changes in BK channel voltage activation from SMC inside-out patch preparations in response to selective activation and inhibition of channel-associated protein phosphatases and kinases (CAPAKs). We show that BK channel activity is modulated during development by differential phosphorylation and that the activities of CAPAKs change substantially during development. In particular, excised membrane patches from adult SMCs exhibited greater protein kinase A activity than those from a fetus. In contrast, fetal SMCs exhibited greater protein kinase G activity and phosphatase activity than adult SMCs. These findings extend our previous observation that the BK channel Ca2+ setpoint differs significantly in adult and fetal cerebrovascular myocytes and suggest a biochemical mechanism for this difference. In addition, these findings suggest that the functional stoichiometry of CAPAKs varies significantly during development and that such variation may be a hitherto unrecognized mechanism of ion channel regulation.

Developmental differences in Ca2+-activated K+ channel activity in ovine basilar artery.

A primary determinant of vascular smooth muscle (VSM) tone and contractility is the resting membrane potential, which, in turn, is influenced heavily by K+ channel activity. Previous studies from our laboratory and others have demonstrated differences in the contractility of cerebral arteries from near-term fetal and adult animals. To test the hypothesis that these contractility differences result from maturational changes in voltage-gated K+ channel function, we compared this function in VSM myocytes from adult and fetal sheep cerebral arteries. The primary current-carrying, voltage-gated K+ channels in VSM myocytes are the large conductance Ca2+-activated K+ channels (BKCa) and voltage-activated K+ (KV) channels. We observed that at voltage-clamped membrane potentials of +60 mV in perforated whole cell studies, the normalized outward current densities in fetal myocytes were >30% higher than in those of the adult (P < 0.05) and that these were predominantly due to iberiotoxin-sensitive currents from BKCa channels. Excised, insideout membrane patches revealed nearly identical unitary conductances and Hill coefficients for BKCa channels. The plot of log intracellular [Ca2+] ([Ca2+]i) versus voltage for half-maximal activation (V(1/2)) yielded linear and parallel relationships, and the change in V(1/2) for a 10-fold change in [Ca2+] was also similar. Channel activity increased e-fold for a 19 +/- 2-mV depolarization for adult myocytes and for an 18 +/- 1-mV depolarization for fetal myocytes (P > 0.05). However, the relationship between BKCa open probability and membrane potential had a relative leftward shift for the fetal compared with adult myocytes at different [Ca2+]i. The [Ca2+] for half-maximal activation (i.e., the calcium set points) at 0 mV were 8.8 and 4.7 microM for adult and fetal myocytes, respectively. Thus the increased BKCa current density in fetal myocytes appears to result from a lower calcium set point.

Apparent membrane pore-formation by Portuguese Man-of-war (Physalia physalis) venom in intact cultured cells.

Intracellular, ratiometric microfluorimetry with fura-2 reveals that low doses of Portuguese Man-of-war (Physalia physalis) venom cause a linear increase in intracellular calcium accumulation by cultured L-929 cells. The influx of calcium is preceded by a lag period that is relatively independent of venom concentration, except at very low concentrations. Electron micrographs of negatively stained preparations of membranes from venom-treated L-929 and GH(4)C(1) cells exhibit 10-80 nm diameter lesions. The number and diameter of these lesions correlate with venom concentration. The venom forms lesions in GH(4)C(1) cells at much lower concentrations than in L-929 cells. Osmotic protectants such as sucrose and polyethylene glycol (PEG), reduce the extent of lactate dehydrogenase (LDH) release from venom-treated cells with the higher molecular weight PEG causing a greater inhibition of LDH release than sucrose. These results imply that Man-of-war venom produces pore-like structures in the membranes of target cells, which leads to colloid osmotic swelling with subsequent release of intracellular proteins and cell lysis.