scholarly journals Glycolysis selectively shapes the presynaptic action potential waveform

2016 ◽  
Vol 116 (6) ◽  
pp. 2523-2540 ◽  
Author(s):  
Brendan Lujan ◽  
Christopher Kushmerick ◽  
Tania Das Banerjee ◽  
Ruben K. Dagda ◽  
Robert Renden
Keyword(s):  
Action Potential ◽  
Synaptic Transmission ◽  
Channel Modeling ◽  
Time Frame ◽  
Iodoacetic Acid ◽  
Experimental Manipulation ◽  
Atp Production ◽  
Presynaptic Action ◽  
Inhibition Of Glycolysis ◽  
Reduced Temperature

Mitochondria are major suppliers of cellular energy in neurons; however, utilization of energy from glycolysis vs. mitochondrial oxidative phosphorylation (OxPhos) in the presynaptic compartment during neurotransmission is largely unknown. Using presynaptic and postsynaptic recordings from the mouse calyx of Held, we examined the effect of acute selective pharmacological inhibition of glycolysis or mitochondrial OxPhos on multiple mechanisms regulating presynaptic function. Inhibition of glycolysis via glucose depletion and iodoacetic acid (1 mM) treatment, but not mitochondrial OxPhos, rapidly altered transmission, resulting in highly variable, oscillating responses. At reduced temperature, this same treatment attenuated synaptic transmission because of a smaller and broader presynaptic action potential (AP) waveform. We show via experimental manipulation and ion channel modeling that the altered AP waveform results in smaller Ca2+ influx, resulting in attenuated excitatory postsynaptic currents (EPSCs). In contrast, inhibition of mitochondria-derived ATP production via extracellular pyruvate depletion and bath-applied oligomycin (1 μM) had no significant effect on Ca2+ influx and did not alter the AP waveform within the same time frame (up to 30 min), and the resultant EPSC remained unaffected. Glycolysis, but not mitochondrial OxPhos, is thus required to maintain basal synaptic transmission at the presynaptic terminal. We propose that glycolytic enzymes are closely apposed to ATP-dependent ion pumps on the presynaptic membrane. Our results indicate a novel mechanism for the effect of hypoglycemia on neurotransmission. Attenuated transmission likely results from a single presynaptic mechanism at reduced temperature: a slower, smaller AP, before and independent of any effect on synaptic vesicle release or receptor activity.

scholarly journals KCNQ channels enable reliable presynaptic spiking and synaptic transmission at high-frequency

2019 ◽  
Author(s):  
Yihui Zhang ◽  
Dainan Li ◽  
Youad Darwish ◽  
Laurence O. Trussell ◽  
Hai Huang
Keyword(s):  
Action Potential ◽  
Synaptic Transmission ◽  
High Frequency ◽  
Calcium Influx ◽  
List Type ◽  
Kcnq Channels ◽  
Axon Terminals ◽  
Presynaptic Action ◽  
Action Potential Waveform ◽  
Potential Waveform

SUMMARYThe presynaptic action potential (AP) results in calcium influx which triggers neurotransmitter release. For this reason, the AP waveform is crucial in determining the timing and strength of synaptic transmission. The calyx of Held nerve terminals of rat show minimum changes in AP waveform during high-frequency AP firing. We found that the stability of the calyceal AP waveform requires KCNQ K+ channel activated during high-frequency spiking activity. High-frequency presynaptic spikes gradually led to accumulation of KCNQ channels in open states which kept interspike membrane potential sufficiently negative to maintain Na+ channel availability. Accordingly, blocking KCNQ channels during stimulus trains led to inactivation of presynaptic Na+, and to a lesser extent KV1 channels, thereby reducing the AP height and broadening AP duration. Thus, while KCNQ channels are generally thought to prevent hyperactivity of neurons, we find that in axon terminals these channels function to facilitate high-frequency firing needed for sensory coding.HIGHLIGHTSKCNQ channels are activated during high-frequency firingThe activity of KCNQ channels helps the recovery of Na+ and KV1 channels from inactivation and maintains action potential waveformReliable presynaptic action potential waveform preserves stable Ca2+ influx and reliable synaptic signaling

scholarly journals What is transmitted in “synaptic transmission”?

2010 ◽  
Vol 34 (2) ◽  
pp. 115-116 ◽  
Author(s):  
Erik Montagna ◽  
Adriana M. S. de Azevedo ◽  
Camilla Romano ◽  
Ronald Ranvaud
Keyword(s):  
Action Potential ◽  
Synaptic Transmission ◽  
Presynaptic Terminal ◽  
Synaptic Integration ◽  
High Grade ◽  
Transmission Right ◽  
The Mind

Even students that obtain a high grade in neurophysiology often carry away a serious misconception concerning the final result of the complex set of events that follows the arrival of an action potential at the presynaptic terminal. The misconception consists in considering that “at a synapse, information is passed on from one neuron to the next” is equivalent to (and often expressed explicitly as) “the action potential passes from one neuron to the next.” More than half of four groups of students who were asked to comment on an excerpt from a recent physiology textbook that openly stated the misconception had no clear objection to the text presented. We propose that the first culprit in generating this misconception is the term “synaptic transmission,” which promotes the notion of transferring something or passing something along (implicitly unchanged). To avoid establishing this misconception, the first simple suggestion is to use words like “synaptic integration” rather than “synaptic transmission” right from the start. More generally, it would be important to focus on the function of synaptic events rather than on rote listing of all the numerous steps that are known to occur, which are so complex as to saturate the mind of the student.

Outward current and repolarization in hypoxic rat myocardium

1983 ◽  
Vol 244 (3) ◽  
pp. H341-H350
Author(s):  
C. H. Conrad ◽  
R. G. Mark ◽  
O. H. Bing
Keyword(s):  
Action Potential ◽  
Action Potentials ◽  
Outward Current ◽  
Iodoacetic Acid ◽  
Mechanical Activity ◽  
Potential Range ◽  
Papillary Muscles ◽  
Rat Myocardium ◽  
Cable Properties ◽  
Sucrose Gap

We studied the effects of brief periods (20-30 min) of hypoxia in the presence of 5 and 50 mM glucose and of glycolytic blockade (10(-4) M iodoacetic acid, IAA) on action potentials, membrane currents, and mechanical activity in rat ventricular papillary muscles using a single sucrose gap voltage-clamp technique. Steady-state outward current (iss) was determined at the end of a 500-ms clamp to the test potential following a 600-ms clamp to a holding potential of -50 mV. In the presence of 5 mM glucose, hypoxia resulted in a decrease in action potential duration (APD) and an increase in iss (on the order of 60% at 0 mV) over the potential range studied. The increase in iss did not appear to be due to an increase in leakage current or to a change in the cable properties of the preparation. Addition of 50 mM glucose prevented the change in both APD and iss with hypoxia. In addition, glycolytic blockade with IAA did not alter iss in the presence of oxygen. We conclude that an increase in iss appears to be a major factor in the abbreviation of rat ventricular action potential seen with hypoxia. Glycolysis appears to be a sufficient (with 50 mM glucose) but not necessary source of energy for the maintenance of normal iss.

Abstract P309: Particulate Matter Increases Oxidative Stress And Shortens The Action Potential In IPS-derived Cardiomyocytes

2021 ◽  
Vol 129 (Suppl_1) ◽  
Author(s):  
Mariana Argenziano ◽  
jiajia yang ◽  
Mariana Burgos Angulo ◽  
Thomas V McDonald
Keyword(s):  
Oxidative Stress ◽  
Particulate Matter ◽  
Action Potential ◽  
Cardiac Electrophysiology ◽  
Structural Changes ◽  
Hospital Admissions ◽  
Induced Pluripotent Stem Cell ◽  
Toxic Substances ◽  
Direct Role ◽  
Atp Production

Introduction: Air particulate matter (PM) represents one of the most critical environmental issues worldwide, causing more than 3 million deaths a year. In the US, hospital admissions due to heart failure (HF) increase by 0.8% for every 10 μg/m3 elevation in PM. However, the biological mechanisms behind the effects of PM on cardiovascular disease (CVD) remain poorly defined. Recent studies showed that PM 2.5 can translocate into the circulation, causing cumulative toxicity. With air pollution increasing due to human activity and the growing prevalence of HF, there is a critical need to understand PM's contributions to CVD to develop preventive treatments and novel therapeutic approaches. Hypothesis: We hypothesize that PM can exert its toxic effect by increasing oxidative stress and apoptosis and affecting cardiac electrophysiology. Methods: Three independent induced pluripotent stem cell lines (IPSC) were differentiated into cardiomyocytes (iCMs) and cultured for 30 days before treatment with 100 μg/ml of PM 2.5 for 48h. Experiments including immunostaining, qPCR, RNAseq and Multielectrode Array (MEA) were performed in control (CT) and PM-treated iCMs (PM). Results: Treatment with PM increased ROS and decreased ATP production (CT 9.9±1.2pmol vs PM 6.6±0.8pmol, p<0.01, n=20). Immunostaining showed mitochondrial fragmentation and increased expression of cleaved caspase3 without structural changes. Moreover, PM caused upregulation of the apoptotic markers P53 , PARP1 and CASP3, oxidative stress markers CYP1A1, CYP1B1 and MT2A, and cardiac markers CACNA1C together with downregulation of GJA1 . RNAseq analysis showed upregulation of Gene Ontology terms related to detoxification, response to toxic substances and oxidative stress. Upregulated KEGG pathways included oxidative phosphorylation, hypertrophic cardiomyopathy and dilated cardiomyopathy. MEA experiments revealed a decrease in the spike amplitude and conduction velocity, along with shortening of the action potential (APD90: CT 577±20ms vs. PM 489±16ms, p<0.05, n=20) and increased beat period irregularity (CT 3.2±0.7% vs. PM 13.1±1.6%, p<0.001, n=20). These electrophysiological changes were reversed by treatment with the antioxidant N-acetylcysteine. Conclusions: We conclude that PM plays a direct role in the development of CVD, causing an increase in oxidative stress and affecting the electrophysiology of the heart. Further functional studies in iCMs from HF patients will provide evidence of the effects of these changes on the phenotype of the disease.

Cerebral anoxia tolerance in turtles: regulation of intracellular calcium and pH

1992 ◽  
Vol 263 (6) ◽  
pp. R1298-R1302
Author(s):  
P. E. Bickler
Keyword(s):  
Intracellular Calcium ◽  
Brain Slices ◽  
Calcium Flux ◽  
Anoxia Tolerance ◽  
Acetoxymethyl Ester ◽  
Fluorescent Indicators ◽  
Cerebral Anoxia ◽  
Atp Production ◽  
Laboratory Rats ◽  
Inhibition Of Glycolysis

To investigate mechanisms of cerebral anoxia tolerance, cerebrocortical intracellular calcium ([Ca2+]i) and pH (pHi) regulation were compared in turtles (Trachemys scripta) and laboratory rats. [Ca2+]i and pHi in living 200 to 300-microns-thick cortical brain slices were measured with the fluorescent indicators fura-2/acetoxymethyl ester (AM) and 2',7'-bis(carboxyethyl)-5(6)-carboxyfluorescein during exposure to anoxia. Within 5 min, [Ca2+]i increased to > 1,000 nM in rat brain slices exposed to anoxia but [Ca2+]i was normal even after 5 h of anoxia in turtles. ATP levels remained normal in anoxic turtle brain but fell rapidly in rats. During anoxia, pHi fell by 0.25 +/- 0.08 pH units in rats but only 0.10 +/- 0.04 in turtles (P < 0.05). Inhibition of glycolysis in anoxic turtle brain with iodoacetate resulted in large increases in [Ca2+]i but prior exposure of slices to anoxia resulted in greatly attenuated calcium entry. The reduction in calcium flux was greater with increasing exposure to anoxia, suggesting progressive arrest of calcium channel activity. Tolerance of cerebral anoxia in turtles may be related to anaerobic ATP production, arrest of calcium channels, and attenuation of changes in pHi.

Histaminergic synaptic transmission in the cerebral ganglion of Aplysia

1985 ◽  
Vol 53 (4) ◽  
pp. 1016-1037 ◽  
Author(s):  
R. E. McCaman ◽  
D. Weinreich
Keyword(s):  
Action Potential ◽  
Synaptic Transmission ◽  
Voltage Clamp ◽  
Cerebral Ganglion ◽  
Major Influence ◽  
Electrical Synapses ◽  
Postsynaptic Potentials ◽  
Synaptic Potentials ◽  
Chemical Synapses ◽  
Synaptic Responses

Standard intracellular stimulating and recording techniques including voltage-clamp were used to analyze the synaptic responses mediated by two identifiable histamine-containing neurons (HCNs), designated C2 neurons, located in bilaterally symmetric clusters of the isolated cerebral ganglion of Aplysia california. Activation of each C2 induced unitary chemically mediated synaptic potentials in over 15 identified ipsilateral follower neurons. Several additional followers were connected to the HCNs by nonrectifying electrical synapses. Most of the follower neurons examined received only chemical synapses from the C2s. Some of the followers were reciprocally connected with each other through nonrectifying electrical synapses. A single C2 action potential can evoke six distinctive types of chemically mediated postsynaptic potentials (PSPs) in different follower neurons. Most of the PSPs have been shown to be multicomponent, i.e., they are comprised of various combinations of individual fast (less than or equal to 150 ms), slow (1-2 s), and very slow (greater than or equal to 4 s) depolarizing and hyperpolarizing components. The combination of these components produces PSPs of varying complexity, from simple monophasic responses such as the frequently observed slow excitatory PSPs and slow inhibitory PSPs to responses consisting of two to three components such as fast excitatory, slow inhibitory PSPs or fast inhibitory, slow excitatory PSPs. All of the multicomponent PSPs appear to be mediated through monosynaptic connections from the C2, as determined by various electrophysiological criteria. The slow and very slow synaptic components of the multicomponent PSPs were markedly potentiated in amplitude and duration after repetitive C2 activation. This property of the slow components permits the slower PSPs to exert a major influence on the excitability and integrative properties of the follower neurons.

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