Mitchell Chesler, Ph.D., M.D.

Preemptive Regulation of Intracellular pH in Hippocampal Neurons by a Dual Mechanism of Depolarization-Induced Alkalinization
Svichar, Nataliya; Esquenazi, Susana; Chen, Huei-Ying; Chesler, Mitchell
2011 May 11;31(19):6997-7004, Journal of neuroscience
Numerous studies have documented the mechanisms that regulate intracellular pH (pH(i)) in hippocampal neurons in response to an acid load. Here, we studied the response of pH(i) to depolarization in cultured hippocampal neurons. Elevation of external K(+) (6-30 mm) elicited an acid transient followed by a large net alkaline shift. Similar responses were observed in acutely dissociated hippocampal neurons. In Ca(2+)-free media, the acid response was curtailed and the alkaline shift enhanced. DIDS blocked the alkaline response and revealed a prolonged underlying acidification that was highly dependent on Ca(2+) entry. Similar alkaline responses could be elicited by AMPA, indicating that this rise in pH(i) was a depolarization-induced alkalinization (DIA). The DIA was found to consist of Cl(-)-dependent and Cl(-)-independent components, each accounting for approximately one-half of the peak amplitude. The Cl(-)-independent component was postulated to arise from operation of the electrogenic Na(+)-HCO(3)(-) cotransporter NBCe1. Quantitative PCR and single-cell multiplex reverse transcription-PCR demonstrated message for NBCe1 in our hippocampal neurons. In neurons cultured from Slc4a4 knock-out (KO) mice, the DIA was reduced by approximately one-half compared with wild type, suggesting that NBCe1 was responsible for the Cl(-)-independent DIA. In Slc4a4 KO neurons, the remaining DIA was virtually abolished in Cl(-)-free media. These data demonstrate that DIA of hippocampal neurons occurs via NBCe1, and a parallel DIDS-sensitive, Cl(-)-dependent mechanism. Our results indicate that, by activating net acid extrusion in response to depolarization, hippocampal neurons can preempt a large, prolonged, Ca(2+)-dependent acidosis
— id: 132318, year: 2011, vol: 31, page: 6997, stat: Journal Article,

Barium Plateau Potentials of CA1 Pyramidal Neurons Elicit All-or-None Extracellular Alkaline Shifts Via the Plasma Membrane Calcium ATPase
Makani, Sachin; Chesler, Mitchell
2010 Sep;104(3):1438-1444, Journal of neurophysiology
In many brain regions, synchronous neural activity causes a rapid rise in extracellular pH. In the CA1 region of hippocampus, this population alkaline transient (PAT) enhances responses from postsynaptic, pH-sensitive N-methyl-d-aspartate (NMDA) receptors. Recently, we showed that the plasma membrane Ca(2+)-ATPase (PMCA), a ubiquitous transporter that exchanges internal Ca(2+) for external H(+), is largely responsible for the PAT. It has also been shown that a PAT can be generated after replacing extracellular Ca(2+) with Ba(2+). The cause of this PAT is unknown, however, because the ability of the mammalian PMCA to transport Ba(2+) is unclear. If the PMCA did not carry Ba(2+), a different alkalinizing source would have to be postulated. Here, we address this issue in mouse hippocampal slices, using concentric (high-speed, low-noise) pH microelectrodes. In Ba(2+)-containing, Ca(2+)-free artificial cerebrospinal fluid, a single antidromic shock to the alveus elicited a large (0.1-0.2 unit pH), 'all-or-none' PAT in the CA1 cell body region. In whole cell current clamp of single CA1 pyramidal neurons, the same stimulus evoked a prolonged plateau potential that was similarly all-or-none. Using this plateau as the voltage command in other cells, we recorded Ba(2+)-dependent surface alkaline transients (SATs). The SATs were suppressed by adding 5 mM extracellular HEPES and abolished when carboxyeosin (a PMCA inhibitor) was in the patch pipette solution. These results suggest that the PAT evoked in the presence of Ba(2+) is caused by the PMCA and that this transporter is responsible for the PAT whether Ca(2+) or Ba(2+) is the charge carrying divalent cation
— id: 112427, year: 2010, vol: 104, page: 1438, stat: Journal Article,

Rapid Rise of Extracellular pH Evoked by Neural Activity is Generated by the Plasma Membrane Calcium ATPase
Makani, Sachin; Chesler, Mitchell
2010 Feb;103(2):667-676, Journal of neurophysiology
In hippocampus, synchronous activation of CA1 pyramidal neurons causes a rapid, extracellular, population alkaline transient (PAT). It has been suggested that the plasma membrane Ca(2+)-ATPase (PMCA) is the source of this alkalinization, as it exchanges cytosolic Ca(2+) for external H(+). Evidence supporting this hypothesis, however, has thus far been inconclusive. We addressed this long-standing problem by measuring surface alkaline transients (SATs) from voltage clamped CA1 pyramidal neurons in juvenile mouse hippocampal slices, using concentric (high-speed, low-noise) pH microelectrodes placed against the somata. In saline containing benzolamide (a poorly-permeant carbonic anhydrase blocker), a 2 s step from -60 to 0 mV caused a mean SAT of 0.02 unit pH. Addition of 5 mM HEPES to the ACSF diminished the SAT by 91 percent. Nifedipine reduced the SAT by 53 percent. Removal of Ca(2+) from the saline abolished the SAT, and addition of BAPTA to the patch pipette reduced it by 79 percent. The inclusion of carboxyeosin (a PMCA inhibitor) in the pipette abolished the SAT, whether it was induced by a depolarizing step, or by simulated, repetitive, antidromic firing. The peak amplitude of the 'antidromic' SAT of a single cell averaged 11 percent of the PAT elicited by comparable real antidromic activation of the CA1 neuronal population. Caloxin 2A1, an extracellular PMCA peptide-inhibitor, blocked both the SAT and PAT by 42 percent. These results provide the first direct evidence that the PMCA can explain the extracellular alkaline shift elicited by synchronous firing
— id: 105537, year: 2010, vol: 103, page: 667, stat: Journal Article,

Carbonic anhydrases CA4 and CA14 both enhance AE3-mediated Cl--HCO3- exchange in hippocampal neurons
Svichar, Nataliya; Waheed, Abdul; Sly, William S; Hennings, Jean C; Hubner, Christian A; Chesler, Mitchell
2009 Mar 11;29(10):3252-3258, Journal of neuroscience
Carbonic anhydrase (CA) activity in the brain extracellular space is attributable mainly to isoforms CA4 and CA14. In brain, these enzymes have been studied mostly in the context of buffering activity-dependent extracellular pH transients. Yet evidence from others has suggested that CA4 acts in a complex with anion exchangers (AEs) to facilitate Cl(-)-HCO(3)(-) exchange in cotransfected cells. To investigate whether CA4 or CA14 plays such a role in hippocampal neurons, we studied NH(4)(+)-induced alkalinization of the cytosol, which is mitigated by Cl(-) entry and HCO(3)(-) exit. The NH(4)(+)-induced alkalinization was enhanced when the extracellular CAs were inhibited by the poorly permeant CA blocker, benzolamide, or by inhibitory antibodies specific for either CA4 or CA14. The NH(4)(+)-induced alkalinization was also increased with inhibition of anion exchange by 4,4*-diisothiocyanostilbene-2,2*-disulfonic acid, or by eliminating Cl(-) from the medium. No effect of benzolamide was seen under these conditions, in which no Cl(-)-HCO(3)(-) exchange was possible. Quantitative PCR on RNA from the neuronal cultures indicated that AE3 was the predominant AE isoform. Single-cell PCR also showed that Slc4a3 (AE3) transcripts were abundant in isolated neurons. In hippocampal neurons dissociated from AE3-null mice, the NH(4)(+)-induced alkalinization was much larger than that seen in neurons from wild-type mice, suggesting little or no Cl(-)-HCO(3)(-) exchange in the absence of AE3. Benzolamide had no effect on the NH(4)(+)-induced alkalinization in the AE3 knock-out neurons. Our results indicate that CA4 and CA14 both play important roles in the regulation of intracellular pH in hippocampal neurons, by facilitating AE3-mediated Cl(-)-HCO(3)(-) exchange
— id: 96169, year: 2009, vol: 29, page: 3252, stat: Journal Article,

Regulation of postsynaptic Ca2+ influx in hippocampal CA1 pyramidal neurons via extracellular carbonic anhydrase
Fedirko, Nataliya; Avshalumov, Marat; Rice, Margaret E; Chesler, Mitchell
2007 Jan 31;27(5):1167-1175, Journal of neuroscience
Synchronous neural activity causes rapid changes of extracellular pH (pH(e)) in the nervous system. In the CA1 region of the hippocampus, stimulation of the Schaffer collaterals elicits an alkaline pH(e) transient in stratum radiatum that is limited by extracellular carbonic anhydrase (ECA). When interstitial buffering is diminished by inhibition of ECA, the alkalosis is enhanced and NMDA receptor (NMDAR)-mediated postsynaptic currents can be augmented. Accordingly, the dendritic influx of Ca2+ elicited by synaptic excitation may be expected to increase if ECA activity were blocked. We tested this hypothesis in the CA1 stratum radiatum of hippocampal slices from juvenile rats, using extracellular, concentric pH- and Ca2+-selective microelectrodes with response times of a few milliseconds, as well as Fluo-5F imaging of intracellular Ca2+ transients. Brief stimulation of the Schaffer collaterals elicited an alkaline pH(e) transient, a transient decrease in free extracellular Ca2+ concentration ([Ca2+]e), and a corresponding transient rise in free intracellular Ca2+ concentration ([Ca2+]i). Inhibition of ECA with benzolamide caused a marked amplification and prolonged recovery of the pH(e) and [Ca2+]e responses, as well as the dendritic [Ca2+]i transients. The increase in amplitude caused by benzolamide did not occur in the presence of the NMDAR antagonist APV, but the decay of the responses was still prolonged. These results indicate that ECA can shape dendritic Ca2+ dynamics governed by NMDARs by virtue of its regulation of concomitant activity-dependent pH(e) shifts. The data also suggest that Ca2+ transients are influenced by additional mechanisms sensitive to shifts in pH(e)
— id: 71148, year: 2007, vol: 27, page: 1167, stat: Journal Article,

Endogenous alkaline transients boost postsynaptic NMDA receptor responses in hippocampal CA1 pyramidal neurons
Makani, Sachin; Chesler, Mitchell
2007 Jul 11;27(28):7438-7446, Journal of neuroscience
In hippocampus, activation of the Schaffer collaterals generates an extracellular alkaline transient both in vitro and in vivo. This pH change may provide relief of the H+ block of NMDA receptors (NMDARs) and thereby increase excitability. To test this hypothesis, we augmented extracellular buffering in mouse hippocampal slices by adding 2 microM bovine type II carbonic anhydrase to the superfusate. With addition of enzyme, the alkaline transient elicited by a 10 pulse, 100 Hz stimulus train was reduced by 33%. At a holding potential (V(H)) of -30 mV, the enzyme decreased the half-time of decay and charge transfer of EPSCs by 32 and 39%, respectively, but had no effect at a V(H) of -80 mV. In current clamp, a 10 pulse, 100 Hz stimulus train gave rise to an NMDAR-dependent afterdepolarization (ADP). Exogenous enzyme curtailed the ADP half-width and voltage integral by 20 and 25%, respectively. Similar reduction of the ADP was noted with a brief 12 Hz stimulus train. The effect persisted in the presence of GABAergic antagonists or the L-type Ca2+ channel blocker methoxyverapamil hydrochloride but was absent in the presence of the carbonic anhydrase inhibitor benzolamide or when the exogenous enzyme was heat inactivated. The effects of the enzyme in voltage and current clamp were noted in 0 Mg2+ media but were abolished when (+)-5-methyl-10,11-dihydro-5H-dibenzo[a,d]-cyclohepten-5,10-imine maleate was included in the patch pipette. These results provide strong evidence that endogenous alkaline transients are sufficiently large in the vicinity of the synapse to augment NMDAR responses
— id: 73386, year: 2007, vol: 27, page: 7438, stat: Journal Article,

Fabrication and use of high-speed, concentric h+- and Ca2+-selective microelectrodes suitable for in vitro extracellular recording
Fedirko, Nataliya; Svichar, Nataliya; Chesler, Mitchell
2006 Aug;96(2):919-924, Journal of neurophysiology
Ion-selective microelectrodes (ISMs) have been used extensively in neurophysiological studies. ISMs selective for H(+) and Ca(2+) are notable for their sensitivity and selectivity, but suffer from a slow response time, and susceptibility to noise because of the high electrical resistance of the respective ion exchange cocktails. These drawbacks can be overcome by using a 'coaxial' or 'concentric' inner micropipette to shunt the bulk of the ion exchanger resistance. This approach was used decades ago to record extracellular [Ca(2+)] transients in cat cortex, but has not been subsequently used. Here, we describe a method for the rapid fabrication of concentric pH- and Ca(2+)-selective microelectrodes useful for extracellular studies in brain slices or other work in vitro. Construction was simplified compared with previous implementations, by using commercially available, thin-walled borosilicate glass, drawing an outer barrel with a rapid taper (similar to a patch pipette), and by use of a quick and reliable silanization procedure. Using a piezoelectric stepper to effect a rapid solution change, the response time constants of the concentric pH and Ca(2+)-electrodes were 14.9 +/- 1.3 and 5.3 +/- 0.90 ms, respectively. Use of these concentric ISMs is demonstrated in rat hippocampal slices. Activity-dependent, extracellular pH, and [Ca(2+)] transients are shown to arise two- to threefold faster, and attain amplitudes two- to fourfold greater, when recorded by concentric versus conventional ISMs. The advantage of concentric ISMs for studies of ion transport and ion diffusion is discussed
— id: 69056, year: 2006, vol: 96, page: 919, stat: Journal Article,

Functional demonstration of surface carbonic anhydrase IV activity on rat astrocytes
Svichar, Nataliya; Esquenazi, Susana; Waheed, Abdul; Sly, William S; Chesler, Mitchell
2006 Feb;53(3):241-247, Glia
Buffering of the brain extracellular fluid is catalyzed by carbonic anhydrase (CA) activity. Whereas the extracellular isoform CA XIV has been localized exclusively to neurons in the brain, and to glial cells in the retina, there has been uncertainty regarding the form or forms of CA on the surface of brain astrocytes. We addressed this issue using physiological methods on cultured and acutely dissociated rat astrocytes. Prior work showed that the intracellular lactate-induced acidification (LIA) of astrocytes is diminished by benzolamide, a poorly permeant, nonspecific CA inhibitor. We demonstrate that pretreatment of astrocytes with phosphatidylinositol-specific phospholipase C (PI-PLC) results in a similar inhibition of the mean LIA (by 66 +/- 3%), suggesting that the glycosylphosphatidylinositol-anchored CA IV was responsible. Pretreatment of astrocytes with CA IV inhibitory antisera also markedly reduced the mean LIA in both cultured cortical (by 46 +/- 4%) and acutely dissociated hippocampal astrocytes (by 54 +/- 8%). Pre-immune sera had no effect. The inhibition produced by PIPLC or CA IV antisera was not significantly less than that by benzolamide, suggesting that the majority of detectable surface CA activity was attributable to CA IV. Thus, our data collectively document the presence of CAIV on the surface of brain astrocytes, and suggest that this is the predominant CA isoform on these cells
— id: 62604, year: 2006, vol: 53, page: 241, stat: Journal Article,

Kinetics of activity-evoked pH transients and extracellular pH buffering in rat hippocampal slices
Tong, Chi-Kun; Chen, Kevin; Chesler, Mitchell
2006 Jun;95(6):3686-3697, Journal of neurophysiology
The kinetics of activity-dependent, extracellular alkaline transients, and the buffering of extracellular pH (pH(e)), were studied in rat hippocampal slices using a fluorescein-dextran probe. Orthodromic stimuli generated alkaline transients < or = 0.05 pH units that peaked in 273 +/- 26 ms and decayed with a half-time of 508 +/- 43 ms. Inhibition of extracellular carbonic anhydrase (ECA) with benzolamide increased the rate of rise by 25%, doubled peak amplitude, and prolonged the decay three- to fourfold. The slow decay in benzolamide allowed marked temporal summation, resulting in a severalfold increase in amplitude during long stimulus trains. Addition of exogenous carbonic anhydrase reduced the rate of rise, halved the peak amplitude, but had no effect on the normalized decay. A simulation of extracellular buffering kinetics generated recoveries from a base load consistent with the observed decay of the alkaline transient in the presence of benzolamide. Under control conditions, the model approximated the observed decays with an acceleration of the CO2 hydration-dehydration reactions by a factor of 2.5. These data suggest low endogenous ECA activity, insufficient to maintain equilibrium during the alkaline transients. Disequilibrium implies a time-dependent buffering capacity, with a CO2/HCO3- contribution that is small shortly after a base load. It is suggested that within 100 ms, extracellular buffering capacity is about 1% of the value at equilibrium and is provided mainly by phosphate. Accordingly, in the time frame of synaptic transmission, small base loads would generate relatively large changes in interstitial pH
— id: 65797, year: 2006, vol: 95, page: 3686, stat: Journal Article,

Role of Na+-H+ and Na+-Ca2+ exchange in hypoxia-related acute astrocyte death
Bondarenko, Alexander; Svichar, Nataliya; Chesler, Mitchell
2005 Jan 1;49(1):143-152, Glia
Cultured astrocytes do not succumb to hypoxia/zero glucose for up to 24 h, yet astrocyte death following injury can occur within 1 h. It was previously demonstrated that astrocyte loss can occur quickly when the gaseous and interstitial ionic changes of transient brain ischemia are simulated: After a 20-40-min exposure to hypoxic, acidic, ion-shifted Ringer (HAIR), most cells died within 30 min after return to normal saline (i.e., 'reperfusion'). Astrocyte death required external Ca2+ and was blocked by KB-R7943, an inhibitor of reversed Na+-Ca2+ exchange, suggesting that injury was triggered by a rise in [Ca2+]i. In the present study, we confirmed the elevation of [Ca2+]i during reperfusion and studied the role of Na+-Ca2+ and Na+-H+ exchange in this process. Upon reperfusion, elevation of [Ca2+]i was detectable by Fura-2 and was blocked by KB-R7943. The low-affinity Ca2+ indicator Fura-FF indicated a mean [Ca2+]i rise to 4.8+/-0.4 microM. Loading astrocytes with Fura-2 provided significant protection from injury, presumably due to the high affinity of the dye for Ca2+. Injury was prevented by the Na+-H+ exchange inhibitors ethyl isopropyl amiloride or HOE-694, and the rise of [Ca2+]i at the onset of reperfusion was blocked by HOE-694. Acidic reperfusion media was also protective. These data are consistent with Na+ loading via Na+-H+ exchange, fostering reversal of Na+-Ca2+ exchange and cytotoxic elevation of [Ca2+]i. The results indicate that mechanisms involved in pH regulation may play a role in the fate of astrocytes following acute CNS injuries
— id: 49342, year: 2005, vol: 49, page: 143, stat: Journal Article,

Failure and function of intracellular pH regulation in acute hypoxic-ischemic injury of astrocytes
Chesler, Mitchell
2005 Jun;50(4):398-406, Glia
Astrocytes can die rapidly following ischemic and traumatic injury to the CNS. Brain acid-base status has featured prominently in theories of acute astrocyte injury. Failure of astrocyte pH regulation can lead to cell loss under conditions of severe acidosis. By contrast, the function of astrocyte pH regulatory mechanisms appears to be necessary for acute cell death following the simulation of transient ischemia and reperfusion. Severe lactic acidosis, and the failure of astrocytes to regulate intracellular pH (pH(i)) have been emphasized in brain ischemia under hyperglycemic conditions. Direct measurements of astrocyte pH(i) after cardiac arrest demonstrated a mean pH(i) of 5.3 in hyperglycemic rats. In addition, both in vivo and in vitro studies of astrocytes have shown similar pH levels to be cytotoxic. Whereas astrocytes exposed to hypoxia alone may require 12-24 h to die, acidosis has been found to exacerbate and speed hypoxic loss of these cells. Recently, astrocyte cultures were exposed to hypoxic, acidic media in which the large ionic perturbations characteristic of brain ischemia were simulated. Upon return to normal saline ('reperfusion'), the majority of cells died. This injury was dependent on external Ca2+ and was prevented by inhibition of reversed Na(+)-Ca2+ exchange, blockade of Na(+)-H+ exchange, or by low pH of the reperfusion saline. These data suggested that cytotoxic elevation of [Ca2+]i occurred during reperfusion due to a sequence of activated Na(+)-H+ exchange, cytosolic Na+ loading, and resultant reversal of Na(+)-Ca2+ exchange. The significance of this reperfusion model to ischemic astrocyte injury in vivo is discussed
— id: 56003, year: 2005, vol: 50, page: 398, stat: Journal Article,

Carbonic anhydrase IV and XIV knockout mice: roles of the respective carbonic anhydrases in buffering the extracellular space in brain
Shah, Gul N; Ulmasov, Barbara; Waheed, Abdul; Becker, Timothy; Makani, Sachin; Svichar, Nataliya; Chesler, Mitchell; Sly, William S
2005 Nov 15;102(46):16771-16776, Proceedings of the National Academy of Sciences of the United States of America
Previous studies have implicated extracellular carbonic anhydrases (CAs) in buffering the alkaline pH shifts that accompany neuronal activity in the rat and mouse hippocampus. CAs IV and XIV both have been proposed to mediate this extracellular buffering. To examine the relative importance of these two isozymes in this and other physiological functions attributed to extracellular CAs, we produced CA IV and CA XIV knockout (KO) mice by targeted mutagenesis and the doubly deficient CA IV/XIV KO mice by intercrossing the individual null mice. Although CA IV and CA XIV null mice both are viable, the CA IV nulls are produced in smaller numbers than predicted, indicating either fetal or postnatal losses, which preferentially affect females. CA IV/XIV double KO mice are also produced in fewer numbers than predicted and are smaller than WT mice, and many females die prematurely before and after weaning. Electrophysiological studies on hippocampal slices on these KO mice showed that either CA can mediate buffering after synaptic transmission in hippocampal slices in the absence of the other, but that eliminating both is nearly as effective as the CA inhibitor, benzolamide, in blocking the buffering seen in the WT mice. Thus, both CA IV and CA XIV contribute to extracellular buffering in the central nervous system, although CA IV appears to be more important in the hippocampus. These individual and double KO mice should be valuable tools in clarifying the relative contributions of each CA to other physiological functions where extracellular CAs have been implicated
— id: 96170, year: 2005, vol: 102, page: 16771, stat: Journal Article,

Regulation and modulation of pH in the brain
Chesler, Mitchell
2003 Oct;83(4):1183-1221, Physiological reviews
The regulation of pH is a vital homeostatic function shared by all tissues. Mechanisms that govern H+ in the intracellular and extracellular fluid are especially important in the brain, because electrical activity can elicit rapid pH changes in both compartments. These acid-base transients may in turn influence neural activity by affecting a variety of ion channels. The mechanisms responsible for the regulation of intracellular pH in brain are similar to those of other tissues and are comprised principally of forms of Na+/H+ exchange, Na+-driven Cl-/HCO3- exchange, Na+-HCO3- cotransport, and passive Cl-/HCO3- exchange. Differences in the expression or efficacy of these mechanisms have been noted among the functionally and morphologically diverse neurons and glial cells that have been studied. Molecular identification of transporter isoforms has revealed heterogeneity among brain regions and cell types. Neural activity gives rise to an assortment of extracellular and intracellular pH shifts that originate from a variety of mechanisms. Intracellular pH shifts in neurons and glia have been linked to Ca2+ transport, activation of acid extrusion systems, and the accumulation of metabolic products. Extracellular pH shifts can occur within milliseconds of neural activity, arise from an assortment of mechanisms, and are governed by the activity of extracellular carbonic anhydrase. The functional significance of these compartmental, activity-dependent pH shifts is discussed
— id: 39059, year: 2003, vol: 83, page: 1183, stat: Journal Article,

Surface carbonic anhydrase activity on astrocytes and neurons facilitates lactate transport
Svichar, Nataliya; Chesler, Mitchell
2003 Mar;41(4):415-419, Glia
A number of studies have provided physiological evidence for extracellular carbonic anhydrase (CA) in brain. Association of extracellular CA with glia has been limited to functional studies of gliotic slices and retinal Muller cells. While astrocytes contain intracellular CA, there has been no direct evidence for surface CA on these cells. In fact, some morphological studies suggest that the extracellular CA in brain parenchyma resides on neurons, not glia. There has been no functional demonstration of extracellular CA activity on CNS neurons, however. Here we capitalized on the H(+) dependence of inward lactate transport to reveal functional extracellular CA activity on cultured astrocytes and acutely isolated hippocampal pyramidal neurons. Exposure to 20 mM L-lactate produced a rapid acidification of astrocytes that was reversibly blocked by 10 microM benzolamide. The lactate-induced acidification (LIA) was also blocked by a dextran-conjugated CA inhibitor. In CO(2)/HCO(3) (-)-free, HEPES-buffered media, the LIA was largely unaffected. Acutely dissociated hippocampal pyramidal neurons underwent a similar LIA that was reversibly blocked by benzolamide. Surface CA is likely to facilitate lactate transport by enabling rapid replenishment (i.e., buffering) of surface H(+) required for inward lactate-H(+) cotransport. These results demonstrate functional surface CA for the first time on individual mammalian astrocytes and neurons and suggest that this enzyme may play a role in the utilization of monocarboxylate substrates such as lactate and pyruvate by the brain
— id: 39322, year: 2003, vol: 41, page: 415, stat: Journal Article,

Axon-glia interactions and the domain organization of myelinated axons requires neurexin IV/Caspr/Paranodin
Bhat MA; Rios JC; Lu Y; Garcia-Fresco GP; Ching W; St Martin M; Li J; Einheber S; Chesler M; Rosenbluth J; Salzer JL; Bellen HJ
2001 May;30(2):369-383, Neuron
Myelinated fibers are organized into distinct domains that are necessary for saltatory conduction. These domains include the nodes of Ranvier and the flanking paranodal regions where glial cells closely appose and form specialized septate-like junctions with axons. These junctions contain a Drosophila Neurexin IV-related protein, Caspr/Paranodin (NCP1). Mice that lack NCP1 exhibit tremor, ataxia, and significant motor paresis. In the absence of NCP1, normal paranodal junctions fail to form, and the organization of the paranodal loops is disrupted. Contactin is undetectable in the paranodes, and K(+) channels are displaced from the juxtaparanodal into the paranodal domains. Loss of NCP1 also results in a severe decrease in peripheral nerve conduction velocity. These results show a critical role for NCP1 in the delineation of specific axonal domains and the axon-glia interactions required for normal saltatory conduction
— id: 27407, year: 2001, vol: 30, page: 369, stat: Journal Article,

Calcium dependence of rapid astrocyte death induced by transient hypoxia, acidosis, and extracellular ion shifts
Bondarenko A; Chesler M
2001 Apr 15;34(2):143-149, Glia
Exposure to hypoxic, acidic, ion-shifted Ringer (HAIR) for 15-40 min has been shown to cause rapid astrocyte death upon reperfusion with normal media. The ion shifts of the HAIR solution included a rise in extracellular K(+) (e.g., [K(+)](o)) and a fall in [Na(+)](o), [Cl(-)](o), and [Ca(2+)](o), characteristic of ischemic-traumatic brain insults. We investigated the ionic basis of the HAIR-induced injury. After HAIR exposure, reperfusion in 0 Ca(2+)/EGTA media completely protected astrocytes. Preincubation of cells in BAPTA-AM ester was also protective, indicating that the injury was triggered by Ca(2+) influx during reperfusion. Neither nimodipine, CNQX, APV, nor TTX reduced injury. Astrocyte death could be blocked by 100 microM Ni(2+) or 100 microM benzamil, suggesting involvement of Na(+)-Ca(2+) exchange. KB-R7943, which preferentially inhibits reverse Na(+)-Ca(2+) exchange, also protected astrocytes. Elevation of [K(+)](o) was not necessary for astrocyte death. However, when [Na(+)](o) was maintained at 151 mM throughout the HAIR protocol, cell death was markedly reduced. We postulate that [Na(+)](o) shifts aid reversal of Na(+)-Ca(2+) exchange by favoring cytosolic Na(+) loading. Possible means of astrocytic Na(+) accumulation are discussed
— id: 21195, year: 2001, vol: 34, page: 143, stat: Journal Article,

Rapid astrocyte death induced by transient hypoxia, acidosis, and extracellular ion shifts
Bondarenko A; Chesler M
2001 Apr 15;34(2):134-142, Glia
Death of astrocytes requires hours to days in injury models that use hypoxia, acidosis, or calcium paradox protocols. These methods do not incorporate the shifts in extracellular K(+), Na(+), Cl(-), and Ca(2+) that accompany acute brain insults. We studied astrocyte survival after exposure to hypoxic, acidic, ion-shifted Ringer (HAIR), with respective [Ca(2+)], [K(+)], [Na(+)], [Cl(-)], and [HCO(-)(3)] of 0.13, 65, 51, 75, and 13 mM (15% CO(2)/85% N(2), pH 6.6). Intracellular pH (pH(i)) was monitored with the fluorescent dye BCECF. Cell death was indicated by a steep fall in the pH-insensitive, 440-nm-induced fluorescence (F440) and was confirmed by propidium iodide staining. After 15-40-min HAIR exposure, reperfusion with standard Ringer caused death of most cultured (and acutely dissociated) astrocytes within 20 min. Cell death was not prevented if low Ca(2+) was maintained during reperfusion. Survival fell with increased HAIR duration, elevated temperature, or absence of external glucose. Comparable durations of hypoxia, acidosis, or ion shifts alone did not lead to acute cell death, while modest loss was noted when acidosis was paired with either hypoxia or ion shifts. Severe cell loss required the triad of hypoxia, acidosis, and ion shifts. Intracellular pH was significantly higher in HAIR media, compared with solutions of low pH alone or with low pH plus hypoxia. These results indicate that astrocytes can be killed rapidly by changes in the extracellular microenvironment that occur in settings of traumatic and ischemic brain injury
— id: 21196, year: 2001, vol: 34, page: 134, stat: Journal Article,

HEPES prevents edema in rat brain slices
MacGregor DG; Chesler M; Rice ME
2001 May 11;303(3):141-144, Neuroscience letters
Brain slices gain water when maintained in bicarbonate-buffered artificial cerebro-spinal fluid (ACSF) at 35 degrees C. We previously showed that this edema is linked to glutamate receptor activation and oxidative stress. An additional factor that may contribute to swelling is acidosis, which arises from high CO(2) tension in brain slices. To examine the role of acidosis in slice edema, we added N-2-hydroxyethylpiperazine-N'-2-ethanesulfonic acid (HEPES) to osmotically balanced ACSF (HEPES-ACSF), thereby increasing buffering capacity beyond that provided by bicarbonate/CO(2). Water gain was markedly inhibited in HEPES-ACSF. After 3 h incubation in HEPES-ACSF at 35 degrees C, water gain was limited to that of fresh slices after 1 h recovery in ACSF at room temperature. The effect of HEPES in decreasing slice water gain was concentration dependent from 0.3 to 20 mM. The inhibition of water gain by HEPES suggests that tissue acidosis is a contributing factor in brain slice edema
— id: 20706, year: 2001, vol: 303, page: 141, stat: Journal Article,

Proton release as a modulator of presynaptic function
Traynelis, SF; Chesler, M
2001 DEC 26 ;32(6):960-962, Neuron
In this issue of Neuron, DeVries (2001) describes experiments suggesting that acidification of the synaptic cleft can reduce Ca2+ channel activity and thereby act as a brake on tonic synaptic release of glutamate from cone cells. This work hints at a potentially important new facet to the regulation of synaptic transmission
— id: 55366, year: 2001, vol: 32, page: 960, stat: Journal Article,

Extracellular pH changes and accompanying cation shifts during ouabain-induced spreading depression
Menna G; Tong CK; Chesler M
2000 Mar;83(3):1338-1345, Journal of neurophysiology
Interstitial ionic shifts that accompany ouabain-induced spreading depression (SD) were studied in rat hippocampal and cortical slices in the presence and absence of extracellular Ca(2+). A double-barreled ion-selective microelectrode specific for H(+), K(+), Na(+), or Ca(2+) was placed in the CA1 stratum radiatum or midcortical layer. Superfusion of 100 microM ouabain caused a rapid, negative, interstitial voltage shift (2-10 mV) after 3-5 min. The negativity was accompanied by a rapid alkaline transient followed by prolonged acidosis. In media containing 3 mM Ca(2+), the alkalosis induced by ouabain averaged 0.07 +/- 0.01 unit pH. In media with no added Ca(2+) and 2 mM EGTA, the alkaline shift was not significantly different (0.09 +/- 0.02 unit pH). The alkaline transient was unaffected by inhibiting Na(+)-H(+) exchange with ethylisopropylamiloride (EIPA) or by blocking endoplasmic reticulum Ca(2+) uptake with thapsigargin or cyclopiazonic acid. Alkaline transients were also observed in Ca(2+)-free media when SD was induced by microinjecting high K(+). The late acidification accompanying ouabain-induced SD was significantly reduced in Ca(2+)-free media and in solutions containing EIPA. The ouabain-induced SD was associated with a rapid but relatively modest increase in [K(+)](o). In the presence of 3 mM external Ca(2+), the mean peak elevation of [K(+)](o) was 12 +/- 0.62 mM. In Ca(2+)-free media, the elevation of [K(+)](o) had a more gradual onset and reached a significantly larger peak value, which averaged 22 +/- 1.1 mM. The decrease in [Na(+)](o) that accompanied ouabain-induced SD was somewhat greater. The [Na(+)](o) decreased by averages of 40 +/- 7 and 33 +/- 3 mM in Ca(2+) and Ca(2+)-free media, respectively. In media containing 1.2 mM Ca(2+), ouabain-induced SD was associated with a substantial decrease in [Ca(2+)](o) that averaged 0.73 +/- 0. 07 mM. These data demonstrate that in comparison with conventional SD, ouabain-induced SD exhibits ion shifts that are qualitatively similar but quantitatively diminished. The presence of external Ca(2+) can modulate the phenomenon but is irrelevant to the generation of the SD and its accompanying alkaline pH transient. Significance of these results is discussed in reference to the propagation of SD and the generation of interstitial pH changes
— id: 11806, year: 2000, vol: 83, page: 1338, stat: Journal Article,

Interstitial carbonic anhydrase (CA) activity in brain is attributable to membrane-bound CA type IV
Tong CK; Brion LP; Suarez C; Chesler M
2000 Nov 15;20(22):8247-8253, Journal of neuroscience
We tested the hypothesis that extracellular membrane-bound carbonic anhydrase (CA) type IV is responsible for the regulation of interstitial pH (pH(o)) transients in brain. Rat hippocampal slices were incubated in phosphatidylinositol-specific phospholipase C (PI-PLC), which cleaves the link of CA IV to the external face of plasma membranes. Then evoked alkaline pH(o) shifts were studied in a recording chamber, using pH microelectrodes. Incubation fluid was saved for later analysis. The ability to buffer a rapid alkaline load was reduced markedly in PI-PLC-treated tissue as compared with adjacent, paired control slices. The effect of benzolamide (a poorly permeant CA inhibitor) on evoked pH(o) shifts was diminished greatly in the PI-PLC-treated tissue, consistent with the washout of interstitial CA. Treatment of the incubation fluid with SDS abolished nearly all of the CA activity in fluid from controls, whereas an SDS-insensitive component remained in the fluid from PI-PLC-treated slices. These data suggested that CA type II (which is blocked by SDS) leaked from injured glial cells in both slice preparations, whereas CA type IV (which is insensitive to SDS) was liberated selectively into the fluid from PI-PLC-treated tissue. Western blot analysis was consistent with this interpretation, demonstrating a predominance of CA IV in the incubation fluid from PI-PLC-treated tissue and variable amounts of CA II in fluid from PI-PLC-treated and control slices. These results demonstrate that interstitial CA activity brain is attributable principally to membrane-bound CA IV
— id: 39521, year: 2000, vol: 20, page: 8247, stat: Journal Article,

Activity-dependent pH shifts in hippocampal slices from normal and carbonic anhydrase II-deficient mice
Tong CK; Cammer W; Chesler M
2000 Aug;31(2):125-130, Glia
The type II isoform of carbonic anhydrase is abundant in astrocytes and oligodendroglia. To explore whether the expression of the type II isoform is required for interstitial carbonic anhydrase activity, we studied extracellular pH transients in hippocampal slices from mutant mice devoid of carbonic anhydrase type II and from wild-type littermates. Stimulation of the Schaffer collateral afferents evoked similar extracellular pH transients in the CA1 stratum pyramidale, consisting of a predominant alkaline shift and little or no subsequent acidosis. After 5-s stimulus trains at 10 Hz, alkaline shifts were not significantly different in carbonic anhydrase II-deficient and wild-type preparations, averaging 0.09 +/- 0.04 and 0.08 +/- 0.04 unit pH, respectively. Addition of 1.5 microM benzolamide amplified the alkaline shifts by 385 +/- 146 and 345 +/- 75% in the mutant and wild-type preparations, respectively. Dose response studies with benzolamide displayed similar sensitivity to this carbonic anhydrase inhibitor over a concentration range of 0. 03-10 microM. These data indicate that interstitial carbonic anhydrase activity is effectively unaltered in brains devoid of carbonic anhydrase type II. The results are consistent with the interpretation that a distinct extracellular isoform of carbonic anhydrase exists in brain.
— id: 11626, year: 2000, vol: 31, page: 125, stat: Journal Article,

Modulation of spreading depression by changes in extracellular pH
Tong CK; Chesler M
2000 Nov;84(5):2449-2457, Journal of neurophysiology
Spreading depression (SD) and related phenomena have been implicated in hypoxic-ischemic injury. In such settings, SD occurs in the presence of marked extracellular acidosis. SD itself can also generate changes in extracellular pH (pH(o)), including a pronounced early alkaline shift. In a hippocampal slice model, we investigated the effect of interstitial acidosis on the generation and propagation of SD in the CA1 stratum radiatum. In addition, a carbonic anhydrase inhibitor (benzolamide) was used to decrease buffering of the alkaline shift to investigate its role in the modulation of SD. pH(o) was lowered by a decrease in saline HCO(3)(-) (from 26 to 13 to 6.5 mM at 5% CO(2)), or by an increase in the CO(2) content (from 5 to 15% in 26 mM HCO(3)(-)). Recordings with pH microelectrodes revealed respective pHo values of 7.23 +/- 0. 13, 6.95 +/- 0.10, 6.67 +/- 0.09, and 6.97 +/- 0.12. The overall effect of acidosis was an increase in the threshold for SD induction, a decrease in velocity, and a shortened SD duration. This inhibition was most pronounced at the lowest pH(o) (in 6.5 mM HCO(3)(-)) where SD was often blocked. The effects of acidosis were reversible on return to control saline. Benzolamide (10 microM) caused an approximate doubling of the early alkaline shift to an amplitude of 0.3-0.4 U pH. The amplified alkalosis was associated with an increased duration and/or increased velocity of the wave. These effects were most pronounced in acidic media (13 mM HCO(3)(-)/5% CO(2)) where benzolamide increased the SD duration by 55 +/- 32%. The initial velocity (including time for induction) and propagation velocity (measured between distal electrodes) were enhanced by 35 +/- 25 and 26 +/- 16%, respectively. Measurements of [Ca(2+)](o) demonstrated an increase in duration of the Ca(2+) transient when the alkaline shift was amplified by benzolamide. The augmentation of SD caused by benzolamide was blocked in media containing the N-methyl-D-aspartate (NMDA) receptor antagonist DL-2-amino-5-phosphonovaleric acid. These data indicate that the induction and propagation of SD is inhibited by a fall in baseline pH characteristic of ischemic conditions and that the early alkaline shift can remove this inhibition by relieving the proton block on NMDA receptors. Under ischemic conditions, the intrinsic alkalosis may therefore enable SD and thereby contribute to NMDA receptor-mediated injury
— id: 39523, year: 2000, vol: 84, page: 2449, stat: Journal Article,

Interstitial shifts in pH, K+ and Na+ during spreading depression evoked in zero calcium media
Menna, G; Tong, C K; Chesler, M
1999 Oct 23-28;25(1-2):2104-2104, Abstracts (Society for Neuroscience)
— id: 15839, year: 1999, vol: 25, page: 2104, stat: Journal Article,

Effect of divalent cations on AMPA-evoked extracellular alkaline shifts in rat hippocampal slices
Smith SE; Chesler M
1999 Oct;82(4):1902-1908, Journal of neurophysiology
The generation of activity-evoked extracellular alkaline shifts has been linked to the presence of external Ca(2+) or Ba(2+). We further investigated this dependence using pH- and Ca(2+)-selective microelectrodes in the CA1 area of juvenile, rat hippocampal slices. In HEPES-buffered media, alkaline transients evoked by pressure ejection of RS-alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA) averaged approximately 0.07 unit pH and were calculated to arise from the equivalent net addition of approximately 1 mM strong base to the interstitial space. These alkaline responses were correlated with a mean decrease in [Ca(2+)](o) of approximately 300 microM. The alkalinizations were abolished reversibly in zero-Ca(2+) media, becoming indiscernible at a [Ca(2+)](o) of 117+/-29 microM. Addition of as little as 30-50 microM Ba(2+) caused the reappearance of an alkaline response. In approximately one-fourth of slices, a persistent alkaline shift of approximately 0.03 unit pH was observed in zero-Ca(2+) saline containing EGTA. In HEPES media, addition of 300 microM Cd(2+), 100 microM Ni(2+), or 100 microM nimodipine inhibited the alkaline shifts by roughly one-half, one-third, and one-third, respectively, whereas Cd(+) and Ni(2+) in combination fully blocked the response. In bicarbonate media, by contrast, Cd(+) and Ni(2+) blocked only two-thirds of the response. In the presence of bicarbonate, Ni(2+) caused an unexpected enhancement of the alkalinization by approximately 150%. However, when the extracellular carbonic anhydrase was blocked by benzolamide, addition of Ni(2+) reduced the alkaline shift. These results suggested that Ni(2+) partially inhibited the interstitial carbonic anhydrase and thereby increased the alkaline responses. These data indicate that an activity-dependent alkaline shift is largely dependent on the entry of Ca(2+) or Ba(2+) via voltage-gated calcium channels. However, sizable alkaline transients still can be generated with little or no external presence of these ions. Implications for the mechanism of the activity-dependent alkaline shift are discussed
— id: 11949, year: 1999, vol: 82, page: 1902, stat: Journal Article,

Activity-evoked extracellular pH shifts in slices of rat dorsal lateral geniculate nucleus
Tong CK; Chesler M
1999 Jan 9;815(2):373-381, Brain research
Activity-dependent extracellular pH shifts were studied in slices of the rat dorsal lateral geniculate nucleus (dLGN) using double-barreled pH-sensitive microelectrodes. In 26 mM HCO3--buffered media, afferent activation (10 Hz, 5 s) elicited an early alkaline shift of 0.04+/-0.02 pH units associated with a later, slow acid shift of 0.05+/-0.03 pH units. Extracellular pH shifts in the ventral lateral geniculate nucleus were rare, and limited to acidifications of approximately 0.02 pH units. The alkaline shift in the dLGN increased in the presence of benzolamide (1-2 microM), an extracellular carbonic anhydrase inhibitor. The mean alkaline shift in benzolamide was 0.10+/-0.05 pH units. In 26 mM HEPES-buffered saline, the alkaline response averaged 0.09+/-0.03 pH units. The alkaline shifts persisted in 100 microM picrotoxin (PiTX) but were blocked by 25 microM CNQX/50 microM APV. If stimulation intensity was raised in the presence of CNQX/APV, a second alkalinization arose, presumably due to direct activation of dLGN neurons. The direct responses were amplified by benzolamide, and blocked by either 0 Ca2+/EGTA, Cd2+ or TTX. In 0 Ca2+, addition of 500 microM-5 mM Ba2+ restored the alkalosis. Alkaline shifts evoked with extracellular Ba2+ were larger and faster than those elicited by equimolar Ca2+. In summary, synchronous activation in the dLGN results in an extracellular H+ sink, via a Ca2+-dependent mechanism, similar to activity-dependent alkaline shifts in hippocampus
— id: 57077, year: 1999, vol: 815, page: 373, stat: Journal Article,

Endogenous pH shifts facilitate spreading depression by effect on NMDA receptors
Tong CK; Chesler M
1999 Apr;81(4):1988-1991, Journal of neurophysiology
Rapid extracellular alkalinizations accompany normal neuronal activity and have been implicated in the modulation of N-methyl-D-aspartate (NMDA) receptors. Particularly large alkaline transients also occur at the onset of spreading depression (SD). To test whether these endogenous pH shifts can modulate SD, the alkaline shift was amplified using benzolamide, a poorly permeant inhibitor of interstitial carbonic anhydrase. SD was evoked by microinjection of 1.2 M KCl into the CA1 stratum radiatum of rat hippocampal slices and recorded by a proximal double-barreled pH microelectrode and a distal potential electrode. In Ringer solution of pH 7.1 containing picrotoxin (but not at a bath pH of 7.4), addition of 10 microM benzolamide increased the SD alkaline shift from 0.20 +/- 0.07 to 0.38 +/- 0.17 unit pH (means +/- SE). This was correlated with a significant shortening of the latency and an increase in the conduction velocity by 26 +/- 16%. In the presence of the NMDA receptor antagonist DL-2-amino-5-phosphonovaleric acid (APV), benzolamide still amplified the alkaline transient, however, its effect on the SD latency and propagation velocity was abolished. The intrinsic modulation of SD by its alkaline transient may play an important role under focal ischemic conditions by removing the proton block of NMDA receptors where interstitial acidosis would otherwise limit NMDA receptor activity
— id: 56420, year: 1999, vol: 81, page: 1988, stat: Journal Article,

Characterization of an intracellular alkaline shift in rat astrocytes triggered by metabotropic glutamate receptors
Amos BJ; Chesler M
1998 Feb;79(2):695-703, Journal of neurophysiology
The modulation of intracellular pH by activation of metabotropic glutamate receptors was investigated in cultured and acutely dissociated rat astrocytes. One minute superfusion of 100 microM (1S,3R)-1-aminocyclopentane-1, 3-dicarboxcylic acid (ACPD) evoked an alkaline shift of 0.13 +/- 0. 013 (mean +/- SE) and 0.16 +/- 0.03 pH units in cultured (cortical or cerebellar) and acutely dissociated cortical astrocytes, respectively. Alkalinizations were elicited by concentrations of ACPD as low as 1 muM. The ACPD response was mimicked by S-3-hydroxyphenylglycine (3-HPG) and by (s)-4-carboxy-3-hydroxyphenylglycine (4C-3HPG) but was not blocked by alpha-methyl-4-carboxyphenylglycine (MCPG) or (RS)-1-aminoindan-1, 5-dicarboxcylic acid (AIDA), features consistent with an mGluR5 receptor-mediated mechanism. The ACPD-evoked alkaline shift was insensitive to amiloride, 4,4'-diisothiocyanostilbene-2, 2'-disulfonic acid (DIDS), and the v-type ATPase inhibitors 7-chloro-4-nitrobenz-2-oxa-1,3-diazol (NBD-Cl), bafilomycin, and concanamycin. The alkaline response persisted in Na+- or Cl--free saline, but was reversibly blocked in bicarbonate-free, N-2-hydroxyethylpiperazine-N'-2-ethanesulfonic acid (HEPES)-buffered solutions. A bicarbonate-dependent and Na+-independent alkaline shift could also be elicited by either 3 mM caffeine or 1 muM ionomycin. These data suggest that a rise in cytosolic Ca2+ activity is instrumental in triggering the alkalinizing mechanism and that this response is independent of the classic depolarization-induced alkalinization mediated by electrogenic sodium-bicarbonate cotransport
— id: 57093, year: 1998, vol: 79, page: 695, stat: Journal Article,

Properties of an intracellular alkalinization of rat astrocytes triggered by metabotropic glutamate receptors
Amos, BJ; Chesler, M
1998 FEB ;506P(2):12S-13S, Journal of physiology
— id: 53541, year: 1998, vol: 506P, page: 12S, stat: Journal Article,

Temporal resolution of activity-dependent pH shifts in rat hippocampal slices
Gottfried JA; Chesler M
1996 Oct;76(4):2804-2807, Journal of neurophysiology
1. The rise time of activity-dependent extracellular pH shifts was measured in the CA1 stratum radiatum of rat hippocampal slices by recording pH-sensitive fluorescence of a fluorescein-conjugated dextran. Optical data were compared with simultaneous pH microelectrode recordings. 2. The pH shifts generated by CO2 or by stimulation of the Schaffer collaterals were paralleled by shifts in fluorescence emissions at 535 nm when the probe was excited with 490-nm light (delta F490). Emissions at 535 nm induced by 440-nm light were unchanged in these paradigms. 3. A train of three stimuli at 100 Hz was repeated at 30-s intervals and the stimulus-triggered delta F490 was averaged. The mean rise time of the delta F490 was 69 +/- 24 (SE) ms (range 20-200 ms, n = 6). The mean increase in emission was 0.75 +/- 0.22% of baseline, associated with a pH microelectrode response of +0.06 +/- 0.02 unit pH. 4. These data demonstrate that synaptically evoked alkaline transients develop within tens of milliseconds. The occurrence of the alkalinization in the same time frame as excitatory postsynaptic currents indicates that these pH shifts arise with sufficient speed to modulate synaptic transmission
— id: 57465, year: 1996, vol: 76, page: 2804, stat: Journal Article,

Calcium- and barium-dependent extracellular alkaline shifts evoked by electrical activity in rat hippocampal slices
Grichtchenko II; Chesler M
1996 Dec;75(4):1117-1126, Neuroscience
Synaptic activation of central neurons has been associated with rapid extracellular alkalinization. In this report, we directly activated CA1 pyramidal cells by antidromic invasion, or by field stimulation. Antidromic activation produced no pH change, despite a robust population spike in five of 11 slices. In six slices, antidromic stimulation at 10 Hz evoked a small alkalinization in stratum pyramidale (0.04 +/- 0.01 unit pH) which grew to 0.10-0.20 unit pH at 50-100 Hz, and was blocked in 0 Ca2+ media. Simultaneous pH recordings revealed no alkalinizations in stratum radiatum, despite robust alkaline shifts in stratum pyramidale. When synaptic transmission was blocked by 6-cyano-7-nitroquinoxaline-2,3-dione, DL-2-amino-5-phosphonovalerate and picrotoxin, the Schaffer collateral-induced alkaline shift in stratum radiatum was abolished. With adequate stimulus strength and orientation, however, alkaline shifts in stratum radiatum could still be elicited, presumably by direct activation of the CA1 population. The non-synaptic alkaline shifts ranged from 0.10-0.20 unit pH, were amplified by benzolamide, and blocked by tetrodotoxin, 0 Ca2+ saline, and 300-400 microM Cd2+. Although directly activated alkaline shifts were never observed in 0 Ca2+ saline, large stimulus evoked responses could be elicited upon addition of 5-10 mM Ba2+. The Ba(2+)-dependent responses were also amplified by benzolamide and blocked by tetrodotoxin, Cd2+ or high Mg2+. These data demonstrate that stratum pyramidale can undergo an extracellular alkaline shift independent of stratum radiatum. The ionic dependence and pharmacologic sensitivity of the alkaline shifts suggest that voltage-gated Ca2+ channels are instrumental in triggering the alkalinizing mechanism. However, the ability of Ba2+ to support the alkaline shifts indicates that Ca2+ entry is not an absolute requirement. Implications for the mechanism of these pH changes are discussed
— id: 12465, year: 1996, vol: 75, page: 1117, stat: Journal Article,

Benzolamide inhibits low-threshold calcium currents in hippocampal pyramidal neurons
Gottfried JA; Chesler M
1995 Dec;74(6):2774-2777, Journal of neurophysiology
1. Benzolamide is a poorly permeant sulfonamide inhibitor of the enzyme carbonic anhydrase. We studied the effect of benzolamide on low-threshold (LT) Ca currents in neonatal hippocampal CAl neurons. 2. In hippocampal slices, benzolamide (2-10 microM) inhibited the LT current 30-75% in voltage-clamped CAl pyramidal cells (n = 6). In slices bathed in N-2-hydroxypiperazine-N'-2-ethane-sulfonic acid (HEPES)-buffered Ringer, benzolamide also reduced the LT current, indicating that the action of the drug was not bicarbonate dependent. 3. Benzolamide inhibited LT Ca currents 20-75% in acutely dissociated CAl neurons in HEPES (n = 18): inhibition was 36 +/- 8% (mean +/- SE; n = 7) and 50 +/- 8% (n = 7) at 10 and 50 microM benzolamide, respectively. By contrast, high-threshold calcium currents recorded in CAl pyramidal cells (n = 18) and dorsal root ganglion neurons (n = 4) were virtually unaffected by benzolamide. 4. These results indicate that benzolamide inhibits LT Ca channels in central neurons and suggest caution in the use of this agent to inhibit extracellular carbonic anhydrase in excitable tissues
— id: 57359, year: 1995, vol: 74, page: 2774, stat: Journal Article,

Addition of carbonic anhydrase augments extracellular pH buffering in rat cerebral cortex
Huang W; Smith SE; Chesler M
1995 Oct;74(4):1806-1809, Journal of neurophysiology
1. The ability of the extracellular space to buffer rapid alkaline shifts was studied in rat cortex in vitro and in vivo. Alkaline shifts were generated by iontophoresis of OH- or were evoked by pressure ejection of alpha-amino-3-hydroxy-5-methylisoxazole-4-propionic acid (AMPA). 2. In cortical slices, alkaline shifts induced by OH- were enhanced by the carbonic anhydrase (CA) inhibitor benzolamide (83 +/- 16%, mean +/- SE), and were decreased by superfusion of 10 mg/l CA (-59 +/- 4%). CA had no effect at 1 mg/l, and no additional effect at 100 mg/l. 3. In slices, and in vivo, alkaline shifts induced by AMPA were similarly enhanced by benzolamide and decreased by superfusion of CA. 4. These data indicate that extracellular CA activity is less than that required for maximum buffering. This suggests that equilibrium between CO2 and bicarbonate may not be attained during rapid extracellular pH shifts
— id: 56763, year: 1995, vol: 74, page: 1806, stat: Journal Article,

Determination of extracellular bicarbonate and carbon dioxide concentrations in brain slices using carbonate and pH-selective microelectrodes
Chesler M; Chen JC; Kraig RP
1994 Aug;53(2):129-136, Journal of neuroscience methods
The extracellular pH of the brain is subject to shifts during neural activity. To understand these pH changes, it is necessary to measure [H+], [HCO3-], [CO3(2-)] and [CO2]. In principle, this can be accomplished using CO3(2-) and pH-sensitive microelectrodes; however, interference from HCO3- and Cl-, and physiological changes in [HCO3-], complicate measurements with CO3(2-) electrodes. Calibration requires knowledge of slope response, interference constants and corrections for [HCO3-] shifts. We show that when [HCO3-] is altered at constant [CO2] in the absence of Cl-, the HCO3- interference cancels and the Nikolsky equation reduces to the Nernst equation for CO3(2-). Measurement of CO3(2-) slope response by this method yielded a value of 28.5 +/- 0.72 mV per decade change in [CO3(2-)]. In Cl(-)-containing solutions, interference coefficient for HCO3- and Cl- were determined by altering [HCO3-] at constant [CO2], changing [CO2] at constant [HCO3-], then solving the simultaneous Nikolsky equations for each transition. The mean interference constants corresponded to selectivity ratios of 245:1 and 1150:1 for CO3(2-) over HCO3- and Cl- respectively. To correct for possible changes in [HCO3-], the equilibrium relation between CO3(2-) and HCO3- was substituted into the Nikolsky equation to yield an equation in [CO3(2-)] and [H+]. By simultaneously measuring shifts in [H+] with a pH microelectrode, this equation is readily solved for [CO3(2-)]. These methods were tested by measuring [HCO3-] and [CO2] in experimental solutions, and in the extracellular fluid of rat hippocampal slices
— id: 56622, year: 1994, vol: 53, page: 129, stat: Journal Article,

Elevation and clearance of extracellular K+ following graded contusion of the rat spinal cord
Chesler M; Young W; Hassan AZ; Sakatani K; Moriya T
1994 Jan;125(1):93-98, Experimental neurology
The elevation and clearance of extracellular potassium concentration ([K+]e) were studied following graded contusion injury of the rat thoracic spinal cord. Animals were anesthetized, paralyzed, laminectomized at T9-T10, and then artificially ventilated. A 10-g rod was dropped 1.25, 2.5, or 5 cm onto the dorsal thoracic cord with the dura intact. After impact, and incision of the dura-arachnoid and pial membranes, double-barreled, potassium-selective microelectrodes were inserted midway between the midline and lateral edge of the cord. For all three injury levels, the elevation of [K+]e was greatest within the first 1000 microns from the dorsal surface. In 50 g-cm injuries, increasing [K+]e was sometimes observed between 250 and 1000 microns; however such gradients were not typically observed in 25 and 12.5 g-cm injuries. Measured at 3-7 min after injury, the mean peak elevations of [K+]e were significantly different, measuring 13 +/- 2.4, 27 +/- 5.5, and 44 +/- 4.2 mM following 12.5, 25, and 50 g-cm contusions, respectively. The exponential half-times of [K+]e clearance averaged 5.8 +/- 1.0, 9.2 +/- 1.8, and 17 +/- 5.7 min for the same respective injury levels. These results indicate that elevation of [K+]e following traumatic injury to the spinal cord is a graded phenomenon, dependent on the energy of impact. This finding is consistent with a mechanism in which simple mechanical injury of cell membranes is the proximate cause of potassium release
— id: 6333, year: 1994, vol: 125, page: 93, stat: Journal Article,

Endogenous H+ modulation of NMDA receptor-mediated EPSCs revealed by carbonic anhydrase inhibition in rat hippocampus
Gottfried JA; Chesler M
1994 Aug 1;478 Pt 3:373-378, Journal of physiology
1. The occurrence of extracellular alkaline transients during excitatory synaptic transmission suggests that the NMDA receptor H(+)-modulatory site may have a physiological role. Here we amplify these pH shifts using benzolamide (a carbonic anhydrase inhibitor) and describe concomitant effects on EPSCs in whole-cell clamped CA1 neurones in rat hippocampal slices. 2. In CO2-HCO3(-)-buffered media, benzolamide increased the time to 50% decay (t50) of the EPSCs by 78 +/- 14% (P < 0.01, n = 10). This occurred simultaneously with amplification of the extracellular alkaline shift (154 +/- 14%). 3. In CO2-HCO3(-)-buffered media containing DL-2-amino-5-phosphonovalerate (APV), the EPSC t50 was unaltered by benzolamide, while the extracellular alkaline shifts were increased (111 +/- 23%, n = 8). 4. In Hepes-buffered media, neither the EPSC t50 nor the extracellular alkaline shift was altered by benzolamide (n = 9). 5. These data demonstrate that NMDA receptor activity is dependent on the buffering kinetics of the brain extracellular space. The results suggest that endogenous pH shifts can modulate NMDA receptor function in a physiologically relevant time frame
— id: 12941, year: 1994, vol: 478 Pt 3, page: 373, stat: Journal Article,

Depolarization-induced acid secretion in gliotic hippocampal slices
Grichtchenko II; Chesler M
1994 Oct;62(4):1057-1070, Neuroscience
Gliotic hippocampal slices were used to study glial acid secretion in a tissue largely devoid of neural elements. Rat hippocampal slices were prepared 10-28 days after sterotaxic injection of kainate. Cresyl Violet staining and immunohistochemistry for glial fibrillary acidic protein demonstrated a loss of neurons and a proliferation of reactive astrocytes in area CA3. Extracellular pH and K+ shifts were recorded in CA3 in response to K+ iontophoresis. Elevation of K+ evoked an extracellular acid shift that was two- to three-fold larger in gliotic versus unlesioned tissue. Ba2+ caused a slow extracellular acidification, and blocked both the depolarizing responses of the glial cells and the acid shifts evoked by K+. The K(+)-evoked acid shifts were abolished in Na(+)-free media, and diminished in HEPES-buffered solutions. Inhibition of extracellular carbonic anhydrase caused a reversible enhancement of the K(+)-evoked acid shifts, an effect that could be mimicked during H+ iontophoresis in agarose gels. Gliotic acid shifts were unaffected by amiloride or its analogs, stilbenes, zero Cl- media, zero or elevated glucose, lactate transport inhibitors, zero Ca2+ or Cd2+. Smaller acid shifts could be evoked in normal slices which were also enhanced by benzolamide, and blocked by Ba2+ and zero Na+ media. It is concluded that acid secretion by reactive astrocytes is Na+ and HCO3(-)-dependent and is triggered by depolarization. The similar pharmacological and ionic sensitivity of the acid shifts in non-gliotic tissue suggest that these properties are shared by normal astrocytes. These characteristics are consistent with the operation of an electrogenic Na(+)-HCO3- co-transporter. However, the enhancement of the acid shifts by inhibitors of extracellular carbonic anhydrase suggests that CO3(2-), rather than HCO3-, is the transported acid equivalent
— id: 56648, year: 1994, vol: 62, page: 1057, stat: Journal Article,

DEPOLARIZATION-INDUCED ALKALINIZATION OF ASTROCYTES IN GLIOTIC HIPPOCAMPAL SLICES
GRICHTCHENKO, II; CHESLER, M
1994 OCT ;62(4):1071-1078, Neuroscience
Depolarization-induced, intracellular alkaline shifts were studied in reactive astrocytes within slices of gliotic hippocampus. Slices were prepared 10-28 days after sterotaxic injection of kainic acid into the hippocampus of anesthetized rats. Astrocytes in gliotic CA3 were impaled with double-barreled pH sensitive microelectrodes and depolarized by iontophoresis of K+ from an adjacent micropipette. Elevation of extracellular K+ produced an intracellular alkalinization that grew with increasing membrane depolarization, ranging from approximately 0.10 to 0.30 pH units. Exposure to Ba2+ depolarized the cells and produced a similar alkalinization. In the presence of Ba2+, the K+-induced depolarization and the associated alkaline shift were abolished. The depolarization-induced alkaline shifts were partially inhibited (40 +/- 8.9%) in Na+-free media and were enhanced in bicarbonate versus HEPES-buffered saline. The alkalinizations were unaffected by incubation in chloride-free media, or by the stilbene 4,4'-dinitrostilbene-2,2'-disulfonic acid. It is concluded that the depolarization-induced alkaline shift of reactive astrocytes is mediated in part by a Na+ and HCO3--dependent mechanism that is insensitive to stilbenes. These characteristics correspond well with the properties of depolarization-induced acid secretion in the gliotic tissue. In addition, a separate, Na+-independent mechanism contributes to the depolarization-induced alkalinization. In view of the absolute Na+ dependence of acid secretion in the gliotic slices, we propose that the latter mechanism does not extrude acid across the plasma membrane
— id: 52314, year: 1994, vol: 62, page: 1071, stat: Journal Article,

Dynamics of extracellular calcium activity following contusion of the rat spinal cord
Moriya T; Hassan AZ; Young W; Chesler M
1994 Jun;11(3):255-263, Journal of neurotrauma
The role of Ca2+ in cellular injury has received particular attention in studies of acute spinal cord trauma. In this context, the spatial and temporal distribution of extracellular Ca2+ ([Ca2+]e) may have an important bearing on the development of secondary tissue injury. We therefore studied the spatial-temporal distribution of [Ca2+]e following moderate (25 g-cm) contusive injury to the rat thoracic (T9-T11) spinal cord. Double-barreled, Ca(2+)-selective microelectrodes were used to measure the magnitude and time course of [Ca2+]e at increasing depths from the dorsal spinal cord surface. After 2 h, the tissue was frozen and later analyzed for total Ca concentration using atomic absorption spectroscopy. [Ca2+]e fell at all depths, but the decrease was maximal at 250 and 500 microns from the dorsal surface, where, at 0-10 min after injury, [Ca2+]e averaged 0.09 +/- 0.03 and 0.06 +/- 0.03 mM respectively. By 2 h postinjury, [Ca2+]e recovered to nearly 1 mM across all depths. Over this time, total tissue calcium concentration ([Ca]t) was 4.54 +/- 0.16 mumol/g in injured cords vs 2.75 +/- 0.1 mumol/g in sham-operated controls. These data place emphasis on the dorsal gray matter as a principal site of ionic derangement in acute spinal cord injury. The implications of these findings are discussed with reference to secondary injury processes
— id: 6699, year: 1994, vol: 11, page: 255, stat: Journal Article,

Effects of GABA on axonal conduction and extracellular potassium activity in the neonatal rat optic nerve
Sakatani K; Hassan AZ; Chesler M
1994 Jun;127(2):291-297, Experimental neurology
GABA depolarizes rat optic nerve axons and modulates axonal conduction through the activation of GABA-A receptors. To address whether an increase of [K+]e plays a major role in GABA actions on the rat optic nerve, we studied the effects of GABA on axonal conduction and [K+]e in the neonatal rat optic nerve in vitro. Double-barrelled K(+)-sensitive microelectrodes were used to record [K+]e. GABA (10(-4)-10(-3) M) increased [K+]e in the neonatal optic nerve. During prolonged application, the [K+]e slowly recovered. The increase in [K+]e induced by GABA was markedly reduced by the GABA-A receptor blocker bicuculline (10(-4) M). Isoguvacine (10(-4) M), a GABA-A agonist, mimicked the effect of GABA but produced larger responses at the same concentration. In contrast, baclofen (10(-4) M), a GABA-B agonist, had no effect on [K+]e. The changes in the compound action potential induced by GABA correlated only partially with the [K+]e changes. Furthermore, the changes in the compound action potential induced by elevation of K+ were far less than those induced by GABA. These results demonstrate that the GABA-evoked accumulation of [K+]e plays a secondary role in GABA actions on the neonatal rat optic nerve
— id: 12964, year: 1994, vol: 127, page: 291, stat: Journal Article,

Calcium dependence of glutamate receptor-evoked alkaline shifts in hippocampus
Smith SE; Gottfried JA; Chen JC; Chesler M
1994 Dec 20;5(18):2441-2445, Neuroreport
Glutamate receptor activation induces an extracellular alkalinization in rodent hippocampus. We studied its Ca2+ dependence and pharmacology in hippocampal slices. Glutamate-evoked alkaline shifts were blocked by 0 Ca2+ saline. Alkalinizations induced by AMPA (alpha-amino-3-hydroxy-5-methylisoxazole-4-propionic acid) and NMDA (N-methyl-D-aspartate) were abolished by 20 microM CNQX (6-cyano-7-nitro-nitroquinoxaline-2,3-dione) and 50 microM APV (DL-2-amino-5-phosphonovalerate), respectively. The AMPA- and NMDA-evoked alkaline shifts were blocked by 0 Ca2+, however, AMPA-induced [K+]o elevation was unaffected. These data suggest that the glutamate receptor-channel does not mediate H+ influx, and support a role for Ca(2+)-H+ exchange
— id: 12855, year: 1994, vol: 5, page: 2441, stat: Journal Article,

Non-synaptic modulation of dorsal column conduction by endogenous GABA in neonatal rat spinal cord
Sakatani K; Chesler M; Hassan AZ; Lee M; Young W
1993 Sep 17;622(1-2):43-50, Brain research
GABAA receptor activation can modulate axonal conduction in the isolated dorsal column of the neonatal rat spinal cord in vitro. However, it is not known whether axonal conduction in the dorsal column can be modulated by endogenous GABA in the developing spinal cord. We consequently compared the effects of GABA, a GABAA agonist, and a GABA uptake inhibitor on axonal conduction in the dorsal column of hemisected neonatal (0- to 9-day-old) rat spinal cords in vitro. Extracellular compound action potentials evoked by supramaximal stimuli were recorded at two points with glass microelectrodes. GABA (10(-4) to 10(-3) M) reversibly decreased the compound action potential amplitude and the population conduction velocity. At 10(-4) M, compound action potential amplitudes fell by 45.0 +/- 6.5% of control while the conduction velocity slowed by 11.8 +/- 4.3% (n = 5). The GABAA receptor agonist, isoguvacine, mimicked the effects of GABA on the dorsal column compound action potential. In contrast, while GABA at 10(-5) M decreased the amplitude by 7.7 +/- 3.1%, it increased conduction velocity by 9.7 +/- 1.3% (n = 5). The GABA uptake inhibitor, nipecotic acid (10(-3) M), consistently decreased the compound action potential amplitude by 17.7 +/- 6.5% (n = 6) but the conduction velocity slowed in four out of six preparations. In two instances, nipecotic acid decreased the amplitude and increased the conduction velocity. The effects of nipecotic acid on the dorsal column compound action potential were blocked in the presence of the GABAA antagonist bicuculline.(ABSTRACT TRUNCATED AT 250 WORDS)
— id: 6506, year: 1993, vol: 622, page: 43, stat: Journal Article,

Extracellular alkaline shifts in rat hippocampal slice are mediated by NMDA and non-NMDA receptors
Chen JC; Chesler M
1992 Jul;68(1):342-344, Journal of neurophysiology
1. The pharmacology of synaptically evoked extracellular alkaline shifts was studied in the CA1 area of rat hippocampal slices. 2. Stimulus-evoked alkalinizations were unaffected by 2-amino-5-phosphonovalerate (APV) (20 microM). 3. 6-Cyano-7-nitro-nitroquinoxaline-2,3-dione (CNQX) (10 microM) inhibited the alkalinizations. In the continued presence of CNQX, an APV-sensitive, picrotoxin-insensitive, alkaline shift was elicited in low Mg2+ media. 4. Antidromic stimulation produced small alkaline shifts in comparison with orthodromic activation. 5. Our results demonstrate that in the hippocampal CA1 region, synaptically evoked alkalinizations can arise through both N-methyl-D-aspartate (NMDA) and non-NMDA glutamate receptors. These responses cannot be explained by cell firing per se
— id: 13552, year: 1992, vol: 68, page: 342, stat: Journal Article,

Modulation of extracellular pH by glutamate and GABA in rat hippocampal slices
Chen JC; Chesler M
1992 Jan;67(1):29-36, Journal of neurophysiology
1. Alkaline extracellular pH transients evoked by afferent stimulation, and local pressure ejection of glutamate and gamma-aminobutyric acid (GABA), were studied in the CA1 region of rat hippocampal slices. Amino acid-evoked responses were obtained by use of a dual micromanipulator, with the tip of a double-barreled pH-sensitive microelectrode positioned 50 microns from a pressure ejection pipette. 2. At 31 degrees C, in Ringer solutions buffered with 26 mM HCO3- and 5% CO2, mean extracellular pH in submerged 300-microns slices was 7.15 +/- 0.12 (n = 27 slices), at a tissue depth of approximately 150 microns. In Ringer buffered with 35 mM HCO3- and 5% CO2, extracellular pH was 7.29 +/- 0.10 (n = 19 slices). 3. Repetitive stimulation of the Schaffer collaterals caused an extracellular alkaline shift in stratum oriens, pyramidale, and radiatum, averaging 0.05 +/- 0.03 pH units among all regions (n = 138), with a maximum response of 0.16 pH units. Alkaline transients of similar appearance were obtained by local ejection of glutamate (0.01-0.12 pH units, n = 110) and GABA (0.01-0.18 pH units, n = 137). Control ejection of these amino acids into dilute agar caused only small acid shifts. 4. Superfusion of 100 microM picrotoxin abolished the GABA-evoked alkaline shift but failed to inhibit the Schaffer collateral- and glutamate-evoked alkalinizations. 5. Superfusion of 10(-5)-10(-3) M acetazolamide acidified the baseline by 0.05-0.10 pH units and amplified the Schaffer collateral- and glutamate-evoked alkaline shifts.(ABSTRACT TRUNCATED AT 250 WORDS)
— id: 13790, year: 1992, vol: 67, page: 29, stat: Journal Article,

pH transients evoked by excitatory synaptic transmission are increased by inhibition of extracellular carbonic anhydrase
Chen JC; Chesler M
1992 Aug 15;89(16):7786-7790, Proceedings of the National Academy of Sciences of the United States of America
Excitatory synaptic transmission has been associated with a rapid alkalinization of the brain extracellular space. These pH shifts are markedly increased by acetazolamide, an inhibitor of carbonic anhydrase. Although this effect can be readily explained by inhibition of extracellular carbonic anhydrase, this enzyme has been considered strictly intracellular in the central nervous system. To determine whether these alkaline shifts are regulated by extracellular carbonic anhydrase, we studied the effects of a membrane impermeant, dextran-bound inhibitor of this enzyme. Extracellular alkaline transients, measured with pH-sensitive microelectrodes, were generated in the CA1 region of rat hippocampal slices by repetitive electrical stimulation of Schaeffer collateral fibers or by local ejection of glutamate. More direct alkalinizations were elicited by focal ejection of NaOH in the vicinity of a pH microelectrode. These pH transients were reversibly enhanced by addition of the dextran-bound inhibitor. We conclude that there is significant carbonic anhydrase activity in the extracellular space of the brain. We postulate that this enzyme functions in the regulation and modulation of extracellular pH transients associated with neuronal activity
— id: 13477, year: 1992, vol: 89, page: 7786, stat: Journal Article,

Alkaline extracellular pH shifts generated by two transmitter-dependent mechanisms
Chesler M; Chen JC
1992 ;70 Suppl:S286-S292, Canadian journal of physiology & pharmacology
Recent studies of the effect of gamma-aminobutyric acid (GABA) on brain extracellular pH are reviewed. Experiments were performed on isolated turtle cerebellum, using double-barrelled pH-sensitive microelectrodes. Superfusion of GABA (1 mM) caused a rapid extracellular alkaline shift accompanied by a rise in extracellular K+. Washout of GABA was often associated with an acid rebound, concomitant with an undershoot of extracellular K+. The GABA-evoked alkaline shift was blocked by picrotoxin and mimicked by the GABA-A agonists isoguvacine and muscimol. The response persisted in the nominal absence of extracellular calcium, but it was reversibly abolished in nominally bicarbonate free media. In contrast, extracellular alkaline shifts evoked by repetitive stimulation of the parallel fibers were amplified in bicarbonate-free media and were insensitive to picrotoxin. These results indicate the existence of separate, transmitter-dependent mechanisms of extracellular alkalinization: (i) a GABA-A receptor mediated process, most likely associated with efflux of bicarbonate ions across GABA-A anion channels and (ii) a bicarbonate-independent process associated with excitatory synaptic transmission
— id: 13789, year: 1992, vol: 70 Suppl, page: S286, stat: Journal Article,

Modulation of pH by neuronal activity
Chesler M; Kaila K
1992 Oct;15(10):396-402, Trends in neurosciences
Although the requirement for a strict regulation of pH in the brain is frequently emphasized, recent studies indicate that neuronal activity gives rise to significant changes in intracellular and extracellular pH. Given the sensitivity of many ion channels to hydrogen ions, this modulation of local pH might influence brain function, particularly where pH shifts are sufficiently large and rapid. Studies using pH-sensitive microelectrodes have demonstrated marked cellular and regional variability of activity-dependent pH shifts, and have begun to uncover several of their underlying mechanisms. Accumulating evidence suggests that regional and subcellular pH dynamics are governed by the respective localization of glial cells, ligand-gated ion channels, and extracellular and intracellular carbonic anhydrase
— id: 13435, year: 1992, vol: 15, page: 396, stat: Journal Article,

Extracellular alkalinization evoked by GABA and its relationship to activity-dependent pH shifts in turtle cerebellum
Chen JC; Chesler M
1991 Oct;442:431-446, Journal of physiology
1. The effect of gamma-aminobutyric acid (GABA) on extracellular pH (pHo) was investigated in the turtle cerebellum, in vitro, using double-barrelled, H(+)-selective microelectrodes. Responses evoked by GABA were compared with pHo shifts evoked by repetitive stimulation of the parallel fibres. 2. In media buffered with 35 mM-HCO3- and 5% CO2, superfusion of GABA (1 mM) elicited an abrupt alkaline shift in the molecular layer, which averaged 0.05 +/- 0.02 pH units (+/- S.D., range 0.02-0.12 pH units). pHo often recovered in the continued presence of GABA, and displayed a rebound acidification upon wash-out. 3. The GABA-evoked alkaline shift was blocked by picrotoxin and was mimicked by the GABAA agonists isoguvacine and muscimol. The GABAB agonist baclofen did not elicit an alkaline shift. Alkaline shifts evoked by stimulation of the parallel fibres were unaffected by picrotoxin. 4. In nominally HCO3(-)-free solutions, buffered with 35 mM-HEPES, superfusion of GABA caused either no pHo change or a slow acid shift. In contrast, the alkaline shift evoked by stimulation of the parallel fibres became enhanced in HEPES-buffered media. 5. The alkaline shift evoked by GABA was accompanied by an increase in extracellular K+ ([K+]o) which averaged 1.7 mM above baseline. Experimental elevation of [K+]o to a comparable level always caused a pure acid shift in the extracellular space. 6. The GABA-evoked alkaline shift persisted when synaptic transmission was blocked using 4 mM-kynurenic acid or saline prepared with nominally zero Ca2+ and 10 mM-Mg2+. The alkaline shift evoked by repetitive stimulation of the parallel fibres was completely abolished in these media. 7. Although the GABA-evoked alkaline shift was blocked in nominally HCO3(-)-free media, substitution of 35 mM-formate for HCO3- restored the GABA response. Superfusion of 1 mM-GABA in formate saline produced an alkaline shift of 0.040 +/- 0.034 pH units. 8. These results indicate that gating of GABAA channels in the vertebrate CNS gives rise to an HCO3- efflux which can significantly increase the pH of the brain microenvironment. However, this mechanism cannot account for the extracellular alkalinization caused by parallel fibre stimulation. Extracellular alkaline shifts capable of modulating local synaptic operations may therefore be a consequence of either excitatory or inhibitory synaptic transmission
— id: 13886, year: 1991, vol: 442, page: 431, stat: Journal Article,

Extracellular alkaline-acid pH shifts evoked by iontophoresis of glutamate and aspartate in turtle cerebellum
Chesler M; Rice ME
1991 ;41(1):257-267, Neuroscience
The effect of glutamate and aspartate iontophoresis on extracellular pH was investigated in the turtle cerebellum in vitro. Both amino acids produced a rapid alkaline transient, typically followed by a prolonged acidification. These responses could be evoked in all layers of the cerebellum. Transition from bicarbonate to N-2-hydroxyethylpiperazine-N'-2-ethanesulfonic acid-buffered media amplified the pH shifts. Similar alkaline-acid transients could be evoked in the molecular layer by electrical stimulation of the parallel fibers or the ipsilateral peduncle, or by superfusion of glutamate or aspartate. However, no alkaline shifts were evoked in the granular layer by either parallel fiber or peduncle stimulation. In contrast, the iontophoretically induced alkaline shifts were largest in the granular layer. Compared with the stimulus-evoked alkalinizations, the iontophoretic alkaline shifts were relatively insensitive to Mn2+ or Cd2+. These data suggest that the activity-dependent alkalinization of brain extracellular space is generated by a bicarbonate-independent mechanism related to excitatory synaptic transmission. The results are consistent with a flux of hydrogen ions through cationic channels, but do not support a direct role for voltage-dependent Ca2+ channels. In view of the sensitivity of ion channels to changes in external pH, and the magnitude of the amino acid-induced pH shifts, these results indicate that extracellular pH could play an important modulatory role in excitatory synaptic transmission
— id: 14225, year: 1991, vol: 41, page: 257, stat: Journal Article,

Elevation and clearance of extracellular K+ following contusion of the rat spinal cord
Chesler M; Sakatani K; Hassan AZ
1991 Aug 9;556(1):71-77, Brain research
The elevation and clearance of extracellular potassium following a standard contusion injury was studied in the thoracic spinal cord of rats. Animals were anesthetized, paralyzed, laminectomized at T9-T11, then artificially ventilated. A 10-g rod was released 5.0 cm above the cord with the dura intact. After impact, the dura-arachnoid and pial membranes were incised to allow penetration of K(+)-selective microelectrodes. Electrodes utilized a valinomycin ionophore and were double-barreled, with tip diameters of 3-5 microns. Extracellular potassium activity ([K+]o) increased with the depth of penetration. The maximum values of [K+]o occurred at depths greater than 500 microns, and remained so with time after injury. These data indicate that a dorsal-ventral gradient of [K+]o develops in spinal cords contused from the dorsal surface, with the greatest elevation of [K+]o in the gray matter. In 8 preparations, the maximum [K+]o was 65 +/- 8 mM (mean +/- S.E.M.) at 5 +/- 1 min after injury. The [K+]o peak values decayed with a half-time of 11.0 +/- 3.4 min. Compared with data available for the injured cat spinal cord, the peak [K+]o recovered relatively rapidly. Although a simple diffusion model could account for the rapid clearance of [K+]o, the persistence of dorsal-ventral [K+]o gradients could not be explained by such a model. It is postulated that secondary injury processes contributed to the persistent [K+]o gradients
— id: 13940, year: 1991, vol: 556, page: 71, stat: Journal Article,

GABAA receptors modulate axonal conduction in dorsal columns of neonatal rat spinal cord
Sakatani K; Chesler M; Hassan AZ
1991 Mar 1;542(2):273-279, Brain research
gamma-Aminobutyric acid (GABA) can influence conduction in a number of axonal preparations from the peripheral and central nervous system. In the spinal cord, the excitability of primary afferent terminals has long been known to be affected by GABA. Whether conduction in the long fiber tracts of the spinal cord can be similarly modulated is unknown. Since GABA causes a pronounced depression of excitability in preparations of unmyelinated axons, and myelination is incomplete in the neonatal rat, we tested whether GABA can modulate conduction in the dorsal columns of 10-17-day-old rats. Experiments were performed in vitro, on isolated dorsal column segments (n = 18). The extracellular compound action potential evoked by submaximal stimuli was recorded with a glass micropipette positioned 0.5-2.0 mm from a stimulating electrode. At concentrations of 10(-4) - 10(-3) M, GABA decreased excitability, reversibly depressing the compound action potential amplitude, and increasing the latency by 47 +/- 11% and 22 +/- 9% (mean +/- S.E.M., n = 5, 10(-3) M), respectively. These effects were blocked by picrotoxin and mimicked by isoguvacine (10(-4) M), which decreased the compound action potential amplitude by 44 +/- 10% and increased the latency by 9 +/- 4% (n = 5). Lower concentrations of these agents caused a modest increase in excitability. At 10(-5) M, GABA increased the compound action potential amplitude by 14 +/- 2% and decreased the latency by 3 +/- 2% (n = 5). Our results demonstrate that functional GABAA receptors are present in neonatal dorsal columns.(ABSTRACT TRUNCATED AT 250 WORDS)
— id: 14123, year: 1991, vol: 542, page: 273, stat: Journal Article,

GABA-sensitivity of dorsal column axons: an in vitro comparison between adult and neonatal rat spinal cords
Sakatani K; Hassan AZ; Chesler M
1991 Jul 16;61(1):139-142, Brain research. Developmental brain research
In neonatal rat spinal cord, conduction in the dorsal column is reversibly depressed by GABA. We compared the GABA-sensitivity of dorsal columns in neonate versus adult rats, using in vitro isolated dorsal column preparations. The extracellular compound action potential evoked by submaximal stimuli was recorded with a glass micropipette. GABA (10(-4)-10(-3) M) reversibly depressed the compound action potential of both neonatal and adult rat dorsal columns. The GABA-induced reduction of dorsal column compound action potential amplitudes was blocked by the GABAA antagonist picrotoxin (10(-3) M) and mimicked by the GABAA agonist isoguvacine (10(-4-10(-3) M). The compound action potential reduction by GABA was far less pronounced on adult dorsal columns. The reduction of compound action potential amplitudes by isoguvacine (10(-4)-10(-3) M) was also significantly less in adult dorsal columns. These data suggest that GABAA receptors may play a role in extrasynaptic modulation of spinal long tract conduction in an age-dependent manner
— id: 13963, year: 1991, vol: 61, page: 139, stat: Journal Article,

A bicarbonate-dependent increase in extracellular pH mediated by GABAA receptors in turtle cerebellum
Chen JC; Chesler M
1990 Aug 14;116(1-2):130-135, Neuroscience letters
The gamma-aminobutyric acid (GABA)-gated anion channel has been found to have a significant permeability to bicarbonate in isolated nerve cells and crayfish muscle. We have studied the extracellular pH of the in vitro turtle cerebellum to determine whether the extracellular pH of vertebrate brain can be modulated by GABA. Exposure to 10(-3) M GABA produced an extracellular alkaline transient with a mean amplitude of 0.054 +/- 0.19 pH units (n = 49, range 0.018-0.091 pH units). The GABA-evoked alkaline shift was blocked by picrotoxin and was dependent on the presence of HCO3- in the bathing media. These data suggest that GABAA receptors gate an HCO3(-)-efflux which is sufficient to modulate brain pH
— id: 62288, year: 1990, vol: 116, page: 130, stat: Journal Article,

THE REGULATION AND MODULATION OF PH IN THE NERVOUS-SYSTEM
Chesler, M
1990 Apr;34(5):401-427, Progress in neurobiology
— id: 31948, year: 1990, vol: 34, page: 401, stat: Journal Article,

Pharmacologic studies of alkaline extracellular pH transients in the in vitro turtle cerebellum
Chesler M; Rice ME
1989 ;582:61-61, Acta physiologica Scandinavica. Supplementum
— id: 10757, year: 1989, vol: 582, page: 61, stat: Journal Article,

Stimulus-induced extracellular pH transients in the in vitro turtle cerebellum
Chesler M; Chan CY
1988 Dec;27(3):941-948, Neuroscience
In a number of CNS preparations, neuronal activation has been shown to result in a rapid extracellular alkaline transient, followed by a prolonged acid shift. The isolated turtle cerebellum was used to investigate the early alkaline transient. Double-barreled ion-sensitive microelectrodes for H+, K+ and tetramethylammonium were used to measure field potentials and extracellular ion and volume shifts in response to bipolar electrical stimulation of the parallel fibers. Transition from 15 mM HEPES to 35 mM HCO3- -buffered Ringer decreased the amplitude of the alkaline shift, presumably due to a marked increase in extracellular buffering power. In HEPES-buffered Ringer, repetitive stimulation produced alkaline shifts as large as 0.3-0.4 pH. Single shocks produced an alkaline shift of 0.006 +/- 0.0002 pH with a latency as short as 70 ms. Kynurenic acid (an excitatory amino acid antagonist), or Mn2+, blocked the alkaline shift and the postsynaptic component of the field potential. The alkaline shift was not blocked by the Na-H exchange inhibitor amiloride. The relationship between pHo and extracellular volume transients was studied using tetramethylammonium as an extracellular volume indicator. In nominally HCO3-free Ringer, stimulation at 5 Hz for 10 s caused a decrease in extracellular volume of 3.0 +/- 0.2 per cent. The volume transient was unaffected by 3 mM Mn2+, while the alkaline shift was completely abolished. The data for the alkaline shift are consistent with a channel-mediated transmembrane flux of proton equivalents. The size of the pH change and the underlying perturbation it represents, indicate that acid-base shifts may be a functionally important consequence of neuronal activity
— id: 10863, year: 1988, vol: 27, page: 941, stat: Journal Article,

Activity-related extracellular potassium transients in the neonatal rat spinal cord: an in vitro study
Walton KD; Chesler M
1988 Jun;25(3):983-995, Neuroscience
Transient increases and decreases in extracellular potassium (delta[K+]o) were recorded from the gray matter of hemisected, neonatal rat spinal cords isolated from 3, 4, 9- and 10-day-old pups. delta[K+]o were evoked in both the ventral and dorsal regions of the gray matter by electrical stimulation. In the ventral horn, repetitive stimulation of the ventral root was required to elicit detectable delta[K+]o. By contrast, single dorsal root stimuli evoked clear delta[K+]o. In the dorsal horn, single orthodromic stimuli elicited delta[K+]o as large as 4-5 mM from a baseline of 4.5 mM. With repetitive stimulation the [K+]o reached, but never exceeded, a ceiling of 10-11 mM. Undershoots were seen only after repetitive stimulation. Spontaneous delta[K+]o were observed in the ventral horn and were well correlated with ventral root activity. Spontaneous delta[K+]o were rare in the dorsal cord, but were recorded after bath application of apamin or tetraethylammonium. The magnitude and distribution of evoked K+ transients and postsynaptic components of the evoked field potential were well correlated in both the dorsal and the ventral gray matter. delta[K+]o were reversibly blocked by 1 mM CdCl2 in the bath and diminished by 1 mM BaCl2. Bath application of mephenesin, apamin or tetraethylammonium diminished evoked delta[K+]o in a stimulus-dependent manner. In apamin and tetraethylammonium, decreases from control responses were largest with high intensity stimulation, the opposite was the case with mephenesin. These results are interpreted in terms of the spinal circuits activated by high- and low-intensity electrical stimulation. We conclude that activity-related delta[K+]o in neonatal spinal cord are large enough to modulate neuronal electrical activity and the [K+]o is well regulated compared to other immature CNS regions studied. Thus, local increases in [K+]o may, by modulating neuronal activity, play a role in neonatal spinal cord developmental processes
— id: 11086, year: 1988, vol: 25, page: 983, stat: Journal Article,

PH REGULATION IN THE VERTEBRATE CENTRAL-NERVOUS-SYSTEM - MICROELECTRODE STUDIES IN THE BRAIN-STEM OF THE LAMPREY
CHESLER, M
1987 MAY ;65(5):986-993, Canadian journal of physiology & pharmacology
— id: 41696, year: 1987, vol: 65, page: 986, stat: Journal Article,

EVOKED AND SPONTANEOUS [K+]O TRANSIENTS ARE LARGE IN NEONATAL RAT LUMBAR SPINAL-CORD - AN INVITRO STUDY
Chesler, M; Walton, K
1987 Sep;390(9):P46-P46, Journal of physiology
— id: 31355, year: 1987, vol: 390, page: P46, stat: Journal Article,

REGULATION OF INTRACELLULAR PH IN RETICULOSPINAL NEURONS OF THE LAMPREY, PETROMYZON-MARINUS
CHESLER, M
1986 DEC ;381(4):241-261, Journal of physiology
— id: 41529, year: 1986, vol: 381, page: 241, stat: Journal Article,

Organization of the filum terminale in the frog
Chesler, M; Nicholson, C
1985 Sep 22;239(4):431-444, Journal of comparative neurology
The histological organization of the filum terminale of the spinal cord in Rana catesbeiana and Rana pipiens was characterized to determine if this region possessed an organized neuropil or whether it was merely a glial remnant that persisted after absorption of the larval tail. The excised filum was maintained in vitro. Intracellular electrophysiological recording was performed with horseradish peroxidase injection. Tyrosine hydroxylase and serotonin distribution were revealed by immunocytochemical methods. Astroglia were the dominant cell type and displayed an elaborate variety of forms. The mean membrane potential was logarithmically related to the extracellular potassium concentration but displayed a sub-Nernstian slope. Oligodendroglia were also seen, as well as ependyma that extended from the central canal to the pial surface. Neuronal activity was revealed by occasional intracellular penetration of elements that displayed spontaneous excitatory postsynaptic or action potentials. The major evidence for the presence of neurons was the demonstration of tyrosine hydroxylase (TH) immunoreactivity in a large population of cerebrospinal fluid-contacting neurons that abutted the ventral half of the central canal. The axons of these cells entered a ventral bundle and ascended the cord; some fibers left this tract and apparently terminated on large arcuate neurons within the filum. Serotoninergic fibers were primarily confined to a subpial location at the dorsal midline. We conclude that the filum terminale of the frog has a sparse but functional neuropil that is organized around the central canal and supported by a profusion of elaborate glial forms
— id: 148801, year: 1985, vol: 239, page: 431, stat: Journal Article,

Regulation of intracellular pH in vertebrate central neurons
Chesler, M; Nicholson, C
1985 Jan 28;325(1-2):313-316, Brain research
The regulation of intracellular pH (pHi) was investigated in reticulospinal neurons of the lamprey using ion-selective microelectrodes. Steady-state pHi in 23 mM HCO-3-buffered Ringer was 7.44 +/- 0.03 with a membrane potential of 54 +/- 4 mV (mean +/- S.E.M., n = 6). In nominally HCO-3-free solutions, pHi recovery from acid loading was blocked by 10(-3)M amiloride. Recovery was stimulated by transition to HCO-3-containing solutions. Results suggest that pHi regulation in lamprey reticulospinal neurons is mediated by a Na+-H+ exchanger. The presence of a distinct, HCO-3-dependent pHi regulatory mechanism is postulated
— id: 148777, year: 1985, vol: 325, page: 313, stat: Journal Article,