A-Type Potassium Current in Retinal Arteriolar Smooth Muscle Cells

doi:10.1167/iovs.04-1465

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A-Type Potassium Current in Retinal Arteriolar Smooth Muscle Cells

Mary K. McGahon, Jennine M. Dawicki, C. Norman Scholfield, J. Graham McGeown, and Tim M. Curtis

From the Centre of Vision Sciences, The Queen’s University of Belfast, Institute of Clinical Sciences, The Royal Victoria Hospital, Belfast, Northern Ireland.

Abstract

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Abstract
Methods
Results
Discussion
References

PURPOSE. By their control of membrane potential and intracellularfree Ca²⁺ ([Ca²⁺]_i), K⁺ currents are pivotal in the regulationof arterial smooth muscle tone. The goal of the present studywas to identify and characterize the A-type K⁺ current in retinalmicrovascular smooth muscle (MVSM) and to examine its role inmodulating membrane potential and cellular contractility.

METHODS. Whole-cell perforated patch–clamp recordingswere made from MVSM cells within intact isolated arteriolarsegments. Before patch-clamping, retinal arterioles were anchoredin the physiological recording bath and perfused with an enzymecocktail to remove surface basal lamina and to uncouple electricallythe endothelial cells from the overlying MVSM cells.

RESULTS. K⁺ currents were activated by depolarizing steps from–80 to +100 mV in 20-mV increments. A dominant, noninactivatingcurrent was elicited by depolarization to potentials positiveof –50 mV. Inhibition of this current by 100 nM of theCa²⁺-activated K⁺ channel blocker, Penitrem A, revealed a rapidlyinactivating K⁺ current that resembled an A-type current. TheA-type current was insensitive to tetraethylammonium (TEA) at1 mM, but was partially suppressed by higher concentrations(10 mM). 4-Aminopyridine (10 mM; 4-AP) completely blocked theA-type current. The 4-AP-sensitive transient current was activatedat a potential of –60 mV with peak current densities averaging29.7 ± 5.68 pA/pF at +60 mV. The voltage of half-inactivationwas –28.3 ± 1.9 mV, and the time constant for recoveryfrom inactivation at +60 mV was 118.7 ± 7.9 ms. Undercurrent–clamp conditions 4-AP depolarized the membranepotential by $~$ 3 to 4 mV and triggered small contractions andrelaxations of individual MVSM cells within the walls of thearterioles.

CONCLUSIONS. A-type current is the major voltage-dependent K⁺current in retinal MVSM and appears to play a physiologicalrole in suppressing cell excitability and contractility.

The contractile activity, or vascular tone, of microvascularsmooth muscle (MVSM) cells in the walls of retinal arteriolesis the major determinant of resistance to blood flow throughthe retinal circulation.¹ Retinal arterioles therefore havea primary physiological role in controlling blood pressure andlocal tissue perfusion in the retina. Because the retinal vasculaturehas no obvious autonomic nerve supply,² retinal MVSM tone islargely dependent on the complex interplay of vasodilator andvasoconstrictor stimuli released from neighboring endothelialand retinal cells.³ These signals evoke changes in MVSM contractilityby influencing the level of free intracellular Ca²⁺ ([Ca²⁺]_i)available to the contractile apparatus.⁴ ⁵ Retinal MVSM cellshave multiple mechanisms for regulating their intracellularCa²⁺ concentrations, including influx,⁶ efflux,⁷ and Ca²⁺release and uptake by the sarcoplasmic reticulum (SR).⁵ Plasmalemmalion channels play an important role in the regulation of [Ca²⁺]_i,both by providing pathways for Ca²⁺ entry and by regulatingMVSM cell membrane potentials. Such channels are therefore keyagents in the control of [Ca²⁺]_i and contractility.

K⁺ currents are important physiological regulators of membranepotential in arterial smooth muscle cells.⁸ The opening ofK⁺ channels in the cell membrane increases K⁺ efflux, leadingto membrane hyperpolarization. This closes voltage-dependentCa²⁺ channels, which decreases Ca²⁺ influx and results in vasodilatation.⁹ There are four main classes of K⁺ channels in the arterialsmooth muscle cell membrane: ATP-sensitive K⁺ channels (K_ATP),calcium-activated K⁺ channels (K_Ca), voltage-activated K⁺ channels(K_V), and inward rectifier K⁺ channels (K_IR). All these arebelieved to participate in the regulation of MVSM tone.¹⁰

K_V channels are the most numerous and diversified ion channelstructures.¹¹ However, K_V currents may be broadly categorizedas either slow "delayed rectifier" currents or rapid "A-type"currents, according to their time-dependent features. Delayedrectifier currents exhibit a delayed onset of activation followedby little or slow inactivation, whereas A-type currents aretypically distinguished by their rapid rates of inactivation.¹² A-type currents are classically associated with neurons, inwhich they are thought to play a role in regulating firing frequency.¹³¹⁴ These currents have also been identified in macro- and MVSMcells,¹⁵ ¹⁶ ¹⁷ ¹⁸ but their physiological role has yet to befully elucidated.¹²

In the present study we have, for the first time, identifieda rapidly inactivating K⁺ current in retinal MVSM that has severalelectrophysiological and pharmacological properties consistentwith an A-type current, but also demonstrates some novel features.Current–clamp studies were also performed, and the resultssuggest that this current plays a physiological role in retinalMVSM, increasing the membrane potential and thereby reducingexcitability.

Methods

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Abstract
Methods
Results
Discussion
References

Retinal Arteriole Preparation
Male Sprague-Dawley rats (200–300 g) were anesthetizedwith CO₂ and killed by cervical dislocation. Animal use conformedto the guidelines of the ARVO Statement for the Use of Animalsin Ophthalmic and Vision Research and the UK Home Office Regulations.Retinas were rapidly removed, and arterioles, devoid of surroundingneuropile, were isolated as previously described.¹ ⁵ ⁶ In brief,retinas were lightly triturated with a fire-polished Pasteurpipette (internal tip diameter, 0.3 mm) in a low-Ca²⁺ Hanks’solution. Homogenates were centrifuged at 2800 rpm (952g) for1 minute, the supernatant aspirated off, and the tissue washedagain with low-Ca²⁺ medium. The suspension was then stored at21°C until needed. Arteriolar segments remained useablefor up to 10 hours under these conditions.

Electrophysiology
Homogenate was placed in a 2-mL recording bath on the stageof an inverted microscope. Arteriolar segments were visuallydistinguished from venules by the presence of a thick wall ofcircularly arranged smooth muscle cells and lack of abluminalpericytes. Arterioles were anchored with tungsten wire slips(50 µm diameter, 2 mm length) and superfused with normalHanks’ solution at 37°C. Enzyme and drug solutionswere delivered by a seven-way micromanifold with an exchangetime of $~$ 1 second, as measured by switching to a dye solution.Before electrophysiological recording, vessels were digestedfor 20 minutes with an enzyme cocktail of collagenase 1A (0.1mg/mL) and protease type XIV (0.01 mg/mL) to remove surfacebasal lamina and to uncouple electrically the endothelial cellsfrom overlying arteriolar smooth muscle cells (Fig. 1) . Cellstreated in this manner remained viable as confirmed by theirability to exclude trypan blue solution (0.04% in normal Hanks’solution) for periods of >2 hours (n = 6). As a further measureof cell viability, retinal MVSM cell [Ca²⁺]_i was measured byfura-2 microfluorometry, as previously described.⁵ ⁶ No changesin [Ca²⁺]_i were observed after a 20-minute enzyme digestion(basal [Ca²⁺]_i: 72.4 ± 11.5 nM before, 65.4 ±9.9 nM after; n = 5; P = 0.44; paired t-test).

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FIGURE 1. (A) Light micrograph of an untreated retinal arteriole stained with toluidine blue (converted to gray scale). The endothelial cells and smooth muscle cells were in tight apposition throughout the cross-section. (B) Electron micrograph at x40,000 magnification of an untreated retinal arteriole. The basal lamina (BL) can be clearly seen between the endothelial cells (E) and the smooth muscle (SM). (C) Light micrograph of a retinal arteriole treated with collagenase and protease for 20 minutes. The endothelial cells completely pulled away from the overlying smooth muscle layer, creating a 1- to 5-µm separation cleft (SC). (D) Electron micrograph at x28,000 magnification of a retinal arteriole treated with enzyme for 20 minutes. Remnants of digested basal lamina can be seen in the separation cleft. Projections (P) normally connecting the endothelial cells to the smooth muscle layer have broken away. AJ, adherens junction. (E) Photomicrograph of an untreated retinal arteriole anchored in the physiological recording bath. (F) The same vessel after 20 minutes of digestion with collagenase and protease. The separation of the endothelial cells from the smooth muscle layer is clearly visible. Scale bars, 5 µm.

Ionic currents were recorded from retinal MVSM cells while stillembedded within their parent arterioles. Arterioles used forthe experiments were 25 to 40 µm in diameter; and, toguarantee adequate space clamping, recordings were restrictedto microvessels $≤$ 500 µm in length.¹⁹ ²⁰ Current–and voltage–clamp experiments were performed using thewhole-cell perforated patch–clamp technique²¹ with apatch–clamp amplifier (Axopatch-1D; Axon Instruments,Foster City, CA). Electrodes (1–2 M ${Omega}$ in free bathing solution)were pulled from filamented borosilicate glass capillaries (1.5mm outside diameter ;1.17 mm inside diameter; Clark ElectromedicalInstruments, Elderbridge, UK). Internal pipette solutions wereK⁺ based with amphotericin B as the perforating agent (see solutionsin the next section). Recordings were delayed until full perforationof the membrane patch had been achieved, as judged from thedevelopment of repeatable currents in response to step depolarizations.This usually took 3 to 5 minutes. Liquid junction potentials(<2 mV) were compensated electronically. Series resistance(34.5 ± 3.86 M ${Omega}$ ; n = 15) and cell capacitance (14.2 ±0.5 pF; n = 15) were usually uncompensated. Recordings werelow-pass filtered at 0.5 kHz and sampled at 2 kHz by an interface(PC1200; National Instruments, Austin, TX), using software providedby John Dempster (University of Strathclyde, Strathclyde, UK).Leakage currents were subtracted off-line from the active currentswith the use of the standard leak subtraction protocol containedwithin the patch software suite. For determination of whole-cellcurrent densities, cell membrane capacitance was determinedfrom the time constant of a capacitance transient elicited bya 20-mV depolarization from –80 mV, with a sampling frequencyof 20 kHz.

For current-clamp experiments, digital video recordings of thearterioles were collected simultaneously. This was accomplishedby attaching a video camera (WAT-902B; Watec, Yamagata, Japan)to the side port of the inverted microscope and the signal capturedonline by an A/D converter (Data Translation, Marlboro, MA)and stored on a computer.

Solutions and Drugs
The bath solution had the following composition (in mM): 140NaCl; 6 KCl; 5 D-glucose; 2 CaCl₂; 1.3 MgCl₂; and 10 HEPES (pH7.4 with NaOH). Low-Ca²⁺ medium differed only in that it contained0.1 mM CaCl₂. For perforated patch–clamp recordings, thepipette contained (mM): 138 KCl; 1 MgCl₂; 0.5 EGTA; 0.2 CaCl₂;10 HEPES (pH adjusted to 7.2 using NaOH); free Ca²⁺: 100 nM,to which 600 µg/mL amphotericin B was added.

Amphotericin B, collagenase 1A, Penitrem A, protease type XIV,tetraethylammonium chloride (TEA), 4-aminopyridine (4-AP), and9-anthracene carboxylic acid (9-AC) were purchased from Sigma-Aldrich.The effects of channel inhibitors were deemed to be througha direct action on the MVSM, in light of our previous findingsthat drug agents gain limited access to the endothelial cellswhen applied to the outside of the vessels.⁵ In addition, delaminationof the vessels in the present study further restricts the likelihoodof drugs mediating their effects through endothelial cell releaseof putative diffusible messengers.

Data Analysis
Data are reported as the mean ± SEM, and n denotes thenumber of arterioles from which recordings were made. Curvefitting was performed in an iterative fashion (Sigmaplot ver.8; Systat Software, Evanston, IL). SEMs for biophysical datawere calculated from curve fits for individual arterioles.

Results

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Abstract
Methods
Results
Discussion
References

Pharmacological Isolation of the A-Type Current
Outward currents were measured in MVSM cells still embeddedin retinal arteriolar fragments using the perforated patch–clamptechnique. Patch pipettes were K⁺ filled, and 9-AC (1 mM) wasincluded in the external bathing solution to minimize contaminationfrom Ca²⁺-activated Cl^– currents. Application of depolarizingvoltage steps with 20-mV increments from a holding potentialof –80 mV elicited an outward current that was composedof an initial transient and then a sustained component (Fig. 2A(i)). Spontaneous transient outward currents (STOCs) weresuperimposed on the background of the current and became morepronounced at increasingly positive membrane potentials. Thecomplex kinetics of the net outward current suggests that itmay be formed from multiple components. Addition of 100 nM PenitremA, a potent inhibitor of large-conductance Ca²⁺-activated K⁺channels (BK_Ca),²² reduced the sustained current and abolishedSTOCs, revealing a rapidly inactivating current that resembledan A-type current (Fig. 2A(ii)) . This transient current persistedduring exposure to Ca²⁺-free/EGTA solution (n = 4), suggestingthat it was Ca²⁺-independent and was unaffected by the K_ATPchannel inhibitor, glibenclamide (1 µM; n = 6). In allsubsequent voltage-clamp experiments, 100 nM Penitrem A wasadded to the external bathing solution to eliminate BK_Ca current.

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FIGURE 2. A family of whole-cell currents in a representative retinal arteriole. Currents were elicited by 1-second depolarizing steps from a holding potential of –80 mV in the absence (Ai) and presence (Aii) of 100 nM Penitrem A. (B) Average peak current density as a function of voltage for the Penitrem A insensitive current (n = 10).

In other types of smooth muscle, the A-type current often coexistswith delayed rectifier current.¹² These currents can be separatedfrom one another on the basis of their respective sensitivitiesto 4-AP and TEA. In retinal MVSM cells, low levels of TEA (1mM) had no effect on the A-type current, but partially inhibitedthe residual sustained current (Figs. 3A 3C) . External TEAat higher concentrations (10 mM) caused some depression of thepeak A-type current (Figs. 3B 3C) . It was evident from thesedata that the A-type and delayed rectifier currents in retinalMVSM could not be fully separated on the basis of their differentialsensitivity to TEA. In contrast, we found that the currentscould be isolated by applying 4-AP (10 mM). 4-AP caused nearlycomplete inhibition of peak A-type current, whereas the sustained,delayed rectifier current was unaffected (Fig. 4A) . The 4-AP-differencecurrents were characterized by a rapid rise and peak, whichthen subsided to baseline levels (Fig. 4B) . An average peakcurrent–voltage relationship for the 4-AP-sensitive A-typecurrent recorded in nine arterioles is plotted in Figure 4C. Peak current density at +60 mV was 29.7 ± 5.68 pA/pF.

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FIGURE 3. Effects of tetraethylammonium (TEA) on retinal MVSM transient outward currents. The membrane potential was stepped for 1 second from –80 to +100 mV in 10 mV increments. (A, B) Whole-cell A-type currents before (i) and after (ii) 1 and 10 mM TEA, respectively. (iii) Difference currents for the individual TEA concentrations obtained by subtracting (ii) from (i) at the voltage steps indicated. Dashed lines: zero current. (C) Average peak current–density relationships for the difference currents in 1 mM (n = 6) and 10 mM (n = 5) TEA.

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FIGURE 4. Effect of 4-AP on retinal arteriole A-type currents. (A) Whole-cell currents before (Ai) and after (Aii) external 4-AP (10 mM). (B) Difference currents obtained by subtracting (Ai) from (Aii) at the voltage steps specified. Dashed lines: zero current. (C) Average peak current density as a function of voltage for the 4-AP-sensitive current (n = 9).

Biophysical Properties
Our pharmacologic data with 4-AP indicate that the A-type currentin retinal MVSM is closely approximated by the peak minus thesustained components of the net outward current in PenitremA. Using this method, we investigated the biophysical propertiesof the A-type current in retinal MVSM cells. The voltage dependenceof inactivation was investigated by holding the retinal arteriolesat different membrane potentials during a conditioning prepulseand then applying a common test pulse (+60 mV). The amplitudeof the peak current during the test pulse decreased as the conditioningpotential was increased from –100 to 0 mV (Fig. 5A) .The peak current flowing during each test pulse was expressedrelative to the maximum current recorded after the conditioningprepulse at –100 mV (I/I_max) and the data were fittedwith a Boltzmann function. The voltage for half-inactivationof the A-type current was –28.3 ± 1.9 mV. The factthat the channels underlying the A-type current in retinal MVSMbegan to inactivate only at the threshold potential for activationof the delayed rectifier current (–50 mV; see Fig. 3C, 1 mM TEA) precluded a full separation of these componentsbased on their voltage sensitivities. This differs from thesituation in other types of smooth muscle, where the A-typeand delayed rectifier currents can be separated by shiftingthe prepulse holding potential from –80 to –40 mV.²³

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FIGURE 5. Electrophysiological properties of the A-type current. (A) A double-pulse protocol was applied to obtain the steady state, voltage-dependent inactivation. Membrane currents were measured at +60 mV after 3-second conditioning potentials ranging from –100 to 0 mV. (B) Voltage dependence of activation and inactivation measured in 10 arterioles. Normalized conductance (G/G_max) is plotted against membrane potential. (C) Recovery from inactivation of the A-type current using the voltage protocol depicted at the bottom. (D) Average time course of the recovery from inactivation in 10 vessels. Dashed lines: zero current in (A, C).

To examine the voltage dependency of activation (Fig. 5B) ,peak currents were converted to a conductance by the followingequation: G = I/(V_m– E_k), where I is the current amplitude,V_m is the command potential, and E_k is the equilibrium potentialfor potassium (E_k= –80 mV). Values were then normalizedto the maximum conductance (G/G_max). Fitting this data witha Boltzmann function gave a voltage of half-activation of –6.1± 1.6 mV. The activation and inactivation curves overlapsubstantially between –60 and 0 mV, revealing a relativelylarge window of steady state A-type current within this voltagerange (Fig. 5B) .

Recovery from inactivation was studied by using a double-pulseprotocol with conditioning and test pulses to +60 mV from theholding potential of –80 mV (Fig. 5C) . The interval betweenthe end of the conditioning pulse and the test pulse was increasedand the peak A-type current during test depolarizations wasthen normalized to that during the conditioning pulse. The summarydata have been plotted as a function of the recovery interval(Fig. 5D) . The time course of recovery from inactivation waswell fitted with a single exponential with a time constant of118.7 ± 7.9 ms.

Physiological Function
In the final series of experiments we investigated the contributionof the A-type current to retinal MVSM cell membrane potentialand contractility. In current–clamp mode and in the absenceof Penitrem A and 9-AC, the membrane potential of retinal arterioleswas set to –40 mV, close to the reported resting membranepotential for ocular and distal cerebral MVSM cells measuredusing intracellular recording electrodes.²⁴ ²⁵ Without injectionof negative current, resting membrane potentials were low ( $~$ –15 mV), presumably reflecting the effects of MVSM-endothelialcell uncoupling. 4-AP (10 mM) depolarized retinal arteriolesby $~$ 3 to 4 mV (Fig. 6A) . Despite the small level of depolarization,simultaneous video recordings revealed that 4-AP triggered miniaturecontractions and relaxations of individual MVSM cells withinwalls of the arterioles (Fig. 6B) , suggesting that electricaland mechanical excitability was increased when the A-type currentwas inhibited. No effects on membrane potential or MVSM cellcontractility were observed when current-clamped vessels (at–40 mV) were exposed to 100 nM Penitrem A alone (n = 6).

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FIGURE 6. Effects of 4-AP on electrical and mechanical activity. (A) Retinal MVSM cell membrane potential measured in current–clamp mode before, during, and after washout of 4-AP. Solid line: average trace obtained from five arterioles; dashed lines: SEM. (B) Digital images of a vessel exposed to 4-AP (10 mM). In the presence of 4-AP some cells undergo small contractions (arrows, middle). Movie 1 at http://www.iovs.org/cgi/content/full/46/9/3281/DC1 shows the contractions induced by 4-AP in this vessel.

	Discussion

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Most studies concerning the measurement of ionic currents inMVSM have used freshly isolated cells,¹⁰ but there are severalproblems with this type of approach. In particular, it is oftendifficult to correlate the electrophysiology of the cells witharterioles of a known size, and it is likely that single cellschange their properties when isolated from their tissue environment.²⁶ We therefore opted for a technique based on direct patch–clamprecording from retinal MVSM cells that were still embedded withintheir parent arterioles. Although whole-cell patch–clamprecordings have also been reported for coronary,²⁷ cerebral,²⁸ and choroidal¹⁹ arterioles, this technique has the drawbackthat endothelial cells are usually still present and may contaminatethe current records originating from the MVSM. To avoid thisproblem, we devised a protocol whereby isolated retinal arterioleswere anchored in a recording bath and externally perfused withan enzyme cocktail. This resulted in a gradual delaminationof the arterioles that could be monitored and stopped as soonas the endothelial and MVSM cell layers had fully separated(see Fig. 1 ). The ability to monitor the dissociation of thecell layers proved extremely advantageous, because slight over-digestionof the arterioles resulted in sustained contraction.

In the present study, we have identified and characterized anA-type potassium current in retinal MVSM cells. The featuresof the current, particularly the activation threshold, timeconstant for recovery from inactivation, and high sensitivityto 4-AP, resemble those reported for A-type currents observedin other types of smooth muscle,¹² but there are some importantdifferences. In particular, the voltage for half inactivationof the A-type current in retinal MVSM is $~$ 20 to 40 mV more positivethan values previously reported. Furthermore, the current ispartially suppressed by relatively low levels of TEA. Thesedistinct characteristics may indicate that the molecular compositionof the channels underlying the A-type current is different inretinal MVSM. Potassium channel ${alpha}$ subunits with A-type propertiesare found in several potassium channel families, including Shaker(K_V 1.3, K_V1.4 & K_V1.7), Shaw (K_V3.3 & K_V3.4), and Shal(K_v4.1, Kv4.2, K_v4.3), and transcripts for most of these subunitshave been detected in vascular smooth muscle.²⁹ Of note, noneof these subunits, when expressed in heterologous expressionsystems,¹¹ mediate A-type currents with properties analogousto those presently described in retinal MVSM. This may be explainedby the fact that K_V channels within the same subfamily are ableto form heteromultimeric channels that can exhibit hybrid biophysicaland pharmacologic properties.¹¹ Furthermore, in native cells,the presence and interaction of accessory ß-subunitsis also an important determinant of the kinetic features ofthe A-type current.¹¹ ¹² Considering these findings, it isapparent that a whole host of distinct A-type K⁺ currents mayexist, and molecular-based studies are now warranted to identifythe major components of the A-type current in retinal MVSM cells.

The functional importance of A-type currents in vascular smoothmuscle depends on the existence of sustained channel activityat physiological membrane potentials. The exact physiologicalfunction of A-type currents in vascular smooth muscle is controversial,because in many cases the currents should be completely inactivatedat the resting membrane potential.¹² Our experiments characterizingthe voltage dependence of activation and inactivation in retinalMVSM cells suggest, however, that the voltage window over whicha steady state A-type current persists, overlaps the restingmembrane potential in this tissue. This was confirmed by testingthe effects of 4-AP (which specifically blocks the A-type currentin retinal arterioles; see Fig. 4 ) in current–clamp mode.From an initial membrane voltage of –40 mV, 4-AP causeda small but measurable depolarization. Some reports have suggestedthat the primary role of the A-type current in vascular smoothmuscle is to suppress membrane excitability.¹⁶ ¹⁸ We have directevidence for this in retinal MVSM, because application of 4-APto current-clamped vessels not only caused membrane depolarization,but also increased cell contractility. Thus, it seems probablethat regulation of A-type channels at the molecular or functionallevel in retinal MVSM cells may have important implicationsfor the control of local tissue perfusion in the retina.

To conclude, this is the first study to identify and characterizethe A-type K⁺ current in retinal MVSM cells. We have begun todefine the physiological significance of this current, but furtherstudies are now needed to establish its molecular basis andits role in regulating retinal blood flow. Such studies maycritically underpin future work aimed at providing a betterunderstanding of retinal hemodynamic abnormalities in diseaseslike diabetes.

Acknowledgements

The authors thank Claire Lagan for assistance with the vascularhistology.

Footnotes

Supported by The Juvenile Diabetes Research Foundation (USA),Fight for Sight (UK) and The Wellcome Trust (UK).

Submitted for publication December 13, 2004; revised April 11,2005; accepted July 5, 2005.

Disclosure: M.K. McGahon, None; J.M. Dawicki, None; C.N. Scholfield,None; J.G. McGeown, None; T.M. Curtis, None

The publication costs of this article were defrayed in partby page charge payment. This article must therefore be marked"advertisement" in accordance with 18 U.S.C. $§$ 1734 solely toindicate this fact.

Corresponding author: Tim M. Curtis, Centre of Vision Sciences,The Queen’s University of Belfast, Institute of ClinicalSciences, The Royal Victoria Hospital, Grosvenor Road, BelfastBT12 6BA. Northern Ireland; t.curtis{at}qub.ac.uk.

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