{alpha}2-Adrenoceptor Agonists Inhibit Vitreal Glutamate and Aspartate Accumulation and Preserve Retinal Function after Transient Ischemia

Assistant Professor of Medicine (Clinician-Educator)

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Vol. 296, Issue 1, 216-223, January 2001

$alpha$ ₂-Adrenoceptor Agonists Inhibit Vitreal Glutamate and Aspartate Accumulation and Preserve Retinal Function after Transient Ischemia

John E. Donello, Edwin U. Padillo, Michelle L. Webster, Larry A. Wheeler and Daniel W. Gil

Department of Biological Sciences, Allergan, Inc., Irvine, California

	Abstract

Top Abstract Introduction Materials and Methods Results Discussion References

Recent studies have suggested that $alpha$ ₂-adrenergic agonists prevent neuronal cell death in a number of animal models, althoughthe mechanism of $alpha$ ₂-neuroprotection remains unclear. In a retinalischemia model, the $alpha$ ₂-specific agonist brimonidine (1 mg/kg i.p.)preserves approximately 80% of the electroretinogram (ERG) b-wave.The protective effect of brimonidine is completely blocked bycoadministration of the $alpha$ ₂- antagonist rauwolscine. Brimonidinetreatment preserves the ERG b-wave if animals are treated 1 or3 h before ischemia, but has no effect if it is injected duringischemia. The 3-h pretreatment effect is blocked by i.v. injectionof rauwolscine 2 h later (1 h before ischemia). A comparison ofvitreous humor glutamate levels between untreated and brimonidine-treatedeyes shows that 1) after ischemia, glutamate levels rise 2- to3-fold in the untreated animals, and 2) glutamate levels in thebrimonidine-treated animals are comparable to the nonischemiccontrols. Hence, the mechanism for brimonidine-mediated protectionin the retinal ischemia model requires activation of the $alpha$ ₂-adrenergicreceptors immediately before and during ischemia. These data suggestthat activation of the $alpha$ ₂-adrenergic receptor may reduce ischemicretinal injury by preventing the accumulation of extracellularglutamate andaspartate.

	Introduction

Top Abstract Introduction Materials and Methods Results Discussion References

Activation of $alpha$ ₂-adrenoceptors can result in the regulation of multiple signaling pathways and protein targets, some of whichare thought to be potentially neuroprotective. $alpha$ ₂-Agonists activateinward rectifying K⁺ channels and block voltage-gated Ca²⁺ channels, which hyperpolarizes neurons and inhibits presynapticneurotransmitter release (Lakhlani et al., 1996). $alpha$ ₂-Adrenoceptorsalso induce the phosphorylation of mitogen-activated protein kinaseand inhibit the cyclic AMP-dependent phosphorylation of cAMP responseelement-binding protein (Alblas et al., 1993; Fitzgerald et al.,1999). In vivo, systemic administration of the $alpha$ ₂-agonists clonidineand xylazine has been shown to activate the extracellular signal-regulatedkinases p42/p44 (Wen et al., 1996).

$alpha$ ₂-Adrenergic agonists significantly improve neurological outcomes in multiple models of brain ischemia. Dexmedetomidine,a selective $alpha$ ₂-agonist, reduced infarct size in a rat forebrainincomplete ischemia model (Hoffman et al., 1991). The drug alsoreduced central nervous system infarct size in rabbit focal ischemiaand gerbil global ischemia (Maier et al., 1993; Koistinaho andHokfelt, 1997).

Although multiple models have been proposed, the mechanism(s) by which $alpha$ ₂-adrenoceptors prevent neuronal cell death remainsunclear. One study has suggested that $alpha$ ₂- agonists prevent ischemia-inducedbrain damage by inhibiting the accumulation of glutamate (Maieret al., 1993). Consistent with this hypothesis, previous studieshave demonstrated that the $alpha$ ₂-agonists dexmedetomidine, mivazerol,and clonidine decrease hypoxia-induced glutamate accumulationin a hippocampal brain slice preparation (Bickler and Hansen,1996; Talke and Bickler, 1996). A separate study demonstratedthat dexmedetomidine partially inhibited the ischemia-inducedexpression of the immediate early genes c-fos and hsp70 (Wittneret al., 1997). The authors speculated that altered gene regulationmay reflect the protective mechanism of dexmedetomidine. Wen etal. (1996) have postulated that $alpha$ ₂-adrenoceptor-mediated transcriptionalup-regulation of basic fibroblast growth factor may be sufficientfor reduction of light-induced photoreceptor degeneration in rats.The $alpha$ ₂-agonist brimonidine also slows the rate of retinal ganglioncell loss after a partial crush of the rat optic nerve (Yoleset al., 1999). These data suggest that $alpha$ ₂-agonists protect multipleretinal cells from a variety of differentinsults.

Acute reversible retinal ischemia is an ideal model system for investigating the mechanism by which various compounds reduceischemia-induced injury. The retina exhibits a well defined structure,is easy to experimentally access, and can be functionally characterizedby electroretinography (ERG). These properties enable one to evaluateand quantify the extent of retinal injury electrophysiologicallyandhistologically.

Numerous studies suggest that excitotoxicity plays a major role in ischemia-induced retinal cell death; there is a large increasein extracellular glutamate concentrations and glutamate ionotropicantagonists will partially block ischemia-induced damage (Choiand Rothman, 1990). However, the ischemic state is complex andmost likely consists of additional insults, including energy depletionand free radicals. The present study demonstrates that pretreatmentwith $alpha$ ₂- agonists leads to a reduction of ischemic retinal injuryand prevents an ischemia-induced rise in extracellular glutamateandaspartate.

	Materials and Methods

Top Abstract Introduction Materials and Methods Results Discussion References

Retinal Ischemia. Rats were anesthetized with isoflurane and placed onto a warm surface to maintain constant body temperature. Animals' temperatureand heart rate were monitored throughout the ischemic period.Pupils were dilated with 1% tropicamide and a drop of Opthainewas instilled in the eye. A 30-gauge cannula, attached to a raisedsaline reservoir, was placed into the anterior chamber of oneeye. The intraocular pressure was raised to over 110 mm Hg, sufficientto induce complete retinal ischemia (Buchi et al., 1991). A hand-heldophthalmoscope was used to visually inspect the retinal bloodvessels and verify ischemia. After 50 min, the saline reservoirwas lowered and, for 10 min, the intraocular pressure and retinalcirculation was allowed to return to normal. The cannula was removedfrom the cornea and the animals were recovered. All experimentswere performed in accordance with the Association for Researchin Vision and Ophthalmology Statement for the Use of Animals inOphthalmic and VisionResearch.

Electrophysiology. Rats were dark adapted for 30 min. A drop of 1% tropicamide was instilled in each eye and the animals were anesthetized withketamine (65 mg/kg) in combination with xylazine (20 mg/kg). Thenonrecorded eye was occluded and subcutaneous needle electrodeswere placed in the cheek (reference) and back (ground). The corneawas moistened with Celluvisc, the eyelids gently retracted, agold ring ERG electrode (i.d. = 3 mm) was placed onto the surfaceof the cornea and a Grass model 1533 photic stimulator was positioned10 cm from the eye on the optical axis. ERG responses were elicitedby a brief flash of light. Stimuli consisted of brief flashesof 10-µs duration, 0.09 Joule, and delivered at 10-s intervals.The measured values were averaged and the amplitudes of the a-and b-waves were calculated and compared using a Student's t test.The ERG response was normalized by dividing the amplitude of theb-wave with the amplitude of the a-wave (Fig. 2). The percentageof protection was calculated by dividing the experimental valuesby control values and multiplying by 100 {(experimental b-wave+ experimental a-wave)/experimental a-wave} $-$ 1/{(control b-wave+ control a-wave)/control a-wave} $-$ 1 × 100 to get percentageofprotection.

Histology. Animals were euthanized with an overdose of sodium pentobarbital. Both eyes were enucleated and placed in Davidson's fixativeovernight. The following day, the eyes were transferred to 10%neutral-buffered formalin. To control the angle of sectioning,the fixed eyes were placed in customized eye block. The blockcontains a groove with which the ciliary artery was aligned toensure a consistent plane of blocking. The eyes were then paraffinembedded with the blocked surface flush with the embedding mold.Only sections that included the optic nerve were counterstainedwith H&E, which ensured that similar sections were comparablebetween retinas. Images were collected using ImagePro Plus softwareand then ischemic retinas were visually compared with nonischemicretinas.

Retrograde Labeling of Retinal Ganglion Cells (RGCs). Rats were anesthetized with ketamine (65 mg/kg), xylazine (6.5 mg/kg), and acepromazine (12 mg/kg) and a drop of ophthalmicanesthetic was placed in the right eye. Using a dissecting microscope,a small incision was made in the conjuctiva and, using blunt dissection,the optic nerve was exposed and transected within the dura. Crystalsof rhodamine-labeled dextran (3000 mol. wt.; Molecular Probes,Eugene, OR) were placed in the transected site. After 24 h, theanimals were euthanized and the eyes were post fixed in 4% paraformaldehydefor 2 h. The retinas were flat mounted onto black nitrocellulosefilter paper and RGCs were counted from eight 40× fields thatwere equal distance from the optic nerve. The fields were averagedfor each animal and compared with control eyes using a Student'sttest.

LC/MS/MS Analysis. Vitreous humor samples collected from the untreated and brimonidine-treated rats were analyzed in a masked manner by highpressure liquid chromatography using an HP 1100 pump and autosampler(Hewlett Packard, Wilmington, DE) equipped with a reversed phasecolumn (LUNA C18, 30 × 2.0 mm, 3-µm particle size) and a linearacetonitrile/10 mM ammonium formate gradient containing 0.5% formicacid at a flow rate of 50 µl/min. The column effluent was introducedinto a PE-Sciex API 365 tandem mass spectrometer (PerkinElmer-Sciex,Ontario, Canada) via the Turbo Ionspray interface. Mass spectrometricanalysis was performed by multiple reaction monitoring-positiveionization monitoring 148 $right-arrow$ 84 m/z for glutamate, 132 $right-arrow$ 86 m/zfor leucine, 134 $right-arrow$ 74 m/z for aspartate, and 154 $right-arrow$ 137 m/z fordopamine. Calibration standard samples at concentrations of 1.0to 10,000 ng/ml were prepared by spiking the distilled water withknown amounts of analytes. The standards were routinely analyzedwith the vitreous humorsamples.

	Results

Top Abstract Introduction Materials and Methods Results Discussion References

Brimonidine Prevents Ischemia-Induced Damage. To determine whether brimonidine can prevent retinal damage in a retinal transient ischemia model, Brown Norway rats wereinjected i.p. with 1 mg/kg brimonidine 1 h before the transientischemic insult. Histological examination of the retina 7 dayslater demonstrated that, compared with saline-treated animals,brimonidine prevents ischemia-induced retinal damage (Fig. 1).Compared with nonischemic retinas (Fig. 1A), the ischemic retinasof the saline-treated animals display significant damage, includingthe loss of the ordered retinal structure, reduced ganglion celland inner plexiform layers, and loss of cells in the inner nuclearlayer (Fig. 1B). In contrast, ischemic retinas from the brimonidine-treatedanimals, shown in Fig. 1D, are indistinguishable from the fellownonischemic retina (Fig. 1C). A masked visual comparison of thenonischemic and brimonidine-treated retinas found that there wasno observable loss of the ganglion cell, inner plexiform, or innernuclear layers. These data demonstrate that the $alpha$ ₂-agonist brimonidineprevents the appearance of overt histological evidence for ischemia-inducedstructural damage in the retina.

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Fig. 1. Brimonidine prevents ischemia-induced damage to the inner retina. Animals were treated with saline or brimonidine (1.0 mg/kg i.p., 1 h before ischemia) and allowed to recover for 7 days. A, nonischemic retina from the saline-treated group. B, ischemic retina from saline-treated group. C, nonischemic retina from the brimonidine-treated group. D, ischemic retina from the brimonidine-treated group. GCL, ganglion cell layer; IPL, inner plexiform layer; INL, inner nuclear layer; OPL, outer plexiform layer; ONL, outer nuclear layer; RPE, pigmented epithelium.

To test whether brimonidine also maintains retinal function after an ischemic insult, retinal function was assessed by ERG.The ERG consists of the a-wave, primarily a measure of photoreceptorcell function, and the b-wave, primarily a measure of bipolarcell function (Kline et al., 1978

; Stockton and Slaughter, 1989

).A representative ERG response of a saline-treated ischemic eye,shown in Fig. 2B, indicates the ischemic insult selectively abrogatesthe b-wave response. The a-wave is relatively unchanged, comparedwith the nonischemic fellow eye (Fig. 2A). Both histological andERG measures show that injury is limited to the inner retina,consistent with previous studies of this model (Buchi et al.,1991

). Brimonidine pretreatment prevents the ischemia-inducedloss of the ERG b-wave response (Fig. 2D), which is similar tothe nonischemic fellow eye (Fig. 2C). The protection of the ERGb-wave by brimonidine is dose-responsive (approximately 20% at0.1 mg/kg and 85% at 0.5 mg/kg) and the $alpha$ ₂- agonist clonidineis also effective at protecting the ERG b-wave (Fig. 2E).

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Fig. 2. $alpha$ ₂-Agonists prevent the loss of the ERG b-wave in a dose-responsive manner. Animals were treated with saline or the indicated $alpha$ ₂-agonist 1 h before ischemia. The ERG measurement was taken 7 days after ischemia and represents an average of 10 responses from a single animal. Representative ERG traces of A, nonischemic eye from the saline-treated group; B, ischemic fellow eye from the saline-treated group; C, nonischemic eye from the brimonidine-treated group (1 mg/kg i.p.); D, ischemic eye from the brimonidine-treated group (1 mg/kg i.p.); and E, dose response of ERG b-wave protection by 0.1, 0.5, and 1.0 mg/kg brimondine and 0.5 mg/kg clonidine. All values are the average ± S.E.M. of results from six animals. Statistical significance: *P < 0.05, **P < 0.01, ***P < 0.001.

To test whether brimonidine-mediated protection is $alpha$ ₂-adrenoceptor-dependent, animals were cotreated with the $alpha$ ₂- adrenoceptor-specificantagonist rauwolscine (10 mg/kg i.v.) and brimonidine (1 mg/kgi.p.) 1 h before ischemia. Figure 3 demonstrates that brimonidine-mediatedprotection is blocked by the $alpha$ ₂-antagonist rauwolscine. At highdoses rauwolscine may also block 5-hydroxytryptamine receptors,but the 5-hydroxytryptamine antagonist ketanserin did not inhibitthe brimonidine-protective effect (data not shown). These data,plus the protective effect of the $alpha$ ₂-agonist clonidine, suggestthat the protective effect of brimonidine is mediated by activationof $alpha$ ₂-adrenoceptors.

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Fig. 3. Protective effect of brimonidine is $alpha$ ₂-adrenoceptor-mediated. Animals were treated 1 h before ischemia with saline (n = 4), 1.0 mg/kg brimonidine i.p. (n = 6), 1.0 mg/kg brimonidine i.p. + 10.0 mg/kg rauwolscine i.v. (n = 11), or 10.0 mg/kg rauwolscine i.v. (n = 5) and allowed to recover for 7 days. All values are the average ± S.E.M. Statistical significance: *P < 0.05, **P < 0.01, ***P < 0.001.

To assess the ability of brimonidine to preserve retinal ganglion cell viability, ganglion cell retrograde transport of rhodamine-labeleddextran was assessed 7 days after ischemia. The data, shown inTable 1 as number of labeled retinal ganglion cells per field,demonstrate that brimonidine also prevents the loss of retinalganglion cell retrograde transport induced by ischemia. The protectionis dose-responsive and clonidine is as effective as brimonidine.The histology, ERG analysis, and RGC retrograde transport measuresdemonstrate that activation of $alpha$ ₂-adrenoceptors by $alpha$ ₂- agonistscan prevent the loss of multiple retinal cell types and maintainretinal function after an ischemic insult.

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TABLE 1
$alpha$ ₂-Agonists prevent ischemia-induced loss of RGC retrograde transport
Animals were injected i.p. 1 h prior to ischemia (dose as indicated). Animals recovered for 8 days following ischemia. Retinal ganglion cells were retrograde labeled and counted (n = 5). Values indicate the average number of ganglion cells per microscope field ± S.E.M. determined in eight fields from five animals.

Therapeutic Window of Brimonidine in Retinal Ischemia. To determine the therapeutic window for brimonidine treatment, animals were treated with brimonidine at varying times beforeand during the ischemic insult. Figure 4 demonstrates that animalstreated with brimonidine 12 or 6 h before ischemia were not protectedfrom ischemia-induced damage. In addition, brimonidine treatmentduring ischemia did not rescue the ERG response from ischemicdamage. Animals treated 1 h after or 24 h before ischemia werealso not protected (data not shown). Brimonidine maintains approximately80% of the ERG b-wave if animals are treated with brimonidinewithin 3 h before the start of ischemia. A 30- or 15-min brimonidinetreatment before ischemia is sufficient to protect the retinafrom an ischemic insult. These data demonstrate that the protectivemechanism does not require significant time to be activated andthat, to preserve retinal function, animals must be treated withbrimonidine before the ischemic insult.

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Fig. 4. Brimonidine protects the ERG-b wave by acutely activating $alpha$ ₂- adrenoceptors. A, therapeutic window of brimonidine. Brimonidine-treated animals (

) were dosed 1.0 mg/kg 15 min prior to ischemia (PTI) i.v. (n = 6); 30 min PTI i.p. (n = 5); 60 min PTI i.p. (n = 12); 3 h PTI i.p. (n = 12), 6 h PTI i.p. (n = 15); 12 h PTI i.p. (n = 13); and 40 min into ischemia (n = 8). Saline-treated animals ( $black-square$ ) were dosed for 3, 6, and 12 h (n = 8), or for 1 h, 30 min, and 15 min (n = 6). The gray hatched bar represents the 50-min ischemic period. B, brimonidine must activate the $alpha$ ₂-adrenoceptors immediately before ischemia. Animals were treated as indicated and allowed to recover for 7 days: saline (n = 4), brimonidine 3 h PTI i.p. (n = 5), brimonidine 3 h PTI i.p. + rauwolscine 1 h PTI i.v. (n = 12). All values are the average ± S.E.M. Statistical significance: *P < 0.05, **P < 0.01, ***P < 0.001.

To test whether the brimonidine-protective effect requires activation of the $alpha$ ₂-adrenoceptor immediately before and duringthe onset of ischemia, an agonist pulse-antagonist chase experimentwas performed. Animals were treated with brimonidine (1 mg/kgi.p.) 3 h before the ischemic insult. The animals were subsequentlytreated with rauwolscine (10 mg/kg i.v.) 1 h before ischemia.In this experimental paradigm, brimonidine stimulates the $alpha$ ₂-adrenoceptorsfor 2 h before rauwolscine administration. Once rauwolscine isadministered, brimonidine is blocked from further stimulatingthe $alpha$ ₂-adrenoceptors. The ERG data, shown in Fig. 4B, demonstratethat rauwolscine blocks the brimonidine-protective effect evenif $alpha$ ₂-adrenoceptors have already been stimulated for 2 h. Theprotective mechanism of brimonidine requires $alpha$ ₂-adrenoceptor stimulationimmediately before and during ischemia. The time course, antagonist,and pulse-chase data suggest that brimonidine protects retinalfunction from ischemic damage by an immediate and acute mechanismthat is downstream of $alpha$ ₂-adrenoceptoractivation.

Inhibition of Ischemia-Induced Glutamate and Aspartate Accumulation by $alpha$ ₂-Adrenergic Agonists. Excitotoxicity, driven by high extracellular concentrations of glutamate, is thought to play a significant role in ischemia-inducedneuronal cell death. Multiple studies have shown that after ischemia,there is a large rise in the extracellular concentration of glutamate.In the retinal ischemia model, an increase in extracellular retinalglutamate would result in an increase of glutamate in the vitreoushumor. To determine whether extracellular glutamate concentrationsrise after retinal ischemia, vitreous humor was isolated fromsaline- and brimonidine-treated animals at varying times duringand after ischemia. The samples were analyzed by LC/MS/MS forthe concentrations of glutamate, aspartate, dopamine, and leucine.Figure 5A demonstrates that brimonidine inhibits an ischemia-inducedincrease in the vitreal glutamate concentrations. In the nonischemicgroup, the average vitreal glutamate concentration was approximately30 µM. Glutamate levels rise during ischemia and continue to riseafter ischemia, reaching 60 µM at 30 min after ischemia. In thebrimonidine group, the vitreal glutamate concentration is significantlylower than the saline group after ischemia. These data suggestthat brimonidine inhibits the vitreal accumulation of glutamateduring and after an ischemic insult.

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Fig. 5. Brimonidine inhibits the accumulation of intravitreal glutamate and aspartate. Nonischemic eye ( $black-diamond$ ); brimonidine-treated, ischemic eye (

); saline-treated ischemic eye ( $black-square$ ). A, intravitreal glutamate concentration at varying times during and after ischemia. B, intravitreal aspartate concentrations at varying times during and after ischemia. C, intravitreal dopamine concentrations at varying times during and after ischemia. D, intravitreal leucine concentrations at varying times during and after ischemia. Animals were treated with saline or 1.0 mg/kg brimonidine 1 h before ischemia, i.p. At the specified time during or after ischemia, the animals were sacrificed and vitreous humor was isolated. Each point represents a minimum of five vitreal samples. The same samples were analyzed for glutamate, aspartate, dopamine, and leucine. All values are the average ± S.E.M. Statistical significance: *P < 0.05, **P < 0.01, ***P < 0.001 compared with nonischemic eye. ⁺P < 0.05 compared with saline-treated eye for panel C.

Figure 5B demonstrates that pretreatment with brimonidine also inhibits the ischemia-induced vitreal accumulation of aspartate.In nonischemic eyes, the vitreal aspartate concentration is approximately4 µM. The vitreal concentrations of aspartate in the saline-treatedischemic eyes increase during and after ischemia, reaching a peakof more than 9 µM at 45 min after ischemia. However, aspartatedoes not accumulate in the brimonidine-treated ischemic group.Interestingly, the time courses of ischemia-induced aspartateand glutamate accumulation are remarkably similar and brimonidineinhibits accumulation ofboth.

To determine the specificity of brimonidine-mediated inhibition of glutamate and aspartate accumulation, the vitreal concentrationsof the catecholamine dopamine and the amino acid leucine wereanalyzed. Figure 5C indicates that vitreal dopamine accumulatesrapidly immediately after the onset of the ischemic insult. Thirtyminutes of ischemia induces a large increase in vitreal dopamineconcentrations in the saline- and brimonidine-treated groups,to approximately 12 and 8 µM, respectively, from a nonischemiccontrol dopamine concentration of 1 µM. Brimonidine partiallyinhibits the rise in vitreal dopamine concentrations because thedopamine concentrations are significantly different between thesaline- and brimonidine-treated groups at the 0-, 10-, and 20-mintime points after ischemia. Vitreal dopamine concentrations inboth groups decrease rapidly, and return to baseline levels 1h after ischemia. The vitreal dopamine accumulation time courseis markedly different from the accumulation time course of aspartateand glutamate. Vitreal leucine concentrations do not change duringor after ischemia in either the saline- or brimonidine-treatedgroups. There is no consistently significant difference from thenonischemic eye (Fig. 5D). The lack of accumulation of leucineand markedly different time course of dopamine accumulation suggestthat brimonidine inhibits the vitreal accumulation of aspartateand glutamate during and after an ischemic insult by a specificmechanism.

Figure 6 illustrates that the inhibition of ischemia-induced glutamate accumulation by brimonidine is dose-responsive and $alpha$ ₂-adrenoceptor-dependent. Vitreous humor was isolated 45 minafter the end of ischemia. The accumulation of vitreal glutamatewas inhibited approximately 30% at 0.1 mg/kg and 95% at 0.5 mg/kg.Topical dosing of brimonidine (0.2 or 0.5%) also inhibited glutamateaccumulation in a dose-responsive manner. Clonidine (0.5 mg/kg)also inhibited glutamate accumulation (data not shown). The inhibitionof vitreal glutamate accumulation by brimonidine was significantlyblocked by coadministration of the $alpha$ ₂-antagonist rauwolscine.The inhibition of aspartate accumulation was also dose-responsiveand blocked by rauwolscine cotreatment (data not shown).

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Fig. 6. The inhibition of glutamate accumulation by brimonidine is dose-responsive and $alpha$ ₂-adrenoceptor-dependent. Animals were treated 1 h before ischemia with saline; 0.1, 0.5, or 1.0 mg/kg brimonidine i.p.; 1.0 mg/kg brimonidine i.p. + 10.0 mg/kg rauwolscine i.v.; and 0.2 or 0.5% topical brimonidine. Animals were sacrificed 45 min after the end of ischemia. The animals were sacrificed and vitreous humor was isolated. Each point represents a minimum of five vitreal samples. Statistical significance: **P < 0.01 compared with nonischemic eye.

	Discussion

Top Abstract Introduction Materials and Methods Results Discussion References

Previous studies have suggested that $alpha$ ₂-adrenergic agonists will decrease ischemia-induced damage in the brain (Maier et al.,1993; Berkman et al., 1998). In this study, we demonstrate thatthe $alpha$ ₂-agonist brimonidine will protect retinal structure andfunction from a transient ischemic stress. Figure 1 illustrateshistologically that brimonidine pretreatment prevents the lossof ganglion cell, inner plexiform, and inner nuclear structurallayers. The ERG b-wave analyses, an electrophysiological measureof bipolar cell function, demonstrate that brimonidine also protectsretinal function (Kline et al., 1978; Stockton and Slaughter,1989). Retrograde labeling of RGCs (Table 1) demonstrates thatbrimonidine will also prevent an ischemia-induced loss of RGCs.These data show that brimonidine treatment prevents the ischemia-inducedinjury to multiple cell types in the inner retina. Dose-responsestudies and experiments with the $alpha$ ₂-agonist clonidine and the $alpha$ ₂-antagonist rauwolscine demonstrate that brimonidine-mediatedprotection is $alpha$ ₂-adrenoceptor-dependent.

A number of neuroprotective molecular mechanisms have been proposed for the $alpha$ ₂-adrenergic receptors, including the inhibitionof glutamate release (Talke and Bickler, 1996), transcriptionalup-regulation of basic fibroblast growth factor (Wen et al., 1996),or activation of an antiapoptotic signaling cascade (p44/p42 extracellularsignal-regulated kinases) (Peng et al., 1998). To elucidate theneuroprotective mechanism of brimonidine in the retinal ischemiamodel, the therapeutic window of brimonidine was defined. Thebeneficial therapeutic window of brimonidine is small and tightlycorrelates with the approximately 3-h systemic half-life of brimonidine(data not shown). For instance, a single dose 6 or 12 h beforeischemia, which would result in very low levels of plasma brimonidineat the time of ischemia, was not protective. However, a singlebrimonidine dose 15 min before ischemia is efficacious. Thesedata demonstrate that, to prevent the ischemia-induced damage,brimonidine must be present immediately before or during ischemia.The agonist pulse-antagonist chase data (Fig. 4B) also suggestthat, to be protective, the $alpha$ ₂-adrenoceptors must be stimulatedimmediately before and during ischemia. The time course and pulse-chasedata are inconsistent with a protective mechanism that requiresthe activation of gene transcription ortranslation.

Glutamatergic excitotoxicity, driven by high extracellular concentrations of glutamate, is thought to play a significant rolein ischemia-induced neuronal cell death (Choi and Rothman, 1990;Meldrum and Garthwaite, 1990). Figure 5, A and B, demonstratesthat, after ischemia, there was a significant accumulation ofaspartate and glutamate within the vitreous humor of the saline-treatedanimals. Previous reports of rat and rabbit retinal ischemia modelshave reported similar increases of glutamate (Louzada-Junior etal., 1992). Pretreatment with brimonidine completely preventedthe ischemia-induced vitreal accumulation of glutamate and aspartate.The inhibition of glutamate accumulation by brimonidine was dose-responsiveand blocked by rauwolscine, suggesting that inhibition of glutamateaccumulation is also $alpha$ ₂-adrenoceptor-dependent. The time courseof dopamine accumulation was markedly different from glutamateand aspartate, and brimonidine only partially inhibited the accumulationof dopamine. Previous reports have shown that $alpha$ ₂-adrenoceptoragonists can decrease the presynaptic release of dopamine. Thepartial inhibition of dopamine accumulation can be explained ifonly a subset of the retinal dopaminergic cells express $alpha$ ₂-adrenoceptors.The brimonidine-mediated inhibition of glutamate and aspartateaccumulation is specific because vitreal leucine concentrationswere not altered by ischemia and the ischemia-induced dopamineaccumulation was not greatly inhibited by brimonidine. Therefore,the brimonidine-mediated inhibition of glutamate and aspartateis not likely to be a secondary effect of preventing cells fromdying and subsequently disgorging their intracellular contents.Taken together, these data argue that activation of $alpha$ ₂-adrenoceptorswill prevent an ischemia-induced accumulation of glutamate andaspartate by a specificmechanism.

Several pieces of evidence suggest that the inhibition of glutamate accumulation is the main mechanism by which brimonidineprevents ischemia-induced damage. First, the dose-response andantagonist profiles are remarkably similar for the protectionof the ERG b-wave, the protection of retinal ganglion cells, andthe inhibition of glutamate accumulation. Second, the data demonstratethat glutamate and aspartate begin to accumulate by the end ofthe ischemic period. These data are consistent with the therapeuticwindow of brimonidine; if brimonidine is not present in the retinaimmediately before ischemia, and therefore before glutamate andaspartate accumulation, brimonidine cannot prevent the ischemia-induceddamage.

If mechanisms other than the accumulation of glutamate and aspartate are involved in neuroprotection by brimonidine duringtransient ischemia, brimonidine should protect in the presenceof acute elevations of glutamate. Previous studies have demonstratedthat the inner retina is sensitive to glutamate and the glutamateanalog kainate. An intravitreal injection of kainate producesischemia-like damage, including loss of the inner retina and ERGb-wave. A high extracellular concentration of kainate kills neuronsby an excitotoxic mechanism, including Ca²⁺ overload and death. Brimonidine does not prevent the loss ofthe b-wave caused by an intravitreal injection of kainate (J.E. Donello and E. U. Padillo, unpublished data). These data supportthe hypothesis that brimonidine protects the retina by inhibitingglutamate and aspartate accumulation and inhibiting subsequentexcitotoxicity. However, $alpha$ ₂-agonists may protect neurons by mechanismsother than the inhibition of glutamate accumulation in slowerretinal degeneration models, such as the partial optic nervecrush.

The molecular mechanism by which $alpha$ ₂-agonists inhibit ischemia-induced accumulation of aspartate and glutamate is not clear.Previous studies have demonstrated that activation of $alpha$ ₂-adrenoceptorswill result in the activation of inward rectifying G-protein-coupledK⁺ channels and block voltage-gated Ca²⁺ channels (Aghajanian and VanderMaelen, 1982; Williams et al.,1985). Hence, activated $alpha$ ₂-adrenoceptors will hyperpolarize neuronsand inhibit the presynaptic release of glutamate, aspartate, andnorepinephrine (Kamisaki et al., 1992) Brimonidine might inhibitglutamate accumulation by decreasing the amount of presynapticglutamate released duringischemia.

Alternatively, brimonidine might prevent glutamate accumulation by maintaining the glutamate-buffering activity of Mullercells. Muller cells are retinal glial cells and are critical formaintaining low levels of extracellular glutamate, via the electrogenicNa⁺-dependent glutamate/aspartate transporter GLAST (Harada et al.,1998; Pow et al., 2000). Glutamate/aspartate transporters requirea negative membrane potential to transport extracellular glutamateand aspartate into the cell. It has been proposed that, duringischemia, the electrogenic glutamate/aspartate transporter willreverse and begin to pump intracellular glutamate into the extracellularspace (Rossi et al., 2000). The similarity between the glutamateand aspartate time course and accumulation levels suggest thatactivation of $alpha$ ₂-adrenoceptors may prevent glutamate and aspartateaccumulation by maintaining activity of the glutamate/aspartatetransporters. Future studies of isolated Muller cells will beable to address whether $alpha$ ₂-adrenoceptors might regulate the glutamate/aspartatetransporters.

Glaucoma is a leading cause of blindness worldwide. As a disease, glaucoma remains relatively uncharacterized and the causativefactors are not understood. Glaucomatous patients are phenotypicallycharacterized by a gradual loss of visual field, due to the degenerationof the optic nerve, and often display abnormally high intraocularpressure. Although the causative agent of visual field loss iscontroversial, one hypothesis states that stresses such as abnormallyhigh intraocular pressure may directly result in an ongoing insultto which retinal ganglion cells are especially sensitive. Dreyeret al. (1996) have demonstrated that intravitreal glutamate concentrationsare elevated 2-fold in glaucoma patients undergoing cataract surgery.Animal models of glaucoma also exhibit elevated levels of intravitrealglutamate (Dreyer et al., 1996; Brooks et al., 1997). It has beensubsequently shown that a chronic exposure of retinal ganglioncells to a low dose of glutamate is toxic to RGCs (Vorwerk etal., 1996). The "excitotoxicity glaucoma hypothesis" would suggestthat preventing excess intravitreal glutamate levels or blockingthe glutamate ionotropic receptors would prevent glaucomatousvision loss (Sucher et al., 1997). Indeed, there has been mucheffort in identifying new classes of compounds that can protectretinal cells from excitotoxicinjury.

Brimonidine is a therapeutic agent currently used to lower high intraocular pressure in glaucomatous patients (Burke and Schwartz,1996). This study demonstrates that brimonidine exhibits additionalproperties, beyond its pressure-lowering activity, that are potentiallybeneficial for glaucomapatients.

	Acknowledgments

We are indebted to Dr. Ron Lai for sharing the observation that brimonidine inhibits ischemic-induced retinal damage. We alsothank Theresa Chun and Dain Hasson for demonstrating the ischemiaand ERG methods. We are indebted to Dahai Dong, Dr. John Ling,and Dr. Andrew Acheampong for their expertise in LC/MS/MS. Weare also grateful to Dr. Elizabeth WoldeMussie and Lupe Ruiz forsharing their histology expertise and demonstrating the RGC labelingmethod. Drs. William Hare, Ron Lai, Elizabeth WoldeMussie, JamesDong, and Joe Adorante have been invaluable for their criticalscientific comments and helpful discussions. We also thank LindaJohnson for assistance with the manuscriptfigures.

	Footnotes

Accepted for publication September 8, 2000.

Received for publication June 30, 2000.

Send reprint requests to: John E. Donello, Ph.D., Department of Biological Sciences, Allergan, Inc., 2525 Dupont Dr., Irvine, CA 92612. E-mail: Donello_john{at}allergan.com

	Abbreviations

ERG, electroretinogram/electroretinography; RGC, retinal ganglion cell; LC/MS/MS, liquid chromatography/mass spectrometry/mass spectrometry; PTI, prior to ischemia.

	References

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				M. Saylor, L. K. McLoon, A. R. Harrison, and M. S. Lee Experimental and Clinical Evidence for Brimonidine as an Optic Nerve and Retinal Neuroprotective Agent: An Evidence-Based Review Arch Ophthalmol, April 1, 2009; 127(4): 402 - 406. [Abstract] [Full Text] [PDF]

				C.-J. Dong, Y. Guo, P. Agey, L. Wheeler, and W. A. Hare {alpha}2 Adrenergic Modulation of NMDA Receptor Function as a Major Mechanism of RGC Protection in Experimental Glaucoma and Retinal Excitotoxicity Invest. Ophthalmol. Vis. Sci., October 1, 2008; 49(10): 4515 - 4522. [Abstract] [Full Text] [PDF]

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				R. H. Rosa Jr., T. W. Hein, Z. Yuan, W. Xu, M. I. Pechal, R. L. Geraets, J. M. Newman, and L. Kuo Brimonidine evokes heterogeneous vasomotor response of retinal arterioles: diminished nitric oxide-mediated vasodilation when size goes small Am J Physiol Heart Circ Physiol, July 1, 2006; 291(1): H231 - H238. [Abstract] [Full Text] [PDF]

				S. Mayor-Torroglosa, P. De la Villa, M. E. Rodriguez, M. P. L. Lopez-Herrera, M. Aviles-Trigueros, A. Garcia-Aviles, J. Miralles de Imperial, M. P. Villegas-Perez, and M. Vidal-Sanz Ischemia Results 3 Months Later in Altered ERG, Degeneration of Inner Layers, and Deafferented Tectum: Neuroprotection with Brimonidine Invest. Ophthalmol. Vis. Sci., October 1, 2005; 46(10): 3825 - 3835. [Abstract] [Full Text] [PDF]

				F B Kalapesi, M T Coroneo, and M A Hill Human ganglion cells express the alpha-2 adrenergic receptor: relevance to neuroprotection Br. J. Ophthalmol., June 1, 2005; 89(6): 758 - 763. [Abstract] [Full Text] [PDF]

				T. Da and A. S. Verkman Aquaporin-4 Gene Disruption in Mice Protects against Impaired Retinal Function and Cell Death after Ischemia Invest. Ophthalmol. Vis. Sci., December 1, 2004; 45(12): 4477 - 4483. [Abstract] [Full Text] [PDF]

				D W Evans, S L Hosking, D Gherghel, and J D Bartlett Contrast sensitivity improves after brimonidine therapy in primary open angle glaucoma: a case for neuroprotection Br. J. Ophthalmol., December 1, 2003; 87(12): 1463 - 1465. [Abstract] [Full Text] [PDF]

				S. D. Grozdanic, D. S. Sakaguchi, Y. H. Kwon, R. H. Kardon, and I. M. Sonea Functional Characterization of Retina and Optic Nerve after Acute Ocular Ischemia in Rats Invest. Ophthalmol. Vis. Sci., June 1, 2003; 44(6): 2597 - 2605. [Abstract] [Full Text] [PDF]

				D. C. Baptiste, A. T. E. Hartwick, C. A. B. Jollimore, W. H. Baldridge, B. C. Chauhan, F. Tremblay, and M. E. M. Kelly Comparison of the Neuroprotective Effects of Adrenoceptor Drugs in Retinal Cell Culture and Intact Retina Invest. Ophthalmol. Vis. Sci., August 1, 2002; 43(8): 2666 - 2676. [Abstract] [Full Text] [PDF]

				A. A. Acheampong, M. Shackleton, B. John, J. Burke, L. Wheeler, and D. Tang-Liu Distribution of Brimonidine into Anterior and Posterior Tissues of Monkey, Rabbit, and Rat Eyes Drug Metab. Dispos., April 1, 2002; 30(4): 421 - 429. [Abstract] [Full Text] [PDF]

				E. WoldeMussie, G. Ruiz, M. Wijono, and L. A. Wheeler Neuroprotection of Retinal Ganglion Cells by Brimonidine in Rats with Laser-Induced Chronic Ocular Hypertension Invest. Ophthalmol. Vis. Sci., November 1, 2001; 42(12): 2849 - 2855. [Abstract] [Full Text] [PDF]

				M. P. Lafuente, M. P. Villegas-Perez, P. Sobrado-Calvo, A. Garcia-Aviles, J. Miralles de Imperial, and M. Vidal-Sanz Neuroprotective Effects of {alpha}2-Selective Adrenergic Agonists against Ischemia-Induced Retinal Ganglion Cell Death Invest. Ophthalmol. Vis. Sci., August 1, 2001; 42(9): 2074 - 2084. [Abstract] [Full Text] [PDF]