Characterization of Alpha-2D Adrenergic Receptor Subtypes in Bovine Ocular Tissue Homogenates

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Vol. 281, Issue 3, 1171-1177, 1997

Characterization of Alpha-2D Adrenergic Receptor Subtypes in Bovine Ocular Tissue Homogenates

David B. Bylund, Laurie J. Iversen, William J. Matulka and David M. Chacko

Departments of Pharmacology (D.B.B., L.J.I., W.J.M.) and Ophthalmology (D.M.C.), University of Nebraska Medical Center, Omaha, Nebraska

	Abstract

Top Abstract Introduction Materials & Methods Results Discussion References

The alpha-2 adrenergic receptors are known to be present in the mammalian eye and to mediate the effects of alpha-2 agonistsused in the treatment of glaucoma. Little is known, however, regardingthe relative densities of the three alpha-2 subtypes in the varioustissues of the eye. We used receptor binding experiments withthe radioligand [³H]RX821002 to characterize the alpha-2 adrenergic receptors inthree tissues of the bovine eye, the ciliary body, retinal pigmentepithelium/choriocapillaris and iris. The K_D values inthe three tissues were similar (0.12-0.14 nM), and the B_max valuesranged from 100 fmol/mg of protein for the ciliary body and retinalpigment epithelium/choriocapillaris to 200 fmol/mg of proteinfor the iris. The pharmacological characteristics of the alpha-2receptors in all three tissues of the bovine eye, as assessedby competition studies, were essentially identical and were similarto the characteristics of the alpha-2A/D receptors of the bovineneurosensory retina. The correlation coefficients between thelogarithms of the K_i values for the three tissues andthe neurosensory retina for nine adrenergic agents were .98 to.99. We conclude that the alpha-2 adrenergic receptors in theciliary body, iris and retinal pigment epithelium/choriocapillarisof the bovine eye are mainly alpha-2D.

	Introduction

Top Abstract Introduction Materials & Methods Results Discussion References

Three major types or subfamilies of adrenergic receptors have been identified: alpha-1, alpha-2 and beta. Within each of thesethree main types of adrenergic receptors, three or more subtypeshave been defined (Bylund, 1988, 1992). Based on pharmacologicalcharacteristics and molecular cloning, the alpha-2 adrenergicreceptor subfamily currently includes three genetic and four pharmacologicalsubtypes: alpha-2A, alpha-2B, alpha-2C and alpha-2D (Bylund etal., 1994). The alpha-2A adrenergic receptor subtype, for whichprazosin and ARC-239 have relatively low affinity, is found inthe human platelet and the HT29 cell (Bylund et al., 1988). Thegene for this receptor has been cloned from the human (Kobilkaet al., 1987), and orthologous clones have been found in the pig(Guyer et al., 1990), rat (Lanier et al., 1991), mouse (Link etal., 1992) and guinea pig (Svensson et al., 1996). The secondsubtype, alpha-2B, which has been identified in neonatal rat lungand the NG108 cell line (Bylund et al., 1988), has been clonedfrom the rat (Zeng et al., 1990), human (Lomasney et al., 1990;Weinshank et al., 1990), mouse (Chruscinski et al., 1992) andguinea pig (Svensson et al., 1996) and has a relatively high affinityfor prazosin and ARC-239. A third subtype, alpha-2C, has beenidentified in an opossum kidney cell line (Murphy and Bylund,1988), and its cDNA has been identified by molecular cloning (Blaxallet al., 1994). Species orthologs have been cloned from the human(Regan et al., 1988), rat (Lanier et al., 1991), mouse (Link etal., 1992) and guinea pig (Svensson et al., 1996). Although thealpha-2C subtype also has relatively high affinity for prazosinand ARC-239, its overall pharmacological profile is clearly differentfrom that of alpha-2B. A fourth pharmacological subtype, alpha-2D,has been identified in the rat salivary gland (Michel et al.,1989) and bovine pineal (Simonneaux et al., 1991). This pharmacologicalsubtype has been cloned from the rat (Lanier et al., 1991) andmouse (Link et al., 1992). On the basis of predicted amino acidsequence, the alpha-2D appears to be a species ortholog of thehuman alpha-2A. Thus, only three subtypes occur in any given species:alpha-2A/D, alpha-2B and alpha-2C.

The actions of norepinephrine, an important neuroregulator that controls many physiological functions in the eye, are mediatedby adrenergic receptors. Numerous agents have been developed thatinteract with adrenergic receptors, many of which are used fordiagnostic and therapeutic purposes in ophthalmology. Glaucomais characterized by a progressive loss of visual sensitivity resultingfrom optic nerve damage. Because high intraocular pressure isthe most important risk factor for glaucoma, the treatment ofglaucoma has emphasized the reduction of intraocular pressure.Adrenergic drugs are effective ocular hypotensive agents. Currently,beta adrenergic antagonists are the most commonly used drugs forthe medical treatment of glaucoma (Quigley, 1993). The alpha-2adrenergic agonists are also used for reducing intraocular pressure(Chacko and Camras, 1994), although their mechanism of actionis not clear (Serle, 1994; Toris et al., 1995a, 1995b). The developmentof subtype-selective alpha-2 adrenergic agents for topical applicationis considered desirable to reduce both systemic and ocular sideeffects. An understanding of the distribution of alpha-2 receptorsubtypes in the eye would be useful in designing new drugs withgreater effectiveness and fewer adverse effects.

The alpha-2 adrenergic receptors have been identified in some ocular tissues, including the rabbit iris-ciliary body (Jinet al., 1994; Mittag and Tormay, 1985) and the bovine retina (Bittigeret al., 1980; Convents et al., 1987; Osborne, 1982; Van Liefdeet al., 1993) by radioligand binding studies and the rabbit retinaby using the inhibition of cyclic AMP production as the assay(Osborne, 1991). Autoradiographic studies have indicated the presenceof alpha-2 receptors in rat, rabbit and human eye (Elena et al.,1989; Matsuo and Cynader, 1992; Zarbin et al., 1986). This workhas clearly established the presence of alpha-2 receptors in oculartissues. However, little work has been done on the more importantissue of the identification and localization of the three alpha-2receptor subtypes in ocular tissues from various species. Antibodiesselective for the subtypes have been used in an attempt to localizethe subtypes in the ciliary body of the human and rabbit eye (Huanget al., 1995). These studies found evidence for all three subtypesin the rabbit ciliary body but for only alpha-2B and alpha-2Cin the human ciliary body (Huang et al., 1995). Previous workfrom our laboratory using the radioligand binding assay has establishedthat the bovine neurosensory retina contains alpha-2A/D but notalpha-2B or alpha-2C adrenergic receptors (Berlie et al., 1995).The presence of the alpha-2D subtype in the bovine has been recentlyconfirmed by molecular techniques (Venkataraman et al., 1996).We present an evaluation of the characteristics of the alpha-2adrenergic receptor subtypes in three additional tissues of thebovine eye: the ciliary body, RPE/choriocapillaris and iris. Onthe basis of receptor binding experiments using the alpha-2 antagonistradioligand [³H]RX821002, we conclude that the alpha-2 adrenergic receptorsin these tissues of the bovine eye are mainly alpha-2D.

	Materials and Methods

Top Abstract Introduction Materials & Methods Results Discussion References

Drugs and chemicals. [³H]RX821002 (specific activity, 55 Ci/mmol) was obtained from Amersham International (London, UK). Rauwolscine, WB 4101 andspiroxatrine were purchased from Research Biochemicals, Inc. (Natick,MA). Oxymetazoline was obtained from Sigma Chemical Co. (St. Louis,MO). The following were gifts: prazosin from Pfizer, Inc. (Groton,CT), ARC-239 from Boehringer-Ingelheim (Ridgefield, CT) and phentolaminefrom Ciba-Geigy Corp. (Suffern, NY). Prazosin was prepared inmethanol, spiroxatrine was prepared in 80% dimethylsulfoxide/20%1 M HCl, SK&F 104078 was prepared in 50% ethanol and all otherdrugs were prepared in 5 mM HCl. Drugs were prepared as 5 or 10mM stock solutions and diluted in 5 mM HCl.

Tissue preparation. Bovine eyes (Pel-Freez Biologicals, Rogers, AR) were thawed and cut coronally 7 to 8 mm posterior to the limbus while bathedin 50 mM Tris buffer at 4°C. The vitreous and lens were discarded,and the iris was separated from its attachment on the ciliarybody. The remnants of neurosensory retina, RPE/choriocapillaris,were trimmed from the anterior portion of the bisected globe,and the ciliary body was dislodged from the scleral spur. TheRPE/choriocapillaris were detached from the posterior pole afterthe neurosensory retina was removed. The various tissues weresuspended in 25 ml of ice-cold 50 mM Tris·HCl, pH 8, and homogenizedwith a Polytron (model PT 10-35; Brinkman, Westbury, NY). Thehomogenate was filtered through a 53-µm nylon mesh and centrifugedat 1,400 rpm for 10 min. The supernatant was transferred to anothertube, recentrifuged at 20,000 rpm for 10 min and frozen at $-$ 80°C.

Radioligand binding assays. Saturation and competition binding experiments were performed as described previously using 25 mM sodium phosphate bufferat pH 7.4 (Berlie et al., 1995; Bylund et al., 1988; Deupree etal., 1996). Briefly, saturation experiments were performed usingtwo sets of duplicate tubes that contained 970 µl of membranesuspension and 20 µl of [³H]RX821002 (final concentration, 0.24 ± 0.04 nM). The proteinconcentration was adjusted to ensure that the specifically boundradioligand was <10% of the total added radioligand. One set contained10 µl of 100 µM ( $-$ )-norepinephrine to determine nonspecific binding.Specific binding was calculated as the difference between totaland nonspecific binding. After a 30-min incubation at room temperature,the suspensions were filtered through GF/B glass-fiber filterstrips (Whatman, Clifton, NJ) that had been soaked overnight in0.2% polyethylenimine, using a 48-sample manifold (Brandel CellHarvester, Biomedical Research and Development, Gaithersburg,MD). The tubes and filters were washed twice with 5 ml of ice-cold50 mM Tris·HCl, pH 8.0, and the radioactivity on the filter wasdetermined by liquid scintillation spectroscopy. The K_D and B_maxvalues were calculated from nonlinear regression of bound vs.free ligand concentrations. K_D values are geometric mean values,and B_max values are arithmetic mean values. Protein concentrationswere determined according to the method of Bradford (1976) withbovine serum albumin used as the standard.

For inhibition experiments, 20 µl of a fixed concentration of radioligand [³H]RX821002 (~0.2 nM, which is close to the K_D concentration) andvarious concentrations of unlabeled drug (10 µl) were added toduplicate tubes containing 970 µl of the membrane suspension.Assays were then performed as described above for saturation experiments.Competition binding data were analyzed with the Prism program(GraphPAD, San Diego, CA) to determine IC₅₀ values assuming aone-site model, and the pseudo-Hill slope was determined fromfitting the data to the four-parameter logistic equation. IC₅₀values were converted to K_i values according to the method ofCheng and Prusoff (1973)

and are presented as geometric mean values.

	Results

Top Abstract Introduction Materials & Methods Results Discussion References

The alpha-2 adrenergic receptors in the ciliary body, iris and RPE/choriocapillaris of the bovine eye were characterized bysaturation binding using [³H]RX821002 as the radioligand (Berlie et al., 1995; Galitzky etal., 1990; O'Rourke et al., 1994b). [³H]RX821002 has similar and high affinities for all four pharmacologicalsubtypes of the alpha-2 adrenergic receptor (O'Rourke et al.,1994a, 1994b; Renouard et al., 1994). As shown in figure 1, bindingis saturable and of high affinity (K_D ~ 0.1 nM) in all three tissues.The nonspecific binding is relatively low (20-30% at the K_D concentrations).When the data are transformed according to the Rosenthal procedure(Rosenthal, 1967), they fall on a straight line, indicating thata single class of binding sites is being labeled. The iris hadthe highest receptor density (B_max = 200 fmol/mg of protein) ofthe three tissues, about double that of the ciliary body and RPE/choriocapillaris.The mean K_D and B_max values for four saturation experiments aregiven in table 1. The B_max values for these three bovine eyetissues are 5- to 10-fold lower than that found in the bovineneurosensory retina (Berlie et al., 1995).

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Fig. 1. Saturation of [³H]RX821002 binding in the bovine eye tissues. A, Various concentrations of [³H]RX821002 (total [³H]RX821002) were incubated with membranes prepared from the iris( $black-triangle$ , $triangle$ ), ciliary body ( $black-square$ , $square$ ) or RPE/choriocapillaris ( $bullet$ , $open circle$ ). Thetotal binding (closed symbols) and the nonspecific binding (opensymbols) as determined with the use of 10⁴ M norepinephrine are shown. B, Specific binding as calculatedas the difference between total and nonspecific binding. C, LinearRosenthal transformation (Rosenthal, 1967

) of the specific bindingdata plotted as bound [³H]RX821002 divided by free [³H]RX821002 vs. bound [³H]RX821002 converted to units of pM. For this experiment, theK_D values as calculated by nonlinear regression analysiswere 0.09, 0.10 and 0.09 nM and the B_max values were 163, 91 and75 fmol/mg of protein for the iris, ciliary body and RPE/choriocapillaris,respectively. The mean values for four experiments are given intable 1.

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TABLE 1
Affinity (K_D) and density (B_max) of [³H]RX821002 binding to alpha-2 adrenergic receptors in bovine eye tissues

The pharmacological characteristics of the alpha-2 adrenergic receptors in the ciliary body, iris and RPE/choriocapillarisof the bovine eye were assessed by competition radioligand bindingstudies. Representative curves of the inhibition of [³H]RX821002 binding in membrane preparations by rauwolscine, ARC-239and norepinephrine are shown in figure 2. Table 2 gives the meanK_i values with pseudo-Hill slopes for eight adrenergic antagonistsand for norepinephrine. These are a subset of the antagoniststhat we used previously to characterize the alpha-2A, alpha-2B,alpha-2C and alpha-2D adrenergic receptor subtypes in a varietyof tissues (Bylund et al., 1988, 1992; O'Rourke et al., 1994a,1994b). For purposes of comparison, table 2 includes data forthe neurosensory retina, which we have previously shown to containexclusively the alpha-2D subtype (Berlie et al., 1995), as wellas the data for ciliary body, iris and RPE/choriocapillaris. Fornone of the eight antagonists in the three tissues were the pseudo-Hillslopes significantly <1.0, which is consistent with the conclusionthat only a single subtype of alpha-2 adrenergic receptor is presentin these bovine eye tissues. Prazosin and ARC-239 are alpha-1-selectiveantagonists that also differentiate alpha-2A/D from alpha-2B andalpha-2C subtypes. The low affinity of prazosin (2- 3 µM) andARC-239 (0.5 µM) indicates that the predominate subtype is thealpha-2A/D rather than the alpha-2B or alpha-2C (table 3). Therelatively high affinity of the receptors in the bovine eye tissuesfor oxymetazoline (20 nM) also eliminates the alpha-2B subtype.Similarly, the affinity of spiroxatrine is consistent with alpha-2A/Drather than the alpha-2B or alpha-2C subtypes. The affinity ofrauwolscine (10 nM) is consistent with the alpha-2D rather thanthe alpha-2A subtype, as would be expected for bovine tissues.Overall, the affinities of the drugs for the alpha-2 receptorsin the bovine ciliary body, iris and RPE/choriocapillaris aresimilar to their affinities in the bovine neurosensory retinaand bovine pineal gland but clearly different from the human alpha-2A,alpha-2B and alpha-2C subtypes, as determined previously usingthe human clones transfected into COS cells (table 3).

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Fig. 2. Inhibition of [³H]RX821002 binding by alpha-2 adrenergic antagonists. Various concentrations of rauwolscine (A), ARC-239 (B)or norepinephrine (C), as indicated on the abscissa, were incubatedwith ~0.3 nM [³H]RX821002 and with membranes prepared from the iris ( $black-triangle$ ), ciliarybody ( $black-square$ ) or RPE/choriocapillaris ( $bullet$ ). The total binding is plottedon the ordinate. The binding in the absence of any inhibitingcompound is indicated by data points on the left (at an inhibitorconcentration of $-$ 11). Norepinephrine at 10⁴ M was included in all experiments to determine nonspecific bindingand is included in the curves as the $-$ 4 data points. Values aremean ± S.E.M. of duplicate determinations from single experiments.Mean K_i values for three or four experiments are givenin table 2.

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TABLE 2
Affinity (K_i) of adrenergic agents in inhibiting [³H]RX821002 binding to alpha-2 adrenergic receptors in bovine eyetissues

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TABLE 3
Comparison of affinities (K_i) of drugs for alpha-2 adrenergic receptor subtype in various tissues

Rather than comparing affinities for two tissues or receptor subtypes according to one drug at a time, it is often helpfulto consider all the drugs in a single comparison by correlatingthe negative logarithms of K_i values (pK_i values). Figure 3 presentsthe correlation of the pK_i values for the four bovine eye tissueswith our published data for the alpha-2D receptor of the bovinepineal gland. The correlation between each of the four eye tissuesand the bovine pineal is excellent (correlation coefficients,r = .97-1.00), indicating that the pharmacological characteristicsof the alpha-2 receptors in these bovine tissues are identical.These results indicate that in the bovine ciliary body, iris andRPE/choriocapillaris as well as in the neurosensory retina (Berlieet al., 1995), the predominate alpha-2 adrenergic receptor subtypeis alpha-2D.

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Fig. 3. Correlation of antagonist affinities for alpha-2 adrenergic receptors in four tissues of the bovine eye with their affinitiesin the bovine pineal gland. The affinities (pK_i values)are derived from table 3. The lines are the least-squares correlationlines, and r is the correlation coefficient. The slopes of thecorrelation lines are 1.11, 1.19, 1.14 and 1.11 for the ciliarybody, iris, RPE/choriocapillaris and neurosensory retina, respectively.

We also used correlation analyses to compare the pK_i values in bovine eye tissues with our published data for the human alpha-2A,alpha-2B and alpha-2C clones, as well as the rat alpha-2D clone(table 4). For the alpha-2B and alpha-2C subtypes of the alpha-2adrenergic receptor, the correlation coefficients are poor (r= .31-.45), indicating that the characteristics of these receptorsare significantly different from the four bovine ocular tissuesused in this study. In contrast, the rat alpha-2D pK_i values aresimilar to the bovine eye tissues (r = .96-.97), supporting theconclusion that these ocular tissues are alpha-2D . The correlationcoefficients for the human alpha-2A and bovine ocular tissues(.86-.89) are much higher than those found with the human alpha-2Band alpha-2C subtypes (.31-.45) but somewhat lower than thosewith the rat alpha-2D clone (.97-1.00). This is as expected becausethe alpha-2A and alpha-2D are orthologous subtypes and have similarcorrelation coefficients, as have been documented in previousstudies (O'Rourke et al., 1994b).

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TABLE 4
Correlation of pK_i values for the bovine eye tissues with those of the alpha-2A, alpha-2B, alpha-2C and alpha-2Dsubtypes

	Discussion

Top Abstract Introduction Materials & Methods Results Discussion References

The mechanisms through which alpha-2 adrenergic agents lower intraocular pressure are not well understood. Three presumedsites of action for these agonists are the ciliary nonpigmentedepithelium (reduction of aqueous humor production), ciliary muscle(increase in uveoscleral outflow facility) and trabecular meshwork(increase in trabecular outflow). Recent evidence suggests thatalpha-2 agonists may have differential effects at these sitesof action. In animal studies, although both apraclonidine andbrimonidine have been found to reduce intraocular pressure inpart by reducing aqueous flow, brimonidine increases uveoscleraloutflow facility, whereas apraclonidine does not (Serle et al.,1991a, 1991b). Similar conclusions have recently been reachedfor human eyes. Both alpha-2 agonists appear to lower intraocularpressure in part by decreasing aqueous humor production, presumablyby acting on the nonpigmented epithelium of the ciliary body.However, brimonidine (Toris et al., 1995a) and oxymetazoline (Wanget al., 1993) appear to increase uveoscleral outflow, whereasapraclonidine increases outflow through the trabecular meshwork(Toris et al., 1995b). To understand the mechanisms of these agentsand the differences among them, an understanding of the distributionof the subtype in various eye tissues is needed.

Several techniques have been used to localize alpha-2 adrenergic receptors in the eye. Initial radioligand binding studiesindicated that the majority of the alpha adrenergic receptorsin the rabbit iris-ciliary body were of the alpha-2 type (Mittagand Tormay, 1985). The alpha-2 adrenergic receptors were alsodemonstrated to exist in the bovine retina (Bittiger et al., 1980;Van Liefde et al., 1993). An autoradiographic study of alpha-2adrenergic receptor localization found that alpha-2 adrenergicreceptors were most dense in the inner plexiform layer in ratsand might be found in the inner nuclear and ganglion cell layer(Zarbin et al., 1986). A similar study found that alpha-2 adrenergicreceptors were localized to ocular muscles, ciliary processesand retina in rat and rabbit eye (Elena et al., 1989). Autoradiographicstudies in the human eye found alpha-2 adrenergic receptors athigh levels in the iris epithelium and ciliary epithelium, aswell in the ciliary muscle, retina and retinal pigment epithelium(Matsuo and Cynader, 1992).

More recent efforts have been directed at identifying which alpha-2 adrenergic receptor subtypes are present in the eye. Ofthe four pharmacological alpha-2 subtypes, only three appear tobe present in a given species. The alpha-2A adrenergic receptoris present in humans, rabbits and pigs, whereas alpha-2D subtypeis present in the bovine, rat, mouse and guinea pig. Because thealpha-2A and -2D pharmacological subtypes are species orthologsand thus mutually exclusive in the same species, they are sometimesreferred to as the alpha-2A/D subtype. The affinities of drugsinhibiting the binding of both the agonist [¹²⁵I]-p-iodoclonidine and the antagonist [³H]rauwolscine are consistent with the conclusion that the majorityof the alpha-2 receptors in the rabbit iris-ciliary body are ofthe alpha-2A subtype (Jin et al., 1994). Immunofluorescence microscopywith antibodies to each of the three human alpha-2 subtypes indicatesthe presence of not only the alpha-2A subtype but also the alpha-2Band alpha-2C subtypes in rabbit ciliary body (Huang et al., 1995).In the bovine retina, radioligand binding studies with [³H]RX821002 and [³H]rauwolscine have demonstrated the presence of the alpha-2A/Dreceptor and excluded the presence of even a minor populationof the alpha-2B and alpha-2C subtypes (Berlie et al., 1995). Thepresence of the alpha-2D subtype in the bovine retina has beenrecently confirmed by molecular techniques (Venkataraman et al.,1996)

Our data indicate that the alpha-2A/D is the main, if not the only, subtype present in the bovine ciliary body, iris, RPE/choriocapillarisand retina. This conclusion is based on a comparison of K_i valuesin the ocular tissues with previous data from our laboratory.Some of these earlier experiments were performed with glycylglycinebuffer, whereas the current data were obtained using a phosphatebuffer. In a recent study, we documented that buffer compositioncan affect the affinity of antagonists as determined in radioligandbinding experiments (Deupree et al., 1996). We demonstrate, however,that the affinity of all antagonists is affected in a consistentfashion, and thus correlation analysis of pK_i values remains avalid approach for identifying alpha-2 receptor subtypes. Ourconclusion that the alpha-2A/D is the major subtype in bovineocular tissues is consistent with radioligand binding studiesin the rabbit and pig, which also identify the alpha-2A subtypeas the main subtype (Jin et al., 1994; Wikberg-Matsson et al.,1996). In the human ciliary body, immunofluorescence labelingindicated the presence of alpha-2B and alpha-2C subtypes but notthe alpha-2A subtype (Huang et al., 1995). It is of interest thatthe immunofluorescence identifies all three subtypes in the rabbitciliary body (Huang et al., 1995), whereas the radioligand approachfinds only the alpha-2A subtype. Because immunofluorescence isnot a quantitative approach, it may be that the other two subtypesare present in such low concentrations that they are not detectedby the radioligand binding technique or that they are not functionalproteins. The lack of immunofluorescence to the alpha-2A in thehuman is of concern because this is the major subtype detectedby the radioligand technique in all three species investigatedto date: rabbit, porcine and bovine. As Huang et al. (1995) pointout, the alpha-2A subtype may well exist in the human but wasnot detected in their immunofluorescence experiments, perhapsbecause the antibody used was not sufficiently sensitive. It willbe important to determine whether this apparent discrepancy isreally due to a species difference or the immunofluorescence techniqueis providing misleading data. Thus, the alpha-2 subtypes in humanocular tissues need to be identified by the radioligand bindingtechnique.

The alpha-2 adrenergic agonists are increasingly used as adjunctive agents with beta adrenergic blockers in stepwise glaucomatherapy. The ocular hypotensive effects of some adrenergic drugsmay not always correlate with the protection of the optic nerve,possibly because of a reduction in posterior segment blood flow.However, the vasoconstrictive side effects of apraclonidine areseen mainly in the anterior segment and apparently do not affectblood flow to the optic nerve. Nevertheless, long-term studiesare needed to evaluate the extent to which apraclonidine and otheralpha-2 adrenergic agents preserve visual function. An understandingof the alpha-2 adrenergic receptor subtype mediating the ocularhypotensive effects of alpha-2 adrenergic receptor agonists willbe important in designing new alpha-2 agents with increased specificityand reduced side effects.

	Footnotes

Accepted for publication February 3, 1997.

Received for publication June 13, 1996.

Send reprint requests to: David B. Bylund, Ph.D., Department of Pharmacology, University of Nebraska Medical Center, 600 South 42nd Street, Box 986260, Omaha, NE 68198-6260.

	Abbreviation

RPE, retinal pigment epithelium.

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