Purinergic signalling in the subretinal space: a role in the communication between the retina and the RPE

Claire H. Mitchell David Reigada The retinal pigment epithelium (RPE) is separated from the photoreceptor outer segments by the subretinal space. While the actual volume of this space is minimal, the communication that occurs across this microenvironment is important to the visual process, and accumulating evidence suggests the purines ATP and adenosine contribute to this communication. P1 and P2 receptors are localized to membranes on both the photoreceptor outer segments and on the apical membrane of the RPE which border subretinal space. ATP is released across the apical membrane of the RPE into this space in response to various triggers including glutamate and chemical ischemia. This ATP is dephosphorylated into adenosine by a series of ectoenzymes on the RPE apical membrane. Regulation of release and ectoenzyme activity in response to light-sensitive signals can alter the balance of purines in subretinal space, and thus coordinate communication across subretinal space with the visual process. - Abbreviations ADP adenosine diphosphate AMP adenosine monophosphate ATP adenosine triphosphate ARL67156 6-N,N-diethyl-D-,+-dibromomethylene ATP BAPTA (1,2-bis(o-aminophenoxy)ethane-N,N,N,Ntetraacetic acid) The retinal pigment epithelium (RPE) lies between the outer segments of the photoreceptors and the choroidal blood supply (Fig. 1). The RPE combines the functions of epithelial and glial cells, providing a barrier while also supporting the neural photoreceptors and modulating their function. Tight communication between photoreceptors and the RPE is critical to coordinate the multiple levels of Fig. 1 Schematic illustration of the key components of purinergic signaling in the subretinal microenvironment. Stimulation of P2 receptors on the RPE can enhance transepithelial fluid absorption while P1 receptors can modulate phagocytosis. ATP released through CFTR and other Cl channels can stimulate P2 receptors or be converted to ADP, AMP, and adenosine (Ado) by a series of ectonucleotidases present on the apical membrane of the RPE. By controlling the balance of extracellular purines available to stimulate these receptors these mechanisms can control levels of endogenous purines available to activate the receptors. While theoretically possible, it remains to be determined whether these subretinal purines can actually stimulate photoreceptors ATP interaction, and the purinergic contribution to this communication is becoming apparent. The relevance of this purinergic input is emphasized by the many functional effects of P1 and P2 receptor stimulation and by the multiple mechanisms in place to regulate subretinal levels of purine agonists. As the dynamics of ATP release and extracellular conversion into adenosine will modify agonist availability, the modulation of these processes can exert a temporal control on purinergic signaling. The following review will outline the main interactions between the RPE and photoreceptors, describe the effects of stimulating purinergic receptors on both sides of subretinal space, and summarize how levels of ATP, ADP, and adenosine are manipulated in this microenvironment. Purines and subretinal space RPE-photoreceptor interactions across the subretinal space The outer segments of the rods and cones are responsible for the initial stages of vision, converting photon energy into a series of enzymatic reactions that close the lightsensitive channels on the photoreceptor plasma membrane, hyperpolarize the cells, and reduce the release of glutamate from the synaptic terminals [1, 2]. Efficient photoreceptor function depends upon both short-term and long-term support from the RPE. The critical nature of these interactions is evident from the rapid degeneration of photoreceptors in the absence of a healthy RPE layer and by the RPE localization of defective gene product in some forms of hereditary photoreceptor degeneration [3]. The apical membrane of the RPE is separated from the plasma membrane of the outer segments by an extracellular space of only 1020 nm [4]. Although small, this subretinal space contains a highly structured matrix which ensheathes the outer segments and extends to the RPE [5, 6]. The presence of enzymes within this interphotoreceptor matrix emphasizes that this extracellular space itself is functionally active [7, 8]. This intimate anatomical relationship between photoreceptors and the RPE reflects multiple functional interactions. For example, the RPE accepts, recycles, and exports central components of the phototransduction process [9]. The outer segments are continuously resynthesized, and the phagocytosis, degradation, and processing of shed outer segment tips by the RPE cells is central to this renewal [10]. The ion channels and transporters on the apical membrane of the RPE help regulate the ionic composition of the subretinal space [11]. As extracellular levels of ions can modify the ionic driving forces across the photoreceptor plasma membrane, these RPE transporters can influence the state of neural activity. The transport of fluid and ions from the apical membrane to basolateral membrane of the RPE is also one of the main forces keeping the retina attached [12]. The control of photoreceptor activity by light gives a rapid temporal dependence to some interactions between the photoreceptors and the RPE. The volume of subretinal space increases in response to light [13], linking small changes in the ionic composition of the subretinal space with activity of the RPE transport mechanisms which maintain this volume [14, 15]. Other processes are controlled on a diurnal cycle. The shed tips of the outer segments are phagocytosed by the RPE soon after the onset of light [16, 17]. These processes can both be modulated by purine levels in subretinal space, indicating purinergic regulation is important over multiple time scales. Purinergic receptors on photoreceptors A2 adenosine receptors were localized to both the inner and outer segments of photoreceptor outer segments over a decade ago by Blazynski and colleagues [18], with more recent reports emphasizing their functional role. A2 agonists inhibit the L-type Ca2+ channel on rod outer segments [19] and can inhibit the synaptic release of glutamate from rods, suggesting changes in adenosine levels in subretinal space could modulate light sensitivity [20]. The A2 agonist DPMA and the adenosine deaminase inhibitor EHNA reduce mRNA for opsin in rods, suggesting that endogenous levels of adenosine can downregulate opsin message at night [21]. EHNA and the A2A receptor agonist CGS21680 also increase the survival of chick embryonic photoreceptors in culture [22], indicating a long-term neuroprotective role for adenosine. P2 receptors are also present in the photoreceptors. mRNA for the P2X2 receptor is expressed in the photoreceptor cell bodies, with immunohistochemical localization of the protein to outer segments [23]. In situ hybridization indicates the photoreceptor layer ha (...truncated)