RGS9-G beta 5 substrate selectivity in photoreceptors. Opposing effects of constituent domains yield high affinity of RGS interaction with the G protein-effector complex.

RGS proteins regulate the duration of G protein signaling by increasing the rate of GTP hydrolysis on G protein alpha subunits. The complex of RGS9 with type 5 G protein beta subunit (G beta 5) is abundant in photoreceptors, where it stimulates the GTPase activity of transducin. An important functional feature of RGS9-G beta 5 is its ability to activate transducin GTPase much more efficiently after transducin binds to its effector, cGMP phosphodiesterase. Here we show that different domains of RGS9-G beta 5 make opposite contributions toward this selectivity. G beta 5 bound to the G protein gamma subunit-like domain of RGS9 acts to reduce RGS9 affinity for transducin, whereas other structures restore this affinity specifically for the transducin-phosphodiesterase complex. We suggest that this mechanism may serve as a general principle conferring specificity of RGS protein action.

The gain of rod phototransduction: reconciliation of biochemical and electrophysiological measurements.

We have resolved a central and long-standing paradox in understanding the amplification of rod phototransduction by making direct measurements of the gains of the underlying enzymatic amplifiers. We find that under optimized conditions a single photoisomerized rhodopsin activates transducin molecules and phosphodiesterase (PDE) catalytic subunits at rates of 120-150/s, much lower than indirect estimates from light-scattering experiments. Further, we measure the Michaelis constant, Km, of the rod PDE activated by transducin to be 10 microM, at least 10-fold lower than published estimates. Thus, the gain of cGMP hydrolysis (determined by kcat/Km) is at least 10-fold higher than reported in the literature. Accordingly, our results now provide a quantitative account of the overall gain of the rod cascade in terms of directly measured factors.

The effector enzyme regulates the duration of G protein signaling in vertebrate photoreceptors by increasing the affinity between transducin and RGS protein.

The photoreceptor-specific G protein transducin acts as a molecular switch, stimulating the activity of its downstream effector in its GTP-bound form and inactivating the effector upon GTP hydrolysis. This activity makes the rate of transducin GTPase an essential factor in determining the duration of photoresponse in vertebrate rods and cones. In photoreceptors, the slow intrinsic rate of transducin GTPase is accelerated by the complex of the ninth member of the regulators of G protein signaling family with the long splice variant of type 5 G protein beta subunit (RGS9.Gbeta5L). However, physiologically rapid GTPase is observed only when transducin forms a complex with its effector, the gamma subunit of cGMP phosphodiesterase (PDEgamma). In this study, we addressed the mechanism by which PDEgamma regulates the rate of transducin GTPase. We found that RGS9.Gbeta5L alone has a significant ability to activate transducin GTPase, but its affinity for transducin is low. PDEgamma acts by enhancing the affinity between activated transducin and RGS9.Gbeta5L by more than 15-fold, which is evident both from kinetic measurements of transducin GTPase rate and from protein binding assays with immobilized transducin. Furthermore, our data indicate that a single RGS9.Gbeta5L molecule is capable of accelerating the GTPase activity of approximately 100 transducin molecules/s. This rate is faster than the rates reported previously for any RGS protein and is sufficient for timely photoreceptor recovery in both rod and cone photoreceptors.

The GTPase activating factor for transducin in rod photoreceptors is the complex between RGS9 and type 5 G protein beta subunit.

Proteins of the regulators of G protein signaling (RGS) family modulate the duration of intracellular signaling by stimulating the GTPase activity of G protein alpha subunits. It has been established that the ninth member of the RGS family (RGS9) participates in accelerating the GTPase activity of the photoreceptor-specific G protein, transducin. This process is essential for timely inactivation of the phototransduction cascade during the recovery from a photoresponse. Here we report that functionally active RGS9 from vertebrate photoreceptors exists as a tight complex with the long splice variant of the G protein beta subunit (Gbeta5L). RGS9 and Gbeta5L also form a complex when coexpressed in cell culture. Our data are consistent with the recent observation that several RGS proteins, including RGS9, contain G protein gamma-subunit like domain that can mediate their association with Gbeta5 (Snow, B. E., Krumins, A. M., Brothers, G. M., Lee, S. F., Wall, M. A., Chung, S., Mangion, J., Arya, S., Gilman, A. G. & Siderovski, D. P. (1998) Proc. Natl. Acad. Sci. USA 95, 13307-13312). We report an example of such a complex whose cellular localization and function are clearly defined.

Interaction sites of the C-terminal region of the cGMP phosphodiesterase inhibitory subunit with the GDP-bound transducin alpha-subunit.

In the present report, the region of interaction between the GDP-bound alpha-subunit of transducin (alphat.GTP) and the cGMP phosphodiesterase inhibitory gamma-subunit (Pgamma) has been studied. It is widely accepted that the alphat.GTP is the active form of transducin and that the GDP-bound transducin alpha-subunit (alphat. GDP) is the inactive form. We have reported previously that the binding region of the C-terminal of Pgamma on alphat.GTP is in a region between the exposed face of the alpha3 and alpha4 helices of alphat.GTP [Liu, Arshavsky and Ruoho (1996) J. Biol. Chem. 271, 26900-26907]. We now report that N-[(3-[125I]iodo-4-azidophenylpropionamido-S-(2-thiopyridyl) ]cysteine ([125I]ACTP)-derivatized Pgamma (at Cys-68) reversibly undergoes a unique disulphide exchange of the radioiodinated moiety N-(3-[125I]iodo-4-azidophenylpropionamido)cysteine ([125I]APC) from Cys-68 of Pgamma to alphat.GDP but not to the guanosine 5'-(gamma-thio)-triphosphate (GTP[S])-bound transducin alpha-subunit (alphat-GTP[S]). The specificity of the interaction was demonstrated by the fact that exchange was protected by the functionally active Cys-68-->Ala Pgamma mutant, and by pretreatment of the alphat.GDP with the betagamma-subunit of transducin. Chemical cleavage and amino acid sequencing demonstrated that the [125I]ACTP-derived Pgamma specifically transferred the [125I]APC group to Cys-250 and Cys-210 of alphat.GDP. These data indicate that the C-terminal region (especially Cys-68-Trp-70) of Pgamma interacts with alphat. GDP on the exposed interface between alpha2/beta4 and alpha3/beta5 of the alpha-subunit of transducin. Disulphide exchange was also observed with the alpha-subunit of holotransducin but this was only approx. 60% of that of pure alphat.GDP. The variation in the binding pattern between alphat.GDP and alphat.GTP with the C-terminal region of Pgamma may contribute to the functional difference between the GDP- and GTP-bound states.

Role for the target enzyme in deactivation of photoreceptor G protein in vivo.

Heterotrimeric guanosine 5'-triphosphate (GTP)-binding proteins (G proteins) are deactivated by hydrolysis of the GTP that they bind when activated by transmembrane receptors. Transducin, the G protein that relays visual excitation from rhodopsin to the cyclic guanosine 3',5'-monophosphate phosphodiesterase (PDE) in retinal photoreceptors, must be deactivated for the light response to recover. A point mutation in the gamma subunit of PDE impaired transducin-PDE interactions and slowed the recovery rate of the flash response in transgenic mouse rods. These results indicate that the normal deactivation of transducin in vivo requires the G protein to interact with its target enzyme.

Photoreceptor phosphodiesterase: interaction of inhibitory gamma subunit and cyclic GMP with specific binding sites on catalytic subunits.

The photoreceptor phosphodiesterase (PDE6) is the central effector enzyme in the phototransduction cascade of photoreceptor cells. It is the only known PDE isoform the activity of which is regulated by interaction with a heterotrimeric G protein. The rod PDE6 holoenzyme is a tetrameric protein consisting of two large catalytic alpha and beta subunits and two small gamma subunits, which serve as potent inhibitors of PDE6. In dark-adapted photoreceptors, the gamma subunits maintain PDE6 activity at a low level. When exposed to light the visual pigment rhodopsin activates the retinal G protein, transducin, leading to release of the inhibitory action of the gamma subunits. In addition to the active sites where cGMP is hydrolyzed, the alpha and beta catalytic subunits have high-affinity, noncatalytic cGMP binding sites. These noncatalytic sites do not directly regulate cGMP catalysis at the active site, but rather can modulate the affinity with which the gamma subunits bind to the catalytic subunits. This article describes a number of experimental approaches that have recently been developed for studying the interactions between catalytic and inhibitory subunits of PDE6, as well as the dynamics of cGMP binding to and dissociation from the PDE6 noncatalytic sites.

Onset of feedback reactions underlying vertebrate rod photoreceptor light adaptation.

Light adaptation in vertebrate photoreceptors is thought to be mediated through a number of biochemical feedback reactions that reduce the sensitivity of the photoreceptor and accelerate the kinetics of the photoresponse. Ca2+ plays a major role in this process by regulating several components of the phototransduction cascade. Guanylate cyclase and rhodopsin kinase are suggested to be the major sites regulated by Ca2+. Recently, it was proposed that cGMP may be another messenger of light adaptation since it is able to regulate the rate of transducin GTPase and thus the lifetime of activated cGMP phosphodiesterase. Here we report measurements of the rates at which the changes in Ca2+ and cGMP are followed by the changes in the rates of corresponding enzymatic reactions in frog rod outer segments. Our data indicate that there is a temporal hierarchy among reactions that underlie light adaptation. Guanylate cyclase activity and rhodopsin phosphorylation respond to changes in Ca2+ very rapidly, on a subsecond time scale. This enables them to accelerate the falling phase of the flash response and to modulate flash sensitivity during continuous illumination. To the contrary, the acceleration of transducin GTPase, even after significant reduction in cGMP, occurs over several tens of seconds. It is substantially delayed by the slow dissociation of cGMP from the noncatalytic sites for cGMP binding located on cGMP phosphodiesterase. Therefore, cGMP-dependent regulation of transducin GTPase is likely to occur only during prolonged bright illumination.

The regulation of the cGMP-binding cGMP phosphodiesterase by proteins that are immunologically related to gamma subunit of the photoreceptor cGMP phosphodiesterase.

The cGMP phosphodiesterase from retinal rods (PDE-6) is an alphabetagamma2 heterotetramer. The alpha and beta subunits contain catalytic sites for cGMP hydrolysis, whereas the gamma subunits serve as a protein inhibitor of the enzyme. Visual excitation of photoreceptors enables the activated GTP-bound form of the G-protein transducin to remove the inhibitory action of the gamma subunit, thereby triggering PDE-6 activation. The type 5 phosphodiesterase (PDE-5) isoform shares a number of similar characteristics with PDE-6, including binding of cGMP to noncatalytic sites, the cyclic nucleotide specificity, and inhibitor sensitivities. Although the functional role of PDE-5 remains unclear, it has been shown to be activated by protein kinase A (PKA) (Burns, F., Rodger, I. W. & Pyne, N. J. (1992) Biochem. J. 283, 487-491). Here we report that both the recombinant gamma subunit and a peptide corresponding to amino acids 24-46 in this protein inhibited the activation of PDE-5 by PKA. Furthermore, immunoblotting airway smooth muscle membranes with a specific antibody against amino acids 24-46 of the PDE-6 gamma subunit identified two major immunoreactive small molecular mass proteins of 14 and 18 kDa (p14 and p18). These appear to form a complex with PDE-5, because PDE activity was immunoprecipitated using antibody against the PDE-6 gamma subunit. p14 and p18 were also substrates for phosphorylation by a unidentified kinase that was stimulated by a pertussis toxin-sensitive G-protein. Phosphorylation of p14/p18 in membranes treated with guanine nucleotides correlated with a concurrent reduction in the activation of PDE-5 by PKA. We suggest that p14 and p18 share an epitope common to PDE-6 gamma and that this region may interact with PDE-5 to prevent its activation by PKA.

Activation of transducin guanosine triphosphatase by two proteins of the RGS family.

RGS proteins (regulators of G protein signaling) constitute a newly appreciated group of negative regulators of G protein signaling. Several members of this group stimulate the guanosine triphosphatase (GTPase) activity of various G protein alpha-subunits, including the photoreceptor G protein, transducin. In photoreceptor cells transducin GTPase is known to be substantially accelerated by the coordinated action of the gamma-subunit of its effector enzyme, cGMP phosphodiesterase (PDE gamma), and another yet unidentified membrane-associated protein factor. Here we test the possibility that this factor belongs to the RGS family of GTPase stimulators. We report a detailed kinetic analysis of transducin GTPase activation by two members of the RGS family, RGS4 and G alpha interacting protein (GAIP). RGS4, being at least 5-fold more potent than GAIP, stimulates the rate of transducin GTPase by 2 orders of magnitude. Neither RGS4 nor GAIP requires PDE gamma for activating transducin. Rather, PDE gamma causes a partial reversal of transducin GTPase activation by RGS proteins. The effect of PDE gamma is based on a decreased apparent affinity of RGS for the alpha-subunit of transducin. Our observations indicate that GTPase activity of transducin can be activated by at least two distinct mechanisms, one based on the action of RGS proteins alone and another involving the cooperative action of the effector enzyme and another protein.

Interaction sites of the COOH-terminal region of the gamma subunit of cGMP phosphodiesterase with the GTP-bound alpha subunit of transducin.

In photoreceptor cells, visual transduction occurs through photoexcitation of rhodopsin, GTP activation of the alpha subunit of transducin, and interaction between GTP-bound transducin alpha subunit and the inhibitory gamma subunit of phosphodiesterase. The gamma subunit of phosphodiesterase, in turn, accelerates the hydrolysis of GTP on the alpha subunit of transducin. Within the COOH-terminal residues (46-87) of the phosphodiesterase gamma subunit, Trp-70 has been implicated in phosphodiesterase activation, transducin alpha subunit-phosphodiesterase gamma subunit interaction, and the GTP hydrolysis accelerating activity. We have derivatized the phosphodiesterase gamma subunit with a reversible photoactivatable reagent, [125I]N-[(3-iodo-4-azidophenylpropionamido-S-(2-thiopyridyl) ]cysteine ([125I]ACTP), at cysteine (Cys-68). A light-dependent, cross-linked complex of guanosine 5'-(gamma-thio)triphosphate-bound transducin alpha subunit and ACTPderivatized phosphodiesterase gamma subunit formed after photolysis of a 1:1 stoichiometic complex of the two proteins. The specificity of complex formation between the transducin alpha subunit and the phosphodiesterase gamma subunit was demonstrated by specific protection by the C68A mutant of the phosphodiesterase gamma subunit. The cross-linked complex was treated with beta-mercaptoethanol to transfer the 125I photomoiety from the phosphodiesterase gamma subunit to the transducin alpha subunit. Combined techniques involving electrophoresis, chemical and enzymatic cleavage, and chemical and radiosequencing were used to identify photoinsertion sites on the alpha3 and alpha4/beta6 regions of the transducin alpha subunit. Three photo-labeled residues, His-244 (alpha3 helix), Met-308, and Arg-310 (alpha4/beta6 interface), were specifically identified as photoinsertion sites. Utilizing the crystal structure coordinates of the GTP-bound transducin alpha subunit and molecular modeling, we conclude that Cys-68 of the phosphodiesterase gamma subunit is located at a position between the exposed face of the alpha3 and alpha4 helices of the transducin alpha subunit. We propose that the phosphodiesterase gamma subunit interacts with GTP-bound transducin alpha subunit at multiple sites in which the cysteine 68 to tryptophan 70 sequence of the phosphodiesterase gamma subunit, which is critical for GTP hydrolysis accelerating activity, interacts in the alpha3/alpha4/beta6 region of GTP-bound transducin alpha subunit.

Phosphorylation of non-bleached rhodopsin in intact retinas and living frogs.

The photoresponse in retinal photoreceptors begins when a molecule of rhodopsin is excited by a photon of light. Photoexcited rhodopsin activates an enzymatic cascade including the G-protein transducin and cyclic GMP phosphodiesterase. As a result, cytoplasmic cyclic GMP concentration is decreased and the photoresponse is initiated. This process is terminated when rhodopsin is phosphorylated by rhodopsin kinase and subsequently blocked by a protein called arrestin. It has been noted by several investigators that light can cause phosphorylation of not only photoexcited but also non-excited rhodopsin in rod photoreceptors. A goal of this study was to determine how much non-bleached rhodopsin is phosphorylated. To determine how the structural integrity of the photoreceptor influences the extent of non-bleached rhodopsin phosphorylation, we studied the reaction in electropermeabilized rod outer segments, in rod outer segments still attached to isolated retinas and in living frogs. In the first two preparations, we found that the maximum extent of non-bleached rhodopsin phosphorylation was approximately 1% of the total rhodopsin pool. In living frogs, the maximal amount of non-bleached rhodopsin phosphorylation was approximately 2% of the total rhodopsin pool and occurred after prolonged illumination by the relatively dim light intensity of 20 lux. These data appear to exclude models for light adaptation that postulate high levels of phosphorylation of non-bleached rhodopsin in rod photoreceptors.

An effector site that stimulates G-protein GTPase in photoreceptors.

Heterotrimeric G-proteins mediate between receptors and effectors, acting as molecular clocks. G-protein interactions with activated receptors catalyze the replacement of GDP bound to the alpha-subunit with GTP. alpha-Subunits then modulate the activity of downstream effectors until the bound GTP is hydrolyzed. In several signal transduction pathways, including the cGMP cascade of photoreceptor cells, the relatively slow GTPase activity of heterotrimeric G-proteins can be significantly accelerated when they are complexed with corresponding effectors. In the phototransduction cascade the GTPase activity of photoreceptor G-protein, transducin, is substantially accelerated in a complex with its effector, cGMP phosphodiesterase. Here we characterize the stimulation of transducin GTPase by a set of 23 mutant phosphodiesterase gamma-subunits (PDE gamma) containing single alanine substitutions within a stretch of the 25 C-terminal amino acid residues known to be primarily responsible for the GTPase regulation. The substitution of tryptophan at position 70 completely abolished the acceleration of GTP hydrolysis by transducin in a complex with this mutant. This mutation also resulted in a reduction of PDE gamma affinity for transducin, but did not affect PDE gamma interactions with the phosphodiesterase catalytic subunits. Single substitutions of 7 other hydrophobic amino acids resulted in a 50-70% reduction in the ability of PDE gamma to stimulate transducin GTPase, while substitutions of charged and polar amino acids had little or no effect. These observations suggest that the role of PDE gamma in activation of the transducin GTPase rate may be based on multiple hydrophobic interactions between these molecules.

Regulation of transducin GTPase activity in bovine rod outer segments.

The photoreceptor G-protein, transducin, belongs to the class of heterotrimeric GTP-binding proteins that transfer information from activated seven-span membrane receptors to effector enzymes or ion channels. Like other G-proteins, transducin acts as a molecular clock. It is activated by photoexcited rhodopsin which catalyzes the exchange of transducin-bound GDP for GTP and then stays active until bound GTP is hydrolyzed by an intrinsic GTPase activity. Our previous study on the components of the amphibian phototransduction cascade (Arshavsky, V. Y., and Bownds, M. D. (1992) Nature 357, 416-417) has shown that transducin GTPase can be significantly accelerated by the target enzyme, cGMP phosphodiesterase (PDE), and more specifically its gamma-subunit (PDE gamma). Here we report that an analogous mechanism is present in bovine photoreceptors. Addition of recombinant PDE gamma to the test photoreceptor membranes which retain transducin but are depleted of endogenous PDE causes a significant acceleration of transducin GTPase activity. A similar effect was observed with the PDE holoenzyme, but not with the complex of PDE alpha- and beta-subunits prepared by a limited proteolysis of PDE with trypsin. The activating effect of PDE gamma is increased as test membrane concentration increases, exceeding 20-fold at rhodopsin concentrations over 80 microM and approaching the rate of the photoresponse turnoff. This suggests either that photoreceptor membranes contain a further factor which is essential for PDE-dependent regulation of transducin-bound GTP hydrolysis or that components of the phototransduction cascade interact in a cooperative manner. We also report that the GTPase-activating epitope is located within the C-terminal third of PDE gamma: the peptide corresponding to the 25 C-terminal amino acid residues of PDE gamma can accelerate transducin GTPase almost as well as the full-length PDE gamma. A part of the GTPase activating epitope is located within the 3 C-terminal amino acid residues: the truncation PDE gamma mutant lacking these residues accelerates transducin GTPase considerably less than the whole length PDE gamma.

Rod outer segment structure influences the apparent kinetic parameters of cyclic GMP phosphodiesterase.

Cyclic GMP hydrolysis by the phosphodiesterase (PDE) of retinal rod outer segments (ROS) is a key amplification step in phototransduction. Definitive estimates of the turnover number, kcat, and of the Km are crucial to quantifying the amplification contributed by the PDE. Published estimates for these kinetic parameters vary widely; moreover, light-dependent changes in the Km of PDE have been reported. The experiments and analyses reported here account for most observed variations in apparent Km, and they lead to definitive estimates of the intrinsic kinetic parameters in amphibian rods. We first obtained a new and highly accurate estimate of the ratio of holo-PDE to rhodopsin in the amphibian ROS, 1:270. We then estimated the apparent kinetic parameters of light-activated PDE of suspensions of disrupted frog ROS whose structural integrity was systematically varied. In the most severely disrupted ROS preparation, we found Km = 95 microM and kcat = 4,400 cGMP.s-1. In suspensions of disc-stack fragments of greater integrity, the apparent Km increased to approximately 600 microM, though kcat remained unchanged. In contrast, the Km for cAMP was not shifted in the disc stack preparations. A theoretical analysis shows that the elevated apparent Km of suspensions of disc stacks can be explained as a consequence of diffusion with hydrolysis in the disc stack, which causes active PDEs nearer the center of the stack to be exposed to a lower concentration of cyclic GMP than PDEs at the disc stack rim. The analysis predicts our observation that the apparent Km for cGMP is elevated with no accompanying decrease in kcat. The analysis also predicts the lack of a Km shift for cAMP and the previously reported light dependence of the apparent Km for cGMP. We conclude that the intrinsic kinetic parameters of the PDE do not vary with light or structural integrity, and are those of the most severely disrupted disc stacks.

cGMP binding sites on photoreceptor phosphodiesterase: role in feedback regulation of visual transduction.

A central step in vertebrate visual transduction is the rapid drop in cGMP levels that causes cGMP-gated ion channels in the photoreceptor cell membrane to close. It has long been a puzzle that the cGMP phosphodiesterase (PDE) whose activation causes this decrease contains not only catalytic sites for cGMP hydrolysis but also noncatalytic cGMP binding sites. Recent work has shown that occupancy of these noncatalytic sites slows the rate of PDE inactivation. We report here that PDE activation induced by activated transduction lowers the cGMP binding affinity for noncatalytic sites on PDE and accelerates the dissociation of cGMP from these sites. These sites can exist in three states: high affinity (Kd = 60 nM) for the nonactivated PDE, intermediate affinity (Kd approximately 180 nM) when the enzyme is activated in a complex with transducin, and low affinity (Kd > 1 microM) when transducin physically removes the inhibitory subunits of PDE from the PDE catalytic subunits. Activation of PDE by transducin causes a 10-fold increase in the rate of cGMP dissociation from one of the two noncatalytic sites; physical removal of the inhibitory subunits from the PDE catalytic subunits further accelerates the cGMP dissociation rate from both sites > 50-fold. Because PDE molecules lacking bound cGMP inactivate more rapidly, this suggests that a prolonged cGMP decrease may act as a negative feedback regulator to generate the faster, smaller photoresponses characteristic of light-adapted photoreceptors.

Two types of mechanosensitive channels in the Escherichia coli cell envelope: solubilization and functional reconstitution.

Mechanosensitive ion channels (MSCs) which could provide for fast osmoregulatory responses in bacteria, remain unidentified as molecular entities. MSCs from Escherichia coli (strain AW740) were examined using the patch-clamp technique, either (a) in giant spheroplasts, (b) after reconstitution by fusing native membrane vesicles with asolectin liposomes, or (c) by reassembly of octylglucoside-solubilized membrane extract into asolectin liposomes. MSC activities were similar in all three preparations, consisting of a large nonselective MSC of 3-nS conductance (in 200 mM KCl) that was activated by high negative pressures, and a small weakly anion-selective MSC of 1 nS activated by lower negative pressures. Both channels appeared more sensitive to suction in liposomes than in spheroplasts. After gel filtration of the solubilized membrane extract and reconstituting the fractions, both large MSC and small MSC activities were retrieved in liposomes. The positions of the peaks of channel activity in the column eluate, assayed by patch sampling of individual fractions reconstituted in liposomes, showed an apparent molecular mass under nondenaturing conditions of about 60-80 kDa for the large and 200-400 kDa for the small MSC. We conclude that (a) the large MSC and the small MSC are distinct molecular entities, (b) the fact that both MSCs were functional in liposomes following chromatography strongly suggests that these channels are gated by tension transduced via lipid bilayer, and (c) chromatographic fractionation of detergent-solubilized membrane proteins with subsequent patch sampling of reconstituted fractions can be used to identify and isolate these MS channel proteins.