Protein-specific energy requirements for protein transport across or into thylakoid membranes. Two lumenal proteins are transported in the absence of ATP.

Cytosolically synthesized thylakoid proteins must be translocated across the chloroplast envelope membranes, traverse the stroma, and then be translocated into or across the thylakoid membrane. Protein transport across the envelope requires ATP hydrolysis but not electrical or proton gradients. The energy requirements for the thylakoid translocation step were studied here for the light-harvesting chlorophyll a/b protein (LHCP), an integral membrane protein, and for several thylakoid lumen-resident proteins: plastocyanin and OE33, OE23, and OE17 (the 33-, 23-, and 17-kDa subunits of the oxygen-evolving complex, respectively). Dissipation of the thylakoid protonmotive force during an in organello protein import assay partially inhibited the thylakoid localization of LHCP and OE33, totally inhibited localization of OE23 and OE17, and had no effect on localization of plastocyanin. We used reconstitution assays for LHCP insertion and for OE23 and OE17 transport into isolated thylakoids to investigate the energy requirements in detail. The results indicated that LHCP insertion absolutely requires ATP hydrolysis and is enhanced by a transthylakoid delta pH and that transport of OE23 and OE17 is absolutely dependent upon a delta pH. Surprisingly, OE23 and OE17 transport occurred maximally in the complete absence of ATP. These results establish the thylakoid membrane as the only membrane system in which a delta pH can provide all of the energy required to translocate proteins across the bilayer. They also demonstrate that the energy requirements for integration into or translocation across the thylakoid membranes are protein-specific.     

ATP stimulates signal recognition particle (SRP)/FtsY-supported protein integration in chloroplasts

The signal recognition particle (SRP) and its receptor (FtsY in prokaryotes) are essential for cotranslational protein targeting to the endoplasmic reticulum in eukaryotes and the cytoplasmic membrane in prokaryotes. An SRP/FtsY-like protein targeting/integration pathway in chloroplasts mediates the posttranslational integration of the light-harvesting chlorophyll a/b-binding protein (LHCP) into thylakoid membranes. GTP, chloroplast SRP (cpSRP), and chloroplast FtsY (cpFtsY) are required for LHCP integration into thylakoid membranes. Here, we report the reconstitution of the LHCP integration reaction with purified recombinant proteins and salt-washed thylakoids. Our data demonstrate that cpSRP and cpFtsY are the only soluble protein components required for LHCP integration. In addition, our studies reveal that ATP, though not absolutely required, remarkably stimulates LHCP integration into salt-washed thylakoids. ATP stimulates LHCP integration by a mechanism independent of the thylakoidal pH gradient (DeltapH) and exerts no detectable effect on the formation of the soluble LHCP-cpSRP-targeting complex. Taken together, our results indicate the participation of a thylakoid ATP-binding protein in LHCP integration.     

Chloroplast Oxa1p homolog albino3 is required for post-translational integration of the light harvesting chlorophyll-binding protein into thylakoid membranes

Multiple sorting pathways operate in chloroplasts to localize proteins to the thylakoid membrane. The signal recognition particle (SRP) pathway in chloroplasts employs the function of a signal recognition particle (cpSRP) to target light harvesting chlorophyll-binding protein (LHCP) to the thylakoid membrane. In assays that reconstitute stroma-dependent LHCP integration in vitro, the stroma is replaceable by the addition of GTP, cpSRP, and an SRP receptor homolog, cpFtsY. Still lacking is an understanding of events that take place at the thylakoid membrane including the identification of membrane proteins that may function at the level of cpFtsY binding or LHCP integration. The identification of Oxa1p in mitochondria, an inner membrane translocase component homologous to predicted proteins in bacteria and to the albino3 (ALB3) protein in thylakoids, led us to investigate the potential role of ALB3 in LHCP integration. Antibody raised against a 50-amino acid region of ALB3 (ALB3-50aa) identified a single 45-kDa thylakoid protein. Treatment of thylakoids with antibody to ALB3-50aa inhibited LHCP integration, whereas the same antibody treatment performed in the presence of antigen reversed the inhibition. In contrast, transport by the thylakoid Sec or Delta pH pathways was unaffected. These data support a model whereby a distinct translocase containing ALB3 is used to integrate LHCP into thylakoid membranes.     

An imported thylakoid protein accumulates in the stroma when insertion into thylakoids is inhibited

The light-harvesting chlorophyll a/b protein (LHCP) is synthesized in the cytosol as a precursor (pLHCP) that is imported into chloroplasts and assembled into thylakoid membranes. Under appropriate conditions, either pLHCP or LHCP will integrate into isolated thylakoids. We have identified two situations that inhibit integration in this assay. Ionophores and uncouplers inhibited integration up to 70%. Carboxyl-terminal truncations of pLHCP also interfered with integration. A 22-residue truncation reduced integration to about 25% of control, whereas a 93 residue truncation completely abolished it. When pLHCP was imported into chloroplasts in the presence of uncouplers or when truncated forms of pLHCP were used, significant amounts of the imported proteins failed to insert into thylakoids and instead accumulated in the aqueous stroma. Accumulation of stromal LHCP occurred at uncoupler concentrations required to dissipate the trans-thylakoid proton electrochemical gradient and was enhanced at reduced levels of ATP. The latter effect may be a secondary consequence of a reduction in ATP-dependent degradation within the stroma. These results indicate that the stroma is an intermediate location in the LHCP assembly pathway and provide the first evidence for a soluble intermediate during biogenesis of a chloroplast membrane protein.     

A stromal protein factor maintains the solubility and insertion competence of an imported thylakoid membrane protein

The light-harvesting chlorophyll a/b protein (LHCP) is an approximately 25,000-D thylakoid membrane protein. LHCP is synthesized in the cytosol as a precursor and must translocate across the chloroplast envelope before becoming integrally associated with the thylakoid bilayer. Previous studies demonstrated that imported LHCP traverses the chloroplast stroma as a soluble intermediate before thylakoid insertion. Here, examination of this intermediate revealed that it is a stable, discrete approximately 120,000-D species and thus either an LHCP oligomer or a complex with another component. In vitro-synthesized LHCP can be converted to a similar form by incubation with a stromal extract. The stromal component responsible for this conversion is proteinaceous as evidenced by its inactivation by heat, protease, and NEM. Furthermore, the conversion activity coelutes from a gel filtration column with a stromal protein factor(s) previously shown to be necessary for LHCP integration into isolated thylakoids. Conversion of LHCP to the 120-kD form prevents aggregation and maintains its competence for thylakoid insertion. However, conversion to this form is apparently not sufficient for membrane insertion because the isolated 120-kD LHCP still requires stroma to complete the integration process. This suggests a need for at least one more stroma-mediated reaction. Our results explain how a hydrophobic thylakoid protein remains soluble as it traverses the aqueous stroma. Moreover, they describe in part the function of the stromal requirement for insertion into the thylakoid membrane.     

Degradation of mistargeted OEE33 in the chloroplast stroma

OEE33, a component of the oxygen-evolving enzyme in chloroplasts, normally resides in the thylakoid lumen. In an attempt to study the fate of mistargeted proteins in chloroplasts, we substituted the bipartite transit peptide of OEE33 with that of CAB7, an integral thylakoid-membrane protein. As a result, when imported into isolated chloroplasts, the chimeric protein was targeted to the stroma instead of the thylakoid lumen. Whereas the wild-type OEE33 was totally stable for at least 2 h, the chimeric protein was rapidly degraded, with a half-life of 60 min. Degradation of the chimeric protein was stimulated by ATP supplementation. Degradation could also be observed in lysed chloroplasts, in an ATP-stimulated manner. When lysates were fractionated, the proteolytic activity was found to be associated mainly with the stromal fraction. This activity was very effectively inhibited by all tested inhibitors of serine proteases. Western blot analysis demonstrated that the stromal fraction active in degrading the chimeric OEE33 contains ClpC and ClpP, homologues of the regulatory and proteolytic subunits, respectively, of the bacterial, ATP-dependent, serine-type Clp protease.     

Requirement for three membrane-spanning alpha-helices in the post-translational insertion of a thylakoid membrane protein.

The insertion of a protein into a lipid bilayer usually involves a short signal sequence and can occur either during or after translation. A light-harvesting chlorophyll a/b-binding protein (LHCP) is synthesized in the cytoplasm of plant cells as a precursor and is post-translationally imported into chloroplasts where it subsequently inserts into the thylakoid membrane. Only mature LHCP is required for insertion into the thylakoid. To define which sequences of the mature protein are necessary and sufficient for thylakoid integration, fusion and deletion proteins and proteins with internal rearrangements were synthesized and incubated with isolated thylakoids and stroma. No evidence is found for the existence of a short signal sequence within LHCP, and, with the exception of the amino terminus and a short lumenal loop, the entire mature protein with consecutively ordered alpha-helices is required for insertion into thylakoid membranes. The addition of positive charges into stromal but not lumenal segments permits the insertion of mutant LHCPs into isolated thylakoids. Replacement of the LHCP transit peptide with the transit peptide from plastocyanin has no effect on LHCP insertion and does not restore insertion of the lumenal charge addition mutants.     

Binding of periodate-oxidized guanine nucleotides to eukaryotic elongation factor 2

Periodate-oxidized guanine nucleotides (GTPox and GDPox) were shown to bind stoichiometrically to rat liver elongation factor 2 (EF-2). This binding was quantitatively inhibited in the presence of GTP. After binding, oxidized nucleotides remained on EF-2 despite extensive dialysis. They exchanged, however, with free quanine nucleotides in the course of prolonged (greater than 1 h) incubations. The prior reduction EF-2.GTPox with NaBH4 abolished, to a large extent, this slow exchange. Thus, a Schiff's base was implicated to be formed between EF-2 and oxidized guanine nucleotides. Mg2+ increased the GTPox concentration necessary for a stoichiometric binding to EF-2. EF-2-oxidized nucleotide conjugates bound in the presence of ribosomes a second molecule of GTP (or GTPox). GTPox bound to EF-2 in the presence of ribosomes appeared to exchange readily with free GTP. Moreover, GTPox proved to be active as substrate in EF-2 and ribosome-dependent GTPase reaction: Km values found for GTPox and GTP were 7.7 and 3.4 microM, respectively. The binding of GTPox to EF-2 inhibited only partially the subsequent ribosome-dependent GTP binding, and GTPase reaction or polyphenylalanine (polyPhe) synthesis. On the other hand, the binding of GuoPP[CH2]Pox to EF-2 inhibited all of these reactions strongly. The nature of the binding site involved in the direct interactions of EF-2 with guanine nucleotides is discussed in the light of these results.     

Chloroplast FtsY, chloroplast signal recognition particle, and GTP are required to reconstitute the soluble phase of light-harvesting chlorophyll protein transport into thylakoid membranes.

The integration of light-harvesting chlorophyll proteins (LHCPs) into the thylakoid membrane proceeds in two steps. First, LHCP interacts with a chloroplast signal recognition particle (cpSRP) to form a soluble targeting intermediate called the transit complex. Second, LHCP integrates into the thylakoid membrane in the presence of GTP, at least one other soluble factor, and undefined membrane components. We previously determined that cpSRP is composed of 43- and 54-kDa polypeptides. We have examined the subunit stoichiometry of cpSRP and find that it is trimeric and composed of two subunits of cpSRP43/subunit of cpSRP54. A chloroplast homologue of FtsY, an Escherichia coli protein that is critical for the function of E. coli SRP, was found largely in the stroma unassociated with cpSRP. When chloroplast FtsY was combined with cpSRP and GTP, the three factors promoted efficient LHCP integration into thylakoid membranes in the absence of stroma, demonstrating that they are all required for reconstituting the soluble phase of LHCP transport.     

Integration of nuclear-encoded proteins into pea thylakoids with different pigment contents

The in vitro membrane integration of the light-harvesting protein of photosystem II (LHCP), the Rieske FeS protein of the cytochrome (Cyt) blf-complex, and the NADPH:protochlorophyllide oxidoreductase (Pchlide reductase) into pea thylakoids with different pigment composition was studied. Pea plants (Pisum sativum L. cv. Kelvedon Wonder) with different contents of chlorophyll (Chl) and carotenoids were obtained by growing the seedlings in a greenhouse or in weak red light with or without the herbicide Norflurazon, an inhibitor of carotenoid biosynthesis. Chloroplasts from untreated and Norflurazon-treated plants grown in weak red light contained approximately 29 and 14% of Chl compared to chloroplasts from untreated plants grown in the greenhouse. The corresponding carotenoid contents were 66 and 5%. Following an integration reaction using LHCP precursor protein and chloroplast lysate, thylakoids from untreated and Norflurazon-treated plants grown in weak red light contained approximately 30 and 5% of protease-protected LHCP, respectively, compared to thylakoids of untreated plants grown in a greenhouse. In contrast to LHCP, the in vitro assembly of the Pchlide reductase was only sligthly reduced in chloroplast lysates of plants grown in weak red light compared to greenhouse-grown plants. In chloroplast lysates of Norflurazon-treated plants, however, the amount of membrane associated, protease-protected Pchlide reductase was reduced to 32% of the amount in untreated plants grown under the same light conditions. In contrast, the integration of the Rieske FeS protein occurred to almost similar levels irrespective of light conditions and herbicide treatments. Reconstitution assays where stroma from Norflurazon-treated plants was added to thylakoids from untreated plants, showed that the herbicide did not affect any stromal component(s) vital for the insertion reaction. Removal of samples during the integration reaction of LHCP showed that no degradation of the protein occurred during the assay. Neither was the assembled protein degraded up to 24 h after the termination of the assay. This indicates that growing plants in weak red light, with or without Norflurazon treatment, mainly affected the primary step in thylakoid assembly of LHCP, i.e. the insertion reaction into the membrane. The results further indicate that proteins normally bound to pigments also require pigments for membrane recognition or integration.     

Light-Harvesting Chlorophyll a/b Protein : Membrane Insertion, Proteolytic Processing, Assembly into LHC II, and Localization to Appressed Membranes Occurs in Chloroplast Lysates

The apoprotein of the light-harvesting chlorophyll a/b protein (LHCP) is a major integral thylakoid membrane protein that is normally complexed with chlorophyll and xanthophylls and serves as the antenna complex of photosystem II. LHCP is encoded in the nucleus and synthesized in the cytosol as a higher molecular weight precursor that is subsequently imported into chloroplasts and assembled into thylakoids. In a previous study it was established that the LHCP precursor can integrate into isolated thylakoid membranes. The present study demonstrates that under conditions designed to preserve thylakoid structure, the inserted LHCP precursor is processed to mature size, assembled into the LHC II chlorophyll-protein complex, and localized to the appressed thylakoid membranes. Under these conditions, light can partially replace exogenous ATP in the membrane integration process.     

Processing of a wheat light-harvesting chlorophyll a/b protein precursor by a soluble enzyme from higher plant chloroplasts

A processing activity has been identified in higher plant chloroplasts that cleaves the precursor of the light-harvesting chlorophyll a/b- binding protein (LHCP). A wheat LHCP gene previously characterized (Lamppa, G.K., G. Morelli, and N.-H. Chua, 1985. Mol. Cell Biol. 5:1370- 1378) was used to synthesize RNA and subsequently the labeled precursor polypeptide in vitro. Incubation of the LHCP precursors with a soluble extract from lysed chloroplasts, after removal of the thylakoids and membrane vesicles, resulted in the release of a single 25-kD peptide. In contrast, when the LHCP precursors were used in an import reaction with intact pea or wheat chloroplasts, two forms (25 and 26 kD) of mature LHCP were found. The peptide released by the processing activity in the organelle-free assay comigrated with the lower molecular mass form of mature LHCP produced during import. Properties of the processing activity suggest that it is an endopeptidase. Chloroplasts from both pea and wheat, two divergent higher plants, contain the processing enzyme, suggesting its physiological importance in LHCP assembly into the thylakoids. We discuss the implications of LHCP precursor processing by a soluble enzyme that may be in the stromal compartment.     

The chlorophyll a/b-binding protein inserts into the thylakoids independent of its cognate transit peptide

In order to determine if the cognate transit peptide of the light-harvesting chlorophyll a/b-binding protein (LHCP) is essential for LHCP import into the chloroplast and proper localization to the thylakoids, it was replaced with the transit peptide of the small subunit (S) of ribulose-1,5-bisphosphate carboxylase/oxygenase, a stromal protein. Wheat LHCP and S genes were fused to make a chimeric gene coding for the hybrid precursor, which was synthesized in vitro and incubated with purified pea chloroplasts. My results show that LHCP is translocated into chloroplasts by the S transit peptide. The hybrid precursor was processed; and most importantly, mature LHCP did not remain in the stroma, but was inserted into thylakoid membranes, where it normally functions. Density gradient centrifugation showed no LHCP in the envelope fraction. Hence, the transit peptide of LHCP is not required for intraorganellar routing, and LHCP itself contains an internal signal for localization to the correct membrane compartment.     

Deletion Mutants of Chlorophyll a/b Binding Proteins Are Efficiently Imported into Chloroplasts but Do Not Integrate into Thylakoid Membranes

Chlorophyll a/b binding polypeptides (CABp) are integral thylakoid membrane proteins containing three membrane-spanning helices. We have created a series of mutations in tomato CABp to test whether individual membrane helices with hydrophilic flanking sequences, when fused to a transit peptide, can be imported into chloroplasts and correctly targeted to thylakoid membranes. All of the mutated precursors, including those with large C-terminal and internal deletions, were imported successfully, showing that these regions of the mature CABp are not required for import into chloroplasts. All mutants tested, containing either one or two membrane helices, were found primarily in the stroma and not in the thylakoids. The small amount of protein found associated with the thylakoids was largely resistant to alkali extraction but was sensitive to protease, unlike wild-type protein, which is resistant to both treatments. When incubated with thylakoids in the absence of stroma and/or ATP, a significant amount of wild-type protein assumes a form that is resistant to alkali extraction but is protease sensitive, like the imported deletion proteins. This form of the wild-type protein is not chased into a protease-resistant form by adding stroma and/or ATP. These results suggest that CABp can spontaneously associate with membranes as an aberrant species that is not an intermediate in the process of integration. The inability of the deletion forms of CABp to assume a protease-resistant conformation suggests that correct integration is afforded by elements within the entire protein that collectively contribute to the proper conformation of the protein. The ability of deletion mutants to associate with thylakoids in a nonphysiological way suggests that the study of such mutants may not be useful in elucidating thylakoid-targeting signals.     

Transport of Proteins into the Thylakoid Lumen--Stromal Processing and Energy Requirements for the Import of the Precursor to the 23-kDa Protein of PS II

Transport of the precursor to the 23-kDa protein of photosystemII was examined by incubation of the precursor with isolatedintact chloroplasts in the presence of ATP in darkness. An intermediary-sizedform was accumulated in the stroma at 0.1–1 mM ATP. Athigher concentrations of ATP (3.2–10 mM), the precursorwas imported into the thylakoid lumen and processed to the matureform. The precursor was not imported even as far as the stromain the absence of ATP. The intermediary-sized form that accumulatedat low concentrations of ATP was imported into the thylakoidlumen and processed to the mature form when chloroplasts weresubsequently incubated in the light. These observations indicatethat the accumulated intermediary-sized form was suitable forfurther translocation and that the intermediary-sized form isa transport intermediate that occurs under natural conditions.Import of the protein into the thylakoid lumen, which was observedat the higher concentrations of ATP, was inhibited by the additionof nigericin or carbonylcyanide m-chlorophenyl hydrazine. Theeffects of these ionophores suggests that the translocationof the protein across thylakoid membrane requires a proton gradientacross the membrane. The results together show that the proteinis imported from the cytosol into the thylakoid lumen in discretesteps: ATP-driven translocation across envelope membranes, stromalprocessing to the intermediate, translocation of the intermediateacross the thylakoid membrane and final processing to the matureprotein within the thylakoids. (Received June 3, 1992; Accepted December 17, 1992)     

A hydrophobic, carboxy-proximal region of a light-harvesting chlorophyll a/b protein is necessary for stable integration into thylakoid membranes.

Proteins synthesized as soluble precursors in the cytoplasm of eukaryotic cells often cross organellar membrane barriers and then insert into lipid bilayers. One such polypeptide, the light-harvesting chlorophyll a/b-binding protein (LHCP), must also associate with pigment molecules and be assembled into the photosystem II light-harvesting complex in the chloroplast thylakoid membrane. A study of the import of mutant LHCPs into isolated chloroplasts has shown that a putative alpha-helical membrane-spanning domain near the carboxy terminus (helix 3) is essential for the stable insertion of LHCP in the thylakoid. Protease digestion experiments are consistent with the carboxy terminus of the protein being in the lumen. This report also shows that helix 3, when fused to a soluble protein, can target it to the thylakoids of isolated, intact chloroplasts. Although helix 3 is required for the insertion of LHCP and mutant derivatives into the thylakoid, the full insertion of helix 3 itself requires additionally the presence of other regions of LHCP. Thus, LHCP targeting and integration into thylakoid membranes requires a complex interaction involving a number of different domains of the LHCP polypeptide.     

Loss of efficient import and thylakoid insertion due to N- and C-terminal deletions in the light-harvesting chlorophyll a/b binding protein.

C-terminally truncated precursors of wheat light-harvesting chlorophyll a/b binding protein (LHCP) were synthesized to investigate the origin of the two forms (about 25 kD and 26 kD) of the mature protein observed upon in vitro import into the chloroplast. Precursors p delta 13 and p delta 27, lacking 13 and 27 amino acids, respectively, were successfully imported, and both gave rise to two smaller forms proportional to the size of their deletions. These results demonstrate that there are two N-terminal sites that are cleaved during import of the LHCP precursor, undoubtedly contributing to the heterogeneity of LHCP found in vivo. Significantly, p delta 27 yielded only 50% of mature LHCP when compared with wild type. Although the products of p delta 27 import were localized to the thylakoids, in contrast to p delta 13 they were not correctly inserted into the membranes, indicating that residues essential for this step are missing. p delta 27 is distinguished from p delta 13 by lacking the carboxy end of a domain highly conserved between LHCP of photosystems II and I. Other specific precursor mutants with larger C-terminal deletions were not efficiently transported into the organelle in time course experiments, nor did they insert directly into the thylakoids using chloroplast lysates, in an assay independent of translocation across the envelope. In addition, the mutant p delta 18n, lacking the first 18 amino acids of mature LHCP, was only found bound to the chloroplast envelope. However, both p delta 18n and the mature protein, i.e., LHCP, synthesized in vitro without its 34-amino acid transit peptide inserted into the thylakoids in chloroplast lysates. The overall conformation of the mutant precursor polypeptides was probed using the chloroplast soluble processing enzyme in an organelle-free reaction optimized for the LHCP precursor and the more general protease trypsin. A tightly folded, protease-resistant conformation was not apparent to explain the loss of efficient import.     

The L18 domain of light-harvesting chlorophyll proteins binds to chloroplast signal recognition particle 43

Chloroplast signal recognition particle (cpSRP) is a novel type of SRP that contains a homolog of SRP54 and a 43-kDa subunit absent from all cytoplasmic SRPs but lacks RNA. It is also distinctive in its ability to post-translationally interact with light-harvesting chlorophyll proteins (LHCP), hydrophobic proteins synthesized in the cytoplasm and targeted to the thylakoid via the stroma. LHCP integration into thylakoid membranes requires the two subunits of cpSRP, cpFtsY, GTP, and the membrane protein ALB3. It had previously been shown that the L18 domain, an 18-amino acid peptide between the second and third transmembrane domains, and a hydrophobic domain are required for interaction with cpSRP. In the present study we used a pull-down assay, with cpSRP43 or cpSRP54 fused to glutathione-transferase, to study interactions between cpSRP43, cpSRP54, LHCP, and cpFtsY. cpFtsY was not observed to form significant interactions with any of the proteins even in the presence of nonhydrolyzable GTP analogs. Our data indicate that cpSRP43 binds to the L18 domain, that cpSRP54 binds to the hydrophobic domain, and that LHCP and cpSRP54 independently bind to cpSRP43. These data confirm that the novel post-translational interaction between LHCP and cpSRP is mediated through binding to cpSRP43.     

Light-regulated biochemical events in invertebrate photoreceptors. 1. Light-activated guanosinetriphosphatase, guanine nucleotide binding, and cholera toxin catalyzed labeling of squid photoreceptor membranes

The occurrence of a guanine nucleotide binding protein activated by squid rhodopsin was established by examination of GTPase activity, guanine nucleotide binding, and cholera toxin catalyzed labeling of squid photoreceptor membranes. Purified squid (Loligo opalescens) photoreceptors exhibited GTPase activity that increased 3-4-fold by illumination. Half-maximal GTPase activity was observed when 2% of the rhodopsin was photoconverted to metarhodopsin. The Km of the light-regulated activity was 1 microM GTP. Binding of the hydrolysis-resistant GTP analogue guanosine 5'-(beta, gamma-imidotriphosphate) [Gpp(NH)p] was enhanced greater than 10 times by illumination. A protein, Mr 44 000, was identified as a component of the light-activated guanine nucleotide binding protein/GTPase through its specific labeling with [32P]NAD catalyzed by cholera toxin: light increased the extent of 32P incorporation 7-fold. The addition of ATP to the membrane suspension enhanced labeling, while guanine nucleotides inhibited labeling with the relative potency GTP gamma S much greater than GDP greater than GTP greater than Gpp(NH)p. The 44 000-dalton protein was membrane bound irrespective of variations in ionic strength and divalent ion concentration over a wide range. These results suggest that a G protein, which incorporates both GTP binding and hydrolysis functions, is intimately involved in the visual process of invertebrate photoreceptors.