Conversion of GDP into GTP by nucleoside diphosphate kinase on the GTP-binding proteins

A direct interaction of alpha beta gamma trimeric GTP binding proteins (G proteins; G0 and Gs) with nucleoside diphosphate kinase (NDP kinase) was investigated with homogeneously purified proteins. There was a progressive release of 32Pi from [gamma-32P]ATP when GDP-bound G0 was incubated together with NDP kinase. The Pi release induced by the interaction of G0 with NDP kinase was not accompanied by the dissociation of GDP bound to the alpha-subunit of G0. This was a sharp contrast to G protein-catalyzed GTP hydrolysis observed with GTP as the substrate; the dissociation of bound GDP was essentially required for the following binding of the substrate, GTP, to be hydrolyzed. A kinetic analysis displayed different properties for the substrate of NDP kinase between free GDP and G protein-bound GDP. NDP kinase-dependent phosphorylation of GDP on G0 was indeed demonstrated with adenosine 5'-(3-O-thio)triphosphate as the phosphate donor; there was a formation of guanosine 5'-(3-O-thio)triphosphate-bound G0 from the ATP analogue. Moreover, purified Gs was readily ADP-ribosylated by cholera toxin in the presence of NDP kinase, ATP, and an ADP-ribosylation factor, also suggesting that the nucleotide form on Gs was certainly GTP. These results indicate that NDP kinase can transfer the gamma-phosphate of ATP directly to GDP bound to G proteins and that this phosphorylation results in the activation of the signal-coupling proteins. A possible role of the new activation mechanism of G proteins is discussed in comparison with the previously characterized GDP-GTP exchange pathway by the agonist-receptor complex.     

High energy phosphate transfer by NDPK B/Gβγcomplexes - an alternative signaling pathway involved in the regulation of basal cAMP production

The activation of heterotrimeric G proteins induced by G protein coupled receptors (GPCR) is generally believed to occur by a GDP/GTP exchange at the G protein α -subunit. Nevertheless, nucleoside diphosphate kinase (NDPK) and the β-subunit of G proteins (Gβ) participate in G protein activation by phosphate transfer reactions leading to the formation of GTP from GDP. Recent work elucidated the role of these reactions. Apparently, the NDPK isoform B (NDPK B) forms a complex with β; γ; dimers in which NDPK B acts as a histidine kinase phosphorylating G#x03B2; at His266. Out of this high energetic phosphoamidate bond the phosphate can be transferred specifically onto GDP. The formed GTP binds to the G protein α -subunit and thus activates the respective G protein. Evidence is presented, that this process occurs independent of the classical GPCR-induced GTP/GTP exchange und thus contributes, e.g. to the regulation of basal cAMP synthesis in cells.     

Tubulin-associated nucleoside diphosphokinase.

Microtubule protein, prepared by cycles of polymerisation and dissociation, contained a nucleoside diphosphokinase (NDP kinase) activity (EC 2.7.4.6). This activity was not intrinsic to the tubulin dimer or the so-called microtubule-associated proteins. The NDP kinase had the following properties. (1) The enzyme existed in a low-molecular-weight form and in association with the complex of microtubule-associated proteins and tubulin (i.e. multimeric tubulin). (2) The low-molecular-weight species was also formed by dissociation of multimeric tubulin by salt or by removal of microtubule-associated proteins on phosphocellulose. (3) GDP bound to the exchangeable site of multimeric tubulin and also GDP derived from the E site of the tubulin dimer was a substrate for the NDP kinase. (4) The NDP kinase showed a 7-fold increase in activity during ATP-dependent microtubule assembly. On the basis of these properties, it is proposed that microtubule protein contains an NDP kinase specifically associated with tubulin and its functions.     

Subcellular Localization and Characterization of Nucleoside Diphosphate Kinase in Rat Retina: Effect of Diabetes

Nucleoside diphosphate kinase (NDP kinase) catalyzes the transfer of terminal phosphate from nucleotide triphosphates (e.g. ATP) to nucleotide diphosphates (e.g. GDP) to yield nucleotide triphosphates (e.g. GTP). Since guanine nucleotides play critical role(s) in GTP-binding protein (G-protein)-mediated signal transduction mechanisms in retina, we quantitated NDP kinase activity in subcellular fraction-derived from normal rat retina. A greater than 85% of the total specific activity was present in the soluble fraction, which was stimulated (up to 7 fold) by 2 mM magnesium. NDP kinase exhibited saturation kinetics towards di- and tri-phosphate substrates, and was inhibited by known inhibitors of NDP kinase, uridine diphosphate (UDP) or cromoglycate (CRG). We have previously reported significant abnormalities in the activation of G-proteins in streptozotocin (STZ)-diabetic rat retina (Kowluru et al. Diabetologia 35:624–631, 1992). Since NDP kinase hasbeen implicated in direct interaction with and/or activation of various G-proteins, we quantitated both basal and magnesium-stimulated NDP kinase activity in soluble and particulate fractions of retina derived from STZ-diabetic rats to examine whether abnormalities in G-protein function in diabetes are attributable to alterations in retinal NDP kinase. There was no effect of diabetes either on the basal or the magnesium-activated retinal NDP kinase activity. This study represents the first characterization of NDP kinase activity in rat retina, and suggests that in diabetes, this enzyme may not be rate-limiting and/or causal for the observed alterations in retinal G-protein functions.     

Nucleoside diphosphate kinase from haloalkaliphilic archaeon Natronobacterium magadii: purification and characterization

An ATP-binding protein from the haloalkaliphilic archaeon Natronobacterium magadii was purified and characterized by affinity chromatography on ATP-agarose and by fast protein liquid chromatography (FPLC) on a Mono Q column. The N-terminal 20 amino acid sequence of the kinase showed a strong sequence similarity of this protein with nucleoside diphosphate (NDP) kinases from different organisms and, accordingly, we believe that this protein is a nucleoside diphosphate kinase, an enzyme whose main function is to exchange γ-phosphates between nucleoside triphosphates and diphosphates. Comparison of the molecular weights of the NDP kinase monomer determined by sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE) (23 000) and of the oligomer determined by sedimentation equilibrium experiments (125 000) indicated that the oligomer is a hexamer. The enzyme was autophosphorylated in the presence of [γ-³²P]ATP, and Mg²⁺ was required for the incorporation of phosphate. The kinase preserved the ability to transfer γ-phosphate from ATP to GDP in the range of NaCl concentration from 90 mM to 3.5 M and in the range of pH from 5 to 12. It was found and confirmed by Western blotting that this kinase is one of the proteins that bind specifically to natronobacterial flagellins. NDP kinase from haloalkaliphiles appeared to be simple to purify and to be a suitable enzyme for studies of structure and stability compared with NDP kinases from mesophilic organisms. Received: December 3, 1997 / Accepted: January 29, 1998     

Nm23-H1/NDP kinase folding intermediates and cancer: a hypothesis

The Nm23-H1/nucleoside diphosphate (NDP) kinase A is a metastasis suppressor, besides its enzymatic activity. The mutant S120G has been found in high-grade neuroblastomas. The mutant protein, once denatured in urea, is unable to refold in vitro. A size-exclusion chromatography analysis of the folding/association pathway showed that recombinant wild-type and S120G mutant human Nm23-H1/NDP kinase A unfold and refold passing through a molten globule state while typical hexameric NDP kinases unfold without dissociated species and refold through a native monomeric intermediate. A survey of the recent literature showed that several proteins involved in cancer, and their mutants, are marginally stable, like the wild-type Nm23-H1/NDP kinase A, or are misfolded, like its S120G mutant. We therefore suggest that the low thermodynamic stability and the folding intermediate of the Nm23-H1/NDP kinase A may be necessary for its regulatory properties.     

Nucleoside diphosphate kinases in mammalian signal transduction systems: recent development and perspective

The role of nucleoside diphosphate (NDP) kinase with special reference to mammalian signal transduction systems was described. The interaction between NDP kinases and G proteins was reevaluated in view of their protein structural information and its significance was extended further on the basis of recent findings obtained with small molecular weight G proteins such as Rad, menin, and Rac. Meanwhile, observations suggesting involvement of NDP kinases in the regulation of cell growth and differentiation led to the realization that NDP kinases may play a crucial role in receptor tyrosine kinase signal transduction systems. In fact, a number of experimental results, particularly obtained with PC12 cells, implicate that NDP kinases appear to regulate differentiation marker proteins and cell-cycle-associated proteins cooperatively. Consequently, we propose a hypothesis that NDP kinases might act like a molecular switch to determine the cell fate toward proliferation or differentiation in response to environmental signals.     

Investigation of chimerical and tagged forms of recombinant rat nucleoside diphosphate kinases α and β. Interaction with rhodopsin—transducin complex and thermal stability

To elucidate the physicochemical basis of differences between the isoforms of mammalian multifunctional nucleoside diphosphate kinase (NDP), we investigated the recombinant rat homohexameric NDP kinases alpha and beta, consisting of highly homologous alpha or beta subunits of 152 residues each and differing only in variable regions V1 and V2, and their chimerical forms (NDP kinase alpha(1-130)beta(131-152) and NDP kinase beta(1-130)alpha(131-152)) and tagged derivatives (NDP kinase HA-alpha(1-130)beta(131-152), NDP kinase HA-beta(1-130)alpha(131-152), and NDP kinase HA-beta). The thermal stability of these proteins and the ability of some of them to interact with the rhodopsin-transducin (R*Gt) complex have been studied. It was found that NDP kinase alpha, NDP kinase alpha(1-130)beta(131-152), and NDP kinase HA-alpha(1-130)beta(131-152) were similar in their thermal stability (T(1/2) = 61-63 degrees C). NDP kinase beta, NDP kinase beta(1-130)alpha(131-152), NDP kinase HA-beta(1-130)alpha(131-152), and NDP kinase HA-beta were inactivated at a lower temperature (T(1/2) = 51-54 degrees C). NDP kinase HA-alpha(1-130)beta(131-152) interacted with the R*Gt complex in the same manner as NDP kinase alpha, whereas the interaction of NDP kinase HA-beta(1-130)alpha(131-152) and NDP kinase beta with the photoreceptor membranes under the same conditions was very weak. It is suggested that the variability of the region V1 is a structural basis for the multifunctionality of NDP kinase hexamers in the cell.     

Activation of G-proteins by receptor-stimulated nucleoside diphosphate kinase in Dictyostelium.

Recently, interest in the enzyme nucleoside diphosphate kinase (EC2.7.4.6) has increased as a result of its possible involvement in cell proliferation and development. Since NDP kinase is one of the major sources of GTP in cells, it has been suggested that the effects of an altered NDP kinase activity on cellular processes might be the result of altered transmembrane signal transduction via guanine nucleotide-binding proteins (G-proteins). In the cellular slime mould Dictyostelium discoideum, extracellular cAMP induces an increase of phospholipase C activity via a surface cAMP receptor and G-proteins. In this paper it is demonstrated that part of the cellular NDP kinase is associated with the membrane and stimulated by cell surface cAMP receptors. The GTP produced by the action of NDP kinase is capable of activating G-proteins as monitored by altered G-protein-receptor interaction and the activation of the effector enzyme phospholipase C. Furthermore, specific monoclonal antibodies inhibit the effect of NDP kinase on G-protein activation. These results suggest that receptor-stimulated NDP kinase contributes to the mediation of hormone action by producing GTP for the activation of GTP-binding proteins.     

Structural Evidence for a Sequential Release Mechanism for Activation of Heterotrimeric G Proteins

Heptahelical G-protein (heterotrimeric guanine nucleotide-binding protein)-coupled receptors couple to heterotrimeric G proteins to relay extracellular signals to intracellular signaling networks, but the molecular mechanism underlying guanosine 5′-diphosphate (GDP) release by the G protein α-subunit is not well understood. Amino acid substitutions in the conserved α5 helix of G_i, which extends from the C-terminal region to the nucleotide-binding pocket, cause dramatic increases in basal (receptor-independent) GDP release rates. For example, mutant Gα_i1-T329A shows an 18-fold increase in basal GDP release rate and, when expressed in culture, it causes a significant decrease in forskolin-stimulated cAMP accumulation. The crystal structure of Gα_i1-T329A·GDP shows substantial conformational rearrangement of the switch I region and additional striking alterations of side chains lining the catalytic pocket that disrupt the Mg⁺² coordination sphere and dislodge bound Mg⁺². We propose a “sequential release” mechanism whereby a transient conformational change in the α5 helix alters switch I to induce GDP release. Interestingly, this mechanistic model for heterotrimeric G protein activation is similar to that suggested for the activation of the plant small G protein Rop4 by RopGEF8.     

Phosphotransfer reactions as a means of G protein activation

Heterotrimeric guanine nucleotide-binding regulatory proteins (G proteins) serve to transduce information from agonist-bound receptors to effector enzymes or ion channels. Current models of G protein activation-deactivation indicate that the oligomeric GDP-bound form must undergo release of GDP, bind GTP and undergo subunit dissociation, in order to be in active form (GTP bound subunits and free dimers) and to regulate effectors. The effect of receptor occupation by an agonist is generally accepted to be promotion of guanine nucleotide exchange thus allowing activation of the G protein. Recent studies indicate that transphosphorylation leading to the formation of GTP from GDP and ATP in the close vicinity, or even at the G protein, catalysed by membrane-associated nucleoside diphosphate kinase, may further activate G proteins. This activation is demonstrated by a decreased affinity of G protein-coupled receptors for agonists and an increased response of G protein coupled effectors. In addition, a phosphorylation of G protein subunits and consequent phosphate transfer reaction resulting in G protein activation has also been demonstrated. Finally, endogenously formed GTP was preferentially effective in activating some G proteins compared to exogenous GTR The aim of this report is to present an overview of the evidence to date for a transphosphorylation as a means of G protein activation (see also refs [1 and 2] for reviews). (Mol Cell Biochem 157: 593, 1996)Recipient of Servier Investigator Award     

Microtubules and nucleoside diphosphate kinase. Nucleoside diphosphate kinase binds to co-purifying contaminants rather than to microtubule proteins.

Nucleoside diphosphate (NDP) kinase has been postulated to generate GTP from the GDP bound to tubulin. The purified chick brain enzyme was studied with respect to its kinetic parameters, and the protein-protein interactions between the NDP kinase and tubulin were examined. No specific interaction is observed between the enzyme and assembled microtubules, tubulin dimers, or tubulin-microtubule-associated protein (MAP) oligomers under a variety of nucleotide conditions. The apparent association is demonstrated to result from NDP kinase binding to a co-purifying contaminant. The absence of detectable NDP kinase-tubulin interactions indicates that NDP kinase does not directly charge up tubulin-GDP.     

Viroporin-mediated calcium-activated autophagy

Autophagy is a cellular response activated by many pathogens, but the mechanism of activation is largely unknown. Recently we showed for the first time that rotavirus initiates the autophagy pathway through a calcium-mediated mechanism. Expression of the rotavirus-encoded NSP4, a pore-forming protein (viroporin), elicits the release of endoplasmic reticulum (ER) lumenal calcium into the cytoplasm of the infected cell. The increased cytoplasmic calcium activates a calcium signaling pathway involving calcium/calmodulin-dependent protein kinase kinase 2 (CAMKK2) and 5′ adenosine monophosphate-activated protein kinase (AMPK) to trigger autophagy. Rotavirus further manipulates autophagy membrane trafficking to transport viral ER-associated proteins to viroplasms, sites of viral genome replication and immature particle assembly. Transport of viral proteins to viroplasms is required for assembly of infectious virus. Thus, NSP4, a multifunctional viral protein known to regulate infectious particle assembly, also modulates membrane trafficking by orchestrating the activation of autophagy to benefit viral replication.     

ATP and guanine nucleotide dependence of neutrophil activation. Evidence for the involvement of two distinct GTP-binding proteins

In phagocytes, activation of the respiratory burst by chemoattractants requires ATP and involves a pertussis toxin-sensitive G protein. ATP is also required for the response elicited in permeabilized neutrophils by nonhydrolyzable GTP analogs, indicating that at least one of the ATP-dependent steps lies downstream of the receptor-coupled G protein(s). A respiratory burst can also be produced in a reconstituted cell-free system by addition of arachidonic acid. Most investigators find this response to be independent of ATP, yet stimulated by GTP analogs, implying that the ATP-dependent steps observed in the unbroken cells must precede the guanine nucleotide-requiring event. To resolve this apparent discrepancy, we studied the ATP and guanine nucleotide dependence of the oxidative response elicited by arachidonic acid in electrically permeabilized human neutrophils. Two components of the response were apparent: one was ATP-dependent, the other ATP-independent. The ATP-dependent component was partially inhibited by staurosporine, suggesting involvement of protein kinase C. This kinase signals activation of the NADPH oxidase without intervening G proteins, since stimulation by phorbol ester was unaffected by guanosine 5'-(beta-thio)diphosphate (GDP beta S). Although nonhydrolyzable GTP analogs failed to stimulate the oxidase in the absence of ATP, the ATP-independent response stimulated by arachidonic acid was found to require GTP or one of its analogs and to be inhibited by GDP beta S. The relative potency of the guanine nucleotides to support the arachidonic acid response in the absence of ATP (5'-guanylyl imidodiphosphate (GMP-PNP) greater than or equal to guanosine 5'-(gamma-thio)triphosphate GTP gamma S) greater than or equal to (GTP) differed from their efficacy to stimulate the burst in the presence of ATP (GTP gamma S greater than GMP-PNP much greater than GTP). These observations suggest the involvement of two distinct GTP-binding proteins in oxidase activation: a receptor-coupled, heterotrimeric, pertussis toxin-sensitive G protein, and a second GTP-binding protein(s) located downstream of the ATP-requiring steps, which may lie in close proximity to the NADPH oxidase. This secondary GTP-binding protein could be part of the pathway activated by chemoattractants, but does not mediate stimulation via protein kinase C. Therefore multiple parallel routes may exist for activation of the NADPH oxidase.     

Point mutations affecting the oligomeric structure of Nm23-H1 abrogates its inhibitory activity on colonization and invasion of prostate cancer cells

In order to identify Nm23-H1's structural motifs influencing its metastasis-inhibitory activity, we transfected DU 145 human prostate carcinoma cells with the expression vector encoding the Nm23-H1 protein with mutations at the following amino acids: serine-44, a phosphorylation site; proline-96, a site corresponding to the k-pn mutation that causes developmental defects in Drosophila; and serine-120, a site of mutation in human neuroblastoma and phosphorylation. Significant decrease in colonization in soft agar and invasiveness of DU 145 cells was observed in the wild type nm23-H1 transfectants, and also in the serine-44 and serine-120 to alanine mutant nm23-H1-transfected cell lines. However, the k-pn type proline-96 to serine (P96S) and neuroblastoma type serine-120 to glycine (S120G) mutations of Nm23-H1 abrogated its inhibitory activity on colonization and invasion. Meanwhile, all of the recombinant mutant Nm23-H1 proteins produced in Escherichia coli exhibited NDP kinase activity levels at the wild type protein, although the P96S and S120G mutant proteins exhibited decreased histidine protein kinase activity and autophosphorylation level, respectively. Interestingly, only two of the mutant recombinant Nm23-H1 proteins examined, P96S and S120G, exhibited reduced hexameric and increased dimeric oligomerization relative to the wild type. These correlative data suggest that the metastasis-suppressing activity of Nm23-H1 may depend on its oligomeric structure, but not on its NDP kinase activity.     

G protein activation by the leukotriene B4 receptor dimer. Evidence for an absence of trans-activation

There is compelling evidence that G protein-coupled receptors exist as homo- and heterodimers, but the way these assemblies function at the molecular level remains unclear. We used here the purified leukotriene B(4) receptor BLT1 stabilized in its dimeric state to analyze how a receptor dimer activates G proteins. For this, we produced heterodimers between the wild-type BLT1 and a BLT1/ALXR chimera. The latter is no longer activated by leukotriene B(4) but is still activated by ALXR agonists. In this heterodimer, agonist binding to either one of the two protomers induced asymmetric conformational changes within the receptor dimer. Of importance, no G protein activation was observed when using a dimer where the ligand-loaded protomer was not able to trigger GDP/GTP exchange due to specific mutations in its third intracellular loop, establishing that the conformation of the agonist-free protomer is not competent for G protein activation. Taken together, these data indicate that although ligand binding to one protomer in the heterodimer is associated with cross-conformational changes, a trans-activation mechanism where the ligand-free subunit would trigger GDP/GTP exchange cannot be considered in this case for G protein activation. This observation sheds light into the way GPCR dimers, in particular heterodimers, could activate their cognate G proteins.     

Nucleoside diphosphate kinase from Xenopus oocytes; partial purification and characterization

We have identified and partially purified a soluble nucleoside diphosphate kinase (NDP kinase) from Xenopus laevis oocytes. The enzyme preparation can catalyze the transfer of phosphate from ATP to all of the major oxy- and deoxynucleotides. It can also catalyze the transfer of a phosphorothioate group from gamma-S-ATP to an acceptor GDP forming gamma-S-GTP. Like NDP kinases from other sources, the catalytic mechanism appears to involve a phosphoenzyme intermediate which can be isolated. Transfer of phosphate from nucleoside triphosphates to protein is rapid, reaching saturation within 1 min following the addition of nucleoside triphosphates. The transfer of phosphate from phosphoprotein intermediate to nucleoside diphosphates is equally fast. While nucleoside diphosphate kinases are generally thought to require magnesium for activity, both the oocyte enzyme preparation and a commercial bovine liver enzyme preparation are only partially inhibited by short (10 min) exposures to 25 mM EDTA. Both enzyme preparations are, however, further inhibited by long incubations with this metal chelator (2 h, 70% inhibition). Zinc enhances the inhibition of NDP kinase by EDTA, but is ineffective on its own. Rapid phosphorylation in the presence of [gamma-32P]ATP and EDTA could be used to identify the phosphoenzyme intermediate in homogenates of Xenopus oocytes and facilitated its isolation. Sodium dodecyl sulfate polyacrylamide gel electrophoresis coupled with autoradiography indicated the presence of only a single phosphorylated species of Mr 21,500 in supernatants of fresh oocyte homogenates. Partial purification of this protein utilizing salt precipitation, hydrophobic-interaction chromatography and an affinity step with Affi-Gel Blue Sepharose resulted in a 100-fold purification and a 29% overall yield of NDP-kinase activity. Size-exclusion chromatography of the purified preparation yielded two peaks containing enzyme activity. They eluted with apparent molecular weights of 45,000 and 70,000, suggesting a native enzyme that is multimeric or associated with other proteins.     

Nucleoside diphosphate kinase from brain. Purification and effect on microtubule assembly in vitro

Tubulin strictly requires GTP for its polymerization. Nevertheless, microtubule assembly can be observed in the presence of ATP as the only nucleotide triphosphate, due to the nucleoside diphosphate kinase (NDP kinase) present in microtubule preparations, and which phosphorylates the GDP into GTP. We have purified this enzyme from pig brain to homogeneity, and shown that its relative mass is close to 100 000 in its native state, and 17 000 under denaturing conditions. Therefore it is probably a hexamer, as previously shown for the enzyme from other sources, and also presents a microheterogeneity, with the major isoforms between pI 5.0 and 6.0. The enzyme is transiently phosphorylated during catalysis, as expected within a ping-pong bi-bi mechanism. The effect of the NDP kinase on pure tubulin polymerization was studied: in the presence of NDP kinase, the lag time observed in the kinetics of microtubule assembly was shorter and the final extent of assembly was unchanged. The effect of the enzyme was observed at enzyme concentrations 900-fold lower than tubulin concentration, which shows that the NDP kinase acts catalytically. Kinetic data show that the catalytic effect of the NDP kinase is faster than the rate of nucleotide exchange on tubulin under the same conditions. This result demonstrates that the tubulin-GDP complex itself is a substrate for the enzyme, which may indicate that the GDP bound to tubulin at the E site is exposed on the surface of dimeric tubulin.     

Quaternary Structure of Nucleoside Diphosphate Kinases

Nucleoside (NDP) diphosphate kinases are oligomeric enzymes. Most are hexameric, but somebacterial enzymes are tetrameric. Hexamers and tetramers are constructed by assemblingidentical dimers. The hexameric structure is important for protein stability, as demonstratedby studies with natural mutants (the Killer-of-prune mutant ofDrosophila NDP kinase andthe S120G mutant of the human NDP kinase A in neuroblastomas) and with mutants obtainedby site-directed mutagenesis. It is also essential for enzymic activity. The function of the tetrameric structure is unclear.     

A GTP-binding protein activates chloride channels in a renal epithelium

Although G proteins have been shown to regulate cation channels, regulation of Cl- channels by G proteins has not been demonstrated directly. Accordingly, the objective of this study was to examine whether a G protein regulates Cl- channels in the apical membrane of rabbit kidney CCD cells grown in culture. Previous studies showed that this channel is activated by adenosine and protein kinase C and has a single channel conductance of 305 picosiemens. The PCl-:PNa+ is 9:1 and the PCl-:PHCO3- is 2:1 (Schwiebert, E.M., Light, D.B., Dietl, P., Fejes-Toth, G., Naray-Fejes-Toth, A., and Stanton, B. (1990) Kidney Int. 37,216). In the present study, Cl- channels in the apical membrane of CCD cells were studied by the patch clamp technique. GTP and guanosine 5'-O(3-thiophosphate) (GTP gamma S), a nonhydrolyzable analog of GTP, increased the single channel open probability (Po). In contrast, guanosine 5'-O-(2-thiophosphate), a nonhydrolyzable analog of GDP, and pertussis toxin (PTX) decreased the Po. GTP gamma S, but not GTP, reversed PTX inhibition of the channel. The alpha i-3-subunit of Gi increased the Po in both untreated and PTX-treated membrane patches. Because GTP gamma S activated the Cl- channel in the presence of H8, a protein kinase inhibitor, we conclude that the G protein does not activate the channel by stimulating a protein kinase. Thus, a PTX-sensitive G protein activates a Cl- channel in the apical membrane of renal CCD cells.