Aquaporin 0-calmodulin interaction and the effect of aquaporin 0 phosphorylation.

Aquaporin 0 (AQP0), also known as major intrinsic protein of lens, is the most abundant membrane protein in the lens and it undergoes a host of C-terminally directed posttranslational modifications. The C-terminal region containing the major phosphorylation sites is a putative calmodulin-binding site, and calmodulin has been shown to regulate AQP0 water permeability. The purpose of the present study was to elucidate the role of AQP0 phosphorylation on calmodulin binding. AQP0 C-terminal peptides were synthesized with and without serine phosphorylation on S231 and S235, and the ability of these peptides to bind dansyl-labeled calmodulin and the calcium dependence of the interaction was assessed using a fluorescence binding assay. The AQP0 C-terminal phosphorylated peptides were found to have 20-50-fold lower affinities for calmodulin than the unphosphorylated peptide. Chemical cross-linking studies revealed specific sites of AQP0-calmodulin interaction that are significantly reduced by AQP0 phosphorylation. These data suggest that AQP0 C-terminal phosphorylation affects calmodulin binding in vivo and has a role in regulation of AQP0 function.

Identification of a region in G protein gamma subunits conserved across species but hypervariable among subunit isoforms.

The heterotrimeric GTP binding proteins, G proteins, consist of three distinct subunits: alpha, beta, and gamma. There are 12 known mammalian gamma subunit genes whose products are the smallest and most variable of the G protein subunits. Sequencing of the bovine brain gamma(10) protein by electrospray mass spectrometry revealed that it differs from the human protein by an Ala to Val substitution near the N-terminus. Comparison of gamma isoform subunit sequences indicated that they vary substantially more at the N-terminus than at other parts of the protein. Thus, species variation of this region might reflect the lack of conservation of a functionally unimportant part of the protein. Analysis of 38 gamma subunit sequences from four different species shows that the N-terminus of a given gamma subunit isoform is as conserved between different species as any other part of the protein, including highly conserved regions. These data suggest that the N-terminus of gamma is a functionally important part of the protein exhibiting substantial isoform-specific variation.

Identification of Gbetagamma binding sites in the third intracellular loop of the M(3)-muscarinic receptor and their role in receptor regulation.

Gbetagamma binds directly to the third intracellular (i3) loop subdomain of the M(3)-muscarinic receptor (MR). In this report, we identified the Gbetagamma binding motif and G-protein-coupled receptor kinase (GRK2) phosphorylation sites in the M(3)-MR i3 loop via a strategy of deletional and site-directed mutagenesis. The Gbetagamma binding domain was localized to Cys(289)-His(330) within the M(3)-MR-Arg(252)-Gln(490) i3 loop, and the binding properties (affinity, influence of ionic strength) of the M(3)-MR-Cys(289)-His(330) i3 loop subdomain were similar to those observed for the entire i3 loop. Site-directed mutagenesis of the M(3)-MR-Cys(289)-His(330) i3 loop subdomain indicated that Phe(312), Phe(314), and a negatively charged region (Glu(324)-Asp(329)) were required for interaction with Gbetagamma. Generation of the full-length M(3)-MR-Arg(252)-Gln(490) i3 peptides containing the F312A mutation were also deficient in Gbetagamma binding and exhibited a reduced capacity for phosphorylation by GRK2. A similar, parallel strategy resulted in identification of major residues ((331)SSS(333) and (348)SASS(351)) phosphorylated by GRK2, which were just downstream of the Gbetagamma binding motif. Full-length M(3)-MR constructs lacking the 42-amino acid Gbetagamma binding domain (Cys(289)-His(330)) or containing the F312A mutation exhibited ligand recognition properties similar to wild type receptor and also effectively mediated agonist-induced increases in intracellular calcium following receptor expression in Chinese hamster ovary and/or COS 7 cells. However, the M(3)-MRDeltaCys(289)-His(330) and M(3)-MR(F312A) constructs were deficient in agonist-induced sequestration, indicating a key role for the Gbetagamma-M(3)-MR i3 loop interaction in receptor regulation and signal processing.

The relationship of G(o)alpha subunit deamidation to the tissue distribution, nucleotide binding properties, and betagamma dimer interactions of G(o)alpha subunit isoforms.

The distribution and properties in brain of the alpha subunits of the major bovine brain Go isoforms, GoA, GoB and GoC, were characterized. The alpha(o)A and alpha(o)B isoforms arise from alternative splicing of RNAs from a single alpha(o) gene, whereas alpha(o)C is a deamidated form of alpha(o)A. All three Go isoforms purify from brain with different populations of betagamma dimers. This variable subunit composition of Go heterotrimers is likely a consequence of their functional differences. This study examined the biochemical properties of the alpha(o) isoforms to see if these properties explain the variable betagamma composition of their heterotrimers. The brain distribution of alpha(o)B differed substantially from that of alpha(o)A and alpha(o)C, as did its guanine nucleotide binding properties. The unique subunit composition of GoB can be explained by its expression in different brain regions. The alpha(o)A and alpha(o)C showed slight differences in guanine nucleotide binding properties but no preference for particular betagamma dimers when reassociated with a heterogeneous betagamma pool. The alpha(o)C protein occurred in a constant ratio to alpha(o)A throughout the brain, but was a much larger percent of total brain alpha(o) than previously thought, approximately 35%. These results suggest that alpha(o)A is a precursor of alpha(o)C and that the association of G(o)alpha subunits with different betagamma dimers reflects the function of an adaptive, G-protein signaling mechanism in brain.

The N54 mutant of Galphas has a conditional dominant negative phenotype which suppresses hormone-stimulated but not basal cAMP levels.

The phenotype of a Ser to Asn mutation at position 54 of the alpha subunit of G(s)(N54-alpha(s)) was characterized in transient transfection experiments in COS and HEK293 cells. Expression of either wild type or N54-alpha(s) increased basal cAMP levels. In contrast, expression of wild type alpha(s), potentiated agonist-stimulated cAMP levels, while expression of N54-alpha(s)caused a decrease. Thus, the N54-alpha(s) mutant possesses a conditional dominant negative phenotype, suppressing preferentially hormone-stimulated effects.

Characterization of the major bovine brain Go alpha isoforms. Mapping the structural differences between the alpha subunit isoforms identifies a variable region of the protein involved in receptor interactions.

Go is the major G protein in bovine brain, with at least three isoforms, GoA, GoB, and GoC. Whereas alphaoA and alphaoB arise from a single Goalpha gene as alternatively spliced mRNAs, alphaoA and alphaoC are thought to differ by covalent modification. To test the hypothesis that alphaoA and alphaoC have different N-terminal lipid modifications, proteolytic fragments of alphao isoforms were immunoprecipitated with an N terminus-specific antibody and analyzed by matrix-assisted laser desorption ionization mass spectrometry. The major masses observed in immunoprecipitates were the same for all three alphao isoforms and corresponded to the predicted mass of a myristoylated N-terminal fragment. Structural differences between alphaoA and alphaoC were also compared before and after limited tryptic proteolysis using SDS-polyacrylamide gel electrophoresis containing 6 M urea. Based upon the alphao subunit fragments produced under activating and nonactivating conditions, differences between alphaoA and alphaoC were localized to a C-terminal fragment of the protein. This region, involved in receptor and effector interactions, implies divergent signaling roles for these two alphao proteins. Finally, the structural difference between alphaoA and alphaoC is associated with a difference of at most 2 daltons based upon measurements by electrospay ionization mass spectrometry.

A major G protein alpha O isoform in bovine brain is deamidated at Asn346 and Asn347, residues involved in receptor coupling.

The structural differences between two major forms of the alpha subunit of the heterotrimeric G protein GO were found to be due to deamidation of either of two Asn residues near the C-terminus of the proteins, in a region involved in receptor recognition. GO is the most abundant heterotrimeric G protein in mammalian brain. Two forms of the protein, GOA and GOB, are known to be generated by alternative splicing of a single GOalpha gene. A third isoform, alphaOC, represents about 1/3 of the alphaO protein in brain and is related to alphaOA, from which it is thought to be generated by protein modification. Mass spectrometry and chemical derivatization of tryptic fragments of the proteins were used to localize the structural difference between alphaOA and alphaOC to a C-terminal peptide. Sequence analysis of a C-terminal chymotryptic fragment both by ion trap mass spectrometry and by Edman degradation identified Asn346 and Asn347 of alphaOA as alternative deamidation sites in alphaOC. These structural differences have immediate implications for G protein function, as they occur in a conformationally sensitive part of the protein involved in receptor recognition and activation. Since Asn347 is a conserved residue present in most G protein alpha subunits outside the alphas family, these observations may have general significance for many G proteins. Deamidation may be a component of a novel process for modifying or adapting cellular responses mediated by G proteins.

Heterogeneous processing of a G protein gamma subunit at a site critical for protein and membrane interactions.

The G protein gamma5 subunit is selectively associated with specific G protein alpha subunits [Wilcox, M. D., et al. (1995) J. Biol. Chem. 270, 4189] and is localized preferentially in focal adhesion plaques [Hansen, C. A., et al. (1996) J. Cell Biol. 126, 811]. What determines the differential association of G proteins and their subunits with specific cellular structures or compartments is not clear, but one factor could be variation in the pattern of processing of the proteins. To study gamma5 subunit diversity and modifications, G protein subunits were fractionated on an HPLC phenyl column and analyzed with a gamma5-specific antiserum. The gamma5 eluted from the column as two peaks of immunoreactivity. Analysis by matrix-assisted laser desorption ionization (MALDI) mass spectrometry and electrospray ionization tandem mass spectrometry revealed that the first immunoreactive peak corresponded to the predicted gamma5 isoform (N-terminally acetylated after removal of methionine, C-terminally geranylgeranylated and carboxymethylated with removal of the last three amino acids), while the second peak of immunoreactivity contained a gamma5 isoform isoprenylated at the C-terminus but retaining its three terminal amino acids. This alternatively processed protein is the predominant gamma5 subunit isoform associated with Go and Gi proteins purified from bovine brain. These results describe a new C-terminal processing pattern for G protein gamma subunits and establish the principle that G protein gamma subunits can be heterogeneously modified at their C-termini. This is a site on the gamma subunit critical for membrane and protein-protein interactions of G proteins. These results open the possibility that one determinant of the localization of G proteins in cells could be the pattern of processing of their gamma subunit constituents.

Receptor docking sites for G-protein betagamma subunits. Implications for signal regulation.

We report the direct interaction of Gbetagamma with the third intracellular (i3) loop of the M2- and M3-muscarinic receptors (MR) and the importance of this interaction relative to effective phosphorylation of the receptor subdomain. The i3 loop of the M2- and the M3-MR were expressed in bacteria and purified as glutathione S-transferase fusion proteins for utilization as an affinity matrix and to generate substrate for receptor subdomain phosphorylation. In its inactive heterotrimeric state stabilized by GDP, brain G-protein did not associate with the i3 peptide affinity matrix. However, stimulation of subunit dissociation by GTPgammaS/Mg2+ resulted in the retention of Gbetagamma, but not the Galpha subunit, by the M2- and M3-MR i3 peptide resin. Purified Gbetagamma bound to the M3-MR i3 peptide with an apparent affinity similar to that observed for the Gbetagamma binding domain of the receptor kinase GRK2 and Bruton tyrosine kinase, whereas transducin betagamma was not recognized by the M3-MR i3 peptide. Effective phosphorylation of the M3-MR peptide by GRK2 required both Gbetagamma and lipid as is the case for the intact receptor. Incubation of purified GRK2 with the i3 peptide in the presence of Gbetagamma resulted in the formation of a functional ternary complex in which Gbetagamma served as an adapter protein. Such a complex provides a mechanism for specific spatial translocation of GRK2 within the cell positioning the enzyme on its substrate, the activated receptor. The apparent ability of Gbetagamma to act as a docking protein may also serve to provide an interface for this class of membrane-bound receptors to an expanded array of signaling pathways.

Role of subunit diversity in signaling by heterotrimeric G proteins.

The heterotrimeric G proteins are extensively involved in the regulation of cells by extracellular signals. The receptors that control them are often the targets of drugs. There are many isoforms of each of the three subunits that make up these proteins. Thus far, genes for at least sixteen alpha subunits, five beta subunits, and eleven gamma subunits have been identified. In addition, some of these proteins have splice variants or are differentially modified. Based upon what is already known, there are well over a thousand possible G protein heterotrimer combinations. The role of subunit diversity in heterotrimer formation and its effect on signaling by G proteins are still not well understood. However, many current lines of research are leading toward an understanding of these roles. The functional significance of subunit heterogeneity is related to the mechanisms used by G proteins to transmit and integrate the many signals coming into cells through this system. Described here are the basic mechanisms by which G proteins integrate cellular responses, the possible role of subunit heterogeneity in these mechanisms, and the evidence for and against their physiological significance. Recent studies suggest the likely possibility that subunit heterogeneity plays an important role in signaling by G proteins. This role has the potential to extend substantially the flexibility of G proteins in mediating cellular responses to extracellular signals. However, the details of this are yet to be worked out, and they are the subject of many different avenues of research.

A surface on the G protein beta-subunit involved in interactions with adenylyl cyclases.

Receptor activation of heterotrimeric G proteins dissociates G alpha from the G betagamma complex, allowing both to regulate effectors. Little is known about the effector-interaction regions of G betagamma. We had used molecular modeling to dock a peptide encoding the region of residues 956-982 of adenylyl cyclase (AC) 2 onto Gbeta to identify residues on Gbeta that may interact with effectors. Based on predictions from the model, we synthesized peptides encoding sequences of residues 86-105 (Gbeta 86-105) and 115-135 (Gbeta 115-135) from Gbeta. The Gbeta 86-105 peptide inhibited G betagamma stimulation of AC2 and blocked G betagamma inhibition of AC1 and by itself inhibited calmodulin-stimulated AC1, thus displaying partial agonist activity. Substitution of Met-101 with Asn in this peptide resulted in the loss of both the inhibitory and partial agonist activities. Most activities of the Gbeta 115-135 peptide were similar to those of Gbeta 86-105 but Gbeta 115-135 was less efficacious in blocking G betagamma inhibition of AC1. Substitution of Tyr-124 with Val in the Gbeta 115-135 peptide diminished all of its activities. These results identify the region encoded by amino acids 84-143 of Gbeta as a surface that is involved in transmitting signals to effectors.

Characterization of a G-protein activator in the neuroblastoma-glioma cell hybrid NG108-15.

Purified bovine brain G-protein was used in a solution phase assay to identify membrane-associated proteins that influenced the activation of heterotrimeric G-proteins. Detergent-solubilized membrane extracts from the neuroblastoma-glioma cell hybrid NG108-15, but not the parent C6B4 glioma cell line, increased [35S]GTPgammaS binding to purified G-protein by approximately 460%. The G-protein activator was heat-sensitive, and the magnitude of its action was related to the amount of extract protein. The biophysical and biochemical properties of the G-protein activator were determined using DEAE ion exchange chromatography, gel filtration, and a lectin affinity matrix. In the presence of added GDP (1 microM), the enriched G-protein activator increased the initial rate of [35S]GTPgammaS binding to brain G-protein by up to 4-fold. In the absence of added GDP, the G-protein activator elicited an initial burst in [35S]GTPgammaS binding to brain G-protein within the first 30 s, after which the rate of nucleotide binding to G-protein was similar in the absence or presence of the G-protein activator. The stimulation of nucleotide binding to brain G-protein by the activator was also observed after resolution of Galpha from Gbetagamma. The G-protein activator was distinct from other proteins (neuromodulin, tubulin, and beta-amyloid precursor protein) that influence nucleotide binding to G-protein, indicating the existence of a novel signal accelerator.

Gbeta subunit interacts with a peptide encoding region 956-982 of adenylyl cyclase 2. Cross-linking of the peptide to free Gbetagamma but not the heterotrimer.

The region encoded by amino acids 956-982 of adenylyl cyclase 2 is important for Gbetagamma stimulation. Interactions of a peptide encoding the 956-982 region of adenylyl cyclase 2 (QEHAQEPERQYMHIGTMVEFAYALVGK (QEHA peptide)) with Gbetagamma subunits were studied. QEHA peptide was covalently attached to beta subunit of free Gbetagamma by the cross-linker N-succinimidyl(4-iodoacetyl)aminobenzoate. Cross-linking was proportional to the amount of QEHA peptide added; other control peptides cross-linked minimally. When Go was used, very little cross-linking was observed with GDP and EDTA, but upon activation by guanosine 5'-3-O-(thio)triphosphate and Mg2+, specific cross-linking of the QEHA peptide to Gbeta was observed. We conclude that beta subunits of G proteins contain effector interaction domains that are occluded by Galpha subunits in the heterotrimer. Molecular modeling studies used to dock the QEHA peptide on to Gbeta indicate that amino acids 75-165 of Gbeta may be involved in effector interactions.

Determination of the complete covalent structure of the gamma 2 subunit of bovine brain G proteins by mass spectrometry.

The complete covalent structure of the gamma 2 subunit of bovine brain G proteins was determined by peptide mapping using matrix-assisted laser desorption ionization and electrospray ionization mass spectrometry and by partial sequencing using tandem mass spectrometry. Fragments were identified in proteolytic digests corresponding to all predicted internal sequences of gamma 2, but not for N- or C-terminal sequences. Fragments consistent with modifications of the terminal peptides were observed, however. The presence of these postulated modifications was verified by tandem mass spectrometry. These studies define the structure of the native protein and provide a basis for comparison to expressed proteins.

Factors determining specificity of signal transduction by G-protein-coupled receptors. Regulation of signal transfer from receptor to G-protein.

Among subfamilies of G-protein-coupled receptors, agonists initiate several cell signaling events depending on the receptor subtype (R) and the type of G-protein (G) or effector molecule (E) expressed in a particular cell. Determinants of signaling specificity/efficiency may operate at the R-G interface, where events are influenced by cell architecture or accessory proteins found in the receptor's microenvironment. This issue was addressed by characterizing signal transfer from R to G following stable expression of the alpha 2A/D adrenergic receptor in two different membrane environments (NIH-3T3 fibroblasts and the pheochromocytoma cell line, PC-12). Receptor coupling to endogenous G-proteins in both cell types was eliminated by pertussis toxin pretreatment and R-G signal transfer restored by reconstitution of cell membranes with purified brain G-protein. Thus, the receptor has access to the same population of G-proteins in the two different environments. In this signal restoration assay, agonist-induced activation of G was 3-9-fold greater in PC-12 as compared with NIH-3T3 alpha 2-adrenergic receptor transfectants. The cell-specific differences in signal transfer were observed over a range of receptor densities or G-protein concentration. The augmented signal transfer in PC-12 versus NIH-3T3 transfectants occurred despite a 2-3-fold lower level of receptors existing in the R-G-coupled state (high affinity, guanyl-5'-yl imidodiphosphate-sensitive agonist binding), suggesting the existence of other membrane factors that influence the nucleotide binding behavior of G-protein in the two cell types. Detergent extraction of PC-12 but not NIH-3T3 membranes yielded a heat-sensitive, macromolecular entity that increased 35S-labeled guanosine 5'-O-(thiotriphosphate) binding to brain G-protein in a concentration-dependent manner. These data indicate that the transfer of signal from R to G is regulated by a cell type-specific, membrane-associated protein that enhances the agonist-induced activation of G.

Gi is involved in ethanol inhibition of L-type calcium channels in undifferentiated but not differentiated PC-12 cells.

The effects of acute exposure to 25 mM ethanol on high voltage-activated, L-type Ca2+ channels in undifferentiated and nerve growth factor-treated pheochromocytoma (PC-12) cells were examined using conventional, whole-cell, patch-clamp techniques. Acute exposure to 25 mM ethanol inhibited macroscopic L-type Ca2+ currents in undifferentiated PC-12 cells significantly more than in nerve growth factor-treated PC-12 cells. Intracellular infusion with guanosine-5'-O-(2-thio)diphosphate or pretreatment with pertussis toxin reduced ethanol inhibition in undifferentiated cells without altering inhibition in nerve growth factor-treated cells, suggesting the involvement of a G protein in ethanol inhibition of Ca2+ channels in undifferentiated cells. Intracellular infusion with an affinity-purified antibody that recognizes the carboxyl termini of alpha i1 and alpha i2 significantly reduced ethanol inhibition in undifferentiated cells, in contrast to the effects of antibodies that recognize the carboxyl termini of alpha oA and alpha oB. None of these antibodies reduced ethanol inhibition in nerve growth factor-treated cells. These results indicate that Gi1 alpha or Gi2 alpha mediates ethanol inhibition of L-type Ca2+ channel currents in undifferentiated but not in nerve growth factor-treated PC-12 cells.

Bovine brain GO isoforms have distinct gamma subunit compositions.

The gamma subunit composition of the major bovine brain Go and Gi proteins (GOA, GOB, GOC, Gi1, and Gi2) was characterized using antibodies against specific gamma isoforms. Each of the purified G protein heterotrimers contained a heterogeneous population of gamma subunits, and the profiles of the gamma subunits found with Gi1, Gi2, and GOA were similar. In contrast, each GO isoform had a distinct pattern of associated gamma subunits. These differences were surprising given that all three alpha O isoforms are thought to share a common amino-terminal sequence important for the binding of beta gamma dimers and that the alpha OA and alpha OC proteins may come from the same alpha O1 mRNA. The free alpha OA and alpha OC subunits had unique elution behaviors during MonoQ chromatography, compatible with differences in their post-translational processing. These results indicate that both the alpha and gamma subunit compositions of heterotrimers define the structure of an intact G protein. Furthermore, the exact subunit composition of G protein heterotrimers may depend upon regulated expression of different subunit isoforms or upon cellular processing of alpha subunits.

Analysis of G protein gamma subunit heterogeneity using mass spectrometry.

The diversity of the gamma subunits in bovine brain G protein preparations was investigated using matrix-assisted laser desorption ionization (MALDI) mass spectrometry. Analysis of these G protein mixtures revealed at least four gamma subunit masses by the following four criteria. 1) The measured masses were in the same mass range as the predicted molecular weights of gamma isoforms. 2) The masses were reproducible between the same or different preparations of G proteins. 3) The masses were independent of the matrix used for MALDI analysis. 4) The masses comigrated with the gamma subunit, as part of the heterotrimer, the beta gamma dimer, or the separated gamma subunit. These measured masses were compared with those calculated from cDNA sequences of known bovine brain gamma isoforms with the addition of plausible post-translational modifications. The mass of each spectral peak was consistent with the calculated mass for only one of four known bovine brain gamma subunit isoforms, but the data suggest modifications of the gamma subunits in addition to those already known or suspected at their carboxyl termini. Besides these four major masses, several additional, less resolved spectral peaks were observed whose measured masses did not correlate with any known gamma subunit or plausible modification. MALDI mass spectrometry promises to be a powerful technique for the analysis of the diversity of the gamma subunit in G proteins and for the characterization of their post-translational modifications.

The effect of pertussis toxin on the growth of vascular smooth muscle cells stimulated by serum or platelet-derived growth factor.

The involvement of a Gi- or G(o)-related G-protein as a regulator of the growth of guinea pig thoracic aorta smooth muscle (TASM) cells was studied by investigating the effects of pertussis toxin (PTX) on the growth of these cells. PTX treatment decreased the growth rate of TASM cells by 70-100%. This effect was apparent within 24 h after exposure to the toxin and persisted for at least 10 days after starting the treatment. The effect of the toxin appeared to be the result of the inactivation of a G-protein because 1) TASM cell membranes contained a 40-kilodalton substrate for the toxin in in vitro assays that was absent in membranes prepared from cells pretreated with toxin; and 2) the effect required both the enzymatic component (A-protomer) of the toxin that inactivates Gi/G(o)-related G-proteins and its B-oligomer necessary for binding and internalization of the A-protomer. The effect of the toxin was not due to an increased level of intracellular cAMP brought about by inactivation of a G-protein that normally inhibits adenylyl cyclase activity. Further, the toxin did not merely make some unknown mitogen rate limiting, because neither increasing concentrations of serum in the growth medium nor supplementation with platelet-derived growth factor could overcome its inhibition of TASM cell growth. Instead, some unknown process regulated by a PTX-sensitive G-protein appears to be required for the normal growth of these cells.