Expanding role of G proteins in tight junction regulation: Galpha(s) stimulates TJ assembly.

Multiple signaling mechanisms regulate epithelial cell tight junction (TJ) assembly and maintenance. Several G proteins are likely to regulate these processes, but only G(i/o) have been specifically tested. Treatment of MDCK cells with cholera toxin, a Galpha(s) activator, accelerated TJ development in the calcium switch as measured by the time to half-maximal [T(50) (H)] transepithelial resistance (TER). Galpha(s) was predominantly localized in the lateral membrane, but a fraction colocalizes with ZO-1 in the TJ. MDCK cell lines expressing epitope-tagged Galpha(s) and constitutively active (R201Calpha(s)) showed a similar localization. TJ assembly was significantly faster in R201Calpha(s)-MDCK cell lines (T(50) (H) of 1.7 versus 3.3 h for controls) without detectable differences in cAMP levels. Confocal studies showed R201Calpha(s)-MDCK cells more rapidly localized ZO-1 and occludin into the developing TJ without affecting E-cadherin or Na(+)/K(+) ATPase localization. Endogenous Galpha(s) and R201Calpha(s) were immunoprecipitated with ZO-1 at baseline and during TJ assembly. The data supports a model of multiple Galpha subunits interacting with TJ proteins to regulate the assembly and maintenance of the TJ.

Reassembly of the tight junction after oxidative stress depends on tyrosine kinase activity.

Oxidative stress compromises the tight junction, but the mechanisms underlying its recovery remain unclear. We developed a model in which oxidative stress reversibly disrupts the tight junction. Exposure of Madin-Darby canine kidney cells to hydrogen peroxide markedly reduced transepithelial resistance and disrupted the staining patterns of the tight junction proteins ZO-1 and occludin. These changes were reversed by catalase. The short-term reassembly of tight junctions was not dependent on new protein synthesis, suggesting that recovery occurs through re-utilization of existing proteins. Although ATP levels were reduced, the reduction was insufficient to explain the observed changes, since a comparable reduction of ATP levels (with 2-deoxy-D-glucose) did not induce these changes. The intracellular hydrogen peroxide scavenger pyruvate protected Madin-Darby canine kidney cells from loss of transepithelial resistance as did the heavy metal scavenger N,N,N',N'-tetrakis(2-pyridylmethyl)ethylenediamine. Of a wide variety of agents examined, only tyrosine kinase inhibitors and protein kinase C inhibitors markedly inhibited tight junction reassembly. During reassembly, tyrosine phosphorylation in or near the lateral membrane, was detected by immunofluorescence. The tyrosine kinase inhibitors genistein and PP-2 inhibited the recovery of transepithelial resistance and perturbed the relocalization of ZO-1 and occludin to the tight junction, indicating that tyrosine kinases, possibly members of the Src family, are critical for reassembly after oxidative stress.

Degradation of heterotrimeric Galpha(o) subunits via the proteosome pathway is induced by the hsp90-specific compound geldanamycin.

One mechanism utilized by cells to maintain signaling pathways is to regulate the levels of specific signal transduction proteins. The compound geldanamycin (GA) specifically interacts with heat shock protein 90 (hsp90) complexes and has been widely utilized to study the role of hsp90 in modulating the function of signaling proteins. In this study, we used GA to demonstrate that levels of heterotrimeric Galpha subunits can be regulated through interactions with hsp90. In a dose-dependent manner, GA significantly reduced the steady state levels of endogenous Galpha(o) expression in two cell lines (PC12 and GH3) and had a similar effect on Galpha(o) transiently expressed in COS cells. Galpha(o) synthesis and degradation was studied in PC12 cells and in transiently transfected COS cells. (35)S labeling followed by immunoprecipitation demonstrated no effect of GA on the rate of Galpha(o) synthesis, but GA accelerated degradation of Galpha(o) in both PC12 cells and COS cells. The use of inhibitors, including lactacystin (a proteosome-specific inhibitor), suggests that Galpha(o) is predominantly degraded through the proteosome pathway. In vitro translated (35)S-labeled Galpha(o) could be detected in hsp90 immunoprecipitates, and this interaction did not require N-terminal myristoylation. Taken together, these results suggest that heterotrimeric Galpha(o) subunits are protected from degradation by interaction with hsp90 and that the interaction of Galpha subunits with heat shock proteins may be a general mechanism for regulating Galpha levels in the cell.

Interaction of heterotrimeric G protein Galphao with Purkinje cell protein-2. Evidence for a novel nucleotide exchange factor.

The heterotrimeric G protein Galphao is ubiquitously expressed throughout the central nervous system, but many of its functions remain to be defined. To search for novel proteins that interact with Galphao, a mouse brain library was screened using the yeast two-hybrid interaction system. Pcp2 (Purkinje cell protein-2) was identified as a partner for Galphao in this system. Pcp2 is expressed in cerebellar Purkinje cells and retinal bipolar neurons, two locations where Galphao is also expressed. Pcp2 was first identified as a candidate gene to explain Purkinje cell degeneration in pcd mice (Nordquist, D. T., Kozak, C. A., and Orr, H. T. (1988) J. Neurosci. 8, 4780-4789), but its function remains unknown as Pcp2 knockout mice are normal (Mohn, A. R., Feddersen, R. M., Nguyen, M. S., and Koller, B. H. (1997) Mol. Cell. Neurosci. 9, 63-76). Galphao and Pcp2 binding was confirmed in vitro using glutathione S-transferase-Pcp2 fusion proteins and in vitro translated [35S]methionine-labeled Galphao. In addition, when Galphao and Pcp2 were cotransfected into COS cells, Galphao was detected in immunoprecipitates of Pcp2. To determine whether Pcp2 could modulate Galphao function, kinetic constants kcat and koff of bovine brain Galphao were determined in the presence and absence of Pcp2. Pcp2 stimulates GDP release from Galphao more than 5-fold without affecting kcat. These findings define a novel nucleotide exchange function for Pcp2 and suggest that the interaction between Pcp2 and Galphao is important to Purkinje cell function.

Involvement of Galphai2 in the maintenance and biogenesis of epithelial cell tight junctions.

Polarized epithelial cells have highly developed tight junctions (TJ) to maintain an impermeant barrier and segregate plasma membrane functions, but the mechanisms that promote TJ formation and maintain its integrity are only partially defined. Treatment of confluent monolayers of Madin-Darby canine kidney (MDCK) cells with AlF4- (activator of heterotrimeric G protein alpha subunits) results in a 3-4-fold increase in transepithelial resistances (TER), a reliable indicator of TJ integrity. MOCK cells transfected with activated Galpha0 (Q205L) have acclerated TJ formation (Denker, B. M., Saha, C. , Khawaja, S., and Nigam, S. J. (1996) J. Biol. Chem. 271, 25750-25753). Galphai2 has been localized within the tight junction, and a role for Galphai2 in the formation and/or maintenance of the tight junction was studied by transfection of MDCK cells with vector without insert (PC), wild type Galphai2, or a GTPase-deficient mutant (constitutively activated), Q205Lalphai2. Tryptic conformational analysis confirmed expression of a constitutively active Galphai2 in Q205Lalphai2-MDCK cells, and confocal microscopy showed a similar pattern of Galphai2 localization in the three cell lines. Q205Lalphai2-MDCK cells had significantly higher base-line TER values than wild type Galphai2- or PC-MDCK cells (1187 +/- 150 versus 576 +/- 89 (Galphai2); 377 +/- 52 Omega.cm2 (PC)), and both Galphai2- and Q205Lalphai2-transfected cell lines more rapidly develop TER in the Ca2+ switch, a model widely used to study the mechanisms of junctional assembly. Treatment of cells with AlF4- during the Ca2+ switch had little effect on the kinetics of TER development in Galphai2- or Q205Lalphai2-MDCK cells, but PC cells reached half-maximal TER significantly sooner in the presence of AlF4- (similar times to Galphai2-transfected cells). Base-line TER values obtained after the switch were significantly higher for all three cell lines in the presence of AlF4-. These findings indicate that Galphai2 is important for both the maintenance and development of the TJ, although additional Galpha subunits are likely to play a role.

Molecular structure and assembly of the tight junction.

Polarized epithelial cells separate two extremely different cellular milieus. The tight junction (TJ) is the most apical component of the junctional complex and serves as the permeability barrier between these environments. The tight junctional complex appears to be a dynamic and regulated structure. Some of its protein components have been identified and include the transmembrane protein occludin. Nontransmembrane proteins on the cytosolic leaflet including ZO-1, ZO-2, cingulin, 7H6, and several unidentified phosphoproteins are also believed to be part of the TJ. Interactions of some of these proteins with the actin cytoskeleton are a major determinant of TJ structure and may also play a role in the regulation of TJ assembly. Recent progress using the "calcium switch" and the "ATP depletion-repletion" model of TJ formation offers new insight regarding how these structures form. TJ biogenesis appears to be regulated, in part, by classic signal transduction pathways involving heterotrimeric G proteins, release of intracellular Ca2+, and activation of protein kinase C. Although many of the details of the signaling pathways have yet to be defined, these observations may provide insight into how TJs form during tubular development. Furthermore, it may be possible to suggest potential therapeutic targets for intervention in a variety of diseases (e.g., ischemia, toxic injury to the kidney and other epithelial tissue) where TJ integrity has been compromised and reassembly is required.

N-terminal binding domain of Galpha subunits: involvement of amino acids 11-14 of Galphao in membrane attachment.

Heterotrimeric guanine nucleotide binding proteins (G-proteins) transmit signals from membrane receptors to a variety of intracellular effectors. G-proteins reversibly associate with components of the signal transduction system, yet remain membrane attached throughout the cycle of activation. The Galpha subunits remain attached to the plasma membrane through a combination of factors that are only partially defined. We now demonstrate that amino acids within the N-terminal domain of Galpha subunits are involved in membrane binding. We used in vitro translation, a technique widely utilized to characterize functional aspects of G-proteins, and interactions with donor-acceptor membranes to demonstrate that amino acids 11-14 of Galphao contribute to membrane binding. The membrane binding of Galphao lacking amino acids 11-14 (D[11-14]) was significantly reduced at all membrane concentrations in comparison with wild-type Galphao. Several other N-terminal mutants of Galphao were characterized as controls, and these results indicate that differences in myristoylation, palmitoylation and betagamma interactions do not account for the reduced membrane binding of D[11-14]. Furthermore, when membrane attachment of Galphao and mutants was characterized in transiently transfected 35S-labelled and [3H]myristate-labelled COS cells, amino acids 11-14 contributed to membrane binding. These studies reveal that membrane binding of Galpha subunits occurs by a combination of factors that include lipids and amino acid sequences. These regions may provide novel sites for interaction with membrane components and allow additional modulation of signal transduction.

Analysis of the N-terminal binding domain of Go alpha.

Signalling from membrane receptors through heterotrimeric G-proteins (G alpha and G beta gamma) to intracellular effectors is a highly regulated process. Receptor activation causes exchange of GTP for GDP on G alpha and dissociation of G alpha from G beta gamma. Both subunits remain membrane-associated and interact with a series of other molecules throughout the cycle of activation. The N-terminal binding domain of G alpha subunits interacts with the membrane by several partially defined mechanisms: the anchoring of G alpha to the more hydrophobic G beta gamma subunits, the interaction of N-terminal lipids (palmitate and/or myristate) with the membrane, and attachment of amino acid regions to the membrane {amino acids 11-14 of Go alpha (D[11-14]); Busconi, Boutin and Denker (1997) Biochem. J. 323, 239-244}. We characterized N-terminal mutants of Go alpha with known G beta gamma-binding properties for the ability to interact with phospholipid vesicles and membranes prepared from cultured cells (acceptor membranes). In vitro analysis allows membrane interactions that are important to the activated and depalmitoylated state of G alpha to be characterized. Subcellular localization was also determined in transiently transfected COS cells. All of the mutant proteins are myristoylated, and differences in myristoylation do not account for changes in membrane binding. Disrupting the N-terminal alpha-helix of Go alpha with a proline point mutation at Arg-9 (R9P) does not affect interactions with G beta gamma on sucrose-density gradients but significantly reduces acceptor membrane binding. Deletion of amino acids 6-15 (D[6-15]; reduced G beta gamma binding) or deletion of amino acids 3-21 (D[3-21]); no detectable G beta gamma binding) further reduces acceptor membrane binding. When expressed in COS cells, R9P and D[6-15] are localized in the membrane similar to wild-type Go alpha as a result of the contribution from palmitoylation. In contrast, D[3-21] is completely soluble in COS cells, and no palmitoylation is detected. The binding of Go alpha and mutants translated in vitro to liposomes indicates that Go alpha preferentially binds to neutral phospholipids (phosphatidylcholine). R9P and D[11-14] bind to phosphatidylcholine liposomes like Go alpha, but D[6-15] exhibits no detectable binding. Taken together, these studies suggest that interactions of the N-terminus of G alpha subunits with the membrane may be affected by both membrane proteins and lipids. A detailed understanding of G alpha-membrane interactions may reveal unique mechanisms for regulating signal transduction.

Involvement of a heterotrimeric G protein alpha subunit in tight junction biogenesis.

The tight junction (TJ) of polarized epithelial cells is critical for maintaining an impermeant barrier and epithelial cell polarity. The signaling events important for TJ assembly require regulated calcium stores and protein kinase C (PKC), but the earliest signaling events in the cascade have not been well defined. We now show that Galphai2 in Madin Darby canine kidney (MDCK) cells localizes to a region overlapping with the TJ. To further analyze the localization of Galpha subunits in epithelial cells, rat Galphao, Q205Lalphao (Galphao "activated" by point mutation) and plasmid without insert (PC) were transfected into MDCK cells and localized by immunofluorescence and confocal microscopy. Similar to endogenous Galphai2, Galphao-MDCK cells localize Galphao, (84% similar to Galphai2) in the subapical region overlapping with ZO-1 (zona occludens-I), a key component of the TJ. PC-MDCK cells have no detectable Galphao. In Galphao-MDCK cells, a physical association of Galphao with components of the TJ was detectable by immunoprecipitation of ZO-1. Immunoprecipitates of ZO-1 from Galphao-MDCK cells consistently coprecipitated Galphao. Constitutively active Q205LGalphao localized to the subapical lateral membrane similar to wild-type Galphao. To determine if constitutively activated Galpha subunits can affect TJ biogenesis, the formation of tight junctions in PC, Galphao, and Q205Lalphao-MDCK cells was followed by measurement of transepithelial resistance (TER) during the Ca2+ switch, a model widely used to study mechanisms of junctional assembly. Baseline and post Ca2+ switch TER values did not differ among the cell lines. However, constitutively activated Q205Lalphao-MDCK cells developed TER significantly faster than PC and Galphao cells in the early phase (0-4 h) (54 +/- 4 versus 23 +/- 3 (PC); 12 +/- 1 (Galphao) Omega.m2/h) and late phase (4-h peak) (117 +/- 10 versus 45 +/- 5 (PC); 66 +/- 7 (Galphao) Omega.m2/h) after Ca2+ switch. Peak TER values were significantly higher in Q205Lalphao-MDCK cells (1168 +/- 107 versus 437 +/- 37 (PC); 548 +/- 54 (Galphao) Omega.cm2). These results indicate that Galphao and Q205Lalphao expressed in MDCK cells are localized near the junctional complex, associate with at least one TJ protein, and that activated Galphao accelerates TJ biogenesis without significantly affecting the maintenance of the TJ. Together, these results suggest an important role for heterotrimeric G proteins in TJ assembly.

Interactions between the amino- and carboxyl-terminal regions of G alpha subunits: analysis of mutated G alpha o/G alpha i2 chimeras.

Receptors activate the G alpha subunits of heterotrimeric G proteins by binding to the C-terminus and reducing their affinity for bound GDP, therefore promoting exchange of GDP for GTP. Although this general mechanism is the same for all G alpha subunits, different G alpha subunits vary in nucleotide binding and hydrolysis even though the residues that make up the guanine nucleotide binding site are virtually identical. We have shown previously that truncation of 14 amino acids from the C-terminus of G alpha o decreased the apparent affinity for GDP and permitted us to see an activated conformation with GTP [Denker, B. M., et al. (1992) J. Biol. Chem. 267, 9998-10002]. To test whether mutations in the receptor binding region lead to different phenotypes in closely related G alpha subunits, we made the equivalent deletions in G alpha i2, synthesized the proteins in vitro in a rabbit reticulocyte lysate and used the pattern of native tryptic proteolysis as an index of conformation. The phenotype of truncated G alpha i2 was different from that of truncated G alpha o: GDP affinity was reduced, but we could not detect an activated conformation with GTP (although GTP gamma S activated normally). Analysis of shorter deletions showed that loss of three hydrophobic residues (between 11 and 13 residues from the C-terminus) was responsible for the phenotypes. To define the regions of G alpha o and G alpha i2 that were responsible for their different phenotypes, we used a conserved BamHI site (codon 212) to make chimeras. Each chimera truncated at the C-terminus had the phenotype of the donor of the amino-terminal portion. Both truncated chimeras were activated by GTP gamma S-like wild-type proteins, and both had decreased apparent affinity for GDP. Full-length chimeric subunits behaved like wild-type proteins. The crystal structure of G alpha t and G alpha i1 shows that the three hydrophobic amino acids we have identified make contact with residues in the N- and C-terminal portions of the protein. Our studies point to the importance of the contacts in the N-terminal region (start of beta strands 1 and 3) that may stabilize the C-terminal alpha helix, affect nucleotide binding, and determine the characteristic features of different G alpha subunits.

Promotion of the GTP-liganded state of the Go alpha protein by deletion of the C terminus.

G proteins are active as long as GTP is bound to the alpha subunit. Activation ends when GTP is cleaved to GDP that then stays bound to the active site. Agonist-liganded receptors allow formation of the active state by decreasing the affinity of alpha subunits for GDP allowing exchange of GDP for GTP. Since receptors interact with the C terminus of the alpha subunits, we tested whether deletion of the C terminus could mimic activation by receptors. Three deletions and one point mutation at the C terminus of alpha o were engineered in alpha o cDNA by the polymerase chain reaction, transcribed into RNA, and translated in a rabbit reticulocyte lysate. The ability of in vitro synthesized protein to bind guanine nucleotide was inferred from analysis of native tryptic cleavage patterns, while the ability of the proteins to associate with beta gamma was measured by sucrose density gradient centrifugation. Deletion of 14 amino acids, alpha oD[341], from the C terminus causes a large decrease in GDP affinity, with little or no change in guanosine 5'-3-O-(thio)triphosphate affinity. When GTP is present, alpha oD[341] remains in the activated conformation because exchange of GTP for GDP is rapid. Deletion of 10 amino acids, alpha oD[345], lowers GDP affinity, but less dramatically than in alpha oD[341]. Deletion of 5 amino acids, alpha oD[350], or mutation of Arg-349 to proline alpha oR[349P] has no detectable effects on GDP affinity. Deletion of up to 10 amino acids from the C terminus does not prevent formation of alpha beta gamma heterotrimers. We propose that the C terminus of the alpha subunit is a mobile region that blocks dissociation of GDP. Agonist-liganded receptors may move it aside to allow release of GDP, exchange for GTP, and activation of the alpha subunit.

Mutagenesis of the amino terminus of the alpha subunit of the G protein Go. In vitro characterization of alpha o beta gamma interactions.

Heterotrimeric guanine nucleotide-binding proteins are composed of alpha and beta gamma subunits and couple a variety of cell-surface receptors to intracellular enzymes or ion channels. The heterotrimer dissociates into alpha and beta gamma subunits when the alpha subunit is activated by guanine nucleoside triphosphates. Several lines of evidence show that the amino terminus of the alpha subunit is important for the interaction with the beta gamma subunit (Neer, E. J., Pulsifer, L., and Wolf, L. G. (1988) J. Biol. Chem. 263, 8996-9000; Fung, B. K.-K., and Nash, C. R. (1983) J. Biol. Chem. 258, 10503-10510). We have mutagenized the amino terminus of alpha o to dissect the relative contributions of amino-terminal myristoylation and specific amino acid sequences to subunit interaction. Wild-type and mutant alpha o cDNAs were translated in vitro in a rabbit reticulocyte lysate. All proteins were able to bind guanosine 5'-(gamma-thio)triphosphate and to achieve the necessary conformation for protection from tryptic digestion. Two assays of alpha o beta gamma interactions were used: sucrose density gradients to look for stable heterotrimer formation and ADP-ribosylation by pertussis toxin to detect weak or transient alpha o beta gamma interactions. Our results indicate that myristoylation is essential for stable heterotrimer formation, but that nonmyristoylated proteins are also capable of interacting with the beta gamma subunit. Amino acids 7-10 have an important role in alpha o beta gamma interactions whether alpha o is myristoylated or not. Deletion of this region diminishes the ability of alpha o to interact with the beta gamma subunit, but substitutions at this position indicate that other amino acids can be tolerated without affecting subunit interaction.

Characterization of a mastoparan-stimulated nucleotidase from bovine brain.

Mastoparan is a 14-amino-acid peptide that stimulates secretion from several cell types. Secretion can be partially blocked by pertussis toxin and may be mediated by guanine-nucleotide-binding proteins (G-proteins). Mastoparan can act directly on G-proteins, probably at the hormone receptor-binding site, to stimulate guanosine 5'-[gamma-thio]triphosphate binding and GTPase activities of pertussis-toxin substrates Go and Gi [Higashijima, Uzu, Nakajima & Ross (1988) J. Biol. Chem. 263, 6491-6494]. We now describe a nucleotidase from bovine brain that is not a known G-protein whose GTPase and ATPase activities are stimulated by mastoparan. This nucleotidase hydrolyses ATP faster than GTP, but has similar affinities for both (0.4 microM). Mastoparan maximally stimulates both ATPase and GTPase activities by about 8-fold after insertion of the protein into phospholipid vesicles, but does not affect the EC50 (concentration at which half the maximal effect is observed) for ATP and GTP. The EC50 for mastoparan stimulation of GTPase and ATPase is 6 and 12 microM respectively. The native molecular mass of the partially purified mastoparan-stimulated nucleotidase is 87 kDa. This nucleotidase may be another receptor-activated enzyme, and its identification may be useful for understanding mastoparan-stimulated processes.

GO associates with another 40 kDa brain protein.

Guanine nucleotide binding proteins (G proteins) mediate a variety of cellular responses to external stimuli. Pure G protein, receptor, and effector are sufficient to reconstitute hormonal activation of an effector in phospholipid vesicles, but other components may be important for specificity or localization in vivo. If another protein associates with GO, the molecular weight of GO solubilized from membranes would be larger than the molecular weight of GO after purification. We find that GO solubilized from bovine brain membranes by Triton X-100 behaves as a single population of molecules on sucrose density gradients and gel filtration columns. Its molecular mass is about 40 kDa larger than pure GO. Association of GO with the other protein is fragile as the proteins dissociate on further purification. There was no difference in ADP-ribosylation or tryptic cleavage of GO in larger and smaller form. These studies provide a basis for future experiments to stabilize the interaction and identify the protein.

Structural and functional studies of cross-linked Go protein subunits.

The guanine nucleotide binding proteins (G proteins) that couple hormone and other receptors to a variety of intracellular effector enzymes and ion channels are heterotrimers of alpha, beta, and gamma subunits. One way to study the interfaces between subunits is to analyze the consequences of chemically cross-linking them. We have used 1,6-bismaleimidohexane (BMH), a homobifunctional cross-linking reagent that reacts with sulfhydryl groups, to cross-link alpha to beta subunits of Go and Gi-1. Two cross-linked products are formed from each G protein with apparent molecular masses of 140 and 122 kDa on sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Both bands formed from Go reacted with anti-alpha o and anti-beta antibody. The mobility on sodium dodecyl sulfate-polyacrylamide gel electrophoresis is anomalous since the undenatured, cross-linked proteins have the same Stokes radius as the native, uncross-linked alpha beta gamma heterotrimer. Therefore, each cross-linked product contains one alpha and one beta subunit. Activation of Go by guanosine 5'-3-O-(thio)triphosphate (GTP gamma S) does not prevent cross-linking of alpha to beta gamma, consistent with an equilibrium between associated and dissociated subunits even in the presence of GTP gamma S. The same cross-linked products of Go are formed in brain membranes reacted with BMH as are formed in solution, indicating that the residues cross-linked by BMH in the pure protein are accessible when Go is membrane bound. Analysis of tryptic peptides formed from the cross-linked products indicates that the alpha subunit is cross-linked to the 26-kDa carboxyl-terminal portion of the beta subunit. The cross-linked G protein is functional, and its alpha subunit can change conformation upon binding GTP gamma S. GTP gamma S stabilizes alpha o to digestion by trypsin (Winslow, J.W., Van Amsterdam, J.R., and Neer, E.J. (1986) J. Biol. Chem. 261, 7571-7579) and also stabilizes the alpha subunit in the cross-linked product. Cross-linked G o can be ADP-ribosylated by pertussis toxin. This ADP-ribosylation is inhibited by GTP gamma S with a concentration dependence that is indistinguishable from that of the control, uncross-linked G o. These two kinds of experiments indicate that alpha o is able to change its conformation even though it cannot separate completely from beta gamma. Thus, although dissociation of the subunits accompanies activation of G o in solution, it is not obligatory for a conformational change to occur in the alpha subunit.

Isolation of proteins related to the Rh polypeptides from nonhuman erythrocytes.

It is thought that the Rh antigens may be important in maintaining normal erythrocyte membrane integrity. Despite their name, Rh antigens are serologically present only on human erythrocytes. Rh structural polymorphisms are known to reside within a family of nonglycosylated Mr 32,000 integral membrane proteins that can be purified by hydroxylapatite chromatography. Mr 32,000 integral membrane proteins were purified similarly from erythrocyte membrane vesicles prepared from rhesus monkeys, cows, cats, and rats, but could not be purified from human Rhmod erythrocytes, a rare syndrome lacking Rh antigens. The purified Mr 32,000 polypeptides were labeled with 125I, digested with chymotrypsin, and found to be 30-60% identical to human Rh polypeptides when compared by two-dimensional iodopeptide mapping. The physiologic function of the Rh polypeptides remains to be identified; however, the existence of related proteins in nonhuman erythrocytes supports the concept that the Rh polypeptides are erythrocyte membrane components of fundamental significance.

Identification, purification, and partial characterization of a novel Mr 28,000 integral membrane protein from erythrocytes and renal tubules.

A novel Mr 28,000 integral membrane protein ("28kDa") was identified in human erythrocytes and found entirely associated with the Triton X-100 insoluble membrane skeletons. Antibodies to 28kDa reacted strongly on immunoblots with 28kDa and a diffuse region of Mr 35,000-60,000 ("HMW-28kDa"). Selective proteolytic digestions of membranes demonstrated that HMW-28kDa has an extracellular domain, and both 28kDa and HMW-28kDa have intracellular domains. 28kDa and HMW-28kDa were purified to homogeneity. Quantitative immunoblots indicate that each erythrocyte contains 120,000-160,000 copies of 28kDa. Two-dimensional iodopeptide maps of 28kDa and HMW-28kDa were nearly identical; peptide-N-glycosidase digestion of purified HMW-28kDa demonstrated that it is the N-glycosylated form of 28kDa. When concentrated, 28kDa formed a series of larger oligomers which were stable in sodium dodecyl sulfate. Of several nonerythroid tissues studied with anti-28kDa immunoblots, only kidney displayed immunoreactive 28kDa. Purified rat kidney 28kDa was nearly identical to rat erythrocyte 28kDa when compared by two-dimensional iodopeptide mapping. Immunohistochemical staining of human kidney with anti-28kDa demonstrated prominent staining over the apical brush borders of proximal convoluted tubules. A novel integral membrane protein has been purified from erythrocyte and kidney membranes. This new protein may play a role in linkage of the membrane skeleton to the lipid bilayer.