Protein kinase C phosphorylates RGS2 and modulates its capacity for negative regulation of Galpha 11 signaling.

RGS proteins (regulators of G protein signaling) attenuate heterotrimeric G protein signaling by functioning as both GTPase-activating proteins (GAPs) and inhibitors of G protein/effector interaction. RGS2 has been shown to regulate Galpha(q)-mediated inositol lipid signaling. Although purified RGS2 blocks PLC-beta activation by the nonhydrolyzable GTP analog guanosine 5'-O-thiophosphate (GTPgammaS), its capacity to regulate inositol lipid signaling under conditions where GTPase-promoted hydrolysis of GTP is operative has not been fully explored. Utilizing the turkey erythrocyte membrane model of inositol lipid signaling, we investigated regulation by RGS2 of both GTP and GTPgammaS-stimulated Galpha(11) signaling. Different inhibitory potencies of RGS2 were observed under conditions assessing its activity as a GAP versus as an effector antagonist; i.e. RGS2 was a 10-20-fold more potent inhibitor of aluminum fluoride and GTP-stimulated PLC-betat activity than of GTPgammaS-promoted PLC-betat activity. We also examined whether RGS2 was regulated by downstream components of the inositol lipid signaling pathway. RGS2 was phosphorylated by PKC in vitro to a stoichiometry of approximately unity by both a mixture of PKC isozymes and individual calcium and phospholipid-dependent PKC isoforms. Moreover, RGS2 was phosphorylated in intact COS7 cells in response to PKC activation by 4beta-phorbol 12beta-myristate 13alpha-acetate and, to a lesser extent, by the P2Y(2) receptor agonist UTP. In vitro phosphorylation of RGS2 by PKC decreased its capacity to attenuate both GTP and GTPgammaS-stimulated PLC-betat activation, with the extent of attenuation correlating with the level of RGS2 phosphorylation. A phosphorylation-dependent inhibition of RGS2 GAP activity was also observed in proteoliposomes reconstituted with purified P2Y(1) receptor and Galpha(q)betagamma. These results identify for the first time a phosphorylation-induced change in the activity of an RGS protein and suggest a mechanism for potentiation of inositol lipid signaling by PKC.

Molecular cloning and expression of an avian G protein-coupled P2Y receptor.

A family of G protein-coupled P2Y receptors that are activated by adenine and uridine nucleotides has been identified recently. Degenerate primers based on conserved sequences in these P2Y receptors were used to amplify turkey DNA, which was used to isolate the complete coding sequence of a cDNA that encodes a novel G protein-coupled receptor. Stable expression of this avian cDNA in 1321N1 human astrocytoma cells resulted in the conveyance of marked inositol phosphate responses to various nucleotides. Although this cloned avian receptor exhibited its highest homology to the previously cloned mammalian P2Y4 receptor, its pharmacological selectivity was not consistent with the avian receptor's being a species homologue of the P2Y4 receptor. That is, whereas the P2Y4 receptor is selectively activated by UTP and is not activated by ATP or Ap4A, the novel avian receptor was potently activated by ATP and Ap4A as well as by UTP. Taken together, these results describe the identification of an avian phospholipase C-coupled P2Y receptor that, like the mammalian P2Y2 receptor, is activated by both adenine and uridine nucleotides.

Molecular cloning, expression and regulatory activity of G alpha 11- and beta gamma-subunit-stimulated phospholipase C-beta from avian erythrocytes.

A turkey erythrocyte phospholipase C (PLC) has been instrumental in delineating the role of G-proteins in receptor-regulated inositol lipid signalling. This isoenzyme is uniquely regulated both by alpha-subunits of the Gq family and by G-protein beta gamma-subunits. A 4819 bp cDNA encoding this PLC has been cloned from a turkey erythrocyte cDNA library. The open reading frame of this cDNA encodes a 1211-amino-acid protein (calculated molecular mass 139050 Da) that contains amino acid sequences of 16 peptides sequenced from the turkey erythrocyte PLC. The predicted sequence of the turkey PLC shows considerable similarity with the sequences of previously cloned members of the PLC-beta family, with the highest identity (71%) shared with PLC-beta 2 and lesser identities observed with PLC-beta 1 (49%), PLC-beta 3 (46%) and PLC-beta 4 (37%). The largest differences in sequence between the turkey PLC-beta and other PLC-beta isoenzymes occur in the C-terminal domain and in the region between the X- and Y-domains. The turkey isoenzyme and PLC-beta 2, which differ in their regulation by G-protein alpha-subunits, are only 44% similar across the approx. 400 amino acid residues of the C-terminal domain that has been implicated in alpha q activation of these proteins. Recombinant turkey PLC-beta was purified to homogeneity following expression from a recombinant baculovirus in Sf9 insect cells. The immunoreactivity and mobility on SDS/PAGE of the recombinant enzyme were the same as observed with native turkey erythrocyte PLC-beta. Moreover, the catalytic activities of the recombinant enzyme were indistinguishable from those of native turkey erythrocyte PLC-beta in assays carried out in the presence of cholate and Ca2+, or in assays of activity after reconstitution with G alpha 11 or G-protein beta gamma-subunits. The turkey PLC-beta was more sensitive to activation by G alpha 11 than was PLC-beta 2, and was more sensitive to activation by beta gamma-subunits than either PLC-beta 2 or PLC-beta 1.

Selective activation of phospholipase C by recombinant G-protein alpha- and beta gamma-subunits.

Receptor activation of phospholipase C (PLC) via G-proteins occurs by pertussis toxin-sensitive and toxin-insensitive signaling pathways. The alpha-subunits of the Gq family are presumed to mediate the toxin-insensitive pathway, but the nature of the G-proteins mediating the toxin-sensitive pathway is not established. Recently, PLC-beta has been shown to be activated by G-protein beta gamma-subunits of mixed or undefined composition. The relative activities of G-protein subunits that might activate PLC-beta were examined using defined recombinant alpha- and beta gamma-subunits obtained from the baculovirus expression system by reconstituting the purified subunits with purified bovine brain PLC-beta 1 or turkey erythrocyte PLC-beta in unilamellar phospholipid vesicles. Turkey erythrocyte G alpha 11 and recombinant G alpha 11 and G alpha q obtained after expression in Sf9 cells activated both bovine brain PLC-beta 1 and turkey erythrocyte PLC-beta. In contrast, under the same assay conditions, recombinant G alpha i1, G alpha i2, G alpha i3, and G alpha o were without effect on either type of PLC. All types of beta gamma-subunits tested (r beta 1 gamma 2, r beta 1 gamma 3, r beta 2 gamma 2, r beta 2 gamma 3, bovine brain beta gamma or turkey erythrocyte beta gamma) inhibited G alpha 11-mediated activation of PLC, presumably by promotion of formation of inactive heterotrimeric G-protein. All types of beta gamma-subunits also markedly stimulated the activity of turkey erythrocyte PLC-beta but did not activate bovine brain PLC-beta 1. Of the four different beta gamma complexes of defined composition, three stimulated PLC with similar activities whereas beta 2 gamma 3 was less effective. The data suggest that pertussis toxin-sensitive activation of PLC is mediated by the beta gamma-subunits of G-proteins acting on specific phospholipase C isoenzymes.

Identification of G alpha 11 as the phospholipase C-activating G-protein of turkey erythrocytes.

A 43 kDa phospholipase C-activating protein has been purified previously from turkey erythrocytes and shown to express immunological properties expected of that of the Gq family of G-protein alpha-subunits [Waldo, Boyer, Morris and Harden (1991) J. Biol. Chem. 266, 14217-14225]. Internal amino acid sequence has now been obtained from this protein which shares 50-100% sequence identity with sequences encoded by mammalian G alpha 11 and G alpha q cDNAs. To identify the purified protein unambiguously, it was necessary to compare its amino acid sequence with the sequence encoded by avian G-protein alpha-subunit cDNA. As such, mouse G alpha q was used as a probe to screen turkey brain and fetal-turkey blood cDNA libraries. A full-length cDNA was identified that encodes avian G alpha 11, on the basis of its 96-98% amino acid identity with mammalian G alpha 11. All eight peptides sequenced from the turkey erythrocyte phospholipase C-activating protein are completely contained within the deduced amino acid sequence of the avian G alpha 11 cDNA. Expression of this cDNA in Sf9 cells by using a baculovirus expression system resulted in the production of a 43 kDa protein that reacts strongly with antisera to the Gq family of G-protein alpha-subunits and activated purified avian phospholipase C in an AlF4(-)-dependent manner. Taken together, these results unambiguously identify the protein purified from turkey erythrocytes, on the basis of its capacity to activate avian phospholipase C, as G alpha 11.

Beta gamma-subunit activation of G-protein-regulated phospholipase C.

The availability of purified G alpha 11 and the G-protein-regulated phospholipase C from turkey erythrocytes has allowed an examination of the direct effects of G-protein beta gamma-subunit on the components of the inositol lipid signaling system. Reconstitution of purified turkey erythrocyte or bovine brain beta gamma-subunit into phospholipid vesicles containing G alpha 11 inhibited AlF4- induced activation of phospholipase C. However, beta gamma-subunit at higher concentrations increased phospholipase C activity. This stimulatory effect of beta gamma-subunit on phospholipase C did not require the presence of the alpha-subunit. G alpha o had no effect on the catalytic activity of phospholipase C. However, coreconstitution of G alpha o and beta gamma-subunit shifted to the right the concentration-effect curve for beta gamma-subunit-promoted activation of phospholipase C. As was observed with G alpha 11, the increase in activity observed in the presence of beta gamma-subunit occurred as an increase in the maximal activity and with no change in the apparent affinity for Ca2+ for phospholipase C activation. The concentration dependence of G alpha 11 for activation of turkey erythrocyte phospholipase C and bovine brain phospholipase C-beta, as well as the concentration dependence of the two enzymes for activation by G alpha 11, were very similar. In contrast, beta gamma-subunit was a much less effective activator of bovine brain phospholipase C-beta than the turkey erythrocyte enzyme. The observation of direct effects of free beta gamma-subunit on phospholipase C extend the possibilities for receptor-mediated regulation of this signaling pathway.

Receptor- and G-protein-regulated 150-kDa avian phospholipase C: inhibition of enzyme activity by isoenzyme-specific antisera and nonidentity with mammalian phospholipase C isoenzymes established by immunoreactivity and peptide sequence.

A 150-kDa phospholipase C previously was purified from turkey erythrocytes and shown to be a P2Y-purinergic receptor- and guanine nucleotide-binding protein-regulated enzyme [J. Biol. Chem. 265:13508-13514 (1990)]. The relationship of this enzyme to the 150-kDa mammalian phospholipase C isoenzymes, termed phospholipase C-beta and -gamma, has been examined. Four antisera to the turkey erythrocyte phospholipase C recognized the avian enzyme in immunoblots but failed to recognize phospholipase C-gamma; one of the these weakly recognized phospholipase C-beta. Antibodies to phospholipase C-beta and -gamma failed to recognize the turkey erythrocyte phospholipase C. However, two antibodies raised against peptide sequence in regions of conserved sequence common to mammalian phospholipase C isoenzymes recognized the 150-kDa turkey erythrocyte phospholipase C. Antisera against the native form of the turkey erythrocyte phospholipase C inhibited the activity of this enzyme against phosphatidylinositol 4,5-bisphosphate presented as a component of mixed phospholipid vesicles or of mixed phospholipid and sodium cholate micelles; inhibition occurred as a decrease in Vmax, with no apparent change in Km for substrate or in the Ca2+ dependence of phospholipase C activity. Catalytic activity of phospholipase C-beta or -gamma against exogenous substrate was unaffected by antisera to the turkey erythrocyte enzyme. Antisera against the native form of the turkey erythrocyte phospholipase C also partially inhibited (50-60% inhibition) the capacity of AIF4- or adenosine 5'-O-(beta-thio) diphosphate plus guanosine 5'-O-(gamma-thio) triphosphate to stimulate phosphoinositide hydrolysis in ghosts prepared from [3H]inositol-prelabeled turkey erythrocytes. Moreover, the capacity of the purified 150-kDa enzyme to reconstitute receptor and G-protein-regulated phospholipase C activity in purified turkey erythrocyte plasma membranes devoid of this activity was completely inhibited by antisera to the turkey erythrocyte enzyme. Five peptides that were purified by high performance liquid chromatography from a tryptic digest of the turkey erythrocyte 150-kDa phospholipase C had no recognizable sequence homology with any deduced sequence of the mammalian phospholipase C isoenzymes. One turkey erythrocyte phospholipase C-derived peptide had clear homology with sequence in the first (X-domain) conserved region common to at least three of the mammalian phospholipase C isoenzymes, and another 16-amino acid peptide had partial sequence homology with the second (Y-domain) conserved region common to the mammalian enzymes. An 8-amino acid peptide from the tryptic digest had 75% homology with a sequence near the carboxyl terminus of mammalian phospholipase C-beta.(ABSTRACT TRUNCATED AT 400 WORDS)

Purification of an AlF4- and G-protein beta gamma-subunit-regulated phospholipase C-activating protein.

A 150-kDa phospholipase C has previously been purified from turkey erythrocytes and has been shown by reconstitution with turkey erythrocyte membranes to be a receptor- and G-protein-regulated enzyme (Morris, A. J., Waldo, G. L., Downes, C.P., and Harden, T. K. (1990) J. Biol. Chem. 265, 13501-13507; Morris, A.J., Waldo, G.L., Downes, C.P., and Harden, T.K. (1990) J. Biol. Chem. 265, 13508-13514). Combination of this 150-kDa protein with phosphoinositide substrate-containing phospholipid vesicles prepared with a cholate extract from purified turkey erythrocyte plasma membranes resulted in conferrence of AlF4- sensitivity to the purified phospholipase C. Guanosine 5'-3-O-(thio)triphosphate also activated the reconstituted phospholipase C in a manner that was inhibited by guanosine 5'-2-O-(thio)-diphosphate. The magnitude of the AlF4- stimulation was increased with increasing amounts of plasma membrane extract, and was also dependent on the concentration of purified phospholipase C. Using reconstitution of AlF4- sensitivity as an assay, the putative G-protein conferring regulation to the 150-kDa phospholipase C was purified to near homogeneity by sequential chromatography over Q-Sepharose, Sephacryl S-300, octyl-Sepharose, hydroxylapatite, and Mono-Q. Reconstituting activity co-purified with an approximately 43-kDa protein identified by silver staining; lesser amounts of a 35-kDa protein was present in the final purified fractions, as was a minor 40-kDa protein. The 43-kDa protein strongly reacted with antiserum against a 12-amino acid sequence found at the carboxyl terminus of Gq and G11, the 35-kDa protein strongly reacted with G-protein beta-subunit antiserum, and the 40-kDa protein reacted with antiserum that recognizes Gi3. Immunoprecipitation of the 43-kDa protein resulted in loss of phospholipase C-stimulating activity of the purified fraction. The idea that this is a phospholipase C-regulating G-protein is further supported by the observation that co-reconstitution of G-protein beta gamma-subunit with the purified phospholipase C-activating fraction resulted in a beta gamma-subunit-dependent inhibition of AlF(4-)-stimulated phospholipase C activity in the reconstituted preparation.

A receptor and G-protein-regulated polyphosphoinositide-specific phospholipase C from turkey erythrocytes. I. Purification and properties.

Eighty-three percent of polyphosphoinositide-specific phospholipase C activity was recovered in a cytosolic fraction after nitrogen cavitation of turkey erythrocytes. This activity has been purified approximately 50,000-fold when compared to the starting cytosol with a yield of 1.7-5.0%. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of the phospholipase C preparation revealed a major polypeptide of 150 kDa. The specific activity of the purified enzyme was 6.7-14.0 mumol/min/mg of protein with phosphatidylinositol 4,5-bisphosphate or phosphatidylinositol 4-phosphate as substrate. Phospholipase C activity was markedly dependent on the presence of Ca2+. The phospholipase C showed an acidic pH optimum (pH 4.0). At neutral pH, noncyclic inositol phosphates were the major products formed by the phospholipase C, while at pH 4.0, substantial formation of inositol 1:2-cyclic phosphate derivatives occurred. Properties of the purified 150-kDa turkey erythrocyte phospholipase C were compared with the approximately 150-kDa phospholipase C-beta and -gamma isoenzymes previously purified from bovine brain (Ryu, S. H., Cho, K. S., Lee, K. Y., Suh, P. G., and Rhee, S. G. (1987) J. Biol. Chem. 262, 12511-12518). The turkey erythrocyte phospholipase C differed from the two mammalian phospholipases with respect to the effect of sodium cholate on the rate of polyphosphoinositide hydrolysis observed. Moreover, when presented with dispersions of pure inositol lipids, phospholipases C-beta and -gamma displayed comparable maximal rates of polyphosphoinositide and phosphatidylinositol hydrolysis. By contrast, the turkey erythrocyte phospholipase C displays a marked preference for polyphosphoinositide substrates.

A receptor and G-protein-regulated polyphosphoinositide-specific phospholipase C from turkey erythrocytes. II. P2Y-purinergic receptor and G-protein-mediated regulation of the purified enzyme reconstituted with turkey erythrocyte ghosts.

The preceding paper describes purification and properties of a 150-kDa polyphosphoinositide-specific phospholipase C from a cytosolic fraction of turkey erythrocytes (Morris, A. J., Waldo, G. L., Downes, C. P., and Harden, T. K. (1990) J. Biol. Chem. 265, 13501-13507). Turkey erythrocytes express a P2Y-purinergic receptor that employs an unidentified G-protein to activate phospholipase C (Boyer, J. L., Downes, C. P., and Harden, T. K. (1989) J. Biol. Chem. 264, 884-890; Cooper, C. L., Morris, A. J., and Harden, T. K. (1989) J. Biol. Chem. 264, 6202-6206). This paper describes receptor and G-protein regulation of the purified turkey erythrocyte phospholipase C after reconstitution of the enzyme using [3H]inositol pre-labeled turkey erythrocyte ghosts as acceptor membranes. These membranes contain polyphosphoinositides labeled to high specific radioactivity and display reduced responsiveness of their endogenous phospholipase C to P2Y-purinergic receptor agonists and guanine nucleotides. Reconstitution of purified enzyme had no effect on basal inositol phosphate production, but markedly increased P2Y-purinergic receptor agonist and guanine nucleotide-dependent accumulation of inositol phosphates. Reconstitution of 5 ng of purified phospholipase C with 10 micrograms of acceptor membrane protein produced half-maximal effects, and maximal activity was observed with reconstitution of 100 ng of purified enzyme. Agonist and guanine nucleotide-regulated phospholipase C activity measured using a reconstitution assay co-purified with phospholipase C activity detected using exogenously provided phosphatidylinositol 4,5-bisphosphate during purification of the 150-kDa protein. Only the maximal rate of inositol phosphate formation attained upon activation was increased in the presence of the purified phospholipase C. K0.5 values for adenosine 5'-O-(2-thiodiphosphate), guanosine 5'-3-O-(thio)triphosphate, and A1F4- activation of the purified enzyme were the same as for the endogenous phospholipase C activity of the acceptor membranes.

Modification of AlF-4- and receptor-stimulated phospholipase C activity by G-protein beta gamma subunits.

Turkey erythrocyte membranes possess a phospholipase C that is markedly activated by P2Y-purinergic receptor agonists and guanine nucleotides. Reconstitution of [3H]inositol-labeled turkey erythrocyte membranes with guanine nucleotide regulatory protein (G-protein) beta gamma subunits resulted in inhibition of both AlF-4-stimulated adenylate cyclase and AlF-4-stimulated phospholipase C activities. The apparent potency (K0.5 approximately 1 microgram or 20 pmol of beta gamma/mg of membrane protein) of beta gamma subunits for inhibition of each enzyme activity was similar and occurred with beta gamma purified by different methodologies from turkey erythrocyte, bovine brain, or human placenta membranes. In contrast to the effect on AlF-4-stimulated activity, the stimulatory effect on phospholipase C of the P2Y-purinergic receptor agonist 2-methylthioadenosine 5'-triphosphate in the presence of guanine nucleotides was potentiated by 50-100% in a concentration-dependent manner by reconstitution of beta gamma subunits. beta gamma subunits did not affect the K0.5 value of 2-methylthioadenosine 5'-triphosphate for the stimulation of phospholipase C activity. These results indicate that beta gamma subunits influence phospholipase C activity in a concentration range similar to that necessary for regulation of adenylate cyclase activity and suggest the involvement of a G-protein possessing an alpha beta gamma heterotrimeric structure in coupling hormone receptors to phospholipase C.

Identification and purification from bovine brain of a guanine-nucleotide-binding protein distinct from Gs, Gi and Go.

A guanine-nucleotide-binding protein (G-protein) was purified from cholate extracts of bovine brain membranes by sequential DEAE-Sephacel, Ultrogel AcA-34, heptylamine-Sepharose and Sephadex G-150 chromatography. Guanosine 5'-[gamma-[35S]thio]triphosphate (GTP[35S])-binding activity copurified with a 25,000 Da peptide and a 35,000-36,000 Da protein doublet. Neither pertussis toxin nor cholera toxin catalysed the ADP-ribosylation of a protein associated with the GTP[35S]-binding activity. Photoaffinity labelling of the purified protein with 8-azido[gamma-32P]GTP indicated that the GTP-binding site resides on the 25,000 Da protein. The 35,000-36,000 Da protein doublet was electrophoretically indistinguishable from the beta-subunits of other GTP-binding proteins, and the 36,000 Da protein was recognized by antiserum to oligomeric Gt. The purified protein specifically bound 17.2 nmol of GTP[35S]/mg of protein. The Kd of the binding site for radioligand was approx. 15 nM. The brain GTP-binding protein co-migrated during SDS/polyacrylamide-gel electrophoresis with a GTP-binding protein, named Gp, purified from human placenta [Evans, Brown, Fraser & Northup (1986) J. Biol. Chem. 261, 7052-7059], and cross-reacted with antiserum raised against the placental protein, but not with antiserum raised to brain Go. SDS/polyacrylamide-gel electrophoresis of the brain and placental GTP-binding proteins in the presence of Staphylococcus aureus V8 protease yielded identical peptide maps.

Comparison of binding of 125I-iodopindolol to control and desensitized cells at 37 degrees and on ice.

Binding of 125I-iodopindolol (IPIN) to intact 1321N1 human astrocytoma cell B-adrenergic receptors was measured at 37 degrees and on ice. Control cells showed a single component of IPIN binding on ice with the same total number of receptors as measured at 37 degrees. In desensitized cells (pretreated for 20 min with 1 microM isoproterenol) approximately 40% of IPIN binding on ice exhibited kinetics similar to those observed in control cells. The remaining 60% of receptors were labelled by IPIN at a much slower rate requiring the use of very high concentrations of IPIN. Sucrose density gradient fractionation was used to separately study the labelling of plasma membrane receptors and those associated with a light vesicle fraction. Labelling by IPIN on ice of the plasma membrane receptors of control cells was rapid, labelling of the light vesicle receptors of desensitized cells was slow, and labelling of the plasma membrane receptors of desensitized cells appeared to occur with both rapid and slow components. Selective labelling of the plasma membrane receptors of intact cells thus could be obtained by incubation with IPIN on ice under selected conditions. Similar results were obtained when broken cell preparations from control and desensitized cells were used. The decreased binding of IPIN on ice to B-adrenergic receptors in the light vesicle fraction not only provides further evidence consistent with sequestration of B-adrenergic receptors during desensitization, it also provides a convenient and inexpensive means to assay the sequestration reaction.

Agonist-induced alteration in the membrane form of muscarinic cholinergic receptors.

Incubation of 1321N1 human astrocytoma cells with carbachol resulted in a rapid loss of binding of [3H]N-methylscopolamine ([3H]NMS) to muscarinic cholinergic receptors measured at 4 degrees C on intact cells; loss of muscarinic receptors in lysates from the same cells measured with [3H]quinuclidinyl benzilate [( 3H]QNB) at 37 degrees C occurred at a slower rate. Upon removal of agonist from the medium, the lost [3H]NMS binding sites measured on intact cells recovered with a t1/2 of approximately 20 min, but only to the level to which [3H]QNB binding sites had been lost; no recovery of "lost" [3H]QNB binding sites occurred over the same period. Based on these data and the arguments of Galper et al. (Galper, J. B., Dziekan, L. C., O'Hara, D. S., and Smith, T. W. (1982) J. Biol. Chem. 257, 10344-10356) regarding the relative hydrophilicity of [3H]NMS versus [3H]QNB, it is proposed that carbachol induces a rapid sequestration of muscarinic receptors that is followed by a loss of these receptors from the cell. These carbachol-induced changes are accompanied by a change in the membrane form of the muscarinic receptor. Although essentially all of the muscarinic receptors from control cells co-purified with the plasma membrane fraction on sucrose density gradients, 20-35% of the muscarinic receptors from cells treated for 30 min with 100 microM carbachol migrated to a much lower sucrose density. This conversion of muscarinic receptors to a "light vesicle" form occurred with a t1/2 approximately 10 min, and reversed with a t1/2 approximately 20 min. In contrast to previous results in this cell line regarding beta-adrenergic receptors (Harden, T. K., Cotton, C. U., Waldo, G. L., Lutton, J. K., and Perkins, J. P. (1980) Science 210, 441-443), agonist binding to muscarinic receptors in the light vesicle fraction obtained from carbachol-treated cells was still regulated by GTP. One interpretation of these data is that agonists induce an internalization of muscarinic receptors with the retention of their functional interaction with a guanine nucleotide regulatory protein.

Use of a density shift method to assess beta-adrenergic receptor synthesis during recovery from catecholamine-induced down-regulation in human astrocytoma cells.

Exposure of postconfluent 1321N1 human astrocytoma cells to 1.0 microM isoproterenol for 12-24 hr results in a 90% loss of beta-adrenergic receptors. Upon removal of agonist, recovery of beta-receptors to control levels occurs within 72 hr. The recovery of receptors is completely blocked by cycloheximide [R. C. Doss, J. P. Perkins, and T. K. Harden, J. Biol. Chem. 256:12281-12286 (1981)]. In contrast cycloheximide does not block recovery of beta-receptors after down-regulation in preconfluent cultures. To determine unambiguously if beta-receptor synthesis accounts for the recovery of receptors after down-regulation, post confluent cultures were incubated with isoproterenol and then transferred to agonist-free medium containing either normal or "heavy" (2H, 13C, 15N) amino acids. The rate and extent of beta-receptor recovery were similar in both normal and heavy amino acid-containing medium. When beta-receptors that had recovered in the heavy amino acid-containing medium were labeled with 125I-cyanopindolol, solubilized in Lubrol PX, and subjected to centrifugation on a 5-15% sucrose density gradient, they exhibited an increased mass compared to beta-receptors that recovered in the presence of normal amino acids. These results confirm that the density shift method is a useful approach for the study of beta-receptor synthesis and that new receptor synthesis occurs during recovery of beta-receptors from catecholamine-induced down-regulation in postconfluent cultures.

Relationship between an altered membrane form and a low affinity form of the beta-adrenergic receptor occurring during catecholamine-induced desensitization. Evidence for receptor internalization.

We have investigated the relationship between the catecholamine-induced occurrence in 1321N1 human astrocytoma cells of beta-adrenergic receptors that exhibit low apparent affinity for hydrophilic ligands in short-time assays with intact cells and a population of beta-adrenergic receptors that migrate in a light vesicle fraction on sucrose density gradients. Pretreatment of cells with concanavalin A prevents the generation of both of these forms of the receptor during incubation with agonists but does not prevent the agonist-induced decrease in isoproterenol-stimulated cyclic AMP production that also occurs during desensitization. Selective labeling of the low affinity beta-receptors with 125I-pindolol followed by centrifugation on sucrose density gradients revealed that all of the receptors in the light vesicle fraction from desensitized cells were of the low affinity type, but that a portion of the low affinity receptors also migrated in a heavier sucrose fraction together with the plasma membrane. In contrast, in control cells, no low affinity receptors were present in the heavy sucrose fractions. The agonist-induced occurrence of these various forms of the beta-adrenergic receptor can be explained on the basis of current models of desensitization involving agonist-induced internalization of beta-adrenergic receptors.