Inhibition of human pancreatic islet insulin release by receptor-selective somatostatin analogs directed to somatostatin receptor subtype 5.

Somatostatin (SS)-14 and SS28 are produced by pancreatic D cells and gut mucosa and inhibit pancreatic islet insulin and glucagon release. There are five distinct SS receptor (SSTR) subtypes, namely SSTR1-5, which show different affinities for SS14 and SS28. In order to identify the subtype responsible for inhibition of insulin release by human B cells, SSTR-selective SS analogs were tested in isolated human islets. Glucose-stimulated insulin secretion in human islets incubated for 1 hr at 20 mM glucose, and in islets cultured for 24 hr at a near-physiological (6.1 mM) glucose concentration, was inhibited (<50% of the control) by SSTR5-specific analogs and by SS14 and SS28. SS14, SS28, and different SSTR5 preferential analogs also inhibited islet amyloid polypeptide release during the 24-hr culture. On the other hand, a group of SSTR2-selective analogs failed to inhibit insulin release. Analysis by reverse transcription-polymerase chain reaction indicated that human islets express similar amounts of SSTR2 and SSTR5 mRNAs, while human pancreatic ductal cells express much lower levels of these mRNAs. In conclusion, our data suggest that SSTR5 is an important mediator of the insulin inhibitory action of SS in cultured human islets.

Real-time evaluation of somatostatin subtype 2 receptor activity employing the technique of cytosensor microphysiometry.

Five types of somatostatin (SS) receptors (sst1-5) have been cloned and are widely distributed in the central nervous system and variably expressed in target tissues of the periphery. At the cellular level, adenylate cyclase inhibition has been classically described in native and transfected cells expressing sst subtypes. In addition, ion channel modulation (K+, Ca2+), phospholipase C, phospholipase A2, and tyrosine phosphatase activation have also been reported. The present study describes a novel in vitro approach based on quantifying receptor-activated metabolic rate changes to evaluate SS biological activity in cells (CHO-K1) stably expressing the human (h) sst2 receptors. Real-time metabolic rate changes were evaluated by determining the rate of extracellular acidification (microphysiometry). The metabolic rate was transiently and potently (EC50 1 nM) increased in response to natural SS ligands, SS-14 and SS-28. The peak activation time was approximately 2 min. Pharmacological analysis for the sst2 receptor yielded rank order of potency for SS analogues of: MK-678 > BIM-23027 > octreotide > BIM-23014C << L-362,855 > BIM-23052 << BIM-23056. Similar rank orders were obtained from in vitro receptor binding studies in the same cell line. These results demonstrate that microphysiometry is a rapid and valid technique to evaluate the pharmacology SS receptor activation.

Exofacial epitope-tagged glucose transporter chimeras reveal COOH-terminal sequences governing cellular localization.

The insulin-regulated adipocyte/skeletal muscle glucose transporter (GLUT4) displays a characteristic steady-state intracellular localization under basal conditions, whereas the erythrocyte/brain transporter isoform (GLUT1) distributes mostly to the cell surface. To identify possible structural elements in these transporter proteins that determine their cellular localization, GLUT1/GLUT4 chimera cDNA constructs that contain the hemagglutinin epitope YPYDVPDYA (HA) in their major exofacial loops were engineered. Binding of monoclonal anti-HA antibody to non-permeabilized COS-7 cells expressing HA-tagged transporter chimeras revealed that expression of transporters on the cell surface was strongly influenced by their cytoplasmic COOH-terminal domain. This method also revealed a less marked, but significant effect on cellular localization of amino acid residues between transporter exofacial and middle loops. The subcellular distribution of expressed chimeras was confirmed by immunofluorescence microscopy of permeabilized COS-7 cells. Thus, HA-tagged native GLUT4 was concentrated in the perinuclear region, whereas a chimera containing the COOH-terminal 29 residues of GLUT1 substituted onto GLUT4 distributed to the plasma membrane, as did native GLUT1. Furthermore, a chimera composed of GLUT1 with a GLUT4 COOH-terminal 30-residue substitution exhibited a predominantly intracellular localization. Similar data was obtained in CHO cells stably expressing these chimeras. Taken together, these results define the unique COOH-terminal cytoplasmic sequences of the GLUT1 and GLUT4 glucose transporters as important determinants of cellular localization in COS-7 and CHO cells.

Catalysis of serine and tyrosine autophosphorylation by the human insulin receptor.

The protein kinase activity of human insulin receptors purified from Sf9 insect cells after infection with a recombinant baculovirus was evaluated. The following experimental observations led to the unexpected conclusion that this receptor protein catalyzes both serine and tyrosine autophosphorylation at significant stoichiometries. (i) Phosphorylation of lectin-purified insulin receptors with [gamma-32P]ATP resulted in rapid receptor tyrosine phosphorylation (7 mol of P per high-affinity binding site) and the delayed onset of insulin-stimulated receptor serine phosphorylation (about 7% of total phosphorylation). The tyrosine kinase inhibitor (hydroxy-2-naphthalenylmethyl)phosphonic acid (HNMPA), which has no effect on protein kinase C or cyclic AMP-dependent protein kinase activities, inhibited both the receptor serine and tyrosine phosphorylation. (ii) Phosphorylation of a synthetic peptide substrate composed of insulin receptor residues 1290-1319 on serines-1305/1306 by partially purified insulin receptors was also inhibited by HNMPA. (iii) Insulin receptors sequentially affinity-purified on immobilized wheat germ agglutinin and immobilized insulin showed no apparent contaminant proteins on silver-stained SDS/polyacrylamide gels yet catalyzed autophosphorylation on receptor serine and tyrosine residues when incubated with [gamma-32P]ATP. These results suggest that the catalytic site of the insulin receptor tyrosine kinase also recognizes receptor serine residues as substrates for the phosphotransfer reaction. Furthermore, insulin-stimulated receptor serine phosphorylation in intact cells may occur in part by an autophosphorylation mechanism subsequent to tyrosine phosphorylation of the insulin receptor.

Complex regulation of simple sugar transport in insulin-responsive cells.

Facilitated sugar entry into mammalian cells is catalysed by multiple isoforms of the glucose transporter and regulated by hormonal stimuli, nutritional status and oncogenesis. A large reserve of latent glucose transport capacity must be maintained by muscle and adipose cells that are sensitive to insulin, the primary activator of sugar uptake after feeding. Intracellular sequestration of sugar transporters accounts for a large part of this latent capacity, but new findings suggest that there is also reversible suppression of intrinsic catalytic activity of those glucose transporters residing at the cell surface. The mechanism of this suppression appears to be occlusion or disruption of the exofacial sugar-binding sites on the glucose-transporter proteins.

Evidence that functional erythrocyte-type glucose transporters are oligomers.

In this study we tested the hypothesis that functional erythrocyte-type glucose transporters (GLUT1) exist as oligomeric complexes by expressing chimeric transporter proteins in Chinese hamster ovary cells harboring endogenous GLUT1 transporters. The chimeric transporters were GLUT1-4c, in which the 29 C-terminal residues of human GLUT1 were replaced by the 30 C-terminal residues of rat skeletal muscle glucose transporter (GLUT4), and GLUT1n-4, containing the N-terminal 199 residues of GLUT1 and the 294 C-terminal residues of GLUT4. Endogenous GLUT1 was quantitatively co-immunoprecipitated by using an anti-GLUT4 C-terminal peptide antibody from detergent extracts of Chinese hamster ovary cells expressing either of the chimeric proteins, as detected by immunoblotting the precipitates with an anti-GLUT1 C-terminal peptide antiserum. No co-immunoprecipitation of native GLUT1 with native GLUT4 from extracts of 3T3-L1 adipocytes, which contain both these transporters, was observed with the same antibody. These data are consistent with the hypothesis that GLUT1 transporters exist as homodimers or higher order oligomers and that a major determinant of oligomerization is located within the first 199 residues of GLUT1.

G alpha i-G alpha s chimeras define the function of alpha chain domains in control of G protein activation and beta gamma subunit complex interactions.

Gs and Gi2 are G proteins whose alpha subunits are 65% homologous. Within the 355 amino acid alpha i2 polypeptide, substitution of residues Ile213-Lys319 with the corresponding alpha s region (Ile235-Arg356) generated a chimera that activated adenylyl cyclase, indicating that the alpha s activation domain resides within this 122 amino acid alpha s sequence. Mutation within alpha s residues Glu15-Pro144 resulted in an alpha s polypeptide having an enhanced rate of GDP dissociation. Mutation within two regions of the N-terminus influenced the ability of pertussis toxin to ADP-ribosylate the alpha subunit polypeptide, a reaction controlled by the beta gamma subunit complex. The findings define the G protein alpha subunit N-terminus as a regulatory region controlling beta gamma subunit interactions and GDP dissociation independent of the GTPase and effector activation domains.

Mutation of the Gs protein alpha subunit NH2 terminus relieves an attenuator function, resulting in constitutive adenylyl cyclase stimulation.

G-proteins couple hormonal activation of receptors to the regulation of specific enzymes and ion channels. Gs and Gi are G-proteins which regulate the stimulation and inhibition, respectively, of adenylyl cyclase. We have constructed two chimeric cDNAs in which different lengths of the alpha subunit of Gs (alpha s) have been replaced with the corresponding sequence of the Gi alpha subunit (alpha i2). One chimera, referred to as alpha i(54)/s' replaces the NH2-terminal 61 amino acids of alpha s with the first 54 residues of alpha i. Within this sequence there are 7 residues unique to alpha s, and 16 of the remaining 54 amino acids are nonhomologous between alpha i and alpha s. The second chimera, referred to as alpha i/s(Bam), replaces the first 234 amino acids of alpha s with the corresponding 212 residues of alpha i. Transient expression of alpha i(54)/s in COS-1 cells resulted in an 18- to 20-fold increase in cyclic AMP (cAMP) levels, whereas expression of either alpha i/s(Bam) or the wild-type alpha s polypeptide resulted in only a 5- to 6-fold increase in cellular cAMP levels. COS-1 cells transfected with alpha i showed a small decrease in cAMP levels. Stable expression of the chimeric alpha i(54)/s polypeptide in Chinese hamster ovary (CHO) cells constitutively increased both cAMP synthesis and cAMP-dependent protein kinase activity. CHO clones expressing transfected alpha i/s(Bam) or the wild-type alpha s and alpha i cDNAs exhibited cAMP levels and cAMP-dependent protein kinase activities similar to those in control CHO cells. Therefore, the alpha i(54)/s chimera behaves as a constitutively active alpha s polypeptide, whereas the alpha i/s(Bam) polypeptide is regulated similarly to wild-type alpha s. Expression in cyc-S49 cells, which lack expression of wild-type alpha s, confirmed that the alpha i(54)/s polypeptide is a highly active alpha s molecule whose robust activity is independent of any change in intrinsic GTPase activity. The difference in phenotypes observed upon expression of alpha i(54)/s or alpha i/s(Bam) indicates that the NH2-terminal moieties of alpha s and alpha i function as attenuators of the effector enzyme activator domain which is within the COOH-terminal half of the alpha subunit. Mutation at the NH2 terminus of alpha s relieves the attenuator control of the Gs protein and results in a dominant active G-protein mutant.

Mutation of glycine 49 to valine in the alpha subunit of GS results in the constitutive elevation of cyclic AMP synthesis.

The G-protein GS couples hormone-activated receptors with adenylyl cyclase and stimulates increased cyclic AMP synthesis. Transient expression in COS-1 cells of cDNAs coding for the GS alpha-subunit (alpha S) or alpha S cDNAs having single amino acid mutations Gly49----Val or Gly225----Thr elevated cyclic AMP levels, resulting in the activation of cyclic AMP dependent protein kinase. Stable expression in Chinese hamster ovary cells of alpha S Val49 cDNA resulted in a small constitutive elevation of cyclic AMP that was sufficient to persistently activate cyclic AMP dependent protein kinase activity 1.5-2-fold over basal activity. Stable expression of wild-type alpha S or alpha S Thr225 in Chinese hamster ovary cells was less effective in sustaining elevated cyclic AMP synthesis and kinase activation compared to alpha SVal49.

Expression of a G alpha s/G alpha i chimera that constitutively activates cyclic AMP synthesis.

A chimeric G alpha subunit cDNA, referred to as G alpha s/i(38), was constructed containing the complete 5'-untranslated region of G alpha s, the first 356 codons of the rat G alpha s and the last 36 codons and 428 base pairs of the 3'-untranslated region of the rat G alpha i cDNA. Transient expression of the G alpha s/i(38) protein in COS cells allowed detection of a chimeric protein which was recognized by antibodies generated against an internal G alpha s sequence as well as antibodies recognizing the carboxyl terminus of G alpha i2. Chinese hamster ovary cell clones stably expressing the chimeric G-protein alpha subunit transcript (G alpha s/i(38] demonstrated 1.5-2.5-fold constitutively elevated cyclic AMP levels and a 3-4-fold increase in the activity ratio of cyclic AMP-dependent protein kinase, although expression of the chimeric polypeptide could not be demonstrated presumably because of low expression of the mutant alpha s. Expression of the rat G alpha s transcript yielded clones that were similar to wild-type Chinese hamster ovary cells in regard to cyclic AMP levels and protein kinase activity. In the presence of methyl isobutylxanthine, a cyclic AMP phosphodiesterase inhibitor, cyclic AMP levels in clones expressing the G alpha s/i(38) transcript were 10-15-fold higher than G alpha s expressing clones. Adenylyl cyclase activation by guanosine 5'-O-(thiotriphosphate) (GTP gamma S) in membranes from clones expressing the G alpha s/i(38) transcript demonstrated a diminished lag time for maximal activation, indicating an increased relative GDP dissociation rate for the chimeric G alpha subunit and an increase in total adenylyl cyclase activity relative to wild-type G alpha s expressing clones. Cholate extracts from membranes of G alpha s/i(38) expressing clones, when mixed with cyc- S49 membranes, reconstituted an increased GTP gamma S-stimulated adenylyl cyclase activity and a diminished lag time for maximal activation compared to cholate extracts prepared from G alpha s-expressing clones. The G alpha s/i(38) construct confers a dominant constitutive activation of adenylyl cyclase when expressed in cells in the presence of a background of wild-type G alpha s.

Receptor activation of G proteins.

G proteins are a highly conserved family of membrane-associated proteins composed of alpha, beta, and gamma subunits. The alpha subunit, which is unique for each G protein, binds GDP or GTP. Receptors such as those for beta- and alpha-adrenergic catecholamines, muscarinic agonists, and the retinal photoreceptor rhodopsin, catalyze the exchange of GDP for GTP binding to the alpha subunit of a specific G protein. G alpha.GTP regulates appropriate effector enzymes such as adenylyl cyclase or the cyclic GMP phosphodiesterase. The beta gamma-subunit complex of G proteins is required for efficient receptor-catalyzed alpha subunit guanine nucleotide exchange and also functions as an attenuator of alpha subunit activation of effector enzymes. Recent elucidation of both receptor and G protein primary sequence has allowed structural predictions and new experimental approaches to study the mechanism of receptor-catalyzed G protein regulation of specific effector systems and the control of cell function including metabolism, secretion, and growth.

Human liver phosphatase 2A: cDNA and amino acid sequence of two catalytic subunit isotypes.

Two cDNA clones were isolated from a human liver library that encode two phosphatase 2A catalytic subunits. The two cDNAs differed in eight amino acids (97% identity) with three nonconservative substitutions. All of the amino acid substitutions were clustered in the amino-terminal domain of the protein. Amino acid sequence of one human liver clone (HL-14) was identical to the rabbit skeletal muscle phosphatase 2A cDNA (with 97% nucleotide identity). The second human liver clone (HL-1) is encoded by a separate gene, and RNA gel blot analysis indicates that both mRNAs are expressed similarly in several human clonal cell lines. Sequence comparison with phosphatase 1 and 2A indicates highly divergent amino acid sequences at the amino and carboxyl termini of the proteins and identifies six highly conserved regions between the two proteins that are predicted to be important for phosphatase enzymatic activity.