Activation of adenylate cyclase in cultured fibroblasts by trypsin

Adenylate cyclase activity measured in membranes of cultured normal rat kidney (NRK) fibroblasts was markedly increased by prior treatment of the intact cells with trypsin. Cell population density influenced the extent of activation observed. Trypsin treatment of sparse cells significantly enhanced adenylate cyclase activity, whereas similar treatment of confluent cells caused only a slight increase in adenylate cyclase activity. The degree of activation noted after trypsin treatment also varied depending on the adenylate cyclase function measured. Activity determined in the presence of GTP alone showed the greatest increase after trypsin treatment. Similar enhancement of adenylate cyclase activity of a washed cell membrane preparation was achieved by the addition of low concentrations of trypsin directly to the adenylate cyclase reaction mixture. The membranes of confluent NRK fibroblasts initially exhibited higher adenylate cyclase activity than did membranes of sparse cells. The present results suggest that this change in adenylate cyclase activity at cell confluence is not due to an increase in the amount of adenylate cyclase in the cell membrane but rather to a change in membrane components that regulate its activity. Proteolytic activation of adenylate cyclase appears to result from degradation of cell membrane proteins that modulate the activity of this enzyme.     

Limited trypsin proteolysis of photoreceptor GTP-binding protein. Light- and GTP-induced conformational changes

The amphibian photoreceptor rod outer segment contains a guanine nucleotide-binding complex which consists of a 39,000-dalton polypeptide that binds guanine nucleotides (G protein), a 36,000-dalton polypeptide (H protein), and an approximately 6,500-dalton polypeptide. Sensitivity to trypsin proteolysis was utilized as a probe of structure-function relationships for these polypeptides. Digestion of the H protein generated fragments of 26,000 and 15,000 daltons whose proteolytic susceptibility was not altered by guanosine triphosphates, light, or membranes. The approximately 6,500-dalton polypeptide was not trypsin sensitive. When the G protein was eluted from illuminated membranes by GTP, trypsin proteolysis cleaved a terminal 1,000-dalton fragment (G1) to yield a 38,000-dalton fragment (G38). With increased digestion time, a 6,000-dalton fragment (G6) was removed from G38 to yield a 32,000-dalton fragment (G32). G32 was subsequently digested to fragments of 23,000 and 12,000 daltons. However, when the G protein was eluted from illuminated membranes by hydrolysis-resistant analogues of GTP, G32 was protected from further digestion. This is consistent with a GTP-induced conformational change in the G protein which is altered by GTP hydrolysis. Proteolysis of the G protein after covalent labeling with a photoaffinity analogue of GTP demonstrated that the analogue is bound to first G38 and then G32, indicating the GTP-binding site is associated with G32. Fragment G6 was cleaved when the G protein was soluble or bound to unilluminated membranes. However, when bound to illuminated membranes, fragments were generated reflecting the loss of 7,500, 9,000, or 11,000 daltons from the G protein. This light-induced alteration in proteolytic susceptibility indicates there is a light-induced conformational change in the G protein. Fragment G1 was not removed from the G protein when it was membrane bound, suggesting G1 is involved in binding to a membrane structure. These data suggest that the light-induced binding of the G protein to illuminated membranes and the reversal of this binding by GTP are mediated through conformational changes in the G protein and that three conformations exist: 1) a basal, inactive conformation; 2) a primed conformation induced by binding to photolyzed rhodopsin, with a high affinity for GTP; and 3) an active conformation, induced by binding of GTP, which activates the catalytic complex of light-activated phosphodiesterase.     

Trypsin modifies the activity of adenylate cyclase from normal, malignant and hybrid mammalian cells

Adenylate cyclase (ATP pyrophosphate-lyase (cylizing), EC 4.6.1.1) activity, measured in homogenates of normal, malignant and hybrid mammalian cell lines, is enhanced and subsequently inhibited by increasing concentrations of trypsin (EC 3.4.21.4). Treatment of intact cells with trypsin appears to cause latent activation of adenylate cyclase (i.e. activation which is only expressed after homogenization of the cells). Conversely, adenylate cyclase activity of a normal Chinese hamster fibroblast cell line is inhibited in intact cells by trypsin through the degradation of some site on the outer surface of the plasma membrane. The prostaglandin E1 receptor is not affected by trypsinization of cells.     

Does the guanine nucleotide regulatory protein Ni mediate progesterone inhibition of Xenopus oocyte adenylate cyclase?

In Xenopus laevis oocytes progesterone is able to inhibit directly the plasma membrane adenylate cyclase activity and induce reinitiation of meiotic maturation. To determine whether progesterone inhibition is mediated by the inhibitory guanine nucleotide-binding regulatory component of adenylate cyclase, Ni, the effect of the Bordetella pertussis toxin (IAP) and limited proteolysis on progesterone action in oocytes was investigated. Treatment of oocyte membranes with islet activating protein (IAP) in the presence of [32P]NAD led to incorporation of radiolabel into a 41 000-dalton membrane protein. However, exposure of isolated oocytes to 100 ng/ml IAP for up to 24 h, or oocyte membranes with concentrations of toxin as high as 100 micrograms/ml, had no effect on either progesterone inhibition of adenylate cyclase or induction of maturation. Similarly, limited alpha-chymotrypsin proteolysis of oocyte membranes failed to modify progesterone-induced inhibition of adenylate cyclase. In contrast, inhibition of human platelet adenylate cyclase by epinephrine, acting via a GTP-dependent, alpha 2-adrenergic receptor-mediated pathway, is almost completely abolished by both IAP treatment and limited proteolysis of platelet membranes. These data indicate that unlike attenuation of platelet enzyme activity, the inhibition of adenylate cyclase in oocyte membranes by progesterone does not occur via a classical Ni-mediated pathway.     

Activation of pigeon erythrocyte adenylate cyclase by cholera toxin partial purification of an essential macromolecular factor from horse erythrocyte cytosol

A cytosolic, macromolecular factor required for the cholera toxin-dependent activation of pigeon erythrocyte adenylate cyclase and cholera toxin-dependent ADP-ribosylation of a membrane-bound 43 000 dalton polypeptide has been purified 1100-fold from horse erythrocyte cytosol using organic solvent precipitation and heat treatment. This factor, 13 000 daltons, does not absorb to anionic or cationic exchange resins, is sensitive to trypsin or 10% trichloroacetic acid and is not extractable by diethyl ether. Activation of adenylate cyclase by cholera toxin requires the simultaneous presence of ATP (including possible trace GTP), NAD⁺, dithiothreitol, cholera toxin, membranes and the cytosolic macromolecular factor. Reversal of cholera toxin activation of adenylate cyclase, and of the toxin-dependent ADP-ribosylation, requires the presence of the cytosolic factor. The ability of the purified cytosolic factor to influence the hormonal sensitivity of liver membrane adenylate cyclase may provide clues to its physiological functions.     

Activation of rat brain adenylate cyclase by proteases: involvement of distinct protein components in the activation by α-chymotrypsin and trypsin

Adenylate cyclase in synaptic plasma membranes from rat brain is activated by α-chymotrypsin or trypsin. These proteases also activate adenylate cyclase reconstituted from the catalytic subunit of adenylate cyclase and the partially purified fraction of the GTP-binding proteins containing both the stimulatory and inhibitory GTP-binding proteins. Properties of the activation of reconstituted adenylate cyclase by the proteases are as follows. (1) The proteases do not directly activate the catalytic subunit. However, the pre-treatment of the partially purified GTP-binding proteins with α-chymotrypsin (100 μg/ml) increases the subsequently reconstituted cyclase activity at least 3-fold. Trypsin (10–30 μg/ml) much more weakly enhances the cyclase activity. (2) α-Chymotrypsin and trypsin synergistically activate the cyclase. (3) Trypsin but not α-chymotrypsin no longer activates the cyclase when the purified stimulatory GTP-binding protein (Gs) replaces the partially purified GTP-binding proteins. (4) The stimulatory effects of α-chymotrypsin and trypsin on the cyclase activity are little or slight unless 5′-guanylylimidodiphosphate (Gpp(NH)p) is present in the reconstitution. (5) The purified βγ-subunits of the GTP-binding proteins markedly inhibit adenylate cyclase. This inhibition is nearly completely attenuated by treating the βα-subunits with α-chymotrypsin (> 10 μg/ml). (6) Trypsin (1–10 μg/ml) inactivates the GTPase of the α-subunit of the inhibitory GTP-binding protein (Gi). This inactivation of the GTPase seems to correlate with the activation of the reconstituted adenylate cyclase by trypsin.We conclude that two distinct protein components are involved in the activation of adenylate cyclase by α-chymotrypsin and trypsin. One component sensitive to α-chymotrypsin is probably the βγ-subunits of the GTP-binding proteins. The other component sensitive to trypsin may be the α-subunit of Gi.     

Activation of rat liver guanylate cyclase by proteolysis.

Guanylate cyclase activity (GTP pyrophosphate-lyase (cyclizing), EC 4.6.1.2.), measured in purified rat liver plasma membranes, was markedly increased by treatment with various purified proteases. The effect was maximal with trypsin, alpha-chymotrypsin, papain, and thermolysin (6- to 8-fold increase with 5 to 20 microgram of protease/ml) and lower with subtilisin and elastase (3- to 4-fold increase). The activation was due to an increase in the maximal velocity of the cyclizing reaction. No modification was observed either in the apparent affinity for the substrate MnGTP or in the cooperative behavior of the enzyme kinetics which displayed Hill coefficients of 1.6 for both basal and activated states. The Triton X-100-dispersed guanylate cyclase remained sensitive to papain, which suggests that the action of proteases was not restricted to an indirect action upon the membranous environment of the guanylate cyclase. In contrast, the cytosolic soluble guanylate cyclase, assayed in the presence or absence of sodium azide, was absolutely insensitive to papain. Thus, proteolysis represents a previously undescribed mechanism for activating membranous guanylate cyclase systems, which might be of importance in the physiological regulation of this enzyme.     

Effect of proteases and protease inhibitors on adenylate cyclase activity in rat cerebral cortical membranes

Mild proteolysis of membrane preparations from rat cerebral cortex with low concentrations of endopeptidases such as trypsin or chymotrypsin caused a 50–400% increase in the basal adenylate cyclase activity. Maximal activation of adenylate cyclase was obtained by including the protease in the adenylate cyclase assay, although an activated preparation could be obtained by pretreatment of the membranes with proteolytic enzymes. The proteolytically activated enzyme showed an increased V, with very little change in the K_m for the substrate, ATP. The proteolytically activated enzyme retained responsiveness to activation by sodium fluoride and 5′-guanylylimidodiphosphate (GppNHp), but was no longer activated by gangliosides or calcium-dependent activator protein. Activation by alcohols and detergent was lost or reduced in magnitude. The activity of adenylate cyclase after protease treatment showed a very marked temperature dependence, with maximal activity expressed in the 30–40 °C range and no activation due to the prior protease treatment expressed at either 10 or 50 °C. Basal adenylate cyclase activity was usually slightly inhibited in the presence of various protease inhibitors. Activation by fluoride, gangliosides, or GppNHp was little affected by protease inhibitors although one inhibitor, N-α-tosyl-l-lysine chloromethyl ketone, caused an inhibition of the ganglioside and GppNHp responses, slightly inhibited the fluoride response, and blocked the norepinephrine response normally seen in the presence of gangliosides or GppNHp. This inhibitor caused a loss of β-adrenergic binding sites for dihydroalprenolol in rat cortical membranes which paralleled the loss of the responsiveness of adenylate cyclase to a GppNHp-norepinephrine combination.     

Photoreceptor GTP binding protein mediates fluoride activation of phosphodiesterase

In this report, we show that fluoride activates dark-adapted rod outer segment phosphodiesterase, and that this activation is mediated, in analogy with adenylate cyclase, through a GTP binding protein. The GTP binding protein is released from dark-adapted rod outer segment membranes by exposure to fluoride and subsequent centrifugation. The 39-kilodalton subunit of the GTP binding protein, released from the membrane by this procedure, exhibits altered susceptibility to limited trypsin proteolysis, identical to that seen when hydrolysis-resistant GTP analogs are bound to that subunit. Repeated exposure of dark-adapted rod outer segment membranes to fluoride and subsequent centrifugation results in maximal activation of the membrane-bound phosphodiesterase. Thus, activation of phosphodiesterase by fluoride in the dark appears similar to fluoride activation of adenylate cyclase.     

Topology of mannosidase II in rat liver Golgi membranes and release of the catalytic domain by selective proteolysis

The orientation of mannosidase II, an integral Golgi membrane protein involved in asparagine-linked oligosaccharide processing, has been examined in rat liver Golgi membranes. Previous studies on mannosidase II purified from Golgi membranes revealed an intact subunit of 124,000 daltons, as well as a catalytically active 110,000-dalton degradation product generated during purification (Moremen, K. W., and Touster, O. (1985) J. Biol. Chem. 260, 6654-6662). In Triton X-100 extracts of Golgi membranes, the intact enzyme was cleaved by a variety of proteases to generate degradation products similar to those observed previously. At appropriate concentrations, chymotrypsin, pronase, and proteinase K generated 110,000-dalton species, while trypsin and Staphylococcus aureus V8 protease generated 115,000-dalton forms. Cleavage by chymotrypsin under mild conditions (10 micrograms/ml, 10 min, 20 degrees C) resulted in a complete conversion to a catalytically active 110,000-dalton form of the enzyme which was extremely resistant to further degradation. Attempts to demonstrate these protease digestions in nonpermeabilized Golgi membranes were unsuccessful, a result suggesting that the protease-sensitive regions are not accessible on the external surface of the membrane. In Golgi membranes permeabilized by treatment with 0.5% saponin, mannosidase II could readily be cleaved to the 110,000-dalton form by digestion with chymotrypsin under conditions similar to those which result in a proteolytic inactivation of galactosyltransferase, a lumenal Golgi membrane marker. Although mannosidase II catalytic activity was not diminished by this chymotrypsin digestion, as much as 90% of the enzyme activity was converted to a nonsedimentable form. To examine the effect of the proteolytic cleavage on the partition behavior of the enzyme, control and chymotrypsin-treated Triton X-114 extracts of Golgi membranes were examined by phase separation at 35 degrees C. The undigested enzyme partitioned into the detergent phase consistent with its location as an integral Golgi membrane protein, while the 110,000-dalton chymotrypsin-digested enzyme partitioned almost exclusively into the aqueous phase in a manner characteristic of a soluble protein. These results suggest that mannosidase II catalytic activity resides in a proteolytically resistant, hydrophilic 110,000-dalton domain. Attachment of this catalytic domain to the lumenal face of Golgi membranes is achieved by a proteolytically sensitive linkage to a 14,000-dalton hydrophobic membrane anchoring domain.     

Alteration in the protein components of catecholamine-sensitive adenylate cyclase during maturation of rat reticulocytes

The maturing rat reticulocyte was used as a model system in which to study developmental changes in the protein components of hormone-sensitive adenylate cyclase. Plasma membranes from rat erythrocytes display 10 to 20% of the adenylate cyclase activity and 30 to 50% of the beta-adrenergic receptors which are measured in membranes from rat reticulocytes, as noted by others. Reticulocyte membranes also display equal activities in response to (-)-isoproterenol in the presence of either GTP or GTP gamma S, whereas erythrocyte membrane adenylate cyclase is twice as active in the presence of isoproterenol plus GTP gamma S as in the presence of isoproterenol plus GTP. We have studied this system in greater detail by developing or applying independent assays for the catalytic protein (C) and the guanine nucleotide-binding regulatory protein (G/F) of adenylate cyclase. C was assayed in membranes by its intrinsic Mn2+-stimulated activity. It was also measured by reconstituting membranes with saturating amounts of GTP gamma S-activated G/F, yielding an operationally defined Vmax for the catalyst. By either assay, reticulocytes display about 3-fold greater C activity than do erythrocytes. G/F was assayed by its ability to confer GTP gamma S-stimulated activity upon C (which was supplied by membranes of cyc- S49 lymphoma cells). This assay indicates that reticulocyte membranes contain about 3 times as much G/F as do erythrocyte membranes. Cholera toxin and [32P]NAD were used to [32P]ADP-ribosylate the 45,000- and 52,000-dalton subunits of G/F. Total incorporation of 32P into these subunits decreased 3- to 4-fold with reticulocyte maturation. The ratio of label in the 52,000-dalton peptide to that in the 45,000-dalton peptide decreased from 0.29 in reticulocyte membranes to 0.14 in erythrocyte membranes. The apparently coordinate decrease in the amounts of C, G/F, and beta-adrenergic receptors suggest that the stoichiometry between these components is maintained during maturation, and may account for the decrease in adenylate cyclase in the membranes. However, the qualitative changes in responsiveness to hormones in the presence of GTP or GTP gamma S may be related to loss or proteolysis of the 52,000-dalton subunit of G/F.     

Identification and characterization of cellular targets for tyrosine protein kinases

Protein kinases associated with the transforming proteins of a number of retroviruses are specific for tyrosine. Several proteins in cells transformed by these viruses are phosphorylated at tyrosine. We have now identified three unrelated abundant nonphosphorylated cellular proteins of 46,000, 39,000 and 28,000 daltons in chick embryo cells, which are the unphosphorylated forms of phosphotyrosine-containing proteins and thus are substrates for tyrosine protein kinases. By two-dimensional gel analysis, we have found that the 46,000-dalton protein exists in two unphosphorylated forms of which the more acidic is a minor species. This latter form is phosphorylated, chiefly at serine, in both normal and transformed cells, generating a yet more acidic species. In transformed but not normal cells, the major form is phosphorylated at tyrosine and serine, yielding a fourth isoelectric variant. The 46,000-dalton unphosphorylated protein has been partially purified, and antiserum to it recognizes all four isoelectric variants of the protein. The 39,000-dalton protein has two unphosphorylated forms of which the more acidic is a minor species. The major form is phosphorylated at tyrosine and serine in transformed cells only. The 39,000-dalton unphosphorylated protein has been partially purified, and antiserum raised to it recognizes all three isoelectric variants. The 28,000-dalton protein has a single phosphorylated form which contains serine in normal cells, but both serine and tyrosine in transformed cells.     

Protein kinase C stimulates adenylate cyclase activity in prolactin-secreting rat adenoma (GH4C1) pituicytes by inactivating the inhibitory GTP-binding protein Gi

The phorbol ester 12-O-tetradecanoyl-phorbol 13-acetate (TPA) and thyroliberin exerted additive stimulatory effects on prolactin release and synthesis in rat adenoma GH4C1 pituicytes in culture. Both TPA and thyroliberin activated the adenylate cyclase in broken cell membranes. When combined, the secretagogues displayed additive effects. TPA did not alter the time course (time lag) of adenylate cyclase activation by hormones, guanosine 5'-[beta,gamma-imino]triphosphate or forskolin, nor did it affect the enzyme's apparent affinity (basal, 7.2 mM; thyroliberin-enhanced, 2.2 mM) for free Mg2+. The TPA-mediated adenylate cyclase activation was entirely dependent on exogenously added guanosine triphosphate. ED50 (dose yielding half-maximal activation) was 60 microM. Access to free Ca2+ was necessary to express TPA activation of the enzyme, however, the presence of calmodulin was not mandatory. TPA-stimulated adenylate cyclase activity was abolished by the biologically inactive phorbol ester, 4 alpha-phorbol didecanoate, by the protein kinase C inhibitor polymyxin B and by pertussis toxin, while thyroliberin-sensitive adenylate cyclase remained unaffected. Experimental conditions known to translocate protein kinase C to the plasma membrane and without inducing adenylate cyclase desensitization, increased both basal and thyroliberin-stimulated enzyme activities, while absolute TPA-enhanced adenylate cyclase was maintained. Association of extracted GTP-binding inhibitory protein, Gi, from S49 cyc- murine lymphoma cells with GH4C1 cell membranes yielded a reduction of basal and hormone-stimulated adenylate cyclase activities, while net inhibition of the cyclase of somatostatin was dramatically enhanced. However, TPA restored completely basal and hormone-elicited adenylate cyclase activities in the Gi-enriched membranes. Finally, TPA completely abolished the somatostatin-induced inhibition of adenylate cyclase in both hybrid and non-hybrid membranes. These data suggest that, in GH4C1 cells, protein kinase C stimulation by phorbol esters completely inactivates the n alpha i subunit of the inhibitory GTP-binding protein, leaving the n beta subunit functionally intact. It can also be inferred that thyroliberin conveys its main effect on the adenylate cyclase through activation of the stimulatory GTP-binding protein, Gs.     

A new GTP-binding protein in differentiated human leukemic (HL-60) cells serving as the specific substrate of islet-activating protein, pertussis toxin

A GTP-binding protein serving as the specific substrate of islet-activating protein (IAP), pertussis toxin, was partially purified from human leukemic (HL-60) cells that had been differentiated into neutrophil type. The partially purified protein, referred to as GHL, predominantly consisted of at least two polypeptides with molecular masses of 40,000 daltons (alpha) and 36,000 or 35,000 daltons (beta). The structure was similar to Gi or Go previously purified from rat brain as an alpha beta gamma-heterotrimeric IAP substrate (Katada, T., Oinuma, M., and Ui, M. (1986) J. Biol. Chem. 261, 8182-8191), although the existence of the gamma of GHL was unclear. The 40,000-dalton polypeptide contained the site for IAP-catalyzed ADP-ribosylation and the binding site for guanine nucleotide with a high affinity. The 36,000- and 35,000-dalton polypeptides were cross-reacted with the affinity-purified antibody raised against the beta of brain Gi and Go. Limited proteolysis with trypsin and immunoblot analyses with the use of the affinity-purified antibodies raised against the alpha of brain Gi or Go indicated that the alpha of GHL was different from the alpha of Gi or Go. Kinetics of guanosine 5'-(3-O-thio)triphosphate (GTP gamma S) binding to GHL was also quite different from that to brain Gi or Go. Incubation of GHL with GTP gamma S resulted in a resolution into GTP gamma S-bound alpha and beta(gamma) thus purified had abilities to inhibit a membrane-bound adenylate cyclase activity and to associate with the alpha of brain IAP substrate in a fashion similar to the beta gamma of brain IAP substrates, suggesting that there were no significant differences in the biological activities between the beta(gamma) of GHL and those of Gi or Go. Physiological roles of the new GTP-binding protein, GHL, purified from the neutrophil-like cells in receptor-mediated signal transduction are discussed.     

A protein activator for the adenylate cyclase of Bordetella pertussis.

The activity of Bordetella pertussis extracytoplasmic adenylate cyclase is 100-fold higher in organisms grown on blood agar than in those grown in synthetic medium. This increase in activity is due to in vivo activation of the enzyme by a factor present in erythrocytes. Activation also occurs in killed or disrupted organisms. The activator can be separated from heme proteins and has been purified approximately 100-fold from erythrocytes, yielding material of approximately 105,000 daltons. It is sensitive to trypsin and alpha-chymotrypsin and exhibits considerable heat stability. Activation of cyclase in intact B. pertussis organisms exhibits a lag of 3 to 4 min and is not reversed by washing. Response to the activator decreases with increasing purification of the adenylate cyclase and is absent in the pure enzyme. The activation does not appear to be proteolytic and does not appear to change access to the substrate, ATP. The activator has no effect on a number of eukaryotic cyclases. We conclude that this is a new type of activation and that the activator differs from all those previously described.     

Biochemical analysis of triggering signals induced by bridging of IgE receptors

Bridging of IgE receptors on rat mast cell plasma membranes induces phospholipid methylation and a monophasic increase in cyclic AMP. The stimulation of phospholipid methylation in the plasma membrane appears to be intrinsic to the processes leading to Ca2+ influx and histamine release. Evidence was obtained that IgE receptors are closely associated with methyltransferases and adenylate cyclase in the plasma membranes. The activation of one enzyme is regulated by the other. An increase in the cyclic AMP level before receptor bridging suppressed phospholipid methylation. On the other hand, inhibition of phospholipid methylation may affect the initial rise in cyclic AMP. Our experiments also indicated that bridging the receptor activates a membrane-associated proteolytic enzyme. Inasmuch as the inhibition of the enzyme activation results in the suppression of both phospholipid methylation and initial rise in cyclic AMP induced by receptor bridging, the proteolytic enzyme may be involved in the activation of methyltransferases and adenylate cyclase.     

Activation, desensitization, and recycling of frog erythrocyte beta-adrenergic receptors. Differential perturbation by in situ trypsinization

We have utilized limited in situ trypsinization of the adenylate cyclase-coupled beta-adrenergic receptor of frog erythrocytes to probe the processes of receptor activation, desensitization, and recycling. Treatment of intact erythrocytes with trypsin (1 mg/ml) for 1 h at 20 degrees C converts all the receptor peptides (identified by photoaffinity labeling with p-azido-125I-benzylcarazolol) from a Mr approximately 58,000 to a Mr approximately 40,000 species. Nonetheless, the trypsinized beta-adrenergic receptors bind agonists and antagonists with unaltered affinity and with no change in the number of binding sites. Moreover, the ability of the proteolyzed receptors to interact with the nucleotide regulatory protein to form a high affinity guanine nucleotide-sensitive state and to activate adenylate cyclase were also unaltered. However, upon exposure of intact cells to the agonist isoproterenol, trypsinized beta-adrenergic receptors were more rapidly and more completely cleared from the plasma membranes ("down-regulated") than untrypsinized receptors. Whereas down-regulated receptors from nontrypsinized cells appear to recycle to the cell surface after removal of the agonist, internalized trypsinized beta-adrenergic receptors do not recycle to the plasma membrane and appear to be degraded within the cell. Moreover, when internalized receptors, recovered in a light vesicle fraction, were fused with a heterologous adenylate cyclase system, untreated but not trypsinized receptors reconstituted catecholamine stimulation of the enzyme. These data suggest that the beta-adrenergic receptor contains a trypsin-sensitive site which is exposed on the outer surface of the plasma membrane. Proteolysis at this site releases a fragment which though not critically involved in either ligand binding or "effector coupling" might be important for anchoring the receptors in the plasma membrane. These data also suggest that in situ proteolysis of the receptors might serve as a physiological trigger for their internalization and degradation.     

Translocation of phospholipid/Ca2+-dependent protein kinase in B-lymphocytes activated by phorbol ester or cross-linking of membrane immunoglobulin.

Treatment of hepatocytes with islet activating protein (pertussis toxin) from Bordetella pertussis blocked the ability of insulin to inhibit adenylate cyclase activity both in broken plasma membranes and in intact hepatocytes. Such treatment of intact hepatocytes with pertussis toxin did not prevent insulin from activating the peripheral plasma membrane cyclic AMP phosphodiesterase although it did inhibit the ability of insulin to activate the 'dense-vesicle' cyclic AMP phosphodiesterase. The ability of glucagon pretreatment of hepatocytes to block insulin's activation of the plasma membrane cyclic AMP phosphodiesterase was abolished in pertussis toxin-treated hepatocytes. It is suggested that the ability of insulin to manipulate cyclic AMP concentrations by inhibiting adenylate cyclase and activating the plasma membrane and 'dense-vesicle' cyclic AMP phosphodiesterases involves interactions with the guanine nucleotide regulatory protein system occurring in liver plasma membranes.     

Effects of a membrane-bound trypsin-like proteinase and seminal proteinase inhibitors on the bicarbonate-sensitive adenylate cyclase in porcine sperm plasma membranes

Plasma membranes were purified from flagella of porcine cauda epididymal sperm and proteolytic regulation of bicarbonate-sensitive adenylate cyclase was studied. It was found that the epididymal sperm plasma membrane contained a trypsin-like proteinase which inactivated adenylate cyclase. Bicarbonate activates adenylate cyclase as reported previously, but, at the same time, the anions enhance the inactivation of the enzyme by the membrane-bound trypsin-like proteinase. This phenomenon is not due to the direct activation of the proteinase, but closely related to the activation of adenylate cyclase by bicarbonate. It was also found that seminal proteinase inhibitors blocked the inactivation of adenylate cyclase and maintained the bicarbonate activation of the enzyme at high level. Actually, bicarbonate keeps adenylate cyclase fully active in ejaculated sperm, because membrane-bound proteinase is completely inhibited by the seminal proteinase inhibitors. These results suggest that the interactions between membrane-bound proteinase and seminal proteinase inhibitor are involved in the regulation of the bicarbonate-sensitive adenylate cyclase system.     

Interaction of cysteine proteases with calciotropic hormone receptors

The effect of two cysteine proteases: papain and a cathepsin L-like enzyme purified from the oesophagus of Nephrops norvegicus (NCP) was studied on the specific binding of calcitonin (CT) and calcitonin gene related peptide (CGRP) to rat kidney and liver membranes, respectively. In addition, the response of adenylyl cyclase to increasing concentrations of these two enzymes was investigated. Each protease inhibited the initial CGRP and CT binding to rat liver and kidney membranes, respectively, in a manner not significantly different from that obtained in the presence of the unlabeled standard. The adenylyl cyclase activity in rat liver membranes was increased by the addition of each enzyme. The response was higher with papain that induced a fivefold increase of enzyme activity at a 4-microg/ml enzyme concentration. In rat kidney membranes, the magnitude of the response was identical with both enzymes. In contrast with NCP, papain induced a biphasic response. Leupeptin and E(64), two specific inhibitors of cysteine proteases, reversed the observed effects. Trypsin induced an inhibition of the liver membrane adenylyl cyclase activity and an activation in rat kidney membranes at low protease concentration. Thus, cysteine proteases are able to act, in vitro, at the receptor level in target organs specific for calciotropic hormones.