Dual mechanisms involved in development of diverse biological activities of islet-activating protein,pertussis toxin,as revealed by chemical modification of lysine residues in the toxin molecule

Islet-activating protein (IAP), pertussis toxin, is an oligomeric protein composed of an A-protomer and a B-oligomer. There seem to be at least two molecular mechanisms by which IAP exerts its various effects in vivo and in vitro. On the one hand, some of the effects were not significantly affected by acetamidination of the ε-amino groups of the lysine residues in the molecule. These include the activities in vitro (1) catalyzing ADP-ribosylation of one of the membrane proteins directly, (2) enhancing membrane adenylate cyclase activity in C6 cells, (3) reversing receptor-mediated inhibition of insulin or glycerol release from pancreatic islets of adipocytes, respectively, and the activities in vivo (4) inhibiting epinephrine-induced hyperglycemia, (5) potentiating glucose-induced hyperinsulinemia, (6) reducing hypertension and increasing the heart rate in genetically hypertensive rats. These activities are concluded to develop as a result of ADP-ribosylation catalyzed by the A-protomer which is rendered accessible to its intramembrane substrate thanks to the associated B-oligomer moiety. Thus, neither the enzymic activity of the A-protomer nor the transporting activity of the B-oligomer needs free amino groups of the lysine residues in the IAP molecule. On the other hand, additional effects of IAP, such as (1) mitogenic, (2) lymphocytosis-promoting, (3) histamine-sensitizing, (4) adjuvant and (5) vascular permeability increasing, were markedly suppressed by acetamidination of the intrapeptide lysine residues. The free ε-amino group of lysine would play an indispensable role in the firm (or divalent) attachment of the B-oligomer of IAP to the cell surface that is responsible for development of these activities.     

Structural relationship between the S1 and S4 subunits of pertussis toxin

Abstract Pertussis toxin, the most important protective antigen of Bordetella pertussis , is a 106-kDa hexameric protein composed of an A-promoter (subunit S1) and a pentameric B-oligomer (S2 + S3 + 2S4 + S5). The most potent mouse-protective monoclonal antibodies against both respiratory and intracerebral infections were specified for either S1 or S4 and competed with each other in binding to epitopes of native pertussis toxin captuted by haptoglobin or in solution, although they did not compete on unfolded pertussin toxin. These data suggest that the protective epitope(s) of S1 and S4 are very closely correlated; they are probably close] together sterically. Non-protective anti-S1 and anti-S4 monoclonal antibodies recognized inner antigenic determinants which are not exposed on the surface o native pertussis toxin and interfered with association of the A-protomer and the B-oligomer. These data suggest that the A-protomer and the S4 subunit of the B-oligomer may be closely associated in the native hexameric pertussis toxin molecule.     

Coupling of the guanine nucleotide regulatory protein to chemotactic peptide receptors in neutrophil membranes and its uncoupling by islet-activating protein, pertussis toxin. A possible role of the toxin substrate in Ca2+-mobilizing receptor-mediated signal transduction

A chemotactic peptide stimulated the high-affinity GTPase activity in membrane preparations from guinea pig neutrophils. The enzyme stimulation was inhibited by prior exposure of the membrane-donor cells to islet-activating protein (IAP), pertussis toxin, or by direct incubation of the membrane preparations with its A-protomer (the active peptide) in the presence of NAD. The affinity for the chemotactic peptide binding to its receptors was lowered by guanyl-5'-yl beta, gamma-imidodiphosphate (Gpp(NH)p) reflecting its coupling to the guanine nucleotide regulatory protein in neutrophils. The affinity in the absence of Gpp(NH)p was lower, but the affinity in its presence was not, in the A-protomer-treated membranes than in nontreated membranes. The inhibitory guanine nucleotide regulatory protein of adenylate cyclase (Ni) was purified from rat brain, and reconstituted into the membranes from IAP-treated cells. The reconstitution was very effective in increasing formyl-Met-Leu-Phe-dependent GTPase activity and increasing the chemotactic peptide binding to membranes due to affinity increase. The half-maximal concentration of IAP to inhibit GTPase activity was comparable to that of the toxin to inhibit the cellular arachidonate-releasing response which was well correlated with ADP-ribosylation of a membrane Mr = 41,000 protein (Okajima, F., and Ui, M. (1984) J. Biol. Chem. 259, 13863-13871). It is proposed that the IAP substrate, Ni, couples to the chemotactic peptide receptor and mediates arachidonate-releasing responses in neutrophils, as it mediates adenylate cyclase inhibition in many other cell types.     

Chemical modification of islet-activating protein,pertussis toxin: Essential role of free amino groups in its lymphocytosis-promoting activity

Chemical modification of amino groups in the molecule of islet-activating protein (IAP), pertussis toxin, resulted in differential modification of biological activities of the toxin estimated in vivo with rats. Acetamidination of ε-amino groups of 50% (or more) of lysine residues in the IAP molecule totally abolished the lymphocytosis-promoting activity, but exerted no effects on the epinephrine-hyperglycemia inhibitory activity, of the toxin. Both activities were abolished by acylation of 50% or more of the amino groups probably due to the destruction of the toxin's quarternary structure. In contrast, the subunit assembly of IAP was maintained after exhaustive acetamidination of its lysine residues. The ADP-ribosyltranferase (or NAD-glycohydrolase) activity of the A-protomer (the biggest subunit) of IAP, which is responsible for the principal action of the toxin, enhancing insulin secretory responses and thereby inhibiting epinephrine hyperglycemia, was not affected by acetamidination of lysine residues. Thus, the A-protomer moiety of IAP is not directly involved in, but the amino groups of lysine residues in other subunits are selectively essential for, the development of the toxin-induced lymphocytosis.     

Conversion of adrenergic mechanism from an alpha- to a beta-type during primary culture of rat hepatocytes. Accompanying decreases in the function of the inhibitory guanine nucleotide regulatory component of adenylate cyclase identified as the substrate of islet-activating protein

Adrenergic mechanism for phosphorylase activation was gradually converted from an alpha 1- to a beta 2-type during primary culture of rat hepatocytes. beta 2-Receptor-mediated cAMP generation was also much greater in 8-h cultured cells than in fresh cells. Incubation of hepatocyte membranes with [alpha-32P]NAD and the preactivated A-protomer (an active component) of islet-activating protein (IAP), pertussis toxin, resulted in the ADP-ribosylation of a specific IAP substrate protein (Mr = 41,000). This ADP-ribosylation diminished progressively when the membrane-donor hepatocytes had been cultured. The early diminution was interfered with by the addition of nicotinamide or isonicotinamide, a potent inhibitor of ADP-ribosyltransferase, to the culture medium. The decrease of the IAP substrate was well correlated with the potentiation of beta-adrenergic functions under various conditions of culture. beta-Receptor-mediated activation of GTP-dependent membrane adenylate cyclase was, but glucagon-induced activation was not enhanced by either prior culture of hepatocytes or prior exposure of membranes to the A-protomer of IAP. There was no further enhancement, however, when membranes from cultured cells were exposed to the active toxin. Thus, the IAP-susceptible inhibitory guanine nucleotide-regulatory protein is coupled to beta-adrenergic receptors in such a manner as to reduce the degree of activation of cyclase, and the decrease in this IAP substrate may be responsible, at least partly, for development of beta-receptor functions during culture of hepatocytes. Its possible relation to accompanying inhibition of alpha 1-receptor functions is discussed.     

Loss of the inhibitory function of the guanine nucleotide regulatory component of adenylate cyclase due to its ADP ribosylation by islet-activating protein, pertussis toxin, in adipocyte membranes

Adenylate cyclase of rat adipocyte membranes exhibited dual responses in a strictly GTP-dependent manner; an activation took place in the presence of certain receptor agonists such as isoproterenol or secretin, whereas an inhibitory phase was observed with other agonists such as prostaglandin E1 or purine-modified adenosine as well as with the stimulatory agonists at higher GTP concentrations. Treatment of membrane donor cells with islet-activating protein (IAP), pertussis toxin, abolished the inhibitory phase while preserving the activatory phase. This unique action of IAP was associated with ADP-ribosylation of a membrane Mr = 41,000 protein. In contrast, the inhibitory phase was preserved in membranes from cholera toxin-treated cells. Monophasic and persistent activation of the cyclase was provoked by guanyl-5'-yl beta,gamma-imidodiphosphate. The time lag normally observed for the guanyl-5'-yl beta,gamma-imidodiphosphate activation was decreased by isoproterenol or cholera toxin but was not altered by IAP treatment. Our conclusion is that the sole site of IAP action is the guanine nucleotide regulatory protein (Ni) that is required for transmission of inhibitory signals from receptors to the catalytic unit of adenylate cyclase; the function of Ni is lost upon IAP-catalyzed ADP ribosylation of the Mr = 41,000 protein which appears to be an active subunit of Ni. A possibility is discussed that rather diverse effects of IAP so far reported with various cell types are accounted for in terms of such interference with the function of Ni.     

Simultaneous inhibitions of inositol phospholipid breakdown, arachidonic acid release, and histamine secretion in mast cells by islet-activating protein, pertussis toxin. A possible involvement of the toxin-specific substrate in the Ca2+-mobilizing receptor-mediated biosignaling system

Incubation of rat mast cells with compound 48/80 resulted in transient breakdown of phosphatidylinositol 4,5-bisphosphate, rapid generation of inositol polyphosphates, 45Ca inflow, and the arachidonic acid liberation mainly from phosphatidylcholine, eventually leading to histamine secretion. All of these processes of signaling from Ca-mobilizing receptors to degranulation were markedly inhibited by prior 2-h exposure of cells to islet-activating protein (IAP), pertussis toxin. A23187 caused 45Ca inflow and releases of arachidonic acid and histamine without inducing breakdown of inositol phospholipids. The effects of A23187, in contrast to those of compound 48/80, were not altered by the exposure of cells to IAP. Incubation of the supernatant fraction of mast cell homogenates with the active component of IAP caused the transfer of the ADP-ribosyl moiety of added [alpha-32P]NAD to a protein with Mr = 41,000. The IAP-catalyzed ADP-ribosylation of this protein was prevented by guanosine 5'-(3-O-thio)triphosphate, indicating that this IAP substrate resembles, in character, the alpha-subunit of the guanine nucleotide regulatory protein (Ni) involved in inhibition of adenylate cyclase. The degree of ADP-ribosylation of this IAP substrate was prevented progressively by pre-exposure of the homogenate-donor cells to increasing concentrations of IAP. The half-maximally effective concentrations of the toxin were 0.2 to 0.6 ng/ml for all the IAP-sensitive processes studied. Thus, the ADP-ribosylation of the Mr = 41,000 protein occurring during exposure of cells to IAP appears to be responsible for the inhibition of signaling observed. It is proposed that the alpha-subunit of Ni, or a like protein, mediates signal transduction arising from Ca-mobilizing receptors, probably prior to Ca2+ gating.     

The A protomer of islet-activating protein,pertussis toxin,as an active peptide catalyzing ADP-ribosylation of a membrane protein

Islet-activating protein (IAP), pertussis toxin, is an oligomeric protein composed of an A protomer and a B oligomer. IAP and its A protomer were equipotent, on a molar basis, in enhancing GTP-dependent adenylate cyclase activity and in causing ADP-ribosylation of the 41,000 M_r protein when directly added to the cell-free membrane preparation from rat C6 glioma cells. Similar actions of IAP observed upon its addition to intact C6 cells were not mimicked by its A protomer, indicating that the A protomer had to be associated with the B oligomer to become accessible to its site of action on the inner surface of the membrane of intact cells. The A protomer, but not IAP, exhibited NAD-glycohydrolase activity in the reaction mixture lacking cellular components but containing dithiothreitol. Their actions on membranes were not accelerated by dithiothreitol, but markedly suppressed by oxidized glutathione. Thus, C6 cell membranes may possess certain “processing” enzyme(s) responsible for releasing the A protomer from the IAP molecule and for reductive cleavage of an intrachain disulfide bond in the released protomer, thereby producing an active peptide which functions to cause ADP-ribosylation of one of the subunits of guanine nucleotide regulatory protein in the receptor-adenylate cyclase system.     

Possible involvement of a GTP-binding protein, the substrate of islet-activating protein, in receptor-mediated signaling responsible for cell proliferation

Serum-induced DNA synthesis, as measured by increases in [3H]thymidine incorporation, in Swiss mouse 3T3 fibroblasts was markedly inhibited by exposure of the cells to islet-activating protein (IAP), pertussis toxin. The inhibition was well correlated with the toxin-induced ADP-ribosylation of a membrane GTP-binding protein with Mr = 41,000. The IAP-induced inhibition of cell growth was characterized by the following two features. First, the inhibition was selective to certain growth factors. DNA synthesis in 3T3 cells was supported by a combination of one of the competence factors and a progression factor such as insulin or epidermal growth factor. IAP was inhibitory when thrombin, fibroblast growth factor, prostaglandin F2 alpha, or phosphatidic acid was employed as a competence factor, but was not inhibitory when DNA synthesis was induced by combined addition of cholera toxin or phorbol ester with insulin. Second, IAP-induced inhibition was still observed when the toxin was added to cell culture 1-6 h later than the addition of the IAP-sensitive competence factors, which triggered rapid cellular responses such as adenylate cyclase inhibition, releases of inositol trisphosphate and arachidonic acid, and 45Ca influx within several minutes (Murayama, T., and Ui, M. (1985) J. Biol. Chem. 260, 7226-7233; Murayama, T., and Ui, M. (1987) J. Biol. Chem. 262, 5522-5529). Thus, IAP substrate GTP-binding protein(s) appears to be involved in the duration of rapid signals or the occurrence of new slow signals which are responsible for growth factor-induced cell proliferation. The site of the involvement may be proximal to protein phosphorylation by phorbol ester-activated and cAMP-dependent kinases.     

Inhibitory effects of pertussis toxin on a depolarization-evoked Ca2+ influx in NG108-15 cells

Depolarized stimulation 1.5-fold increased Ca2+ influx which was inhibited by pretreatment with verapamil or LaCl3. Treatment with pertussis toxin, islet-activating protein (IAP), induced a reduction in 50 mM K+-induced Ca2+ influx and stimulated adenylate cyclase (AC) activity in NG108-15 cells. However, addition of dibutyryl cAMP or forskolin treatment elevating cAMP level exerted no effects on a depolarization-induced Ca2+ influx. Dissociated B-oligomer of IAP after treatment with dithiothreitol and ATP increased a depolarization-evoked Ca2+ influx. It is suggested that inhibitory GTP-binding protein (G1) or other IAP substrate proteins could directly be involved in Ca2+ influx via voltage-sensitive Ca2+ channel.