Influence of the carboxyl terminus of luteinizing hormone-releasing hormone and bradykinin on hydrolysis by brain endo-oligopeptidases

A homogeneous preparation of endo-oligopeptidase A from rabbit brain cleaves luteinizing hormone-releasing hormone (less than Glu-His-Trp-Ser-Tyr-Gly-Leu-Arg-Pro-Gly-NH2) at the Tyr-Gly bond only after the removal of Gly-NH2 from the COOH-terminal position of the molecule. The influence of the carboxyl terminus on hydrolysis by brain endo-oligopeptidases was studied using bradykinin as a model substrate. The substitution of the carboxyl group of bradykinin by the amide reduces by 2.5-fold the rate of Phe-Ser bond hydrolysis by endo-oligopeptidase A but has no effect on the rate of hydrolysis of the Pro-Phe bond by endo-oligopeptidase B. On the other hand, the deletion of Phe-Arg from the COOH-terminal portion of bradykinin makes the peptide resistant to hydrolysis by endo-oligopeptidase A whereas it increases by 5-fold the rate of hydrolysis of the Pro-Gly bond by endo-oligopeptidase B.     

Thyroid membrane ADP ribosyltransferase activity. Stimulation by thyrotropin and activity in functioning and nonfunctioning rat thyroid cells in culture

Bovine thyroid membranes possess both ADP ribosyltransferase and NAD glycohydrolase activities with the same Km values for NAD and the same pH optima. In intact membranes, the ADP ribosyltransferase is limited in its extent by the amount of available membrane acceptor which can be ADP-ribosylated; in membranes solubilized with lithium diiodosalicylate, an artificial acceptor, L-arginine methyl ester, can be substituted to eliminate this limitation. The product of the ADP ribosyltransferase is a mono-ADP-ribosylated acceptor whether the intact or solubilized membrane provides the enzyme activity and whether membrane or exogenous acceptor, L-arginine methyl ester, is utilized. The intact membranes and the solubilized preparation also have an enzyme activity which can release AMP from the mono-ADP-ribosylated acceptor whether formed by the action of the membrane ADP ribosyltransferase or the A promoter of cholera toxin. The NAD glycohydrolase activity appears to represent the half-reaction of the ADP ribosyltransferase, i.e. an activity measurable substituting water for a membrane acceptor or L-arginine methyl ester. Membranes from functional rat thyroid cells in culture, i.e. cells chronically stimulated by thyrotropin and unresponsive to further additions of thyrotropin, have low ADP-ribosylation but high NAD glycohydrolase activities. In contrast, membranes from nonfunctional rat thyroid cells, i.e. cells unresponsive to thyrotropin, have high ADP-ribosylation and low NAD glycohydrolase activities. NAD hydrolysis by the NAD glycohydrolase activity cannot account for the low ADP-ribosylation activity in membranes from the functioning cells, and its low level of ADP-ribosylation can be eliminated by solubilizing the membranes and substituting an artificial acceptor, L-arginine methyl ester. The ADP ribosyltransferase activity of rat thyroid cell membrane preparations can be enhanced by thyrotropin in a dose-dependent manner but not by insulin, glucagon, hydrocortisone, adrenocorticotropin, or its glycoprotein hormone analog, human chorionic gonadotropin. It is thus suggested (i) that, in analogy to cholera toxin, thyrotropin-stimulated ADP-ribosylation may be important in the regulation of the adenylate cyclase response and (ii) that the level of membrane acceptor available for ADP-ribosylation may relate both to a stable "'activated" state of the adenylate cyclase system in cells chronically stimulated with thyrotropin and/or to a desensitized state with regard to a failure of more thyrotropin to elicit additional functional responses.     

The value of electrocardiographic R-wave changes in exercise testing: Preexercise versus postexercise measurements

To determine the usefulness of R-wave amplitude changes during exercise testing for the diagnosis of coronary artery disease (CAD) and to understand the discrepancies that have been described in the literature regarding their value, we studied two groups of patients by means of electrocardiographic (EKG) treadmill testing and coronary arteriography. Group I was composed of 149 patients who were studied prospectively. The specificity of R-wave changes measured from preexercise to immediately postexercise (SRV(5)) was 81%, but that of R-wave changes measured from preexercise to peak exercise (URV(5)) was 46%. A group of 156 patients (Group II) evaluated retrospectively showed a high specificity for the SRV(5) (84%) and poor specificity for the URV(5) (39%). The sensitivity of the SRV(5) was 38% in Group I and 42% in Group II. Therefore, if measured during the immediate postexercise period and not at peak exercise, changes in R-wave amplitude may be of value in the diagnosis of coronary artery disease by electrocardiographic exercise testing.     

Synaptosomal phospholipid pool in rabbit brain and its effect on GABA uptake

Rabbit synaptosomes have been used to study the effect of the base-exchange reaction in membrane phospholipids on -aminobutyric acid (GABA) transport in vitro. The uptake of GABA was measured after a base-exchange reaction with ethanolamine, choline, orl-serine and after subsequent displacement of these exchanged moieties from lipid by bases of similar or different structures which were added to the synaptosomal medium. Serine incorporation stimulated GABA transport, but its displacement from membrane lipid by choline or ethanolamine induced an inhibition of GABA transport. Ethanolamine incorporation inhibited GABA transport, but its displacement by serine or choline resulted in stimulation of GABA uptake. Choline incorporation also inhibited GABA transport, although less than ethanolamine. The pool size of synaptosomal phospholipids, presumably involved in GABA uptake, accounted for 0.2 to 10% of the total content of membrane phospholipid. Thus, alteration of phospholipid compositior by exchange of the lipid hydrophilic head-groups influences the extent GABA uptake into rabbit synaptosomes.     

Role in hemolysis of the interaction of tellurium compounds with glutathione

We have shown that tellurite and tellurate require the interaction with reduced glutathione (GSH) to hemolyze human erythrocytes. The study of the nature of this interaction is the main object of this paper. The degree of hemolysis was determined by the method of Angelone. The addition of extracellular 1 mM GSH or cysteine increased the rate of hemolysis. Concanavalin A (0.3 mg/mL) and/or 4 mg/mL adenosine did not affect the hemolysis by 0.1 mM tellurite. One tenth to 1 mM 4-acetamido-4′-isothiocyanostilbene-2,2′-disulfonate (SITS) inhibited this hemolysis by 60–100%. Millimolar GSH released this inhibition. Incubation of 0.1 mM tellurite with 1 mM GSH for 90 min at 37°C, produced a hemolytic agent when prepared and tested under nitrogen, but one that was not active when prepared in air. The hemolysis byp-hydroxymercuribenzoate orp-hydroxymercuriphenylsulfonate did not involve GSH. Scanning electron micrographs showed a sphero-echinocyte transformation, in the pre-hemolytic stage, with all the agents tested. The rate of penetration of tellurite plays a role in determining the rate of hemolysis, as shown by the effect of SITS. The release by GSH of the inhibition by SITS poses questions concerning the site of action and cell membrane penetration of the hemolytic agent. Telluride or some intermediate in the interaction of GSH with tellurite is the actual hemolytic agent.     

Non-polyadenylated 22 s ribonucleoprotein particle is insensitive to translational inhibitor RNA of cryptobiotic gastrulae of Artemia salina.

A free cytoplasmic 22 S ribonucleoprotein particle exhibiting a major template activity in rabbit reticulocyte system has been identified in the cryptobiotic gastrulae of Artemia salina. This particle contains non-polyadenylated 9 S messenger RNA which codes primarily for a non-histone basic protein with an apparent molecular weight of 26 000 daltons. We have previously demonstrated the presence of a translational inhibitor RNA which is apparently responsible for transforming polyadenylated messenger (Slegers et al., FEBS Letters 80, 390-394, 1977). This inhibitor RNA was found to be completely ineffective on the template activity of non-polyadenylated 22 S messenger ribonucleoprotein, confirming the specificity of this regulatory RNA for polyadenylate sequences.