guanosine-triphosphate and 4-hydroxymercuribenzoate

In previous work (McKee EE, Bentley AT, Smith RM Jr, and Ciaccio CE, Biochem Biophys Res Commun 257: 466-472, 1999), the transport of guanine nucleotides into the matrix of intact isolated heart mitochondria was demonstrated. In this study, the time course and mechanisms of guanine nucleotide transport are characterized. Two distinct mechanisms of transport were found to be capable of moving guanine nucleotides across the inner membrane. The first carrier was saturable, displayed temperature dependence, preferred GDP to GTP, and did not transport GMP or IMP. When incubated in the absence of exogenous ATP, this carrier had a V(max) of 946 +/- 53 pmol. mg(-1). min(-1) with a K(m) of 2.9 +/- 0.3 mM for GDP. However, transport of GTP and GDP on this carrier was completely inhibited by physiological concentrations of ATP, suggesting that this carrier was not involved with guanine nucleotide transport in vivo. Because transport on this carrier was also inhibited by atractyloside, this carrier was consistent with the well-characterized ATP/ADP translocase. The second mechanism of guanine nucleotide uptake was insensitive to atractyloside, displayed temperature dependence, and was capable of transporting GMP, GDP, and GTP at approximately equal rates but did not transport IMP, guanine, or guanosine. GTP transport via this mechanism was slow, with a V(max) of 48.7 +/- 1.4 pmol. mg(-1). min(-1) and a K(m) = 4.4 +/- 0.4 mM. However, because the requirement for guanine nucleotide transport is low in nondividing tissues such as the heart, this transport process is nevertheless sufficient to account for the matrix uptake of guanine nucleotides and may represent the physiological mechanism of transport.

Topics: Adenosine Triphosphate; Animals; Atractyloside; Biological Transport; Dose-Response Relationship, Drug; Energy Metabolism; Enzyme Inhibitors; Ethylmaleimide; Guanine Nucleotides; Guanosine Diphosphate; Guanosine Monophosphate; Guanosine Triphosphate; Hydroxymercuribenzoates; Kinetics; Mitochondria; Myocardium; Protease Inhibitors; Rats; Rats, Sprague-Dawley; Tritium

NADP-dependent glutamate dehydrogenase from Dictyostelium discoideum was purified 9300 fold with a yield of 4.6%. The enzyme is a hexamer of apparent molecular weight 294 kDa on Sephacryl S400 and a subunit molecular weight of 52 kDa as determined by SDS gel electrophoresis. The apparent Kms for alpha-ketoglutarate, NADPH and NH4+ are 1.2 mM, 9.7 microM and 2.2 mM respectively, and the purified enzyme has a broad pH optimum with a peak at pH 7.75. GTP has a slight stimulatory effect (22% at 83 microM) as does ADP (11% at 1 mM), and AMP is slightly inhibitory (9% at 1 mM) whereas adenosine, ATP and cAMP have little or no effect. Neither the Zn2+ chelating compound 1,10-phenanthroline nor EDTA have any effect on the enzyme while p-hydroxymercuribenzoic acid inhibits enzyme activity (50% at 80 microM) yet N-ethylmaleimide does not. In addition, the NADP-GDH activity varies little during the various stages of morphogenesis.

Topics: Adenosine Diphosphate; Adenosine Monophosphate; Animals; Cyclic AMP; Dictyostelium; Ethylmaleimide; Glutamate Dehydrogenase; Glutamate Dehydrogenase (NADP+); Guanosine Triphosphate; Hydrogen-Ion Concentration; Hydroxymercuribenzoates; Molecular Weight; Morphogenesis

Guanine nucleotides have been reported to stimulate reticular Ca2+ release. By using the structure-linked latency of microsomal mannose-6-phosphate phosphatase as an index of microsomal permeability [Arion, Ballas, Lange & Wallin (1976) J. Biol. Chem. 251, 4901-4907], the effects of GTP on Ca2+ release and membrane permeability were compared in liver microsomes. In a stripped rough-microsome preparation, GTP caused a dose-dependent increase in mannose 6-phosphate permeability. Half-maximal and maximal effects were observed at 3 microM- and 10 microM-GTP respectively. The time course of the change in membrane permeability coincided with the time course of GTP-dependent Ca2+ release. This increase in microsomal permeability displayed positive to-operativity with respect to GTP (Hill coefficient = 1.8). By analogy to the GTP-dependent Ca2+ release process, guanosine 5'-[gamma-thio]triphosphate and guanosine 5'-[beta gamma-imido]-triphosphate inhibited the ability of GTP to alter microsomal permeability, but were without effect when added alone. In the presence of 50 microM-GTP, complete inhibition of the GTP-dependent increase in microsomal permeability was achieved with 10 microM-guanosine 5'-[gamma-thio]triphosphate, whereas a 25% inhibition was observed with 10 microM-guanosine 5'-[beta gamma-imido]triphosphate. In contrast with previous observations in crude microsomal preparations, GTP-dependent Ca2+ release in the stripped rough-microsome preparation did not require the addition of poly(ethylene glycol), although the latter did stimulate the rate of Ca2+ release. The ability of GTP to alter microsomal permeability was blocked by prior treatment with the thiol reagent p-hydroxymercuribenzoate; complete inhibition was observed after a 10 min exposure to 50 microM. Inhibition was reversed by subsequent treatment with dithiothreitol. The marked similarities between the two GTP-sensitive processes indicate that they may function via the same mechanism.

Topics: Animals; Biological Transport; Calcium; Cell Membrane Permeability; Dose-Response Relationship, Drug; Endoplasmic Reticulum; Guanosine Triphosphate; Hydroxymercuribenzoates; Male; Microsomes, Liver; Nucleotides; Phosphoric Monoester Hydrolases; Polyethylene Glycols; Rats; Rats, Inbred Strains; Structure-Activity Relationship