Intracellular metabolism of 2',3'-dideoxynucleosides in duck hepatocyte primary cultures.

The intracellular fate of the potent duck hepatitis B virus (DHBV) inhibitor 2,6-diaminopurine 2',3'-dideoxyriboside (ddDAPR), its deamination product 2',3'-dideoxyguanosine (ddG), and the less effective DHBV-inhibitor 2',3'-dideoxycytidine (ddC) was investigated in duck hepatocyte primary cultures. After a 1-min exposure of [3H]ddDAPR to duck blood, 95% of the compound was converted to ddG. Similarly, [3H]ddDAPR was converted rapidly to ddG in duck hepatocyte primary cultures, with ddG exhibiting resistance to further catabolism. The major pathway of ddG utilization in these cells was phosphorylation, yielding a concentration of 2.1 and 1.9 microM total ddG nucleotides after 5 and 26 hr, respectively, of exposure to 4 microM ddG. Removal of exogenous ddG led to a rapid (T1/2 = 1.6 hr) decrease in the total intracellular ddG nucleotide pools. Duck hepatocytes treated with 4 microM ddC exhibited a time-dependent accumulation of ddC nucleotides, culminating in a maximum intracellular total ddC nucleotide concentration of 1.4 microM after 24-26 hr. The intracellular total ddC nucleotide level decreased with a T1/2 of 4.4 hr following the removal of exogenous ddC. The formation of ddC nucleotides was reduced in the presence of excess 2'-dideoxycytidine implicating deoxycytidine kinase in the initial step of ddC phosphorylation. A 25-fold excess of 2'-deoxycytidine had no effect on ddG phosphorylation in duck hepatocytes. However, a 92% inhibition of ddG nucleotide formation occurred in duck hepatocytes treated for 5 hr with 4 microM [3H]dG + 100 microM adenosine in the presence of the adenosine deaminase inhibitor 2'-deoxycoformycin, suggesting that, in these cells, adenosine kinase is involved in the ddG phosphorylation process.

Characteristics of Mg2+-dependent, ATP-activated Ca2+ transport in synaptic and microsomal membranes and in permeabilized synaptosomes.

Synaptic plasma membranes isolated from rat brain exhibited a Ca2+ transport process that was strictly dependent on the presence of Mg2+ and activated by ATP hydrolysis. The characteristics of this ATP-activated transport process included a high affinity for Ca2+ and ATP with the Kact for these two substrates being 0.7 and 5 microM, respectively, and a lower affinity for Mg2+, Kact = 54 microM. The estimated constants for ATP-activated Ca2+ transport into synaptic membrane vesicles and the dependence of such transport on Mg2+ were indicative that such transport was related to the previously described high affinity (Ca2+ + Mg2+)-ATPase in synaptic membranes. An ATP- and Mg2+-dependent Ca2+ transport process with very similar kinetic characteristics was present also in a general microsomal membrane fraction obtained from brain tissue. The synaptic and microsomal membrane ATP-activated transport processes exhibited differences in their sensitivity to vanadate inhibition. Interaction with vanadate was fairly complex and best analyzed by a two-component model. Thus, the estimated Ki values for vanadate were 0.2 and 6.6 microM for the synaptic membranes and 0.7 and 13.8 microM for the microsomes. Since the microsomal membranes contain a substantial population of intraneuronal endoplasmic reticulum vesicles, the effects of vanadate on Ca2+ transport into intraneuronal membrane organelles, other than mitochondria, was determined in saponin-permeabilized synaptosomes. The estimated Ki values for vanadate inhibition of Ca2+ transport activity were 0.7 and 13 microM. The accumulation of Ca2+ into synaptic plasma membrane vesicles was readily reversed by activation of the Na+-Ca2+ exchange carrier, whereas the Ca2+ associated with intrasynaptosomal organelles was not affected by changes in [Na+]. Thus, there are at least two ATP-dependent Ca2+ transporting processes localized on two distinct neuronal membranes, one on the plasma membrane and the second on intraneuronal membranes.

Characteristics of adenosine binding sites in atrial sarcolemmal membranes.

The studies reported here involve an exploration of the sites on atrial myocyte membranes with which adenosine interacts to produce its potent physiological effects in atrial muscle. Specific, high affinity binding of the stable adenosine analogs 2-chloro[3H]adenosine (2-ClAdo) and [3H]adenosine 5'-N-ethylcarboxamide (NECA) to atrial sarcolemmal membranes was measured in kinetic and equilibrium studies at 4 degrees C and 35 degrees C. Analysis of the [3H]2-ClAdo binding isotherm indicated the presence of two classes of binding site with equilibrium Kassoc values estimated to be 5.7 X 10(7) M-1 and 2.7 X 10(6) M-1. Displacement of bound [3H]2-ClAdo by adenosine 5'-N-cyclopropylcarboxamide (NCPCA) and by several N6-substituted adenosine analogs confirmed the presence of two classes of binding site. Analysis of the [3H]NECA binding also revealed the presence of two types of binding site for this ligand. The methylxanthines isobutylmethylxanthine and theophylline displaced bound [3H]2-ClAdo whereas adenosine uptake inhibitors and several other purines showed little activity. These atrial membrane binding sites exhibit many of the characteristics of the physiological adenosine receptors studied in intact atria. Furthermore, the [3H]2-ClAdo binding sites were sensitive to treatment with proteolytic enzymes, suggesting that these sites exist on sarcolemmal membrane proteins.

Differential effects of ethanol on two synaptic membrane Ca2+ transport systems.

The Na+-Ca2+ exchange activity in synaptic plasma membranes is inhibited by very low concentrations of ethanol (less than 25 mM). The high affinity Mg2+- and ATP-dependent Ca2+ transport in highly purified synaptic membranes is much less sensitive to inhibition by ethanol, with no statistically significant inhibition observed until an ethanol concentration of nearly 800 mM was used. Manipulations of the lipid environment designed to increase membrane fluidity enhanced the activity of the Na+-Ca2+ exchange system but inhibited the ATP-dependent Ca2+ pump. The differential responses of the two synaptic plasma membrane Ca2+ transporting systems to such modifications of membrane structure suggest that these two ion transport processes differ in the extent to which their activity is dependent on the lipid microenvironment in which they reside. Thus, the effects of ethanol on the Na+-Ca2+ antiporter may represent a fairly selective inhibitory process.

Age-dependent alterations in synaptic membrane systems for Ca2+ regulation.

The effects of aging on two neuronal plasma membrane Ca2+ regulating systems have been examined using synaptic membranes isolated from the brains of adult (5-7-month-old) and aged (23-25-month-old) Fisher 344 rats. The kinetic characteristics of the Na+-dependent Ca2+ transport system were found to be altered in the aged animals. The affinity of the transport carrier for Ca2+ was decreased in membranes from aged animals, with very little change in the maximal transport capacity of the system. The activity of the synaptic membrane Ca2+-activated, Mg2+-dependent ATPase was also altered in membranes from aged animals. In this system, however, the Vmax for Ca2+ activation of the enzymatic activity was lower in the aged animals, while there was no change in the K0.5 for Ca2+ activation. The magnitude of the alterations was small, but the differences were consistent. Even small changes in the effectiveness of the synaptic plasma membrane systems which participate in the maintenance of low intraterminal Ca2+ could progressively affect the integrity of synaptic transmission and lead eventually to neuronal cell death.

High affinity Ca2+-stimulated Mg2+-dependent ATPase in rat brain synaptosomes, synaptic membranes, and microsomes.

High affinity Ca2+-stimulated Mg2+-dependent ATPase activity of nerve ending particles (synaptosomes) from rat brain tissue appears to be associated primarily with isolated synaptic plasma membranes. The synaptic membrane (Ca2+ + Mg2+)-ATPase activity was found to exhibit strict dependence on Mg2+ for the presence of the activity, a high affinity for Ca2+ (K0.5 = 0.23 microM), and relatively high affinities for both Mg2+ and ATP (K0.5 = 6.0 microM for Mg2+ and KM = 18.9 microM for ATP). These kinetic constants were determined in incubation media that were buffered with the divalent cation chelator trans-cyclohexane-1,2-diamine-N,N,N',N'-tetraacetic acid. The enzyme activity was not inhibited by ouabain or oligomycin but was sensitive to low concentrations of vanadate. The microsomal membrane subfraction was the other brain subcellular fraction with a high affinity (Ca2+ + Mg2+)-ATPase activity which approximated that of the synaptic plasma membranes. The two membrane-related high affinity (Ca2+ + Mg2+)-ATPase activities could be distinguished on the basis of their differential sensitivity to vanadate at concentrations below 10 microM. Only the synaptic plasma membrane (Ca2+ + Mg2+)-ATPase was inhibited by 0.25-10 microM vanadate. The studies described here indicate the possible involvement of both the microsomal and the neuronal plasma membrane (Ca2+ + Mg2+)-ATPase in high affinity Ca2+ transport across membranes of brain neurons. In addition, they suggest a means by which the relative contributions of each transport system might be evaluated based on their differential sensitivity to inhibition by vanadate.