Nucleotide exchange between cytosolic ATP and F-actin-bound ADP may be a major energy-utilizing process in unstimulated platelets.

About 40% of the cytosolic ADP of human platelets is tightly bound to protein and the complex is precipitated from the cells by 43% ethanol. We show here that this ADP is bound to F-actin by three criteria (a) copurification with F-actin, (b) specific extraction with water and (c) by specific interaction with DNase I. Platelets contain 0.3 mumol/10(11) cells of this F-actin--ADP complex compared to the total actin content of 0.8 mumol/10(11) cells, which is consistent with the view that actin is maintained in different pools (F-actin--ADP, profilactin, G-actin). In intact platelets the F-actin-bound ADP turns over rapidly and we have determined a turnover rate at 37 degrees C of 0.1 +/- 0.025 s-1 by using a double-labelling procedure. This rapid turnover indicates that F-actin in intact platelets is in a very dynamic state, which may be necessary for rapid responses to stimuli. If it is assumed that the source of the ADP bound to F-actin is cytosolic ATP, the turnover of F-actin ADP measured represents an ATP-consuming process that would account for up to 50% of total ATP consumption in resting platelets.

Effects of antimycin A and 2-deoxyglucose on secretion in human platelets. Differential inhibition of the secretion of acid hydrolases and adenine nucleotides.

1. Shape change, aggregation and secretion of dense-granule constituents in platelets differ in their dependence on cellular energy metabolism. The possibility that such a difference also exists between secretion of dense-granule constituents and acid hydrolases was investigated. 2. Human platelets were incubated with [(14)C]adenine in plasma, and then washed and resuspended in salt solutions. The effects of incubating the cells with antimycin A and 2-deoxyglucose on the concentrations of [(14)C]ATP, ADP, AMP, IMP and inosine plus hypoxanthine and on thrombin-induced secretion of ATP plus ADP and acid hydrolases were studied. The metabolic inhibitors only affected (14)C-labelled nucleotides, whereas thrombin only liberated unlabelled ATP and ADP. 3. The extent of secretion decreased progressively with time during incubation with the metabolic inhibitors. At any time the secretion of acid hydrolases, beta-N-acetylglucosaminidase, beta-glucuronidase and beta-galactosidase was inhibited to a greater extent than secretion of ATP plus ADP (dense-granule secretion). 4. Incubation with the metabolic inhibitors shifted the log (dose)-response relationship to higher thrombin concentrations, and with a greater shift for acid hydrolase secretion than for dense-granule secretion. 5. Antimycin, when present alone, caused a marked decrease in the rate of acid hydrolase secretion, but had no effect on dense-granule secretion. 6. These results further support the view that acid hydrolase secretion and dense-granule secretion are separate processes with different requirements for ATP energy. Acid hydrolase secretion, but not dense-granule secretion, appears to depend on a simultaneous rapid generation of ATP, which can be accomplished by oxidative, but not by glycolytic, ATP production.

Determination of the ADP concentration available to participate in energy metabolism in an actin-rich cell, the platelet.

Almost all cells contain actin, which in its polymerized form, F-actin, binds 1 molecule of ADP/monomer. Little is known about the availability to metabolism of this bound ADP. A comparison was therefore made between perchloric acid and EDTA/ethanol extracts of human blood platelets. When the cells were extracted under conditions where the ATPase activity was negligible, the ethanol extracts had a 75% higher ATP/ADP ratio and a higher adenylate energy charge than perchloric acid extracts. The methods differed in that a considerable portion of protein-bound ADP was not extracted by ethanol. This bound ADP behaved as though it were unavailable to energy metabolism and should thus be considered as a compartment separate from the bulk metabolic pool of extragranular platelet adenine nucleotides. These results suggest that the level of ADP obtained with the common acid extraction overestimates the level available to participation in metabolism.

Abnormal platelet function in Chediak-Higashi syndrome.

Platelets in an infant with Chediak-Higashi (C-H) syndrome without bleeding manifestations and not in the accelerated phase showed abnormal function consistent with storage pool disorder as shown by abnormal aggregation, decreased storage capacity and release of [14C]5-HT, low endogenous 5-HT, reduced ATP and ADP with an increased ATP/ADP ratio, increased specific radioactivity of ADP after [14C]adenine labelling, decreased release of adenine nucleotides after stimulation, impaired secretion of acid hydrolases despite normal stores, and decreased calcium content. Incorporation of [14C]adenine into metabolic pool adenine nucleotides was normal. Nucleotide conversion to hypoxanthine in stimulated platelets was mildly impaired. Platelet cyclic-AMP (c-AMP) was initially elevated, but even when c-AMP returned to normal levels after ascorbate treatment, platelet function was not improved. Elevated intracellular c-AMP was not solely responsible for the abnormal platelet function.

Hydrogen peroxide lowers ATP levels in platelets without altering adenyalte energy charge and platelet function.

H2O2 irreversibly reduced metabolic platelet ATP levels with a corresponding accumulation of hypoxanthine. This process was enhanced by sodium azide or potassium cyanide and by increasing H2O2 concentrations. The adenylate energy charge was unaltered when less than two thirds of the metabolic ATP had disappeared but decreased markedly when more ATP disappeared. Platelet shape change, primary aggregation, dense granule and alpha-granule secretion were unaffected by H2O2-induced lowering of ATP provided that the adenylate energy charge did not fall by more than 5%; at greater adenylate energy charge reduction, platelet functions were inhibited. These results indicate that cell functions depend more on adenyalte energy charge than on the ATP level and expands the applicability of this view from bacterial systems to a mammalian cell, the human platelet.