Gray platelet syndrome: alpha-granule deficiency. Its influence on platelet function.

The ultrastructure, cytochemistry, biochemistry, and functions of platelets from two patients with the familial gray platelet syndrome are described. Ultrastructural studies showed a lack of alpha-granules in the megakaryocytes in the vicinity of a marrow myelofibrosis and/or in platelets. A normal number of mitochondria and a slight increase of dense bodies was confirmed by labeling the whole patient with mepacrine. Platelet peroxidase (in the dense tubular system) and catalase-positive granules (revealed by the cytochemistry) were present. Platelets from both patients had severe deficiency of beta TG either after tritonization (less than 4% of normal) or thrombin treatment (less than 15% of normal), and the plasma beta TG levels were slightly increased. Functional studies of these platelets showed an uptake of [14C]5HT inhibited by reserpine similar to that in the control platelets. Thromboxane formation was within normal limits in the presence of arachidonic acid, ADP, collagen, or ionophore A23187, indicating that (1) the cyclooxygenase/thromboxane synthetase systems were not altered and (2) the phospholipase activities were not impaired. Although the platelet adhesion to prepolymerized fibrillar type III collagen and the ADP-, arachidonic acid-, and ionophore A23187-mediated aggregations were apparently normal, in every case the release of [14C]5HT was either at the low side of the normal range or decreased. This abnormality was increased when collagen or thrombin was added to either PRP or washed platelets from both patients, where at the same time, the aggregation and the release were markedly reduced. The results suggest that alpha-granules or their content has an influence on not only the platelet aggregation but also the dense bodies involved in the [14C]5HT release reaction.

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