We have identified the Src family members, Lck and Fgr in resting human and rodent platelets and compared their subcellular distributions and tyrosine phosphorylation status to those of the other Src family kinases to gain insights into the signal transduction pathways active in maintaining platelets in the circulation. Like Fyn, Lyn, and Yes, most of Fgr and Lck was detergent-insoluble in human and rat platelets. In comparison, Src showed higher detergent solubility than the Src-related kinases. Most all human platelet Src was detergent-soluble, while that of rodent platelets was present in all detergent fractions. We also compared the tyrosine-phosphorylation status of Lck and Fgr to other Src family members in resting platelets using immunoprecipitation and immunoblotting. All of these Src family members except Fgr exhibited substantial phosphotyrosine antibody labeling. The partitioning of these kinases, with the exception of Src, with the detergent-insoluble fraction, their tyrosine-phosphorylation status, and co-localization with endocytotic vesicles lead us to hypothesize that the Src family kinases are involved in signaling events that drive cytoskeletal reorganization and active endocytosis of plasma proteins by circulating platelets.
Rats of the Wistar Furth (WF) strain have hereditary macrothrombocytopenia with decreased platelet alpha-granule proteins. The autosomal recessive pattern of inheritance of the large mean platelet volume (MPV) phenotype and platelet alpha-granule protein deficiencies suggest that a component common to both formation of platelet alpha-granules and subdivision of megakaryocyte cytoplasm into platelets is quantitatively or qualitatively abnormal in WF megakaryocytes and platelets. We examined WF platelets for such an abnormality using electrophoretic and immunologic analyses. Rabbit antiserum prepared against WF rat platelets and absorbed with Wistar rat platelets recognized a major 235-Kd band, and minor bands of WF rat platelets ranging from 200 to 130 Kd, not present in immunoblots of Wistar, Sprague-Dawley, or Long-Evans rat platelets. The minor bands were labeled with affinity-isolated antibody to the 235-Kd band, indicating that all bands contained the same unique antigenic site. The 235-Kd antigen had the same mobility as rat platelet talin identified with a platelet antitalin antibody. Activation of calcium-dependent proteases during Triton X-100 extraction caused conversion of the 235- Kd antigen into a major fragment of 200 Kd and minor fragments ranging to 115 Kd, identical in mobility to fragments of rat platelet talin produced in the same samples. The absorbed anti-WF platelet antiserum also detected a 235-Kd antigen in WF lung, kidney, and small intestine by immunoblotting. Finally, the 235-Kd antigen unique to WF rats was immunoprecipitated from Triton X-100 supernatants of WF platelets with an antitalin monoclonal antibody (MoAb). These data indicate that the unique antigenic site is on WF talin. Examination of talin distribution in Wistar megakaryocytes showed localization beneath the plasma membrane, on the cytosolic face of demarcation membranes, associated with alpha-granule membranes, and diffusely throughout the cytoplasm. Although WF megakaryocytes showed the same general distribution pattern, some differences were apparent. In contrast to membrane systems of the Wistar rat, the large membrane complexes in WF megakaryocytes contained little or no talin. In addition, approximately half of WF megakaryocytes showed an increased peripheral localization of talin, often associated with membrane blebs, with decreased talin in the cytoplasmic interior. The association of the unique talin antigenic determinant and anomalous megakaryocyte talin distribution with abnormal platelet formation in WF rats suggests that talin is abnormal in this rat strain and that talin plays an important role in subdivision of megakaryocyte cytoplasm into platelets.
Hereditary macrothrombocytopenia is a hallmark of Wistar Furth (WF) rats. In addition, a platelet/megakaryocyte alpha granule defect, similar to that of patients with gray platelet syndrome, is present. Several observations indicate cytoskeletal abnormalities in WF platelets and megakaryocytes, suggesting the potential for functional defects in hemostatic processes requiring cytoskeletal reorganization, such as platelet adhesion and spreading. However, no bleeding abnormality has been noted. Here, we report a prolonged bleeding time (>30 minutes in 10 of 11 rats tested) with defective clot formation in the WF strain. Prolonged bleeding time can result from defects in platelet adhesion, aggregation, or the release reaction. Because aggregation to collagen and adenosine diphosphate were reported to be normal, we determined whether WF rat platelets are defective in their ability to adhere to substrates. Platelet adherence and spreading was evaluated from 30 seconds to 30 minutes on Formvar-coated, carbon-stabilized grids or poly-L-lysine–coated glass coverslips by transmission electron microscopy or immunofluorescence, respectively, and scanning electron microscopy. We classified the adhered platelets according to their pattern of spreading, ie, rounded, rounded or spreading with short filopodia, spindle-shaped, spreading with long filopodia, spreading with lamellipodia, and fully spread. Adherent normal rat platelets displayed all stages of spreading within 30 seconds to 2 minutes, including many spindle-shaped forms, and forms with multiple, long filopodia. In contrast, adhered WF platelets at these early time points rarely developed long filopodia or were spindle shaped. The majority of adherent WF platelets at these early time points were either round, spread with a few short filopodia, or extensively spread with wide lamellipodial skirts. By 15 to 30 minutes, most platelets in both Wistar and WF samples were fully spread. These data show abnormal WF platelet spreading. The paucity of spindle-shaped forms and forms with long filopodia may reflect an inability of WF platelets to undergo the early stages of spreading, or, alternatively, their more rapid than normal progression through these stages. We hypothesize that this failure to spread normally may relate to prolonged bleeding times in vivo and defective clot formation in WF rats.
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