ß-1 tubulin R307H SNP alters microtubule dynamics and affects severity of a hereditary thrombocytopenia.

BACKGROUND: Single nucleotide polymorphisms (SNPs) in platelet-associated genes partly explain inherent variability in platelet counts. Patients with monoallelic Bernard Soulier syndrome due to the Bolzano mutation (GPIBA A156V) have variable platelet counts despite a common mutation for unknown reasons. OBJECTIVES: We investigated the effect of the most common SNP (R307H) in the hematopoietic-specific tubulin isotype ß-1 in these Bernard Soulier patients and potential microtubule-based mechanisms of worsened thrombocytopenia. PATIENTS/METHODS: Ninety-four monoallelic Bolzano mutation patients were evaluated for the R307H ß-1 SNP and had platelet counts measured by three methods; the Q43P SNP was also evaluated. To investigate possible mechanisms underlying this association, we used molecular modeling of ß-1 tubulin with and without the R307H SNP. We transfected SNP or non-SNP ß-1 tubulin into MCF-7 and CMK cell lines and measured microtubule regrowth after nocodazole-induced depolymerization. RESULTS: We found that patients with at least one R307H SNP allele had significantly worse thrombocytopenia; manual platelet counting revealed a median platelet count of 124 in non-SNP patients and 76 in SNP patients (both ×10(9)  L(-1) ; P < 0.01). The Q43P SNP had no significant association with platelet count. Molecular modeling suggested a structural relationship between the R307H SNP and microtubule stability via alterations in the M-loop of ß tubulin; in vitro microtubule recovery assays revealed that cells transfected with R307H SNP ß-1 had significantly impaired microtubule recovery. CONCLUSIONS: Our data show that the R307H SNP is significantly associated with the degree of thrombocytopenia in congenital and acquired platelet disorders, and may affect platelets by altering microtubule behavior.

Effects of the actin-stabilizing drug, jasplakinolide, on pigment granule motility in isolated retinal pigment epithelial (RPE) cells of green sunfish, Lepomis cyanellus.

The retinal pigment epithelium (RPE) of teleosts contains pigment granules that migrate in response to changes in light condition. Dissociated, cultured RPE cells in vitro can be triggered to aggregate or disperse pigment granules by the application of cAMP or dopamine, respectively. Previous research using the actin-disrupting drug, cytochalasin D, suggested that pigment granule motility is actin dependent. To further examine the role of actin in pigment granule motility, we tested the effects of the actin-stabilizing drug, jasplakinolide, on pigment granule motility. Pigment granules in previously dispersed RPE cells remained dispersed after jasplakinolide exposure (0.1-1 microM), but the drug halted movement of most pigment granules and stimulated rapid bi-directional movements in a small subset of granules. Jasplakinolide also blocked net pigment granule aggregation and interfered with the maintenance of full aggregation. Although jasplakinolide did not block pigment granule dispersion, it did alter the motility of dispersing granules compared to control cells; rather than the normal saltatory, primarily centrifugal movements, granules of jasplakinolide-treated cells demonstrated slow, creeping centrifugal movements and more rapid bi-directional movements. Jasplakinolide also altered cell morphology; the length and thickness of apical projections increased, and enlarged, paddle-like structures, which contained F-actin appeared at the tips of projections. Actin antibody labeling of jasplakinolide-treated cells revealed a more reticulated network of actin compared to antibody-labeled control cells. These results indicate that jasplakinolide-induced disruption of the actin network compromises normal pigment granule dispersion and aggregation in isolated RPE cells, thus providing further evidence that these movements are actin dependent.