Correlation between wing bone microstructure and different flight styles: The case of the griffon vulture (gyps fulvus) and greater flamingo (phoenicopterus roseus).

Flying is the main means of locomotion for most avian species, and it requires a series of adaptations of the skeleton and of feather distribution on the wing. Flight type is directly associated with the mechanical constraints during flight, which condition both the morphology and microscopic structure of the bones. Three primary flight styles are adopted by avian species: flapping, gliding, and soaring, with different loads among the main wing bones. The purpose of this study was to evaluate the cross-sectional microstructure of the most important skeletal wing bones, humerus, radius, ulna, and carpometacarpus, in griffon vultures (Gyps fulvus) and greater flamingos (Phoenicopterus roseus). These two species show a flapping and soaring flight style, respectively. Densitometry, morphology, and laminarity index were assessed from the main bones of the wing of 10 griffon vultures and 10 flamingos. Regarding bone mineral content, griffon vultures generally displayed a higher mineral density than flamingos. Regarding the morphology of the crucial wing bones involved in flight, while a very slightly longer humerus was observed in the radius and ulna of flamingos, the ulna in griffons was clearly longer than other bones. The laminarity index was significantly higher in griffons. The results of the present study highlight how the mechanics of different types of flight may affect the biomechanical properties of the wing bones most engaged during flight.

Confocal investigation on colocalization between tubulin posttranslational modifications and associated proteins in rat C6 glioma cells.

Glioblastoma multiforme is the most lethal brain tumor. In the study of mechanisms underlying its development attention has been paid to the microtubular network of its cells, mainly on ßIII tubulin, considered as a marker of malignancy. In the present work, we chose to investigate the tubulin code in glioblastoma cells, analyzing the degree of interaction between tubulin post-translational modifications and different proteins associated with them. The pattern of diverse associated proteins such as EB-1, CLIP-170 and kinesin-1 and their degree of co-distribution with the most abundant post-translational tubulin modifications (tyrosination, acetylation and polyglutamylation) were evaluated. Through immunofluorescence we have shown that EB-1, CLIP-170 and kinesin-1 were well detectable in glioblastoma cells. The double fluorescence and colocalization index between the post-translational modifications of tubulin and associated proteins showed that tyrosinated α-tubulin has significantly high affinity with EB-1, CLIP-170 and kinesin-1, while for acetylated and polyglutamylated tubulin, the degree of interaction with the three associated proteins evaluated was less apparent. Data presented in this paper underline the importance of a thorough analysis of the microtubular mechanics in glioblastoma cells. This may suggest new experimental therapeutic approaches able to act more selectively on the microtubular network of cells in this type of cancer.

Nitrosative stress induces proliferation and viability changes in high glucose-exposed rat Schwannoma cells.

OBJECTIVES: Schwann cells may be involved in the pathogenesis of several neuropathies, such as those linked to an excess of d-glucose. Indeed, hyperglicemic condition can often result in the production of high reactive/nitrosative oxygen species concentration and possible damage of several cell structures. In the present work attention has been focused on the possible nitrosative effect of hyperglycemia on RT4 Schwannoma cell lines. METHODS: Cells were cultured for 72hrs in the presence of 180 mM D-glucose. Morphology, growth rate, cell viability, catalase evaluation and Western blot were performed. RESULTS: In D-glucose-exposed cells, 3-Nitrotyrosine increase and subsequent modifications in cell morphology, growth rate, viability and catalase activity were found. CONCLUSION: Our findings suggested a possible primary role played by Schwann cells in the hyperglicemic neuropathy pathogenesis, through the excessive production of RNS and a decrease in antioxidant defense systems, bearing out the importance of the "nitrosative hypothesis" in the hyperglicemic-induced nervous system complications.