Cytoskeletal Dependence of Insulin Granule Movement Dynamics in INS-1 Beta-Cells in Response to Glucose

For pancreatic β-cells to secrete insulin in response to elevated blood glucose, insulin granules retained within the subplasmalemmal space must be transported to sites of secretion on the plasma membrane. Using a combination of super-resolution STORM imaging and live cell TIRF microscopy we investigate how the organization and dynamics of the actin and microtubule cytoskeletons in INS-1 β-cells contribute to this process. GFP-labeled insulin granules display 3 different modes of motion (stationary, diffusive-like, and directed). Diffusive-like motion dominates in basal, low glucose conditions. Upon glucose stimulation no gross rearrangement of the actin cytoskeleton is observed but there are increases in the 1) rate of microtubule polymerization; 2) rate of diffusive-like motion; and 3) proportion of granules undergoing microtubule-based directed motion. By pharmacologically perturbing the actin and microtubule cytoskeletons, we determine that microtubule-dependent granule transport occurs within the subplasmalemmal space and that the actin cytoskeleton limits this transport in basal conditions, when insulin secretion needs to be inhibited.     

Modulation in cytochrome P-420 and P-450 content in Saccharomyces cerevisiae according to physiological conditions and genetic background

The diploid strain D5 of Saccharomyces cerevisiae, relative to other strains of yeast, has a large amount of cytochrome P-450 present during the logarithmic phase of growth and a low amount of cytochrome P-420. As the stationary phase of growth is approached, an increasing intensity of absorbance is observed at 420 nm. If the cells are suspended in buffer during mid-logarithmic growth, the absorbance at 450 nm disappears and absorbance at 420 nm is increased after the cells have been held in buffer for 24 h. At late logarithmic growth, the absorbance at 450 nm is still retained after the cells have been held in buffer for 24 h. Within 44 h of the time of harvest, the absorbance at 450 nm disappears completely and the absorbance at 420 nm is intense. Cytoplasmic petite variants of strain D5 have less of both cytochromes P-450 and P-420 than does the grande D5 strain; the absorbance at 450 and 420 nm are retained up to 96 h when the cells are held in buffer. Haploid spores of strain D5 exhibit absorbances at 450 and 420 nm during the logarithmic phase of growth, and these absorbances are retained after the cells are held in buffer for 24 h.

An hypothesis is proposed which states that cytochrome P-450 is the membrane-bound form and cytochrome P-420 is free in the cytosol; the cytochromes interconvert and are active in either state until the associated enzymes disassociate.     

Premature chromatin condensation upon accumulation of NIMA.

The NIMA protein kinase of Aspergillus nidulans is required for the G2/M transition of the cell cycle. Mutants lacking NIMA arrest without morphological characteristics of mitosis, but they do contain an activated p37nimX kinase (the Aspergillus homologue of p34cdc2). To gain a better understanding of NIMA function we have investigated the effects of expressing various NIMA constructs in Aspergillus, fission yeast and human cells. Our experiments have shown that the instability of the NIMA protein requires sequences in the non-catalytic C-terminus of the protein. Removal of this domain results in a stable protein that, once accumulated, promotes a lethal premature condensation of chromatin without any other aspects of mitosis. Similar effects were also observed in fission yeast and human cells accumulating Aspergillus NIMA. This phenotype is independent of cell cycle progression and does not require p34cdc2 kinase activity. As gain of NIMA function by accumulation results in premature chromatin condensation, and loss of NIMA function results in an inability to enter mitosis, we propose that NIMA functions in G2 to promote the condensation of chromatin normally associated with entry into mitosis.