Tunable Dirac cone in the topological insulator Bi(2-x)Sb(x)Te(3-y)Se(y).

The three-dimensional topological insulator is a quantum state of matter characterized by an insulating bulk state and gapless Dirac cone surface states. Device applications of topological insulators require a highly insulating bulk and tunable Dirac carriers, which has so far been difficult to achieve. Here we demonstrate that Bi(2-x)Sb(x)Te(3-y)Se(y) is a system that simultaneously satisfies both of these requirements. For a series of compositions presenting bulk-insulating transport behaviour, angle-resolved photoemission spectroscopy reveals that the chemical potential is always located in the bulk band gap, whereas the Dirac cone dispersion changes systematically so that the Dirac point moves up in energy with increasing x, leading to a sign change of the Dirac carriers at x~0.9. Such a tunable Dirac cone opens a promising pathway to the development of novel devices based on topological insulators.

Cloning, sequencing, and expression of the genomic DNA encoding the protein phosphatase cdc25 in Dictyostelium discoideum.

A genomic DNA ( Dd-cdc25) encoding the protein phosphatase cdc25 was isolated from the cellular slime mold Dictyostelium discoideum. The Dd-cdc25 DNA sequence, with a length of 2,958 bp, encodes a protein consisting of 986 amino acid (aa) residues. The sequence shares significant identities with cdc25 from human, mouse, Xenopus, Drosophila, and Shizosaccharomyces pombe, particularly at the C-terminal region including the catalytic site for phosphatase activity. The deduced Dictyostelium cdc25 protein (Dd-cdc25) has the highest molecular mass (109.9 kDa) in several cdc25 species so far reported and contains four regions consisting of unusually long asparagine repeats (22-31) in the sequence. Unexpectedly, however, Western blot analysis using a specific antibody raised against the C terminus (aa 892-986) of Dd-cdc25 demonstrated that the protein exists as a short form (56 kDa), which has the C-terminal active site of phosphatase, during the course of Dictyostelium development. The Western blot analysis also revealed marked changes in the phosphorylated state of the Dd-cdc25, coupling with cellular development.

Relevance of histone H1 kinase activity to the G2/M transition during the cell cycle ofDictyostelium discoideum.

The implication of histone H1 kinase activity for the G2/M transition during the cell cycle was investigated usingDictyostelium discoideum Ax-2. Histone H1 kinase with its activity was purified from cell extracts by the use of p13(suc1) affinity gel. In the vegetative cell cycle, the activity of histone H1 kinase including Cdc2 kinase was found using synchronized Ax-2 cells to be highest just before the entry into mitosis. The activity also was markedly enhanced just prior to the M phase from which developing cells (possibly prespore cells) reinitiate their cell cycle at the mound-tipped aggregate stage. These results strongly suggest the importance of Cdc2 kinase activity in the G2 to M phase transition during the cell cycle, as the case for other eukaryotic cells.