Self-assembled nanocage 1 was found to promote the aerobic, aqueous oxidation of styrene and its derivatives with the aid of (en)Pd(NO3)2. Obviously, the reaction was promoted by a double catalysis system: i.e., cage 1 acted as a reverse phase-transfer catalyst, whereas (en)Pd2+ as an oxidation catalyst.
We have identified a novel gene from Schizosaccharomyces pombe that we have named ecl1(+) (extender of the chronological lifespan). When ecl1(+) is provided on a high-copy number plasmid, it extends the viability of both the Deltasty1 MAP kinase mutant and the wild-type cells after entry into the stationary phase. ecl1(+) encodes an 80-amino acid polypeptide that had not been annotated in the current database. The ecl1(+)-mRNA increases transiently when the growth phase is changed from the log phase to the stationary phase. The Ecl1 protein is localized in the nucleus. Calorie restriction extends the chronological lifespan of wild-type and Deltaecl1 cells but not ecl1(+)-overproducing cells. The Deltapka1 mutant shows little, if any, additional extension of viability when Ecl1 is overproduced. The ste11(+) gene that is negatively controlled by Pka1 is up regulated when Ecl1 is overproduced. From these results we propose that the effect of Ecl1 overproduction may be mainly linked to and negatively affects the Pka1-dependent pathway.
Although significant progress has been made in the development of light-emitting materials for organic light-emitting diodes along with the elucidation of emission mechanisms, the electron injection/transport mechanism remains unclear, and the materials used for electron injection/transport have been basically unchanged for more than 20 years. Here, we unravelled the electron injection/transport mechanism by tuning the work function near the cathode to about 2.0 eV using a superbase. This extremely low-work function cathode allows direct electron injection into various materials, and it was found that organic materials can transport electrons independently of their molecular structure. On the basis of these findings, we have realised a simply structured blue organic light-emitting diode with an operational lifetime of more than 1,000,000 hours. Unravelling the electron injection/transport mechanism, as reported in this paper, not only greatly increases the choice of materials to be used for devices, but also allows simple device structures.
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