Degradative pathway of p-aminoazobenzene by Bacillus subtilis

Summary p-Aminoazobenzene was degraded by Bacillus subtilis to aniline and p-phenylenediamine by reductive fission of an azo bond. The aniline was then acetylated to acetanilide while the p-phenylenediamine underwent 2 successive acetylations to yield p-aminoacetanilide and p-phenylenediacetanilide. In addition, another pathway was found in Bacillus subtilis in which p-aminoazobenzene was metabolised to p-acetamidoazobenzene.     

Influence of body size on fecundity and sperm management in the parasitoid wasp Anisopteromalus calandrae

A large body size is considered to be advantageous to the reproductive success of females as a result of several factors, such as the allocation of more resources to reproduction and the efficient management of sperm transferred by males. In the present study, the effects of female body size, female mating status and additional food availability on fecundity and the offspring sex ratio are investigated in the parasitoid wasp Anisopteromalus calandrae Howard (Hymenoptera: Pteromalidae). Because of haplodiploid sex determination, females must fertilize eggs to produce female offspring but not to produce male offspring. As predicted, female fecundity and the number of female offspring are positively correlated with body size. However, although the volume of the spermatheca increases with female body size, the amount of sperm stored in the spermatheca is relatively constant, irrespective of body size. Consequently, larger females produce a greater proportion of male offspring, especially at the end of the oviposition sequence, suggesting that larger females that possess more resources for reproduction and produce a larger number of offspring are more likely to suffer sperm depletion. The results of the present study also show that mated females have an increased fecundity compared with virgin females, although the opportunity to feed on honey along with host feeding has no impact upon fecundity or the sex ratio.     

Fractionation of chromosomal proteins of pea seedlings using procedures which avoid denaturation

Chromatin was prepared from the buds and cotyledons of Alaskapea seedlings. The dissociated chromosomal components in thepresence of 2 M NaCl and 5 M urea were completely fractionatedinto DNA and proteins with a Bio-Gel A50 column. The proteinswere recovered by (NH₄)₂SO₄ and further fractionated into histonesand non-histone proteins using a Bio-Rex 70(Na⁺) column. Thedifference in the ratios of histones to non-histone proteinsbefore and after chromatography with the Bio-Rex 70 was lessthan 10%. The histones and non-histone proteins thus preparedshowed typical protein absorption spectra. Polyacrylamide gelelectrophoresis of histones showed that the histone compositionsin buds and cotyledon were similar, but the amount of HI histoneswas a little less in cotyledons than in buds. Unlike histones,non-histone proteins fractionated by SDS-polyacrylamide gelelectrophoresis indicated distinct differences between the twotissues. Buds had more heterogeneous non-histone proteins, atleast 13 polypeptides, than cotyledons did. On the other hand,non-histone proteins of cotyledons showed less heterogeneityand lacked proteins of high molecular weight which were foundin buds. (Received May 6, 1976; )     

Exposure of Phosphatidylserine by Xk-related Protein Family Members during Apoptosis

Apoptotic cells expose phosphatidylserine (PtdSer) on their surface as an “eat me” signal. Mammalian Xk-related (Xkr) protein 8, which is predicted to contain six transmembrane regions, and its Caenorhabditis elegans homolog CED-8 promote apoptotic PtdSer exposure. The mouse and human Xkr families consist of eight and nine members, respectively. Here, we found that mouse Xkr family members, with the exception of Xkr2, are localized to the plasma membrane. When Xkr8-deficient cells, which do not expose PtdSer during apoptosis, were transformed by Xkr family members, the transformants expressing Xkr4, Xkr8, or Xkr9 responded to apoptotic stimuli by exposing cell surface PtdSer and were efficiently engulfed by macrophages. Like Xkr8, Xkr4 and Xkr9 were found to possess a caspase recognition site in the C-terminal region and to require its direct cleavage by caspases for their function. Site-directed mutagenesis of the amino acid residues conserved among CED-8, Xkr4, Xkr8, and Xkr9 identified several essential residues in the second transmembrane and second cytoplasmic regions. Real time PCR analysis indicated that unlike Xkr8, which is ubiquitously expressed, Xkr4 and Xkr9 expression is tissue-specific.     

Caspase cleavage releases a nuclear protein fragment that stimulates phospholipid scrambling at the plasma membrane

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Über den Einfluß der Ernährung auf die Darmflora der Fische

Ohne Zusammenfassung     

In silico assessment of chemical mutagenesis in comparison with results of Salmonella microsome assay on 909 chemicals

Genotoxicity is one of the important endpoints for risk assessment of environmental chemicals. Many short-term assays to evaluate genotoxicity have been developed and some of them are being used routinely. Although these assays can generally be completed within a short period, their throughput is not sufficient to assess the huge number of chemicals, which exist in our living environment without information on their safety. We have evaluated three commercially available in silico systems, i.e., DEREK, MultiCASE, and ADMEWorks, to assess chemical genotoxicity. We applied these systems to the 703 chemicals that had been evaluated by the Salmonella/microsome assay from CGX database published by Kirkland et al. [1]. We also applied these systems to the 206 existing chemicals in Japan that were recently evaluated using the Salmonella/microsome assay under GLP compliance (ECJ database). Sensitivity (the proportion of the positive in Salmonella/microsome assay correctly identified by the in silico system), specificity (the proportion of the negative in Salmonella/microsome assay correctly identified) and concordance (the proportion of correct identifications of the positive and the negative in Salmonella/microsome assay) were increased when we combined the three in silico systems to make a final decision in mutagenicity, and accordingly we concluded that in silico evaluation could be optimized by combining the evaluations from different systems. We also investigated whether there was any correlation between the Salmonella/microsome assay result and the molecular weight of the chemicals: high molecular weight (>3000) chemicals tended to give negative results. We propose a decision tree to assess chemical genotoxicity using a combination of the three in silico systems after pre-selection according to their molecular weight.     

Construction of novel single-cell screening system using a yeast cell chip for nano-sized modified-protein-displaying libraries

A novel screening system using a microchamber array chip was developed for construction of combinatorial nano-sized protein libraries in combination with yeast cell surface engineering. It is possible to place a single yeast cell into each microchamber, to observe its behavior, and to pick up the target cell. The microchamber array chip is referred to as a “yeast cell chip.” A single EGFP-displaying yeast cell could be detected, picked up by a micro-manipulator, and cultivated on agar medium. Furthermore, a catalytic reaction, the hydrolysis of fluorescein dioctanate, by a single yeast cell displaying Rhizopus oryzae lipase (ROL) was carried out in one microchamber. The ROL-encoding gene in a single ROL-displaying cell was amplified by PCR. These results demonstrate that this yeast cell chip in combination with cell surface engineering could be used as a tool in a high-throughput screening system not only for a single living cell and a whole-cell catalyst with a nano-sized protein cluster but also for modified nano-sized and functional protein molecules from protein libraries on the cell surface.