[Results of antimicrobial susceptibilities of strains clinically isolated at 8 institutions in Hiroshima City to major oral antimicrobial drugs, mainly new quinolone drugs. Hiroshima Levofloxacin Susceptibility Surveillance Group].

To evaluate the resistance for major oral antimicrobial agents, mainly new quinolones, we carried out a drug susceptibility surveillance of 3,050 strains of 11 microbial species clinically isolated at 8 institutions such as general hospitals and examination centers in Hiroshima city. 10 antimicrobial agents were used: 3 new quinolone drugs, 5 beta-lactam drugs, minocycline and clarithromycin. Among Gram-positive bacteria, methicillin resistant Staphylococcus aureus (MRSA) and Enterococcus faecalis showed low susceptibility to the new quinolone drugs, while methicillin susceptible Staphylococcus aureus (MSSA) and Streptococcus pneumoniae were highly sensitive to these drugs. Among Gram-negative bacteria, Pseudomonas aeruginosa showed high resistance for the new quinolone drugs, but enteric bacteria and Haemophilus influenzae did not show marked resistance, maintaining almost good sensitivity to these drugs. To reduce the appearance of resistant bacteria, appropriate antimicrobial agents should be selected. Drug susceptibility surveillance in the community will be also important in the future.

1a-docosahexaenoyl mitomycin C: a novel inhibitor of protein tyrosine kinase.

A series of derivatives of mitomycin C conjugated with various fatty acids at position 1a was synthesized and the effect of these compounds on protein kinase activities was evaluated. 1a-Docosahexaenoyl mitomycin C (DMMC) selectively inhibited protein tyrosine kinase (PTK) activity in the postnuclear fraction of v-src-transformed NIH 3T3 cells although neither derivatives conjugated with other fatty acids or docosahexaenoic acid or mitomycin C did not. DMMC inhibited the activity of calmodulin-dependent kinase III and protein kinase A very weakly, and only barely affected protein kinase C activity. DMMC also attenuated autophosphorylation of immunoprecipitated p60v-src irreversibly. The addition of thiol compounds to the reaction mixture reversed the inhibition by DMMC, suggesting that some thiol moiety of PTK protein might be involved. DMMC also inhibited kinase activity of p210bcr-abl immunoprecipitated from the lysate of K562 cells. These results indicate that DMMC is a novel inhibitor of PTK.

Antibacterial activity of two alkylamines integrated an indane scaffold: mimicry of a complementary unit on magainin 2.

Based on the antibacterial activity of 9-phenylnonylamine (pC9a) against Escherichia coli (ATCC29522) and Staphylococcus aureus (ATCC25923), we have further tested the inhibitory ability of the growth of the bacteria by (+/-)1-(4-aminobutyl)-6-benzylindane (PM2) and (+/-)1-benzyl-6-(4-aminobutyl) indane (PM3), that is, two kinds of 1,6-disubstituted indanes. In an in vitro assay, they showed almost the same antibacterial activities against the bacteria as pC9a, as well as that of magainin 2 analogs (i.e., the peptides MSI-78 and 87-ISM), except in the case of 87-ISM against S. aureus. At the MIC (minimum inhibitory concentration) values, however, their killing rate of E. coli is actually quicker than pC9a. This indicates that an indane scaffold, used as a template to mimic a part of the alpha-helical structure of magainin 2, can accelerate the killing rate. At present, however, it is unknown whether either the hydrophobicity or the alpha-helical structure, or both, of the indane scaffold is involved in accelerating the rate. Moreover, these two indanes also showed stronger antibacterial activity against two strains of Helicobacter pylori (ATCC43526, ATCC43579) than either pC9a or magainin 2 related peptides.

Selective inhibition of DNA polymerase-alpha family with chemically synthesized derivatives of PHYLPA, a unique Physarum lysophosphatidic acid.

PHYLPA, a unique Physarum lysophosphatidic acid (LPA), showed selective inhibition of a family of DNA polymerase alpha, including DNA polymerases alpha, delta and epsilon; but no inhibition of DNA polymerase beta or gamma was observed. To reveal the molecular mechanism of inhibition of DNA polymerases by PHYLPA, four stereoisomers and some other derivatives were synthesized and their effects on DNA polymerases were studied. Among eight derivatives synthesized, PHYLPA-1 (the natural PHYLPA; sodium 1-O-[(9'S,10'R)-9',10'-methanohexadecanoyl]-sn-glycerol 2,3-cyclic phosphate) and PHYLPA-2 (sodium 3-O-[9'S,10'R)-9',10'-methanohexadecanoyl]-sn-glycerol 1,2-cyclic phosphate) were strong and specific inhibitors of a family of DNA polymerase alpha. But their stereoisomers PHYLPA-3 (sodium 1-O-[9'R,10'S)-9',10'-methanohexadecanoyl]-sn-glycerol 2,3-cyclic phosphate) and PHYLPA-4 (sodium 3-O-[9'R,10'S)-9',10'-methanohexadecanoyl-sn-glycerol 1,2 cyclic phosphate) were weak inhibitors, showing the critical importance of stereochemistry of a cyclopropane-containing fatty acid for the inhibitory activity. Some derivatives having no cyclopropane-containing fatty acids--palmitoyl-, oleoyl-, and palmitoleoyl-PHYLPA--showed inhibition to some extent; but 1-palmytoyl and 1-oleoyl lysophosphatidic acid, which has no cyclic phosphate, did not show an apparent inhibitor activity on DNA polymerases. Hence, the extent of the inhibition apparently depends on the stereochemistry of both the fatty acid moiety and the cyclic phosphate.