Inhibition of Propionibacterium acnes lipase activity by the antifungal agent ketoconazole

The common skin disease acne vulgaris is caused by Propionibacterium acnes. A lipase secreted by this microorganism metabolizes sebum and the resulting metabolites evoke inflammation in human skin. The antifungal drug ketoconazole inhibits P. acnes lipase activity. We previously showed that the drug also inhibits the growth of P. acnes. Thus, ketoconazole may serve as an alternative treatment for acne vulgaris, which is important because the number of antibiotic‐resistant P. acnes strains has been increasing.     

Phenotype of Cardiomyopathy in Cardiac-specific Heat Shock Protein B8 K141N Transgenic Mouse

A K141N missense mutation in heat shock protein (HSP) B8, which belongs to the small HSP family, causes distal hereditary motor neuropathy, which is characterized by the formation of inclusion bodies in cells. Although the HSPB8 gene causes hereditary motor neuropathy, obvious expression of HSPB8 is also observed in other tissues, such as the heart. The effects of a single mutation in HSPB8 upon the heart were analyzed using rat neonatal cardiomyocytes. Expression of HSPB8 K141N by adenoviral infection resulted in increased HSPB8-positive aggregates around nuclei, whereas no aggregates were observed in myocytes expressing wild-type HSPB8. HSPB8-positive aggresomes contained amyloid oligomer intermediates that were detected by a specific anti-oligomer antibody (A11). Expression of HSPB8 K141N induced slight cellular toxicity. Recombinant HSPB8 K141N protein showed reactivity against the anti-oligomer antibody, and reactivity of the mutant HSPB8 protein was much higher than that of wild-type HSPB8 protein. To extend our in vitro study, cardiac-specific HSPB8 K141N transgenic (TG) mice were generated. Echocardiography revealed that the HSPB8 K141N TG mice exhibited mild hypertrophy and apical fibrosis as well as slightly reduced cardiac function, although no phenotype was detected in wild-type HSPB8 TG mice. A single point mutation of HSPB8, such as K141N, can cause cardiac disease.     

The fate of radiolabelled C28 and C29 phytosterols in the honey bee

The fate of radiolabelled campesterol, sitosterol and 24-methylenecholesterol fed in chemically-defined diets to honey bee (Apis mellifera L.) workers was determined. At various intervals, sterols of prepupae, newly emerged adults and queens were analyzed qualitatively, quantitatively and radiochemically and it was determined that there was not sufficient radioactivity associated with cholesterol and/or desmosterol in any of the samples to verify that any of the three C₂₈ and C₂₉ sterols was dealkylated and converted to cholesterol. Similarly, there was no evidence for the conversion of campesterol or sitosterol to 24-methylenecholesterol. It was concluded that the major portion of the sterols incorporated into the tissues of the brood larvae originated from the worker bees used to establish the colony. There is good evidence supporting the premise that the workers can make available sterols from their endogenous pools to the nutrient in the hive and that they can replenish these sterols with those from the artificial diet. The queen is also able to replenish sterols utilized in egg production from those obtained by the workers from the artificial diet, and at the end of nine weeks queens contained more than four times as much sterol, on a ‘μg sterol per g fresh weight’ basis, than was found in fertile queens at the beginning of the test period.     

Crucial role of Lys(423) in the electron transfer of neuronal nitric-oxide synthase.

Nitric-oxide synthase (NOS) is composed of an oxygenase domain having cytochrome P450-type heme active site and a reductase domain having FAD- and FMN-binding sites. To investigate the route of electron transfer from the reductase domain to the heme, we generated mutants at Lys(423) in the heme proximal site of neuronal NOS and examined the catalytic activities, electron transfer rates, and NADPH oxidation rates. A K423E mutant showed no NO formation activity (<0.1 nmol/min/nmol heme), in contrast with that (72 nmol/min/nmol heme) of the wild type enzyme. The electron transfer rate (0.01 min(-1)) of the K423E on addition of excess NADPH was much slower than that (>10 min(-1)) of the wild type enzyme. From the crystal structure of the oxygenase domain of endothelial NOS, Lys(423) of neuronal NOS is likely to interact with Trp(409) which lies in contact with the heme plane and with Cys(415), the axial ligand. It is also exposed to solvent and lies in the region where the heme is closest to the protein surface. Thus, it seems likely that ionic interactions between Lys(423) and the reductase domain may help to form a flavin to heme electron transfer pathway.     

A tolerance gene for prenylated flavonoid encodes a 26S proteasome regulatory subunit in Sophora flavescens

Yeast functional screening with a Sophora flavescens cDNA library was performed to identify the genes involved in the tolerant mechanism to the self-producing prenylated flavonoid sophoraflavanone G (SFG). One cDNA, which conferred SFG tolerance, encoded a regulatory particle triple-A ATPase 2 (SfRPT2), a member of the 26S proteasome subunit. The yeast transformant of SfRPT2 showed reduced SFG accumulation in the cells.