Corynebacterium suedekumii sp. nov and Corynebacterium breve sp. nov., isolated from raw cow's milk.

Four Gram-positive, rod-shaped, none-sporeforming, non-motile isolates were obtained from various raw milk samples taken from the cooling tank on a research farm in Königswinter, Germany. Based on phylogenetic analysis of the 16S rRNA genes and whole genome sequences, all isolates were assigned to the genus Corynebacterium, but were divided in two different groups. All isolates contained C18 : 1 cis 9 and C16 : 0 as predominant fatty acids, as well as traces of C18 : 0. They all contained menaquinones MK-8 (H2) and MK-9 (H2) and produced mycolic acids characteristic for the majority of species belonging to the genus Corynebacterium. 16S rRNA gene sequence similarity values to the closest related type strains Corynebacterium humireducens DSM 45392T and Corynebacterium pilosum DSM 20521T were below 98.7 %, average nucleotide identity values were below 86 % and digital DNA-DNA-hybridization values were below 25 %, indicating that the isolates represent two novel species. The names Corynebacterium suedekumii sp. nov. and Corynebacterium breve sp. nov. are proposed, represented by the type strains LM112T (=DSM 116216T=HAMBI 3782T) and R4T (=DSM 116183T=HAMBI 3785T), respectively.

Substrate Inhibition of 5ß-Δ4-3-Ketosteroid Dehydrogenase in Sphingobium sp. Strain Chol11 Acts as Circuit Breaker During Growth With Toxic Bile Salts.

In contrast to many steroid hormones and cholesterol, mammalian bile salts are 5ß-steroids, which leads to a bent structure of the steroid core. Bile salts are surface-active steroids excreted into the environment in large amounts, where they are subject to bacterial degradation. Bacterial steroid degradation is initiated by the oxidation of the A-ring leading to canonical Δ4-3-keto steroids with a double bond in the A-ring. For 5ß-bile salts, this Δ4-double bond is introduced into 3-keto-bile salts by a 5ß-Δ4-ketosteroid dehydrogenase (5ß-Δ4-KSTD). With the Nov2c019 protein from bile-salt degrading Sphingobium sp. strain Chol11, a novel 5ß-Δ4-KSTD for bile-salt degradation belonging to the Old Yellow Enzyme family was identified and named 5ß-Δ4-KSTD1. By heterologous production in Escherichia coli, 5ß-Δ4-KSTD function could be shown for 5ß-Δ4-KSTD1 as well as the homolog CasH from bile-salt degrading Rhodococcus jostii RHA1. The deletion mutant of 5ß-Δ4-kstd1 had a prolonged lag-phase with cholate as sole carbon source and, in accordance with the function of 5ß-Δ4-KSTD1, showed delayed 3-ketocholate transformation. Purified 5ß-Δ4-KSTD1 was specific for 5ß-steroids in contrast to 5α-steroids and converted steroids with a variety of hydroxy groups regardless of the presence of a side chain. 5ß-Δ4-KSTD1 showed a relatively low K m for 3-ketocholate, a very high specific activity and pronounced substrate inhibition. With respect to the toxicity of bile salts, these kinetic properties indicate that 5ß-Δ4-KSTD1 can achieve fast detoxification of the detergent character as well as prevention of an overflow of the catabolic pathway in presence of increased bile-salt concentrations.