Micrococcus cohnii sp. nov., isolated from the air in a medical practice.

Three Gram-reaction-positive bacteria, isolated from the air in a medical practice (strains WS4601(T), WS4602) or a pharmaceutical clean room (strain WS4599), were characterized using a polyphasic approach. Phylogenetic analyses based on 16S rRNA and recA gene sequences of the three novel strains showed that they formed a distinct lineage within the genus Micrococcus, sharing 16S rRNA gene sequence similarities of 96.1-98.0 % with other species of this genus. Chemotaxonomic features also supported the classification of the three novel strains within the genus Micrococcus. The major cellular fatty acids of strain WS4601(T) were anteiso-C(15 : 0) and iso-C(15 : 0), the cell-wall peptidoglycan was of type A3α (L-Lys-L-Ala), and the predominant respiratory quinones were MK-7(H(2)) and MK-8(H(2)). The polar lipid profile contained diphosphatidylglycerol and phosphatidylglycerol, but no phosphatidylinositol. The G+C content of the genomic DNA was 70.4 mol%. Numerous physiological properties were found that clearly distinguished strains WS4599, WS4601(T) and WS4602 from established members of the genus Micrococcus. Based on the phenotypic and phylogenetic data, strains WS4599, WS4601(T) and WS4602 are considered to represent three different strains of a novel species of the genus Micrococcus, for which the name Micrococcus cohnii sp. nov. is proposed. The type strain is WS4601(T) (=DSM 23974(T)=LMG 26183(T)).

Naumannella halotolerans gen. nov., sp. nov., a Gram-positive coccus of the family Propionibacteriaceae isolated from a pharmaceutical clean room and from food.

Four Gram-stain-positive, aerobic bacterial strains isolated from a pharmaceutical clean room (strain WS4616(T)), a dessert milk product (strain WS4617) and from raw milk (strains WS4623 and WS4624) were characterized using a polyphasic approach. Phylogenetic analyses based on 16S rRNA and recA gene sequences showed that they formed a distinct lineage within the family Propionibacteriaceae. Similarity values between 16S rRNA gene sequences of the four novel strains and the type species of all genera belonging to the family Propionibacteriaceae were 89.2-94.1%. The major cellular fatty acid was anteiso-C(15:0) and the major polar lipids were diphosphatidylglycerol and phosphatidylglycerol. Respiratory quinones were MK-8(H(4)) and MK-9(H(4)). The cell-wall peptidoglycan of type A3γ contained ll-diaminopimelic acid, alanine, glycine and glutamic acid. The G+C content of the genomic DNA of strain WS4616(T) was 67.7 mol%. The whole-cell sugar pattern contained ribose, mannose, arabinose, glucose and galactose. On the basis of phenotypic and genetic data, strains WS4616(T), WS4617, WS4623 and WS4624 are classified as members of a novel species in a new genus of the family Propionibacteriaceae, for which the name Naumannella halotolerans gen. nov., sp. nov. is proposed. The type strain is WS4616(T) ( = DSM 24323(T) = LMG 26184(T)) and three additional strains are WS4617, WS4623 and WS4624.

Growth phase- and cell division-dependent activation and inactivation of the {sigma}32 regulon in Escherichia coli.

Alternative sigma factors allow bacteria to reprogram global transcription rapidly and to adapt to changes in the environment. Here we report on growth- and cell division-dependent sigma(32) regulon activity in Escherichia coli in batch culture. By analyzing sigma(32) expression in growing cells, an increase in sigma(32) protein levels is observed during the first round of cell division after exit from stationary phase. Increased sigma(32) protein levels result from transcriptional activation of the rpoH gene. After the first round of bulk cell division, rpoH transcript levels and sigma(32) protein levels decrease again. The late-logarithmic phase and the transition to stationary phase are accompanied by a second increase in sigma(32) levels and enhanced stability of sigma(32) protein but not by enhanced transcription of rpoH. Throughout growth, sigma(32) target genes show expression patterns consistent with oscillating sigma(32) protein levels. However, during the transition to early-stationary phase, despite high sigma(32) protein levels, the transcription of sigma(32) target genes is downregulated, suggesting functional inactivation of sigma(32). It is deduced from these data that there may be a link between sigma(32) regulon activity and cell division events. Further support for this hypothesis is provided by the observation that in cells in which FtsZ is depleted, sigma(32) regulon activation is suppressed.