De novo assembly of Roseomonas mucosa isolated from patients with atopic dermatitis.

Roseomonas mucosa is associated with the normal skin microflora. Here, we present de novo sequence assemblies from R. mucosa isolates obtained from the skin lesions of three atopic dermatitis patients.

De novo assembly of Roseomonas mucosa isolates from healthy human volunteers used to treat atopic dermatitis.

Roseomonas mucosa is a bacterium that is found in the natural microbiota of human skin. Here, we present de novo sequence assemblies from R. mucosa isolated from the skin microflora of three healthy human volunteers that were used to treat atopic dermatitis patients.

Genetic mechanisms of Coxiella burnetii lipopolysaccharide phase variation.

Coxiella burnetii is an intracellular pathogen that causes human Q fever, a disease that normally presents as a severe flu-like illness. Due to high infectivity and disease severity, the pathogen is considered a risk group 3 organism. Full-length lipopolysaccharide (LPS) is required for full virulence and disease by C. burnetii and is the only virulence factor currently defined by infection of an immunocompetent animal. Transition of virulent phase I bacteria with smooth LPS, to avirulent phase II bacteria with rough LPS, occurs during in vitro passage. Semi-rough intermediate forms are also observed. Here, the genetic basis of LPS phase conversion was investigated to obtain a more complete understanding of C. burnetii pathogenesis. Whole genome sequencing of strains producing intermediate and/or phase II LPS identified several common mutations in predicted LPS biosynthesis genes. After passage in broth culture for 30 weeks, phase I strains from different genomic groups exhibited similar phase transition kinetics and elevation of mutations in LPS biosynthesis genes. Targeted mutagenesis and genetic complementation using a new C. burnetii nutritional selection system based on lysine auxotrophy confirmed that six of the mutated genes were necessary for production of phase I LPS. Disruption of two of these genes in a C. burnetii phase I strain resulted in production of phase II LPS, suggesting inhibition of the encoded enzymes could represent a new therapeutic strategy for treatment of Q fever. Additionally, targeted mutagenesis of genes encoding LPS biosynthesis enzymes can now be used to construct new phase II strains from different genomic groups for use in pathogen-host studies at a risk group 2 level.