CrossRef 53 Lane DJ: 16S/23S rRNAsequencing Nucleic acid techni

CrossRef 53. Lane DJ: 16S/23S rRNAsequencing. Nucleic acid techniques in bacterial systematics. In Modern 17DMAG solubility dmso microbiological methods. Edited by: Stackebrandt E, Goodfellow M. Chichester, UK: J Wiley & Sons; 1991:133. 54. Amann RI, Ludwig W, Schleifer KH: Phylogenetic identification and in situ detection of individual microbial cells without cultivation. Microbiol Rev 1995,59(1):143–169.PubMed Authors’ contributions TG has participated in its design and coordination,

participated in the analysis, and drafting and revising the manuscript. MAS conceived part of the study, participated in its design and analysis, and revising the manuscript. KN conceived part of the study, participated in its design and revision of the manuscript. PB performed molecular genetic analyses/cultivations and drafting of the manuscript. LB has participated in the analysis and interpretation of data, and revising the manuscript. JA has been involved in acquisition of Selumetinib chemical structure data and revising the manuscript. MA has been involved in acquisition of data and revising the manuscript. All authors read and approved the final manuscript.”
“Background Pseudomonas aeruginosa, an

ubiquitous environmental Gram-negative microrganism, is one of most important opportunistic bacteria in hospital-acquired infections [1–3]. It is responsible for acute and chronic lung infections in artificially ventilated [4] and in cystic fibrosis patients [5], and for septicemia in immunocompromised patients, including transplant and cancer patients, as well IMP dehydrogenase as patients with severe burn wounds. Nosocomial P. aeruginosa strains are characterized by an intrinsic Evofosfamide datasheet resistance to various antimicrobial agents and common antibiotic therapies. The low permeability of the major outer membrane porins

and the presence of multiple drug efflux pumps are factors that contribute to mechanisms of drug resistance in this species [6]. This high resistance leads to several therapeutic complications and is associated with treatment failure and death. The development of a vaccine against P. aeruginosa for active and/or passive immunization is therefore necessary as another approach to therapy. Despite high numbers of patients who may develop P. aeruginosa infections and the threat of antibiotic treatment failure due to bacterial resistance, there is surprisingly no P. aeruginosa vaccine currently available on the market, although many attempts have been made in the past. A number of different vaccines and several monoclonal antibodies have been developed in the last decades for active and passive vaccination against P. aeruginosa [7]. Different antigens of P. aeruginosa, such as the outer membrane proteins (Oprs), LPS, toxins, pili and flagella, have been investigated as possible targets for the development of vaccines. Vaccination with outer membrane protein antigens has been shown to be efficacious against P.

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