[Legionella Species Isolated in the Water Systems of Ships and Their Molecular Characterization]. / Gemilerin Su Sistemlerinden Izole Edilen Legionella Türleri ve Moleküler Karakterizasyonu.

Legionella species are generally found in nature and in water resources, and they are gram negative bacilli that can cause pneumonia by being transmitted from water systems to humans via aerosol or aspiration. Legionnaires' disease caused by this agent continues to be a public health problem in cruise ships. In this study, it was aimed to determine the prevalence of the colonization of Legionella species by culture method and to determine the molecular characterization of the isolated Legionella in water samples taken from the water systems of the ships docking in Mersin International Port. A total of 158 cold water samples were taken from 18 ferry and/or cargo ships docking in Mersin International Port between December 2014 and June 2015. Fifty-four of the samples were obtained from tanks, 68 from taps and 36 from shower heads. All samples were centrifuged and inoculated from the pellet onto "Buffered Coal Yeast Extract" (BCYE) (Oxoid, CM0655, UK) agar medium supplemented with iron pyrophosphate, L-cysteine and α-ketoglutarate (Oxoid, SR0110, UK). The culture plates were incubated for 10-15 days in microaerophilic environment in a desiccator at 37°C. The suspicious colonies grown in cultures were serogrouped by latex agglutination test (Oxoid, DR0800M, UK) and fluorescent antibody method (m-Tech Monoclonal Technologies, Inc., USA). For the molecular analysis of Legionella species grown in culture, DNA isolation was made from Legionella colonies and then polymerase chain reaction amplification was performed using specific primer sequences targeting the rpoB gene region of the Legionella genome. Direct DNA sequencing of rpoB gene products was performed in the "ABI PRISM 3130XL Genetic Analyzer" (Applied Biosystems, USA). The DNA sequences were typed by BLAST analysis and the determined types, and NCBI (National Center for Biotechnology Information) reference Legionella sequences were phylogenetically compared with the Neighbor-Joining comparison method by using the Mega 7 program. Legionella spp. was isolated in 18 (11.4%) of 158 samples. Of these, four (7.4%, 4/54) were detected from the tank, 11 (16.2%, 11/68) from the tap and three (8.33%, 3/36) from the shower head. After the latex agglutination test performed from the growing bacterial colonies, five (27.8%) were serogrouped as Legionella spp., four (22.2%) as Legionella pneumophila sg 5, two (11.1%, each) as L.pneumophila sg 1,L.pneumophila sg 8 and Legionella bozemanii and one (5.6%) as L.pneumophila sg 3. Two (11.1%) of the isolates grown in culture could not be serogrouped. Molecular characterization of 12 Legionella isolates could be performed. One of them was serologically serogrouped as L.bozemanii, and it was found to be 99% similar to Legionella rubrilucens when compared with NCBI Legionella sequence data in the BLAST program. One isolate that could not be differentiated by serogrouping was identified as Legionella erytra in the BLAST program after DNA sequence analysis. The remaining 10 isolates (55.6%, n= 18) were confirmed as L.pneumophilia after the comparison with reference NCBI sequences. In this study, it was determined that 11.4% of the water samples collected from the water systems of the ships docking in Mersin International Port were contaminated with Legionella species. The detected Legionella species have an important potential source of infection for the captain, ship workers and passengers travelling on the ships. In this respect, this study reveals the necessity of establishing studies to improve the risk management of Legionella in the water systems of ships.

Legionella dumoffii utilizes exogenous choline for phosphatidylcholine synthesis.

Phosphatidycholine (PC) is the major membrane-forming phospholipid in eukaryotes but it has been found in only a limited number of prokaryotes. Bacteria synthesize PC via the phospholipid N-methylation pathway (Pmt) or via the phosphatidylcholine synthase pathway (Pcs) or both. Here, we demonstrated that Legionella dumoffii has the ability to utilize exogenous choline for phosphatidylcholine (PC) synthesis when bacteria grow in the presence of choline. The Pcs seems to be a primary pathway for synthesis of this phospholipid in L. dumoffii. Structurally different PC species were distributed in the outer and inner membranes. As shown by the LC/ESI-MS analyses, PC15:0/15:0, PC16:0/15:0, and PC17:0/17:1 were identified in the outer membrane and PC14:0/16:0, PC16:0/17:1, and PC20:0/15:0 in the inner membrane. L. dumoffii pcsA gene encoding phosphatidylcholine synthase revealed the highest sequence identity to pcsA of L. bozemanae (82%) and L. longbeachae (81%) and lower identity to pcsA of L. drancourtii (78%) and L. pneumophila (71%). The level of TNF-α in THP1-differentiated cells induced by live and temperature-killed L. dumoffii cultured on a medium supplemented with choline was assessed. Live L. dumoffii bacteria cultured on the choline-supplemented medium induced TNF-α three-fold less efficiently than cells grown on the non-supplemented medium. There is an evident effect of PC modification, which impairs the macrophage inflammatory response.

Electrochemical nanoporous alumina membrane-based label-free DNA biosensor for the detection of Legionella sp.

An electrochemical nanoporous alumina membrane-based label free DNA biosensor is developed using 5'-aminated DNA probes immobilized into the nanochannels of alumina. Alumina nanoporous membrane-like structure is carved over platinum wire electrode of 76 µm diameter dimension by electrochemical anodization. The hybridization of complementary target DNA with probe DNA molecules attached inside the nanochannels influences the pore size and ionic conductivity. Electrochemical biosensing signal is derived from only redox species Fe(CN)(6)(4-) across single wire Pt electrode. The biosensors sensing mechanism relies on the monitoring of electrode's Faradaic current response toward redox species, Fe(CN)(6)(4-), which is sensitive toward the hybridization of complementary target with probe DNA immobilized into the alumina nanochannels. The biosensor demonstrates wide linear range over 7 orders of magnitude with ultrasensitive detection limit 3.1×10(-13) M for the quantification of ss 21 mer DNA sequence and selectively differentiates the complementary sequence from target sequences with single base mismatch (MM1) and triple bases mismatch (MM3) of different strain of Legionella sp. Its applicability is also challenged against real time Legionella pneumophila genomic DNA sample derived from the asymmetric PCR method.

Cluster of Legionnaires' disease associated with a public whirlpool spa, France, April-May 2010.

In May 2010, a cluster of three cases of Legionnaires' disease was identified in France. The results of the epidemiological, environmental and microbiological investigations allowed the rapid identification of a public whirlpool spa as the most probable source of contamination and the implementation of appropriate control measures. This investigation has stressed the need for good cooperation between partners and the importance of the molecular analysis of Legionella strains.

Legionella dresdenensis sp. nov., isolated from river water.

Legionella-like isolates, strains W03-356(T), W03-357 and W03-359, from three independent water samples from the river Elbe, Germany, were analysed by using a polyphasic approach. Morphological and biochemical characterization revealed that they were Gram-negative, aerobic, non-spore-forming bacilli with a cut glass colony appearance that grew only on L-cysteine-supplemented buffered charcoal yeast extract agar. Phylogenetic analysis based on sequence comparisons of the 16S rRNA, macrophage infectivity potentiator (mip), gyrase subunit A (gyrA), ribosomal polymerase B (rpoB) and RNase P (rnpB) genes confirmed that the three isolates were distinct from recognized species of the genus Legionella. Phenotypic characterization of strain W03-356(T) based on fatty acid profiles confirmed that it was closely related to Legionella rubrilucens ATCC 35304(T) and Legionella pneumophila ATCC 33152(T), but distinct from other species of the genus Legionella. Serotyping of the isolates showed that they were distinct from all recognized species of the genus Legionella. Strains W03-356(T), W03-357 and W03-359 are thus considered to represent a novel species of the genus Legionella, for which the name Legionella dresdenensis sp. nov. is proposed. The type strain is W03-356(T) (=DSM 19488(T)=NCTC 13409(T)).

Legionella gresilensis sp. nov. and Legionella beliardensis sp. nov., isolated from water in France.

Novel Legionella-like isolates, strains Montbéliard A1T and Gréoux 11 D13T, isolated from two different French water sources, were studied taxonomically and phylogenetically. Morphological and biochemical characterization revealed that they were Gram-negative, aerobic, non-spore-forming bacilli with a cut-glass appearance that grew only on L-cysteine-supplemented buffered charcoal yeast extract agar. Phenotypic characterization using fatty acid and ubiquinone profiles and SDS-PAGE analysis confirmed that they were closely related, but distinct from, other species of the genus Legionella, since serotyping could not relate them to any existing serogroup. Genotypic profiles generated by randomly amplified polymorphic DNA and 16S-23S rDNA spacer region PCR analyses were unique for each of these isolates. DNA-DNA relatedness values of strains Montbéliard A1T and Gréoux 11 D13T to each other and to other Legionella type strains were less than 25%. Phylogenetic affiliation of these organisms obtained by 16S rDNA sequence comparisons confirmed that they were distinct from any other known Legionella species. All the above results confirm that these strains constitute two novel species for which the names Legionella gresilensis sp. nov. (type strain Gréoux 11 D13T = ATCC 700509T = CIP 106631T) and Legionella beliardensis sp. nov. (type strain Montbéliard A1T = ATCC 700512T = CIP 106632T) are proposed.

Enzyme-linked immunoassay for detection of PCR-amplified DNA of legionellae in bronchoalveolar fluid.

A nonradioactive method is described that detects 10 to 100 legionellae in 1 ml of bronchoalveolar lavage fluid. DNA is purified by a proteinase K-phenol protocol or with a commercial DNA preparation kit and amplified by PCR with amplimers specific for the 16S rRNA gene of Legionella pneumophila. The upstream primer is 5' biotinylated. The amplification product is immobilized on streptavidin-coated microtiter plates. Because of the high binding capacity, no removal of nonincorporated biotin from the PCR product is required. After alkaline denaturation, the single-stranded PCR product is hybridized with a 5' digoxigenin-labeled probing oligomer. The amplification product is then detected by using peroxidase-labeled anti-digoxigenin antibodies in a luminescence or colorimetric reaction. The assay detects as few as 10 legionellae in 1-ml bronchoalveolar lavage fluid specimens. It is specific for medically relevant Legionella species, including Legionella pneumophila, L. bozemanii, and L. longbeachae. Of over 250 clinical specimens examined, 8 were positive for legionellae by both culture and the PCR assay. Six further specimens were culture negative but PCR positive for legionellae; of these, five specimens were from patients receiving high-dose erythromycin therapy for suspected or previously diagnosed legionella pneumonia. None of the remaining 240 specimens that were culture negative for legionellae yielded a positive PCR test, although a total of over 30 different bacterial species were cultured from these specimens. The PCR assay therefore appears to exhibit high sensitivity and specificity and thus could prove suitable for use in the routine microbiological diagnostic laboratory.