A second serogroup of Legionella erythra serologically indistinguishable from Legionella rubrilucens.

Twenty-two red-autofluorescent Legionella strains were identified serologically as either Legionella rubrilucens or L. erythra. A rRNA probe was used for restriction fragment length polymorphism (RFLP) analysis of the strains and the patterns generated were used as an additional method of identifying the strains to species level. In two instances strains which were identified as L. rubrilucens by serology appeared to belong to the species L. erythra by RFLP analysis. This apparent contradiction was resolved by measurements of DNA/DNA homology which confirmed the existence of a second serogroup of L. erythra serologically indistinguishable from L. rubrilucens.     

Problems associated with identification of Legionella species from the environment and isolation of six possible new species

Following investigation of an outbreak of legionellosis in South Australia, numerous Legionella-like organisms were isolated from water samples. Because of the limited number of commercially available direct fluorescent-antibody reagents and the cross-reactions found with some reagents, non-pneumophila legionellae proved to be difficult to identify and these isolates were stored at -70 degrees C for later study. Latex agglutination reagents for Legionella pneumophila and Legionella anisa developed by the Institute of Medical and Veterinary Science, Adelaide, Australia, were found to be useful as rapid screening aids. Autofluorescence was useful for placing isolates into broad groups. Cellular fatty acid analysis, ubiquinone analysis, and DNA hybridization techniques were necessary to provide definitive identification. The species which were isolated most frequently were L. pneumophila, followed by L. anisa, Legionella jamestowniensis, Legionella quinlivanii, Legionella rubrilucens, Legionella spiritensis, and a single isolate each of Legionella erythra, Legionella jordanis, Legionella birminghamensis, and Legionella cincinnatiensis. In addition, 10 isolates were found by DNA hybridization studies to be unrelated to any of the 26 currently known species, representing what we believe to be 6 possible new species.     

Problems associated with identification of Legionella species from the environment and isolation of six possible new species.

Following investigation of an outbreak of legionellosis in South Australia, numerous Legionella-like organisms were isolated from water samples. Because of the limited number of commercially available direct fluorescent-antibody reagents and the cross-reactions found with some reagents, non-pneumophila legionellae proved to be difficult to identify and these isolates were stored at -70 degrees C for later study. Latex agglutination reagents for Legionella pneumophila and Legionella anisa developed by the Institute of Medical and Veterinary Science, Adelaide, Australia, were found to be useful as rapid screening aids. Autofluorescence was useful for placing isolates into broad groups. Cellular fatty acid analysis, ubiquinone analysis, and DNA hybridization techniques were necessary to provide definitive identification. The species which were isolated most frequently were L. pneumophila, followed by L. anisa, Legionella jamestowniensis, Legionella quinlivanii, Legionella rubrilucens, Legionella spiritensis, and a single isolate each of Legionella erythra, Legionella jordanis, Legionella birminghamensis, and Legionella cincinnatiensis. In addition, 10 isolates were found by DNA hybridization studies to be unrelated to any of the 26 currently known species, representing what we believe to be 6 possible new species.     

Identification of species of the genus Legionella using a cloned rRNA gene from Legionella pneumophila

A cloned EcoRI fragment from Legionella pneumophila, which includes 16S and 23S rRNA genes, was used to identify bacteria belonging to the genus Legionella by hybridization to a series of species specific restriction fragments. Examination of the type strains of 28 species of legionellae gave different band patterns in every case. When further isolates of these species were tested the patterns obtained were usually either identical, or very similar, to those of the respective type strains. Thirty-one coded isolates were examined and of these 29 were allocated to the correct species. The remaining strains (a non-Legionella and a L. pneumophila) could not be identified using this technique. The rRNA gene probe method should be of great value in the identification of legionellae, particularly for those species which are at present very difficult to distinguish serologically.     

Serological diversity within the species Legionella spiritensis

A strain of Legionella isolated from the environment which could not initially be identified was shown by restriction fragment length polymorphisms to be a Legionella spiritensis. This was confirmed by DNA homology studies, cell wall fatty acid composition and isoprenoid quinone analysis. This strain, which is only the second reported representative of the species, was shown to be serologically distinct from the type strain of L. spiritensis and all other serogroups of Legionella.     

Serological diversity within the species Legionella spiritensis

A strain of Legionella isolated from the environment which could not initially be identified was shown by restriction fragment length polymorphisms to be a Legionella spiritensis. This was confirmed by DNA homology studies, cell wall fatty acid composition and isoprenoid quinone analysis. This strain, which is only the second reported representative of the species, was shown to be serologically distinct from the type strain of L. spiritensis and all other serogroups of Legionella.     

Legionella oakridgensis: unusual new species isolated from cooling tower water.

We describe a new species of Legionella represented by 10 strains isolated from industrial cooling towers. Legionella oakridgensis differed genetically from the other seven species of Legionella in DNA hybridization studies and differed serologically in direct fluorescent-antibody tests. The new species, unlike all other species except L. jordanis, did not require added L-cysteine for growth in serial transfer on charcoal-yeast extract agar. L. oakridgensis, as well as three other species tested, required L-cysteine for primary isolation from animal tissues. L. oakridgensis was the only species of Legionella that failed to produce alkaline phosphatase at pH 8.5. In all other respects, it resembled other species of Legionella, including having a high content of branched-chain cellular fatty acids and being pathogenic for guinea pigs. These bacteria have not yet been associated with human disease, but they are potential causes of legionellosis.     

High-performance liquid chromatographic analysis of ubiquinones from new Legionella species

Abstract The ubiquinone composition of Legionella feeleii, L. oakridgensis, L. rubrilucens, L. sainthelensi, L. wadsworthii and some environmental legionella isolates was investigated by high performance liquid chromatography. The results of the present study indicate ubiquinones are valuable criteria for the rapid identification of Legionella species and the recognition of new taxa.     

Specific DNA probe for detecting Legionella pneumophila

A fragment of the gene for cytolysin has been cloned. The product of the gene has been earlier identified as an immunoserological marker of Legionella pneumophila. Clones were selected by immunodetection of cytolysin gene product expression. An EcoRI 3.8 kb fragment of the genomic DNA from Legionella pneumophila strain Philadelphia-1 was used as a DNA probe that hybridized with the bacterial colonies of 20 Legionella pneumophila strains but not with the colonies of 10 other Legionella species or 8 other bacterial genera. The cloned fragment has been shown to be unique for Legionella pneumophila. The region of homology is suggested to be longer than a possible dimension of the cytolysin gene.     

Genomic heterogenicity amongst phenotypically similar Legionella micdadei strains

Abstract Nine unrelated Legionella micdadei strains isolated from clinical and environmental samples have been characterized biochemically, serologically using polyclonal and monoclonal antibodies and by macrorestriction analyses using pulsed-field gel electrophoresis. All strains were positive in the Bromocresol purple spot test and grew as blue colonies on dye-containing media. They were positive for catalase, weakly positive for oxidase, and negative for sodium-hippurate hydrolysis, β-lactamase and gelatinase. None of the strains showed autofluorescence under long-wave ultraviolet light. A panel of six monoclonal antibodies raised against the ATCC strain TATLOCK revealed no significant differences in the surface antigen composition of the L. micdadei strains. None of these monoclonal antibodies reacted with L. maceachernii and L. longbeachae serogroup 2, the only species that cross-react with polyclonal antisera. Each of the nine L. micdadei strains showed individual restriction patterns of the genomic DNA when using both Sfi I and Not I restriction enzymes in the pulsed-field gel electrophoresis. Macrorestriction analysis is a valuable tool for studies on the molecular epidemiology of L. micdadei .     

Genetic relatedness of Legionella longbeachae isolates from human and environmental sources in Australia.

The genetic relatedness of Legionella longbeachae isolated in Australia since 1987 was investigated by restriction fragment length polymorphism (RFLP) analysis and allozyme electrophoresis. Three radiolabeled probes were used in Southern hybridizations for the RFLP studies. They were Escherichia coli 16S and 23S rRNA and cloned fragments of L. longbeachae selected empirically from genomal banks in lambda and a cosmid. The legionellae included in the study comprised 11 Legionella longbeachae serogroup 1 organisms isolated from humans, 28 L. longbeachae serogroup 1 isolates from environmental sources, and 3 L. longbeachae serogroup 2 environmental isolates. These were compared with the American Type Culture Collection reference strains of both serogroups and some other related Legionella species. Results of allozyme and RFLP analysis showed that all the isolates from humans and all but three of the environmental L. longbeachae serogroup 1 isolates were closely related. They were also closely related to L. longbeachae serogroup 1 ATCC 33462. There was wider variation among the three L. longbeachae serogroup 2 environmental isolates. One of these was closely related to L. longbeachae serogroup 2 ATCC 33484. RFLP studies with the rRNA probe provided the most discrimination among isolates but did not distinguish between the two serogroups.     

Legionella anisa: a new species of Legionella isolated from potable waters and a cooling tower

Between March 1980 and June 1981, five strains of Legionella-like organisms were isolated from water. Four were recovered from potable water collected from hospitals in Chicago, Ill., and Los Angeles, Calif., during outbreaks of nosocomial legionellosis. The fifth strain was isolated from water collected from an industrial cooling tower in Jamestown, N.Y. The strains exhibited biochemical reactions typical of Legionella species and were gram-negative motile rods which grew on buffered charcoal-yeast extract agar but not on blood agar, required cysteine, and were catalase positive, urease negative, nitrate negative, hippurate negative, and nonfermentative. All strains were positive for oxidase and beta-lactamase and produced a brown, diffusible pigment. Of the five strains, four exhibited blue-white autofluorescence under long-wavelength UV light. The fatty-acid composition and ubiquinone content of these strains were consistent with those of other Legionella species. Direct fluorescent-antibody examination of the five strains with conjugates to previously described Legionella species demonstrated no cross-reactions except with the conjugates to L. longbeachae serogroup 2 and L. bozemanii serogroup 2. Four strains gave a 4+ reaction to the L. longbeachae serogroup 2 conjugate and the fifth strain gave a 1+ reaction. Each of the five strains gave a 4+ reaction with the conjugate to L. bozemanii serogroup 2. DNAs from the five strains were highly related (84 to 99%) and showed 5 to 57% relatedness to other Legionella species. These strains constitute a new species in the genus Legionella, and the name Legionella anisa sp. nov. is proposed. The type strain of L. anisa is WA-316-C3 (ATCC 35292).     

Legionella anisa: a new species of Legionella isolated from potable waters and a cooling tower.

Between March 1980 and June 1981, five strains of Legionella-like organisms were isolated from water. Four were recovered from potable water collected from hospitals in Chicago, Ill., and Los Angeles, Calif., during outbreaks of nosocomial legionellosis. The fifth strain was isolated from water collected from an industrial cooling tower in Jamestown, N.Y. The strains exhibited biochemical reactions typical of Legionella species and were gram-negative motile rods which grew on buffered charcoal-yeast extract agar but not on blood agar, required cysteine, and were catalase positive, urease negative, nitrate negative, hippurate negative, and nonfermentative. All strains were positive for oxidase and beta-lactamase and produced a brown, diffusible pigment. Of the five strains, four exhibited blue-white autofluorescence under long-wavelength UV light. The fatty-acid composition and ubiquinone content of these strains were consistent with those of other Legionella species. Direct fluorescent-antibody examination of the five strains with conjugates to previously described Legionella species demonstrated no cross-reactions except with the conjugates to L. longbeachae serogroup 2 and L. bozemanii serogroup 2. Four strains gave a 4+ reaction to the L. longbeachae serogroup 2 conjugate and the fifth strain gave a 1+ reaction. Each of the five strains gave a 4+ reaction with the conjugate to L. bozemanii serogroup 2. DNAs from the five strains were highly related (84 to 99%) and showed 5 to 57% relatedness to other Legionella species. These strains constitute a new species in the genus Legionella, and the name Legionella anisa sp. nov. is proposed. The type strain of L. anisa is WA-316-C3 (ATCC 35292).     

Detection and identification of Legionella pneumophila by PCR-restriction fragment length polymorphism analysis of the RNA polymerase gene (rpoB)

The partial RNA polymerase beta-subunit coding gene (rpoB) sequences of 38 Legionella species (59 reference strains) were used to select both Legionella genus-specific and Legionella pneumophila species-specific primers to amplify the 347-bp and 217-bp DNAs, respectively. Enzyme restriction sites for PCR-restriction fragment length polymorphism (PCR-RFLP) analysis were also generated by a computer program. Thirty-eight Legionella species were well differentiated by the identification scheme for Legionella genus-specific PCR-RFLP using HaeIII, AluI, CfoI, PstI, and MaeII. The most common and important pathogenic species, L. pneumophila, was differentiated into two subspecies (L. pneumophila subsp. pneumophila and L. pneumophila subsp. fraseri) by both Legionella genus-specific PCR-RFLP and L. pneumophila species-specific PCR-RFLP using BamHI. Eighty-two Korean culture isolates could also be easily identified by both PCR-RFLP methods as 68 strains of L. pneumophila subsp. pneumophila, 11 strains of L. pneumophila subsp. fraseri, and three novel strains that were separately confirmed by 16S rDNA and rpoB sequence analysis. These results suggest that the rpoB PCR-RFLP for Legionella is a simple and convenient method, not only for specific detection, but also for the rapid identification of Legionella species.     

Use of the dnaJ gene for the detection and identification of all Legionella pneumophila serogroups and description of the primers used to detect 16S rDNA gene sequences of major members of the genus Legionella

We sequenced about 930 bp of the dnaJ gene from 15 Legionella pneumophila serogroups and some other members of the genus Legionella. As L. pneumophila 16S rDNA sequences could not discriminate between all subspecies and serogroups, we assessed the use of dnaJ gene sequences to differentiate between Legionella subspecies as well as between L. pneumophila serogroups. A phylogenetic analysis revealed that dnaJ gene sequences were more variable between the L. pneumophila serogroups than mip gene and 16S rDNA sequences. By studying 61 strains from 41 species of the genus Legionella, as well as other genera, we established a PCR method that could amplify 285 bp of dnaJ gene from all L. pneumophila serogroups. This primer set was more sensitive than mip gene primers and was able to detect 0.25 ng of purified DNA. We also describe the 16S rDNA primers that were used to detect most Legionella genus members.     

Second serogroup of Legionella quinlivanii isolated from two unrelated sources in the United Kingdom

R.J. BIRTLES, N. DOSHI, N.A. SAUNDERS AND T.G. HARRISON. 1991. A series of strains, presumptively identified as legionellas on the basis of their nutritional requirements and biochemical reactivity, were isolated from two unrelated environmental sources in the UK. Representatives of each of these series had a restriction endonuclease digest pattern indistinguishable from that of the Legionella quinlivanii type strain (1442-AUS-E) and the identity of these strains was confirmed by DNA homology studies. Serological examination of the two strains showed that they were distinct from the type strain 1442-AUS-E but indistinguishable from each other. A second serogroup, L. quinlivanii serogroup 2 (type strain LC870; NCTC 12434), is proposed to accommodate these strains.     

Evaluation of the Duopath Legionella lateral flow assay for identification of Legionella pneumophila and Legionella species culture isolates

Duopath Legionella (Merck KGaA, Darmstadt, Germany) is a new immunochromatographic assay for the simultaneous identification of cultured L. pneumophila and Legionella species other than L. pneumophila. In tests of 89 L. pneumophila strains and 87 Legionella strains other than L. pneumophila representing 41 different species, Duopath and a widely used latex agglutination assay detected L. pneumophila with 100% and 98% accuracy, respectively, whereas the percentages differed significantly for other Legionella spp. (93% versus 37% [P < 0.001]). Since many countries' regulations require the identification of Legionella spp. in water and environmental samples, the use of Duopath Legionella to comply with those regulations could contribute to significantly fewer false-negative results.     

Biofilm formation by Legionella spp. in experiment

Ability of biofilm formation was studied in 28 strains belonging to 12 species of Legionella. Optimal conditions for formation of biofilms were ascertained using reference strain Legionella pneumophila Philadelphia 1. Comparative assessment of the ability of Legionella spp. to form biofilms was performed by cultivation in proteosopepton broth (for 96 hours) and in water (for up to 2 weeks). Highest rates of biofilm formation were observed for strains of L. pneumophila and L. longbeachae. Between L. pneumophila strains the most prominent ability to form biofilms was observed in newly isolated strains BLR-05 and TOTAL 1. Opportunity to use different ability of Legionella species to biofilm formation as a epidemiologically significant marker and for modeling of biofilms of Legionella in association with other microorganisms was discussed.     

Distribution of Legionella longbeachae serogroup 1 and other legionellae in potting soils in Australia

Legionella longbeachae serogroup 1 and other Legionella spp. were isolated from 73% of 45 potting soils made in Australia by 13 manufacturers but were not detected in 19 potting soils made in Greece, Switzerland, and the United Kingdom examined between March 1989 and May 1990. Several Legionella species were isolated from a small number of samples of uncomposted pine sawdusts, but it is not known whether sawdust was the source of some of the legionellae found in potting soils. Legionella spp. persisted for periods ranging from 3 to 10 months in a potting soil held at temperatures between -20 and 35 degrees C. Isolates of L. longbeachae serogroup 1 from soil did not grow at 43 degrees C, a temperature which was also lethal for this species in soil. Most Legionella spp. isolated from potting and natural soils belonged to one distinct group according to analysis of ubiquinones and were serologically related to several known species in this group. A small number of potting soils contained L. pneumophila and L. micdadei.     

Species-specific detection of Legionella using polymerase chain reaction and reverse dot-blotting

Abstract Legionella pneumophila and some other Legionella species are capable of causing Legionnaire's disease, a potentially fatal pneumonia. The identification of legionellae by standard laboratory techniques such as culture is difficult and time-consuming. In the present work, the DNA sequence of the 23S-5S spacer region was determined for 43 Legionella isolates, and the sequence information was used to develop a species-specific detection system using PCR and reverse dot-blotting which employs just one PCR amplicon to perform genus- and species-specific detection. L. pneumophila serogroups 1–16 as well as 21 non- pneumophila isolates could be identified and differentiated at the species level using this system.