DNA-DNA hybridization study of strains of Chryseobacterium, Elizabethkingia and Empedobacter and of other usually indole-producing non-fermenters of CDC groups IIc, IIe, IIh and IIi, mostly from human clinical sources, and proposals of Chryseobacterium bernardetii sp. nov., Chryseobacterium carnis sp. nov., Chryseobacterium lactis sp. nov., Chryseobacterium nakagawai sp. nov. and Chryseobacterium taklimakanense comb. nov.

The taxonomic classification of 182 phenotypically similar isolates was evaluated using DNA-DNA hybridization and 16S rRNA gene sequence analysis. These bacterial isolates were mainly derived from clinical sources; all were Gram-negative non-fermenters and most were indole-producing. Phenotypically, they resembled species from the genera Chryseobacterium, Elizabethkingia or Empedobacter or belonged to CDC groups IIc, IIe, IIh and IIi. Based on these analyses, four novel species are described: Chryseobacterium bernardetii sp. nov. (type strain NCTC 13530(T) = CCUG 60564(T) = CDC G229(T)), Chryseobacterium carnis sp. nov. (type strain NCTC 13525(T) = CCUG 60559(T) = CDC G81(T)), Chryseobacterium lactis sp. nov. (type strain NCTC 11390(T) = CCUG 60566(T) = CDC KC1864(T)) and Chryseobacterium nakagawai sp. nov. (type strain NCTC 13529(T) = CCUG 60563(T) = CDC G41(T)). The new combination Chryseobacterium taklimakanense comb. nov. (type strain NCTC 13490(T) = X-65(T) = CCTCC AB 208154(T) = NRRL B-51322(T)) is also proposed to accommodate the reclassified Planobacterium taklimakanense.

Characterization of human clinical isolates of Dietzia species previously misidentified as Rhodococcus equi.

In this study, 16 human clinical isolates of Dietzia species previously misidentified as Rhodococcus equi were evaluated using phenotypic methods, including traditional and commercial (API Coryne) biochemical tests, antimicrobial susceptibility testing, and 16S rRNA gene and gyrB gene sequencing. Positive results for both the hydrolysis of adenine and Christie-Atkins-Munch-Petersen (CAMP) reaction allowed for differentiation between the Dietzia isolates and the type strain of Rhodococcus equi; however, traditional and commercial phenotypic profiles could not be used to reliably identify Dietzia species. The analysis of 16S rRNA gene and gyrB gene sequences could discriminate all Dietzia strains from the type strain of R. equi. Most Dietzia species had distinct 16S rRNA gene and gyrB gene sequences; however, the 16S rRNA gene sequences of the type strains of D. schimae and D. cercidiphylli were identical to D. maris and D. natronolimnaea, respectively. Based on comparative sequence analysis, five clinical isolates clustered with D. maris/D. schimae and nine with D. natronolimnaea/D. cercidiphylli. The two remaining isolates were found to be most closely related to the D. cinnamea/D. papillomatosis clade. Even though molecular analyses were not sufficiently discriminative to accurately identify all Dietzia species, the method was able to reliably identify isolates that were previously misidentified by phenotypic methods to the genus level.

Aerococcus urinae: polyphasic characterization of the species.

A polyphasic characterization of Aerococcus urinae is presented. In this study the intraspecies relationships between 26 strains of varying geographical origin were examined by phenotypic tests, ribotyping and multilocus enzyme electrophoresis. The results demonstrated two main phenotypic patterns that could be distinguished in tests for hydrolysis of aesculin, and acid production from amygdalin and salicin. Strains were either negative (n=19) or positive (n=6) in these tests. One strain had a deviating pattern. Heterogeneity within the 19 pattern I strains was demonstrated especially by phenotypic tests (acid production from ribose, mannitol, sorbitol, sucrose and D-arabitol) and by multilocus enzyme electrophoresis. However, DNA sequence analysis of the 16S rRNA (n=7) and gyrB genes (n=3) from strains representing the two main patterns showed no variation in sequences among strains. Comparison of A. urinae and representatives of related taxa by 16S rDNA sequence analysis showed that the taxon is related to, but distinct from, other Aerococcus spp.

Identification of the bacterium associated with haemorrhagic septicaemia in rainbow trout as Hafnia alvei.

An unidentified bacterium responsible for epizootic haemorrhagic septicaemic disease in rainbow trout was recently described. This organism exhibited some antigenic similarity to Brucella abortus and to Yersinia ruckeri and was presumed to belong to the family Enterobacteriaceae. Further biochemical characterization and DNA relatedness studies showed that pathogenic fish strains are Hafnia alvei.

A cluster of atypical Yersinia strains with a distinctive 16S rRNA signature.

Thirty-eight bacterial isolates from raw milk samples in Queensland, Australia were identified as members of the genus Yersinia on the basis of biochemical profile, ability to hybridize with a genus-specific DNA probe, comparative 16S rDNA sequence analysis, and the presence of characteristic 16S rDNA signature nucleotides which occur in all Yersinia spp. Twenty-five of these isolates reacted with typing sera (O:22 or O:58) of Y. enterocolitica; the remainder were non-typable. None of the isolates displayed any of the phenotypic or genetic virulence-associated characteristics of Y. enterocolitica. Comparative 16S rDNA sequence analysis revealed that members of this group appear to represent a new sub-line within the genus Yersinia, most closely related to Y. frederiksenii hybridization group 2 (unnamed genomospecies 2). This findings was confirmed by DNA hybridization studies which indicated that the strains belonged to the unnamed genomospecies, Yersinia frederiksenii genomospecies 2, which is biochemically indistinguishable from Y. frederiksenii (Y. frederiksenii genomospecies 1). A 23-nucleotide 16S rDNA signature stretch which characterised these strains was identified.

Genotyping of Serratia marcescens Strains Associated with Cucurbit Yellow Vine Disease by Repetitive Elements-Based Polymerase Chain Reaction and DNA-DNA Hybridization.

ABSTRACT The bacterium that causes cucurbit yellow vine disease (CYVD) has been placed in the species Serratia marcescens based on 16S rDNA and groE sequence analysis. However, phenotypic comparison of the organism with S. marcescens strains isolated from a variety of ecological niches showed significant heterogeneity. In this study, we compared the genomic DNA of S. marcescens strains from different niches as well as type strains of other Serratia spp. through repetitive elements-based polymerase chain reaction (rep-PCR) and DNA-DNA hybridization. With the former, CYVD strains showed identical banding patterns despite the fact that they were from different cucurbit hosts, geographic locations, and years of isolation. In the phylogenetic trees generated from rep-PCR banding patterns, CYVD strains clearly were differentiated from other strains but formed a loosely related group with S. marcescens strains from other niches. The homogeneity of CYVD strains was supported further by the DNA relatedness study, in that labeled DNA from the cantaloupe isolate, C01-A, showed an average relative binding ratio (RBR) of 99%, and 0.33% divergence to other CYVD strains. Used as a representative strain of CYVD, the labeled C01-A had a RBR of 76%, and a 4.5% divergence to the S. marcescens type strain. These data confirm the previous placement of CYVD strains in S. marcescens. Our investigations, including rep-PCR, DNA-DNA hybridization, and previous phenotyping experiments, have demonstrated that CYVD-associated strains of S. marcescens cluster together in a group significantly different from other strains of the species.

Arbitrarily primed-polymerase chain reaction for identification and epidemiologic subtyping of oral isolates of Fusobacterium nucleatum.

BACKGROUND: Fusobacterium nucleatum is the most frequently isolated bacterium in periodontal disease and plays an important role in serious infections in other parts of the body. Arbitrarily primed-polymerase chain reaction (AP-PCR) was used to construct primers for specific identification and subtyping of F. nucleatum. Subtypes may differ in virulence and, hence, are important as periodontal pathogens. Subtypes also may differ in antibiotic susceptibility; therefore, knowing the subtypes may influence choice of treatment. METHODS: We analyzed 70 DNA samples of F. nucleatum isolated from patients with periodontal disease (PD) (N = 32) or AIDS-related PD (N = 8) and from healthy carriers (N = 30). From 90 AP-PCR primers screened, five amplification products were selected, cloned in pCR II vector, and sequenced. These sequences were used to design new pairs of specific primers. Sequences were compared to GenBank entries with BLAST and showed no significant matches. RESULTS: Three primer pairs produced bands of approximately 1 Kb (primer 5059S) or 0.5 Kb (primers FN5047 or M1211) with all F. nucleatum DNAs tested. PCR amplification using primer pair M8171 produced a 1 Kb band with isolates from 7 (22%) PD and 5 (63%) PD-AIDS patients and 9 (30%) healthy controls. Using the same primer pair, 2 other bands of approximately 0.5 Kb and 0.4 Kb were observed with DNA from isolates from 2 (6%) PD and all PD-AIDS patients, but were not observed with DNA samples from healthy controls (P<0.0001). All the primer pairs produced no or different amplicon profiles with DNA samples from bacterial species other than F. nucleatum. CONCLUSIONS: Our results suggest that PCR primer pairs 5059S, FN5047 or M1211 can be used to specifically identify F. nucleatum isolates and distinguish them from other bacteria. The primer pair M8171 could also be used to differentiate F. nucleatum isolated from periodontal patients or healthy individuals. These specific primers can be used in PCR analysis for specific identification of F. nucleatum and to distinguish it from other bacteria associated with human periodontitis. These approaches appear promising in facilitating laboratory identification, molecular subtyping, and taxonomy of putative periodontopathogens.

Reclassification of Leptospira parva Hovind-Hougen et al. 1982 as Turneriella parva gen. nov., comb. nov.

Analysis of the G+C content, DNA-DNA relatedness to other leptospires and 16S rRNA gene sequence of Leptospira parva showed that this species was not related to other Leptospira species. On the basis of these data, it is proposed that Leptospira parva should be transferred to the genus Turneriella as Turneriella parva gen. nov., comb. nov., with strain H(T) (=NCTC 11395(T)=ATCC BAA-1111(T)) as the type strain.

Isolation of Serratia fonticola from birds.

Eight hundred and sixty-seven strains of gram-negative rods obtained from fecal specimens of 90 wild European birds were isolated on selective media. Eighteen of these were identified as Serratia fonticola both biochemically and by DNA hybridization. The biochemical characteristics of the new strains are compared with published results.

DNA relatedness of Leptospira strains isolated from beef cattle in Zimbabwe.

The DNA relatedness of 17 Leptospira strains isolated from beef cattle in Zimbabwe was determined using the hydroxyapatite method. Similarly to previously speciated African strains, all Zimbabwe isolates belonged to either Leptospira borgpetersenii or Leptospira kirschneri. All serovars within serogroups Pyrogenes (kwale, mombe and a strain closely related to serovar nigeria), Hebdomadis (marondera and mhou), Tarassovi (ngavi) and Sejroe (balcanica and hardjo) were L. borgpetersenii. L. kirschneri contained all strains in serovars of serogroups Icterohaemorrhagiae (zimbabwe), Australis (fugis), Bataviae (paidjan) and Pomona (a strain closely related to mozdok). The species designations of the Zimbabwe fugis and paidjan strains were different from those of the reference strains of these two serovars, both of which belong to Leptospira interrogans.

Deoxyribonucleic acid relatedness among species of Erwinia and between Erwinia species and other enterobacteria.

Relatedness in species of Erwinia was assessed by determining the extent of reassociation in heterologous deoxyribonucleic acid preparations. Thermal elution chromatography on hydroxyapatite was used to separate reassociated nucleotide sequences from nonreassociated sequences and to determine the thermal stability of related nucleotide sequences. An apparent 15% core of relatedness is present between fire blight, soft-rot, and "atypical" Erwinia species. All Erwinia species showed low to moderate reaction with representative enteric bacteria.

Classification of the Legionnaires' disease bacterium: Legionella pneumophila, genus novum, species nova, of the family Legionellaceae, familia nova.

Deoxyribonucleic acid (DNA) relatedness was used to classify strains of the Legionnaires' disease (LD) bacterium. These DNA comparisons showed that all strains of the LD bacterium were members of the same species. Included were strains isolated from the environment and strains with three different O-antigens. The DNA from the LD bacterium was not significantly related to DNA from any other group of bacteria that was tested. Biochemical data, growth characteristics, and guanine-plus-cytosine ratios were used to rule out the possibility that the LD bacterium was significantly related to members of genera whose DNA was not tested. In view of these data we propose that the LD bacterium be named Legionella pneumophila species nova, the type species of Legionella, genus novum. The type strain of L. pneumophila is Philadelphia 1.

16S rRNA sequences of Bartonella bacilliformis and cat scratch disease bacillus reveal phylogenetic relationships with the alpha-2 subgroup of the class Proteobacteria.

The primary structures of 16S rRNAs of Bartonella bacilliformis, an isolate of the cat scratch disease (CSD) bacillus, and a strain phenotypically similar to the CSD bacillus were determined by reverse transcriptase sequencing. These microorganisms were found to be members of the alpha-2 subgroup of the class Proteobacteria. The sequence from B. bacilliformis was most closely related to the rRNA of Rochalimaea quintana (91.7% homology), the etiologic agent of trench fever. The sequence from the isolate of the CSD bacillus showed the greatest homology with Brucella abortus (89.7%) and, when compared with oligonucleotide catalog data, formed a cluster with Rhodopseudomonas palustris, Pseudomonas carboxidovorans, Nitrobacter species, and Bradyrhizobium species. The 16S rRNA sequence was also determined for the Cleveland Clinic isolate, which was previously shown to be phenotypically similar to and approximately 30% related, by DNA hybridization, to the CSD bacillus. The Cleveland Clinic isolate was isolated from a patient not diagnosed with CSD. The rRNAs from these bacteria exhibited 98.2% homology, confirming that this isolate is a second species in the same genus as the CSD bacillus. Our data suggest that neither B. bacilliformis nor the CSD bacillus is the etiologic agent of bacillary epithelioid angiomatosis.

Phenotypic and genotypic characterization of Vibrio viscosus sp. nov. and Vibrio wodanis sp. nov. isolated from Atlantic salmon (Salmo salar) with 'winter ulcer'.

Two groups of Vibrio strains isolated from Atlantic salmon with 'winter ulcer' were characterized phenotypically and genotypically. The data obtained indicated that each of the two groups represented a new species in the genus Vibrio. The names Vibrio viscosus sp. nov. [type strain NVI 88/478T (= NCIMB 13584T)] and Vibrio wodanis sp. nov. [type strain NVI 88/441T (= NCIMB 13582T)] are proposed for the new species. V. viscosus strains exhibited a similar total DNA RFLP pattern and a similar plasmid DNA profile. DNA relatedness (hydroxyapatite method) of the V. viscosus type strain to nine other V. viscosus strains was 81-93% at 60 degrees C. Divergence within related sequences was 0.0-1.5% and relatedness at 75 degrees C was 74-100%. V. wodanis strains exhibited marked heterogeneity on the basis of RFLP analysis and plasmid profiles. DNA relatedness of the V. wodanis type strain to 10 other V. wodanis strains was 66-94% at 60 degrees C. Divergence within related sequences was 0.0-1.5% and relatedness at 75 degrees C was 55-97%. Relatedness between V. viscosus and V. wodanis type strains was approximately 20%. Among other Vibrio species, the closest relative of V. viscosus was Vibrio marinus (ATCC 15381T) (43% relatedness at 60 degrees C) and that of V. wodanis was Vibrio logei (ATCC 15382) (57% relatedness at 60 degrees C). These same pairs were the closest phenotypic relatives. DNA sequence analysis of the 16S rRNA gene of V. viscosus indicated an intimate relationship to V. marinus. A total evaluation of the results, however, supports V. viscosus to be a separate species in the genus Vibrio. The analysis of the sequence of the 16S rRNA gene of V. wodanis supports that V. logei (ATCC 15382) was the most related species. Ability to degrade casein, oxidative production of acid from trehalose and production of lysine decarboxylase are important biochemical tests that will differentiate between V. viscosus, V. wodanis, V. marinus (ATCC 15381T) and V. logei (ATCC 15382).

Unusual groups of Morganella ("Proteus") morganii isolated from clinical specimens: lysine-positive and ornithine-negative biogroups.

Morganella ("Proteus") morganii is the only species in the recently proposed genus Morganella, but we suspect there are yet undescribed species in the genus. Two candidates for new species were recently investigated. Nineteen strains isolated from clinical specimens resembled M. morganii but were lysine positive and nonmotile and fermented glycerol within 24 h. Typical M. morganii are lysine negative and motile and ferment glycerol slowly or not at all. The three-test variance from typical M. morganii suggested that this new group might be a new Morganella species; however, strains of the group were closely related to typical M. morganii by deoxyribonucleic acid (DNA)-DNA hybridization. A second group of 14 strains isolated from clinical specimens was ornithine negative but was otherwise very similar to M. morganii. This group was also closely related to M. morganii by DNA hybridization. Both sets of strains clearly belong in the species Morganella morganii as distinct biogroups; they are not separate species as originally suspected. Initially both biogroups posed a problem in identification until their true relationship to M. morganii was determined.

Enterobacter asburiae sp. nov., a new species found in clinical specimens, and reassignment of Erwinia dissolvens and Erwinia nimipressuralis to the genus Enterobacter as Enterobacter dissolvens comb. nov. and Enterobacter nimipressuralis comb. nov.

Enterobacter asburiae sp. nov. is a new species that was formerly referred to as Enteric Group 17 and that consists of 71 strains, 70 of which were isolated from humans. Enterobacter asburiae sp. nov. strains gave positive reactions in tests for methyl red, citrate utilization (Simmons and Christensen's), urea hydrolysis, L-ornithine decarboxylase, growth in KCN, acid and gas production from D-glucose, and acid production from L-arabinose, cellobiose, glycerol (negative in 1 to 2 days, positive in 3 to 7 days), lactose, D-mannitol, alpha-methyl-D-glucoside, salicin, D-sorbitol, sucrose, trehalose, and D-xylose. They gave negative reactions in the Voges-Proskauer test and in tests for indole, H2S production, phenylalanine, L-lysine decarboxylase, motility, gelatin, utilization of malonate, lipase, DNase, tyrosine clearing, acid production from adonitol, D-arabitol, dulcitol, erythritol, i(myo)-inositol, melibiose, and L-rhamnose. They gave variable reactions in tests for L-arginine dihydrolase (25% positive after 2 days) and acid production from raffinose (69% positive after 2 days). Thirty-four Enterobacter asburiae sp. nov. strains were tested for DNA relatedness by the hydroxyapatite method with 32PO4-labeled DNA from the designated type strain (1497-78, ATCC 35953). The strains were 69 to 100% related in 60 degrees C reactions and 63 to 100% related in 75 degrees C reactions. Divergence within related sequences was 0 to 2.5%. Relatedness of Enterobacter asburiae sp. nov. to 84 strains of members of the Enterobacteriaceae was 5 to 63%, with closest relatedness to strains of Enterobacter cloacae, Erwinia dissolvens, Enterobacter taylorae, Enterobacter agglomerans, Erwinia nimipressuralis, and Enterobacter gergoviae. All strains tested were susceptible to gentamicin and sulfdiazine, and most were susceptible to chloramphenicol, colistin, kanamycin, nalidixic acid, carbenicillin and streptomycin. All strains were resistant to ampicillan, cephalothin, and penicillin, and most were resistant or moderately resistant to tetracycline. Enterobacter asburiae sp. nov strains were isolated from a variety of human sources, most prevalent of which were urine (16 strains), respiratory sources (15 strains), stools (12 strains), wounds (11 strains), and blood (7 strains). The clinical significance of Enterobacter aburiae is not known. As a result of this and previous studies, proposals are made to transfer Erwinia dissolvens and Erwinia nimipressuralis to the genus Enterobacter as Enterobacter dissolvens comb. nov. and Enterobacter nimipressuralis comb. nov., respectively.

"Erwinia nulandii" is a subjective synonym of Erwinia persicinus.

The organism named "Erwinia nulandii" was isolated in 1979 from bean seeds and was described in 1981, but the name was never validated. The results of biochemical tests and membrane protein profile and DNA relatedness studies indicated that this name is synonymous with Erwinia persicinus, a validly published name for a species previously isolated from, but not shown to be pathogenic for, tomatoes, bananas, and cucumbers. Pathogenicity tests revealed that all E. persicinus strains, including an "E. nulandii" strain, were pathogenic for bean pods and seeds.

DNA relatedness, phenotypic characteristics, and antimicrobial susceptibilities of Globicatella sanguinis strains.

DNA-DNA reassociation was performed on 15 strains of Globicatella sanguinis to compare their taxonomic status with phenotypic characterization. All 15 strains selected for DNA-DNA reassociation readily met the criteria for species relatedness. The relative binding ratio was 81% or greater at the optimal temperature and 76% or greater at the stringent temperature, and the divergence was less than 3% for all strains hybridized with the type strain. These strains included nine strains from the Centers for Disease Control Streptococcus Laboratory culture collection that were previously included in comparative 16S rRNA gene sequencing studies as well as six additional phenotypically variant isolates. DNA-DNA relatedness was less than 18% at the optimal reassociation temperature to Aerococcus viridans, Enterococcus avium, and Streptococcus uberis, which are phenotypically similar to G. sanguinis. This study confirms these Globicatella strains were previously misidentified as S. uberis or S. uberis-like strains based on biochemical characteristics. The biochemical data from 28 strains was compiled to further define the phenotypic criteria for identification of this species. A revised description of the species should be variable reaction for pyrrolidonylarylamidase production (75% positive), positive reaction for the bile esculin test (100%), growth at 45 degrees C (96%), variable reaction for acid production from arabinose (45% positive), and negative starch hydrolysis (0% positive). We also evaluated four rapid identification systems, the Biomerieux rapid ID32 STREP (ID32), the Crystal rapid gram-positive identification (Cry4), the BBL Crystal gram-positive identification (Cry24), and the Remel IDS RapID STR (IDS) systems for their ability to identify these strains.

Polynucleotide sequence relatedness among three groups of pathogenic Escherichia coli strains.

Escherichia coli strains that cause dysentery-like disease, parenteral infection, and infantile diarrhea form specific groups based on mobility of O and K antigens in immunoelectrophoresis. Members from each of these groups were assayed for gross nucleotide sequence relatedness. The method used was interspecific deoxyribonucleic acid (DNA) reassociation reactions carried out free in solution. Reassociated DNA was separated from unreacted DNA by passage through hydroxyapatite. DNA relatedness between these groups was approximately 80%. The groups containing those strains causing parenteral infection and those responsible for dysentery-like disease showed preferentially high intragroup DNA relatedness. The group containing strains responsible for infantile diarrhea did not show preferentially high intragroup DNA relatedness with the reference strain employed. These strains, however, did exhibit preferentially high DNA relatedness to a second reference strain.