Identification of strains assigned to the genus Gluconobacter Asai 1935 based on the sequence and the restriction analyses of the 16S-23S rDNA internal transcribed spacer regions

Thirteen reference strains, including the type strains of the type species of the genus Gluconobacter, Gluconobacter oxydans (NBRC 14819T), Gluconobacter cerinus (NBRC 3267T), and Gluconobacter frateurii (IFO 3264T) were examined for their species identification based on the sequence and the restriction analyses of the 16S-23S rDNA internal transcribed spacer (ITS) regions. A phylogenetic tree constructed by the neighbor-joining method represented three clusters corresponding respectively to the three species, G. oxydans, G. cerinus, and G. frateurii. The type strain of Gluconobacter asaii (NBRC 3276T), which is a junior subjective synonym of G. cerinus, was included completely in the G. cerinus cluster. Several restriction endonucleases discriminating the three species from one another were selected by computer analyses: Bsp1286I, MboII, SapI, Bpu10I, EarI, BsiHKAI, and FatI. On digestion of the PCR products with restriction endonucleases Bsp1286I and MboII, all the restriction patterns coincided with those of the type strains of the three species except for strain NBRC 3251. This strain gave a different pattern from the type strain of G. frateurii, when digested with MboII. However, strain 3251 was included phylogenetically in the G. frateurii cluster. All the reference strains were thus identified at the species level by the sequence and the restriction analyses of the 16S-23S rDNA ITS regions.     

Heterogeneity of strains assigned to Gluconobacter frateurii Mason and Claus 1989 based on restriction analysis of 16S-23S rDNA internal transcribed spacer regions

Twenty-three strains, which were assigned to Gluconobacter frateurii and maintained at Culture Collection NBRC, were re-identified at the species level on the basis of restriction analysis of 16S-23S rDNA ITS regions by digestion with six restriction endonucleases: Bsp1286I, MboII, AvaII, TaqI, BsoBI, and BstNI. The strains examined were divided into six groups, Group III-1, Group III-2, Group III-3, Group III-4, Group III-5, and Group IV. Group III-1 and Group III-4 respectively were divided into two subgroups, Subgroup III-1a, Subgroup III-1b and Subgroup III-4a, Subgroup III-4b. Gluconobacter frateurii NBRC 3264(T) was included in Group III-2, along with strains NBRC 3265 and NBRC 3270, and G. thailandicus BCC 14116(T) was included in Group III-3, along with strains NBRC 3254, NBRC 3256, NBRC 3258, NBRC 3255, and NBRC 3257. These groupings were supported by a phylogenetic tree based on 16S-23S rDNA ITS sequences. Strains of group III-2 and Group IV were unequivocally re-identified as G. frateurii, but strains of Group III-3, Group III-4, and Group III-5 were not necessarily re-identified as G. frateurii. The results obtained indicate that the 23 strains have a taxonomically heterogeneous nature, and they are referred to as the G. frateurii complex.     

Gluconobacter thailandicus sp. nov., an acetic acid bacterium in the alpha-Proteobacteria

Four strains of acetic acid bacteria were isolated from flowers collected in Thailand. In phylogenetic trees based on 16S rRNA gene sequences and 16S-23S rDNA internal transcribed spacer (ITS) region sequences, the four isolates were located in the lineage of the genus Gluconobacter and constituted a separate cluster from the known Gluconobacter species, Gluconobacter oxydans, Gluconobacter cerinus, and Gluconobacter frateurii. In addition, the isolates were distinguished from the known species by restriction analysis of 16S-23S rDNA ITS region PCR products using three restriction endonucleases Bsp1286I, MboII, and AvaII. The DNA base composition of the isolates ranged from 55.3-56.3 mol% G+C. The four isolates constituted a taxon separate from G. oxydans, G. cerinus, and G. frateurii on the basis of DNA-DNA similarities. Morphologically, physiologically, and biochemically, the four isolates were very similar to the type strains of G. oxydans, G. cerinus, and G. frateurii; however, the isolates were discriminated in their growth at 37 degrees C from the type strains of G. cerinus and G. frateurii, and in their growth on L-arabitol and meso-ribitol from the type strain of G. oxydans. The isolates showed no acid production from myo-inositol or melibiose, which differed from the type strains of the three known species. The major ubiquinone homologue was Q-10. On the basis of the results obtained, Gluconobacter thailandicus sp. nov. was proposed for the four isolates. The type strain is isolate F149-1(T) (=BCC 14116(T)=NBRC 100600(T)=JCM 12310(T)=TISTR 1533(T)=PCU 225(T)), which had 55.8 mol% G+C, isolated from a flower of the Indian cork tree (Millingtonia hortensis) collected in Bangkok, Thailand.     

Identification of Thai isolates assigned to the genus Gluconobacter based on 16S-23S rDNA ITS restriction analysis

Forty-four Thai isolates phenotypically assigned to the genus Gluconobacter were examined for 16S-23S rDNA ITS restriction analysis by MboII and SduI (=Bsp1286I) digestions. The Thai isolates tested were divided into seven groups: Group I for fourteen isolates, Group IX for one isolate, Group X for two isolates, Group V-2 for four isolates, Group XI for three isolates, Group IV for one isolate, and Group III for nineteen isolates. There were no isolates of either Group II or Group V-1 that were identified as G. cerinus. The isolates of Group III, Group IV, and Group XI were subjected to an additional 16S-23S rDNA ITS restriction analysis by AvaII, TaqI, BsoBI, and BstNI digestions. The isolates of Group III were divided into three groups and two subgroups: Group III-2 for five isolates, Group III-6 for two isolates, and Group III-4, which was divided into two subgroups, Subgroup III-4a for four isolates and Subgroup III-4b for eight isolates. The fourteen isolates of Group I were identified as G. oxydans, and the two isolates of Group X were temporarily identified as G. oxydans. The five isolates of Group III-2 and the one isolate of Group IV were identified as G. frateurii. The remaining twenty-two isolates of Group V-2, Group III-4, Group III-6, Group IX, and Group XI were not identified but are candidates for several new species.     

Intrageneric structure of the genus Gluconobacter analyzed by the 16S rRNA gene and 16S-23S rRNA gene internal transcribed spacer sequences

Forty-nine strains belonging to the genus Gluconobacter were re-examined with respect to their species identification based on the sequences of the 16S rDNA and 16S-23S rDNA internal transcribed spacer regions (ITS). A phylogenetic tree constructed from the 16S rDNA sequences indicated the presence of five clusters corresponding, respectively, to the major five species of the genus Gluconobacter, namely G. albidus, G. cerinus, G. frateurii, G. oxydans (type species), and G. thailandicus. The type strain of G. asaii, NBRC 3276T (T=type strain) was included in the G. cerinus cluster, which is consistent with the report that G. asaii is a junior subjective synonym of G. cerinus. Existence of the G. albidus, G. cerinus, G. frateurii, G. oxydans, and G. thailandicus clusters was also recognized by the ITS sequence analysis. Both sequence analyses revealed that the G. cerinus and G. frateurii clusters were heterogeneous. The G. cerinus cluster comprised three strains of G. cerinus and one strain of G. frateurii, while the G. frateurii cluster included ten strains of G. frateurii, three of G. cerinus, and eleven of G. oxydans. These results suggest that phenotypic differences among Gluconobacter species are ambiguous and the species definition must be re-evaluated. The 16S rDNA and ITS sequences determined in this study are valuable for the identification and phylogenetic analysis of Gluconobacter species.     

Heterogeneity of Strains Assigned to Gluconobacter frateurii Mason and Claus 1989 Based on Restriction Analysis of 16S-23S rDNA Internal Transcribed Spacer Regions

Twenty-three strains, which were assigned to Gluconobacter frateurii and maintained at Culture Collection NBRC, were re-identified at the species level on the basis of restriction analysis of 16S-23S rDNA ITS regions by digestion with six restriction endonucleases: Bsp1286I, MboII, AvaII, TaqI, BsoBI, and BstNI. The strains examined were divided into six groups, Group III-1, Group III-2, Group III-3, Group III-4, Group III-5, and Group IV. Group III-1 and Group III-4 respectively were divided into two subgroups, Subgroup III-1a, Subgroup III-1b and Subgroup III-4a, Subgroup III-4b. Gluconobacter frateurii NBRC 3264^T was included in Group III-2, along with strains NBRC 3265 and NBRC 3270, and G. thailandicus BCC 14116^T was included in Group III-3, along with strains NBRC 3254, NBRC 3256, NBRC 3258, NBRC 3255, and NBRC 3257. These groupings were supported by a phylogenetic tree based on 16S-23S rDNA ITS sequences. Strains of group III-2 and Group IV were unequivocally re-identified as G. frateurii, but strains of Group III-3, Group III-4, and Group III-5 were not necessarily re-identified as G. frateurii. The results obtained indicate that the 23 strains have a taxonomically heterogeneous nature, and they are referred to as the G. frateurii complex.     

Gluconobacter sphaericus (Ameyama 1975) comb. nov., a brown pigment-producing acetic acid bacterium in the Alphaproteobacteria

Strain NBRC 12467(T )was examined genetically, phylogenetically, phenotypically, and chemotaxonomically. The DNA G+C content of the strain was 59.5 mol%. The strain represented low levels of DNA-DNA hybridization of 49-9% to the type strains of eight Gluconobacter species. The strain formed a cluster along with the type strains of G. albidus and G. kondonii in phylogenetic trees based on 16S rRNA gene sequences. In a phylogenetic tree based on 16S-23S rRNA gene ITS sequences, however, the strain formed an independent cluster from the type strains of the eight Gluconobacter species. Such phylogenetic relationships were supported by the calculated pair-wise 16S rRNA gene and 16S-23S rRNA gene ITS sequence similarities. The strain was distinguished from the type strains of the eight Gluconobacter species by 16S-23S rRNA gene ITS restriction analysis using five restriction endonucleases. The strain produced a water-soluble brown pigment and 2,5-diketo-D-gluconate from D-glucose, differing from the type strains of the eight Gluconobacter species, and acid from meso-erythritol very weakly, differing from the type strains of the remaining seven Gluconobacter species except for the type strain of G. roseus, but not from maltose, differing from the type strain of G. oxydans, and had Q-10. For the strain, which was once classified as G. oxydans subsp. sphaericus, Gluconobacter sphaericus (Ameyama 1975) comb. nov. is proposed. The type strain is NBRC 12467(T), which is also deposited as BCC 14448(T).     

Identification of Trichinella isolates by polymerase chain reaction--restriction fragment length polymorphism of the mitochondrial cytochrome c-oxidase subunit I gene.

We developed a polymerase chain reaction based approach using restriction fragment length polymorphisms of the mitochondrial cytochrome c-oxidase subunit I to identify nine genotypes (Trichinella spiralis, Trichinella britovi-European strains, Trichinella britovi-Japanese strains, Trichinella nativa, Trichinella nelsoni, Trichinella T5, Trichinella T6, Trichinella T8 and Trichinella pseudospiralis) in the genus Trichinella. Partial mitochondrial cytochrome c-oxidase subunit I genes of nine genotypes were amplified by polymerase chain reaction, sequenced, and digested with three restriction endonucleases (Mse I, Alu I and Bsp1248 I). This polymerase chain reaction based restriction fragment length polymorphism method allowed the identification of Trichinella genotypes. Trichinella spiralis, Trichinella britovi-Japanese strains, Trichinella nelsoni, T5 and Trichinella pseudospiralis were distinguishable by digestion with Mse I. Trichinella britovi-European strains and Trichinella T8 were distinguishable by digestion using Alu I, and Trichinella nativa and Trichinella T6 were distinguishable by double-digestion with Mse I and Bsp1286 I. The results obtained with this polymerase chain reaction based restriction fragment length polymorphism assay confirmed those previously reported by others and support the separation of the Japanese isolates as a new genotype, namely Trichinella T9.     

Phylogenetic position of Gluconobacter species as a coherent cluster separated from all Acetobacter species on the basis of 16S ribosomal RNA sequences

Abstract The 16S rRNA sequences from the Gluconobacter species G. asaii G. cerinus and G. frateurii were determined and compared with homologous sequences from published databases and sequences of G. oxydans and Acetobacter species previously described [Sievers M., Ludwig W. and Teuber M. (1994) System. Appl. Microbiol. 17, 189–196]. The Gluconobacter species have unique 16S rRNA sequences and exhibit sequence similarity values of 97.4 to 99.1%, corresponding to 36 to 14 base differences. The phylogenetic tree inferring methods (distance matrix, maximum parsimony and maximum likelihood) show that the species of Gluconobacter form a coherent, closely related cluster. Based on the distance matrix method including Rhodopila globiformis as an outgroup reference organism, Gluconobacter is well separated from Acetobacter .     

Identification of acetic acid bacteria isolated from Indonesian sources,especially of isolates classified in the genus Gluconobacter

Sixty-four strains of acetic acid bacteria were isolated from Indonesian sources such as fruits, flowers, and fermented foods by the enrichment culture at pH 3.5. Forty-five strains were routinely identified as Acetobacter strains because of their oxidation of acetate and lactate to carbon dioxide and water and their Q-9 isoprenolog, corresponding to 70% of all the 64 acetic acid bacteria isolated. Eight isolates were identified as Gluconacetobacter strains because of their oxidation of acetate and lactate and their Q-10 isoprenolog, occupying 13% of all the isolates. The remaining 11 isolates, accommodated in the genus Gluconobacter because of no oxidation of acetate and lactate and because of their Q-10 isoprenolog, accounted for 17% of all the isolates. They were divided into two groups based on DNA base compositions. One comprised the seven isolates, which had high G1C contents of DNA ranging from 60.3 to 63.5 mol% and of which DNAs hybridized with that of the type strain of Gluconobacter oxydans at values of 64-94% of DNA relatedness. The other comprised the remaining four isolates, which had low G+C contents of DNA ranging from 57.5 to 57.7 mol% and of which DNAs hybridized with that of the type strain of Gluconobacter frateurii at values of 63-77% of DNA relatedness. The high values of DNA relatedness, 84 to 96%, were obtained between the type strains of Gluconobacter cerinus and Gluconobacter asaii.     

Diversity of DNA methylation pattern and total DNA restriction pattern in symbiotic Nostoc

Attempts were made to use total DNA restriction patterns and the response of purified DNA to treatment with restriction endonucleases to characterize several symbiotic Nostoc strains which had been isolated from different host plants cultivated in Italy. Among 27 restriction endonucleases tested, several did not cut any DNA and no significant variation in the susceptibility of the genomes to DNA restriction was seen among the strains. Therefore the Nostoc strains could not be separated into groups based on their different susceptibilities to the action of restriction endonucleases. However, in studies of total DNA restriction patterns, the restriction endonucleases BfrI and HpaI gave unique band patterns for each cyanobacterial isolate. Different profiles were even found in strains isolated from host plants belonging to the same species. The results do not support any definition of symbiotic Nostoc genomic groups or species and show that a tight specificity between the host plant and the cyanobacterium might not exist in the symbiotic associations involving Nostoc.     

Rotavirus A genotype G1P[8]: a novel method to distinguish wild-type strains from the Rotarix vaccine strain

Rotaviruses are important enteric pathogens for humans and animals. Group A rotaviruses (RV-A) are the most common agents of severe gastroenteritis in infants and young children and vaccination is the most effective method to reduce RV-A-associated diseases. G1P[8], the most prevalent RV-A genotype worldwide, is included in the RV-A vaccine Rotarix?. The discrimination between wild-type G1P[8] and vaccine G1P[8] strains is an important topic in the study of RV-A epidemiology to manage outbreaks and to define control measures for vaccinated children. In this study, we developed a novel method to segregate the wild-type and vaccine strains using restriction endonucleases. The dsRNA from the Rotarix? vaccine was sequenced and the NSP3 gene was selected as the target gene. The vaccine strain has a restriction pattern that is different than that of wild-type RV-A G1P[8] isolates after digestion with the restriction endonuclease BspHI. This pattern could be used as a marker for the differentiation of wild-type G1P[8] strains from the vaccine strain.     

Distribution of restriction endonucleases among some entomopathogenic strains of Bacillus sphaericus

The restriction enzyme Bsp TI, an isoschizomer of Hae III (recognition site GGCC), has been detected in eight strains of serotype 5a5b and two serotype 3 strains of the entomopathogenic bacterium Bacillus sphaericus . Strains from other serotypes contained the enzymes Bsp TII and Bsp TIII, which digested pBR322 DNA into similar banding patterns after agarose gel electrophoresis but differed in their susceptibility to methylation of the substrate. Strains from serotypes 9, 25 and 26a26b were lacking in restriction enzyme activity. There was little correlation between phage typing and restriction enzyme activity, suggesting that restriction and modification are not responsible for phage specificity among entomopathogenic B. sphaericus strains.     

Analysis of the clonal relationships between strains of Neisseria meningitidis by pulsed field gel electrophoresis.

Fingerprint patterns were generated from strains of Neisseria meningitidis by digestion of chromosomal DNA samples with 'rare-site' restriction endonucleases and resolution of the resultant fragments by pulsed field gel electrophoresis (PFGE). The potential of this technique for the rapid establishment of the clonal relationships between different isolates of the meningococcus was investigated. The fingerprint patterns from various serogroup A strains, previously assigned to clonal subgroups on the basis of their electrophoretic types (ETs), were compared. Fingerprints generated with the endonucleases SfiI, SpeI and NheI each gave distinctive patterns for the clonal subgroups I-IV of serogroup A. Further, the endonucleases SpeI and, particularly, NheI were capable of resolving differences between various subgroup III strains isolated at different times and geographical locations. Strains isolated during the 'new wave' pandemic, which was associated with the Haj, from Europe, America, and Africa, had a characteristic fingerprint pattern and appeared to be distinct from 'old wave' pandemic strains. The PFGE technique is a relatively rapid and sensitive method for establishing clonal relationships among epidemic strains of N. meningitidis.     

Identification of Acetobacter strains isolated from Indonesian sources,and proposals of Acetobacter syzygii sp. nov., Acetobacter cibinongensis sp. nov., and Acetobacter orientalis sp. nov

Forty-six strains of acetic acid bacteria newly isolated from flowers, fruits, and fermented foods collected in Indonesia were taxonomically studied. They were Gram-negative rods, produced acetic acid from ethanol, oxidized acetate and lactate to CO(2) and H(2)O, and had Q-9 as the major ubiquinone system. On the basis of DNA-DNA similarity, all strains studied, including type strains and reference strains of the genus Acetobacter, were separated into eleven groups (Groups I to XI). Of the 46 isolates, two isolates were included in Group II and identified as Acetobacter pasteurianus, five in Group IV as A. orleanensis, 16 in Group V as A. lovaniensis, five in Group VII as A. indonesiensis, and three in Group VIII as A. tropicalis. The remaining 15 isolates constituted three new groups based on DNA-DNA similarity; four isolates were included in Group IX, two in Group X, and nine in Group XI. No isolates were identified as A. aceti (Group I), A. peroxydans (Group III), and A. estunensis (Group VI). Phylogenetic analysis based on 16S rDNA sequences of representative strains of the Groups indicated belonging to the strains of the genus Acetobacter. On the basis of DNA base composition, DNA-DNA similarity, and 16S rDNA sequences, three new species of the genus Acetobacter are proposed: Acetobacter syzygii sp. nov. for Group IX, Acetobacter cibinongensis sp. nov. for Group X, and Acetobacter orientalis sp. nov. for Group XI. The distribution of Acetobacter strains in Indonesia is discussed in light of isolation sources.     

H2, a temperate bacteriophage isolated from Bacillus amyloliquefaciens strain H

Bacillus amyloliquefaciens strain H is lysogenic for a large temperate phage we call H2. H2 has a polyhedral head 85 nm in diameter and a tail of about 17 x 434 nm. H2 lysogenizes Bacillus subtilis between the tyrA and metB genes, and gives specialized transduction of metB and, at lower frequencies, of ilvD and ilvA. The phage carries a thymidylate synthase gene and converts thymine auxotrophs of B. subtilis to prototrophy. The H2 genome is a linear DNA molecule about 129 kb in length. DNA extracted from phage particles grown in B. subtilis is not cut by the restriction endonucleases HaeIII, Fnu4HI, Bsp1286I, and BamHI; the latter enzyme is produced by B. amyloliquefaciens strain H. The prophage in lysogenic B. subtilis cells can be cut by these enzymes. We have isolated H2 mutants that carry the transposon Tn917, or a mutation resulting in clear-plaque morphology, or both.     

Organization of the ribosomal operon 165-235 gene spacer region in representatives of Neisseria gonorrhoeae

Ribosomal rRNA gene fragments (rDNA) encompassing part of the 16S rDNA, the 16S-23S rDNA spacer region and part of the 23S rDNA of 229 Neisseria gonorrhoeae strains were enzymatically amplified using conserved primers. The fragments of approximately 1200 bp were subjected to restriction analysis with HinfI. This revealed 13 patterns (patterns I-XIII) of which patterns I (78 strains), II (32 strains), III (38 strains) and IV (56 strains) were the most abundant, comprising 89.1% of the strains. The obtained restriction patterns consisted of 3 to 8 bands, ranging in size from 32 to 854 bp. The sum of the obtained bands was about 1200 bp for patterns I, II, III, IV, V, IX, and XIII. However, for patterns VI, VII, VIII, X, XI and XII, the sum of the bands well exceeded the estimated size of approximately 1200 bp. We demonstrated that this results from sequence divergence in the 4 rRNA operons, present in the genome of N. gonorrhoeae, giving rise to patterns that are a combination of several other patterns.     

Polyphasic investigation of the diversity within Lactobacillus plantarum related strains revealed two L. plantarum subgroups

The diversity of 140 strains related to Lactobacillus plantarum was investigated using a polyphasic approach combining two molecular techniques: randomly amplified polymorphic DNA fingerprinting (RAPD) and Southern hybridisation with a pyr probe on BglI digests of chromosomal DNA, as well as phenotypic characterization. The RAPD technique allowed us to classify a subset of 60 representative strains into four groups. One group belonged to Lactobacillus paraplantarum, the second to Lactobacillus pentosus and the two remaining groups to L. plantarum (G(L)p1 and G(L)p2). The Southern hybridisation technique (F. Bringel, M.-C. Curk and J.-C. Hubert, Int. J. Syst. Bacteriol. 46: 588-594, 1996) revealed nine groups of profiles (I to IX). Results indicated an excellent convergence between RAPD and hybridisation classifications for more than 93% (56/60) of the strains studied. When we compared the fermentation patterns of the L. plantarum strains, three differences were found. Melezitose fermentation was not fermented by the G(L)p2 RAPD group, unlike the G(L)p1 RAPD group which included L. plantarum type strain NCIMB11974T. Second, alpha-methyl-D-mannoside was fermented by a majority of the strains of the G(L)p1 RAPD group but by none of the strains in the G(L)p2 RAPD group. Third, dulcitol was catabolized by nearly half of the strains of the G(L)p2 RAPD group but by none of the strains in the G(L)p1 RAPD group. Molecular diversity within L. plantarum was confirmed using Southern profiles, PCR amplification and subsequent sequencing of these PCR products. A 773 bp sequence overlapping the pyrDF genes showed high homology: at least 97% identical in L. plantarum strains (V to IX) and 99.9% identical in hybridisation groups VII and VIII. The same G-T transversion which destroyed the pyrF BglI site was found in 11 strains (hybridisation groups VI, VII and VIII). DNA rearrangements were identified downstream from the pyr genes, by PCR amplification and Southern hybridisation profile analysis in three strains of hybridisation groups VIII and IX, two of which also harboured the G-T transversion.     

鱼类基因组结构研究——Ⅰ.染色体的限制性内切酶显带

本文报道了1种新的鱼类染色体研究方法——限制性内切酶显带技术。我们应用限制性内切酶Bsp631等分别对黄鳝和长春鳊的染色体进行显带处理,结果表明,Bsp631能使这两种鱼的染色体发生稳定的带纹分化:适度的处理产生多重的G-带状带型,而过度的处理则产生特殊的限制性内切酶抗性带型。根据显带结果分析,我们对鱼类染色体限制性内切酶显带的可行性和实用价值进行了讨论。     

Determination of Gardnerella vaginalis Genome Size by Pulsed-Field Gel Electrophoresis

The chromosomal DNA of four strains of Gardnerella vaginaliswere digested with rare cutting restriction enzymes and analyzedby pulsed-field gel electrophoresis (PFGE). The four strainsstudied were two clinical isolates (GVP 004 & GVP 007) andtwo American Type Culture Collection strains (ATCC 14018 &ATCC 14019). The restriction enzyme SfiI generated two DNA fragmentsof about 0.6 Mb and 1.1 Mb in all four strains giving a G. vaginalisgenome size of about 1.7 Mb. A similar genome size was calculatedutilizing two more GC-rich sequence specific restriction endonucleases,NotI and AscI. When digested with AscI, the chromosomal DNAof all four strains gave rise to 11 to 12 DNA fragments rangingbetween 0.01 Mb to 0.43 Mb. DNA from the two clinical isolateswere digested by NotI (yielding 7 to 9 fragments), while theDNA from the two ATCC strains were resistant to NotI digestion.In contrast to the clinical isolates, DNA from the two ATCCstrains gave an identical profile for all restriction endonucleasestested. From double digestion experiments, the two SfiI sitescould be localized on two AscI fragments. From these PFGE studies,it is concluded that the G. vaginalis genome is a circular DNAthat ranges between 1.67 Mb and 1.72 Mb in size.