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.     

Re-identification of Gluconobacter strains based on restriction analysis of 16S-23S rDNA internal transcribed spacer regions

Thirty Gluconobacter strains maintained at Culture Collection NBRC were re-identified at the species level on the basis of restriction analysis of 16S-23S rDNA internal transcribed spacer (ITS) regions by digestion with two restriction endonucleases MboII and Bsp1286I. The strains examined were divided into seven groups, designated as Group I and Group III-VIII, by the combination of the restriction patterns obtained with the two restriction endonucleases. Group I included seven strains, which gave "G. oxydans patterns" with the two restriction endonucleases and were re-identified as G. oxydans. Group III included 12 strains, which gave "G. frateurii patterns" and were re-identified as G. frateurii. Group IV included six strains, which gave "G. cerinus pattern" with MboII and "G. frateurii pattern" with Bsp1286I and were re-identified as G. frateurii. Group V included one strain (NBRC 3274), which gave respectively "G. frateurii pattern" and "G. cerinus pattern" and was re-identified as G. cerinus. Group VI included one strain (NBRC 3990), which gave respectively "G. oxydans pattern" and an unidentified restriction pattern and was re-identified temporarily as G. oxydans. Group VII included two strains (NBRC 3250 and NBRC 3273), which gave respectively an unidentified restriction pattern and "G. oxydans pattern." Group VIII included one strain (NBRC 3266), which gave unidentified restriction patterns. The three strains of Group VII and Group VIII were suggested to constitute new taxa by sequencing of 16S-23S rDNA ITS regions.     

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.     

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.     

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).     

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.     

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.     

Gluconacetobacter maltaceti sp. nov., a novel vinegar producing acetic acid bacterium

Comparison of HaeIII- and HpaII-restriction profiles of PCR-amplified 16S-23S rDNA ITS regions of Gluconacetobacter sp. LMG 1529^T and SKU 1109 with restriction profiles of reference strains of acetic acid bacteria described by Tr?ek and Teuber [34] revealed the same but unique restriction profiles for LMG 1529^T and SKU 1109. Further analyses of nearly complete 16S rRNA gene sequences, nearly complete 16S-23S rDNA ITS sequences, as well as concatenated partial sequences of the housekeeping genes dnaK, groEL and rpoB, allocated both strains to a single phylogenetic cluster well separated from the other species of the genus Gluconacetobacter. DNA–DNA hybridizations confirmed their novel species identity by 73% DNA–DNA relatedness between both strains, and values below the species level (<70%) between SKU 1109 and the type strains of the closest phylogenetic neighbors. The classification of strains LMG 1529^T and SKU 1109 into a single novel species was confirmed also by AFLP and (GTG)₅-PCR DNA fingerprinting data, as well as by phenotypic data. Strains LMG 1529^T and SKU 1109 can be differentiated from their closely related Gluconacetobacter species, Gluconacetobacter entanii and Gluconacetobacter hansenii, by their ability to form 2-keto-d-gluconic acid from d-glucose, their ability to use d-mannitol, d-gluconate and glycerol as carbon source and form acid from d-fructose, and their ability to grow without acetic acid. The major fatty acid of LMG 1529^T and SKU 1109 is C_18:1ω7c (60.2–64.8%). The DNA G + C content of LMG 1529^T and SKU 1109 is 62.5 and 63.3 mol% respectively. The name Gluconacetobacter maltaceti sp. nov. is proposed. The type strain is LMG 1529^T (= NBRC 14815^T = NCIMB 8752^T).     

Lactobionic and cellobionic acid production profiles of the resting cells of acetic acid bacteria

Lactobionic acid was produced by acetic acid bacteria to oxidize lactose. Gluconobacter spp. and Gluconacetobacter spp. showed higher lactose-oxidizing activities than Acetobacter spp. Gluconobacter frateurii NBRC3285 produced the highest amount of lactobionic acid per cell, among the strains tested. This bacterium assimilated neither lactose nor lactobionic acid. At high lactose concentration (30%), resting cells of the bacterium showed sufficient oxidizing activity for efficient production of lactobionic acid. These properties may contribute to industrial production of lactobionic acid by the bacterium. The bacterium showed higher oxidizing activity on cellobiose than that on lactose and produced cellobionic acid.     

Molecular analysis of 16S–23S spacer regions ofAcetobacter species

16S-23S rDNA internal transcribed spacer regions (ITS) similarities were determined in 8 Acetobacter and 1 Gluconacetobacter strains. ITS-PCR amplification of the 16S-23S spacers showed 2 products of similar size in 7 strains; only 1 product of similar size was found in the 2 remaining strains. Analysis of the PCR products using restriction endonucleases HaeIII, HpaII and AluI revealed 3 different restriction groups of A. pasteurianus for AluI and HaeIII, and 4 restriction groups for HpaII. ITS nucleotide sequences of all studied strains exhibited a 52-98% similarity.     

Neokomagataea gen. nov., with Descriptions of Neokomagataea thailandica sp. nov. and Neokomagataea tanensis sp. nov., Osmotolerant Acetic Acid Bacteria of the α-Proteobacteria

Isolates AH11^T and AH13^T were isolated from flowers of lantana and candle bush respectively collected in Thailand. In phylogenetic trees based on 16S rRNA gene sequences, the two isolates formed an independent cluster, which was then connected to the type strain of Saccharibacter floricola. The calculated pair-wise 16S rRNA gene sequence similarities of isolate AH11^T were 95.7–92.3% to the type strains of the type species of the 12 genera of acetic acid bacteria. The DNA base composition was from 51.2 to 56.8 mol % G+C, with a range of 5.6 mol %. When isolate AH11^T was labeled, DNA-DNA similarities were 100, 12, 4, 5, and 4% respectively to isolates AH11^T and AH13^T and the type strains of Saccharibacter floricola, Gluconobacter oxydans, and Acetobacter aceti. The two isolates were non-motile and did not oxidize either acetate or lactate. No growth was found in the presence of 0.35% acetic acid w/v. The two isolates were not osmophilic but osmotolerant, produced 2,5-diketo-D-gluconate from D-glucose, and did not oxidize lactate, thus differing from strains of Saccharibacter floricola, which showed weak lactate oxidation. The two isolates contained unsaturated C_18:1ω7c fatty acid as the major fatty acid, and were unique in the presence of a considerable amount of straight-chain C_18:12OH fatty acid. Q-10 was present as the major isoprenoid quinone. Neokomagataea gen. nov. was proposed with the two species, Neokomagataea thailandica sp. nov. for isolate AH11^T (=BCC 25710 ^T =NBRC 106555^T), which has 56.8 mol % G+C, and Neokomagataea tanensis sp. nov. for isolate AH13^T (=BCC 25711^T=NBRC 106556^T), which has 51.2 mol % G+C.     

Citeromyces cibodasensis sp. nov., a novel yeast species isolated from leaf litter in Indonesia

A novel yeast species was isolated from leaf litter of Macropanax dispermus obtained from the Cibodas Botanical Garden, West Java, Indonesia. The two strains of the species displayed typical characteristics of the genus Citeromyces. Phylogenetic analysis based on the gene sequences of the D1/D2 domains of large subunit (LSU) rDNA, internal transcribed spacer (ITS) including 5.8S rDNA, mitochondrial small-subunit rRNA gene (MtSm), and translation elongation factor-1α (EF-1α) showed that the novel strains were clearly separated from the other four existing species of the genus Citeromyces. Therefore, the two strains were proposed to represent a novel species within the genus Citeromyces, for which the name Citeromyces cibodasensis is proposed; the type strain is NBRC 110244^T (= CBS 14272^T?=?InaCCY703^T?=?AK 01).     

Neoasaia chiangmaiensis gen. nov., sp. nov., a novel osmotolerant acetic acid bacterium in the alpha-Proteobacteria

An acetic acid bacterium, designated as isolate AC28(T), was isolated from a flower of red ginger (khing daeng in Thai; Alpinia purpurata) collected in Chiang Mai, Thailand, at pH 3.5 by use of a glucose/ethanol/acetic acid (0.3%, w/v) medium. A phylogenetic tree based on 16S rRNA gene sequences for 1,376 bases showed that isolate AC28(T) constituted a cluster along with the type strain of Kozakia baliensis. However, the isolate formed an independent cluster in a phylogenetic tree based on 16S-23S rDNA internal transcribed spacer (ITS) region sequences for 586 bases. Pair-wise sequence similarities of the isolate in 16S rRNA gene sequences for 1,457 bases were 93.0-88.3% to the type strains of Asaia, Kozakia, Swaminathania, Acetobacter, Gluconobacter, Gluconacetobacter, Acidomonas, and Saccharibacter species. Restriction analysis of 16S-23S rDNA ITS regions discriminated isolate AC28(T) from the type strains of Asaia and Kozakia species. Cells were non-motile. Colonies were pink, shiny, and smooth. The isolate produced acetic acid from ethanol. Oxidation of acetate and lactate was negative. The isolate grew on glutamate agar and mannitol agar. Growth was positive on 30% D-glucose (w/v) and in the presence of 0.35% acetic acid (w/v), but not in the presence of 1.0% KNO(3) (w/v). Ammoniac nitrogen was hardly assimilated on a glucose medium or a mannitol medium. Production of dihydroxyacetone from glycerol was weakly positive. The isolate did not produce a levan-like polysaccharide on a sucrose medium. Major isoprenoid quinone was Q-10. DNA base composition was 63.1 mol% G+C. On the basis of the results obtained, Neoasaia gen. nov. was proposed with Neoasaia chiangmaiensis sp. nov. The type strain was isolate AC28(T) (=BCC 15763(T) =NBRC 101099(T)).     

Use of a Gluconobacter frateurii Mutant to Prevent Dihydroxyacetone Accumulation during Glyceric Acid Production from Glycerol

To prevent dihydroxyacetone (DHA) by-production during glyceric acid (GA) production from glycerol using Gluconobacter frateurii, we used a G. frateurii THD32 mutant, ΔsldA, in which the glycerol dehydrogenase subunit-encoding gene (sldA) was disrupted, but ΔsldA grew much more slowly than the wild type, growth starting after a lag of 3 d under the same culture conditions. The addition of 1% w/v D-sorbitol to the medium improved both the growth and the GA productivity of the mutant, and ΔsldA produced 89.1 g/l GA during 4 d of incubation without DHA accumulation.     

Effect of glycine betaine on osmoadaptation of Propionibacterium acidipropionici cultivated in elevated osmolarities

The sensitivity of industrial strains Acetobacter aceti, Gluconobacter frateurii, and Propionibacterium acidipropionici to osmotic stress was studied. Growth of A. aceti and G. frateurii was totally inhibited at 0.4 M NaCl concentration, but P. acidipropionici was able to grow on a medium containing 1.2 M NaCl. Addition of glycine betaine to the medium had no detectable osmoprotective effect on A. aceti and G. frateurii cultivations in elevated NaCl concentrations, but it enabled cells of P. acidipropionici to achieve faster the maximum specific growth rate after the prolonged lag phase and therefore to gain faster the final biomass and product concentrations. The final concentrations of biomass and product of P. acidipropionici were the same as for the cultivations of the bacterium without NaCl and glycine betaine present in the medium. Intracellular accumulation of glycine betaine was detected in P. acidipropionici cells cultivated in the medium containing glycine betaine. The amount accumulated increased with NaCl concentration, suggesting that glycine betaine plays an important role in the osmoadaptation. Received: 31 March 2000 / Received revision: 22 May 2000 / Accepted: 3 June 2000     

Ameyamaea chiangmaiensis gen. nov., sp. nov., an Acetic Acid Bacterium in the α-Proteobacteria

Two isolates, AC04^T and AC05, were isolated from the flowers of red ginger collected in Chiang Mai, Thailand. In phylogenetic trees based on 16S rRNA gene sequences, the two isolates were included within a lineage comprised of the genera Acidomonas, Gluconacetobacter, Asaia, Kozakia, Swaminathania, Neoasaia, Granulibacter, and Tanticharoenia, and they formed an independent cluster along with the type strain of Tanticharoenia sakaeratensis. The calculated pair-wise sequence similarities of isolate AC04^T were 97.8–92.5% to the type strains of the type species of the 11 genera of acetic acid bacteria. The DNA base composition was 66.0–66.1 mol % G+C with a range of 0.1 mol %. A single-stranded, labeled DNA from isolate AC04^T presented levels of DNA-DNA hybridization of 100, 85, 4, and 3% respectively to DNAs from isolates AC04^T and AC05 and the type strains of Tanticharoenia sakaeratensis and Gluconacetobacter liquefaciens. The two isolates were unique morphologically in polar flagellation and physiologically in intense acetate oxidation to carbon dioxide and water and weak lactate oxidation. The intensity in acetate oxidation almost equaled that of the type strain of Acetobacter aceti. The two isolates had Q-10. Isolate AC04^T was discriminated from the type strains of the type species of the 11 genera by 16S rRNA gene restriction analysis using restriction endonucleases TaqI and Hin6I. The unique phylogenetic, genetic, morphological, physiological, and biochemical characteristics obtained indicate that the two isolates can be classified into a separate genus, and Ameyamaea chiangmaiensis gen. nov., sp. nov. is proposed. The type strain is isolate AC04^T (=BCC 15744^T, =NBRC 103196^T), which has a DNA G+C content of 66.0 mol %.     

Sequence-based differentiation of strains in the Mycobacterium avium complex.

The complete 16S-23S rDNA internal transcribed spacer (ITS) was sequenced in 35 reference strains of the Mycobacterium avium complex. Twelve distinct ITS sequences were obtained, each of which defined a "sequevar"; a sequevar consists of the strain or strains which have a particular sequence. ITS sequences were identified which corresponded to M. avium (16 strains, four ITS sequevars) and Mycobacterium intracellulare (12 strains, one ITS sequevars). The other seven M. avium complex strains had ITS sequences which varied greatly from those of M. avium and M. intracellulare and from each other. The 16S-23S rDNA ITS was much more variable than 16S rDNA, which is widely used for genus and species identification. Phylogenetic trees based on the ITS were compatible with those based on 16S rDNA but were more detailed and had longer branches. The results of ITS sequencing were consistent with the results of hybridization with M. avium and M. intracellulare probes (Gen-Probe) for 30 of 31 strains tested. Serologic testing correlated poorly with ITS sequencing. Strains with the same sequence were different serovars, and those of the same serovar had different sequences. Sequencing of the 16S-23S rDNA ITS should be useful for species and strain differentiation for a wide variety of bacteria and should be applicable to studies of epidemiology, diagnosis, virulence, and taxonomy.     

Assessment of the genetic diversity of Xylella fastidiosa isolated from citrus in Brazil by PCR-RFLP of the 16S rDNA and 16S-23S intergenic spacer and rep-PCR fingerprinting

The genetic diversity among twenty three strains of Xylella fastidiosa, isolated from sweet orange citrus, was assessed by RFLP analysis of the 16S rDNA and 16S-23S intergenic spacer and by rep-PCR fingerprinting together with strains isolated from coffee, grapevine, plum and pear. The PCR products obtained by amplification of the 16S rDNA and 16S-23S spacer region were digested with restriction enzymes and a low level of polymorphism was detected. In rep-PCR fingerprinting, a relationship between the strains and their hosts was observed by using the BOX, ERIC and REP primers. Two major groups were obtained within the citrus cluster and relationships to the geographic origin of the strains revealed. Citrus strains isolated from the States of São Paulo and Sergipe formed one group and strains from the Southern States formed another group. Distinct origins of X. fastidiosa in the Southern and Southeastern States is postulated. The pear isolate was distantly related to all of the other X. fastidiosa strains.     

Genetic diversity of phenazine- and pyoluteorin-producing pseudomonads isolated from green pepper rhizosphere

The genetic diversity among indigenous phenazine-1-carboxylic acid (PCA)-producing and pyoluteorin (Plt)-producing isolates of pseudomonads screened from green pepper rhizosphere was exploited in this study. A total of 48 bacterium isolates producing one or both of these antibiotics were screened from green pepper rhizosphere in diverse regions in China. Among these isolates, 45 could produce PCA, 3 could produce both PCA and Plt, and none could produce Plt only. Based on the restriction patterns of partial 16S and 16S-23S internal transcribed spacer (ITS) PCR fragments generated by enzyme HaeIII or HinfI, these isolates fell into 19 or 17 distinct groups respectively, indicating that there was a significant diversity among them. Polygenetic analysis of the partial 16S rDNA and 16S-23S ITS sequence from the representative in each group in the context of similar sequence from previously described bacterial species indicated that most isolates were closely related to the species of Pseudomonas fluorescens, P. putida, and Stenotrophomonas maltophilia. Some of these representatives of these isolates, then, are likely to be novel strains or species in these two genera. The GenBank accession numbers for DNA sequences of the partial 16S rDNA with ITS region in each isolate determined in this study were: GP30 DQ003219; GP127 DQ003220; GP83 DQ003221; GP42, DQ003222; GP59 DQ003223; GP50 DQ003224; GP36 DQ003225; GP110 DQ003226; GP26 DQ003227; GP37 DQ003228; GP60 DQ003229; GP31 DQ003230; GP57 DQ003231; GP75 DQ003232; GP115 DQ003233; GP65 DQ003234; GP32 DQ003235; GP76 DQ003236; GP78 DQ003237.