DNA homology and taxonomy of Pseudomonas and Xanthomonas

Paenibacillus maysiensis sp. nov., a Nitrogen-Fixing Species Isolated from the Rhizosphere Soil of Maize

A novel bacterium SX-49^T with nitrogen-fixing capability was isolated from the rhizosphere soil of maize. Phylogenetic analysis of nifH gene fragment and 16S rRNA gene sequence revealed that the strain SX-49^T is a member of the genus Paenibacillus. Values of 16S rRNA gene sequence similarity were highest between SX-49^T and P. jamilae DSM 13815^T (97.0%), P. brasiliensis DSM 14914^T (97.8%), P. polymyxa DSM 36^T (97.5%), and P. terrae DSM 15891^T (98.8%). The similarity between SX-49^T and other Paenibacillus species was < 97.0%. DNA-DNA hybridization values between strain SX-49^T and the four type strains were P. jamilae DSM 13815^T: 40.6%, P. brasiliensis DSM 14914^T: 27.9%, P. polymyxa DSM 36^T: 29.2%, and P. terrae DSM 15891^T: 66.4%. The DNA G+C content of SX-49^T was 46.4 mol%. The predominant fatty acids were anteiso-C_15:0, C_16:0 and iso-C_16:0. The predominant isoprenoid quinone was MK-7. The genome contains 5628 putative protein-coding sequences (CDS), 6 rRNAs and 56 tRNAs. The phenotypic and genotypic characteristics, DNA-DNA relatedness, and genome features suggest that SX-49^T represents a novel species of the genus Paenibacillus, and the name Paenibacillus maysiensis sp. nov. is proposed.

A comparison of the molecular organization of genomic regions associated with resistance to common bacterial blight in two Phaseolus vulgaris genotypes

Resistance to common bacterial blight, caused by Xanthomonas axonopodis pv. phaseoli, in Phaseolus vulgaris is conditioned by several loci on different chromosomes. Previous studies with OAC-Rex, a CBB-resistant, white bean variety of Mesoamerican origin, identified two resistance loci associated with the molecular markers Pv-CTT001 and SU91, on chromosome 4 and 8, respectively. Resistance to CBB is assumed to be derived from an interspecific cross with Phaseolus acutifolius in the pedigree of OAC-Rex. Our current whole genome sequencing effort with OAC-Rex provided the opportunity to compare its genome in the regions associated with CBB resistance with the v1.0 release of the P. vulgaris line G19833, which is a large seeded bean of Andean origin, and (assumed to be) CBB susceptible. In addition, the genomic regions containing SAP6, a marker associated with P. vulgaris-derived CBB-resistance on chromosome 10, were compared. These analyses indicated that gene content was highly conserved between G19833 and OAC-Rex across the regions examined (>80%). However, fifty-nine genes unique to OAC Rex were identified, with resistance gene homologues making up the largest category (10 genes identified). Two unique genes in OAC-Rex located within the SU91 resistance QTL have homology to P. acutifolius ESTs and may be potential sources of CBB resistance. As the genomic sequence assembly of OAC-Rex is completed, we expect that further comparisons between it and the G19833 genome will lead to a greater understanding of CBB resistance in bean.

Taxonomy of bacterial fish pathogens

Bacterial taxonomy has progressed from reliance on highly artificial culture-dependent techniques involving the study of phenotype (including morphological, biochemical and physiological data) to the modern applications of molecular biology, most recently 16S rRNA gene sequencing, which gives an insight into evolutionary pathways (= phylogenetics). The latter is applicable to culture-independent approaches, and has led directly to the recognition of new uncultured bacterial groups, i.e. "Candidatus", which have been associated as the cause of some fish diseases, including rainbow trout summer enteritic syndrome. One immediate benefit is that 16S rRNA gene sequencing has led to increased confidence in the accuracy of names allocated to bacterial pathogens. This is in marked contrast to the previous dominance of phenotyping, and identifications, which have been subsequently challenged in the light of 16S rRNA gene sequencing. To date, there has been some fluidity over the names of bacterial fish pathogens, with some, for example Vibrio anguillarum, being divided into two separate entities (V. anguillarum and V. ordalii). Others have been combined, for example V. carchariae, V. harveyi and V. trachuri as V. harveyi. Confusion may result with some organisms recognized by more than one name; V. anguillarum was reclassified as Beneckea and Listonella, with Vibrio and Listonella persisting in the scientific literature. Notwithstanding, modern methods have permitted real progress in the understanding of the taxonomic relationships of many bacterial fish pathogens.

Characterization of Xanthomonas phaseoli Bacteriophages

Ten bacteriophages for Xanthomonas phaseoli were characterized. On the basis of adsorption rates, latent period and burst size, plaque morphology, host range, efficiency of plating, ultrastructure, sensitivity to osmotic shock, streptomycin sensitivity, temperature effects on plating efficiency, and serology, the phages were separated into at least three groups. Some of the phages were infectious for Pseudomonas phaseolicola (four strains) and P. syringae (one strain) in a narrow temperature range. The taxonomic and ecological significance of this finding is discussed.

Notes on the characterization of prokaryote strains for taxonomic purposes

Taxonomy relies on three key elements: characterization, classification and nomenclature. All three elements are dynamic fields, but each step depends on the one which precedes it. Thus, the nomenclature of a group of organisms depends on the way they are classified, and the classification (among other elements) depends on the information gathered as a result of characterization. While nomenclature is governed by the Bacteriological Code, the classification and characterization of prokaryotes is an area that is not formally regulated and one in which numerous changes have taken place in the last 50 years. The purpose of the present article is to outline the key elements in the way that prokaryotes are characterized, with a view to providing an overview of some of the pitfalls commonly encountered in taxonomic papers.

Physiological and biochemical contributions to the taxonomy of the genus Chlorella. XI. DNA hybridization

1. DNA homology was studied in 12 Chlorella species. The DNA of 88 strains was hybridized with 3H-labelled DNA from C. fusca var. vacuolata 211-8 b and from C. vulgaris 211-8m. The results indicate that the genus Chlorella is a heterogenous taxon which consists of several groups of species. 2. The "C. fusca group" comprises C. fusca var. vacuolata, C. fusca var. rubescens, and C. zofingiensis. Within this group, C. zofingiensis appears to be more closely related to C. fusca var. vacuolata than is C. fusca var. rubescens. C. fusca var. fusca does not belong to this group of taxa. 3. The "C. vulgaris group" consists of C. vulgaris, C. sorokiniana, and C. saccharophila. There are several strains which seem to assume a position intermediate between C. vulgaris and C. saccharophila. C. protothecoides is not related to this group of species. 4. Several groups of strains of C. sorokiniana with different base compositions (guanine + cytosine content) of their DNA appear to belong to the same taxon. 5. In addition to C. fusca var. fusca and C. protothecoides, also C. luteoviridis, C. minutissima, C. kessleri, and C. homosphaera seem to have so little relationship with the other species that their assignment to the genus Chlorella appears questionable.

Improvements of the membrane filter method for DNA:rRNA hybridization

We describe and recommend the following improvements of DNA:rRNA membrane filter hybridization methods. One of our aims was to avoid DNA release from filter discs during hybridization. 1. Our hybridization conditions are 2 SSC in aq. dest., with 20% formamide, 50 C, overnight for 16 hr. 2. Duplexing is over in 8-10 hr. 3. Formamide has to be very pure (O.D. less than or equal to 0.2/cm light path at 270 nm). 4. RNAase treatment: 250 mug/5 ml 2 SSC/filter at 37 C for 1 hr. 5. Our conditions for stepwise thermal denaturation are: 5 degrees C steps from 50 C to 90 C in 1.5 SSC in 20% formamide. 6. Single-stranded DNA, fixed on membrane filters, and stored in vacuo at 4C can be used reliably for hybridization for up to 20 months. 7. Concentrated DNA in 0.1 SSC, quick-frozen at -50 C and stored at -90 C for up to 2 years can be used for hybridization without much change. 8. A CsCl gradient purification step yields much purer DNA, but increases the release of DNA from filters by about 20%. Filters with 20% more DAN is a compensation. 9. rRNA can be stored for 20 months in SSC or 2 SSC at -12 C without changing the hybridization results.

Reexamination of the association between melting point, buoyant density, and chemical base composition of deoxyribonucleic acid

The equations currently used for the calculation of the chemical base composition of deoxyribonucleic acid (DNA), expressed as moles per cent guanine plus cytosine (% GC), from either buoyant density (rho) or midpoint of thermal denaturation (T(m)) were recalculated by using only sets of data on DNA determined with the same strains. All available information from the literature was screened and supplemented by unpublished data. The results were calculated by regression and correlation analysis and treated statistically. From the data on 96 strains of bacteria, it was calculated that% GC = 2.44 (T(m) - 69.4). T(m) appears to be unaffected by the substitution of cytosine by hydroxymethylcytosine. This equation is also valid for nonbacterial DNA. From the data on 84 strains of bacteria, the relation% GC = 1038.47 (-1.6616) was calculated. The constants in this equation are slightly modified when data on nonbacterial DNA are included. Both correlations differ only slightly from those currently used, but now they lean on a statistically sound basis. As a control, the relation between rho and T(m) was calculated from data of 197 strains; it agrees excellently with the above two equations.

Characterization and relatedness of marine vibrios pathogenic to fish: deoxyribonucleic acid homology and base composition

Deoxyribonucleic acid (DNA) isolated from several pathogenic marine vibrios was utilized in studies of base composition and nucleotide sequence relationships. Patterns of relatedness inferred from DNA criteria were found to correlate closely with those inferred from morphological, physiological, and serological analysis of the same organisms. The utility of the phenotypic and genotypic approaches to the determination of relatedness is discussed.

Deoxyribonucleic acid homology and relative genome size in Mycoplasma

The deoxyribonucleic acid homologies of Mycoplasma laidlawii type A and type B, M. pulmonis (#47 and #63), and M. hominis were determined by membrane methodology. The homology data revealed a difference in genome size between M. laidlawii type A and type B. This difference also held with stringent conditions of annealing (high temperature). Little or negligible homology was shown to exist between the M. laidlawii strains type A and type B and M. pulmonis strains 47 and 63 and M. hominis. M. hominis showed less than 10% homology to the M. pulmonis and M. laidlawii strains. Neither of the M. laidlawii strains showed more than 2% annealing to the M. pulmonis strains. Reaction rate studies are suggested as a means of demonstrating the phylogenetic relationship between the Mycoplasma and other microorganisms.

Deoxyribonucleic acid homology in bacterial taxonomy: effect of incubation temperature on reaction specificity

Parameters affecting deoxyribonucleic acid duplex (DNA-DNA) formation on membrane filters were evaluated. The reference strains used were Cytophaga succinicans strain 8, which has a guanine plus cytosine (GC) content of 38%, and Myxococcus xanthus strain FB, which has a GC content of 70%. Both organisms are gliding bacteria classified among the myxobacteria. Among the parameters evaluated, the incubation temperature used during duplex formation was found to be the most important in terms of the physical nature of the reaction product. When an incubation temperature 25 C below the melting point (T(m)) of the native DNA was used, homologous duplexes exhibited a thermal stability similar to that of native DNA. At 35 C below the T(m), a considerable proportion of the duplexes were of much lower stability; at 40 C below the T(m), most of the duplexes were of much lower stability. Similar duplexes of low stability were also formed between DNA molecules from morphologically and nutritionally diverse organisms, provided the GC percentages of the DNA preparations were similar. Competition between unlabeled and labeled DNA fragments for binding sites on immobilized DNA was also greatly influenced by the incubation temperature. Heterologous DNA-DNA complexes exhibited thermal stabilities which correlated with measurements of DNA homology in experiments involving competition. In addition, the difference in thermal stabilities of heterologous and homologous DNA complexes (DeltaT'(m)) may provide a measure of divergence in nucleotide sequences.

Identification of Mycoplasma and other microorganisms by polyacrylamide-gel electrophoresis of cell proteins

The proteins of Mycoplasma cells of various species produce highly reproducible and species-specific electrophoretic patterns in polyacrylamide gels containing 5 m urea and 35% acetic acid. These electrophoretic patterns can be used for the rapid identification and classification of Mycoplasma. Preliminary results indicate that this method may also be used for the identification and classification of other microorganisms.

Deoxyribonucleic acid homology and taxonomy of Agrobacterium, Rhizobium, and Chromobacterium

Hybridization experiments were carried out between high molecular weight, denatured, agar-embedded deoxyribonucleic acid (DNA) and homologous, nonembedded, sheared, denatured (14)C-labeled DNA from a strain of Agrobacterium tumefaciens and Rhizobium leguminosarum (the reference strains) in the presence of sheared, nonembedded, nonlabeled DNA (competing DNA) from the same or different nomen-species of Agrobacterium, Rhizobium, Chromobacterium, and several other organisms. Percentage of DNA homology was calculated from the results. The findings are discussed in relation to previous taximetric studies, present classification schemes, and guanine-cytosine content of the DNA. Strains of A. tumefaciens, A. radiobacter, A. rubi, A. rhizogenes, R. leguminosarum, and R. meliloti exhibited a mean percentage of DNA homology greater than 50 with the two reference strains. A. tumefaciens, A. radiobacter, and A. rubi were indistinguishable on the basis of DNA homology, with strain variations for this group involving up to 30% of their base sequences. The remainder of the organisms studied fall into at least six distinct genetic groups: (i) R. (Agrobacterium) rhizogenes, which is more homologous to R. leguminosarum than to the A. tumefaciens-A. radiobacter group; (ii) R. leguminosarum; (iii) R. meliloti; (iv) R. japonicum, which has a mean DNA homology of some 38 to 45% with the reference strains; (v) Chromobacterium, which is as genetically remote from the reference strains as, for example, Pseudomonas; and (vi) A. pseudotsugae strain 180, which has a DNA homology with A. tumefaciens and R. leguminosarum of only about 10%. Since this latter homology value is similar to what was found after hybridizations between the reference strains and organisms such as Escherichia coli and Bacillus subtilis, A. pseudotsugae should definitely be removed from the genus.