Novel Tellurite-Amended Media and Specific Chromosomal and Ti Plasmid Probes for Direct Analysis of Soil Populations of Agrobacterium Biovars 1 and 2

Ecology and biodiversity studies of Agrobacterium spp. require tools such as selective media and DNA probes. Tellurite was tested as a selective agent and a supplement of previously described media for agrobacteria. The known biodiversity within the genus was taken into account when the selectivity of K₂TeO₃ was analyzed and its potential for isolating Agrobacterium spp. directly from soil was evaluated. A K₂TeO₃ concentration of 60 ppm was found to favor the growth of agrobacteria and restrict the development of other bacteria. Morphotypic analyses were used to define agrobacterial colony types, which were readily distinguished from other colonies. The typical agrobacterial morphotype allowed direct determination of the densities of agrobacterial populations from various environments on K₂TeO₃-amended medium. The bona fide agrobacterium colonies growing on media amended with K₂TeO₃ were confirmed to be Agrobacterium colonies by using 16S ribosomal DNA (rDNA) probes. Specific 16S rDNA probes were designed for Agrobacterium biovar 1 and related species (Agrobacterium rubi and Agrobacterium fici) and for Agrobacterium biovar 2. Specific pathogenic probes from different Ti plasmid regions were used to determine the pathogenic status of agrobacterial colonies. Various morphotype colonies from bulk soil suspensions were characterized by colony blot hybridization with 16S rDNA and pathogenic probes. All the Agrobacterium-like colonies obtained from soil suspensions on amended media were found to be bona fide agrobacteria. Direct colony counting of agrobacterial populations could be done. We found 10³ to 10⁴ agrobacteria · g of dry soil⁻¹ in a silt loam bulk soil cultivated with maize. All of the strains isolated were nonpathogenic bona fide Agrobacterium biovar 1 strains.     

Selective media for three biovars of Agrobacterium

Three selective media for the isolation of the three known biovars of Agrobacterium are described. Selectivity was based on carbon and nitrogen sources; L(—)-arabitol for biovar 1, erythritol for biovar 2 and a combination of tartrate and D-glutamate for biovar 3. The new media were compared with existing selective media. Recovery of agrobacteria from soil was very efficient and discrimination between the three biovars was satisfactory except for tartrate-utilising biovar 1 isolates which grew on the biovar 3 medium. Some strains of Pseudomonas sp. isolated from crown galls on vine could utilise octopine as a source of carbon and nitrogen.     

Seasonal fluctuations and long-term persistence of pathogenic populations of Agrobacterium spp. in soils

Short- and long-term persistence of pathogenic (i.e., tumor forming) agrobacteria in soil was investigated in six nursery plots with a history of high crown gall incidence. No pathogenic Agrobacterium strains were isolated in soil samples taken in fall and winter in any plots, but such strains were isolated from both bulk soils and weed rhizospheres (over 0.5 x 10(5) pathogenic CFU/g of bulk soil or rhizosphere) in three out of six plots in spring and summer. PCR amplifications of a vir sequence from DNA extracted from soil confirmed the presence of Ti plasmids in summer and their absence in fall and winter. The results indicate that strains that harbor a Ti plasmid had an unforeseen positive fitness versus Ti plasmid-free strains in soil and rhizosphere in spring and summer in spite of the apparent absence of tumor, and hence of opines. The gain of fitness occurred during a bloom of all cultivable agrobacteria observed only in conducive soils. An evolution of the pathogenic population was recorded during a 4-year period in one particularly conducive soil. In 1990, the pathogenic population in this soil consisted of only biovar 1 strains harboring both octopine- and nopaline-type Ti plasmids. In 1994, it consisted of only nopaline-type Ti plasmids equally distributed among biovar 1 and 2 strains. These results suggest that nopaline-type Ti plasmids conferred a better survival ability than octopine-type Ti plasmids to biovar 2 agrobacteria under the present field conditions.     

Seasonal Fluctuations and Long-Term Persistence of Pathogenic Populations of Agrobacterium spp. in Soils

Short- and long-term persistence of pathogenic (i.e., tumor forming) agrobacteria in soil was investigated in six nursery plots with a history of high crown gall incidence. No pathogenic Agrobacterium strains were isolated in soil samples taken in fall and winter in any plots, but such strains were isolated from both bulk soils and weed rhizospheres (over 0.5 × 10⁵ pathogenic CFU/g of bulk soil or rhizosphere) in three out of six plots in spring and summer. PCR amplifications of a vir sequence from DNA extracted from soil confirmed the presence of Ti plasmids in summer and their absence in fall and winter. The results indicate that strains that harbor a Ti plasmid had an unforeseen positive fitness versus Ti plasmid-free strains in soil and rhizosphere in spring and summer in spite of the apparent absence of tumor, and hence of opines. The gain of fitness occurred during a bloom of all cultivable agrobacteria observed only in conducive soils. An evolution of the pathogenic population was recorded during a 4-year period in one particularly conducive soil. In 1990, the pathogenic population in this soil consisted of only biovar 1 strains harboring both octopine- and nopaline-type Ti plasmids. In 1994, it consisted of only nopaline-type Ti plasmids equally distributed among biovar 1 and 2 strains. These results suggest that nopaline-type Ti plasmids conferred a better survival ability than octopine-type Ti plasmids to biovar 2 agrobacteria under the present field conditions.     

Isolation of Different Agrobacterium Biovars from a Natural Oak Savanna and Tallgrass Prairie

Populations of agrobacteria in excess of 10⁵ CFU/g were recovered from 12 soil and root samples obtained from the Allison Savanna, Minn., a natural oak savanna and tallgrass prairie which has never been disturbed agriculturally. Of 126 strains picked randomly from selective media, 54 were identified as Agrobacterium spp. Biovar 2 strains predominated (35 of 54), but these strains were distributed into three phenotypically distinct subgroups. Of the remaining Agrobacterium strains, four were biovar 1-2, one was biovar 1, and none were biovar 3. The last 14 Agrobacterium strains formed a homogeneous group which differed biochemically from the hitherto reported biovars. Opine utilization (coded for by genes on the tumor-inducing plasmid in pathogenic Agrobacterium spp.) by these agrobacteria was limited to two biovar 2 strains. In contrast, 10 nonfluorescent gram-negative strains utilized either nopaline or octopine as the sole carbon and nitrogen source. There may be a need to reexamine the source and role of opines in the terrestrial environment because (i) all of these opine utilizers were isolated from an environment free of crown gall, the only known terrestrial source of opines, and (ii) 83% of the opine utilizers were not Agrobacterium spp.     

Construction of physical map and mapping of chromosomal virulence genes of the biovar 3 Agrobacterium (Rhizobium vitis) strain K-Ag-1

Most plant pathogenic Agrobacterium strains have been classified into three biovars, "biovar 1 (A. tumefaciens; Rhizobium radiobacter), biovar 2 (A. rhizogenes; R. rhizogenes) and biovar 3 (A. vitis; R. vitis)". The bacteria possess diverse types of genomic organization depending on the biovar. Previous genomic physical maps indicated difference in location of rDNA and chromosomally-coded virulence genes between biovar 1 and 2 genomes. In order to understand biovar 3 genome and its evolution in relation to the biovar 1, 2 and 3 genomes, we constructed physical map of a pathogenic biovar 3 strain K-Ag-1 in this study. Its genome consisted of two circular chromosomes (3.6 and 1.1 Mbp in length), and three plasmids (560, 230 and 70 kbp). Gene mapping based on the physical map showed presence of two rDNA loci in the larger chromosome and at least one rDNA locus in the smaller chromosome. Six chromosomal virulence genes, namely chvA, chvD, chvE, glgP, exoC and ros were found in the larger chromosome and not in the smaller chromosome. The location of rDNA loci is similar with that of biovar 1 genome, whereas the location of chromosomal virulence genes is similar with that of biovar 2 genome despite of the closer 16S-rRNA based phylogenetic relation of biovar 3 with biovar 1 than with biovar 2. Genomic PFGE RFLP analysis revealed that the K-Ag-1 strain, which was isolated on a kiwifruit plant in Japan, has the closest intra-species relation with two strains isolated from grapevine plants in Japan among eight biovar 3 strains examined. This datum suggests that the line of the strain is a major one in biovar 3 in Japan. Evolution of the genome of the strain is discussed based on the data.     

Colonization of Wheat Root Hairs and Roots by Agrobacteria

Formation of extracellular structures in pure culture and in interaction with wheat root surface was studied by scanning and transmission electron microscopy. The effects of various factors (growth temperature as well as pretreatment of agrobacteria with kalanchoe extract, acetosyringone, and centrifugation) on formation of extracellular structures was tested. The data on Agrobacterium tumefaciens (wild-type strain C58 and mutants LBA2525 (virB2::lacZ) and LBA288 (without the Ti plasmid)) adhesion to wheat root surface and root hairs after pretreatment of agrobacteria with inducer of virulence genes (vir) acetosyringone were obtained. Formation of agrobacterial cell aggregates on wheat root hair tips was demonstrated. The proportion of root hairs with agrobacterial aggregates on the root hair tip insignificantly changed after pretreatment with acetosyringone but considerably increased after treatment of A. tumefaciens C58 and LBA2525 with kalanchoe leaf extract. The most active colonization of root hairs and formation of agrobacterial aggregates on hair root tips was observed at 22°C. The capacity of agrobacteria for adhesion on monocotyledon surface could be changed by pretreatment of bacteria with various surface-active substances. Bacterial cells subjected to centrifugation had a decreased capacity for attachment to both wheat root surface and root hairs. The relationship between the capacity for adhesion and pilus production in agrobacteria was considered.     

Characterization of Two Novel Biovar of <Emphasis Type="Italic">Agrobacterium tumefaciens</Emphasis> Isolated from Root Nodules of <Emphasis Type="Italic">Vicia faba</Emphasis>

A total of eight strains of bacteria were isolated from the root nodule of Vicia faba on the selective media of Rhizobium. Two of these strains produced phenotypically distinct mucoid colonies (one slow growing and the other fast growing) and were examined using a polyphasic approach for taxonomic identification. The two strains (MTCC 7405 and MTCC 7406) turned out to be new strains of biovar 1 Agrobacterium rather than Rhizobium, as they showed growth on alkaline medium as well as on 2% NaCl and neither catabolized lactose as the carbon source nor oxidized Tween-80. The distinctness between the two strains was marked with respect to their growth on dextrose and the production of lysine dihydrolase, ornithine decarboxylase and DNA G + C content. 16S rDNA sequencing and their comparison with the 16S rDNA sequences of previously described agrobacteria as well as rhizobia strains confirmed the novelty of the two strains. Both of the strains clustered with strains of Agrobacterium tumefaciens in the 16S rDNA-based phylogenetic tree. The phenotypic and biochemical properties of the two strains differed from those of the recognized biovar of A. tumefaciens. It is proposed that the strains MTCC 7405 and MTCC 7406 be classified as novel biovar of the species A. tumefaciens (Type strains MTCC 7405 = DQ383275 and MTCC 7406 = DQ383276).

Variability of the 5'-end of the large subunit rDNA and presence of a new short class of rRNA in Rhizobiaceae

E. EVGUENIEVA-HACKENBERG AND S. SELENSKA-POBELL. 1995. A highly variable region of DNA was found between positions 115 and 388 ( Escherichia coli numeration) of the large subunit (ls) rRNA genes of 55 rhizobial and agrobacterial strains. In each case this heterogeneity was accompanied by the presence of a new rRNA species approximately 130 bp long. This novel rRNA species corresponded to the 5'-end of the ls rRNA genes. An additional rRNA processing site was located in the central region of the remaining ls rRNA of many of the Rhizobium leguminosarum and Rh. etli strains, and in all of the agrobacteria studied, excepting the type strain of Agrobacterium vitis NCPPB 3554 and Agrobacterium sp. strain ChAg4.     

Characterization of plasmid-borne and chromosome-encoded traits of Agrobacterium biovar 1, 2, and 3 strains from France

We collected 111 Agrobacterium isolates from galls of various origins (most of them from France) and analyzed both their plasmid-borne and chromosome-encoded traits. Phenotypic analysis of these strains allowed their classification in three phena which exactly matched the delineation of biovars 1, 2, and 3. A fourth phenon was identified which comprises three atypical strains. The phenotypic analysis has also allowed us to identify 12 additional characteristics which could be used to identify the three biovars of Agrobacterium. Our results also suggest that biovar 1 and 2 represent distinct species. Analysis of plasmid-borne traits confirmed that tartrate utilization is a common feature of biovar 3 strains (now named Agrobacterium vitis) and of Agrobacterium grapevine strains in general. Among pathogenic strains of Agrobacterium, several exhibited unusual opine synthesis and degradation patterns, and one strain of biovar 3 induced tumors containing vitopine and a novel opine-like molecule derived from putrescine. We have named this compound ridéopine.     

Systemic movement of Agrobacterium tumefaciens in several plant species

AIMS: The systemic movement of Agrobacterium spp. inside plants of different species was studied to determine the most valuable diagnostic methodology for their detection. METHODS AND RESULTS: Pathogenic agrobacteria were detected by isolation and PCR in tissue away from primary tumours in tomato plants grown in the presence of Agrobacterium spp. Moreover, this bacterium was also able to induce secondary tumours beyond the inoculation site. In addition, the capacity of agrobacteria to translocate and induce secondary tumours was analysed in rose, grapevine, chrysanthemum, cherry and peach x almond hybrid GF677. No differences among strains of Agrobacterium spp. were detected in secondary tumour development, although some of them induced a significantly higher number of primary tumours in some species. Movement of inoculated pathogenic cells of four strains was also demonstrated in symptomless portions of the plant stems by isolation and PCR. Finally, pathogenic agrobacteria were detected in root, crown and stem portions of naturally infected walnuts. In all assays, PCR was the most efficient technique for detecting the movement of Agrobacterium spp. within the plants. CONCLUSIONS: Migration of agrobacteria inside plants is a complex phenomenon and more extensive than previously reported. Therefore, efficient and sensitive detection methods such as PCR must be used to select clean plants to avoid latent infections of Agrobacterium spp. SIGNIFICANCE AND IMPACT OF THE STUDY: The results show that migration of Agrobacterium spp. could be relatively frequent in several cultivated fruit trees, and systemic infections should be taken into account when designing strategies for controlling crown gall disease.     

Isolation and identification of N2-fixing microorganisms from the rhizosphere of Capparis spinosa (L.)

Four bacterial strains, Pseudomonas stutzeri var. mendocina, Comamonas sp., Agrobacterium tumefaciens biovar. 2 and Sphingobacterium sp., isolated from the rhizosphere of wild-grown caper (Capparis spinosa L.) plants were able to fix N₂ as shown by their growth in nitrogen-free medium and by the acetylene reduction test. P. stutzeri var. mendocina and Comamonas sp. contained DNA homologous to the Klebsiella pneumoniae M5a1 nifHDK genes. No hybridization was found with total DNA from either A. tumefaciens biovar. 2 or Sphingobacterium sp. using nifHDK probes from either K. pneumoniae or Rhizobium meliloti.     

Rapid and accurate species and genomic species identification and exhaustive population diversity assessment of Agrobacterium spp. using recA-based PCR

Agrobacteria are common soil bacteria that interact with plants as commensals, plant growth promoting rhizobacteria or alternatively as pathogens. Indigenous agrobacterial populations are composites, generally with several species and/or genomic species and several strains per species. We thus developed a recA-based PCR approach to accurately identify and specifically detect agrobacteria at various taxonomic levels. Specific primers were designed for all species and/or genomic species of Agrobacterium presently known, including 11 genomic species of the Agrobacterium tumefaciens complex (G1-G9, G13 and G14, among which only G2, G4, G8 and G14 still received a Latin epithet: pusense, radiobacter, fabrum and nepotum, respectively), A. larrymoorei, A. rubi, R. skierniewicense, A. sp. 1650, and A. vitis, and for the close relative Allorhizobium undicola. Specific primers were also designed for superior taxa, Agrobacterium spp. and Rhizobiaceace. Primer specificities were assessed with target and non-target pure culture DNAs as well as with DNAs extracted from composite agrobacterial communities. In addition, we showed that the amplicon cloning-sequencing approach used with Agrobacterium-specific or Rhizobiaceae-specific primers is a way to assess the agrobacterial diversity of an indigenous agrobacterial population. Hence, the agrobacterium-specific primers designed in the present study enabled the first accurate and rapid identification of all species and/or genomic species of Agrobacterium, as well as their direct detection in environmental samples.     

Rapid and Efficient Identification of Agrobacterium Species by recA Allele Analysis

The analysis of housekeeping recA gene sequences from 138 strains from 13 species or genomic species of Agrobacterium, nine being biovar 1 genomospecies, and the others Agrobacterium larrymoorei, Agrobacterium rubi, Agrobacterium sp. NCPPB 1650, and Agrobacterium vitis and one “former” Agrobacterium species, Rhizobium rhizogenes, led to the identification of 50 different recA alleles and to a clear delineation of the 14 species or genomospecies entirely consistent with that obtained by amplified fragment length polymorphism (AFLP) analysis. The relevance of a recA sequencing approach for epidemiological analyses was next assessed on agrobacterial Tunisian isolates. All Tunisian isolates were found to belong to the Agrobacterium tumefaciens/biovar 1 species complex by both biochemical tests and rrs sequencing. recA sequence analysis further permitted their unambiguous assignment to A. tumefaciens genomospecies G4, G6, G7, and G8 in total agreement with the results of an AFLP-based analysis. At subspecific level, several Tunisian recA alleles were novel, indicating the power and accuracy of recA-based typing for studies of Agrobacterium spp.     

Application of subtraction hybridization for the development of a Rhizobium leguminosarum biovar phaseoli and Rhizobium tropici group-specific DNA probe

Abstract A combined subtraction hybridization and polymerase chain reaction/amplification technique was used to develop a DNA probe which was specific for the Rhizobium leguminosarum biovar phaseoli and the Rhizobium tropici group. Total genomic DNA preparations from Rhizobium leguminosarum biovar viciae, Rhizobium leguminosarum biovar trifolii, Rhizobium sp., Agrobacterium tumefaciens, Rhizobium fredii, Bradyrhizobium japonicum, Bradyrhizobium ssp. and Rhizobium meliloti were pooled and used as subtracter DNA against total genomic DNA from the Rhizobium leguminosarum biovar phaseolo strain KIM5s. Only one round of subtraction hybridization at 65°C was necessary to remove all cross-hybridizing sequences. Dot blot hybridizations with total genomic DNA of the eight subtracter organisms and 29 bacteria of different groups confirmed the high specificity of the isolated DNA sequences. Dot blot hybridizations and total genomic DNA from ten different R. Leguminosarum biovar phaseoli and R. tropici strains resulted in strong hybridization signals for all strains tested. The DNA probe for the R. tropici and R. leguminosarum biovar phaseoli group was used for dot blot hybridization with DNA extracts from three tropical and one boreal soil. When correlated with data from Most Probable Number analyses the probe was capable of detecting as low as 3 × 10⁴ homologous indigenous rhizobia per g soil. The technique offers great benefits for the development of DNA probes for monitoring bacterial populations in environmental samples.     

Thin aggregative fimbriae and cellulose enhance long-term survival and persistence of Salmonella

Salmonella spp. are environmentally persistent pathogens that have served as one of the important models for understanding how bacteria adapt to stressful conditions. However, it remains poorly understood how they survive extreme conditions encountered outside their hosts. Here we show that the rdar morphotype, a multicellular phenotype characterized by fimbria- and cellulose-mediated colony pattern formation, enhances the resistance of Salmonella to desiccation. When colonies were stored on plastic for several months in the absence of exogenous nutrients, survival of wild-type cells was increased compared to mutants deficient in fimbriae and/or cellulose production. Differences between strains were further highlighted upon exposure to sodium hypochlorite, as cellulose-deficient strains were 1,000-fold more susceptible. Measurements of gene expression using luciferase reporters indicated that production of thin aggregative fimbriae (Tafi) may initiate formation of colony surface patterns characteristic of the rdar morphotype. We hypothesize that Tafi play a role in the organization of different components of the extracellular matrix. Conservation of the rdar morphotype among pathogenic S. enterica isolates and the survival advantages that it provides collectively suggest that this phenotype could play a role in the transmission of Salmonella between hosts.     

Transfer of genetic information from agrobacteria to bacterial and plant cells: membrane and supramembrane structures involved in transfer

The review deals with the supramembrane and membrane structures involved in the initial contact (attachment) of an agrobacterial cell with a bacterial or plant cell during the transfer of the agrobacterial genetic information. The relationships between the donor cell attachment to the recipient cell surface and the infection and conjugation processes are discussed. Experimental data on the recently found agrobacterial pili and surface protein rhicadhesin, which are involved in the conjugative transfer of the plasmid between agrobacteria, are considered. The role of adhesive and conjugative pili of E. coli in the initial and tight contacts is analyzed in the context of the recently proved similarity between the mechanisms of agrobacterial transformation in plants and conjugative transfer in bacteria. Possible involvement of the pilus in the conjugative transfer of agrobacterial DNA across the membranes of donor and recipient (bacterial and plant) cells is discussed.     

Phylogenetic analysis of 23S rRNA gene sequences of. Agrobacterium, Rhizobium and Sinorhizobium strains

The phylogenetic relationship among twelve Agrobacterium, four Rhizobium, and two Sinorhizobium strains originating from various host plants and geographical regions was studied by analysis of the 23S rDNA sequences. The study included Agrobacterium strains belonging to biovars 1, 2 (with tumor- or hairy-root inducing and non-pathogenic strains), A. vitis, A. rubi; representative species of the Rhizobium genus: R. galegae, R. leguminosarum and R. tropici and Sinorhizobium meliloti strains. The phylogenetic analysis showed that within Agrobacterium, the biovar designation was reflected in the 23S rDNA similarity and that strains of Agrobacterium and Rhizobium are closely related to each other. The results suggest that the taxonomic definition of Agrobacterium and Rhizobium should be considered for revision and that the Agrobacterium-biovar identity is probably a reliable taxonomic trait.     

Differentiated Gene Expression in Cells within Yeast Colonies

Yeast cells growing on solid media organize themselves into multicellular structures, colonies, exhibiting patterns specific for particular yeast strains. With the aim of identifying genes involved in regulations of the colony formation, we applied a new approach enabling the extensive screening of Saccharomyces cerevisiae genes, the expression of which is changed during colony development. We used the library of S. cerevisiae DNA fragments inserted in front of the lacZ gene lacking its own promoter. Colonies of transformants with a blue/white patterned morphotype, implying that the expression of the lacZ gene from the inserted yeast promoter is switched on and off during the colony formation, were isolated. We identified several genes with variable expression during colony morphogenesis, including CCR4, PAM1, MEP3, ADE5,7 and CAT2. S. cerevisiae strain deleted in the CCR4 gene forms colonies with less organized morphology when compared with the isogenic parental strain. The synchronization of the expression patterns of some of the isolated genes in neighboring colonies was observed.     

Identification of Genomic Species in Agrobacterium Biovar 1 by AFLP Genomic Markers

Biovar 1 of the genus Agrobacterium consists of at least nine genomic species that have not yet received accepted species names. However, rapid identification of these organisms in various biotopes is needed to elucidate crown gall epidemiology, as well as Agrobacterium ecology. For this purpose, the AFLP methodology provides rapid and unambiguous determination of the genomic species status of agrobacteria, as confirmed by additional DNA-DNA hybridizations. The AFLP method has been proven to be reliable and to eliminate the need for DNA-DNA hybridization. In addition, AFLP fragments common to all members of the three major genomic species of agrobacteria, genomic species G1 (reference strain, strain TT111), G4 (reference strain, strain B6, the type strain of Agrobacterium tumefaciens), and G8 (reference strain, strain C58), have been identified, and these fragments facilitate analysis and show the applicability of the method. The maximal infraspecies current genome mispairing (CGM) value found for the biovar 1 taxon is 10.8%, while the smallest CGM value found for pairs of genomic species is 15.2%. This emphasizes the gap in the distribution of genome divergence values upon which the genomic species definition is based. The three main genomic species of agrobacteria in biovar 1 displayed high infraspecies current genome mispairing values (9 to 9.7%). The common fragments of a genomic species are thus likely “species-specific” markers tagging the core genomes of the species.