Genetic diversity of Agrobacterium species isolated from nodules of common bean and soybean in Brazil, Mexico, Ecuador and Mozambique, and description of the new species Agrobacterium fabacearum sp. nov.

Agrobacterium strains are associated with soil, plants and animals, and known mainly by their pathogenicity. We studied 14 strains isolated from nodules of healthy soybean and common bean plants in Brazil, Mexico, Ecuador and Mozambique. Sequence analysis of the 16S rRNA gene positioned the strains as Agrobacterium, but with low phylogenetic resolution. Multilocus sequence analysis (MLSA) of three partial housekeeping genes (glnII, gyrB and recA) positioned the strains in four distinct clades, with Agrobacterium pusense, Agrobacterium deltaense, Agrobacterium radiobacter and Agrobacterium sp. genomospecies G1. Analysis by BOX-PCR revealed high intraspecies diversity. Genomic analysis of representative strains of the three clades indicated that they carry the protelomerase telA gene, and MLSA analysis with six complete housekeeping genes (atpD, glnII, gyrB, recA, rpoB and thrC), as well as average nucleotide identity (less than 90 % with closest species) and digital DNA-DNA hybridization (less than 41 % with closest species) revealed that strain CNPSo 675T and Agrobacterium sp. genomospecies G1 compose a new species. Other phenotypic and genotypic characteristics were determined for the new clade. Although not able to re-nodulate the host, we hypothesize that several strains of Agrobacterium are endophytes in legume nodules, where they might contribute to plant growth. Our data support the description of the CNPSo 675T and Agrobacterium sp. genomospecies G1 strains as a new species, for which the name Agrobacterium fabacearum is proposed. The type strain is CNPSo 675T (=UMR 1457T=LMG 31642T) and is also deposited in other culture collections.

Taxonomy of rhizobia and agrobacteria from the Rhizobiaceae family in light of genomics.

Phylogenomic analyses showed two major superclades within the family Rhizobiaceae that corresponded to the Rhizobium/Agrobacterium and Shinella/Ensifer groups. Within the Rhizobium/Agrobacterium group, four highly supported clades were evident that could correspond to distinct genera. The Shinella/Ensifer group encompassed not only the genera Shinella and Ensifer but also a separate clade containing the type strain of Rhizobium giardinii. Ensifer adhaerens (Casida A(T)) was an outlier within its group, separated from the rest of the Ensifer strains. The phylogenomic analysis presented provided support for the revival of Allorhizobium as a bona fide genus within the Rhizobiaceae, the distinctiveness of Agrobacterium and the recently proposed Neorhizobium genus, and suggested that R. giardinii may be transferred to a novel genus. Genomics has provided data for defining bacterial-species limits from estimates of average nucleotide identity (ANI) and in silico DNA-DNA hybridization (DDH). ANI reference values are becoming the gold standard in rhizobial taxonomy and are being used to recognize novel rhizobial lineages and species that seem to be biologically coherent, as shown in this study.

Diversidad de cepas de Agrobacterium rubi aisladas de arándanos / Agrobacterium rubi strains from blueberry plants are highly diverse

Se estudió la diversidad de una colección de cepas de Agrobacterium rubi aisladas de arándanos provenientes de distintas regiones de la República Argentina estableciendo su grado de heterogeneidad mediante pruebas microbiológicas clásicas y técnicas de biología molecular. Los resultados obtenidos en las pruebas bioquímicas y fisiológicas, así como mediante rep-PCR y RFLP del gen 23S ADNr, demostraron una alta variabilidad intraespecífica, tanto fenotípica como genotípica

The diversity of a collection of Agrobacterium rubi strains isolated from blueberries from different regions of Argentina was studied by conventional microbiological tests and molecular techniques. Results from biochemical and physiological reactions, as well as from rep-PCR and RFLP analysis of PCR-amplified 23S rDNA showed high phenotypic and genotypic intraspecific variation

Métodos para la detección de Agrobacterium a partir de muestras de material vegetal, suelo y agua / Methods for the detection of Agrobacterium from plant, soil and water samples

El género Agrobacterium incluye especies ftopatógenas que inducen la formación de agallas en el cuello o la proliferación de raíces en cabellera en más de 600 especies de dicotiledóneas, y especies no patógenas cuyo hábitat natural es el suelo. Como no es posible erradicar a las especies patógenas y habida cuenta de que más del 80 % de las infecciones puede provenir de viveros, es importante evitar la diseminación de la enfermedad. Por ello, el objetivo de este trabajo ha sido desarrollar técnicas sensibles y precisas que, aisladamente o combinadas, permitan detectar la presencia de especies y biovares de Agrobacterium a partir de muestras de material vegetal, suelo y agua. Se comprobó que con la estrategia combinada de realizar aislamientos en los medios semiselectivos D1, D1-M y YEM-RCT; PCR multiplex sobre el gen 23S ADNr; PCR específca sobre los genes virC1 y virC2 y bioensayos en plántulas de pimiento cv. California Wonder y en hojas cortadas de kalanchoe, se reduce la posibilidad de obtener falsos negativos y/o falsos positivos. Por lo expuesto, esta combinación de técnicas constituye una herramienta adecuada para el diagnóstico de cepas patógenas de Agrobacterium a partir de distintos tipos de muestras.

The genus Agrobacterium includes phytopathogenic bacteria that induce the development of root crown galls and/or aerial galls at the base of the stem or hairy roots on more than 600 species of plants belonging to 90 dicotyledonous families and non-pathogenic species. These bacteria being natural soil inhabitants are particularly diffcult to eradicate, which is a problem in nurseries where more than 80% of infections occur. Since early detection is crucial to avoid the inadvertent spread of the disease, the aim of this work was to develop sensitive and precise identifcation techniques by using a set of semi-selective and differential culture media in combination with a specifc PCR to amplify a partial sequence derived from the virC operon, as well as a multiplex PCR on the basis of 23SrDNA sequences, and biological assays to identify and differentiate species and biovars of Agrobacterium obtained either from soil, water or plant samples. The combination of the different assays allowed us to reduce the number of false positive and negative results from bacteria isolated from any of the three types of samples. Therefore, the combination of multiplex PCR, specifc PCR, isolations in semi-selective D1, D1-M and YEM-RCT media combined with bioassays on cut leaves of Kalanchoe and seedlings of California Wonder pepper cultivar constitute an accurate tool to detect species and biovars of Agrobacterium for diagnostic purposes.

[Methods for the detection of Agrobacterium from plant, soil and water samples]. / Métodos para la detección de Agrobacterium a partir de muestras de material vegetal, suelo y agua.

The genus Agrobacterium includes phytopathogenic bacteria that induce the development of root crown galls and/or aerial galls at the base of the stem or hairy roots on more than 600 species of plants belonging to 90 dicotyledonous families and non-pathogenic species. These bacteria being natural soil inhabitants are particularly difficult to eradicate, which is a problem in nurseries where more than 80% of infections occur. Since early detection is crucial to avoid the inadvertent spread of the disease, the aim of this work was to develop sensitive and precise identification techniques by using a set of semi-selective and differential culture media in combination with a specific PCR to amplify a partial sequence derived from the virC operon, as well as a multiplex PCR on the basis of 23SrDNA sequences, and biological assays to identify and differentiate species and biovars of Agrobacterium obtained either from soil, water or plant samples. The combination of the different assays allowed us to reduce the number of false positive and negative results from bacteria isolated from any of the three types of samples. Therefore, the combination of multiplex PCR, specific PCR, isolations in semi-selective D1, D1-M and YEM-RCT media combined with bioassays on cut leaves of Kalanchoe and seedlings of California Wonder pepper cultivar constitute an accurate tool to detect species and biovars of Agrobacterium for diagnostic purposes.

On serch of bacterial species definition

The bacterial species concept was examined within the framework of plant and animal associated alpha-2 proteobacteria, taking into consideration the phylogenetic, taxonomic and biological approaches as well as the microbiologists' perception. The virtue of the phylogenetic approach is that it gives an evolutionary perspective of the bacterial lineage; however the methods used possess low resolution for defining species located at the terminal branches of the phylogenetic trees. The merit of the taxonomic approach is that species are defined on the basis of multiple characteristics allowing high resolution at the terminal branches of dendograms; its disadvantage is the inaccuracy in the earlier nodes. On an individual level, the qualitative biological characteristics used for the definition of species frequently reveal shortcomings because many of these properties are the result of coevolution, parallel evolution or the horizontal transfer of genes. Nevertheless, when considered together with the phylogenetic and taxonomic approaches, important uncertainties are discovered: these must be weighed if a practical definition of bacterial species is conceived. The microbiologists' perception is the criterion expressed by a group of sponsors who, based on scientific and practical grounds, propose a new bacterial species. The success of this new proposal is measured by its widespread acceptance and its permanence. A difficult problem concerned with defining bacterial species is how to distinguish if they are independent evolutionary units or if they are reticulate evolutionary units. In the first case the inherence is vertically transmitted as a result of binary fission and clonal expansion. This may be the case of some animal cell associated bacteria in which recombination appears to be precluded or exceptional. In the second case adaptive changes occurring within an individual can be horizontally transferred to many or all group members. This seems to be the condition of many intestinal and plant associated bacteria. Genetic drift and specialization in clonal bacteria will depend almost exclusively on mutation and internal genetic rearrangement processes, whereas specialization in reticulate bacteria will depend not only on these processes but in their genetic interactions with other bacterial strains. This uncertainty, which corresponds to the evolutionary process, is at the same time one of the key factors in defining a bacterial species