ABSTRACT
Abstract: Objective: To compare the genetic determinants involved in plant colonization or virulence in the reported genomes of K. variicola, K. quasipneumoniae and K. pneumoniae. Materials and methods: In silico comparisons and Jaccard analysis of genomic data were used. Fimbrial genes were detected by PCR. Biological assays were performed with plant and clinical isolates. Results: Plant colonization genes such as cellulases, catalases and hemagglutinins were mainly present in K. variicola genomes. Chromosomal β-lactamases were characteristic of this species and had been previously misclassified. K. variicola and K. pneumoniae isolates produced plant hormones. Conclusions: A mosaic distribution of different virulence- and plant-associated genes was found in K. variicola and in K. quasipneumoniae genomes. Some plant colonizing genes were found mainly in K. variicola genomes. The term plantanosis is proposed for plant-borne human infections.
Resumen: Objetivo: Comparar genes de colonización de plantas o de virulencia en los genomas reportados de K. variicola, K. quasipneumoniae y K. pneumoniae. Material y métodos: Se utilizaron análisis in silico y de Jaccard. Por PCR se detectaron genes de fimbrias. Se realizaron ensayos biológicos con aislados de plantas y clínicos. Resultados: Los genes de colonización de plantas como celulasas, catalasas y hemaglutininas se encontraron principalmente en genomas de K. variicola. Las β-lactamasas cromosómicas son características de la especie y en algunos casos estaban mal clasificadas. K. variicola y K. pneumoniae producen hormonas vegetales. Conclusiones: Se encontró una distribución en mosaico de los genes de asociación con plantas y de virulencia en K. variicola y K. quasipneumoniae. Principalmente en K. variicola se encontraron algunos genes involucrados en la colonización de plantas. Se propone el término plantanosis para las infecciones humanas de origen vegetal.
Subject(s)
Humans , Plants/microbiology , Klebsiella Infections/microbiology , Klebsiella/physiology , Bacterial Proteins/physiology , Bacterial Proteins/genetics , Virulence/genetics , Computer Simulation , Disease Reservoirs , Adaptation, Biological/genetics , Genome, Bacterial , Drug Resistance, Multiple, Bacterial , Gene Ontology , Genes, Bacterial , Klebsiella/enzymology , Klebsiella/genetics , Klebsiella/pathogenicityABSTRACT
Abstract: Objective: Due to the fact that K. variicola, K. quasipneumoniae and K. pneumoniae are closely related bacterial species, misclassification can occur due to mistakes either in normal biochemical tests or during submission to public databases. The objective of this work was to identify K. variicola and K. quasipneumoniae genomes misclassified in GenBank database. Materials and methods: Both rpoB phylogenies and average nucleotide identity (ANI) were used to identify a significant number of misclassified Klebsiella spp. genomes. Results: Here we report an update of K. variicola and K. Quasipneumoniae genomes correctly classified and a list of isolated genomes obtained from humans, plants, animals and insects, described originally as K. pneumoniae or K. variicola, but known now to be misclassified. Conclusions: This work contributes to recognize the extensive presence of K. variicola and K. quasipneumoniae isolates in diverse sites and samples.
Resumen: Objetivo: Identificar genomas mal clasificados de K. variicola, y K. quasipneumoniae en la base de datos del GenBank. Material y métodos: En el presente estudio se usaron tanto análisis filogenéticos usando rpoB como la identidad media de nucleótidos (ANI, por sus siglas en ingles) para identificar un número significativo de genomas del género Klebsiella. Resultados: Se reportó una actualización de genomas de K. variicola y K. quasipneumoniae correctamente clasificados y una lista de aquellos aislamientos obtenidos de seres humanos, plantas, animales e insectos, descritos originalmente como K. pneumoniae o K. variicola pero ahora se conoce que están mal clasificados. Conclusiones: Este trabajo contribuye a la presencia extensiva de aislamientos de K. variicola y K. quasipneumoniae en diversos sitios y muestras.
Subject(s)
Animals , Plants/microbiology , Ursidae/microbiology , Klebsiella Infections/microbiology , Bacterial Typing Techniques , Genome, Bacterial , Insecta/microbiology , Klebsiella/classification , Phylogeny , DNA, Bacterial , Sequence Analysis, DNAABSTRACT
Bacillus spp. are well known rhizosphere residents of many crops and usually show plant growth promoting (PGP) activities that include biocontrol capacity against some phytopatogenic fungi. Potato crops in the Andean Highlands of Peru face many nutritional and phytophatogenic problems that have a significant impact on production. In this context is important to investigate the natural presence of these microorganisms in the potato rhizosphere and propose a selective screening to find promising PGP strains. In this study, sixty three Bacillus strains isolated from the rhizosphere of native potato varieties growing in the Andean highlands of Peru were screened for in vitro antagonism against Rhizoctonia solani and Fusarium solani. A high prevalence (68 percent) of antagonists against R. solani was found. Ninety one percent of those strains also inhibited the growth of F. solani. The antagonistic strains were also tested for other plant growth promotion activities. Eighty one percent produced some level of the auxin indole-3-acetic acid, and 58 percent solubilized tricalcium phosphate. Phylogenetic analysis revealed that the majority of the strains belonged to the B. amyloliquefaciens species, while strains Bac17M11, Bac20M1 and Bac20M2 may correspond to a putative new Bacillus species. The results suggested that the rhizosphere of native potatoes growing in their natural habitat in the Andes is a rich source of Bacillus fungal antagonists, which have a potential to be used in the future as PGP inoculants to improve potato crop.
ABSTRACT
La resistencia bacteriana es un problema de salud pública causante de índices elevados de morbi-mortalidad hospitalaria. En la medida en que se usan los diferentes antibióticos se seleccionan bacterias resistentes a múltiples fármacos. El desarrollo de nuevas herramientas moleculares de la genómica y proteómica, como el PCR en tiempo real, pirosecuenciación de ADN, espectrometría de masas, microarreglos de ADN y bioinformática, permite conocer en forma más estrecha la fisiología y estructura de las bacterias y los mecanismos de resistencia a los antibióticos. Estos estudios hacen posible identificar nuevos blancos farmacológicos y diseñar antibióticos específicos para suministrar tratamientos más certeros que combatan las infecciones producidas por bacterias. Con estas técnicas también es posible la identificación rápida de los genes que confieren la resistencia a los antibióticos y el reconocimiento de las estructuras genéticas complejas como los integrones, que intervienen en la diseminación de los genes que producen la multirresistencia.
Bacterial resistance is a public health problem causing high rates of morbidity and mortality in hospital settings. To the extent that different antibiotics are used, bacteria resistant to multiple drugs are selected. The development of new molecular genomic and proteomic tools such as real-time PCR, DNA pyrosequencing, mass spectrometry, DNA microarrays, and bioinformatics allow for more in-depth knowledge about the physiology and structure of bacteria and mechanisms involved in antibiotic resistance. These studies identify new targets for drugs and design specific antibiotics to provide more accurate treatments to combat infections caused by bacteria. Using these techniques, it will also be possible to rapidly identify genes that confer resistance to antibiotics, and to identify complex genetic structures, such as integrons that are involved in the spread of genes that confer multidrug-resistance.
Subject(s)
Drug Resistance, Bacterial/genetics , Genetic Techniques , GenomicsABSTRACT
OBJECTIVE: In this work we report the molecular characterization of beta-lactam antibiotics resistance conferred by genes contained in plasmids from enterobacteria producing extended-spectrum beta-lactamases (ESBL). MATERIAL AND METHODS: Fourteen enterobacterial clinical isolates selected from a group of strains obtained from seven different hospitals in Mexico during 1990-1992 and 1996-1998 were analyzed at the Bacterial Resistance Laboratory (National Institute Public Health, Cuernavaca). Molecular characterization included PFGE, IEF of beta-lactamases, bacterial conjugation, PCR amplification and DNA sequencing, plasmid extraction and restriction. RESULTS: Isolates were genetically unrelated. ESBL identified were SHV-2 (5/14) and SHV-5 (9/14) type. Cephalosporin-resistance was transferable in 9 of 14 (64 percent) clinical isolates with only one conjugative plasmid, DNA finger printing showed a similar band pattern in plasmids. CONCLUSIONS: The dissemination of cephalosporin resistance was due to related plasmids carrying the ESBL genes.
OBJETIVO: En este trabajo se reporta la caracterización molecular de la resistencia a antibiótico beta-lactámicos conferida por genes contenidos en plásmidos de enterobacterias productoras de beta-lactamasas de espectro extendido (BLEEs). MATERIAL Y MÉTODOS: Catorce aislamientos clínicos de enterobacterias fueron seleccionados por conveniencia de un banco de cepas obtenidas de siete diferentes hospitales de México durante los periodos 1990-1992 y 1996-1998 y fueron procesados en el Laboratorio de Resistencia Bacteriana (Instituto Nacional de Salud Pública, Cuernavaca). En la caracterización se empleó PFGE, IEF para beta-lactamasas, conjugación bacteriana, amplificación por PCR y secuenciación de DNA, extracción y restricción de plásmidos. RESULTADOS: Las 14 cepas fueron no relacionadas genéticamente. Se identificaron BLEEs tipo SHV-2 (5/14) y SHV-5 (9/14). La resistencia a cefalosporinas fue transferida por conjugación en 9 de 14 (64 por ciento) aislamientos clínicos mediante un plásmido que mostró un patrón de restricción similar entre ellos. CONCLUSIÓN: Se sugiere que la diseminación de la resistencia a cefalosporinas fue debida a plásmidos relacionados que contienen los genes que codifican BLEEs.