Your search keyword '"Valero-Rello, A"' showing total 11 results

1. An Invertron-Like Linear Plasmid Mediates Intracellular Survival and Virulence in Bovine Isolates of Rhodococcus equi.

Author

Valero-Rello A, Hapeshi A, Anastasi E, Alvarez S, Scortti M, Meijer WG, MacArthur I, and Vázquez-Boland JA

Subjects

Animals, Cattle, Cluster Analysis, Conjugation, Genetic, DNA, Bacterial chemistry, DNA, Bacterial genetics, Gene Transfer, Horizontal, Genes, Bacterial, Mice, Inbred BALB C, Molecular Sequence Data, Phylogeny, Rhodococcus equi genetics, Rhodococcus equi growth & development, Rhodococcus equi isolation & purification, Sequence Analysis, DNA, Sequence Homology, Virulence, Virulence Factors genetics, Macrophages microbiology, Microbial Viability, Plasmids, Rhodococcus equi physiology

Abstract

We report a novel host-associated virulence plasmid in Rhodococcus equi, pVAPN, carried by bovine isolates of this facultative intracellular pathogenic actinomycete. Surprisingly, pVAPN is a 120-kb invertron-like linear replicon unrelated to the circular virulence plasmids associated with equine (pVAPA) and porcine (pVAPB variant) R. equi isolates. pVAPN is similar to the linear plasmid pNSL1 from Rhodococcus sp. NS1 and harbors six new vap multigene family members (vapN to vapS) in a vap pathogenicity locus presumably acquired via en bloc mobilization from a direct predecessor of equine pVAPA. Loss of pVAPN rendered R. equi avirulent in macrophages and mice. Mating experiments using an in vivo transconjugant selection strategy demonstrated that pVAPN transfer is sufficient to confer virulence to a plasmid-cured R. equi recipient. Phylogenetic analyses assigned the vap multigene family complement from pVAPN, pVAPA, and pVAPB to seven monophyletic clades, each containing plasmid type-specific allelic variants of a precursor vap gene carried by the nearest vap island ancestor. Deletion of vapN, the predicted "bovine-type" allelic counterpart of vapA, essential for virulence in pVAPA, abrogated pVAPN-mediated intramacrophage proliferation and virulence in mice. Our findings support a model in which R. equi virulence is conferred by host-adapted plasmids. Their central role is mediating intracellular proliferation in macrophages, promoted by a key vap determinant present in the common ancestor of the plasmid-specific vap islands, with host tropism as a secondary trait selected during coevolution with specific animal species., (Copyright © 2015, American Society for Microbiology. All Rights Reserved.)

Published

2015

2. Rhodococcus equi: the many facets of a pathogenic actinomycete.

Author

Vázquez-Boland JA, Giguère S, Hapeshi A, MacArthur I, Anastasi E, and Valero-Rello A

Subjects

Actinomycetales Infections microbiology, Actinomycetales Infections pathology, Actinomycetales Infections transmission, Animals, Horse Diseases transmission, Horses, Host Specificity, Humans, Phagocytosis genetics, Plasmids genetics, Rhodococcus equi genetics, Rhodococcus equi pathogenicity, Actinomycetales Infections veterinary, Horse Diseases microbiology, Horse Diseases pathology, Rhodococcus equi physiology

Abstract

Rhodococcus equi is a soil-dwelling pathogenic actinomycete that causes pulmonary and extrapulmonary pyogranulomatous infections in a variety of animal species and people. Young foals are particularly susceptible and develop a life-threatening pneumonic disease that is endemic at many horse-breeding farms worldwide. R. equi is a facultative intracellular parasite of macrophages that replicates within a modified phagocytic vacuole. Its pathogenicity depends on a virulence plasmid that promotes intracellular survival by preventing phagosome-lysosome fusion. Species-specific tropism of R. equi for horses, pigs and cattle appears to be determined by host-adapted virulence plasmid types. Molecular epidemiological studies of these plasmids suggest that human R. equi infection is zoonotic. Analysis of the recently determined R. equi genome sequence has identified additional virulence determinants on the bacterial chromosome. This review summarizes our current understanding of the clinical aspects, biology, pathogenesis and immunity of this fascinating microbe with plasmid-governed infectivity., (Copyright © 2013 Elsevier B.V. All rights reserved.)

Published

2013

3. Genome and proteome analysis of phage E3 infecting the soil-borne actinomycete Rhodococcus equi.

Author

Salifu SP, Valero-Rello A, Campbell SA, Inglis NF, Scortti M, Foley S, and Vázquez-Boland JA

Subjects

Bacteriophages isolation & purification, DNA, Viral genetics, Myoviridae isolation & purification, Open Reading Frames, Phylogeny, Proteome genetics, Proteomics methods, Sequence Analysis, DNA, Soil Microbiology, Viral Proteins genetics, Virion genetics, Bacteriophages genetics, Genome, Viral, Myoviridae genetics, Proteome analysis, Rhodococcus equi virology

Abstract

We report on the characterization and genomic analysis of bacteriophage E3 isolated from soil and propagating in Rhodococcus equi strains. Phage E3 has a circular genome of 142 563 bp and is the first Myoviridae reported for the genus Rhodococcus and for a non-mycobacterial actinomycete. Phylogenetic analyses placed E3 in a distinct Myoviridae clade together with Mycobacterium phages Bxz1 and Myrna. The highly syntenic genomes of this myoviridal group comprise vertically evolving core phage modules flanked by hyperplastic regions specific to each phage and rich in horizontally acquired DNA. The hyperplastic regions contain numerous tRNA genes in the mycobacteriophages which are absent in E3, possibly reflecting bacterial host-specific translation-related phage fitness constraints associated with rate-limiting tRNAs. A structural proteome analysis identified 28 E3 polypeptides, including 15 not previously known to be virion-associated proteins. The E3 genome and comparative analysis provide insight into short-term genome evolution and adaptive plasticity in tailed phages from the environmental microbiome., (© 2012 Society for Applied Microbiology and Blackwell Publishing Ltd.)

Published

2013

4. The genome of a pathogenic rhodococcus: cooptive virulence underpinned by key gene acquisitions.

Author

Letek M, González P, Macarthur I, Rodríguez H, Freeman TC, Valero-Rello A, Blanco M, Buckley T, Cherevach I, Fahey R, Hapeshi A, Holdstock J, Leadon D, Navas J, Ocampo A, Quail MA, Sanders M, Scortti MM, Prescott JF, Fogarty U, Meijer WG, Parkhill J, Bentley SD, and Vázquez-Boland JA

Subjects

Adaptation, Physiological genetics, Animals, Chromosomes, Bacterial genetics, Gene Duplication genetics, Gene Regulatory Networks genetics, Gene Transfer, Horizontal genetics, Genetic Loci genetics, Genomics, Intracellular Space microbiology, Kinetics, Macrophages cytology, Macrophages microbiology, Mice, Mutation genetics, Phylogeny, Plasmids genetics, Rhodococcus equi genetics, Rhodococcus equi growth & development, Rhodococcus equi ultrastructure, Virulence genetics, Evolution, Molecular, Genes, Bacterial genetics, Rhodococcus equi pathogenicity

Abstract

We report the genome of the facultative intracellular parasite Rhodococcus equi, the only animal pathogen within the biotechnologically important actinobacterial genus Rhodococcus. The 5.0-Mb R. equi 103S genome is significantly smaller than those of environmental rhodococci. This is due to genome expansion in nonpathogenic species, via a linear gain of paralogous genes and an accelerated genetic flux, rather than reductive evolution in R. equi. The 103S genome lacks the extensive catabolic and secondary metabolic complement of environmental rhodococci, and it displays unique adaptations for host colonization and competition in the short-chain fatty acid-rich intestine and manure of herbivores--two main R. equi reservoirs. Except for a few horizontally acquired (HGT) pathogenicity loci, including a cytoadhesive pilus determinant (rpl) and the virulence plasmid vap pathogenicity island (PAI) required for intramacrophage survival, most of the potential virulence-associated genes identified in R. equi are conserved in environmental rhodococci or have homologs in nonpathogenic Actinobacteria. This suggests a mechanism of virulence evolution based on the cooption of existing core actinobacterial traits, triggered by key host niche-adaptive HGT events. We tested this hypothesis by investigating R. equi virulence plasmid-chromosome crosstalk, by global transcription profiling and expression network analysis. Two chromosomal genes conserved in environmental rhodococci, encoding putative chorismate mutase and anthranilate synthase enzymes involved in aromatic amino acid biosynthesis, were strongly coregulated with vap PAI virulence genes and required for optimal proliferation in macrophages. The regulatory integration of chromosomal metabolic genes under the control of the HGT-acquired plasmid PAI is thus an important element in the cooptive virulence of R. equi., Competing Interests: The authors have declared that no competing interests exist.

Published

2010

5. Genome and proteome analysis of phage E3 infecting the soil-borne actinomyceteRhodococcus equi

Author

José A. Vázquez-Boland, Neil F Inglis, Sophie Foley, Mariela Scortti, Samson Pandam Salifu, Samantha A Campbell, and Ana Valero-Rello

Subjects

Genetics, Bacteriophage, Genome evolution, Mycobacteriophages, biology, Proteome, Myoviridae, Rhodococcus equi, biology.organism_classification, Agricultural and Biological Sciences (miscellaneous), Gene, Genome, Ecology, Evolution, Behavior and Systematics

Abstract

We report on the characterization and genomic analysis of bacteriophage E3 isolated from soil and propagating in Rhodococcus equi strains. Phage E3 has a circular genome of 142 563 bp and is the first Myoviridae reported for the genus Rhodococcus and for a non-mycobacterial actinomycete. Phylogenetic analyses placed E3 in a distinct Myoviridae clade together with Mycobacterium phages Bxz1 and Myrna. The highly syntenic genomes of this myoviridal group comprise vertically evolving core phage modules flanked by hyperplastic regions specific to each phage and rich in horizontally acquired DNA. The hyperplastic regions contain numerous tRNA genes in the mycobacteriophages which are absent in E3, possibly reflecting bacterial host-specific translation-related phage fitness constraints associated with rate-limiting tRNAs. A structural proteome analysis identified 28 E3 polypeptides, including 15 not previously known to be virion-associated proteins. The E3 genome and comparative analysis provide insight into short-term genome evolution and adaptive plasticity in tailed phages from the environmental microbiome.

Published

2013

6. An Invertron-Like Linear Plasmid Mediates Intracellular Survival and Virulence in Bovine Isolates of Rhodococcus equi

Author

Ana Valero-Rello, Elisa Anastasi, Wim G. Meijer, José A. Vázquez-Boland, Iain MacArthur, Mariela Scortti, Alexia Hapeshi, and Sonsiray Alvarez

Subjects

DNA, Bacterial, Gene Transfer, Horizontal, Virulence Factors, Molecular Sequence Data, Immunology, Sequence Homology, Virulence, Host tropism, Microbiology, Bacterial genetics, Plasmid, Rhodococcus equi, Animals, Cluster Analysis, Replicon, Gene, Phylogeny, Genetics, Mice, Inbred BALB C, Microbial Viability, biology, Macrophages, Intracellular parasite, Sequence Analysis, DNA, Bacterial Infections, biology.organism_classification, bacterial infections and mycoses, respiratory tract diseases, Infectious Diseases, Genes, Bacterial, Conjugation, Genetic, Cattle, Parasitology, Plasmids

Abstract

We report a novel host-associated virulence plasmid in Rhodococcus equi , pVAPN, carried by bovine isolates of this facultative intracellular pathogenic actinomycete. Surprisingly, pVAPN is a 120-kb invertron-like linear replicon unrelated to the circular virulence plasmids associated with equine (pVAPA) and porcine (pVAPB variant) R. equi isolates. pVAPN is similar to the linear plasmid pNSL1 from Rhodococcus sp. NS1 and harbors six new vap multigene family members ( vapN to vapS ) in a vap pathogenicity locus presumably acquired via en bloc mobilization from a direct predecessor of equine pVAPA. Loss of pVAPN rendered R. equi avirulent in macrophages and mice. Mating experiments using an in vivo transconjugant selection strategy demonstrated that pVAPN transfer is sufficient to confer virulence to a plasmid-cured R. equi recipient. Phylogenetic analyses assigned the vap multigene family complement from pVAPN, pVAPA, and pVAPB to seven monophyletic clades, each containing plasmid type-specific allelic variants of a precursor vap gene carried by the nearest vap island ancestor. Deletion of vapN , the predicted “bovine-type” allelic counterpart of vapA , essential for virulence in pVAPA, abrogated pVAPN-mediated intramacrophage proliferation and virulence in mice. Our findings support a model in which R. equi virulence is conferred by host-adapted plasmids. Their central role is mediating intracellular proliferation in macrophages, promoted by a key vap determinant present in the common ancestor of the plasmid-specific vap islands, with host tropism as a secondary trait selected during coevolution with specific animal species.

Published

2015

7. Rhodococcus equi: the many facets of a pathogenic actinomycete

Author

Ana Valero-Rello, Steeve Giguère, Iain MacArthur, Alexia Hapeshi, José A. Vázquez-Boland, and Elisa Anastasi

Subjects

Facultative parasite, Infectivity, Whole genome sequencing, General Veterinary, biology, animal diseases, Virulence, General Medicine, biology.organism_classification, Microbiology, Virology, Host Specificity, Plasmid, Phagocytosis, Immunity, Rhodococcus equi, Animals, Humans, Horse Diseases, Horses, Actinomycetales Infections, Tropism, Plasmids

Abstract

Rhodococcus equi is a soil-dwelling pathogenic actinomycete that causes pulmonary and extrapulmonary pyogranulomatous infections in a variety of animal species and people. Young foals are particularly susceptible and develop a life-threatening pneumonic disease that is endemic at many horse-breeding farms worldwide. R. equi is a facultative intracellular parasite of macrophages that replicates within a modified phagocytic vacuole. Its pathogenicity depends on a virulence plasmid that promotes intracellular survival by preventing phagosome–lysosome fusion. Species-specific tropism of R. equi for horses, pigs and cattle appears to be determined by host-adapted virulence plasmid types. Molecular epidemiological studies of these plasmids suggest that human R. equi infection is zoonotic. Analysis of the recently determined R. equi genome sequence has identified additional virulence determinants on the bacterial chromosome. This review summarizes our current understanding of the clinical aspects, biology, pathogenesis and immunity of this fascinating microbe with plasmid-governed infectivity.

Published

2013

8. Genome and proteome analysis of phage E3 infecting the soil-borne actinomyceteRhodococcus equi: Rhodococcusbacteriophage E3

Author

Salifu, Samson Pandam, Valero-Rello, Ana, Campbell, Samantha A., Inglis, Neil F., Scortti, Mariela, Foley, Sophie, Vázquez-Boland, José A, Salifu, Samson P., and Vázquez-Boland, José A.

Subjects

579 Microorganisms, fungi & algae, Rhodococcus equi, Myoviridae, adaptive plasticity, bacteriophage E3, QR Microbiology, genome evolution

Abstract

We report on the characterization and genomic analysis of bacteriophage E3 isolated from soil and propagating in Rhodococcus equi strains. Phage E3 has a circular genome of 142 563 bp and is the first Myoviridae reported for the genus Rhodococcus and for a non-mycobacterial actinomycete. Phylogenetic analyses placed E3 in a distinct Myoviridae clade together with Mycobacterium phages Bxz1 and Myrna. The highly syntenic genomes of this myoviridal group comprise vertically evolving core phage modules flanked by hyperplastic regions specific to each phage and rich in horizontally acquired DNA. The hyperplastic regions contain numerous tRNA genes in the mycobacteriophages which are absent in E3, possibly reflecting bacterial host-specific translation-related phage fitness constraints associated with rate-limiting tRNAs. A structural proteome analysis identified 28 E3 polypeptides, including 15 not previously known to be virion-associated proteins. The E3 genome and comparative analysis provide insight into short-term genome evolution and adaptive plasticity in tailed phages from the environmental microbiome.

Published

2013

9. Genome and proteome analysis of phage E3 infecting the soil-borne actinomycete Rhodococcus equi

Author

Samson P, Salifu, Ana, Valero-Rello, Samantha A, Campbell, Neil F, Inglis, Mariela, Scortti, Sophie, Foley, and José A, Vázquez-Boland

Subjects

Proteomics, Open Reading Frames, Viral Proteins, Proteome, Rhodococcus equi, Myoviridae, DNA, Viral, Virion, Bacteriophages, Genome, Viral, Sequence Analysis, DNA, Phylogeny, Soil Microbiology

Abstract

We report on the characterization and genomic analysis of bacteriophage E3 isolated from soil and propagating in Rhodococcus equi strains. Phage E3 has a circular genome of 142 563 bp and is the first Myoviridae reported for the genus Rhodococcus and for a non-mycobacterial actinomycete. Phylogenetic analyses placed E3 in a distinct Myoviridae clade together with Mycobacterium phages Bxz1 and Myrna. The highly syntenic genomes of this myoviridal group comprise vertically evolving core phage modules flanked by hyperplastic regions specific to each phage and rich in horizontally acquired DNA. The hyperplastic regions contain numerous tRNA genes in the mycobacteriophages which are absent in E3, possibly reflecting bacterial host-specific translation-related phage fitness constraints associated with rate-limiting tRNAs. A structural proteome analysis identified 28 E3 polypeptides, including 15 not previously known to be virion-associated proteins. The E3 genome and comparative analysis provide insight into short-term genome evolution and adaptive plasticity in tailed phages from the environmental microbiome.

Published

2012

10. Rhodococcus equi and Its Pathogenic Mechanisms

Author

José A. Vázquez-Boland, Ursula Fogarty, Michal Letek, Patricia González, Ana Valero-Rello, and Mariela Scortti

Subjects

Intracellular parasite, Cavitary pneumonia, Virulence, Biology, bacterial infections and mycoses, biology.organism_classification, medicine.disease, respiratory tract diseases, Microbiology, Plasmid, Genomic island, parasitic diseases, medicine, Rhodococcus equi, Pathogen, Tropism

Abstract

Rhodococcus equi is the only animal pathogen among the rhodococci. A soil inhabitant, R. equi is prevalent in the farm environment where it uses herbivore manure as growth substrate. In addition to its saprophytic lifestyle, R. equi has the ability to colonize animal host tissues, causing pyogranulomatous infections in a variety of mammals. Although clearly a multihost pathogen, R. equi is best known as the etiologic agent of a severe contagious bronchopneumonic disease in horses. It also causes deadly opportunistic infections in immunosuppressed individuals, particularly tuberculosis-like cavitary pneumonia in HIV-infected patients. R. equi is an intracellular parasite that replicates within a modified phagocytic vacuole in macrophages. Its pathogenicity depends on a horizontally-acquired genomic island carried on a virulence plasmid. This plasmid virulence locus encodes a family of surface-associated antigens, the Vap proteins. The products of the vap island confer the ability to survive within macrophages and recent evidence suggests they are also involved in infectious tropism towards specific animal host species (horses, pigs, and cattle). The complete DNA sequence of the R. equi genome has been recently determined and a detailed analysis will soon be published. This chapter reviews the current, “pregenomic” state of knowledge about the biology and virulence of this fascinating pathogenic actinomycete.

Published

2010

11. The genome of a pathogenic rhodococcus: cooptive virulence underpinned by key gene acquisitions

Author

M. Blanco, José A. Vázquez-Boland, Alain Ocampo, Michal Letek, Inna Cherevach, Tom C. Freeman, Jolyon Holdstock, Desmond P Leadon, John F. Prescott, Mandy Sanders, Tom Buckley, Ruth J. Fahey, Mariela Scortti, Michael A. Quail, Ursula Fogarty, Ana Valero-Rello, Jesús Navas, Héctor Rodríguez, Wim G. Meijer, Patricia González, Julian Parkhill, Stephen D. Bentley, Alexia Hapeshi, Iain MacArthur, and Universidad de Cantabria

Subjects

Cancer Research, Intracellular Space, Genome, Mice, Plasmid, Gene Duplication, Genetics(clinical), Gene Regulatory Networks, Rhodococcus equi, Pathogen, Genetics (clinical), Phylogeny, Genetics, 0303 health sciences, Microbiology/Microbial Evolution and Genomics, biology, Virulence, Genomics, Chromosomes, Bacterial, Adaptation, Physiological, Horizontal gene transfer, Plasmids, Research Article, lcsh:QH426-470, Gene Transfer, Horizontal, Microbiology, Evolution, Molecular, 03 medical and health sciences, QH301, Animals, Gene, Molecular Biology, QH426, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, QR355, 030306 microbiology, Macrophages, biology.organism_classification, bacterial infections and mycoses, Pathogenicity island, lcsh:Genetics, Kinetics, Genes, Bacterial, Genetic Loci, Mutation

Abstract

We report the genome of the facultative intracellular parasite Rhodococcus equi, the only animal pathogen within the biotechnologically important actinobacterial genus Rhodococcus. The 5.0-Mb R. equi 103S genome is significantly smaller than those of environmental rhodococci. This is due to genome expansion in nonpathogenic species, via a linear gain of paralogous genes and an accelerated genetic flux, rather than reductive evolution in R. equi. The 103S genome lacks the extensive catabolic and secondary metabolic complement of environmental rhodococci, and it displays unique adaptations for host colonization and competition in the short-chain fatty acid–rich intestine and manure of herbivores—two main R. equi reservoirs. Except for a few horizontally acquired (HGT) pathogenicity loci, including a cytoadhesive pilus determinant (rpl) and the virulence plasmid vap pathogenicity island (PAI) required for intramacrophage survival, most of the potential virulence-associated genes identified in R. equi are conserved in environmental rhodococci or have homologs in nonpathogenic Actinobacteria. This suggests a mechanism of virulence evolution based on the cooption of existing core actinobacterial traits, triggered by key host niche–adaptive HGT events. We tested this hypothesis by investigating R. equi virulence plasmid-chromosome crosstalk, by global transcription profiling and expression network analysis. Two chromosomal genes conserved in environmental rhodococci, encoding putative chorismate mutase and anthranilate synthase enzymes involved in aromatic amino acid biosynthesis, were strongly coregulated with vap PAI virulence genes and required for optimal proliferation in macrophages. The regulatory integration of chromosomal metabolic genes under the control of the HGT–acquired plasmid PAI is thus an important element in the cooptive virulence of R. equi., Author Summary Rhodococcus is a prototypic genus within the Actinobacteria, one of the largest microbial groups on Earth. Many of the ubiquitous rhodococcal species are biotechnologically useful due to their metabolic versatility and biodegradative properties. We have deciphered the genome of a facultatively parasitic Rhodococcus, the animal and human pathogen R. equi. Comparative genomic analyses of related species provide a unique opportunity to increase our understanding of niche-adaptive genome evolution and specialization. The environmental rhodococci have much larger genomes, richer in metabolic and degradative pathways, due to gene duplication and acquisition, not genome contraction in R. equi. This probably reflects that the host-associated R. equi habitat is more stable and favorable than the chemically diverse but nutrient-poor environmental niches of nonpathogenic rhodococci, necessitating metabolically more complex, expanded genomes. Our work also highlights that the recruitment or cooption of core microbial traits, following the horizontal acquistion of a few critical genes that provide access to the host niche, is an important mechanism in actinobacterial virulence evolution. Gene cooption is a key evolutionary mechanism allowing rapid adaptive change and novel trait acquisition. Recognizing the contribution of cooption to virulence provides a rational framework for understanding and interpreting the emergence and evolution of microbial pathogenicity.

Published

2010