Salmonella serovars
Anti-Salmonella immunity
Anti-Salmonella immunity: Highlighting new research in vaccines, mucosal immunology and systemic disease
from Jennifer L. Bishop, Ellen T. Arena, Kenneth W. Harder and B. Brett Finlay writing in Salmonella: From Genome to Function
Enteric fever and non-typhoidal salmonelloses (NTS) are caused by a wide variety of Salmonella enterica serovars and are a serious health threat throughout the world. Immunity to systemic typhoid and NTS requires intricate crosstalk between both innate and adaptive immune cells spanning multiple organ systems. The development of a number of new mouse and in vitro culture models suitable for studying gastroenteritis has highlighted the complexity of mucosal responses and shown how a diverse subset of cells interact within the intestinal architecture to elicit anti-Salmonella immunity. These include specific dendritic cell subsets, natural killer cells and TH17 skewed T helper cells and the repertoire of cytokines they produce, including IL-17, IL-23, IL-22 and IL-15. Furthermore, the importance of commensal microflora has been stressed in various Salmonella models, and new research has shown the various effects of prebiotics, probiotics and antibiotics on Salmonella pathogenesis. Systemic immune responses are also more explicitly understood, as the location and phenotype of cells harboring intracellular bacteria become more defined. A forthcoming book reviews these recent advances and how they are being translated into new therapies and vaccine studies in the human population.
Read more: Salmonella: From Genome to Function
from Jennifer L. Bishop, Ellen T. Arena, Kenneth W. Harder and B. Brett Finlay writing in Salmonella: From Genome to Function
Enteric fever and non-typhoidal salmonelloses (NTS) are caused by a wide variety of Salmonella enterica serovars and are a serious health threat throughout the world. Immunity to systemic typhoid and NTS requires intricate crosstalk between both innate and adaptive immune cells spanning multiple organ systems. The development of a number of new mouse and in vitro culture models suitable for studying gastroenteritis has highlighted the complexity of mucosal responses and shown how a diverse subset of cells interact within the intestinal architecture to elicit anti-Salmonella immunity. These include specific dendritic cell subsets, natural killer cells and TH17 skewed T helper cells and the repertoire of cytokines they produce, including IL-17, IL-23, IL-22 and IL-15. Furthermore, the importance of commensal microflora has been stressed in various Salmonella models, and new research has shown the various effects of prebiotics, probiotics and antibiotics on Salmonella pathogenesis. Systemic immune responses are also more explicitly understood, as the location and phenotype of cells harboring intracellular bacteria become more defined. A forthcoming book reviews these recent advances and how they are being translated into new therapies and vaccine studies in the human population.
Read more: Salmonella: From Genome to Function
Fimbriae of Salmonella
Fimbrial signature arrangements in Salmonella
from Sean-Paul Nuccio, Nicholas R. Thomson, Maria C. Fookes and Andreas J. Bäumler writing in Salmonella: From Genome to Function
The complement of fimbrial operons held within a genome represents one of the key differentiating features of the sequenced Salmonella serovars and one of the single largest sources of genetic diversity. Generically described as filamentous non-flagellar surface appendages, fimbriae (also known as pili) typically imbue an adhesive trait to the cells expressing them. While much is known about the general biology of fimbrial assembly mechanisms, the role of these structures in Salmonella pathogenesis remains poorly characterized. Here we present fimbrial operon data gathered from the seventeen completed Salmonella genome sequences and discuss its implications in Salmonella pathogenesis and dissemination.
Further reading: Salmonella: From Genome to Function | Pili and Flagella
from Sean-Paul Nuccio, Nicholas R. Thomson, Maria C. Fookes and Andreas J. Bäumler writing in Salmonella: From Genome to Function
The complement of fimbrial operons held within a genome represents one of the key differentiating features of the sequenced Salmonella serovars and one of the single largest sources of genetic diversity. Generically described as filamentous non-flagellar surface appendages, fimbriae (also known as pili) typically imbue an adhesive trait to the cells expressing them. While much is known about the general biology of fimbrial assembly mechanisms, the role of these structures in Salmonella pathogenesis remains poorly characterized. Here we present fimbrial operon data gathered from the seventeen completed Salmonella genome sequences and discuss its implications in Salmonella pathogenesis and dissemination.
Further reading: Salmonella: From Genome to Function | Pili and Flagella
Genomics and Pathogenesis of Salmonella
Genomics and Pathogenesis of Salmonella enterica serovars Typhi and Paratyphi A
from Kathryn E Holt, Tim T Perkins, Gordon Dougan and Robert A Kingsley writing in Salmonella: From Genome to Function
The genomics era has transformed the way that we can study bacterial pathogens. The availability of two complete and 17 draft genomes of S. Typhi has made it possible to study the phylogenetic structure of this pathogen in unparalleled resolution, monitor gene flux, accumulation of pseudogenes, neutral mutations and loci under selective pressure. We describe the molecular basis of Salmonella Typhi pathogenesis, in particular where genomics has contributed to our understanding in the past decade. Potentially important S. Typhi-specific virulence determinants include the Vi polysaccharide capsule, the type IV pilus, and a unique repertoire of fimbria. These may account for key differences in the disease outcome of this pathogen compared with non-typhoidal serotypes. Genome comparison with the closely related serotype S. Paratyphi A identifies a core set of pseudogenes, some of which emerged independently, that may define important features of genome degradation associated with host restriction and pathogenesis of invasive disease. Geo-phylogenetics of S. Typhi constructed from single nucleotide polymorphism data from high throughput draft genome sequences is now being applied to study molecular epidemiology in the field.
Further reading: Salmonella: From Genome to Function
from Kathryn E Holt, Tim T Perkins, Gordon Dougan and Robert A Kingsley writing in Salmonella: From Genome to Function
The genomics era has transformed the way that we can study bacterial pathogens. The availability of two complete and 17 draft genomes of S. Typhi has made it possible to study the phylogenetic structure of this pathogen in unparalleled resolution, monitor gene flux, accumulation of pseudogenes, neutral mutations and loci under selective pressure. We describe the molecular basis of Salmonella Typhi pathogenesis, in particular where genomics has contributed to our understanding in the past decade. Potentially important S. Typhi-specific virulence determinants include the Vi polysaccharide capsule, the type IV pilus, and a unique repertoire of fimbria. These may account for key differences in the disease outcome of this pathogen compared with non-typhoidal serotypes. Genome comparison with the closely related serotype S. Paratyphi A identifies a core set of pseudogenes, some of which emerged independently, that may define important features of genome degradation associated with host restriction and pathogenesis of invasive disease. Geo-phylogenetics of S. Typhi constructed from single nucleotide polymorphism data from high throughput draft genome sequences is now being applied to study molecular epidemiology in the field.
Further reading: Salmonella: From Genome to Function
Phages of Salmonella
Typing phages and prophages of Salmonella
from Wolfgang Rabsch, Sandra Truepschuch, Daniel Windhorst and Roman G. Gerlach writing in Salmonella: From Genome to Function:
Most Salmonella strains contain prophages or remnant phages and release them spontaneously. Special bacteriophages were developed and used in phage typing systems for epidemiological work all over the world since 1947 to control salmonellosis. This method provides fast and inexpensive characterization of frequent serovars such as S. Typhimurium or S. Typhi on the sub-serovar level and is especially useful for primary analysis before investigation by other, more expensive molecular techniques such as sequencing. Prophages are themselves not only variable elements in a chromosome but also variable by module exchange within the prophage genome, thus providing a high discriminating power. The availability of several genome sequences of different Salmonella serovars has recently led to the identification of new prophage-like elements. The prophages present in serovars Typhimurium, Enteritidis and Typhi are discussed. Salmonella phages frequently carry foreign DNA, so called morons. These morons are not necessary for phage functions but provide a benefit for the host. A list of some new morons found in different Salmonella serovars is presented. Recently, a monophasic variant of S. Typhimurium mainly belonging to Anderson phage type DT193 has become one of the dominant causes of salmonellosis in Germany and other European countries. These strains with the antigenic formula 4,[5],12:i:- do not express the 2nd phase flagellum. Investigation of their prophage attachment sites showed that the sites for Gifsy-1, Gifsy-2 and ST64B were occupied by the respective prophages. In about 90% of the monophasic DT193 strains the P22/ST64T attachment site was occupied by a novel 18.4 kb fragment, containing several open reading frames with significant similiarity to phage-related genes.
Further reading: Salmonella: From Genome to Function | Bacteriophage: Genetics and Molecular Biology
from Wolfgang Rabsch, Sandra Truepschuch, Daniel Windhorst and Roman G. Gerlach writing in Salmonella: From Genome to Function:
Most Salmonella strains contain prophages or remnant phages and release them spontaneously. Special bacteriophages were developed and used in phage typing systems for epidemiological work all over the world since 1947 to control salmonellosis. This method provides fast and inexpensive characterization of frequent serovars such as S. Typhimurium or S. Typhi on the sub-serovar level and is especially useful for primary analysis before investigation by other, more expensive molecular techniques such as sequencing. Prophages are themselves not only variable elements in a chromosome but also variable by module exchange within the prophage genome, thus providing a high discriminating power. The availability of several genome sequences of different Salmonella serovars has recently led to the identification of new prophage-like elements. The prophages present in serovars Typhimurium, Enteritidis and Typhi are discussed. Salmonella phages frequently carry foreign DNA, so called morons. These morons are not necessary for phage functions but provide a benefit for the host. A list of some new morons found in different Salmonella serovars is presented. Recently, a monophasic variant of S. Typhimurium mainly belonging to Anderson phage type DT193 has become one of the dominant causes of salmonellosis in Germany and other European countries. These strains with the antigenic formula 4,[5],12:i:- do not express the 2nd phase flagellum. Investigation of their prophage attachment sites showed that the sites for Gifsy-1, Gifsy-2 and ST64B were occupied by the respective prophages. In about 90% of the monophasic DT193 strains the P22/ST64T attachment site was occupied by a novel 18.4 kb fragment, containing several open reading frames with significant similiarity to phage-related genes.
Further reading: Salmonella: From Genome to Function | Bacteriophage: Genetics and Molecular Biology