Daniël J. Wurpel scite author profile

Chaperone-usher (CU) fimbriae are adhesive surface organelles common to many Gram-negative bacteria. Escherichia coli genomes contain a large variety of characterised and putative CU fimbrial operons, however, the classification and annotation of individual loci remains problematic. Here we describe a classification model based on usher phylogeny and genomic locus position to categorise the CU fimbrial types of E. coli. Using the BLASTp algorithm, an iterative usher protein search was performed to identify CU fimbrial operons from 35 E. coli (and one Escherichia fergusonnii) genomes representing different pathogenic and phylogenic lineages, as well as 132 Escherichia spp. plasmids. A total of 458 CU fimbrial operons were identified, which represent 38 distinct fimbrial types based on genomic locus position and usher phylogeny. The majority of fimbrial operon types occupied a specific locus position on the E. coli chromosome; exceptions were associated with mobile genetic elements. A group of core-associated E. coli CU fimbriae were defined and include the Type 1, Yad, Yeh, Yfc, Mat, F9 and Ybg fimbriae. These genes were present as intact or disrupted operons at the same genetic locus in almost all genomes examined. Evaluation of the distribution and prevalence of CU fimbrial types among different pathogenic and phylogenic groups provides an overview of group specific fimbrial profiles and insight into the ancestry and evolution of CU fimbriae in E. coli.

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Characterization of Two Homologous Disulfide Bond Systems Involved in Virulence Factor Biogenesis in Uropathogenic Escherichia coli CFT073

Totsika¹,

Heras

Wurpel³

et al. 2009

J Bacteriol

105

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Disulfide bond (DSB) formation is catalyzed by disulfide bond proteins and is critical for the proper folding and functioning of secreted and membrane-associated bacterial proteins. Uropathogenic Escherichia coli (UPEC) strains possess two paralogous disulfide bond systems: the well-characterized DsbAB system and the recently described DsbLI system. In the DsbAB system, the highly oxidizing DsbA protein introduces disulfide bonds into unfolded polypeptides by donating its redox-active disulfide and is in turn reoxidized by DsbB. DsbA has broad substrate specificity and reacts readily with reduced unfolded proteins entering the periplasm. The DsbLI system also comprises a functional redox pair; however, DsbL catalyzes the specific oxidative folding of the large periplasmic enzyme arylsulfate sulfotransferase (ASST). In this study, we characterized the DsbLI system of the prototypic UPEC strain CFT073 and examined the contributions of the DsbAB and DsbLI systems to the production of functional flagella as well as type 1 and P fimbriae. The DsbLI system was able to catalyze disulfide bond formation in several well-defined DsbA targets when provided in trans on a multicopy plasmid. In a mouse urinary tract infection model, the isogenic dsbAB deletion mutant of CFT073 was severely attenuated, while deletion of dsbLI or assT did not affect colonization.Disulfide bonds bridging cysteine pairs impart structural stability and protease resistance to secreted and membrane-associated proteins. Most organisms contain specific mechanisms for the formation of disulfide bonds in proteins, a process called oxidative protein folding. In bacteria, this folding process is catalyzed by the disulfide bond family of proteins (18,22). The best-characterized bacterial disulfide bond machinery is the Escherichia coli K-12 oxidative system, which consists of two enzymes, the periplasmic DsbA and the inner-membrane DsbB (25,35). DsbA is a monomeric protein comprising a thioredoxin (TRX) domain with an embedded helical insertion and a redox-active CPHC motif (34). This highly oxidizing protein introduces disulfide bonds into unfolded polypeptides by donating its redox-active disulfide (2, 4, 5), and as a result, the two cysteines contained in the CPHC catalytic motif become reduced. DsbB reoxidizes this cysteine pair and restores the oxidizing activity of DsbA, enabling it to assist the folding of a new substrate protein (21).The DsbAB oxidative protein folding system plays a welldocumented part in bacterial virulence. Several studies have demonstrated a direct role for both enzymes, particularly DsbA, in the biogenesis of virulence factors utilized by bacterial pathogens in various stages of the infection process (19). The protein forming the P-ring of E. coli flagella, FlgI, was one of the first DsbA substrates identified (10) and flagellum-mediated motility was subsequently demonstrated to require the presence of functional DsbA in several gram-negative pathogens, including Salmonella enterica (1), Proteus mirabilis (8), Erwinia carotovo...

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Uropathogenic Escherichia coli Mediated Urinary Tract Infection

Totsika¹,

Moriel²,

Idris³

et al. 2012

CDT

108

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Urinary tract infection (UTI) is among the most common infectious diseases of humans and is the most common nosocomial infection in the developed world. They cause significant morbidity and mortality, with approximately 150 million cases globally per year. It is estimated that 40-50% of women and 5% of men will develop a UTI in their lifetime, and UTI accounts for more than 1 million hospitalizations and $1.6 billion in medical expenses each year in the USA. Uropathogenic E. coli (UPEC) is the primary cause of UTI. This review presents an overview of the primary virulence factors of UPEC, the major host responses to infection of the urinary tract, the emergence of specific multidrug resistant clones of UPEC, antibiotic treatment options for UPEC-mediated UTI and the current state of vaccine strategies as well as other novel anti-adhesive and prophylactic approaches to prevent UTI. New and emerging themes in UPEC research are also discussed in the context of future outlooks.

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Identification of Novel Vaccine Candidates against Multidrug-Resistant Acinetobacter baumannii

et al. 2013

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Acinetobacter baumannii is an emerging opportunistic bacterium associated with nosocomial infections in intensive care units. The alarming increase in infections caused by A. baumannii is strongly associated with enhanced resistance to antibiotics, in particular carbapenems. This, together with the lack of a licensed vaccine, has translated into significant economic, logistic and health impacts to health care facilities. In this study, we combined reverse vaccinology and proteomics to identify surface-exposed and secreted antigens from A. baumannii. Using in silico prediction tools and comparative genome analysis in combination with in vitro proteomic approaches, we identified 42 antigens that could be used as potential vaccine targets. Considering the paucity of effective antibiotics available to treat multidrug-resistant A. baumannii infections, these vaccine targets may serve as a framework for the development of a broadly protective multi-component vaccine, an outcome that would have a major impact on the burden of A. baumannii infections in intensive care units across the globe.

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Comparative analysis of the uropathogenic Escherichia coli surface proteome by tandem mass-spectrometry of artificially induced outer membrane vesicles

Wurpel

Moriel

Totsika

et al. 2015

Journal of Proteomics

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Daniël J. Wurpel

Chaperone-Usher Fimbriae of Escherichia coli

Characterization of Two Homologous Disulfide Bond Systems Involved in Virulence Factor Biogenesis in Uropathogenic Escherichia coli CFT073

Uropathogenic Escherichia coli Mediated Urinary Tract Infection

Identification of Novel Vaccine Candidates against Multidrug-Resistant Acinetobacter baumannii

Comparative analysis of the uropathogenic Escherichia coli surface proteome by tandem mass-spectrometry of artificially induced outer membrane vesicles

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