Identification of <i>Yersinia pestis</i> and <i>Escherichia coli</i> Strains by Whole Cell and Outer Membrane Protein Extracts with Mass Spectrometry-Based Proteomics

Jabbour, Rabih E.; Wade, Mary Margaret; Deshpande, Samir V.; Stanford, Michael F.; Wick, Charles H.; Zulich, Alan W.; Snyder, A. Peter

doi:10.1021/pr100402y

Cited by 31 publications

(20 citation statements)

References 48 publications

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“…MS‐based methods have also been effectively applied to the identification and specific detection of biological agents by analysis of intact proteins and/or tryptic digests from bacterial cells . The recent literature also indicates that the quest for specific and reliable markers of pathogenic species, such as B. anthracis or Y. pestis, needs to be pursued especially for their unambiguous discrimination from closely related nonpathogenic species.…”

Section: Detection Of Microorganisms and Toxins In Environmental And mentioning

confidence: 99%

“…A first application in terms of CBRNE threats was proposed with the aim of discriminating and classifying strains of Bacillus anthracis , Bacillus cereus , and Bacillus thuringiensis . A second application was developed on another CBRNE relevant organism, namely, Yersinia pestis . More recently, strain‐specific peptides were shown to be useful for subspecies level discrimination, taking Helicobacter pylori as the pioneering example .…”

Section: Ms‐based Detection Of Pathogenic Microorganisms In a Clinicamentioning

confidence: 99%

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Mass spectrometry for the detection of bioterrorism agents: from environmental to clinical applications

Duriez¹,

Armengaud

Fenaille

et al. 2016

J. Mass Spectrom.

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In the current context of international conflicts and localized terrorist actions, there is unfortunately a permanent threat of attacks with unconventional warfare agents. Among these, biological agents such as toxins, microorganisms, and viruses deserve particular attention owing to their ease of production and dissemination. Mass spectrometry (MS)-based techniques for the detection and quantification of biological agents have a decisive role to play for countermeasures in a scenario of biological attacks. The application of MS to every field of both organic and macromolecular species has in recent years been revolutionized by the development of soft ionization techniques (MALDI and ESI), and by the continuous development of MS technologies (high resolution, accurate mass HR/AM instruments, novel analyzers, hybrid configurations). New possibilities have emerged for exquisite specific and sensitive detection of biological warfare agents. MS-based strategies for clinical application can now address a wide range of analytical questions mainly including issues related to the complexity of biological samples and their available volume. Multiplexed toxin detection, discovery of new markers through omics approaches, and identification of untargeted microbiological or of novel molecular targets are examples of applications. In this paper, we will present these technological advances along with the novel perspectives offered by omics approaches to clinical detection and follow-up.

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Section: Detection Of Microorganisms and Toxins In Environmental And mentioning

confidence: 99%

Section: Ms‐based Detection Of Pathogenic Microorganisms In a Clinicamentioning

confidence: 99%

Mass spectrometry for the detection of bioterrorism agents: from environmental to clinical applications

Duriez¹,

Armengaud

Fenaille

et al. 2016

J. Mass Spectrom.

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“…They have identified unique biomarkers specifically related to growth conditions. The OMPs are analyzed for a nonpathogenic Y. pestis A1122 strain by liquid chromatography–tandem MS (Jabbour et al, 2010) because OMPs are often associated with virulence in Gram-negative pathogens. However, this study only compares the OMPs between Y. pestis and E. coli , and comparative proteome analysis between pathogenic and non-pathogenic Y. pestis can help identify virulence-associated proteins more efficiently.…”

Section: Proteomics For Studying Y Pestis Virulencementioning

confidence: 99%

Omics strategies for revealing Yersinia pestis virulence

Yang¹,

Du²,

Han³

et al. 2012

Front. Cell. Inf. Microbio.

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Omics has remarkably changed the way we investigate and understand life. Omics differs from traditional hypothesis-driven research because it is a discovery-driven approach. Mass datasets produced from omics-based studies require experts from different fields to reveal the salient features behind these data. In this review, we summarize omics-driven studies to reveal the virulence features of Yersinia pestis through genomics, trascriptomics, proteomics, interactomics, etc. These studies serve as foundations for further hypothesis-driven research and help us gain insight into Y. pestis pathogenesis.

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“…It is beneficial for a pathogen to be able to adapt to new environmental niches. The genes that show the greatest sequence variations are often those that encode surface-exposed proteins, including outer membrane proteins (OMPs), that are the first to interact with the host (Suerbaum and Josenhans, 2007; Jabbour et al, 2010). The surface-exposed proteins have different functional roles; they function as adhesion factors (e.g., BabA and SabA), nutrient transporters, secreted toxins, iron-chelating proteins, and proteases, for example (Solis and Cordwell, 2011).…”

Section: Introductionmentioning

confidence: 99%

Comparative Analysis of Two Helicobacter pylori Strains using Genomics and Mass Spectrometry-Based Proteomics

et al. 2016

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Helicobacter pylori, a gastroenteric pathogen believed to have co-evolved with humans over 100,000 years, shows significant genetic variability. This motivates the study of different H. pylori strains and the diseases they cause in order to identify determinants for disease evolution. In this study, we used proteomics tools to compare two H. pylori strains. Nic25_A was isolated in Nicaragua from a patient with intestinal metaplasia, and P12 was isolated in Europe from a patient with duodenal ulcers. Differences in the abundance of surface proteins between the two strains were determined with two mass spectrometry-based methods, label-free quantification (MaxQuant) or the use of tandem mass tags (TMT). Each approach used a lipid-based protein immobilization (LPITM) technique to enrich peptides of surface proteins. Using the MaxQuant software, we found 52 proteins that differed significantly in abundance between the two strains (up- or downregulated by a factor of 1.5); with TMT, we found 18 proteins that differed in abundance between the strains. Strain P12 had a higher abundance of proteins encoded by the cag pathogenicity island, while levels of the acid response regulator ArsR and its regulatory targets (KatA, AmiE, and proteins involved in urease production) were higher in strain Nic25_A. Our results show that differences in protein abundance between H. pylori strains can be detected with proteomic approaches; this could have important implications for the study of disease progression.

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Identification of Yersinia pestis and Escherichia coli Strains by Whole Cell and Outer Membrane Protein Extracts with Mass Spectrometry-Based Proteomics

Cited by 31 publications

References 48 publications

Mass spectrometry for the detection of bioterrorism agents: from environmental to clinical applications

Mass spectrometry for the detection of bioterrorism agents: from environmental to clinical applications

Omics strategies for revealing Yersinia pestis virulence

Comparative Analysis of Two Helicobacter pylori Strains using Genomics and Mass Spectrometry-Based Proteomics

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