bacterio.cict.fr/xz/yersinia.html) that are mostly harmless environmental organisms residing in soil and water [1]. Three Yersinia species are human pathogens, including Yersinia pseudotuberculosis, Yersinia enterocolitica and the plague agent Yersinia pestis OICR-9429 solubility dmso [2–4]. While the two former species are food-borne pathogens responsible primarily for enteric infections, Y. pestis is an ectoparasite-borne species responsible for deadly plague [2]. Moreover, Y. pestis
has been classified in the Centers for Disease Control’s (CDC’s) group A list of potential bioterrorism agents (http://www.bt.cdc.gov/agent/agentlist-category.asp). Thus, rapid and accurate methods of detection and identification are needed for the distinction of Y. pestis among other Yersinia species, as well as Yersinia organisms among other Enterobacteriaceae species. Conventional methods for the phenotypic identification of Yersinia organisms such as biochemical profiling are time-consuming: they require the manipulation of huge quantities Target Selective Inhibitor Library of potentially harmful pathogens and delay accurate identification beyond an appropriate time limit with respect to the medical management of patients and public
health issues. PCR-based techniques [5] and real-time PCR assays reduce these delays to a few hours but require expertise and expensive reagents [6]. Tipifarnib nmr Furthermore, due to the natural instability of Y. pestis plasmids and chromosomal regions, molecular analysis may lead to false negative results when targeting specific genomic regions such as the 3a signature sequence [7–9]. Recognition of the F1 capsular antigen by several immunological techniques has been used for the rapid detection and identification of Y. pestis collected from patients with suspected infections [10] and from skeleton specimens from historical plague burial sites [11]. The identification of bacteria by matrix-assisted laser desorption/ionization time-of-flight (MALDI-TOF) mass spectrometry (MS) has recently emerged as a
rapid Dimethyl sulfoxide and sensitive technology that provides protein profiles for the accurate identification of bacteria at the genus, species or sub-species level [12, 13]. In microbiology, MALDI-TOF-MS has a number of potential advantages over other typing methods. Specimen preparation is relatively simple and can be carried out within minutes. Furthermore, the technique does not require any taxon-specific or costly materials such as antibodies. The workflow is simple and fast and can be standardized for most bacterial species. In addition, many of the procedures for sample preparation, data acquisition, and evaluation can be automated. Although MALDI-TOF-MS has been applied to several Enterobacteriaceae species, including Y. enterocolitica [14], it has not been described for other pathogenic Yersinia species, and only one report has dealt with the avirulent Y. pestis vaccinal strain EV 76 [15].