g , PCR/sequencing) is less feasible By extension, interest will

g., PCR/sequencing) is less feasible. By extension, interest will also be keen to assess the presence, distribution and regulation of β-lactamase expression in biofilms in device-associated infections. When employing the FLABs method for β-lactamase detection, three important caveats should be kept in mind. Firstly, FLABs cannot distinguish between narrow-spectrum (e.g., SHV-1), broad-spectrum (e.g., SHV-11), and Selleck VX-809 ESBLs (e.g., SHV-5 and SHV-12). Nevertheless, for Gram-negative organisms that do not express chromosomal SHV-type β-lactamases (e.g., E. coli, Proteus spp., Enterobacter spp.), evidence of SHV-type

production is often associated with ESBLs. In this case, rapid identification of SHV enzymes could temper the use of cephalosporins and suggest an alternative antibiotic (e.g., carbapenems) in the critically ill patient with a serious infection. Secondly, low level β-lactamase expression due to either promoter mutations or gene copy number may affect the ability of FLABs to detect these enzymes. However, it has been shown that the limit of detection/sensitivity in ELISA experiments is at pg levels [13]. Thirdly, FLABs may cross react and detect the homologous LEN-type

enzyme (possessed by some K. pneumoniae). In this study we were not able to rule out the possibility of cross-reaction between our FLABs and the LEN-type enzymes because we do not possess a highly-purified LEN-type β-lactamase and/or an isolate producing the bla LEN gene alone. Epigenetics inhibitor Based on a comparison of amino acids sequences of SHV-1 and LEN-1 enzymes a homology of 90% was observed. We compared the immunogenic epitopes of SHV-1 to the amino acid sequence of LEN-1 [14]: the most higly recognized

epitope showed 100% identity with the amino acid sequence of SHV-1 (data not shown). Therefore, it is possible that the LEN-type β-lactamase could be detected by our FLABs. Conclusion We developed a rapid and accurate method of visualizing the SHV family of enzymes in clinical samples containing Gram-negative bacilli using fluorescein-labeled polyclonal antibodies. It has not escaped our attention that this approach can also be applied to other β-lactamase Morin Hydrate types and for different Gram-negative species. The application of this methodology for clinical samples could help to rapidly identify SHV production and promptly implement a more appropriate antibiotic therapy improving clinical outcome (e.g., length of hospital stay and mortality) of patients with serious infections due to different Gram-negative bacilli. The development of specific monoclonal antibodies would ensure more widespread application and supply. Further studies are planned to determine the ability of this method to detect SHV β-lactamase in a wide range of clinical isolates and to assess the localization of β-lactamases within the cell [17].

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