With this approach we were able to design KU-60019 solubility dmso primer pairs and a probe that target specific mycobacterial atpE gene, and could be used to detect and quantify very specifically mycobacteria in environmental samples. Although the atpE gene may not be appropriate for microdiversity studies, it appeared to be very useful for specific detection
of the genus Mycobacterium in environmental samples. More generally, genome comparison used here showed its utility to identify specific genera’s targets, and could be used to identify specific proteins for antimicrobial design as previously emphasized [47]. Methods In silico comparison strategy In order to detect M. tuberculosis genes, presenting homologue genes in other mycobacterial
genomes, and not presenting homologue genes in non-mycobacteria genomes, we used the MycoHit software version 14.17 H 89 solubility dmso (Zipped copy of the files and instructions for this application are available in the Behr Research Lab, NSC23766 price https://www.mcgill.ca/molepi/) and performed an alignment search with Stand Alone tblastn algorithm as previously described [27]. Stand Alone tblastn algorithm has been chosen because coding sequences are known to be more conserved in mycobacterial genomes than non-coding sequences, as intergenic regions, insertion sequences, or phage sequences [30]. Genome of M. tuberculosis H37Rv has been used as a reference of the Mycobacterium genus, because it is the most historically described mycobacterial genome [22]. Based on the 3989 predicted proteins from M. tuberculosis H37Rv, Masitinib (AB1010) corresponding to the query sequences used in order to search for matches in the genomic DNA of other organisms (Figure 1), a matrix of 107703 scores (3989 protein sequences blasted against 12 non-mycobacterial genomes
and 15 mycobacterial genomes) was obtained. As previously described [27] and according to NCBI procedures [48], expected value was set at e-10. Following sequence comparisons, the MycoHit software allowed to sort scores according to similarity requests which were performed on the one hand toward mycobacterial genomes, and on the other hand toward non-mycobacterial genomes (Figure 1). A protein list of the reference target, which can be downloaded from NCBI web site (http://www.ncbi.nlm.nih.gov), allowed identification of the conserved mycobacterial proteins presenting no homology in non-mycobacterial genomes (Figure 1). Mycobacterial genome database In order to perform comparisons of pathogenic (P) and non-pathogenic (NP) mycobacterial genomes with M. tuberculosis H37Rv genome using MycoHit software, sequences were obtained at NCBI web site (http://www.ncbi.nlm.nih.gov) using the accession numbers: M. abscessus ATCC 19977 (CU458896.1) (P), M. avium 104 (CP000479.1) (P), M. avium subsp. paratuberculosis K10 (AE016958.1) (P), M. bovis subsp. bovis AF2122/97 (BX248333.1) (P), M. gilvum PYR-GCK (CP000656.1) (NP), M.