RESUMO
Loop-mediated isothermal amplification (LAMP) has gained wide popularity in the detection of Salmonella in foods owing to its simplicity, rapidity, and robustness. This multi-laboratory validation (MLV) study aimed to validate a Salmonella LAMP-based method against the United States Food and Drug Administration (FDA) Bacteriological Analytical Manual (BAM) Chapter 5 Salmonella reference method in a representative animal food matrix (dry dog food). Fourteen independent collaborators from seven laboratories in the United States and Canada participated in the study. Each collaborator received two sets of 24 blind-coded dry dog food samples (eight uninoculated; eight inoculated at a low level, 0.65 MPN/25 g; and eight inoculated at a high level, 3.01 MPN/25 g) and initiated the testing on the same day. The MLV study used an unpaired design where different test portions were analyzed by the LAMP and BAM methods using different preenrichment protocols (buffered peptone water for LAMP and lactose broth for BAM). All LAMP samples were confirmed by culture using the BAM method. BAM samples were also tested by LAMP following lactose broth preenrichment (paired samples). Statistical analysis was carried out by the probability of detection (POD) per AOAC guidelines and by a random intercept logistic regression model. Overall, no significant differences in POD between the Salmonella LAMP and BAM methods were observed with either unpaired or paired samples, indicating the methods were comparable. LAMP testing following preenrichment in buffered peptone water or lactose broth also resulted in insignificant POD differences (P > 0.05). The MLV study strongly supports the utility and applicability of this rapid and reliable LAMP method in routine regulatory screening of Salmonella in animal food.
RESUMO
The discovery of ptsHI operon in Bacillus stearothermophilus XL-65-6 coupled with our previous report of a cel operon (Lai & Ingram, J Bacteriol 175, 6441-6450, 1993) demonstrates that this thermophilic organism contains all of the genes required for cellobiose uptake by the phosphoenolpyruvate-dependent phosphotransferase system (PTS). Genes encoding the two general PTS proteins, HPr (ptsH) and enzyme I (ptsI), were cloned and sequenced. These form an operon which includes a third small gene (ptsT) of unknown function (encoded product M(r) 18428). Both ptsH and ptsI were expressed at high levels from a single plasmid in Escherichia coli and complemented corresponding host mutations. Although the translated sequences for these genes were similar to homologues from Gram-positive mesophiles (64-77% identity), the B. stearothermophilus gene products were unusual in having a higher predicted pI and fewer negatively charged amino acid residues. Enzyme I also contained more alanine and leucine than mesophilic counterparts. Interestingly, ptsT inhibited the growth of E. coli ptsI mutants at 37 degrees C. No such inhibition was observed during incubation at a lower temperature (30 degrees C) or in E. coli DH5 alpha, which is wild-type for ptsI. The predicted translation product from ptsT contained a high proportion of basic amino acids (27%) and had a high predicted pI (pH 11.7), properties similar to bacterial histone-like proteins, but did not exhibit homology to any sequences in the current database. Regions upstream and downstream from the ptsHI operon contain genes with homology to Bacillus subtilis ptsG and wapA (wall-associated protein), respectively.