coli strains. Virulence traits including RDAR morphotype and cell adherence were attenuated as a result of rpoS mutations. In addition, although rpoS mutants constituted www.selleckchem.com/products/kpt-8602.html most of the metabolic enhanced mutants, there was a small fraction of mutants that had intact RpoS function, indicating that other factors can also increase metabolic potential under conditions examined. Interestingly, three of ten tested VTEC strains grew well on succinate, and no growth-enhanced mutants could
be selected. One of these three strains possessed a null rpoS mutation. This indicates that an adaptation to poor carbon source may have occurred in natural E. coli populations. Results Polymorphisms of rpoS in wild type VTEC strains The ten representative VTEC strains
examined in this study (Table 1) belong to five seropathotypes that have been categorized on the basis of virulence and outbreak frequency [29]. To test whether selection for loss of RpoS function can occur in these isolates, we first examined the see more rpoS sequences of these strains. Many nucleotide base substitutions were found in rpoS (Table 2). However, these substitutions did not result in changes in protein sequence, except for a single transversion (G to T) in A-1155463 ic50 strain N99-4390 which formed a premature stop codon, resulting in a loss of 86 amino acids at the C-terminal end of RpoS. As expression of catalase HPII encoded by katE is highly RpoS-dependent [30, 31], catalase production in all strains could be used to assess RpoS activity using plate catalase assays. Only N99-4390 exhibited a low catalase activity, consistent with the expected effect of the identified mutation in this strain. All tested VTEC strains were found to have a GAG
at codon 33, in contrast to CAG in the laboratory K12 strain MG1655 (Table 2). Table 1 Suc++ mutants selected from VTEC strains with attenuated or intact RpoS functions. Sero-pathotype Serotype Strain Source Host Number of mutants Ratio of rpoS/Suc++ Suc++ rpoS Glutathione peroxidase A O157:H7 EDL933 J. Kaper Human 12 11 0.92 B O121:H19 CL106 LFZ Human 12 10 0.83 O111:NM R82F2 LFZ Human N/A N/A C O5:NM N00-4067 BCCDC, NLEP Human 12 12 1.00 O113:H21 CL3 LFZ Human N/A N/A O121:NM N99-4390 BCCDC, NLEP Human N/A N/A D O103:H25 N00-4859 BCCDC, NLEP Human 12 12 1.00 O172:NM EC6-484 LFZ Bovine 12 8 0.67 E O84:NM EC2-044 LFZ Bovine 12 12 1.00 O98:H25 EC3-377 LFZ Bovine 12 12 1.00 Twelve Suc++ mutants from each strain were tested for catalase activity using a plate catalase assay. Mutants impaired in catalase were considered as putative rpoS mutants. Detailed VTEC strain information is described elsewhere [29]. Table 2 Polymorphic codons in rpoS among VTEC strains. Codon 33 54 119 129 154 181 191 243 273 317 Glu Val Leu Arg Ile Thr His Glu Val Leu Consensus GAG GTG CTT CGC ATT ACC CAT GAG GTG CTG MG1655 C . . . . . . . . . . . . . . . . . . . . . . . . . . . . . EDL933 . . . . . . . . . . . T . . . . . A . . . . . . . . A . . .