METHODS: Clarithromycin susceptibility of H pylori isolates was determined by E test. Analyses for point mutations in the domain V of 23S rRNA genes in clarithromycin-resistant and -sensitive strains were performed by sequence analysis of amplified polymerase chain reaction products. Restriction fragment length polymorphism was performed using BsaI and MboII enzymes to detect restriction sites that correspond to the mutations in the clarithromycin-resistant strains.
RESULTS: Of 187 isolates from 120 patients, four were resistant to clarithromycin, while 183 were sensitive. The MIC of the resistant strains ranged from 1.5 to 24 microg/mL. Two isolates had an A2142G mutation and another two had A2143G mutations. A T2182C mutation was detected in two out of four clarithromycin-resistant isolates and in 13 of 14 clarithromycin-sensitive isolates. Restriction enzyme analyses with BsaI and MboII were able to detect the mutations.
CONCLUSION: Clarithromycin resistance is an uncommon occurrence among Malaysian isolates of H pylori strains and the mutations A2142G and A2143G detected were associated with low-level resistance.
METHODS: Comprehensive searches of the NCBI database were performed to identify published peer-reviewed articles and genomes of E. faecalis ST476. Each genome was analysed for resistome, virulome, OptrA variant and optrA genetic contexts. A phylogenetic comparison of ST476 genomes with publicly available genomes of other STs was also performed.
RESULTS: Sixty-six E. faecalis ST476 isolates from 15 countries (China, Japan, South Korea, Austria, Denmark, Spain, Czech Republic, Colombia, Tunisia, Italy, Malaysia, Belgium, Germany, United Arab Emirates and Switzerland) mainly of human and animal origin were identified. Thirty available ST476 genomes compared with genomes of 591 STs indicated a progressive radiation of E. faecalis STs starting from ST21. The closest ancestral node for ST476 was ST1238. Thirty E. faecalis ST476 genomes exhibited 3-916 SNP differences. Several antimicrobial resistance and virulence genes were conserved among the ST476 genomes. The optrA genetic context exhibited a high degree of or complete identity to the chromosomal transposon Tn6674. Only three isolates displayed an optrA-carrying plasmid with complete or partial Tn6674. The WT OptrA protein was most widespread in the ST476 lineage.
CONCLUSIONS: Linezolid-resistant optrA-carrying E. faecalis of the clonal lineage ST476 is globally distributed in human, animal and environmental settings. The presence of such an emerging clone can be of great concern for public health. Thus, a One Health approach is needed to counteract the spread and the evolution of this enterococcal clonal lineage.
METHODS: Seven optrA-carrying E. faecalis obtained from chicken faeces (n=3, August 2017) and retail chicken meat (n=4, August 2017) in Tunisia were analysed. Antimicrobial susceptibility was determined by disc diffusion, broth microdilution and Etest against 13 antibiotics, linezolid and tedizolid, respectively (EUCAST/CLSI). optrA stability (∼600 bacterial generations), transfer (filter mating) and location (S1-PFGE/hybridization) were characterized. WGS (Illumina-HiSeq) was done for four representatives that were analysed through in silico and genomic mapping tools.
RESULTS: Four MDR clones carrying different virulence genes were identified in chicken faeces (ST476) and retail meat (the same ST476 clone plus ST21 and ST859) samples. MICs of linezolid and tedizolid were stably maintained at 8 and 1-2 mg/L, respectively. optrA was located in the same transferable chromosomal Tn6674-like element in ST476 and ST21 clones, similar to isolates from pigs in Malaysia and humans in China. ST859 carried a non-conjugative plasmid of ∼40 kb with an impB-fexA-optrA segment, similar to plasmids from pigs and humans in China.
CONCLUSIONS: The same chromosomal and transferable Tn6674-like element was identified in different E. faecalis clones from humans and animals. The finding of retail meat contaminated with the same linezolid-resistant E. faecalis strain obtained from a food-producing animal highlights the potential role of the food chain in the worrisome dissemination of optrA that can be stably maintained without selective pressure over generations.