Clarithromycin was the drug of choice for Mycobacterium abscessus infections until inducible resistance due to erm(41) was described. Because M. abscessus was split into M. abscessus sensu stricto, Mycobacterium massiliense, and Mycobacterium bolletii, we looked for erm(41) in the three species and determined their clarithromycin susceptibility levels. Ninety strains were included: 87 clinical strains from cystic fibrosis patients (61%) and others (39%), representing 43 M. abscessus, 30 M. massiliense, and 14 M. bolletii strains identified on a molecular basis, and 3 reference strains. Clarithromycin and azithromycin MICs were determined by broth microdilution and Etest with a 14-day incubation period. Mutations in rrl (23S rRNA gene) known to confer acquired clarithromycin resistance were also sought. erm(41) was detected in all strains but with two deletions in all M. massiliense strains. These strains were indeed susceptible to clarithromycin (MIC 90 of 1 g/ml) except for four strains with rrl mutations. M. abscessus strains harbored an intact erm(41) but had a T/C polymorphism at the 28th nucleotide: T28 strains (Trp10 codon) demonstrated inducible clarithromycin resistance (MIC 90 of >16 g/ml), while C28 strains (Arg10) were susceptible (MIC 90 of 2 g/ml) except for two strains with rrl mutations. M. bolletii strains had erm(41) sequences similar to the sequence of the T28 M. abscessus group, associated with inducible clarithromycin resistance (MIC 90 of >16 g/ml). erm(41) sequences appeared species specific within the M. abscessus group and were fully concordant with clarithromycin susceptibility when erm(41) sequencing was associated with detection of rrl mutations. Clarithromycin-resistant strains, including the six rrl mutants, were more often isolated in cystic fibrosis patients, but this was not significantly associated with a previous treatment.Respiratory infections due to rapidly growing mycobacteria were first attributed to the Mycobacterium chelonae complex (45). Some years later, it appeared that they were mostly due to Mycobacterium abscessus (16), a newly described species that was distinguished from M. chelonae by DNA-DNA hybridization (23,25). Indeed, the two species were difficult to distinguish by cultural and biochemical features and even by 16S rRNA gene sequencing, which is widely used for bacterial identification (8, 21). Routine M. abscessus identification became possible mostly with the wide use of PCR sequencing of housekeeping genes other than ribosomal genes (12, 13, 18). Recently, the M. abscessus species has been subclassified into three new species on the basis of rpoB sequences: M. abscessus (sensu stricto), Mycobacterium massiliense, and Mycobacterium bolletii (1, 3). Further taxonomic studies showed that differentiation of the three species was not trivial; they still shared ribosomal sequences, and even multilocus sequencing approaches cannot clearly assign clinical strains to one of the three species (24,27,43,49).The M. abscessus group (also called M. abscessus sensu lato...
