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ksgA mutations confer resistance to kasugamycin in Neisseria gonorrhoeae.

International journal of antimicrobial agents (2008-12-23)
Paul M Duffin, H Steven Seifert
RESUMEN

The aminoglycoside antibiotic kasugamycin (KSG) inhibits translation initiation and thus the growth of many bacteria. In this study, we tested the susceptibilities to KSG of 22 low-passage clinical isolates and 2 laboratory strains of Neisseria gonorrhoeae. Although the range of KSG minimum inhibitory concentrations (MICs) was narrow (seven-fold), clinical isolates and laboratory strains fell into three distinct classes of KSG sensitivity, susceptible, somewhat sensitive and resistant, with MICs of 30, 60-100 and 200 microg/mL, respectively. Two genes have previously been shown to be involved in bacterial KSG resistance: rpsI, which encodes the 30S ribosomal subunit S9 protein; and ksgA, which encodes a predicted dimethyltransferase. Although sequencing of rpsI and ksgA from clinical isolates revealed polymorphisms, none correlated with the MICs of KSG. Ten spontaneous KSG-resistant (KSG(R)) mutants were isolated from laboratory strain FA1090 at a frequency of <4.4x10(-6) resistant colony-forming units (CFU)/total CFU. All isolated KSG(R) variants had mutations in ksgA, whilst no mutations were observed in rpsI. ksgA mutations conferring KSG resistance included four point mutations, two in-frame and one out-of-frame deletions, one in-frame duplication and two frame-shift insertions. These data show a narrow range of susceptibilities for the clinical isolates and laboratory strains examined; moreover, the differences in MICs do not correlate with nucleotide polymorphisms in rpsI or ksgA. Additionally, spontaneous KSG(R) mutants arise by a variety of ksgA mutations.

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Kasugamycin hydrochloride from Streptomyces kasugaensis