GyrB in silico mining in 27 151 global gonococcal genomes from 1928–2021 combined with zoliflodacin in vitro testing of 71 international gonococcal isolates with different GyrB, ParC and ParE substitutions confirms high susceptibility

Abstract

Abstract Objectives Antimicrobial resistance (AMR) in Neisseria gonorrhoeae is a global threat and novel treatment alternatives are imperative. Herein, susceptibility to the novel antimicrobial zoliflodacin, currently in a global Phase 3 randomized controlled clinical trial for gonorrhoea treatment, was investigated by screening for zoliflodacin GyrB target mutations in publicly available gonococcal genomes and, where feasible, determination of the associated zoliflodacin MIC. Methods The European Nucleotide Archive was queried using the search term ‘Taxon: 485’. DNA sequences from 27 151 gonococcal isolates were analysed and gyrB, gyrA, parC and parE alleles characterized. Results GyrB amino acid alterations were rare (97.0% of isolates had a wild-type GyrB sequence). GyrB V470L (2.7% of isolates) was the most prevalent alteration, followed by S467N (0.12%), N. meningitidis GyrB (0.092%), V470I (0.059%), Q468R/P (0.015%), A466T (0.0074%), L425I + L465I (0.0037%), L465I (0.0037%), G482S (0.0037%) and D429V (0.0037%). Only one isolate (0.0037%) carried a substitution in a resistance-associated GyrB codon (D429V), resulting in a zoliflodacin MIC of 8 mg/L. None of the other detected gyrB, gyrA, parC or parE mutations caused a zoliflodacin MIC outside the wild-type MIC distribution. Conclusions The zoliflodacin target GyrB was highly conserved among 27 151 global gonococcal isolates cultured in 1928–2021. The single zoliflodacin-resistant clinical isolate (0.0037%) was cultured from a male patient in Japan in 2000. Evidently, this strain has not clonally expanded nor has the gyrB zoliflodacin-resistance mutation disseminated through horizontal gene transfer to other strains. Phenotypic and genomic surveillance, including gyrB mutations, of zoliflodacin susceptibility are imperative.