Abstract
V. furnissii is a marine bacterium capable of infecting both invertebrates and humans. However, the mechanisms underlying its drug resistance and virulence remain largely elusive. In this study, we isolated a multidrug-resistant V. furnissii strain, MT14, from bivalve mollusks. Genomic analysis revealed that MT14 carries a novel pAQU-type plasmid, designated pMT14, which harbors six antibiotic resistance genes: qnrS2, qnrVC6, dfrA31, tetA; sul2, and bla(GMA-1). Notably, bla(GMA-1) and its variants confer resistance to penicillin-class antibiotics, including ampicillin, amoxicillin, and carbenicillin. Comparative genomic analysis further revealed that V. furnissii strains commonly encode T6SS1, T6SS2, and the hemolysin gene vfh, while only five sequenced strains carry zot toxin gene. To our knowledge, this is the first report of zot in V. furnissii. In addition, the absence of drug resistance genes in the majority of genomes (73.3%, 22/30) suggests that such traits are not intrinsic to the species but have been acquired by specific strains, likely through plasmid transfer or other mobile genetic elements. The emergence of bla(GMA-1) and zot in V. furnissii represents a potential public health concern, underscoring the need for enhanced surveillance of antimicrobial resistance in marine pathogens.