Genetic and Phenotypic Characterization of the Novel Metallo-β-Lactamase NDM-29 From Escherichia coli

Objectives: The New Delhi metallo-beta-lactamase (NDM) can hydrolyze almost all clinically available beta-lactam antibiotics and has widely spread all over the world. NDM-29, a novel carbapenemase, was discovered in an Escherichia coli (19NC225) isolated from a patient with biliary tract infection in 2019 in China. Methods: Conjugation, transformation, cloning test, fitness cost, PacBio Sequel, and Illumina sequencing were performed to analyze the genetic and phenotypic characterization of bla(NDM-29). Results: The susceptibility testing results showed 19NC225 was resistant to cephalosporins, carbapenems, combinations of beta-lactam and beta-lactamase inhibitors, and levofloxacin. Conjugation and transformation were performed to verify the transferability of NDM-29-encoding plasmid, and cloning test was conducted to prove the function of bla(NDM-29) to increase carbapenem resistance. Furthermore, fitness cost test confirmed that the presence of NDM-29 exerts no survival pressure on bacteria. PacBio Sequel and Illumina sequencing were performed to analyze the genetic characterization of 19NC225, which contains two plasmids (pNC225-TEM1B and pNC225-NDM-29). pNC225-NDM-29, exhibiting 99.96% identity and 100% coverage with pNDM-BTR (an IncN1 plasmid from an E. coli in urine specimen from Beijing in 2013), showed responsibility for the multidrug-resistant (MDR) phenotype. Compared with bla(NDM-1), bla(NDM-29), located on pNC225-NDM-29, carries a G388A (D130N) mutation. The region harboring bla(NDM-29) is located in an ISKpn19-based transposon, and two Tn6292 remnants are symmetrically located upstream and downstream of the transposon. The sequence results also indicated several important virulence genes. Conclusion: The findings of the novel carbapenemase NDM-29 could pose a threat to the control of antimicrobial resistance and arouse attention about the mutation of bacteria.

Automated summary

NDM-29, a novel carbapenemase that can hydrolyze almost all clinically available beta-lactam antibiotics, was discovered in an Escherichia coli in China. The presence of NDM-29 may pose a threat to antimicrobial resistance control and highlights the importance of monitoring bacterial mutations.