Emergence of Haemophilus influenzae with low susceptibility to quinolones isolated from pediatric patients in Japan

Longitudinal Trend in Antimicrobial Susceptibility among Haemophilus influenzae: A Single-Centre Study in Japan

Haemophilus influenzae presents significant concerns regarding antimicrobial resistance. The circumstances surrounding H. influenzae have been changing owing to changes in antimicrobial usage. In the present study, to determine the current situation of H. influenzae, the antimicrobial susceptibility trends were investigated. In total, 21 clinical isolates were analyzed. Antimicrobial susceptibility measured using the broth dilution method was compared with that reported in previous studies at the same hospital. Quinolone low-susceptible isolates were further characterized by multi-locus sequence typing. Upon comparing the susceptibility data in 2022 with those in the past 15 years, the number of β-lactamase nonproducing ampicillin-resistant isolates was decreased. Regarding recent changes, β-lactam-susceptible isolates were found to have gradually increased every year. However, β-lactamase-producing isolates did not decrease. In particular, the ratio of β-lactamase-producing amoxicillin and clavulanic acid-resistant isolates in 2022 was the highest among all the years studied. Moreover, quinolone low-susceptible isolates were still present, suggesting that these isolates could have been indigenized in the community. Furthermore, a β-lactamase-producing amoxicillin and clavulanic acid-resistant isolate was found to have emerged among the quinolone low-susceptibility isolates. At first glance, these findings indicate that antimicrobial resistance has decreased among H. influenzae in clinical settings. However, β-lactamase-producing isolates and quinolone low-susceptible isolates have remained at a constant rate in the community.

Unique and Ingenious Mechanisms Underlying Antimicrobial Resistance and Spread of Haemophilus influenzae

Antimicrobial resistance (AMR) is a serious global concern. AMR pathogens are found in hospitals and communities. Haemophilus influenzae is a common pathogen associated with community-acquired infections. H. influenzae infections are usually treated with β-lactams, macrolides, and quinolones. However, the drug-resistant strains have emerged. The resistance mechanisms of H. influenzae are complex but are roughly characterized by the acquisition of a mutation in antimicrobial-targeting genes and exogenous resistant genes. Generally, the former cannot be transferred horizontally to a susceptible strain. However, several studies have demonstrated that, in the case of H. influenzae, both the former and the latter can be transferred horizontally. In this review, we provide an overview of the bacterial features and antimicrobial resistance of H. influenzae. We also summarize the unique and ingenious antimicrobial resistance mechanisms used by this pathogen based on the findings of recent studies. These are expected to facilitate the understanding of AMR pathogens in the community and develop strategies to combat infections.

The Association between Transformation Ability and Antimicrobial Resistant Potential in Haemophilus influenzae

The prevalence of quinolone low-susceptible Haemophilus influenzae has increased in Japan. Low quinolone susceptibility is caused by point mutations in target genes; however, it can also be caused by horizontal gene transfer via natural transformation. In this study, we examined whether this horizontal gene transfer could be associated with resistance to not only quinolones but also other antimicrobial agents. Horizontal transfer ability was quantified using the experimental transfer assay method for low quinolone susceptibility. Further, the association between horizontal transfer ability and resistance to β-lactams, the first-choice drugs for H. influenzae infection, was investigated. The transformation efficiency of 50 clinical isolates varied widely, ranging from 102 to 106 colony forming unit (CFU) of the colonies obtained by horizontal transfer assay. Efficiency was associated with β-lactam resistance caused by ftsI mutations, indicating that strains with high horizontal transfer ability acquired quinolone low-susceptibility as well as β-lactam resistance more easily. Strains with high transformation efficiency increased the transcript level of comA, suggesting that enhanced com operon was associated with a high DNA uptake ability. Overall, this study revealed that the transformation ability of H. influenzae was associated with multiple antimicrobial resistance. Increase in the number of strains with high horizontal transformation ability has raised concerns regarding the rapid spread of antimicrobial-resistant H. influenzae.

Alternative quinolone-resistance pathway caused by simultaneous horizontal gene transfer in Haemophilus influenzae

BACKGROUND

Quinolone-resistant bacteria are known to emerge via the accumulation of mutations in a stepwise manner. Recent studies reported the emergence of quinolone low-susceptible Haemophilus influenzae ST422 isolates harbouring two relevant mutations, although ST422 isolates harbouring one mutation were never identified.

OBJECTIVES

To investigate if GyrA and ParC from quinolone low-susceptible isolates can be transferred horizontally and simultaneously to susceptible isolates.

METHODS

Genomic DNA was extracted from an H. influenzae isolate harbouring amino acid substitutions in both gyrA and parC and mixed with clinical isolates. The emergence of resistant isolates was compared, and WGS analysis was performed.

RESULTS

By adding the genomic DNA harbouring both mutated gyrA and parC, resistant bacteria exhibiting recombination at gyrA only or both gyrA and parC loci were obtained on nalidixic acid and pipemidic acid plates, and the frequency was found to increase with the amount of DNA. Recombination events in gyrA only and in both gyrA and parC occurred with at least 1 and 1-100 ng of DNA, respectively. The genome sequence of a representative strain showed recombination events throughout the genome. The MIC of quinolone for the resulting strains was found to be similar to that of the donor. Although the recombination efficacy was different among the various strains, all strains used in this study obtained multiple genes simultaneously.

CONCLUSIONS

These findings indicate that H. influenzae can simultaneously obtain more than two mutated genes. This mechanism of horizontal transfer could be an alternative pathway for attaining quinolone resistance.

Quinolone resistance is transferred horizontally via uptake signal sequence recognition in Haemophilus influenzae

The presence of Haemophilus influenzae strains with low susceptibility to quinolones has been reported worldwide. However, the emergence and dissemination mechanisms remain unclear. In this study, a total of 14 quinolone-low-susceptible H. influenzae isolates were investigated phylogenetically and in vitro resistance transfer assay in order to elucidate the emergence and dissemination mechanisms. The phylogenetic analysis based on gyrA sequences showed that strains with the same sequence type determined by multilocus sequence typing were classified into different clusters, suggesting that H. influenzae quinolone resistance emerges not only by point mutation, but also by the horizontal transfer of mutated gyrA. Moreover, the in vitro resistance transfer assay confirmed the horizontal transfer of quinolone resistance and indicated an active role of extracellular DNA in the resistance transfer. Interestingly, the horizontal transfer of parC only occurred in those cells that harbored a GyrA with amino acid substitutions, suggesting a possible mechanism of quinolone resistance in clinical settings. Moreover, the uptake signal and uptake-signal-like sequences located downstream of the quinolone resistant-determining regions of gyrA and parC, respectively, contributed to the horizontal transfer of resistance in H. influenzae. Our study demonstrates that the quinolone resistance of H. influenzae could emerge due to the horizontal transfer of gyrA and parC via recognition of an uptake signal sequence or uptake-signal-like sequence. Since the presence of quinolone-low-susceptible H. influenzae with amino acid substitutions in GyrA have been increasing in recent years, it is necessary to focus our attention to the acquisition of further drug resistance in these isolates.