Co-occurrence of Plasmid-Mediated Tigecycline and Carbapenem Resistance in Acinetobacter spp. from Waterfowls and Their Neighboring Environment.

Tigecycline serves as one of the antibiotics of last resort to treat multidrug-resistant (including carbapenem-resistant) pathogens. However, the recently emerged plasmid-mediated tigecycline resistance mechanism, Tet(X), challenges the clinical efficacy of this class of antibiotics. In this study, we detected 180 tet(X)-harboring Acinetobacter isolates (8.9%, n = 180) from 2,018 samples collected from avian farms and adjacent environments in China. Eighteen tet(X)-harboring isolates (10.0%) were found to cocarry the carbapenemase gene blaNDM-1, mostly from waterfowl samples (94.4%, 17/18). Interestingly, among six Acinetobacter strains, tet(X) and blaNDM-1 were found to colocalize on the same plasmids. Moreover, whole-genome sequencing (WGS) revealed a novel orthologue of tet(X) in the six isolates coharboring tet(X) and blaNDM-1 Inverse PCR suggested that the two tet(X) genes form a single transposable unit and may be cotransferred. Sequence comparison between six tet(X)- and blaNDM-1-coharboring plasmids showed that they shared a highly homologous plasmid backbone even though they were isolated from different Acinetobacter species (three from Acinetobacter indicus, two from Acinetobacter schindleri, and one from Acinetobacter lwoffii) from various sources and from different geological regions, suggesting the horizontal genetic transfer of a common tet(X)- and blaNDM-1-coharboring plasmid among Acinetobacter species in China. Emergence and spread of such plasmids and strains are of great clinical concern, and measures must be implemented to avoid their dissemination.

Comprehensive analysis of plasmid-mediated tet(X4)-positive Escherichia coli isolates from clinical settings revealed a high correlation with animals and environments-derived strains.

The emergence of novel plasmid-mediated high-level tigecycline resistance genes tet(X) in the Enterobacteriaceae has increased public health risk for treating severe bacterial infections. Despite growing reports of tet(X)-positive isolates detected in animal sources, the epidemiological association of animal- and environment-derived isolates with human-derived isolates remains unclear. Here, we performed a comprehensive analysis of tet(X4)-positive Escherichia coli isolates collected in a hospital in Guangdong province, China. A total of 48 tet(X4)-positive E. coli isolates were obtained from 1001 fecal samples. The tet(X4)-positive E. coli isolates were genetically diverse but certain strains that belonged to ST48, ST10, and ST877 etc. also have clonally transmitted. Most of the tet(X4) genes from these patient isolates were located on conjugative plasmids that were successfully transferred (64.6%) and generally coexisted with other antibiotic resistance genes including aadA, floR, blaTEM and qnrS. More importantly, we found the IncX1 type plasmid was a common vector for tet(X4) and was prevalent in these patient-derived strains (31.3%). This plasmid type has been detected in animal-derived strains from different species in different regions demonstrating its strong transmission ability and wide host range. Furthermore, phylogenetic analysis revealed that certain strains of patient and animal origin were closely related indicating that the tet(X4)-positive E. coli isolates were likely to have cross-sectorial clonal transmission between humans, animals, and farm environments. Our research greatly expands the limited epidemiological knowledge of tet(X4)-positive strains in clinical settings and provides definitive evidence for the epidemiological link between human-derived tet(X4)-positive isolates and animal-derived isolates.

Reducing tetracycline antibiotics residues in aqueous environments using Tet(X) degrading enzymes expressed in Pichia pastoris.

Tetracycline antibiotics (TCs) are massively produced and consumed in various industries resulting in large quantities of residuals in the environment. In this study, to achieve safe and efficient removal of residual TCs, a Pichia pastoris (P. pastoris) was gained to stably express glycosylated TCs degrading enzyme Tet(X) followed codon and expression parameter optimization of tet(X4). As expected, glycosylated Tet(X) still maintains efficient capacity of degrading TCs. The expressed Tet(X) maintained efficient TCs degrading ability over a pH range of 6.5 - 9.5 and temperature range of 17 - 47 °C. We tested this recombinant protein for its ability to degrade tetracycline in pond water and sewage models of tetracycline removal at starting levels of 10 mg/L substrate. 80.5 ± 3.8% and 26.2 ± 2.6% of tetracycline was degraded within 15 min in the presence of 0.2 µM Tet(X) and 50 µM NADPH, respectively. More importantly, the direct use of a Tet(X) degrading enzymes reduces the risk of gene transmission during degradation. Thus, the Tet(X) degrading enzyme expressed by P. pastoris is an effective and safe method for treating intractable TCs residues.

Evolutionary Trajectory of the Tet(X) Family: Critical Residue Changes towards High-Level Tigecycline Resistance.

The emergence of the plasmid-mediated high-level tigecycline resistance mechanism Tet(X) threatens the role of tigecycline as the "last-resort" antibiotic in the treatment of infections caused by carbapenem-resistant Gram-negative bacteria. Compared with that of the prototypical Tet(X), the enzymatic activities of Tet(X3) and Tet(X4) were significantly enhanced, correlating with high-level tigecycline resistance, but the underlying mechanisms remain unclear. In this study, we probed the key amino acid changes leading to the enhancement of Tet(X) function and clarified the structural characteristics and evolutionary path of Tet(X) based upon the key residue changes. Through domain exchange and site-directed mutagenesis experiments, we successfully identified five candidate residues mutations (L282S, A339T, D340N, V350I, and K351E), involved in Tet(X2) activity enhancement. Importantly, these 5 residue changes were 100% conserved among all reported high-activity Tet(X) orthologs, Tet(X3) to Tet(X7), suggesting the important role of these residue changes in the molecular evolution of Tet(X). Structural analysis suggested that the mutant residues did not directly participate in the substrate and flavin adenine dinucleotide (FAD) recognition or binding, but indirectly altered the conformational dynamics of the enzyme through the interaction with adjacent residues. Matrix-assisted laser desorption ionization-time of flight mass spectrometry (MALDI-TOF MS) and UV full-wavelength scanning experiments confirmed that each mutation led to an increase in activity without changing the biochemical properties of the Tet(X) enzyme. Further phylogenetic analysis suggested that Riemerella anatipestifer served as an important incubator and a main bridge vector for the resistance enhancement and spread of Tet(X). This study expands the knowledge of the structure and function of Tet(X) and provides insights into the evolutionary relationship between Tet(X) orthologs.IMPORTANCE The newly emerged tigecycline-inactivating enzymes Tet(X3) and Tet(X4), which are associated with high-level tigecycline resistance, demonstrated significantly higher activities in comparison to that of the prototypical Tet(X) enzyme, threatening the clinical efficacy of tigecycline as a last-resort antibiotic to treat multidrug-resistant (MDR) Gram-negative bacterial infections. However, the molecular mechanisms leading to high-level tigecycline resistance remain elusive. Here, we identified 5 key residue changes that lead to enhanced Tet(X) activity through domain swapping and site-directed mutagenesis. Instead of direct involvement with substrate binding or catalysis, these residue changes indirectly alter the conformational dynamics and allosterically affect enzyme activities. These findings further broaden the understanding of the structural characteristics and functional evolution of Tet(X) and provide a basis for the subsequent screening of specific inhibitors and the development of novel tetracycline antibiotics.

Genetic diversity and characteristics of high-level tigecycline resistance Tet(X) in Acinetobacter species.

BACKGROUND: The recent emergence and dissemination of high-level mobile tigecycline resistance Tet(X) challenge the clinical effectiveness of tigecycline, one of the last-resort therapeutic options for complicated infections caused by multidrug-resistant Gram-negative and Gram-positive pathogens. Although tet(X) has been found in various bacterial species, less is known about phylogeographic distribution and phenotypic variance of different genetic variants. METHODS: Herein, we conducted a multiregional whole-genome sequencing study of tet(X)-positive Acinetobacter isolates from human, animal, and their surrounding environmental sources in China. The molecular and enzymatic features of tet(X) variants were characterized by clonal expression, microbial degradation, reverse transcription, and gene transfer experiments, while the tet(X) genetic diversity and molecular evolution were explored by comparative genomic and Bayesian evolutionary analyses. RESULTS: We identified 193 tet(X)-positive isolates from 3846 samples, with the prevalence ranging from 2.3 to 25.3% in nine provinces in China. The tet(X) was broadly distributed in 12 Acinetobacter species, including six novel species firstly described here. Besides tet(X3) (n = 188) and tet(X4) (n = 5), two tet(X5) variants, tet(X5.2) (n = 36) and tet(X5.3) (n = 4), were also found together with tet(X3) or tet(X4) but without additive effects on tetracyclines. These tet(X)-positive Acinetobacter spp. isolates exhibited 100% resistance rates to tigecycline and tetracycline, as well as high minimum inhibitory concentrations to eravacycline (2-8 µg/mL) and omadacycline (8-16 µg/mL). Genetic analysis revealed that different tet(X) variants shared an analogous ISCR2-mediated transposon structure. The molecular evolutionary analysis indicated that Tet(X) variants likely shared the same common ancestor with the chromosomal monooxygenases that are found in environmental Flavobacteriaceae bacteria, but sequence divergence suggested separation ~ 9900 years ago (7887 BC), presumably associated with the mobilization of tet(X)-like genes through horizontal transfer. CONCLUSIONS: Four tet(X) variants were identified in this study, and they were widely distributed in multiple Acinetobacter spp. strains from various ecological niches across China. Our research also highlighted the crucial role of ISCR2 in mobilizing tet(X)-like genes between different Acinetobacter species and explored the evolutionary history of Tet(X)-like monooxygenases. Further studies are needed to evaluate the clinical impact of these mobile tigecycline resistance genes.