Profiling of Antimicrobial Resistance Genes and Integron from Escherichia coli Isolates Using Whole Genome Sequencing

PmrB Y358N, E123D amino acid substitutions are not associated with colistin resistance but with phylogeny in Escherichia coli

Colistin resistance in Escherichia coli is of public health significance for its use to treat multidrug-resistant Gram-negative infections. Amino acid variations in PmrB have been implicated in colistin resistance in E. coli. In this cross-sectional study, 288 generic E. coli isolates from surveillance of broiler chicken and feedlot cattle feces, retail meat, wastewater, and well water were whole-genome sequenced. Phylogroup designation and screening for two amino acid substitutions in PmrB putatively linked to colistin resistance (Y358N, E123D) were performed in silico. Three additional data sets of publicly available E. coli assemblies were similarly scrutinized: (i) E. coli isolates from studies identifying the Y358N or E123D substitutions, (ii) colistin-susceptible E. coli isolates reported in the literature, and (iii) a random sampling of 14,700 E. coli assemblies available in the National Center for Biotechnology Information public database. Within all data sets, ≥95% of phylogroup B1 and C isolates have the PmrB Y358N variation. The PmrB E123D amino acid substitution was only identified in phylogroup B2 isolates, of which 94%-100% demonstrate the substitution. Both PmrB amino acid variations were infrequent in other phylogroups. Among published colistin susceptible isolates, colistin minimum inhibitory concentrations (MICs) were not higher in isolates bearing the E123D and Y358N amino acid variations than in isolates without these PmrB substitutions. The E123D and Y358N PmrB amino acid substitutions in E. coli appear strongly associated with phylogroup. The previously observed associations between Y358N and E123D amino acid substitutions in PmrB and colistin resistance in E. coli may be spurious.

IMPORTANCE

Colistin is a critical last-resort treatment for extensively drug-resistant Gram-negative infections in humans. Therefore, accurate identification of the genetic mechanisms of resistance to this antimicrobial is crucial to effectively monitor and mitigate the spread of resistance. Examining over 16,000 whole-genome sequenced Escherichia coli isolates, this study identifies that PmrB E123D and Y358N amino acid substitutions previously associated with colistin resistance in E. coli are strongly associated with phylogroup and are alone not sufficient to confer a colistin-resistant phenotype. This is a critical clarification, as both substitutions are identified as putative mechanisms of colistin resistance in many publications and a common bioinformatic tool. Given the potential spurious nature of initial associations of these substitutions with colistin resistance, this study's findings emphasize the importance of appropriate experimental design and consideration of relevant biological factors such as phylogroup when ascribing causal mechanisms of resistance to chromosomal variations.

Molecular epidemiology, antibiotic resistance profile and frequency of integron 1 and 2 in adherent-invasive Escherichia coli isolates of colorectal cancer patients

This study explores the prevalence of adherent-invasive Escherichia coli (AIEC) in colorectal cancer (CRC) patients and investigates the potential of effective intracellular antibiotics as a therapeutic strategy for CRC patients with AIEC infections. Considering the pivotal role of integrons in bacterial antibiotic resistance, the frequency of class 1 and 2 integrons in AIEC isolated from CRC patients, in one of the referenced 3 gastroenterology clinics in Isfahan, Iran was examined. AIEC strains were isolated from the colorectal biopsies and their antimicrobial sensitivity was assessed using the disc diffusion method. Polymerase chain reaction (PCR) was employed to detect intl1 and intl2. The multilocus sequence typing (MLST) method was utilized to type 10 selected isolates. Of the 150 samples, 24 were identified as AIEC, with the highest number isolated from CRC2 (33.4%) and CRC1 (29.16%), and the least from the FH group (8.3%) and control group (12.5%). int1 in 79.2% and int2 in 45.8% of AIEC strains were found and 41.6% of strains had both integrons. AIEC isolates with int1 exhibited the highest sensitivity to trimethoprim-sulfamethoxazole (57.9%), while those with int2 showed the highest sensitivity to ciprofloxacin (63.6%). A significant association between resistance to rifampin and integron 2 presence in AIEC isolates was observed. Furthermore, a significant correlation between integron 1 presence, invasion, survival, and replication within macrophages in AIEC strains was identified. MLST analysis revealed ST131 from CC131 with integron 1 as the most common sequence type (ST). The emergence of such strains in CRC populations poses a serious public health threat. The distribution pattern of STs varied among studied groups, with pandemic STs highlighting the importance of examining and treating patients infected with these isolates. Comprehensive prospective clinical investigations are warranted to assess the prognostic value of detecting this pathovar in CRC and to evaluate therapeutic techniques targeting drug-resistant AIECs, such as phage therapy, bacteriocins, and anti-adhesion compounds, for CRC prevention and treatment.

Resistome Diversity in Escherichia coli Isolates of Global Wastewaters

Antimicrobial resistance (AMR) is a global health threat requiring urgent attention and effective strategies for containment. AMR is fueled by wastewater mismanagement and global mobility, disseminating multidrug-resistant (MDR) strains worldwide. While global estimates of AMR burden have been informative, community-level understanding has received little attention despite reports of high AMR prevalence in healthy communities. We assessed the "invasion" of antibiotic resistance genes (ARGs) into the normal human flora by characterizing AMR Escherichia coli in local wastewaters contributed by a healthy youth population. This study estimated 26% (out of 300 isolates) resistant and 59% plasmid-bearing E. coli in local wastewater. Of the 78 AMR isolates, the frequency of mono-resistance was higher against tetracycline (32%), followed by kanamycin (17%) and chloramphenicol (9%). Five isolates were potentially MDR. We further sequenced four MDRs and four sensitive strains to comprehend the genome and resistome diversity in comparison to the global wastewater E. coli (genomes from the PATRIC database). The whole-genome analysis revealed extensive genome similarity among global isolates, suggesting global dissemination and colonization of E. coli. Global wastewater resistome majorly comprised ARGs against aminoglycosides (26%), beta-lactam (17%), sulfonamide (11%), and trimethoprim (8%). Resistance to colistin, a last-resort antibiotic, was prevalent in MDRs of European and South Asian isolates. A systems approach is required to address the AMR crisis on a global scale, reduce antibiotic usage, and increase the efficiency of wastewater management and disinfection.