Background <p><i>Escherichia coli</i> (<i>E. coli</i>) is a leading cause of bloodstream infections (BSIs) globally, with multidrug-resistant (MDR) strains complicating treatment outcomes. In South Africa, genomic data on such isolates remain scarce. To elucidate the genomic landscape of <i>E. coli</i> isolates from bloodstream infections (BSIs) collected over a one-year period in the uMgungundlovu District, South Africa, with a focus on the resistance and virulence genes, mobile genetic elements (MGEs), genetic synteny, sequence types (STs), and phylogenomic context.</p> Methods <p>Twenty-five non-duplicate <i>E. coli</i> isolates were recovered from blood cultures and subjected to antimicrobial susceptibility testing. All twelve MDR isolates underwent whole-genome sequencing and bioinformatic analysis.</p> Results <p>The MDR isolates comprised six distinct STs, notably high-risk international lineages ST131 (33.3%) and ST69 (25.0%), spanning five phylogroups, predominantly B2 and D. Eight O: H serotypes were identified, with O25:H4 and O45:H16 being most frequent. CH-typing revealed dominant CH types CH40-30 (ST131) and CH35-27 (ST69) and <i>fimH</i> alleles such as <i>fimH30</i> and <i>fimH27</i>. The isolates encoded β-lactamases, including <i>bla</i><sub>CTX-M-15</sub>, <i>bla</i><sub>TEM-1B</sub> and <i>bla</i><sub>OXA-1,</sub> frequently co-located with MGEs. Notably, <i>bla</i><sub>CTX-M-15</sub> was chromosomally integrated within a Tn<i>3</i>–IS<i>Ecp1</i> transposon unit, while <i>bla</i><sub>TEM-1B</sub> and <i>bla</i><sub>OXA-1</sub> were associated with diverse plasmid-associated syntenic architectures flanked by IS<i>1</i>, IS<i>91</i>, or integron-associated regions. Other antibiotic resistance genes were detected, conferring resistance to aminoglycosides (<i>aph(3’)-Ia</i>, <i>aac(3)-IIa</i>, <i>aac(3)-IIe</i>, <i>aadA1</i>, <i>aadA2</i>), sulfonamides (<i>sul1</i>, <i>sul2</i>) and trimethoprim (<i>dfrA</i> variants). A diverse array of virulence genes was identified, associated with adhesion, iron acquisition, serum resistance, and toxin production. Phylogenomic clustering revealed close relationships between local ST131/ST69 isolates and counterparts across Africa.</p> Conclusions <p>The study identifies diverse MDR <i>E. coli</i> clones circulating in bloodstream infections, notably high-risk lineages ST131, ST69 and ST10, with complex resistance and virulence gene arsenals facilitated by MGEs. These insights reinforce the imperative for genomic surveillance to guide infection control and antibiotic stewardship in high-burden settings.</p>

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Pathogenomics of multidrug-resistant Escherichia coli from bloodstream infections in South Africa

  • Bakoena Ashton Hetsa,
  • Esther Eyram Asare Yeboah,
  • Arshad Ismail,
  • Sabiha Yusuf Essack,
  • Daniel Gyamfi Amoako

摘要

Background

Escherichia coli (E. coli) is a leading cause of bloodstream infections (BSIs) globally, with multidrug-resistant (MDR) strains complicating treatment outcomes. In South Africa, genomic data on such isolates remain scarce. To elucidate the genomic landscape of E. coli isolates from bloodstream infections (BSIs) collected over a one-year period in the uMgungundlovu District, South Africa, with a focus on the resistance and virulence genes, mobile genetic elements (MGEs), genetic synteny, sequence types (STs), and phylogenomic context.

Methods

Twenty-five non-duplicate E. coli isolates were recovered from blood cultures and subjected to antimicrobial susceptibility testing. All twelve MDR isolates underwent whole-genome sequencing and bioinformatic analysis.

Results

The MDR isolates comprised six distinct STs, notably high-risk international lineages ST131 (33.3%) and ST69 (25.0%), spanning five phylogroups, predominantly B2 and D. Eight O: H serotypes were identified, with O25:H4 and O45:H16 being most frequent. CH-typing revealed dominant CH types CH40-30 (ST131) and CH35-27 (ST69) and fimH alleles such as fimH30 and fimH27. The isolates encoded β-lactamases, including blaCTX-M-15, blaTEM-1B and blaOXA-1, frequently co-located with MGEs. Notably, blaCTX-M-15 was chromosomally integrated within a Tn3–ISEcp1 transposon unit, while blaTEM-1B and blaOXA-1 were associated with diverse plasmid-associated syntenic architectures flanked by IS1, IS91, or integron-associated regions. Other antibiotic resistance genes were detected, conferring resistance to aminoglycosides (aph(3’)-Ia, aac(3)-IIa, aac(3)-IIe, aadA1, aadA2), sulfonamides (sul1, sul2) and trimethoprim (dfrA variants). A diverse array of virulence genes was identified, associated with adhesion, iron acquisition, serum resistance, and toxin production. Phylogenomic clustering revealed close relationships between local ST131/ST69 isolates and counterparts across Africa.

Conclusions

The study identifies diverse MDR E. coli clones circulating in bloodstream infections, notably high-risk lineages ST131, ST69 and ST10, with complex resistance and virulence gene arsenals facilitated by MGEs. These insights reinforce the imperative for genomic surveillance to guide infection control and antibiotic stewardship in high-burden settings.