Thermal Adaptation Alters Response to Thermal Stress and Expression of Virulent Genes (eae, stx1, stx2, and hlyA) in Pathogenic Escherichia coli Isolated from Pork.

Escherichia coli encounter variety of environmental and processing stresses during their growth, survival, and infection. Herein, the thermotolerance behavior and transcription of virulent genes responsible for the pathogenicity in isolated strains of pathogenic E. coli were evaluated. Among 176 E. coli isolates, 4 isolates (2.27%) were confirmed to be pathogenic E. coli, out of which 2 isolates were positive for EHEC and 2 were positive for EPEC based on their virulence factors. Thermotolerance was induced under thermal adaptation at higher temperature, regardless of the pathotypes. Cells grown and adapted at 42 °C, exhibited highest transcription of genes associated with adhesion (eae), hemolysis (hlyA), and shiga toxin production (stx1). However, expression of these genes was downregulated in cells adapted at lower temperature of 4 °C and 25 °C compared to control. Further, transcription of stx2 was upregulated by 70% and 17% at 4 °C and 25 °C, respectively, while the transcription level was reduced by 44% relative to control at 42 °C. The findings indicate that expression of virulent genes in pathogenic E. coli at elevated temperature do not be depend on thermotolerance of the strain harboring these genes.