{Reference Type}: Journal Article
{Title}: Preferential use of carbon central metabolism and anaerobic respiratory chains in porcine extraintestinal pathogenic Escherichia coli during bloodstream infection.
{Author}: Ma J;Pan X;Zhong X;Bai Q;Liu G;Yao H;
{Journal}: Vet Microbiol
{Volume}: 249
{Issue}: 0
{Year}: Oct 2020
{Factor}: 3.246
{DOI}: 10.1016/j.vetmic.2020.108830
{Abstract}: Porcine extraintestinal pathogenic Escherichia coli (ExPEC) is occurring with increasing frequency in China, and leads to significant economic and welfare costs in the swine industry. The underlying mechanisms of porcine ExPEC in blood colonization during systematic infection is poorly understood. Here we measured the gene expression of porcine ExPEC in infected animal bloodstream in vivo and fresh swine blood in vitro. Using comparisons with P values of ≤ 0.01, we identified 354 and 313 genes as being significantly up- or down-regulated at least 2-fold change during bloodstream infection, respectively. Excepting for an array of iron acquisition systems, numerous genes involved in carbon central metabolism and anaerobic respiratory chains were upregulated here. These genes were categorized into several clusters including the TCA-cycle (frdABCD, citCEFXG), d-ribose transporter (rbsDACB), nickel transporter (nikABCDER), NiFe hydrogenase (hybOABCDEF, hycBCDEFG), Hyp-complex (hypABCDE), DMSO reductase (dmsABC and ynfEFGHI), format dehydrogenase (fdnGHI) and NADH dehydrogenase I (nuoA-N). The mutant with simultaneous inactivation of ribose and citrate imports showed significant reduced fitness in host blood, suggesting these two carbohydrates are utilized by central metabolism network as important carbon-source during bloodstream infection. Similar deficiency was also observed in the mutant double deleted NiFe hydrogenase 2 and 3 anaerobic respiratory chains. Further study found that FNR (a global regulator facilitating bacterial adaptation to anaerobic conditions) is an important regulator in response to bloodstream to activate center metabolism and anaerobic respiratory chains, thus contribute to the full-virulence of porcine ExPEC. These findings provide compelling evidence to support the notion that carbon central metabolism network and anaerobic respiratory chains play key roles for porcine ExPEC fitness within host bloodstream.