Abstract
Edwardsiella tarda is a facultative intracellular pathogen in humans and animals. The Gram-negative bacterium is widely considered a potentially important bacterial pathogen. Adaptation to acid stress is important for the transmission of intestinal microbes, so the acid-resistance (AR) system is essential. However, the AR systems of E. tarda are totally unknown. In this study, a lysine-dependent acid resistance (LDAR) system in E. tarda, CadBA, was characterized and identified. CadB is a membrane protein and shares high homology with the lysine/cadaverine antiporter. CadA contains a PLP-binding core domain and a pyridoxal phosphate-binding motif. It shares high homology with lysine decarboxylase. cadB and cadA are co-transcribed under one operon. To study the function of the cadBA operon, isogenic cadA, cadB and cadBA deletion mutant strains TX01ΔcadA, TX01ΔcadB and TX01ΔcadBA were constructed. When cultured under normal conditions, the wild type strain and three mutants exhibited the same growth performance. However, when cultured under acid conditions, the growth of three mutants, especially TX01ΔcadA, were obviously retarded, compared to the wild strain TX01, which indicates the important involvement of the cadBA operon in acid resistance. The deletion of cadB or cadA, especially cadBA, significantly attenuated bacterial activity of lysine decarboxylase, suggesting the vital participation of cadBA operon in lysine metabolism, which is closely related to acid resistance. The mutations of cadBA operon enhanced bacterial biofilm formation, especially under acid conditions. The deletions of the cadBA operon reduced bacterial adhesion and invasion to Hela cells. Consistently, the deficiency of cadBA operon abated bacterial survival and replication in macrophages, and decreased bacterial dissemination in fish tissues. Our results also show that the expression of cadBA operon and regulator cadC were up-regulated upon acid stress, and CadC rigorously regulated the expression of cadBA operon, especially under acid conditions. These findings demonstrate that the AR CadBA system was a requisite for the resistance of E. tarda against acid stress, and played a critical role in bacterial infection of host cells and in host tissues. This is the first study about the acid resistance system of E. tarda and provides new insights into the acid-resistance mechanism and pathogenesis of E. tarda.
Highlights
Edwardsiella was isolated from infected humans and animals and identified as a new genus of Enterobacteriaceae in 1965 [1]
Characterization of cadBA operon sequence and its co‐transcription verification some genes or factors were identified to contribute to acid resistance of E. tarda, there is not any report on the classical acid resistance systems in E. tarda
The results show that the predicted Polymerase Chain Reaction (PCR) product of 795 bp was amplified in the reaction using complementary DNA (cDNA) and genomic DNA (gDNA), but not in RNA (Figure 1B), which indicates that cadB and cadA are co-transcribed under one operon
Summary
Edwardsiella was isolated from infected humans and animals and identified as a new genus of Enterobacteriaceae in 1965 [1]. E. tarda has broad host ranges including aquatic animals, reptiles, amphibians, birds, mammals and humans [6,7,8], being a significant zoonotic pathogen [9]. This pathogen can cause serious systemic infections and high mortality in both seawater and freshwater fish, accounting for severe economic losses and heavily influencing the healthy development of aquaculture [10, 11]. E. tarda is widely considered a potentially important bacterial pathogen
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