Elucidating the molecular basis of copper stress in Erwinia amylovora

Abstract

Erwinia amylovora, a quarantine organism of the European Union (EU), is the causal agent of fire blight. This disease causes substantial economic losses in all countries where it is present and its control turns out difficult, due to the absence of effective chemical and biological treatments and the ability of persistence and dissemination of E. amylovora. Cupric treatments constitute the base of the integrated management of fire blight in the European Union countries, because the antibiotics, although have been proved useful against this disease, are forbidden in the EU for plant treatments. This thesis, mostly performed in a P2 security lab, is aimed to dilucidate molecular mechanisms implicated in the response of E. amylovora to copper sulfate as a stress factor, considering that copper is a well known toxic element for bacterial cells over a certain threshold concentration. The global objective was first addressed with the study of a selection of genes that have been related in other bacterial models with copper stress or with stress in general. The quantification of the rpoS gene expression in presence of copper showed that, at least in long-term survival, this gene may be involved in the E. amylovora response to copper stress. Second, a transcriptomic study was performed by microarray after subdue the bacteria to a copper shock treatment. The analysis of the microarray results showed that 44 genes were differentially expressed in presence of this metal. Each one of these genes was studied by gene ontology and, after comparing them with databases published in NCBI, they were classified in functional categories. The gene expression of twenty-five out of fourty-four differentially expressed genes was validated by real-time PCR. In the validation, copA gene was expressed more than 19-fold in presence than in absence of copper and, because of that, it was selected together with other seven genes (soxS, yjcE, ygcF, yhhQ, galF, arcB, EAM_3469), which also showed an increased expression, to generate mutants of E. amylovora. The responses of mutants to copper, and the fact that the wild phenotype was restored in the complemented mutants, has shown the role of copA, soxS, yjcE, ygcF, arcB and yhhQ genes in the E. amylovora in vitro survival against copper stress. Besides, the implication of copA gene has also been proved in planta, in copper treated shoots from pear trees. Finally, all the results obtained along this thesis have allowed to elaborate a putative model of the different genetic mechanisms that seem are involved in the interaction between E. amylovora and copper. The most important mechanism seems to be to face up reactive oxygen species (ROS) by the activation of the soxS and yjcE genes. The activity of these genes is supported by CopA protein, which pumps copper from inside the cell out to the periplasmic space. The activation of arcB gene, which allows the change from aerobic metabolism to anaerobic metabolism, would also help E. amylovora to reduce ROS. Taking together, the results of this thesis have allowed an approximation to the genetic basis of E. amylovora response to copper stress and they constitute a start point to move forward in the knowledge of the molecular mechanisms underlying that response.