Plant stresses caused by phytopathogenic bacteria are categorized into biotic stresses. The study aimed to perform a meta-analysis of A. thaliana transcriptomic data in response to infection by P. syringae and P. syringae pv. maculicola. The gene expression and transcription factors (TFs) of A. thaliana infected by the bacteria were investigated using published RNA-Seq data. Also, critical factors, including hub genes, protein-protein interaction (PPI), and micro RNAs (miRNAs), were analyzed. A total number of ۲۲ biological pathways were significantly enriched with up-/down-regulated differentially expressed genes (DEGs) in the Kyoto Encyclopedia of Genes and Genomes (KEGG) analysis. Also, ۳۹ TFs of A. thaliana were altered during the bacterial infection. Moreover, ۵۰۳۴ DEGs were significantly different from non-stressed plants, of which ۲۲۹۱ and ۲۷۴۳ DEGs were up- and down-regulated, respectively. The expression of genes related to stress response, cellular process, metabolic process, and stimulus response was up-regulated in the bacteria-infected plant. In contrast, the down-regulation of genes involved in the cellular and biosynthesis processes was observed. Regarding molecular function, ۴۱۲ genes associated with kinase, catalase, and oxidoreductase activities were up-regulated in the bacteria-infected plants, while down-regulation of hydrolase and transferase activity genes was observed. The PPI network showed ۱۰۷ nodes and ۱۸۹ edges. The most important hubs genes included MYC۲, WRKY۴۰, WRKY۳۳, and other genes. Moreover, the total number of ۴۱ miRNA families was determined during the A. thaliana-bacterium interaction. Infection of A. thaliana by P. syringae and P. syringae pv. maculicola induced the expression of some stress-responsive genes and pathways among which some defense-related hub genes were identified. The results provide a clearer understanding of the strategies applied to program defense pathways in bacterial infection of A. thaliana.
