Taro [Colocasia esculenta (L.) Schott.] is an important root crop in the world with great economic value. In recent years, outbreaks of soft rot were observed on taro plants in several plantation areas located in Shaoguan, Guangdong Province, China (25°7'57" N, 113°19'5" E). Root tubers of taro (Paodan variety) infected by soft rot had water-soaked lesions with a dark brown-black margin including a rotten smell, they also had internal rot that was also found in root tubers with no external symptoms. In some areas, the incidence of soft rot can reach up to 30%. To isolate the causal agent, ten pieces of taro root tubers with typical symptoms were surface-sterilized with 75% ethanol and 0.1% HgCl2 solution and then washed thrice with sterile water. The tuber slices were soaked in 50 ml sterile water and shaken at 28°C, 200 rpm for 2 h, and 100 µl was streaked onto the modified Yeast Extract Beef (YEB) agar medium (1% peptone, 0.5% yeast extract, 0.5% sucrose, 0.5% NaCl, 1 Mmol/L MgSO4•7H2O, 1.5% agar, pH 7.0) plates (Zhou et al. 2011) and incubated at 28°C for 24 h. Single colonies grown on YEB were selected for preliminary inoculation onto healthy taro (Paodan variety) slices. Two of the Gram-negative bacteria, named as ZXC1 and MPC2, developed symptoms consistent in rotted decay inside the root tubers after incubation for 24h at 30°C. ZXC1 and MPC2 were biochemically profiled using a Biolog Gen III MicroPlate (Microlog 3, 5.2) (Shen et al. 2019) and resulted Dickeya sp. (SIM 0.856 and 0.704). To determine the species of the Dickeya isolates, 16S rRNA sequences were amplified by primers 27F and 1492R (Hauben et al. 1998). Housekeeping genes including gyrB, atpD, rpoB, and infB were also amplified using degenerate primers (Brady et al. 2008). Results from the BLASTn analysis of the 16S rRNA (GenBank accession numbers MN853405, MN853406), gyrB (GenBank accession numbers MN866299, MN866303), atpD (GenBank accession numbers MN866298, MN866302), rpoB (GenBank accession numbers MN866301, MN866305), and infB (GenBank accession numbers MN866300, MN866304) genes in the isolates ZXC1 and MPC2 showed 99% identities to those of the previously reported D. fangzhongdai isolates from Phalaenopsis (Zhang et al. 2018). Multilocus sequence analysis (MLSA) by MEGA 7.0 performed with four housekeeping genes (gyrB, atpD, rpoB, infB) showed that they clustered with D. fangzhongdai isolates. Analyses using scanning and transmission electron microscopy showed that ZXC1 and MPC2 bacteria were rod-shaped, 0.5-1.0 μm × 1.0-3.0 µm, with peritrichous flagella. Pathogenicity tests were performed thrice using surface-sterilized 2-month-old taro seedlings (Paodan variety). Six individual seedlings were inoculated using a sterile syringe with ten microliters of bacterial suspension (108 CFU/ml) in Tris buffer (0.1 mol/L Tris and 0.1 mol/L HCl, pH 7.4). Taro seedlings injected with sterile Tris buffer were used as the negative control. These taro seedlings were grown in the greenhouse (30 ± 2°C, 90 ± 5% relative humidity). At the 25th day post inoculation, soft rot symptoms were observed in inoculated taro, while all control taro plants remained symptom-free. Small and pale yellow with irregular margins colonies consistent with morphological characteristics of those of D. fangzhongdai were re-isolated from symptomatic taro tubers and the housekeeping genes presence was verified by sequencing as described above, fulfilling Koch’s postulates. D. fangzhongdai is a newly emerging bacterial pathogen, which causes bleeding cankers in pear trees (Tian et al. 2016), and soft rot of Phalaenopsis (Zhang et al. 2018). This is the first report of D. fangzhongdai causing soft rot disease in taro. Considering the high incidence of soft rot, this pathogen might pose a significant threat to taro and other economically important crops. Therefore, further researches are needed to investigate host range of the pathogen and develop appropriate integrated management to contain this disease spreading.
The GacS-GacA type Two-component System (TCS) positively regulates pathogenicity-related phenotypes in many plant pathogens. In addition, Dickeya oryzae strain EC1, the causative agent of the soft rot disease, produces antibiotic‐like toxins called zeamines as one of the major virulence factors that inhibit the germination of rice seeds. The present study identified a GacS-GacA type TCS, named TzpS-TzpA, that positively controls the virulence of EC1 mainly by regulating the toxin zeamines production. RNA-seq analysis of strain EC1 and its tzpA mutant showed that the TCS regulated a wide range of virulence genes, especially those encoding zeamines. Protein-protein interaction was detected between TzpS and TzpA through the bacterial two-hybrid system and pull-down assay. In trans expressionof tzpA failed to rescue the defective phenotypes in both the ΔtzpS and ΔtzpSΔtzpA mutants. Furthermore, TzpA controls target gene expression by direct binding to DNA promoters which contain a Gac-box motif, including a regulatory RNA rsmB and the vfm quorum sensing system regulator vfmE. These findings therefore suggested that the EC1 TzpS-TzpA TCS system mediates the pathogenicity of Dickeya oryzae EC1 mainly by regulating the production of zeamines.
The cell motility is one of the key pathogenic factors that contribute to the virulence ofDickeya oryzea,which is a prevalent bacterial pathogen capable of infecting a range of crops and plants. We showed recently that the bacterial second messenger c-di-GMP, and the putrescine-mediated quorum sensing (QS) system, are both involved in the regulation of the bacterial motility inD. oryzeaEC1. In this study, we set to determine whether and how there two signaling mechanisms work together to modulate the bacterial motility. The results showed that the second messenger signaling system interacts with the putrescine QS system via the c-di-GMP receptor YcgR, which could promote the activity of SpeA, the rate-limiting enzyme in the putrescine biosynthesis pathway, thereby increasing the intracellular putrescine levels. However, it was shown that this facilitative effect could be inhibited by c-di-GMP molecules. In addition, we demonstrated the dominance of c-di-GMP over putrescine in the regulation of bacterial motility. The findings from this study provide the first insight into the interaction between c-di-GMP and putrescine in bacteria and provide a valuable reference for the study of intracellular second messenger system and polyamine-mediated quorum sensing system in other bacteria.ImportanceDickea oryzeais a major bacterial pathogen capable of infesting many plants and crops, causing significant economic damage to rice and banana production especially. Bacterial motility is a key pathogenic factor ofD. oryzeato compete for food resources and infect their host species, which is negatively regulated by c-di-GMP and positively regulated by putrescine, respectively. However, the connection between c-di-GMP and putrscine in regulating the motility ofD.oryzeais not understood. Here we revealed the link and the mechanism of interaction between them, showing that c-di-GMP interact with putrescine via a receptor of c-di-GMP. The significance of our research is in providing the first insight into the interaction between c-di-GMP and putrescine and the methods and experimental designs in our study will provide a valuable reference for subsequent studies on the link between c-di-GMP and putrescine in other bacteria and even the regulatory mechanisms of complex bacterial motility networks, respectively.
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