Sebastian Hermann Erdrich (Düsseldorf / DE; Jülich / DE), Ulrich Schurr (Jülich / DE), Guido Grossmann (Düsseldorf / DE), Julia Frunzke (Jülich / DE), Borjana Arsova (Jülich / DE)
With the world population on the rise, it is crucial to optimize the utilization of arable resources and minimize food loss. Plant pathogenic bacteria which are estimated to account for 10% of our annual yield losses are gaining resistance against classical control strategies like antibiotics, which are a major problem. Bacteriophages as very specialized bacterial viruses hold great potential to overcome this challenge. Therefore, we investigate phages as a sustainable and targeted solution for biocontrol in agriculture with the potential to shape the plant microbiome.
Our research has led to the isolation and characterization of novel phages for the economically relevant plant pathogen Xanthomonas (Erdrich et al., 2022). Among those, we recently isolated the strictly virulent phage Seregon, which proved to be suitable for biocontrol of the plant pathogen Xanthomonas campestris. However, the influence of bacteriophages on plant physiology, particularly during interactions with pathogenic bacteria in planta, remains a significant knowledge gap. Understanding the phage's impact on bacterial infection dynamics and plant defence responses is pivotal for successful application strategies.
Here, we present infection studies of Arabidopsis thaliana with the plant pathogen Xanthomonas campestris. The application of the Xanthomonas phage Seregon could successfully counteract the bacterial infection almost to the level of the uninfected control. A meta-transcriptome analysis provided unprecedented insights into expression dynamics in this tripartite system and showed decreased plant defence gene upregulation in the presence of the bacteriophage. While X. campestris infection led to the expression of several salicylic acid-responsive genes and activation of the glucosinolate biosynthetic pathway. Furthermore, we observed a significant reduction of virulence expression in the bacterial transcriptome in the presence of the phage.
In conclusion, we show that natural phage diversity can be harnessed for phage-based plant biocontrol. Furthermore, our findings indicate that the application of phages effectively protects Arabidopsis thaliana against the pathogen Xanthomonas campestris. These results highlight the promising role of phages in plant protection strategies and pave the way for further exploration of their use in agricultural practices.
References
Erdrich et al. 2022. Viruses 14 (7): 1449
Erdrich et al. 2024. Microbial Biotechnology 6 (17): e14507
We use cookies on our website. Cookies are small (text) files that are created and stored on your device (e.g., smartphone, notebook, tablet, PC). Some of these cookies are technically necessary to operate the website, other cookies are used to extend the functionality of the website or for marketing purposes. Apart from the technically necessary cookies, you are free to allow or not allow cookies when visiting our website.