Microorganisms leverage the CRISPR-Cas system as a defense mechanism against viral intrusions. In the realm of genetic engineering, this microbial immune system is repurposed for the targeted modification of the genetic makeup.
Under the leadership of Professor Dr. Alexander Probst, microbiologist at the Research Center One Health Ruhr at the Research Alliance Ruhr a research team has now discovered another function of this specialised genomic sequence: archaea – microorganisms that are often very similar to bacteria in appearance – also use them to fight parasites.
The team has recently published their findings in Nature Microbiology.
Biochemists Emmanuelle Charpentier and Jennifer Doudna received the Nobel Prize for the biotechnological application of the CRISPR-Cas systems, or ‘genetic scissors’, for genetic engineering in 2020. However, many functions of this genetic tool are still unexplored to date. Could microorganisms, for example, use them to fight off other microorganisms that live on them as parasites?
With this research question in mind, Alexander Probst analyzed the genetic material of microbes in the Earth’s deep crust. ‘More than 70 percent of the Earth’s microorganisms are housed in the deep biosphere. If we want to understand diversity on our planet, it is worth taking a look into the deep’, he explains.
With his team, the microbiologist has analyzed the water that a geyser in the USA spits to the surface from the depths, as well as samples from the Horonobe underground laboratory in Japan. The research team focused on archaea, which live in the ecosystem as hosts and parasites. The tiny microbes are highly similar to bacteria in cell size but have substantially different physiological properties.
The result of their genomic analysis provided new insights: there were conspicuously few parasites in the vicinity of the hosts, and the hosts showed genetic resistance to the parasites. The researchers discovered the reason for this in the genetic scissors in the genome of the microorganisms. ‘In the course of evolution, the archaea have incorporated the parasitic
Reference: “A predicted CRISPR-mediated symbiosis between uncultivated archaea” by Sarah P. Esser, Janina Rahlff, Weishu Zhao, Michael Predl, Julia Plewka, Katharina Sures, Franziska Wimmer, Janey Lee, Panagiotis S. Adam, Julia McGonigle, Victoria Turzynski, Indra Banas, Katrin Schwank, Mart Krupovic, Till L. V. Bornemann, Perla Abigail Figueroa-Gonzalez, Jessica Jarett, Thomas Rattei, Yuki Amano, Ian K. Blaby, Jan-Fang Cheng, William J. Brazelton, Chase L. Beisel, Tanja Woyke, Ying Zhang and Alexander J. Probst, 27 July 2023, Nature Microbiology.
DOI: 10.1038/s41564-023-01439-2