An international team led by researchers at The University of Manchester have discovered why some plants "live fast and die young" whilst others have long and healthy lives. The study, published in Science Advances, also helps us understand how plant diversity is maintained. This, in turn, could help improve nature conservation, natural habitat restoration and grow healthier crops. It seems the answer is hidden beneath our feet in the complex relationships between soil microbes and plant roots. Scientists have long suspected that the key to explaining plant diversity lay with their enemies, including harmful fungi found in the soil. However, studying microbial life in soil has been notoriously difficult, earning itself the name of "black box" among scientists. By using new molecular techniques and existing knowledge on what different fungi do in soil, the researchers found that some plants harboured dozens of different harmful fungi in their roots, while others kept harmful microbes at bay and attracted many beneficial fungi that boost plant health. Lead author, Dr Marina Semchenko, from the University's School of Earth and Environmental Sciences (SEES) said: "When walking through a flower-rich meadow, you might wonder why so many different plants grow together and no single plant dominates. We found that plant growth is strongly controlled by how many different harmful and beneficial fungi are attracted to plant roots." The researchers also found that the balance between harmful and beneficial fungi depended on plant lifestyle, providing an insight into why some plants live fast but die young while others grow slowly but enjoy a long life. The study was coordinated by the University of Manchester and involved collaboration between nine institutions including Universities of Colorado, Tartu, Berlin, Edinburgh and Lancaster. (Source: Agriculture and Food News, ScienceDaily. www.sciencedaily.com)
To test the soil the researchers replicated the monocultures of 14 common grassland species with soil from the Yorkshire Dales in controlled lab environment. Photo Credit: Marina Semchenko, the University of Manchester