Max Planck Society
Max Planck Institut for Biogeochemistry



How climate defines the traits of plant roots
June 10, 2021



To analyse their characteristic traits, the roots are washed and spread out in dishes with water. Using various computer programmes, scientists can, e.g., analyse and classify specific root lengths and diameters and display them in different colours. (Picture: Larry York, Noble Research Institute)
Leipzig/Jena/Wyoming/Wageningen. The specific traits of a plant determine the environmental conditions under which this plant prevails. A new study led by the University of Wyoming (UW) together with the German Centre for Integrative Biodiversity Research (iDiv), Leipzig University (UL), the Max Planck Institute for Biogeochemistry (MPI-BGC) and Wageningen University & Research (WUR) published in Nature Ecology and Evolution sheds light on this relationship with a focus on roots – and challenges the nature of ecological trade-offs.

Plant roots generally remain hidden belowground, but their role for the distribution of plants should not be underestimated: Roots are essential for water and nutrient uptake, yet little is known about the influence of root traits on species distributions. To investigate this relationship, an international team of researchers analysed the root trait database GRooT, based on the TRY Plant Trait Database hosted at the Max Planck Institute for Biogeochemistry, and the vegetation database sPlot, each being the largest database of its kind. The work was facilitated by iDiv’s synthesis centre sDiv, which supports collaboration of scientists from different countries and disciplines.

Temperature and water supply define root traits

The researchers analysed several root traits: the specific root length and root diameter on the one hand, and the root tissue density and root nitrogen content on the other hand and compared them to the environmental conditions under which these plants occur. The researchers found that in forests, species with relatively thick fine roots and high root tissue density were more likely to occur in warm climates while species with more delicate and longer fine roots and low root tissue density were found more often in cold climates – a classical trade-off.

By contrast, forest species with large-diameter roots and high root tissue density were more commonly associated with dry climates, but species with the opposite trait values were not associated with wet climates. Instead, a diversity of root traits occurred in warm or wet climates.

Root traits challenge the nature of ecological trade-offs

Ecological theory is built on trade-offs where trait differences among species evolved as adaptations to different environments, but you cannot have it all: an organism can be good in certain things at the cost of something else. For plants, this means that low trait values (e.g. low specific root length in this study) are associated with advantages under certain climate conditions, whereas high trait values (e.g. high specific root length) confer benefits under opposing conditions. However, certain root traits did not follow this general theory but were associated with unidirectional benefits: there is a benefit for high trait values in certain environmental conditions, but no benefit of low trait values in other conditions. “We were surprised at how common these unidirectional benefits were in roots compared to classical trade-offs,” says first author Daniel Laughlin, plant ecologist from the University of Wyoming. “This challenges our understanding of how traits drive species distributions, which we have been puzzled by as a scientific community,” adds last author Alexandra Weigelt, plant ecologist at Leipzig University and member of iDiv.

This suggests that unidirectional benefits might be more widespread than previously thought. Unidirectional benefits were consistently associated with the more extreme cold and dry climates that are more resource-limited than warm and wet climates. By contrast, warm and wet climates were associated with a larger diversity of root traits. “We believe that our work helps to understand the trait combinations that are possible in certain climate zones. This is important knowledge for ecosystem restoration in a changing world,” says Liesje Mommer, plant ecologist at the University of Wageningen.

(adopted from Kati Kietzmann, iDiv)

Original publication
Daniel C. Laughlin, Liesje Mommer…, Francesco Maria Sabatini, Helge Bruelheide, …, Nathaly R. Guerrero-Ramírez, …, Jens Kattge, …, Fons van der Plas, …, Jürgen Dengler, …, Alexandra Weigelt (2021).
Root traits explain plant species distributions along climatic gradients yet challenge the nature of ecological trade-offs.
Nature Ecology and Evolution, DOI: DOI: 10.1038/s41559-021-01471-7
URL: https://www.nature.com/articles/s41559-021-01471-7


Contact at MPI-BGC
Dr. Jens Kattge
jkattge@bgc-jena.mpg.de


Publication




Directions | Disclaimer | Data Protection | Contact | Internal | Webmail | Local weather | PRINT | © 2011-2021 Max Planck Institute for Biogeochemistry