Leaf manganese concentrations as a tool to assess belowground plant functioning in phosphorus-impoverished environments
| Autor: | Hans Lambers, William Foulds, Mark Westoby, Erik J. Veneklaas, Emma F. Gray, Michael W. Shane, Christiana Staudinger, Nigel D. Swarts, William D. Stock, John Turner, Jun Wasaki, Yanggui Xu, Peter J. Bellingham, Lisa Patrick Bentley, Sean M. Gleason, Ian J. Wright, Robert M. Kooyman, Alex Boonman, Yadvinder Malhi, Benjamin L. Turner, Sarah J. Richardson, Caio Guilherme Pereira, Patrick E. Hayes, Lucas A. Cernusak |
|---|---|
| Rok vydání: | 2020 |
| Předmět: |
0106 biological sciences
Rhizosphere Functional type food and beverages Soil Science Plant physiology Climatic variables chemistry.chemical_element 04 agricultural and veterinary sciences Plant Science Manganese 15. Life on land 01 natural sciences chemistry.chemical_compound chemistry Soil pH Botany 040103 agronomy & agriculture 0401 agriculture forestry and fisheries Substrate specificity Carboxylate 010606 plant biology & botany |
| Zdroj: | Plant and Soil. 461:43-61 |
| ISSN: | 1573-5036 0032-079X |
| DOI: | 10.1007/s11104-020-04690-2 |
| Popis: | Root-released carboxylates enhance the availability of manganese (Mn), which enters roots through transporters with low substrate specificity. Leaf Mn concentration ([Mn]) has been proposed as a signature for phosphorus (P)-mobilising carboxylates in the rhizosphere. Here we test whether leaf [Mn] provides a signature for root functional types related to P acquisition. Across 727 species at 66 sites in Australia and New Zealand, we measured leaf [Mn] as related to root functional type, while also considering soil and climate variables. To further assess the specific situations under which leaf [Mn] is a suitable proxy for rhizosphere carboxylate concentration, we studied leaf [Mn] along a strong gradient in water availability on one representative site. In addition, we focused on two systems where a species produced unexpected results. Controlling for background site-specific variation in leaf [Mn] with soil pH and mean annual precipitation, we established that mycorrhizal species have significantly lower leaf [Mn] than non-mycorrhizal species with carboxylate-releasing root structures, e.g., cluster roots. In exception to the general tendency, leaf [Mn] did not provide information about root functional types under seasonally waterlogged conditions, which increase iron availability and thereby interfere with Mn-uptake capacity. Two further exceptions were scrutinised, leading to the conclusion that they were ‘anomalous’ in not functioning like typical species in their families, as expected according to the literature. Leaf [Mn] variation provides considerable insights on differences in belowground functioning among co-occurring species. Using this approach, we concluded that, within typical mycorrhizal families, some species actually depend on a carboxylate-releasing P-mobilising strategy. Likewise, within families that are known to produce carboxylate-releasing cluster roots, some do not produce functional cluster roots when mature. An analysis of leaf [Mn] can alert us to such ‘anomalous’ species. |
| Databáze: | OpenAIRE |
| Externí odkaz: |
|
Full text from SpringerLink