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Why oaks should stay with their close relatives: growing in a distantly related neighbourhood delays and reorganizes nutrient recycling during litter decomposition

Title:	Why oaks should stay with their close relatives: growing in a distantly related neighbourhood delays and reorganizes nutrient recycling during litter decomposition
Authors:	Santonja, Mathieu; Pan, Xu; Courty, Pierre-Emmanuel; Butenschön, Olaf; Berg, Matty P.; Murray, Phil; Yguel, Benjamin; Brulé, Daphnée; Zhang, Keliang; Prinzing, Andreas
Contributors:	Santonja, Mathieu; Pan, Xu; Courty, Pierre-Emmanuel; Butenschön, Olaf; Berg, Matty P.; Murray, Phil; Yguel, Benjamin; Brulé, Daphnée; Zhang, Keliang; Prinzing, Andreas
Publication Year:	2025
Collection:	Georg-August-Universität Göttingen: GoeScholar
Description:	Closely related species often conserve similar niches despite interacting negatively. We suggest that close relatives may interact positively via ecosystem feedbacks: leaf litter produced or exposed in a closely related neighbourhood (low phylogenetic isolation) may decompose more quickly, leading to more rapid nutrient recycling. We studied decomposition of leaf litter of oaks Quercus petraea across 8 and 14 months, reciprocally transplanting leaf litters between low and high phylogenetic isolation to distinguish between effects mediated by leaf litter quality and by decomposition environment. We found that, by affecting litter quality, phylogenetic isolation reduced decomposition across 14 months (loss of litter mass and C). Moreover, by affecting litter quality and decomposition environment, phylogenetic isolation reduced microbial biomass and extensively altered relationships between C and N losses and abundances/diversities of different soil organisms across 8 and 14 months. Phylogenetic isolation was to a large extant driven by percentage of gymnosperms, explaining the decomposition‐environment mediated effects. Such environment‐mediated effects reflected decreasing soil humidity and pH with phylogenetic isolation, while litter‐quality mediated effects reflected decreasing leaf phytophagy or increasing leaf phenolics. Tree‐species richness, in contrast, did not explain effects of phylogenetic isolation, and had little effect overall. To conclude, coexistence of oaks with distant relatives partly impedes recycling of leaf litter and re‐organizes the trajectories of this recycling. In contrast, oaks coexisting with close relatives may profit from a positive ecosystem feedback through increased nutrient recycling, possibly contributing to the conservation of the oak's niches. We suggest that such a positive ecosystem feedback among close relatives might exist in other late successional tree species.
Document Type:	article in journal/newspaper
Language:	English
DOI:	10.1111/oik.10567
Availability:	https://resolver.sub.uni-goettingen.de/purl?gro-2/147687; https://doi.org/10.1111/oik.10567
Rights:	info:eu-repo/semantics/openAccess ; http://creativecommons.org/licenses/by/3.0/
Accession Number:	edsbas.6EB52BE5
Database:	BASE