Stem decomposition of temperate tree species is determined by stem traits and fungal community composition during early stem decay
Dead trees are vital structural elements in forests playing key roles in the carbon and nutrient cycle. Stem traits and fungal community composition are both important drivers of stem decay, and thereby affect ecosystem functioning, but their relative importance for stem decomposition over time remains unclear. To address this issue, we used a common garden decomposition experiment in a Dutch larch forest hosting fresh logs from 13 common temperate tree species. In total 25 fresh wood and bark traits were measured as indicators of wood accessibility for decomposers, nutritional quality, and chemical or physical defense mechanisms. After one and four years of decay, we assessed the richness and composition of wood-inhabiting fungi using amplicon sequencing and determined the proportional wood density loss. Average proportional wood density loss for the first year was 18.5%, with further decomposition occurring at a rate of 4.3% yr-1 for the subsequent three years across tree species. Proportional wood density loss varied widely across tree species in the first year (8.7-24.8% yr-1) and subsequent years (0-11.3% yr-1). The variation was directly driven by initial wood traits during the first decay year, then later directly driven by bark traits and fungal community composition. Moreover, bark traits affected the composition of wood-inhabiting fungi and thereby indirectly affected decomposition rates. Specifically, traits promoting resource acquisition of the living tree, such as wide conduits that increase accessibility and high nutrient concentration, increased initial wood decomposition rates. Fungal community composition, but not fungal richness explained differences in wood decomposition after four years of exposure in the field, where fungal communities dominated by brown-rot and white-rot Basidiomycetes were linked to higher wood decomposition rate. Synthesis. Understanding what drives deadwood decomposition through time is important to understand the dynamics of carbon stocks. Here, using a tailor-made experimental design in a temperate forest setting, we have shown that stem trait variation is key to understanding the roles of these drivers; Initially, wood traits explained decomposition rates while subsequently, bark traits and fungal decomposer composition drove decomposition rates. These findings inform forest management with a view to selecting tree species to promote carbon storage.
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Wageningen University & Research
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| Subjects: | Bark traits, Ecosystem function and services, FOS: Biological sciences, Fungal community, density loss, physical-chemical traits, saprotrophic fungi, wood decomposition, wood traits, |
| Online Access: | https://research.wur.nl/en/datasets/stem-decomposition-of-temperate-tree-species-is-determined-by-ste |
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Bark traits Ecosystem function and services FOS: Biological sciences Fungal community density loss physical-chemical traits saprotrophic fungi wood decomposition wood traits Bark traits Ecosystem function and services FOS: Biological sciences Fungal community density loss physical-chemical traits saprotrophic fungi wood decomposition wood traits |
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Bark traits Ecosystem function and services FOS: Biological sciences Fungal community density loss physical-chemical traits saprotrophic fungi wood decomposition wood traits Bark traits Ecosystem function and services FOS: Biological sciences Fungal community density loss physical-chemical traits saprotrophic fungi wood decomposition wood traits Yang, S.S. Poorter, Lourens Sterck, Frank J. Cornelissen, Johannes H.C. van Logtestijn, Richardus S.P. Kuramae, Eiko E. Hefting, Mariet M. Goudzwaard, Leo Chang, Chenhui Sass-Klaassen, Ute Stem decomposition of temperate tree species is determined by stem traits and fungal community composition during early stem decay |
| description |
Dead trees are vital structural elements in forests playing key roles in the carbon and nutrient cycle. Stem traits and fungal community composition are both important drivers of stem decay, and thereby affect ecosystem functioning, but their relative importance for stem decomposition over time remains unclear. To address this issue, we used a common garden decomposition experiment in a Dutch larch forest hosting fresh logs from 13 common temperate tree species. In total 25 fresh wood and bark traits were measured as indicators of wood accessibility for decomposers, nutritional quality, and chemical or physical defense mechanisms. After one and four years of decay, we assessed the richness and composition of wood-inhabiting fungi using amplicon sequencing and determined the proportional wood density loss. Average proportional wood density loss for the first year was 18.5%, with further decomposition occurring at a rate of 4.3% yr-1 for the subsequent three years across tree species. Proportional wood density loss varied widely across tree species in the first year (8.7-24.8% yr-1) and subsequent years (0-11.3% yr-1). The variation was directly driven by initial wood traits during the first decay year, then later directly driven by bark traits and fungal community composition. Moreover, bark traits affected the composition of wood-inhabiting fungi and thereby indirectly affected decomposition rates. Specifically, traits promoting resource acquisition of the living tree, such as wide conduits that increase accessibility and high nutrient concentration, increased initial wood decomposition rates. Fungal community composition, but not fungal richness explained differences in wood decomposition after four years of exposure in the field, where fungal communities dominated by brown-rot and white-rot Basidiomycetes were linked to higher wood decomposition rate. Synthesis. Understanding what drives deadwood decomposition through time is important to understand the dynamics of carbon stocks. Here, using a tailor-made experimental design in a temperate forest setting, we have shown that stem trait variation is key to understanding the roles of these drivers; Initially, wood traits explained decomposition rates while subsequently, bark traits and fungal decomposer composition drove decomposition rates. These findings inform forest management with a view to selecting tree species to promote carbon storage. |
| format |
Dataset |
| topic_facet |
Bark traits Ecosystem function and services FOS: Biological sciences Fungal community density loss physical-chemical traits saprotrophic fungi wood decomposition wood traits |
| author |
Yang, S.S. Poorter, Lourens Sterck, Frank J. Cornelissen, Johannes H.C. van Logtestijn, Richardus S.P. Kuramae, Eiko E. Hefting, Mariet M. Goudzwaard, Leo Chang, Chenhui Sass-Klaassen, Ute |
| author_facet |
Yang, S.S. Poorter, Lourens Sterck, Frank J. Cornelissen, Johannes H.C. van Logtestijn, Richardus S.P. Kuramae, Eiko E. Hefting, Mariet M. Goudzwaard, Leo Chang, Chenhui Sass-Klaassen, Ute |
| author_sort |
Yang, S.S. |
| title |
Stem decomposition of temperate tree species is determined by stem traits and fungal community composition during early stem decay |
| title_short |
Stem decomposition of temperate tree species is determined by stem traits and fungal community composition during early stem decay |
| title_full |
Stem decomposition of temperate tree species is determined by stem traits and fungal community composition during early stem decay |
| title_fullStr |
Stem decomposition of temperate tree species is determined by stem traits and fungal community composition during early stem decay |
| title_full_unstemmed |
Stem decomposition of temperate tree species is determined by stem traits and fungal community composition during early stem decay |
| title_sort |
stem decomposition of temperate tree species is determined by stem traits and fungal community composition during early stem decay |
| publisher |
Wageningen University & Research |
| url |
https://research.wur.nl/en/datasets/stem-decomposition-of-temperate-tree-species-is-determined-by-ste |
| work_keys_str_mv |
AT yangss stemdecompositionoftemperatetreespeciesisdeterminedbystemtraitsandfungalcommunitycompositionduringearlystemdecay AT poorterlourens stemdecompositionoftemperatetreespeciesisdeterminedbystemtraitsandfungalcommunitycompositionduringearlystemdecay AT sterckfrankj stemdecompositionoftemperatetreespeciesisdeterminedbystemtraitsandfungalcommunitycompositionduringearlystemdecay AT cornelissenjohanneshc stemdecompositionoftemperatetreespeciesisdeterminedbystemtraitsandfungalcommunitycompositionduringearlystemdecay AT vanlogtestijnrichardussp stemdecompositionoftemperatetreespeciesisdeterminedbystemtraitsandfungalcommunitycompositionduringearlystemdecay AT kuramaeeikoe stemdecompositionoftemperatetreespeciesisdeterminedbystemtraitsandfungalcommunitycompositionduringearlystemdecay AT heftingmarietm stemdecompositionoftemperatetreespeciesisdeterminedbystemtraitsandfungalcommunitycompositionduringearlystemdecay AT goudzwaardleo stemdecompositionoftemperatetreespeciesisdeterminedbystemtraitsandfungalcommunitycompositionduringearlystemdecay AT changchenhui stemdecompositionoftemperatetreespeciesisdeterminedbystemtraitsandfungalcommunitycompositionduringearlystemdecay AT sassklaassenute stemdecompositionoftemperatetreespeciesisdeterminedbystemtraitsandfungalcommunitycompositionduringearlystemdecay |
| _version_ |
1813191890748571648 |
| spelling |
dig-wur-nl-wurpubs-6316182024-07-03 Yang, S.S. Poorter, Lourens Sterck, Frank J. Cornelissen, Johannes H.C. van Logtestijn, Richardus S.P. Kuramae, Eiko E. Hefting, Mariet M. Goudzwaard, Leo Chang, Chenhui Sass-Klaassen, Ute Dataset Stem decomposition of temperate tree species is determined by stem traits and fungal community composition during early stem decay 2024 Dead trees are vital structural elements in forests playing key roles in the carbon and nutrient cycle. Stem traits and fungal community composition are both important drivers of stem decay, and thereby affect ecosystem functioning, but their relative importance for stem decomposition over time remains unclear. To address this issue, we used a common garden decomposition experiment in a Dutch larch forest hosting fresh logs from 13 common temperate tree species. In total 25 fresh wood and bark traits were measured as indicators of wood accessibility for decomposers, nutritional quality, and chemical or physical defense mechanisms. After one and four years of decay, we assessed the richness and composition of wood-inhabiting fungi using amplicon sequencing and determined the proportional wood density loss. Average proportional wood density loss for the first year was 18.5%, with further decomposition occurring at a rate of 4.3% yr-1 for the subsequent three years across tree species. Proportional wood density loss varied widely across tree species in the first year (8.7-24.8% yr-1) and subsequent years (0-11.3% yr-1). The variation was directly driven by initial wood traits during the first decay year, then later directly driven by bark traits and fungal community composition. Moreover, bark traits affected the composition of wood-inhabiting fungi and thereby indirectly affected decomposition rates. Specifically, traits promoting resource acquisition of the living tree, such as wide conduits that increase accessibility and high nutrient concentration, increased initial wood decomposition rates. Fungal community composition, but not fungal richness explained differences in wood decomposition after four years of exposure in the field, where fungal communities dominated by brown-rot and white-rot Basidiomycetes were linked to higher wood decomposition rate. Synthesis. Understanding what drives deadwood decomposition through time is important to understand the dynamics of carbon stocks. Here, using a tailor-made experimental design in a temperate forest setting, we have shown that stem trait variation is key to understanding the roles of these drivers; Initially, wood traits explained decomposition rates while subsequently, bark traits and fungal decomposer composition drove decomposition rates. These findings inform forest management with a view to selecting tree species to promote carbon storage. Dead trees are vital structural elements in forests playing key roles in the carbon and nutrient cycle. Stem traits and fungal community composition are both important drivers of stem decay, and thereby affect ecosystem functioning, but their relative importance for stem decomposition over time remains unclear. To address this issue, we used a common garden decomposition experiment in a Dutch larch forest hosting fresh logs from 13 common temperate tree species. In total 25 fresh wood and bark traits were measured as indicators of wood accessibility for decomposers, nutritional quality, and chemical or physical defense mechanisms. After one and four years of decay, we assessed the richness and composition of wood-inhabiting fungi using amplicon sequencing and determined the proportional wood density loss. Average proportional wood density loss for the first year was 18.5%, with further decomposition occurring at a rate of 4.3% yr-1 for the subsequent three years across tree species. Proportional wood density loss varied widely across tree species in the first year (8.7-24.8% yr-1) and subsequent years (0-11.3% yr-1). The variation was directly driven by initial wood traits during the first decay year, then later directly driven by bark traits and fungal community composition. Moreover, bark traits affected the composition of wood-inhabiting fungi and thereby indirectly affected decomposition rates. Specifically, traits promoting resource acquisition of the living tree, such as wide conduits that increase accessibility and high nutrient concentration, increased initial wood decomposition rates. Fungal community composition, but not fungal richness explained differences in wood decomposition after four years of exposure in the field, where fungal communities dominated by brown-rot and white-rot Basidiomycetes were linked to higher wood decomposition rate. Synthesis. Understanding what drives deadwood decomposition through time is important to understand the dynamics of carbon stocks. Here, using a tailor-made experimental design in a temperate forest setting, we have shown that stem trait variation is key to understanding the roles of these drivers; Initially, wood traits explained decomposition rates while subsequently, bark traits and fungal decomposer composition drove decomposition rates. These findings inform forest management with a view to selecting tree species to promote carbon storage. Wageningen University & Research text/html https://research.wur.nl/en/datasets/stem-decomposition-of-temperate-tree-species-is-determined-by-ste 10.5061/dryad.qrfj6q5pw https://edepot.wur.nl/661601 Bark traits Ecosystem function and services FOS: Biological sciences Fungal community density loss physical-chemical traits saprotrophic fungi wood decomposition wood traits Wageningen University & Research |