Tracing the spatial extent and lag time of carbon transfer from Picea abies to ectomycorrhizal fungi differing in host type, taxonomy, or hyphal development

IF 1.9 3区环境科学与生态学 Q3 ECOLOGY

Fungal Ecology Pub Date : 2023-12-05 DOI:10.1016/j.funeco.2023.101315

Erik A. Hobbie , Sonja G. Keel , Tamir Klein , Ido Rog , Matthias Saurer , Rolf Siegwolf , Michael R. Routhier , Christian Körner

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Abstract

We used five mature Picea abies continuously labeled with ¹³C-depleted CO₂ in a broadleaf-dominated Swiss forest to assess the spatial extent and lag time of carbon fluxes to ectomycorrhizal fungi differing in hyphal development and host association. We traced labeled carbon into ectomycorrhizal sporocarps collected for two seasons at different distances from labeled Picea. Picea-derived photosynthate reached conifer-specific sporocarps up to 6–12 m away and reached other sporocarps only 0–6 m away. At 0–6 m, genera of lesser hyphal development acquired more Picea-derived photosynthate than those of greater hyphal development, presumably from preferential fungal colonization of inner root zones by the former genera. Correlations of sporocarp δ¹³C with daily solar radiation integrated for different periods indicated that carbon fluxes from Picea to sporocarps peaked 17–21 days after photosynthesis. Thus, these results provided rough estimates of the spatial extent and temporal lags of carbon transfer from Picea to ectomycorrhizal fungi.

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追踪黑松向宿主类型、分类或菌丝发育不同的外生菌根真菌转移碳的空间范围和滞后时间

我们在瑞士一片以阔叶树为主的森林中使用了五棵连续标记了 13C 贫化二氧化碳的成熟欧鼠李，以评估碳通量的空间范围和滞后时间。我们追踪了两个季节在距离标记的云杉不同距离处收集的外生菌根真菌孢子块中的标记碳。针叶树产生的光合成代谢物可到达 6-12 米外针叶树特有的孢子囊，而其它孢子囊只能到达 0-6 米外。在 0-6 米处，菌丝发育较弱的菌属比菌丝发育较强的菌属获得更多的 Picea 衍生的光合作用物，这可能是由于前者优先在根内侧区域进行真菌定殖。孢子囊δ13C 与不同时期的日太阳辐射综合值的相关性表明，从冰龙属到孢子囊的碳通量在光合作用后 17-21 天达到峰值。因此，这些结果提供了对松柏向外生菌根真菌转移碳的空间范围和时间滞后的粗略估计。

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来源期刊

Fungal Ecology 环境科学-生态学

CiteScore

5.80

自引率

3.40%

发文量

审稿时长

3 months

期刊介绍： Fungal Ecology publishes investigations into all aspects of fungal ecology, including the following (not exclusive): population dynamics; adaptation; evolution; role in ecosystem functioning, nutrient cycling, decomposition, carbon allocation; ecophysiology; intra- and inter-specific mycelial interactions, fungus-plant (pathogens, mycorrhizas, lichens, endophytes), fungus-invertebrate and fungus-microbe interaction; genomics and (evolutionary) genetics; conservation and biodiversity; remote sensing; bioremediation and biodegradation; quantitative and computational aspects - modelling, indicators, complexity, informatics. The usual prerequisites for publication will be originality, clarity, and significance as relevant to a better understanding of the ecology of fungi.