Algae-fungi symbioses and bacteria-fungi co-exclusion drive tree species-specific differences in canopy bark microbiomes

Jule Freudenthal, Kenneth Dumack, Stefan Schaffer, Martin Schlegel, Michael Bonkowski
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Abstract

With over 3 trillion trees, forest ecosystems comprise nearly one-third of the terrestrial surface of the Earth. Very little attention has been given to the exploration of the above-ground plant microbiome of trees, its complex trophic interactions, and variations among tree species. To address this knowledge gap, we applied a primer-independent shotgun metatranscriptomic approach to assess the entire living canopy bark microbiome comprising prokaryotic and eukaryotic primary producers, decomposers, and various groups of consumers. With almost 1500 genera, we found a high microbial diversity on three tree species with distinct bark textures: oak (Quercus robur), linden (Tilia cordata), both with rough bark, and maple (Acer pseudoplatanus) with smooth bark. Core co-occurrence network analysis revealed a rich food web dominated by algal primary producers, and bacterial and fungal decomposers, sustaining a diverse community of consumers, including protists, microscopic metazoans and predatory bacteria. Whereas maple accommodated a depauperate microbiome, oak and linden accommodated a richer microbiome mainly differing in their relative community composition: Bacteria exhibited an increased dominance on linden, whereas co-occurring algae and fungi dominated on oak, highlighting the importance of algal-fungal lichen symbioses even at the microscopic scale. Further, due to bacteria-fungi co-exclusion, bacteria on bark are not the main beneficiaries of algae-derived carbon compounds as it is known from aquatic systems.
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藻类-真菌共生和细菌-真菌共存驱动树冠树皮微生物群的树种特异性差异
森林生态系统拥有超过 3 万亿棵树,占地球陆地表面的近三分之一。人们很少关注树木的地上植物微生物组、其复杂的营养相互作用以及不同树种之间的差异。为了填补这一知识空白,我们采用了一种与引物无关的枪式元转录组学方法来评估整个活树冠树皮微生物组,其中包括原核和真核初级生产者、分解者以及各类消费者。在近 1500 个菌属中,我们发现三种树皮质地不同的树种具有很高的微生物多样性:栎树(Quercus robur)和椴树(Tilia cordata)的树皮都很粗糙,而枫树(Acer pseudoplatanus)的树皮则很光滑。核心共现网络分析揭示了一个以藻类初级生产者、细菌和真菌分解者为主的丰富的食物网,维持着包括原生动物、微小元虫和捕食性细菌在内的多种消费者群落。枫树的微生物群落较为贫乏,而橡树和椴树的微生物群落较为丰富,这主要体现在它们的相对群落组成上:细菌在椴树上占主导地位,而共生的藻类和真菌在橡树上占主导地位,这突出表明了藻类-真菌地衣共生的重要性,即使在微观尺度上也是如此。此外,由于细菌与真菌共生,树皮上的细菌并不是藻类衍生碳化合物的主要受益者,这在水生系统中是众所周知的。
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