Serpula lacrymans reacts with a general, unspecialized chemical response during interaction with mycoparasitic Trichoderma spp. and bacteria

IF 1.9 3区环境科学与生态学 Q3 ECOLOGY Fungal Ecology Pub Date : 2023-06-01 DOI:10.1016/j.funeco.2023.101230

Julia Embacher , Manuela Seehauser , Christoph Kappacher , Stefan Stuppner , Susanne Zeilinger , Martin Kirchmair , Sigrid Neuhauser

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Abstract

Serpula lacrymans causes structural damage in timber via cellulose and hemicellulose decomposition. Serpula lacrymans shares its habitat with bacteria and fungi, interactions that often result in stress and changed behaviour of the partners. A typical response to environmental stress is the production of bioactive metabolites and pigments. The diversity and function of these metabolites in inter- and intra-kingdom interactions, is largely elusive. Using dual culture approaches and secondary metabolite fingerprinting with high performance thin layer chromatography (HPTLC) it was demonstrated that stress induces an unspecific vs. Similar metabolite patterns were identified when S. lacrymans was co-cultured with different bacteria and mycoparasitic fungi (Trichoderma spp.). By analysing the metabolites produced along the gradient from the contact zone to more remote parts of the mycelium, we show a systemic reaction of S. lacrymans and that direct contact with other microbes is not a necessity to induce secondary metabolites.

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在与支寄生虫、木霉和细菌的相互作用中，泪螺具有一般的、非特化的化学反应

Serpula lacrymans通过纤维素和半纤维素分解导致木材结构损伤。Serpula lacrymans与细菌和真菌共享栖息地，这种相互作用往往会导致伴侣的压力和行为改变。对环境压力的典型反应是产生生物活性代谢产物和色素。这些代谢物在王国间和王国内相互作用中的多样性和功能在很大程度上是难以捉摸的。使用双重培养方法和具有高效薄层色谱（HPTLC）的次级代谢产物指纹图谱，证明了应激诱导非特异性vs。当S.lacrymans与不同的细菌和分枝寄生真菌（木霉属）共同培养时，发现了类似的代谢产物模式。通过分析沿着从接触区到菌丝体更偏远部分的梯度产生的代谢产物，我们显示了S.lacrymans的系统反应，并且与其他微生物的直接接触不是诱导次级代谢产物的必要条件。

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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.