Department of Chemical Engineering, Mid Sweden University, Sundsvall, Sweden.
Department of Plant Protection Biology, Swedish University of Agricultural Sciences, Alnarp, Sweden.
Appl Environ Microbiol. 2019 Oct 16;85(21). doi: 10.1128/AEM.01761-19. Print 2019 Nov 1.
Yeasts form mutualistic interactions with insects. Hallmarks of this interaction include provision of essential nutrients, while insects facilitate yeast dispersal and growth on plant substrates. A phylogenetically ancient chemical dialogue coordinates this interaction, where the vocabulary, the volatile chemicals that mediate the insect response, remains largely unknown. Here, we used gas chromatography-mass spectrometry, followed by hierarchical cluster and orthogonal partial least-squares discriminant analyses, to profile the volatomes of six spp., , and brewer's yeast (). The yeasts, which are all found in association with insects feeding on foliage or fruit, emit characteristic, species-specific volatile blends that reflect the phylogenetic context. Species specificity of these volatome profiles aligned with differential feeding of cotton leafworm () larvae on these yeasts. Bioactivity correlates with yeast ecology; phylloplane species elicited a stronger response than fruit yeasts, and larval discrimination may provide a mechanism for establishment of insect-yeast associations. The yeast volatomes contained a suite of insect attractants known from plant and especially floral headspace, including ()-hexenyl acetate, ethyl (2,4)-deca-2,4-dienoate (pear ester), (3)-4,8-dimethylnona-1,3,7-triene (DMNT), linalool, α-terpineol, β-myrcene, or (,)-α-farnesene. A wide overlap of yeast and plant volatiles, notably floral scents, further emphasizes the prominent role of yeasts in plant-microbe-insect relationships, including pollination. The knowledge of insect-yeast interactions can be readily brought to practical application, as live yeasts or yeast metabolites mediating insect attraction provide an ample toolbox for the development of sustainable insect management. Yeasts interface insect herbivores with their food plants. Communication depends on volatile metabolites, and decoding this chemical dialogue is key to understanding the ecology of insect-yeast interactions. This study explores the volatomes of eight yeast species which have been isolated from foliage, from flowers or fruit, and from plant-feeding insects. These yeasts each release a rich bouquet of volatile metabolites, including a suite of known insect attractants from plant and floral scent. This overlap underlines the phylogenetic dimension of insect-yeast associations, which according to the fossil record long predate the appearance of flowering plants. Volatome composition is characteristic for each species, aligns with yeast taxonomy, and is further reflected by a differential behavioral response of cotton leafworm larvae, which naturally feed on foliage of a wide spectrum of broad-leaved plants. Larval discrimination may establish and maintain associations with yeasts and is also a substrate for designing sustainable insect management techniques.
酵母与昆虫形成共生关系。这种相互作用的特征包括提供必需的营养物质,而昆虫则有助于酵母在植物基质上的传播和生长。这种共生关系是由一种古老的化学对话来协调的,其中词汇,即介导昆虫反应的挥发性化学物质,在很大程度上仍然未知。在这里,我们使用气相色谱-质谱联用仪,随后进行层次聚类和正交偏最小二乘判别分析,对六种酵母属的挥发性组进行了分析:酿酒酵母()、毕赤酵母()、汉逊酵母()、假丝酵母()、卡氏酵母()和脆壁克鲁维酵母()。这些酵母都存在于以树叶或果实为食的昆虫中,它们释放出特征性的、特定于物种的挥发性混合物,反映了其系统发育背景。这些挥发性组谱的物种特异性与棉铃虫幼虫对这些酵母的不同摄食相一致。生物活性与酵母的生态环境相关联;叶际酵母比果实酵母更能引起幼虫的强烈反应,幼虫的辨别可能为昆虫-酵母的共生关系的建立提供了一种机制。酵母的挥发性组包含了一套已知的来自植物、特别是花头部空间的昆虫引诱剂,包括()-己烯基乙酸酯、乙基(2,4)-癸-2,4-二烯酸酯(梨酯)、(3)-4,8-二甲基壬-1,3,7-三烯(DMNT)、芳樟醇、α-萜品醇、β-月桂烯、或(,)-α-法呢烯。酵母和植物挥发物的广泛重叠,特别是花香,进一步强调了酵母在植物-微生物-昆虫关系中的突出作用,包括授粉。对昆虫-酵母相互作用的了解可以很容易地应用于实际应用,因为活酵母或介导昆虫吸引的酵母代谢物为可持续的昆虫管理提供了丰富的工具。酵母将昆虫草食者与它们的食物植物联系起来。交流依赖于挥发性代谢物,解码这种化学对话是理解昆虫-酵母相互作用生态的关键。本研究探索了从树叶、花朵或果实以及植物取食昆虫中分离出来的八种酵母的挥发性组。这些酵母各自释放出丰富的挥发性代谢物,包括一套来自植物和花香的已知昆虫引诱剂。这种重叠突出了昆虫-酵母共生关系的系统发育维度,根据化石记录,这种共生关系早在开花植物出现之前就已经存在了。挥发物的组成对每个物种都是特征性的,与酵母的分类学一致,并且进一步反映在棉铃虫幼虫的不同行为反应上,棉铃虫幼虫自然以广泛的阔叶植物的叶子为食。幼虫的辨别可能建立和维持与酵母的联系,也是设计可持续的昆虫管理技术的基础。
