在地上或地下微气候条件下,由蚂蚁互惠者养殖的真菌热性能曲线的演变。

IF 2.1 3区 生物学 Q3 ECOLOGY
Oscar Hess, Tiem van der Deure, Mille Bolander, Caio Leal Dutra, Jonathan Z Shik
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引用次数: 0

摘要

真菌种类繁多,在全球范围内具有重要的生态意义,但人们对真菌的热适应性是由生化约束(即 "越热越好模式",HBM)还是进化权衡(即 "专才通才模式",SGM)决定的却知之甚少。我们通过生成由六种巴拿马真菌养殖蚂蚁养殖的真菌栽培品种的热性能曲线(TPCs)来验证这些假设。这些真菌代表了养殖策略的进化转变,其中四个栽培品种是蚂蚁在接近 25°C 的稳定温度下在地下养殖的,而两个栽培品种是在温度变化的情况下在地上养殖的。我们利用一个普通的花园实验,将真菌分离物限制在不同的温度下,生成了 TPCs,然后利用贝叶斯分层建模方法比较了相互竞争的温度敏感性模型。在不同的种植策略下,一些热性能特征具有一致性差异,地上栽培品种具有以下特征1)对低温的耐受性更高(CTLmin);2)在最佳温度下的最大生长率更高(rmax)。然而,HBM 或 SGM 的两个核心假设并没有得到支持,因为地上栽培品种的最适温度(Topt)或耐热广度都没有出现系统性增长。这些结果利用蚂蚁养殖系统作为长期自然实验,将环境温度变化和先天生理温度敏感性对真菌热进化的影响分离开来。这些结果对于预测气候变暖引起的动物-微生物互生关系的断裂点具有明显的意义。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
The evolution of thermal performance curves in fungi farmed by attine ant mutualists in aboveground or belowground microclimates.

Fungi are abundant and ecologically important at a global scale, but little is known about whether their thermal adaptations are shaped by biochemical constraints (i.e. the Hotter is Better Model, HBM) or evolutionary tradeoffs (i.e., the Specialist Generalist Model, SGM). We tested these hypotheses by generating thermal performance curves (TPCs) of fungal cultivars farmed by six species of Panamanian fungus-farming 'attine' ants. These fungi represent evolutionary transitions in farming strategies as four cultivars are farmed by ants belowground at stable temperatures near 25°C and two cultivars are farmed aboveground at variable temperatures. We generated TPCs using a common garden experiment confining fungal isolates to different temperatures and then used a Bayesian hierarchical modeling approach to compare competing temperature sensitivity models. Some thermal performance traits differed consistently across farming strategies, with aboveground cultivars having: 1) higher tolerance to low temperatures (CTLmin) and 2) higher maximum growth rate at the optimal temperature (rmax). However, two core assumptions shared by the HBM or SGM were not supported as aboveground cultivars did not show systematic increases in either their optimal temperature (Topt) or thermal tolerance breadth. These results harness ant farming systems as long-term natural experiments to decouple the effects of environmental thermal variation and innate physiological temperature sensitivity on fungal thermal evolution. The results have clear implications for predicting climate warming induced breaking points in animal-microbe mutualisms.

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来源期刊
Journal of Evolutionary Biology
Journal of Evolutionary Biology 生物-进化生物学
CiteScore
4.20
自引率
4.80%
发文量
152
审稿时长
3-6 weeks
期刊介绍: It covers both micro- and macro-evolution of all types of organisms. The aim of the Journal is to integrate perspectives across molecular and microbial evolution, behaviour, genetics, ecology, life histories, development, palaeontology, systematics and morphology.
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