Short-term temperature fluctuations increase disease in a Daphnia-parasite infectious disease system.

IF 7.8 1区 生物学 Q1 BIOCHEMISTRY & MOLECULAR BIOLOGY PLoS Biology Pub Date : 2023-09-08 eCollection Date: 2023-09-01 DOI:10.1371/journal.pbio.3002260
Leila Krichel, Devin Kirk, Clara Pencer, Madison Hönig, Kiran Wadhawan, Martin Krkošek
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引用次数: 1

Abstract

Climate change has profound effects on infectious disease dynamics, yet the impacts of increased short-term temperature fluctuations on disease spread remain poorly understood. We empirically tested the theoretical prediction that short-term thermal fluctuations suppress endemic infection prevalence at the pathogen's thermal optimum. This prediction follows from a mechanistic disease transmission model analyzed using stochastic simulations of the model parameterized with thermal performance curves (TPCs) from metabolic scaling theory and using nonlinear averaging, which predicts ecological outcomes consistent with Jensen's inequality (i.e., reduced performance around concave-down portions of a thermal response curve). Experimental observations of replicated epidemics of the microparasite Ordospora colligata in Daphnia magna populations indicate that temperature variability had the opposite effect of our theoretical predictions and instead increase endemic infection prevalence. This positive effect of temperature variability is qualitatively consistent with a published hypothesis that parasites may acclimate more rapidly to fluctuating temperatures than their hosts; however, incorporating hypothetical effects of delayed host acclimation into the mechanistic transmission model did not fully account for the observed pattern. The experimental data indicate that shifts in the distribution of infection burden underlie the positive effect of temperature fluctuations on endemic prevalence. The increase in disease risk associated with climate fluctuations may therefore result from disease processes interacting across scales, particularly within-host dynamics, that are not captured by combining standard transmission models with metabolic scaling theory.

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短期温度波动会增加水蚤寄生虫传染病系统中的疾病。
气候变化对传染病动态有着深远的影响,但人们对短期温度波动增加对疾病传播的影响仍知之甚少。我们实证检验了理论预测,即短期的热波动在病原体的热最佳状态下抑制了地方性感染的流行率。这一预测源于一个机制性疾病传播模型,该模型使用代谢标度理论中的热性能曲线(TPCs)参数化模型的随机模拟进行分析,并使用非线性平均,该模型预测与Jensen不等式一致的生态结果(即,热响应曲线凹下部分周围的性能降低)。对大型水蚤种群中微小寄生虫综合Ordospora重复流行的实验观察表明,温度变化的影响与我们的理论预测相反,反而增加了地方性感染的流行率。温度变化的这种积极影响在质量上与一项已发表的假说一致,即寄生虫可能比宿主更快地适应波动的温度;然而,将宿主适应延迟的假设效应纳入机制传播模型并不能完全解释观察到的模式。实验数据表明,感染负担分布的变化是温度波动对地方病流行率产生积极影响的基础。因此,与气候波动相关的疾病风险增加可能是由于疾病过程在尺度上相互作用,特别是在宿主动力学内,而标准传播模型与代谢尺度理论相结合并不能捕捉到这些过程。
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来源期刊
PLoS Biology
PLoS Biology 生物-生化与分子生物学
CiteScore
14.40
自引率
2.00%
发文量
359
审稿时长
3 months
期刊介绍: PLOS Biology is an open-access, peer-reviewed general biology journal published by PLOS, a nonprofit organization of scientists and physicians dedicated to making the world's scientific and medical literature freely accessible. The journal publishes new articles online weekly, with issues compiled and published monthly. ISSN Numbers: eISSN: 1545-7885 ISSN: 1544-9173
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