美国南部鹦鹉羽毛象鼻虫(Phytobius (=Parenthis) vestitus)快速冷硬化和适应性的种内差异

IF 3.7 2区 农林科学 Q2 BIOTECHNOLOGY & APPLIED MICROBIOLOGY Biological Control Pub Date : 2024-11-06 DOI:10.1016/j.biocontrol.2024.105651
Nathan E. Harms , Megann M. Harlow , A. Blake DeRossette , Ian A. Knight
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引用次数: 0

摘要

例如,通过适应或快速冷硬化表现出来的热耐受性的可塑性为生物提供了一种机制,以应对热环境中意想不到的、通常是快速的变化。对高温或低温反应的空间变异可能是由于进化适应,特别是当适应能力的提高与快速应对环境变化的能力相吻合时。用于生物防治的益虫的热耐受性决定了昆虫在什么地方和什么热条件下能为管理计划提供价值。我们利用美国南部的四种入侵性鹦鹉热象鼻虫(Phytobius vestitus)种群研究了热表型可塑性的两个方面。在低温条件下,我们使用两种升温速率测定了四个种群中一个种群快速冷硬化的存在和变化。与此相反,在高温条件下,所有 P. vestitus 种群都表现出明显的热适应反应,表现为适应后运动控制和运动功能温度的升高。因此,观察到的可塑性模式在高温和低温之间以及不同来源种群之间存在差异。这些结果表明,表型可塑性对热环境的反应存在地理差异,并强调在选择适应气候的生物防治种群时需要考虑可塑性。
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Intraspecific variation in rapid cold hardening and acclimation of the adventive parrot’s feather weevil, Phytobius (=Parenthis) vestitus, in the southern USA
Plasticity in thermal tolerance, expressed through acclimation or rapid cold hardening, for example, provides organisms with a mechanism to deal with unexpected and often rapid changes in the thermal environment. Spatial variation in response to high or low temperatures may occur due to evolutionary adaptation, particularly if a fitness increase coincides with the ability to respond quickly to environmental change. Thermal tolerances of beneficial insects used for biological control dictate where and under what thermal conditions the insects will provide value to management programs. We investigated two aspects of thermal phenotypic plasticity in response to thermal conditions using four populations of the adventive parrot’s feather weevil, Phytobius vestitus, from the southern USA. At low temperatures, we determined the presence and variation in rapid cold hardening in one of the four populations using two temperature ramping rates. In contrast, at high temperatures, all P. vestitus populations displayed a significant heat acclimation response, documented as elevated loss of motor control and motor function temperatures after acclimation. Thus, observed patterns of plasticity differed between high and low temperatures and among source populations. These results demonstrate the presence of geographic variation in phenotypic plasticity in response to thermal environments and emphasizes the need to consider plasticity when selecting climate-adapted populations of biological control agents.
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来源期刊
Biological Control
Biological Control 生物-昆虫学
CiteScore
7.40
自引率
7.10%
发文量
220
审稿时长
63 days
期刊介绍: Biological control is an environmentally sound and effective means of reducing or mitigating pests and pest effects through the use of natural enemies. The aim of Biological Control is to promote this science and technology through publication of original research articles and reviews of research and theory. The journal devotes a section to reports on biotechnologies dealing with the elucidation and use of genes or gene products for the enhancement of biological control agents. The journal encompasses biological control of viral, microbial, nematode, insect, mite, weed, and vertebrate pests in agriculture, aquatic, forest, natural resource, stored product, and urban environments. Biological control of arthropod pests of human and domestic animals is also included. Ecological, molecular, and biotechnological approaches to the understanding of biological control are welcome.
期刊最新文献
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