A New SDM-Based Approach for Assessing Climate Change Effects on Plant-Pollinator Networks.

IF 2.7 2区 农林科学 Q1 ENTOMOLOGY
Insects Pub Date : 2024-10-28 DOI:10.3390/insects15110842
Ehsan Rahimi, Chuleui Jung
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引用次数: 0

Abstract

Current methods for studying the effects of climate change on plants and pollinators can be grouped into two main categories. The first category involves using species distribution models (SDMs) to generate habitat suitability maps, followed by applying climate change scenarios to predict the future distribution of plants and pollinators separately. The second category involves constructing interaction matrices between plants and pollinators and then either randomly removing species or selectively removing generalist or specialist species, as a way to estimate how climate change might affect the plant-pollinator network. The primary limitation of the first approach is that it examines plant and pollinator distributions separately, without considering their interactions within the context of a pollination network. The main weakness of the second approach is that it does not accurately predict climate change impacts, as it arbitrarily selects species to remove without knowing which species will truly shift, decline, or increase in distribution due to climate change. Therefore, a new approach is needed to bridge the gap between these two methods while avoiding their specific limitations. In this context, we introduced an innovative approach that first requires the creation of binary climate suitability maps for plants and pollinators, based on SDMs, for both the current and future periods. This step aligns with the first category of methods mentioned earlier. To assess the effects of climate change within a network framework, we consider species co-overlapping in a geographic matrix. For this purpose, we developed a Python program that overlays the binary distribution maps of plants and pollinators, generating interaction matrices. These matrices represent potential plant-pollinator interactions, with a '0' indicating no overlap and a '1' where both species coincide in the same cell. As a result, for each cell within the study area, we can construct interaction matrices for both the present and future periods. This means that for each cell, we can analyze at least two pollination networks based on species co-overlap. By comparing the topology of these matrices over time, we can infer how climate change might affect plant-pollinator interactions at a fine spatial scale. We applied our methodology to Chile as a case study, generating climate suitability maps for 187 plant species and 171 pollinator species, resulting in 2906 pollination networks. We then evaluated how climate change could affect the network topology across Chile on a cell-by-cell basis. Our findings indicated that the primary effect of climate change on pollination networks is likely to manifest more significantly through network extinctions, rather than major changes in network topology.

基于 SDM 的新方法,用于评估气候变化对植物-传粉者网络的影响。
目前研究气候变化对植物和传粉昆虫影响的方法可分为两大类。第一类是使用物种分布模型(SDM)生成栖息地适宜性地图,然后应用气候变化情景分别预测植物和传粉昆虫的未来分布。第二类方法是构建植物与传粉昆虫之间的相互作用矩阵,然后随机移除物种或有选择地移除通性或专性物种,以此来估计气候变化可能对植物-传粉昆虫网络产生的影响。第一种方法的主要局限性在于,它将植物和授粉昆虫的分布分开研究,而没有考虑它们在授粉网络中的相互作用。第二种方法的主要缺点是不能准确预测气候变化的影响,因为它任意选择要移除的物种,而不知道哪些物种的分布会因气候变化而真正发生变化、减少或增加。因此,我们需要一种新的方法来弥补这两种方法之间的差距,同时避免它们各自的局限性。在此背景下,我们引入了一种创新方法,首先需要根据可持续发展机制为植物和传粉昆虫绘制当前和未来时期的二元气候适宜性地图。这一步骤与前面提到的第一类方法一致。为了在网络框架内评估气候变化的影响,我们考虑了物种在地理矩阵中的重叠情况。为此,我们开发了一个 Python 程序,将植物和传粉昆虫的二元分布图重叠,生成相互作用矩阵。这些矩阵代表了植物与授粉昆虫之间潜在的相互作用,"0 "表示没有重叠,"1 "表示两个物种在同一单元中重合。因此,对于研究区域内的每个单元,我们都可以构建当前和未来时期的相互作用矩阵。这意味着,对于每个小区,我们至少可以根据物种共重叠来分析两个授粉网络。通过比较这些矩阵随时间变化的拓扑结构,我们可以推断出气候变化可能如何影响植物与传粉昆虫在精细空间尺度上的相互作用。我们将智利作为案例研究对象,应用我们的方法生成了 187 种植物和 171 种授粉昆虫的气候适宜性图谱,从而形成了 2906 个授粉网络。然后,我们逐个单元评估了气候变化如何影响整个智利的网络拓扑结构。我们的研究结果表明,气候变化对授粉网络的主要影响可能主要表现为网络的灭绝,而不是网络拓扑结构的重大变化。
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来源期刊
Insects
Insects Agricultural and Biological Sciences-Insect Science
CiteScore
5.10
自引率
10.00%
发文量
1013
审稿时长
21.77 days
期刊介绍: Insects (ISSN 2075-4450) is an international, peer-reviewed open access journal of entomology published by MDPI online quarterly. It publishes reviews, research papers and communications related to the biology, physiology and the behavior of insects and arthropods. Our aim is to encourage scientists to publish their experimental and theoretical results in as much detail as possible. There is no restriction on the length of the papers. The full experimental details must be provided so that the results can be reproduced. Electronic files regarding the full details of the experimental procedure, if unable to be published in a normal way, can be deposited as supplementary material.
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