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研究生: 詹仕凡
Chan, Shih-Fan
論文名稱: 行為如何影響變動熱環境下的種間關係
How does behavior modulate species interactions in changing thermal environments
指導教授: 沈聖峰
Shen, Sheng-Feng
口試委員: 王慧瑜
Wang, Hui-Yu
陳一菁
Chen, I-Ching
謝志豪
Hsieh, Chih-Hao
洪志銘
Hung, Chih-Ming
沈聖峰
Shen, Sheng-Feng
口試日期: 2023/03/17
學位類別: 博士
Doctor
系所名稱: 生命科學系
Department of Life Science
論文出版年: 2023
畢業學年度: 111
語文別: 英文
論文頁數: 150
中文關鍵詞: 氣候變遷土地利用改變協同效應種間競爭日溫差時間生態棲位溫度生態棲位阿利效應埋葬蟲麗蠅
英文關鍵詞: climate, land-use change, synergistic effect, interspecific competition, DTR, temporal niche, thermal niche, Allee effect, burying beetle, blowfly
研究方法: 實驗設計法
DOI URL: http://doi.org/10.6345/NTNU202300424
論文種類: 學術論文
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  • 預測人為的氣候變遷和土地利用改變所導致的熱環境變化將如何影響物種間的交互作用,對於預測物種在面臨全球環境變遷下族群的可持續性至關重要。在本研究中,我們透過建立數學模型,並對共同競爭資源的尼泊爾埋葬蟲(Nicrophorus nepalensis)和麗蠅(Calliphoridae spp.)進行實驗來回答這個問題。我們發現,土地利用的變化(即森林砍伐)導致日溫差的增加,在原本適合埋葬蟲的高海拔山區,加劇了來自麗蠅蛆的種間競爭壓力,導致夜間活動的埋葬蟲的競爭劣勢。此外,我們還透過理論模式說明,開採型競爭對於調節具有不同時間生態棲位的物種間的關係尤其重要,且日溫差會加劇此競爭對夜行性物種的負面影響。另一方面,我們發現森林減少會透過降低尼泊爾埋葬蟲的族群密度,使行合作繁殖的尼泊爾埋葬蟲無法足成大的合作群體,進而降低了它們在溫暖環境下麗蠅競爭的抵抗能力。綜合上述的研究結果顯示,在變動的熱環境中,有兩類不同的行為機制可以調節物種間的交互作用: (1)決定生物體所經歷的熱環境的行為,例如時間的生態棲位;(2)改變生物體的熱生態棲位的的行為,例如合作。我們的研究結果也凸顯了同時從行為和生理兩個角度來預測全球環境變遷下物種交互作用的重要性。

    Predicting how species interact under changing thermal environments due to anthropogenic environmental changes (e.g., climate & land-use changes) is crucial for forecasting future population sustainability. Here, we used mathematical models and field experiments on burying beetles (Nicrophorus nepalensis) and blowflies (Calliphoridae spp.) that compete for resources in common to tackle the questions. We found that land-use changes (i.e., deforestation) increase temperature variability and exacerbate the competitive disadvantage of nocturnal burying beetles. Furthermore, we also show that exploitative competition is critical in modulating competition between the above two species with distinct temporal niches. On the other hand, we found that declines in the population density of the cooperative burying beetles also reduce their resistance to blowfly competition in warmer low elevations in deforested landscapes. The above results show two distinct categories of behavioral mechanisms modulating species interactions in changing thermal environments: (1) behaviors that determine the thermal environment experienced by the organisms and (2) behaviors that modify the thermal niche of the organisms. The results also highlight the importance of incorporating behavior and physiology to predict species interactions in the ongoing global environmental changes.

    Acknowledgement i 摘要 iii English Abstract iv Table of Contents v List of Tables ix List of Figures xi CHAPTER 1 GENERAL INTRODUCTION 1 CHAPTER 2 HIGHER TEMPERATURE VARIABILITY IN DEFORESTED MOUNTAIN REGIONS IMPACTS THE COMPETITIVE ADVANTAGE OF NOCTURNAL SPECIES 4 Abstract 4 2.1 Introduction 6 2.2 Materials and Methods 9 2.2.1 Predicting the impact of deforestation on DTR worldwide 9 2.2.2 TPC for burying beetles and blowfly maggots 11 2.2.3 Effect of deforestation on the mean and variability of temperature at a regional scale 14 2.2.4 Predicting realized beetle performance with TPCs, daily activity patterns, and environmental temperature profiles 16 2.2.5 Field experiments of competition between burying beetles and blowflies 17 2.2.6 Identifying the primary time of the day that burying beetles search for carcasses 18 2.2.7 Laboratory experiments on maggot performance at different DTRs 19 2.2.8 Field experiments preventing blowflies’ competition 20 2.2.9 Data analysis 20 2.3 Results 22 2.3.1 The potential effect of deforestation on DTR worldwide 22 2.3.2 TPC for burying beetles and blowfly maggots 22 2.3.3 Effect of deforestation on the mean and variability of temperature at a regional scale 23 2.3.4 Predicting realized beetle performance with TPCs, daily activity patterns, and environmental temperature profiles 24 2.3.5 Effects of deforestation on interspecific competition between species with different daily activity patterns 26 2.3.6 Behavioral mechanisms of how DTR affects competition between burying beetles and blowflies 27 2.3.7 Field experiments preventing blowflies’ competition 28 2.4 Discussion 29 2.5 Figures 34 2.6 Tables 47 CHAPTER 3 HOW DOES DAILY TEMPORAL NICHE MODULATE SPECIES INTERACTIONS IN THERMALLY FLUCTUATED ENVIRONMENTS 55 Abstract 55 3.1 Introduction 56 3.2 Theoretical model 59 3.2.1 Using thermal performance curve to estimate fitness under fluctuating environments 60 3.2.2 Modeling competition between diurnal and nocturnal species 65 3.2.3 Modeling the effects of temporal niche shifts on species interactions 67 3.3 Empirical studies 69 3.3.1 Daily temporal niche and species interactions under various biodiversity stressors 69 3.3.2 Exploitative competition 70 3.3.3 Daily temporal niche shift and interference competition 74 3.4 Conclusion 75 3.5 Figures 78 CHAPTER 4 LAND-USE CHANGES ALTER POPULATION DEMOGRAPHICS AND SHAPE THERMAL PERFORMANCE IN SOCIAL INSECTS 80 Abstract 80 4.1 Introduction 82 4.2 Materials and methods 86 4.2.1 Individual-based model 86 4.2.2 Field surveys to estimate beetle population densities 90 4.2.3 Field breeding experiments 90 4.2.4 Breeding experiments to examine the influence of local population density 92 4.2.5 Forest cover 94 4.2.6 Environmental temperature monitoring 94 4.2.7 Data analysis 95 4.3 Results 97 4.3.1 Individual-based model 97 4.3.2 Empirical results 101 4.4 Discussion 105 4.5 Figures 109 4.6 Tables 119 CHAPTER 5 GENERAL CONCLUSIONS 132 References 135

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