Biodiv Sci ›› 2020, Vol. 28 ›› Issue (11): 1362-1375. DOI: 10.17520/biods.2020243
Special Issue: 物种形成与系统进化; 生物入侵
• Reviews • Previous Articles Next Articles
Received:
2020-06-15
Accepted:
2020-07-24
Online:
2020-11-20
Published:
2020-08-16
Contact:
Shaopeng Li
Wenbo Yu, Shaopeng Li. Modern coexistence theory as a framework for invasion ecology[J]. Biodiv Sci, 2020, 28(11): 1362-1375.
Fig. 1 A conceptual diagram using modern coexistence theory as a framework for invasive ecology. According to the framework, the invasion outcome depends on both exotic-native niche and fitness differences. On one hand, increasing exotics-native niche difference promotes the success of the exotics but hinders their impacts on natives. On the other hand, fitness difference, here measured as the fitness advantage of invaders over the natives, could enhance both invasion success and their impacts on native species. Adapted from MacDougall et al (2009), Cadotte et al (2018), and Li et al (2019).
假说 Hypothesis | 定义 Definition | 强调的差异 Ecological difference | 在现代物种共存理论框架下的解读 Interpretation under the framework of modern coexistence theory | 参考文献 References | ||
---|---|---|---|---|---|---|
空余生态位假说 Empty niche hypothesis | 外来种通过占领入侵地未被土著种占据的空余生态位, 进而实现成功入侵。Exotics successfully invade when occupying niche space unused by the native communities. | 生态位差异 Niche difference | 外来种和土著种的生态位差异导致空余生态位的存在, 促进入侵。Exotic-native niche differences create empty niches and promote invasion. | |||
生物抵抗假说 Biotic resistance hypothesis | 多样性高的群落能够更有效地利用资源, 空余的生态位更少, 因此更难以被入侵。More diverse communities have less available resources and vacant niches, preventing invasion. | 生态位差异 Niche difference | 多样性高的群落土著种和外来种生态位重叠的概率更高, 抑制入侵。Higher probability of exotic-native niche overlap in more diverse communities inhibits invasion. | |||
资源机遇假说 Resource opportunity hypothesis | 入侵地具备外来种必需的生物和非生物资源, 且这些资源大多未被土著种有效利用, 促进外来种入侵。The resident communities are more susceptible to invasions when they contain high availability of resources on which a potential invader depends. | 生态位差异 Niche difference | 外来种和土著种的生态位差异导致入侵地中外来种的必需资源未被利用, 促进入侵。 Exotic-native niche differences making the essential resources of exotics available, promoting invasion. | |||
环境异质性假说 Environmental heterogeneity hypothesis | 异质性高的生境中具有更多的生态位, 外来种可以占据其中可用的生态位实现成功入侵。 Heterogeneous environment contain a diverse array of niches, and invaders would be successful by filling the available niches. | 生态位差异 Niche difference | 在异质性高的环境中, 外来种和土著种的生态位差异大, 促进入侵。Exotic-native niche differences would be larger in heterogeneous environment, promoting invasion. | |||
干扰假说 Disturbance hypothesis | 干扰在群落中形成空余生态位, 降低土著群落的抵抗力, 促进外来种成功定居。Disturbance events increase vacant niches and decrease the resistance of native communities, promoting invasion. | 生态位差异 Niche difference | 干扰导致空余生态位的存在, 促进了和土著种生态位差异大的外来种的入侵。Empty niches created by disturbance events benefit the invasion of exotics with large niche differences to natives. | |||
波动资源假说 Fluctuating resources hypothesis | 资源在时间上的波动打破了资源供给和获取的平衡, 导致外来种可利用资源的增加, 提高了群落的可入侵性。Fluctuations in resource availability change resource input and uptake rates, and promote invasion. | 生态位差异 Niche difference | 资源的波动提供了空余生态位, 促进了和土著种生态位差异大的外来种的入侵。 Fluctuating resources offer empty niches, which benefit the invasion of exotics with large niche differences to natives. | |||
达尔文归化假说 Darwin’s naturalization hypothesis | 达尔文认为和本土物种亲缘关系远的外来种更容易归化, 因为它们和本土物种差异大, 生态位重叠小, 种间竞争弱。Exotics distantly related to natives are more likely to naturalize, as they occupy distinct niches and complete less stronger with natives. | 生态位差异 Niche difference | 远缘物种生态位差异大, 因此与土著种亲缘关系远的外来种更容易入侵。Distantly related species have large niche differences, which promote the invasion of exotics that distantly related to natives. | |||
内禀优势假说 Inherent superiority hypothesis | 成功入侵的外来种在形态、生理、生态、遗传和行为等特征上具备独特的内禀优势。Successfully invaded exotics have intrinsic characteristics superior to native species. | 适合度差异 Fitness difference | 相比土著种, 成功入侵的外来种本身具有更高适合度。Successfully invaded exotics are at a fitness advantage relative to the resident communities. | |||
理想杂草特征假说 Ideal weed characteristics hypothesis | 入侵种具备类似理想杂草的生物特性, 这些特征使其很好地适应环境, 并在竞争中占据优势。Invasive species share similar characteristics to ideal weeds, making them well adapt to the environment and exhibit competitive advantages. | 适合度差异 Fitness difference | 相比土著种, 成功入侵的外来种具有的杂草特征使其具有更高的适合度。Exotic species with ideal weed characteristics show higher fitness than the native species in the resident communities. | |||
繁殖体压力假说 Propagule pressure hypothesis | 繁殖体引入的数量、频率和质量在入侵初期起决定性作用, 繁殖体压力越大, 成功入侵概率越高。 High quantity, frequency and quality of propagule introductions increase chance of successful invasion. | 适合度差异 Fitness difference | 繁殖体压力越大, 外来种适合度越高, 越容易入侵成功。Exotic species with high propagule pressure show high fitness advantage, and are more likely to invade. | |||
竞争能力增强进化假说 Evolution of increased competitive ability | 外来入侵植物到达入侵地后, 会把原来用于防御天敌的物质和能量转移到生长系统, 增强自身竞争能力, 实现成功入侵。After releasing from native specialist predators, exotic species evolve with less investment in anti-herbivore defenses and allocate more resources to vegetative and reproductive growth. This strategy promotes invasion. | 适合度差异 Fitness difference | 竞争能力的增强使外来种具有更高的适合度, 进而在和土著种竞争时占据优势, 成功入侵。The increased competitive ability makes the exotics show higher fitness advantage than the natives, promoting invasion. | |||
假说 Hypothesis | 定义 Definition | 强调的差异 Ecological difference | 在现代物种共存理论框架下的解读 Interpretation under the framework of modern coexistence theory | 参考文献 References | ||
氮分配进化假说 Hypothesis of the evolution of nitrogen allocation | 相比原产地, 外来种在入侵地降低体内氮元素向防御作用的分配, 增加了氮向光合机构的转移, 提高了自身光合能力。Comparing to native ranges, exotics evolve to decrease nitrogen allocation to defenses and increase nitrogen allocation to photosynthesis in introduced ranges. | 适合度差异 Fitness difference | 氮分配的改变提高了外来种在入侵地的适合度。The evolution of nitrogen allocation increases the fitness of exotics in the introduced habitats. | |||
新武器假说 New weapon hypothesis | 入侵植物能够分泌特异的化感物质抑制土著种。土著种对这些化感物质缺乏适应性, 导致外来种在竞争中占据上风。Exotics release allopatric chemicals that inhibit and repress the native competitors in new range, enhancing the exotics’ competitive ability and success. | 适合度差异 Fitness difference | 化感物质提高了外来种的适合度, 降低了土著种的适合度, 促进入侵。Allopatric chemicals increase the fitness of exotics and decrease the fitness of natives, promoting invasion. | |||
天敌逃逸假说 Enemy release hypothesis | 当外来种被引入入侵地后, 脱离了原产地天敌的控制, 进而可以快速生长繁殖扩散。After introduction into new areas, exotics escape from their old enemies, benefiting their growth and spread. | 适合度差异 Fitness difference | 脱离天敌控制后, 外来种适合度增加, 提高了相对于土著种的适合度优势, 有利于成功入侵。After escaping from the natural enemies, exotics increase their fitness, promoting invasion. | |||
预适应假说 Preadaptation hypothesis | 达尔文认为近缘种偏好相似的生境, 因此土著种占据的生境更适合与其近缘的外来种定居。Close relatives favor similar environments, the habitats occupied by native species were more suitable for the establishment of their closely related exotics. | 适合度差异 Fitness difference | 在被土著种占据的生境中, 与土著种亲缘关系近的外来种具有更高适合度, 因此更容易入侵。In the habitats occupied by native species, the exotics that closely related to these natives would have high fitness and are more likely to invade. | |||
新生态位假说 Novel niche hypothesis | 环境变化和人类活动形成了新的生态位, 这些新生态位更适合外来种生存。Anthropogenic changes create novel niches, and these niches are better exploited by exotic species. | 生态位差异和适合度差异 Niche and fitness difference | (1)由于外来种和土著种的生态位差异, 新生态位只能被外来种占据。The novel niches could only be occupied by exotics due to the large exotic-native niche differences. (2)外来种比土著种在新生态位中具有更高的适合度。Exotics exhibit higher fitness than natives in exploiting the new niches. |
Table 1 Leading invasion hypotheses and their relationship to modern coexistence theory
假说 Hypothesis | 定义 Definition | 强调的差异 Ecological difference | 在现代物种共存理论框架下的解读 Interpretation under the framework of modern coexistence theory | 参考文献 References | ||
---|---|---|---|---|---|---|
空余生态位假说 Empty niche hypothesis | 外来种通过占领入侵地未被土著种占据的空余生态位, 进而实现成功入侵。Exotics successfully invade when occupying niche space unused by the native communities. | 生态位差异 Niche difference | 外来种和土著种的生态位差异导致空余生态位的存在, 促进入侵。Exotic-native niche differences create empty niches and promote invasion. | |||
生物抵抗假说 Biotic resistance hypothesis | 多样性高的群落能够更有效地利用资源, 空余的生态位更少, 因此更难以被入侵。More diverse communities have less available resources and vacant niches, preventing invasion. | 生态位差异 Niche difference | 多样性高的群落土著种和外来种生态位重叠的概率更高, 抑制入侵。Higher probability of exotic-native niche overlap in more diverse communities inhibits invasion. | |||
资源机遇假说 Resource opportunity hypothesis | 入侵地具备外来种必需的生物和非生物资源, 且这些资源大多未被土著种有效利用, 促进外来种入侵。The resident communities are more susceptible to invasions when they contain high availability of resources on which a potential invader depends. | 生态位差异 Niche difference | 外来种和土著种的生态位差异导致入侵地中外来种的必需资源未被利用, 促进入侵。 Exotic-native niche differences making the essential resources of exotics available, promoting invasion. | |||
环境异质性假说 Environmental heterogeneity hypothesis | 异质性高的生境中具有更多的生态位, 外来种可以占据其中可用的生态位实现成功入侵。 Heterogeneous environment contain a diverse array of niches, and invaders would be successful by filling the available niches. | 生态位差异 Niche difference | 在异质性高的环境中, 外来种和土著种的生态位差异大, 促进入侵。Exotic-native niche differences would be larger in heterogeneous environment, promoting invasion. | |||
干扰假说 Disturbance hypothesis | 干扰在群落中形成空余生态位, 降低土著群落的抵抗力, 促进外来种成功定居。Disturbance events increase vacant niches and decrease the resistance of native communities, promoting invasion. | 生态位差异 Niche difference | 干扰导致空余生态位的存在, 促进了和土著种生态位差异大的外来种的入侵。Empty niches created by disturbance events benefit the invasion of exotics with large niche differences to natives. | |||
波动资源假说 Fluctuating resources hypothesis | 资源在时间上的波动打破了资源供给和获取的平衡, 导致外来种可利用资源的增加, 提高了群落的可入侵性。Fluctuations in resource availability change resource input and uptake rates, and promote invasion. | 生态位差异 Niche difference | 资源的波动提供了空余生态位, 促进了和土著种生态位差异大的外来种的入侵。 Fluctuating resources offer empty niches, which benefit the invasion of exotics with large niche differences to natives. | |||
达尔文归化假说 Darwin’s naturalization hypothesis | 达尔文认为和本土物种亲缘关系远的外来种更容易归化, 因为它们和本土物种差异大, 生态位重叠小, 种间竞争弱。Exotics distantly related to natives are more likely to naturalize, as they occupy distinct niches and complete less stronger with natives. | 生态位差异 Niche difference | 远缘物种生态位差异大, 因此与土著种亲缘关系远的外来种更容易入侵。Distantly related species have large niche differences, which promote the invasion of exotics that distantly related to natives. | |||
内禀优势假说 Inherent superiority hypothesis | 成功入侵的外来种在形态、生理、生态、遗传和行为等特征上具备独特的内禀优势。Successfully invaded exotics have intrinsic characteristics superior to native species. | 适合度差异 Fitness difference | 相比土著种, 成功入侵的外来种本身具有更高适合度。Successfully invaded exotics are at a fitness advantage relative to the resident communities. | |||
理想杂草特征假说 Ideal weed characteristics hypothesis | 入侵种具备类似理想杂草的生物特性, 这些特征使其很好地适应环境, 并在竞争中占据优势。Invasive species share similar characteristics to ideal weeds, making them well adapt to the environment and exhibit competitive advantages. | 适合度差异 Fitness difference | 相比土著种, 成功入侵的外来种具有的杂草特征使其具有更高的适合度。Exotic species with ideal weed characteristics show higher fitness than the native species in the resident communities. | |||
繁殖体压力假说 Propagule pressure hypothesis | 繁殖体引入的数量、频率和质量在入侵初期起决定性作用, 繁殖体压力越大, 成功入侵概率越高。 High quantity, frequency and quality of propagule introductions increase chance of successful invasion. | 适合度差异 Fitness difference | 繁殖体压力越大, 外来种适合度越高, 越容易入侵成功。Exotic species with high propagule pressure show high fitness advantage, and are more likely to invade. | |||
竞争能力增强进化假说 Evolution of increased competitive ability | 外来入侵植物到达入侵地后, 会把原来用于防御天敌的物质和能量转移到生长系统, 增强自身竞争能力, 实现成功入侵。After releasing from native specialist predators, exotic species evolve with less investment in anti-herbivore defenses and allocate more resources to vegetative and reproductive growth. This strategy promotes invasion. | 适合度差异 Fitness difference | 竞争能力的增强使外来种具有更高的适合度, 进而在和土著种竞争时占据优势, 成功入侵。The increased competitive ability makes the exotics show higher fitness advantage than the natives, promoting invasion. | |||
假说 Hypothesis | 定义 Definition | 强调的差异 Ecological difference | 在现代物种共存理论框架下的解读 Interpretation under the framework of modern coexistence theory | 参考文献 References | ||
氮分配进化假说 Hypothesis of the evolution of nitrogen allocation | 相比原产地, 外来种在入侵地降低体内氮元素向防御作用的分配, 增加了氮向光合机构的转移, 提高了自身光合能力。Comparing to native ranges, exotics evolve to decrease nitrogen allocation to defenses and increase nitrogen allocation to photosynthesis in introduced ranges. | 适合度差异 Fitness difference | 氮分配的改变提高了外来种在入侵地的适合度。The evolution of nitrogen allocation increases the fitness of exotics in the introduced habitats. | |||
新武器假说 New weapon hypothesis | 入侵植物能够分泌特异的化感物质抑制土著种。土著种对这些化感物质缺乏适应性, 导致外来种在竞争中占据上风。Exotics release allopatric chemicals that inhibit and repress the native competitors in new range, enhancing the exotics’ competitive ability and success. | 适合度差异 Fitness difference | 化感物质提高了外来种的适合度, 降低了土著种的适合度, 促进入侵。Allopatric chemicals increase the fitness of exotics and decrease the fitness of natives, promoting invasion. | |||
天敌逃逸假说 Enemy release hypothesis | 当外来种被引入入侵地后, 脱离了原产地天敌的控制, 进而可以快速生长繁殖扩散。After introduction into new areas, exotics escape from their old enemies, benefiting their growth and spread. | 适合度差异 Fitness difference | 脱离天敌控制后, 外来种适合度增加, 提高了相对于土著种的适合度优势, 有利于成功入侵。After escaping from the natural enemies, exotics increase their fitness, promoting invasion. | |||
预适应假说 Preadaptation hypothesis | 达尔文认为近缘种偏好相似的生境, 因此土著种占据的生境更适合与其近缘的外来种定居。Close relatives favor similar environments, the habitats occupied by native species were more suitable for the establishment of their closely related exotics. | 适合度差异 Fitness difference | 在被土著种占据的生境中, 与土著种亲缘关系近的外来种具有更高适合度, 因此更容易入侵。In the habitats occupied by native species, the exotics that closely related to these natives would have high fitness and are more likely to invade. | |||
新生态位假说 Novel niche hypothesis | 环境变化和人类活动形成了新的生态位, 这些新生态位更适合外来种生存。Anthropogenic changes create novel niches, and these niches are better exploited by exotic species. | 生态位差异和适合度差异 Niche and fitness difference | (1)由于外来种和土著种的生态位差异, 新生态位只能被外来种占据。The novel niches could only be occupied by exotics due to the large exotic-native niche differences. (2)外来种比土著种在新生态位中具有更高的适合度。Exotics exhibit higher fitness than natives in exploiting the new niches. |
Fig. 2 The effects of the ecological differences between exotics and natives on invasion outcome. Exotic-native phylogenetic distances influence their trait differences, which translate into exotic-native niche and/or fitness differences that combine to determine invasion success and impact.
[1] |
Adler PB, HilleRisLambers J, Levine JM (2007) A niche for neutrality. Ecology Letters, 10, 95-104.
URL PMID |
[2] | Baker HG (1974) The evolution of weeds. Annual Review of Ecology and Systematics, 5, 1-24. |
[3] | Barabás G, D’Andrea R, Stump SM (2018) Chesson’s coexistence theory. Ecological Monographs, 88, 277-303. |
[4] |
Blackburn TM, Pyšek P, Bacher S, Carlton JT, Duncan RP, Jarošík V, Wilson JRU, Richardson DM (2011) A proposed unified framework for biological invasions. Trends in Ecology and Evolution, 26, 333-339.
URL PMID |
[5] | Blossey B, Notzold R (1995) Evolution of increased competitive ability in invasive nonindigenous plants: A hypothesis. Journal of Ecology, 83, 887-889. |
[6] |
Cadotte MW, Campbell SE, Li SP, Sodhi DS, Mandrak NE (2018) Preadaptation and naturalization of nonnative species: Darwin’s two fundamental insights into species invasion. Annual Review of Plant Biology, 69, 661-684.
DOI URL PMID |
[7] |
Callaway RM, Aschehoug ET (2000) Invasive plants versus their new and old neighbors: A mechanism for exotic invasion. Science, 290, 521-523.
DOI URL PMID |
[8] |
Carboni M, Münkemüller T, Lavergne S, Choler P, Borgy B, Violle C, Essl F, Roquet C, Munoz F, Consortium D, Thuiller W (2016) What it takes to invade grassland ecosystems: Traits, introduction history and filtering processes. Ecology Letters, 19, 219-229.
URL PMID |
[9] | Carroll IT, Cardinale BJ, Nisbet RM (2011) Niche and fitness differences relate the maintenance of diversity to ecosystem function. Ecology, 92, 1157-1165. |
[10] | Catford JA, Jansson R, Nilsson C (2009) Reducing redundancy in invasion ecology by integrating hypotheses into a single theoretical framework. Diversity and Distributions, 15, 22-40. |
[11] | Chesson P (2000) Mechanisms of maintenance of species diversity. Annual Review of Ecology and Systematics, 31, 343-366. |
[12] | Chesson P (2018) Updates on mechanisms of maintenance of species diversity. Journal of Ecology, 106, 1773-1794. |
[13] | Chu CJ, Adler PB (2015) Large niche differences emerge at the recruitment stage to stabilize grassland coexistence. Ecological Monographs, 85, 373-392. |
[14] | Chu CJ, Wang YS, Liu Y, Jiang L, He FL (2017) Advances in species coexistence theory. Biodiversity Science, 25, 345-354. (in Chinese with English abstract) |
[ 储诚进, 王酉石, 刘宇, 蒋林, 何芳良 (2017) 物种共存理论研究进展. 生物多样性, 25, 345-354.] | |
[15] |
Daehler CC (2001) Darwin’s naturalization hypothesis revisited. The American Naturalist, 158, 324-330.
URL PMID |
[16] | Daehler CC (2003) Performance comparisons of co-occurring native and alien invasive plants: Implications for conservation and restoration. Annual Review of Ecology, Evolution, and Systematics, 34, 183-211. |
[17] | Darwin C (1859) On the Origin of Species. John Murray, London. |
[18] | Davidson AM, Jennions M, Nicotra AB (2011) Do invasive species show higher phenotypic plasticity than native species and, if so, is it adaptive? A meta-analysis. Ecology Letters, 14, 419-431. |
[19] | Davis MA, Grime JP, Thompson K (2000) Fluctuating resources in plant communities: A general theory of invasibility. Journal of Ecology, 88, 528-534. |
[20] | Davis MA (2009) Invasion Biology. Oxford University Press, Oxford. |
[21] | Davis MA, Chew MK, Hobbs RJ, Lugo AE, Ewel JJ, Vermeij GJ, Brown JH, Rosenzweig ML, Gardener MR, Carroll SP, Thompson K, Pickett STA, Stromberg JC, Del Tredici P, Suding KN, Ehrenfeld JG, Grime JP, Mascaro J, Briggs JC (2011) Don’t judge species on their origins. Nature, 474, 153-154. |
[22] | Diez JM, Sullivan JJ, Hulme PE, Edwards G, Duncan RP (2008) Darwin’s naturalization conundrum: Dissecting taxonomic patterns of species invasions. Ecology Letters, 11, 674-681. |
[23] |
Divíšek J, Chytrý M, Beckage B, Gotelli NJ, Lososová Z, Pyšek P, Richardson DM, Molofsky J (2018) Similarity of introduced plant species to native ones facilitates naturalization, but differences enhance invasion success. Nature Communications, 9, 4631.
URL PMID |
[24] | Drake JA, Mooney HA, di Castri F, Groves RH, Kruger FJ, Rejmánek M, Williamson M (1989) Biological Invasions: A Global Perspective. Wiley, Chichester. |
[25] | El-Barougy RF, Elgamal I, Rohr RP, Probert AF, Abdel-hamid AK, Bacher S (2020) Functional similarity and dissimilarity facilitate alien plant invasiveness along biotic and abiotic gradients in an arid protected area. Biological Invasions, 22, 1997-2016. |
[26] | Ellner SP, Snyder RE, Adler PB, Hooker G (2019) An expanded modern coexistence theory for empirical applications. Ecology Letters, 22, 3-18. |
[27] | Elton CS (1958) The Ecology of Invasions by Animals and Plants. Chapman and Hall, London. |
[28] | Escoriza D, Ruhí A (2016) Functional distance to recipient communities may favour invasiveness: Insights from two invasive frogs. Diversity and Distributions, 22, 519-533. |
[29] |
Facon B, Genton BJ, Shykoff J, Jarne P, Estoup A, David P (2006) A general eco-evolutionary framework for understanding bioinvasions. Trends in Ecology and Evolution, 21, 130-135.
URL PMID |
[30] | Fargione JE, Tilman D (2005) Diversity decreases invasion via both sampling and complementarity effects. Ecology Letters, 8, 604-611. |
[31] | Feng YL, Lei YB, Wang RF, Callaway RM, Valiente-Banuet A, Inderjit, Li YP, Zheng YL (2009) Evolutionary tradeoffs for nitrogen allocation to photosynthesis versus cell walls in an invasive plant. Proceedings of the National Academy of Sciences, USA, 106, 1853-1856. |
[32] | Fukami T (2015) Historical contingency in community assembly: Integrating niches, species pools, and priority effects. Annual Review of Ecology, Evolution, and Systematics, 46, 1-23. |
[33] | Gallien L, Carboni M (2017) The community ecology of invasive species: Where are we and what’s next? Ecography, 40, 335-352. |
[34] |
Godoy O, Levine JM (2014) Phenology effects on invasion success: Insights from coupling field experiments to coexistence theory. Ecology, 95, 726-736.
DOI URL PMID |
[35] | Godoy O (2019) Coexistence theory as a tool to understand biological invasions in species interaction networks: Implications for the study of novel ecosystems. Functional Ecology, 33, 1190-1201. |
[36] | Godwin CM, Chang FH, Cardinale BJ (2020) An empiricist’s guide to modern coexistence theory for competitive communities. Oikos, 129, 1109-1127. |
[37] | Grainger TN, Letten AD, Gilbert B, Fukami T (2019a) Applying modern coexistence theory to priority effects. Proceedings of the National Academy of Sciences, USA, 116, 6205-6210. |
[38] | Grainger TN, Levine JM, Gilbert B (2019b) The invasion criterion: A common currency for ecological research. Trends in Ecology and Evolution, 34, 925-935. |
[39] | Hulme PE, Bernard-Verdier M (2018) Comparing traits of native and alien plants: Can we do better? Functional Ecology, 32, 117-125. |
[40] | Ju RT, Li H, Shih CJ, Li B (2012) Progress of biological invasions research in China over the last decade. Biodiversity Science, 20, 581-611. (in Chinese with English abstract) |
[ 鞠瑞亭, 李慧, 石正人, 李博 (2012) 近十年中国生物入侵研究进展. 生物多样性, 20, 581-611.] | |
[41] | Ke PJ, Wan J (2020) Effects of soil microbes on plant competition: A perspective from modern coexistence theory. Ecological Monographs, 90, e01391. |
[42] | Keane RM, Crawley MJ (2002) Exotic plant invasions and the enemy release hypothesis. Trends in Ecology and Evolution, 17, 164-170. |
[43] | Kinnunen M, Dechesne A, Proctor C, Hammes F, Johnson D, Quintela-Baluja M, Graham D, Daffonchio D, Fodelianakis S, Hahn N, Boon N, Smets BF (2016) A conceptual framework for invasion in microbial communities. The ISME Journal, 10, 2773-2779. |
[44] | Kraft NJB, Godoy O, Levine JM (2015) Plant functional traits and the multidimensional nature of species coexistence. Proceedings of the National Academy of Sciences, USA, 112, 797-802. |
[45] |
Lai HR, Mayfield MM, Gay-des-combes JM, Spiegelberger T, Dwyer JM (2015) Distinct invasion strategies operating within a natural annual plant system. Ecology Letters, 18, 336-346.
DOI URL PMID |
[46] | Lawton JH (1999) Are there general laws in ecology? Oikos, 84, 177-192. |
[47] |
Leffler AJ, James JJ, Monaco TA, Sheley RL (2014) A new perspective on trait differences between native and invasive exotic plants. Ecology, 95, 298-305.
URL PMID |
[48] | Leishman MR, Thomson VP, Cooke J (2010) Native and exotic invasive plants have fundamentally similar carbon capture strategies. Journal of Ecology, 98, 28-42. |
[49] | Lemoine NP, Burkepile DE, Parker JD (2016) Quantifying differences between native and introduced species. Trends in Ecology and Evolution, 31, 372-381. |
[50] | Levine JM, D’Antonio CM (1999) Elton revisited: A review of evidence linking diversity and invasibility. Oikos, 87, 15-26. |
[51] |
Levine JM, Bascompte J, Adler PB, Allesina S (2017) Beyond pairwise mechanisms of species coexistence in complex communities. Nature, 546, 56-64.
URL PMID |
[52] |
Li SP, Cadotte MW, Meiners SJ, Hua ZS, Shu HY, Li JT, Shu WS (2015a) The effects of phylogenetic relatedness on invasion success and impact: Deconstructing Darwin’s naturalization conundrum. Ecology Letters, 18, 1285-1292.
DOI URL PMID |
[53] | Li SP, Guo T, Cadotte MW, Chen YJ, Kuang JL, Hua ZS, Zeng Y, Song Y, Liu Z, Shu WS, Li JT (2015b) Contrasting effects of phylogenetic relatedness on plant invader success in experimental grassland communities. Journal of Applied Ecology, 52, 89-99. |
[54] |
Li SP, Tan J, Yang X, Ma C, Jiang L (2019) Niche and fitness differences determine invasion success and impact in laboratory bacterial communities. The ISME Journal, 13, 402-412.
DOI URL PMID |
[55] | Li YZ, Xiao JL, Liu HL, Wang YS, Chu CJ (2020) Advances in higher-order interactions between organisms. Biodiversity Science, 28, 1333-1344. (in Chinese with English abstract) |
[ 李远智, 肖俊丽, 刘翰伦, 王酉石, 储诚进 (2020) 生物间高阶相互作用研究进展. 生物多样性, 28, 1333-1344.] | |
[56] | Lockwood JL, Cassey P, Blackburn T (2005) The role of propagule pressure in explaining species invasions. Trends in Ecology and Evolution, 20, 223-228. |
[57] | Lockwood JL, Hoopes MF, Marchetti MP (2007) Invasion Ecology. Blackwell Publishing, Malden. |
[58] |
Lowry E, Rollinson EJ, Laybourn AJ, Scott TE, Aiello-Lammens ME, Gray SM, Mickley J, Gurevitch J (2013) Biological invasions: A field synopsis, systematic review, and database of the literature. Ecology and Evolution, 3, 182-196.
DOI URL PMID |
[59] | Lozon JD, MacIsaac HJ (1997) Biological invasions: Are they dependent on disturbance? Environmental Reviews, 5, 131-144. |
[60] | Ma C, Li SP, Pu ZC, Tan JQ, Liu MQ, Zhou J, Li HX, Jiang L (2016) Different effects of invader-native phylogenetic relatedness on invasion success and impact: A meta-analysis of Darwin’s naturalization hypothesis. Proceedings of the Royal Society B: Biological Sciences, 283, 20160663. |
[61] | MacDougall AS, Gilbert B, Levine JM (2009) Plant invasions and the niche. Journal of Ecology, 97, 609-615. |
[62] | Melbourne BA, Cornell HV, Davies KF, Dugaw CJ, Elmendorf S, Freestone AL, Hall RJ, Harrison S, Hastings A, Holland M, Holyland M, Holyoak M, Lambrinos J, Moore K, Yokomizo H (2007) Invasion in a heterogeneous world: Resistance, coexistence or hostile takeover? Ecology Letters, 10, 77-94. |
[63] | Mooney HA, Drake JA (1986) Ecology of Biological Invasions of North America and Hawaii. Springer, New York. |
[64] | Ordonez A, Wright IJ, Olff H (2010) Functional differences between native and alien species: A global-scale comparison. Functional Ecology, 24, 1353-1361. |
[65] | Park DS, Feng X, Maitner BS, Ernst KC, Enquist BJ (2020) Darwin’s naturalization conundrum can be explained by spatial scale. Proceedings of the National Academy of Sciences, USA, 117, 10904-10910. |
[66] |
Pearson DE, Ortega YK, Eren Ö, Hierro JL (2018) Community assembly theory as a framework for biological invasions. Trends in Ecology and Evolution, 33, 313-325.
DOI URL PMID |
[67] |
Petermann JS, Fergus AJF, Turnbull LA, Schmid B (2008) Janzen-Connell effects are widespread and strong enough to maintain diversity in grasslands. Ecology, 89, 2399-2406.
URL PMID |
[68] | Pettitt-Wade H, Wellband KW, Heath DD, Fisk AT (2015) Niche plasticity in invasive fishes in the Great Lakes. Biological Invasions, 17, 2565-2580. |
[69] | Pyšek P, Hulme PE (2009) Invasion biology is a discipline that’s too young to die. Nature, 460, 324-324. |
[70] | Ricciardi A, Mottiar M (2006) Does Darwin’s naturalization hypothesis explain fish invasions? Biological Invasions, 8, 1403-1407. |
[71] | Richardson DM, Pyšek P (2006) Plant invasions: Merging the concepts of species invasiveness and community invasibility. Progress in Physical Geography: Earth and Environment, 30, 409-431. |
[72] | Richardson DM, Ricciardi A (2013) Misleading criticisms of invasion science: A field guide. Diversity and Distributions, 19, 1461-1467. |
[73] | Shea K, Chesson P (2002) Community ecology theory as a framework for biological invasions. Trends in Ecology and Evolution, 17, 170-176. |
[74] | Sheppard CS (2019) Relative performance of co-occurring alien plant invaders depends on traits related to competitive ability more than niche differences. Biological Invasions, 21, 1101-1114. |
[75] | Shigesada N, Kawasaki K (1997) Biological Invasions: Theory and Practice. Oxford University Press, Oxford. |
[76] | Simberloff D, Von Holle B (1999) Positive interactions of nonindigenous species: Invasional meltdown? Biological Invasions, 1, 21-32. |
[77] |
Simberloff D (2011) Non-natives: 141 scientists object. Nature, 475, 36.
DOI URL PMID |
[78] | Simberloff D, Vitule JRS (2014) A call for an end to calls for the end of invasion biology. Oikos, 123, 408-413. |
[79] |
Simberloff D (2015) Non-native invasive species and novel ecosystems. F1000prime Reports, 7, 47.
DOI URL PMID |
[80] |
Song C, Barabás G, Saavedra S (2019) On the consequences of the interdependence of stabilizing and equalizing mechanisms. The American Naturalist, 194, 627-639.
DOI URL PMID |
[81] | Song CL (2020) Structural stability: Concepts, methods, and applications. Biodiversity Science, 28, 1345-1361. (in Chinese with English abstract) |
[ 宋础良 (2020) 结构稳定性: 概念、方法和应用. 生物多样性, 28, 1345-1361.] | |
[82] | Suda J, Meyerson LA, Leitch IJ, Pyšek P (2015) The hidden side of plant invasions: The role of genome size. New Phytologist, 205, 994-1007. |
[83] |
Thompson K, Davis MA (2011) Why research on traits of invasive plants tells us very little. Trends in Ecology and Evolution, 26, 155-156.
DOI URL PMID |
[84] | Valdovinos FS, Berlow EL, de Espanés PM, Ramos-Jiliberto R, Vázquez DP, Martinez ND (2018) Species traits and network structure predict the success and impacts of pollinator invasions. Nature Communications, 9, 2153. |
[85] | Valéry L, Fritz H, Lefeuvre JC (2013) Another call for the end of invasion biology. Oikos, 122, 1143-1146. |
[86] | Vallano DM, Selmants PC, Zavaleta ES (2012) Simulated nitrogen deposition enhances the performance of an exotic grass relative to native serpentine grassland competitors. Plant Ecology, 213, 1015-1026. |
[87] |
van Kleunen M, Dawson W, Schlaepfer D, Jeschke JM, Fischer M (2010a) Are invaders different? A conceptual framework of comparative approaches for assessing determinants of invasiveness. Ecology Letters, 13, 947-958.
DOI URL PMID |
[88] |
van Kleunen M, Weber E, Fischer M (2010b) A meta-analysis of trait differences between invasive and non-invasive plant species. Ecology Letters, 13, 235-245.
URL PMID |
[89] | Vellend M (2016) The Theory of Ecological Communities. Princeton University Press, Princeton and Oxford. |
[90] | Wan FH, Hou YM, Jiang MX (2015) Invasion Biology. Science Press, Beijing. (in Chinese) |
[ 万方浩, 侯有明, 蒋明星 (2015) 入侵生物学. 科学出版社, 北京.] | |
[91] | Wang MN, Dai ZC, Qi SS, Wang XY, Du DL (2014) Main hypotheses and research progress of invasive mechanism of alien plants. Jiangsu Agricultural Sciences, 42(12), 378-382. (in Chinese) |
[ 王明娜, 戴志聪, 祁珊珊, 王晓莹, 杜道林 (2014) 外来植物入侵机制主要假说及其研究进展. 江苏农业科学, 42(12), 378-382.] | |
[92] | Wang SP (2020) Food web structure and functioning: Theoretical advances and outlook. Biodiversity Science, 28, 1391-1404. (in Chinese with English abstract) |
[ 王少鹏 (2020) 食物网结构与功能: 理论进展与展望. 生物多样性, 28, 1391-1404.] | |
[93] | Williamson M (1996) Biological Invasions. Springer, New York. |
[94] | Wu H, Ding JQ (2014) Recent progress in invasion ecology. Chinese Science Bulletin, 59, 438-448. (in Chinese with English abstract) |
[ 吴昊, 丁建清 (2014) 入侵生态学最新研究动态. 科学通报, 59, 438-448.] | |
[95] | Xu CY, Zhang WJ, Lu BR, Chen JK (2001) Progress in studies on mechanisms of biological invasion. Biodiversity Science, 9, 430-438. (in Chinese with English abstract) |
[ 徐承远, 张文驹, 卢宝荣, 陈家宽 (2001) 生物入侵机制研究进展. 生物多样性, 9, 430-438.] | |
[96] | Xu RM, Ye WH (2003) Biological Invasions: Theory and Practice. Science Press, Beijing. (in Chinese) |
[ 徐汝梅, 叶万辉 (2003) 生物入侵理论与实践. 科学出版社, 北京.] | |
[97] | Zhang ZJ, van Kleunen M (2019) Common alien plants are more competitive than rare natives but not than common natives. Ecology Letters, 22, 1378-1386. |
[98] | Zheng JM, Ma KP (2010) Invasion Ecology. Higher Education Press, Beijing. (in Chinese) |
[ 郑景明, 马克平 (2010) 入侵生态学. 高等教育出版社, 北京.] | |
[99] | Zhu BR, Zhang DY (2011) A process-based theoretical framework for community ecology. Biodiversity Science, 19, 389-399. (in Chinese with English abstract) |
[ 朱璧如, 张大勇 (2011) 基于过程的群落生态学理论框架. 生物多样性, 19, 389-399.] |
[1] | Rui Qu, Zhenjun Zuo, Youxin Wang, Liangjian Zhang, Zhigang Wu, Xiujuan Qiao, Zhong Wang. The biogeochemical niche based on elementome and its applications in different ecosystems [J]. Biodiv Sci, 2024, 32(4): 23378-. |
[2] | Xiaobo Lü, Donghai Li, Xiaobo Yang, Mengwen Zhang. The species coexisted in mangrove communities through niche differentiation of flooding time and salinity [J]. Biodiv Sci, 2024, 32(3): 23302-. |
[3] | Ren Jialong, Wang Yongzhen, Feng Yilin, Zhao Wenzhi, Yan Qihan, Qin Chang, Fang Jing, Xin Weidong, Liu Jiliang. Beetle data set collected by pitfall trapping in the gobi desert of the Hexi Corridor [J]. Biodiv Sci, 2024, 32(2): 23375-. |
[4] | Lixia Han, Yongjian Wang, Xuan Liu. Comparisons between non-native species invasion and native species range expansion [J]. Biodiv Sci, 2024, 32(1): 23396-. |
[5] | Zhifa Liu, Xincai Wang, Yuening Gong, Daojian Chen, Qiang Zhang. Diversity and elevational distribution of birds and mammals based on infrared camera monitoring in Guangdong Nanling National Nature Reserve [J]. Biodiv Sci, 2023, 31(8): 22689-. |
[6] | Xintong Gong, Fei Chen, Huanhuan Gao, Xinqiang Xi. Larva and adult competition between two Drosophila species and the effects on species coexistence [J]. Biodiv Sci, 2023, 31(8): 22603-. |
[7] | Kunming Zhao, Shengbin Chen, Xifu Yang. Investigation of the diversity of mammals and birds and the activity rhythm of dominant species using camera trapping in a fragmented forest in the Dujiangyan region, Sichuan Province [J]. Biodiv Sci, 2023, 31(6): 22529-. |
[8] | Buqing Peng, Ling Tao, Jing Li, Ronghui Fan, Shunde Chen, Changkun Fu, Qiong Wang, Keyi Tang. DNA metabarcoding dietary analysis of six sympatric small mammals at the Laojunshan National Nature Reserve, Sichuan Province [J]. Biodiv Sci, 2023, 31(4): 22474-. |
[9] | Shusen Fu, Puqing Song, Yuan Li, Yuanyuan Li, Ran Zhang, Hushun Zhang, Rui Wang, Longshan Lin. Trophic levels and trophic niches of fish from the Bering Sea and Chukchi Sea [J]. Biodiv Sci, 2023, 31(4): 22521-. |
[10] | Minhao Chen, Chao Zhang, Jiadong Wang, Zhenjie Zhan, Junzhi Chen, Xiaofeng Luan. Distribution and niche overlap of American mink and Eurasian otter in Northeast China [J]. Biodiv Sci, 2023, 31(1): 22289-. |
[11] | Tingting Li, Xihong Zhu, Guangnian Wu, Xiao Song, Aichun Xu. Spawning ground microhabitat selection by the Chinhai spiny newt (Echinotriton chinhaiensis) [J]. Biodiv Sci, 2023, 31(1): 22293-. |
[12] | Zhilin Li, Tianming Wang. Competition and coexistence between tigers and leopards in Asia [J]. Biodiv Sci, 2022, 30(9): 22271-. |
[13] | Bo Wei, Linshan Liu, Changjun Gu, Haibin Yu, Yili Zhang, Binghua Zhang, Bohao Cui, Dianqing Gong, Yanli Tu. The climate niche is stable and the distribution area of Ageratina adenophora is predicted to expand in China [J]. Biodiv Sci, 2022, 30(8): 21443-. |
[14] | Tianxiang Zhou, Hualin Yang, Guiquan Zhang, Jian Yang, Xi Feng, Qiang Hu, Yuehong Cheng, Jindong Zhang, Bin Wang, Caiquan Zhou. Temporal and spatial niche differentiation among three alpine Galliformes with sympatric distribution in the Wolong National Nature Reserve, Sichuan Province [J]. Biodiv Sci, 2022, 30(6): 22026-. |
[15] | Tian Luo, Fangyuan Yu, Juyu Lian, Junjie Wang, Jian Shen, Zhifeng Wu, Wanhui Ye. Impact of canopy vertical height on leaf functional traits in a lower subtropical evergreen broad-leaved forest of Dinghushan [J]. Biodiv Sci, 2022, 30(5): 21414-. |
Viewed | ||||||
Full text |
|
|||||
Abstract |
|
|||||
Copyright © 2022 Biodiversity Science
Editorial Office of Biodiversity Science, 20 Nanxincun, Xiangshan, Beijing 100093, China
Tel: 010-62836137, 62836665 E-mail: biodiversity@ibcas.ac.cn