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Charles Darwin mentioned evolutionary interactions between flowering plants and insects in On the Origin of Species (1859). Although he did not use the word coevolution, he suggested how plants and insects could evolve through reciprocal evolutionary changes. Naturalists in the late 1800s studied other examples of how interactions among species could result in reciprocal evolutionary change. Beginning in the 1940s, plant pathologists developed breeding programs that were examples of human-induced coevolution. Development of new crop plant varieties that were resistant to some diseases favored rapid evolution in pathogen populations to overcome those plant defenses. That, in turn, required the development of yet new resistant crop plant varieties, producing an ongoing cycle of reciprocal evolution in crop plants and diseases that continues to this day.
 
Charles Darwin mentioned evolutionary interactions between flowering plants and insects in On the Origin of Species (1859). Although he did not use the word coevolution, he suggested how plants and insects could evolve through reciprocal evolutionary changes. Naturalists in the late 1800s studied other examples of how interactions among species could result in reciprocal evolutionary change. Beginning in the 1940s, plant pathologists developed breeding programs that were examples of human-induced coevolution. Development of new crop plant varieties that were resistant to some diseases favored rapid evolution in pathogen populations to overcome those plant defenses. That, in turn, required the development of yet new resistant crop plant varieties, producing an ongoing cycle of reciprocal evolution in crop plants and diseases that continues to this day.
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1859年,查尔斯·达尔文在他的著作''物种起源''中提到了被子植物和昆虫之间的进化互动。尽管他没有使用共同进化这个词,但他提出了植物和昆虫是如何通过相互的进化变化而进化的。19世纪晚期的博物学家研究了物种间的交互如何导致彼此演变的其他例子。从20世纪40年代开始的由植物病理学家开发的育种程序就是人类诱导共同进化的例子。培育能够抵抗某些疾病作物的新品种有利于病原体种群的快速进化以克服作物的这些抵御。这反过来又需要开发新的抗性作物品种,这样就造成了在作物和疾病之间的一个持续共同演化的循环;如此的循环一直持续到了今天。
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1859年,查尔斯·达尔文在他的著作''物种起源''中提到了被子植物和昆虫之间的进化互动。尽管他没有使用共同进化这个词,但他提出了植物和昆虫是如何通过相互进化的改变而演化的。19世纪晚期的博物学家研究了物种间的交互如何导致彼此演变的其他例子。从20世纪40年代开始的由植物病理学家开发的育种程序就是人类诱导共同进化的例子。培育能够抵抗某些疾病作物的新品种有利于病原体种群的快速进化以克服作物的这些抵御。这反过来又需要开发新的抗性作物品种,这样就造成了在作物和疾病之间的一个持续共同演化的循环;如此的循环一直持续到了今天。
    
Coevolution as a major topic for study in nature expanded rapidly after the middle 1960s, when Daniel H. Janzen showed coevolution between acacias and ants (see below) and [[Paul R. Ehrlich]] and [[Peter H. Raven]] suggested how [[Escape and radiate coevolution|coevolution between plants and butterflies]] may have contributed to the diversification of species in both groups. The theoretical underpinnings of coevolution are now well-developed (e.g., the geographic mosaic theory of coevolution), and demonstrate that coevolution can play an important role in driving major evolutionary transitions such as the evolution of sexual reproduction or shifts in ploidy. More recently, it has also been demonstrated that coevolution can influence the structure and function of ecological communities, the evolution of groups of mutualists such as plants and their pollinators, and the dynamics of infectious disease.
 
Coevolution as a major topic for study in nature expanded rapidly after the middle 1960s, when Daniel H. Janzen showed coevolution between acacias and ants (see below) and [[Paul R. Ehrlich]] and [[Peter H. Raven]] suggested how [[Escape and radiate coevolution|coevolution between plants and butterflies]] may have contributed to the diversification of species in both groups. The theoretical underpinnings of coevolution are now well-developed (e.g., the geographic mosaic theory of coevolution), and demonstrate that coevolution can play an important role in driving major evolutionary transitions such as the evolution of sexual reproduction or shifts in ploidy. More recently, it has also been demonstrated that coevolution can influence the structure and function of ecological communities, the evolution of groups of mutualists such as plants and their pollinators, and the dynamics of infectious disease.
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Predators and prey interact and coevolve: the predator to catch the prey more effectively, the prey to escape. The coevolution of the two mutually imposes selective pressures. These often lead to an evolutionary arms race between prey and predator, resulting in anti-predator adaptations.
 
Predators and prey interact and coevolve: the predator to catch the prey more effectively, the prey to escape. The coevolution of the two mutually imposes selective pressures. These often lead to an evolutionary arms race between prey and predator, resulting in anti-predator adaptations.
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捕食者和猎物互动并共同演化:捕食者去更有效地捕捉猎物,猎物去逃离追捕。两者的共同演化相互施加这一选择压。这往往导致猎物和捕食者之间的进化军备竞赛,并导致反捕食适应。
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捕食者和猎物互动并共同演化:捕食者去更有效地捕捉猎物,猎物去逃离追捕。两者的共同演化相互施加这一选择压。这往往导致猎物和捕食者之间的进化军备竞赛,并导致反捕食者适应。
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The same applies to [[herbivore]]s, animals that eat plants, and the plants that they eat.  [[Paul R. Ehrlich]] and [[Peter H. Raven]] in 1964 proposed the theory of [[escape and radiate coevolution]] to describe the evolutionary diversification of plants and butterflies.<ref>{{cite journal |last1=Ehrlich |first1=Paul R. |author1-link=Paul R. Ehrlich |last2=Raven |first2=Peter H. |author2-link= Peter H. Raven |year=1964 |title=Butterflies and Plants: A Study in Coevolution |journal=Evolution |volume=18 |issue=4 |pages=586–608 |doi=10.2307/2406212 |jstor=2406212}}</ref> In the [[Rocky Mountains]], [[red squirrel]]s and [[crossbill]]s (seed-eating birds) compete for seeds of the [[lodgepole pine]]. The squirrels get at pine seeds by gnawing through the cone scales, whereas the crossbills get at the seeds by extracting them with their unusual crossed mandibles. In areas where there are squirrels, the lodgepole's cones are heavier, and have fewer seeds and thinner scales, making it more difficult for squirrels to get at the seeds. Conversely, where there are crossbills but no squirrels, the cones are lighter in construction, but have thicker scales, making it more difficult for crossbills to get at the seeds. The lodgepole's cones are in an evolutionary arms race with the two kinds of herbivore.<ref name="Berkeley">{{cite web |title=Coevolution |url=https://evolution.berkeley.edu/evolibrary/article/evo_33 |publisher=University of California Berkeley |access-date=17 January 2017}} and the two following pages of the web article.</ref>
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The same applies to [[herbivore]]s, animals that eat plants, and the plants that they eat.  [[Paul R. Ehrlich]] and [[Peter H. Raven]] in 1964 proposed the theory of [[escape and radiate coevolution]] to describe the evolutionary diversification of plants and butterflies. In the [[Rocky Mountains]], [[red squirrel]]s and [[crossbill]]s (seed-eating birds) compete for seeds of the [[lodgepole pine]]. The squirrels get at pine seeds by gnawing through the cone scales, whereas the crossbills get at the seeds by extracting them with their unusual crossed mandibles. In areas where there are squirrels, the lodgepole's cones are heavier, and have fewer seeds and thinner scales, making it more difficult for squirrels to get at the seeds. Conversely, where there are crossbills but no squirrels, the cones are lighter in construction, but have thicker scales, making it more difficult for crossbills to get at the seeds. The lodgepole's cones are in an evolutionary arms race with the two kinds of herbivore.
    
The same applies to herbivores, animals that eat plants, and the plants that they eat.  Paul R. Ehrlich and Peter H. Raven in 1964 proposed the theory of escape and radiate coevolution to describe the evolutionary diversification of plants and butterflies. In the Rocky Mountains, red squirrels and crossbills (seed-eating birds) compete for seeds of the lodgepole pine. The squirrels get at pine seeds by gnawing through the cone scales, whereas the crossbills get at the seeds by extracting them with their unusual crossed mandibles. In areas where there are squirrels, the lodgepole's cones are heavier, and have fewer seeds and thinner scales, making it more difficult for squirrels to get at the seeds. Conversely, where there are crossbills but no squirrels, the cones are lighter in construction, but have thicker scales, making it more difficult for crossbills to get at the seeds. The lodgepole's cones are in an evolutionary arms race with the two kinds of herbivore. and the two following pages of the web article.
 
The same applies to herbivores, animals that eat plants, and the plants that they eat.  Paul R. Ehrlich and Peter H. Raven in 1964 proposed the theory of escape and radiate coevolution to describe the evolutionary diversification of plants and butterflies. In the Rocky Mountains, red squirrels and crossbills (seed-eating birds) compete for seeds of the lodgepole pine. The squirrels get at pine seeds by gnawing through the cone scales, whereas the crossbills get at the seeds by extracting them with their unusual crossed mandibles. In areas where there are squirrels, the lodgepole's cones are heavier, and have fewer seeds and thinner scales, making it more difficult for squirrels to get at the seeds. Conversely, where there are crossbills but no squirrels, the cones are lighter in construction, but have thicker scales, making it more difficult for crossbills to get at the seeds. The lodgepole's cones are in an evolutionary arms race with the two kinds of herbivore. and the two following pages of the web article.
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这同样适用于草食动物、植食动物,以及它们吃的植物。1964年,保罗·R·欧里希和彼得R·瑞文提出了逃逸辐射共同进化理论来描述植物和蝴蝶的进化多样性。在落基山脉,红松鼠和斑鸠(食种子的鸟)争夺海滩松的种子。松鼠通过啃咬松果鳞片来获取松子,而交喙则通过它们不寻常的交叉下颚来获取松子。在有松鼠的地方,海滩鱼的球果更重,种子更少,鳞片更薄,这使得松鼠更难获得种子。相反,如果有交喙,但没有松鼠,球果的结构较轻,但有较厚的鳞片,使交喙更难以获得种子。海滩上的锥形细胞与这两种食草动物进行着一场进化中的军备竞赛。以及接下来两页的网络文章。
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这同样适用于草食动物、植食动物,以及它们吃的植物。1964年,保罗·R·欧里希和彼得·R·瑞文提出了逃逸和辐射的共同演化理论来描述植物和蝴蝶的进化多样性。<ref>{{cite journal |last1=Ehrlich |first1=Paul R. |author1-link=Paul R. Ehrlich |last2=Raven |first2=Peter H. |author2-link= Peter H. Raven |year=1964 |title=Butterflies and Plants: A Study in Coevolution |journal=Evolution |volume=18 |issue=4 |pages=586–608 |doi=10.2307/2406212 |jstor=2406212}}</ref>在落基山脉,红松鼠和斑鸠(食种子的鸟)争夺海滩松的种子。松鼠通过啃咬松果鳞片来获取松子,而交喙则通过它们不寻常的交叉下颚来获取松子。在有松鼠的地方,海滩鱼的球果更重,种子更少,鳞片更薄,这使得松鼠更难获得种子。相反,如果有交喙,但没有松鼠,球果的结构较轻,但有较厚的鳞片,使交喙更难以获得种子。海滩上的锥形细胞与这两种食草动物进行着一场进化中的军备竞赛。以及接下来两页的网络文章。<ref name="Berkeley">{{cite web |title=Coevolution |url=https://evolution.berkeley.edu/evolibrary/article/evo_33 |publisher=University of California Berkeley |access-date=17 January 2017}} and the two following pages of the web article.</ref>
    
[[File:Drosophila.melanogaster.couple.2.jpg|thumb|upright|[[Sexual conflict]] has been studied in ''[[Drosophila melanogaster]]'' (shown mating, male on right).|链接=Special:FilePath/Drosophila.melanogaster.couple.2.jpg]]
 
[[File:Drosophila.melanogaster.couple.2.jpg|thumb|upright|[[Sexual conflict]] has been studied in ''[[Drosophila melanogaster]]'' (shown mating, male on right).|链接=Special:FilePath/Drosophila.melanogaster.couple.2.jpg]]
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{{Main|Intraspecific competition|Interspecific competition}}
 
{{Main|Intraspecific competition|Interspecific competition}}
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Both [[intraspecific competition]], with features such as [[sexual conflict]]<ref>{{cite journal |doi=10.1098/rstb.2005.1785 |title=Sexual conflict over mating and fertilization: An overview |year=2006 |last1=Parker |first1=G. A. |journal=Philosophical Transactions of the Royal Society B: Biological Sciences |volume=361 |issue=1466 |pages=235–59 |pmid=16612884 |pmc=1569603}}</ref> and [[sexual selection]],<ref name="UCL">{{cite web|title=Biol 2007 - Coevolution|url=https://www.ucl.ac.uk/~ucbhdjm/courses/b242/Coevol/Coevol.html|publisher=[[University College, London]]|access-date=19 January 2017}}</ref> and [[interspecific competition]], such as between predators, may be able to drive coevolution.<ref>{{cite journal |last1=Connell |first1=Joseph H. |s2cid=5576868 |title=Diversity and the Coevolution of Competitors, or the Ghost of Competition Past |journal=Oikos |date=October 1980 |volume=35 |issue=2 |pages=131–138 |doi=10.2307/3544421 |jstor=3544421}}</ref>
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Both [[intraspecific competition]], with features such as [[sexual conflict]] and [[sexual selection]], and [[interspecific competition]], such as between predators, may be able to drive coevolution.
    
Both intraspecific competition, with features such as sexual conflict and sexual selection, and interspecific competition, such as between predators, may be able to drive coevolution.
 
Both intraspecific competition, with features such as sexual conflict and sexual selection, and interspecific competition, such as between predators, may be able to drive coevolution.
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无论是具有如性冲突和性选择等特征的种内竞争,还是具有如食肉动物之间的种间竞争,都可能推动共同进化。
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无论是具有如性冲突<ref>{{cite journal |doi=10.1098/rstb.2005.1785 |title=Sexual conflict over mating and fertilization: An overview |year=2006 |last1=Parker |first1=G. A. |journal=Philosophical Transactions of the Royal Society B: Biological Sciences |volume=361 |issue=1466 |pages=235–59 |pmid=16612884 |pmc=1569603}}</ref>和性选择<ref name="UCL">{{cite web|title=Biol 2007 - Coevolution|url=https://www.ucl.ac.uk/~ucbhdjm/courses/b242/Coevol/Coevol.html|publisher=[[University College, London]]|access-date=19 January 2017}}</ref>等特征的种内竞争,还是具有如食肉动物之间的种间竞争,都可能推动共同进化。<ref>{{cite journal |last1=Connell |first1=Joseph H. |s2cid=5576868 |title=Diversity and the Coevolution of Competitors, or the Ghost of Competition Past |journal=Oikos |date=October 1980 |volume=35 |issue=2 |pages=131–138 |doi=10.2307/3544421 |jstor=3544421}}</ref>
    
== Multispecies ==
 
== Multispecies ==
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