Department of Zoology, University of Cambridge, United Kingdom.
Biol Rev Camb Philos Soc. 2011 Nov;86(4):836-52. doi: 10.1111/j.1469-185X.2010.00173.x. Epub 2011 Jan 12.
Avian parents and social insect colonies are victimized by interspecific brood parasites-cheats that procure costly care for their dependent offspring by leaving them in another species' nursery. Birds and insects defend themselves from attack by brood parasites; their defences in turn select counter-strategies in the parasite, thus setting in motion antagonistic co-evolution between the two parties. Despite their considerable taxonomic disparity, here we show striking parallels in the way that co-evolution between brood parasites and their hosts proceeds in insects and birds. First, we identify five types of co-evolutionary arms race from the empirical literature, which are common to both systems. These are: (a) directional co-evolution of weaponry and armoury; (b) furtiveness in the parasite countered by strategies in the host to expose the parasite; (c) specialist parasites mimicking hosts who escape by diversifying their genetic signatures; (d) generalist parasites mimicking hosts who escape by favouring signatures that force specialization in the parasite; and (e) parasites using crypsis to evade recognition by hosts who then simplify their signatures to make the parasite more detectable. Arms races a and c are well characterized in the theoretical literature on co-evolution, but the other types have received little or no formal theoretical attention. Empirical work suggests that hosts are doomed to lose arms races b and e to the parasite, in the sense that parasites typically evade host defences and successfully parasitize the nest. Nevertheless hosts may win when the co-evolutionary trajectory follows arms race a, c or d. Next, we show that there are four common outcomes of the co-evolutionary arms race for hosts. These are: (1) successful resistance; (2) the evolution of defence portfolios (or multiple lines of resistance); (3) acceptance of the parasite; and (4) tolerance of the parasite. The particular outcome is not determined by the type of preceding arms race but depends more on whether hosts or parasites control the co-evolutionary trajectory: tolerance is an outcome that parasites inflict on hosts, whereas the other three outcomes are more dependent on properties intrinsic to the host species. Finally, our review highlights considerable interspecific variation in the complexity and depth of host defence portfolios. Whether this variation is adaptive or merely reflects evolutionary lag is unclear. We propose an adaptive explanation, which centres on the relative strength of two opposing processes: strategy-facilitation, in which one line of host defence promotes the evolution of another form of resistance, and strategy-blocking, in which one line of defence may relax selection on another so completely that it causes it to decay. We suggest that when strategy-facilitation outweighs strategy-blocking, hosts will possess complex defence portfolios and we identify selective conditions in which this is likely to be the case.
鸟类父母和社会性昆虫群体成为种间巢寄生者的受害者——这些骗子将自己的后代托付给另一个物种的巢穴,从而获得昂贵的照料。鸟类和昆虫会保护自己免受巢寄生者的攻击;它们的防御措施反过来又会选择寄生虫的反策略,从而在两者之间引发对抗性的共同进化。尽管它们在分类学上存在很大的差异,但我们在这里展示了在昆虫和鸟类中,巢寄生者与其宿主之间的共同进化方式惊人的相似之处。首先,我们从实证文献中确定了五种类型的共同进化军备竞赛,这在两个系统中都很常见。这些是:(a)武器和盔甲的定向进化;(b)寄生虫的隐蔽性被宿主用来暴露寄生虫的策略所抵消;(c)寄生虫模仿宿主,而宿主通过多样化遗传特征来逃避,寄生虫则通过专门化来模仿;(d)寄生虫模仿宿主,宿主通过偏爱迫使寄生虫专门化的特征来逃避,而寄生虫则通过伪装来逃避宿主的识别,宿主则通过简化特征来使寄生虫更容易被识别;(e)寄生虫使用伪装来逃避宿主的识别,宿主则简化特征来使寄生虫更容易被识别。军备竞赛 a 和 c 在共同进化的理论文献中有很好的描述,但其他类型的军备竞赛很少或根本没有受到正式的理论关注。实证研究表明,宿主在军备竞赛 b 和 e 中注定会输给寄生虫,因为寄生虫通常会逃避宿主的防御并成功寄生巢穴。然而,当共同进化轨迹遵循军备竞赛 a、c 或 d 时,宿主可能会获胜。其次,我们表明,宿主的共同进化军备竞赛有四种常见的结果。这些是:(1)成功抵抗;(2)防御组合的进化(或多种抵抗形式);(3)接受寄生虫;(4)容忍寄生虫。特定的结果不是由之前的军备竞赛类型决定的,而是更多地取决于宿主还是寄生虫控制着共同进化的轨迹:容忍是寄生虫对宿主施加的结果,而其他三个结果则更多地取决于宿主物种的内在特性。最后,我们的综述强调了宿主防御组合的复杂性和深度存在相当大的种间差异。这种差异是适应性的还是仅仅反映了进化滞后尚不清楚。我们提出了一个适应性解释,其中心思想是两个相反过程的相对强度:策略促进,其中一种宿主防御促进另一种抵抗形式的进化,以及策略阻断,其中一种防御形式可能完全放松对另一种的选择,从而导致其退化。我们认为,当策略促进大于策略阻断时,宿主将拥有复杂的防御组合,我们确定了这种情况可能出现的选择性条件。
