The growth, survival, defense and reproduction of herbivores are influenced by plant nutrient concentrations. I integrated nutritional ecology with principles of ecological stoichiomtery and chemical ecology to explore the effects of plant quality on insect herbivores. Although nitrogen (N) is considered to be the major limiting nutrient for terrestrial insect herbivores, evidence suggests that the stoichiometric balance between N and phosphorus (P) may be equally important. In Chapter 2, I explored potential P limitation in the monarch caterpillar Danaus plexippus and an aphid Aphis asclepiadis, which are specialist insects feeding on milkweeds (Asclepias). I found that although the host plant, A. syriaca was co-limited by soil N and P, neither of the two insect species experienced induced P limitation. The body tissues of A. asclepiadis always exhibited higher N: P ratios than those of the plants, suggesting that the N demand of the aphid always exceeds P demand, even under high N levels. Additionally, P fertilization increased the production of latex in milkweed, which is a defense trait that negatively affected D. plexippus growth rate. In Chapter 3, I found that although foliar N concentration in A. syriaca was positively correlated with the growth rate of D. plexippus, this relationship disappeared when caterpillars fed on A. incarnata, and became negative when fed on A. curassavica. The mechanism for the negative relationship was because per unit toxicity of cardenolide was higher at high foliar N levels. Because monarchs sequester cardenolides from milkweeds as defense, the increased toxicity under high N could influence sequestration efficiency. Indeed, in chapter 4, I found that the efficiency with which D. plexippus sequesters cardenolides from milkweed was reduced by soil fertilization. Finally, I explored feedback between herbivore activity and nutrient allocation in plants. I showed that herbivores can exert top-down effects on plant nutrient concentration by changing plant resource allocation patterns. Specifically, when under simultaneous attack by above- and belowground herbivores, A. syriaca was able to allocate newly absorbed N to stems and render it unavailable to future attack by both herbivores. Such nutrient reallocation may represent an important mechanism by which plants tolerate herbivore attack.
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机译:草食动物的生长,存活,防御和繁殖受植物营养素浓度的影响。我将营养生态学与生态化学计量学和化学生态学原理相结合,以探索植物质量对昆虫食草动物的影响。尽管氮(N)被认为是陆地昆虫食草动物的主要限制性营养素,但证据表明,氮和磷(P)之间的化学计量平衡可能同样重要。在第2章中,我探讨了帝王毛虫Danaus plexippus和蚜虫Aphis asclepiadis的潜在P限制,它们是以乳草(Asclepias)为食的专门昆虫。我发现,尽管寄主植物A. syriaca受土壤N和P共同限制,但这两种昆虫都没有受到诱导的P限制。 A. asclepiadis的身体组织总是表现出比植物更高的N:P比,这表明即使在高N水平下,蚜虫的N需求也总是超过P需求。此外,磷肥增加了乳草中乳胶的产量,这是一种防御性状,对丛枝线虫的生长速度有负面影响。在第3章中,我发现虽然syriaca中的叶N含量与D.plexippus的生长速率呈正相关,但当以毛虫为食时,这种关系消失了,而以curassavica为食时,这种关系变为负相关。负相关的机制是因为在高叶面氮水平下,烯醇内酯的单位毒性较高。由于君主从乳草中螯合了烯属内酯作为防御,因此在高氮下增加的毒性可能会影响螯合效率。确实,在第4章中,我发现土壤肥力降低了丛枝线虫D.螯合乳草中的烯醇内酯的效率。最后,我探索了草食动物活动与植物营养分配之间的反馈。我发现草食动物可以通过改变植物资源的分配方式对植物营养素浓度产生自上而下的影响。具体来说,当同时受到地上和地下食草动物的攻击时,A。syriaca能够将新吸收的N分配给茎,从而使其日后无法被两种食草动物攻击。这种营养素的重新分配可能代表植物耐受草食动物攻击的重要机制。
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