A small number of the forest species of lepidoptera (moths and butterflies, which exist as caterpillars during most of their life cycle) exhibit regularly recurring patterns of population growth and decline—such fluctuations in population are known as population cycles. Although many different variables influence population levels, a regular pattern such as a population cycle seems to imply a dominant, driving force. Identification of that driving force, however, has proved surprisingly elusive despite considerable research. The common approach of studying causes of population cycles by measuring the mortality caused by different agents, such as predatory birds or parasites, has been unproductive in the case of lepidoptera. Moreover, population ecologists' attempts to alter cycles by changing the caterpillars' habitat and by reducing caterpillar populations have not succeeded. In short, the evidence implies that these insect populations, if not self-regulating, may at least be regulated by an agent more intimately connected with the insect than are predatory birds or parasites.
Recent work suggests that this agent may be a virus. For many years, viral disease had been reported in declining populations of caterpillars, but population ecologists had usually considered viral disease to have contributed to the decline once it was underway rather than to have initiated it. The recent work has been made possible by new techniques of molecular biology that allow viral DNA to be detected at low concentrations in the environment. Nuclear polyhedrosis viruses are hypothesized to be the driving force behind population cycles in lepidoptera in part because the viruses themselves follow an infectious cycle in which, if protected from direct sunlight, they may remain virulent for many years in the environment, embedded in durable crystals of polyhedrin protein. Once ingested by a caterpillar, the crystals dissolve, releasing the virus to infect the insect's cells. Late in the course of the infection, millions of new virus particles are formed and enclosed in polyhedrin crystals. These crystals reenter the environment after the insect dies and decomposes, thus becoming available to infect other caterpillars.
One of the attractions of this hypothesis is its broad applicability. Remarkably, despite significant differences in habitat and behavior, many species of lepidoptera have population cycles of similar length, between eight and 11 years. Nuclear polyhedrosis viral infection is one factor these disparate species share.
It can be inferred from the passage that the mortality caused by agents such as predatory birds or parasites was measured in an attempt to
develop an explanation for the existence of lepidoptera population cycles
identify behavioral factors in lepidoptera that affect survival rates
identify possible methods for controlling lepidoptera population growth
provide evidence that lepidoptera populations are self-regulating
determine the life stages of lepidoptera at which mortality rates are highest
题目分析:
文章推断题:文章提到“测量鸟或者寄生虫造成的死亡率”是为了?
原文:研究population cycle的原因时,通常使用的方法(测量鸟或寄生虫造成的死亡率)不适用于L。
选项分析:
A选项:正确。解释L的population cycle的存在:使用这个方法的目的是为了找driving force,但结果是失败的。
B选项:辨别出影响L生存率的行为:没有提
C选项:找出可以控制L数量增长的方法:文章没有提到控制数量。
D选项:证明L的数量是自我调节的:并没有。
E选项:确认L在哪个阶段死亡率最高:并没有。
他们试图是去解释cycle,尽管最后发现是无关的,但他们最开始的目的并不是为了证明他的数量是self-regulating
说到点子上了
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