PrepTest 53, Section 4, Question 21

Difficulty: 
Passage
Game
4

Sometimes there is no more effective means of controlling an agricultural pest than giving free rein to its natural predators. A case in point is the cyclamen mite, a pest whose population can be effectively controlled by a predatory mite of the genus Typhlodromus. Cyclamen mites infest strawberry plants; they typically establish themselves in a strawberry field shortly after planting, but their populations do not reach significantly damaging levels until the plants' second year. Typhlodromus mites usually invade the strawberry fields during the second year, rapidly subdue the cyclamen mite populations, and keep them from reaching significantly damaging levels.

Typhlodromus owes its effectiveness as a predator to several factors in addition to its voracious appetite. Its population can increase as rapidly as that of its prey. Both species reproduce by parthenogenesis—a mode of reproduction in which unfertilized eggs develop into fertile females. Cyclamen mites lay three eggs per day over the four or five days of their reproductive life span; Typhlodromus lay two or three eggs per day for eight to ten days. Seasonal synchrony of Typhlodromus reproduction with the growth of prey populations and ability to survive at low prey densities also contribute to the predatory efficiency of Typhlodromus. During winter, when cyclamen mite populations dwindle to a few individuals hidden in the crevices and folds of leaves in the crowns of the strawberry plants, the predatory mites subsist on the honeydew produced by aphids and white flies. They do not reproduce except when they are feeding on the cyclamen mites. These features, which make Typhlodromus well-suited for exploiting the seasonal rises and falls of its prey, are common among predators that control prey populations.

Greenhouse experiments have verified the importance of Typhlodromus predation for keeping cyclamen mites in check. One group of strawberry plants was stocked with both predator and prey mites; a second group was kept predator-free by regular application of parathion, an insecticide that kills the predatory species but does not affect the cyclamen mite. Throughout the study, populations of cyclamen mites remained low in plots shared with Typhlodromus, but their infestation attained significantly damaging proportions on predator-free plants.

Applying parathion in this instance is a clear case in which using a pesticide would do far more harm than good to an agricultural enterprise. The results were similar in field plantings of strawberries, where cyclamen mites also reached damaging levels when predators were eliminated by parathion, but they did not attain such levels in untreated plots. When cyclamen mite populations began to increase in an untreated planting, the predator populations quickly responded to reduce the outbreak. On average, cyclamen mites were about 25 times more abundant in the absence of predators than in their presence.

Sometimes there is no more effective means of controlling an agricultural pest than giving free rein to its natural predators. A case in point is the cyclamen mite, a pest whose population can be effectively controlled by a predatory mite of the genus Typhlodromus. Cyclamen mites infest strawberry plants; they typically establish themselves in a strawberry field shortly after planting, but their populations do not reach significantly damaging levels until the plants' second year. Typhlodromus mites usually invade the strawberry fields during the second year, rapidly subdue the cyclamen mite populations, and keep them from reaching significantly damaging levels.

Typhlodromus owes its effectiveness as a predator to several factors in addition to its voracious appetite. Its population can increase as rapidly as that of its prey. Both species reproduce by parthenogenesis—a mode of reproduction in which unfertilized eggs develop into fertile females. Cyclamen mites lay three eggs per day over the four or five days of their reproductive life span; Typhlodromus lay two or three eggs per day for eight to ten days. Seasonal synchrony of Typhlodromus reproduction with the growth of prey populations and ability to survive at low prey densities also contribute to the predatory efficiency of Typhlodromus. During winter, when cyclamen mite populations dwindle to a few individuals hidden in the crevices and folds of leaves in the crowns of the strawberry plants, the predatory mites subsist on the honeydew produced by aphids and white flies. They do not reproduce except when they are feeding on the cyclamen mites. These features, which make Typhlodromus well-suited for exploiting the seasonal rises and falls of its prey, are common among predators that control prey populations.

Greenhouse experiments have verified the importance of Typhlodromus predation for keeping cyclamen mites in check. One group of strawberry plants was stocked with both predator and prey mites; a second group was kept predator-free by regular application of parathion, an insecticide that kills the predatory species but does not affect the cyclamen mite. Throughout the study, populations of cyclamen mites remained low in plots shared with Typhlodromus, but their infestation attained significantly damaging proportions on predator-free plants.

Applying parathion in this instance is a clear case in which using a pesticide would do far more harm than good to an agricultural enterprise. The results were similar in field plantings of strawberries, where cyclamen mites also reached damaging levels when predators were eliminated by parathion, but they did not attain such levels in untreated plots. When cyclamen mite populations began to increase in an untreated planting, the predator populations quickly responded to reduce the outbreak. On average, cyclamen mites were about 25 times more abundant in the absence of predators than in their presence.

Sometimes there is no more effective means of controlling an agricultural pest than giving free rein to its natural predators. A case in point is the cyclamen mite, a pest whose population can be effectively controlled by a predatory mite of the genus Typhlodromus. Cyclamen mites infest strawberry plants; they typically establish themselves in a strawberry field shortly after planting, but their populations do not reach significantly damaging levels until the plants' second year. Typhlodromus mites usually invade the strawberry fields during the second year, rapidly subdue the cyclamen mite populations, and keep them from reaching significantly damaging levels.

Typhlodromus owes its effectiveness as a predator to several factors in addition to its voracious appetite. Its population can increase as rapidly as that of its prey. Both species reproduce by parthenogenesis—a mode of reproduction in which unfertilized eggs develop into fertile females. Cyclamen mites lay three eggs per day over the four or five days of their reproductive life span; Typhlodromus lay two or three eggs per day for eight to ten days. Seasonal synchrony of Typhlodromus reproduction with the growth of prey populations and ability to survive at low prey densities also contribute to the predatory efficiency of Typhlodromus. During winter, when cyclamen mite populations dwindle to a few individuals hidden in the crevices and folds of leaves in the crowns of the strawberry plants, the predatory mites subsist on the honeydew produced by aphids and white flies. They do not reproduce except when they are feeding on the cyclamen mites. These features, which make Typhlodromus well-suited for exploiting the seasonal rises and falls of its prey, are common among predators that control prey populations.

Greenhouse experiments have verified the importance of Typhlodromus predation for keeping cyclamen mites in check. One group of strawberry plants was stocked with both predator and prey mites; a second group was kept predator-free by regular application of parathion, an insecticide that kills the predatory species but does not affect the cyclamen mite. Throughout the study, populations of cyclamen mites remained low in plots shared with Typhlodromus, but their infestation attained significantly damaging proportions on predator-free plants.

Applying parathion in this instance is a clear case in which using a pesticide would do far more harm than good to an agricultural enterprise. The results were similar in field plantings of strawberries, where cyclamen mites also reached damaging levels when predators were eliminated by parathion, but they did not attain such levels in untreated plots. When cyclamen mite populations began to increase in an untreated planting, the predator populations quickly responded to reduce the outbreak. On average, cyclamen mites were about 25 times more abundant in the absence of predators than in their presence.

Sometimes there is no more effective means of controlling an agricultural pest than giving free rein to its natural predators. A case in point is the cyclamen mite, a pest whose population can be effectively controlled by a predatory mite of the genus Typhlodromus. Cyclamen mites infest strawberry plants; they typically establish themselves in a strawberry field shortly after planting, but their populations do not reach significantly damaging levels until the plants' second year. Typhlodromus mites usually invade the strawberry fields during the second year, rapidly subdue the cyclamen mite populations, and keep them from reaching significantly damaging levels.

Typhlodromus owes its effectiveness as a predator to several factors in addition to its voracious appetite. Its population can increase as rapidly as that of its prey. Both species reproduce by parthenogenesis—a mode of reproduction in which unfertilized eggs develop into fertile females. Cyclamen mites lay three eggs per day over the four or five days of their reproductive life span; Typhlodromus lay two or three eggs per day for eight to ten days. Seasonal synchrony of Typhlodromus reproduction with the growth of prey populations and ability to survive at low prey densities also contribute to the predatory efficiency of Typhlodromus. During winter, when cyclamen mite populations dwindle to a few individuals hidden in the crevices and folds of leaves in the crowns of the strawberry plants, the predatory mites subsist on the honeydew produced by aphids and white flies. They do not reproduce except when they are feeding on the cyclamen mites. These features, which make Typhlodromus well-suited for exploiting the seasonal rises and falls of its prey, are common among predators that control prey populations.

Greenhouse experiments have verified the importance of Typhlodromus predation for keeping cyclamen mites in check. One group of strawberry plants was stocked with both predator and prey mites; a second group was kept predator-free by regular application of parathion, an insecticide that kills the predatory species but does not affect the cyclamen mite. Throughout the study, populations of cyclamen mites remained low in plots shared with Typhlodromus, but their infestation attained significantly damaging proportions on predator-free plants.

Applying parathion in this instance is a clear case in which using a pesticide would do far more harm than good to an agricultural enterprise. The results were similar in field plantings of strawberries, where cyclamen mites also reached damaging levels when predators were eliminated by parathion, but they did not attain such levels in untreated plots. When cyclamen mite populations began to increase in an untreated planting, the predator populations quickly responded to reduce the outbreak. On average, cyclamen mites were about 25 times more abundant in the absence of predators than in their presence.

Question
21

Based on the passage, the author would probably hold that which one of the following principles is fundamental to long-term predatory control of agricultural pests?

The reproduction of the predator population should be synchronized with that of the prey population, so that the number of predators surges just prior to a surge in prey numbers.

The effectiveness of the predatory relationship should be experimentally demonstrable in greenhouse as well as field applications.

The prey population should be able to survive in times of low crop productivity, so that the predator population will not decrease to very low levels.

The predator population's level of consumption of the prey species should be responsive to variations in the size of the prey population.

The predator population should be vulnerable only to pesticides to which the prey population is also vulnerable.

D
Raise Hand   ✋

Explanations

Cyclamen mites
A
B
C
D
E

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