AP Biology : Understanding Food Webs

Study concepts, example questions & explanations for AP Biology

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Example Questions

Example Question #1 : Understanding Food Webs

What is the term for a relationship between two organisms of different species in which one benefits while the other neither benefits, nor is harmed?

Possible Answers:

Parasitism

Cohabitation

Mutualism

Symbiosis

Commensalism

Correct answer:

Commensalism

Explanation:

Commensalism is the type of relationship between two organisms in which one benefits while the other remains neutral. One such example of this is the relationship between whales and barnacles. The barnacles benefit, as they are able to gain mobility and feed off the current generated by movement of the whale. The whale, however, remains neutral; it gains no advantage or disadvantage from the presence of the barnacles.

Cohabitation relationships imply that both species remain neutral, while symbiotic and mutualistic relationships imply that both species gain benefit. In symbiosis, the two species depend on each other for survival. Parasitism implies benefit of one species, at the harm of the other.

Example Question #2 : Understanding Food Webs

Of the following types of organism, which can directly obtain energy from any of the other types of organisms in an ecosystem?

Possible Answers:

Herbivore

Producer

Omnivore

Carnivore

Saprotroph

Correct answer:

Saprotroph

Explanation:

Saprotrophs are decomposers that are capable of breaking down dead or dying organisms. Because of this, saprotrophs can obtain energy directly from any other organisms in an ecosystem.

Producers are autotrophs, and do not require organic input to create energy. Carnivores, herbivores, and omnivores are loose classifications of organisms based on diet. Carnivores typically feed on heterotrophs, while herbivores generally feed on autotrophs. Omnivores typically feed on both autotrophs and heterotrophs.

Example Question #2 : Ecology

Human intestines contain numerous microorganism species, includes a species of bacteria that synthesizes vitamin K and out-competes dangerous E. coli species. This species does not harm its human host in any way, and the species benefits from its intestinal habitat. Which term best describes this relationship?

Possible Answers:

Parasitism

Mutualism

Predation

Commensalism

Correct answer:

Mutualism

Explanation:

In a mutualistic relationship, both organisms benefit from the relationship. In this example, the human host benefits because (s)he gains access to nutrients and is at a lower risk of hosting dangerous E. coli, while the bacteria species benefits because it gains access to a habitat.

A competitive relationship exists when two species share a predator, are competing for the same resources, or otherwise interfere with one another.

Predation refers to an organism eating another organism; animals can prey on animals, or on plants.

In a parasitic relationship, one species benefits while the other is negatively impacted.

In a commensal relationship, one species benefits while the other is not impacted. 

Example Question #4 : Ecology

Only about 10% of the energy stored in a trophic level can be converted to matter in the next trophic level. Which of the following is not a consequence of this fact?

Possible Answers:

Producers always have the greatest biomass of any trophic level

Food chains almost never have more than four or five trophic levels

A species can occupy different trophic levels, depending on what it is eating; for example, an omnivore is a primary consumer when it eats plant leaves, but could be a secondary or tertiary consumer when it eats other animal species.

Fluctuating population sizes at different trophic levels cause longer food chains to be less stable than shorter food chains

Correct answer:

A species can occupy different trophic levels, depending on what it is eating; for example, an omnivore is a primary consumer when it eats plant leaves, but could be a secondary or tertiary consumer when it eats other animal species.

Explanation:

Though all of these statements are true, the fact that species can occupy different trophic levels depending on what they're eating is not a consequence of the fact that only 10% of all stored energy can ascend from one trophic level to the next. These facts are related, but one does not cause the other.

Food chains only have four or five trophic levels at maximum because the food chain is rapidly depleted of stored energy after each trophic level increase. Logically, producers always have the most biomass of any trophic level because they must produce all of the energy that will sustain the trophic levels above them. Finally, it makes sense that fluctuating population sizes threaten the stability of longer food chains because if even one trophic level suffers a population decrease, then all of the trophic levels above it are potentially jeopardized. 

Example Question #3 : Ecology

Which of the following is not an example of a producer?

Possible Answers:

A species of ant that cultivates its own fungus "gardens"

A species of coastal phytoplankton

A fern growing next to a waterfall

An oak tree growing on a California fault line 

Correct answer:

A species of ant that cultivates its own fungus "gardens"

Explanation:

For a species to be a producer, it must be an autotroph and must be able to convert light or chemicals into storable chemical energy, usually as a form of sugar. Green plants are some of the most familiar producers, but some species of plankton (phytoplankton) are also able to engage in photosynthesis and supply energy to fuel food chains/webs.

As decomposers, all species of fungi are heterotrophs, rather than producers (autotrophs). Ants are also not producers, as they also cannot convert light or chemicals into sugars.  

Example Question #2 : Understanding Food Webs

Why are organisms at higher trophic levels more susceptible to the effects of biological magnification than are organisms at lower trophic levels?

Possible Answers:

Animals at higher trophic levels are often larger than animals at lower trophic levels; as a result, they have more surface area through which to absorb environmental toxins. 

All other answers are correct

Organisms at higher trophic levels tend to eat a larger proportion of their own weight in food, which means that they have a greater risk of being exposed to and concentrating biological toxins within their tissues.

Toxins found at trace levels in low trophic levels become concentrated (magnified) through the higher trophic levels. If an organism is unable to excrete toxins at the rate it absorbs them, then it will store excess toxins which will later be absorbed by whatever higher trophic level organism preys on it.

Correct answer:

Toxins found at trace levels in low trophic levels become concentrated (magnified) through the higher trophic levels. If an organism is unable to excrete toxins at the rate it absorbs them, then it will store excess toxins which will later be absorbed by whatever higher trophic level organism preys on it.

Explanation:

Biological magnification is most commonly a problem with compounds that are toxic, slow to degrade, and can accumulate in organisms' bodies such as DDT and methylmercury. For example, consider methylmercury. Methylmercury breaks down into less toxic forms very slowly over time and it is excreted from organisms' bodies relatively slowly. Though aquatic plankton may only absorb relatively small or trace amounts of methylmercury over their life spans, they are likely unable to excrete the chemical at the rate that they absorb it into their bodies. Small fish that feed on the plankton must eat large amounts of plankton to survive—in doing so, they are exposed to all of the methylmercury that has accumulated in the bodies of the plankton. They, too, are unable to excrete this methylmercury at the rate they absorb it. When larger fish feed on the small fish, these larger fish are exposed to and absorb the methylmercury contained in the small fish. They are likely unable to excrete the majority of this methylmercury at the rate that they continue consuming mercury found in the small fish. This process continues upwards through the trophic levels, until organisms at high trophic levels, such as birds of prey (or humans!) are exposed to high levels of methylmercury that have been concentrated/magnified up through the trophic levels.

Example Question #2 : Ecology

Which of the following best defines a dominant species in a community?

Possible Answers:

The most resilient species, which stands the best chance of surviving a catastrophic environmental event

The species that is either the most abundant or that has the highest collective biomass

The species that, though not abundant in the community, exerts major control over the distribution and abundance of surrounding species

The species at the highest trophic level in the community

Correct answer:

The species that is either the most abundant or that has the highest collective biomass

Explanation:

Dominant species are more numerous than their competitors in an ecological community. They can be said to define their communities, and they exert influence over the other species within their communities. For example: mangroves are generally the dominant species in tropical tidal swamps.

Critically, dominant species are different from keystone species. Despite their often relatively low total biomass, keystone species have a large impact on the distribution and abundance of species around them. Sea otters are a good example of a keystone species: even though otters have relatively low total biomass, they are crucial to many marine ecosystems because they prey on sea urchins. If otters are removed from a habitat, sea urchins will eat or destroy large portions of the habitat's kelp, which can threaten species at all trophic levels. 

Example Question #1 : Understanding Food Webs

Which of the following contributes to the phenomenon of biological magnification?

Possible Answers:

The biomass at higher trophic levels needs a larger amount of biomass at lower levels to support it

Decomposers consume at every trophic level

The biomass at higher trophic levels needs to be equal to the amount of biomass at lower levels to support it

Plants cannot absorb toxins from the environment

The biomass at higher trophic levels needs a smaller amount of biomass at lower levels to support it

Correct answer:

The biomass at higher trophic levels needs a larger amount of biomass at lower levels to support it

Explanation:

Because energy transfer between trophic levels is only about 10% efficient, it takes several organisms at a lower trophic level to support one organism at a higher trophic level. If each fish (lower level organism) has 10 toxin molecules in its body, and each eagle (higher level organism) eats 10 fish, the eagle now has 100 toxin molecules in its body. Molecules stored in an organism accumulate at higher trophic levels; this accumulation is known as biological magnification.

Example Question #1 : Ecology

Organisms that consume organic compounds produced by other organisms are called __________.

Possible Answers:

scavengers 

autotrophs

mutants

heterotrophs

Correct answer:

heterotrophs

Explanation:

Heterotrophs obtain their organic materials by feeding on other organic organisms. Scavengers are an examples of heterotrophs. Autotrophs are self-feeders in that they do not consume organic material but rather create their own organic material from inorganic substances.  

Example Question #1 : Ecology

In terms of trophic structure, the cascade model follows which of the following viewpoints?

Possible Answers:

Trophic relationships are unpredictable and are dependent on environmental factors 

There is a unidirectional influence from higher to lower trophic levels 

Lower trophic levels affect higher trophic levels unpredictably 

There is a unidirectional influence from lower to higher trophic levels 

Higher trophic levels affect higher trophic levels unpredictably 

Correct answer:

There is a unidirectional influence from higher to lower trophic levels 

Explanation:

The cascade model, or top-down model, states that there is a unidirectional influence from higher to lower trophic levels. This model follows the idea that predation controls community organization. Predators limit the number of herbivores, and herbivores limit plants, and plants limit the amount of nutrients available in the soil. 

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