All AP Biology Resources
Example Questions
Example Question #1 : Identify Evolutionary Change Mechanisms
What conclusion did Darwin draw from the finches he observed at the Galapagos Islands?
The larger organisms have a large advantage in nature and will out-compete the smaller organisms.
Organisms will evolve in order to fill unoccupied niches in their environment.
Finches will all live in the same area of a tree, regardless of species type.
Birds reserve a herd mentality, and will aspire to remain similar in appearance to one another.
Organisms will evolve in order to fill unoccupied niches in their environment.
Darwin observed that the finches found on the Galapagos had adapted different sized beaks to eat different diets. By doing this, the birds had evolved to eat diets that would be inedible by other finches. This concept of a "niche" means that different species will exploit and use their environment in different ways.
Example Question #1 : Identify Evolutionary Change Mechanisms
Which of the following was not part of Darwin's theory of evolution?
None of these - Darwin did not develop a theory of evolution
The inheritance of traits in discrete units called alleles
Over time, traits that are beneficial to an organism in a given environment are likely to accumulate in a population
Organisms that are best adapted to their environments are most likely to survive and reproduce
Organisms of the same species display a variety of different traits
The inheritance of traits in discrete units called alleles
The inheritance of traits through discrete units called alleles was not a part of Darwin's theory of evolution. A monk named Gregor Mendel developed the theory of inheritance through alleles. Darwin's theory did not propose a method of inheritance, and Darwin was unaware of Mendel’s work. The works of Darwin and Mendel were later combined by scientists to create the modern theory of evolution.
Example Question #2 : Identify Evolutionary Change Mechanisms
Charles Darwin is well-known for his work on Galapagos finches. He found that the finches' beaks had different sizes and shapes that corresponded to their preferred food source. Which of the following phenomenon does this best illustrate?
Acclimation
Stabilizing selection
Adaptation
Heredity
Adaptation
The finches' beaks are highly adapted to their preferred diet. Therefore, this is an excellent example of adaptation. Acclimation occurs on a very short-term basis and does not apply to speciation. Stabilizing selection decreases the amount of genetic diversity among a population, and does not promote speciation as seen among finches. Heredity is simply the degree to which a parent's genes are passed to its offspring and is not demonstrated by this example.
Example Question #261 : Evolution And Genetics
The various species of Galapagos finches utilize their beaks to access food resources in many ways. Those with longer beaks use their beaks to penetrate cactus fruit and eat the inside, while those with short beaks tear apart the base of the cactus and eat insect larvae and pupae.
Cacti in the Galapagos fail to produce any fruit for several generations, causing finches with long beaks to die. With these environmental changes, selection will favor those with short beaks over those with long beaks. What type of selection is described?
Stabilizing selection
Disruptive selection
Sexual selection
Directional selection
Directional selection
The answer is directional selection. This environmental change will cause a shift in the mean beak size of the population towards smaller beaks because their food resource was not affected. There is selection against long beak size only.
Example Question #2 : Identify Evolutionary Change Mechanisms
Which of the following is an outcome of artificial selection?
Artificial selection increases the compatibility between organisms and their environment
Artificial selection can result in dramatic changes to a species in a relatively short period of time
Artificial selection increases the variation of traits within a population
Artificial selection tends to favor wild type traits
Artificial selection can result in dramatic changes to a species in a relatively short period of time
Artificial selection is a process by which humans have modified species over many generations by selecting and breeding individuals that possess desired traits. The result of such a selection is a narrowing of the traits originally present from its ancestors. The goal of artificial selection is generally to make certain desired traits fixed in the population, with an allele frequency of 100%. These traits are relatively arbitrary, and may be wild type, recessive, advantageous, or disadvantageous. The key factor is a decrease in genetic variability in a small population.
Examples of artificial selection include the derivation of individual breeds of dog and the production of genetically specific lab mice.
Example Question #3 : Identify Evolutionary Change Mechanisms
A species of moth that has a predominantly darker coloration in industrial urban areas, predominantly lighter coloration in rural areas, and limited intermediate coloration in both habitats. This is an example of what type of selection?
Directional selection
Disruptive selection
Stabilizing selection
Artificial selection
Disruptive selection
Disruptive selection occurs when conditions in a habitat favor individuals that are on the extremes of the phenotypic range, instead of individuals with intermediate phenotypic traits. In the example provided in the question, dark-colored moths and light-colored moths each have regions of the habitat where they gain an advantage, but intermediate grey coloring is not favored in any region of the habitat. As a result, both extremes will experience positive selection, while the intermediate will decrease, giving rise to a disruptive selection trend.
Stabilizing occurs when the intermediate phenotype is favored over either extreme. Directional selection occurs when a single extreme is favored over any other phenotype. Artificial selection is the result of human manipulation of breeding, selecting for chosen traits.
Example Question #4 : Identify Evolutionary Change Mechanisms
Which type of selection is depicted by the graph if the solid line represents the original population and the dashed line is the population following selection?
Disruptive selection
Directional selection
Stabilizing selection
Artificial selection
Stabilizing selection
Stabilizing selection removes extreme variants, as they do not provide a survival advantage in a given environment, and increases the frequency of the intermediate phenotype. For example, the bone density of a species of bird is likely to experience stabilizing selection. Bones that are too dense will inhibit the bird's ability to fly, and bones that are too light will be brittle and prone to injury. Stabilizing selection moderates the influence of these two factors and selects for the intermediate phenotype that is neither too heavy, nor too weak.
Disruptive selection shows an increase the in the frequency of extreme traits and a decline in the intermediate trait. For example, if two extremes are white and black coloration, disruptive selection will act against grey coloration and favor both white and back. Directional selection favors only one extreme, for example favoring black over grey and grey over white. Artificial selection occurs when humans interfere with breeding habits to promote the inheritance of a specific trait.
Example Question #4 : Identify Evolutionary Change Mechanisms
The various species of Galapagos finches utilize their beaks to access food resources in many ways. Those with longer beaks use their beaks to penetrate cactus fruit and eat the inside, while those with short beaks tear apart the base of the cactus and eat insect larvae and pupae.
Finches with medium beak size feed on seeds. These birds aren't specialized to feed on insect larvae or cactus fruit like finches with short or long beaks. What type of selection would be observed if deforestation removed all the trees from the area where these birds obtained seeds?
Directional selection
Multi-directional selection
Disruptive selection
Sexual selection
Stabilizing selection
Disruptive selection
In this example the extreme beak sizes are favored over the mean; however the mean beak size does not change. There is selection against the mean, without affecting the value of the mean. This type of selection is known as disruptive selection.
Example Question #5 : Identify Evolutionary Change Mechanisms
Due to the abundance of blue-bellied lizards, they are easier for predators to find. Predators such as hawks become adapted to spotting these blue-bellied lizards and prey on them more frequently than yellow-bellied lizards. When the blue-bellied lizard population begins to decline, the yellow-bellied lizard population begins to rise (due to more abundant resources and the fact that they are preyed on less than the blue-bellies). Which of the following best describes the relationship between the two types of lizards?
Heterozygote advantage
Relative fitness
Intersexual selection
Frequency-dependent selection
Disruptive selection
Frequency-dependent selection
This relationship displays a frequency-dependent selection. Frequency-dependent selection occurs when the fitness of a phenotype depends on how common it is in the population. When blue-bellied lizards are preyed on the most because they are most abundant, the yellow-bellied lizard population grows quickly. However, as the blue-bellied lizard population declines, predators will begin to prey on the yellow-bellied lizards. As the yellow-bellied lizard population declines, the blue-bellied lizard population will increase, and so on. The number of blue or yellow-bellied lizards depends on the relative amount of lizards of a different phenotype, demonstrating frequency-dependent selection.
Example Question #5 : Identify Evolutionary Change Mechanisms
What is true regarding mutations?
All of these
Mutations may be harmful
Mutations are changes to a cell's genome
Duplications, inversions, and translocations are all types of mutations
All of these
Mutations are changes to a cell’s genome and include inversions, duplications, translocations, and deletions, among other unplanned changes to the DNA. Mutations can be harmful to the organism, but can also have beneficial or neutral impacts. Mutation is an important means of evolution because it introduces new genetic combinations into a genome, allowing for the potential of new functions.