Chapter 16 Table of Contents Section 1 Genetic Equilibrium Population Genetics and Speciation Chapter 16 Table of Contents Section 1 Genetic Equilibrium Section 2 Disruption of Genetic Equilibrium Section 3 Formation of Species

Chapter 16 Standards Section 1 Genetic Equilibrium SPI 3210.5.1 Compare and contrast the structural, functional, and behavioral adaptations of animals or plants found in different environments. SPI 3210.5.2 Recognize the relationship between form and function in living things. SPI 3210.5.3 Recognize the relationships among environmental change, genetic variation, natural selection, and the emergence of a new species. SPI 3210.5.4 Describe the relationship between the amount of biodiversity and the ability of a population to adapt to a changing environment. SPI 3210.5.5 Apply evidence from the fossil record, comparative anatomy, amino acid sequences, and DNA structure that support modern classification systems. SPI 3210.5.6 Infer relatedness among different organisms using modern classification systems.

Chapter 16 Objectives Section 1 Genetic Equilibrium Identify traits that vary in populations and that may be studied. Explain the importance of the bell curve to population genetics. Compare three causes of genetic variation in a population. Calculate allele frequency and phenotype frequency. Explain Hardy-Weinberg genetic equilibrium.

Variation of Traits Within a Population Section 1 Genetic Equilibrium Chapter 16 Variation of Traits Within a Population Population biologists study many different traits in populations, such as size and color.

Variation of Traits Within a Population, continued Section 1 Genetic Equilibrium Chapter 16 Variation of Traits Within a Population, continued Causes of Variation Traits vary and can be mapped along a bell curve, which shows that most individuals have average traits, whereas a few individuals have extreme traits. Variations in genotype arise by mutation, recombination, and the random pairing of gametes.

Section 1 Genetic Equilibrium Chapter 16 The Gene Pool The total genetic information available in a population is called the gene pool.

The Gene Pool, continued Section 1 Genetic Equilibrium Chapter 16 The Gene Pool, continued Allele frequency is determined by dividing the total number of a certain allele by the total number of alleles of all types in the population.

The Gene Pool, continued Section 1 Genetic Equilibrium Chapter 16 The Gene Pool, continued Predicting Phenotype Phenotype frequency is equal to the number of individuals with a particular phenotype divided by the total number of individuals in the population.

The Hardy-Weinberg Genetic Equilibrium Section 1 Genetic Equilibrium Chapter 16 The Hardy-Weinberg Genetic Equilibrium Allele frequencies in the gene pool do not change unless acted upon by certain forces. Hardy-Weinberg genetic equilibrium is a theoretical model of a population in which no evolution occurs and the gene pool of the population is stable.

Section 1 Genetic Equilibrium Chapter 16 Phenotype Frequency

Chapter 16 Objectives Section 2 Disruption of Genetic Equilibrium List five conditions under which evolution may take place. Explain how migration can affect the genetics of populations. Explain how genetic drift can affect populations of different sizes. Contrast the effects of stabilizing selection, directional selection, and disruptive selection on populations over time. Identify examples of nonrandom mating.

Chapter 16 Standards Section 1 Genetic Equilibrium SPI 3210.5.1 Compare and contrast the structural, functional, and behavioral adaptations of animals or plants found in different environments. SPI 3210.5.2 Recognize the relationship between form and function in living things. SPI 3210.5.3 Recognize the relationships among environmental change, genetic variation, natural selection, and the emergence of a new species. SPI 3210.5.4 Describe the relationship between the amount of biodiversity and the ability of a population to adapt to a changing environment. SPI 3210.5.5 Apply evidence from the fossil record, comparative anatomy, amino acid sequences, and DNA structure that support modern classification systems. SPI 3210.5.6 Infer relatedness among different organisms using modern classification systems.

Section 2 Disruption of Genetic Equilibrium Chapter 16 Mutation Evolution may take place when populations are subject to genetic mutations, gene flow, genetic drift, nonrandom mating, or natural selection. Mutations are changes in the DNA.

Section 2 Disruption of Genetic Equilibrium Chapter 16 Gene Flow Emigration and immigration cause gene flow between populations and can thus affect gene frequencies.

Section 2 Disruption of Genetic Equilibrium Chapter 16 Genetic Drift Genetic drift is a change in allele frequencies due to random events. Genetic drift operates most strongly in small populations.

Chapter 16 Nonrandom Mating Section 2 Disruption of Genetic Equilibrium Chapter 16 Nonrandom Mating Mating is nonrandom whenever individuals may choose partners.

Nonrandom Mating, continued Section 2 Disruption of Genetic Equilibrium Chapter 16 Nonrandom Mating, continued Sexual Selection Sexual selection occurs when certain traits increase an individual’s success at mating. Sexual selection explains the development of traits that improve reproductive success but that may harm the individual.

Chapter 16 Natural Selection Section 2 Disruption of Genetic Equilibrium Chapter 16 Natural Selection Natural selection can influence evolution in one of three general patterns.

Natural Selection, continued Section 2 Disruption of Genetic Equilibrium Chapter 16 Natural Selection, continued Stabilizing Selection Stabilizing selection favors the formation of average traits.

Natural Selection, continued Section 2 Disruption of Genetic Equilibrium Chapter 16 Natural Selection, continued Disruptive Selection Disruptive selection favors extreme traits rather than average traits.

Natural Selection, continued Section 2 Disruption of Genetic Equilibrium Chapter 16 Natural Selection, continued Directional Selection Directional selection favors the formation of more-extreme traits.

Chapter 16 Two Kinds of Selection Section 2 Disruption of Genetic Equilibrium Chapter 16 Two Kinds of Selection

Chapter 16 Objectives Section 3 Formation of Species Relate the biological species concept to the modern definition of species. Explain how the isolation of populations can lead to speciation. Compare two kinds of isolation and the pattern of speciation associated with each. Contrast the model of punctuated equilibrium with the model of gradual change.

Chapter 16 Standards Section 1 Genetic Equilibrium SPI 3210.5.1 Compare and contrast the structural, functional, and behavioral adaptations of animals or plants found in different environments. SPI 3210.5.2 Recognize the relationship between form and function in living things. SPI 3210.5.3 Recognize the relationships among environmental change, genetic variation, natural selection, and the emergence of a new species. SPI 3210.5.4 Describe the relationship between the amount of biodiversity and the ability of a population to adapt to a changing environment. SPI 3210.5.5 Apply evidence from the fossil record, comparative anatomy, amino acid sequences, and DNA structure that support modern classification systems. SPI 3210.5.6 Infer relatedness among different organisms using modern classification systems.

Chapter 16 The Concept of Species Section 3 Formation of Species Chapter 16 The Concept of Species According to the biological species concept, a species is a population of organisms that can successfully interbreed but cannot breed with other groups.

Isolation and Speciation Section 3 Formation of Species Chapter 16 Isolation and Speciation Geographic Isolation Geographic isolation results from the separation of population subgroups by geographic barriers.

Click below to watch the Visual Concept. Section 3 Formation of Species Chapter 16 Geographic Isolation Click below to watch the Visual Concept.

Isolation and Speciation, continued Section 3 Formation of Species Chapter 16 Isolation and Speciation, continued Allopatric Speciation Geographic isolation may lead to allopatric speciation.

Isolation and Speciation, continued Section 3 Formation of Species Chapter 16 Isolation and Speciation, continued Reproductive Isolation Reproductive isolation results from the separation of population subgroups by barriers to successful breeding.

Click below to watch the Visual Concept. Section 3 Formation of Species Chapter 16 Reproductive Isolation Click below to watch the Visual Concept.

Isolation and Speciation, continued Section 3 Formation of Species Chapter 16 Isolation and Speciation, continued Sympatric Speciation Reproductive isolation within the same geographic area is known as sympatric speciation.

Chapter 16 Rates of Speciation Section 3 Formation of Species Chapter 16 Rates of Speciation In the gradual model of speciation (gradualism), species undergo small changes at a constant rate. Under punctuated equilibrium, new species arise abruptly, differ greatly from their ancestors, and then change little over long periods.

Chapter 16 Comparing Punctuated Equilibrium and Gradualism Section 3 Formation of Species Chapter 16 Comparing Punctuated Equilibrium and Gradualism