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Chapter 13 How Populations Evolve Clown, Fool, or Simply Well Adapted? • The blue-footed booby has many specialized characteristics that are very functional in water but less useful on land • Such evolutionary adaptations are inherited traits that enhance an organism's ability to survive and reproduce in its particular environment • Evolution is the changes in organisms over time DARWIN'S THEORY OF EVOLUTION 13.1 A sea voyage helped Darwin frame his theory of evolution • Pre-Darwinian ideas about the origin of species – Early Greek philosophers: Simpler life forms preceded more complex ones – Aristotle: Species are fixed and do not evolve; had a great impact on Western thinking – Judeo-Christian biblical view: All species were individually designed by a divine creator • In the century prior to Darwin, only a few scientists questioned the belief that species are fixed – Buffon: The study of fossils suggested that Earth is older than 6,000 years, and fossil forms might be early versions of modern forms – Lamarck: Fossils are related to modern forms because life evolves; acquired characteristics are inherited • Charles Darwin made a round-the-world sea voyage as a naturalist on HMS Beagle in the 1830s – Darwin observed similarities between living and fossil organisms and the diversity of life on the Galápagos Islands – Darwin's experiences during the voyage helped him frame his ideas about evolution – Lyell's Principles of Geology led him to realize that still-operating natural forces gradually change Earth • After his return, Darwin began to document his observations and his new theory of evolution – Alfred Wallace conceived a theory almost identical to Darwin's; both works were presented to the scientific community – Darwin's On the Origin of Species by Means of Natural Selection was published in 1859 • "Descent with modification" summarizes Darwin's view of life – All organisms are related through descent from a remote common ancestor – Descendants spread into diverse habitats over millions of years and acquired adaptations to their environments – The history of life resembles a tree with multiple branchings from a common trunk – Species that are closely related share characteristics 13.2 Darwin proposed natural selection as the mechanism of evolution • The essence of Darwin's theory of natural selection is differential success in reproduction – Organisms produce more offspring than the environment can support – Organisms vary in many characteristics that can be inherited – Excessive numbers of organisms lead to a struggle for survival – Individuals whose characteristics are best adapted to their environment are more likely to survive and reproduce – The unequal ability of individuals to survive and reproduce leads to a gradual change in the characteristics of a population over generations • Natural selection is supported by evidence from artificial selection 13.3 The study of fossils provides strong evidence for evolution • Fossils are the hard parts of organisms that remain after organic materials decay – Rarely, an entire organism is fossilized • The fossil record strongly supports the theory of evolution – Changes in sea level and drying and refilling of lakes over time result in rock strata that trap organisms – Fossils appear in an ordered array within layers of sedimentary rocks – The fossil record reveals that organisms have evolved in a historical sequence • Many fossils link early extinct species with species living today Video: Grand Canyon 13.4 A mass of other evidence reinforces the evolutionary view of life • Biogeography – The geographic distribution of species suggested to Darwin that organisms evolve from common ancestors – Isolated organisms resemble each other more than organisms in similar but distant places • Comparative anatomy – Homologous structures are features that often have different functions but are structurally similar because of common ancestry – Vestigial structures are remnants of structures that served important functions in an organism's ancestors LE 13-4a Human Cat Whale Bat • Comparative embryology – Common embryonic structures in all vertebrates are evidence for common descent • Molecular biology – Comparisons of DNA and amino acid sequences between different organisms reveal evolutionary relationships – Molecular biology provides strong evidence that all life forms are related CONNECTION 13.5 Scientists can observe natural selection in action • Examples of evolutionary adaptation observed over a short time – Different camouflage adaptations in different environments – Development of pesticide resistance in insects Video: Seahorse Camouflage LE 13-5b Chromosome with gene conferring resistance to pesticide Additional applications of the same pesticide will be less effective, and the frequency of resistant insects in the population will grow Pesticide application Survivor • Examples of evolutionary adaptation reveal three key points about natural selection – Natural selection is more of an editing process than a creative mechanism – Natural selection is contingent on time and place – Significant evolutionary change can occur in a short time POPULATION GENETICS AND THE MODERN SYNTHESIS • 13.6 Populations are the units of evolution – Population • A group of individuals of the same species living in the same place at the same time • May be isolated from other groups or concentrated • The smallest unit that can evolve Copyright © 2005 Pearson Education, Inc. publishing as Benjamin Cummings • Population genetics – Combines Darwin's and Mendel's ideas in studying how populations change genetically over time – The modern synthesis • Connects population genetics with other sciences • Focuses on population as the unit of evolution and central role of natural selection • Studying evolution at the population level – Evolution: change in the prevalence of certain heritable characteristics in a population over a span of generations – Gene pool: the total collection of genes in a population at any one time – Microevolution: a change in the relative frequencies of alleles in a gene pool – Species: a group of populations capable of interbreeding and producing fertile offspring 13.7 The gene pool of a nonevolving population remains constant over the generations • In a nonevolving population, the shuffling of alleles that accompanies sexual reproduction does not alter the genetic makeup of the population • In Hardy-Weinberg equilibrium, the frequency of each allele in the gene pool will remain constant unless acted upon by other agents • For a population to be in Hardy-Weinberg equilibrium, it must satisfy five main conditions – The population is very large – The population is isolated – Mutations do not alter the gene pool – Mating is random – All individuals are equal in reproductive success • The Hardy-Weinberg conditions are rarely met in nature – We can follow alleles in a population to observe if Hardy-Weinberg equilibrium exists – Hardy-Weinberg equilibrium provides a basis for understanding how populations evolve LE 13-7a Webbing No webbing LE 13-7b Phenotypes Genotypes WW Ww ww Number of animals (total = 500) 320 160 20 Genotype frequencies 320 500 160 500 = 0.64 Number of alleles in gene pool (total = 1,000) 640 W Allele frequencies 800 1,000 = 0.32 160 W + 160 w = 0.8 W 200 1,000 20 500 40 w = 0.2 w = 0.04 LE 13-7c Recombination of alleles from parent generation Sperm W sperm p = 0.8 w sperm q = 0.2 WW = 0.64 Ww pq = 0.16 p2 W egg p = 0.8 Eggs w egg q = 0.2 wW qp = 0.16 q2 ww = 0.04 Next generation: Genotype frequencies Allele frequencies 0.64 WW 0.8 W 0.32 Ww 0.04 ww 0.2 w CONNECTION 13.8 The Hardy-Weinberg equation is useful in public health science • Public health scientists use the HardyWeinberg equation to estimate frequencies of disease-causing alleles in the human population – Example: phenylketonuria (PKU) 13.9 In addition to natural selection, genetic drift and gene flow can contribute to evolution • Genetic drift: change in the gene pool of a population due to chance – Can alter allele frequencies in a population – The smaller the population, the greater the impact • Bottleneck effect: an event that drastically reduces population size • Founder effect: colonization of a new location by a small number of individuals • Gene flow: the movement of individuals or gametes between populations – Can alter allele frequencies in a population – Tends to reduce differences between populations • Natural selection – Best-adapted individuals have the most reproductive success – Results in accumulation of traits that adapt a population to its environment MECHANISMS OF CHANGE MUTATIONS GENE FLOW (MIGRATION) GENETIC DRIFT NATURAL SELECTION CONNECTION 13.10 Endangered species often have reduced variation • Loss of genetic variability due to bottlenecking may reduce a population's ability to adapt to environmental change – Particularly threatening to endangered species such as the cheetah VARIATION AND NATURAL SELECTION 13.11 Variation is extensive in most populations • Individual variation exists in all sexually reproducing populations • Heritable variation results from a combination of genotype and environmental influences – Polymorphism: two or more forms of phenotypic characteristics – Geographic variation: variation of an inherited characteristic from place to place • May occur along a geographic continuum (a cline) 13.12 Mutation and sexual recombination generate variation • Mutations-changes in the nucleotide sequence of DNA-can create new alleles – Only mutations in cells that produce gametes can affect a population's gene pool – A mutation may rarely improve adaptation to the environment and thus contribute to evolution • Sexual recombination generates variation by shuffling alleles during meiosis LE 13-12a A1 Parents A2 A1 A3 Meiosis A1 Gametes A2 A3 LE 13-12b A1 A2 A3 Gametes Fertilization Offspring, with new combinations of alleles A1 A1 A2 and A3 CONNECTION 13.13 The evolution of antibiotic resistance in bacteria is a serious public health concern • Natural selection has led to the evolution of antibiotic-resistant bacteria • Overuse and misuse of antibiotics has contributed to the proliferation of antibioticresistant strains – Example: tuberculosis 13.14 Diploidy and balancing selection preserve variation • Diploidy (two sets of chromosomes) helps to prevent populations from becoming genetically uniform – Recessive alleles are "hidden" from natural selection and remain in the population • Balancing selection allows two or more phenotypic forms in a population – Balanced polymorphism may result from • Heterozygote advantage; example: sickle-cell disease • Frequency-dependent selection • Neutral variation provides no apparent advantage or disadvantage – Example: fingerprints 13.15 The perpetuation of genes defines evolutionary fitness • Evolutionary fitness is the relative contribution an individual makes to the gene pool of the next generation • Survival of genes depends on production of fertile offspring • Selection indirectly adapts a population to its environment by acting on phenotype 13.16 Natural selection can alter variation in a population in three ways • Stabilizing selection: favors intermediate phenotypes • Directional selection: acts against individuals at one of the phenotypic extremes • Disruptive selection: favors individuals at both extremes of the phenotypic range Frequency of individuals LE 13-16 Original population Phenotypes (fur color) Original population Evolved population Stabilizing selection Directional selection Disruptive selection 13.17 Sexual selection may produce sexual dimorphism • Sexual dimorphism – The distinction in appearance between males and females of a species • Sexual selection – The determining of "who mates with whom" – Leads to the evolution of secondary sexual characteristics that may give individuals an advantage in mating 13.18 Natural selection cannot fashion perfect organisms • There are at least four reasons why natural selection cannot produce perfection – Organisms are limited by historical constraints – Adaptations are often compromises – Chance and natural selection interact – Selection can only edit existing variations