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Chapters 14, 15, and 16 Evolution Evolution The definition of Evolution is: Change over time. Biological Evolution is: Change in allele frequency in population over time Process by which modern organisms have descended from ancient organisms (slow change over long time) • Even relatively quick evolution takes hundreds of thousands of years. Age of the Earth We now know Earth is approximately 4.5 billion years old. Activity Time: Organize the strips of matter chronologically from oldest to most recent. The evolution model includes the scientific evidence and the related inferences suggesting that: I. The universe and the solar system emerged by naturalistic processes. II. Life emerged from nonlife by naturalistic processes. III. All present kinds emerged from simpler earlier kinds, so that single-celled organisms evolved into invertebrates, then vertebrates, then amphibians, then reptiles, then mammals, then primates, including man. IV. Mutation and natural selection have brought about the emergence of present complex kinds from a simple primordial organism. V. Man and apes emerged from a common ancestor. VI. The earth's geologic features were fashioned largely by slow, gradual processes, with infrequent catastrophic events restricted to a local scale (uniformitarianism). VII. The inception of the earth and then of life must have occurred several billion years ago. James Hutton In the late 1700’s, James Hutton (a geologist) proposed that rocks, mountains, and valleys have been changed by water, wind, temperature, volcanoes, and other natural forces. He theorized that Earth was much older than a few thousand years, which didn’t set well in the traditional timeframe of Creationism. Geologists Charles Lyell (early 1800’s) – agreed with Hutton and said that scientists must always explain past events in terms of observable, PRESENT events and processes (uniformitarianism). Darwin used the work of Hutton and Lyell as a basis for his theories of slow change over time. Darwin’s work was a biological duplicate of Hutton and Lyell’s works in geology. Geologists study Earth’s rocks Fossils are preserved remains of ancient organisms Found in Sedimentary rock: layers of sand, silt, and clay in streams, lakes, rivers, and seas form rock that may have trapped living organisms Fossils can be direct evidence (ex. Bones, hair, feathers) or indirect evidence (ex. Molds, footprints) Fossil Hominid Skulls Fossil Evidence Fossil record – Shows change over time. Some timeframes are missing, but will show change of climate and geography. Ex: Shark teeth in Utah • How can this be? Geologists study Earth’s rocks As fossils are found that don’t resemble organisms today, evidence increases that Earth has changed and that organisms have changed with it. Biologists and geologists date Earth’s past with the help of rocks. Geological Time Scale RELATIVE DATING Technique used to determine age of fossils relative to other fossils in different layers of rock. This technique is VERY approximate. Geological Time Scale ABSOLUTE (RADIOACTIVE) DATING Using radioactive elements in rock that decay at a steady rate to determine age. Decay measured in terms of HALF-LIFE. Radioactive Decay During radioactive decay, the atoms of one element break down to form something else. Lose a proton 6 protons 4 neutrons 5 protons 4 neutrons Rocks contain radioactive elements, each having a different half-life. Half-life – time required for half the radioactive atoms in a sample to decay End of half life half of remaining atoms have decayed EXAMPLES: Uranium-238 Lead-206 HL = 4.5 B yrs Potassium-40 Argon-40 HL = 1.3 B yrs Carbon-14 Nitrogen-14 HL = 5770 yrs Scientists often date rocks using Potassium-40. This element decays to form the stable element Argon-40. It has a half life of 1.3 billion years This is used in the oldest rocks on earth. K-40 Formed K-40 Ar-40 Ar-40 1.3 billion 2.6 billion Uranium and Potassium are useful for dating rocks Carbon-14 is useful for dating things that were once alive such as wood, natural fiber, or cloth C-14 is in the atmosphere; living things take it in their cells. After the organism dies, it doesn’t take in any more C-14. We can then compare the amounts of C-14 to N-14, knowing its half-life, to determine the age of the sample PRACTICE 1. 20 g C → 10 g C → 5 g C How long did this take? 2. What happened to the other 15 g of C? 3. 3.9 Billion years have passed and there is only 10 g of Potassium left. What was the original amount before radioactive decay started happening? Jean Baptiste de Lamarck (1744-1829) He also recognized that organisms were adapted to their environments and that they change He relied on three ideas: 1. A desire to change (innate drive for perfection) 2. Use and disuse (Giraffe’s necks and vestigial organs) 3. Inheritance of acquired characteristics Darwin’s Dilemma Set sail around the world in 1831 on HMS Beagle on a 5 year voyage He had prior knowledge of geology (Lyell was a good friend) and agriculture that helped influence the development of his theory Anchored all along the way and took samples from each place Voyage of the Beagle Darwin’s Dilemma He collected and studied beetles from Brazil, birds from Chile, and iguanas, tortoises, and finches from the Galápagos Islands He noticed similarities between mainland (Ecuador) and Galapagos finches Later, he noticed differences in beak size among finches from different islands in the Galapagos Darwin’s Dilemma Thomas Malthus – wrote paper on population growth in Great Britain Population grows exponentially Limiting factors on growth (carrying capacity) • Food • Area • Resources Darwin’s Dilemma Darwin applied Malthus’, Hutton’s, and Lyell’s work to species’ ability to change, and called the mechanism Natural Selection Nat.Sel.: Process by which organisms with favorable variations survive and produce more offspring than less welladapted organisms He was sure Nat.Sel. was true, but he feared public ridicule. So, he kept his ideas to himself Darwin’s Dilemma Alfred Russel Wallace (1823-1913), working independently, came to the same conclusions as Darwin He sent a manuscript to Darwin, basically for proofreading “I never saw a more striking coincidence… so all my originality, whatever it may amount to, will be smashed.” – Charles Darwin Letter to Charles Lyell, June 18, 1858 Darwin quickly abridged and published his work “On the Origin of Species” Evidence in Living Organisms Comparative embryology: These anatomical similarities indicate similar genetics are at work Become more dissimilar as they grow • Cell specialization and differentiation Common ancestor? Ernst Haeckel “fudged” his data • Big no-no; hurt evolutionary theory for a long time Evidence in Living Organisms Evidence in Living Organisms Comparative anatomy: Homologous Structures – structures that are similar in anatomy, but may serve very different functions. • Ex: cat, whale, and human forearm Homologous Structures Flying Swimming Running Grasping Evidence in Living Organisms Comparative Anatomy (cont.): Analogous Structures – structures that serve similar functions, but have evolved independently of each other Not homologous; analogous Not homologous; not analogous Homologous; not analogous Homologous; analogous Evidence in Living Organisms. Comparative Anatomy (cont.): Vestigial organs – organs that have little or no purpose in the organism; may become smaller or even disappear • Ex: Tailbone or appendix in humans • Ex: Tiny leg bones in snakes (boas and pythons) thought to come from 4 legged ancestor Evidence in Living Organisms Comparative biochemistry and molecular biology: All cells have DNA, RNA, ribosomes, the same 20 amino acids and use ATP as an energy carrier. Similarities in chemical compounds such as DNA and RNA Evidence in Living Organisms Cytochrome c is a highly conserved respiratory protein containing 104 amino acids in humans What Homologies tell us… Similarities in structure and chemistry provide powerful evidence that all living things evolved from a common ancestor Darwin Concluded: Living organisms evolved through gradual modifications of earlier forms descent with modification What Similarities tell us… Two types of evolution can account for homologous AND analogous structures Divergent evolution Convergent evolution What Similarities tell us… 1. Divergent evolution – two species evolve from a common ancestor (speciation) They share similarities in anatomy, biochemistry, and embryology due to common ancestry Explains homologous structures What Similarities tell us… 2. Convergent – two species apparently becoming more similar Two species have adapted in similar ways to similar environmental conditions NOT due to common ancestry Explains analogous structures Convergent Evolution Ocotillo from California and allauidi from Madagascar have evolved similar mechanisms for protecting themselves Diversity of Life Fitness: Physical traits and behaviors that enable organisms to survive and reproduce in their environment arises from adaptation. Adaptation allows species to be better suited to their environment and therefore can survive and reproduce. 4 Driving Forces behind Evol. 1. Mutation Any change in the original DNA ONLY source of variation in a population!! 2. Gene Flow Movement of genes either in or out of a population Migration – Immigration and Emigration 4 Driving Forces behind Evol. 3. Genetic Drift Change in the allele frequency in a population by chance alone. • Bottleneck Effect • Founder Effect 4 Driving Forces behind Evol. 3. Genetic Drift Bottleneck Effect: population undergoes a high mortality rate; genetic variation decreases dramatically Ex: Cheetahs Genetic Drift: Bottleneck Effect 4 Driving Forces behind Evol. 3. Genetic Drift Founder Effect: few individuals leave a large population to start their own; gene pool is very limited Ex: polydactyly in PA Amish Genetic Drift: Founder Effect Genetic Drift: Founder Effect 4 Driving Forces behind Evol. 4. Selection Natural – differential success in the reproduction of different phenotypes resulting from the interaction of organisms with their environment • Nature does the selecting 4 Driving Forces behind Evol. 4. Selection (Natural) Resistance – overuse of insecticides and antibiotics have bred resistant species of bugs and germs 4 Driving Forces behind Evol. 4. Selection Artificial – breeding of domesticated plants and animals • Humans intentionally do the selecting • Cabbage, cauliflower, Brussels sprouts, kale, kohlrabi and broccoli have a common ancestor in one species of wild mustard 4 Driving Forces behind Evol. Problems with artificial selection – not enough genetic variation 4 Driving Forces behind Evol. 4. Selection (Sexual) Intrasexual selection – selection within the same sex (competition, usually between males Competition, usually between males Exaggerated anatomy Bighorn Sheep Rocky Mountain Elk Five-horned Rhinoceros Beetles Stagbeetles 4 Driving Forces behind Evol. 4. Selection (Sexual) Intersexual selection – one sex selects mate based on phenotypes Exaggerated anatomy Evolutionary Time Scales Evolution can take a long time or can occur relatively quickly Gradualism Punctuated Equilibrium Evolutionary Time Scales Gradualism – big evolutionary changes are the result of many small ones over a long period of time Evolutionary Time Scales Punctuated Equilibrium – speciation occurs fairly rapidly then remain constant Selection can influence populations in three major ways: Directional Sel. Stabilizing Sel. Disruptive (diversifying) Sel. Directional Selection Environment selects against one phenotypic extreme, allowing the other to become more prevalent Disruptive Selection Environment selects against intermediate phenotype, allowing both extremes to become more prevalent Stabilizing Selection Environment selects against two extreme phenotypes, allowing the intermediates to become more prevalent Key Points 1. Natural selection does not cause genetic changes in individuals. 2. Natural selection acts on individuals; evolution occurs in populations. 3. Evolution is a change in the allele frequencies of a population, owing to unequal success at reproduction among organisms bearing different alleles. 4. Evolutionary changes are not “good” nor “progressive” in any absolute sense. Evolutionary Theory Foundation on which the rest of the biological science is built. Collection of carefully reasoned and tested hypotheses about how evolutionary change occurs.