Tracing Evolutionary History Chapter 15 Tracing Evolutionary History
Day 1: Do Now: 295, HW Define words from 15. 1-15. 6, Notes 15. 7-15 Day 1: Do Now: 295, HW Define words from 15.1-15.6, Notes 15.7-15.10, Video on Early Earth Formation (united streaming) Day 2: Do Now: 15.6 Explain how bird feathers are a exaptation, Notes: 15.11-15.14, Simple classification lab Day 3: Caminalcules Lab Day 4 and 5: Biodiversity Lab Day 6 Test on chapter 14-15.
Do Now: Read pg 294-295 Green Book What evidence did experts use to conclude that birds were dinosaurs with feathers? What piece of evidence was found recently that disagrees with this hypothesis? HW: Read 296-302 and define the following words Macroevolution, Geologic time scale, Radiometric dating, continental drift, Pangea, plate techtonics, exaptation
Are Birds Really Dinosaurs with Feathers? For decades, evolutionary biologists debated whether birds evolved from dinosaurs Fossil Archaeopteryx supported this view Conflicting view posited birds evolving from a very different reptile group Bird-dinosaur link was supported by cladistics and corroborated in the 1990s by fossil evidence Debate continues on how birds learned to fly
MACROEVOLUTION AND EARTH'S HISTORY 15.1 The fossil record chronicles macroevolution Macroevolution is the main event in the evolutionary history of life on Earth Documented in the fossil record The geologic record is based on the sequence of fossils Earth's history divided into three eons Within the most recent eon, eras and periods marked by mass or lesser extinctions
Animation: The Geologic Record Some major events in the history of life Precambrian period: oldest known fossils- prokaryotes from 3.5 billion years ago Paleozoic era: lineages that gave rise to modern life forms Mesozoic era: age of reptiles, including dinosaurs Cenozoic era: Explosive evolution of mammals, birds, and flowering plants Animation: The Geologic Record
15.2 The actual ages of rocks and fossils mark geologic time Radiometric dating can gauge the actual ages of fossils and the rocks in which they are found Based on the decay time of radioactive isotopes relative to other isotopes Carbon-14 for relatively young fossils Isotopes with longer half-lives for older fossils
15.3 Continental drift has played a major role in macroevolution Continental drift is the slow, incessant movement of Earth's crustal plates on the hot mantle World geography changes constantly
LE 15-03a Eurasian Plate North American Plate Arabian Plate Indian Pacific Plate African Plate Split developing South American Plate Nazca Plate Australian Plate Antarctic Plate Edge of one plate being pushed over edge of neighboring plate (zones of violent geologic events)
Continental movements have greatly influenced the distribution of organisms around the world Formation of Pangaea 250 million years ago altered habitats and triggered extinctions Breakup of Pangea beginning 180 million years ago created a number of separate evolutionary arenas Explains the geographical distribution of diverse life forms Examples: marsupials, lungfishes
LE 15-03b 65 135 251 Cenozoic Millions of years ago Mesozoic Paleozoic Cenozoic North America Eurasia 65 Africa South America India Australia Antarctica Laurasia 135 Millions of years ago Mesozoic Gondwana 251 Pangaea Paleozoic
LE 15-03d North America Asia Europe Africa South America Australia = Living lungfishes = Fossilized lungfishes
Video: Galápagos Islands Overview CONNECTION 15.4 Tectonic trauma imperils local life Plate tectonics are the forces involved in movements of Earth's crustal plates The geologic processes that result include volcanoes and earthquakes Can create devastation or opportunities for organisms The boundaries of plates are hot spots of such geologic activity Video: Galápagos Islands Overview
LE 15-04a San Andreas Fault North American Plate San Francisco Santa Cruz Pacific Plate Los Angeles California
15.5 Mass extinctions were followed by diversification of life-forms Extinctions occur all the time, but extinction rates have not been steady Over the last 600 million years, at least six periods of mass extinctions have occurred, including Permian extinction (250 million years ago); claimed 96% of aquatic life Cretaceous extinction (65 million years ago); eliminated dinosaurs
Cause of mass extinctions is unclear Permian extinction occurred at a time of enormous volcanic explosions Cretaceous extinction may have been caused by an asteroid Mass extinctions have been followed by an explosive increase in diversity Provide surviving organisms with new environmental opportunities Example: rise of mammals after extinction of dinosaurs
LE 15-05 North America Chicxulub crater Yucatan Peninsula Yucatan ¢ Yucatan Peninsula ¢
15.6 Key adaptations may enable species to proliferate after mass extinctions Exaptation is a structure that evolved in one context and later was adapted for another function Example: birds had feathers and light bones before the benefit of flight
15.7 Genes that control development are important in evolution "Evo-devo" combines evolutionary and developmental biology Studies how slight genetic changes can be magnified into significant phenotypic changes Many striking evolutionary transformations are the result of a change in the rate or timing of developmental changes Paedamorphosis: retention in adult of features that were juvenile in its ancestors
LE 14-12b Chimpanzee fetus Chimpanzee adult Human fetus Human adult
Important in human evolution Large skull and long childhood provide humans with more space for brain and more opportunity to learn from adults Juvenile physical traits may make adults more caring and protective Example: "evolution" of Mickey Mouse
15.8 Evolutionary trends do not mean that evolution is goal directed Evolutionary trends reflect the unequal speciation or unequal survival of species on a branching evolutionary tree Example: lineages of horses that died out Evolutionary trends do not imply an intrinsic drive toward a goal If environmental conditions change, an apparent trend may cease or reverse
Hippidion and other genera LE 14-13 RECENT Equus Hippidion and other genera PLEISTOCENE Nannippus Pliohippus Hipparion Neohipparion PLIOCENE Sinohippus Megahippus Callippus Archaeohippus Merychippus MIOCENE Anchitherium Hypohippus Parahippus Miohippus OLIGOCENE Mesohippus Paleotherium Epihippus Propalaeotherium Pachynolophus Orohippus EOCENE Grazers Hyracotherium Browsers
15.9 Phylogenetic trees strive to represent evolutionary history - Easy with living organisms, hard with extinct - Still a hypothesis
15.10 Systematists classify organisms by phylogeny A phylogenetic tree is a hypothetical hierarchy of evolutionary relationships A binomial gives each species a two-part name Genus (a group of related species) Species within the genus Genera are grouped into progressively more inclusive categories (taxa) Family, order, class, phylum, kingdom, domain
LE 15-07a Felis catus Species Felis Genus Felidae Family Carnivora Order Mammalia Class Chordata Phylum Animalia Kingdom Eukarya Domain
LE 15-07b Genus Felis Mephitis Lutra Canis Family Felidae Mustelidae catus Mephitis mephitis Lutra lutra Canis familiaris Canis lupus Species (domestic cat) (striped skunk) (European otter) (domestic dog) (wolf) Genus Felis Mephitis Lutra Canis Family Felidae Mustelidae Canidae Order Carnivora
PHYLOGENY AND SYSTEMATICS 15.11 Homology indicates common ancestry, but analogy does not Phylogeny Traced partly from the fossil record Inferred from morphological and molecular homologies among living organisms Not all likenesses are inherited from a common ancestor Analogy: similarity due to convergent evolution Species from different branches resemble each other if they live in similar environments
15.12 Molecular biology is a powerful tool in systematics Molecular systematics uses DNA and RNA to compare relatedness The closer the nucleic acid sequences between two organisms, the more likely they are to share a common ancestor Humans are more closely related to fungi than to plants
LE 15-09a Polar bear Asiatic black bear American black bear Sun bear Sloth bear Spectacled bear Giant panda Lesser panda Brown bear Raccoon Pleistocene Pliocene 10 Miocene 15 20 Millions of years ago Ursidae 25 30 Procyonidae Oligocene 35 Common ancestral carnivorans 40
Types and indications Proteins that change more rapidly are useful among closely related species DNA (more direct) Mt DNA changes faster, better for closely related organisms rRNA changes slowly, relationships in early branches Some sections of DNA changes at a constant rate Changes are proportional to time Genes can be used to calculate a molecular clock
LE 15-09c Human Chimpanzee Gorilla Orangutan Common ancestor
15.13 Cladograms are diagrams based on shared characters among species Cladistics is concerned with the order of branching in phylogenetic lineages Each branch (clade) on a cladogram represents an ancestral species and all its descendants Each clade consists of taxa that are monophyletic (from a "single tribe")
All the taxa on a clade share one or more homologous features Shared derived characters: New traits unique to each lineage Shared primitive characters: Traits present in the ancestral groups Comparison of ingroup and outgroup is important Ingroup: Group of taxa being analyzed Outgroup: Closely related to the ingroup but not a member of it
Parsimony seeks the simplest explanation of observed data The simplest hypothesis of relationships creates the most likely phylogenetic tree
LE 15-08b Lizards Snakes Crocodiles Birds Common reptilian ancestor
15.14 Arranging life into kingdoms is a work in progress Five-kingdom system (now six) All prokaryotes are in kingdom Monera (Now two Archeabacteria and Eubacteria) Eukaryotes are grouped into four kingdoms: Protista, Plantae, Fungi, Animalia Molecular studies have found flaws in this system
Animation: Classification Schemes The domain system Prokaryotes are in two domains: Bacteria and Archaea All eukaryotes are in domain Eukarya All classification systems are human constructions, not facts of nature Will always be refined by new data Animation: Classification Schemes
Three Domains (Superkingdoms) Of Living Organisms I Three Domains (Superkingdoms) Of Living Organisms I. Bacteria (19): Most of the Known Prokaryotes Kingdom (s): Not Available at This Time Division (Phylum) Proteobacteria: N-Fixing Bacteria Division (Phylum) Cyanobacteria: Blue-Green Bacteria Division (Phylum) Eubacteria: True Gram Posive Bacteria Division (Phylum) Spirochetes: Spiral Bacteria Division (Phylum) Chlamydiae: Intracellular Parasites II. Archaea (16): Prokaryotes of Extreme Environments Kingdom Crenarchaeota: Thermophiles Kingdom Euryarchaeota: Methanogens & Halophiles Kingdom Korarchaeota: Some Hot Springs Microbes III. Eukarya (35): Eukaryotic Cells Kingdom Protista (Protoctista) Kingdom Fungi Kingdom Plantae Kingdom Animalia
Monera Protista Plantae Fungi Animalia Earliest organisms Prokaryotes LE 15-10a Monera Protista Plantae Fungi Animalia Earliest organisms Prokaryotes Eukaryotes
LE 15-un311-1 Lizards Birds Mammals