Transcript Chapter-24
Animals II– The Chordates Chapter 24 Biology Concepts and Applications, Eight Edition, by Starr, Evers, Starr. Brooks/Cole, Cengage Learning 2011. 24.1 Windows on the Past Archaeopteryx Fossil Size of a large crow, long, bony tail, three clawed fingers on each forelimb, and a heavy jaw with short, spiky teeth, and feathers. Radiometric dating indicates that the fossil lived 150 million years ago. Most widely known transitional fossil in the bird lineage Fossils of China Sinosauropteryx prima • Found in 1994 – China • Flightless bird that used the feathers to stay warm Confuciusornis sanctus • 1st bird with a beak • Wings had digits with claws at their tips Evolutionary Biology Fossils are physical evidence of changes and radiometric dating assigns the fossils to places in time Structure, biochemistry, and genetic makeup provide information about branching 24.2 Chordate Heritage Four features define chordates • • • • A notochord A dorsal hollow nerve cord A pharynx with gill slits A tail extending past the anus All features form in embryos • May or may not persist in adults Invertebrate Chordates Tunicates and lancelets (marine filter-feeders) • Tunicate invertebrate chordate that loses its defining chordate traits during the transition into adulthood • Lancelet invertebrate chordate that has a fishlike shape and retains the defining chordate traits into adulthood Tunicate Body Plans Adult and larva Lancelet Body Plan Craniates Chordates with a braincase of cartilage or bone • Hagfish (jawless fish): Simplest modern craniate tentacles gill slits (twelve pairs) mucous glands Fig. 24.5, p.387 Chordate Family Tree 1. Braincase Develops Craniates 2. Backbone Develops Vertebrates - Endoskeleton: internal skeleton made up of hardened components such as bones 3. Jaw Develops 4. Swim bladder or lungs Develop 5. Bony Appendages Develop 6. Four limbs develop Tetrapods 7. Amniote eggs develop Amniotes - Amniote: vertebrate in which the embryo develops surrounded by fluid by membranes inside the egg Key Concepts: CHARACTERISTICS OF CHORDATES A unique set of four traits characterizes chordates: a supporting rod (notochord), a dorsal nerve cord, a pharynx with gill slits in the wall, and a tail extending past an anus Certain invertebrates and all vertebrates belong to this group Vertebrate Evolution Key innovations laid the foundation for adaptive radiations of vertebrates • Vertebral column of cartilaginous or bony segments • Jaws evolved in predatory fishes • Gills evolved in water, then lungs for dry land • Paired fins were a starting point for other limbs 24.3 The Fishes Early Body Forms – Lamprey Vertebrate Hagfish Jawless fish with a skull case but no backbone Lamprey Jawless fish with a backbone of cartilage Gill-Supporting Structures and the Evolution of the Jaw Fig. 24.7, p.388 Fig. 24.7, p.388 Fig. 24.7, p.388 Major Vertebrate Groups Key Concepts: TRENDS AMONG VERTEBRATES In some vertebrate lineages, a backbone replaced the notochord as the partner of muscles used in motion Jaws evolved, sparking the evolution of novel sensory organs and brain expansions Key Concepts: TRENDS AMONG VERTEBRATES (cont.) On land, lungs replaced gills, and more efficient blood circulation enhanced gas exchange Fleshy fins with skeletal supports evolved into limbs, now typical of vertebrates on land Jawed Fishes and Tetrapods Jawed fishes • Cartilaginous fishes (sharks and rays) • Skeleton of cartilage • Bony fishes • Lungs or swim bladder and a skeleton of bone Body plans adapted to life in water • Streamlined shape reduces drag • Swim bladder (in bony fishes) adjusts buoyancy Cartilaginous Fishes Bony Fishes The most diverse vertebrates • Lungfishes • Lobe-finned fishes (coelacanth) • Fleshy fins that contain bones • Ray-finned fishes • Fins supported by thin rays derived from skin Body Plan: Ray-Finned Bony Fishes 24.4 Amphibians – The First Tetrapods Late in the Devonian, lobe-finned bony fishes gave rise to tetrapods (four-legged vertebrates) Early Lineages Coelacanth, lungfish, and Devonian tetrapod Amphibians Amphibians • Tetrapod with a three-chambered heart and scaleless skin • Typically develops in water then lives on land as a carnivore with lungs Frogs, toads, and salamanders • Carnivorous vertebrates • First to evolve from aquatic Devonian tetrapods • Adapted to life on land (lungs, 3-chambered heart) • Nearly all return to the water to reproduce Amphibian Evolution Vanishing Amphibians Many amphibians now face extinction due to pollution and habitat loss Frog deformity due to infection from fluke Key Concepts: TRANSITION FROM WATER TO LAND Vertebrates first evolved in the seas, where lineages of cartilaginous and bony fishes persist Of all vertebrates, modern bony fishes show the most diversity Mutations in master genes that control body plans were pivotal in the rise of aquatic tetrapods and their move onto dry land 24.5 Amniotes First vertebrates able to complete their life cycle on dry land • Water-conserving skin and kidneys • Amniote eggs (four membranes) • Allow amniote embryo to develop away from water • Active life-styles Reptiles • Amniote subgroup that includes lizards, snakes, turtles, crocodilians, and birds Amniote Eggs Amniote Family Tree 24.6 Nonbird Reptiles Major Groups • • • • • Turtles (shell attached to skeleton) Lizards (the most diverse reptiles) Snakes (limbless) Tuataras (some amphibian-like traits; third eye) Crocodilians (closest relatives of birds) 24.6 Nonbird Reptiles Ectotherm “heated from outside” • Control its internal temperature by altering its behavior – sitting on a warm rock • “cold-blooded” animals • Fish and amphibians Endotherms “heated from within” • Control its internal temperature by adjusting it metabolism • Birds and mammals Reptile Characteristics General characteristics • Live on land or in water • Cold-blooded • Have a cloaca (opening for wastes and reproduction) • Eggs are fertilized in the body, usually laid on land Turtle Bony shell attached to their skeleton When threatened, withdraw into shell Lived in the sea about 200 million years ago No Teeth – horny beak over their jaw Crocodilian Closest living relative of birds, four chamber heart. Jaw, snout, and sharp teeth Can weigh up to 2,200 lbs hindbrain, midbrain, forebrain olfactory lobe (sense of smell) spinal vertebral column cord gonad kidney (control of water, solute levels in internal environment) snout unmatched rows of teeth on upper and lower jaws esophagus lung heart liver stomach intestine cloaca Fig. 24.16, p.396 24.7 Birds – Reptiles with Feathers Birds are warm-blooded amniotes Only living animals with feathers • • • • • Light weight Derived from scales Insulates Allows for flight Displays courtship Adaptations for Flight and Migration Feathers, lightweight bones, and highly efficient respiratory and circulatory systems Bird Skeleton and Flight Muscles skull internal structure of bird limb bones radius ulna pectoral girdle humerus pelvic girdle Sternum (breastbone) two main flight muscles attached to keel of sternum Stepped Art Fig. 24.21, p.399 24.8 Mammals Animals with hair or fur Females that nourish young with milk from mammary glands a single lower jawbone and four kinds of teeth incisors molars premolars canines Fig. 24.22, p.400 Modern Mammals Three major lineages • Egg-laying mammals (monotremes) • Pouched mammals (marsupials) • Placental mammals (eutherians), the most diverse and widespread mammals Three Major Lineages Placental Mammals placenta uterus embryo Fig. 24.25, p.401 Key Concepts: THE AMNIOTES As a group, the amniotes—known informally as the reptiles, birds, and mammals—are vertebrate lineages that radiated into nearly all habitats on land 24.9 Primates Include prosimians (lemurs and tarsiers), anthropoids (such as monkeys and apes), and hominids (humans and extinct humanlike forms) Primates Primate Evolution Key trends • • • • • • Better daytime vision Upright walking (bipedalism) More refined hand movements Smaller teeth Bigger brains Social complexity (extended parental care; culture evolved in some lineages) • Grasping hands with nails The Foramen Magnum Four-legged walkers versus upright walkers Origins and Early Divergences Early primates were shrewlike Tree Shrew 24.10 Emergence of Early Humans Hominoids and hominids originated in Africa Australopiths: Upright Walking Early Humans Humans (Homo) arose 2 million years ago • H. habilis was an early toolmaking species • H. erectus dispersed into Europe and Asia 24.11 Emergence of Modern Humans Extinct Neandertals and modern humans are close relatives with distinct gene pools Modern H. sapiens evolved 195,000 years ago Multiregional Model H. erectus populations in many regions slowly evolve into H. sapiens Replacement Model (African Emergence) Modern humans evolved from H. erectus in Africa, then dispersed and replaced H. erectus populations, driving them to extinction Multiregional model Replacement model Fig. 24.34, p.406 African Emergence Most data support the African emergence model • Regional variations among human groups evolved very recently • Influenced by longterm shifts in climate Dispersal of Homo sapiens Based on fossils and studies of genetic markers Key Concepts: EARLY HUMANS AND THEIR ANCESTORS Primates that were ancestral to the human lineage became physically and behaviorally adapted to changes in global climate and available resources Behavioral and cultural flexibility helped humans disperse from Africa throughout the world Animation: Amniote egg Animation: Avian bone and muscle structure Animation: Bony fish body plan Animation: Cartilaginous fishes Animation: Crocodile body plan Animation: Evolution of jaws Animation: Evolution of limb bones Animation: Feather development Animation: Fossils of australopiths Animation: Homo skulls Animation: Jawless fishes Animation: Lancelet body plan Animation: Mammalian radiations Animation: Primate skeletons Animation: Structure of the placenta Animation: Tortoise shell and skeleton Animation: Tunicate body plan Animation: Vertebrate evolution