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Chordate Evolution and Diversity

Explore the origins, diversity, and evolution of chordates, including the ancient ancestors and modern groups such as fishes, amphibians, reptiles, birds, and mammals. Learn about the important features and adaptations that have shaped the evolution of chordates over time.

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Chordate Evolution and Diversity

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  1. Lesson Overview 26.2 Chordate Evolution and Diversity

  2. THINK ABOUT IT • At first glance, fishes, amphibians, reptiles, birds, and mammals appear to be very different. Yet, all are members of the phylum in which we ourselves are classified—phylum Chordata.

  3. Origins of the Chordates • What are the most ancient chordates?

  4. Origins of the Chordates • What are the most ancient chordates? • Embryological studies suggest that the most ancient chordates were related to the ancestors of echinoderms.

  5. The Earliest Chordates • The Cambrian fossil deposits include some early chordate fossils, such as Pikaia, which is shown in the figure. • Scientists first thought it was a worm but then determined that it had a notochord and paired muscles arranged in a series, like those of simple modern chordates.

  6. The Earliest Chordates • In 1999, fossil beds from later in the Cambrian Period yielded specimens of Myllokunmingia, the earliest known vertebrate. • These fossils show muscles arranged in a series, traces of fins, sets of feathery gills, a head with paired sense organs, and a skull and skeletal structures likely made of cartilage. • 1.Cartilage is a strong connective tissue that is softer and more flexible than bone. It supports all or part of a vertebrate’s body.

  7. Myllokunmingia

  8. Modern Chordate Diversity • 2. Modern chordates consist of six groups: the nonvertebrate chordates and the five groups of vertebrates—fishes, amphibians, reptiles, birds, and mammals.

  9. Modern Chordate Diversity • 3 About 96 percent of all modern chordate species are vertebrates, with fishes making up the largest group. • Today’s chordate species are only a small fraction of the total number of chordates that have existed over time.

  10. Cladogram of Chordates • What can we learn by studying the cladogram of chordates?

  11. Cladogram of Chordates • What can we learn by studying the cladogram of chordates? • The cladogram of chordates presents current hypotheses about relationships among chordate groups. It also shows at which points important vertebrate features, such as jaws and limbs, evolved.

  12. Cladogram of Chordates • The cladogram of chordates presents current hypotheses about the evolutionary relationships among chordate groups.

  13. Cladogram of Chordates • 4. The appearance of certain adaptive features, such as jaws and limbs, during chordate evolutionlead to major adaptive radiations

  14. Nonvertebrate Chordates • Fossil evidence suggests that the ancestors of living nonvertebrate chordates diverged from the ancestors of vertebrates more than 550 million years ago. • Two chordate groups lack backbones: tunicates and lancelets.

  15. Nonvertebrate Chordates • 5. Adult turnicates (subphylum Urochordata) look more like sponges than us. They have neither a notochord nor a tail. But their larval forms have all the key chordate characteristics. • For example, the small, fishlike lancelets (subphylum Cephalochordata) live on the sandy ocean bottom.

  16. turnicates

  17. Jawless Fishes • The 6. earliest fishes appeared in the fossil record about 510 million years ago. They had no true jaws or teeth, and their skeletons were made of cartilage. • Some armored jawless fishes, such as those shown in the figure, became extinct about 360 million years ago.

  18. Jawless Fishes • Two other ancient clades of jawless fishes gave rise to the 7. two clades of modern jawless fishes: lampreys and hagfishes exist, both lack vertebrae and have notochords as adults. .

  19. Jawless Fishes • Lampreys are filter feeders as larvae and parasites as adults. • Hagfishes have pinkish gray, wormlike bodies, secrete incredible amounts of slime, and tie themselves into knots!

  20. LAMPREY

  21. Sharks and Their Relatives • Other 8. ancient fishes evolved a revolutionary feeding adaptation: jaws. • Jaws make it possible to bite and chew plants and other animals. • Dunkleosteus, an ancient fish, could eat just about anything.

  22. Sharks and Their Relatives • 9. early fish also evolved paired pectoral (anterior) and pelvic (posterior) fins. • Paired fins offered more control of body movement, while tail fins and powerful muscles gave greater thrust.

  23. Sharks and Their Relatives • 10. The evolution of paired fins and tail fins launched the adaptive radiation of the class Chondrichthyes: the sharks, rays, and skates. • The Greek word chondros means “cartilage,” the tissue that makes up the skeletons of these “cartilaginous” fishes.

  24. Bony Fishes • 11. Another group of ancient fishes evolved skeletons made of true bone, launching the radiation of the class Osteichthyes, the bony fishes.

  25. Ray-Finned Fishes • 12. Most living bony fishes belong to a huge group called ray-finned fishes. • Ray-finned fishes are aquatic vertebrates with skeletons of true bone; most have paired fins, scales, and gills. • Most fishes you are familiar with, such as eels, goldfish, and catfish, are ray-finned fishes.

  26. Lobe-Finned Fishes • 13. Lobe-finned fishes are bony fishes that evolved fleshy fins supported by larger, more substantial bones. • The modern fishes that are descendants of ancient lobe-finned fishes include lungfishes and coelacanths.

  27. LUNGFISH

  28. Lobe-Finned Fishes • 14. Another group of ancient lobe-finned fishes evolved into the ancestors of amphibians or four-limbed vertebrates, or tetrapods.

  29. Amphibians • 15. Amphibians are vertebrates that require water for reproduction, breathe with lungs as adults, have moist skin with mucous glands, and lack scales and claws.

  30. The Unique “Fishapod” • Fossils indicate that various lines of lobe-finned fishes evolved sturdier appendages, which resembled the limbs of tetrapods. • A series of transitional fossils have been discovered that document the skeletal transformation from lobe-fins to limbs, as shown on the following slides.

  31. The Unique “Fishapod”

  32. The Unique “Fishapod” • Eusthenopteron was an early bony fish that used its muscular front fins for steering more than for swimming. • Panderichthys was a fish with sturdier, more mobile, and proportionately larger front fins than earlier fishes had. • Tiktaalik was not quite a fish and not quite a tetrapod. It had stout, stubby front fins with flexible wrists that likely enabled it to prop itself up on land, but it had no digits. It had gills and lungs.

  33. The Unique “Fishapod” • Acanthostega had digits on its front feet but spent most of its time in the water. Though it had gills, it may have used its limbs to prop itself out of oxygen-poor water so it could breathe air with its lungs. • Ichthyostega had sturdy hind feet with several digits. It probably used them more to paddle through the water than to walk on land. • Proterogyrinus was a true tetrapod and agile both in water and on land, similar to today’s alligators.

  34. The Unique “Fishapod” • The Tiktaalik fossilshows both fish and tetrapod features, so its discoverers informally refer to it as a “fishapod”—part fish, part tetrapod.

  35. Terrestrial Adaptations • Early 16. amphibians evolved ways to breathe air and protect themselves from drying out, which fueled another adaptive radiation. • Amphibians became the dominant vertebrates of the Carboniferous Period, but climate changes caused most amphibian groups to become extinct by the end of the Permian Period.

  36. Terrestrial Adaptations • Only three orders of amphibians survive today—frogs and toads, salamanders, and caecilians.

  37. Reptiles • Reptiles were the first vertebrates to evolve adaptations to drier conditions. • A 17. reptile is a vertebrate with dry, scaly skin, well-developed lungs, strong limbs, and shelled eggs that do not develop in water.

  38. Reptiles • Living reptiles are represented by four groups: lizards and snakes, crocodilians, turtles and tortoises, and the tuatara.

  39. Reptiles • As the Carboniferous Period ended and the Permian Period began, Earth’s climate became cooler and less humid, and adaptive radiation of reptiles began. • This cladogram shows current hypotheses about the relationships between living and extinct reptiles.

  40. Enter the Dinosaurs • The 18. Triassic and Jurassic periods saw a great adaptive radiation of reptiles. Dinosaurs lived all over the world, and they were diverse in appearance and in habit. • The evolutionary lineage that led to modern birds came from one group of feathered dinosaurs.

  41. Exit the Dinosaurs • At the end of the Cretaceous Period, a worldwide mass extinction occurred. According to current hypotheses, it was caused by a series of natural disasters: a string of volcanic eruptions, a fall in sea level, and a huge asteroid smashing into what is now the Yucatán Peninsula in Mexico. • After these events, dinosaurs, along with many other animal and plant groups, became extinct both on land and in the sea.

  42. Birds • 19. Birds are reptiles that regulate their internal body temperature (endothermy.) • They have an outer covering of feathers; strong yet lightweight bones; two legs covered with scales that are used for walking or perching; and front limbs modified into wings.

  43. Bird Roots • Recent fossil discoveries support the hypothesis that birds evolved from a group of dinosaurs. • The first birdlike fossil discovered was Archaeopteryx, which shows both bird characteristics (flight feathers) and dinosaur characteristics (teeth and bony tail). • A fossil and an artist’s conception of Archaeopteryx are shown.

  44. Bird Classification • Birds, the traditional class Aves, make up a clade that is part of the clade containing dinosaurs. • Because the clade containing dinosaurs is part of a larger clade of reptiles, modern birds are also reptiles.

  45. Bird Classification • The traditional class Reptilia, which includes living reptiles and dinosaurs but not birds, however, is not a clade.

  46. Mammals • Characteristics unique to 20. mammals have mammary glands in females that produce milk to nourish young, and hair. • Mammals also breathe air, have four-chambered hearts, and regulate their internal body temperature.

  47. The First Mammals • True mammals first appeared during the late Triassic Period. • They were very small and resembled modern tree shrews.

  48. The First Mammals • While dinosaurs ruled, mammals remained generally small and were probably active mostly at night. • New fossils and DNA analyses suggest that the first members of modern mammalian groups, including primates, rodents, and hoofed mammals, evolved during this period. • After the great dinosaur extinction, mammals diversified, increased in size, and occupied many niches. • The Cenozoic Era is usually called the Age of Mammals.

  49. Modern Mammals • By the beginning of the Cenozoic Era,three major groups of mammals had evolved—monotremes, marsupials, and placentals. • These three groups A: differ in their means of reproduction and development. • Only five species of the B: egg-laying monotremes, including the duckbill platypus, exist today, all in Australia and New Guinea. • C: Marsupials, which include kangaroos, koalas, and wombats, bear live young that usually complete their development in an external pouch. • D: Placental mammals have embryos that develop further while still inside the mother. After birth, most placental mammals care for their young and nurse them to provide nourishment.

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