27 The Rise of Animal Diversity
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1 CAMPBELL BIOLOGY IN FOCUS Urry Cain Wasserman Minorsky Jackson Reece 27 The Rise of Animal Diversity Lecture Presentations by Kathleen Fitzpatrick and Nicole Tunbridge
2 Overview: Life Becomes Dangerous Most animals are mobile and use traits such as strength, speed, toxins, or camouflage to detect, capture, and eat other organisms For example, the chameleon captures insect prey with its long, sticky, fast-moving tongue
3 Figure 27.1 What adaptations make a chameleon a fearsome predator?
4 Concept 27.1: Animals originated more than 700 million years ago Current evidence indicates that animals evolved from single-celled eukaryotes similar to present-day choanoflagellates More than 1.3 million animal species have been named to date; the actual number of species is estimated to be nearly 8 million
5 Fossil and Molecular Evidence Fossil biochemical evidence and molecular clock studies date the common ancestor of all living animals to the period between 700 and 770 million years ago Early members of the animal fossil record include the Ediacaran biota, which dates from about 560 million years ago
6 Figure 27.2 Ediacaran fossils (a) Dickinsonia 2.5 cm costata (taxonomic affiliation unknown) (b) The fossil mollusc Kimberella 1 cm
7 Figure 27.2a Ediacaran fossils (part 1: Dickinsonia costata) (a) Dickinsonia 2.5 cm costata (taxonomic affiliation unknown)
8 Figure 27.2b Ediacaran fossils (part 2: Kimberella) (b) The fossil mollusc Kimberella 1 cm
9 Early-Diverging Animal Groups Sponges and cnidarians are two early-diverging groups of animals
10 Figure 27.UN01 sponges and cnidarians mini-tree, p. 529 Sponges Cnidarians Other animal groups
11 Sponges Animals in the phylum Porifera are known informally as sponges Sponges are filter feeders, capturing food particles suspended in the water that passes through their body Water is drawn through pores into a central cavity and out through an opening at the top Sponges lack true tissues, groups of cells that function as a unit
12 Figure 27.3 Anatomy of a sponge Flagellum Collar Food particles in mucus Choanocyte Choanocyte Phagocytosis of food particles Amoebocyte Pores Water flow Spicules Amoebocytes Azure vase sponge (Callyspongia plicifera)
13 Figure 27.3a Anatomy of a sponge (photo) Azure vase sponge (Callyspongia plicifera)
14 Choanocytes, flagellated collar cells, generate a water current through the sponge and ingest suspended food Morphological similarities between choanocytes and choanoflagellates are consistent with the hypothesis that animals evolved from a choanoflagellate-like ancestor Amoebocytes are mobile cells that play roles in digestion and structure
15 Cnidarians Like most animals, members of the phylum Cnidaria have true tissues Cnidarians are one of the oldest groups of animals, dating back to 680 million years ago Cnidarians have diversified into a wide range of both sessile and motile forms, including hydrozoans, jellies, and sea anemones
16 Video: Clownfish Anemone
17 Video: Coral Reef
18 Video: Hydra Budding
19 Video: Hydra Eating
20 Video: Jelly Swimming
21 Video: Thimble Jellies
22 Figure 27.4 Major groups of cnidarians (a) Hydrozoa (b) Scyphozoa (c) Anthozoa
23 Figure 27.4a (part 1: hydrozoa) (a) Hydrozoa
24 Figure 27.4b (part 2: scyphozoa) (b) Scyphozoa
25 Figure 27.4c (part 3: anthozoa) (c) Anthozoa
26 The basic body plan of a cnidarian is a sac with a central digestive compartment, the gastrovascular cavity A single opening functions as mouth and anus Cnidarians are carnivores that use tentacles to capture prey Cnidarians have no brain, but instead have a noncentralized nerve net associated with sensory structures distributed throughout the body
27 Concept 27.2: The diversity of large animals increased dramatically during the Cambrian explosion The Cambrian explosion (535 to 525 million years ago) marks the earliest fossil appearance of many major groups of living animals
28 Evolutionary Change in the Cambrian Explosion Strata formed during the Cambrian explosion contain the oldest fossils of about half of all extant animal phyla
29 Figure 27.5 Appearance of selected animal groups Sponges Cnidarians Echinoderms Chordates Brachiopods 635 PROTEROZOIC Ediacaran Molluscs Annelids Arthropods PALEOZOIC Cambrian Time (millions of years age)
30 Fossils from the Cambrian period include the first hard, mineralized skeletons Most fossils from this period are of bilaterians, a clade whose members have a complete digestive tract and a bilaterally symmetric form
31 Figure 27.6 A Cambrian seascape Hallucigenia fossil (530 mya) 1 cm
32 Figure 27.6a A Cambrian seascape (part 1: painting)
33 Figure 27.6b (part 2: Hallucigenia) Hallucigenia fossil (530 mya) 1 cm
34 There are several hypotheses regarding the cause of the Cambrian explosion and decline of Ediacaran biota New predator-prey relationships A rise in atmospheric oxygen The evolution of the Hox gene complex
35 Dating the Origin of Bilaterians Molecular clock estimates date the bilaterians to 100 million years earlier than the oldest fossil, which lived 560 million years ago The appearance of larger, well-defended eukaryotes million years ago indicates that bilaterian predators may have originated by that time
36 Figure 27.7 Indirect evidence of the appearance of bilaterians? 15 m (a) Valeria (800 mya): roughly spherical, no structural defenses, soft-bodied 75 m (b) Spiny acritarch (575 mya): about five times larger than Valeria and covered in hard spines
37 Figure 27.7a (part 1: Valeria) 15 m (a) Valeria (800 mya): roughly spherical, no structural defenses, soft-bodied
38 Figure 27.7b (part 2: spiny acritarch) 75 m (b) Spiny acritarch (575 mya): about five times larger than Valeria and covered in hard spines
39 Concept 27.3: Diverse animal groups radiated in aquatic environments Animals in the early Cambrian oceans were very diverse in morphology, way of life, and taxonomic affiliation
40 Animal Body Plans Zoologists sometimes categorize animals according to a body plan, a set of morphological and developmental traits There are three important aspects of animal body plans Symmetry Tissues Body cavities
41 Symmetry Animals can be categorized according to the symmetry of their bodies or lack of it Some animals have radial symmetry, with no front and back or left and right
42 Figure 27.8 (a) Radial symmetry (b) Bilateral symmetry
43 Two-sided symmetry is called bilateral symmetry Bilaterally symmetrical animals have A dorsal (top) side and a ventral (bottom) side A right and left side Anterior (head) and posterior (tail) ends Many also have sensory equipment concentrated in the anterior end, including a brain in the head
44 Radial animals are often sessile or planktonic (drifting or weakly swimming) Bilateral animals often move actively and have a central nervous system enabling coordinated movement
45 Tissues Animal body plans also vary according to the organization of the animal s tissues Tissues are collections of specialized cells isolated from other tissues by membranous layers During development, three germ layers give rise to the tissues and organs of the animal embryo
46 Figure 27.9 Tissue layers in bilaterians Body cavity Body covering (from ectoderm) Digestive tract (from endoderm) Tissue layer lining body cavity and suspending internal organs (from mesoderm)
47 Ectoderm is the germ layer covering the embryo s surface Endoderm is the innermost germ layer and lines the developing digestive tube, called the archenteron Cnidarians have only these two germ layers Mesoderm is a third germ layer that fills the space between the ectoderm and the endoderm in all bilaterally symmetric animals
48 Body Cavities Most bilaterians possess a body cavity (coelom), a fluid- or air-filled space between the digestive tract and the outer body wall The body cavity may Cushion suspended organs Act as a hydrostatic skeleton Enable internal organs to move independently of the body wall
49 The Diversification of Animals Zoologists recognize about three dozen animal phyla Phylogenies now combine molecular data from multiple sources with morphological data to determine the relationships among animal phyla
50 Video: C. Elegans Crawling
51 Video: Earthworm Locomotion
52 Video: Echinoderm Tubefeet
53 Video: Nudibranchs
54 Video: Rotifer
55 Figure A current hypothesis of animal phylogeny Porifera ANCESTRAL PROTIST Metazoa 770 million years ago Eumetazoa 680 million years ago Bilateria 670 million years ago Deuterostomia Lophotrochozoa Ecdysozoa Ctenophora Cnidaria Hemichordata Echinodermata Chordata Platyhelminthes Rotifera Ectoprocta Brachiopoda Mollusca Annelida Nematoda Arthropoda
56 The following points are reflected in the animal phylogeny 1. All animals share a common ancestor 2. Sponges are basal animals 3. Eumetazoa is a clade of animals (eumetazoans) with true tissues 4. Most animal phyla belong to the clade Bilateria and are called bilaterians 5. Most animals are invertebrates, lacking a backbone; Chordata is the only phylum that includes vertebrates, animals with a backbone
57 Bilaterian Radiation I: Diverse Invertebrates Bilaterians have diversified into three major clades Lophotrochozoa Ecdysozoa Deuterostomia
58 An Overview of Invertebrate Diversity Bilaterian invertebrates account for 95% of known animal species They are morphologically diverse and occupy almost every habitat on Earth This morphological diversity is mirrored by extensive taxonomic diversity The vast majority of invertebrate species belong to the Lophotrochozoa and Ecdysozoa; a few belong to the Deuterostomia
59 Figure Exploring the diversity of invertebrate bilaterians Ectoprocta (4,500 species) Lophotrochozoa Mollusca (93,000 species) Nematoda (25,000 species) Ecdysozoa Arthropoda (1,000,000 species) An octopus Annelida (16,500 species) A roundworm Ectoprocts A web-building spider (an arachnid) A fireworm, a marine annelid Hemichordata (85 species) Deuterostomia Echinodermata (7,000 species) An acorn worm Sea urchins and a sea star
60 Figure 27.11a part 1 Ectoprocta (4,500 species) Lophotrochozoa Mollusca (93,000 species) An octopus Annelida (16,500 species) Ectoprocts A fireworm, a marine annelid
61 Exploring the diversity of invertebrate bilaterians (part 1a: Ectoprocta) Figure 27.11aa Ectoprocta (4,500 species) Ectoprocts
62 Figure 27.11ab Exploring the diversity of invertebrate bilaterians (part 1b: Mollusca) Mollusca (93,000 species) An octopus
63 Figure 27.11ac (part 1c: Annelida) Annelida (16,500 species) A fireworm, a marine annelid
64 Figure 27.11b Exploring the diversity of invertebrate bilaterians (part 2: Ecdysozoa) Nematoda (25,000 species) Ecdysozoa Arthropoda (1,000,000 species) A roundworm A web-building spider (an arachnid)
65 Figure 27.11ba Exploring the diversity of invertebrate bilaterians (part 2a: Nematoda) Nematoda (25,000 species) A roundworm
66 Figure 27.11bb Exploring the diversity of invertebrate bilaterians (part 2b: Arthropoda) Arthropoda (1,000,000 species) A web-building spider (an arachnid)
67 Figure 27.11c Exploring the diversity of invertebrate bilaterians (part 3: Deuterostomia Hemichordata (85 species) Deuterostomia Echinodermata (7,000 species An acorn worm Sea urchins and a sea star
68 Figure 27.11ca (part 3a: Hemichordata) Hemichordata (85 species) An acorn worm
69 Figure 27.11cb Exploring the diversity of invertebrate bilaterians (part 3b: Echinodermata) Echinodermata (7,000 species) Sea urchins and a sea star
70 Arthropod Origins Two out of every three known species of animals are arthropods Members of the phylum Arthropoda are found in nearly all habitats of the biosphere
71 The arthropod body plan consists of a segmented body, hard exoskeleton, and jointed appendages This body plan dates to the Cambrian explosion ( million years ago) Early arthropods show little variation from segment to segment
72 Figure 27.UN02 fossil trilobite, p. 536 A fossil trilobite
73 Arthropod evolution is characterized by a decrease in the number of segments and an increase in appendage specialization These changes may have been caused by changes in Hox gene sequence or regulation
74 Figure Experiment Did the arthropod body plan result from new Hox genes? Origin of Ubx and abd-a Hox genes? Other ecdysozoans Arthropods Common ancestor Results Onychophorans Red indicates regions in which Ubx or abd-a genes were expressed. Ant antenna J jaws L1 L15 body segments
75 Figure 27.12a Did the arthropod body plan result from new Hox genes? (results) Results Red indicates regions in which Ubx or abd-a genes were expressed. Ant antenna J jaws L1 L15 body segments
76 Bilaterian Radiation II: Aquatic Vertebrates The appearance of large predatory animals and the explosive radiation of bilaterian invertebrates radically altered life in the oceans One type of animal gave rise to vertebrates, one of the most successful groups of animals
77 Figure Myllokunmingia fengjiaoa, a 530-million-year-old chordate
78 The animals called vertebrates get their name from vertebrae, the series of bones that make up the backbone Vertebrates are members of phylum Chordata Chordates are bilaterian animals that belong to the clade of animals known as Deuterostomia
79 Early Chordate Evolution All chordates share a set of derived characters Some species have some of these traits only during embryonic development Four key characters of chordates Notochord, a flexible rod providing support Dorsal, hollow nerve cord Pharyngeal slits or pharyngeal clefts, which function in filter feeding, as gills, or as parts of the head Muscular, post-anal tail
80 Video: Clownfish Anemone
81 Video: Coral Reef
82 Video: Manta Ray
83 Video: Sea Horses
84 Figure Chordate characteristics Notochord Dorsal, hollow nerve cord Muscle segments Mouth Anus Post-anal tail Pharyngeal slits or clefts
85 Lancelets are a basal group of extant, blade-shaped animals that closely resemble the idealized chordate Tunicates are another early diverging chordate group, but they only display key chordate traits during their larval stage The ancestral chordate may have looked similar to a lancelet
86 Figure Present-day basal groups of chordates (a) Lancelet (b) Tunicate
87 Figure 27.15a (part 1: lancelet) (a) Lancelet
88 Figure 27.15b (part 2: tunicate) (b) Tunicate
89 In addition to the features of all chordates, early vertebrates had a backbone and a well-defined head with sensory organs and a skull Fossils representing the transition to vertebrates formed during the Cambrian explosion
90 The Rise of Vertebrates Early vertebrates were more efficient at capturing food and evading predators than their ancestors The earliest vertebrates were conodonts, softbodied, jawless animals that hunted prey using a set of barbed hooks in their mouth There are only two extant lineages of jawless vertebrates, the hagfishes and lampreys
91 Figure Exploring vertebrate diversity Common ancestor of vertebrates Myxini (hagfishes) Petromyzontida (lampreys) Vertebrates Vertebral column Jaws, mineralized skeleton Lungs or lung derivatives Lobed fins Limbs with digits Chondrichthyes (sharks, rays, chimaeras) Actinopterygii (ray-finned fishes) Actinistia (coelacanths) Dipnoi (lungfishes) Tetrapoda (amphibians, reptiles, mammals) Tetrapods Lobe-fins Osteichthyans Gnathostomes Myxini Petromyzontida Dipnoi Chondrichthyes Actinopterygii Actinistia Tetrapoda
92 Figure 27.16a Common ancestor of vertebrates Exploring vertebrate diversity (part 1: tree) Myxini (hagfishes) Petromyzontida (lampreys) Vertebrates Vertebral column Jaws, mineralized skeleton Lungs or lung derivatives Lobed fins Limbs with digits Chondrichthyes (sharks, rays, chimaeras) Actinopterygii (ray-finned fishes) Actinistia (coelacanths) Dipnoi (lungfishes) Tetrapoda (amphibians, reptiles, mammals) Tetrapods Lobe-fins Osteichthyans Gnathostomes
93 Figure 27.16b Exploring vertebrate diversity (part 2: photos) Myxini Actinopterygii Actinistia Petromyzontida Dipnoi Chondrichthyes Tetrapoda
94 Figure 27.16ba Exploring vertebrate diversity (part 2a: Myxini) Myxini
95 Figure 27.16bb Exploring vertebrate diversity (part 2b: Petromyzontida) Petromyzontida
96 Figure 27.16bba Exploring vertebrate diversity (part 2ba: lamprey)
97 Figure 27.16bbb Exploring vertebrate diversity (part 2bb: lamprey mouth)
98 Figure 27.16bc Exploring vertebrate diversity (part 2c: Chondrichthyes) Chondrichthyes Skeletons are made primarily of cartilage
99 Figure 27.16bd Exploring vertebrate diversity (part 2d: Actinopterygii) Actinopterygii
100 Figure 27.16be Exploring vertebrate diversity (part 2e: Actinistia) Actinistia
101 Figure 27.16bf Exploring vertebrate diversity (part 2f: Dipnoi) Dipnoi
102 Figure 27.16bg Exploring vertebrate diversity (part 2g: Tetrapoda) Tetrapoda
103 Today, jawed vertebrates, or gnathostomes, outnumber jawless vertebrates Early gnathostome success is likely due to adaptations for predation including paired fins and tails for efficient swimming and jaws for grasping prey
104 Video: Lobster Mouth Parts
105 Figure Fossil of an early gnathostome 0.5 m
106 Gnathostomes diverged into three surviving lineages, chondrichthyans, ray-finned fishes, and lobe-fins Humans and other terrestrial animals are included in the lobe-fins
107 Chondrichthyans include sharks, rays, and their relatives The skeletons of chondrichthyans are composed primarily of cartilage This group includes some of the largest and most successful vertebrate predators
108 Ray-finned fishes include nearly all the familiar aquatic osteichthyans The vast majority of vertebrates belong to the clade of gnathostomes called Osteichthyes Nearly all living osteichthyans have a bony endoskeleton
109 Lobe-fins are the other major lineage of osteichthyans A key derived trait in the lobe-fins is the presence of rod-shaped bones surrounded by a thick layer of muscle in their pectoral and pelvic fins Three lineages survive: the coelacanths, lungfishes, and tetrapods, terrestrial vertebrates with limbs and digits
110 Concept 27.4: Several animal groups had features facilitating their colonization of land Some bilaterian animals colonized land following the Cambrian explosion, causing profound changes in terrestrial communities
111 Early Land Animals Members of many animal groups made the transition to terrestrial life Arthropods were among the first animals to colonize the land about 450 million years ago Vertebrates colonized land 365 million years ago
112 The evolutionary changes that accompanied the transition to terrestrial life were much less extensive in animals than in plants
113 Video: Bee Pollinating
114 Video: Butterfly Emerging
115 TERRESTRIAL ORGANISM CHARACTER AQUATIC ANCESTOR Figure Descent with modification during the colonization of land GREEN ALGA MARINE CRUSTACEAN AQUATIC LOBE-FIN Anchoring structure Derived (roots) N/A N/A Support structure Derived (lignin/stems) Ancestral Ancestral (skeletal system) Derived (limbs) Internal transport Derived (vascular system) Ancestral Ancestral Muscle/ nerve cells N/A Ancestral Ancestral Protection against desiccation Derived (cuticle) Ancestral Derived (amniotic egg/scales) Gas exchange Derived (stomata) Derived (tracheal system) Ancestral LAND PLANTS INSECTS TERRESTRIAL VERTEBRATES
116 TERRESTRIAL ORGANISM CHARACTER AQUATIC ANCESTOR Figure 27.18a (part 1: plants) GREEN ALGA Anchoring structure Support structure Internal transport Muscle/nerve cells Protection against desiccation Gas exchange Derived (roots) Derived (lignin/stems) Derived (vascular system) N/A Derived (cuticle) Derived (stomata) LAND PLANTS
117 TERRESTRIAL ORGANISM CHARACTER AQUATIC ANCESTOR Figure 27.18b (part 2: insects) MARINE CRUSTACEAN Anchoring structure Support structure Internal transport Muscle/nerve cells Protection against desiccation Gas exchange N/A Ancestral Ancestral Ancestral Ancestral Derived (tracheal system) INSECTS
118 TERRESTRIAL ORGANISM CHARACTER AQUATIC ANCESTOR Figure 27.18c (part 3: vertebrates) AQUATIC LOBE-FIN Anchoring structure Support structure Internal transport Muscle/nerve cells Protection against desiccation Gas exchange N/A Ancestral (skeletal system) Derived (limbs) Ancestral Ancestral Derived (amniotic egg/scales) Ancestral TERRESTRIAL VERTEBRATES
119 Colonization of Land by Arthropods Terrestrial lineages have arisen in several different arthropod groups, including millipedes, spiders, crabs, and insects
120 General Characteristics of Arthropods The appendages of some living arthropods are modified for functions such as walking, feeding, sensory reception, reproduction, and defense
121 Figure Cephalothorax Abdomen External anatomy of an arthropod Antennae (sensory reception) Head Thorax Swimming appendages (one pair per abdominal segment) Pincer (defense) Mouthparts (feeding) Walking legs
122 The body of an arthropod is completely covered by the cuticle, an exoskeleton made of layers of protein and the polysaccharide chitin The exoskeleton provides structural support and protection from physical harm and desiccation A variety of organs specialized for gas exchange have evolved in arthropods
123 Insects The insects and their relatives include more species than all other forms of life combined They live in almost every terrestrial habitat and in fresh water
124 Figure Insect diversity Lepidopterans Hymenopterans Hemipterans
125 Figure 27.20a (part 1: lepidopterans) Lepidopterans
126 Figure 27.20aa (part 1a: butterfly)
127 Figure 27.20ab (part 1b: caterpillar)
128 Figure 27.20b (part 2: hymenopterans) Hymenopterans
129 Figure 27.20c (part 3: hemipterans) Hemipterans
130 Insects diversified several times following the evolution of flight, adaptation to feeding on gymnosperms, and the expansion of angiosperms Insect and plant diversity declined during the Cretaceous extinction, but has been increasing in the 65 million years since
131 Flight is one key to the great success of insects An animal that can fly can escape predators, find food, and disperse to new habitats much faster than organisms that can only crawl
132 Figure Ladybird beetle in flight
133 Terrestrial Vertebrates One of the most significant events in vertebrate history was when the fins of some lobe-fins evolved into the limbs and feet of tetrapods
134 The Origin of Tetrapods Tiktaalik, nicknamed a fishapod, shows both fish and tetrapod characteristics It had Fins, gills, lungs, and scales Ribs to breathe air and support its body A neck and shoulders Fins with the bone pattern of a tetrapod limb
135 Figure Fish Characters Scales Fins Gills and lungs Tetrapod Characters Neck Ribs Fin skeleton Flat skull Eyes on top of skull Discovery of a fishapod : Tiktaalik Head Neck Shoulder bones Ribs Scales Eyes on top of skull Flat skull Fin Elbow Radius Humerus Ulna Wrist Fin skeleton
136 Figure 27.22a Discovery of a fishapod : Tiktaalik (part 1: detail) Eyes on top of skull Flat skull Head Neck Shoulder bones Fin
137 Figure 27.22b (part 2: ribs) Ribs
138 Figure 27.22c Scales
139 Figure 27.22d (part 4: fin skeleton) Elbow Radius Humerus Ulna Wrist Fin skeleton
140 Tiktaalik could most likely prop itself on its fins, but not walk Fins became progressively more limb-like over evolutionary time, leading to the first appearance of tetrapods 365 million years ago
141 Figure Lungfishes Eusthenopteron Panderichthys Tiktaalik Acanthostega Limbs with digits Tulerpeton Silurian Devonian Amphibians Amniotes PALEOZOIC Carboniferous Permian Time (millions of years ago) Steps in the origin of limbs with digits Key to limb bones Ulna Radius Humerus
142 Figure 27.23a Lungfishes Eusthenopteron Panderichthys Tiktaalik Key to Lobe-fins with limbs with digits limb bones Ulna Silurian PALEOZOIC Radius Devonian Carboniferous Permian Humerus Time (millions of years ago) (part 1: lobe-fins with limbs without digits)
143 Figure 27.23b (part 2: lobe-fins with limbs with digits) Acanthostega Limbs with digits Tulerpeton Silurian Devonian Amphibians Amniotes PALEOZOIC Carboniferous Permian Time (millions of years ago) Key to limb bones Ulna Radius Humerus
144 Amphibians Amphibians are represented by about 6,150 species including salamanders, frogs, and caecilians Amphibians are restricted to moist areas within their terrestrial habitats
145 Video: Marine Iguana
146 Video: Flapping Geese
147 Video: Snake Wrestling
148 Video: Soaring Hawk
149 Video: Swans Taking Flight
150 Video: Tortoise
151 Figure Amphibian diversity Salamanders retain their tails as adults. Caecilians have no legs and are mainly burrowing animals. Frogs and toads lack tails as adults.
152 Figure 27.24a (part 1: salamanders) Salamanders retain their tails as adults.
153 Figure 27.24b (part 2: frogs and toads) Frogs and toads lack tails as adults.
154 Figure 27.24c (part 3: caecilians) Caecilians have no legs and are mainly burrowing animals.
155 Terrestrial Adaptations in Amniotes Amniotes are a group of tetrapods whose living members are the reptiles, including birds, and mammals Amniotes are named for the major derived character of the clade, the amniotic egg, which contains membranes that protect the embryo The extraembryonic membranes are the amnion, chorion, yolk sac, and allantois The amniotic eggs of most reptiles and some mammals have a shell
156 Video: Bat Licking
157 Video: Bat Pollinating
158 Video: Chimp Agonistic
159 Video: Chimp Cracking Nut
160 Video: Gibbon Brachiating
161 Video: Sea Lion
162 Video: Shark Eating Seal
163 Video: Wolves Agonistic
164 Figure The amniotic egg Extraembryonic membranes Amnion Allantois Chorion Yolk sac Embryo Amniotic cavity with amniotic fluid Yolk (nutrients) Shell Albumen
165 The Origin and Radiation of Amniotes Living amphibians and amniotes split from a common ancestor about 350 million years ago Early amniotes were more tolerant of dry conditions than early tetrapods The earliest amniotes were small predators with sharp teeth and long jaws
166 Reptiles are one of two living lineages of amniotes Members of the reptile clade includes the tuataras, lizards, snakes, turtles, crocodilians, birds, and some extinct groups
167 Figure Exploring reptilian diversity Plesiosaurs Crocodilians Pterosaurs Common ancestor of reptiles Common ancestor of dinosaurs Ornithischian dinosaurs Saurischian dinosaurs other than birds Birds Turtles Turtles Tuataras Squamates Squamates Crocodilians Birds Tuataras
168 Figure 27.26a Exploring reptilian diversity (part 1: tree) Plesiosaurs Crocodilians Pterosaurs Common ancestor of reptiles Common ancestor of dinosaurs Ornithischian dinosaurs Saurischian dinosaurs other than birds Birds Turtles Tuataras Squamates
169 Figure 27.26b (part 2: photos) Crocodilians Tuataras Squamates Birds Turtles
170 Figure 27.26ba Crocodilians
171 Figure 27.26bb (part 2b: birds) Birds
172 Figure 27.26bba (part 2ba: wings and feathers)
173 Figure 27.26bbb (part 2bb: honeycombed bone)
174 Figure 27.26bc Turtles
175 Figure 27.26bd Tuataras
176 Figure 27.26be Squamates
177 Reptiles have scales that create a waterproof barrier Most reptiles lay shelled eggs on land Most reptiles are ectothermic, absorbing external heat as the main source of body heat Birds are endothermic, capable of keeping the body warm through metabolism
178 Mammals are the other extant lineage of amniotes There are many distinctive traits of mammals including Mammary glands that produce milk Hair A fat layer under the skin A high metabolic rate, due to endothermy Differentiated teeth
179 The first true mammals evolved from synapsids and arose about 180 million years ago By 140 million years ago, the three living lineages of mammals had emerged Monotremes, egg-laying mammals Marsupials, mammals with a pouch Eutherians, placental mammals
180 Figure The major mammalian lineages Monotremes Marsupials Eutherians
181 Figure 27.27a The major mammalian lineages (part 1: monotremes) Monotremes
182 Figure 27.27aa (part 1a: spiny anteater
183 Figure 27.27ab (part 1b: monotreme egg)
184 Figure 27.27b (part 2: marsupials) Marsupials
185 Figure 27.27c (part 3: eutherians) Eutherians
186 Human Evolution Humans (Homo sapiens) are primates, nested within a group informally called apes
187 Figure The human evolutionary tree New World monkeys Old World monkeys Gibbons Apes Orangutans Gorillas Chimpanzees and bonobos Humans
188 A number of characters distinguish humans from other apes Upright posture and bipedal locomotion Larger brains capable of language, symbolic thought, artistic expression, and the use of complex tools
189 The evolution of bipedalism preceded the evolution of increased brain size in early human ancestors Brain size, body size, and tool use increased over time in Homo species Modern humans, H. sapiens, originated in Africa about 200,000 years ago and colonized the rest of the world from there
190 Figure Early fossils of Homo sapiens
191 Concept 27.5: Animals have transformed ecosystems and altered the course of evolution The rise of animals from a microbe-only world affected all aspects of ecological communities, in the sea and on land
192 Ecological Effects of Animals The oceans of early Earth likely had very different properties than the oceans of today
193 Figure A sea change for Earth s oceans Murky, poorly-mixed Low oxygen Cyanobacteria (a) Ocean conditions before 600 mya Clear, well-mixed High oxygen Eukaryotic algae (b) Changes to ocean conditions by 530 mya
194 Marine Ecosystems The rise of filter-feeding animals likely caused the decline of cyanobacteria and other suspended particles in the oceans during the early Cambrian This resulted in a shift to algae as the dominant producers and changed the feeding relationships in marine ecosystems
195 Terrestrial Ecosystems Terrestrial ecosystems were transformed with the move of animals to land Herbivores, such as the lesser snow goose, can improve the growth of plants at low population sizes through additions of nutrient-rich wastes At high population sizes herbivores can defoliate large tracts of land
196 Figure Effects of herbivory
197 Evolutionary Effects of Animals The origin of mobile, heterotrophic animals with a complete digestive tract drove some species to extinction and initiated ongoing arms races between bilaterian predators and prey
198 Evolutionary Radiations Two species that interact can exert strong, reciprocal selective pressures on one another For example, flower form can be influenced by the structure of its pollinators mouth parts, and vice versa
199 Figure Results of Reciprocal selection
200 Reciprocal selection pressures can also occur when the origin of new species in one group stimulates further radiation in another group For example, the origin of a new group of animals provides new food sources for parasites, resulting in radiations in parasite groups
201 Human Impacts on Evolution Humans have made large changes to the environment that have altered the selective pressures faced by many species For example, human targeting of large fish for harvesting has led to the reduction in age and size at which individuals reach sexual maturity
202 Age at maturity (years) Figure Reproducing at a younger age Year
203 Figure 27.33a
204 Rapid species declines over the past 400 years indicate that human activities may be driving a sixth mass extinction Molluscs, including pearl mussels, have suffered the greatest impact of human-caused extinctions
205 Figure The silent extinction Other invertebrates Molluscs An endangered Pacific island land snail, Partula suturalis Insects Fishes Birds Amphibians Mammals Reptiles (excluding birds) Recorded extinctions of animal species Workers on a mound of pearl mussels killed to make buttons (ca. 1919)
206 Figure 27.34a Other The silent extinction (part 1: pie chart) invertebrates Molluscs Insects Fishes Birds Mammals Amphibians Reptiles (excluding birds) Recorded extinctions of animal species
207 Figure 27.34b The silent extinction (part 2: snail) An endangered Pacific island land snail, Partula suturalis
208 Figure 27.43c The silent extinction (part 3: workers) Workers on a mound of pearl mussels killed to make buttons (ca. 1919)
209 The major threats imposed on species by human activities include habitat loss, pollution, and competition or predation by introduced, non-native species
210 Figure 27.UN03 Average number of periwinkles killed Southern Northern Source population of crab Southern periwinkles Northern periwinkles
211 Figure 27.UN mya: Cambrian explosion 560 mya: Ediacaran animals Era 365 mya: Early land animals Paleozoic Origin and diversification of dinosaurs Mesozoic Diversification of mammals Neoproterozoic Cenozoic 1, Millions of years age (mya)
212 Figure 27.UN05
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