Evolution of Animal Diversity
Chapter 18
Animal Evolution Basics• Animal Evolution was rapid, occurring
~ 600 million years ago (Precambrian Era)
• Evidence suggests that animals have evolved from protists that lived as colonies of cells.
• Colonies form when cells divide, but do not separate.
• These cells differentiated and became specialized.
Protoanimals• Model of blastula and grastula
used to represent these early animals.
Sources: http://farm3.static.flickr.com/2372/2121294845_dab7667079.jpg?v=0; http://www.dkimages.com/discover/previews/800/912525.JPG
Cambrian Explosion (545 mya)
• Time period in which all the major body plans seen today developed.
• Occurred during a short, 10 million year period of time.
• Why??– Ecological (food), Geological
(atmosphere), Genetic (reg. genes)
Animal Specs.
• Multicellular, eukaryotes that are heterotrophic (utilize ingestion).
• Animal cells lack cell walls, utilize intercellular junctions, proteins.
• Utilize muscle cells for movement
Animal Reproduction• Reproduce sexually• Mitosis & Meiosis involved• Blastula -> Grastula -> Ectoderm
(epidermis) -> Endoderm (lines digestive tract) -> Mesoderm (internal organs)
• Larval stages & Metamorphosis sometimes present
• Hox genes = reg genes that control development.
Invertebrates / Vertebrates
• Invertebrates = lack vertebral column
• Vertebrates = have vertebral column
Animal Ancestry
• Ancient Choanoflagellates = ancestor of all animals species today.– Colonial protist.
– Fig. 18.3 E
Radial Symmetry
• Animal body parts are arranged in a pie-like shape (around central axis).– Ex: Phylum Cnidaria: jellyfish
Phylum Porifera: Cylindrical sponges
– Fig. 18.3 B
Sponge Nutrition (Phylum Porifera)
• Suspension Feeders = animals that collect food particles from water passed through some type of food-trapping mechanism.– Choanocytes: Trap and obtain bacteria
from water via mucus.
– Amoebocytes: digest food packaged in vacuoles.
– Package food via phagocytosis (engulfment)
Cnidarians
• Have gastrovascular cavity– Incomplete digestion: undigested
foods exit through mouth.
– Classified as polyp or medusa
– Ex: Sea anemones, jellies
Bilateral Symmetry
• Animal can be divided equally by a single cut; left & right mirror image.
• Anterior (Head) - houses brain, sensory organs, and mouth.
• Posterior (Tail)
• Dorsal (Back)
• Ventral (Bottom)
• Lateral (Side)
Bilateral Symmetry
• Animals with this symmetry are very active and travel headfirst through its environment.
• Most have complete digestive tract (mouth to anus) & a body cavity between digestive tract and body wall.
• *Importance in evolution of animals*
Body Cavity• *Fluid-filled space between the
digestive tract and the body wall was important in the evolution of animals*
• Pseudocoelom = body cavity not completely lined by tissue derived from mesoderm.
• Coelom (“sea-lum”) = body cavity completely lined by tissue derived from mesoderm (complete digestive tract)
Advantages to having a Body Cavity
• Flexibility
• Allows use of muscles by force derived from “hydroskeleton.”
• Allows internal organs to develop and move independently of outer body wall.
• Fluid aids in protecting internal organs.
• Circulate nutrients and oxygen.
• Aids in waste disposal
Complete Digestive Tract
• Anterior portions of body churn and mix food with digestive enzymes.
• Posterior portions of body absorb nutrients and dispose of wastes.
Circulatory System
• An organ system that distributes nutrients and oxygen throughout the body.
Segmentation• Subdivision of the body along its
length into a series of repeated parts.
• Allows for grouping of specialized cells.
• Flexibility = adaptation for movement– Ex: Earthworm - grooved rings (external),
coelom partitioned by walls (internal)
– Ex: Dragon fly (head, abdomen, & thorax) human (vertebrae & abdominal muscles)
Arthropods
• Have an exoskeleton = hard external skeleton.– Consists of layers of protein and chitin
(polysaccharide)
– Serves as protection and points of attachment for muscles.
– Shedding of exoskeleton = molting.
Echinoderms
• Endoskeleton - hard internal skeleton.
Chordates
• Have the following features:– Dorsal, hollow nerve chord
– Notochord
– Pharyngeal slits
– Post-anal tail
Vertebrate chordates
Invertebrate chordates
(tunicates & lancelets)
Vertebrates (Chordates)
• Have the following features:– Skull & Backbone (encases brain and
main parts of nervous system)
– Endoskeleton (cartilage / hard bone)
*Evolution of jaws were of great importance in fish development*
Amphibians• 1st terrestrial vertebrates
• *Evolution of lungs and appendages were major evolutionary advances in fishes and allowed evolution of amphibians / adaptation to land*
• Adapted to living in shallow aquatic habitats and water’s edge.
• Proliferated during Carboniferous period.
Reptiles
• Adaptations to living on land:
–Skin with scales (keratin)
–Eggs that retain water
–Amniotic eggs = self-contained nourishment.
–Exothermic = absorption of heat externally.
Reptiles
• Dinosaurs:– Endothermic animals = use heat
generated by metabolism to maintain constant body temperature.
– Mass extinction ~65 mya
– Evolution of Birds
Birds• Relationship to Reptiles:
–Presence of amniotic eggs
–Scales on legs of birds
–Toenails of keratin
–Similar body structuring to reptiles
• Flight Structures:– No teeth, hollow shafted feathers,
honeycombed bones (strong, but light)
Birds
• High Metabolic Rate
• Endothermic (feathers ensure insulation of body temperature)
• Efficient circulatory system
Mammals• Evolved about 220 mya from reptiles.
• Mass extinction of dinosaurs allowed for a proliferation of mammals
–Exposure to greater resources & lack of predation)
• Endothermic, high metabolic rate, presence of hair, and mammary glands.
Mammals
• 3 Groups:
1) Monotremes – EX: duck-billed platypus (egg-laying).
2) Marsupials – EX: kangaroo
(External pouch)
3) Eutherians – EX: dogs, cats, humans
(Reptile Homologous structure = amniotic tissues)
Mammals
• Placenta = structure joining mother & embryo within uterus (#2 & #3)
• Placentas provide long-lasting association between mother and developing young.
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