chapter 32 animal evolution...cnidaria platyhelminthes sponges jellyfish flatworms roundworms...
TRANSCRIPT
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Chapter 32—Animal Evolution
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Domain
Bacteria
Domain
Archaea
Domain
Eukarya
Common ancestor
Kingdom: Animals
Domain Eukarya
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I. Animal Characteristics • Heterotrophs
– must ingest other organisms for nutrients
• Multicellular – complex bodies
• No cell walls – allows active movement
– nervous & muscle tissue
• Sexual reproduction – no alternation of generations
(as in plants)
– diploid stage dominates life cycle
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Early Embryonic Development
Ectoderm → epidermis (skin), nervous system
GERM LAYERS: Mesoderm → muscles, bones, connective tissue
Endoderm → digestive tract and organs, lungs
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II. Animal
Diversity
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Radial vs. Bilateral Symmetry
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Porifera
Cnidaria
Platyhelminthes
sponges jellyfish flatworms roundworms
Nematoda
Mollusca Arthropoda Chordata
Annelida Echinodermata
mollusks
multicellularity
Ancestral Protist
tissues
bilateral symmetry
body cavity
segmentation
Animal Evolution
coelom
starfish vertebrates
endoskeleton
segmented worms
insects spiders
backbone
specialization & body complexity
specialized structure & function,
muscle & nerve tissue
distinct body plan; cephalization
body complexity
digestive & repro sys
digestive sys
body size
redundancy,
specialization, mobility
body & brain
size, mobility
radial
bilateral
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Body Plans of the Bilateria
• Acoelomate
– lack a body cavity
• Pseudocoelomate
– ―false‖ body cavity only
partially lined by mesoderm
• Coelomate
– true body cavity completely
lined by mesoderm
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Body Cavity ectoderm
ectoderm
mesoderm
endoderm
ectoderm
mesoderm
endoderm
mesoderm
endoderm
acoelomate
pseudocoelomate
coelomate
coelom cavity
pseudocoel
• Space for organ system development – increase digestive &
reproductive systems
• increase food capacity & digestion
• increase gamete production
• Coelem – mesoderm & endoderm
interact during development
– allows complex structures to develop in digestive system
• ex. stomach
protostome vs. deuterostome
flatworms
roundworms
Segmented
worms
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Protostomes
(―1st mouth‖)
vs.
Deuterostomes
(―2nd mouth‖)
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Chapter 33—Invertebrates
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Invertebrate: Porifera
• Sponges
– no distinct tissues or organs
• do have specialized cells
– no symmetry
– sessile (as adults)
food taken into each
cell by endocytosis
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Invertebrate: Cnidaria
• Jellyfish, hydra, sea anemone, coral
– tissues, but no organs
– two cell layers
– radial symmetry
– predators
• tentacles surround
gut opening
• extracellular
digestion
– release enzymes
into gut cavity
– absorption by cells
lining gut
medusa polyp
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hydra
stinging cell with nematocyst
trigger
discharged nematocyst
undischarged nematocyst
tentacles
mouth
sensory cell
stinging cell
Stinging cells of
Cnidarians
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Invertebrate: Platyhelminthes
ectoderm
mesoderm
endoderm
• Flatworms
– tapeworm, planaria
– mostly parasitic
– bilaterally symmetrical
• have right & left & then have
head (anterior) end & posterior end
– cephalization = development of brain
– concentration of sense organs in head
• increased specialization in body plan
acoelomate
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Invertebrate: Nematoda
• Roundworms – bilaterally symmetrical
– body cavity • pseudocoelom = simple body cavity
• digestive system
– tube running through length of body (mouth to anus)
– many are parasitic • hookworm
C. elegans
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Invertebrate: Mollusca • Mollusks
– slugs, snails, clams, octopuses, squids, oysters, mussels
– bilaterally symmetrical (with exceptions)
– soft bodies, mostly protected by hard shells
– true coelem • increases complexity & specialization of internal organs
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Invertebrate: Annelida • Segmented worms
– earthworms, leeches
– segments • increase mobility
• redundancy in body sections
– bilaterally symmetrical
– true coelem fan worm leech
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Invertebrate: Arthropoda
• Spiders, insects, crustaceans
– most successful animal phylum (diversity, distribution, & #s)
– bilaterally symmetrical
– segmented
• specialized segments
• allows jointed appendages
– exoskeleton
• chitin + protein
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Arthropod groups
insects 6 legs, 3 body parts
crustaceans gills, 2 pairs antennae
crab, lobster, barnacles,
shrimp
arachnids 8 legs, 2 body parts
spiders, ticks, scorpions
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Invertebrate: Echinodermata
• Starfish, sea urchins, sea cucumber – radially symmetrical as adults
– spiny endoskeleton
– deuterostome loss of bilateral symmetry?
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Invertebrate quick check…
• Which group includes snails, clams, and squid?
• Which group is the sponges?
• Which are the flatworms? …segmented worms?
…roundworms?
• Which group has jointed appendages & an exoskeleton?
• Which two groups have radial symmetry?
• What is the adaptive advantage of bilateral symmetry?
• Which group has no symmetry?
Invertebrates: Porifera, Cnidaria, Platyhelminthes, Nematoda,
Annelida, Mollusca, Arthropoda, Echinodermata
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Chapter 34—Vertebrates
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• Vertebrates
– fish, amphibians, reptiles, birds, mammals
– internal bony skeleton
• backbone encasing
spinal column
• skull-encased brain
– deuterostome
postanal tail notochord
hollow dorsal nerve cord
pharyngeal pouches
Chordata
becomes brain & spinal cord
becomes vertebrae
become gills or Eustachian tube
becomes tail or tailbone
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Extant
Vertebrates
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Vertebrates: Fish salmon, trout, sharks
450 mya
• Characteristics
– body structure
• bony & cartilaginous skeleton
• jaws & paired appendages (fins)
• scales
– body function
• gills for gas exchange
• two-chambered heart;
single loop blood circulation
• ectotherms
– reproduction
• external fertilization
• external development in
aquatic egg
gills
body
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Transition to
Land Evolution of tetrapods
Tibia
Femur
Fibula
Humerus Shoulder
Radius Ulna
Tibia
Femur Pelvis
Fibula Lobe-finned fish
Humerus
Shoulder
Radius
Ulna
Pelvis
Early amphibian
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lung
buccal cavity
glottis closed
Vertebrates: Amphibia
• Characteristics – body structure
• legs (tetrapods)
• moist skin
– body function • lungs (positive pressure) &
diffusion through skin for gas exchange
• three-chambered heart; veins from lungs back to heart
• ectotherms
– reproduction • external fertilization
• external development in aquatic egg
• metamorphosis (tadpole to adult)
frogs
salamanders
toads
350 mya
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Vertebrates: Reptiles • Characteristics
– body structure • dry skin, scales, armor
– body function • lungs for gas exchange
• thoracic breathing; negative pressure
• three-chambered heart
• ectotherms
– reproduction • internal fertilization
• external development in amniotic egg
250 mya dinosaurs, turtles
lizards, snakes
alligators, crocodile
embryo leathery shell
chorion
allantois yolk sac
amnion
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Vertebrates: Birds (Aves) • Characteristics
– body structure • feathers & wings
• thin, hollow bone; flight skeleton
– body function • very efficient lungs & air sacs
• four-chambered heart
• endotherms
– reproduction • internal fertilization
• external development in amniotic egg
150 mya finch, hawk
ostrich, turkey
trachea
anterior air sacs
lung
posterior air sacs
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Vertebrates: Mammals 220 mya / 65 mya
mice, ferrets
elephants, bats
whales, humans
muscles contract
diaphragm contracts
• Characteristics – body structure
• hair
• specialized teeth
– body function • lungs, diaphragm; negative pressure
• four-chambered heart
• endotherms
– reproduction • internal fertilization
• internal development in uterus
– nourishment through placenta
• birth live young
• mammary glands make milk
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Vertebrates: Mammals • Sub-groups
– monotremes • egg-laying mammals
• lack placenta & true nipples
• duckbilled platypus, echidna
– marsupials • pouched mammals
– offspring feed from nipples in pouch
• short-lived placenta
• koala, kangaroo, opossum
– placental • true placenta
– Nutrient delivery & waste filter
• shrews, bats, whales, humans
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Vertebrate quick check… • Which vertebrates lay eggs with shells?
• Which vertebrates are covered with scales?
• What adaptations do birds have for flying?
• What kind of symmetry do all vertebrates have?
• Which vertebrates are ectothermic and which
are endothermic
• Why must amphibians live near water?
• What reproductive adaptations made mammals
very successful?
• What characteristics distinguish the 3 sub-
groups of mammals?