1. Evolution of Vertebrates
The animals called vertebrates get their name from vertebrae, the series of bones that make up the backbone
There are about 52,000 species of vertebrates, including the largest organisms ever to live on the Earth
Vertebrates have great disparity, a wide range of differences within the group

2. (sister group to chordates)
Fig. 34-2
Echinodermata
(sister group to chordates)
Cephalochordata
(lancelets)
ANCESTRAL
DEUTERO-
STOME
Chordates
Urochordata
(tunicates)
Notochord
Myxini
(hagfishes)
Common
ancestor of
chordates
Craniates
Petromyzontida
(lampreys)
Head
Chondrichthyes
(sharks, rays, chimaeras)
Vertebrates
Vertebral column
Actinopterygii
(ray-finned fishes)
Gnathostomes
Jaws, mineralized skeleton
Actinistia
(coelacanths)
Osteichthyans
Lungs or lung derivatives
Figure 34.2 Phylogeny of living chordates
Lobe-fins
Dipnoi
(lungfishes)
Lobed fins
Amphibia (frogs,
salamanders)
Legs
Reptilia
(turtles, snakes,
crocodiles, birds)
Tetrapods
Amniotes
Amniotic egg
Mammalia
(mammals)
Milk

3. Derived Characters of Chordates
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
Dorsal, hollow nerve cord
Pharyngeal slits or clefts
Muscular, post-anal tail

4. Dorsal, hollow nerve cord Pharyngeal slits or clefts Muscular,
Fig. 34-3
Dorsal,
hollow
nerve cord
Muscle
segments
Notochord
Mouth
Figure 34.3 Chordate characteristics
Anus
Pharyngeal
slits or clefts
Muscular,
post-anal tail

5. Notochord
The notochord is a longitudinal, flexible rod between the digestive tube and nerve cord
It provides skeletal support throughout most of the length of a chordate
In most vertebrates, a more complex, jointed skeleton develops, and the adult retains only remnants of the embryonic notochord

6. Dorsal, Hollow Nerve Cord
The nerve cord of a chordate embryo develops from a plate of ectoderm that rolls into a tube dorsal to the notochord
The nerve cord develops into the central nervous system: the brain and the spinal cord

7. Pharyngeal Slits or Clefts
In most chordates, grooves in the pharynx called pharyngeal clefts develop into slits that open to the outside of the body
Functions of pharyngeal slits:
Suspension-feeding structures in many invertebrate chordates
Gas exchange in vertebrates (except vertebrates with limbs, the tetrapods)
Develop into parts of the ear, head, and neck in tetrapods

8. Muscular, Post-Anal Tail
Chordates have a tail posterior to the anus
In many species, the tail is greatly reduced during embryonic development
The tail contains skeletal elements and muscles
It provides propelling force in many aquatic species

9. Oh, look… your first baby picture!
Chordata
Vertebrates
fish, amphibians, reptiles, birds, mammals
internal bony skeleton
backbone encasing spinal column
skull-encased brain
deuterostome
hollow dorsal
nerve cord
becomes brain & spinal cord
becomes gills or Eustachian tube
Oh, look… your first baby picture!
pharyngeal
pouches
becomes vertebrae
postanal
tail
becomes tail or tailbone
notochord

10. Lancelets
Lancelets (Cephalochordata) are named for their bladelike shape
They are marine suspension feeders that retain characteristics of the chordate body plan as adults

11. Cirri 2 cm Mouth Pharyngeal slits Atrium Notochord Digestive tract
Fig. 34-4
Cirri
2 cm
Mouth
Pharyngeal slits
Atrium
Notochord
Digestive tract
Atriopore
Dorsal, hollow
nerve cord
Segmental
muscles
Figure 34.4 The lancelet Branchiostoma, a cephalochordate
Anus
Tail

12. Tunicates
Tunicates (Urochordata) are more closely related to other chordates than are lancelets
They are marine suspension feeders commonly called sea squirts
As an adult, a tunicate draws in water through an incurrent siphon, filtering food particles

13. Tunicates most resemble chordates during their larval stage, which may last only a few minutes
Incurrent
siphon
to mouth
Water flow
Notochord
Dorsal, hollow
nerve cord
Excurrent
siphon
Excurrent
siphon
Tail
Excurrent
siphon
Atrium
Muscle
segments
Incurrent
siphon
Pharynx
with
slits
Figure 34.5 A tunicate, a urochordate
Intestine
Anus
Stomach
Tunic
Intestine
Atrium
Esophagus
Pharynx with slits
An adult tunicate
Stomach
A tunicate larva

14. Early Chordate Evolution
Ancestral chordates may have resembled lancelets
Genome sequencing of tunicates has identified genes shared by tunicates and vertebrates
Gene expression in lancelets holds clues to the evolution of the vertebrate form

15. Craniates: chordates with a head
The origin of a head opened up a completely new way of feeding for chordates: active predation
Craniates share some characteristics: a skull, brain, eyes, and other sensory organs

16. Derived Characters of Craniates
Craniates have two clusters of Hox genes; lancelets and tunicates have only one cluster
Neural crest, a collection of cells near the dorsal margins of the closing neural tube in an embryo
Neural crest cells give rise some of the bones and cartilage of the skull

17. Dorsal edges of neural plate Neural crest Neural tube Migrating neural
Fig. 34-7
Dorsal edges
of neural plate
Neural
crest
Neural
tube
Migrating neural
crest cells
Figure 34.7 The neural crest, embryonic source of many unique craniate characters
Notochord

18. In aquatic craniates the pharyngeal clefts evolved into gill slits
Craniates have a higher metabolism and are more muscular than tunicates and lancelets
Craniates have a heart with at least two chambers, red blood cells with hemoglobin, and kidneys

19. Hagfishes
The least derived surviving craniate lineage is Myxini, the hagfishes
Hagfishes have a cartilaginous skull and axial rod of cartilage derived from the notochord, but lack jaws and vertebrae

20. Fig. 34-9
Slime glands
Figure 34.9 A hagfish

21. Vertebrates are craniates that have a backbone
During the Cambrian period, a lineage of craniates evolved into vertebrates
Vertebrates became more efficient at capturing food and avoiding being eaten

22. Derived Characters of Vertebrates
Vertebrates have the following derived characters:
Vertebrae enclosing a spinal cord
An elaborate skull
Fin rays, in the aquatic forms

23. Lampreys
Lampreys (Petromyzontida) represent the oldest living lineage of vertebrates
They are jawless vertebrates inhabiting various marine and freshwater habitats
They have cartilaginous segments surrounding the notochord and arching partly over the nerve cord

24. Fig
Figure A sea lamprey

25. Origins of Bone and Teeth
Mineralization appears to have originated with vertebrate mouthparts
The vertebrate endoskeleton became fully mineralized much later

26. Gnathostomes are vertebrates that have jaws
Today, jawed vertebrates, or gnathostomes, outnumber jawless vertebrates
Gnathostomes have jaws that might have evolved from skeletal supports of the pharyngeal slits

27. Gill slits Cranium Mouth Skeletal rods Fig. 34-13-3
Figure Hypothesis for the evolution of vertebrate jaws

28. Other characters common to gnathostomes:
An additional duplication of Hox genes
An enlarged forebrain associated with enhanced smell and vision
In aquatic gnathostomes, the lateral line system, which is sensitive to vibrations

29. Vertebrates: Fish Characteristics body structure body function
salmon, trout, sharks
450 mya
Vertebrates: Fish
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

30. Chondrichthyans (Sharks, Rays, and Their Relatives)
Chondrichthyans (Chondrichthyes) have a skeleton composed primarily of cartilage
The cartilaginous skeleton evolved secondarily from an ancestral mineralized skeleton
The largest and most diverse group of chondrichthyans includes the sharks, rays, and skates

31. Most sharks Have a streamlined body and are swift swimmers
Are carnivores
Have a short digestive tract; a ridge called the spiral valve increases the digestive surface area
Have acute senses

32. Shark eggs are fertilized internally but embryos can develop in different ways:
Oviparous: eggs hatch outside the mother’s body
Ovoviviparous: the embryo develops within the uterus and is nourished by the egg yolk
Viviparous: the embryo develops within the uterus and is nourished through a yolk sac placenta from the mother’s blood

33. Ray-Finned Fishes and Lobe-Fins
The vast majority of vertebrates belong to a clade of gnathostomes called Osteichthyes
Osteichthyes includes the bony fish and tetrapods

34. Nearly all living osteichthyans have a bony endoskeleton
Aquatic osteichthyans are the vertebrates we informally call fishes
Most fishes breathe by drawing water over gills protected by an operculum
Fishes control their buoyancy with an air sac known as a swim bladder

35. Tetrapods are gnathostomes that have limbs
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
Tetrapods have some specific adaptations:
Four limbs, and feet with digits
Ears for detecting airborne sounds

36. Transition to Land Evolution of tetrapods Lobe-finned fish
Tibia
Femur
Fibula
Humerus
Shoulder
Radius
Ulna
Pelvis
Lobe-finned fish
Early amphibian

37. Bones supporting gills Tetrapod limb skeleton Fig. 34-19
Figure Acanthostega, a Devonian relative of tetrapods
Tetrapod
limb
skeleton

38. Vertebrates: Amphibian
350 mya
frogs
salamanders toads
Vertebrates: Amphibian
lung
buccal
cavity
glottis
closed
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)

39. Amniotes are tetrapods that have a terrestrially adapted egg
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

40. Chorion Allantois Amnion Yolk sac Embryo Amniotic cavity with amniotic
Fig
Chorion
Allantois
Amnion
Yolk sac
Embryo
Amniotic
cavity
with
amniotic
fluid
Yolk
(nutrients)
Figure The amniotic egg
Shell
Albumen

41. Vertebrates: Reptiles
250 mya
dinosaurs, turtles
lizards, snakes
alligators, crocodile
Vertebrates: Reptiles
Characteristics
body structure
dry skin, scales, armor
body function
lungs for gas exchange
thoracic breathing; negative pressure
most have a three-chambered heart
ectotherms
reproduction
internal fertilization
external development in amniotic egg
embryo
leathery
shell
chorion
allantois
yolk sac
amnion

42. Vertebrates: Birds (Aves)
150 mya
finches, hawk
ostrich, turkey
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
trachea
anterior
air sacs
lung
posterior

43. The Origin of Birds
Birds probably descended from small theropods, a group of carnivorous dinosaurs
By 150 million years ago, feathered theropods had evolved into birds
Archaeopteryx remains the oldest bird known

44. Toothed beak Wing claw Airfoil wing with contour feathers
Fig
Toothed beak
Wing claw
Figure Artist’s reconstruction of Archaeopteryx, the earliest known bird
Airfoil wing
with contour
feathers
Long tail with
many vertebrae

45. Living Birds Living birds belong to the clade Neornithes
Several groups of birds are flightless
The ratites, order Struthioniformes
Penguins, order Sphenisciformes
Certain species of rails, ducks, and pigeons

46. The demands of flight have rendered the general body form of many flying birds similar to one another
Foot structure in birds shows considerable variation

47. Finger 1 (b) Bone structure Palm (a) Wing Finger 2 Finger 3 Forearm
Fig
Finger 1
(b) Bone structure
Palm
(a) Wing
Finger 2
Finger 3
Forearm
Wrist
Figure Form fits function: the avian wing and feather
Shaft
Shaft
Barb
Vane
Barbule
Hook
(c) Feather structure

48. Vertebrates: Mammals Characteristics body structure body function
220 mya / 65 mya
mice, ferret
elephants, bats whales, humans
Vertebrates: Mammals
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
muscles
contract
diaphragm
contracts

49. Derived Characters of Mammals
Mammals, class Mammalia, are represented by more than 5,300 species
Mammals have
Mammary glands, which produce milk
Hair
A larger brain than other vertebrates of equivalent size
Differentiated teeth

50. Vertebrates: Mammals Sub-groups monotremes marsupials placental
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 & waste filter
shrews, bats, whales, humans

51. Fig b
Figure Mammalian diversity

52. 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?