1. Vertebrate Biology
Chapter 34

2. Classification Phylum Chordata Subphylum Urochordata Subphylum
Cephalochordata
Subphylum
Vertebrata
lancets
Agnathans
Fish
Sharks
tetrapods
tunicates

4. Chordate Characteristics

5. Burgess Shale Fauna (540 MYBP)
Pikaia- earliest known chordate

6. Possible evolution of 1st fish
lancelet
Proto-vertebrate
Tunicate larvae
Adult tunicate

7. Adult tunicate
Larval tunicate
Amphioxus

8. Geologic Time Scale end of dinosaurs 1st dinosaur 1st reptiles
Millions of Years
end of dinosaurs
1st dinosaur
1st reptiles
1st amphibians
1st land plants
1st fish
1st invertebrates

10. Class Agnatha, the jawless fishes
Class Agnatha, the jawless fishes Subclass (or order) Cyclostomata, the lampreys and hagfishes.
Class Chondrichthyes, the cartilaginous-skeleton fishes Subclass Holocephali, the chimaeras, or ratfishes Subclass Elasmobranchii, the sharks, skates, and rays
Class Placodermi
Class Acanthodii
Class Osteichthyes, the bony fishes Subclass Actinopterygii, the ray-finned fishes Superorder Chondrostei, the primitive ray-finned bony fishes: sturgeons, paddlefish, and bichirs Superorder Holostei or Neopterygii, the intermediate ray-finned fishes: gars and the bowfin Superorder Teleostei or Neopterygii, the advanced bony fishes: herring, salmon, perch.
Subclass Crossopterygii, the coelacanth Subclass Dipnoi or Dipneusti, the lungfishes

11. Evolution of Jaws in fish
chondocranium
palatoquadrate
Hyomandibular arch
Meckel’s cartilage
all gill arches derived from neural crest ectoderm
all other cartilage in the body is derived from mesoderm
ossifymoves gills forward and add teeth
epibranchialbecomes upper jaw = palatoquadrate
ceratobranchiallower jaw = mandibular bone
epibranchial and ceratobranchial fused to form hyomandibular arch (which ossified) and supports lower jaw
 recent evidence suggests that the 3rd gill arch became the jaw and the 4th arch became the hyomandibular
the 1st two gill arches became part of the cranium (the 1st may have disappeared, the 2nd definitely became part of the cranium
agnathostome
gnathostome
1st appeared 400 mya

12. Class Agnatha Lack jaws, paired fins, scales
Possess medial nostril, medial fins, notocord rather than vertebral column
Heterostracans are represented by nearly 300 species. They were marine but lived in sandy lagoons or deltas. Some species, however, are regarded as fresh water. They are known exclusively from North America, Europe and Siberia. They probably fed by scraping the bottom with their fan-shaped oral plates that armed their lower lip. They were poor swimmers and probably bottom-dewellers. It has been suggested that their posteriorly placed common gill opening could serve as a jet propulsion device and that made them moved like Cousteau''s diving saucer.
Although most heterostracans are relatively small (5 to 30 cm in total length), some of them, the Psammosteidae, could grow to a very large size (up to 1.5 m in length) and developed steer-like branchial plates.
The heterostracan head armor comprises large ventral and dorsal shields and a variable number of separate plates, laterally (cornual, branchial plates) and around the mouth (oral, postoral, orogonal plates). In some taxa (Pteraspidiformes, Traquairaspidiformes), the dorsal shield can be compound of several distinct plates (orbital, pineal, rostral), but there always remains a large median dorsal "disk".
Since heterostracans have no calcified endoskeleton, their internal anatomy is only known from the impressions of the internal organs on the internal surface of the dermal armor. One may trace the impressions of the brain, gills, eyeballs, paired olfactory organ, and two distinct vertical semicircular canals of the labyrinth. Although paired, the olfactory organs seem to have opened ventrally into a large, median inhalent duct, as in extant hagfishes (see Hyperotreti).
Ostracoderm
400 mya
heterostracan

13. Hagfish

14. Hagfish characteristics
Strictly marine
No bone
Rasping tongue
Eyes degenerate, covered by skin; no pineal; single pair of semicircular canals
No lateral line organs
5-15 pair gills
Partial open circulatory system
Holonephros and neotenic pronephros
Numerous slime glands in skin, secrete copious amounts of mucus;
Separate sexes, but all individuals have ovitestis,
Eggs deposited at sea; direct development; totally marine

15. Lamprey

16. Lamprey Characteristics
Oral disc/buccal funnel, with epidermal denticles and rasping tongue; active "predatory parasites”
No bone
Nostril on top of head
Well-developed vertebrate eyes
Well-developed Lateral Line system
Best developed pineal “eye” of any aquatic vertebrate;
2 pairs of semicircular canals;
Uniformly 7 pairs of gills
Cranium cartilaginous, open on top
Opisthonephros
Eggs deposited in freshwater; freshwater larva; many species have freshwater adult, but most migrate to sea and have marine adult stage (anadromous).

17. Class
Chondrichthyes
Posses jaws with teeth, cartilaginous skeleton, paired fins
Scales (denticles) have same origin and composition as teeth
Possesses 5-7 gills
Spiral valve intestine
Ureoosmotic strategy
Lateral line
No swim bladder
Heterocercal tail
Relatively unchanged (480 mybp)
Placoid scales

18. Basic Shark Anatomy

19. Class
Chondrichthyes

20. Class Placodermi Totally fossil, early jawed fishes;
Bony armor usually present around head-trunk, generally flattened body, tend to be bottom-adapted with eyes rather dorsal (other various designs);
No true teeth
Notochord persistent, un-constricted.

21. Class Placodermi

23. Class Osteichthyes Posses jaws with teeth bony skeleton paired fins
4 paired gill arches covered by operculum
Intestine- simple, no spiral valve
Swim bladder
Lateral line
Homocercal tail
Scales- cycloid, ctenoid, ganoid

24. Basic Fish Structure

25. Superorder Chondrostei
sturgeon
paddlefish
ganoid scales (don’t form rings as they grow)
heterocercal tail
persistent notochord; centra absent or cartilage rings
large mouth, long maxilla attached at rear
open spiracle

26. Superorder Holostei gar L.Permian-Recent, but mostly Juras. & Cretac.;
Abbreviated heterocercal tail, often symmetric caudal fin;
Ganoid or cycloid scales
Single dorsal swim bladder, hydrostatic & respiratory; physostomous;
No open spiracle
Vertebral centra often at least partly ossified, constricting persistent notochord;
More modernized jaws (than Chondrosteans) - maxilla shorter, free at rear; shorter mouth

27. Superorder Holostei
bowfin

28. Superorder Teleostei

29. Fish Diversity
680 species of fish in the islands' waters.
About 30% of these fish are endemic to the area .

30. White mouthed morey Achilles tang trumpetfish Domino damsel
Trigger (Humu)
White mouthed
morey
Porcupine
Dwarf moray
Achilles tang
trumpetfish

31. Subclass Crossopterygii
Latimeria
Swim bladder modified to lungs
Paired appendages
May have given rise to terrestrial tetrapods
Bony head
Scales and teeth

32. Coelacanth
Thought to be extinct 80 million years ago Found in 1938 off the coast of the Comoro Islands

33. Coelacanth Anatomy

34. Subclass Dipnoi Lungfish
While there are seven families of fossil lungfish known, only two survived into the Triassic (and still exist today). There are only three genera of lungfish alive today and each is found on a single continent. The Australian lungfish is Neoceratodus; in South America lives Leipdosiren; and Protopterus lives in Africa. The largest of these is the Australian species, which may grow to as long as 1.8 meters. Though Neoceratodus today is found only in Australia, fossils of that genus and the related Ceratodus have been found almost worldwide in Mesozoic strata, indicating that this group once had a much wider distribution.
Lungfish are believed to be the closest living relatives of the tetrapods, and share a number of important characteristics with them. Among these characters are tooth enamel, separation of pulmonary blood flow from body blood flow, arrangement of the skull bones, and the presence of four similarly sized limbs with the same position and structure as the four tetrapod legs. However, there is still debate about the relationships among the Sarcopterygii.
Lungfish

35. Acanthostega Foot of Acanthostega had 8 digits 360 mya
                           
Among the most primitive early tetrapods is Acanthostega, from freshwater sediments deposited during the Late Devonian of Greenland (a cold and dry region today, but a warm, moist equatorial setting during the Devonian). As compared to Eusthenopteron and Panderichthys, a major development in Acanthostega is in the modification of bony fins to form a limb with digits (8 fingers were found on a preserved forelimb). Significantly, the pectoral girdle has become detached from the skull (so that crawling would not be such a "mind jarring" experience), and the pelvic girdle is attached to the vertebral column by means a specialized sacral (hip) vertebra for greater support and more efficient locomotion.
However, Acanthostega still posseses many primitive, fish-like characteristics. The vertebrae are delicate, with only weakly developed ribs and largely without well developed zygapophyses (processes that interlock adjacent vertebrae in terrestrial tetrapods). The sacral vertebra is not strongly differentiated from adjacent vertebrae, and the hip girdle is relatively small. It does not seem that Acanthostega could have supported itself on land for any great length of time, and that the limbs were primarily, perhaps exclusively, useful for locomotion in shallow water (where it is more efficient to crawl rather than swim). In this respect, it might have lived in a manner similar to the living giant salamander seen in the video (and which Acanthostega resembled in bodily proportions). The tail supported a caudal fin for propulsion in deeper water. In view of the skull, the external naris of Acanthostega is small, suggesting that, like Eusthenopteron, it was primarily a mouth breather. A preoperculum (one of the opercular series of bones found in osteichthyans) is still present. Bones on the interior of the skull and hip girdle are channeled, suggesting that in life they harbored blood vessels which would have connected to a set of internal gills that were reduced as compared to osteolepiforms, but still functional.
Foot of Acanthostega had 8 digits
360 mya

36. Acanthostega First complete tetrapod with free digits
- eight digits on each hand
Retained “fishy” characters:
gills
tail fin
Partial connection between skull and pectoral girdle
Labyrinthodont teeth
Lateral line
Ulna shorter than radius

37. Ichthyostega Transition fossil from fw Crossopterygian to tetrapod
Ichthyostega (also from the Late Devonian of Greenland), retains a fish-like caudal fin, but exhibits morphology that is better adapted for terrestrial walking as compared to Acanthostega. The ribs of Ichthyostega are long, thick, and supportive, but their overlapping nature would have limited the range of lateral motion considerably. The limbs, hip girdle, and vertebrae are more stoutly constructed than are those of Acanthostega, and the vertebrae possess more strongly developed zygapophyses (so they could work together to produce a supporting framework). These traits indicate Ichthyostega spent considerable time out of the water in between fishing forays. The forelimbs appear to be larger than the hindlimbs, and it has been suggested that terrestrial locomotion in Ichthyostega was similar to that seen in modern sea lions (which wiggle back and forth with their powerful fore-flippers). The hindlimb bears 7 toes; Ichthyostega, Acanthostega, and a few other early tetrapods (all Devonian) are the only representatives that possess more than five digits.
It does not appear that any of the first terrestrial vertebrates were specialists for utilizing plants or insects as a potential food source, for they retain the relatively large body size and needle-like teeth of the sarcopterygians, indicating a diet of fish (which are difficult to catch, but can generally be swallowed whole). Nevertheless, coming onto land would have provided Ichthyostega and more advanced tetrapods with three primary advantages over strictly aquatic life. 1) As was the case with plants, land offered a refuge from predators. 2) Basking in the sun provides warm internal temperatures that would produce faster and more efficient digestion of food. 3) Early terrestrial tetrapods could deposit their fish-like eggs into isolated pools of freshwater (lakes and ponds). The developing young would then grow in an environment free from large predators and filled with potential food (larval insects).

38. Ichthyosetga Much like Acanthostega, but…
- stronger limbs; radius & ulna of equal length
- no gills in adults
- reduced number of skull bones
Still retains panderichthyid-like skull, tail fin, labrinthodont teeth, lateral line
First tetrapod known that was capable of life on land

39. Class Amphibia
Rana cancrivora

41. Amniotic Egg

42. Class Reptilia Saltwater crocodile Marine iguana Marine turtle
Sea snake

43. Phylogeny of the Amniotes
Therapsids
Anapsids
Diapsids
Synapsids
Sauropsids
Ancestral amniote

44. Archaeopteryx

45. Ratites
                                                                  
Carinate

46. Class Aves

47. The skeletons of birds have several adaptations that make them light, flexible, but strong.
The bones are honeycombed to reduce weight without sacrificing much strength.

48. Class Mammalia Polar bear Whales & Dolphins hair or fur mammary glands
endothermic
Sea otter
manatee
Seals & sealions
Dugong

49. Evolution of the mammalian jaw and ear bones

50. Therapsid (mammal-like reptile)

51. Prototherians (Monotremes): Cretaceous-Recent
Egg-laying, aquatic predators on arthropods and worms
Milk oozes from the skin (no breasts).
Hair
Ear bones shift from lower jaw to skull during embryonic development.
Electroreception

52. Metatheria (Marsupials): Cretaceous-Recent
Pouched mammals.
Born as gross little embryos.  Crawl into pouch, attach to nipple, and develop.
Cretaceous ones were fairly opossum-like in their ecology.  Later ones are more diverse.
Today, they are most diverse on Australia and South America.
They share complex type of molar tooth shape with Placental mammals.

53. Eutheria (Placentals): Cretaceous-Recent
Nourish their young internally with a placenta
Placentals give birth to offspring that are more "adult" like and independent. Cretaceous ones were shrew-like in their ecology. 
Later placentals are spectacularly diverse.

56. Copyright © 2002 Pearson Education, Inc
Copyright © 2002 Pearson Education, Inc., publishing as Benjamin Cummings

57. Copyright © 2002 Pearson Education, Inc
Copyright © 2002 Pearson Education, Inc., publishing as Benjamin Cummings

58. Copyright © 2002 Pearson Education, Inc
Copyright © 2002 Pearson Education, Inc., publishing as Benjamin Cummings

59. Copyright © 2002 Pearson Education, Inc
Copyright © 2002 Pearson Education, Inc., publishing as Benjamin Cummings

60. The current hypothesis, based on molecular systematics, for the evolutionary relationships among eutherian orders clusters them into four main clades.
Fig
Copyright © 2002 Pearson Education, Inc., publishing as Benjamin Cummings

62. Human Evolution

64. Multiregional Model- modern humans evolved in parallel in different parts of the world

65. Multiregional Model

66. African Origins Model- modern humans evolved in Africa and dispersed to different parts of the world

67. African Origins Model
Homo erectus
Homo sapiens