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2. Reversal Homoplasy
The Case of Tetrapods

3. Figure 28.4 Where Do Whales Belong on the Tree of Life?
(a) Data set 1 (morphological traits): Whales diverged before the origin of artiodactyls.
(b) Data set 2 (DNA sequences): Whales and hippos share a common ancestor.
Perissodactyls (horses and rhinos)
Perissodactyls (horses and rhinos)
ARTIODACTYLS
Whale
Camel
ARTIODACTYLS
Camel
Peccary
Gain of pulley- shaped astragalus
Peccary
Pig
Gain of pulley-shaped astragalus
Pig
Hippo
Hippo
Whale
Loss of pulley- shaped astragalus
Astragalus (ankle bone)
Deer
Deer
Figure 28.4 Where Do Whales Belong on the Tree of Life?
Cow
Cow
(c) Data set 3 (presence and absence of SINEs): Supports the close relationship between whales and hippos.
Locus
1  SINE present
0  SINE absent
?  still undetermined
Cow
Deer
Whale
Whales and hippos share four unique SINEs (4, 5, 6, and 7)
Hippo
Pig
Peccary
Camel 3

4. Figure 28.4b Where Do Whales Belong on the Tree of Life?
Cow
Deer
Whale
Hippo
Pig
Peccary
Camel
Loss of pulley- shaped astragalus
Gain of pulley- shaped astragalus
Perissodactyls (horses and rhinos)
ARTIODACTYLS
Figure 28.4b
Figure 28.4b Where Do Whales Belong on the Tree of Life?
(c) Data set 3 (presence and absence of SINEs): Supports the close relationship between whales and hippos.
1  SINE present
0  SINE absent
?  still undetermined
Whales and hippos share four unique SINEs (4, 5, 6, and 7)
Cow
Deer
Whale
Hippo
Pig
Peccary
Camel
Locus 4

5. Vertebrate Clade Homeothermy (a homoplasy) Homeotherms are ?-phyletic

6. Vertebrate Clade Homeothermy (a homoplasy)
Homeotherms are polyphyletic
Reptiles are?

7. Reptiles are a grade (are paraphyletic)
Vertebrate Clade
Homeothermy
(a homoplasy)
Homeotherms are polyphyletic
Reptiles are a grade (are paraphyletic)

8. Time Distal elements and radius Ulna Humerus Tulerpeton (362 mya)
Figure 25.4
Distal
elements
and radius
Ulna
Humerus
Tulerpeton (362 mya)
Acanthostega (365 mya)
Figure 25.4 Transitional Features during the Evolution of the Tetrapod Limb.
Tiktaalik (375 mya)
Time
Fin rays
Eusthenopteron (385 mya) 8

9. Tetrapod Limb: Homologous Structures
Figure 25.9
Tetrapod Limb: Homologous Structures
Humerus
Radius
and ulna
Carpals
Metacarpals
Phalanges
Figure 25.9 Structural Homology: Limbs with Different Functions Have the Same Underlying Structure.
Turtle
Human
Horse
Bird
Bat
Seal
crawl type run arm-fly hand-fly swim 9

10. Tetrapod limbs are complex
Ball joint at girdle (pectoral or pelvic)
Proximal segment has one heavy bone
Hinge joint at elbow or knee
Distal segment has two bones for rotation of hand/foot
Small cuboidal bones at wrist and ankle for flexibility of hand/foot position
Long metacarpal/metatarsals for palm/instep
Phalanges for the digits (fingers/toes)

11. Tetrapod limbs are stereotypical
The complex structures are shared among these tetrapods:
Amphibians
Reptiles
Birds
Mammals
Conclusion: rather than evolving complex limb form and function separately and identically among all these groups of species (i.e., many homoplasies), the tetrapod leg design evolved just once in a common ancestor (i.e., more parsimonious)

12. Reversal of a complex trait is comparatively parsimonious
Forward evolution of a leg requires modification of:
Bones
Muscles
Connectives
Vascular Paths
Neural Paths
Reversal of a complex trait is comparatively parsimonious
Reversal could be just ONE point mutation in ONE gene that normally puts limb development into motion.
Without the first step, the rest does not happen.

13. Tetrapod evolution has been reversed multiple times!
Thus, it must be easily done… i.e. is parsimonious
Legless amphibians: caecilians
Legless lizards: glass lizards
Ajolote: mole lizards
Snakes
So some gene functioning early in tetrapod development can mutate (become defective), rendering some ancestral species (and its descendants) legless.
All the rest of the tetrapod genes that had evolved to make the limbs, are made useless by this one mutation.
The useless genes are still present, however! And can be documented.

14. terrestrial amphibians
Caecilians:
terrestrial amphibians

15. A photo of parent Caecilian with offspring
R635RmqosDI/AAAAAAAANYc/jwcNDv1suD4/flesh+eating+amphibian+caecilians%5B2%5D

16. http://www. unexplained-mysteries
This ajolote is a snake that reversed the reversal blocking only pectoral limbs (note: belly scale pattern and limb location)
Or it is a lizard that has lost only its pelvic limbs (reversal homoplasy)

17. There are also partial losses: the Boa has vestigial pelvic limbs
Of course the alternative interpretation is a partial reversal of loss

18. This is a verified reversal of a reversal:
This snake has reversed the reversal blocking pelvic limbs

19. Of course humans will make false claims!
This claim of pectoral limbs is clearly false:
This snake is in the act of swallowing a frog, NOT sprouting legs!

20. There are several clear examples of reversals of reversals but:
Has this snake reversed the reversal blocking pectoral limbs??

21. Is dark body a complex characteristic?
There are two possible explanations—
which is most parsimonious?
OG F E B A D C
dark --
body
-- dark bodyR
-- dark
bodyR
-- black eye
-- long wing
Two
Forward
Evolutions
-- wide neck
-- dark bodyR
-- long leg
-- dark body
-- large eye
A homoplasy of
parallelism or…
convergence
-- thick leg
-- wide body
A single evolution
But three reversals
-- dark body F
-- wide wing
-- long stinger
Is dark body a complex characteristic?
Maybe one enzyme!
Is it easier to evolve or to lose a characteristic?

22. Is dark body a complex characteristic?
There are two possible explanations—
which is most parsimonious?
OG F E B A D C
dark --
body
-- dark
bodyR
-- black eye
-- long wing
Two
Forward
Evolutions
-- wide neck
-- dark bodyR
-- long leg
-- dark body
-- large eye
A homoplasy of
parallelism or…
convergence
-- thick leg
-- wide body
A single evolution
But two reversals
-- dark body F
-- wide wing
-- long stinger
Is dark body a complex characteristic?
Maybe one enzyme!

23. And one fewer step! Maybe one enzyme!
There are two possible explanations—
which is most parsimonious?
OG F E B A D C
dark --
body
-- black eye
-- long wing
Two
Forward
Evolutions
-- wide neck
-- long leg
-- dark body
-- large eye
A homoplasy of
parallelism or…
convergence
-- thick leg
-- wide body F
And one fewer step!
-- wide wing
-- long stinger
Maybe one enzyme!

24. In other words, is the MOST PARSIMONIOUS!
Make sure your homework cladogram (Page 6) is solved:
applying the homoplasy to the simplest character
uses the fewest steps, and
uses a forward and a reverse rather than two forward evolutionary steps!!
In other words, is the MOST PARSIMONIOUS!