1. Phylogeny and the Tree of Life
Chapter 26
Phylogeny and the Tree of Life

2. Overview: Investigating the Tree of Life
Legless lizards have evolved independently in several different groups
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3. Figure 26.1
Figure 26.1 What is this organism?

4. _______________ is the evolutionary history of a species or group of related species
The discipline of ____________ classifies organisms and determines their evolutionary relationships
Systematists use ________________________ _______________________to infer evolutionary relationships
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5. Figure 26.2
Figure 26.2 An unexpected family tree.

6. Concept 26.1: Phylogenies show evolutionary relationships
________________ is the ordered division and naming of organisms
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7. Binomial Nomenclature
In the 18th century, __________________ published a system of taxonomy based on resemblances
Two key features of his system remain useful today: _____________________ and _____________________ classification
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8. The two-part scientific name of a species is called a ________________
The first part of the name is the __________
The second part, called the ______________, is unique for each species within the genus
The first letter of the genus is ___________, and the entire species name is ______________
Both parts together name the __________ (not the specific epithet alone)
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9. Hierarchical Classification
Linnaeus introduced a system for grouping species in increasingly broad categories
The taxonomic groups from broad to narrow are _______________________________________ ___________________
A taxonomic unit at any level of hierarchy is called a ___________
The broader taxa are _______________ between lineages
For example, an order of snails has less genetic diversity than an order of mammals
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10. Species: Panthera pardus Genus: Panthera Family: Felidae Order:
Figure 26.3
Species:
Panthera pardus
Genus:
Panthera
Family:
Felidae
Order:
Carnivora
Class:
Mammalia
Figure 26.3 Linnaean classification.
Phylum:
Chordata
Kingdom:
Animalia
Domain:
Bacteria
Domain:
Archaea
Domain:
Eukarya

11. Linking Classification and Phylogeny
Systematists depict evolutionary relationships in branching __________________
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12. Order Family Genus Species Panthera pardus (leopard) Felidae Panthera
Figure 26.4
Order
Family
Genus
Species
Panthera
pardus
(leopard)
Felidae
Panthera
Taxidea
taxus
(American
badger)
Taxidea
Carnivora
Mustelidae
Lutra lutra
(European
otter)
Lutra
Figure 26.4 The connection between classification and phylogeny.
Canis
latrans
(coyote)
Canidae
Canis
Canis
lupus
(gray wolf)

13. Linnaean classification and phylogeny _________ from each other
Systematists have proposed the ____________, which recognizes only groups that include a ____________________ and all its descendants
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14. Each ______________ represents the divergence of two species
A phylogenetic tree represents a __________ about evolutionary relationships
Each ______________ represents the divergence of two species
_______________ are groups that share an immediate common ancestor
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15. A ______________ is a branch from which more than two groups emerge
A ______________tree includes a branch to represent the last common ancestor of all taxa in the tree
A ______________ diverges early in the history of a group and originates near the common ancestor of the group
A ______________ is a branch from which more than two groups emerge
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16. where lineages diverge Taxon A
Figure 26.5
Branch point:
where lineages diverge
Taxon A
Taxon B
Sister
taxa
Taxon C
Taxon D
Taxon E
ANCESTRAL
LINEAGE
Taxon F
Figure 26.5 How to read a phylogenetic tree.
Basal
taxon
Taxon G
This branch point
represents the
common ancestor of
taxa A–G.
This branch point forms a
polytomy: an unresolved
pattern of divergence.

17. What We Can and Cannot Learn from Phylogenetic Trees
Phylogenetic trees show __________________, not phenotypic similarity
Phylogenetic trees do not indicate _______ species evolved or _______________________ occurred in a lineage
It ______________ be assumed that a taxon evolved from the taxon next to it
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18. Applying Phylogenies
Phylogeny provides important information about __________________ in closely related species
A phylogeny was used to identify the species of whale from which “whale meat” originated
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19. Minke (Southern Hemisphere)
Figure 26.6
RESULTS
Minke (Southern Hemisphere)
Unknowns #1a, 2, 3, 4, 5, 6, 7, 8
Minke (North Atlantic)
Unknown #9
Humpback (North Atlantic)
Humpback (North Pacific)
Unknown #1b
Gray
Figure 26.6 Inquiry: What is the species identity of food being sold as whale meat?
Blue
Unknowns #10, 11, 12
Unknown #13
Fin (Mediterranean)
Fin (Iceland)

20. Concept 26.2: Phylogenies are inferred from morphological and molecular data
To infer phylogenies, systematists gather information about _________________________ ______________________of living organisms
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21. Morphological and Molecular Homologies
Phenotypic and genetic similarities due to shared ancestry are called ___________________
Organisms with similar _____________________ sequences are likely to be more closely related than organisms with different structures or sequences
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22. Sorting Homology from Analogy
When constructing a phylogeny, systematists need to distinguish whether a similarity is the result of homology or ______________
___________ is similarity due to shared ancestry
___________ is similarity due to convergent evolution
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23. ___________________ occurs when similar environmental pressures and natural selection produce similar (analogous) adaptations in organisms from different evolutionary lineages
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24. Figure 26.7
Figure 26.7 Convergent evolution of analogous burrowing characteristics.

25. Bat and bird wings are ______________ as forelimbs, but _____________as functional wings
Analogous structures or molecular sequences that evolved independently are also called _________________
Homology can be distinguished from analogy by comparing ________________and the degree of _______________
The more complex two similar structures are, the more likely it is that they are _________________
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26. Evaluating Molecular Homologies
Systematists use _____________________ and ___________________ when analyzing comparable DNA segments from different organisms
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27. 1 1 2 Deletion 2 1 2 Insertion 3 1 2 4 1 2 Figure 26.8-4
Figure 26.8 Aligning segments of DNA. 2 4 1 2

28. It is also important to distinguish homology from analogy in _________________similarities
Mathematical tools help to identify molecular __________________, or coincidences
_______________________ uses DNA and other molecular data to determine evolutionary relationships
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29. Concept 26.3: Shared characters are used to construct phylogenetic trees
Once homologous characters have been identified, they can be used to infer a __________
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30. Cladistics _________ groups organisms by common descent
A __________ is a group of species that includes an ancestral species and all its descendants
Clades can be nested in larger clades, but not all groupings of organisms qualify as clades
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31. A valid clade is ______________, signifying that it consists of the ancestor species and all its descendants
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32. (a) Monophyletic group (clade)
Figure 26.10a
(a) Monophyletic group (clade) A B
Group  C D
Figure Monophyletic, paraphyletic, and polyphyletic groups. E F G

33. A ______________ grouping consists of an ancestral species and some, but not all, of the descendants
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34. (b) Paraphyletic group
Figure 26.10b
(b) Paraphyletic group A B C D
Figure Monophyletic, paraphyletic, and polyphyletic groups. E
Group  F G

35. A __________________ grouping consists of various species with different ancestors
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36. (c) Polyphyletic group
Figure 26.10c
(c) Polyphyletic group A B
Group  C D
Figure Monophyletic, paraphyletic, and polyphyletic groups. E F G

37. Shared Ancestral and Shared Derived Characters
In comparison with its ancestor, an organism has both _________ and ___________ characteristics
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38. A __________________ is a character that originated in an ancestor of the taxon
A ______________________is an evolutionary novelty unique to a particular clade
A character ________________ ancestral and derived, depending on the context
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39. Inferring Phylogenies Using Derived Characters
When inferring evolutionary relationships, it is useful to know in which ___________ a shared derived character first appeared
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40. Figure 26.11
TAXA
Lancelet
(outgroup)
(outgroup)
Lancelet
Lamprey
Lamprey
Leopard
Bass
Frog
Turtle
Vertebral
column
(backbone) 1 1 1 1 1
Bass
Vertebral
column
Hinged jaws 1 1 1 1
Frog
Hinged jaws
Four walking
legs
CHARACTERS 1 1 1
Turtle
Four walking legs
Amnion 1 1
Figure Constructing a phylogenetic tree.
Amnion
Hair 1
Leopard
Hair
(a) Character table
(b) Phylogenetic tree

41. The outgroup is a group that has _____________ before the ingroup
An _______________ is a species or group of species that is closely related to the ___________, the various species being studied
The outgroup is a group that has _____________ before the ingroup
Systematists compare each ingroup species with the outgroup to differentiate between __________ __________ and ______________ characteristics
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42. Characters shared by the outgroup and ingroup are ___________________ that predate the divergence of both groups from a common ancestor
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43. Phylogenetic Trees with Proportional Branch Lengths
In some trees, the length of a branch can reflect the number of genetic changes that have taken place in a particular DNA sequence in that lineage
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44. Drosophila Lancelet Zebrafish Frog Chicken Human Mouse Figure 26.12
Figure Branch lengths can represent genetic change.
Human
Mouse

45. In other trees, branch length can represent chronological time, and branching points can be determined from the fossil record
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46. Drosophila Lancelet Zebrafish Frog Chicken Human Mouse 542 251 65.5
Figure 26.13
Drosophila
Lancelet
Zebrafish
Frog
Chicken
Human
Figure Branch lengths can indicate time.
Mouse
PALEOZOIC
MESOZOIC
CENOZOIC
542
251
65.5
Present
Millions of years ago

47. Maximum Parsimony and Maximum Likelihood
_____________can never be sure of finding the best tree in a large data set
They narrow possibilities by applying the principles of _________________________ and _________ ____________________
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48. _______________________ assumes that the tree that requires the fewest evolutionary events (appearances of shared derived characters) is the most likely
The principle of __________________ states that, given certain rules about how DNA changes over time, a tree can be found that reflects the most likely sequence of evolutionary events
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49. (a) Percentage differences between sequences
Figure 26.14
Human
Mushroom
Tulip
Human
30%
40%
Mushroom
40%
Tulip
(a) Percentage differences between sequences
15% 5% 5%
Figure Trees with different likelihoods.
15%
15%
10%
20%
25%
Tree 1: More likely
Tree 2: Less likely
(b) Comparison of possible trees

50. Computer programs are used to search for trees that are ______________________________
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51. Species  Species  Species           TECHNIQUE
Figure 26.15a
TECHNIQUE
Species 
Species 
Species  1
Figure Research Method: Applying parsimony to a problem in molecular systematics
Three phylogenetic hypotheses:  
 
 
  

52. TECHNIQUE Site 1 2 3 4 Species  C T A T Species  C T T C
Figure 26.15b
TECHNIQUE
Site 2 1 2 3 4
Species  C T A T
Species  C T T C
Species  A G A C
Figure Research Method: Applying parsimony to a problem in molecular systematics
Ancestral sequence A G T T

53. 3 4 TECHNIQUE RESULTS 6 events 7 events 7 events 1/C    1/C 
Figure 26.15c
TECHNIQUE 3
1/C  

1/C 
 
1/C
  
1/C
1/C 4
3/A
2/T
3/A  

2/T
3/A
4/C 
 
4/C
4/C
2/T
  
Figure Research Method: Applying parsimony to a problem in molecular systematics
3/A
4/C
2/T
4/C
2/T
3/A
RESULTS  
 
 
  
6 events
7 events
7 events

54. Phylogenetic Trees as Hypotheses
The best hypotheses for phylogenetic trees fit the most data: _______________________________
________________________ allows us to predict features of an ancestor from features of its descendants
For example, phylogenetic bracketing allows us to infer characteristics of dinosaurs
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55. Lizards and snakes Crocodilians Ornithischian dinosaurs Common
Figure 26.16
Lizards
and snakes
Crocodilians
Ornithischian
dinosaurs
Common
ancestor of
crocodilians,
dinosaurs,
and birds
Saurischian
dinosaurs
Figure A phylogenetic tree of birds and their close relatives.
Birds

56. The fossil record supports nest building and brooding in dinosaurs
Birds and crocodiles share several features: four-chambered hearts, song, nest building, and brooding
These characteristics likely evolved in a common ancestor and were shared by all of its descendants, including dinosaurs
The fossil record supports nest building and brooding in dinosaurs
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57. (b) Artist’s reconstruction of the dinosaur’s
Figure 26.17
Front limb
Hind limb
Figure Fossil support for a phylogenetic prediction: Dinosaurs built nests and brooded their eggs.
Eggs
(a) Fossil remains of
Oviraptor and eggs
(b) Artist’s reconstruction of the dinosaur’s
posture based on the fossil findings

58. Concept 26.4: An organism’s evolutionary history is documented in its genome
Comparing _______________ or other ________ to infer relatedness is a valuable approach for tracing organisms’ evolutionary history
_______ that codes for __________ changes relatively slowly and is useful for investigating branching points hundreds of millions of years ago
__________ evolves _____________ and can be used to explore recent evolutionary events
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59. Gene Duplications and Gene Families
___________________ increases the number of genes in the genome, providing more opportunities for evolutionary changes
Repeated gene duplications result in __________ _____________________
Like homologous genes, ___________________ can be traced to a common ancestor
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60. They can diverge only after speciation occurs
Orthologous genes are found in a single copy in the genome and are homologous between species
They can diverge only after speciation occurs
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61. Speciation with divergence of gene
Figure 26.18
Formation of orthologous genes:
a product of speciation
Formation of paralogous genes:
within a species
Ancestral gene
Ancestral gene
Ancestral species
Species C
Speciation with
divergence of gene
Gene duplication and divergence
Figure Two types of homologous genes.
Orthologous genes
Paralogous genes
Species A
Species B
Species C after many generations

62. __________________ result from gene duplication, so are found in more than one copy in the genome
They can ________________ within the clade that carries them and often evolve new functions
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63. Formation of paralogous genes: within a species
Figure 26.18b
Formation of paralogous genes:
within a species
Ancestral gene
Species C
Gene duplication and divergence
Figure Two types of homologous genes.
Paralogous genes
Species C after many generations

64. Genome Evolution
____________________ are widespread and extend across many widely varied species
For example, humans and mice diverged about 65 million years ago, and ______ of our genes are orthologous
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65. Gene number and the complexity of an organism are _____________________________
For example, humans have only _____________ as many genes as yeast, a single-celled eukaryote
Genes in complex organisms appear to be very ______________, and each gene can perform many functions
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66. Concept 26.5: Molecular clocks help track evolutionary time
To extend molecular phylogenies beyond the fossil record, we must make an assumption about ________________________________ over time
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67. Molecular Clocks
A ________________ uses constant rates of evolution in some genes to estimate the absolute time of evolutionary change
In __________________, nucleotide substitutions are proportional to the time since they last shared a common ancestor
In ___________________, nucleotide substitutions are proportional to the time since the genes became duplicated
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68. Individual genes vary in how clocklike they are
_______________________ are calibrated against branches whose dates are known from the fossil record
Individual genes vary in how clocklike they are
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69. Divergence time (millions of years)
Figure 26.19 90 60
Number of mutations 30
Figure A molecular clock for mammals. 30 60 90
120
Divergence time (millions of years)

70. Neutral Theory
__________________ states that much evolutionary change in genes and proteins has no effect on ___________ and is not influenced by natural selection
It states that the rate of molecular change in these genes and proteins should be ____________ like a clock
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71. Problems with Molecular Clocks
The molecular clock does not run as smoothly as neutral theory predicts
_______________result from natural selection in which some DNA changes are favored over others
Estimates of evolutionary divergences older than the fossil record have a high degree of _________
The use of ____________________ may improve estimates
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72. Applying a Molecular Clock: The Origin of HIV
Phylogenetic analysis shows that _________ is descended from viruses that infect chimpanzees and other primates
HIV spread to humans ___________________
Comparison of HIV samples shows that the virus evolved in a very _______________ way
Application of a molecular clock to one strain of HIV suggests that that strain spread to humans during the ____________
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73. Index of base changes between HIV gene sequences
Figure 26.20
0.20
0.15
HIV
Index of base changes between HIV gene sequences
0.10
Range
Adjusted best-fit line
(accounts for uncertain
dates of HIV sequences)
Figure Dating the origin of HIV-1 M with a molecular clock.
0.05
1900
1920
1940
1960
1980
2000
Year

74. Concept 26.6: New information continues to revise our understanding of the tree of life
Recently, we have gained insight into the very deepest branches of the tree of life through _______________________
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75. From Two Kingdoms to Three Domains
Early taxonomists classified all species as either _________________
Later, five kingdoms were recognized: _________ __________________________________________________________
More recently, the three-domain system has been adopted: __________________________
The three-domain system is supported by data from many sequenced Classification Schemes genomes
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76. Eukarya Bacteria Archaea Figure 26.21
Land plants
Dinoflagellates
Green algae
Forams
Ciliates
Diatoms
Red algae
Amoebas
Cellular slime molds
Euglena
Trypanosomes
Animals
Leishmania
Fungi
Sulfolobus
Green
nonsulfur bacteria
Thermophiles
(Mitochondrion)
Figure The three domains of life.
Spirochetes
Halophiles
Chlamydia
COMMON
ANCESTOR
OF ALL
LIFE
Green
sulfur bacteria
Bacteria
Methanobacterium
Cyanobacteria
Archaea
(Plastids, including
chloroplasts)

77. A Simple Tree of All Life
The tree of life suggests that _______________ __________________ are more closely related to each other than to bacteria
The tree of life is based largely on ____________, as these have evolved slowly
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78. There have been substantial interchanges of genes between organisms in different domains
_____________________ is the movement of genes from one genome to another
Horizontal gene transfer occurs by exchange of _______________________________________ __________________, and fusion of organisms
Horizontal gene transfer _______________ efforts to build a tree of life
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79. Bacteria Eukarya Archaea 4 3 2 1 Billions of years ago Figure 26.22
Figure The role of horizontal gene transfer in the history of life. 4 3 2 1
Billions of years ago

80. Is the Tree of Life Really a Ring?
Some researchers suggest that eukaryotes arose as a _______________ between a bacterium and archaean
If so, early evolutionary relationships might be better depicted by a ______________ instead of a tree of life
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81. Figure 26.23
Archaea
Eukarya
Figure A ring of life.
Bacteria