Exam 4 (Parapatric Speciation - Human Evolution)

Question 1

How does parapatric speciation occur?

Answer 1

A population doing well expands its geographic range and experiences a stepped cline and a hybrid zone is formed

Question 2

What is a cline?

Answer 2

A range of area where the environment rapidly changes and there are different selective pressures on either side

Question 3

What is a hybrid zone?

Answer 3

A primary contact zone where the populations have never been separated by physical barriers

Question 4

What is a tension zone?

Answer 4

A zone where the hybrids are less fit than their parents and sets up conditions for reinforcement to be maintained

Question 5

What is reinforcement?

Answer 5

When hybrids are less fit than their parents because they are not suited to either parental environment and selection will favor assortative mating

Question 6

What is a primary contact zone? What about secondary?

Answer 6

Primary = the populations have never been separated
Secondary = populations separated at first then populations meet
** most hybrid zones have been secondary; it is hard to determine whether hybrid zones are either or

Question 7

Why do we expect to find greater prezygotic isolation closer to the hybrid zone than away from it?

Answer 7

We would expect to find a selection for a greater amount of assortative mating near the step because individuals are hybridizing with each other more than the individuals farther from the step who are interbreeding amongst themselves

Question 8

Why should selection for assortative mating be strongest at the cline?

Answer 8

The individuals farther away from the step are mating with those in their own environments so there is no selection on them for assortative mating; they do not experience any fitness advantage because they have been selected to live in that environment; individuals at the step can hybridize and have less fitness if they do because they are not suited for either environment

Question 9

What do we actually see regarding prezygotic isolation and the hybrid zone?

Answer 9

In reality, we do not often find greater prezygotic isolation closer to the hybrid zone than away from it

Question 10

What can we conclude about parapatric speciation?

Answer 10

It is possible but evidence suggests it is not common

Question 11

What is sympatric speciation?

Answer 11

2 populations of the same species stay in the same environment and still speciate

Question 12

What are the 2 types of sympatric speciation?

Answer 12

Gradual and Instantaneous

Question 13

What is required for gradual sympatric speciation?

Answer 13

A population has to have at least 2 morphs and a patchy environment

Question 14

What is a patchy environment?

Answer 14

Places within the environment where one morph does better than the other

Question 15

Why is this not small scale allopatry?

Answer 15

There is no physical barrier just different habitat preferences and the different morphs can still breed with each other

Question 16

Why are hybrids less fit?

Answer 16

They are not suited to either parental environment

Question 17

Why does that favor the evolution of assortative mating?

Answer 17

Individuals mating with other like individuals will mean their offspring will be suited for the parental environments (greater fitness) compared to a hybrid individuals not suited for either one (lower fitness)

Question 18

What is a host shift?

Answer 18

The movement of a parasite, disease, insect herbivore from one host to another

Question 19

Explain an example of a host shift & how it relates to sympatric speciation.

Answer 19

The tephritid fly (R. Pomonella) originally lived on hawthorns (native to U.S.), then it was seen on other species such as apples, pears, cherries and have genetically differentiated on their different hosts since apple-morph maggots do best on apple while hawthorn-morph maggots do best on hawthorn

Question 20

Why do the developmental biases of species like these promote speciation?

Answer 20

Females prefer to lay eggs in the same fruit type as they developed and in turn their female offspring do the same
The pre-exisiting genetically-based behaviors quickly create high levels of pre-zygotic isolation since maggots in apples attracted to the apple smell as adults, they find mates there, and won’t usually interact with adults that were hawthorn maggots

Question 21

What are the 2 types of instantaneous sympatric speciation?

Answer 21

Allopolyploid Hybrids and Diploid Hybrids

Question 22

What are allopolyploid hybrids?

Answer 22

When 2 different hybridize but their offspring inherit the complete diploid nuclear genomes of their parents; have a higher ploidy level
** N1 != N2 (ploidy levels of parents)

Question 23

Why is this instanteous?

Answer 23

A backcross to either parent will produce a triploid offspring which will be completely sterile if not inviable due to inability to assort properly during meiosis

Question 24

What are diploid hybrids?

Answer 24

The normal haploid gametes from 2 species combine to produce a diploid hybrid
** N1 == N2

Question 25

Why is speciation not instantaneous for diploid hybrids?

Answer 25

The hybrid can backcross to its parents

Question 26

How does the hybrid become isolated then?

Answer 26

The combination of the parental genomes creates a hybrid with new phenotype combinations and there is selection for survival in a different habitat than either of the parental species OR chromosomal rearrangements promote post-zygotic incompatibility

Question 27

What chromosomal rearrangements are most important in this process? Why?

Answer 27

Inversion but mostly multiple translocations can cause multivalents to form during meiosis

Question 28

What were the pre-biotic conditions of early earth like?

Answer 28

There was volcanic activity, the atmosphere was primarily composed of 80% nitrogen and reducing

Question 29

Why did oxygen take so long to accumulate?

Answer 29

Oxygen was reacting with other elements instead

Question 30

What was the Miller-Urey experiment?

Answer 30

They recreated the conditions of early earth: added energy (lightning/UV) to a reducing atmosphere

Question 31

What were the results of their experiment?

Answer 31

Were able to produce 17/20 amino acids, produced the nucleic acids: AUCG, T was not produced but it is just a methylated form of U

Question 32

What does the RNA world theory hypothesize?

Answer 32

RNA came before DNA so RNA was the first genetic material and RNA sequences are the catalysts instead of proteins (ribozymes), some are self-catalytic for their own replication

Question 33

What evidence is there for the RNA world theory?

Answer 33

The presence of uracil and very little thymidine in the Miller-Urey experiment, modern ribozymes such as self splicing introns & ribosomes, and experimental production of artificial ribozymes that self-reproduce

Question 34

When does life start?

Answer 34

Precambrian about 3.6 bya - 541 mya

Question 35

What evidence do we have for the first life?

Answer 35

Best fossil evidence = fossil stromatolites, bacteria like cells that were mostly unicellular and probably heterotrophic due to lack of oxygen

Question 36

Why are fossils rare?

Answer 36

Fossils form easier in marine environments than terrestrial ones and due to subduction zones

Question 37

What are subduction zones?

Answer 37

When marine and continental plates collide, marine plates are pushed underneath the continental ones because they are more dense while the continental one is pushed up
The fossils go under as well and are lost

Question 38

Why did the accumulation of oxygen lead to profound changes in life?

Answer 38

Oxygen at first acted as a poison to the aerobic forms of life (also highly combustible); Selection for aerobic life forms that could tolerate it
Allowed greater metabolic efficiency (Anaerobic = 2 ATP/ glucose vs. 30-32 ATP/glucose
Made the complex multicellular life forms that require much higher levels of energy possible
Development of ozone layer which protects against UV radiation (allowing terrestrial life)
Decrease the greenhouse effect from CO2

Question 39

What were the first eukaryotes like?

Answer 39

No evidence for eukaryotic cells until 1.8 bya
Mitochondria acquired from purple line of Eubacteria
Chloroplasts acquired from cyanobacteria
Development of nucleus
Precursor for multicellular life

Question 40

What was multicellular life like?

Answer 40

The first organism (a fungus) appears about 2.4 bya
First animals appear about 670 - 550 mya: mostly soft bodied animals

Question 41

What was the Cambrian explosion?

Answer 41

Sudden increase in fossil diversity
Evolution of hard parts likes bones, exoskeletons

Question 42

Why does speciation produce nested sets of species?

Answer 42

Most speciation occurs when a single interbreeding group gets divided into two groups that stop interbreeding with one another; This process will necessarily create a nested set/hierarchical set of relationships among species

Question 43

What are the 2 classification scheme criteria?

Answer 43

Objectivity Criterion & Naturalness

Question 44

What is the objectivity criterion about?

Answer 44

Reasoning for grouping allows other people to have access to the same characters and apply it themselves and the characters are directly measured and observed

Question 45

What is naturalness?

Answer 45

characters not used to determine the common features of a group will produce the same classification as the characters used to determine the group

Question 46

What is character conflict?

Answer 46

Different sets of characters indicate different groupings (unnaturalness)

Question 47

Why do we use these classification criteria?

Answer 47

They allow rational people to independently discover the same classification scheme; the classification is stable and repeatable

Question 48

What is a sister species?

Answer 48

Species derived from the same most recent common ancestor (MRCA)

Question 49

What is a homologous character?

Answer 49

Character shared between species because of common descent (inherited from the ancestral species)
EX: tetrapod forelimbs have the same bone structure

Question 50

What is an analogous character?

Answer 50

Character shared due to convergence (similarity due to either chance or common selective pressures)
EX: Cacti & Euphorbs (also have spines)

Question 51

What is a similarity?

Answer 51

Two character appear alike without making a claim about common descent or convergence

Question 52

What is a symplesiomorphy?

Answer 52

A trait inherited from a MRCA of a group BUT NOT ALL descendants have the character (shared ancestral homology)

Question 53

What is a synapomorphy?

Answer 53

A character derived in multiple lineages

Question 54

What is a monophyletic group?

Answer 54

All descendants from a single common ancestor (a clade) which is created using synapomorphies and only used for cladistic classification

Question 55

What is a paraphyletic group?

Answer 55

Some but not all descendants of a MRCA which is created using symplesiomorphies

Question 56

What is a polyphyletic group?

Answer 56

Species not grouped due to the same CA which is produced using analogies and not used in any classification

Question 57

Why can’t symplesiomorphies be used for classification?

Answer 57

They don’t include all members of the clade defined by the first CA with the trait
Different symplesiomorphies can indicate different groupings

Question 58

Why can analogies never be used to make inferences about relationships?

Answer 58

Traits evolved independently, groupings won’t reflect a single clade

Question 59

Does the phylogenetic approach meet the classification criteria?

Answer 59

YES

Question 60

What is a polytomy? What does it indicate?

Answer 60

More than 2 branches coming from the same root (star tree)
Used when you know nothing about the species relationships
If a tree has a polytomy, it is not resolved

Question 61

What does a fully resolved tree have?

Answer 61

Only 2 branches from each node

Question 62

What does a phylogram show?

Answer 62

Topology and evolutionary distance

Question 63

What does a cladogram show?

Answer 63

Only topology (branching order)

Question 64

What is a parsimony? How is it used to construct phylogenetic trees?

Answer 64

The simplest explanation is best
A tree that has the least number of changes for characters

Question 65

When is parsimony violated?

Answer 65

When there is too much change because we can’t really discover what actually occurred

Question 66

What does parsimony work well for? Why?

Answer 66

Complex organs because it is unlikely to have unrisen repeatedly in the same way

Question 67

What doesn’t parsimony work well for? Why?

Answer 67

DNA sequences because a nucleotide of DNA has a 25% chance of being similar to one in another species just by chance

Question 68

What are the 2 steps to produce a tree?

Answer 68

Find the shortest possible unrooted tree (requires fewest changes) then root the tree

Question 69

How do you unroot a tree?

Answer 69

Remove time from the tree
Take 2 branches coming from the root and make them a single branch
Rearrange the branching pattern so that time is not reflected in the unrooted tree
** repeat for all possible unrooted trees
Count the number of evolutionary events & choose the most parsimonious

Question 70

What is the process for morphological characters?

Answer 70

Choose and measure good characters
Find true homologies
Figure out character polarities
Make & root the tree

Question 71

How do you determine good characters?

Answer 71

Good characters are complex ones unlikely to have evolved the same way twice and heritable (homologies)

Question 72

What are the 3 principles to determine homologies?

Answer 72

Homologous characters show the same fundamental structure
Homologies have the same fundamental relationships to surrounding characters
Same embryonic development in different groups

Question 73

What are some dangers in determining homologies?

Answer 73

Mistakenly classifying analogies as homologies can introduce character conflict and useful info can be lost

Question 74

What are the 3 methods determine synapomorphies to figure out character polarity?
(Did A or A’ come first)

Answer 74

Outgroup comparison
Embryological criterion
Paleontological criterion

Question 75

What is outgroup comparison?

Answer 75

Use a close relative (sister) of the species being studied to determine the ancestral character state using parsimony to judge the most likely set of events

Question 76

What are the shortcomings of outgroup comparison?

Answer 76

Different outgroups can sometimes give conflicting info about which character state is ancestral
We must already have some phylogenetic knowledge to be able to select the sister group

Question 77

What is the embryological criterion?

Answer 77

The general features of a large group of animals appear earlier in the embryo than the special features

Question 78

What are shortcomings of the embryological criterion?

Answer 78

Some derived features get inserted into an older developmental sequence
Ex: metamorphosis- caterpillar state was inserted

Question 79

What is the paleontological criterion?

Answer 79

Any recorded characters in the fossil record
Features in earlier fossils are ancestral to ones found in later fossils

Question 80

What are the shortcomings of the paleontological criterion?

Answer 80

The incompleteness of the fossil record can give a misleading view of what characters are ancestral or derived

Question 81

What should you do even if there is still character conflict after the methods?

Answer 81

Go to parsimony anyways or continue to collect data & refine analysis
** once the phylogeny is constructed, we may reassign conflicting characters to symplesiomorphic or analogous status

Question 82

What criterions are needed to root a tree?

Answer 82

Outgroup Comparison: can use for almost any group
Embryological Criterion: only useful for multicellular organisms
Paleontological Criterion: mostly only for organisms with hard body parts

Question 83

How do you root a tree?

Answer 83

Take the branch to be the most parsimonious for adding the outgroup and break it into 2 to make the root
Rearrange the tree to be a normal rooted representation

Question 84

What are good characters for the molecular method?

Answer 84

Nucleotides and amino acids in a sequence is a character

Question 85

What are some advantages to 4 bases?

Answer 85

There are millions or billions of characters available for analysis for many organisms

Question 86

What is the process for molecular characters?

Answer 86

Collect characters
Align character for positional homology
Go straight to parsimony
Choose the most parsimonious unrooted tree
Root the tree

Question 87

How do the 3 principles for determining homologies apply to molecular characters?

Answer 87

Homologous characters show the same fundamental structure: all molecules of the same name have the same structure
Homologies have same fundamental relationships to surrounding characters: same as above
Same embryonic development in different groups: nucleotides and aa’s don’t have development

Question 88

What is positional homology?

Answer 88

History of the nucleotide or amino acid at that position

Question 89

Explain why getting the correct alignment of a set of DNA sequences is essential for using them for phylogenetic inference.

Answer 89

Each column of nucleotides/AAs in an alignment needs to represent the actual history of the nucleotide/AA at that position (positional homology)
Otherwise, you’ll be inferring the phylogeny using sequence histories that didn’t really happen and you will infer the incorrect phylogeny

Question 90

Why do we go straight to parsimony?

Answer 90

There is no means to determining homologies & analogies

Question 91

How do we determine the most parsimonious unrooted tree?

Answer 91

Only outgroup comparison is available because molecular fossils are rare and there is no embryological development of NT’s and aa’s

Question 92

What are some issues with phylogenetic inference?

Answer 92

The number of combinations is enormous even with a relatively small number of taxa (we can only exhaustively search through trees for about 30 species)
Need at least as many synapomorphies as taxa to be resolved (can have several results that are compatible with the evidence due to not enough sites to distinguish them)
Need to pick a molecule that evolves at an appropriate rate (too slow = not enough info to resolve the phylogeny; too fast = too many analogous changes to make sense of the relationship)

Question 93

What is coevolution?

Answer 93

When 2 or more species act as reciprocal selective agents/ forces on one another, selection on each other

Question 94

What is needed for coevolution?

Answer 94

The biota acts as a selective pressure on itself
Selection must be reciprocal
There can be feedback loops

Question 95

Which types of species interactions could lead to coevolution?

Answer 95

Consumer-Resource: predation, herbivory, parasitism (+,-)
Mutualism (+,+)

Question 96

Why do commensalism (+,0) and amensalism (-,0) not lead to coevolution?

Answer 96

There is no selective affect for one of the species in both cases

Question 97

Why does competition (-,-) not lead to coevolution?

Answer 97

It is rare that both species are equally competitive so the less competitive one is driven to extinction or has to switch to a different resource and therefore no longer in competition

Question 98

What is a component of coevolution?

Answer 98

Coadaptation: mutual adaptation of 2 species to one another
Cospeciation: when a pair of species that are associated with each other speciates at the same approx. time

Question 99

What are the 2 types of coadaptation?

Answer 99

Positive (mutualism)
Negative (arms race)

Question 100

What is positive coadaptation?

Answer 100

A coadaptive relationship where 2 or more species experience increased fitness from the mutual adaptations

Question 101

What is negative coadaptation?

Answer 101

A coadaptive relationship where one species experience increased fitness and the other experiences decreased fitness

Question 102

Explain an example of positive coadaptation?

Answer 102

Pseudomyrmex ants and tropical Acacia trees
Acacia benefits the ants by swollen thorns providing shelter, beltian bodies provide food
Ants benefits the trees by defending them against herbivore and disease (attack organisms & ants lower the amount of pathogenic bacteria

Question 103

How do we know that the ant-plant mutualism is an example of positive coadaptation?

Answer 103

The tree evolved in response to the ants because not all species of acacia tree have the swollen thorns and beltian bodies

Question 104

How does cospeciation work?

Answer 104

When one of the species undergoes a speciation event, association is maintained since they are adapted to each other
As a consequence, the other member also undergoes speciation

Question 105

Why is cospeciation needed?

Answer 105

What appears to be coevolution could just be association by chance
Could be preadapted to each other
The role of history important

Question 106

Why are synonymous mutations more clocklike?

Answer 106

There is a constant rate of substitutions occurring in a region of DNA like a clock because the only thing acting on them is drift not selection since neutral

Question 107

How does negative coevolution work?

Answer 107

The feeding of insects on plants exerts a selective pressure on the plants for antiherbivore defense
The plant evolves a chemical defense against the plants (taste nasty, make sick)
That defense creates a selective pressure on the insects for resistance (will have higher fitness & replace non-resistant ones)
Process repeats

Question 108

How does negative coevolution work in the context of disease and hosts?

Answer 108

The host would be under selective pressure to evolve resistance to a parasite because of improved fitness for the host
The disease would evolve to better exploit its host (increased population growth & increased virulence)

Question 109

What is virulence in this context?

Answer 109

The degree to which a parasite reduces the hosts fitness (taking more resources from the host)

Question 110

What is virulence limited by?

Answer 110

A disease can’t be so virulent that its host dies before it moves on to the next host

Question 111

What is the exception?

Answer 111

Extremely virulent diseases that can stay in the environment for a long time after the host dies

Question 112

Why do we expect diseases to evolve to be more virulent over time?

Answer 112

Selection doesn’t look ahead
More rapid reproduction = using more of hosts resources
Provides immediate fitness increase over avirulent types

Question 113

How do so many diseases actually evolve to be less virulent over time?

Answer 113

Mode of transmission and Rate of infection

Question 114

What are the 2 modes of transmission?

Answer 114

Vertical and horizontal

Question 115

What is vertical transmission?

Answer 115

From parent to offspring
The juvenile must live long enough after to grow and reproduce
Promotes lower virulence

Question 116

What is horizontal transmission?

Answer 116

Movement from one host to another without respect to the genetic relationships of the hosts
Only needs to live long enough to for the disease to be transmitted
Doesn’t favor lower virulence

Question 117

How does high rate of infection work?

Answer 117

If there are individuals with both types of genotypes: avirulent and virulent
Virulent is reproducing at higher rate, the lesser competitor dies out and the other dominates
Virulent type has a selection advantage
Avirulent type only has as much time to reproduce as the virulent type gives it before the host dies

Question 118

How does lower rate of infection work?

Answer 118

Individuals only affected with one genotype at a time
Virulent type kills its host but this time the avirulent isn’t dying off
Avirulent type has more time to reproduce since virulent type eventually dies off

Question 119

Explain an example of the evolution of lower virulence.

Answer 119

Control of rabbit populations with myxoma virus
At first, the introduction of the virus to the pests killed off 100% of rabbits affected
Over time virulence declined because the density of rabbits lowered the rate of infection (changed as it progressed)

Question 120

How do we know coevolution occurred in the above example?

Answer 120

The lab strain of rabbits was less affected by later genotypes of the virus
Wild rabbits were also less susceptible to the original strain stored in the lab