Week 2

Question 1

What must be the cause of behaviour?

Answer 1

Behaviour must stem from a genetic basis for it to evolve and be adaptive

Question 2

What is the inherent nature of behaviour?

Answer 2

Evolution of behaviour are driven by individual based evolution, and are not for the good of the group or species

Question 3

How can behaviour evolve?

Answer 3

Behaviour is genetically controlled, dynamic and heritable
Timespans of selection are sufficient for adaptation to occur
The it of selection is the individual and its genes (not the roup or the species)

Question 4

What is an example of behaviour being selfish?

Answer 4

In 80s and 90s wildlife documentaries might say, a salmon swims up rive to produce thousands of eggs to help the species – however this is not how evolution works – selection acts on the individual salmon who will behave in this way for their own fitness not for the species.

Question 5

How is phenotypic variation attributed to genotype variance?

Answer 5

Proportion of phenotypic variance in a population that can be attributed to genotypic variance
0 heritability = completely environmentally determined
1 heritability = completely genetically determined
0 – 1 = mix of environmental and genetic determination

Question 6

What are examples of things that are different ends of the heritability spectrum?

Answer 6

Varies from 0 to 1. Religion conceivably 0, phenylketonuria (PKU) conceivably close to 1

Question 7

Does heritability determine what proportion of a trait is determined by genes?

Answer 7

Heritability does not indicate what proportion of a trait is determined by genes and what proportion is determined by environment. So, a heritability of 0.7 does not mean that a trait is 70% caused by genetic factors; it means that 70% of the variability in the trait in a population is due to genetic differences among people.

Question 8

How can we measure heritability?

Answer 8

Breed from female cow that produces lots of milk compared to a beef cow that was selected for meat
Go into the wild and determine if there is variation
We can screen for mutants and measure what causes the mutation

Question 9

How can you find gene function through forward genetics in Drosophilia melanogaster?

Answer 9

Random mutagenesis in many fruit flies
Select phenotype of interest
Indentify responsibel gene
Stidy gene and properties and function
Identify and study related genes in mice

Question 10

How did they determine whether mating speed in Drosophila melanogaster?

Answer 10

First example – drosophila are complex creatures, when they mate there is a lot of behavioral phenotypes. The males transfer as many as 200 seminal fluid proteins, some are used for cooperation, some are manipulative signals that benefit the male – the point here is that mating behaviour and copulation time is a complex behaviour.
Selected how long fruit flies mate for, x axis is number of generations of selection, y axis is mating time

Question 11

What were the results of the selecting for long mating speeds in Drosophila melanogaster?

Answer 11

First example – drosophila are complex creatures, when they mate there is a lot of behavioral phenotypes. The males transfer as many as 200 seminal fluid proteins, some are used for cooperation, some are manipulative signals that benefit the male – the point here is that mating behaviour and copulation time is a complex behaviour.
Selected how long fruit flies mate for, x axis is number of generations of selection, y axis is mating time

Question 12

What is an example of selective behaviour in rats?

Answer 12

Rats get much better at solving a maze – genetic component to something artificial yet simple

Question 13

Is behaviour heritable?

Answer 13

Repeated selection experiments consistently show high heritability in animal behaviour

Question 14

What is an example of heritable behvaiour in wild population?

Answer 14

Blackcap (Sylvia atricapilla) - A partial migrant warbler (some migrate some don’t) – main breeding population in Germany, and they either fly south east to Greece, or they go south west to spain for the winter (in both cases it’s warmer)
One population flies north west to the UK to overwinter – possibly to take advantage of food being put on tables

Question 15

How can you measure migration behaviour in Sylvia atricapilla?

Answer 15

You can measure this migratory behaviour using emblem funnels – the bird can see the sky, and there is an ink pad at the bottom of the funnel, its restlessness and direction can be measured in this way – 80% show an increase in migration – so you can select for individuals to be more interested in migrating
Increasing migratory restlessness – can make it 100% or 0% using selection experiments

Question 16

How did Sylvia atricapilla behaviour vary amogst groups in different populations?

Answer 16

Collect individuals from UK, these individuals want to migrate to UK towards the end of the summer, whereas if you take individuals from Germany they want to migrate to spain so individuals want to migrate their preferred direction

Question 17

What happens if you bred Sylvia atricapilla together with different migratory patterns?

Answer 17

We can breed individuals from Spanish migrants with east European migrants –
Hybrids show migration that’s intermediate
You can see there is probably lots of genes as there is a huge amount of variation in the offspring ie its polygenic – which happens when you have complex and variable traits

Question 18

What is the hertitability of behaviour?

Answer 18

Most behaviour is polygenic, and therefore some is genetic, but some of it is learned

Question 19

What is the score of most behavioural heritability?

Answer 19

Rare for behaviour to be highly heritable, I mentioned height can be as much as 0.9, but behaviour is rarely more than 0.5, possible due to ease of measuring physical traits, but also due to strong environmental influences on the expression of behaviour

Question 20

Can you find single gene examples for behaviours?

Answer 20

Very rare to find single gene examples (possible one in the honey bee)

Question 21

What is an example of gene mutation impacting behaviour?

Answer 21

Dunce – it prevents fruit flies from learning

Question 22

How did they experiment on flies and the behavioural response to smell?

Answer 22

Experiment encouraged flies to move into a chamber – and there are different smells in each chamber
A is a smell that is associated with a mild electric shock that the flies don’t like (coming from a circuit board in the tube)
B is a smell that does not cause a shock
Learn with 3 trial runs for each smell
So do they prefer to go to the shock odorant, or do they prefer to stay at the bottom – you can see that flies only like to fly to the smell that is associated with no shock

Question 23

How did the dunce mutation impact the results of flies responding to smell that gave electric shock?

Answer 23

Dunce mutant flies forget that the odorant A is associated with a shock

Question 24

How does the dunce gene work?

Answer 24

Dunce flies differ at one locus coding for phosphodiesterase enzyme
Phosphodiesterase metabolises cyclic AMP – important in nerve transmission
Nice example of a single locus that controls for learning
Natural selection would probably select out this gene in the wild as it is maladaptive

Question 25

What is the cellular breakdown of Trichoplax adhaerens (placozoa)?

Answer 25

They haveonly six different types of cells, 98 million base pairs in their genome and digest their food outside of their body. This last is necessary because they have no internal organs, no brain or nervous system, no mouth, anus of digestive tract and no circulatory or excretory systems.

Question 26

What is timeline of life?

Answer 26

Earliest known evidence of life: bacterial fossil impressions in rock in Western Australia ~3.6 billion years old
First eukaryotes ~2 billion years ago
First eukaryotic ‘animals’ ~1.5 billion years ago
First multicellular organisms evolved ~800 million years ago - probably Placozoa!!
First ‘backboned’ organisms evolved ~570 million years ago at the latest

Question 27

How long has behavioural evolution potentially occured?

Answer 27

Behavioural evolution for ~500 to ~800+ million years

Question 28

What is altruism?

Answer 28

Behaviour that increases another individual’s survival/reproduction at a cost to one’s own survival/reproduction

Question 29

What is an example of Altruism in Meerkats?

Answer 29

Barking call alarm in guard meerkat helps family but puts guard meerkat at higher risk

Question 30

What are the problems with the good of the species arguement?

Answer 30

Selection occurs on individuals and genes
Selection ‘for the good of the species’ would be inefficient
Selection for selfishness in individuals generally overcomes group co-operation (except in special circumstances)
Few/no empirical examples of group selection

Question 31

What was Darwins special difficulty?

Answer 31

In social insects like ants why are some individuals sterile?
If some individuals are sterile, how do they continue to evolve?

Question 32

What species was used to test why altruism evolves?

Answer 32

White-fronted bee-eater
Merops bullockoides

Question 33

How did they test altruism in the white-fronted bee-eater?

Answer 33

5-year behavioural study of marked bee-eaters

Tested 3 general hypotheses for why helping exists:
Helping improves current overall breeding success?
Helping improves an individual’s future breeding success?
Is helping behaviour higher when the helpers and recipients are related?

Question 34

What was the results of the 3 general hypothesis?

Answer 34

Individuals that breed in a group increase their reproductive success
Breeders that were formerly helpers do not have more breeding success than naïve breeders
Non-breeders provide more help to their relatives

Question 35

Is helping behaviour in White-fronted bee-eater higher the more closely related the helpers and recipients are?

Answer 35

The amount of helping is positively related to relatedness

Question 36

Why does the amount of helping positively related to relatedness?

Answer 36

Helping among relatives increases their inclusive fitness

Question 37

What is inclusive fitness?

Answer 37

Inclusive fitness = fitness gained through personal reproduction PLUS fitness gained from aiding the survival and reproduction of non-descendant kin
However, not all relatives are equally ‘valuable’ (for personal fitness) when it comes to inclusive fitness

Question 38

How are worker ant individuals sterile?

Answer 38

Selection for sterility and helping occurs by increasing inclusive fitness

Question 39

What causes kin selection?

Answer 39

Altruism with relatedness allows inclusive fitness via kin selection

Question 40

What is kin selection?

Answer 40

An evolutionary force which favours the evolution of traits (or persistence of genes) because of their net beneficial effect on the survival of reproduction of genetic relatives

Question 41

What letter is used to represent relatedness?

Answer 41

r = coefficnent of relatedness between two individuals

Question 42

What are the two potential definitions of relatedness?

Answer 42

The probability that a particular allele (form of a gene), present in one individual is also present in another because of their descent from a common ancestor
or
The summed / averaged probabilities of all genes within an individual and, therefore, the proportion of genotypes in 2 individuals that are identical because of common descent

Question 43

What are the basic rules of kin selection theory?

Answer 43

Evolutionary force which favours the evolution of traits (or persistence of genes) because of their net beneficial effect on the survival or reproduction of genetic relatives
The conditions under which an altruistic behaviour will spread via kin selection are defined by Hamiltons Rule

Question 44

What is hamiltons rule?

Answer 44

The rule under which altruistic genes for cooperation can persist

Question 45

What is the equation for hamilton’s rule?

Answer 45

rB>C

Question 46

What do the letters mean in Hamilton’s rule?

Answer 46

r = Relatedness between donor and recipient
B = Benefit to recipient of the altruistic act
C = Cost to the donor of the act

Question 47

What is Hamilton’s rule of offspring production?

Answer 47

𝐵 / 𝐶 > (𝑟 𝑑𝑜𝑛𝑜𝑟 𝑡𝑜 𝑜𝑤𝑛 𝑜𝑓𝑓𝑠𝑝𝑟𝑖𝑛𝑔) / (𝑟 𝑑𝑜𝑛𝑜𝑟 𝑡𝑜 𝑟𝑒𝑐𝑖𝑝𝑖𝑒𝑛𝑡𝑠 𝑜𝑓𝑓𝑠𝑝𝑟𝑖𝑛𝑔)

Question 48

What would hamiltons rule of offspring with helping parents?

Answer 48

Since (𝑟 𝑑𝑜𝑛𝑜𝑟 𝑡𝑜 𝑜𝑤𝑛 𝑜𝑓𝑓𝑠𝑝𝑟𝑖𝑛𝑔)/(𝑟 𝑑𝑜𝑛𝑜𝑟 𝑡𝑜 𝑟𝑒𝑐𝑖𝑝𝑖𝑒𝑛𝑡𝑠 𝑜𝑓𝑓𝑠𝑝𝑟𝑖𝑛𝑔) = 0.5/0.5 =1.0
𝑇ℎ𝑒𝑛 𝐵/𝐶 >1 𝑠𝑜 𝐵>𝐶

Question 49

What would hamiltons rule of offspring with helping parent raise half sibling?

Answer 49

Since (𝑟 𝑑𝑜𝑛𝑜𝑟 𝑡𝑜 𝑜𝑤𝑛 𝑜𝑓𝑓𝑠𝑝𝑟𝑖𝑛𝑔)/(𝑟 𝑑𝑜𝑛𝑜𝑟 𝑡𝑜 𝑟𝑒𝑐𝑖𝑝𝑖𝑒𝑛𝑡𝑠 𝑜𝑓𝑓𝑠𝑝𝑟𝑖𝑛𝑔) = 0.5/0.25 =2.0
𝑇ℎ𝑒𝑛 𝐵/𝐶 >2 𝑠𝑜 2𝐵>𝐶

Question 50

How would hamiltons rule apply for helping cousin’s offspring?

Answer 50

Since (𝑟 𝑑𝑜𝑛𝑜𝑟 𝑡𝑜 𝑜𝑤𝑛 𝑜𝑓𝑓𝑠𝑝𝑟𝑖𝑛𝑔)/(𝑟 𝑑𝑜𝑛𝑜𝑟 𝑡𝑜 𝑟𝑒𝑐𝑖𝑝𝑖𝑒𝑛𝑡𝑠 𝑜𝑓𝑓𝑠𝑝𝑟𝑖𝑛𝑔) = 0.5/0.125 = 4.0
𝑇ℎ𝑒𝑛 𝐵/𝐶 >4 𝑠𝑜 4𝐵>𝐶

Question 51

What is the mating overview in the tasmanian native hen (Tribonyx mortierii)?

Answer 51

Male-biased sex ratio
Mating system: monogamous pairs and trios (2 males + 1 female)
In trios, one male is dominant but both males copulate with the female

Question 52

How is the cost benefit determined in tasmanian native hen?

Answer 52

N1 = No. of offspring produced by a male in a pair
N2 = Total no. of offspring produced in a trio
Dominant cooperates = 0.2N2 (Also 0.5N2 in subordinate)
Dominant selfish = N1 (all offsbring theirs)

Question 53

How can you work the benefit of tasmanian native hen working together?

Answer 53

Benefits of cooperation to subordinate (i.e. recipient of altruism)
0.5N2 – 0 = what he gains through cooperation minus what he might have won alone
Cost of cooperation to dominant (i.e. donor of altruism)
N1 – 0.5N2 = what he could gain by being selfish, minus what he loses through cooperation

Question 54

What is the reproductive sucess of tasmanian native hens when in pairs or trios?

Answer 54

Pairs (N1) produce 6.6 young
Trios (N2) produce 9.6 young

Question 55

What does the reproductive sucess of tasmanian native hens mean for the 0.5N2 - 0 and N1 - 0.5N2 equation?

Answer 55

Benefit to recipient (subordinate) is:
0.5 N2 – 0 = 4.8
Cost to donor (dominant) is:
N1 – 0.5N2 = 6.6 – 4.8 = 1.8

Question 56

What is the only relationship that can promote the reproductive sucess of tasmanian native hens being involved in trios?

Answer 56

Full siblings
4.8 / 1.8 > 0.5 / 0.25 = 2.67 > 2.0

Question 57

What did they discover about mate sharing in male tasmanian native hens?

Answer 57

Both were full siblings which is the fact dependant in two males forming a trio

Question 58

What is an extreme proof of kin selection theory?

Answer 58

Completely sterile non-reproductive worker casts can evolve because they help relatives to reproduce genes – inclusively
Eusocial animals - ants, bees, wasps and naked mole rats

Question 59

What are misconceptions about evolutionary selection of altruism through kin selection?

Answer 59

To ensure the survival of the species
For the good of the species
Natures way of making sure species survive

Question 60

What are the outcomes for prisoners dilemma?

Answer 60

Remain silent and do not confess
If the other prisoner is silent – you will get a short sentence
If the other prisoner confesses and dobs you in – large sentence
OR
Confess and dob on the other prisoner
If the other prisoner is silent - you will be rewarded and released
If the other prisoner confesses and dobs you in – you will get a medium sentence

Question 61

What does the prisoners dilemma illustrate?

Answer 61

Illustrates that selfish NON-cooperation can be an evolutionary stable strategy
Even when net population benefits are higher under cooperation
An ESS is a theoretically determined strategy which, if adopted by the majority of the population cannot be beaten (or invaded) by an alternative strategy

Question 62

Why can non-kin altruism exist?

Answer 62

Yes. Under certain conditions, when both players play repeatedly, an ESS of cooperation and helping can be maintained

Question 63

What are the different approaches for the prisoner dilemma?

Answer 63

Always cooperate
Always cheat
Tit for Tat
Cooperate on the first move then do whatever your opponent did on the previous move
Allows reciprocal benefit, but cheats gain only marginal benefits when they defect and are then punished by loosing cooperative benefits
Grudger
Start with cooperate but if an opponent cheats switch to always cheat
Tit for two Tats
The same as tit for tat but will only start cheating if the opponent cheats twice in a row

Question 64

What are the conditions for tit for tat?

Answer 64

Conditions required:
Altruistic act has a relatively low cost (high cost encourages big benefits and cheating)
Benefit exceeds cost
Defection leads to ‘punishment’ (e.g. loosing cooperative benefits)
Encounter rate probabilities between individual are high ( = spatial clustering)
Individuals recognise one another ( = higher animals)

Question 65

How did they research tit for tat in vampire bats?

Answer 65

Field study in Costa Rica
400 hours of behavioural observations at roosts
Marked with wing bands
Record group structure and behaviour

Question 66

What did they find out about altruism in vampire bats?

Answer 66

Bats form tight associations
Especially between regurgitators
Relationship between food intake and starvation is negative exponential
Which means that donation incurs a much bigger relative benefit to starving bats then a cost to (well fed) donating bat
Primarily would donate if previously recieved food with relatedness not playing a major role