Human Evolution Summary PDF HS 2021

Summary

This document provides a summary of human evolution. It covers various aspects like basic evolution theory, different theories (Plato, Aristotle, Lamarck, and Darwin) and phylogenetic concepts. It also touches on homology, analogy and adaptive radiation.

Full Transcript

BIO 115 Annik W.

Human Evolution – Summary

L1: Basic Evolution Theory
1.1 What is evolution
Biological evolution is the change in the properties (Eigenschaften) of organisms over the course of
generations. The changes are passed via genetic material into the next generation. Ontogeny
(development/growth) of organisms is not evolution.
f.e: antibiotic resistance

1.2 Different evolution theories
Plato: Variation is accidental imperfection
Aristotle: Species have fixed properties (human f.e: talking, walk on two feet)
Christians believe: Gods creation, „great chain of being” must be permanent/unchanging as change implies
imperfection
Carolus Linnaeus: catalogue plan of creation, systema naturae, classification of animals and plants

1.2.1 Lamarck (1809)
Species originated spontaneously
Evolution aims to get more complex (always climbing up the scale of organization)
No common ancestors between species
Species differ because of their different needs
Alternations are inherited
No sorting process
Organic progression à nervous fluid
Transformational evolution: organisms can pass on traits that they acquired during their lifetime to
their offspring (à if one has muscles, all offspring have muscles)
Transformational evolution says that a population simultaneously acquire the same structures and
adaptations as the result of an inherent progressive tendency which drives them continuously towards
greater complexity

1.2.2 Darwin(1809-1882)
On his voyage: mockingbirds on different islands look different à adaptations
2 breakthroughs
Descent with modification: all species have descended from one “original” forms of life
Natural selection
5 theories
1. Characteristics of lineages change over time
2. Common descent: Different species arose from one single common ancestor
3. Gradualism (changes occur step by step)
4. Individuals of a species can vary from each other (have different characteristics)
5. Natural selection: only those individuals who are adapted best will survive and get into the next
generationà survival of the fittest / best adapted
Variational evolution implies that individuals in an evolving population vary from one to another, and that
these variations may accumulate during evolution due to a sorting process by which some variants become
either more or less common. Evolution is not goal-oriented (not aimed to be more complex)

1.3 Phylogeny (evolutionary tree)
A phylogeny, or evolutionary tree, represents the evolutionary relationships among a set of organisms,
called taxa. The tips of the tree represent groups of descendent taxa (often species) and the nodes on the
tree represent the common ancestors of those descendants.
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History of events by which species have originated from common ancestor
Each branch point (node) represents the division of an ancestral lineage into two or more lineages
Closely related species have more recent common ancestor
The longer a branch, the more time has passed and the more mutations taken place (genetic
change over time may happen faster on one species than on others)
Tree based on parsimony (Sparsamkeit) only as much branches as needed
May include reticulation (Vernetzung) because of hybridisation

Phenotypic similarity is not always phylogenetic similarity. Some individuals may look pretty similar, so
phenotypically they are alike but they may not be closely related (shark and dolphin look alike, but dolphin
and hippo are closer because they are both mammals).

Coalescence analysis:
Coalescence analysis allows tracking back to the most recent common ancestor. By the
coalescent tree we can track the sampled (erfasste) lineages (no chance to track all lineages)
and then represent all as good as possible

1.4 Difference between homology and analogy
Homology: structures that are similar in related organisms. Homologous means that sth had the same
basic plan and the same phylogenetic origin but they can now have specific adaptions and different
functions. f.e.: construction of bones the same as the common ancestor had

Analogy: structures that are similar in unrelated organisms. They had different basic plans but now have
similarities in adaption and function (homoplasy). The phylogenetic development that was independent
but lead to a similar result is called convergent evolution. (only because they look the same doesn’t mean
they have the same ancestor)
f.e.: Wings make both able to fly but they achieved it in independent pathways of
evolution (so birds have feathers, bats have skin)

1.5 Adaptive radiation
Adaptive radiation is a process in which numerous related lineages arise and
diversify rapidly from an ancestral species into a multiple new forms in a really short
time. Particularly when a change in the environment makes new resources available
or opens new environmental niches. Evolve into different directions as they adapt to
different habitats à most common pattern of evolution

1.6 Darwin’s difficulties explaining variation
new species and other evolutionary changes arise by the accumulation of small variations
blending inheritance and selection would destroy variations in population => natural selection can’t
continue
ð Darwin had no answer to that
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L2: Genetic variation
2.1 The problem with “blending inheritance”
The theory assumes that both parental substances mix to determine offspring characteristic, so offspring is
an intermediate of parents. But by that, all variation would disappear + selection would also remove
variants. à how is variation maintained?

2.2 Mendel’s experiment
Mendel isolated traits of a pea plant with only two forms (variants) and bred them to make heterozygous
offspring. The breeding between the heterozygous plants lead to a predictable mixture of genotypes.
Mendel found out that characteristics are determined by two particles, one from the mother and one of
the father, that equally likely to be transmitted when gametes are formed. The particles are chromosomes.

2.3 What creates genetic variations?
Gene-mixing by segregation: both alleles segregate independently
Gene-mixing by recombination: Crossovers between genes leads to recombinant chromosomes =>
new combinations
Independent assortment of homologous chromosomes during meiosis
Mutations: change in the DNA (mutation rate varies between species)
Point mutation
Structural mutation (Deletion, Duplication, Inversion)
Genome duplication
ð Mutations can affect fitness of an individual
Pleiotropic effects: A pleiotropic gene is a gene that controls more than one gene, so if there is a
mutation in a gene it can have impact on many other functions of an organism à great for
evolution to act upon

2.4 Linkage disequilibrium
When two loci are found inherited together more than expected it’s called linkage disequilibrium. The
closer two Loci are, the lower the possibility that they get separated because of crossing-over
Recombination rate “r”: probability that recombination takes place
Large distance = high possibility that two Alleles are separated through cross-over à low LD
Short distance = little possibility that two Alleles are separated à high LD

2.5 Solving Darwin’s Problem
Problem 1: Selection will remove variants from population:
New variants arise in every generation (segregation, recombination)
Mutations
Changes in gene regulation
Pleiotropic effect
Problem 2: If blending inheritance was true: natural selection would destroy variation
“Blending” is not the right word, an offspring receives 50% of the mother’s DNA and 50% of the father’s
DNA but they remain separate and don’t blend.
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L4: Selection and adaption in humans
4.1Natural and artificial selection
Nature:
Peppered moth: mutation of Melanin, dark mutant à decreasing pollution, less dark trunks
Cockroaches: different taste receptors à some can avoid traps set by humans
Artificial:
Rapid evolution when humans select traits à chicken selection (their weight within 60 days in
different years)

4.2 Selection and fitness
Trait will evolve if
These is a correlation between phenotype in parents and in their offspring
There is a correlation between phenotype of parents and their number of offspring (their fitness)
ð Without selection, no evolution (stay as it is)
ð Selection can affect fitness in different stages of life

Fitness: number of offspring an individual leaves to next generation
!"#$. '(")*)+, -#.+-("*-/
Absolute Fitness (w): number of zygotes produced by one individual W= 01!02-.3(.$0" #44'!"*35
Relative fitness (wpop): average number of offspring in a population
f.e: W = 2
wpop = 1 à Individual has good fitness compared to others
wpop = 4 àIndividual has bad fitness compared to others
ð relative fitness plays important role in determining
speed and result of evolution by selection

4.3 Selection and reducing variation:
Selective sweep: Process through which a new beneficial
mutation that increases its frequency and becomes fixated
(reaches frequency = 1). Selective sweeps eliminate
polymorphisms at near regions of the mutation and thus
variation is reduced. Neutral sites close to the loci
“hitchhike” and get fixated as well because they are linked.
Positive selection: occurs whenever one allele has a higher fitness à allele frequency of beneficial
mutation increases in order to reach fixation (alleles can hitchhike an also become fixated)
Selective coefficient “s”: measure of strength of selection that favours beneficial allele (the stronger
the quicker it will take over a population.
=> Evolution is proportional to strength of selection (s) and amount of genetic variation (depends on allele
frequencies)

4.4 Dominance and time within fixation:
Relation between s and time: how many generations until fixed (the higher “s” the faster)
Dominant: frequency increases rapidly
Recessive: frequency spreads slowly
No dominance: intermediate
Deleterious mutations:
“s” is negative à change in allele frequency is negative
Difficult to remove recessive disease because most people are heterozygous (Carrier) and don’t die

Many genes have evolved in response to strong natural selection
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Lactose tolerance: our ancestor could not digest lactose, now we can (beneficial mutation) à
different alleles lead to lactase persistence = convergent evolution
Golden Gene: Mutation decreasing skin pigmentation à lighter skin

4.5 Selection and preserving variation:
Standing genetic variation: Environmental change suddenly gives fitness
advantage to a mutation that is already present in the population..
Region of reduced variation is smaller than if mutation had an advantage
from the beginning.

Balancing selection: maintains genetic variation à polymorphic equilibrium
f.e: mutation in a gene makes bad erythrocytes but protection against malaria

4.6 Selection and Allele frequency changes
Positive: positive selection favours one specific allele à fixation (go to top,
independent on start frequency)
Overdominance (balancing): heterozygote has higher fitness à polymorphic
equilibrium and maintaining genetic variation (get to the middle)
Underdominance: heterozygous has lowest fitness à fixated or lost
(depending on start frequency)

4.7 Population genetics:
Fst: is a measure of genetic differentiation between population
Fst = 0 no difference
Fst = 1 complete differentiation

Detect selection: compare two population. Big difference in Fst shows, that selection was active and some
allele was more efficient and now has a higher frequency than in the other population
f.e:
comparison between Inuit, Chinese and European: branch between Chinese/european and inuit is
long: big amount of mutations that took place à adaption to arctic environment (temperature,
marine food)
Tibetans show very high level of differentiation from Chinese people à adaption to high altitude

4.8 Summary
Natural selection is any consistent difference in fitness among different phenotypes (selection acts
on phenotype)
Rate at which beneficial mutations spread depends on s and the amount of genetic variation
present in the population
Selective sweeps reduce genetic variation in region close to selected locus
Selection can maintain genetic diversity à overdominance
Deleterious mutations occur frequently à are maintained in population by mutation even if
selection want to remove them
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L12: Genetic drift & human evolution
Loss of genetic diversity:
Small population: little option of interaction
Harmen structure: one male with many females

12.1 Genetic drift
Genetic drift is the change in the frequency of an existing gene variant (allele) in a population due to
random sampling of organisms
Genetic change between generations also happens when selection is not at work
Mutations can change allele frequencies
Chance plays a big role in evolution (survival, reproduction, meiosis) only one allele in
heterozygotes gets passed on => proof by in-silico experiment

In-silico evolution (experiment)
5 populations with two qual alleles, each generation starts with a given number of individuals, there’s no
selection on survival nor on reproductive success, all adults die after reproduction.
Result:
Random fluctuations are larger in smaller populations
Genetic drift causes genetic variation to be lost
Genetic drift causes populations that are identical to become different
Alleles can become fixed without the benefit of selection (random allele is fixed, not the better one)
ð The smaller the population is, the bigger the chance
that alleles get lost by random occasion
ð Other allele got extinct because it was not inherited
anymore

12.2 Genealogy of genes
For any given locus in the human genome, there was a copy of that gene in the past that was the ancestor
of all copies of the gene now carried by all living humans. When lineages of two gene copies merge they
coalesce => shows most recent common ancestor (MRCA) of that gene. Due to
chance many lineages become extinct after time, depending on how strong the drift
is, it takes longer.

12.3 Genetic drift and effective population size:
The strength of random genetic drift in a population is measured by effective
population size Ne. Ne is the number of individuals that would give an idealised
population (individuals have same chance of leaving offspring) the same strength of
random drift as the actual population. Average time back to common acestror is 2Ne

What affects drift:
Size (large population => small drift => maintain genetic variation)
Changes in size => bottleneck: when part of a society leaves there’s is reduced option for mating =>
genetic diversity decreases with further distance from Africa
Age demography
Unequal reproduction (f.e. harem)

Ne varies between species and depends on
History of species
Variation in mutation rates
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Selective sweeps
Background selection
Reproduction

12.4 Genetic diversity of great apes vs humans
Genetic variation within orangutan and gorillas is much higher than in humans despite the much smaller
population size because it takes a long time for genetic variation to build up: mutations take time to evolve
=>Most human diversity occurs in Africa (genetic splits much deeper in Africa)
=>Genetic splits in Great Apes deeper than in humans

Why are humans genetically less diverse than other great apes?
Very recent speciation event: Great apes are way older than humans are
Genetic diversity and size of ancestral population
Demographic events: bottlenecks f.e. migration and thus split of a group
Stochastic events: genetic drift (and chance) shape our genetic variation

12.5 Genetic diversity within the modern human
Linnaeus (1756): described different human “races” due to different looks but also on intellectual and
cultural characteristics.

Race: natural subdivision of a s species in biologically distinct groups forming incipient subspecies. => is
there enough genetic diversity for human “races”?

Human ó Great Apes
Variation within population Variation between population

Humans: two Europeans have more differences than a European and an Asian
Great Apes: Are genetically more diverse both within and between subspecies than humans but more
different between groups (narrow within group but big step to next group)

12.6 Structure analysis of human genetic diversity
Algorithm that classifies humans into wanted number of groups (K) and see how different “races” based on
genetic diversity would be put together.
Result:
Difference between clusters is very small
Shows us that European, Middle East and C/S Asia are genetically similar
=> genetic variation WITHIN population: 93-95%
=> genetic variation BETWEEN population: 3-5%
=> To justify “races” it should be around 30% between groups => no genetical races!
Furthermore:
Humans are much less differentiated than other mammals (FST very low, even though we are
widely spread)
Genetic diversity in human follows a gradient => not “fixed” classification possible
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V5: Mismatches
5.1 Evolutionary Mismatch
What:
State of disequilibrium whereby a trait that evolved in one environment becomes maladaptive in
another environment
Integral part of evolution in changing environment
Important to humans as environment changes drastically
Can occur through cultural evolution in addition to genetic evolution
When:
Adaptation evolve in context of selective pressure = adaptively relevant past environment
“Ancestral environment” doesn’t imply that relevant selection pressures were homogenous
à is becoming increasingly common as our environment is changing rapidly

5.2 The way evolution shapes our health goes far back in past
Humans are apes with derived adaptations (f.e. pelvis that is smaller due to upright walking, brain
got bigger (4x bigger)
obstetric dilemma: contra productive evolutionary development as pelvic got smaller but head got
bigger =>stabilizing selection for birth weight
Maternal and neonatal mortality as consequence of obstructed labour: survival and reproduction
are at stake

5.3 Mismatches and major cultural transitions
Hunter-gatherers:
Humans evolved their derived characteristics as hunter-gatherers
Hu-gath. today are not a perfect representation of early homo sapiens because they adapted as
well but still closest to how our ancestors lived
o Bayaka
o Agta

What was important:
Food availability is unpredictable (low resource predictability)
low environmental carrying capacity (number of people that can be sustained at a steady state with
the available resources)
craved food that was energetic and versatile but hard to get
physical work to get food
ð consequences of low carrying capacity: high mobility,
no possession
ð cooperation becomes important

Adaptions of hunter-gatherers:
group structure and kinship system
egalitarianism (equality)
variety of tools to process foods
cooperation and equality
running and throwing
ð increased reproductive success than ancestors
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1.Transition to farming
Mismatches:
Quality of food decreased: loss of variety and more carbohydrates
o Dental caries, abscesses, tooth decay visible on skeleton
Increased parasite loads / viral infection
Animal domestication was bad for health
Mortality rate increased

But why was farming evolutionary successful?
Quantity of food increased
Predictability of food
Starch and baby food lead to less mortality of baby
Carrying capacity increased because of more productive land and storage possibility
physical work increased
long-term immunity
ð fertility rate increased à reproductive success was
higher
ð fertility > mortality à population size increased à fast
expansion
ð BUT: sex equality decreased
First transition:
Demographic: caused by increased quantity and predictability of food
Epidemiological: increased of communicable diseases and less diverse food

2. Transition to modern life
started recently in comparison to transition to farming

Solving problems brought by agriculture:
Fighting communicable (übertragbare) diseases with vaccination, hygiene, medicine, more food
variety
First from high mortality to low mortality
Then from high fertility to low fertility (less offspring)
Life expectancy improved (living longer)
à population still grows because mortality decreased before fertility decreased

What were new mismatches?
New non-communicable diseases (Alzheimer, Diabetes, Osteoporosis, heart diseases)
“Having too much”: Significant health problem are increasing from easy availability of high-calorie
food (carbs, fat, sugar, fibre) => diabetes
“Doing too little”: decreasing of physical work
“Environment of evolutionary adaptedness” à human is genetically adapted to a hunting-gatherer
way of life not to modern life
à Not because of the consequence that humans live longer, but of the drastic change of the
environment
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L7: Life History and Reproductive Health
7.1 What is life history theory?
Life history studies the changes organisms undergo through lifetime from birth to death
Focus on reproduction and survival (offspring vs soma, see L6)
Explains phases of life cycle as a consequence of evolution by natural selection

7.2 Trade-offs:
Time invested in growth and somatic maintenance length of reproductive span
Trade-off determines the optimal age at first reproduction (Energy switched from growth to reproduction)
-Different body sizes have different life schedules:
Elephant: big, needs much time to grow -> reproduction late
Mouse: small, doesn’t need much time to grow -> reproduction early

Trade off and different extrinsic mortalities create continuum:

Increased extrinsic mortality Decreases extrinsic mortality
Great number of offspring less offspring
Shorter lifespan longer lifespan
Fast growth slow growth
Early reproduction late reproduction
Early sexual maturation late sexual maturation
Small body size => fast living big body size => slow living

7.3 Slow life history of human:
Investing in quality:
1. Gestation: long period of pregnancy
2. Birth: larges and fattest babies of all mammals -> proportionally expensive
3. Long-term dependent children (because brain and body need time to grow)
ð Mortality rate is low
ð Humans adopted the extreme of the slow life history
stragety adopted by Apes
7.4 Menstruation and Menopause
Menstruation:
Because human babies are energetically expensive humans are one of few species that evolved
menstruation to eliminate abnormal embryos
When ovulation high inflammatory response to select good embroys over bad ones (body attacks
everything but only good embryos are selected)

After ovulation: anti-inflammatory response that embryo can attach to endometrium
If no embryo “good enough” and no attachment -> menstruation (elimination of bad embryos)
à Due to menstruation women are in control over embryo unlike in other species where embryo has
control

Why Menopause?
Human have a long lifespan but our post reproductive span can be longer than reproductive span.
Menopause is the result of a mismatch between the rates of reproductive and somatic senescence.
longer lifespan than expected for our body size ó stop reproducing earlier than expected for our lifespan
BIO 115 Annik W.
Why not selection for longer reproductive span if we life longer?
1. Theory “good mother”:
If a mother of old age has a baby she may not be able to raise the child until independence, so there needs
to be a menopause to minimize that risk
=>but post-productive time is way longer than the time it takes for an independent child

2.Theory: “Grandmother hypothesis”
-Short IBI (fast new baby) ó still investing in quality
-Grandmothers have important role because they help raising grandchildren
-> we can wean (entwöhnen) infants way faster so we can reproduce again faster
-> Menopause to help family and that women can contain high fertility

7.5 Difference between humans and apes who also have “slow life history”
Shorter lactation period (breastfeeding period)
Shorter interbirth interval (IBI)
fertility is much higher (quantity high) => fast life

Paradox:
We adapted in ways to invest in quality (trough menstruation) and in quantity (through menopause)

Slow life history Fast life history
Long pregnancy high fertility
Large & fat babies short breastfeeding period
Long-term dependent children early weaning (entwöhnen)
Low mortality rates short interbirth interval (IBI)
= investment in quality = investment in high quantity
à MENSTRUATION àMENOPAUSE

7.6 Mismatches and Diseases in female reproduction
Although menstruation and menopause are important life history adaptions to ensure quality and quantity
of offspring, changes in current reproductive patterns lead to maladaptation (mismatches) in western
society. Not present in hunter-gatherers

Changes in reproductive traits lead to mismatches
- Early Menarche (first period 1860: 15, today: 12)
- Menopause late
- Lactation phase shorter
- Less pregnancies
à More menstrual cycles (450 today, 160 in hunter-gatherers) = More inflammatory cycles
à increased risk of mutation lead to higher risk of reproductive cancer

Cancer:
Endometrial cancer (Gebärmutterschleimhaut): Oestrogen promotes proliferation, also it has
inflammatory effect on body, so the more menstrual cycles woman has, the more inflammatory
processes take place à can lead to cancer
Ovarian cancer: multiple ovulations injures the ovarian epithelium
Breast cancer: Women who breastfeed longer have more differentiated cells and less
undifferentiated cells. Undifferentiated cells suspected to mutate and become cancer cell
Birth control pill leads to 12-13 menstruations a year which keeps oestrogen level really high, may
lead to health risk in later life
BIO 115 Annik W.
à Progesterone has protective effect on body, so rather than simulating menstruation, pills should
simulate pregnancy because while being pregnant, progesterone level high
àMenopausal symptoms are result of sudden decrease of very high lifetime oestrogen level to zero when
menopause comes.

Auto Immune Diseases:
Increased immune reactivity (ups and downs all the time) lead to excess production of antibody, coupled
with fewer immune challenges due to cleaner environment lead to increased susceptibility (Anfälligkeit) to
autoimmune diseases for women (pregnancy improves symptoms in autoimmune disease).
BIO 115 Annik W.

L6: Senescence (ageing)
If there is so much variation natural selection could select extreme longevity?
All living organisms will die, but lifespan is extremely variable
Natural variation in the population => selection of the fittest

6.1 What is ageing?
Is the process of declining in fertility and survivorship rates with age leading to increasing mortality
rate
Decrease of physical function
Decrease in reproductive rate
Increase in age-specific mortality rate
=> ageing seriously reduces individual fitness and therefore should be opposed by natural selection. why
do we still age?

Positive senescence: mortality arises with age (mammals)
Negative senescence: mortality sinks with age (the older the less risk to die)
No senescence: age-specific mortality does not increase
If humans maintained tiny mortality rate -> average person could last up to 1200 years

6.2 Different ageing-theories
1. Programmed ageing-group selection
Ageing evolved by “group selection” => Idea of altruism
For the benefit of a group the old individuals would be replaced by new ones
Ageing and death are themselves adaptive
Evidence for the theory:
o telomeres are parts of a chromosome. As cell divides over time they get shorter, causing
cells to stop functioning and then lead to ageing
o Lemmings who commited suicide as benefit for the group
o Senescence protects population from epidemics by controlling population density
BUT:
Natural selection acts upon one individual not on a group. There’s no benefit for one individual if it
has to die for a group (only disadvantage)
No theoretical reason to explain why ageing would be programmed

2. Rate-of-living-theory:
Non-adaptive theory
Death and senescence are not determined by natural selection
Ageing is caused by accumulation of irreparable damages of cell that happen as a by-product of
normal metabolic process
When the damage overcomes the rates of repair mechanisms à ageing
Reduce caloric intake should reduce metabolic rates leading to less oxidative stress and slow ageing
Animals with higher metabolism should age faster (mouse has higher metabolism compared to
body size than an elephant) -> large animals tend to live longer because of the slower metabolism
Reducing calory intake should reduce metabolic rate -> slow ageing -> increased lifespan
BIO 115 Annik W.

BUT:
Ageing cannot be a direct by-product of metabolic rate because all animals of the same size would
then have the same lifespan
Animals that have higher metabolic rate for same size would age faster and die earlier (compore
bat to a mouse)
Since species are set to be as efficient as possible in repairing damages, they should not be able to
evolve longer lifespan (but they are)
Can be selected for and thus an adaptive trait, not just a by-product
=> All these theories imply that we die because we age, different rates of ageing lead to different ages of
death

3. Life-history-theory (Reproduction versus Soma)
Ageing is consequence of accumulation of mutation (cell damage) at different rates according to extrinsic
mortality
Focus either on reproduction or Soma -> Trade-off
When focused on reproduction rather than somatic maintenance than errors accumulate fast ->
leads to strong senescence and shorter lifespan
Mutation that affects individual late in life have no effect on reproductive success (because
offspring were already made)
=>“Charnov’s theory”: we age because we die (senescence as a consequence of death)

External/extrinsic factor:
Each environment gives different ecological risk to die (extrinsic mortality)
Animals lifespan depends on external factor an environment has (death through predators,
diseases, starvation, accidents
Death is an external factor that cannot completely be controlled => is inevitable
Time is a limited resource

6.3 Why does selection not produce eternal lives?
Extrinsic mortality cannot be completely controlled (external factor). The higher the extrinsic mortality, the
faster will the animal age and then die because it rather invests in reproducing early than in somatic
maintenance. Individuals adapt to extrinsic mortality rate.

6.4 Correlation between mortality, fertility and ageing:
high mortality => fertility high in early age (offspring early) => ageing faster as focus on reproduction than
on somatic maintenance
Species with different extrinsic mortality should have different probabilities of surviving (independent of
senescence)

6.5 Senescence as an evolutionary consequence
Average lifespan is a consequence of the ecological mortality rate
Senescence is the evolutionary consequence of the inevitable death

Why?
1. Removing deleterious mutations decreases as chances of accidental death increases
2. Every mutation that kills you in young age will not be passed to next generation -> selection has less
power to eliminate bad mutations in later life
BIO 115 Annik W.

=> ageing means we accumulate bad mutations that we cannot eliminate through selection in old ages,
because it’s always passed to the next generation
=>old age: garbage bin of all accumulated deleterious mutations that selection couldn’t eliminate

6.7 Why are genes associated with aging diseases selected for?
Antagonistic pleiotropy:
Pleiotropy: one gene has more than one effect on phenotype
Antagonistic: one effect is beneficial, one is detrimental
Organisms that need to have offspring as early as possible, genes favouring early reproduction are selected
at cost of effect in later life. Reproduction is favoured over soma. Anything that provides having offspring
early will be selected even if its detrimental when older.
o Testosterone: high levels early lead to high fitness but decreased fitness later à will be
selected for because it provides good fitness when young
à Age can be accelerated by antagonistic pleiotropy, where genes that have an advantageous effect at
early age can be selected for even if they have negative effect later on
BIO 115 Annik W.

L8: Human brain and cognition
8.1 Brain sizes and body size
Brain size: Different primates have different brain sizes. Great Apes have a wide range but they don’t
overlap with other other primates. Humans have a very large brain. We evolved from an ancestor that
already had a big brain but we took it to a new level.

Body size: Most variation in brain size is explained by different body sizes. Brain responds to body size. But
it’s only the expected brain size compared to body size of a species, not the absolute number. => body size
scaling

Encephalisation &EQ:
Encephalisation is measured by encephalisation-quotiend (EQ)
EQ = observed brain size / expected brain size
EQ = 3 => 3 times larger brain than expected for body size => species is encephalised
Primates are highly encephalised => cat and capuchin monkey weigh the same but monkey
has a 3 times bigger brain
Humans are the most encephalised species (dolphins after us) => EQ = 6-7

8.2 Brain structure
Neocortex ration: Brains vary in structures. Key difference is „neocortex ratio“
(associated with higher functions. => Primates have high neocortex ratio.
Brain connectivity: ratio of white (connection) /grey matter (functional modules)
small brains are mostly grey
Humans have a lot of white matter (but whales have even more)
Humans are no exception, we follow the general scaling
But big brains cause a problem: obstetrical dilemma

8.3 Obstetrical dilemma:
Brains need to fit inside a skull and skull needs to fit through hips of a mother. => encephalisation vs pelvic
adaption. Solution: reduce space of the brain by packing and folding the grey matter, increase brain
convolution. But result is that convolution reduces the amount of white matter required to connect
functional modules. But because of the shape we have a large surface (many other species have smooth
brain) convolution correlates with absolute brain size (dolphins and whales have more convoluted brains)

Summary: what makes a human brain special?
Humans…
Have large brains (but not the largest, primate brains were large before human brains were)
Are highly encephalised (we had encephalised ancestor but we took it even further)
Have a lot of white matter (but it’s not an exception)
Have higly convoluted brains (as a consequence of high encephalisation)
Have a unique structured brain with large neocortex ratio

8.4 Brains and minds
Lobes:
Neocortex is divided into 4 units /lobes: frontal, parietal, temporal, occipital
Sensory function (vision, hearing) are processed in the posterior regions
sensory information are transmitted from raw input into primary area (V1) to secondary area (V2,3)
Damage of primary: total blindness
Damage of secondary: specific visual deficit (f.e colour blindness)
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Vision involves significant processing and interpretation of raw inputs
Somatosensory information is sent from thalamus to somatosensory cortex (S1)
Movement is commanded by the primary motor cortex (frontal lobe)

8.5 Association areas:
Cortical regions that are not primary sensory (input) / motor (output) => association area
(„thinking“ and high cognition part)
Mammals: Association parts are rather small (input / output)
Human: Most of the brain is association part
Cross-modal information: Association area put sensory information together: vision, sound, smell to
recognise object => can lead to disagreement (video with dada, baba) => human brain is very visual (see
the sound rather than hear it)

8.6 Working memory:
Is the set of mental processes holding limited information in a temporarily accessible state (here and now)
Many regions in the neocortex are activated by working memory tasks
Hippocampus (not neocortex): long-term memory, only fraction of our experiences is filtered into
„past“ memory
Damaged Hippocampus: only presence is available, facts remain (semantic memory) but personal
experiences are gone (episodic memory), reality based on 10-30 sec windows
Learning without episodic memory is possible (handshake with pin)
Link between memory (real experience) and imagination (constructed experience) => experiment of
words on a list and the picture the mind makes, mind „makes things up“ that were not reality
Constructive memory: memory is re-imagined every time its recalled
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L3: Cooperation
3.1 Major transition in evolution require cooperation
single-cells à multicell-systems
RNA as gene à DNA
solitary individuals à colonies with task specialisation
=>Natural selection favours individuals that maximise their fitness: competition “struggle for existence” /
“survival of the fittest”
=> How can natural selection then favour cooperative traits that benefit others?

3.2 Problem with cooperation:
Cooperation is observed everywhere in nature, but it’s not compatible with Darwin’s theory of natural
selection and adaption (survival of the fittest)

3.3 Hamilton’s rule
Hamilton’s rule: helps to classify social behaviour (not only
cooperation)
rb > c
c= cost of actor
b= benefit of receiver
r = relatedness between actor and receiver

Relatedness: is a measure of interaction probability
high relatedness: interactions occurs more often among individuals that are alike than expected
low relatedness: interaction occurs as often among individuals that are alike as expected

The 4 cases of interaction
mutually beneficial cooperation (beneficial for both => r= low )
§ cooperative agreements between people
§ group hunting
Altruism (reduces my own fitness but benefits someone else => relatedness must be high)
§ worker bees that help the queen producing offspring
§ menopause: help the daughters to raise their offspring
selfish behaviour (benefits me but harms the other => r=low )
§ lions kill young offspring of previous males
§ stag fights: one can stay with the female, other has to go
spite (harms both => r= must be low)
§ warfare: both are likely to be killed
§ toxin production in bacteria: kill the acter and recipient

Personal fitness: number of offspring that one individual leaves
Inclusive fitness: number of offspring that are supported / hindered through behaviour of one individual

Summary:
it matters with whom you interact and what the cost and benefit is
natural selection favours individuals that maximise their inclusive fitness
inclusive fitness theory explains any social interaction, not only cooperation between relatives

3.4 Relatedness(r) and kin discrimination
High relatedness through
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limited dispersal => keeps relatives together and favours indiscriminate cooperation (no
discrimination is required)
Kin discrimination: allows individuals to selectively cooperate directly with relatives: kind
recognition is an individual’s ability to distinguish between genetic related and non-related
individuals.
o Primates and humans have cognitive ability to recognize each other
o Ants form odour (Gestalt) to recognize colony member
o amoeba
green beard effect: mechanism to recognize other carriers of the cooperative allele. The
cooperative allel is here linked to the “green beard”, no common ancestry.
o r = 1at green beard locus
o r= low at the rest of the genome

3.5 High relatedness and kin competition:
High relatedness can promote kin competition and cancel out cooperative benefits.
inelastic population (can’t grow): by helping on, one indirectly harms other
elastic population: extra offspring by cooperation
global competition: cooperation will lead to higher success probability

Selection mainly acts on the individual as the carrier of genes and not on a whole group!

3.6 Conditional cooperation:
Individuals can decide whether to cooperate or not
Prisoner’s dilemma: Snowdrift game
better if you defect in both scenarios! Here it depends on what the other does!

Other typical human interaction
Iteration: learning and reciprocal interaction
Tit-for-tat: players react to opponents last move (cooperate first and then copy other)
Win-stay-lose-shift: players react to the opponents and their own last move (if you win you repeat,
if you lose you change strategy)
Indirect reciprocity: observer recognizes what others are doing and pick who cooperates
Generalized reciprocity: own decisions are based on previous positive interaction
Costly punishment: punishment and threat are strategies to enforce cooperation

=> Conditional strategies occur outside of human
o Rats groom if they were groomed by another
=> Require cognitive abilities and memory
=> Repeated interactions foster cooperation
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L9: Humans & infectious diseases
Pathogens: virus, bacteria, protists, micro parasites
Obligate: relies on a host for replication and transmission
Opportunistic: replicate in environmental habitats

9.1 Transmission routes:
Environmentally acquired: food, water
Vector: mosquito, tick
Horizontal: via sex, blood, aerosols
Vertically: from mother to offspring
Nosocominal: through hospitalisation

Ethiology: Study of the causes and origin of diseases
Epidemiology: Study of distribution (frequency and pattern) and causes of a diseases in order to
control it
Endemic: local outbreaks, easy to control
Epidemic: large outbreak (f.e. Influenza)
Pandemic: affect large part of worldwide population (swine flu, corona)

9.2Correlation vs Causation
Correlation: means something is linked but one does not have to be the „trigger“ for other
Causation: One thing only happens because of other thing

Distribution of diseases worldwide:
Disease diversity: more diseases at equator than in colder regions
Disease composition: many diseases have limited distribution range (only few occur worldwide,
many locally (mostly at equator))
ð Equator: Diverse but local
ð Temperate zone: Few but more globally spread
Migration patterns correlate with fewer but more widespread pathogens (out of Africa)
=> Globalisation: dispersal is a key parameter for epidemiology

9.3 Where do human infectious diseases originate from?
Correlation with wild animals: higher probability for multi-host and zoonotic pathogens to emerge
when there‘s a high diversity of animals
Correlation with domesticated animals: domestication leads to close interaction with animals which
increases the possibility for pathogens to hop from animals to humans => positive correlation
between years since domestication and shared pathogens
Correlation to agriculture: Agriculture lead to higher density, larger groups, closer interaction,
increased transmission opportunities
o African hunter-gatherers: big reservoir of wild animals, many local pathogens, less acute but
stay for long
o Temperate-zone agriculture: domesticated animals, fewer pathogens but more globally
spread, acute (either recover or die), longlasting immunity

Diseases in temperate-zone: acute, long-lasting immunity, genetic adaption to diseases => lead to drastic
historical change: europeans came to America with diseases they were not immune to (pox) => many died
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9.4 5 stages from animal to human pathogen:
1. Only among animals
2. Primary infection
3. Limited outbreak (among human)
4. Large outbreak (among human)
5. Exclusive human agent (only human)
ð Not every pathogen will go through all stages!
Step 1 to 2:
Reasons:
Land use
Agriculture
Livestock (Viehzucht)
Bush meat use
ð Higher jumping rate
Step 2 to 4:
Ecological:
Urbanization
Travel and migration
Hygiene practice
Climate change
Evolutionary:
Genetic change in pathogen in reservoir
Genetic change in pathogens within human
ð Increased transmission within human
ð Threshold effect (Schwelle, R0 of pathogen)

9.5 Pathogen reproduction number R0
R0: average number of secondary cases generated by a single primary case introduced into a large
population of hosts.
R0 < 1 => infected individuals infect less than one other individual as secondary infect (low level of
transmission but extinct over time)
R0 = 1 => low levels of transmission, infection might persist at low frequency
R0 > 1 => spread of infection through population (over 1 can lead to epidemic spread)

ð R0 < 1 will not lead to mutation within pathogen (in
order to stop mutations, R0 must be below 1)
ð R0 > 1 evolution can act upon the pathogen
Factors that increase R0
Mass breeding => high contact rate => international trading
Migration of virus from remote places to cities due to increased mobility
Higher transmission due to higher sexual partner change
Evolutionary change in the virus (outside and inside the host)
Increased bush meat trades
Human expansion into natural habitat
Traditional health care and funeral practice
Spread in hospitals
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Spreading and virulence of viruses
The more virulent a pathogen is, the less it can be spread because the individuals rapidly die or
because people can get isolated quickly because they notice that they are sick => extinct
Less virulent pathogens have a higher risk to be globally spread because transmission rate is higher

f.e:
Ebola: very virulent, people quickly died thus not globally spread
SARS-2003: spread rapidly but very virulent (immediately sick) => could get extinct => could not
evolve
SARS-CoV-2: spreads rapidly and is not as virulent as SARS-2003 => transmission rate is high
because a lot of carriers don’t know they are sick => many infected people => high chance for virus
to evolve / adapt
Influenza: seasonal flu due to variation in antigenetic properties from year to year (antigenic drift)
ð Antigenic drift: accumulation of small mutation in
antigenic properties
ð Antigenic shift: major, radical change in antigens

Summary:
Human history, migration, agriculture, and domestication of animals explain pathogen origin and
distribution
Emerging pathogens help us to understand how diseases evolve, when pathogens climb up the
pyramid and what human activities promote or hinder their spread
Pathogen reproduction number R0 is a key parameter, determine the success (transmission) of a
pathogen
=> but not yet a good understanding of evolution between host and pathogen => L10
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L10: Human-Pathogen Co-evolution
10.1 Co-evolution:
evolutionary changes that occur within two or more organisms as a response to interaction between them,
and the mutual selective pressures that those interaction causes.
Mutualistic co-evolution: interaction is beneficial for both (humming bird – plant)
Antagonistic co-evolution: interaction is harmful for at least one organism (lynx – snow hare)

10.2 Antagonistic co-evolution:
Evolutionary change in one partner can have dramatic negative fitness consequences for opponent
To alleviate (lindern) the negative fitness consequence, the opponent has to counter adapt
Low evolutionary potential in one partner can lead to its extinction
Population number within interaction comes in “waves”:
o Lot of hare => lynx population will go up => more hares hunted => hare population
decreases => lynx have less to eat and decrease as well => hare population goes up again

Red-queen hypothesis:
If one partner adapts, other partner counteradapts and this leads to new selection pressure for first
partner to adapt again. If one improves, other improves as well => running but staying in the same place

10.3 Co-evolution can lead to…..
…different population dynamics:
Selective sweep: alleles get fixated => accumulated improvements in both populaitons
Dynamic polymorphism: fluncuation in allele frequencies (Schwankung)

…local adaption:
Evolutionary changes differ within different “patches”. In one patch maybe well adapted and in
another patch it would be maladapted.
Local adaption Is often taken as evidence for antagonistic co-evolution
Gene x Environment interaction (GxE): When two different phenotypes respond to environmental
variation in different ways. A good allele in one time and place may be a bad allele in another time
and place

10.4 Host vs. pathogen and their adaptation
Evolvability: is the ability of a biological system to produce phenotypic variation that is both heritable and
adaptive
Human Pathogens
Mutation rate: low high
Generation time long short
Population size small large
Selective spread low high

=>human have no chance to keep pace with rapid evolution of pathogens
=> adaptive immunity: protection of the host from pathogens/toxins by immunological memory
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10.5 Human adaptation to disease
Finding association between allele frequencies in humans and diseases:
Selecting on standing genetic variation
Arising of new allels by mutation

Sickle cell allele (HbS) distribution
“Sick” allele HbS is recessive and should be selected against and go extinct but HbS is maintained. There is
a co-occurrence between malaria and HbS => Heterozygous HbA/HbS individuals have a selective
advantage = beter fitness because it reduces the risk of malaria.
ð Many mutations in red blood cell genes are associated
with malaria resistance
Human leukocyte antigen (HLA) selection
HLA are part the immune response, as they expose non-self structures on the surface. Enormous allele
diversity on human population => Correlation between viral species richness and HLA diversity. Balancing
selection leads to dynamic polymorphism in populations => maintains diversity.
ð Enormous diversity at HLA / MHC loci evolved in
response to pathogen diversity and is maintained by
balancing selection

10.6 HLA & Mate choice experiment
Better partner if he has dissimilar HLA /MHC profiles
ð Sex is good for mixing diversity
ð Natural selection acts on behavioural traits
ð Pathogens seem to exert selection on human
bevahiour (mate choice)
Liffe history traits: describe a species / populations strategies related to reproduction (fitness)
f.e: number of offspring, timing of reproduction, duration of reproductive period,

10.7 Pathogen adaptation to humans
Important pathogen traits: finding a host, infectivity, growth within host, virulence factors & transmission
=> all these factors contribute to virulence and affect pathogen fitness BUT not all traits can be optimized
which leads to trade-offs between growth and transmission rate
Too virulent = host dies too soon = resources not used efficiently
Low virulence: host survival is too long = no transmission
Phases
Phase 1: accidental infection, not adapted to the host
Phase 2: phatogen starts to transmitting, still maladapted with regard to virulence, rapid evolution
Phase 3: virulence settles as an intermediate level where the pathogens transmission success is maximized

10.8 Treatment agains pathogenes
Vaccines: injection of pathogen antigen/toxins à adaptive immune system produces antibodies à
immune agains infection
Response to vaccination: Pathogenes adapt their surface proteins in order to not be recognized by the
immune system that were injected with the vaccine => no immunity => new vaccine needs to be made. Or
phages lose the “virulent” DNA and become avirulent and thus won’t be attacked
ð Vaccination causes arms race, increasing virulence and
fatalities for unvaccinated individuals
ð Natural selection has favoured pathogen traits (high
antigen variation) that allow pathogens to escape
vaccines
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Antibiotics
The evolution of antibiotic resistance is the result of natural selection. When there’s a antibiotic treatment
and only one pathogen with a mutation survives, all new pathogenes will be the adapted mutated version
=> selection for the adapted.
Mechanism of resistance:
Prevent drug entry
Increase drug efflux
Enzymatic activation that cleave antibiotic
Modification of the antibiotic to inhibit its action
=>Here again, not all traits can be optimizes which lead to trade-offs between susceptible and resistant
bacteria
=>removing antibiotics after treatment will leave bacteria with bad fitness, as they adapted, which costed
and then they are maladapted

New approaches:
Combinatory therapy: combine two antibiotics because the chance of two random mutations that
lead to resistance is very low
Phage therapy: page kill bacteria very efficiently
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L11: Microbiome & Cancer evolution

11.1 Introduction to microbiome
Higher Organisms Bacteria
Fixed set of genes that evolves within organism genes and genetic elements move
Share genes with closest relatives share a core genome, differ in accessory genome
20’000 genes 2’000’000 genes
=>similar genes =>different genes

Microbiome: the collection of microbial organisms within a community

11.2 Characterize a microbiome:
Microbes colonize all our external body surface
Can be collected by cultivating on media or by sequencing
o 16S rRNA by PCR amplification: useful for bacterial identification & phylogeny
o shotgun metagenomics without cultivating

11.3 The human microbiome
Our body offers many different ecological niches, each selecting for a specific microbial community.
High variation in the microbiome composition between individual at all body sites but the functions
performed are constant across individuals
Positive correlation between microbiome dissimilarity and phylogenetic divergence over time (the
bigger the divergence, the more dissimilarity)
Diet plays important role to our microbiome

How do we acquire the microbiome and how does it change?
1. Pregnancy: microbiome diversity of vagina and gut
2. Delivery: natural birth => Vaginal microbiome, caesarean section => skin microbiome (clear
differences)
3. Baby: enrichment, milk digestion
4. Child: diversification of microbiome, digest carbohdydrates
=>Microbiome develops from birth to childhood and is influenced by many factors

Antibiotic treatments and diet
Antibiotics long-term reduce the diversity of microbiome significantly
Antibiotic resistance appears and persists after treatment
Gut microbiome differs between Western and non-western societies => reduced in western
=>Our gut microbiome affects physiology, vegetative nervous systeme and the brain

11.4 Microbiome and human disease:
Many links between the microbiome and diseases (correlation vs. causation)
o Causation: the shift in the microbiome that causes a disease
o Correlation: a disease leads to current inflammation which then selects for another
microbiome (its not the microbiome to cause the disease)
Mouse model to establish causalities
o Change in microbiome causes disease X => infect mice to find out if mouse is diseased or not
Microbiome can be used as biomarker for treatments (fecal transplant)
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11.5 Microbial interaction
Assembly of microbiomes
Top-down approach: complex sample -> sequencing -> descriptive analyses -> correlation with disease
Bottom-up-approach: assembly of microbiomes -> ecological dynamics (interaction) -> evolutionary
dynamics -> identify forces that lead to healthy microbiomes

Interaction:
Bacteria often interact through the secretion of small molecules
competition: release toxins to fight each other
Cooperation: share resources through enzymes
=>difficult to find out which factors lead to a dynamic and stable microbiome

11.6 Cancer evolution
What leads to cancer:
Germ cells: genetic predisposition to develop cancer
Somatic cells: cancer is a somatic process of mutation-accumulation and selection => a sequence of
events is needed for a healthy cell to turn into a cancer cell

Key mutational targets:
Oncogenes: control cell growth => mutation leads to uncontrolled growth
Tumor suppressor gene: removes damaged cells => mutation leads to proliferation of damaged
cells
DNA repair genes: DNA errors are fixed => Mutation leads to remaining DNA errors

Carcinogenesis: development of cancer
Multistep mutational process
Associated with chromosomal insability
Tumor mutations need to be on both copies to be harmful (one can partly compensate for the
mutated gene)

11.7 Tumors:
Tumors consist of multiple cell lineages => own little ecosystem
Each tumor is unique => makes it hard for therapy
Social interaction between tumor lineages
o Negative interaction: one is harmed (competition)
o Positive interaction: one is benefited (cooperation, synergism)
=>interaction is very important for tumors: tumor growth, metastasis, therapeutic resistance
Therapy:
Targeting selfish or neutral cells
Targeting cooperational cell lines, which provide servise to others

11.8 Cancer lottery
The cancer lottery: given ó lottery ó consequence
Given:
Lifestyle: diet, smoking
Genetic disposition
Exposure to mutagenic agents (radioactive radiation, UV, chemicals)
Evolutionary trade-offs:
Consequence:
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Mutational patterns
Selection
Cancer adaption
Fatale consequences

11.9 Trade-offs:
1. Evolutionary trade-offs:
DNA double strand breaks: recombination is beneficial ó chromosome instability
Tissue regeneration: regeneration capacity of stemcells ó immortal cells that replicate
Inflammation: remove pathogens ó causing DNA damage
=>either get rid of these characteristics or have cancer under control
=> has no eyes for the future, selects for what is best in the moment => winners of today are the loosers of
tomorrow

2.Life history trade-offs:
Dark skin -> out of Africa -> light skin -> Australia -> maladapted -> increased skin cancer risk
Women have less babies -> less pregnancies -> different hormone levels -> breast & ovarian cancer
Growing up in clean environment -> low exposure to pathogenes -> evolutionary mismatch ->
modern disease like asthma, allergies, diabetes and leukemia

Why is cancer not selected against?
Cancer mostly evolves in older people after they had offspring (after reproductive period). Natural
selection selects for good fitness of individual. Selection against any kind of disease that manifests after
reproductive period is absent or weak!

Peto’s paradox: no correlation between cancer incidences and body mass longevity
What we think: Elephant has a higher risk of cancer than mouse has. => Wrong!
Elephants have 20 tumorsuppressor genes
Elephants have a better DNA repair mechanism than a mouse => less mutations