Demography and Genetic Variation (first 4)

Question 1

Define demography

Answer 1

The study of the age structure and growth of populations. Encompasses current stock of human population (age/sex structure) and the flow of vital events (births/deaths/migrations).

Question 2

Define crude birth rate. What is the world average? What is the UK average?

Answer 2

Number of births per unit of person-time.
20 births per 1000 person/years
UK: 10.7 per 1000 person years

Question 3

Define crude death rate. What is the world average?

Answer 3

Number of deaths per unit of person-time. 9 per 1000 person/years

Question 4

Define crude rate of natural increase/decrease. What is the world average?

Answer 4

Crude birth rate - crude death rate. 11 per 1000 person years.

Question 5

Define total fertility rate. What is it in the UK?

Answer 5

Total number of babies per average reproductive lifetime. 2 per woman.

Question 6

Define gross reproductive rate. What is its relationshio to total fertility rate. What is it in the UK?

Answer 6

Total number of daughters per average reproductive lifetime.
Gross reproductive rate = proportion of female births * total fertility rate.
Sex ratio at birth:105 boys to 100 girls
100/(100+1.05) * total fertility rate = 0.98 daughters per women’s reproductive lifetime.

Question 7

What is the infant mortality rate? What is it in western vs low income countries?

Answer 7

Probability of dying before the first birthday.
Western less than 1 per 1000 live births.
Low income greater than 100 per 1000 live births.

Question 8

What is the child mortality rate?

Answer 8

Probability of dying before the age of 5

Question 9

What is the adult mortality rate?

Answer 9

Probability of dying between 15 and 60 years.

Question 10

What do you need to do to compare birth and death rates?

Answer 10

Age standardise

Question 11

What is the age-standardised death rate?

Answer 11

Overall death rate of the population of interest after removing the effect of age. Estimate by calculating a weighted average of the age-specific death rates in the population of interest, where the weights represent the contribution of each age stratum in a standard population.

Question 12

In a life table, how do you calculate number dying during age interval?

Answer 12

Number living at beginning of age interval * proportion dying during age interval

Question 13

In a life table, how do you calculate number of person years of life lived in age interval?

Answer 13

Number living at beginning of age interval - 0.5(number dying during age interval).
Assume deaths to occur linearly within each age year. Can’t do this for ages 0-1.

Question 14

In a life table, how do you calculate the number of person years of life lived in this and all subsequent age intervals?

Answer 14

Sum of number of person-years of life (L(x)) lived in age interval from age x to final row.

Question 15

How do you calculate the life expectancy at the beginning of an age interval in a life table?

Answer 15

e(x)= T(x) / l(x)

T(x) = number of person years of life lived in this and all subsequent age intervals
L(x) = number living at beginning of age interval

Question 16

Define risk

Answer 16

Probability of an event occurring over a specific amount of time

Question 17

Define rate

Answer 17

Ratio - measure of frequency per unit time.

Question 18

Define net reproductive rate

Answer 18

Average number of daughters per mother expected to survive to reproductive age.
(Birth cohort of girls - expected number of deaths)

Question 19

What information do you need to be given to calculate a life table?

Answer 19

Proportion dying during different age intervals

Question 20

What are the limitations of life tables?

Answer 20

Usually based on estimated age-specific mortality rates in recent past. Projections not representative due to current advances in medicine, public health and safety standards which did not exist in the early years of the cohort.

Question 21

What is health expectancy?

Answer 21

Remaining number of years a person can expect to live in a specific health state

Question 22

What are Omaran’s three typical phases of transition?

Answer 22

1. Age of pestilence and famine: high mortality, low life expectancy (20-4), increase in infectious diseases, lots of dietary deficiencies.
2. Age of receding pandemics: declining mortality, rising life expectancy (30-50). Shift from infectious to chronic diseases. Transition period.
3. Age of degenerative and man-made diseases. Low mortality, high life expectancy (50+). Late 19th-20th century. Infectious disease transferred to chronic disease.

Question 23

When were the biggest improvements in mortality risk?

Answer 23

Children = early 20th century reduced by 50%
Adult = late 20th century

Question 24

Why did the rapid improvement in child survival in early C20 England and US happen?

Answer 24

General diffusion of useful knowledge including domestic medicine

Question 25

Why did food improvements not contribute to the rapid improvement of child survival?

Answer 25

In England there were already laws in place to stop people not getting enough food (workhouses).

Question 26

Which other factor was mentioned as not the reason child survival improved?

Answer 26

Professional medicine

Question 27

What is the name of the graph showing the changing relationship between life expectancy and income during C20? What is the major observation?

Answer 27

Preston curve

1. Rising income doesn’t account for major gains in life expectancy at birth

Question 28

What did the census at the beginning of the C20 show?

Answer 28

• Not a strong relationship between social rank and child survival (under 5 mortality rate) at the beginning of the 20th century
• Mortality more related to residence than social class

Question 29

Why did education not help raise child mortality rate?

Answer 29

Education only helps if it enables you to make better use of what is known.

Question 30

Give an example of new knowledge around the turn of the 20th century?

Answer 30

in 1889 thought diarrhoea was caused by sour milk/unripe fruit/inhalation of sewer gas/emanations from the soil. In 1899 ‘no doubt that the immediate cause is an infection of the alimentary canal, by bacteria contained in milk or other forms of food’

Question 31

What were the two major transitions in mortality risks in adults?

Answer 31

The decline in TB

The decline in tobacco-caused disease (the single most important contributor)

Question 32

Why did TB decline?

Answer 32

Developed streptomycin

Question 33

Why did tobacco-caused disease fall?

Answer 33

• New scientific evidence
• Number of articles on smoking and health rose
• Percentage of population that believed smoking caused lung cancer rose
• People expected doctors and the government to give lifestyle advice

Question 34

What are the current failures in life expectancy?

Answer 34

1. Unequal success across social strata
2. Unequal success between countries
   - Less access to healthcare= less knowledge

Question 35

What are the main contributors to health inequalities currently?

Answer 35

Vascular diseases

Tobacco-caused disease

Question 36

How many nucleotides in the human genome?

Answer 36

3 billion

Question 37

How many genes in the human genome, and thus what proportion of the genome are genes?

Answer 37

20,000, so 2%

Question 38

Which groups of organisms have the largest genome size?

Answer 38

Protists, plants (over 100Gb)

Question 39

What proportion of genetic content do humans share?

Answer 39

95%

Question 40

What proportion of genetic content do humans share? What proportion do they share excluding structural variants?

Answer 40

95%

99.9%

Question 41

Define allele

Answer 41

Different versions of a genetic locus

Question 42

Describe multiple genome alignment

Answer 42

Multiple genomes
Arbitrarily take one sequence as reference sequence
Count the differences between one genome and another

Question 43

How can you represent multiple genome alignment?

Answer 43

Make a genetic distance matrix (table according to the pairwise comparisons)
Triangle with lengths proportional to genetic distance for 3 people
3D shape for 4x4 matrix or higher. Can do with principal component analysis.

Question 44

Where in the world is there most genetic diversity?

Answer 44

More within Africa than within all of the non-Africans

Question 45

Where in the world is there most genetic diversity?

Answer 45

More within Africa than within all of the non-Africans

Question 46

What are genetic trees?

Answer 46

A representation of an evolutionary timescale with differences between individuals corresponding to mutations which have occurred since the most recent common ancestor.

Question 47

How can you use genetic trees?

Answer 47

If you assume mutation rate = 0.5x10-9/bp/yr
Count number of mutations
Work out how far back two species diverged

Question 48

What does fossil evidence show?

Answer 48

Humans colonised the rest of the world from Africa
Mated with archaic ancestors of humans
Means that there isn’t really a tree of human populations but a tangled web of interactions

Question 49

Describe the processes of human evolution

Answer 49

1. Natural selection: positive, negative or balancing
2. Germline mutation
3. Genetic drift
4. Demography (influences strength of drift and efficacy of selection)

Question 50

What is negative selection otherwise known as?

Answer 50

Purifying selection

Question 51

Which model do we use to look at effects of population size on genetic drift? Explain

Answer 51

Wright-Fisher model
Plot generation x vs allele freq y
With no mutation and no selection pressure, over time a small population will often fix at 100% or 0% allele freq (genetic drift larger)
With a larger population, most stay about 50%.

Question 52

Define genetic drift

Answer 52

Random changes in allele frequency from one generation to the next.
Stronger in smaller populations, leading to a loss of genetic diversity

Question 53

Describe the founder effect

Answer 53

Founder population is a much smaller gene pool than the original population. Can alter allele proportions

Question 54

Give 4 examples of deleterious pathogenic alleles persisting due to small and isolated populations

Answer 54

1. Amish, Hutterite and Mennonite communities in N America. Increased prevalence of microcephaly and other genetic diseases.
2. Tay-Sachs disease in Ashkenazi Jews
3. Finnish Disease Heritage of 36 monogenic diseases
4. Ireland - Coeliac disease

Question 55

What is Tay-Sachs disease?

Answer 55

An inherited metabolic disorder in which certain lipids accumulate in the brain, causing spasticity and death in childhood

Question 56

Give 3 categories of disease and examples

Answer 56

1. Mendelian e.g. CF, Down, Sickle-Cell, Charcot-Marie-Tooth
2. Complex, influenced by both environment and ancestry e.g. Alzheimer’s, cardiovascular disease, type II diabetes, Parkinson’s
3. Environmental diseases. Often infections, genetic component with regards to susceptibility e.g. flu, hepatitis, measles

Question 57

What is the risk odds ratio?

Answer 57

Allele effect on risk of developing a disease
OR = P(disease/carrying allele)/P(no disease/carrying allele) over P(disease/not carrying allele)/P(no disease/not carrying allele)

OR>1 increased risk
OR<1 reduced risk (protective)
OR 1 no effect

Question 58

How do you identify low frequency alleles with large effects?

Answer 58

Linkage analysis - should find family carrying the same allele

Question 59

How do you identify high frequency alleles with small effects?

Answer 59

GWAS

Question 60

Describe GWAS

Answer 60

Genome wide association studies
Collect controls and cases
Sequence whole genome
Look for variants that tend to be more associated with cases than controls

Question 61

Which test can we use to check if there is an association between a disease and each allele in GWAS?

Answer 61

Chi squared test

Question 62

What is the chi squared equation?

Answer 62

Chi squared = sum (O-E)2/E

E = number of people * allele freq

Question 63

What are the two approaches to using chi squared information?

Answer 63

1. Ranking approach: chi squared values calculated for many loci across the genome. Loci ranked in order of chi squared and top loci considered for further investigation.
2. Significance threshold approach. Convert chi squared values to p values. Set a genome wide significance threshold (typically 10^-8) and consider all loci with p values less than this).

Question 64

What does P value mean?

Answer 64

Probability of seeing a particular (chi squared) value or greater by chance even if no association.

Question 65

What are the caveats of GWAS?

Answer 65

Computationally intensive - require large sample sizes to achieve sufficient statistical power.
Population structure can lead to false signals of association, i.e. if cases and controls have different genetic ancestry.

Question 66

Why are there lots of GWAS hits on the short arm of chromosome 6?

Answer 66

Immune system here!

Question 67

What were the hoped for benefits of GWAS?

Answer 67

Identification of susceptibility variants

1. New biological insights –> clinical advances in therapeutic targets/biomarkers/prevention
2. Improved measures of individual aetiological processes –> personalised medicine –> diagnostics/prognostics/therapeutic optimisation

Question 68

Why may GWAS not fully deliver?

Answer 68

Most common diseases and traits are highly polygenic, so much of heritability may lie in genetic loci not deemed statistically significant.
Natural selection limits the frequency of variants with large effect size.

Question 69

Why may genes with small effect size be promising targets for drug development?

Answer 69

A drug targeting the associated gene may perturb it more than the GWAS variant does, and hence may have a larger effect on the gene.

Question 70

How do you estimate mutation rate?

Answer 70

1. Dominant disease loci
   - Consider dominant disease-causing gene. Count the number x cases in N families where a child is affected by but neither parent is. Gives estimate of per-generation mutation rate at that locus (mu locus = x/2N)
2. Phylogenetic comparison
   - Compare sequence divergence between species against the estimated time since speciation (using fossils). Mu = D/2T mutation rate per year
3. Direct sequencing
   - Observe de novo mutations as differences between genome sequences of parents and offspring

Question 71

What is the directly measured rate of mutation?

Answer 71

1.75x10-8 per bp per generation, half that estimated from phylogenetic comparison

Question 72

What is the paternal age effect?

Answer 72

Older fathers contribute more de novo mutations