Population Biology Primer PDF

Summary

This document is a primer on population biology, focusing on the challenges faced by small populations and the genetic factors influencing extinction. The lecture covers topics including population growth rates, demographic stochasticity, and the impact of inbreeding. This introduction to conservation genetics is suitable for postgraduate courses.

Full Transcript

1

Population biology: a primer
Tania Gilbert, BSc, MSc, PhD
Conservation Biologist, Marwell Wildlife

Learning outcomes

2

At the end of this lecture you will be able to:
1. Demonstrate knowledge & understanding of the
challenges faced by small populations
2. Evaluate the genetic factors that cause population
extinction & propose management interventions to counter
these

3

Introduction
• Many species threatened with extinction
• Human related activities reduce population sizes (deterministic
threats) where they then become susceptible to additional
environmental, catastrophic, demographic and genetic factors
(stochasticity)

4

The extinction process

The extinction process
• Declining population paradigm
– The cause of ‘smallness’ (deterministic threats)
• Habitat destruction
• Habitat degradation
• Habitat fragmentation
• Over-hunting & live capture
• Pollution
• Invasive species
• Major disease outbreaks

5

The extinction process
• Small population paradigm
– The effects of ‘smallness’
– Factors causing extinction under the small-population paradigm
• Environmental stochasticity
• Catastrophes
• Demographic stochasticity
• Genetic deterioration

6

• Environmental stochasticity: random unpredictable variation in
environmental factors such as temperature and rainfall

7

• Demographic stochasticity: random unpredictable variation in
sex ratios, and birth and death rates
• Catastrophes: extreme environmental events such as disease
epidemics or hurricanes
• Genetic stochasticity: inbreeding depression, loss of genetic
diversity and the accumulation of deleterious mutations
• Small populations tend to be more inbred, lose genetic diversity
more rapidly, and have a reduced ability to adapt to
environmental change than large populations

The extinction process
• Small population paradigm
– The effects of ‘smallness’
– Factors causing extinction under the small-population paradigm
• Environmental stochasticity
• Catastrophes
• Demographic stochasticity
• Genetic deterioration

• Even if the cause of the original population decline is removed,
the problems associated with small populations will persist
• Threatened species have small and/or declining populations

8

9

Demography: the numbers game
• Population growth rates
• Mortality, reproductive rates and life tables
• Demographic stability
• Demographic stochasticity

Stable age distributions
• An age pyramid graphically
demonstrates the sex and
age structure of a population

Scimitar-horned oryx EEP

11

Demographic stochasticity
• If we genuinely want to understand how a population is likely
to behave, we need to understand how stochasticity impacts
it
• Fluctuation in annual life-history events due to chance alone
– Births
– Deaths
– Sex ratio at birth

• Demographic stochasticity has a larger impact in smaller
populations

12

600

Population size

500

400

λ = 1.053
300

200

100

0
1

2

3

4

5

6

7

8

9

10

Year

11

12

13

14

15

16

17

18

19

20

21

13

Including stochasticity
600

500

400

N

λ = 1.053
300

200

100

0
1

2

3

4

5

6

7

8

9

10

Year

11

12

13

14

15

16

17

18

19

20

21

The effect of environmental & demographic
stochasticity: 1 iteration

14

The effect of environmental & demographic
stochasticity: 1 iteration

15

The effect of environmental & demographic
stochasticity: 1 iteration

16

The effect of environmental & demographic
stochasticity: 1 iteration

17

The effect of environmental & demographic
stochasticity: 10 iterations

18

The effect of environmental & demographic
stochasticity: 100 iterations

19

The effect of environmental & demographic
stochasticity: 500 iterations

20

21

Population genetics

22

Population genetics
• The long-term survival of a population depends on the retention
of genetic diversity
• Genetic variation enables populations to retain evolutionary
potential for adaptation to both short- & long-term changing
environmental conditions
• New infectious pests, parasites & diseases, food sources,
competitors, predators, pollution, global climate change

• “Inbreeding & loss of genetic diversity are unavoidable in small
populations of threatened species. They reduce reproduction
and survival in the short term, diminish the capacity of
populations to evolve in response to environmental change in
the long term, and thereby increase extinction risk”
- Frankham et al., 2010

23

What is genetic diversity?
• Genetic diversity is the variety of alleles & genotypes present
in the group (species, population, group) under study
• All genetic diversity is originally generated by mutations that
change the nucleotide sequence in the DNA
• Polymorphism
• Allelic diversity
• Average heterozygosity
– Expected heterozygosity
– Observed heterozygosity

24

What is genetic diversity?
E.g. African lions
• 23% of coding loci were polymorphic
• 7.1% of loci were heterozygous in an average individual
• There were an average of 1.27 alleles per locus (allelic
diversity)
• Typical levels of genetic diversity for a non-threatened
mammal species

25

Allelic diversity
• Different forms of an allele
for a particular trait (e.g.
eccentricity)
• Alleles present: A, b, c & d
• Allelic diversity = 4
• Allelic diversity important
for evolutionary adaptation
to environmental change

Ab
Ac

cc

cd
Ad

26

Heterozygosity
How alleles are combined

AA

Ab

Homozygote: same alleles (AA)
Heterozygote: different alleles (Ab)

27

Observed heterozygosity (Ho)
• Proportion of individuals in the population that are
heterozygous
• e.g. 23 heterozygotes & 42 homozygotes
• Ho = 23/65 = 0.35

Expected heterozygosity (He) otherwise
known as Gene Diversity (GD)

28

• Proportion of animals in the population expected to be
heterozygous if random breeding takes place
• It is defined as the probability that two homologous genes
randomly drawn from the population are distinct alleles
• It is the mean heterozygosity that would exist in a population
if it were in Hardy-Weinberg equilibrium
• The rate at which a population responds to selection is
related to expected heterozygosity
pp.69 – 86 Frankham et al. 2010. Introduction to Conservation Genetics

29

Small populations & the
effective population size

30

Small populations & genetics
• Evolutionary processes in small populations differ from those
in large populations
• In large populations selection is the predominant force for
genetic change
• In small populations, the role of chance predominates & the
effects of selection are greatly reduced or removed
• Chance introduces a stochastic element into the evolution of
small populations

• Small population have lower levels of genetic diversity &
become inbred at a faster rate than large populations, and so
are more likely to go extinct

31

Effective population size Ne
• Genetically, it is not the actual size of the population that is
important, rather the portion of the population that passes its
genes onto the next generation i.e. the effective population
size (Ne)

N

Ne

32

Effective population size Ne definition
• The Ne is the number of individuals that would result in
the same loss of genetic diversity, inbreeding or genetic
drift if they behaved in the manner of an idealized
population
• Idealized population: a conceptual random mating
population with equal numbers of hermaphrodite
individuals breeding in each generation, and Poisson
variation in family sizes

Effective population size Ne

Assumptions of an idealized population
–
–
–
–
–
–

No fluctuations in population size from generation to generation
Discrete (non-overlapping) generations
Equal family sizes
Hermaphrodite individuals
Random mating
N = 394; Ne = 74; Ne/N ratio = 0.20

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34

Effective population size Ne
• In reality the Ne is often much smaller than N
• It is often expressed as Ne/N ratio
• The rate that genetic diversity is lost is dependent on Ne
not N
• 50/500 rule

• Ne > 50 short-term – to avoid the immediate deleterious
effects of inbreeding
• Ne > 500 long-term – to allow new mutations to restore
heterozygosity and additive genetic variation as rapidly as
it is lost by genetic drift
• Now thought that Ne should be at least Ne = 1000, or even
Ne= 5000 to avoid loss of genetic diversity through drift

35

Drift & selection in small
populations

36

Genetic Drift & Selection in small populations
• Consequences of random sampling in small populations as
parents pass their genes onto the next generation:
1. Alleles (both adaptive & maladaptive) are lost due to genetic drift
• Rare alleles are lost by chance
• Potential increase in deleterious alleles

2. Loss of genetic diversity & fixation of alleles within populations
(with the reduction in the ability to evolve)
3. Diversification of allele frequencies between replicate populations
from the same original source

• Loss is inversely proportional to Ne
• Sampling occurs in every generation & the effects are
cumulative
• It is the primary process affecting genetic variation
• Overrides the effects of selection & mutation

37

Genetic Drift
N = 30
1.0

0.9

Allele frequency

0.8

0.7

A
B
C

0.6

D
E

0.5

F
G

0.4

H
I

0.3

J

0.2

0.1

0.0
0

10

20

Year

30

40

50

38

Genetic Drift
N = 300
1.0

0.9

Allele frequency

0.8

0.7

A
B

0.6

C
D
E

0.5

F
G

0.4

H
I

0.3

J

0.2

0.1

0.0

0

10

20

Year

30

40

50

39

Genetic Drift
N = 3000
1.0

0.9

Allele frequency

0.8

0.7

A
B

0.6

C
D

0.5

E
F
G

0.4

H
I

0.3

J

0.2

0.1

0.0

0

10

20

Year

30

40

50

40

Population bottlenecks

Population bottlenecks
• Caused when populations undergo a substantial contraction
– Catastrophes
– Habitat loss
– Population fragmentation

• Created when individuals in the wild migrate to form new
populations
• When individuals from the wild are caught to form captive
populations
• When wild-to-wild conservation translocations take place
• When reintroductions take place

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42

Population bottlenecks

• Threatened populations have lower genetic diversity than nonthreatened populations
• Populations that have gone through bottlenecks have lower
genetic diversity than those that have not
Disease

Habitat loss

Subsequent bottlenecks in a wild population

Time

43

Population bottlenecks

• Threatened populations have lower genetic diversity than nonthreatened populations
• Populations that have gone through bottlenecks have lower
genetic diversity than those that have not

Catch-up

Wild

Captive

Release

Reintroduced

44

Population bottlenecks
• Many threatened species have been bottlenecked
–
–
–
–
–
–
–
–
–
–
–

Amur tiger
Arabian oryx
Black-footed ferrets
California condor
Chatham Island black robin
European bison
Guam rail
Mauritius kestrel
Père David’s deer
Red-ruffed lemur
Scimitar-horned oryx

25
10
7
14
5
13
12
2
~5
7
45

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Inbreeding & outbreeding

46

Inbreeding
• Mating between relatives
• Causes an increase in homozygosity & decrease in
heterozygosity
• Measured by an inbreeding coefficient (F) which is the
probability that two alleles are identical by descent

• Increases the chance of expression of recessive deleterious
alleles in the phenotype
• Can lead to inbreeding depression
–
–
–
–

Increased juvenile mortality
Reduced longevity
Reduced reproduction
Increased susceptibility to disease

47

• Inbreeding depression is found in almost all naturally
outbreeding species (90%), but varies depending on the
species, population & environment

• Inbreeding increases the risk of extinction (80-90% of
deliberately inbred populations went extinct)
• Applicable to a wide range of species
• It has caused population declines & extinctions in the wild in…
– Bighorn sheep, Florida panthers, heath hens, greater prairie
chickens, adders, wolf spiders, middle spotted woodpeckers
& many plants species

48

Inbreeding coefficient (F): a measure of the relatedness of
an individual’s parents

♂

♀
Ab

cd
0.5 c

♂

0.5 A

0.5

A

Ac

0.5 A

AA

49

Inbreeding coefficient (F): a measure of the relatedness of
an individual’s parents

♀
Ab

♂

0.5 A

0.5

A

Ac

0.5 A

AA
• A = 0.5 x 0.5 x 0.5 = 0.125

50

Inbreeding coefficient (F): a measure of the relatedness of
an individual’s parents

♀
Ab

♂

0.5 b

0.5

b

bc

0.5 b

bb
• b = 0.5 x 0.5 x 0.5 = 0.125

51

Inbreeding coefficient (F): a measure of the relatedness of
an individual’s parents

♀
Ab

♂

0.5 A

0.5

A

Ac

0.5 A

AA
• F = probability of AA or bb = 0.125 (AA) + 0.125 (bb) = 0.25
• 12.5% chance ‘AA’ + 12.5% chance ‘bb’ (homozygous)
• 75% chance A or b with c or d (heterozygous)

52

Inbreeding coefficient (F)
• Father/daughter
• Brother/sister

F = 0.2500

• Half brother/sister
• Uncle/niece
• Grandfather/granddaughter

F = 0.1250

• First cousins

F = 0.0625

• Unrelated male & female

F = 0.0000

Outbreeding depression

53

• Deleterious effects (e.g. reduced reproductive fitness such as
reduced offspring survival) that sometimes occur as a result
of outcrossing genetically differentiated populations
• Expected in crosses between different sub-species or
species e.g. crosses between Bengal & Amur tigers would
produce offspring maladapted to both environments
• Ibex in the Tatra Mountains, Slovakia
– Introduction of desert-adapted sub-species from Turkey & Sinai
– Hybridised with local population
– Maladapted hybrids mated in early autumn & gave birth in
February at the height of winter. Offspring did not survive
– The population went extinct

Outbreeding depression
• Inbreeding and outbreeding depression can occur
simultaneously (Arabian oryx)

• Heterosis (hybrid vigor) – improved fitness of hybrids

54

Population structure &
fragmentation

55

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Population structure & fragmentation
• Population fragmentation results in a number of small
populations. At risk of factors that impact all small populations
EU BT 0
EU LRZ 8
EU BT 1 & 8
EU BT 8
Non-EU

Ne = 10

Ne = 16

Ne = 33

Ne = 17

Ne = 0

Population structure & fragmentation

57

58

The extinction vortex

Habitat loss

Epidemic disease

Overhunting

59
Invasive species

Small fragmented
isolated
population
Demographic
stochasticity

Catastrophes

Reduced N

Extinction
vortex

Environmental
variation

Reduced
adaptability, survival
and reproduction

Loss of genetic
diversity and
inbreeding

The extinction vortex
• The adverse interaction between human
impacts, inbreeding & demographic
fluctuation that results in a feedback loop
that spirals towards extinction
• Small populations become more inbred &
less demographically stable, further
reducing N & increasing inbreeding
• The complicated interactions between
genetic, demographic and environmental
factors can make it extremely difficult to
identify the immediate cause of any
extinction event
• Small populations are more susceptible
to extinction than larger ones for
demographic, genetic and ecological
reasons

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