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Life History Strategies

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Title: Life History Strategies


1
Life History Strategies
  • Chapter 5

2
Life History Strategies
  • An organisms life history concerns its lifetime
    pattern of growth and reproduction.
  • Some organisms produce many, usually smaller
    offspring, while others produce fewer but larger
    offspring.
  • Some reproduce only once, others many times.

3
Life History Strategies
  • Understanding these differences in life history
    strategies is vital to understanding how
    populations grow.

4
Reproductive Strategies
  • Semelparity
  • Organisms that produce all of their offspring in
    a single reproductive event.
  • May live several years before reproducing or they
    may have a total lifespan of just one year (e.g.
    annual plants).

5
Semelparity
  • Examples of semelparous organisms
  • Salmon
  • Yucca

6
Reproductive Strategies
  • Iteroparity
  • Organisms that reproduce in successive years or
    breeding seasons.
  • Variation in the number of clutches and number of
    offspring per clutch.

7
Iteroparity
  • Some species have distinct breeding seasons.
  • Ex. Temperate birds and temperate forest trees.
  • Breeding seasons lead to distinct generations.

8
Iteroparity
  • Some species reproduce repeatedly and at any time
    during the year (continuous iteroparity).
  • Ex. Some tropical species, many parasites, and
    humans.

9
Reproductive Strategies
  • Environmental uncertainty favors iteroparity.
  • If survival of juveniles is poor and
    unpredictable, selection favors
  • Repeated reproduction.
  • Long reproductive life.
  • Spread the risk over a longer period (bet
    hedging).

10
Reproductive Strategies
  • A stable environment favors semelparity.
  • An organism can put all of its efforts into
    reproduction (e.g. annual plants producing many
    seeds) instead of self-maintenance.
  • If environment becomes stressful, problems arise
    annual plants have to rely on dormant seeds.

11
Reproductive Strategies
  • Reproductive strategies differ among organisms
    with some breeding continuously, others in
    discrete intervals, and others just once in their
    lifetimes.

12
Age Structure
  • Reproductive strategy has an effect on the age
    structure of a population.
  • Growing populations have a large number of young.

13
Age Structure
  • Semelparous organisms
  • Often produce groups of same-aged young
    cohorts.
  • Cohorts grow at similar rates.
  • Iteroparous organisms
  • Many young at different ages.

14
Age Structure
  • The age structure of populations can be
    characterized by specific age categories
  • Eggs, larvae, or pupae in insects.
  • Years in mammals.
  • Size classes in plants.

15
Age Structure
  • Increasing populations large number of young.
  • Decreasing populations few young.
  • Loss of age classes Influence on population.

16
Age Structure
  • Ex. Overexploited fish populations older age
    classes removed.
  • Reproductive age classes are removed.
  • Leads to reproductive failure.
  • Results in population collapse.

17
Age Structure
  • Ex. Removal of younger age classes.
  • Deer removing all young trees.
  • Population consists of only older trees.
  • When they die, there are no replacements.

18
Mating Systems
  • Sex ratio proportion of males females in the
    population.
  • Applied ecology
  • Hunters prefer deer populations dominated by
    males.
  • Too many males limits population growth.

19
Why Is the Sex Ratio Usually 11?
  • Arent males superfluous? One male can fertilize
    many females.
  • Answer Selfish genes!
  • Populations predominately female - Selection
    would favor sons.
  • Populations predominately male - Selection
    would favor daughters.
  • Over time, sex ratio would be kept at 11.

20
Mating Systems
  • Exception to 11
  • One male dominates in breeding.
  • Occurs in species with
  • Low powers of dispersal.
  • Frequent inbreeding.

21
Mating Systems
  • Ex. Parasitic Wasps
  • Females mate once and store sperm.
  • Females control sex ratio
  • Use sperm to create females.
  • Without sperm to create males.
  • Process termed haplodiploid.
  • Ex. The mite Acarophenox
  • Brood size 20 (1 male).
  • Male mates with sisters, dies before birth.

22
Mating Systems in Animals
  • Monogamy
  • Exclusive mating over at least one breeding
    cycle.
  • Common among birds (90) of species.
  • Advantageous to male to stick around and help
    raise offspring because few would survive if he
    did not.
  • Monogamy is rare among other vertebrates.

23
Mating Systems
  • Polygamy
  • Individuals mate with multiple partners.
  • Polygyny
  • One male mates with multiple females.
  • Females mate with only one male.
  • Polyandry
  • One female mates with multiple males.
  • Males mate with only one female.

24
Polygyny
  • Polygyny one male mates with multiple females.
  • In species where females usually care for the
    young, the male may desert.
  • Mammals tend to be polygynous.
  • Occasionally, females can desert young.
  • A fish may deposit eggs in a males territory and
    then leave him to guard the eggs.
  • He may guard the eggs of several females.

25
Mating Systems
  • Mating systems may be influenced by spatial and
    temporal distribution of females.
  • Monogamous relationships can result from all
    females becoming sexually receptive at the same
    time.
  • Female receptiveness spread over weeks or months
    polygyny can result.

26
Mating Systems
  • Two contrasting examples
  • Common toads lay all their eggs within about one
    week, so a male only has time to mate with one
    female.
  • In the bullfrog, the mating season lasts several
    weeks, giving males time to mate with up to six
    females.

27
Mating Systems
  • Resource-based polygyny
  • Critical resource is patchily distributed or in
    short supply.
  • Male can dominate resource and breed with more
    than one visiting female.

28
Resource-Based Polygyny
  • Disadvantages for the female
  • Must share resources.
  • More females means less success.
  • Advantageous for male to have more than one mate.

29
Mating Systems
  • Non-resource based polygyny
  • Harem-based polygyny is common in groups or
    herds.
  • Elephant seals
  • Protection from predators.
  • Harem master does not remain for long.

30
Non-Resource Based Polygyny
  • Communal courting areas leks
  • Females choose a male after he performs an
    elaborate courtship display.
  • Many females choose the same male.

31
Mating Systems
  • Polyandry one female mates with several males.
  • Much less common.
  • Practiced by a few species of birds.

32
Mating Systems
  • Ex. Spotted sandpiper in the Arctic tundra
  • Reproductive success not limited by food.
  • Females lay up to five 20-egg clutches in 40
    days.
  • Limited by the number of males needed to incubate
    eggs.
  • Females compete for males, defending territories
    where males sit.

33
Mating Systems
  • Ex. American jacana
  • Egg predation is high.
  • Females have large territories with several nests
    each attended by a male.
  • Males incubate eggs.
  • If male tries to abandon nest in order to mate
    with another female, it is likely that he will
    lose his eggs to a predator.

34
Life History Strategies
  • Success of populations
  • Reproductive strategies.
  • Survival strategies.
  • Habitat usage.
  • Competition with other organisms.
  • r and K selection represent two extremes of a
    continuum of life history strategies developed
    by McArthur and Wilson (1967)

35
Life History Strategies
  • r-selected species have
  • High rate of population growth (r).
  • Poor competitive abilities.
  • Example weed that quickly colonizes a vacant
    lot, goes through a few generations and
    disappears as better competitors take over.
  • Grows quickly
  • Reaches maturity, reproduces dies in 1 year
  • Produces lots of small seeds

36
Life History Strategies
  • K-selected species
  • Populations increase slowly toward the carrying
    capacity (K) of the environment.
  • Low reproductive allocations.
  • Iteroparous.
  • High competitive abilities eventually displace
    weedy species.

37
K-selected species
  • Ex. Mature forest trees that occupy a
    non-disturbed habitat.
  • Grow slowly.
  • Reach reproductive age late.
  • Devote large amounts of energy to growth and
    maintenance.
  • Grow to large sizes and shade-out r-selected
    species.
  • Long-lived and produce seeds repeatedly every
    year while mature.
  • Seeds are bigger than r-selected species
    provide food reserves to help them get started.

38
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39
Life History Strategies
  • There is a trade-off between the size and number
    of seeds
  • A few big seeds or lots of small seeds.
  • Animals are r-K selected as well
  • Insects often r-selected.
  • Many young, short life cycle.
  • Large mammals (elephants) K-selected.
  • Grow slowly, have few young, reach large sizes.

40
Life History Strategies
  • K-selected species may be at risk of extinction.
  • Bigger need larger areas.
  • Fewer offspring populations cant recover as
    fast from disturbance.
  • Breed later generation time is long.
  • Population size often small greater risk of
    inbreeding.

41
Life History Strategies
  • The r-K system brings together several life
    history attributes.
  • Reproductive strategy.
  • Habitat selection.
  • Ability to disperse.
  • Population size.

42
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43
Life History Strategies
  • Alternatives to the r and K continuum
  • Ruderals, competitors, and stress tolerators
    (Grime 1977 and 1979).
  • Ruderals (botanical term for weed)
  • Adapted to cope with habitat disturbances.
  • Competitors
  • Adapted to live in highly competitive but benign
    environments (e.g., tropics).
  • Stress tolerators
  • Adapted to cope with severe environmental
    conditions (e.g., salt marsh plants).

44
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45
Life History Strategies
  • Demographic interpretation of this idea
  • Species could either survive a long time as
    adults, grow large, or produce a lot of seeds,
    but not all three.
  • Trade-off.
  • Growth, survival and fecundity triangle.

46
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47
Summary
  • Life history concerns lifetime patterns in
    reproduction and growth.
  • Semelparous
  • Iteroparous

48
Summary
  • Reproductive strategy strongly affects age
    structure.
  • Low ratio of young to adults population in
    decline.
  • High ratio of young to adults population
    growing.

49
Summary
  • Sex ratio
  • 11 ratio expected in most populations.
  • Polygamy is often based on limited resources.
  • Polygynous
  • Males mate with more than one female.
  • Polyandrous
  • Females mate with more than one male.
  • Monogamous
  • Each individual has one mate.

50
Summary
  • Categorizing life history strategies
  • r-K continuum
  • r-selected
  • Poor competitors
  • High population growth rate
  • Disperse well
  • Colonize new habitats
  • Many, smaller offspring
  • K-Selected
  • Good competitors
  • Usually exist in mature habitats, close to the
    carrying capacity.
  • Grow slowly
  • Produce, few but larger offspring

51
Summary
  • Alternative life history strategies
  • Ruderals, competitors, and stress tolerators
    classification
  • Growth-longevity-fecundity triangle
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