Life History
Dec 16, 2015
Life History
Introduction Different species reproduce at vastly
different rates over lifetimes that may differ dramatically.
Life history consists of the adaptations of an organism that influence the number of offspring it will produce, size and age at reproductive maturity, number of reproductive events, etc.
Introduction Why does diversity in life histories exist?
Why haven't rapidly reproducing asexual bacteria taken over the world? The study of life history investigates the underlying strategies that have generated the enormous diversity found among organisms.
Life History Variation Arises from Constraints The limited resources available must be
divided among all of an organism's biological needs for survival and reproduction (e.g., maintenance, defense, growth). The need to allocate limited resources generates trade-offs. For example, energy spent on growth cannot be spent on producing eggs.
Trade-Offs Maximizing one
life history trait may come at a cost to another. Grow large OR
reproduce early Attract mates OR
hide from predators
How Many Eggs? In birds, clutch size
(the number of eggs laid in one reproductive bout) increases with increasing latitude and day-length. More food available. Unpredictable from
year to year.
Successful Life Histories A successful life history strategy is
indicated by a stable or growing population; or in other words, a population is successful if r ≥ 0. where r is traditionally used to represent the
rate of growth of a population. Values for r can be categorized like this:
Positive (r > 0): the population is growing. Negative (r < 0): the population is shrinking. Near 0 (r = 0): the population is stable.
Age Structure A graph of age
structure can give us information about whether a population is growing, remaining stable or declining.
Life Tables Detailed, age-specific population data
can be summarized for analysis using a life table, which categorizes the probabilities of reproduction, death, and survivorship for different ages or age groups.
Survivorship is roughly the opposite of mortality—it is the proportion of a cohort of individuals that survives to a given age.
Survivorship Curves Information in the
life tables can be used to plot survivorship curves.
Ecological Management Using Life Table Data Ecologists build
and use life tables to address important management questions.
What is the best life stage to protect loggerhead turtles?
Trade-Offs Animals only have a certain amount of
resources to divide between growth, reproduction, etc. Results in trade-offs A strategy that works well in one
environment may work poorly in another. Within limits, individuals can modify their strategies to respond to ever-changing external factors. Natural Selection
Trade-Offs Many organisms
(like the SimSturgeon) face a trade-off between fecundity and age of maturation.
Trade-Offs A trade-off that is seen
with real sturgeon is between fecundity and body size. Larger females can
produce more eggs. Waiting to reproduce
can allow the female to have more offspring,
But, she has a greater chance of dying before reproducing.
Adult Survival and Reproductive Allocation Reproductive effort: the allocation of
energy, time, and other resources to the production and care of offspring.
Any energy or biomass used for one function, such as growth, reduces the amount of energy available for another function, such as reproduction. Trade-offs between reproduction, growth,
and maintenance.
Trade-Offs Trade-off between
reproduction and growth/survival. Douglas Firs grow
less in the years that they reproduce more (many cones).
Red deer have a higher winter mortality when they are raising calves.
Classifying Life Histories In areas that are frequently disturbed
through fire, floods, storms, etc. organisms that could reach maturity and reproduce quickly, producing many offspring would be favored. (r-selected) Weedy species
In stable environments, it would be better to grow larger, reproduce later, having fewer, larger offspring. (K-selected) Beter competitors
Life History Classification r vs K selection
r selection (per capita rate of increase) Characteristic high population growth rate. Strongest in species colonizing new or
disturbed habitats. Type III survivorship curve
K selection (carrying capacity) Characteristic efficient resource use. Most prominent in species whose populations
are near the carrying capacity much of the time. Type I or II survivorship curve
Life History Classification r and K are ends of a continuum, while
most organisms are in-between. r selection: favored in unpredictable
environments. K selection: favored in predictable
environments.
r and K: Fundamental Contrasts r-selected species:
High intrinsic rate of natural increase (r)
Low competitive ability
Rapid development Early reproduction Small body size at
first reproduction Semelparous –
single reproductive event
Many small offspring produced
r and K: Fundamental ContrastsK-selected species:
Low intrinsic rate of natural increase (r)
Strong competitive ability (K)
Slow development Late reproduction Large body size Iteroparous –
repeated reproduction Few large offspring
produced Parental care
Plant Life Histories Two most important variables exerting
selective pressures in plants: Intensity of disturbance:
Any process limiting plants by destroying biomass.
Intensity of stress: External constraints limiting rate of dry
matter production.
Plant Life Histories Four Environmental Extremes:
Low Disturbance : Low Stress Low Disturbance : High Stress High Disturbance : Low Stress High Disturbance : High Stress
No viable strategy here.
Plant Life Histories Ruderals (highly disturbed habitats)
Grow rapidly and produce seeds quickly. Disturbance frees them from competition.
Stress-Tolerant (high stress - no disturbance) Grow slowly - conserve resources.
Competitive (low disturbance low stress) Grow well, but eventually compete with
others for resources.
Opportunistic, Equilibrium,and Periodic Life Histories Winemiller and Rose proposed new
classification scheme based on age of reproductive maturity (α), juvenile survivorship (lx) and fecundity (mx). Opportunistic: low lx - low mx - early α Equilibrium: high lx - low mx - late α Periodic: low lx - high mx - late α
Complex Trade-Offs What happens
when the benefits of raising a brood are reduced when some offspring are lost? Continue care of
remaining offspring?
Or, start over?
Complex Trade-Offs To deal with trade-
offs, some species morph into completely different forms, either as alternatives or sequentially through one lifetime. Sneaky male bluegill
sunfish look like females.