View
40
Download
0
Category
Tags:
Preview:
DESCRIPTION
R 0 , the net reproductive rate, is a fitness estimator:. R 0 = S l(x)b(x). Time of first reproduction? mature fast and have babies (lay eggs) right away. Survivorship after reproduction? high, robust and strong mature body. Fecundity in successive years? - PowerPoint PPT Presentation
Citation preview
R0, the net reproductive rate, is a fitness estimator:
R0 = l(x)b(x)
Time of first reproduction?• mature fast and have babies (lay eggs) right away
Survivorship after reproduction?• high, robust and strong mature body
Fecundity in successive years?• high: many offspring every year
Offspring survivorship?• high: large newborns, fed and protected by their parents
Longevity?• high: become very old and reproduce till the end
Tradeoffs- a key concept in evolutionary ecology -
+ = false
An evolutionary tradeoff between two traits exists when an increase in fitness due to a change in one trait
is opposed by a decrease in fitness due to a concomitant change in the second trait.
Why should there be tradeoffs?
1) Limiting energy or materials. Increased allocation of energy or material to one function, reduce allocation to another function.
2) Traits evolved by natural selection of the fittest phenotype. Traits are already organized to give organisms peak fitness, maximizing the use of energy and materials.
Trait Dim
ension 1
Trait Dimension 2
Tradeoffs in life history evolution
1) A tradeoff between survivorship and reproduction
Mammals: species that breed early, have a shorter life span.(Both axes corrected for differences in female body size)
(Harvey and Zammuto 1985)
Tradeoffs in life history evolution
2) A size-number tradeoff for offspring
Across 64 grassland species, species that produce larger seeds produce fewer seeds.
(Coombs and Grubb 2003)
Tradeoffs in life history evolution
3) A size-growth tradeoff
Among mammals, excluding humans, species with larger brains relative to body mass, have lower population growth rates (rmax ). The relationship is weaker in species with
cooperative breeding (precocials)(Isler&Sckaik, 2012)
Tradeoffs in life history evolution
4) A size-size tradeoff
Among mammals, but excluding humans, species with more fat tissues have smaller brains relative to body size.
(Navarrete et al. 2011)
Residual brain mass
Re
sid
ual
adi
pos
e d
ep
osits
Implication for human evolutionof large brains
Brains are “expensive tissues”. In many animals they cannot grow bigger without decreasing the size of other organs (gut, gonads, etc).
= gray ceiling
However, some groups of animals overcome the prohibitive cost of larger brains by
sharing costs among group membersreducing metabolic expenditures (upright walk)
Death valley Hot & dry most of the time, but reliable winter rains!
Ecological circumstances determine which strategy is best.
Annuals germinate and spring and can set seeds within weeks.
The drier the desert, the more annual plants there are.
Spring in Death Valley
General Principle:
When risks to adults are high, species should invest less in traits that increase survivorship (annuals).
When risks to adults are few, species should invest in surviving and reproducing repeatedly (shrubs).
Pheasant nest Bald eagle nest
General Principle:
When newborns are safe, species can invest more in parental care, at the cost of reduced brood size (tree-top breeding eagle).
When newborns are unsafe, species should invest more in spreading the risk by increasing brood size, at the cost of reduced parental care (ground-breeding pheasant).
A corn field in spring An oak forest
Typical weed seeds Acorns
General Principle:
In an unstable environment (population size << K), organisms invest in breeding early and many small offspring (thus maximizing r: weeds).
In stable environments (population size ≈ K), organisms invest in provisioning for their offspring (large seeds), at the cost of producing fewer offspring (thus maximizing competitive ability: trees)
These strategies are often called r-selected (weed) versus K-selected (tree).
Pygmyism
Pygmy elephants of Borneo
Pygmy hippo of West Africa
Pygmy possum of Australia
Pygmyism
Baka pygmies of Africa
Batak pygmies of the Philippines
Why are the pygmies short? Bamberg Migliano, Vinicius, Mirazon Lahr 2007. Life history trade-offs
explain the evolution of human pygmies. PNAS 104: 20216-20219
pygmies
non-pygmies
Pygmies initially grow at a similar rate but stop growing around age 14 rather than 18.
Why are the pygmies short?
pygmies
non-pygmies
Pygmies have much lower survivorships. Their life expectancy at birth is between 16 and 24, compared to 34 to 48 in non-pygmy
hunter-gatherers
chimps
Why are the pygmies short?
pygmies
non-pygmies
Pygmy fertility peaks at ages 20-24 compared to 30-34 in non-pygmy hunter-gatherers.
Pygmies are short because they live in a dangerous environment. To ensure that enough
females live to reproduction, pygmies reach sexual maturity earlier, at the cost of reduced
allocation of limited resources to growth.
Short stature is therefore not the goal of adaptive evolution, hastened maturity is, short stature is the
price paid.
5) A size-growth tradeoff
Summary:
1.Species evolve to make maximal use (fitness) of available resources and metabolic limitations.
2.Different fitness components therefore compete for resources and energy. This generates evolutionary tradeoffs.
3.Between species, one can observe tradeoffs as correlated variation among traits.
4.Species take different positions along the tradeoff axes due to differences in their ecological circumstances (resource abundance, risks, stability).
Recommended