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The Evolution of Life Histories

The Evolution of Life Histories. 報告者:王韋政 林致綱. Introduction. Callosobruchus maculatus 四紋豆象 Ficedula albicollis 白領姬鶲. This chapter…. Concentrate on Life history theory . Two approaches: phenotypic and genetic . Which trade-off can be measure.

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The Evolution of Life Histories

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  1. The Evolution of Life Histories 報告者:王韋政 林致綱

  2. Introduction • Callosobruchus maculatus 四紋豆象 • Ficedula albicollis白領姬鶲

  3. This chapter… • Concentrate on Life history theory. • Two approaches: phenotypic and genetic. • Which trade-off can be measure. • Evolution of clutch size, delayed maturity and semelparity. • Phenotypic plasticity of life history.

  4. Approaches to life history evolution • Phenotypic approach =>about the adaptive value of trait. • Genetic approach =>consider about gene frequencies.

  5. Optimality models of life histories • Decision variables(life history trait) => age-specific values of fecundity and mortality • Currency => RVx = Σ(ly/lx) .my .e -r(y-x+1) • Constraint => fitness curve => trade-off curve

  6. Measuring constraints Fecundity

  7. Why phenotypic correlations can’t be used to measure? • Lack of non-adaptive variation in allocation. • Adaptive variation in allocation. or

  8. How can constraints to be measured? • Experimental manipulations -Direct manipulation: clutch or brood size -Indirect manipulation: supplementary feeding • Genetic correlations -Breeding experiment -Selection experiment

  9. Longevity (days) Fecundity

  10. The cost of reproduction • Current reproduction can be increase only at the expense of future survival or fecundity. • Physiological or ecological origin.

  11. male female Gustafsson and Sutherland, 1988

  12. Cost of reproduction • Increased broods size ->increased their provisioning rates. (Nur, 1984a; Reid, 1987; Pettifor 1989) Blue tits Glaucous-winged gull

  13. Trade-off between the number and fitness of offspring

  14. Optimal clutch size in insects and birds • Lack’s hypothesis: As clutch increased, each of nestlings would survive less well

  15. Optimal clutch size is determined bytrade-off between the number and fitness of offspring (Lack’s solution) • But, measured clutch size<predicted most productive brood size (mpbs) …why? →there are four kinds of expanation

  16. (1)Measurement of offspring fitness is incomplete • Need to include different survival of offspring in the post-fledging period (Lack , 1954) • Inclusion of the effects of brood size on post-fledging survival in insects and birds • mpbs↓ in some species

  17. mpbs mpbs (2)Maximizing fitness per clutches does not maxmize lifetime fitness

  18. (3)Muptiple oviposition

  19. http://www.bbc.co.uk/devon/content/image_galleries/wildlife_15_gallery.shtml?22http://www.bbc.co.uk/devon/content/image_galleries/wildlife_15_gallery.shtml?22 (4)Stochastic variation in clutch size or fitness • When female do not have perfect control over the family size → optimum clutch size <mpbs • Blue tit →fitness measurement (geometric mean better than arithmetic mean)

  20. Extreme of reproductive effort:semelparity and deferred maturity • Cole’s paradox: when offsprings → semelparity +1= Iteroparity • Solution of paradox: Cole neglect mortality in his model

  21. If... Produce 2P/Y extra young→ semelparity low P/Y → Iteroparity P=parental survival Y=juvenile survival to the next breeding season

  22. Iteroparity Semelparity Deferred maturity

  23. Age at maturity

  24. Deferred maturity:result from RV at age of maturity being dependent on experience rather than size

  25. Comparative studies of life history traits • Habitat classification “r selection” and “k selection” • Relationships between life history traits are more strongly related to each other than they are to the environment.

  26. Phenotypic plasticity • Reaction norm (norm of reaction): the relationship between phenotype and the environment for each genotype. • phenotypic plasticity: growth rate, morphology, egg production.

  27. couch’s spadefoot toad https://webspace.utexas.edu/s681/webpage/LLAnura.html larvae of fly Ephydra cinerea http://bugguide.net/node/view/37112/bgimage Adaptive phenotypic plasticity? pied flycatchers (handicapped juvenile and re-nest) http://www.djsphotography.co.uk/BritishBirds/Flycatcher.htm

  28. Conditions favouring the evolution of phenotypic plasticity • The environment changes on small scale geographically, or short interval →flightless thrips • The existence of environmental cues →great tit and peak caterpillar abundance (hatch asynchronously)

  29. Individual optimization, directional selection and heritability • Genetic variation in clutch size: ex: lesser snow geese →why is there no response to selection? • If the trait is heritable and environmental variable which independently affects fitness.

  30. Genetic variation in reaction norm

  31. THE END

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