1 / 43

Adaptation vs Plasticity

Adaptation vs Plasticity. The Problem:. People often wish to jump to the conclusion that a trait change they see is the result of adaptation However , that is not always the case. There are other mechanisms that could cause phenotypic variation

gretel
Download Presentation

Adaptation vs Plasticity

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Adaptation vs Plasticity

  2. The Problem: • People often wish to jump to the conclusion that a traitchange they see is the result of adaptation • However, that is not always the case. There are other mechanisms that could cause phenotypic variation • This is what Stephen Jay Gould called the “Adaptationist Paradigm”

  3. The Problem: • Adaptations are ubiquitous, but demonstrating that a particular trait is an adaptation is not always easy

  4. Critique of the “AdaptationistProgramme” Gould & Lewontin 1979. The Spandrels of San Marco and the Panglossian Paradigm: A Critique of the AdaptationistProgramme. • One of the most important papers in Evolutionary Biology • They critique the “Adaptationist” and “PanglossianProgramme” that assumes that a phenotypic change is the result of adaptation • Gould & Lewontin point out that not all phenotypic variation or phenotypic evolution is the result of adaptation

  5. Gould & Lewontin: The spandrels of San Marco San Marco Cathedral, Venice

  6. Gould & Lewontin on Physical Constraint: The spandrels of San Marco might not have been created for a reason, but might simply be a by product due to the creation of arches San Marco Cathedral, Venice

  7. Physical Constraint Developmental constraint Constraint in Body Plan If body size increases, brain size has to increase If a larger eye evolves, need a bigger socket (the socket itself is not the target of selection) Analogy: the Spandrels of San Marco

  8. Gould & Lewontin Other potential causes of phenotypic variation that is NOT Adaptation: (A) Plasticity: phenotypic change without evolution (B) Nonadaptive Evolutionary Forces: Genetic Drift Genetic Constraint (Linkage, Pleiotropy) (C) Physical Constraint (allometry, Mechanical compensation)

  9. Not All Phenotypic Variation is due to Adaptation Phenotypic change and variation could have other causes: • Changes that are not due to genetic changes, but due to changes in gene expression: Phenotypic Plasticity • Changes that are Genetic, but NOT adaptive: • Genetic Drift: random chance • Linkage and Genetic Hitchhiking: Genetic changes that occur because the gene was right next to another gene on a chromosome that was under selection • Constraint: physical or structural (like the Spandrels)

  10. Adaptation Requires Natural Selection Requires polymorphism in a population MUST have an effect on Fitness Is a frequency (%) change in a population There must be a Selective Force

  11. How can you tell if a trait evolved as a result of adaptation? (1) The trait must be heritable (2) The differences between populations are genetically based differences rather than inducible differences (plasticity) (3) The trait has fitness consequences (promotes survival, performance, and number of offspring) (If a trait evolved due to genetic drift, linkage or pleiotropy, the change is genetic, but may confer no fitness advantage)

  12. Measuring Heritable Variation • Quantitative traits are controlled by many loci, many of which with small effects. For quantitative traits, we depict the sources of variation as follows: • Phenotypic variation is a result of variation that is due to genetic effects (VG),variation due to environmental factors(VE) and their interaction. VP= VG + VE + VGxE • So, some of the variation could be due to genetic causes, but some might be induced by the environment (as a result of gene expression).

  13. Conceptual Confusions Trait variation is often assumed to be due to Adaptation, when the differencesmight be due to Phenotypic Plasticity or nonadaptive genetic causes

  14. Phenotypic Plasticity • Differences in phenotype that a genotype exhibits across a range of environments • Some traits with a plastic component: intelligence, height, temperature tolerance, salinity tolerance, muscle mass… Definition:

  15. Acclimation(≠ Adaptation) 1) Result ofPhenotypic Plasticity 2) Not heritable 3) Short term or developmental response within a single generation 4) Arises through differential gene expression or other regulatory mechanism rather than natural selection

  16. Nature vs Nurture • Both environment and genetics affect many traits, but need to experimentally or statistically separate these factors • How? • Example: Common-garden experiment • Having appropriate controls • Statistically assessing the effect of environment

  17. This is a general problem • This type of problem is a factor in all studies that attempt to associate a gene with a trait • You need to account for the effects of environment • For example, problems arise when different labs attempt to associate a gene with a disease using laboratory mice that have been reared under different conditions

  18. Types of Plasticity • Short-term reversible • Development acclimation: generally irreversible Genotype --> Development --> Phenotype • Within normal tolerance range • In response to Stress

  19. Plasticity can be depicted graphically as a Reaction Norm • Response Environment Reaction Norm: the function which describes the plastic response

  20. Response Environment • In the case of plasticity, the different phenotypes in different environments are NOT the result of Adaptation… • The Genotype(s) in the environments are NOT changing • The differences between them are due to differences in response (such as gene expression) in different environments

  21. Dodson, SI. 1989. Predator induced reaction norms. BioScience 39:447–452

  22. Predator induced formation of helmets in Daphnia Hebert and Grewe, 1985

  23. Genotype x Environment Interaction • Changes in rank or level of performance among genotypes when tested in different environments • Reveals genetic variation for plasticity • Could reflect tradeoffs between fitness of different genotypes in different environments

  24. When lines cross, the implication is that different environments will select for different phenotypes • Response Environment Trade-offs in different environments

  25. Select for this reaction norm in cold environments big • Size Select for this reaction norm in hot environments small hot cold Temperature Could get selection for different reaction norms (different plasticity) in different environments

  26. Genetic variation for plasticity can be determined by examining the significance of the interaction term from an Analysis of Variance (ANOVA) Genetic Variation for Plasticity No Genetic Variation for Plasticity • Response Environment Environment

  27. Most Importantly, • Must distinguish plasticity from adaptations to understand heritable (and permanent) vs inducible differences, in order to interpret experiments properly • Many experiments fail to do this • Examples: drug response, hormone replacement therapy

  28. How to distinguish between genetically based traits vs. phenotypic plasticity? • Animal Model Analyses: Determine how much of a trait is due to additive, dominance, genetic variance etc (quantitative genetic methods) – not cover here • Common-garden experiment: rear different populations in a common environmentto remove the effects of environmental plasticity, and determine how much variation is remaining (and due to genetic effects). • Look at selection response in nature (R= h2S, breeder’s equation) • Selection Experiments (Experimental Evolution): Impose selection on a population, then examine evolutionary shift • Molecular Genetic Approaches: transgenic or gene knockout studies, to determine the impacts of particular genes

  29. What is a common-garden Experiment? • An Experiment in which individuals from different populations or species are reared under identical conditions (can be over a range of conditions) • Remove differences due to environmental plasticity

  30. Example: Different Populations A saltwater population and a freshwater population of a small crustacean (copepod) show differences in salinity tolerance. Are the differences due to simply being reared at different salinities, or are the differences due to genetically based differences?

  31. Common Garden Experiment Different Populations Rear under common conditions To determine the differences when the environment is held constant

  32. Common Garden Experiment If the populations still differ under common-garden conditions, the differences are genetically based. But are these genetic differences the result of adaptation? (or some other genetic cause) Different Populations

  33. Laboratory Selection Experiments • But is salinityreally the factor causing the evolutionary physiological change? • Perform selection experiments to test whether the evolutionary change happens in response to salinity alone.

  34. saline ancestors Control Selection in the Lab Selection for severalgenerations Take the saline population and then imposed selection for freshwater tolerance Compare the populations before and after selection Do the selection lines show the same evolutionary shift to fresh water as the wild population? ancestor freshwater selected lines acclimate at same salinity 5 5 5 5 15 0 Common garden experiment at the end of the selection

  35. How do we detect Evolutionary Adaptations? • Transgenic and gene knockout studies • Is that gene causing the trait, and does it have fitness consequences? • Generally use model systems, such as mice, fruit flies, etc.

  36. Example: Human IQ Data • Data: Many studies use survey data on human populations in the US (not a common-garden experiment, where environment is held constant) • Did not statistically account for differences in environment • A correlation is associative, and not necessarily causative

  37. Problems with data and statistical analysis: • Several reanalyses have found that socio-economic status (and historical factors) was a stronger determinant of IQ scores than race. • Socio-economic status could reflect nutrition, access to education, etc.

  38. Impact of environment must be accounted for: • There is an IQ gap between blacks and whites in America, Japanese and Koreans in Japan, Ashkenazi and Sephardic Jews in Israel, and Protestants and Catholics in Northern Ireland. As economic conditions improve for the subordinated groups, the gaps are reduced • A common-garden experiment has never been performed on humans with respect to IQ scores to determine actual genetic differences with environmental effects removed • Do not know of any study that has effectively controlled for socio-economic differences

  39. Examples: Adaptation or not? • A plant grows taller to obtain more sunlight • Weeds in cornfields (corn is tall) are on average taller than weeds of the same species in soybean fields in order to obtain more sunlight

  40. Examples: Adaptation or not? • A plant grows taller to obtain more sunlight Plasticity • Weeds in cornfields (corn is tall) are on average taller than weeds of the same species in soybean fields in order to obtain more sunlight Not enough information

  41. Examples: Adaptation or not? • Weeds in a cornfield have been found to grow taller than those in soybean fields when both populations are reared in common-garden conditions • Taller weeds in the cornfields survive and a greater rate and leave more offspring

  42. Examples: Adaptation or not? • Weeds in a cornfield have been found to grow taller than those in soybean fields when both populations are reared in common-garden conditions They are genetically different, but not know for sure if it is adaptation (could be linkage, genetic drift) • Taller weeds in the cornfields survive and a greater rate and leave more offspring Adaptation

More Related