Evolution Midterm

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(Fall 2013) Flashcards on Evolution Midterm, created by j_sunga on 10/10/2013.
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Flashcards by j_sunga, updated more than 1 year ago
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Created by j_sunga about 11 years ago
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Question Answer
Define Inference moving logically between observations and conclusions
Deduction: general knowledge to specific conclusion. Premise must be correct and logic sound
Induction general condition from specific observation - conclusion must be tested
Hypothesis tentative, testable statement
prediction deductive inference regarding outcome of experiment
Law descriptive generalization about how aspects behave under specific circumstances
Explain Lamarck's theory of evolutionary change evolve based on use, system strengthens with use and changes are heritable, new species formed at bottom of scale, no extinction or common ancestry
Challenges to Natural Selection (4) Neo-Lamarckism, Mutationism (new species formed all at once), Orthogenesis (internal forces), Saltationism (evolution my macromutations)
What ruled out Lamarckian evolution? discovery of germ line/somatic line differentiation
Explain evolution as fact, theory and path Fact - species related by decent, theory - mechanisms, path - actual course of evolution
Transitional Fossil shows some traits only found in ancestor and some only in descendant OR an intermediate feature
Atavism reappearance of ancestral trait in modern individuals (ex. horse toes, bird teeth)
Evidence for Natural Selection (6) Fossil Record, Biogeography, Homology, Embryology, Atavisms, Vestigial Structures, Suboptimality
Polytomy and soft polytomy unresolved/multi-branching node, soft = branching unknown
Cladogram vs. Phylogram Cladogram only good for topology (relatedness), phylogram lengths signify amount of divergence
Microevolution small scale processes operating within populations to change allele frequencies
Macroevolution large scale patterns of change above the species level (includes origin of new species)
Extrapolationists evolution = change in allele frequency, macroevolution = extrapolated microevolution
Macroevolutionists multi-level/hierarchical selection
Mendel's First Law (Segregation) alleles separate during gamete production (1 from each parent)
Mendel's Second Law (independent assortment) alleles at different loci separate with no effect on each other
Population: group of interbreeding individuals and their offspring
Gene Pool set of all copies of all alleles in a population that can be passed to the next generation
Assumptions of Hardy-Weinberg (4) large gene pool, no alleles lost or gained, no migration, random mating
Hardy-Weinberg Equilibrium equation p^2+2pq+q^2=1, p+q=1
Transition vs. Transversion Point mutations, transition = purine to purine/pyrimidine to pyrimidine, transversion = purine to pyrimidine
Translocation chromosome mutation - piece of one chromosome breaks off and joins another
Polyploidy occurs by hybridization in cell division, multiple copies of entire genome
Mutation Rate measure of how commonly new mutations occur (μ)
reasons for varied mutation rates (5) sexual/asexual reproduction, generation time, mutagen exposure, repair efficiency, other properties
Darwin's postulates (4) individuals are variable, variability is heritable, some individuals are more successful than others, success associated with heritable traits
Natural Selection non-random differences in survival and reproduction
frequency of deleterious recessive alleles at equilibrium q= root (μ/s)
Types of Natural Selection (4) Stabilizing (against extremes), Diversifying (for extremes), Directional (against one extreme), balancing (maintenance of multiple alleles)
Genetic Drift Random changes in allele frequency due to sampling error (unpredictable)
Types of Genetic Drift (3) Population bottleneck, founder effect, gamete sampling error
Explain "Drunkards Walk" probability of neutral allele becoming fixed in a population = current frequency
Average time and likelihood for new allele to reach fixation probability = 1/2N (population size), time = 4N generations
likelihood of fixation for present allele x/2N (x=current # of allele copies)
Effective Population Size number of breeding individuals in a population Ne = 4NmNf/ (Nm + Nf)
Gene Flow Movement of alleles from one population to another (makes populations more similar)
Inbreeding non-random mating of genetic relatives with each other, results in reduction in # of heterozygotes
Inbreeding Coefficient (F) likelihood of getting same allele twice in descendants (identical by descent)
Inbreeding depression reduction in fitness resulting from combining of unfavourable alleles
Adaptive Radiation divergence of one ancestral species into several species that occupy different niches
EPP Extra pair paternity - different male raising offspring
Longevity # of times an individual mates, largest determinant of overall fitness
Adaptations characteristic that enhances fitness of individual relative to alternatives, evolved through natural selection
Direct Adaptive Evolution point A to point B, all intermediate forms are functional and favoured
Indirect Evolution no end goal, past and current function can be different
mechanisms of indirect evolution (6) exaptation (cooption), duplication, gene sharing, tinkering (bricolage), collage, scaffolding
Exaptation coopted for given function but originally evolved for another reason (followed by secondary adaptation)
Exaptation possibilities (7) existing to new function, second function, existing modified so new function is possible, multiple functions - becomes specialized, divergence of redundant organs, reduced to new function, non-functional to functional
Collage existing materials brought together to take on new function
Reasons for suboptimality genetic drift, balancing selection, mutation-selection balance, lack of foresight of natural selection, adaptation to past conditions, antagonistic pleiotropy, trade-offs, constraints
Types of constraints (4) genetic, physical, developmental, historical
Antagonistic pleiotropy one gene does multiple things, one of which is bad
trade-offs investment in one feature at expense of another
Panglossian Paradigm all things have been created for the best purpose (adaptationism)
Scaffolding supportive component is present early on but then lost, leaving behind indivisibly complex structure
stratigraphy study of layers of rock
uniformitarianism ongoing, constant processes shaping earth
significance of Natural History of Creation beginning of ideas similar to Darwin, originally published anonymously
3 pieces of evidence that DNA is genetic material involved in transformations of bacteria, constant within species, used by viruses to infect host
Chargaff's Rules 1:1 ratio of A:G and T:C, base pair compostion varies among species
"purifying" selection directional selection removing an unwanted allele
frequency dependant selection fitness depends on abundance of trait (can be positive or negative)
Gene flow equation P’I = (1-m)(PI) + (m)(PC), equilibrium = 0 = m(Pc-Pi)
A1A1 frequency, A1A2 frequency p2(1-F) + pF, 2pq(1-F)
steps of direct adaptive evolution (3) fittest leave more offspring, offspring distribution skewed towards fitter traits, mutation introduces new variation
hypothetic-deductive method predictions can be tested by new observations (used where experimentation is difficult)
explain "ontogeny recapitulates phylogeny" development shows evolutionary processes (wrong)
How do byproducts of dimorphism occur? trait evloves as adaptation for one sex, feature is produced early in embryo or before sexual differentiation
Allometry differential growth rates between features
Reasons for features to become vestigial (3) natural selection, genetic drift, correlation with other features (trade-off)
reasons vestigial structures remain (4) some partial function, further reduction has direct consequences, indirect consequences, not lost yet
Population Genetics includes natural selection and genetic drift, allows predictions on what happens to alleles in entire populations and across many generations
Adaptations to... (6) energy intake, defence, locomotion, physical environment, sensing, reproduction
Secondary Adaptation mutations that enhance new function of a feature are selected for
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