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POPULATION GENETICS, SELECTION AND SPECIATION. CAPE BIOLOGY FEBRUARY 18, 2013 MRS. S. HAUGHTON. A population is a group of organisms of the same species usually found in a clearly defined geographical area.
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POPULATION GENETICS, SELECTION AND SPECIATION CAPE BIOLOGY FEBRUARY 18, 2013 MRS. S. HAUGHTON
A population is a group of organisms of the same species usually found in a clearly defined geographical area. • Genes, sometimes working together with environmental factors, determine the phenotypes of organisms and are responsible for variations within populations.
Theory of natural selection suggests that phenotypes adapted to the environmental conditions are selected for. • Non-adapted phenotypes are selected against and eventually eliminated. • Long term effects of natural selection are at the population level and not individual level.
GENE POOL • This is the total variety of genes and alleles present in a sexually reproducing population. • New gene combinationsnew phenotypes • May constantly change from generation to generationevolutionary change. • Static gene poolnon-evolving.
ALLELE FREQUENCY • The number of organisms in a population carrying a particular allele determines the allele frequency. • E.g. frequency of dominant alleles for skin pigmentation is 99% in population while that for lack of pigment (albinism) is 1%.
HARDY-WEINBERG EQUILIBRIUM • This theory states that the frequency of dominant and recessive alleles in a population will remain constant from generation to generation provided to following factors exist: • Population is large • Mating is random • No mutations occur
FACTORS PRODUCING CHANGES IN POPULATIONS • Crossing over (meiosis) • Independent segregation (meiosis) • Random fertilization • Mutation • Non-random breeding • Small population leading to genetic drift • Genetic load • Gene flow occurring between populations
NON-RANDOM BREEDING • If individuals (usually females) are choosy in their selection of mates (leading to non-randomness), the gene frequencies may become altered. • Darwin called this sexual selection. • Influenced by breeding territories, courtship displays, "pecking orders“. • In each case certain individuals do not get to make their proportionate contribution to the next generation. • Organisms with less favourable characteristics have a decreased reproductive potential and the frequency of their alleles being passed on to subsequent generations is reduced.
GENETIC DRIFT • An allele may increase — or decrease — in frequency simply through chance. • Not every member of the population will become a parent and not every set of parents will produce the same number of offspring. • The effect, called random genetic drift, is particularly strong in small populations (e.g., 100 breeding pairs or fewer). • Eventually the entire population may become homozygous for the allele or — equally likely — the allele may disappear. • Before either of these fates occurs, the allele represents a polymorphism.
GENETIC LOAD • This is the existence within the population of disadvantageous alleles in heterozygous phenotypes. • Any increase in recessive alleles in a population as a result of harmful mutations will increase the genetic load. • Genetic load is a measure of the cost of lost alleles due to selection (selectional load) or mutation (mutational load). It is a value in the range 0 < L < 1, where 0 represents no load.
GENE FLOW • The movement of alleles from one population to another as a result of interbreeding between members of the two populations. • Random introduction of new alleles into the recipient population from the donor population changes the allele frequency in both populations.
SELECTION • The process by which those organisms which seem physically, physiologically, and behaviorally better adapted to the environment survive and reproduce. • Those not well adapted fail and die out. • Advantageous alleles kept, disadvantageous not • Selection depends on the existence of phenotypic variation within the population. • There are three types of selection process occurring in natural and artificial selection: stabilising, directional and disruptive.
STABILISING SELECTION • Form of natural selection responsible for preserving adaptive characteristics of organisms under constant environmental conditions. • Operates by means of the removal, or elimination, of individuals who deviate from the established norm. • Therefore, a population remains unchanged for a given characteristic, despite the continuous process of mutagenesis. • Favours "average" organisms best adapted to that environment • Selects against organisms with extreme forms of characteristics/mutations • E.g. Heaviest and lightest babies have highest mortality
DIRECTIONAL SELECTION • Natural selection favours organisms with one extreme form of a characteristic while removing those from the other extreme and averge. • Pesticide resistance (warfarin - poison used to kill rats) • Resistant rats / need a lot of vitamin K / stabilising selection • New environmental effect: warfarin / kills normal rats • Resistant rats survived, reproduced, pass on resistance gene • New population forms by directional selection • Antibiotic resistance (penicillin resistance) • Resistant bacteria / unnecessary enzymes / selected against • New environmental factor: penicillin / kills normal bacteria • Resistant bacteria survived, reproduced, passed on resistance gene
DISRUPTIVE SELECTION • Natural selection favours organism with two extreme forms of a characteristic • A population is divided into subgroups that are still connected. They can still reproduce, but the flow of genes is reduced. Directional selection takes place within each of the subgroups. • Sickle-cell anaemia • Abnormal Hb makes red blood cells sickle-shaped / stick in capillaries • People homozygous for this recessive allele die before reproducing • People heterozygous for the allele should be at a disadvantage / red blood cells can sickle during exercise / allele should be selected against and rare • Where malaria is found, people heterozygous for sickle-cell have an advantage (resistant) and are likely to survive, reproduce and pass on the allele; people without the allele also have an advantage, because their red cells behave normally • Balanced polymorphism is produced / carrier is heterozygous for sickle cell
SELECTION PRESSURE • This is due to factors which may decrease or increase the spread of an allele between the gene pools. • Both the environment and population size operate together to produce selection pressure which can vary in intensity.
INTENSITY OF SELECTION PRESSURE • The intensity on a population varies at different times. • External factors include increase in predators, pathogens and competition from other species (interspecific competition). • Internal factors include rapid increase in population size increasing competition for resources (intraspecific competition). • Selection pressure may cause organisms to take up narrower and narrower niches.
SPECIES CONCEPT • A species represents the lowest taxonomic group capable of being defined with any degree of precision. • Members of a species usually exist as a small interbreeding population with their own gene pool. • Spatial separation causes each group to come under different types and degrees of selection pressure.
DEFINITIONS OF SPECIES • A group of organisms capable of interbreeding to produce fertile offspring. • A group of organisms sharing the same ecological niche. • A group of organisms showing close similarity in genotype. • A group of organisms sharing a unique collection of structural and functional characteristics.
The process by which one or more species arise from previously existing species. SPECIATION
INTRASPECIFIC SPECIATION • If a single species gives rise to a new species this is intraspecific speciation. • Gene flow within populations in interrupted. • Each subpopulation becomes genetically isolated. • If interbreeding between the species is successful they still belong to the same species. If not speciation has occurred. • Speciation will only occur as a result of the formation of barriers which lead to reproductive isolation between the populationsisolating mechanisms.
ISOLATING MECHANISMS • Prezygotic mechanisms (barriers to the formation of hybrids) • Seasonal isolation-two species mate at different times of the year • Ecological isolation-species in same region but prefer different habitats. • Behavioral isolation- species with different courtship patterns and styles. • Mechanical isolation-different genitalia so copulation compromised; or related plants pollinated by different animals
ISOLATING MECHANISMS • Postzygotic mechanisms (barriers affecting hybrids) • Hybrid inviability- hybrids are produced by fail to develop to maturity. • Hybrid sterility – hybrids fail to produce functional gametes • Hybrid breakdown- F1 hybrids are fertile but F2 hybrids are not
Intrapsecific speciation is of two types: • Allopatric speciation • Sympatric speciation
ALLOPATRIC SPECIATION • If intraspecific speciation occurs while species are separated. • Geographical barriers such as mountain ranges, seas, rivers pr habitat preference may produce a barrier to gene flow because is spatial separation. • Adaptations to new conditions or random genetic drift in small populations leads to changes in allele and genotypic frequency.
SYMPATRIC SPECIATION • If speciation occurs while the populations are occupying the same geographical area. • If populations that were once separated are brought together and interbreed hybrids may form. • These hybrids have reduced fertility and serve as a reproductive barrier to gene flow between to two original populations.
INTERSPECIFIC HYBRIDIZATION • If two different species give rise to a new species this is interspecific hybridisation. • This is a form of sympatric speciation. • Fertile hybrids only occur usually in the case of interspecific hybridisation as result of a form of chromosomal mutation called allopolyploidy.