Lecture 21 Flashcards
Anagenesis
- microevolution
- evolution within the lineage (within the level of species)
- i.e. drought changed average beak depth over time. Must be heritable (genetic basis), and variability
Cladogenesis
- macroevolution
- splitting of lineages into two or more lineages
- as it creates new species, we can see it as evolution above the level of species
- any evidence for common descent-homologous structures, biogeography, embryology-should suffice to demonstrate cladogenesis, but some won’t accept this
Implication of genetics in reproductive isolation
- reciprocal translocation (produce aneuploid gametes)
- polyploidy: autopolyploidy, allopolyploidy
- hybrid sterility in Drosophila
- genetic incompatibilities (common ancestry, phylogenetic trees and parts, relatedness)
Reciprocal Translocation
- non-homologous chromosomes exchange DNA
- this exchange can fix (goes to 100% frequency) in one population, while another population does not have it
- when gametes from these two populations meet in a hybrid, this individual produces aneuploid gametes and has reduced fertility
Aneuploidy
- a genome lacks or has an extra copy(ies) of a chromosome(s). usually bad because it disrupts balance that exists for gene products in a cell
- ex in humans trisomy 21
Hybrids
- have plenty of opportunity for aneuploid gametes (reduced fertility)
- the hybrid of an autopolyploid and a diploid produces aneuploid gametes and is largely sterile (look at slide) can’t fertilize each other or go back and fertilize parents
Autopolyploid
- formed with the union of unreduced gametes of an individual(s) from the same species
- look at slide
Allopolyploid
-is formed with the union of gametes from individuals of different species
Bottom Line
-either by autopolyploidy or allopolyploidy, new species can arise because hybrids will produce aneuploid gametes and will therefore have reduced fertility
Hybrid Sterility in Drosophila
- took females from D. simulans and crossed with males from D. mauritiana
- took hybrid females and back crossed with males from D. Simulans
- scored hybrid male fertility
- when male had sex chromosome from other species fertility would reduce to almost 0 and the only difference is the genetic composition between species
- this experiment implicated genetics in replicative isolation in drosophila
Allopatric Populations
-isolated populations that do not exchange alleles
-incompatible genetic variants can evolve in separate populations due to vicariance
-geographic barrier prevents gene flow between populations and each can reach fixation in their own trait
-if they go back to sympatry they will be reproductively isolated and will constitute 2 species (if they mate hybrid dies)
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Sympatric Populations
- populations that exist in the same location and whose individuals can meet
- genetic variants that cause reproductive isolation may not increase in frequency easily
- one trait may take over via natural selection
Indirect Evidence for Allopatric Speciation
-as you increase geographic distance between any pair of species, the species are more reproductively isolated
Direct Evidence that Reproductive Isolation Can Evolve
- yeast in high salinity (S) and low glucose (M)
- mate to get S/M hybrid
- measured mitotic fitness in low glucose–S/M had lowest fitness and M had the highest
- measured mitotic fitness in high salinity–S/M had lowest fitness, S had highest
- measured meiotic fitness in environment permissive to sexual reproduction (count of daughter cells after 72 hr)–S/M had lower fitness
Selection for Prezygotic Isolation Reinforcement–Dobzhansky-Muller Model
- initial populations is separated in two allopatric populations (no gene flow)
- two genes L and R
- allopatric populations accumulate incompatible genetic variants (red and green)
- L gene mutates into red so 1/3 are red and R gene mutates into green so 1/3 are green
- incompatible genetic variants increase in frequency due to selection and/or drift
- populations reunited in sympatry before reaching full reproductive isolation (barrier disappears before speciation totally complete)
- 3 possible crosses in the one where the red and green alleles cross 25% of offspring die because they are bad together–individuals in this cross have lower fitness and they like and/or are willing or capable of mating with the other population
- result of these genotypes having lower fitness?–>selection against breeding with the other population–>REINFORCEMENT (because of natural selection)
