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Lecture 10 Molecular evolution
Jim Watson, Francis Crick, and DNA
Molecular Evolution
1. c-value paradox
2. Molecular evolution is sometimes decoupled from morphological evolution 3. Molecular clock
4. Neutral theory of Evolution
4 characteristics
Molecular Evolution
1. c-value paradox Kb
Navicola (diatom) 35,000Drosophila (fruitfly) 180,000Gallus (chicken) 1,200,000Cyprinus (carp) 1,700,000Boa (snake) 2,100,000Rattus (rat) 2,900,000Homo (human) 3,400,000Schistocerca (locust) 9,300,000Allium (onion) 18,000,000Lilium (lily) 36,000,000Ophioglossum (fern) 160,000,000Amoeba (amoeba) 290,000,000
Isochores
(low GC)
L Cold-blooded vertebrates
L L L H3 H2 H1
(low GC) (high GC)
Warm-blooded vertebrates
Isochores
L L L H3 H2 H1
(low GC) (high GC)
Warm-blooded vertebrates
- Chromatin structure - Time of replication - Gene types - Gene concentration - Retroviruses
(Mb)
GC, %
Isochores of human chromosome 21 (Macaya et al., 1976) Costantini et al., 2006
GC, %
Molecular Evolution
2. Molecular evolution is sometimes decoupled from morphological evolution
Morphological Genetic Similarity Similarity 1. low low 2. high high
3. high low 4. low high
Molecular Evolution Morphological Genetic Similarity Similarity
3. high low
Living fossils
Latimeria, Coelacanth Limulus, Horseshoe crab
Molecular Evolution
Morphological Genetic Similarity Similarity
4. low high
Pan, Chimp Homo, Human
- distance between humans and chimpanzees is less than between sibling species of Drosophila.
- for example, from a sample of 11 proteins representing 1271 amino acids, only 5 differ between humans and chimps.
- the other six proteins are identical in primary structure.
- most proteins that have been sequenced exhibit no amino acid differences - e.g., alphaglobin
- when the rates of silent substitution at a gene are compared to its rate of replacement substitution, the former typically exceeds the latter by a factor of 5-10. Conclusion: the majority of evolution involves the substitution of silent mutations – likely by random drift. - these observations led to the proposal of the neutral theory of molecular evolution in 1968 by Motoo Kimura.
Molecular clock
Motoo Kimura 1924-1994
�the survival of the luckiest�
1. most mutations are harmful and thus removed by �negative� (or �purifying�) natural selection. 2. some mutations are neutral and thus accumulate in natural populations by random genetic drift. 3. very rarely, beneficial mutations occur and are fixed by �positive� Natural selection. 4. The rate of evolution of a molecule is determined by its degree of �functional constraint�.
The neutral theory of molecular evolution
5. neutral mutations and random genetic drift are responsible for virtually all molecular evolution. - this theory gave rise to a bitter dispute known as the neutralist-selectionist controversy.
- the controversy raged throughout the 1970�s and 1980�s and has not been satisfactorily resolved.
- the essence of this controversy is not whether natural selection or random genetic drift operate at the molecular level, but rather what is the relative importance of each.
- Testing the validity of the neutral theory has been very difficult.
The neutral theory of molecular evolution
�Classical� versus �balanced� views of genome structure
• controversy began in the 1920�s with the establishment of two schools of genetics.
• the �Naturalists� studied natural populations (e.g. Dobzhansky, Mayr).
• the �Mendelians� studied genetics exclusively in the laboratory (e.g., Morgan, Sturtevant, Muller).
Classical Balanced
+ + - + + +
+ + + + + +
A1 B2 C1 D4 E3 F6
A3 B2 C4 D5 E5 -
Most loci homozygous Most loci heterozygous for �wild type� alleles Polymorphism rare Polymorphism common
+ = �wild type� allele - = deleterious recessive allele
Why is this distinction important?
Classical Balanced Speciation Difficult Easy
(mutation- (opportunity- limited) limited)
Selection Purifying Balancing Population Inter > Intra Intra > Inter variation Polymorphism transient balanced
(short-lived) (long-lived)
Allozyme electrophoresis setup
Starch gel stained for Phosphoglucomutase (Pgm)
Extensive allozyme variation exists in nature
Vertebrates (648 species)
Extensive allozyme variation exists in nature… …so this confirms the balanced view?
Vertebrates (648 species)
NO! MOST POLYMORPHISMS MAY BE NEUTRAL!
The neutral theory of molecular evolution
• first proposed by Motoo Kimura in 1968.
The neutral theory of molecular evolution
• first proposed by Motoo Kimura in 1968.
• two observations led Kimura to develop neutral theory:
1. �Excessive� amounts of protein (allozyme) polymorphism
• this would impart a severe "segregational load" if adaptive.
Example: sickle cell anemia
Genotype HbAHbA HbAHbS HbSHbS
Fitness 1-s 1 1-t
s=0.12 t=0.86
Segregational load = st/(s + t) = 0.11
• this means that 11% of the population dies every generation because of this polymorphism!
2. The molecular clock • first reported by Zuckerkandl and Pauling in 1962.
2. The molecular clock • first reported by Zuckerkandl and Pauling in 1962.
Method:
1. Obtain homologous amino acid sequences from a group of taxa.
2. Estimate divergence times (from the fossil record)
3. Assess relationship between protein divergence and evolutionary time.
100 200 300 400 500
Time (millions of years)
No. of amino acid substitutions
The molecular clock
α-globin gene in vertebrates
The molecular clock ticks at different rates for synonymous and nonsynonymous mutations
Kimura argued that the molecular clock reflects the action of random drift, not selection!
100 200 300 400 500
Time (millions of years)
No. of amino acid substitutions
α-globin gene in vertebrates
Main features of the neutral theory
1. The rate of protein evolution is roughly constant per site per year.
- this is the "molecular clock" hypothesis.
- why per site PER YEAR, not per site PER GENERATION?
2. Rate of substitution of neutral alleles equals the mutation rate to neutral alleles.
• let µ = neutral mutation rate at a locus.
• the rate of appearance of a neutral allele = 2Nµ.
• the frequency of the new neutral allele = 1/2N. • this frequency represents the allele�s probability of fixation.
2. Rate of substitution of neutral alleles equals the mutation rate to neutral alleles.
Rate of evolution = rate of appearance x probability of fixation
= 2Nµ x 1/2N
= µ
• this rate is unaffected by population size!
3. Heterozygosity (H) levels are determined by the �neutral parameter�, 4Neµ.
H = 4Neµ/(4Neµ + 1)
4. Rates of protein evolution vary with degree of selective constraint.
• �selective constraint��represents the ability of a protein to �tolerate� random mutations.
• for highly constrained molecules, most mutations are deleterious and few are neutral.
• for weakly constrained molecules, more mutations are neutral and few are deleterious.
100 200 300 400 500
Time (millions of years)
No. of amino acid substitions
α-globin
histone H4
Degree of constraint dictates rate of evolution
high constraint → low µ → low H, slow rate of
evolution low constraint → high µ → high H, fast rate of
evolution
Testing the neutral theory by studying DNA sequences
1. Comparisons of polymorphism and divergence
• studying DNA sequences enables the comparison of replacement and silent mutations!
N A E R T R
D. melanogaster AAT GCG GAA CGG ACT CGT
--C --- --- --- --- ---
--- --- --- --- T-- ---
D. simulans --- --C -T- --- --- --C
--- --- -T- --- --- --C
--- --- -T- --- --- --C
N A E R T R D. melanogaster AAT GCG GAA CGG ACT CGT
--C --- --- --- --- ---
--- --- --- --- T-- ---
D. simulans --- --C -T- --- --- --C
--- --- -T- --- --- --C
--- --- -T- --- --- --C
Mutations are either:
1. fixed between species 2. polymorphic within species
Mutations are also either:
1. silent 2. replacement
Polymorphic Fixed Replacement a c
Silent b d
• the degree of selective constraint determines the ratio of a:b and c:d.
• however, because polymorphism is a transient phase of molecular evolution, the neutral theory predicts that
ratio a:b = ratio c:d
↑ ↑ short term evolution = long term evolution
This is the McDonald-Kreitman test
Two examples:
1. The alcohol dehydrogenase (Adh) locus in Drosophila melanogaster, D. yakuba and D. simulans
polymorphic fixed
replacement 2 7
silent 42 17
G = 7.43, P < 0.001
Conclusion: too many fixed replacements!
Two examples:
2. The glucose-6-phosphate dehydrogenase (G6pdh) locus in D. melanogaster and D. simulans.
polymorphic fixed
replacement 2 21
silent 36 26
G = 19.0, P < 0.0001
Conclusion: too many fixed replacements!
2. Tests for positive selection
• positive selection occurs when the rate of replacement substitution exceeds the rate of silent substitution.
• although rare, is widely documented at two broad classes of genes:
1. Genes involved in host-pathogen interactions
• notably the major histocompatibility complex (MHC) and pathogen surface coat proteins.
2. Genes functioning in reproduction
• notably seminal fluid proteins and surface proteins on sperm and egg.
Conclusion: Natural selection may be more important in directing molecular evolution than previously believed!
Nearly Neutral Theory of Evolution
Tomoko Ohta
