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Transcript
Gregor Mendel (1822-1844) & the Foundations of Genetics Early Views of Inheritance • The Humunculus - in the egg or sperm? • Pangenesis - the mechanism of acquired inheritance – each tissue has its own genes, which migrate to the egg & sperm • Blended Inheritance - characters take on characteristics of both parents Why Mendel Liked Peas • Several variable characters with two discrete traits – easy to score (yellow or green) • Can control fertilization, including selffertilization – can produce pure lines • Offspring always have one of the parental traits P X F1 100% F1 X F2 + 25% 75% P F1 F2 aa X Aa X aa 25% + AA Aa 25% AA 50%Aa 75% F2 P aabb X F1 AaBb X AABB AaBb aabb aaBb aaBB AAbb Aabb 6% 1 19% 3 19% 3 AABB AABb AaBb AaBB 56% 9 Mendel’s Inferences • Alternate traits caused by alternate forms of genes, the unit of heredity • An organism has two genes, one from each parent, for each character – can produce pure lines • Offspring always have one of the parental traits • Sperm & eggs always have just one allele (gene variant), because they segregate • When two alleles are different, one is fully expressed and one is masked (dominant or recessive) Mendel’s First Conclusion: Law of Segregation • All allele pairs randomly segregate during gamete formation • Paired condition restored with fusion (fertilization) Aa A a 1 : 1 Mendel’s Second Conclusion: Law of Independent Assortment • Each allele pair segregates independently of all others AaBb aB 1 AB : 1 ab : 1 Ab : 1 Chromosomes are the location of genes • Chromosomes: long, threadlike associations of genes found in the nucleus consisting of protein & DNA • Mendel’s Laws hold for chromosomes, within chromosomes there is some shuffling, called crossing-over • Humans: 46 chromosomes - 22 pairs of autosomes plus 2 sex chromosomes (X and Y) Mendel’s Laws are a powerful source of variation 23 2 possible combinations of chromosomes to form gametes > 8,000,000 different gametes When two gametes combine (fertilization), there are approximately (8 million) 2 combinations Actual # of possible combinations of zygotes (fertilized eggs) in humans = 70, 368, 744, 177, 664 No shuffling (change) 2n 4n 2n 2n 2n n 2n n Shuffling 2n Mitosis 4n (no change) 2n Meiosis Somatic (body) vs Germ Somatic vs Germ Cells (reproductive) Cells 2n 2n n 2n n No shuffling (change) 2n 46 4n 92 2n 46 2n 46 2n 23 2n 23 Shuffling 46 Mitosis 92 (no change) 46 Meiosis Somatic (body) vs Germ Somatic vs Germ Cells (reproductive) Cells in Humans 46 2n 23 2n 23 Crossing Over in Meiosis Another Way to Generate Variation Genes on the same chromosome are linked - independence of segregation depends on distance and frequency of crossing-over From DNA to Protein DNA Base Pairs A-C-G-T Protein (polymer of Amino Acids) Triplet Codons for (20) Amino Acids AAA - CAT etc. RNA Intermediaries What Proteins Do…. • • • • • Provide structure Catalyze reactions Recognize molecules Transport molecules Regulate gene expression Mutation Point Mutations • Change in one base pair - may or may not change amino acid, changed amino acid may or may not change protein conformation • Spontaneous, but also increased by radiation, heat, chemical mutagens • Rate ‘Infrequent’: one in a billion bases AATAAGAA AATATGAA Detectable Genetic Mutations • Many amino acid substitutions do not effect a protein’s function - they are silent • Non-silent substitutions affect the proteins conformation (shape) or expression (promote or stop) • Sometimes silent substitutions become revealed when the environment is changed • Many important genetic diseases (e.g. PKU, SickleCell) • Frequency: about one in a million amino acids Three Genetic Mutations Deletion AATAAGAA Substitution AATAAGAA Insertion AATAAGAA AATAGAA AATATGAA AATAAAGAA Chromosomal Mutations • Chromosomes can be duplicated, portions can be translocated to a different chromosome or inverted on the same, or deleted • Usually has profound consequences - sterility or worse • Common, e.g. Down’s syndrome 1:700 births • Major mode of ‘instantaneous’ speciation in selffertilizing or inbreeding species, especially plants Human genomes are complex, but …. • Only 1/3 more genes than a worm - Genes like components in assembly lines? • Many more harmful mutations per generation • Much less coding DNA (rest junk or spacer or ?? ) Genetic Load • For humans, estimated by reduced fertility and increase in birth defects associated with conceptions between relatives • 4 recessive lethals per individual, more than one new lethal per generation • In women’s eggs, chromosomal defects in eggs increase with age • In men’s sperm, DNA sequence changes increase with age • In outbred human conceptions – 70% of conceptions never come to term – 2 per 1000 live births have genetic defects What Changes Gene Frequencies? • • • • • Mutation Genetic drift (random change in small pops) Non-random Mating Migration = Gene Flow Natural Selection Purifying Selection • Dominant or Sex-linked (X or Y) deleterious mutant alleles eliminated rapidly by natural selection • Recessive autosomal deleterious mutant alleles reduced slowly by selection – heterozygotes ‘protect’ recessive deleterious mutant alleles – never eliminated: a mutation - selection equilibrium is reached Stabilizing Selection decreases variation, doesn’t shift mean Old Mean Frequency Frequency Mean Trait value Trait value Parents Offspring Directional Selection may reduce variation, shifts mean Old Mean Frequency Frequency Mean Trait value Trait value Parents Offspring Disruptive Selection increases variation, may shift mean Old Mean Frequency Frequency Mean Trait value Trait value Parents Offspring Sexual Selection Forms of Sexual Selection • Intrasexual (usually male-male competition) – Weapons for within-sex competition • Intersexual (usually females choosing males) – Ornaments or signals to attract choosy mates – Why are animals choosy: aesthetic preferences (Darwin’s hyp.) or signals indicate mate quality? Consequences of Sexual Selection • Drives species away from the ecological optimum • Major cause of sexual dimorphism via disruptive selection: since ornaments are an advantage in only one sex, there is selection for modifiers that lead to expression in one sex only
