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Mystery of Heredity • Before the 20th century, 2 concepts were the basis for ideas about heredity – heredity occurs within species – traits are transmitted directly from parent to offspring • Thought traits were borne through fluid and blended in offspring • Paradox – if blending occurs why don’t all individuals look alike? Early Work • Josef Kolreuter – 1760 – crossed tobacco strains to produce hybrids that differed from both parents – additional variation observed in 2nd generation offspring contradicts direct transmission • T.A. Knight – 1823 – crossed 2 varieties of garden pea, Pisum sativa – crossed 2 true-breeding strains – 1st generation resembled only 1 parent strain – 2nd generation resembled both Gregor Mendel Chose to study pea plants because: 1. Other research showed that pea hybrids could be produced 2. Many pea varieties were available 3. Peas are small plants and easy to grow 4. Peas can self-fertilize or be cross-fertilized Mendel’s Experimental Method • Usually 3 stages 1. Produce true-breeding strains for each trait he was studying 2. Cross-fertilize true-breeding strains having alternate forms of a trait – also perform reciprocal crosses 3. Allow the hybrid offspring to self-fertilize for several generations and count the number of offspring showing each form of the trait Monohybrid Crosses • Cross to study only 2 variations of a single trait • Mendel produced true-breeding pea strains for 7 different traits – each trait had 2 variants F1 Generation • First filial generation • Offspring produced by crossing 2 true-breeding strains • For every trait Mendel studied, all F1 plants resembled only 1 parent – referred to this trait as dominant – alternative trait was recessive • No plants with characteristics intermediate between the 2 parents were produced F2 Generation • Second filial generation • Offspring resulting from the self-fertilization of F1 plants • Although hidden in the F1 generation, the recessive trait had reappeared among some F2 individuals • Counted proportions of traits – always found about 3:1 ratio 3:1 is actually 1:2:1 • F2 plants – ¾ plants with the dominant form – ¼ plants with the recessive form – the dominant to recessive ratio was 3:1 • Mendel discovered the ratio is actually: – 1 true-breeding dominant plant – 2 not-true-breeding dominant plants – 1 true-breeding recessive plant Conclusions • His plants did not show intermediate traits – each trait is intact, discrete • For each pair, one trait was dominant, the other recessive • Pairs of alternative traits examined were segregated among the progeny of a particular cross • Alternative traits were expressed in the F2 generation in the ratio of ¾ dominant to ¼ recessive Five-Element Model 1. Parents transmit discrete factors (genes) 2. Each individual receives one copy of a gene from each parent 3. Not all copies of a gene are identical – Allele – alternative form of a gene – Homozygous – 2 of the same allele – Heterozygous – different alleles 4. Alleles remain discrete – no blending 5. Presence of allele does not guarantee expression – Dominant allele – expressed – Recessive allele – hidden by dominant allele • Genotype – total set of alleles an individual contains • Phenotype – physical appearance Principle of Segregation • Two alleles for a gene segregate during gamete formation and are rejoined at random, one from each parent, during fertilization • Physical basis for allele segregation is the behavior of chromosomes during meiosis • Mendel had no knowledge of chromosomes or meiosis – had not yet been described Punnett Square • • • • Cross purple-flowered plant with white-flowered plant P is dominant allele – purple flowers p is recessive allele – white flowers True-breeding white-flowered plant is pp – homozygous recessive • True-breeding purple-flowered plant is PP – homozygous dominant • Pp is heterozygote purple-flowered plant Human Traits • Some human traits are controlled by a single gene – some of these exhibit dominant and recessive inheritance • Pedigree analysis is used to track inheritance patterns in families • Dominant pedigree – dominant trait appears in every generation • Recessive pedigree – most affected individuals have unaffected parents Dihybrid crosses • • • • Examination of 2 separate traits in a single cross Produced true-breeding lines for 2 traits RRYY x rryy The F1 generation of a dihybrid cross (RrYy) shows only the dominant phenotypes for each trait • Allow F1 to self-fertilize to produce F2 F1 self-fertilizes • RrYy x RrYy • The F2 generation shows all four possible phenotypes in a set ratio – 9:3:3:1 – R_Y_:R_yy:rrY_:rryy – round yellow:round green:wrinkled yellow:wrinkled green Principle of Independent Assortment • In a dihybrid cross, the alleles of each gene assort independently • The segregation of different allele pairs is independent • Independent alignment of different homologous chromosome pairs during metaphase I leads to the independent segregation of the different allele pairs Probability • Rule of addition – probability of 2 mutually exclusive events occurring simultaneously is the sum of their individual probabilities • When crossing Pp x Pp, the probability of producing Pp offspring is – probability of obtaining Pp (1/4), PLUS probability of obtaining pP (1/4) –¼ + ¼ = ½ Probability • Rule of multiplication – probability of 2 independent events occurring simultaneously is the product of their individual probabilities • When crossing Pp x Pp, the probability of obtaining pp offspring is – probability of obtaining p from father = ½ – probability of obtaining p from mother = ½ – probability of pp = ½ x ½ = ¼ Testcross • Cross used to determine the genotype of an individual with dominant phenotype • Cross the individual with unknown genotype (e.g. P_) with a homozygous recessive (pp) • Phenotypic ratios among offspring are different, depending on the genotype of the unknown parent Extensions to Mendel • Mendel’s model of inheritance assumes that – each trait is controlled by a single gene – each gene has only 2 alleles – there is a clear dominant-recessive relationship between the alleles • Most genes do not meet these criteria Polygenic Inheritance • Occurs when multiple genes are involved in controlling the phenotype of a trait • The phenotype is an accumulation of contributions by multiple genes • These traits show continuous variation and are referred to as quantitative traits – for example – human height – histogram shows normal distribution Pleiotropy • Refers to an allele which has more than one effect on the phenotype • Pleiotropic effects are difficult to predict, because a gene that affects one trait often performs other, unknown functions • This can be seen in human diseases such as cystic fibrosis or sickle cell anemia – multiple symptoms can be traced back to one defective allele Multiple Alleles • May be more than 2 alleles for a gene in a population • ABO blood types in humans – 3 alleles • Each individual can only have 2 alleles • Number of alleles possible for any gene is constrained, but usually more than two alleles exist for any gene in an outbreeding population • Incomplete dominance – heterozygote is intermediate in phenotype between the 2 homozygotes – red flowers x white flowers = pink flowers • Codominance – heterozygote shows some aspect of the phenotypes of both homozygotes – Type AB blood Human ABO Blood Group • The system demonstrates both – multiple alleles • 3 alleles of the I gene (IA, IB, and i) – Codominance • IA and IB are dominant to i but codominant to each other Environmental Influence • Coat color in Himalayan rabbits and Siamese cats – allele produces an enzyme that allows pigment production only at temperatures below 33oC