190 likes | 329 Views
Mendelian Genetics. Laws of Inheritance. Terms. Phenotype: the appearance of the trait in the organism Genotype : the genetic make-up of an organism Genetics : biology dealing with the principles of variation and inheritance in animals and plants.
E N D
Mendelian Genetics Laws of Inheritance
Terms Phenotype: • the appearance of the trait in the organism Genotype: • the genetic make-up of an organism Genetics: • biology dealing with the principles of variation and inheritance in animals and plants. • gives us greater understanding of how we can determine the likelihood of inheriting certain phenotypes.
History • Since 460 B.C.E philosophers, physicians and scientists have been theorizing heredity • Most believed inheritance involved a “mixing” of genetic information from the mother and father • During the 19th century the “blending theory” of genetics was quite popular. -offspring’s phenotypes were a blend of the parents’ • Didn’t understand how phenotypes were expressed, or WHY some phenotypes in the P generation were NOT expressed in their offspring’s generation
Gregor Mendel (1822-1884) • Austrian monk • Developed principles that became genetics through 8 yrs of conducting experiments on pea plants Why the pea plant? • Commercially available • Easy to grow, and matures quickly • Sexual organs (re: reproductive organs) entirely enclosed in the flower – meaning plants self-pollinate so Mendel could control reproduction
Mendel’s Experiments • introduced pollen from the flower of one pea plant to the pistil (ovaries) of another flower • resulted in a variety of different, easily distinguishable phenotypes • examined seven of the resulting phenotypes – each of which only had two possible variations
Experiment #1 – F1 Generation • obtained plant “purebreds” (P* – parent generation) *only use this notation if purebred • crossed each P generation with its opposite -ex: tall P plant is crossed with a short P • this produced the F1* generation (1st filial) -hybrids since a cross between two different purebreds *only use this notation if hybrid offspring of 2 purebreds • called a Monohybrid Cross (only 1 trait was selected – plant height
Results: • all F1 plants were tall • concluded the trait for tall plants must be dominant • trait for short plants must be recessive Dominant: • a phenotype that is always expressed Recessive: • a characteristic that is always latent (present but inactive) • not usually expressed in an individual Principle of Dominance: • When individuals with contrasting traits are crossed, the offspring will express only the dominant trait
Experiment #2 – F2 Generation • Crossed F1 generations • produced F2 generation Results: • 3 were tall, 1 was short • ratio of 3:1 is known as the Mendelian ratio
Mendel’s Law of Segregation • Each parent has 2 copies of each gene Gene– part of the chromosome that controls expression of a certain trait • Genes can exist in different forms, known as alleles. • Alleles for pea seed shape include round and wrinkled. • Offspring inherit one allele of a gene from each parent. • If both alleles are the same = homozygous for that gene. • If alleles are different = heterozygousfor that gene. • Alleles can be dominant or recessive. • Dominant alleles are expressed in heterozygous offspring. • Recessive alleles are only expressed in homozygous offspring. • Each gamete carries only one allele for each trait.
Genotypes & Phenotypes • Capital letters used for dominant allele • lowercase of the same letter used for recessive • ex. round seeds are dominant over wrinkled. • R = round, r = wrinkled Genotype • the alleles for an individual, ex. for seeds: - RR (homozygous round) - rr (homozygous wrinkled) - Rr (heterozygous round) Phenotype • the expressed trait for an individual (what is seen) ex. for seeds: - round - wrinkled • Heterozygous genotypes (Rr) always have the phenotype of the dominant allele.
P Generation Tall short True-breeding parents Tall = dominant = TShort = recessive = t TT tt F1 Generation Hybrid offspringAll heterozygous all Tall all Tt F2 Generation Genotypes1 TT : 2 Tt : 1 tt Phenotypes3 Tall :1 short Monohybrid crossfrom F1 generation short Tall Tall Tall tt TT Tt Tt Plant Height Experiments • F1 genotype: - 4 Tt (heterozygous) • F1 phenotype: - 4 tall • F2 genotypes: - 1 TT (homozygous dominant) - 2 Tt (heterozygous) - 1 tt (homozygous recessive) - ratio 1:2:1 • F2 phenotypes: - 3 tall - 1 short - ratio 3:1
Probability & Punnet Squares Probability – the likelihood of an outcome Punnett square - used to determine the probabilities of allele combinations when the genotypes of the parents are known
Practice Problem #1 • Ageneticist crosses two pea plants. One of the plants is heterozygous for the dominant inflated pea pod trait, and the other plant has constricted pea pods. What would be the expected genotypic and phenotypic proportions of the offspring? Given • inflated pod (I) - dominant • constricted pod (i) - recessive • II or Ii = Inflated pods • ii = constricted pods • heterozygous inflated x constricted = Ii x ii Required • Punnet square • gametes from the cross • expected proportions of F1 plants with genotypes II, Ii, and ii • expected proportions of phenotypes (inflated pods and constricted)
Solution • The Ii parent produces gametes I and i. • The ii parent produces gametes i and i. Paraphrase 1/2 of the offspring would be heterozygous (Ii) and 1/2 would be ii. Therefore, 1/2 of the offspring would have inflated pods, and 1/2 would have constricted pods.
Solutions #2- 4 2. Solution • The Aa parent produces gametes A and a. • The aa parent produces gametes a and a. Paraphrase • ½ the offspring would be heterozygous (Aa) and ½ would be aa. Therefore, ½ of the offspring would be brown, and ½ would be albino 3. Solution • The DD parent produces gametes D and D. • The Dd parent produces gametes D and d. Paraphrase • ½ of the offspring would be heterozygous (Aa) and ½ would be homozygous (AA). Therefore, all of the offspring would have dimples. 4. Solution • The Tt parents produce gametes T and t. Paraphrase • ½ of the offspring would be heterozygous (Tt), ¼ would be homozygous dominant (TT) and ¼ would be homozygous recessive (tt). Therefore, ¾ of the offspring would taste PTC, and ¼ would not.
Test Crosses • how genotype can be determined from phenotype • breed an individual with the dominant phenotype with a homozygous recessive • If offspring are all dominant phenotype, the parent was homozygous dominant • If offspring are half dominant phenotype, and half recessive phenotype, the parent was heterozygous dominant.