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Chapter 8 Mendel, Peas, and Heredity

Chapter 8 Mendel, Peas, and Heredity. 8-1 Origins of Genetics. Heredity – the passing of traits from parents to offspring Genetics – science that focuses of heredity Gregor Mendel – considered the father of genetics Why?. Mendel.

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Chapter 8 Mendel, Peas, and Heredity

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  1. Chapter 8 Mendel, Peas, and Heredity

  2. 8-1 Origins of Genetics • Heredity – the passing of traits from parents to offspring • Genetics – science that focuses of heredity • Gregor Mendel – considered the father of genetics • Why?

  3. Mendel • Austrian monk who used his math and science background to study heredity • Used the experiments of T.A. Knight (studied pea plants) • Used math to analyze his results (1st to do so) • Published his work in 1866

  4. Why Peas? • They taste good with butter • You can smash them with mashed potatoes • Just kidding

  5. Has many traits that come in only two forms • Can easily control the mating of plants • Small, grows fast, produces many offspring

  6. Mendel’s Classic Experiment • His experiment was called a monohybrid cross (cross that involves one pair of contrasting traits) • Used plants that were true-breeding in the beginning • True-breeding – all offspring would display one form of a specific trait

  7. Step 1 • Allowed a group of plants to self-pollinate for several generations • Why? • To ensure they were true-breeding • These plants would serve as the P Generation (Parent) • White Flowered TB Plant x Purple Flowered TB Plant

  8. Step 2 • Results of P generation cross were all Purple Flowered Offspring • Called the F1 Generation • Recorded the number of plants expressing the trait

  9. Step 3 • Allowed the F1 plants to self-pollinate • Resulting offspring called the F2 Generation • Most were purple flower plants, some were white flowered plants • Why?

  10. 8-2 Mendel’s Hypotheses • For each inherited trait, an individual has a copy of a gene from each parent • There are alternative versions of genes (allele) • When two different alleles occur together, one may be completely expressed, while the other is not observable (dominant vs. recessive)

  11. When gametes form, alleles for each gene separate independently of one another (haploid cells)

  12. Homozygous – two of the same alleles (TT or tt) • Heterozygous – two different alleles (Tt) • Genotype – set of alleles an organism has (TT or Tt or tt) • Phenotype – physical expression of a trait (tall or short)

  13. Laws of Heredity • Law of Segregation – the alleles of a gene are separated during meiosis

  14. Law of Independent Assortment – States that a random assortment of maternally and fraternally derived chromosomes during meiosis results in gametes that have different combinations of genes • Allele for plant height separates from allele for flower color during meiosis

  15. 8-3 Studying Heredity • Punnett Squares show the probability of a certain cross • Remember, not actual results, only possible results

  16. Pedigree • Pedigree – a family history that shows how a trait is inherited over several generations • Helpful for tracking genetic disorders

  17. Autosomal or Sex-Linked? • If a trait is autosomal, it will affect both males and females equally • Sex-Linked traits have their allele on the X chromosome • Most are recessive • Males usually exhibit the trait because they only have one X chromosome. Why?

  18. Females get two chances to get a dominant allele while males only get one allele • Females can be carriers of a sex-linked trait (if they are heterozygous)

  19. Rules of Pedigrees • Squares = Male • Circle = Female • Line between male and female means they are married • Different generations happen on different levels of the pedigree

  20. Example of a Pedigree • This pedigree tracks albinism • Albinism is a recessive trait that is autosomal • All genotypes are known

  21. Example of a Pedigree • This pedigree tracks albinism • Only genotype known are those showing the recessive condition

  22. Modes of Inheritance • Autosomal Dominant – males and females can be affected, and trait does not skip generations • Autosomal Recessive – can affect males and females, and may skip generations

  23. 8-4 Patterns of Heredity • Most traits are not controlled by dominant vs. recessive alleles • When several genes control a trait, they are called polygenic traits • Eye color, skin color, height, and weight are all polygenic traits

  24. Incomplete Dominance • When an individual is heterozygous for a trait, the individual displays an intermediate form between the two alleles • Red Snap Dragon crossed with a White Snap Dragon, and the offspring are pink

  25. Codominance • When an individual is heterozygous for a trait, both alleles are expressed at the same time • When a homozygous white horsed is crossed with a homozygous red horse, the offspring is roan (red and white hairs)

  26. Multiple Alleles • Traits with three or more alleles • Human Blood Type has three alleles, • IA, IB, and i

  27. Sex Linked Traits • Traits whose genes are located on the X or Y chromosome • Usually men are more likely to be affected with diseases that are sex linked traits

  28. Environmental Influence • Phenotypes often are influenced by the environment • Examples of influences include nutrition, social exposure, and temperature

  29. Genetic Disorders • Sickle Cell Anemia – autosomal recessive condition caused by abnormal hemoglobin molecules • Tay-Sachs – autosomal recessive condition that causes a defective form of a brain protein

  30. Cystic Fibrosis – autosomal recessive condition that causes a defective chloride-ion transport protein • Hemophilia A – sex-linked recessive condition that causes a defective blood clotting factor • Huntington’s Disease – autosomal dominant condition that causes an inhibitor of brain-cell metabolism

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