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Chapter 10: Sexual Reproduction and Genetics

Chapter 10: Sexual Reproduction and Genetics. Fall 2011 Wood. Chapter Overview (p.268). Big Idea Reproductive cells, which pass on genetic traits from the parents to the child, are produced by the pattern of meiosis. Sections 1) Meiosis 2) Mendellian genetics

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Chapter 10: Sexual Reproduction and Genetics

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  1. Chapter 10: Sexual Reproduction and Genetics • Fall 2011 • Wood

  2. Chapter Overview (p.268) • Big Idea • Reproductive cells, which pass on genetic traits from the parents to the child, are produced by the pattern of meiosis. • Sections • 1) Meiosis • 2) Mendellian genetics • 3)Gene linkage and polyploidy

  3. Section 1: Meiosis • Each cell in the body has a specific number of chromosomes. • For humans, our cells contain 46 chromosomes. • We receive 23 chromosomes from the mother, and 23 chromosomes from the father

  4. Human Cells • Where do our 46 chromosomes come from? • Having 2 sets of DNA is called having homologous chromosomes. • Same chromosome but carrying different versions of traits.

  5. Dad Mom

  6. Haploid Cells • A cell that contains one set of chomosomes (n) is considered haploid (half-loid). • For humans these cells would only have 23 chromosomes • These cells are called gametes

  7. Diploid Cells • These are cells that contain 2 sets (2n) of chromosomes. • For humans, these would be normal cells with 46 chromosomes

  8. Haploid & Diploid Cycle

  9. Gamete formation • Gametes, or haploid cells, are formed during a process called meiosis. • Meiosis starts with one diploid cell, and ends up creating 4 haploid cells. • Meiosis is split into 2 divisions: • Meiosis I • Meiosis 2

  10. Interphase • These cells still must go through interphase prior to meiosis. • This allows the cell to make a copy if the DNA during the S-Phase

  11. Meiosis I • First phase is Prophase I • Chromosomes condense • Nuclear membrane dissolves

  12. Metaphase I • Homologous chromosomes align on the equator.

  13. Anaphase I • Homologous chromosomes separate and move to opposite poles.

  14. Telophase I • Chromosomes uncoil to form 2 nuclei • The cell divides.

  15. Meiosis II • Prophase II • Repeat of prophase 1

  16. Metaphase II • Haploid number of chromosomes align on the midline.

  17. Anaphase II • Sister chromatids are pulled to opposite poles.

  18. Telophase II • Chromosomes reach the poles, and nuclear membranes form.

  19. Cytokinesis II • Meiosis results in 4 haploid cells each with n number of chromosomes.

  20. Importance of Meiosis • Creates 4 haploid daughter cells that are not identical. • Results in genetic variation • Random creation of gametes • Ex) crossing over

  21. Crossing over • Occurs during prophase I to create genetic variation. • Happens when parts of chromosomes are traded between a pair of homologous chromosomes.

  22. Section 2: Mendellian genetics • Overview • Start of genetics • Alleles • Dominant and recessive • Genotype and phenotype • 2 laws of genetics • Punnett squares

  23. The start of genetics • In 1866, Greger Mendel published his findings on inheritance. • He is now known as the “Father of Genetics” • He was an Austrian monk who studied garden pea plants.

  24. Mendel performed cross pollination in pea plants. • He then studied these traits about the passing of traits through generations: • Seed color, flower color, seed shape or texture, and flower position.

  25. Generations • The parent generation is also known as the “P” generation.

  26. The generation created by the parents is known as the “F1” or first fillial generation. • The second generation is called the “F2” or second fillial generation.

  27. Why was the second generation, or f1, all yellow? Why was there not green? • This is due to the fact that genes always have different forms called allelles.

  28. Alleles • The alleles for our example are yellow and green. • An allele is simply an alternate form of a gene. • One allele will be dominant and the other will be recessive.

  29. Where did the green seed come from in the third generation? They were not there in the second generation. • Dominant alleles are shown, and recessive alleles are masked. • Yellow seeds are dominant over green seeds.

  30. Dominant vs Recessive • Dominant alleles are always shown by a capital letter. Recessive genes are always shown by a lowercase letter. • Ex) yyYYYy • Green yellow yellow

  31. Homozygous vs heterozygous • An individual can be one of 3 types: • Homozygous dominant • Heterozygous • Homozygous recessive

  32. Genotype vs Phenotype • A genotype is what genes an individual has. • A phenotype is what characteristics are observed. • Yyvsyyvs YY

  33. Law of Segregation • States that two alleles for a gene must separate during meiosis.

  34. Law of Independent Assortment • This law states that alleles occur in a random distribution. • Aka) the genes from one parent do not always stay together.

  35. 2 Laws of Genetics • Mendel formulated 2 laws for genetics: • 1) Law of Segregation • 2) Law of Independent Assortment

  36. Punnett Squares • These predict the possible offspring of a cross between two known genotypes. • Monohybrid cross

  37. Section 3: Gene Linkage and Polyploidy • Overview • Genetic recombination • Gene Linkage • Polyploidy

  38. Genetic Recombination • The new combination of genes produced by crossing over and independent assortment is called genetic recombination. • Human cells have a possible 223 combinations. Combine 2 cells and there are over 70 trillion possibilities.

  39. Gene Linkage • Genes that are located close to one another on a chromosome are said to be linked. This means that they usually travel together during meiosis.

  40. Polyploidy • This is the occurance of one of more extra sets of chromosomes in an organism. • Ex) strawberries are 8n, coffee is 4n, and wheat is typically 6n.

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