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Genetics, Meiosis, and the Molecular Basis of Heredity

Explore the molecular mechanisms of genetics, meiosis, and the fascinating theories behind inheritance. Learn about sexual reproduction, mitosis, meiosis, and the introduction of variation through recombination. Discover the role of gametes and chromosomes in heredity.

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Genetics, Meiosis, and the Molecular Basis of Heredity

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  1. Genetics, Meiosis, and the Molecular Basis of Heredity

  2. Theories on Inheritance • It was clear for millennia that offspring resembled their parents, but how this came about was unclear. • Do males and females harbor homunculi? • Do the components of sperm and egg mix like paint? • What role do gametes and chromosomes play?

  3. Theories on Inheritance • Genetics = the science of heredity • This section will focus on the molecular mechanisms of genetics

  4. Genetics, Meiosis, and the Molecular Basis of Heredity • Topics • Sexual reproduction (advantages, disadvantages, meiosis) • Mendelian inheritance • Experimental genetics

  5. Simple Inheritance • Bacteria and some other organisms reproduce simply by making exact copies of themselves • This is asexual reproduction • The basic mechanism for most unicellular eukaryotes is mitosis

  6. Mitosis • Mitosis is part of the eukaryotic cell cycle, which consists of two growth phases (G1, G2), a synthesis phase (S), and an M phase during which cell division occurs

  7. Mitosis • During M-phase, a cell must complete a nuclear division and a cytoplasmic division and faithfully distribute replicated chromosomes to each daughter nucleus

  8. Mitosis • Although they overlap extensively, M-phase is typically divided into six phases

  9. Mitosis • Although they overlap extensively, M-phase is typically divided into six phases

  10. Mitosis • Although they overlap extensively, M-phase is typically divided into six phases

  11. Mitosis • Although they overlap extensively, M-phase is typically divided into six phases

  12. Mitosis • Although they overlap extensively, M-phase is typically divided into six phases

  13. Mitosis • Although they overlap extensively, M-phase is typically divided into six phases • Animal cells and plant cells differ with respect to cytokinesis

  14. Mitosis • Movie

  15. Sexual Reproduction • Sexual reproduction involves the mixing of genomes from two individuals to produce offspring that are genetically distinct from either parent and from other offspring • Disadvantages – • Half of your genes don’t make it to the next generation • very costly to produce specialized cells • interaction with other organisms is dangerous • mixing genes can produce unexpected results • Advantages • One word – variation • The introduction of variation allows for better survival in a changing environment and for the rapid spread or reduction of advantageous and deleterious genes – (see video on guppies)

  16. Sexual Reproduction • Sexual reproduction occurs in diploid organisms • Diploid organisms have two complete sets of chromosomes, one from each parent • Diploid organisms therefore carry two copies of most genes • Diploid organisms use haploid cells to reproduce • Haploid cells contain only one copy of each chromosome set

  17. Sexual Reproduction • The basics of sexual reproduction • The germ cells (gametes) are haploid • Gametes are generated through meiosis • There are typically two types in animals • A large, immobile egg • Small, mobile sperm • During sexual reproduction, the gametes fuse to produce a diploid zygote

  18. Sexual Reproduction • Primordial germ cells are produced by mitosis • Ova and sperm by meiosis • Spermatogenesis continues throughout male mammals life • Increased mutation rate in males due to increased number of replication events

  19. Sexual Reproduction:Mitosis review • Diploid cells reproduce through mitosis • This NOT how gametes are made

  20. Sexual Reproduction:Meiosis (producing gametes) • In mitosis, a diploid cell produces twodiploid daughter cells • In meiosis, a diploid cell gives rise to fourhaploid cells

  21. Sexual Reproduction:Meiosis (producing gametes) • Major differences between mitosis and meiosis • Mitosis – once cell division • Meiosis – two cell divisions • Mitosis – replicated chromosomes line up ‘single file’ during metaphase • Meiosis – replicated homologs line up in pairs during metaphase I and ‘single file’ in metaphase II

  22. Sexual Reproduction:Meiosis (producing gametes)

  23. Sexual Reproduction:Meiosis (producing gametes) • Variation is introduced to the offspring by combining the chromosomes of both parents into a single cell • A second level of variation is introduced via recombination during meiosis (prophase I) • Recombination is an exchange of material between homologous chromosomes via a process called ‘crossing over’ • Thus, the gametes you produce will be novel combinations of the chromosomes you received from your parents

  24. Sexual Reproduction:Recombination

  25. Sexual Reproduction:Recombination

  26. Sexual Reproduction:Recombination • The end result of meiosis is a pool of gametes in which the genetic information of the parent has been extensively rearranged • Merely by combining different sets of paternal and maternal chromosomes, there are 223 (8,400,000) distinct gametes possible • By introducing recombination you increase that number exponentially

  27. Sexual Reproduction:Creating variation

  28. Sexual Reproduction:Mistakes during meiosis • A cell must keep track of 92 chromosomes (23 x 4) during meiosis and sometimes errors occur • Nondisjunction – failure of chromosomes to separate properly • Results in gametes with more or fewer than the standard number

  29. Sexual Reproduction:Nondisjunction • Zygotes resulting from aneuploid (abnormal chromosome number) gametes typically don’t survive but sometimes do • Down syndrome (trisomy 21) • Edward’s syndrome (trisomy 18) • Patau’s syndrome (trisomy 13)

  30. Sexual Reproduction:Fertilization • Fertilization is the union of two gametes to produce a diploid zygote • ~200 of the 3 million sperm in a human male ejaculate reach the egg • To ensure only one sperm fertilizes the egg, a chemical cascade ‘hardens’ the egg once one has fused with it

  31. Sexual Reproduction:Fertilization • Ca++ Wave During Sea Urchin Egg Fertilization • The sperm enters at about the 2 o'clock position. Note the elevation of the fertilization membrane in the left panel and the calcium wave in the right panel.

  32. Mendelian Inheritance • As a result of the processed described for sexual reproduction, the genomes of diploid organisms are a mixture of discrete segments of their parents’ genomes • Some traits are inherited in a simple fashion through individual genes. • Other traits are polygenic • Others are simple and/or polygenic and influenced by the environment

  33. Mendelian Inheritance • Simple Mendelian inheritance • Attached earlobes • PTC (phenylthiocarbamide) tasting • ‘uncombable hair’ • Complex (polygenic) inheritance • Eye color • Height • Studying inheritance in humans is difficult for ethical reasons but more easily done in other organisms

  34. Mendelian Inheritance • Named for Gregor Mendel • 1822-1884 • Studied discrete (+/-, white/black) traits in pea plants

  35. Mendelian Inheritance • Mendel began with true-breeding plants • True-breeding - when mated with themselves or others of the same type, produce the same offspring • Cross-pollinated these true breeding varieties • Crossed the offspring (F1’s) with each other or back to the parents • Kept very detailed numerical records of the offspring of each cross

  36. Mendelian Inheritance • A classic experiment • What did it tell Mendel? • That pod color was inherited as a discrete trait, inheritance was not ‘blended’ for this trait • That one trait was ‘dominant’ over the other • yellow + green ≠ yellow-green • yellow + green = yellow

  37. Mendelian Inheritance • By continuing the experiment, more can be learned • The trait that was ‘lost’ in the first generation (F1) was regained by the second (F2) • yellow + yellow = yellow and green • The cause of the trait was not destroyed, but was harbored unseen in the parent • There was a definite mathematical pattern to the occurrence of the traits (3:1)

  38. Mendelian Inheritance • Mendel concluded: • Heredity was caused by discrete ‘factors’ (genes) • These ‘factors’ remain separate instead of blending • The ‘factors’ came in different ‘flavors’ (alleles) • Each offspring must inherit one gene from each parent (2 total) • The phenotype (appearance) of the plants was determined by the genotype (actual combination of alleles)

  39. Mendelian Inheritance • Genotype vs. phenotype

  40. Mendelian Inheritance • The true-breeders only had one type of allele (homozygous) • Each parent passes on one of the alleles they have to the offspring • The first generation will all be heterozygous (have two different alleles) • One of the alleles is able to block the other (yellow is dominant vs. green is recessive) • The F1’s pass on both of their alleles in a random manner • Mendel’s Law of Segregation – the alleles for a trait separate randomly during gamete formation and reunite at fertilization

  41. Mendelian Inheritance • Mendel’s results held true for other plants (corn, beans) • They can also be generalized to any sexually reproducing organism including humans

  42. Mendelian Inheritance • Humans don’t typically have families large enough to see mendelian ratios • Inheritance can be tracked through the use of pedigrees • Are the traits in white and black dominant or recessive?

  43. Mendelian Inheritance • If the trait indicated in black is dominant we would expect the cross between 2 and 3 to produce either 100% black trait offspring or ~50% black trait and ~50% white trait offspring • That ain’t the case BB bb Bb Bb Bb Bb Bb Bb Bb bb Bb bb bb bb Bb Bb

  44. Mendelian Inheritance • If the trait indicated in black is recessive we would expect the cross between 2 and 3 to produce all white trait offspring • Although it is possible for individual 3 to have a Bb genotype, it is unlikely (0.56 = 0.016) • What is the genotype of #2’s sister? bb BB Bb Bb Bb Bb Bb Bb

  45. B? B? B? Bb Bb bb Bb Bb bb Bb Bb bb bb bb bb bb bb Mendelian Inheritance • Using the information from the previous slides we can deduce most individual’s genotypes Bb BB bb Bb Bb Bb Bb Bb Bb

  46. Mendelian Inheritance • The examples above are referred to as monohybrid crosses since they deal with only one trait at a time • Mendel also followed dihybrid crosses in which two traits are followed at once • Would the traits segregate as a single unit or independently?

  47. Mendelian Inheritance • A dihybrid cross

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