Difference Between Mitosis and Meiosis

1. Meiosis H BIOLOGY LANE TECH February 2018

2. What is the difference between Mitosis and Meiosis?

3. Types of Reproduction • Asexual • One parent produces genetically identical offspring • Ex: body cells (mitosis), bacteria • Sexual • Two parents produce genetically different offspring through fertilization • Different type of cell division must be used to create an egg & a sperm! (meiosis) 46 23 + 23

4. What is Fertilization? • Fertilization: A sperm cell and an egg cell fuse together • Creates a zygote which is a fertilized egg • Half the genetic information is from “dad” and half is from “mom”

5. Diploid Male (2n=46) Diploid Female (2n=46) MEIOSIS Egg Cell (n=23) Sperm Cell (n=23) FERTILIZATION Zygote (2n=46) Embryo (2n=46) MITOSIS begins  helps grow the embryo into a human!

6. 2 Groups of Cells in our Body • Somatic Cells: • Also called “Body Cells” • Every cell in your body, except for your sex cells (eggs and sperm) • Divide by Mitosis continuously until death • Gametes: • Sex cells (eggs and sperm)

7. Chromosomes within Cells • Remember, within our cells, we have chromosomes! • These are found…. in the nucleus! • Different species have different numbers of chromosomes • How many chromosomes do humans have? • 46 (23 pairs of chromosomes)

8. Chromosomes within Cells • Recall those 2 groups of cells we talked about earlier…? • 1st - Somatic Cells • ContainAutosomal Chromosomes – code for physical traits (in pairs) • 22 pairs = 44 chromosomes total • 2nd - Gamete Cell(s) • Containsex chromosomes – determine gender (in pairs) • 1 pair = 2 chromosomes total

9. Sex chromosomes • Found in gamete cells  determines gender (male/female) • 2 forms  X and Y • Mom’s egg always gives an “X” • Sperm can give “X” or “Y” • Results in: • Males: XY • Females: XX FUN FACT: Why was King Henry VIII a big jerk?!

10. Somatic vs. Gametes Sex chromosomes from GAMETE CELLS ALL AUTOSOMAL CHROMOSOMES  from SOMATIC CELLS

11. FUN FACT: Meiosis in men creates 4 sperm cells, whereas meiosis in women creates 1 (large!) egg cell Only 1 3 1 2 4

12. Another Difference between Somatic & Gamete Cells? • Somatic and Gamete Cells contain different amounts of chromosomes (and therefore, DNA) • Two types: • Haploid (n) • Diploid (2n)

13. Haploid vs. Diploid • Haploid (n): • Produced by meiosis • These are GAMETES (sex cells) • Contain a single set of chromosomes  23 chromosomes (n) • Diploid (2n): • A complete set(2 sets total) of homologouschromosomes  1 from mom, 1 from dad • Contain 23 pairs in humans = 46 chromosomes FUN FACT: in humans, n = 23….

14. What are Homologous Chromosomes? • HOMOLOGOUS – pair of chromosomes that are the same shape, size, and have the same gene pattern • NOT identical  you get one set from mom and one set from dad • 23 homologous pairs = 46 chromosomes One pair of homologous chromosomes = tetrad

15. What is Meiosis? • Meiosis: • Part of Sexual reproduction • Increases genetic variation • Type of cell division that produces 4 haploid daughter cells • Goal: each daughter cell has half the number of chromosomes as parent cell • Only occurs in sex organs (testes, ovaries)

16. Meiosis Overview2 Cell Divisons • Meiosis I • Prophase I • Separates Homologous Pair • Metaphase I • Anaphase I • Telophase I • Meiosis II • Prophase II • Separates sister chromatids • Metaphase II • Anaphase II • Telophase II

17. Meiosis 1 • Prophase I • Nuclear Envelope breaks down • Chromatin condenses – why is this important? HINT: which of these would be easier to accurately divide in half?

18. Meiosis 1 • Prophase I (con’d) • Homologous chromosomes stick together • 2 homologous chromosomes = a tetrad = 4 chromatids • Crossing Over happens! • Sister chromatids exchange genetic material

19. Meiosis 1 • Metaphase I: • Tetradsline up in the middle of the cell • Anaphase I: • Tetrads(homologous pairs) split and move to opposite poles of cell

20. Meiosis 1 • Telophase I: • Spindle fibers disappear • Nucleus envelope reappears • Cytokinesis • 2 Haploid daughter cells (1n)

21. Meiosis 1 Summary TELOHASE II TELOHASE I DNA info from mom and dad wrapped into 1 chromosome (92 chromatids = 46 chromatids worth of information from both parents) PROPHASE I

22. Meiosis 2 • Prophase II • Nuclear Envelope breaks down, centrosomes and centrioles move to pole ends and spindle fibers assemble (same as in Prophase I except NO Crossing Over) • Metaphase II • 23 chromosomes align at the cell equator, each chromosome still has TWO sister chromatids • Anaphase II • Sister chromatids pull apart • Telophase II • Nuclear membranes re-form around each set of chromosomes, spindle fibers break apart 4 cells total now have 23 chromosomes  a combo from both mom and dad

23. Prophase I - Duplicate Homologues Pair Up = Tetrad

24. Metaphase I – Tetrads Align in the Middle

25. Anaphase I – Tetrads Separate

26. Telophase I – Nucleus reforms. 23 chromosomes (46 chromatids) in each of TWO new cells

27. Prophase II – 46 chromatids move toward equator plate

28. Metaphase II – 23 Chromatid Pairs align between the poles

29. Anaphase II – 46 chromatids are pulled apart and become 46 chromosomes

30. Telophase II – 23 chromosomes (haploid 1n) in each cell!

32. How is it All Related?

33. Complications of Meiosis: Genetic Disorders • Caused by an abnormality in an individual’s DNA • How do these abnormalities occur? • Non-disjunction • Addition or subtraction of chromosome or a set of chromosomes • Mutations • Change to DNA sequence (gene)

34. Non-Disjunction QUESTION: Is it possible for non-disjunction to occur and still end up with a healthy individual?

35. Non-Disjunction • Non-disjunction- failure of the chromosomes to separate properly in meiosis I or II • What are some disorders caused by non-disjunction? • Downs Syndrome • Trisomy 21 • Patau Syndrome • Trisomy 13 • Edwards Syndrome • Trisomy 18 • Klinefelter’s Syndrome • XXY • Turner Syndrome • Monosomy X

36. What is a Karyotype? • Karyotype: • Display of chromosomes (condensed)

37. Human Karyotype -

38. What’s the problem?

39. What’s the problem?

40. What’s the problem?

41. Klinefelter’s Syndrome

42. Klinefelter Syndrome

43. Turner Syndrome

44. Turner Syndrome

45. Inheritance Patterns of Disorders • Codominant Inheritance • Sickle cell anemia • Dominant Inheritance • Huntington’s Disease • Recessive Inheritance • Cystic fibrosis (recessive) • Maple syrup urine disorder (recessive) • Congenital hypothyroidism (recessive)

46. Sickle Cell Anemia • Hemoglobin is the O2 carrying protein in red blood cells • SCA is an inherited blood disease where hemoglobin clumps together  causes red blood cells to stiffen and curl into a sickle/crescent shape  because of this, the RBC cannot transport O2 effectively

47. Huntington’s Disease • Huntington’s disease • Develops in middle age, death soon follows • Deterioration of nervous system, uncontrollable movements until person dies  • Found on Chromosome 4 • Chromosome 4 spans more than 186 million base pairs • HD is a dominantgene… • …this means any child of an affected person has a 50% chance of inheriting the disease

48. Recessive Disorders • Over a thousand human genetic disorders are known to have Mendelian inheritance patterns • Cystic Fibrosis • Excess mucus in lungs, digestive tract, liver • More susceptible to pneumonia, infection • Early death ~ average age of 37 • Tay-Sachs • Lipid accumulation in brain cells, mental retardation • Blindness, death in childhood

49. Recessive Disorders • The majority of people with recessive disordersare born to parents who are heterozygous and do not have the recessive disorder • People who have one copy of the allele for a recessive disorder, but do not show any symptoms are called carriers