1. 1 Cellular Division copyright cmassengale

2. 2 Cell Division All cells are derived from pre- existing cells All cells are derived from pre- existing cells New cells are produced for growth and to replace damaged or old cells New cells are produced for growth and to replace damaged or old cells Differs in prokaryotes (bacteria) and eukaryotes (protists, fungi, plants, & animals) Differs in prokaryotes (bacteria) and eukaryotes (protists, fungi, plants, & animals) copyright cmassengale

3. 3 Keeping Cells Identical The instructions for making cell parts are encoded in the DNA, so each new cell must get a complete set of the DNA molecules copyright cmassengale

4. 4 DNA Replication DNA must be copied or replicated before cell division DNA must be copied or replicated before cell division Each new cell will then have an identical copy of the DNA Each new cell will then have an identical copy of the DNA Original DNA strand Two new, identical DNA strands copyright cmassengale

5. 5 Identical Daughter Cells Parent Cell Two identical daughter cells copyright cmassengale

6. 6 Chromosomes

7. 7 Prokaryotic Chromosome The DNA of prokaryotes (bacteria) is one, circular chromosome attached to the inside of the cell membrane The DNA of prokaryotes (bacteria) is one, circular chromosome attached to the inside of the cell membrane copyright cmassengale

8. 8 Eukaryotic Chromosomes All eukaryotic cells store genetic information in chromosomes All eukaryotic cells store genetic information in chromosomes Most eukaryotes have between 10 and 50 chromosomes in their body cells Most eukaryotes have between 10 and 50 chromosomes in their body cells Human body cells have 46 (Diploid) chromosomes or 23 (haploid) identical pairs Human body cells have 46 (Diploid) chromosomes or 23 (haploid) identical pairs copyright cmassengale

9. 9 Eukaryotic Chromosomes Each chromosome is composed of a single, tightly coiled DNA molecule Each chromosome is composed of a single, tightly coiled DNA molecule Chromosomes can’t be seen when cells aren’t dividing and are called chromatin Chromosomes can’t be seen when cells aren’t dividing and are called chromatin copyright cmassengale

10. 10 Compacting DNA into Chromosomes DNA is tightly coiled around proteins called histones copyright cmassengale

11. 11 Chromosomes in Dividing Cells Duplicated chromosomes are called chromatids & are held together by the centromere Called Sister Chromatids copyright cmassengale

12. 12 Karyotype A picture of the chromosomes from a human cell arranged in pairs by size A picture of the chromosomes from a human cell arranged in pairs by size First 22 pairs are called autosomes First 22 pairs are called autosomes Last pair are the sex chromosomes Last pair are the sex chromosomes XX female or XY male XX female or XY male copyright cmassengale

13. 13 Boy or Girl? Y - Chromosome X - Chromosome The Y Chromosome Decides copyright cmassengale

14. 14 Cell Reproduction copyright cmassengale

15. 15 Types of Cell Reproduction Asexual reproduction involves a single cell dividing to make 2 new, identical daughter cells Asexual reproduction involves a single cell dividing to make 2 new, identical daughter cells Mitosis & binary fission are examples of asexual reproduction Mitosis & binary fission are examples of asexual reproduction Sexual reproduction involves two cells (egg & sperm) joining to make a new cell (zygote) that is NOT identical to the original cells Sexual reproduction involves two cells (egg & sperm) joining to make a new cell (zygote) that is NOT identical to the original cells Meiosis is an example Meiosis is an example copyright cmassengale

16. 16 Cell Division in Prokaryotes copyright cmassengale

17. 17 Cell Division in Prokaryotes Prokaryotes such as bacteria divide into 2 identical cells by the process of binary fission Prokaryotes such as bacteria divide into 2 identical cells by the process of binary fission Single chromosome makes a copy of itself Single chromosome makes a copy of itself Cell wall forms between the chromosomes dividing the cell Cell wall forms between the chromosomes dividing the cell Parent cell 2 identical daughter cells Chromosome replicates Cell splits copyright cmassengale

18. 18 Prokaryotic Cell Undergoing Binary Fission copyright cmassengale

19. 19 Animation of Binary Fission copyright cmassengale

20. 20 The Cell Cycle copyright cmassengale

21. 21 Five Phases of the Cell Cycle G 1 - primary growth phase G 1 - primary growth phase S – synthesis; DNA replicated S – synthesis; DNA replicated G 2 - secondary growth phase G 2 - secondary growth phase collectively these 3 stages are called interphase M - mitosis M - mitosis C - cytokinesis C - cytokinesis copyright cmassengale

22. 22 Cell Cycle copyright cmassengale

23. 23 Interphase - G 1 Stage 1 st growth stage after cell division 1 st growth stage after cell division Cells mature by making more cytoplasm & organelles Cells mature by making more cytoplasm & organelles Cell carries on its normal metabolic activities Cell carries on its normal metabolic activities copyright cmassengale

24. 24 Interphase – S Stage Synthesis stage Synthesis stage DNA is copied or replicated DNA is copied or replicated Two identical copies of DNA Original DNA copyright cmassengale

25. 25 Interphase – G 2 Stage 2 nd Growth Stage 2 nd Growth Stage Occurs after DNA has been copied Occurs after DNA has been copied All cell structures needed for division are made (e.g. centrioles) All cell structures needed for division are made (e.g. centrioles) Both organelles & proteins are synthesized Both organelles & proteins are synthesized copyright cmassengale

26. 26 What’s Happening in Interphase? What the cell looks like Animal Cell What’s occurring copyright cmassengale

27. 27 Sketch the Cell Cycle Daughter Cells DNA Copied Cells Mature Cells prepare for Division Cell Divides into Identical cells copyright cmassengale

28. 28 Mitosis copyright cmassengale

29. 29 Mitosis Division of the nucleus Division of the nucleus Also called karyokinesis Also called karyokinesis Only occurs in eukaryotes Only occurs in eukaryotes Has four stages Has four stages Doesn’t occur in some cells such as brain cells Doesn’t occur in some cells such as brain cells copyright cmassengale

30. 30 Four Mitotic Stages Prophase Prophase Metaphase Metaphase Anaphase Anaphase Telophase Telophase copyright cmassengale

31. 31 Early Prophase Chromatin in nucleus condenses to form visible chromosomes Chromatin in nucleus condenses to form visible chromosomes Mitotic spindle forms from fibers in cytoskeleton or centrioles (animal) Mitotic spindle forms from fibers in cytoskeleton or centrioles (animal) Chromosomes Nucleolus Cytoplasm Nuclear Membrane copyright cmassengale

32. 32 Late Prophase Nuclear membrane & nucleolus are broken down Nuclear membrane & nucleolus are broken down Chromosomes continue condensing & are clearly visible Chromosomes continue condensing & are clearly visible Spindle fibers called kinetochores attach to the centromere of each chromosome Spindle fibers called kinetochores attach to the centromere of each chromosome Spindle finishes forming between the poles of the cell Spindle finishes forming between the poles of the cell copyright cmassengale

33. 33 Late Prophase Nucleus & Nucleolus have disintegrated Chromosomes copyright cmassengale

34. 34 Spindle Fiber attached to Chromosome Kinetochore Fiber Chromosome copyright cmassengale

35. 35 Review of Prophase What the cell looks like What’s happening copyright cmassengale

36. 36 Spindle Fibers The mitotic spindle form from the microtubules in plants and centrioles in animal cells The mitotic spindle form from the microtubules in plants and centrioles in animal cells Polar fibers extend from one pole of the cell to the opposite pole Polar fibers extend from one pole of the cell to the opposite pole Kinetochore fibers extend from the pole to the centromere of the chromosome to which they attach Kinetochore fibers extend from the pole to the centromere of the chromosome to which they attach Asters are short fibers radiating from centrioles Asters are short fibers radiating from centrioles copyright cmassengale

37. 37 Sketch The Spindle copyright cmassengale

38. 38 Metaphase Chromosomes, attached to the kinetochore fibers, move to the center of the cell Chromosomes, attached to the kinetochore fibers, move to the center of the cell Chromosomes are now lined up at the equator Chromosomes are now lined up at the equator Pole of the Cell Equator of Cell copyright cmassengale

39. 39 Metaphase Chromosomes lined at the Equator Asters at the poles Spindle Fibers copyright cmassengale

40. 40 Metaphase Aster Chromosomes at Equator copyright cmassengale

41. 41 Review of Metaphase What the cell looks like What’s occurring copyright cmassengale

42. 42 Anaphase Occurs rapidly Occurs rapidly Sister chromatids are pulled apart to opposite poles of the cell by kinetochore fibers Sister chromatids are pulled apart to opposite poles of the cell by kinetochore fibers copyright cmassengale

43. 43 Anaphase Sister Chromatids being separated copyright cmassengale

44. 44 Anaphase Review What the cell looks like What’s occurring copyright cmassengale

45. 45 Telophase Sister chromatids at opposite poles Sister chromatids at opposite poles Spindle disassembles Spindle disassembles Nuclear envelope forms around each set of sister chromatids Nuclear envelope forms around each set of sister chromatids Nucleolus reappears Nucleolus reappears CYTOKINESIS occurs CYTOKINESIS occurs Chromosomes reappear as chromatin Chromosomes reappear as chromatin copyright cmassengale

46. 46 Comparison of Anaphase & Telophase copyright cmassengale

47. 47 Cytokinesis Means division of the cytoplasm Means division of the cytoplasm Division of cell into two, identical halves called daughter cells Division of cell into two, identical halves called daughter cells In plant cells, cell plate forms at the equator to divide cell In plant cells, cell plate forms at the equator to divide cell In animal cells, cleavage furrow forms to split cell In animal cells, cleavage furrow forms to split cell copyright cmassengale

48. 48 Cytokinesis Cleavage furrow in animal cell Cell plate in plant cell copyright cmassengale

49. 49 Mitotic Stages copyright cmassengale

50. 50 Daughter Cells of Mitosis Have the same number of chromosomes as each other and as the parent cell from which they were formed Have the same number of chromosomes as each other and as the parent cell from which they were formed Identical to each other, but smaller than parent cell Identical to each other, but smaller than parent cell Must grow in size to become mature cells (G 1 of Interphase) Must grow in size to become mature cells (G 1 of Interphase) copyright cmassengale

51. 51 Identical Daughter Cells Chromosome number the same, but cells smaller than parent cell What is the 2n or diploid number? 2 copyright cmassengale

52. 52 Review of Mitosis copyright cmassengale

53. 53 Draw & Learn these Stages copyright cmassengale

54. 54 Draw & Learn these Stages copyright cmassengale

55. 55 Interphase Prophase Metaphase Anaphase Telophase Name the Mitotic Stages: Name this? copyright cmassengale

56. 56 Eukaryotic Cell Division Used for growth and repair Used for growth and repair Produce two new cells identical to the original cell Produce two new cells identical to the original cell Cells are diploid (2n) Cells are diploid (2n) Chromosomes during Metaphase of mitosis ProphaseMetaphase Anaphase Telophase Cytokinesis copyright cmassengale

57. 57 Mitosis Animation Name each stage as you see it occur? copyright cmassengale

58. 58 Mitosis in Onion Root Tips Do you see any stages of mitosis? copyright cmassengale

59. 59 Test Yourself over Mitosis copyright cmassengale

60. 60 Mitosis Quiz copyright cmassengale

61. 61 Mitosis Quiz copyright cmassengale

62. 62 Name the Stages of Mitosis: Interphase Early prophase Mid-Prophase Late Prophase Metaphase Late Anaphase Early Anaphase Early Telophase, Begin cytokinesis Late telophase, Advanced cytokinesis copyright cmassengale

63. 63 Identify the Stages Early, Middle, & Late Prophase Late Prophase MetaphaseAnaphase Late Anaphase Telophase Telophase & Cytokinesis ? ? ?? ? ?? copyright cmassengale

64. 64 Locate the Four Mitotic Stages in Plants Metaphase Prophase Anaphase Telophase copyright cmassengale

65. 65 Uncontrolled Mitosis If mitosis is not controlled, unlimited cell division occurs causing cancerous tumors If mitosis is not controlled, unlimited cell division occurs causing cancerous tumors Oncogenes are special proteins increase the chance that a normal cell develops into a tumor cell Oncogenes are special proteins that increase the chance that a normal cell develops into a tumor cell Cancer cells copyright cmassengale

66. 66 Meiosis Formation of Gametes (Eggs & Sperm) copyright cmassengale

67. 67 Facts About Meiosis Preceded by interphase which includes chromosome replication Preceded by interphase which includes chromosome replication Two meiotic divisions --- Meiosis I and Meiosis II Two meiotic divisions --- Meiosis I and Meiosis II Called Reduction- division Called Reduction- division Original cell is diploid (2n) Original cell is diploid (2n) Four daughter cells produced that are monoploid (1n) Four daughter cells produced that are monoploid (1n) copyright cmassengale

68. 68 Facts About Meiosis Daughter cells contain half the number of chromosomes as the original cell Daughter cells contain half the number of chromosomes as the original cell Produces gametes (eggs & sperm) Produces gametes (eggs & sperm) Occurs in the testes in males (Spermatogenesis) Occurs in the testes in males (Spermatogenesis) Occurs in the ovaries in females (Oogenesis) Occurs in the ovaries in females (Oogenesis) copyright cmassengale

69. 69 Start with 46 double stranded chromosomes (2n) After 1 division - 23 double stranded chromosomes (n) After 1 division - 23 double stranded chromosomes (n) After 2nd division - 23 single stranded chromosomes (n) After 2nd division - 23 single stranded chromosomes (n) Occurs in our germ cells that produce gametes More Meiosis Facts copyright cmassengale

70. 70 Why Do we Need Meiosis? It is the fundamental basis of sexual reproduction It is the fundamental basis of sexual reproduction Two haploid (1n) gametes are brought together through fertilization to form a diploid (2n) zygote Two haploid (1n) gametes are brought together through fertilization to form a diploid (2n) zygote copyright cmassengale

71. 71 Fertilization – “Putting it all together” 1n =3 2n = 6 copyright cmassengale

72. 72 Replication of Chromosomes Replication is the process of duplicating a chromosome Replication is the process of duplicating a chromosome Occurs prior to division Occurs prior to division Replicated copies are called sister chromatids Replicated copies are called sister chromatids Held together at centromere Held together at centromere Occurs in Interphase copyright cmassengale

73. 73 A Replicated Chromosome Homologs Homologs (same genes, different alleles) (same genes, different alleles) Sister Chromatids (same genes, same alleles) Gene X Homologs separate in meiosis I and therefore different alleles separate. copyright cmassengale

74. 74 Meiosis Forms Haploid Gametes Meiosis must reduce the chromosome number by half Meiosis must reduce the chromosome number by half Fertilization then restores the 2n number Fertilization then restores the 2n number from momfrom dadchild meiosis reduces genetic content too much! The right number! copyright cmassengale

75. 75 Meiosis: Two Part Cell Division Homologsseparate Sisterchromatidsseparate Diploid Meiosis I Meiosis II Diploid Haploid copyright cmassengale

76. 76 Meiosis I: Reduction Division Nucleus Spindlefibers Nuclearenvelope Early Prophase I (Chromosome number doubled) Late Prophase I Metaphase I Anaphase I Telophase I (diploid) copyright cmassengale

77. 77 Prophase I Early prophase Homologs pair. Homologs pair. Crossing over occurs Crossing over occurs. Late prophase Chromosomes condense. Chromosomes condense. Spindle forms. Spindle forms. Nuclear envelope fragments. Nuclear envelope fragments. copyright cmassengale

78. 78 Tetrads Form in Prophase I Homologous chromosomes (each with sister chromatids) Homologous chromosomes (each with sister chromatids) Join to form a TETRAD Called Synapsis copyright cmassengale

79. 79 Crossing-Over Homologous chromosomes in a tetrad cross over each other Homologous chromosomes in a tetrad cross over each other Pieces of chromosomes or genes are exchanged Pieces of chromosomes or genes are exchanged Produces Genetic recombination in the offspring Produces Genetic recombination in the offspring copyright cmassengale

80. 80 Homologous Chromosomes During Crossing-Over copyright cmassengale

81. 81 Crossing-over multiplies the already huge number of different gamete types produced by independent assortment Crossing-Over copyright cmassengale

82. 82 Metaphase I Homologous pairs of chromosomes align along the equator of the cell copyright cmassengale

83. 83 Anaphase I Homologs separate and move to opposite poles. Sister chromatids remain attached at their centromeres attached at their centromeres. copyright cmassengale

84. 84 Telophase I Nuclear envelopes reassemble. Spindle disappears. Cytokinesis divides cell into two. copyright cmassengale

85. 85 Meiosis II Only one homolog of each chromosome is present in the cell Only one homolog of each chromosome is present in the cell. Meiosis II produces gametes with one copy of each chromosome and thus one copy of each gene. Sister chromatids carry identical genetic information. Gene X copyright cmassengale

86. 86 Meiosis II: Reducing Chromosome Number Prophase II Metaphase II Anaphase II Telophase II 4 Genetically Different haploid cells copyright cmassengale

87. 87 Prophase II Nuclear envelope fragments. Spindle forms. copyright cmassengale

88. 88 Metaphase II Chromosomes align along equator of cell. copyright cmassengale

89. 89 Anaphase II Sister chromatids separate and move to opposite poles Sister chromatids separate and move to opposite poles. Equator Pole copyright cmassengale

90. 90 Telophase II Nuclear envelope assembles. Chromosomes decondense. Spindle disappears. Cytokinesis divides cell into two. copyright cmassengale

91. 91 Results of Meiosis Gametes (egg & sperm) form Four haploid cells with one copy of each chromosome One allele of each gene Different combinations of alleles for different genes along the chromosome copyright cmassengale

92. 92 Meiosis Animation copyright cmassengale

93. 93 Gametogenesis Oogenesis or Spermatogenesis copyright cmassengale

94. 94 Spermatogenesis Occurs in the testes Occurs in the testes Two divisions produce 4 spermatids Two divisions produce 4 spermatids Spermatids mature into sperm Spermatids mature into sperm Men produce about 250,000,000 sperm per day Men produce about 250,000,000 sperm per day copyright cmassengale

95. 95 Spermatogenesis in the Testes Spermatid copyright cmassengale

96. 96Spermatogenesis copyright cmassengale

97. 97 Oogenesis Occurs in the ovaries Occurs in the ovaries Two divisions produce 3 polar bodies that die and 1 egg Two divisions produce 3 polar bodies that die and 1 egg Polar bodies die because of unequal division of cytoplasm Polar bodies die because of unequal division of cytoplasm Immature egg called oocyte Immature egg called oocyte Starting at puberty, one oocyte matures into an ovum (egg) every 28 days Starting at puberty, one oocyte matures into an ovum (egg) every 28 days copyright cmassengale

98. 98 Oogenesis in the Ovaries copyright cmassengale

99. 99 Oogenesis Oogonium(diploid) Mitosis Primaryoocyte(diploid) Meiosis I Secondaryoocyte(haploid) Meiosis II (if fertilization occurs) First polar body may divide (haploid)Polarbodiesdie Ovum (egg) Second polar body (haploid) a A X X a X A X a X a X Matureegg A X A X copyright cmassengale

100. 100 Comparing Mitosis and Meiosis copyright cmassengale

101. 101 MitosisMeiosis Number of divisions 12 Number of daughter cells 24 Genetically identical? YesNo Chromosome # Same as parent Half of parent Where Somatic cells Germ cells When Throughout life At sexual maturity Role Growth and repair Sexual reproduction Comparison of Divisions copyright cmassengale

102. 102copyright cmassengale