1. Variations on a Theme
Living organisms are distinguished by their ability to reproduce their own kind
Genetics is the scientific study of heredity and variation
Heredity is the transmission of traits from one generation to the next
Variation is demonstrated by the differences in appearance that offspring show from parents and siblings

2. Figure 13.1 What accounts for family resemblance?

3. Inheritance of Genes
Genes are the units of heredity, and are made up of segments of DNA
Genes are passed to the next generation through reproductive cells called gametes (sperm and eggs)
Each gene has a specific location called a locus on a certain chromosome
Most DNA is packaged into chromosomes
One set of chromosomes is inherited from each parent

4. Comparison of Asexual and Sexual Reproduction
In asexual reproduction, one parent produces genetically identical offspring by mitosis
A clone is a group of genetically identical individuals from the same parent
In sexual reproduction, two parents give rise to offspring that have unique combinations of genes inherited from the two parents

5. 0.5 mm Parent Bud (a) Hydra (b) Redwoods
Figure 13.2 Asexual reproduction in two multicellular organisms
Parent
Bud
(a) Hydra
(b) Redwoods

6. Fertilization and meiosis alternate in sexual life cycles
A life cycle is the generation-to-generation sequence of stages in the reproductive history of an organism

7. Sets of Chromosomes in Human Cells
Human somatic cells (any cell other than a gamete) have 23 pairs of chromosomes
A karyotype is an ordered display of the pairs of chromosomes from a cell
The two chromosomes in each pair are called homologous chromosomes, or homologs
Chromosomes in a homologous pair are the same length and carry genes controlling the same inherited characters

8. APPLICATION
Figure 13.3 Preparing a karyotype

9. TECHNIQUE 5 µm Pair of homologous replicated chromosomes Centromere
Figure 13.3 Preparing a karyotype
Sister
chromatids
Metaphase
chromosome

10. The sex chromosomes are called X and Y
Human females have a homologous pair of X chromosomes (XX)
Human males have one X and one Y chromosome
The 22 pairs of chromosomes that do not determine sex are called autosomes

11. Each pair of homologous chromosomes includes one chromosome from each parent
The 46 chromosomes in a human somatic cell are two sets of 23: one from the mother and one from the father
A diploid cell (2n) has two sets of chromosomes
For humans, the diploid number is 46 (2n = 46)

12. Key Maternal set of chromosomes (n = 3) 2n = 6 Paternal set of
Two sister chromatids
of one replicated
chromosome
Figure 13.4 Describing chromosomes
Centromere
Two nonsister
chromatids in
a homologous pair
Pair of homologous
chromosomes
(one from each set)

13. A gamete (sperm or egg) contains a single set of chromosomes, and is haploid (n)
For humans, the haploid number is 23 (n = 23)
Each set of 23 consists of 22 autosomes and a single sex chromosome
In an unfertilized egg (ovum), the sex chromosome is X
In a sperm cell, the sex chromosome may be either X or Y

14. Behavior of Chromosome Sets in the Human Life Cycle
Fertilization is the union of gametes (the sperm and the egg)
The fertilized egg is called a zygote and has one set of chromosomes from each parent
The zygote produces somatic cells by mitosis and develops into an adult

15. At sexual maturity, the ovaries and testes produce haploid gametes
Gametes are the only types of human cells produced by meiosis, rather than mitosis
Meiosis results in one set of chromosomes in each gamete
Fertilization and meiosis alternate in sexual life cycles to maintain chromosome number

16. Multicellular diploid adults (2n = 46)
Key
Haploid gametes (n = 23)
Haploid (n)
Egg (n)
Diploid (2n)
Sperm (n)
MEIOSIS
FERTILIZATION
Figure 13.5 The human life cycle
Ovary
Testis
Diploid
zygote
(2n = 46)
Mitosis and
development
Multicellular diploid
adults (2n = 46)

17. The Variety of Sexual Life Cycles
The alternation of meiosis and fertilization is common to all organisms that reproduce sexually
The three main types of sexual life cycles differ in the timing of meiosis and fertilization

18. In animals, meiosis produces gametes, which undergo no further cell division before fertilization
Gametes are the only haploid cells in animals
Gametes fuse to form a diploid zygote that divides by mitosis to develop into a multicellular organism

19. Figure 13.6 Three types of sexual life cycles
Key
Haploid (n)
Haploid unicellular or
multicellular organism
Diploid (2n)
Haploid multi-
cellular organism
(gametophyte) n
Gametes n n
Mitosis n
Mitosis
Mitosis n
Mitosis n n n n n
MEIOSIS
FERTILIZATION
Spores n
Figure 13.6 Three types of sexual life cycles
Gametes n
Gametes n
MEIOSIS
FERTILIZATION
Zygote
MEIOSIS
FERTILIZATION 2n 2n 2n 2n
Diploid
multicellular
organism
Zygote
Diploid
multicellular
organism
(sporophyte) 2n
Mitosis
Mitosis
Zygote
(a) Animals
(b) Plants and some algae
(c) Most fungi and some protists

20. Key Haploid (n) Diploid (2n) Gametes n n n MEIOSIS FERTILIZATION
Figure 13.6a Three types of sexual life cycles—animals
Zygote 2n 2n
Diploid
multicellular
organism
Mitosis
(a) Animals

21. Plants and some algae exhibit an alternation of generations
This life cycle includes both a diploid and haploid multicellular stage
The diploid organism, called the sporophyte, makes haploid spores by meiosis

22. Each spore grows by mitosis into a haploid organism called a gametophyte
A gametophyte makes haploid gametes by mitosis
Fertilization of gametes results in a diploid sporophyte

23. (b) Plants and some algae
Key
Haploid (n)
Haploid multi-
cellular organism
(gametophyte)
Diploid (2n)
Mitosis
Mitosis n n n n n
Spores
Gametes
Figure 13.6b Three types of sexual life cycles—plants and some algae
MEIOSIS
FERTILIZATION 2n 2n
Zygote
Diploid
multicellular
organism
(sporophyte)
Mitosis
(b) Plants and some algae

24. In most fungi and some protists, the only diploid stage is the single-celled zygote; there is no multicellular diploid stage
The zygote produces haploid cells by meiosis
Each haploid cell grows by mitosis into a haploid multicellular organism
The haploid adult produces gametes by mitosis

25. Haploid unicellular or multicellular organism Diploid (2n)
Key
Haploid (n)
Haploid unicellular or
multicellular organism
Diploid (2n)
Mitosis
Mitosis n n n n
Figure 13.6c Three types of sexual life cycles—most fungi and some protists
Gametes n
MEIOSIS
FERTILIZATION 2n
Zygote
(c) Most fungi and some protists

26. Depending on the type of life cycle, either haploid or diploid cells can divide by mitosis
However, only diploid cells can undergo meiosis
In all three life cycles, the halving and doubling of chromosomes contributes to genetic variation in offspring

27. Meiosis reduces the number of chromosome sets from diploid to haploid
Like mitosis, meiosis is preceded by the replication of chromosomes
Meiosis takes place in two sets of cell divisions, called meiosis I and meiosis II
The two cell divisions result in four daughter cells, rather than the two daughter cells in mitosis
Each daughter cell has only half as many chromosomes as the parent cell

28. The Stages of Meiosis
In the first cell division (meiosis I), homologous chromosomes separate
Meiosis I results in two haploid daughter cells with replicated chromosomes; it is called the reductional division
In the second cell division (meiosis II), sister chromatids separate
Meiosis II results in four haploid daughter cells with unreplicated chromosomes; it is called the equational division

29. Figure 13.7 Overview of meiosis: how meiosis reduces chromosome number
Interphase
Homologous pair of chromosomes
in diploid parent cell
Chromosomes
replicate
Homologous pair of replicated chromosomes
Sister
chromatids
Diploid cell with
replicated
chromosomes
Figure 13.7 Overview of meiosis: how meiosis reduces chromosome number
Meiosis I 1
Homologous
chromosomes
separate
Haploid cells with
replicated chromosomes
Meiosis II 2
Sister chromatids
separate
Haploid cells with unreplicated chromosomes

30. The single centrosome replicates, forming two centrosomes
Meiosis I is preceded by interphase, in which chromosomes are replicated to form sister chromatids
The sister chromatids are genetically identical and joined at the centromere
The single centrosome replicates, forming two centrosomes
For the Cell Biology Video Meiosis I in Sperm Formation, go to Animation and Video Files.

31. Prophase I Metaphase I Anaphase I Centrosome (with centriole pair)
Telophase I and
Cytokinesis
Prophase I
Metaphase I
Anaphase I
Centrosome
(with centriole pair)
Sister chromatids
remain attached
Centromere
(with kinetochore)
Sister
chromatids
Chiasmata
Spindle
Metaphase
plate
Figure 13.8 The meiotic division of an animal cell
Cleavage
furrow
Homologous
chromosomes
Homologous
chromosomes
separate
Fragments
of nuclear
envelope
Microtubule
attached to
kinetochore

32. Prophase I
Prophase I typically occupies more than 90% of the time required for meiosis
Chromosomes begin to condense
In synapsis, homologous chromosomes loosely pair up, aligned gene by gene

33. In crossing over, nonsister chromatids exchange DNA segments
Each pair of chromosomes forms a tetrad, a group of four chromatids
Each tetrad usually has one or more chiasmata, X-shaped regions where crossing over occurred

34. Metaphase I
In metaphase I, tetrads line up at the metaphase plate, with one chromosome facing each pole
Microtubules from one pole are attached to the kinetochore of one chromosome of each tetrad
Microtubules from the other pole are attached to the kinetochore of the other chromosome

35. Prophase I Metaphase I Centrosome (with centriole pair) Centromere
(with kinetochore)
Sister
chromatids
Chiasmata
Spindle
Metaphase
plate
Figure 13.8 The meiotic division of an animal cell
Homologous
chromosomes
Fragments
of nuclear
envelope
Microtubule
attached to
kinetochore

36. Anaphase I
In anaphase I, pairs of homologous chromosomes separate
One chromosome moves toward each pole, guided by the spindle apparatus
Sister chromatids remain attached at the centromere and move as one unit toward the pole

37. Telophase I and Cytokinesis
In the beginning of telophase I, each half of the cell has a haploid set of chromosomes; each chromosome still consists of two sister chromatids
Cytokinesis usually occurs simultaneously, forming two haploid daughter cells

38. In animal cells, a cleavage furrow forms; in plant cells, a cell plate forms
NO chromosome replication occurs between the end of meiosis I and the beginning of meiosis II because the chromosomes are already replicated

39. Telophase I and Cytokinesis
Anaphase I
Sister chromatids
remain attached
Figure 13.8 The meiotic division of an animal cell
Homologous
chromosomes
separate
Cleavage
furrow

40. Division in meiosis II also occurs in four phases:
– Prophase II
– Metaphase II
– Anaphase II
– Telophase II and cytokinesis
Meiosis II is very similar to mitosis

41. Telophase II and Cytokinesis
Prophase II
Metaphase II
Anaphase II
Figure 13.8 The meiotic division of an animal cell
Sister chromatids
separate
Haploid daughter cells
forming

42. Metaphase II
In metaphase II, the sister chromatids are arranged at the metaphase plate
Because of crossing over in meiosis I, the two sister chromatids of each chromosome are no longer genetically identical
The kinetochores of sister chromatids attach to microtubules extending from opposite poles

43. Prophase II Metaphase II
Figure 13.8 The meiotic division of an animal cell

44. Anaphase II
In anaphase II, the sister chromatids separate
The sister chromatids of each chromosome now move as two newly individual chromosomes toward opposite poles

45. Telophase II and Cytokinesis
In telophase II, the chromosomes arrive at opposite poles
Nuclei form, and the chromosomes begin decondensing

46. Cytokinesis separates the cytoplasm
At the end of meiosis, there are four daughter cells, each with a haploid set of unreplicated chromosomes
Each daughter cell is genetically distinct from the others and from the parent cell

47. Telephase II and Cytokinesis
Anaphase II
Figure 13.8 The meiotic division of an animal cell
Sister chromatids
separate
Haploid daughter cells
forming

48. A Comparison of Mitosis and Meiosis
Mitosis conserves the number of chromosome sets, producing cells that are genetically identical to the parent cell
Meiosis reduces the number of chromosomes sets from two (diploid) to one (haploid), producing cells that differ genetically from each other and from the parent cell
The mechanism for separating sister chromatids is virtually identical in meiosis II and mitosis

49. Replicated chromosome
MITOSIS
MEIOSIS
MEIOSIS I
Parent cell
Chiasma
Chromosome
replication
Chromosome
replication
Prophase
Prophase I
Homologous
chromosome
pair
2n = 6
Replicated chromosome
Metaphase
Metaphase I
Figure 13.9 A comparison of mitosis and meiosis in diploid cells
Anaphase
Telophase
Anaphase I
Telophase I
Haploid
n = 3
Daughter
cells of
meiosis I 2n 2n
MEIOSIS II
Daughter cells
of mitosis n n n n
Daughter cells of meiosis II

50. Figure 13.9 A comparison of mitosis and meiosis in diploid cells
SUMMARY
Property
Mitosis
Meiosis
DNA
replication
Occurs during interphase before
mitosis begins
Occurs during interphase before meiosis I begins
Number of
divisions
One, including prophase, metaphase,
anaphase, and telophase
Two, each including prophase, metaphase, anaphase, and
telophase
Synapsis of
homologous
chromosomes
Figure 13.9 A comparison of mitosis and meiosis in diploid cells
Does not occur
Occurs during prophase I along with crossing over
between nonsister chromatids; resulting chiasmata
hold pairs together due to sister chromatid cohesion
Number of
daughter cells
and genetic
composition
Two, each diploid (2n) and genetically
identical to the parent cell
Four, each haploid (n), containing half as many chromosomes
as the parent cell; genetically different from the parent
cell and from each other
Role in the
animal body
Enables multicellular adult to arise from
zygote; produces cells for growth, repair,
and, in some species, asexual reproduction
Produces gametes; reduces number of chromosomes by half
and introduces genetic variability among the gametes

51. Three events are unique to meiosis, and all three occur in meiosis l:
– Synapsis and crossing over in prophase I: Homologous chromosomes physically connect and exchange genetic information
– At the metaphase plate, there are paired homologous chromosomes (tetrads), instead of individual replicated chromosomes
– At anaphase I, it is homologous chromosomes, instead of sister chromatids, that separate

52. Sister chromatid cohesion allows sister chromatids of a single chromosome to stay together through meiosis I
Protein complexes called cohesins are responsible for this cohesion
In mitosis, cohesins are cleaved at the end of metaphase
In meiosis, cohesins are cleaved along the chromosome arms in anaphase I (separation of homologs) and at the centromeres in anaphase II (separation of sister chromatids)

53. Genetic variation produced in sexual life cycles contributes to evolution
Mutations (changes in an organism’s DNA) are the original source of genetic diversity
Mutations create different versions of genes called alleles
Reshuffling of alleles during sexual reproduction produces genetic variation

54. Origins of Genetic Variation Among Offspring
The behavior of chromosomes during meiosis and fertilization is responsible for most of the variation that arises in each generation
Three mechanisms contribute to genetic variation:
Independent assortment of chromosomes
Crossing over
Random fertilization

55. Independent Assortment of Chromosomes
Homologous pairs of chromosomes orient randomly at metaphase I of meiosis
In independent assortment, each pair of chromosomes sorts maternal and paternal homologues into daughter cells independently of the other pairs

56. The number of combinations possible when chromosomes assort independently into gametes is 2n, where n is the haploid number
For humans (n = 23), there are more than million (223) possible combinations of chromosomes

57. Possibility 1 Possibility 2 Two equally probable arrangements of
chromosomes at
metaphase I
Figure The independent assortment of homologous chromosomes in meiosis
Metaphase II
Daughter
cells
Combination 1
Combination 2
Combination 3
Combination 4

58. Crossing Over
Crossing over produces recombinant chromosomes, which combine genes inherited from each parent
Crossing over begins very early in prophase I, as homologous chromosomes pair up gene by gene

59. In crossing over, homologous portions of two nonsister chromatids trade places
Crossing over contributes to genetic variation by combining DNA from two parents into a single chromosome

60. Recombinant chromosomes
Prophase I
of meiosis
Nonsister
chromatids
held together
during synapsis
Pair of
homologs
Chiasma
Centromere
TEM
Figure The results of crossing over during meiosis
Anaphase I
Anaphase II
Daughter
cells
Recombinant chromosomes

61. Random Fertilization
Random fertilization adds to genetic variation because any sperm can fuse with any ovum (unfertilized egg)
The fusion of two gametes (each with 8.4 million possible chromosome combinations from independent assortment) produces a zygote with any of about 70 trillion diploid combinations

62. The Evolutionary Significance of Genetic Variation Within Populations
Natural selection results in the accumulation of genetic variations favored by the environment
Sexual reproduction contributes to the genetic variation in a population, which originates from mutations
Crossing over adds even more variation
Each zygote has a unique genetic identity

64. Animations and Videos Meiosis Tutorial Meiosis - 1 Meiosis - 2
Stages of Meiosis
Anaphase Separase
Spermatogenesis
Production of Male and Female Gametes
Polar Body Formation

65. Animations and Videos Random Orientation of Chromosomes During Meiosis
Independent Assortment
Independent Assortment and Gamete Diversity
Alleles That Do Not Assort Independently
Comparison of Mitosis and Meiosis
Bozeman - Diploid vs. Haploid Cells
Activity- Mitosis and Meiosis
Bozeman - Mitosis and Meiosis Simulation

66. Animations and Videos Meiosis - Nondisjunction – 1
Crossing Over
Changes in Chromosome Structure
The Consequence of Inversion
Bozeman - Cell Cycle (Mitosis and Meiosis)
X Inactivation
Bozeman - X Inactivation

67. Animations and Videos Density-Dependent Inhibition
Cytotoxic T Lymphocytes Attack a Melanoma Cell
Metastasis of a Cancer
Amniocentesis Animation
Chorionic Villus Sampling
Karyotype Animation
Human Melanoma Cells Dividing
Chapter Quiz Questions – 1
Chapter Quiz Questions – 2

68. Which of the following transmits genes from both parents to child, or from one generation of a family to another?
DNA
gametes
somatic cells
mitosis
nucleotides
Answer: B

69. Which of the following transmits genes from both parents to child, or from one generation of a family to another?
DNA
gametes
somatic cells
mitosis
nucleotides 69

70. Fertilization is to zygote as meiosis is to which of the following?
mitosis
diploid
chromosome
replication
gamete
Answer: E 70

71. Fertilization is to zygote as meiosis is to which of the following?
mitosis
diploid
chromosome
replication
gamete 71

72. Privet shrubs and humans each have a diploid number of 46 chromosomes per cell. Why are the two species so dissimilar?
Privet chromosomes undergo only mitosis.
Privet chromosomes are shaped differently.
Human chromosomes have genes grouped together differently.
The two species have appreciably different genes.
Privets do not have sex chromosomes.
Answer: D 72

73. Privet shrubs and humans each have a diploid number of 46 chromosomes per cell. Why are the two species so dissimilar?
Privet chromosomes undergo only mitosis.
Privet chromosomes are shaped differently.
Human chromosomes have genes grouped together differently.
The two species have appreciably different genes.
Privets do not have sex chromosomes. 73

74. Why is it more practical to prepare karyotypes by viewing somatic diploid cells rather than haploid gametes?
Somatic diploid cells do not contain organelles to interfere with karyotyping.
Both sets of chromosomes, which are present in somatic diploid cells, need to be examined.
DNA in haploid gametes will not stain.
The chromosomes are larger in a somatic diploid cell.
Haploid gametes do not have sex chromosomes.
Answer: B 74

75. Why is it more practical to prepare karyotypes by viewing somatic diploid cells rather than haploid gametes?
Somatic diploid cells do not contain organelles to interfere with karyotyping.
Both sets of chromosomes, which are present in somatic diploid cells, need to be examined.
DNA in haploid gametes will not stain.
The chromosomes are larger in a somatic diploid cell.
Haploid gametes do not have sex chromosomes. 75

76. Diploid cells may undergo either mitosis or meiosis
Diploid cells may undergo either mitosis or meiosis. Haploid cells may undergo mitosis (for certain species) but not meiosis because
the sister chromatids cannot separate.
the synaptonemal complex is too strong.
crossing over has occurred.
cohesins are no longer present.
homologous chromosomes cannot pair.
Answer: E 76

77. Diploid cells may undergo either mitosis or meiosis
Diploid cells may undergo either mitosis or meiosis. Haploid cells may undergo mitosis (for certain species) but not meiosis because
the sister chromatids cannot separate.
the synaptonemal complex is too strong.
crossing over has occurred.
cohesins are no longer present.
homologous chromosomes cannot pair.
Answer: E 77

78. How and at what stage do chromosomes undergo independent assortment?
meiosis I pairing of homologs
anaphase I separation of homologs
meiosis II separation of homologs
meiosis I metaphase alignment
meiosis I telophase separation
Answer: D 78

79. How and at what stage do chromosomes undergo independent assortment?
meiosis I pairing of homologs
anaphase I separation of homologs
meiosis II separation of homologs
meiosis I metaphase alignment
meiosis I telophase separation 79

80. What allows sister chromatids to separate in which phase of meiosis?
release of cohesin along sister chromatid arms in anaphase I
crossing over of chromatids in prophase I
release of cohesin at centromeres in anaphase I
release of cohesin at centromeres in anaphase II
crossing over of homologs in prophase I
Answer: D 80

81. What allows sister chromatids to separate in which phase of meiosis?
release of cohesin along sister chromatid arms in anaphase I
crossing over of chromatids in prophase I
release of cohesin at centromeres in anaphase I
release of cohesin at centromeres in anaphase II
crossing over of homologs in prophase I 81

82. Gametes produced from one meiotic event
are genetically identical to each other.
each have the same chromosome number.
are genetically identical to the cells produced from meiosis I.
are genetically identical to the parent cell.
each have the same mutations.
Answer: B 82

83. Gametes produced from one meiotic event
are genetically identical to each other.
each have the same chromosome number.
are genetically identical to the cells produced from meiosis I.
are genetically identical to the parent cell.
each have the same mutations. 83

84. Crossing over begins to occur during
anaphase I
anaphase II
prophase I
metaphase II
telophase II
Answer: C 84

85. Crossing over begins to occur during
anaphase I
anaphase II
prophase I
metaphase II
telophase II
Answer: C 85

86. In this cell, what phase is represented?
mitotic metaphase
meiosis I anaphase
meiosis I metaphase
meiosis II anaphase
meiosis II metaphase
Answer: C 86

87. In this cell, what phase is represented?
mitotic metaphase
meiosis I anaphase
meiosis I metaphase
meiosis II anaphase
meiosis II metaphase 87

88. Scientific Skills Exercise
When nutrients are low, cells of the budding yeast (Saccharomyces cerevisiae) exit the mitotic cell cycle and enter meiosis. In this exercise, you will track the DNA content of a population of yeast cells as they progress through meiosis.
Researchers grew a culture of yeast cells in a nutrient-rich medium and then transferred them to a nutrient-poor medium to induce meiosis. At different times after induction, the DNA content per cell was measured in a sample of the cells, and the average DNA content per cell was recorded in femtograms (fg; 1 femtogram  1 × 10–15 gram). Their data are shown in the table to the right.

89. Most of the yeast cells in the culture were in G1 of the cell cycle before being moved to the nutrient-poor medium to induce meiosis. How many femtograms of DNA are there in a yeast cell in G1? Estimate this value from the data in the table.
12 fg
24 fg
40 fg
48 fg
Answer: B

90. Most of the yeast cells in the culture were in G1 of the cell cycle before being moved to the nutrient-poor medium to induce meiosis. How many femtograms of DNA are there in a yeast cell in G1? Estimate this value from the data in the table.
12 fg
24 fg
40 fg
48 fg
Answer: B

91. How many femtograms of DNA are present in a cell in G2?
12 fg
24 fg
40 fg
48 fg
Answer: D

92. How many femtograms of DNA are present in a cell in G2?
12 fg
24 fg
40 fg
48 fg
Answer: D

93. How many femtograms of DNA are present in a cell at the end of meiosis I?
12 fg
24 fg
40 fg
48 fg
Answer: B

94. How many femtograms of DNA are present in a cell at the end of meiosis I?
12 fg
24 fg
40 fg
48 fg

95. How many femtograms of DNA are present in a cell at the end of meiosis II?
12 fg
24 fg
40 fg
48 fg
Answer: A

96. How many femtograms of DNA are present in a cell at the end of meiosis II?
12 fg
24 fg
40 fg
48 fg
Answer: A

97. A graph with labels indicating the different phases of the meiotic cell cycle (MI  meiosis I; MII  meiosis II) is shown to the right, based on the data from the table. Think carefully about the point on the graph where the line at the highest value begins to slope downward, indicated by the red arrow. What specific point of meiosis does this “corner” represent?
Answer: C
metaphase I
prophase II
cytokinesis
anaphase I

98. A graph with labels indicating the different phases of the meiotic cell cycle (MI  meiosis I; MII  meiosis II) is shown to the right, based on the data from the table. Think carefully about the point on the graph where the line at the highest value begins to slope downward, indicated by the red arrow. What specific point of meiosis does this “corner” represent?
metaphase I
prophase II
cytokinesis
anaphase I

99. Based on this data, how much DNA is present in a gamete of Saccharomyces cerevisiae?
12 fg
24 fg
48 fg
Answer: A

100. Based on this data, how much DNA is present in a gamete of Saccharomyces cerevisiae?
12 fg
24 fg
48 fg

101. 0.08 Mb (8.0  104 base pairs) 1.2 Mb (1.2  106 base pairs)
Given the fact that 1 fg of DNA  9.78  105 base pairs (on average), you can convert the amount of DNA per cell to the length of DNA in numbers of base pairs. Millions of base pairs (Mb) is the standard unit for expressing genome size. Calculate the approximate number of base pairs of DNA in the haploid yeast genome.
Answer: C
0.08 Mb (8.0  104 base pairs)
1.2 Mb (1.2  106 base pairs)
12 Mb (12  106 base pairs)
23 Mb (23  106 base pairs)

102. 0.08 Mb (8.0  104 base pairs) 1.2 Mb (1.2  106 base pairs)
Given the fact that 1 fg of DNA  9.78  105 base pairs (on average), you can convert the amount of DNA per cell to the length of DNA in numbers of base pairs. Millions of base pairs (Mb) is the standard unit for expressing genome size. Calculate the approximate number of base pairs of DNA in the haploid yeast genome.
0.08 Mb (8.0  104 base pairs)
1.2 Mb (1.2  106 base pairs)
12 Mb (12  106 base pairs)
23 Mb (23  106 base pairs)

103. Given the fact that 1 fg of DNA  9
Given the fact that 1 fg of DNA  9.78  105 base pairs (on average), you can estimate the rate of DNA synthesis in Saccharomyces cerevisiae. Approximately how many base pairs per minute were synthesized during the S phase of these yeast cells?
0.19 (1.9  10–1) base pair per minute
100,000 (1.0  105) base pairs per minute
200,000 (2.0  105) base pairs per minute
11,000,000 (11.0  106) base pairs per minute
Answer: C
Because the S phase took place from approximately the 1-hour mark to the 3-hour mark, start by finding the difference between the amount of DNA at 3 hours and the amount at 1 hour: 47.0 fg – 24.0 fg = 23.0 fg. Now calculate the rate of fg synthesized per minute by dividing that amount by the number of minutes in two hours: 23.0 fg/ 120 minutes = fg/min. Finally, you need to convert from fg/min to base pairs/min: fg/min × (9.78 × 105 base pairs/fg) = 187,800, or approximately 200,000 base pairs/min.

104. Given the fact that 1 fg of DNA  9
Given the fact that 1 fg of DNA  9.78  105 base pairs (on average), you can estimate the rate of DNA synthesis in Saccharomyces cerevisiae. Approximately how many base pairs per minute were synthesized during the S phase of these yeast cells?
0.19 (1.9  10–1) base pair per minute
100,000 (1.0  105) base pairs per minute
200,000 (2.0  105) base pairs per minute
11,000,000 (11.0  106) base pairs per minute
Answer: C
Because the S phase took place from approximately the 1-hour mark to the 3-hour mark, start by finding the difference between the amount of DNA at 3 hours and the amount at 1 hour: 47.0 fg – 24.0 fg = 23.0 fg. Now calculate the rate of fg synthesized per minute by dividing that amount by the number of minutes in two hours: 23.0 fg/ 120 minutes = fg/min. Finally, you need to convert from fg/min to base pairs/min: fg/min × (9.78 × 105 base pairs/fg) = 187,800, or approximately 200,000 base pairs/min.