1. The Cellular Basis of Reproduction and Inheritance
Chapter 8
The Cellular Basis of Reproduction and Inheritance

2. CONNECTIONS BETWEEN CELL DIVISION AND REPRODUCTION
Organisms can reproduce sexually or asexually
Reproduction
Sexual reproduction : the reproduction process that involves the union of a sperm and an egg
Asexual reproduction : the production of offsprings by a single parent without the participation of sperm and egg

3. 8.1 Cell division plays many important roles in the lives of organisms
Some organisms make exact copies of themselves, asexual reproduction

4. Other organisms make similar copies of themselves in a more complex process, sexual reproduction
Adults
Sperm Egg
fertilization
Zygote (fertilized egg)
development
Offspring

5. 8.2 Cells arise only from preexisting cells
All cells come from cells
Cellular reproduction is called cell division
Cell division allows an embryo to develop into an adult
It also ensures the continuity of life from one generation to the next

6. 8.3 Prokaryotes reproduce by binary fission
Prokaryotic cells (bacteria, archaea) divide asexually
These cells possess a single chromosome, containing genes
The chromosome is replicated
The cell then divides into two cells, a process called binary fission
Prokaryotic chromosomes
Figure 8.3B

7. Binary fission of a prokaryotic cell
chromosome
Plasma
membrane
Cell wall
Duplication of chromosome
and separation of copies
Continued elongation of the
cell and movement of copies
Division into
two daughter cells

8. Figure 11-8
STEPS IN BACTERIAL CELL DIVISION
1. Chromosome
is located mid-
cell.
2. Chromosome
replicates.
3. Chromosomes
pull apart; ring
of FtsZ protein
forms.
4. FtsZ ring
constricts.
Membrane
and cell wall
infold.
5. Fission
complete.

9. THE EUKARYOTIC CELL CYCLE AND MITOSIS
Eukaryotic cells have multiple chromosomes, while prokaryotic cells have usually one chromosome
A chromosome consists of one molecule of DNA and a number of proteins
The eukaryotic chromosome consists of a linear DNA, while prokaryotic one consists of a circular DNA
The number of chromosomes in a eukaryotic cell depends on the species

10. Chromatin
Chromosome

12. Chromosomes contain a very long DNA molecule with thousands of genes
Individual chromosomes are only visible during cell division
They are packaged as chromatin

13. Before a cell starts dividing, the chromosomes are duplicated
Sister chromatids
This process produces sister chromatids
Centromere
Figure 8.4B

14. When the cell divides, the sister chromatids separate
Two daughter cells are produced
Each has a complete and identical set of chromosomes

15. Chromosomes DNA molecules Sister chromatids Chromosome duplication
Figure 8.3B
Chromosomes
DNA molecules
Sister
chromatids
Chromosome
duplication
Sister
chromatids
Centromere
Chromosome
distribution
to the
daughter
cells

16. 8.5 The cell cycle multiplies cells
The cell cycle consists of two major phases:
Interphase, where chromosomes duplicate and cell parts are made
The mitotic phase, when cell division occurs

17. 8.6 Cell division is a continuum of dynamic changes
Eukaryotic cell division consists of two stages:
Mitosis : one nucleus  two nuclei
Cytokinesis : the cytoplasm is divided into two
Mitosis
Cytokinesis

18. Mitosis : the equal division of one nucleus into two genetically identical daughter nuclei
Prophase
Metaphase
Anaphase
Telophase
Interphase (G1, S, G2 phases)
Chromosomal DNA is present as a form of chromatin
DNA duplication in S-phase

19. Prophase
Chromatin  chromosome structure
Nucleoli disappear
The nuclear envelope disappears
Formation of the mitotic spindle
Spindle microtubules attach to the kinetochores of chromosomes
compaction
At the centromere region, each sister chromatid has a protein structure called a “kinetochore”

20. MITOSIS
INTERPHASE
Prophase
Prometaphase
Centrosomes
(with centriole pairs)
Early mitotic
spindle
Fragments of
the nuclear envelope
Centrosome
Chromatin
Centrioles
Kinetochore
Nuclear
envelope
Plasma
membrane
Centromere
Chromosome,
consisting of two
sister chromatids
Spindle
microtubules

21. Metaphase
Arrangement of the chromosomes on the metaphase plate
Anaphase
Separation of the sister chromatids toward the poles
Telophase
Daughter nuclei reappear
Chromosome  chromatin
Nucleoli reappear
Mitotic spindles disappear
Cytokinesis와 telophase는 동시에 진행

22. MITOSIS
Metaphase
Anaphase
Telophase and Cytokinesis
Metaphase
plate
Cleavage
furrow
Mitotic
spindle
Nuclear
envelope
forming
Daughter
chromosomes

23. Microtubules –
Tubulin
subunits
Fibers
containing
motor
proteins + +
Chromosome
movement
Kinetochore
plates
Chromosome

24. 8.7 Cytokinesis differs for plant and animal cells
In animals, cytokinesis occurs by cleavage
This process pinches the cell apart
Cleavage
furrow
Cleavage
furrow
SEM 140
Cytokinesis occurs with telophase, although it may actually begin in late anaphase
Cleavage furrow
Contracting ring of
microfilaments
Daughter cells
Figure 8.7A

25. In plants, a membranous cell plate splits the cell in two
Cytokinesis
New
cell wall
Cell wall
of the
parent cell
Cell wall
Plasma
membrane
Daughter
nucleus
Vesicles
containing
cell wall
material
Cell plate
Daughter
cells
Cell plate
forming

26. Most animal cells divide only when stimulated, and others not at all
8.8 Anchorage, cell density, and chemical growth factors affect cell division
Most animal cells divide only when stimulated, and others not at all
In laboratory cultures, most normal cells divide only when attached to a surface
They are anchorage dependent
Most animal cells are normally anchored to an extracellular matrix or to other cells of the same tissue

27. Cells continue dividing until they touch one another
This is called density-dependent inhibition
Figure 8.8A

28. Cultured cells
suspended in liquid
The addition of
growth
factor

29. Anchorage
Single layer
of cells
Removal
of cells
Restoration
of single
layer by cell
division

30. 8.9 Growth factors signal the cell cycle control system
Proteins within the cell control the cell cycle
Signals affecting critical checkpoints determine whether the cell will go through a complete cycle and divide
Most important, in the middle of G1
G1 checkpoint
Control system
At the boundary of
meta- and anaphase
(at the G2-M boundary)
M checkpoint
G2 checkpoint

31. G2 checkpoint
Metaphase checkpoint
Pass this checkpoint if:
• chromosome replication
is successfully completed
• no DNA damage
• activated MPF present
Pass this checkpoint if:
• all chromosomes are
attached to mitotic spindle M
Mitosis G2
Second gap
First gap G1
DNA synthesis G0 S
Mature cells do not
pass this checkpoint
(they enter G0 state)
G1 checkpoint
Pass this checkpoint if:
• nutrients are sufficient
• growth factors (signals from other cells) are present
• cell size is adequate
• DNA is undamaged

32. Cyclin-dependent kinase
Cyclin concentration regulates MPF concentration. G1 S G2
M phase G1 S G2
M phase G1 S
MPF activated by
dephosphorylation
of MPF Cdk
MPF activated by
dephosphorylation
of MPF Cdk P P
MPF component concentration
MPF Cdk
Cdk2
Cyclin A
MPF Cyclin
Time
Activated MPF has an array of effects.
Cdk
Cyclin-dependent kinase
Phosphorylate chromosomal
proteins; initiate M phase
Activated MPF P
Phosphorylate nuclear
lamins; initiate nuclear
envelope breakdown
Cyclin
Cdk
Phosphorylate microtubule-
associated proteins. Activate
mitotic spindle?
Cyclin + Cdk with
dephosphorylated,
cyclin-dependent
kinase subunit P
Phosphorylate an enzyme
that degrades cyclin; cyclin
concentrations decline

34. The binding of growth factors to specific receptors on the plasma membrane is usually necessary for cell division
Figure 8.8B
Receptor
protein
Signal
transduction
pathway
Growth
factor
Relay proteins
Plasma membrane
EXTRACELLULAR FLUID
CYTOPLASM G1
checkpoint S M G2
Control
system

35. Growth factors stimulate cell cycling
e.g., Cells in your skin (arrested at G1 checkpoint)
When you got a cut in the skin
Platelets release platelet-derived growth factor
Cell division of skin cells at wound

36. Cancer cells have abnormal cell cycle control systems
8.10 Connection: Growing out of control, cancer cells produce malignant tumors
Cancer cells have abnormal cell cycle control systems
They divide excessively and can form abnormal masses called tumors
Radiation and chemotherapy are effective as cancer treatments because they interfere with cell division

37. Metastasis (전이): the spread of cells beyond their original site
Lymph
vessels
Blood
vessel
Tumor
Tumor in
another
part of
the body
Glandular
tissue
Growth
Invasion
Metastasis

38. Tumor : an abnormal mass of cells
Benign tumor : an abnormal mass of normal cells
Malignant tumor : an abnormal mass of cancer cells
Classification of cancers
Carcinoma : cancers derived from epithelial cells. E.g., skin cancer, cancers in lung, stomach, and other organs
Sarcoma : cancers arising from connective tissue (bone, muscle, cartilage, fat, nerve)
Lymphoma and leukemia : cancer arising from hematopoietic cells
Blastoma : cancers derived from immature precursor cells
Germ cell tumor

39. Cell cycle control system Function correctly Malfunction
Normal cell
Cancer cell
Cell cycle control system
Function correctly
Malfunction
Metastasis no
yes
Density-dependent inhibition of cell division
Anchorage dependence of cell division
The number of cell division
definitely
indefinitely

40. 8.11 Review of the functions of mitosis: Growth, cell replacement, and asexual reproduction
When the cell cycle operates normally, mitotic cell division functions in:
Growth (seen here in an onion root)

41. Cell replacement (seen here in skin)
Dead cells
Epidermis, the outer layer of the skin
Dividing cells
Dermis
Figure 8.11B

42. Asexual reproduction (seen here in a hydra)
Offspring  clone of its parent
Clones : genetically same organisms

43. Cell
Somatic cell (body cell) – diploid cell
Gamete (reproductive cell) – haploid cell

44. 8.12 Chromosomes are matched in homologous pairs
MEIOSIS AND CROSSING OVER
8.12 Chromosomes are matched in homologous pairs
Somatic cells of each species contain a specific number of chromosomes
Human cells have 46, making up 23 pairs of homologous chromosomes
Pair of homologous
chromosomes
Locus
Centromere
Sister
chromatids
One duplicated
chromosome

45. 8.13 Gametes have a single set of chromosomes
Cells with two sets of chromosomes are said to be diploid
Gametes are haploid, with only one set of chromosomes
e.g., Human diploid cell의 chromosome No.
2n (diploid number) = 46
Human haploid cell의 chromosome No.
n (haploid number) = 23

46. Chromosome
Autosome
Sex chromosome : XX female, XY male in mammals
e.g., 44 autosomes and 2 sex chromosomes in humans

47. At fertilization, a sperm fuses with an egg, forming a diploid zygote
The Human life cycle
At fertilization, a sperm fuses with an egg, forming a diploid zygote
Repeated mitotic divisions lead to the development of a mature adult
The adult makes haploid gametes by meiosis
Meiosis : the chromosome number is reduced to half (2nn)
Occur only in the reproductive organs (ovary, testis)

48. The human life cycle Haploid gametes (n  23) n Egg cell n Sperm cell
Meiosis
Fertilization
Ovary
Testis
Diploid
zygote
(2n  46) 2n
Key
Mitosis
Haploid stage (n)
Multicellular diploid
adults (2n  46)
Figure 8.13
Diploid stage (2n)

49. 8.14 Meiosis reduces the chromosome number from diploid to haploid
1 Diploid cell (2n) Haploid cells (n)
Interphase (S)meiosis Imeiosis II n
Mitosis
1 Diploid cell (2n) Diploid cells (2n)

50. Meiosis I
Prophase I
Over 90% of the time required for meiotic cell division
Chromatin  chromosome
Synapsis occurs : formation of a tetrad consisting of a homologous chromosome pair  homologous recombination (crossing over) occurs. e.g., 23 tetrads in human cells
The nucleoli and nuclear envelope disappear
Formation of mitotic spindle
Attachment of spindle microtubules to tetrads

52. MEIOSIS I: Homologous chromosomes separate
INTERPHASE:
Chromosomes duplicate
Prophase I
Metaphase I
Anaphase I
Centrosomes
(with centriole
pairs)
Spindle microtubules
attached to a kinetochore
Sister chromatids
remain attached
Sites of crossing over
Centrioles
Spindle
Tetrad
Chromatin
Sister
chromatids
Nuclear
envelope
Centromere
(with a
kinetochore)
Metaphase
plate
Fragments
of the
nuclear
envelope
Homologous
chromosomes
separate

53. 2. Metaphase I
Alignment of the chromosome tetrads on the metaphase plate
3. Anaphase I
Separation (split-up) of tetrads toward the opposite poles
4. Telophase I and cytokinesis
Reversal of prophase I

54. Meiosis II is essentially the same as mitosis
The sister chromatids of each chromosome separate
The result is four haploid daughter cells

55. MEIOSIS II: Sister chromatids separate
Telophase II
and Cytokinesis
Telophase I and Cytokinesis
Prophase II
Metaphase II
Anaphase II
Cleavage
furrow
Sister chromatids
separate
Haploid daughter
cells forming
Figure 8.14, part 2

56. 8.15 Review: A comparison of mitosis and meiosis
For both processes, chromosomes replicate only once, during interphase
Mitosis
Meiosis
Function
Growth
Cell replacement
Asexual reproduction
Production of haploid cells
Nuclear division
Once : 1 diploid cell  2 diploid cells
Two times : 1 diploid cell  4 haploid cells
Genetic recombination no
yes
Daughter cells
Genetically same
Genetically different

57. (before chromosome duplication)
MITOSIS
MEIOSIS I
Parent cell
(before chromosome duplication)
Prophase
Site of
crossing
over
Prophase I
Duplicated
chromosome
(two sister
chromatids)
Tetrad formed
by synapsis of
homologous
chromosomes
Chromosome
duplication
Chromosome
duplication
2n  4
Metaphase
Metaphase I
Chromosomes
align at the
metaphase plate
Tetrads (homologous
pairs) align at the
metaphase plate
Anaphase
Telophase
Anaphase I
Telophase I
Homologous
chromosomes
separate during
anaphase I;
sister
chromatids
remain together
Sister chromatids
separate during
anaphase
Daughter
cells of
meiosis I
Haploid
n  2
MEIOSIS II 2n 2n
No further
chromosomal
duplication;
sister
chromatids
separate during
anaphase II
Daughter cells of mitosis n n n n
Daughter cells of meiosis II

58. 8.16 The mechanisms for production of offspring with genetic diversity from the same parent
Independent orientation of chromosome tetrads at metaphase I of meiosis : n개의 homologous chromosome pair를 가지는 organism은 2n종류의 genetically different gamete를 형성
Random fertilization : n 종류의 sperm과 n 종류의 egg가 만나면 n2 종류의 zygote형성
Homologous (genetic) recombination at prophase I of meiosis
Mutations

59. Two equally probable arrangements of chromosomes at metaphase I
POSSIBILITY 1
POSSIBILITY 2
Two equally probable arrangements of chromosomes at metaphase I
Metaphase II
Gametes
Combination 1
Combination 2
Combination 3
Combination 4
Figure 8.16

60. 8.17 Homologous chromosomes carry different versions of genes
The differences between homologous chromosomes are based on the fact that they can carry different versions of a gene at corresponding loci
Alleles : different versions of a gene

61. duplicated chromosomes)
Coat-color
genes
Eye-color
genes C E
Brown
Black
Brown coat (C);
black eyes (E) C E C E
Meiosis c e c e c e
White
Pink
Tetrad in parent cell
(homologous pair of
duplicated chromosomes)
Chromosomes of
the four gametes
White coat (c);
pink eyes (e)

62. 8.18 Crossing over further increases genetic variability
Crossing over is the exchange of corresponding segments between two homologous chromosomes
Genetic recombination results from crossing over during prophase I of meiosis
This increases variation further

63. Chiasma
Tetrad
Figure 8.18A

64. How crossing over leads to genetic recombination
Coat-color genes
Eye-color genes
How crossing over leads to genetic recombination
Tetrad (homologous pair of chromosomes in synapsis) 1
Breakage of homologous chromatids
Chiasma : the site on a tetrad where crossing over occurs
Multiple crossovers can occur in each tetrad 2
Joining of homologous chromatids
Chiasma
Separation of homologous chromosomes at anaphase I 3
Separation of chromatids at anaphase II and completion of meiosis 4
Parental type of chromosome
Recombinant chromosome
Recombinant chromosome
Parental type of chromosome
Figure 8.18B
Gametes of four genetic types

65. ALTERATIONS OF CHROMOSOME NUMBER AND STRUCTURE
8.19 A karyotype is a photographic inventory of an individual’s chromosomes
Karyotype: the number and appearance of chromosomes in the nucleus of an eukaryotic cell
Karyotyping is performed using lymphocytes arrested at metaphase
A karyotype usually shows 22 pairs of autosomes and one pair of sex chromosomes

66. Giemsa Karyogram Hypotonic Fixative Packed red and solution
white blood cells
Fixative
Giemsa
White blood
cells
Stain
Centrifuge
Blood
culture
Fluid
Centromere
Sister
chromatids
Pair of homologous
chromosomes
2,600
Karyogram

67. 8.20 Connection: An extra copy of chromosome 21 causes Down syndrome
This karyotype shows three number 21 chromosomes  trisomy 21
An extra copy of chromosome 21 causes Down syndrome (47 chromosomes)

68. The chance of having a Down syndrome child goes up with maternal age
Figure 8.20C

69. 8.21 Accidents during meiosis can alter chromosome number
Abnormal chromosome count is a result of nondisjunction
Either homologous pairs fail to separate during meiosis I
Nondisjunction in meiosis I
Normal meiosis II
Gametes
n + 1
n + 1
n – 1
n – 1
Number of chromosomes

70. Or sister chromatids fail to separate during meiosis II
Normal meiosis I
Nondisjunction in meiosis II
Gametes
n + 1
n – 1 n n
Number of chromosomes
Figure 8.21B

71. Fertilization after nondisjunction in the mother results in a zygote with an extra chromosome
Egg cell
n + 1
Zygote 2n + 1
Sperm cell
n (normal)
Figure 8.21C

73. 8.23 Connection: Alterations of chromosome structure can cause birth defects and cancer
Chromosome breakage can lead to rearrangements that can produce genetic disorders or cancer
Four types of rearrangement are deletion, duplication, inversion, and translocation

74. Deletion
Inversion
Duplication
Reciprocal translocation
Homologous
chromosomes
Nonhomologous
chromosomes

75. Cell death
Necrosis (괴사)
Apoptosis (programmed cell death)