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Chromosomes, Mitosis and Chromosomes, Mitosis and MeiosisMeiosis
Chapter 10 Chapter 10
Learning Objective 1Learning Objective 1
• What is the significance of What is the significance of chromosomeschromosomes in terms of information?in terms of information?
ChromosomesChromosomes
OrganizationOrganization
• GenesGenes• cell’s informational unitscell’s informational units• made of DNA made of DNA
• ChromatinChromatin • DNA and proteinDNA and protein• makes up chromosomes (eukaryotes)makes up chromosomes (eukaryotes)
• ChromosomesChromosomes• allow DNA sortingallow DNA sorting• into daughter cellsinto daughter cells
KEY CONCEPTSKEY CONCEPTS
• In eukaryotic cells, DNA is wound around In eukaryotic cells, DNA is wound around specific proteins to form specific proteins to form chromatinchromatin, which , which in turn is folded and packaged to make in turn is folded and packaged to make individual individual chromosomeschromosomes
Learning ObjectiveLearning Objective 22
• How is DNA organized in How is DNA organized in prokaryoticprokaryotic and and eukaryoticeukaryotic cells? cells?
Prokaryotic CellsProkaryotic Cells
• Contain circular DNA moleculesContain circular DNA molecules
Eukaryotic ChromosomesEukaryotic Chromosomes
• NucleosomeNucleosome• histone histone (protein) bead wrapped in DNA(protein) bead wrapped in DNA• organized into coiled loopsorganized into coiled loops• held together by nonhistone held together by nonhistone scaffolding scaffolding
proteinsproteins
NucleosomesNucleosomes
Fig. 10-2a, p. 213
DNA wound around a cluster of histone molecules
Histone tails
Linker DNA
Nucleosome (10 nm diameter)
Fig. 10-2b, p. 213
100 nm
Scaffolding ProteinsScaffolding Proteins
Fig. 10-3, p. 213
DNA
Scaffolding proteins
2 μm
Chromosome OrganizationChromosome Organization
Fig. 10-4, p. 214
1400 nm
700 nm 300 nm fiber (looped domains)
30 nm chromatin fiber
Condensed chromosome
DNA wound around a cluster of histone molecules
Scaffolding proteinCondensed
chromatin Extended chromatin
Packed nucleosomes
Histone10 nm
2 nm Nucleosomes
DNA double helix
Learning ObjectiveLearning Objective 33
• What are the stages in the eukaryotic What are the stages in the eukaryotic cell cell cyclecycle, and their principal events?, and their principal events?
Eukaryotic Eukaryotic Cell CycleCell Cycle
• Cycle of cell divisionCycle of cell division• interphaseinterphase• M phaseM phase
Fig. 10-5, p. 215
INTERPHASE
G1 (First gap phase)
S (Synthesis phase)
G2 (Second gap
phase)
M PHASE (Mitosis and cytokinesis)
InterphaseInterphase
• First gap phase (First gap phase (G1 phase)G1 phase)• cell grows and prepares for S phasecell grows and prepares for S phase
• Synthesis phase (Synthesis phase (S phase)S phase)• DNA and chromosome protein synthesisDNA and chromosome protein synthesis• chromosome duplicationchromosome duplication
• Second gap phase (Second gap phase (G2 phaseG2 phase))• protein synthesis increasesprotein synthesis increases• preparation for cell divisionpreparation for cell division
M PhaseM Phase
• MitosisMitosis• nuclear divisionnuclear division• two nuclei identical to parent nucleustwo nuclei identical to parent nucleus
• CytokinesisCytokinesis• cytoplasm dividescytoplasm divides• two daughter cellstwo daughter cells
KEY CONCEPTSKEY CONCEPTS
• Cell divisionCell division is an important part of the is an important part of the cell cell cyclecycle, which consists of the successive , which consists of the successive stages through which a cell passesstages through which a cell passes
Animation: The Cell CycleAnimation: The Cell Cycle
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Learning ObjectiveLearning Objective 44
• What is the structure of a duplicated What is the structure of a duplicated chromosome, including the chromosome, including the sister sister chromatidschromatids, , centromerescentromeres, and , and kinetochoreskinetochores??
A Duplicated ChromosomeA Duplicated Chromosome
• Consists of a pair of Consists of a pair of sister chromatidssister chromatids• containing identical DNA sequencescontaining identical DNA sequences
• CentromereCentromere• constricted regionconstricted region• joins sister chromatidsjoins sister chromatids
• KinetochoreKinetochore• protein to which microtubules bindprotein to which microtubules bind• attached to centromere attached to centromere
Sister ChromatidsSister Chromatids
Fig. 10-7, p. 218
Centromere region
Microtubules
Kinetochore
Sister chromatids
1.0 μm
Learning ObjectiveLearning Objective 55
• What is the process and significance of What is the process and significance of mitosismitosis??
MitosisMitosis
• Preserves chromosome numberPreserves chromosome number• in eukaryotic cell divisionin eukaryotic cell division
• Identical chromosomes are distributed to Identical chromosomes are distributed to each pole of the celleach pole of the cell• nuclear envelopenuclear envelope forms around each set forms around each set
InterphaseInterphase
Fig. 10-6a, p. 216
INTERPHASE PROPHASE PROMETAPHASE
ChromatinNucleolus Sister chromatids
of duplicated chromosome
KinetochoreNucleus
Spindle microtubule
Pieces of nuclear envelope
Nuclear envelope
Plasma membrane
Developing mitotic spindle
Centrioles
ProphaseProphase
• Chromatin condenses into duplicated Chromatin condenses into duplicated chromosomes (pair of sister chromatids)chromosomes (pair of sister chromatids)
• Nuclear envelope begins to disappearNuclear envelope begins to disappear• Mitotic spindleMitotic spindle begins to form begins to form
Mitotic SpindleMitotic Spindle
Fig. 10-9a, p. 219
Metaphase plate (cell’s midplane)
Kinetochore microtubule (spindle microtubule)
Centrioles
Astral microtubules
Pericentriolar material
Polar (non- kinetochore) microtubule
Sister chromatids
Fig. 10-9b, p. 219
10 μm
ProphaseProphase
PrometaphasePrometaphase
• SpindleSpindle microtubules attach to microtubules attach to kinetochoreskinetochores of chromosomes of chromosomes
• Chromosomes begin to move toward cell’s Chromosomes begin to move toward cell’s midplanemidplane
PrometaphasePrometaphase
MetaphaseMetaphase
• Chromosomes align on cell’s midplane Chromosomes align on cell’s midplane ((metaphase plate)metaphase plate)
• Mitotic spindle is completeMitotic spindle is complete• Microtubules attach kinetochores of sister Microtubules attach kinetochores of sister
chromatids to opposite poles of cell chromatids to opposite poles of cell
MetaphaseMetaphase
AnaphaseAnaphase
• Sister chromatids separateSister chromatids separate• move to opposite polesmove to opposite poles
• Each former chromatid is now a Each former chromatid is now a chromosomechromosome
AnaphaseAnaphase
TelophaseTelophase
• Nuclear envelope re-formsNuclear envelope re-forms• Nucleoli appearNucleoli appear• Chromosomes uncoilChromosomes uncoil• Spindle disappearsSpindle disappears• Cytokinesis beginsCytokinesis begins
TelophaseTelophase
Fig. 10-6b, p. 217
METAPHASE ANAPHASE TELOPHASE
25 μ
m
SpindleCleavage furrow
Centriole pair at spindle pole
Reforming nuclear envelopeCell’s midplane
(metaphase plate)
Daughter chromosomes
KEY CONCEPTSKEY CONCEPTS
• In cell division by In cell division by mitosismitosis, duplicated , duplicated chromosomes separate (split apart) and chromosomes separate (split apart) and are evenly distributed into two daughter are evenly distributed into two daughter nucleinuclei
CytokinesisCytokinesis
Fig. 10-10a, p. 220
Cleavage furrow
Actomyosin contractile ring
10 μm
Fig. 10-10b, p. 220
NucleusCell plate forming
Vesicles gather on
cell’s midplane
Small vesicles
fuse, forming larger
vesicles
Eventually one large
vesicle exists
New cell walls (from
vesicle contents)
Plasma membrane
Cell wall
Cell plate forming
New plasma membranes (from vesicle membranes)
5 μm
Learning ObjectiveLearning Objective 66
• How is the cell cycle controlled?How is the cell cycle controlled?
Cell-Cycle ControlCell-Cycle Control
• Cyclin-dependent kinases (Cdks)Cyclin-dependent kinases (Cdks)• protein kinasesprotein kinases that control cell cycle that control cell cycle• active only when bound to active only when bound to cyclinscyclins
• CyclinsCyclins• regulatory proteinsregulatory proteins• levels fluctuate during cell cyclelevels fluctuate during cell cycle
CyclinsCyclins
Fig. 10-12, p. 222
11 Cyclin is synthesized and accumulates.
2 Cdk associates with cyclin, forming a cyclin–Cdk complex, M-Cdk.
Cdk5 G1
S
M-Cdk phosphorylates proteins, activating those that facilitate mitosis and inactivating those that inhibit mitosis.
3
4 An activated enzyme complex recognizes a specific amino acid sequence in cyclin and targets it for destruction. When cyclin is degraded, M-Cdk activity is terminated, and the cells formed by mitosis enter G1.
M G2
Cyclin 5 Cdk is not degraded but is recycled and reused.
2
Degraded cyclin
Cdk4
M-Cdk (triggers M phase)
3
1
2
3
4
5
KEY CONCEPTSKEY CONCEPTS
• An internal genetic program interacts with An internal genetic program interacts with external signals to regulate the external signals to regulate the cell cyclecell cycle
Learning ObjectiveLearning Objective 77
• What is the difference between What is the difference between asexualasexual and and sexualsexual reproduction? reproduction?
Asexual ReproductionAsexual Reproduction
• Single parent Single parent • offspring have identical hereditary traitsoffspring have identical hereditary traits
• MitosisMitosis• basis for eukaryotic asexual reproductionbasis for eukaryotic asexual reproduction
Binary Binary FissionFission
Fig. 10-11, p. 221
Prokaryotic cellPlasma membrane
1 DNA replication begins at single site on bacterial DNA.Cell wall
Bacterial DNA
Origin of replication
2 Replication continues, as replication enzymes work in both directions from site where replication began.
Two copies of bacterial DNA
3 Replication is completed. Cell begins to divide, as plasma membrane grows inward.
4 Binary fission is complete. Two identical prokaryotic cells result.
Two identical prokaryotic cells
Sexual ReproductionSexual Reproduction
• Two haploid sex cells Two haploid sex cells (gametes)(gametes) fuse to fuse to form a single diploid form a single diploid zygotezygote
• MeiosisMeiosis • produces gametesproduces gametes
Learning ObjectiveLearning Objective 88
• What is the difference between What is the difference between haploidhaploid and and diploiddiploid cells? cells?
• What are What are homologous chromosomeshomologous chromosomes??
DiploidDiploid Cell Cell
• Chromosomes are paired (Chromosomes are paired (homologous homologous chromosomeschromosomes))• similar in length, shape, other featuressimilar in length, shape, other features• carry genes affecting the same traitscarry genes affecting the same traits
HaploidHaploid Cell Cell
• Contains only one member of each Contains only one member of each homologous chromosome pairhomologous chromosome pair
Fig. 10-16, p. 229
Fig. 10-16a, p. 229
MITOSIS
PROPHASE
No synapsis of homologous chromosomes
ANAPHASE
Sister chromatids move to opposite poles
DAUGHTER CELLS
Two 2n cells with unduplicated chromosomes
Fig. 10-16b, p. 229
MEIOSIS
PROPHASE I
Synapsis of homologous chromosomes to form tetrads
ANAPHASE IHomologous chromosomes move to opposite poles
PROPHASE IITwo n cells with duplicated chromosomes
ANAPHASE IISister chromatids move to opposite poles
HAPLOID CELLSFour n cells with unduplicated chromosomes
Learning ObjectiveLearning Objective 99
• What is the process and significance of What is the process and significance of meiosismeiosis??
MeiosisMeiosis
• One One diploiddiploid cell divides two times, yielding cell divides two times, yielding four four haploidhaploid cells cells
• Sexual life cycles in eukaryotes require Sexual life cycles in eukaryotes require meiosismeiosis• each gamete contains half the number of each gamete contains half the number of
chromosomes in parent cellchromosomes in parent cell
Meiosis IMeiosis I
• Prophase IProphase I• homologous chromosomes join homologous chromosomes join (synapsis)(synapsis)
• Crossing-overCrossing-over• between homologous (nonsister) chromatids between homologous (nonsister) chromatids • exchanges segments of DNA strandsexchanges segments of DNA strands
• Results in Results in genetic recombinationgenetic recombination
SynapsisSynapsis
Fig. 10-14a, p. 228
Maternal sister chromatids
Paternal sister chromatids
Synaptonemal complex
ChromatinProtein
Chromatin Maternal sister chromatids
Fig. 10-14b, p. 228
Chromosome
Chromosome
0.5 μm
Synaptonemal complex
Meiosis IMeiosis I
• Metaphase IMetaphase I• tetrads tetrads (homologous chromosomes joined by (homologous chromosomes joined by
chiasmatachiasmata)) line up on metaphase plate line up on metaphase plate
• Anaphase IAnaphase I • homologous chromosomes separate homologous chromosomes separate • distributed to different nucleidistributed to different nuclei
• Each nucleus contains haploid number of Each nucleus contains haploid number of chromosomeschromosomes• each chromosome has 2 chromatidseach chromosome has 2 chromatids
Tetrads and ChiasmataTetrads and Chiasmata
Fig. 10-15a, p. 228
Chiasmata Sister chromatids
Kinetochores
Sister chromatids
1 μm
Fig. 10-15b, p. 228
Sister chromatidsChiasmata
Kinetochores
Meiosis IIMeiosis II
• Two chromatids of each chromosome Two chromatids of each chromosome separateseparate• one distributed to each daughter cell one distributed to each daughter cell
• Each former chromatid is now a Each former chromatid is now a chromosomechromosome
MeiosisMeiosis
MeiosisMeiosis
Fig. 10-13a (1), p. 226
INTERPHASE MEIOSIS I
Mid-prophase I Late prophase I
Nucleolus
Homologous chromosomesChromatin
Developing meiotic spindleCentrioles
Nuclear envelope
Interphase preceding meiosis; DNA replicates.
Homologous chromosomes synapse, forming tetrads; nuclear envelope breaks down.
Fig. 10-13a (2), p. 226
MEIOSIS IIProphase II Metaphase II Anaphase II
Daughter chromosomes
Chromosomes condense again following brief period of interkinesis. DNA does not replicate again.
Chromosomes line up along cell's midplane.
Sister chromatids separate, and chromosomes move to opposite poles.
Fig. 10-13b (1), p. 227
Metaphase I Anaphase I Telophase I
Microtubule attached to kinetochore
Cleavage furrow
Separation of homologous chromosomes
Sister chromatids
Tetrads line up on cell's midplane. Tetrads held together at chiasmata (sites of prior crossing-over).
Homologous chromosomes separate and move to opposite poles. Note that sister chromatids remain attached at their centromeres.
One of each pair of homologous chromosomes is at each pole. Cytokinesis occurs.
Fig. 10-13b (2), p. 227
Telophase II Four haploid cells
25 μm
Nuclei form at opposite poles of each cell. Cytokinesis occurs.
Four gametes (animal) or four spores (plant) are produced.
Learning ObjectiveLearning Objective 1010
• What are the different processes and What are the different processes and outcomes of outcomes of mitosismitosis and and meiosismeiosis? ?
MitosisMitosis
• Single nuclear divisionSingle nuclear division• 2 daughter cells genetically identical to 2 daughter cells genetically identical to
each other and to original celleach other and to original cell• No synapsis of homologous chromosomes No synapsis of homologous chromosomes
MitosisMitosis
MeiosisMeiosis
• Two successive nuclear divisions form Two successive nuclear divisions form four haploid cellsfour haploid cells
• Synapsis of homologous chromosomes Synapsis of homologous chromosomes occurs during prophase Ioccurs during prophase I
MeiosisMeiosis
KEY CONCEPTSKEY CONCEPTS
• MeiosisMeiosis, which reduces the number of , which reduces the number of chromosome sets from chromosome sets from diploiddiploid to to haploidhaploid, , is necessary to maintain the normal is necessary to maintain the normal chromosome number when two cells join chromosome number when two cells join during sexual reproductionduring sexual reproduction
KEY CONCEPTSKEY CONCEPTS
• Meiosis helps to increase Meiosis helps to increase genetic variationgenetic variation among offspringamong offspring
Learning ObjectiveLearning Objective 1111
• Compare the roles of mitosis and meiosis Compare the roles of mitosis and meiosis in various generalized in various generalized life cycleslife cycles
AnimalsAnimals
• Somatic cellsSomatic cells are diploid are diploid• produced by mitosisproduced by mitosis
• GametesGametes are haploid are haploid • produced by meiosis (produced by meiosis (gametogenesis)gametogenesis)
Animal Life CycleAnimal Life Cycle
Fig. 10-17a, p. 230
Gametes (n)
Meiosis Fertilization
Zygote (2n)
Mitosis
Multicellular diploid
organism (2n)
Animals
Simple EukaryotesSimple Eukaryotes
• May be haploidMay be haploid• produced by mitosisproduced by mitosis
• Only diploid stage is the Only diploid stage is the zygotezygote• which undergoes meiosis to restore the which undergoes meiosis to restore the
haploid statehaploid state
Simple Eukaryote Life CycleSimple Eukaryote Life Cycle
Fig. 10-17b, p. 230
Unicellular or multicellular
haploid organism (n)
Mitosis Mitosis
Gametes (n)
Meiosis Fertilization
Zygote (2n)
Simple eukaryotes
PlantsPlants
• Alternation of generationsAlternation of generations::• sporophyte generationsporophyte generation• gametophyte generationgametophyte generation
PlantsPlants
• Sporophyte generationSporophyte generation• multicellular diploid multicellular diploid • forms haploid spores by meiosisforms haploid spores by meiosis
• Spore divides (mitosis) to form Spore divides (mitosis) to form gametophyte generationgametophyte generation• multicellular haploidmulticellular haploid• produces gametes by mitosis produces gametes by mitosis
PlantsPlants
• Two haploid gametes fuse to form diploid Two haploid gametes fuse to form diploid zygotezygote
• ZygoteZygote divides (mitosis) to produce new divides (mitosis) to produce new diploid sporophyte generationdiploid sporophyte generation
Plant Life CyclePlant Life Cycle
Fig. 10-17c, p. 230
Gametophyte (n) (multicellular haploid
organism)
Mitosis Mitosis
Spores (n) Gametes (n)
Meiosis Fertilization
Zygote (2n)
Mitosis
Sporophyte (2n) (multicellular diploid
organism)
Plants, some algae, and some fungi
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