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Mitosis and Meiosis
• Chapter 12 & 13• Mitosis & Meiosis
Next Unit: Genetics & DNA
• Chapter 12 & 13: Mitosis & Meiosis
• Chapter 14: Principles of Heredity
• Chapter 15: Human Genetics & Disorders• Chapter 16: DNA: History, Structure & Function
• **Three Labs will be done for this Unit • Goal: to complete before Thanksgiving and to take
Test #3 on 11/20 (Tuesday)
Video #1: Generations-Mitosis & Meiosis1. In the mid 1800’s what did Paseur, Lister do? In 1876, What did Walter
Flemming do that provided better visualization of parts in the cell? What did he see & discover?
2. Chromosomes literally mean: “_______”3. What is a centromere and what is its function?4. What is a karyotype and what does it reveal? What are “homologous
chromosomes”?5. How many chromosomes do humans, fruit flies (Drosophila), horsetails,
Toads, and pea plants have?6. Name the business used in the 2nd segment to show the importance of
mitosis. 7. Briefly explain what “grafting” is? 8. A complete cycle can be completed in about ______hrs in a rapidly
dividing tissue such as bone marrow. During this time mitosis occurs for only _______ hr(s). Pg. 221
9. Name the FOUR phases of Mitosis and two key events that occur. (See pg. 222-223)
10. Name two differences between Mitosis & Meiosis after watching the final segment.
****Write the Title for each segment and THREE key statements for each segment.
Introductory Questions #11) How much DNA does a typical human cell have?
How are chromosomes differ from chromatin?2) How is a somatic cell different from a gamete?3) How is every species different in regards to their
chromosomes? 4) Name the main stages of the cell cycle. (pg. 221)5) What are the four stages of mitosis? Which stage
is the longest and which stage is the shortest?6) Give three specific events that occur during
prophase.7) How are plant cell different from animal cells when
they divide?
Mitosis
• Occurs only in certain types of cells
• Form of asexual reproduction
• Produces two genetically identical cells from one cell.
• The splitting or dividing of the nucleus
• Viewed in different stages by examining chromosome formation and behavior.
Significance of Understanding Mitosis
• Preserves the continuity of life
• Allows organisms to grow, repair, and reproduce
• Important in unlocking the mysteries of embryonic development & stem cells
• Important in understanding how cancer develops and could someday provide clues in stopping cancer.
• Cell replacement (seen here in skin)
Deadcells
Figure 8.11B
Dividingcells
Epidermis, the outer layer of the skin
Dermis
Packaging of Genetic Materialhttp://www.biostudio.com/demo_freeman_dna_coiling.htm
Structure / Activity Diameter
• DNA: smallest structure about (2 nm)
• DNA & Histones = Nucleosome (10 nm)
• Chromatin Fibers** (30 nm)
• Extensive Looping (300 nm)
• Further Condensing (700 nm)
• Fully Formed Chromosome (1400 nm)
Chromosomes
• Condensed DNA attached to proteins• Can only be seen when a cell is actively
undergoing mitosis.• Typical humans form 46 chromosomes vs. other
organisms which varies significantly.• Our 46 chromosomes are thought to contain
anywhere from 25,000 to 100,000 genes.• Duplicated before mitosis occurs producing a
sister chromatid (identical copy)• Sister chromatids held together by “Centromere”
• When the cell cycle operates normally, mitotic cell division functions in:– Growth (seen here in an onion root)
Cells from an onion Root tip
Figure 8.11A
• E. coli dividing
Figure 8.3x
• Asexual reproduction (seen here in a hydra)
Figure 8.11C
• A eukaryotic cell has many more genes than a prokaryotic cell– The genes are grouped into
multiple chromosomes, found in the nucleus
– The chromosomes of this plant cell are stained dark purple
THE EUKARYOTIC CELL CYCLE AND MITOSIS
Figure 8.4A
• Human male bands
Figure 8.19x3
• Human female karyotype
Figure 8.19x2
• Before a cell starts dividing, the chromosomes are duplicated
– This process produces sister chromatids
Centromere
Sister chromatids
Figure 8.4B
• When the cell divides, the sister chromatids separate
– Two daughter cells are produced
– Each has a complete and identical set of chromosomes
Centromere Sister chromatids
Figure 8.4C
Chromosomeduplication
Chromosomedistribution
todaughter
cells
INTERPHASE PROPHASE
Figure 8.6
See Pgs 222-223
METAPHASE TELOPHASE AND CYTOKINESIS
Metaphaseplate
Spindle Daughterchromosomes
Cleavagefurrow
Nucleolusforming
Nuclearenvelopeforming
ANAPHASE
Figure 8.6 (continued)
The Cell Cycle: Generation Time
• Interphase: most of a cell’s life (90%)-G1: 1st gap of growth
-S phase: DNA is duplicated
(synthesized)
-G2 phase: 2nd gap of growth
• Mitosis: splitting of the nucleus (PMAT)
• Cytokinesis: separation of the cytoplasm
• The cell cycle consists of two major phases:– Interphase, where chromosomes duplicate
and cell parts are made
– The mitotic phase, when cell division occurs
The cell cycle multiplies cells
Figure 8.5
Interphase
Interphase • Cells spend most of its time in this phase
• Cells are growing
• DNA has to be replicated (all 2 meters of it)
• Proteins are being produced
• 90% of all cells are in this phase
• Three phases: G1, S, and G2
Prophase
Prophase• Chromatin thickens (coils) into chromosomes• Two copies of DNA are present: sister chromatids
(twice the amount of DNA is present)• Centrioles replicate forming another centrosome
separate.• Centrioles separate to each side of the nucleus• Nuclear membrane (envelope) disappears• Microtubules elongate forming the spindle apparatus
Metaphase
Metaphase• Chromosomes align themselves up in the
center of the cell
• Spindle fibers (microtubules) attach to the centromere of the chromosomes
• Longest phase of Mitosis
Metaphase
• Mitotic spindle
Figure 8.6x2
Anaphase - Early & Late
Anaphase• Chromosomes separate by the shortening of
the microtubules.
• The sister chromatids separate to each side (pole) of the cell. (humans: 46 to each side)
• The centrosome is located at each side of the cell.
Telophase (Plant & Animal)
Cytokinesis: Plant vs Animal Cells
• Cleavage furrow: animals cells
• Cell plate: Plant cells
• In animals, cytokinesis occurs by cleavage– This process pinches
the cell apart
Cytokinesis differs for plant and animal cells
Figure 8.7A
Cleavagefurrow
Cleavagefurrow
Contracting ring ofmicrofilaments
Daughter cells
• In plants, a membranous cell plate splits the cell in two
Vesicles containingcell wall material
Cell plateforming
Figure 8.7BCell plate Daughter
cells
Wall ofparent cell
Daughternucleus
Cell wall New cell wall
• When the cell cycle operates normally, mitotic cell division functions in:– Growth (seen here in an onion root)
Cells from an onion Root tip
Figure 8.11A
• Mitosis collage, light micrographs
Figure 8.6x1
Whitefish-phases of Mitosis
Various phases of Mitosis-Plants
Which Phase is this?
• Sea urchin development
Figure 8.0x
• Cell cycle collage
Figure 8.5x
• Fibroblast growth
Figure 8.8x
Total Class Data for all Three Classes: Fall 2005
Interphase Prophase Metaphase Anaphase TelophaseTotal # of cells 11806 2451 386 264 516% in each phase 77% 16% 3% 2% 3%Time in each phase (min) 1102.3 228.8 36.0 24.6 48.2Hours 18.4 3.8 0.6 0.4 0.8
Total Class Data for all Three Classes: Fall 2006
Interphase Prophase Metaphase Anaphase Telophase
Total # of cells 18296 1821 529 461 695% in each phase 84% 8% 2% 2% 3%Time in each phase (min) 1208.1 122.3 35.2 29.9 44.5Hours 20.1 2.0 0.6 0.5 0.7
Regulation of Cell Division
• Driven by specific molecular signals
• Research has shown:– Two cells in different phases causes the other to
be pushed into the next phases.– Ex.
• S phase & G1 grown together will cause the G1 cell to enter into the S phase immediately
• M phase cell & G1 cell will cause the G1 cell to enter into the M phase immediately.
• There is an obvious control system in place.
Regulating Mitosis-Control System(pg. 229-231)
• Most cells can divide up to 50 times• Control of the Cell cycle involves three checkpoints
-G1 (most important checkpoint) = restriction point
(G0: non-dividing state)
-G2
-M phase• Growth factors (proteins): Cyclins & Kinases
– Kinases: phosphorylate proteins, gives the go ahead– Cdk: are kinases that must be attached to a cyclin to be activated– MPF: Maturation promoting factor (Fig: pg. 230)
• Complex of kinase and cyclin• Triggers the passage from G2 phase into M phase• peaks during Metaphase
• Proteins within the cell control the cell cycle– Signals affecting critical checkpoints determine
whether the cell will go through a complete cycle and divide
Growth factors signal the cell cycle control system
G1 checkpoint
M checkpoint G2 checkpoint
Controlsystem
Figure 8.9A
Cyclin & Kinase effects on the cell cycle.
• Animated link: http://nobelprize.org/educational_games/medicine/2001/cellcycle.html
Introductory Questions #21) Which checkpoint in the regulation of mitosis is considered
the “restriction point”? Why point and not the others? 2) Name the two protein molecules that are high in
concentration during the mitotic (M) phase of the cell cycle. Name the complex that it forms.
3) Why are telomeres considered to be a “mitotic clock”?4) How are tumor supressor genes different from an
oncogene? What is the difference between a malignant tumor and a benign tumor?
5) When looking at the hypothetical sequence of how mitosis may have evolved how is the process different in a bacteria and diatom from a plant and animal cell?
Cyclin & MPF Concentrations
Growth Factors that stimulate Cell Division
PDGF: Platelet-derived growth factor causes fibroblasts to divide in response to an injury. Has been shown to be effective in artificial conditions
Cytokinins: key hormone in plants that promotes cell division
• The binding of growth factors to specific receptors on the plasma membrane is usually necessary for cell division
Growth factor
Figure 8.8B
Cell cyclecontrolsystem
Plasma membrane
Receptorprotein
Signal transduction pathway
G1 checkpointRelayproteins
Mitotic Clock Mechanisms in CellsTelomeres, Proteins, Cell size (SA), hormones, &
Growth factors
• Telomeres: Segments of DNA (200 repeated sequences of nucleotides) are lost at the tips of the chromosomes with each mitotic event.– (Mitotic clock) the tips of chromosomes wear
down and lose DNA sequences over time.– Six Nucleotide sequence repeated hundreds of
times– 1,200 nucleotides are removed after each mitotic
event
Image of Telomeres-notice light Blue Regions
Chromosomes in green & Telomeres in yellow
• 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
Anchorage, cell density, and chemical growth factors affect cell
division
• Cells continue dividing until they touch one another
– This is called density-dependent inhibition
Cells anchor to dish surface and divide.
Figure 8.8A
When cells have formed a complete single layer, they stop dividing (density-dependent inhibition).
If some cells are scraped away, the remaining cells divide to fill the dish with a single layer and then stop (density-dependent inhibition).
• Growth factors are proteins secreted by cells that stimulate other cells to divide
After forming a single layer, cells have stopped dividing.
Figure 8.8B
Providing an additional supply of growth factors stimulates further cell division.
See pg. 232
• Malignant tumors can invade other tissues and may kill the organism
Tumor
Figure 8.10
Glandulartissue
1 2 3A tumor grows from a single cancer cell.
Cancer cells invade neighboring tissue.
Lymphvessels
Cancer cells spread through lymph and blood vessels to other parts of the body.
Metastasis
• Cancer cells have abnormal cell cycles– They divide excessively and can form abnormal
masses called tumors
• Radiation and chemotherapy are effective as cancer treatments because they interfere with cell division
Growing out of control, cancer cells produce Malignant tumors
• Breast cancer cell
Figure 8.10x1
• Mammograms
Figure 8.10x2
Anti-Cancer drugs
• Colchicine: blocks microtubules from forming
-binds & inhibits unpolymerized tubulin
-breakdown of microtubules occur
-polyploidy could occur
• Taxol: Found in the bark of yew trees
-blocks ovarian cancer from forminghttp://www.ncl.ox.ac.uk/quicktime/taxol.html
Genes that are thought to cause CancerSee Pgs: 371-372
• Oncogenes: a gene that increases cell division and triggers cancerous characteristics.
• Tumor Suppressor genes: a gene that inactivates or inhibits cell division. Prevents uncontrolled cell growth (cancer). It keeps mitosis in check and controls the cell cycle.
• Failure of normal cell programmed death (Apotosis) Pgs. 800 & 902
Stem Cells (pgs. 415-418)• Undifferentiated cells
• Progenitor cells: partially specialized cell. an intermediate between a stem cell and a fully differentiated cell.
• Pluripotent cells: follows fewer pathways that it can develop into.
• Totipotent cells: cells that are very early in development when the zygote has developed into a small ball of cells.
Cell Differentiationhttp://learn.genetics.utah.edu/units/stemcells/whatissc/
Evolution of Mitosis
Chromosomes attach to the plasma membrane
Chromosomes attach to the nuclear membrane
Pass through the nucleus
Spindle forms within the nucleus
Introductory Questions #31) Which phase is used to obtain pictures of chromosomes
in order to generate a karyotype2) 3) Give five differences between Mitosis and Meiosis.3) Name three factors in Meiosis & reproduction that
contributes in increasing genetic variability within a population.
4) What is a polar body? How is oogenesis different from spematogenesis?
5) How is a sporophyte different from a gametophyte? What do they produce and what process is involved, mitosis or meiosis?
6) What is a tetrad? Which phase of Meiosis does crossing over occur?
Heredity, Life Cycles, and Meiosis Chapter 13
HeredityHeredity: the transmission of traits
from one generation to the nextAsexual reproduction: clonesSexual reproduction: variationHuman life cycle: 23 pairs of homologous chromosomes 1 pair of sex chromosomes (X or Y) and 22 pairs of autosomes;Karyotype : Pix of chromosomes-Gametes are haploid (n)-All other cells (somatic) are diploid
(2n)
-Fertilization (syngamy) joining (fusion)
of gametes to produce a zygote
Meiosis: cell division to produce haploid gametes
• The human life cycle
Figure 8.13
MEIOSIS FERTILIZATION
Haploid gametes (n = 23)
Egg cell
Sperm cell
Diploidzygote
(2n = 46)Multicellular
diploid adults (2n = 46)
Mitosis anddevelopment
Alternative Life CyclesFungi/some algae-Meiosis produces haploid cells (n) that divide by mitosis to produce-Haploid (n) adults (gametes produced by mitosis)
Plants/some algae Do Alternation of generations: 2n = Sporophyte generation n = Gametophyte generation
Meiosis occurs & produces spores:Spores are haploid (n) Spores divide by mitosis to generate
more haploid cells (n)Gametes are produced by mitosis
which then fertilize into a sporophyte (2n)
• Human female karyotype
Figure 8.19x2
• Human male karyotype
Figure 8.19x4
Meiosis• Chromosome replicate• 2 Cell divisions occur (Meiosis I & Meiosis II)• 4 daughter cells are
made all are (n): haploid• Homologous Chrom’s
separate in meiosis I• Meiosis II = Mitosis
(chromatids separate)
• The differences between homologous chromosomes are based on the fact that they can carry different versions of a gene (alleles) at corresponding loci
Homologous chromosomes carry different versions of genes
Homologous Chromosomes(Are they identical?)
Sister Chromatids
♂ from father from mother
Tetrad (Bivalent)
Figure 8.14, part 1
MEIOSIS I: Homologous chromosomes separate
INTERPHASE PROPHASE I METAPHASE I ANAPHASE I
Centrosomes(withcentriolepairs)
Nuclearenvelope
Chromatin
Sites of crossing over
Spindle
Sisterchromatids
Tetrad
Microtubules attached tokinetochore
Metaphaseplate
Centromere(with kinetochore)
Sister chromatidsremain attached
Homologouschromosomes separate
• Crossing over is the exchange of corresponding segments between two homologous chromosomes
• Genetic recombination results from crossing over during prophase I of meiosis
Crossing over further increases genetic variability
Figure 8.18A
TetradChaisma
Centromere
Synaptonemal Complex- Pg 213
• Protein that hold homologous chromosomes together
• Thought to be involved in crossing over events
• How crossing over leads to genetic recombination
Figure 8.18B
Tetrad(homologous pair ofchromosomes in synapsis)
Breakage of homologous chromatids
Joining of homologous chromatids
Chiasma
Separation of homologouschromosomes at anaphase I
Separation of chromatids atanaphase II and completion of meiosis
Parental type of chromosome
Recombinant chromosome
Recombinant chromosome
Parental type of chromosome
Gametes of four genetic types
1
2
3
4
Coat-colorgenes
Eye-colorgenes
Figure 8.17A, B
Coat-color genes Eye-color genes
Brown Black
C E
c e
White Pink
C E
c e
C E
c e
Tetrad in parent cell(homologous pair of
duplicated chromosomes)
Chromosomes ofthe four gametes
Origins of Genetic Variation
(1) Independent assortment: How they line up during metaphase I
Matters!!!
Homologous pairs of chromosomesposition and orient themselvesRandomly. (random positioning)
Different combinations are possible when gametes are produced.
Figure 8.16
POSSIBILITY 1 POSSIBILITY 2
Two equally probable
arrangements of chromosomes at
metaphase I
Metaphase II
Gametes
Combination 1 Combination 2 Combination 3 Combination 4
Origins of Genetic Variation(2) Crossing over (prophase I): -the reciprocal exchange of genetic material between nonsister chromatids during synapsis of meiosis I (recombinant chromosomes)
(3) Random fertilization:
1 sperm (1 of 8 million possible chromosome combinations) x 1 ovum (1 of 8 million different possibilities) = 64 trillion diploid combinations!
Figure 8.14, part 2
MEIOSIS II: Sister chromatids separate
TELOPHASE IAND CYTOKINESIS PROPHASE II METAPHASE II ANAPHASE II
Cleavagefurrow
Sister chromatidsseparate
TELOPHASE IIAND CYTOKINESIS
Haploiddaughter cellsforming
Meiosis vs. Mitosishttp://www.pbs.org/wgbh/nova/baby/divi_flash.html
• Synapsis/tetrad/chiasmata (prophase I)
• Homologous vs. individual chromosomes (metaphase I)
• Sister chromatids do not separate (anaphase I)
• Meiosis I separates homologous pairs of chromosomes, not sister chromatids of individual chromosomes.
Figure 8.15
MITOSIS MEIOSIS
PARENT CELL(before chromosome replication)
Site ofcrossing over
MEIOSIS I
PROPHASE ITetrad formedby synapsis of homologous chromosomes
PROPHASE
Duplicatedchromosome(two sister chromatids)
METAPHASE
Chromosomereplication
Chromosomereplication
2n = 4
ANAPHASETELOPHASE
Chromosomes align at the metaphase plate
Tetradsalign at themetaphase plate
METAPHASE I
ANAPHASE ITELOPHASE I
Sister chromatidsseparate duringanaphase
Homologouschromosomesseparateduringanaphase I;sisterchromatids remain together
No further chromosomal replication; sister chromatids separate during anaphase II
2n 2n
Daughter cellsof mitosis
Daughter cells of meiosis II
MEIOSIS II
Daughtercells of
meiosis I
Haploidn = 2
n n n n
Introductory Questions #21) From our the overall data in our Mitosis lab, what stage was the
shortest and which stage was the longest? If Telophase was supposed to be the shortest phase, what would have contributed to our different results?
2) Which phase is used to obtain pictures of chromosomes in order to generate a karyotype?
3) Give five differences between Mitosis and Meiosis.4) Name three factors in Meiosis & reproduction that contributes
in increasing genetic variability within a population.5) What is a polar body? How is oogenesis different from
spematogenesis? 6) How is a sporophyte different from a gametophyte? What do
they produce and what process is involved, mitosis or meiosis? 7) What is a tetrad? Which phase of Meiosis does crossing over
occur?
• Translocation
Figure 8.23Bx
• 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– All of these processes make up the sexual life
cycle of organisms
• The large number of possible arrangements of chromosome pairs at metaphase I of meiosis leads to many different combinations of chromosomes in gametes
• Random fertilization also increases variation in offspring
• Human female bands
Figure 8.19x1
• Human female karyotype
Figure 8.19x2
• Human male bands
Figure 8.19x3
• Human male karyotype
Figure 8.19x4
• Down syndrome karyotype
Figure 8.20Ax
• Klinefelter’s karyotype
Figure 8.22Ax
• XYY karyotype
Figure 8.22x