1. The Cell Cycle & Mitosis
細胞周期與細胞分裂

3. Cell Cycle 
There are so many accelerators and brakes.

6. The Cell Cycle
During development from stem to fully differentiated, cells in the body alternately divide (mitosis) and "appear" to be resting (interphase). This sequence of activities exhibited by cells is called the cell cycle.
Interphase, which appears to the eye to be a resting stage between cell divisions, is actually a period of diverse activities. Those interphase activities are indispensible in making the next mitosis possible.

8. Leland Hartwell used baker's yeast, Saccharomyces cerevisiae, as a model system for genetic studies of the cell cycle. In a series of experiments , he isolated yeast cells, in which genes controlling the cell cycle were mutated.
By this approach, he identified genes specifically involved in cell cycle control, CDC genes (cell division cycle genes). One of these genes, designated CDC28, controls the first step in the progression through the
G1 phase of the cell cycle (the function "start").
Hartwell also identified the fundamental role of "checkpoints" in cell cycle control. These checkpoints monitor that all steps in the previous phase have been correctly executed and ensure a correct order between the cell cycle phases.
Leland Hartwell, Fred Hutchinson Cancer Research Center, Seattle, WA, USA.
               

9.                                                       
                               .
                                                              
Leland Hartwell used baker's yeast, Saccharomyces cerevisiae (left). Paul Nurse used another type of yeast, Schizosaccharomyces pombe (middle). Tim Hunt used sea urchin, Arbacia (right).

10. Paul Nurse identified the key regulator of the cell cycle, the gene cdc2, during the years The product of this gene controls cell division (transition from G2 to M). The gene cdc2 in the fission yeast Schizosaccharomyces pombe had the same function as the gene CDC28 in the baker's yeast. cdc2 controls both the transition from G1 to S and G2 to M. In He isolated the human gene CDK1. The CDK function has been conserved through evolution. CDK1 encodes cyclin dependent kinases (CDK). These molecules function by linking phosphate groups to other proteins. Today half a dozen different CDK-molecules have been found in humans.
Paul Nurse, Imperial Cancer Research Fund, Lincoln's Inn Fields, London, UK
               

11. CDK and cyclin together form an enzyme that activates other proteins by phosphorylation. The amount of CDK molecules is constant during the cell cycle, but their activities vary because of the regulatory function of the cyclins.
CDK can be compared with an engine and cyclin with a gear box controlling whether the engine will run in the idling state or drive the cell forward in the cell cycle.
                                                                        

12. Tim Hunt discovered cyclins, proteins that bind to the CDK molecules.
Cyclins regulate the CDK activity and select the target proteins to be phosphorylated. The proteins were named cyclins because of their cyclic variation in amount during the cell cycle.
Cyclins were degraded during mitosis turned out to be another fundamental control mechanism in the cell cycle.
Tim Hunt discovered the first cyclin molecule in 1982, using eggs from sea urchin, Arbacia, as a model system. He also found that cyclins, like CDK, were conserved during evolution. Today around ten different cyclins have been found in humans.
Tim Hunt, 1943, Imperial Cancer Research Fund, Clare Hall Lab, south Mimms, UK.
               

13.                                                                  
                
                                                                                                 
Cyclins are proteins formed and degraded during each cell cycle. Periodic protein degradation is an important control mechanism of the cell cycle. (D = cell division.)
The fundamental molecular mechanisms controlling the cell cycle are highly conserved through evolution and operate in the same manner in yeasts, insects, plants, animals and humans.

14. Chromosomal instability in cancer cells may be the result of defective cell cycle control. Three pairs of chromosomes (1, 3 and 14) in normal cells, compared with the cancer cells. In cancer cells, the chromosome number may be altered (aneuploidy) and parts of chromosomes may be rearranged

17. 染色體 - genetic information in the form of chromatin, highly folded ribbon-like complexes of deoxyribonucleic acid (DNA) and a class of proteins called histones.
                           

18.                            
When a cell divides, chromatin fibers are very highly folded, and become visible in the light microscope as chromosomes.
During interphase (between divisions), chromatin is more extended, a form used for expression genetic information.

20.                            
The DNA of chromatin is wrapped around a complex of histones appears in the electron microscope as "beads on a string" or nucleosomes. Changes in folding between chromatin and the mitotic chromosomes is controlled by the packing of the nucleosome complexes. .

21. DNA or deoxyribonucleic acid is a large molecule structured
DNA or deoxyribonucleic acid is a large molecule structured from chains of repeating units of the sugar deoxyribose and phosphate linked to four different bases abbreviated A, T, G, C

22. The Cell Cycle
Stages of the cell cycle The cell cycle is an ordered set of events, culminating in cell growth and division into two daughter cells. Non-dividing cells not considered to be in the cell cycle.
The G1 stage stands for "GAP 1".
The S stage stands for "Synthesis". This is the stage when DNA replication occurs.
The G2 stage stands for "GAP 2".
The M stage stands for "mitosis", and is when nuclear (chromosomes separate) and cytoplasmic (cytokinesis) division occur.
Mitosis is further divided into 4 phases

23. Eukaryotic Cell Cycle
                                                                                                              

24. Regulation of the cell cycle How cell division (and thus tissue
Regulation of the cell cycle How cell division (and thus tissue growth) is controlled is very complex.
Cdk (cyclin dependent kinase, adds phosphate to a protein), along with cyclins, are major control switches for the cell cycle, causing the cell to move from G1 to S or G2 to M.
MPF (Maturation Promoting Factor) includes the CdK and cyclins that triggers progression through the cell cycle.
p53 is a protein that functions to block the cell cycle if the DNA is damaged. If the damage is severe this protein can cause apoptosis (cell death).

25. p21

26. p53 levels are increased in damaged cells
p53 levels are increased in damaged cells. This allows time to repair DNA by blocking the cell cycle.
A p53 mutation is the most frequent mutation leading to cancer. An extreme case of this is Li Fraumeni syndrome, where a genetic a defect in p53 leads to a high frequency of cancer in affected individuals.
3. p53 protein binds DNA and stimulates another gene to produce a p21 that interacts with cdk2. Stop the cell cycle.
4. p27 binds to cyclin and CdK blocking entry into S phase. Breast cancer prognosis is determined by p27 levels. Reduced levels of p27 predict a poor outcome.

27. Cyclins
a G1 cyclin (cyclin D)
S-phase cyclins (cyclins E & A)
mitotic cyclins (cyclins B & A)
Their levels in the cell rise and fall with the stages of the cell cycle.
Cyclin-dependent kinases (Cdks)
G1 Cdk (Cdk4)
S-phase Cdk (Cdk2)
M-phase Cdk (Cdk1) Their levels in the cell remain fairly stable, but each must bind the appropriate cyclin in order to be activated. They add phosphate groups to a variety of protein substrates that control processes in the cell cycle.

29. Cdk
cyclin

30. The anaphase-promoting complex (APC)
The APC is also called the cyclosome, and the complex is often designated as the APC/C.
The APC/C
triggers the events leading to destruction of the cohesins
thus allowing the sister chromatids to separate
degrades the mitotic cyclin B.

31. Steps in the cycle
A rising level of G1-cyclins bind to their Cdks and signal the cell to prepare the chromosomes for replication.
A rising level of S-phase promoting factor (SPF) — which includes cyclin A bound to Cdk2 — enters the nucleus and prepares the cell to duplicate its DNA (and its centrosomes).
As DNA replication continues, cyclin E is destroyed, and the level of mitotic cyclins begins to rise (in G2).

32. One example of a well-known transcription factor activation is the Rb/E2F protein regulation of the G1 to S phase transition in mammals cells

34. M-phase promoting factor (the complex of mitotic cyclins
M-phase promoting factor (the complex of mitotic cyclins with the M-phase Cdk) initiates
assembly of the mitotic spindle
breakdown of the nuclear envelope
condensation of the chromosomes
These events take the cell to metaphase of mitosis.
At this point, the M-phase promoting factor activates the anaphase-promoting complex (APC/C)

35. APC/C
allows the sister chromatids at the metaphase plate to separate and move to the poles (= anaphase), completing mitosis;
destroys cyclin B. It does this by attaching it to the protein ubiquitin which targets it for destruction by proteasomes.
turns on synthesis of G1 cyclin for the next turn of the cycle;
degrades geminin, a protein that has kept the freshly-synthesized DNA in S phase from being re-replicated before mitosis.
This is only one mechanism by which the cell ensures that every portion of its genome is copied once — and only once —during S phase.

36. Checkpoints: Quality Control of the Cell Cycle
The cell has several systems for interrupting the cell cycle if something goes wrong.
A check on completion of S phase. The cell seems to monitor the presence of the Okazaki fragments on the lagging strand during DNA replication. The cell is not permitted to proceed in the cell cycle until these have disappeared.
DNA damage checkpoints. These sense DNA damage
before the cell enters S phase (a G1 checkpoint);
during S phase, and
after DNA replication (a G2 checkpoint).
Spindle checkpoints
detect any failure of spindle fibers to attach to kinetochores and arrest the cell in metaphase (M checkpoint);
detect improper alignment of the spindle itself and block cytokinesis
trigger apoptosis if the damage is irreparable

38.                
Cancer

39. p53
The p53 protein senses DNA damage and can halt progression of the cell cycle in G1.
Both copies of the p53 gene must be mutated for this to fail so mutations in p53 are recessive, and p53 qualifies as a tumor suppressor gene.
.The p53 protein is also a key player in apoptosis, forcing "bad" cells to commit suicide.
Mutant p53 develops into a cancer.
More than half of all human cancers harbor p53 mutations and have no functioning p53 protein.

41. The p53 gene is found in chromosome 17.
In the cell, p53 protein binds DNA and stimulates p21 that interacts
with cdk2.
When p21 is complexed with cdk2 the cell cannot pass through to the next stage of cell division.
Mutant p53 can no longer bind DNA in an effective way, and the p21 protein is not made available to act as the 'stop signal' for cell division.
Thus cells divide uncontrollably, and form tumors.

43. A genetically-engineered adenovirus, called ONYX-015, can
A genetically-engineered adenovirus, called ONYX-015, can only replicate in human cells lacking p53.
Thus it infects, replicates, and ultimately kills many types of cancer cells in vitro.
Clinical trials are now proceeding to see if injections of ONYX- 015 can shrink a variety of types of cancers in human patients.

44. p53 seems to evaluate the extent of damage to DNA, at least for
p53 seems to evaluate the extent of damage to DNA, at least for damage by radiation.
At low levels of radiation, producing damage that can be repaired, p53 triggers arrest of the cell cycle until the damage is repaired.
At high levels of radiation, producing hopelessly damaged DNA, p53 triggers apoptosis. Possible mechanism:
Serious damage, e.g., double-stranded breaks (DSBs), causes a linker histone (H1) to be released from the chromatin.
H1 leaves the nucleus and enters the cytosol where it triggers the release of cytochrome c from mitochondria leading to apoptosis

46. ATM
ATM (ataxia telangiectasia mutated) gets its name from a human disease of that name, whose patients — among other things — are at increased risk of cancer.
The ATM protein is involved in
detecting DNA damage, especially double-strand breaks
interrupting (with the aid of p53) the cell cycle when damage is found;
maintaining normal telomere length

47. MAD MAD (mitotic arrest deficient) genes (there are two) encode proteins that bind to each kinetochore until a spindle fiber (one microtubule will do) attaches to it. If there is any failure to attach, MAD remains and blocks entry into anaphase.
Mutations in MAD produce a defective protein and failure of the checkpoint. The cell finishes mitosis but produces daughter cells with too many or too few chromosomes (aneuploidy).
Aneuploidy is one of the hallmarks of cancer cells suggesting that failure of the spindle checkpoint is a major step in the conversion of a normal cell into a cancerous one.

50. Infection with the human T cell leukemia virus-1 (HTLV-1)
Infection with the human T cell leukemia virus-1 (HTLV-1) leads to a cancer (ATL = adult T cell leukemia) in about 5% of its victims.
HTLV-1 encodes a protein, called Tax, that binds to MAD protein causing failure of the spindle checkpoint.
The leukemic cells in these patients show many chromosome abnormalities including aneuploidy

51. G0
Many times a cell will leave the cell cycle, temporarily or permanently.
It exits the cycle at G1 and enters a stage designated G0 (G zero). A G0 cell is often called "quiescent", but that is probably more a reflection of the interests of the scientists studying the cell cycle than the cell itself.
Many G0 cells are anything but quiescent. They are busy carrying out their functions in the organism. e.g., secretion, attacking pathogens.
Often G0 cells are terminally differentiated: they will never reenter the cell cycle but instead will carry out their function in the organism until they die.

53. For other cells, G0 can be followed by reentry into the cell cycle.
Most of the lymphocytes in human blood are in G0. However, with proper stimulation, such as encountering the appropriate antigen, they can be stimulated to reenter the cell cycle (at G1) and proceed on to new rounds of alternating S phases and mitosis.
G0 represents not simply the absence of signals for mitosis but an active repression of the genes needed for mitosis.
Cancer cells cannot enter G0 and are destined to repeat the cell cycle indefinitely

55. Cell Cycle Pathway
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57. Retinoblastoma

58. Loss of Rb function: lung cancer, lymphoma & breast cancer.
The retinoblastoma gene was isolated in It was the first tumor suppressor gene that was isolated based on knowledge of its chromosomal location: chrom 13 band q14. Germ line mutations in the Rb gene, predispose to a pediatric malignancy of the eye: retinoblastoma.
Loss of Rb predisposes to a variety of other tumors later in life, with osteosarcoma being the most prominent secondary tumor.
Loss of Rb function: lung cancer, lymphoma & breast cancer.
The Rb gene encodes a 110 kDa phosphoprotein (pRb) that is expressed in almost every cell of the human body and contributes to growth regulation in these cells. Reintroduction of a functional Rb gene in retinoblastoma tumor cells results in growth arrest, indicating that the function of the gene is to restrict proliferation.

59. ATM acts as a tumor suppressor
ATM acts as a tumor suppressor. ATM activation, via IR damage to DNA, stimulates DNA repair and blocks cell cycle progression. p53 can cause growth arrest of the cell at a checkpoint to allow for DNA damage repair or can cause the cell to undergo apoptosis. p53 is mutated in over 50% of cancers.

61. The p53 tumor suppressor protein can bind to specific DNA elements and in free from can activate transcription of genes that harbor p53 response elements in their promoters.
The activity of p53 is counteracted by a protein called Mdm2.
Mdm2 can bind to the transactivation domain of p53 and thereby prevent transactivation by p53. In addition, Mdm2 acts as a “ubiquitin ligase” that can target p53 for degradation by the proteasome. Thus, p53 in complex with Mdm2 is both inactive and unstable.
Binding of Mdm2 to p53 can be disrupted by a protein named p19ARF (or ARF for short). ARF can bind Mdm2 which renders it unable to interact with p53.
Expression of ARF therefore activates p53 by releasing Mdm2.

63. Click HERE for your print copy.
THE GENETICS OF CANCER Regulation of cell number and division
Key Ideas
The cells of "higher" eukaryotes contain mechanisms that control their survival and ability to proliferate.
These cells constantly evaluate their own condition via continuous communication among neighboring cells and tissues. Survival and proliferation controls are highly integrated and dependent on these inter-cellular communications.
A normal cell's proliferation is regulated at the level of the cell cycle (mitosis).
Apoptosis (from the Greek apo meaning "from, or away" and pto meaning "fall"), or programmed cell death, (The word is pronounced ah poh toh' sis, NOT a pop toh' sis; the second "p" is silent.) is a normal process by which cells are destroyed by intra- and extra-cellular mechanisms.
Cells may be triggered into an apoptotic cycle if they are damaged, dangerously abnormal, or needed only transiently during development.
Intercellular signaling systems allow organised cell proliferation and apotosis to proceed within any given population of cells.
In cancer cells, proliferation and apoptosis mechanisms have failed due to mutations normal tumor-suppressing genes, preventing self-destruct mechanisms from operating. Cancer cells are immortal and highly proliferative.
Many of the genes in which mutations cause cancer are those which contribute either directly or indirectly to the normal control of growth and differentiation mechanisms in the cell.
Early detection and treatment of cancer is becoming more sophisticated with the application of functional genomics (i.e., discovering not only what genes are in the genome, but what they code for).
Normal cell proliferation is important for
growth and development (stem cells are totipotent)
replacement of destroyed cells
Cell death is important for
programmed death of cells not needed after a certain point in development
removal of potentially dangerous damaged cells
Cell proliferation and cell death balance one another, and when mechanisms controlling either or both go awry, NEOPLASIA (from the Greek neo meaning "new" and plas meaning "form" or "shape", this means cancer formation). formation) can result.
CELL PROLIFERATION
Mitosis consists of
M phase (active mitosis)
G1 phase (pre DNA synthesis)
S phase (DNA synthesis)
G2 phase (post DNA synthesis)
Of these, only the G1 phase is variable in length, mainly because of the variation in an optional resting phase known as G0. The cell must pass through "checkpoints"--fail safe mechanisms that won't allow the cell to proceed to one phase until all the parts of the previous phase are complete--during the cell cycle.
Enzymes involved in the proliferation process are
protein kinases - phosphorylate specific amino acid residues on target proteins
cyclins
cyclin-dependent protein kinases (CDK proteins)
protein phosphatases - remove phosphates from specific amino acid residues on target proteins
Cyclical variation in the phosphorylation/dephosphorylation of these key proteins determine which ones are active for each portion of the cell cycle.
CELL DEATH
Notes on cell death...
In multicellular organisms, programmed cell death occurs primarily in somatic cells.
cell proliferation replaces somatic cells lost to cell death.
mechanisms have evolved to eliminate certain cells, and the process of such programmed cell death is known as apoptosis.
Enzymes & cells involved in apoptosis are
caspases - disrupt structural and functional systems of the target cell
scavenger cells - engulf and remove the "carcasses" of cells that have undergone apoptosis
The cell must respond to internal and external environmental cues to know when to proliferate and when to die. These consist of
To understand what happens when a Cell Goes Bad, we must first understand the behavior of a Nice, Normal Cell....
                                                                                                                                                                                                           
intercellular chemical signals
receptors of those signals
transduction systems that relay the signal from receptor to other parts of the cell
Recall protein kinases, the enzymes that phosphorylate particular target proteins.
Cyclins
exist in families of related enzymes, each of which is present only during a specific phase of the cell cycle.
are generated by the previous phase's specific cyclin-CDK complex, which acts as a transcription factor for its gene activation
don't last long in the cell! One type is rapidly removed and replaced by the next via
quick inactivation of the transcription activator for a particular cyclin's gene (no transcription, no translation)
instability of cyclin mRNA (easily degraded by nucleases)
instability of cyclin protein itself
CDK
A kinase phosphorylates proteins.
A cyclin-dependent kinase is activated by cyclin
The cyclin component of a cyclin-CDK compound determines the target protein of that particular cyclin-CDK complex. (Cyclin binds the protein, and kinase phosphorylates it.)
phosphorylation is transient and reversible
                                                                                                     
Variations in cyclin-CDK follow the cell cycle...
                                                                                                      One example of a well-known transcription factor activation is the Rb/E2F protein regulation of the G1 to S phase transition in mammals cells...
APOPTOSIS
This is sometimes referred to as "programmed cell death" and it is
triggered by a variety of signals. It involves...
Sequential destruction of cell
fragmentation of chromosomes
organelle disruption
fragmentation of cell
And it is driven by activity of caspases
cysteine-containing aspartate-specific proteases
these are normally inactive as zymogen (harmless to cell)
zymogen form is activated by proteolysis of one part of the zymogen polypeptide
such active caspases target other proteins for destruction
ACTIVATOR caspases respond by cleaving in response to protein signals from other cleaved proteins. These cleave the EXECUTIONAR caspases, activating them.
                                                                
Mutations in the genes encoding any of these highly specific "tumor suppressor" genes can result in CANCER.
Cancer cells are
immortal (do not undergo apoptosis)
highly proliferative
clonal (usually derived from a single aberrant Founder Cell)
malignant/invasive
Many different cell types can be altered to become cancerous. What are the common threads uniting them?
A cancer cell can be considered an aberrent cell with an accumulation of mutations that cause it to lose its proliferation and apoptotic controls. (In other words, a single mutation in a cell is not likely to cause it to become cancerous.) A cell that has a mutation preventing apoptosis will have more time to accumulate proliferation-promoting mutations that will cause it to become cancerous.
Some such mutations can be inherited via the germline (as in familial/heritable cancers)
Not all these genes have full penetrance: individuals having the mutations do not always develop the predicted cancers.
Others can arise de novoin the somatic cell lineage of a particular cell due to mutagenesis.
which suggests that the fewer carginogens to which an organism is subjected, the lower its likelihood of developing cancers
Two major types of mutations are associated with carcinogenesis. Mutations in
Oncogenes
Tumor-suppressor genes
                                                                                                       
ONCOGENES
An ONCOGENE is a dominant mutant gene that contributes to the formation of (animal) cancer.
The non-mutant form of an oncogene is known as a PROTO-ONCOGENE.
These usually encode a protein active only when proper regulatlyr signals activate them.
Often, these are proteins involved in positive control pathways.
Other proto-oncogenes encode negative controls of the apoptotic pathway.
The mutation of an oncogene uncouples the activity of a protein from its normal regulatory function.
This causes unregulated proliferation and no apoptosis of affected cells.
Oncogenes have been isolated from certain viruses known to have carcinogenic activity.
About 100 different oncogenes have thus far been identified.
Oncogenes can change due to
point mutations
loss of vital protein domain coding regions
gene fusion (as in the case of the Philadelphia chromosome. More on that in a moment.)
The carcinogencity of these genes is associated with the activation of certain proteins in cells containing at least one copy of a dominant allele.
TUMOR SUPPRESSOR GENES
These are genes that encode an active form of protein that ordinarily functions to maintain normal proliferation (e.g., rb; a mutant form of this gene encodes a mutant, non-functional RB protein, and cells containing this mutation proliferate out of control.
Example: Retinoblastoma, a cancer of the retina usually expressed in childhood, is often caused by a somatic rb mutation. Patients with this form of the cancer usually express it sporadically, and not in many areas. Very early diagnosis and enucleation can effect a cure.
Another form of retinoblastoma (HBR) is heritable. People who have inherited this form have the mutation in many cells, and suffer from tumors throughout the body, as well as both eyes. In this form, enucleation of the eye(s) is pointless, as tumors arise in many other locations.
mutant rb cells either carry two copies of a gene with the same mutation, or heterozygous for two different mutations of the same rb gene, meaning that the mutation is recessive.
Strangely enough, though, HBR is passed along as if it were autosomal dominant. How can this be?
                                                                                                                                                                                                                                   
If the mutation is inherited via the germline, mitotic crossing over (not uncommon during development) will result in at least some retinal cells will acquire two mutant copies of the gene, resulting in retinoblastomic cells.
Recall the activity of Rb protein, to see how this can be a problem!                                                                                                                                  
Other tumor suppressor mutations involve problems with positive regulation of apoptosis (e.g., p53).
Mutations of p53 are associated with many different types of cancers.
p53 is thus considered a TUMOR SUPPRESSOR GENE
Normal P53 protein is a transcription factor activated in response to DNA damage.
prevents progression of cell cycle in the presence of damaged DNA
can induce apoptosis under some circumstances
Mutant p53 cannot induce apoptosis, and cannot halt the cell cycle in the presence of damaged DNA.
This results in an increase in the overal frequency of mutations
If some of those mutations occur in proteins regulating proliferation and apoptosis, CANCER will result.
carcinogenesis of p53 causes cancer indirectly, as it simply causes an elevated rate of retained mutation, increasing the chances of carcinogenic mutations.
Mutations of any of these genes result in inactive forms of the protein, allowing uncontrolled proliferation and/or lack of apoptosis.
Tumor suppressor mutations are generally recessive.
Tumor-promoting mutations were first identified by study of cells from cancer patients in single families showing the same type of cancer. These shared cancers variously showed
similar mutant sequences in specific genes
characteristic translocations or deletions of certain chromosomal regions
Example: 95% of chronic myelogenous leukemia (CML) have a characteristic translocation between chromosomes 9 and 22. (The "Philadelphia Chromosome") Breakpoint locations:
middle of a gene known as c-abl, a gene that normally encodes a functional tyrosine kinase
bcr1 gene, also coding a kinase
The translocation produces a hybrid Bcr-1-Abl protein that cannot effect normal repressor controls on the proteins upon which normal Abl protein acts. This results in a disruption of normal cell cycle activity.
As you can see, a wide variety of mutations can potentially cause cancer, and cancer cannot be considered a single "disease." It is a failure of normal gene function.
As geneticists continue to work in the realm of FUNCTIONAL GENOMICS, determining not only the sequence of our genes, but their function, greater headway will be made in finally finding the answer to controlling this genetic disorder.
(Will you be the one to find the key?)

66. Proliferation vs. Apoptosis Controls
These are interrelated, and may induce apoptosis in cells that fail to successfully complete some phase of cell cycle.
Intracellular signals
cell cycle negative controls: inhibition of CDK-cyclin
cell cycle positive controls: activation of CDK-cyclin
MITOGENS are polypeptide ligands
Some of these are growth factors that activate receptor tyrosine kinases (RTK proteins). This initiates a signal cascade that affects the configuration of many different transcription factors, affecting the gene activity in the cell
apoptosis positive controls: leakage of cytochrome c from defective mitochondria acts as a trigger for apoptosis
apoptosis negative controls: proteins such as Bcl-2 & Bcl-x block the release of cytochrome c from mitochondria, possibly stabilizing the mitochondrial membrane and preventing its rupture).
Extracellular signals
based on cell-cell communication         

71. 節食減少代謝 使NAD, Sir2增加

73. What is (and is not) mitosis?
Mitosis is nuclear division plus cytokinesis, and produces two identical daughter cells during prophase, prometaphase, metaphase, anaphase, and telophase.
Interphase is often included in discussions of mitosis, but interphase is technically not part of mitosis, but rather encompasses stages G1, S, and G2 of the cell cycle.

74. Interphase
               
The cell is engaged in metabolic activity and performing its prepare for mitosis.
Chromosomes are not clearly discerned in the nucleus, although a dark spot
called the nucleolus may be visible. The cell may contain a pair of centrioles
both of which are organizational sites for microtubules.

75. Prophase
               
Chromatin in the nucleus begins to condense and becomes visible in the light microscope as chromosomes. The nucleolus disappears. Centrioles begin moving to opposite ends of the cell and fibers extend from the centromeres. Some fibers cross the cell to form the mitotic spindle.

76. Prometaphase
               
The nuclear membrane dissolves, marking the beginning of prometaphase. Proteins attach to the centromeres creating the kinetochores.
Microtubules attach at the kinetochores and the chromosomes
begin moving.

77. Metaphase
               
Spindle fibers align the chromosomes along the middle of the cell nucleus. This line is referred to as the metaphase plate. This organization helps to ensure that in the next phase, when the chromosomes are separated, each new nucleus will receive one copy of each chromosome.

78. Anaphase
               
The paired chromosomes separate at the kinetochores and move to opposite sides of the cell. Motion results from a combination of kinetochore movement along the spindle microtubules and through the physical interaction of polar microtubules.

79. Telophase
               
Chromatids arrive at opposite poles of cell, and new membranes form around the daughter nuclei. The chromosomes disperse and are no longer visible under the light microscope. The spindle fibers disperse, and cytokinesis or the partitioning of the cell may also begin during this stage.

80. Cytokinesis
               
In animal cells, cytokinesis results when a fiber ring composed of a protein called actin around the center of the cell contracts pinching the cell into two daughter cells, each with one nucleus. In plant cells, the rigid wall requires that a cell plate be synthesized between the two daughter cells.