Term
define: tumor suppressor gene
what happens when the tumor suppressor gene is mutated? |
|
Definition
when this is functioning (active), it stops the formation of tumors
when tumor suppressor genes are mutated, their activity is not able to stop tumors and therefore cause cancers |
|
|
Term
| Let's say that I have a tumor in my brain. What does this mean in terms of p53 gene? |
|
Definition
| it means that the p53 gene is mutated b/c if the p53 gene was functioning normally, it would suppress that tumor before it forms in my brain but b/c it didn't do that, we can assume that the p53 gene is mutated |
|
|
Term
| T/F: every type of tumor that produces in the body is linked with the p53 gene |
|
Definition
False:
not necessarily
however yes, most tumors are due to mutations on the p53 gene
*50% of all tumor types in humans are due to mutations on the p53 tumor supressor gene* |
|
|
Term
|
Definition
| process by which normal cells are turned into cancer cells |
|
|
Term
| what are the two cellular outcomes of activities of wild type p53 gene? |
|
Definition
cell cycle arrest
and
apoptosis |
|
|
Term
| what is the point of the article "Regulation of tumor suppressor gene: p53"? |
|
Definition
| the point like the title says is to regulate the tumor suppressor gene: p53 b/c p53 as we know functions on cells that have lesions that might go into cancerous state thereby killing those cells but too much p53 activity may act on normal cells which we dont so the body needs to regulate when to activate p53 gene and when to stop its activity and that is the point of this article |
|
|
Term
| Under normal conditions, p53 gene is probably _______ |
|
Definition
|
|
Term
| T/F: p53 gene is not usually needed for the normal functioning of cells |
|
Definition
True:
p53 is not essential for normal functioning of cells |
|
|
Term
| there are many things that can induce the p53 gene. what is the common denominator of all these factors? |
|
Definition
|
|
Term
| what all causes the induction of p53 gene? |
|
Definition
| conditions include direct DNA damage as well as damage to components involved in the proper handling and segregation of the cellular genetic material such as: hypoxia, heat shock, exposure to NO, mitotic spindle ribonucleotide depletion |
|
|
Term
| which chromosome is p53 gene mapped to? |
|
Definition
|
|
Term
T/F: p21 has earned the nickname "guardian of the genome"
Why? |
|
Definition
False:
p53 has earned that nickname b/c it maintains the genomic integrity (cell cycle arrest, apoptosis, DNA repair) |
|
|
Term
| Besides causing cell cycle arrest and apoptosis, what else does p53 gene do? |
|
Definition
| p53 gene may also directly or indirectly contribute to DNA repair process by activating another gene |
|
|
Term
| how is p21 gene related to p53 gene? |
|
Definition
| p53 gene contributes directly or indirectly to particular DNA repair processes by activating another gene called p21 |
|
|
Term
| generally speaking, how does p53 interact with p21? |
|
Definition
| it activates the p21 gene |
|
|
Term
| we know that if a mutation occurs on a gene, then p53 can undergo cell cycle arrest, apoptosis, or DNA repair. what occurs first? |
|
Definition
first, p53 will try to repair the mutation
if that doens't work, then p53 will undergo apoptosis |
|
|
Term
| what is the meaning of post translational regulation? |
|
Definition
it means that if there is too much p53 protein in the cell, the cell will get rid of some of it so the p53 is not taking over the cell: this literally means post translational regulation
in the online notes, it says "accumulation of active p53 in response to stress occurs mainly through post translational mechanisms" - this is what I wrote above
steps:
1) cellular stress
2) induction of p53 gene
3) p53 proteins produced
4) assuming no regulation at transcriptional level which leads to too much p53 protein produced
5) cell gets rid of some of p53 proteins
6) known as post translational mechanism |
|
|
Term
| generally speaking, when p53 protein is produced by the p53 gene, what does the p53 protein do? |
|
Definition
| the p53 protein binds to DNA of another target gene |
|
|
Term
| what is associated with 'gene specific transcriptional activator'? |
|
Definition
| p53 protein* operates as a gene-specific transcriptional activator |
|
|
Term
| T/F: p53 protein cannot bind just anywhere on a targeted gene |
|
Definition
True:
p53 is a gene-specific transcriptional activator which relies on its ability to bind defined sequence elements within target genes |
|
|
Term
| what kind of regulation occurs when p53 protein binds to defined sequence elements within target genes? |
|
Definition
negative regulation
the sequence-specific DNA binding activity is subject to constitutive negative regulation |
|
|
Term
| what is the function of the active form of p53? not like that it causes cell cycle arrest etc but in terms transcription, translation etc |
|
Definition
| active p53 gene operates as a gene-specific transcriptional activator |
|
|
Term
| in what ways can the transcriptional activity of p53 be induced? |
|
Definition
1) relieving the inhibition of its C-terminal resulting in increased DNA binding
2) modifications of the N-terminal transactivation domain enabling a much more efficient recruitment of components of the transcription machinery
3) change in subcellular localization: latent p53 may be in the cytosol while active p53 may be in nucleus |
|
|
Term
| how is the binding of p53 protein to DNA subject to negative reguation - in other words, through what? |
|
Definition
| its subject to negative regulation primarily through its inhibitory C-terminal domain |
|
|
Term
|
Definition
| this is a gene that when mutated or expressed at high levels helps turn a normal cell into a cancerous cell |
|
|
Term
| what is associated with an oncogene? |
|
Definition
Mdm2 protein* (not gene)
Mdm2 protein is the product of an oncogene |
|
|
Term
| generally speaking, how is p53 related to mdm2 gene? |
|
Definition
| Mdm2 gene is a key player in the regulation of p53 gene |
|
|
Term
| what are the two general ways in which the p53 is made non-functional? |
|
Definition
1) inactivation of p53 by not allowing transcription
2) complete elimination of p53 by proteolytic degradation
both of these are done by binding of mdm2 with p53 |
|
|
Term
| how does mdm2 gene inactivate p53? |
|
Definition
| mdm2 protein* binds to p53 gene and inactivates it b/c the binding occurs at the transactivation domain, interfering with the basal transcription machinery thereby not allowing transcription of p53 gene to occur |
|
|
Term
| what does p53 protein bind to in order to get killed by proteolytic degradation? |
|
Definition
p53 protein binds to mdm2 gene* (not protein)
recall that mdm2 protein* binds to p53 gene* in order to inactivate the p53 gene |
|
|
Term
| T/F: p53 is killed when p53 protein binds to mdm2 gene |
|
Definition
False:
p53 is killed (proteolytic degradation) when mdm2 protein binds to p53 protein
point of asking this question: we know p53 can be inactivated or killed and both happen when mdm2 protein binds to p53 protein
the only thing that happens when p53 protein binds to mdm2 gene is the stimulation of mdm2 gene to make mdm2 proteins |
|
|
Term
| explain the negative and positive feedbacks that occur involving p53 and mdm2 gene: |
|
Definition
when p53 protein binds to mdm2 gene to stimulate its transcription is positive feedback
when mdm2 proteins are produced in response to the positive feedback stated above and the mdm2 protein binds to p53 protein and inactivates or kills p53 protein is negative feedback |
|
|
Term
| in some situations, the induction of transcription of mdm2 gene occurs later than that of induction of transcription of other p53 target genes. why is that? |
|
Definition
| this may set a time window within which p53 is allowed to exert its biochemical and biological effects b/c remember that once mdm2 gene transcription is induced, mdm2 protein will inactivate/kill p53 |
|
|
Term
| what happens if the mdm2 gene is inactivated? |
|
Definition
| results in embryonal lethality |
|
|
Term
| what happens if the mdm2 protein is nonfunctional? |
|
Definition
| p53 becomes strongly deregulated to the extent that its excess activity leads to embryonic death |
|
|
Term
| what happens when there is excessive Mdm2 expression? |
|
Definition
| leads to constitutive inhibition of p53 and thereby promote cancer without a need to alter the p53 gene itself |
|
|
Term
| summarize what happens in response non-functional mdm2 gene, non-functional mdm2 protein, and excessive mdm2 gene |
|
Definition
1) non-functional mdm2 gene: embryonic lethality
2) non-functional mdm2 protein: deregulation of p53 to an extent that its activity leads to embryonic death
3) excessive mdm2 gene: constitutive inhibition of p53 and thereby promoting cancer without a need to alter the p53 gene itself |
|
|
Term
| T/F: Cancer is only promoted when there is too much mdm2 activity that binds to p53 |
|
Definition
False:
we know that excessive mdm2 gene leads to constitutive inhibition of p53 and thereby promoting cancer without the need to alter the p53 gene itself.
excessive mdm2 gene can also promote cancer independently of p53* |
|
|
Term
| how is excessive mdm2 gene achieved? |
|
Definition
| gene amplifications or other mechanisms |
|
|
Term
| what kind of a protein is the mdm2 protein? |
|
Definition
|
|
Term
| tell all about the mdm2 protein: |
|
Definition
1) its a nuclear phosphoprotein that binds to and inhibits transactivation by tumor protein p53 as part of an autoregulatory negative feedback loop
2) the protein has E3 ubiquitin ligase activity which targets tumor protein p53 for proteosmal degradation
3) protien affects cell cycle, apoptosis, and tumorigenesis through interactions with other proteins |
|
|
Term
| T/F: ubiquitin is found on mdm2 protein |
|
Definition
True:
E3 ubiquitin ligase activity is found on mdm2 protein and when it binds to p53 protein, causes the p53 protein to undergo proteolytic degradation |
|
|
Term
activation of p53 is primarily achieved through _______
demise of p53 is primarily achieved through _______ |
|
Definition
p53 stabilization
ubiquitin-proteasome pathway |
|
|
Term
| what happens when there is interference between the binding of mdm2 protein and p53 protein? |
|
Definition
| if these two cant bind, it causes dramatic stabilization and accumulation of p53 in non-stressed cells |
|
|
Term
| what suggests that mdm2 gene is what produces ubiquinated forms of p53? |
|
Definition
| when there is too much mdm2 activity, it augments the accumulation of ubiquinated forms of p53 |
|
|
Term
| low basal levels of p53 in normal cells are primarily due to ____________ |
|
Definition
are primarily due to continuous mdm2 promoted degradation
binding of mdm2 protein and p53 protein |
|
|
Term
| how is rapid post-trnaslational activation of signaling protiens achieved? |
|
Definition
| rapid post-translational activation of signaling proteins is achieved through covalent modifications, particularly protein phosphorylation |
|
|
Term
covalent modification of p53 generally means what?
what is the result? |
|
Definition
means that the p53 protein* has been phosphorylated
the result is that it causes stabilization and activation of p53 through inhibition of p53 ubiquitination and degradation - in other words, phosphorylating p53 protein prevents degradation by mdm2 protein |
|
|
Term
| T/F: protein phosphorylation only occurs on p53, particulary on the transactivation domain |
|
Definition
False:
yes, the phosphorylation occurs on the transactivation domain of the p53 protein but phosphorylation can occur on either mdm2 protein or p53 protein
phosphorylating either binding domains inhibits binding of the two proteins thereby preventing degradation of p53 |
|
|
Term
| what exactly is phosphorylated on p53 protein/mdm2 protein? |
|
Definition
|
|
Term
| why does phosphorylating binding domains p53/mdm2 protein prevent binding of the two proteins? |
|
Definition
| it reduces the affinity of the proteins for each other |
|
|
Term
| T/F: different parts of the binding domain on p53 protein are phosphorylated for specific outcomes |
|
Definition
True:
specific amino acids on the binding domain of p53 are phosphorylated in order to bring specific outcomes
for ex: phosphrylation of specific amino acid on p53 is necessary for repair of ionization radiation and some other types of DNA damage |
|
|
Term
| T/F: when binding domain on mdm2 protein is phosphorylated, the sole result is reduced affinity of p53 binding |
|
Definition
False:
that is one possibility but phosphorylation may actually retain binding ability of p53 with mdm2 domain but may impair the proteolytic ability of mdm2 protein |
|
|
Term
what happens when binding domains of both the mdm2 protein and the p53 protein are phospohrylated?
|
|
Definition
| if binding domains on proteins are phosphorylated, it prevents binding of the two proteins with each other --> no ubiquitination of p53 protein --> no p53 degradation (stabilization of p53) |
|
|
Term
| what happens when only one protein's (either mdm2 protein or p53 protein) binding domain is phosphorylated? |
|
Definition
| if only one of the two protein's binding domain is phosphorylated, binding of the two proteins will occur but p53 will be ubiquitated and therefore will not be degraded (stabilization of p53) |
|
|
Term
| T/F: ARF protein can bind to either mdm2 protein or p53 protein |
|
Definition
True:
ARF protein can bind to mdm2 protein and p53 protein but it binds to mdm2 protein more commonly
recall that phosphorylation can occur on either mdm2 binding domain or p53 binding domain and its the same with ARF protein however it binds to mdm2 protein more than it binds to p53 protein |
|
|
Term
| what is the result of the binding of ARF protein to mdm2 protein? |
|
Definition
| when ARF protein binds to mdm2 protein, binding of p53 and mdm2 protein does occur but ubiquitination of p53 does not occur and p53 is not degraded (stabilization of p53) |
|
|
Term
| explain how ARF, mdm2, p53, CDK4, cyclin, and p16 are related |
|
Definition
ARF is a regulatory protein that binds to mdm2 protein
binding of ARF to mdm2 protein leads to stabilization of p53 b/c although binding of p53 and mdm2 protein occurs, it does not allow for ubiquitination and therefore degradation
ARF arises through translation of an alternative reading frame derived from INK4A (aka p16 gene)
INK4A's (p16 gene) product is a suppressor of CDK4A |
|
|
Term
define: cyclin dependent kinase
define: cyclin |
|
Definition
cyclin depenent kinases are protein kinases that regulate cell cycle progression in all eukaryotes and require physical association with cyclins to achieve full enzymatic activity
cyclin are proteins that bind to CDKs helping them in cell maturation |
|
|
Term
| when there is cellular stress like DNA damage, we need p53 genes so they can suppress the tumor by cell cycle arrest or apoptosis. but we also have mdm2 genes that inactivate/eliminate the p53 proteins so how does that work - in other words, what keeps the mdm2 protein from not binding to p53 protein? |
|
Definition
well we already that covalent modification (phosphorylation) of either mdm2 protein or p53 protein can inhibiting binding of the two proteins thereby preventing ubiquitination and degradation of p53 so the p53 can remain stabilized and continue functioning
another way that we have already mentioned is ARF protein which binds to mdm2 protein (and p53 protein to a lesser extent) which leads to the binding of the two proteins but does not allow ubiquitination and degradation of p53 thereby allowing the p53 to remain stabilized and continue functioning
|
|
|
Term
| phosphorylation/ARF of p53 and mdm2 binding domain occurs in the cytoplasm and the result is stabilization of p53 protein. but the problem is that target genes are located in the nucleus and if all this is going on in the cytoplasm, how does the p53 protien get inside the nucleus? |
|
Definition
the p53 protein has a hydrophobic element which allows for the p53 protein to get into the nucleus
this p53 protein that is entering the nucleus is known as a nuclear phosphoprotein |
|
|
Term
| when phosphorylatin of mdm2 protein and p53 protein occurs on its binding domain to allow for stabilization of p53 protein, is the p53 protein that survives remain phosphorylated? |
|
Definition
| I think it does - the survived p53 protein remains phosphorylated and goes into the nucleus with its phosphorylation |
|
|
Term
| excess activity of oncoproteins leads to _________ (phosporylation of mdm2/p53 protein or induction of ARF protein) |
|
Definition
induction of ARF protein
preventing ubiquitination and degradation of p53 protein |
|
|
Term
| explain the role of p53 in melanoma: |
|
Definition
1) UV is known to cause distinct mutations in keratinocytes
2) keratinocytes = epidermal cells that make keratin
3) keratin = protein important in hair, skin, nails and ultimately contributes to development of non-melanoma skin cancers such as basal cell carcinoma and squamous cell carcinoma
4) process by which these mutations are introduce into these cells begin with the interaction between UV photons and cell DNA
5) as photons are absorbed by DNA, an excited state is produced rearranging electrons and producing a photoproduct
6) photoproducts if not repaired interfere with DNA replication and cause specific mutations in DNA
7) mutations caused by UV-B in DNA cause a single base shift of C by T
8) mutations caused by UV-A in DNA are not well characterized -- UV-A mutations are known to be 1000 times less mutagenic than UV-B
9) molecular basis of nonherited melanomca are not completely understood
10) sunlight plays a role
|
|
|
Term
| what are the target genes of DNA damage caused by UV radiation? |
|
Definition
proto-oncogenes
and
tumor suppressor genes
so either of these genes can have their DNA damaged due to exposure to UV radiation
however, mutations in the tumor suppressor genes are thought to play a critical role in precancerous lesions and have been in implicated in all types of skin cancers |
|
|
Term
| what are all the parts of the p53 protein? |
|
Definition
on the N-terminal (amino side): we have the transactivation domain that binds to mdm2 protein, then going left to right we have the DNA binding domain for transcription, then TET (tetramerization domain and on the C-terminal) which contains NES and NLS - the NES is for p53 going into the nucleus and the NLS is for p53 to find the gene, then at last, we have the NEG which binds to damaged DNA and this is also the place where ubiquitin binds
note: Mdm2 binds on the N-terminal while ubiquitin binds on the C-terminal
first, the NES allows p53 to enter the nucleus, then NLS allows p53 to find the target gene which it will transcribe, and lastly the DNA binding domain will allow p53 to bind to that target gene |
|
|
Term
| T/F: NEG consists of NES and NLS |
|
Definition
False:
TET consists of NES and NLS
NEG is what allows p53 to bind to damaged DNA and this is where ubiquitin binds |
|
|
Term
| which segment of p53 makes p53 protein biologically functional? |
|
Definition
TET domain
what we mean by making the p53 protien biologically functional is that the binding of the target gene is located on the TET domain therefore the TET domain is the one that is responsible for making the p53 protien functional |
|
|
Term
| T/F: the DNA binding domain on p53 protien is the domain where the target gene binds |
|
Definition
False:
the DNA binding domain which is in the middle of the p53 protein is not where the target gene binds
this is the location where the gene binds for transcription
the location where the target gene binds is on the TET domain |
|
|
Term
what is the target gene that the p53 protein binds to?
where does the target gene bind on the p53 protein? |
|
Definition
the damaged DNA is the target gene that p53 protein binds to
the damaged DNA binds on the TET domain of the p53 protein |
|
|
Term
| on what part of the segment of p53 protein do most of the cancer-causing mutations occur? give the amount of mutation that occurs here |
|
Definition
DNA-binding domain
95% of the mutations occur on this domain |
|
|
Term
| what structural form of p53 actually binds to DNA and how is that structural form produced? |
|
Definition
tetramer
1 monomer p53 + 1 monomer p53 = 1 dimer p53
1 dimer p53 + 1 dimer p53 = 1 tetramer p53 |
|
|
Term
| T/F: only the tetramer form of p53 is biologically functional |
|
Definition
True:
dimers or monomers are not biologically functional |
|
|
Term
_______ base pairs make up one full spiral of DNA
________ angstrom between two base pairs
length of entire spiral = _______ angstrom |
|
Definition
10 base pairs
3.4 angstrom between two base pairs
34 angstrom = length of entire spiral |
|
|
Term
| T/F: each monomer of p53 binds to 10 base pairs |
|
Definition
False:
each dimer* (not monomer) binds to 10 base pairs |
|
|
Term
| one tetramer of p53 binds to _______ base pairs |
|
Definition
20 base pairs
b/c one dimer binds to 10 base pairs so one tetramer binds to 20 base pairs |
|
|
Term
|
Definition
| this is when one tetramer p53 binds to 20 base pairs of DNA |
|
|
Term
what has current study about the location of mutations on p53 dimer other than the fact that mutations are located on DNA binding domain on p53?
what is the importance of this? |
|
Definition
the point of contact between the two core domains of a pair of p53 forming a dimer is related to the part of the protein where the mutation occurs
so when two monomers p53 bind each other to form a dimer, the point of contact where they bind is related to the part of p53 where the mutation occurs
this is imporant b/c this suggests that this point of contact is as important as the interface between tetramer binding to DNA b/c the interface of tetramer binding to DNA is dependent on where the point of contact where the two monomers bind |
|
|
Term
| we know that p53 protein functions to repair or kill the damaged cells hence acting as tumor suppressor genes. to which part of the damaged DNA does p53 bind and why to that part? |
|
Definition
p53 binds to the downstream region of the damaged gene
it binds here b/c downstream region is responsible for growth so binding and activating expression of this region inhibits growth of the damaged DNA |
|
|
Term
|
Definition
these are enzymes that regulate the cell cycle like the checkpoints of cell cycle
CDK = cyclin dependent kinases |
|
|
Term
what is CDK2, CDK4, and CDK6?
what happens if these two kinases are disrupted? |
|
Definition
these are kinases that regulate the G1 phase
if these two kinases are disrupted, the G1 phase of the cell cycle is rested |
|
|
Term
what are the stages of the cell cycle?
how many checkpoints are there in the cell cycle?
when do the checkpoints occur? |
|
Definition
we have G1 phase = growth and development
S phase = DNA replication
G2 phase = growth and development
M phase = cell division
there are 3 checkpoints
first checkpoint = between G1 and S phase
second checkpoint = between S and G2 phase
third checkpoint = between G2 and M phase |
|
|
Term
| what is the point of having DNA binding domain on p53 - what is the point of this region activating transcription since this DNA that the p53 binds to is not even the target gene (damaged DNA)? |
|
Definition
the DNA binding domain as we know is the region where DNA binds to p53
we know that this DNA is not DNA of the target gene
this DNA is of some gene (i dont know what in particular) but binding to this DNA will in turn activate p21 gene to make p21 protein and this p21 protein will interact with CDK and this complex of p21 and CDK will cause cell cycle arrest so the p53 protein can repair whatever damage that has occurred on the damaged DNA
|
|
|
Term
| T/F: checkpoints are not available in cancer cells |
|
Definition
True:
there are no checkpoints available in cancer cells
so this allows cancer cells to become immortal (keep dividing) b/c there is no regulation of the cell cycle |
|
|
Term
| which proteins are essential for progression of cell cycle from G1 to S phase? |
|
Definition
cyclin E + CDK2
cyclin D + CDK4
cyclin D + CDK6 |
|
|
Term
| what are the steps leading to the repairing of damaged DNA in terms of G1 phase? |
|
Definition
1) damaged DNA activates p53 = transcriptional activator of p21
2) p21 gene into p21 proteins
3) inhibits all the cyclins (cyclin D and E) from binding to their respective CDKs (CDK 2,4,6) so CDK cannot function and causes cell cycle arrest
4) G1 phase cannot proceed to S phase anymore
5) given enough time of this cell cycle arrest, DNA damage repair will occur |
|
|
Term
| T/F: CDKs can only function when they are bound to p53 |
|
Definition
False:
first of all, CDK are not bound to p53
CDK can only function when they are bound to cyclin** hence named cyclin-dependent kinases |
|
|
Term
| what do CDK phosphorylate? |
|
Definition
CDKs phosphorylate cell cycle regulatory proteins
we know that CDK/cyclin complexes are important for cell cycle progression and we know kinases (like CDK) phosphorylate things so CDK will of course phosphorylate proteins that are cell cycle regulatory proteins |
|
|
Term
| T/F: CDKs are more important in cell cycle progression while cyclins are more important in cell cycle arrest |
|
Definition
False:
first of all, it should be obvious that CDKs do not function without being bound to cyclins so CDK/cyclin complexes are important in both cell cycle progression and cell cycle arrest, not just CDK |
|
|
Term
| why are CDKs called serine/threonine kinases? |
|
Definition
we know that CDKs are kinases meaning that they phosphorylate things
well it turns out that CDKs in particular phoshporylate amino acid residues serine and threonine therefore CDKs are called serine/threonine kinases |
|
|
Term
| what is the activity of CDK kinase dependent on? |
|
Definition
it depends on what kind of a kinase the CDK is bound to
for example: if CDK2,4,6 are bound to cyclin D and E, then the CDK/cyclin complex regulate G1/S checkpoint of the cell cycle |
|
|
Term
which gene binds to cyclin D?
which gene binds to cyclin E?
which gene binds to cyclin A?
|
|
Definition
p21, p27, p57, and p16 bind to cyclin D and E
p21 and p27 bind to cyclin A |
|
|
Term
| does cell cycle arrest mean that the cell cycle stops at that particular phase and cannot go ahead anymore? |
|
Definition
yes and no
cell cycle arrest does mean that the cell cycle stops at a particular phase (wherever the cell cycle arrest took place) BUT this is only for a given period of time - in other words, once that time is over, the cell cycle will continue progression and go on |
|
|
Term
| what are all the inhibitors of cyclins/CDK? inhibitors meaning p21 etc |
|
Definition
there are 5 things:
p21, p27, p57, p16, and cyclin G1 |
|
|
Term
which inhibitors are part of the Cip family?
which are part of the Kip family? |
|
Definition
p21 is part of the Cip family
p27, p57, and p16 are part of the Kip family |
|
|
Term
| which inhibitors are non-p53 mediated? |
|
Definition
p21, p27, p57, and p16
dunno this one
|
|
|
Term
| if inhibitors are non-p53 mediated, what activates their transcription if p53 doesn't? |
|
Definition
| the inhibitors that are non-p53 mediated use transcription factor smad proteins |
|
|
Term
| which inhibitors are p53-mediated? |
|
Definition
|
|
Term
| what are kip1, kip2, WAF, and CDK4i? |
|
Definition
kip1 = p27
kip2 = p57
WAF = p21
CDK4i = p16 (i = inhibitor) |
|
|
Term
| what are Bcl-xL and Bcl-2 proteins? |
|
Definition
| these are anti-apoptotic proteins - they tell the cell to not die |
|
|
Term
| what will make Bcl-2 and Bcl-xL non-functional? |
|
Definition
recall that these two proteins are anti-apoptotic proteins meaning they will tell the cell to not die
in order to make them non-functional (ie. so the cell does die), PUMA protein has to bind to them |
|
|
Term
| in our notes, he talks about one way of killing cells (apoptosis). what is that? |
|
Definition
| making the mitochondrial membrane permeable so there is release of cytochrome c enzyme into the cytoplasm leading to eventual cell death b/c no ATP is generated so the cell can't do any work |
|
|
Term
| there are two mechanisms by which cell death can occur in terms of mitochondrial membrane permeabilization. generally speaking, what are the two mechanisms? |
|
Definition
1) PUMA protein beinds to Bcl-2 and Bcl-xL making these two proteins non-functional causing mitochondrial membrane permeabilization
2) PUMA protein causing p53 to be removed from Bcl-xL so p53 can activate Bax and induce mitochondrial membrane permeabilization |
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Term
| T/F: PUMA protein causes p53 to be removed from Bcl-2 protein |
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Definition
False:
PUMA protein causes p53 to be removed from Bcl-xL protein not Bcl-2 protein |
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Term
| PUMA protein induces apoptosis induced by both ________ and _______ |
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Definition
| nuclear p53 and cytoplasmic p53 |
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Term
how does p53 function when PUMA protien mediates apoptosis induced by nuclear p53?
how does p53 function when PUMA protein mediates apoptosis induced by cytoplasmic p53? |
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Definition
1) nuclear p53 - p53 functions as transcriptional activator making PUMA proteins which can bind to Bcl-2 and Bcl-xL and making them non-functional
2) cytoplasmic p53 - PUMA displaces cytoplasmic p53 from Bcl-xL, allowing p53 to activate Bax and cause cell death |
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Term
| what exactly happens to the mitochondrial membrane leading to cell death? |
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Definition
| if PUMA binds Bcl-2 and Bcl-xL, PUMA makes them nonfunctional - this causes the mitochondrial membrane to become permeable - this permeability causes reduction of membrane potential - this causes release of cytochrome c enzyme into the cytoplasm - this activates caspase 3 and 9 - this causes decreased expression of pro-caspase 3 - this causes increased expression of caspase-3 and caspase-9 - this causes cleavage of poly(ADP-ribose) polymerase (PARP) - and cleavage of PARP is theh hallmark of the induction of apoptotic response |
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Term
| how do we cause in vivo activation of p53 pathway? |
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Definition
we do this by taking a small molecule antagonist of Mdm2**
we know that mdm2 has a p53 binding domain which is the place where p53 binds and this binding causes mdm2 to inactivate or kill p53 (proteolytic degradation)
but if p53 is inactivated or killed then p53 cannot repair or kill cancer cells - we want lots of p53 in the body
so in in vivo activation of p53, just so p53 cannot bind to mdm2 protein, we place another antagonist so that way, p53 survives and can kill cancer cells |
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Term
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Definition
| nutlins are small molecule antagonists that bind to p53 binding domain on mdm2 proteins so p53 cannot bind |
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Term
| T/F: nutlins only bind to mdm2 proteins and not p53 proteins |
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Definition
True:
nutlins bind to the p53 binding domain on mdm2 proteins |
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