Checkpoint control Flashcards
what 2 processes does the genetic material of daughter cells depend on? what happens if these processes go wrong and how do cells avoid this?
- the faithful replication of the mother cell’s genome is S phase
- the proper allocation of the resulting duplicated DNA to the daughter cells during M phase
defects in either of these processes can lead to cancer, so cells must use checkpoints to ensure successful duplication
what are cell cycle checkpoints?
Surveillance mechanisms to monitor each step of the cell cycle progression
- Cells are allowed to proceed with the cell cycle only if the pre-requisite step has been completed successfully
what does the checkpoint trigger if the cell has not completed a phase successfully?
Halt to further advance until the problems have been addressed:
- If the error is fixed, the cells can progress
- If the error isn’t fixed, cells undergo apoptosis
what are the 5 key cell cycle checkpoints?
- R
- G1/S checkpoint
- S-phase checkpoint
- G2/M checkpoint
- spindle assembly checkpoint
what does the G1/S checkpoint ensure?
A cell will not be permitted to enter S-phase if the genome needs repair due to DNA damage
- Prevents duplication of faulty DNA
what does the S-phase checkpoint ensure?
DNA replication will be paused in response to DNA damage (this can cause the doubling of the time required to complete DNA synthesis) – extension of S phase duration
what does the G2/M checkpoint ensure?
A cell will not proceed through G2 to M until the DNA replication of S phase has been completed & entrance in M phase is blocked if the DNA is damaged
- If duplication has been delayed in S phase due to damage, cells will not progress until all DNA has been synthesised
what does the spindle assembly checkpoint ensure?
A cell is not permitted to enter anaphase until all of its chromosomes are properly assembled on the mitotic spindle during metaphase
how do cancer cells progress through the cell cycle, despite having faulty DNA?
by inactivating the checkpoints
how does cancer have a proliferative advantage?
The increased mutability of the genome provides cancer cells with proliferative advantage:
- incompatible with normal cell cycle progression
- checkpoint controls block advance through the cell cycle if DNA has been damaged
- In addition to acquiring activated oncogenes and inactivated TSGs, cancer cells have inactivated one or more checkpoint controls
what protein controls the R point?
Rb protein (pRb)
what is pRb?
pRb is the molecular governor of the R point
- expressed by the Rb tumour suppressor gene
- nuclear phosphoprotein
- undergoes phosphorylation to control cell cycle progression
how is pRb regulated at the R point?
pRb is regulated by phosphorylation:
- phosphorylation of pRb is regulated as cells progress through the cycle
- if pRb is active, cells do not go through the R point
- for cells to proliferate, pRb must be inactivated, and inactivation is induced by phosphorylation
what is the key role of pRb?
to prevent cells progressing through the R point
-it is a tumour suppressor
how is pRb inactivated? what does this enable?
pRb is inactivated by hyperphosphorylation:
- this means that cells can now progress through the R point and proliferate
what must occur to pRb for cells to progress through the R point?
Cells can go through the R point only if pRb becomes INACTIVATED through hyperphosphorylation: pRb = guardian of the R point gate
what regulates the phosphorylation of pRb?
the cyclin/CDK complexes
how do cyclin/CDK complexes regulate pRb phosphorylation in G1?
Early and mid-G1: in presence of mitogens, cyclin D and CDK4/6 initiate pRb hypophosphorylation (low phosphorylation level):
- Not enough to fully inactivate pRb and progress through R
- Hypophosphorylation is necessary but not sufficient for pRb inactivation
Cyclin E levels increase at the R-point:
- cyclin E/CDK2 mediate pRb hyperphosphorylation
- Enough to inactivate pRb and progress through cell cycle
What does pRb phosphorylation release to control the progression from G1 into S phase?
Unphosphorylated/hypophosphorylated pRb binds to E2Fs (transcription factors), while it dissociates from E2Fs when hyperphosphorylated
- Early and mid G1: hypophosphorylated pRb binds to E2Fs, preventing the transcription of E2F-dependent genes (E2F is sequestered)
- R point: pRb hyperphosphorylation means pRb cannot bind to E2F -> E2Fs are released -> transcription of genes mediating G1/S transition
- E2F active transcription is short-lived
why is E2F transcription at the R point short-lived?
they remain active for short time as they are only needed to enable cells to enter S-phase
- their activity must be inhibited soon after the cells have entered S
how is E2F transcription inhibited after the G1/S transition?
as the cells undergo G1/S transition, cyclin A/CDK2 inhibit the transcriptional activity of E2Fs, which are targeted for degradation by ubiquitination
how is cell cycle progression ensured to occur in one direction?
Via positive feedback mechanisms - irreversibility of the cell cycle ensures unidirectional advancement and rapid excecution
what positive feedback mechanisms ensure the unidirectional advancement of the cell cycle progression?
- when E2Fs are activated, they promote cyclin E expression:
- increased cyclin E results in increased CDK2 activation, which leads to the further hyperphosphorylation of pRb
- hyperphosphorylated pRb then release even more E2Fs (positive feedback loop) - when cyclin E/CDK2 complex is active, they phosphorylate the CKI p27Kip1, leading to the CKIs inactivation and degradation:
- this means more E/CDK2 is released from inhibition
how is pRb implicated in cancer?
it is a tumour suppressor gene which is inactivated in cancer
- this means that cells cannot be inhibited from progressing through the R point, as E2F is constantly active
what are the 3 main mechanisms of pRb inactivation in cancer?
- RB1 mutation
- Inactivation of pRb by deregulated hyperphosphorylation
- interaction with viral protein
how does RB1 mutation lead to pRb inactivation in cancer?
RB1 mutations – pRb can no longer inhibit E2F, so cell cycle progression is constantly active
- The rate of RB1 gene mutations varies significantly among different tumour types, but is highest in retinoblastoma, osteosarcoma and small cell lung cancer.
- Mutations targeting the RB1 gene directly affect pRb function by either completely abrogating its expression or by producing a non-functional protein.
how does deregulated pRb hyperphosphorylation lead to its inactivation in cancer?
if pRb is constantly hyperphosphorylated, it can no longer bind and sequester E2F, meaning E2F is now constitutively active and can promote continuous cell cycle progression and proliferation
how does interaction with viral proteins lead to pRb inactivation in cancer?
E7 produced by human papilloma virus displaces E2F from pRb, so E2F is no longer sequestered and can promote cell cycle progression
- leads to uncontrolled cell proliferation in cervical cancers
what cyclins are implicated in pRb inactivation in cancer?
cyclin D and cyclin E are often overexpressed in tumours, leading to pRb phosphorylation and inactivation
- this drives cell proliferation and tumour formation
why are cyclins difficult pharmacological targets? how has this been overcome?
they have no kinase activity and they are located intracellularly:
- many CDK inhibitors have been developed and are now in clinical trials -these will have a knock-on effect in inhibiting cyclins
- Promising results from in vitro and mouse studies of different cancer types
what is Palbociclib?
a selective inhibitor of CDK4 and CDK6 by competing with ATP
- CDK4/6 inhibitor
- thus it inhibits cyclin D-dependent kinase activity = therapeutic value as anti-cancer treatment
- inhibits breast cancer cell growth in vitro without affecting normal cells
why is Palbociclib (CDK4/6 inhibitor) limited?
CDK4/6 inhibitor resistance developed
- All patients with metastatic disease will develop resistance, via 3 main mechanisms
what were the 3 main mechanisms in which metastatic cancer developed resistance against CDK4/6 inhibitor (Palbociclib)?
- activation of upstream effectors
- inactivating mutations in pRb and overexpression of CDK6
- cell cycle progresses regardless of CDK4/6 - downstream bypass pathways
- cyclin E overexpression causing cyclin E/CDK2 activation, which phosphorylates and inactivates pRb
what genes did Palbociclib-resistant cells overexpress?
Overexpression of cyclin E (CCNE1) and cMyc was observed in CDK4/6 inhibitor-resistant cells:
- MYC-over-expressing cells are able to grow in the presence of CDK4/6i (Palbociclib)
- Resistant cells overexpress myc, so increase cyclin E expression
- Palbocyclib treatment -> increased Myc expression -> increased cyclin E activation
what treatment was developed to overcome Palbociclib-resistant cancer cells?
CDK2/4/6 inhibitor called PF3600:
- CDK2 inhibitor used as it will inhibit cyclin E overexpression seen in the resistant cells
- Cyclin E-overexpressing tumours are resistant to CDK4/6i (palbociclib), but sensitive to CDK2/4/6i (PF3600)
how was PF3600 developed? what is the limitation of this method?
using patient-derived xenografts (PDX):
- tumours extracted from patient and injected into mice
- tumours will form in the mice which can be treated with different drugs
limitation: Animal must be immunocompromised for injection of patient tissue into mouse
what is taxol?
antimitotic therapy used for cancer to induce DNA damage
