Cell cycle checkpoint
Cell cycle checkpoints are control mechanisms in eukaryotic cells which ensure proper division of the cell. Each checkpoint serves as a potential point along the cell cycle, during which the conditions of the cell are assessed, with progression through the various phases of the cell cycle occurring when favorable conditions are met. Currently, there are three known checkpoints: the G1 checkpoint, also known as the restriction or start checkpoint or (Major Checkpoint); the G2/M checkpoint; and the metaphase checkpoint, also known as the spindle checkpoint.
Contents
1 Background
2 G1 (restriction) checkpoint
3 G2 checkpoint
4 Metaphase checkpoint
5 Cancer
6 See also
7 References
Background
All living organisms are the products of repeated rounds of cell growth and division.[1] During this process, known as the cell cycle, a cell duplicates its contents and then divides in two. The purpose of the cell cycle is to accurately duplicate each organism's DNA and then divide the cell and its contents evenly between the two resulting cells. In eukaryotes, the cell cycle consists of four main stages: G1, during which a cell is metabolically active and continuously grows; S phase, during which DNA replication takes place; G2, during which cell growth continues and the cell synthesizes various proteins in preparation for division; and the M (mitosis) phase, during which the duplicated chromosomes (known as the sister chromatids) separate into two daughter nuclei, and the cell divides into two daughter cells, each with a full copy of DNA.[2] Compared to the eukaryotic cell cycle, the prokaryotic cell cycle (known as binary fission) is relatively simple and quick: the chromosome replicates from the origin of replication, a new membrane is assembled, and the cell wall forms a septum which divides the cell into two.[3]
As the eukaryotic cell cycle is a complex process, eukaryotes have evolved a network of regulatory proteins, known as the cell cycle control system, which monitors and dictates the progression of the cell through the cell cycle.[1] This system acts like a timer, or a clock, which sets a fixed amount of time for the cell to spend in each phase of the cell cycle, while at the same time it also responds to information received from the processes it controls. The cell cycle checkpoints play an important role in the control system by sensing defects that occur during essential processes such as DNA replication or chromosome segregation, and inducing a cell cycle arrest in response until the defects are repaired.[4] The main mechanism of action of the cell cycle checkpoints is through the regulation of the activities of a family of protein kinases known as the cyclin-dependent kinases (CDKs), which bind to different classes of regulator proteins known as cyclins, with specific cyclin-CDK complexes being formed and activated at different phases of the cell cycle. Those complexes, in turn, activate different downstream targets to promote or prevent cell cycle progression.[5]
G1 (restriction) checkpoint
The G1 checkpoint, also known as the restriction point in mammalian cells and the start point in yeast, is the point at which the cell becomes committed to entering the cell cycle. As the cell progresses through G1, depending on internal and external conditions, it can either delay G1, enter a quiescent state known as G0, or proceed past the restriction point.[1] DNA damage is the main indication for a cell to "restrict"and not enter the cell cycle. The decision to commit to a new round of cell division occurs when the cell activates cyclin-CDK-dependent transcription which promotes entry into S phase.[6]
During early G1, there are three transcriptional repressors, known as pocket proteins, that bind to E2F transcription factors. The E2F gene family is a group of transcription factors that target many genes that are important for control of the cell cycle, including cyclins, CDKs, checkpoint regulators, and DNA repair proteins. Misregulation of the E2F family is often found in cancer cases, providing evidence that the E2F family is essential for the tight regulation of DNA replication and division.[6] The three pocket proteins are Retinoblastoma (Rb), p107, and p130, which bind to the E2F transcription factors to prevent progression past the G1 checkpoint.
The E2F gene family contains some proteins with activator mechanisms and some proteins with repressing mechanisms. P107 and p130 act as co-repressors for E2F4 and E2F5, which work to repress transcription of G1-to-S promoting factors. The third pocket protein, Rb, binds to and represses E2F1, E2F2, and E2F3, which are the E2F proteins with activating abilities.[6]
Positive feedback plays an essential role in regulating the progression from G1 to S phase, particularly involving the phosphorylation of Rb by a Cyclin/CDK protein complex. Rb without a phosphate, or unphosphorylated Rb, regulates G0 cell cycle exit and differentiation. During the beginning of the G1 phase, growth factors and DNA damage signal for the rise of cyclin D levels, which then binds to Cdk4 and Cdk6 to form the CyclinD:Cdk4/6 complex.[7] This complex is known to inactivate Rb by phosphorylation. However, the details of Rb phosphorylation are quite complex and specific compared to previous knowledge about the G1checkpoint. Cyclin:Cdk4/6 places only one phosphate, or monophosphorylates, Rb at one of its’s fourteen accessible and unique phosphorylation sites. Each of the fourteen specific mono-phosphorylated isoforms has a differential binding preference to E2F family members, which likely adds to the diversity of cellular processes within the mammalian body.[7]
E2F4 and E2F 5 are dependent on p107 and p130 to maintain their nuclear localization. However, Cyclin D:Cdk 4/6 also phosphorylates p107 and p130, a process which releases their bind from E2F4 and 5 (which then escape to the cytoplasm), and allowing for E2F1-3 to bind to the DNA and initiate transcription of Cyclin E.[6] Rb proteins maintain their mono-phosphorylated state during early G1 phase, while Cyclin E is accumulating and binding to Cdk2.
CyclinE:Cdk2 plays an additional important phosphorylation role in the G1-to-S transition. Particularly, CyclinE:Cdk2 promotes a positive feedback loop which creates and “all or nothing” switch. In many genetic control networks, positive feedback ensures that cells do not slip back and forth between cell cycle phases [8] Cyclin E:Cdk2 proceeds to phosphorylate Rb at all of its phosphorylation sites, also termed “hyper-phosphorylate”, which ensures complete inactivation of Rb. The hyper phosphorylation of Rb is considered the late G1 restriction point, after which the cell cannot go backwards in the cell cycle. At this point, E2F 1-3 proteins bind to DNA and transcribe Cyclin A and Cdc 6.[7]
Cyclin-dependent kinase inhibitor 1B (CDKN1B), also known as p27, binds to and prevents the activation of CyclinE:Cdk2 by inhibition. However, as Cyclin A accumulates and binds to Cdk2, they form and complex and inhibit p27. The G1 phase cyclin-dependent kinase works together with S phase cyclin-dependent kinase target p27 for degradation. In turn, this allows for full activation of Cyclin A:Cdk2, a complex which phosphorylates E2F1-3 initiating their disassociation from the DNA promoter sites. This allows E2F 6-8 to bind to the DNA and inhibit transcription.[6] The negative feedback loop used to successfully inhibit the inhibitor, p27, is another essential process used by cells to ensure mono-directional movement and no backtrack through the cell cycle.
When DNA damage occurs, or when the cell detects any defects which necessitate it to delay or halt the cell cycle in G1, arrest occurs through several mechanisms. The rapid response involves phosphorylation events that initiate with either kinase ATM (Ataxia telangiectasia mutated) or ATR (Ataxia Telangiectasia and Rad3 related), which act as sensors, depending on the type of damage. These kinases phosphorylate and activate the effector kinases Chk2 and Chk1, respectively, which in turn phosphorylate the phosphatase Cdc25A, thus marking it for ubiquitination and degradation. As Cdc25A activates the previously mentioned cyclin E-CDK2 complex by removing inhibitory phosphates from CDK2, in the absence of Cdc25A, cyclin E-CDK2 remains inactive, and the cell remains in G1.
To maintain the arrest, another response is initiated, by which Chk2 or Chk1 phosphorylate p53, a tumor suppressor, and this stabilizes p53 by preventing it from binding Mdm2, a ubiquitin ligase which inhibits p53 by targeting it for degradation. The stable p53 then acts a transcriptional activator of several target genes, including p21, an inhibitor of the G1-to-S promoting complex cyclin E-CDK2. In addition, another mechanism by which p21 is activated is through the accumulation of p16 in response to DNA damage. p16 disrupts cyclin D-CDK4 complexes, thus causing the release of p21 from the complexes, which leads to the dephosphorylation and activation of Rb, which allows Rb to bind and inhibit E2F1-3, thus keeping the cell from transitioning to S phase.[9] Recently, some aspects of this model have been disputed.[10]
G2 checkpoint
Following DNA replication in S phase, the cell undergoes a growth phase known as G2. During this time, necessary mitotic proteins are produced and the cell is once more subjected to regulatory mechanisms to ensure proper status for entry into the proliferative Mitotic (M) phase. Multiple mechanistic checkpoints are involved in this transition from G2 to M, with a common uniting factor of cyclin-Cdk activity.
Although variations in requisite cyclin-Cdk complexes exist across organisms, the necessity of the kinase activity is conserved and typically focuses on a single pairing. In fission yeast three different forms of mitotic cyclin exist, and six in budding yeast, yet the primary cyclin utilized is cyclin B.[11] Cyclin B will serve as reference for discussion of the G2/M checkpoint transition.
Similar to S Phase, G2 experiences a DNA damage checkpoint. The cell is once more examined for sites of DNA damage or incomplete replication, and the kinases ATR and ATM recruited to damage sites. Activation of Chk1 and Chk2 also transpire, as well as p53 activation, to induce cell cycle arrest and halt progression into mitosis. An additional component of S phase, the Pre-Replicative Complex, must be inactivated via cyclin B-Cdk1 phosphorylation.[12]
As these previous checkpoints are assessed, G2 protein accumulation serves to activate cyclinB-Cdk1 activity via multiple mechanisms. CyclinA-Cdk2 activates Cdc25, an activator of cyclinB-Cdk1, which then deactivates the cyclinB-Cdk1 inhibitor, Wee1. This results in a positive feedback loop, significantly increasing cyclinB expression and Cdk1 activation. As the cell progresses through G2 and reaches the G2/M transition, the kinase Plk1 phosphorylates Wee1, which targets Wee1 for degradation via the SCF ubiquitin ligase complex.[13] An additional function of Plk1 is to activate Cdc25 through phosphorylation. The compound effect of Wee1 degradation and Cdc25 activation is the net removal of inhibitory phosphorylation from cdc2, which activates cdc2. Plk1 is activated at the G2/M transition by the Aurora A and Bora, which accumulate during G2 and form an activation complex. The Plk1-Cdc2-cdc25 complex then initiates a positive feedback loop which serves to further activate Cdc2, and in conjunction with an increase in cyclin B levels during G2, the resulting cdc2-cyclin B complexes then activate downstream targets which promote entry into mitosis.[14] The resultant Cdk1 activity also activates expression of Mem1-Fkh, a G2/M transition gene.[15] The rapid surge in cyclinB-Cdk1 activity is necessary, as M phase initiation is an all-or-nothing event engaging in hysteresis. Hysteresis of Cdk1 activity via cyclin B drives M phase entry by establishing a minimum threshold of cyclinB concentration. This exists at a level higher than the minimum needed for the continuation of M phase after entry, acting to safeguard the all-or-nothing event. This entry concentration is further increased in the case of incomplete DNA replication, adding another regulatory mechanism at the G2/M transition point.[16] The presence of hysteresis allows for M phase entry to be highly regulated as a function of cyclinB-Cdk1 activity.
The mechanisms by which mitotic entry is prevented in response to DNA damage are similar to those in the G1/S checkpoint. DNA damage triggers the activation of the aforementioned ATM/ATR pathway, in which ATM/ATR phosphorylate and activate the Chk1/Chk2 checkpoint kinases. Chk1/2 phosphorylate cdc25 which, in addition to being inhibited, is also sequestered in the cytoplasm by the 14-3-3 proteins. 14-3-3 are upregulated by p53, which, as previously mentioned, is activated by Chk1 and ATM/ATR. p53 also transactivates p21, and both p21 and the 14-3-3 in turn inhibit cyclin B-cdc2 complexes through the phosphorylation and cytoplasmic sequestering of cdc2. In addition, the inactivation of cdc25 results in its inability to dephosphorylate and activate cdc2.[17][18] Finally, another mechanism of damage response is through the negative regulation of Plk1 by ATM/ATR, which in turn results in the stabilization of Wee1 and Myt1, which can then phosphorylate and inhibit cdc2, thus keeping the cell arrested in G2 until the damage is fixed.[19]
Metaphase checkpoint
The mitotic spindle checkpoint occurs at the point in metaphase where all the chromosomes should/have aligned at the mitotic plate and be under bipolar tension. The tension created by this bipolar attachment is what is sensed, which initiates the anaphase entry. To do this, the sensing mechanism ensures that the anaphase-promoting complex (APC/C) is no longer inhibited, which is now free to degrade cyclin B, which harbors a D-box (destruction box), and to break down securin.[20] The latter is a protein whose function is to inhibit separase, which in turn cuts the cohesins, the protein composite responsible for cohesion of sister chromatids.[21] Once this inhibitory protein is degraded via ubiquitination and subsequent proteolysis, separase then causes sister chromatid separation.[22] After the cell has split into its two daughter cells, the cell enters G1.
Cancer
DNA repair processes and cell cycle checkpoints have been intimately linked with cancer due to their functions regulating genome stability and cell progression, respectively. The precise molecular mechanisms that connect dysfunctions in these pathways to the onset of particular cancers are not well understood in most cases.[23]
The loss of ATM has been shown to precede lymphoma development presumably due to excessive homologous recombination, leading to high genomic instability.[24] Disruption of Chk1 in mice led significant misregulation of cell cycle checkpoints, an accumulation of DNA damage, and an increased incidence of tumorigenesis.[25] Perhaps most famously, single mutant inheritance of BRCA1 or BRCA2 predisposes women toward breast and ovarian cancers.[26] BRCA1 is known to be required for S and G2/M transitions, and is involved in the cellular response to DNA damage. BRCA2 is believed to be involved in homologous recombination and regulating the S-phase checkpoint, and mutations of deficiencies in BRCA2 are strongly linked to tumorigenesis.[27]
See also
- Biochemical switches in the cell cycle
- Cell cycle analysis
- G2-M DNA damage checkpoint
- Postreplication checkpoint
- Meiotic recombination checkpoint
References
^ abc al.], Julian Lewis ... [et (2007). Molecular biology of the cell (5th ed.). New York: Garland Science. ISBN 9780815341055..mw-parser-output cite.citation{font-style:inherit}.mw-parser-output .citation q{quotes:"""""""'""'"}.mw-parser-output .citation .cs1-lock-free a{background:url("//upload.wikimedia.org/wikipedia/commons/thumb/6/65/Lock-green.svg/9px-Lock-green.svg.png")no-repeat;background-position:right .1em center}.mw-parser-output .citation .cs1-lock-limited a,.mw-parser-output .citation .cs1-lock-registration a{background:url("//upload.wikimedia.org/wikipedia/commons/thumb/d/d6/Lock-gray-alt-2.svg/9px-Lock-gray-alt-2.svg.png")no-repeat;background-position:right .1em center}.mw-parser-output .citation .cs1-lock-subscription a{background:url("//upload.wikimedia.org/wikipedia/commons/thumb/a/aa/Lock-red-alt-2.svg/9px-Lock-red-alt-2.svg.png")no-repeat;background-position:right .1em center}.mw-parser-output .cs1-subscription,.mw-parser-output .cs1-registration{color:#555}.mw-parser-output .cs1-subscription span,.mw-parser-output .cs1-registration span{border-bottom:1px dotted;cursor:help}.mw-parser-output .cs1-ws-icon a{background:url("//upload.wikimedia.org/wikipedia/commons/thumb/4/4c/Wikisource-logo.svg/12px-Wikisource-logo.svg.png")no-repeat;background-position:right .1em center}.mw-parser-output code.cs1-code{color:inherit;background:inherit;border:inherit;padding:inherit}.mw-parser-output .cs1-hidden-error{display:none;font-size:100%}.mw-parser-output .cs1-visible-error{font-size:100%}.mw-parser-output .cs1-maint{display:none;color:#33aa33;margin-left:0.3em}.mw-parser-output .cs1-subscription,.mw-parser-output .cs1-registration,.mw-parser-output .cs1-format{font-size:95%}.mw-parser-output .cs1-kern-left,.mw-parser-output .cs1-kern-wl-left{padding-left:0.2em}.mw-parser-output .cs1-kern-right,.mw-parser-output .cs1-kern-wl-right{padding-right:0.2em}
^ Cooper, Geoffrey M. (2000). The cell : a molecular approach (2nd ed.). Washington (DC): ASM Press. ISBN 0-87893-106-6.
^ al.], Harvey Lodish ... [et (2000). Molecular cell biology (4th ed.). New York: Scientific American Books. ISBN 0-7167-3136-3.
^ Malumbres, Marcos; Barbacid, Mariano (March 2009). "Cell cycle, CDKs and cancer: a changing paradigm". Nature Reviews Cancer. 9 (3): 153–166. doi:10.1038/nrc2602. PMID 19238148.
^ Vermeulen, Katrien; Van Bockstaele, Dirk R.; Berneman, Zwi N. (June 2003). "The cell cycle: a review of regulation, deregulation and therapeutic targets in cancer". Cell Proliferation. 36 (3): 131–149. doi:10.1046/j.1365-2184.2003.00266.x.
^ abcde Bertoli, Cosetta; Skotheim, Jan M.; de Bruin, Robertus A. M. (23 July 2013). "Control of cell cycle transcription during G1 and S phases". Nature Reviews Molecular Cell Biology. 14 (8): 518–528. doi:10.1038/nrm3629. PMC 4569015. PMID 23877564.
^ abc Narasimha, Anil M; Kaulich, Manuel; Shapiro, Gary S (4 June 2014). "Cyclin D activates the Rb tumor suppressor by mono-phosphorylation". eLife. doi:10.7554/eLife.02872.
^ Skotheim, Jan M.; Di Talia, Stefano; Siggia, Eric D.; Cross, Frederick R. (17 July 2008). "Positive feedback of G1 cyclins ensures coherent cell cycle entry". Nature. 454 (7202): 291–296. doi:10.1038/nature07118. PMC 2606905. PMID 18633409.
^ Bartek, Jiri; Lukas, Jiri (December 2001). "Mammalian G1- and S-phase checkpoints in response to DNA damage". Current Opinion in Cell Biology. 13 (6): 738–747. doi:10.1016/S0955-0674(00)00280-5.
^ Bertoli, Cosetta; de Bruin, Robertus Antonius Maria (1 July 2014). "Turning cell cycle entry on its head". eLife. 3. doi:10.7554/eLife.03475.
^ Morgan, David (2007). The Cell Cycle Principles of Control. New Science Press. pp. 92–95.
^ Morgan, David (2007). The Cell Cycle Principles of Control. New Science Press. pp. 228–229.
^ Guardavaccaro, Daniele; Pagano, Michele (April 2006). "Stabilizers and Destabilizers Controlling Cell Cycle Oscillators". Molecular Cell. 22 (1): 1–4. doi:10.1016/j.molcel.2006.03.017. PMID 16600864.
^ Seki, A.; Coppinger, J. A.; Jang, C.-Y.; Yates, J. R.; Fang, G. (20 June 2008). "Bora and the Kinase Aurora A Cooperatively Activate the Kinase Plk1 and Control Mitotic Entry". Science. 320 (5883): 1655–1658. doi:10.1126/science.1157425. PMC 2834883. PMID 18566290.
^ Morgan, David (2007). The Cell Cycle Principles of Control. New Science Press. pp. 44–45, 90.
^ Sha, Wei; et al. (September 2002). "Hysteresis drives cell-cycle transitions in Xenopus laevis egg extracts". Proceedings of the National Academy of Sciences. 100: 975–980. doi:10.1073/pnas.0235349100. PMC 298711.
^ Wang, Yingmei; Ji, Ping; Liu, Jinsong; Broaddus, Russell R; Xue, Fengxia; Zhang, Wei (2009). "Centrosome-associated regulators of the G2/M checkpoint as targets for cancer therapy". Molecular Cancer. 8 (1): 8. doi:10.1186/1476-4598-8-8.
^ Löbrich, Markus; Jeggo, Penny A. (November 2007). "The impact of a negligent G2/M checkpoint on genomic instability and cancer induction". Nature Reviews Cancer. 7 (11): 861–869. doi:10.1038/nrc2248. PMID 17943134.
^ Harper, J. Wade; Elledge, Stephen J. (December 2007). "The DNA Damage Response: Ten Years After". Molecular Cell. 28 (5): 739–745. doi:10.1016/j.molcel.2007.11.015. PMID 18082599.
^ Peters, Jan-Michael (1998). "SCF and APC: the Yin and Yang of cell cycle regulated proteolysis". Current Opinion in Cell Biology. 10 (6): 759–68. doi:10.1016/S0955-0674(98)80119-1. PMID 9914180.
^ Ciosk, Rafal; Zachariae, Wolfgang; Michaelis, Christine; Shevchenko, Andrej; Mann, Matthias; Nasmyth, Kim (1998). "An ESP1/PDS1 Complex Regulates Loss of Sister Chromatid Cohesion at the Metaphase to Anaphase Transition in Yeast". Cell. 93 (6): 1067–76. doi:10.1016/S0092-8674(00)81211-8. PMID 9635435.
^ Karp, Gerald (2005). Cell and Molecular Biology: Concepts and Experiments (4th ed.). Hoboken, New Jersey: John Wiley and Sons. pp. 598–9. ISBN 0-471-16231-0.
^ Kastan, MB; Bartek, J (18 November 2004). "Cell-cycle checkpoints and cancer". Nature. 432 (7015): 316–23. doi:10.1038/nature03097. PMID 15549093.
^ Shiloh, Y; Kastan, MB (2001). "ATM: genome stability, neuronal development, and cancer cross paths". Advances in cancer research. 83: 209–54. doi:10.1016/s0065-230x(01)83007-4. PMID 11665719.
^ Lam, Michael H; Liu, Qinghua; Elledge, Stephen J; Rosen, Jeffrey M (July 2004). "Chk1 is haploinsufficient for multiple functions critical to tumor suppression". Cancer Cell. 6 (1): 45–59. doi:10.1016/j.ccr.2004.06.015. PMID 15261141.
^ King, MC; Marks, JH; Mandell, JB; New York Breast Cancer Study, Group (24 October 2003). "Breast and ovarian cancer risks due to inherited mutations in BRCA1 and BRCA2". Science. 302 (5645): 643–6. doi:10.1126/science.1088759. PMID 14576434.
^ Venkitaraman, AR (25 January 2002). "Cancer susceptibility and the functions of BRCA1 and BRCA2". Cell. 108 (2): 171–82. doi:10.1016/s0092-8674(02)00615-3. PMID 11832208.