Chapter 17: Cell Proliferation

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17.5:

Inhibición de la actividad de los CDK

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Molecular Biology
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JoVE Core Molecular Biology
Inhibition of Cdk Activity
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17.4: Positive Regulator Molecules

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During cell cycle transitions, Cdk activity is regulated by multiple proteins, ensuring controlled cell growth, complete DNA replication, and mitotic distribution of the chromosomes to daughter cells. In the absence of regulatory proteins, an abnormal cell goes unchecked, leading to conditions such as cancer. In a normal cell, Cdk activity is regulated through multiple mechanisms including cyclin degradation, inhibitory phosphorylation, and inhibitory conformational changes induced by Cdk inhibitor binding. Cyclin levels are known to fluctuate during the cell cycle. Cdks are only active when bound to cyclin, therefore, cyclin degradation leaves Cdks inactive and unable to promote the transition to the next cell cycle stage. In another mechanism, a kinase named Wee1, phosphorylates the active site in Cdk.  This phosphorylation inhibits the activity of the cyclin-Cdk complex. Additionally, Cdk inhibitors or CKIs, such as p16, p21, and p27, regulate Cdk activity through inhibitory conformational changes. For instance, if DNA damage occurs during G1, p16 interacts with the cyclin-Cdk complex. This interaction causes a large structural rearrangement, detaching the bound cyclin, causing Cdk inactivation.  DNA damage in the G1 phase can also trigger the tumor suppressor protein, p53, to activate p21. G1/S-Cdk and S-Cdk complexes are bound and inhibited by p21, arresting the cells in the G1 phase, and allowing enough time for DNA repair. For the G1/S phase transition to take place, the cell is required to have all the resources needed for DNA replication. If the cell lacks the necessary resources, p27 binds to G1/S-Cdk and S-Cdk complexes, inhibiting the enzyme activity. Once favorable conditions for cell cycle progression are met, p27 is degraded, restoring Cdk activity and promoting cell transition.
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17.5:

Inhibición de la actividad de los CDK

The orderly progression of the cell cycle depends on the activation of CDK protein by binding to its cyclin partner. However, the cell cycle must be restricted when the cell undergoes abnormal changes. Most cancers correlate to the deregulated cell cycle, and since CDKs are a central component of the cell cycle, the CDK inhibitors are extensively studied to develop anticancer agents. For instance, cyclin D associates with several CDKs, such as CDK 4/6, to form an active complex. The cyclin D-CDK4/6 complex then phosphorylates and inactivates the tumor suppressor retinoblastoma protein (Rb) to promote the G1-to-S phase transition of the cell cycle. In normal cells, Rb protein is reactivated through the regulation of CDK activity, thus, preventing abnormal cell cycle transitions.

There are at least three known mechanisms by which CDK activity is regulated- cyclin degradation, inhibitory phosphorylation, or binding of inhibitory proteins. Mutations that prevent these mechanisms lead to CDK-mediated tumorigenesis.

Because CDK 4/6 plays a substantial role in tumor formation, several CDK inhibitors have been developed for clinical use. The most recent ones are selective for CDK4 and CDK6. There are at least three clinically approved CDK 4/6 inhibitors: abemaciclib, ribociclib, and palbociclib. These inhibitors bind to the ATP pocket of CDK 4 and 6, inactivating the Cyclin D-CDK4/6 complexes, leading to Rb protein activation and subsequent cell cycle arrest. In some cases, the inhibitor-mediated  cell cycle arrest causes an increase in apoptosis in tumor cells.

Inhibition of the cell cycle and subsequent programmed cell death are the most common mechanisms of CDK4/6 inhibitors. However, a recent study in mouse models of breast cancer showed that CDK4/6 inhibition could also lead to severe immunogenic effects. During the study, the CDK inhibitor seemed to enhance tumor cells' antigen-presenting ability, thereby allowing cytotoxic T cells to recognize and destroy the tumor cells.

Suggested Reading

  1. Carnero, A. "Targeting the cell cycle for cancer therapy." British journal of cancer 87, no. 2 (2002): 129-133.
  2. Law, Mary E., Patrick E. Corsino, Satya Narayan, and Brian K. Law. "Cyclin-dependent kinase inhibitors as anticancer therapeutics." Molecular  Pharmacology 88, no. 5 (2015): 846-852.

Tags

Cdk ActivityCell CycleCyclin PartnerCdk InhibitorsAnticancer AgentsCyclin D-Cdk4/6 ComplexRetinoblastoma Protein (Rb)G1-to-S Phase TransitionRb Protein ReactivationCyclin DegradationInhibitory PhosphorylationInhibitory ProteinsCdk-mediated TumorigenesisCdk4/6 InhibitorsAbemaciclibRibociclibPalbociclibATP Pocket