Qu, MacLellan, Weiss, 2003

Model Status

This CellML version of the model has been checked in COR and PCEnv and the model runs to replicate the results in the original published paper. The units have been checked and are consistent.

Model Structure

ABSTRACT: We have developed a generic mathematical model of a cell cycle signaling network in higher eukaryotes that can be used to simulate both the G1/S and G2/M transitions. In our model, the positive feedback facilitated by CDC25 and wee1 causes bistability in cyclin-dependent kinase activity, whereas the negative feedback facilitated by SKP2 or anaphase-promoting-complex turns this bistable behavior into limit cycle behavior. The cell cycle checkpoint is a Hopf bifurcation point. These behaviors are coordinated by growth and division to maintain normal cell cycle and size homeostasis. This model successfully reproduces sizer, timer, and the restriction point features of the eukaryotic cell cycle, in addition to other experimental findings.

The complete original paper reference is cited below:

Dynamics of the Cell Cycle: Checkpoints, Sizers, and Timers, Zhilin Qu, W. Robb MacLellan, James N. Weiss, 2003, Biophysical Journal , 85, 3600-3611. (A PDF version of the article is available to subscribers on the journal website.) PubMed ID: 14645053

Signaling networks for cyclin and CDK regulation.
SKP2 regulation.
APC/CDC20 regulation.

Please note that equation 2 on page 3604 of the paper describing the cell size is not included in the CellML description.

Source
Derived from workspace Qu, Maclellan, Weiss, 2003 at changeset 864a5672c293.
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