In distributive phosphorylation catalytic constants enable non-trivial dynamics

Conradi, Carsten; Mincheva, Maya

doi:10.1007/s00285-024-02114-8

J. Math. Biol.

2024

DOI: 10.1007/s00285-024-02114-8

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In distributive phosphorylation catalytic constants enable non-trivial dynamics

Carsten Conradi,

Maya Mincheva

Abstract: Ordered distributive double phosphorylation is a recurrent motif in intracellular signaling and control. It is either sequential (where the site phosphorylated last is dephosphorylated first) or cyclic (where the site phosphorylated first is dephosphorylated first). Sequential distributive double phosphorylation has been extensively studied and an inequality involving only the catalytic constants of kinase and phosphatase is known to be sufficient for multistationarity. As multistationarity is necessary for bi… Show more

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Empirically exploring the space of monostationarity in dual phosphorylation

Cai,

Himmelmann,

Ostermann

2024

J Math Chem

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The dual phosphorylation network provides an essential component of intracellular signaling, affecting the expression of phenotypes and cell metabolism. For particular choices of kinetic parameters, this system exhibits multistationarity, a property that is relevant in the decision-making of cells. Determining which reaction rate constants correspond to monostationarity and which produce multistationarity is an open problem. The system’s monostationarity is linked to the nonnegativity of a specific polynomial. A previous study by Feliu et al. provides a sufficient condition for monostationarity via a decomposition of this polynomial into nonnegative circuit polynomials. However, this decomposition is not unique. We extend their work by a systematic approach to classifying such decompositions in the dual phosphorylation network. Using this classification, we provide a qualitative comparison of the decompositions into nonnegative circuit polynomials via empirical experiments and improve on previous conditions for the region of monostationarity.

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Empirically exploring the space of monostationarity in dual phosphorylation

Cai,

Himmelmann,

Ostermann

2024

J Math Chem

View full text Add to dashboard Cite

show abstract

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In distributive phosphorylation catalytic constants enable non-trivial dynamics

Cited by 1 publication

References 29 publications

Empirically exploring the space of monostationarity in dual phosphorylation

Empirically exploring the space of monostationarity in dual phosphorylation

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