Model of IP3 and Ca2+ oscillations: Frequency encoding and identification of underlying feedbacks

¹ Humboldt University Berlin
² University of Medicine and Dentistry of New Jersey

^* To whom correspondence should be addressed. E-mail: thomas.hoefer{at}rz.hu-berlin.de.

Submitted on August 29, 2005
Revised on October 7, 2005
Accepted on 26 January 2006

	Abstract

Hormones that act through the calcium-releasing messenger, inositol 1,4,5-trisphosphate (IP₃), cause intracellular calcium oscillations, which have been ascribed to calcium feedbacks on the IP₃ receptor. Recent studies have shown that IP₃ levels oscillate together with the cytoplasmic calcium concentration. To investigate the functional significance of this phenomenon, we have developed mathematical models of the interaction of both second messengers. The models account for both positive and negative feedbacks of calcium on IP₃ metabolism, mediated by calcium activation of phospholipase C and IP₃ 3-kinase, respectively. The coupled IP₃ and calcium oscillations have a greatly expanded frequency range compared to calcium fluctuations obtained with clamped IP₃. Therefore the feedbacks can be physiologically important in supporting the efficient frequency encoding of hormone concentration observed in many cell types. This action of the feedbacks depends on the turnover rate of IP₃. To shape the oscillations, positive feedback requires fast IP₃ turnover, whereas negative feedback requires slow IP₃ turnover. The ectopic expression of an IP₃ binding protein has been used to decrease the rate of IP₃ turnover experimentally, resulting in a dose-dependent slowing and eventual quenching of the Ca²⁺ oscillations. These results are consistent with a model based on positive feedback of Ca²⁺ on IP₃ production.

Key Words: IP₃ buffer, IP₃ metabolism, bifurcation analysis, calcium signaling, feedback regulation, mathematical modeling

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