Linear control analysis of the autocatalytic glycolysis system

Author

Chandra, Fiona A. ; Buzi, Gentian ; Doyle, John C.

Author_Institution

Dept. of Bioeng., California Inst. of Technol., Pasadena, CA, USA

fYear

2009

fDate

10-12 June 2009

Firstpage

319

Lastpage

324

Abstract

Autocatalysis is necessary and ubiquitous in both engineered and biological systems but can aggravate control performance and cause instability. We analyze the properties of autocatalysis in the universal and well studied glycolytic pathway. A simple two-state model incorporating ATP autocatalysis and inhibitory feedback control captures the essential dynamics, including limit cycle oscillations, observed experimentally. System performance is limited by the inherent autocatalytic stoichiometry and higher levels of autocatalysis exacerbate stability and performance. We show that glycolytic oscillations are not merely a ldquofrozen accidentrdquo but a result of the intrinsic stability tradeoffs emerging from the autocatalytic mechanism. This model has pedagogical value as well as appearing to be the simplest and most complete illustration yet of Bode´s integral formula.

Keywords

control system analysis; feedback; linear systems; modelling; stability; Bode´s integral formula; autocatalysis; autocatalytic glycolysis; autocatalytic mechanism; autocatalytic stoichiometry; glycolytic oscillation; glycolytic pathway; inhibitory feedback control; intrinsic stability; limit cycle oscillation; linear control analysis; two-state model; Biological control systems; Biological system modeling; Biological systems; Control system analysis; Control systems; Feedback control; Limit-cycles; Stability; System performance; Systems engineering and theory;

fLanguage

English

Publisher

ieee

Conference_Titel

American Control Conference, 2009. ACC '09.

Conference_Location

St. Louis, MO

ISSN

0743-1619

Print_ISBN

978-1-4244-4523-3

Electronic_ISBN

0743-1619

Type

conf

DOI

10.1109/ACC.2009.5159925

Filename

5159925