TY - JOUR

T1 - Single Enzyme Studies Reveal the Existence of Discrete Functional States for Monomeric Enzymes and How They Are “Selected” upon Allosteric Regulation

A1 - Hatzakis,Nikos S.

A1 - Wei,Li

A1 - Jørgensen,Sune Klamer

A1 - Kunding,Andreas Hjarne

A1 - Bolinger,Pierre-Yves

A1 - Ehrlich,Nicky

A1 - Makarov,Ivan

A1 - Skjot,Michael

A1 - Svendsen,Allan

A1 - Hedegård,Per

A1 - Stamou,Dimitrios

AU - Hatzakis,Nikos S.

AU - Wei,Li

AU - Jørgensen,Sune Klamer

AU - Kunding,Andreas Hjarne

AU - Bolinger,Pierre-Yves

AU - Ehrlich,Nicky

AU - Makarov,Ivan

AU - Skjot,Michael

AU - Svendsen,Allan

AU - Hedegård,Per

AU - Stamou,Dimitrios

PB - American Chemical Society

PY - 2012

Y1 - 2012

N2 - Allosteric regulation of enzymatic activity forms the basis for controlling a plethora of vital cellular processes.<br/>While the mechanism underlying regulation of multimeric enzymes is generally well understood and proposed to<br/>primarily operate via conformational selection, the mechanism underlying allosteric regulation of monomeric enzymes is<br/>poorly understood. Here we monitored for the first time allosteric regulation of enzymatic activity at the single molecule<br/>level. We measured single stochastic catalytic turnovers of a monomeric metabolic enzyme (Thermomyces lanuginosus<br/>Lipase) while titrating its proximity to a lipid membrane that acts as an allosteric effector. The single molecule measurements revealed the existence of discrete binary functional states that could not be identified in macroscopic measurements due to ensemble averaging. The discrete functional states correlate with the enzyme’s major conformational states and are redistributed in the presence of the regulatory effector. Thus, our data support<br/>allosteric regulation of monomeric enzymes to operate via selection of preexisting functional states and not via induction of ones.

AB - Allosteric regulation of enzymatic activity forms the basis for controlling a plethora of vital cellular processes.<br/>While the mechanism underlying regulation of multimeric enzymes is generally well understood and proposed to<br/>primarily operate via conformational selection, the mechanism underlying allosteric regulation of monomeric enzymes is<br/>poorly understood. Here we monitored for the first time allosteric regulation of enzymatic activity at the single molecule<br/>level. We measured single stochastic catalytic turnovers of a monomeric metabolic enzyme (Thermomyces lanuginosus<br/>Lipase) while titrating its proximity to a lipid membrane that acts as an allosteric effector. The single molecule measurements revealed the existence of discrete binary functional states that could not be identified in macroscopic measurements due to ensemble averaging. The discrete functional states correlate with the enzyme’s major conformational states and are redistributed in the presence of the regulatory effector. Thus, our data support<br/>allosteric regulation of monomeric enzymes to operate via selection of preexisting functional states and not via induction of ones.

UR - http://pubs.acs.org/doi/abs/10.1021/ja3011429

U2 - 10.1021/ja3011429

DO - 10.1021/ja3011429

JO - Journal of the American Chemical Society

JF - Journal of the American Chemical Society

SN - 0002-7863

IS - 22

VL - 134

SP - 9296

EP - 9302

ER -