Functional differences between dimeric and octameric mitochondrial creatine kinase

Abstract

Mitochondrial creatine kinase (Mi-CK) consists of octameric and dimeric molecules that are interconvertible. In the present study, the kinetic properties of purified chicken heart Mi-CK (Mib-CK) dimers and octamers were investigated separately under highly controlled conditions. Gel-permeation chromatography was performed before and after kinetic measurements in order to clearly define the proportions of octamers and dimers. ‘Dimeric’ Mi-CK solutions consisted of > or = 90% dimers throughout the experiment whereas ‘octameric’ Mi-CK solutions consisted in the beginning of 90% octamers, but upon measuring with the highest concentrations of creatine (Cr) and ATP approximately one-third of the octamers dissociated into dimers. These proper controls enabled us to pinpoint the observed kinetic differences between dimers and octamers solely to the oligomeric state of Mib-CK. Both dimeric and octameric Mi-CK displayed synergism in substrate binding (Kd values are higher than Km values), meaning that binding of the first substrate facilities subsequent binding of the second substrate. Most interestingly, Km(Cr) and Kd(Cr) values are both 2-3 times higher for octameric than for dimeric Mi-CK. Thus, at low Cr concentrations, the dimer is kinetically favoured for the forward direction of the reaction (phosphorylcreatine synthesis) compared with the octamer. The possible physiological significance of the lower Kd(Cr) value of dimeric versus octameric Mib-CK, as well as the apparent negative cooperativity of ATP binding at higher [Cr], are discussed within the context of a possible functional role for dimeric Mib-CK in vivo.