O2-triggered changes of membrane fatty acid composition have no effect on Arrhenius discontinuities of respiration in sycamore (Acer pseudoplatanus L.) cells.

Abstract

Sycamore cells (Acer pseudoplatanus L.) in suspension culture were grown at 25 degrees C in culture medium containing two oxygen concentrations: 250 microM O2 (standard conditions) and 10 microM O2 (O2-limiting conditions). The decrease of O2 concentration in the culture medium did not modify significantly the relative proportion of each phospholipid. In contrast, the molar proportion of fatty acids was dramatically changed in all lipid classes of the cell membranes; the average percentage of oleate increased from 3 to 45% whereas that of linoleate decreased from 49 to 22%. When normal culture conditions were restored (250 microM O2), oleate underwent a rapid desaturation process; the loss of oleic acid was associated with a stoichiometric appearance of linoleic acid at a rate of about 4 nmol of oleate desaturated/h/10(6) cells. Under these conditions, no change in the Arrhenius-type plots of the rate of sycamore cell respiration was observed; the values of the transition temperature and of the Arrhenius activation energy (Ea) associated with the cell respiration as well as with the respiration-associated enzymes remained unchanged. Thus it was concluded that the fact that a strong decrease in the fraction of unsaturated fatty acid residues present in the mitochondria had no effect on electron transport rates and Arrhenius plot discontinuities casts doubt on the significance of such changes in terms of chilling injury. Finally it is suggested that some of the Arrhenius discontinuities observed at the level of membrane enzyme could be the consequence of intrinsic thermotropic changes in protein arrangement independent of lipid fluidity.