Purification and physiological role of a peptide stabilizing factor of rat liver phosphofructokinase.

Abstract

A substance has been purified to apparent homogeneity from rat liver which, as previously reported (Dunaway, G. A., Jr., and Segal, H. L. (1974) Biochem. Biophys. Res. Commun. 56, 689-696), specifically stabilizes the major liver isozyme of phosphofructokinase (PFK-L2) against thermal inactivation and whose level in vivo changes in parallel with and in precedence to that of the enzyme. Molecular weight determinations gave values around 3,500. Evidence for the peptide nature of the factor includes its correspondence with ninhydrin-positive material on gel filtration and paper electrophoresis and its susceptibility to pronase. Electrophoretic behavior indicated at least one free amino group and several carboxyl groups. Amino acid analysis of the peptide yielded only glutamate, glycine, and half-cystine, in equimolar amounts. However, neither GSH nor GSSG have PFK-L2-stabilizing activity. No free sulfhydryl groups were present. Chemical analysis for tryptophan was also negative. The ultraviolet spectrum confirmed the absence of aromatic amino acids. The spectrum exhibited a characteristic peptide peak at 190 nm with no absorbance beyond 240 nm. The factor is unstable to storage in the cold except in the presence of glucose or dithiothreitol. Sucrose, fructose, and GSH were ineffective in this regard. It was slowly denatured by heat or reduced pH even in the presence of glucose. The factor was induced in fasted animals specifically by glucose, of the nutrients tested, and in diabetic animals by insulin. Induction by both glucose and insulin was blocked by cycloheximide and actinomycin. The time course of the glucose induction was the more rapid of the two with a marked overshoot to 3 times normal levels at 12 hours. Increased levels of the factor preceded the increased levels of PFK-L2 brought about by glucose or insulin administration. Native PFK-L2 was inactivated by lysosomal extracts, and this inactivation was strongly inhibited by the peptide factor. These results are in accord with the proposal that the peptide plays a role in regulating PFK-L2 turnover in vivo. The factor also activated the phosphofructokinase-catalyzed reaction by promoting fructose-6-P binding. This effect is analogous to that of AMP on the kinetics of the reaction; however, the factor effect was additive to that of AMP, and the factor did not reverse inhibition by excess ATP as does AMP. We postulate that the stabilizing factor affects an equilibrium between PFK-L2 conformers in favor of one more resistant to lysosomal and thermal inactivation and with greater affinity for fructose-6-P.