Tre~lo~6-phosphate (P) ~mpetitively inhibited the hexokinases from ~~cc~omyee~ cerevisiae. The strongest inhibition was observed upon hexokinase II, with a K, of 40 FM, while in the case of hexoklnase I the K, was 200 NM. Glucokinase was not inhibited by trehalose-6-P up to 5 mM. This inhibition appears to have physiological significance, since the intracellular levels of trehalose-6-P were about 0.2 mM. Hexokinases from other organisms were also inhibited, while glucokinases were unaffected. The hexokinase from the yeast, Yarrowia iipolytica, was particularly sensitive to the inhibition by trehalose-6-P: when assayed with 2 mM fructose an apparent K, of 5 PM was calculated. Two 5. cerevisiae mutants with abnormal levels of trehalose-6-P exhibited defects in glucose metabolism. It is concluded that trehalose-6-P plays an important role in the regulation of the first steps of yeast glycolysis, mainly through the inhibition of hexokinase II.Trehalose-6-phosphate; Hexokinase; Glycolysis; Yeast
PRODUCTIONControl of the glycolytic flux in Succhurowryces cerevisicze has been considered to occur mainly at the level of phosphofructokinase and pyruvate kinase. Phosphofructokinase is regulated through activation by fructose-2,6-bisphosphate, phosphate (P) and AMP, and inhibition by ATP, while pyruvate kinase activity is modulated by its activation by fructose-l,(i-bisphosphate (for a review see [l]). However, since phosphof~~tokinase does not catalyze the first irreversible step in the utilization of glucose, its regulation is not sufficient to control the rate of glucose utilization, and thus some mechanism should exist to regulate the rate of glucose transport, phosphorylation, or both. Regulation of glucose transport by glucose-6-P was suggested by Sols [2], but experimental results obtained using mutants affected in phosphoglucose isomerase activity did not support this idea [3,4]. Besides, none of the yeast kinases that phosphorylate glucose are sensitive to glucose-6-P, in contrast with the mammalian hexokinase
PI-The need for a regulation of the first steps of yeast glycolysis is illustrated by the pattern of ambulation of metabolites in certain yeast mutants upon addition of glucose [6-81. Yeast strains carrying the mutations fdpl [6] or cifl [7] do not grow on glucose, although the glycolytic enzymes are operative. These mutations turned out to be allelic [9], and strains bearing them become depleted of ATP upon addition of glucose and accumulate fructose-l ,6-bisphosphate up to 20 mM [6,7,10], suggesting that the rate of the first glycolytic steps exceeds the capacity of the glycolytic pathway. The sequence of the CIFZ gene [lo] encodes the small subunit of the trehalose-6-P synthase/trehalose-6-P phosphatase complex [ 11,123. A plausible explanation for the growth behaviour and the metabolic defects of cifl strains could be that either trehalose or trehalose-6-P play a role in the regulation of the yeast glycolytic flux. We show in this article that trehalose-6-P inhibits sugar phospho~lation.The stron~st inh...
