Simple and reliable protocols are described for an extensive analysis of metabolites in extracts from different biological sources. The separation was performed by high performance ionic-exchange ...chromatography (HPIC) at alkaline pH using two types of chromatography columns and two detection methods. Organic acids and inorganic anions were separated on an ionPac AS11 column using a 0.5 to 35 mM Na0H gradient. Detection limits in the range of milligrams per liter were achieved by use of a conductivity detector equipped with an anion self-regenerating suppressor. Twelve phosphorylated compounds belonging to the glycolytic and the pentose phosphate pathways could be resolved on a CarboPac PA1 column using a Na0H/Na-acetate gradient. Quantification was achieved by pulsed amperometry with detection limits in the micromolar range. Cell extracts obtained by extraction in boiling buffered ethanol described previously could be directly injected onto HPIC columns for the separation of metabolites because the extraction procedure affected neither the retention time nor the stability of most of the metabolites, and yielded very clean chromatograms. These improved protocols were applied for a dynamic analysis of intracellular metabolites in Saccharomyces cerevisiae in response to a glucose pulse.
Yeast phosphofructo-1-kinase (Pf1k) and pyruvate kinase (Pyk1) are allosterically regulated enzymes that catalyse essentially irreversible reactions in glycolysis. Both the synthesis and activity of ...these enzymes are tightly regulated. To separate experimentally the control of Pf1k and Pyk1 synthesis from their allosteric regulation, a congenic set of PFK1, PFK2 and PYK1 mutants was constructed in which these wild-type coding regions were driven by alternative promoters. Mutants carrying PGK1 promoter fusions displayed normal rates of growth, glucose consumption and ethanol production, indicating that the relatively tight regulation of Pyk1 and Pf1k synthesis is not essential for glycolytic control under fermentative growth conditions. Mutants carrying fusions to an enhancer-less version of the PGK1 promoter (PGK1(Delta767)) expressed Pyk1 and Pf1k at about 2.5-fold lower levels than normal. Physiological and metabolic analysis of the PFK1 PFK2 double mutant indicated that decreased Pf1k had no significant effect on growth, apparently due to compensatory increases in its positive effector, fructose 2,6-bisphosphate. In contrast, growth rate and glycolytic flux were reduced in the PGK1(Delta767)-PYK1 mutant, which had decreased Pyk1 levels. Unexpectedly, the reduced Pyk1 levels caused the flow of carbon to the TCA cycle to increase, even under fermentative growth conditions. Therefore, Pyk1 exerts a significant level of control over both the rate and direction of carbon flux in yeast.