An analysis of the kinetic positions held by five enzymes of carbohydrate metabolism in Dictyostelium discoideum

Construction of kinetic models to understand metabolism in vivo

This review describes increasingly complex kinetic models that simulate carbohydrate metabolism in a simple eucaryotic system which undergoes differentiation. Dynamic models of complex metabolic networks serve to organize and analyze the many interdependent variables involves and to define the rate-limiting events controlling metabolism in vivo. Since the ultimate justification for and test of any model are its predictive values, a series of predictions and related experiments will be described.

Fourth expansion and glucose perturbation of the Dictyostelium kinetic model

The kinetic model of carbohydrate metabolism has been expanded to include: (a) the accumulation of alpha and beta-cellulose, insoluble cell-wall glycogen and mucopolysaccharide; (b) the role of RNA turnover as a source of carbon for end-product synthesis and as a buffer regulating the level of uridine nucleotides in this metabolic network; and (c) the role of purine-nucleoside phosphorylase, 5'-AMP nucleotidase, nucleosidediphosphate kinase and polynucleotide phosphorylase. One of many predictions based on this model is that cells differentiating in the presence of glucose will produce sorocarps with an abnormally high trehalose to cellulose ratio. External perturbation of either the model or of developing cells by glucose increases the levels of sorocarp trehalose and glycogen, 5-fold and 6-fold respectively. Evaluation of the experimental data and the simulation analyses have allowed several predictions to be made concerning the compartmentation of metabolites and the permeability of cells to glucose during differentiation.