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The self-inhibitory nature of metabolic networks and its alleviation through compartmentalization

M. T. Alam ; V. Olin-Sandoval ; A. Stincone ; M. A. Keller ; Aleksej Zelezniak (Institutionen för biologi och bioteknik, Systembiologi) ; B. F. Luisi ; M. Ralser
Nature Communications (2041-1723). Vol. 8 (2017), p. Article no 16018.
[Artikel, refereegranskad vetenskaplig]

Metabolites can inhibit the enzymes that generate them. To explore the general nature of metabolic self-inhibition, we surveyed enzymological data accrued from a century of experimentation and generated a genome-scale enzyme-inhibition network. Enzyme inhibition is often driven by essential metabolites, affects the majority of biochemical processes, and is executed by a structured network whose topological organization is reflecting chemical similarities that exist between metabolites. Most inhibitory interactions are competitive, emerge in the close neighbourhood of the inhibited enzymes, and result from structural similarities between substrate and inhibitors. Structural constraints also explain one-third of allosteric inhibitors, a finding rationalized by crystallographic analysis of allosterically inhibited L-lactate dehydrogenase. Our findings suggest that the primary cause of metabolic enzyme inhibition is not the evolution of regulatory metabolite-enzyme interactions, but a finite structural diversity prevalent within the metabolome. In eukaryotes, compartmentalization minimizes inevitable enzyme inhibition and alleviates constraints that self-inhibition places on metabolism.

Nyckelord: Pyruvate-Kinase, Fructose 2,6-Bisphosphate, Lactate-Dehydrogenase, Triosephosphate Isomerase, Bacillus-Subtilis, Escherichia-Coli, Yeast, Glycolysis, Enzyme Function, Genome, Substrate

Denna post skapades 2017-08-14. Senast ändrad 2017-08-21.
CPL Pubid: 251081


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Institutioner (Chalmers)

Institutionen för biologi och bioteknik, Systembiologi


Biokemi och molekylärbiologi

Chalmers infrastruktur