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. 1975 Apr;55(4):720–726. doi: 10.1104/pp.55.4.720

Regulation of Ribulose 1,5-Diphosphate Carboxylase by Substrates and Other Metabolites

Further Evidence for Several Types of Binding Sites 1

Douglas K Chu a,2, James A Bassham a
PMCID: PMC541693  PMID: 16659154

Abstract

Ribulose 1,5-diphosphate carboxylase (RuDPCase, EC 4.1.1.39) isolated from spinach leaves is metabolically regulated at 10 mm Mg2+ and low CO2 concentrations by its substrates (RuDP and CO2) and by effectors which include 6-phosphogluconate (6-PGluA), NADPH, and fructose 1,6-diphosphate (FDP), but not fructose 6-phosphate. Physiological concentrations of RuDP severely inhibit the enzyme activity when the enzyme has not been preincubated with HCO3 and Mg2−, and this inactivity persists for 20 minutes or longer after 1 mm HCO3 and 10 mm Mg2+ are added. Maximum activity requires that the preincubation mixture also include either 0.01 mm 6-PGluA or 0.5 mm NADPH.

When the enzyme, following preincubation with HCO3 and Mg2+, is presented with RuDP plus either 6-PGluA or FDP, competitive inhibition is observed with respect to RuDP. The Ki value for 6-PGluA is 0.02 mm and the Ki value for FDP is 190 μm. NADPH or 3-phosphoglycerate (PGA) at physiological concentrations does not have any effect when presented simultaneously with RuDP. Other studies on the order of addition of substrates and effectors, concentration effects, and kinetics provide additional information that serves as a basis for a proposed model of allosteric regulation combined with competitive inhibition.

In this model, there are catalytic sites at which the substrates and 6-PGluA and FDP can bind, and at least four allosteric regulatory sites, which we designate I, A1, A2, and A3. RuDP binds very tightly to site I (in the absence of Mg2+ or HCO3), causing a conformational change in the protein to an inactive form which persists for as long as 20 minutes in the subsequent presence of Mg2+ and 1 mm HCO3. Mg2+ and HCO3 (or CO2) bind to site A3 (in the absence of RuDP), holding the enzyme in an active form which has a much lower affinity for RuDP at site I, so that when physiological levels of RuDP are then added, only part of the enzyme activity is lost. This active form of the enzyme can bind 6-PGluA or FDP at site A1 and NADPH at site A2 during preincubation with Mg2+ and HCO3. With optimal levels of bound effectors, 6-PGluA or NADPH, enzyme activity is fully maintained, even when RuDP is subsequently added. Without one of these effectors present, addition of RuDP following preincubation reduces enzyme activity to about 40% at the levels of substrates and effectors studied. FDP is a much poorer effector, and this is ascribed to a possible binding of FDP at site I, as well as at site A1.

The physiological role of this regulation is discussed, particularly with respect to protection of “C-3” plants against oxidation of RuDP to phosphoglycolate.

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Selected References

These references are in PubMed. This may not be the complete list of references from this article.

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