A kinetic and ligand binding study on maize (Zea mays) malate synthase is presented. It is concluded from kinetic measurements that the enzyme proceeds through a ternary-complex mechanism. Michaelis constants (Km,glyoxylate and Km,acetyl-CoA) were determined to be 104 microM and 20 microM respectively. C.d. measurements in the near u.v.-region indicate that a conformational change is induced in the enzyme by its substrate, glyoxylate. From these studies we are able to calculate the affinity for the substrate (Kd,glyoxylate) as 100 microM. A number of inhibitors apparently trigger the same conformational change in the enzyme, i.e. pyruvate, glycollate and fluoroacetate. Another series of inhibitors bearing more bulky groups and/or an extra carboxylic acid also induce a conformational change, which is, however, clearly different from the former one. Limited proteolysis with trypsin results in cleavage of malate synthase into two fragments of respectively 45 and 19 kDa. Even when no more intact malate synthase chains are present, the final enzymic activity still amounts to 30% of the original activity. If trypsinolysis is performed in the presence of acetyl-CoA, the cleavage reaction is appreciably slowed down. The dissociation constant for acetyl-CoA (Kd,acetyl-CoA) was calculated to be 14.8 microM when the glyoxylate subsite is fully occupied by pyruvate and 950 microM (= 50 x Km) when the second subsite is empty. It is concluded that malate synthase follows a compulsory-order mechanism, glyoxylate being the first-binding substrate. Glyoxylate triggers a conformational change in the enzyme and, as a consequence, the correctly shaped binding site for acetyl-CoA is created. Demetallization of malate synthase has no effect on the c.d. spectrum in the near u.v.-region. Moreover, glyoxylate induces the same spectral change in the absence of Mg2+ as in its presence. Nevertheless, malate synthase shows no activity in the absence of the cation. We conclude that Mg2+ is essential for catalysis, rather than for the structure of the enzyme's catalytic site.
The role of Mg# + in the structure and activity of maize isocitrate lyase has been studied by CD, limited proteolysis, protection by ligands against inactivation, and activity measurements at various metal concentrations. From CD and trypsinolysis experiments, the existence of high-affinity binding sites for Mg# + was demonstrated, and a K dME of 200 µM was determined. Both free enzyme (E) and enzyme molecules with high-affinity sites occupied (ME) are catalytically competent, the former showing 40 % of the activity of the latter. Mg# + thus acts as a non-essential activator. A second Mg# + -binding site with a K dMEM of 6 mM was revealed from protection experiments by increasing Mg# + concentrations against inactivation. From activity measurements at different
A purified 15,000-molecular-weight (Mr) Prague strain Rous sarcoma virus gag gene-coded structural protein, p15, was shown to enzymatically cleave the previously described 130,000 Mr feline sarcoma virus-coded polyprotein, Prl30. Cleavage products included proteins ranging in molecular weight from 12,000 to 110,000. The specificity of this cleavage reactivity was indicated by the fact that, under similar conditions, neither purified type C viral structural proteins nor nonviral proteins such as bovine serum albumin were cleaved to significant extents. Moreover, feline leukemia virus PrW5gag was efficiently cleaved, resulting in the generation of proteins of 30,000 (p30), 15,000 (p15), 12,000 (p12), and 10,000 (plO) Mr. Using enzymatically (p15) treated feline sarcoma virus Prl30 as starting material, we were able to purify a major 72,000 Mr cleavage product and to show it to contain the previously described feline sarcoma virus-coded nonstructural component.
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