The Dissociation and Reconstitution of Aldolase<sup>*</sup>

Stellwagen, Earle; Schachman, H. K.

doi:10.1021/bi00912a016

Cited by 208 publications

(69 citation statements)

References 46 publications

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“…However, the fact that the sedimentation rate seemed to increase stepwise with time of chase makes this possibility unlikely. The sedimentation rate of the ␣ form was similar to that of aldolase (data not shown), which has a sedimentation coefficient of 7.4 S (Stellwagen and Schachman, 1962); that of secreted ␣ 1 I 3 is 8.6 S (Esnard and Gauthier, 1980).…”

Section: Resultssupporting

confidence: 54%

Posttranslational Folding of α1-Inhibitor 3

Wassler

Esnard

Fries

1995

Journal of Biological Chemistry

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␣ 1 -Inhibitor 3 (␣ 1 I 3 ) is a rodent-specific proteinase inhibitor of about 190 kDa belonging to the ␣ 2 -macroglobulin family. It consists of five globular domains, three of which are connected by disulfide bridges, and contains an intramolecular thiol ester which can react with attacking proteinases. To explore the folding of newly synthesized ␣ 1 I 3 , we have used rat hepatocytes and pulsechase experiments. In one of the analyses, the radiolabeled protein was isolated from cell lysates by immunoprecipitation and its Asp-Pro bonds cleaved by treatment with formic acid. The size of the major fragment, as assessed by electrophoresis under nonreducing conditions, was found to increase from 100 to 150 kDa upon the chasing. This result, together with knowledge of the positions of the cleavage sites and the disulfide arrangement, indicates that one of the interdomain disulfide bonds is formed after the synthesis of the polypeptide. Analysis of the same material by limited proteolysis and by velocity centrifugation showed that the folded regions became larger and that the protein became more compact; the thiol ester was found to be formed after these conformational changes. These results suggest that the domains of ␣ 1 I 3 are only partially developed directly after the synthesis of the polypeptide and that they acquire their final structure as the protein condenses and the domains interact with one another.

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Section: Resultssupporting

confidence: 54%

Posttranslational Folding of α1-Inhibitor 3

Wassler

Esnard

Fries

1995

Journal of Biological Chemistry

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“…The methyl ester and acetate (10 M acetate/ 1 M diumycin) of diumycin aggregate in aqueous buffer with molecular weights of 32,000 and 38,000 daltons, respectively (Table I). The stability of the 32,000-dalton aggregate under these conditions indicates that ionic forces (noncovalent interactions between polar groups), including salt linkages (14,15) and hydrogen bonds (16,17), contribute only slightly to stabilize the 32,000-dalton aggregate. Some involvement of ionic forces is indicated by the molecular weight of 17,000 daltons in 5 M NaC14.02 M phosphate buffer (pH 6.85) and the higher concentration of the 65,000-dalton aggregate than the 32,000-dalton aggregate at pH 2.2 and 4.05 (Table I) (Table I); (b) the inability of a lipidless diumycin to aggregate ( Table I); and (c) the increasing efficacy of alcohols as disaggregating agents as the length of their hydrocarbon portion increases (Table I).…”

Section: Resultsmentioning

confidence: 96%

“…Vinylpyridine-vinylpyrrolidone copolymers-synthesis 0 Equilibrium dialysis-copolymer-p-toluene sulfonic acid sodium interaction Binding sites-copolymer-p-toluene sulfonate ions Urea effect-alkyl copolymer binding sulfonate ions UV spectrophotometry-identity During the past 3 decades, several interactions have been reported which involved binding of drugs by plasma proteins; notable examples are penicillins (I), sulfonamides (2-5), methyl orange (6-7), and shortand long-chain fatty acids (8)(9)(10)(11)(12)(13)(14). In connection with these binding studies, it has been reported that the interactions primarily take place through ionic forces, but a further contribution to the stability of proteindrug complex is made by the hydrophobic part of a drug molecule.…”

Section: Keyphrasesmentioning

confidence: 99%

Intermolecular Bonding of the Antibiotic Diumycin

Kirschbaum

Slusarchyk

Weisenborn

1970

Journal of Pharmaceutical Sciences

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“…Enzymically active intermediates formed during reactivation are selectively labilized in the presence of 2.3 M urea [4,24] or at elevated temperature [25,26]. This observation in connection with the concentration dependence and sigmoidicity of the reactivation kinetics after treatment with 2.3 M urea [4] suggest precursors of the final tetrameric product of refolding to be active.…”

Section: Discussionmentioning

confidence: 99%

Kinetics of Refolding and Reactivation of Rabbit‐Muscle Aldolase after Acid Dissociation

Rudolph¹,

Engelhard²,

Jaenicke³

1976

European Journal of Biochemistry

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Tetrameric rabbit muscle aldolase has been dissociated to the monomer at pH 2.3 and fully reassociated and reactivated at pH 7.6.Kinetics of reactivation and refolding were followed by slow and fast kinetic techniques after neutralization of the acidic enzyme solutions by dilution or rapid mixing. Rate constants (k), reaction orders (n), and activation energies ( E ) were calculated from measurements on the time, concentration, and temperature dependence of the reactions. The experimental results prove reactivation at high enzyme concentration (c > 4 pg/ml) to obey first-order kinetics; at lower concentrations a transition to a higher reaction order is observed. Because of concentration-dependent deactivation at low enzyme concentrations reactivation measurements could not be extended below c x 0.5 pg/ml. In the accessible concentration range incomplete separation of reassociation and transconformation processes as well as intrinsic residual activity of the isolated subunits lead to an average value of n = 1.40 f 0.18.Renaturation as monitored by protein fluorescence is a multi-step process composed of a fast increase in fluorescence emission (first-order rate constant k FZ 15 s-') and a slow concentrationdependent decrease which parallels the recovery of enzyme activity (n = 1.46 ? 0.12). The activation energy of both processes is of the order of E = 12-16 kcal/mol (50-67 kJ/mol). Reassociation is a prerequisite of full catalytic function and native fluorescence.In the preceding paper [l] equilibrium studies on the reversible dissociation, denaturation, and deactivation of rabbit muscle aldolase were reported. As shown by ultracentrifugation, spectroscopy, and optical tests the three processes run parallel although different conformational markers reflect different structural changes. In the pH-range of dissociation the accompanying conformational changes and the respective deactivation represent true equilibria. After separation of an irreversibly denatured fraction of the renatured enzyme, the product of reassociation turns out to be indistinguishable from the enzyme in its initial native state. The aforementioned results are the basis of the following kinetic analysis since the significance of an investigation of the mechanism by which the nascent polypeptide chain folds into its specific conformation depends on whether or to which degree the initial and final states in the dissociation/reassociation processes are comparable.The aim of the following kinetic experiments is to determine the order of the refolding and reactivation Abbreviation. c, enzyme concentration. Enzyme. Rabbit muscle aldolase or fructose 1,6-bisphosphate : o-glyceraldehyde 3-phosphate lyase (EC 4.1.2.13).reactions and to calculate the respective rate constants over the whole time range from the rapid elementary processes to the slow reshuffling of the native conformation.Comparison of the data of reactivation and renaturation may answer the question whether the subunits of aldolase possess full enzymic activity or not [2-81. On the other...

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The Dissociation and Reconstitution of Aldolase^*

Cited by 208 publications

References 46 publications

Posttranslational Folding of α1-Inhibitor 3

Posttranslational Folding of α1-Inhibitor 3

Intermolecular Bonding of the Antibiotic Diumycin

Kinetics of Refolding and Reactivation of Rabbit‐Muscle Aldolase after Acid Dissociation

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The Dissociation and Reconstitution of Aldolase*

Cited by 208 publications

References 46 publications

Posttranslational Folding of α1-Inhibitor 3

Posttranslational Folding of α1-Inhibitor 3

Intermolecular Bonding of the Antibiotic Diumycin

Kinetics of Refolding and Reactivation of Rabbit‐Muscle Aldolase after Acid Dissociation

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The Dissociation and Reconstitution of Aldolase^*