Structural properties of an active form of rabbit muscle phosphofructokinase

The quaternary structure of an active form of rabbit muscle phosphofructokinase was studied by sedimentation and electron microscopy. Active enzyme centrifugation studies at pH 7.0 and 23 +/- 1 degrees C showed that phosphofructokinase sediments as a single component with a sedimentation coefficient of 12.2 +/- 0.5 S. Identical results were obtained in two assay and three solvent systems. Boundary sedimentation studies of phosphofructokinase in the presence of 1.0 mM fructose 6-phosphate, 0.1 mM adenylyl imidodiphosphate at pH 7.0 and 23 +/- 1 degrees C were performed. The results showed that the sedimentation coefficient of phosphofructokinase remains constant within the range of protein concentration studied and assumes a value of 12.4 S. The molecular weights of the subunit and the 12.4 S component were measured by sedimentation equilibrium yielding values of 83,000 and 330,000 for the monomeric and polymeric species, respectively. It is, therefore, concluded that the active form of phosphofructokinase is indeed the tetrameric species. The structure of the phosphofructokinase tetramer was also studied by electron microscopy of negatively stained specimens. Particles identified as tetramers measured approximately 9 nm in diameter by 14 nm in length. The observed size and shape are consistent with the hydrodynamic measurements. Structural features within the tetramer were interpreted as due to the four individual subunits, each one approximately 4 X 6 X 6 nm in size, arranged with D2 symmetry.     

The mechanism of rabbit muscle phosphofructokinase at pH8.

The mechanism of rabbit muscle phosphofructokinase was investigated by measurement of fluxes, isotope trapping and steady-state velocities at pH8 in triethanolamine/HCl buffer with 4 mM free Mg2+. Most observations were made at I0.2. The ratio Flux of fructose 1,6-bisphosphate----fructose 6-phosphate/Flux of fructose 1,6-bisphosphate----ATP at zero ATP concentration increased hyperbolically from unity to about 3.2 as the concentration of fructose 6-phosphate was increased. Similarly, the ratio Flux of fructose 1,6-bisphosphate----ATP/Flux of fructose 1,6-bisphosphate----fructose 6-phosphate at zero fructose 6-phosphate concentration increased from unity to about 1.4 as the concentration of ATP was increased. The addition of substrates must therefore be random, whatever the other aspects of the reaction. Further, from the plateau values of the ratios, it follows that the substrates dissociate very infrequently from the ternary complex and that at a low substrate concentration 72% of the reaction follows the pathway in which ATP adds first to the enzyme. Isotope-trapping studies with [32P]ATP confirmed that ATP can bind first to the enzyme in rate-limiting step and that dissociation of ATP from the ternary complex is slow in relation to the forward reaction. No isotope trapping of [U-14C]-fructose 6-phosphate could be demonstrated. The ratios Flux of ATP----fructose 1,6-bisphosphate/Flux of ATP----ADP measured at zero ADP concentration and the reciprocal of the ratio measured at zero fructose 1,6-bisphosphate concentration did not differ significantly from unity. Calculated values for these ratios based on the kinetics of the reverse reaction and assuming ordered dissociations of products or a ping-pong mechanism gave values very significantly greater than unity. These findings exclude an ordered dissociation or a substantial contribution from a ping-pong mechanism, and it is concluded that the reaction is sequential and that dissociation of products is random. Rate constants were calculated for the steps in the enzyme reaction. The results indicate a considerable degree of co-operativity in the binding between the two substrates. The observations on phosphofructokinase are discussed in relation to methods of measurement and interpretation of flux ratios and in relation to the mechanism of other kinase enzymes.     

Self-association of rabbit muscle phosphofructokinase at pH 7.0: stoichiometry

The self-association of rabbit muscle phosphofructokinase at pH 7.0 was investigated by velocity sedimentation. The process was demonstrated to be in a rapid, dynamic equilibrium. The concentration dependence of the weight-average sedimentation coefficient was monitored within the range of 10-750 microgram/mL. The sedimentation properties of phosphofructokinase were analyzed by theoretical simulations or an associating system in rapid equilibrium. In the absence of any ligands and at a temperature of 23 degrees C, the simplest computed model which gives the best fit between theoretical and experimental points can be described as progressive association of monomer in equilibrium or formed from tetramer in equilibrium or formed from 16-mer with apparent equilibrium constants K4 = 5.06 X 10(5) (mL/mg)3 and K16 = 3.25 X 10(23) (mL/mg)15. However, at 5 degrees C, the equilibrium was altered and can best be described as monomer in equilibrium or formed from dimer in equilibrium or formed from tetramer in equilibrium or formed from 16-mer.     

Stabilization of active form of rabbit liver phosphofructokinase

(1) The active form of rabbit liver phosphofructokinase when preincubated in presence of F^? and effectors of the enzyme is stabilized against its conversion to less active form as a result of dilution. (2) The stabilized active form of enzyme has a Km value of 0.01 mM for fructose 6-phosphate, the same as measured in presence of all the positive effectors, and is lower, by 13 times, than the Km value of the non-stabilized control enzyme, and exhibits normal Michaelis-Menten kinetics, in contrast to the non-stabilized control enzyme which shows sigmoidal kinetics. (3) The stabilized active form of enzyme is neither inhibited by excess concentration of ATP nor activated by activators of phosphofructokinase. (4) The data thus support the proposition that the enzyme does indeed exist in two interconvertible forms with enormous difference in their affinities for fructose 6-phosphate and effectors.     

Physical studies of rabbit muscle phosphofructokinase: sedimentation behavior of the enzymatic reactive form.

Reacting enzyme sedimentation experiments were carried out to identify the active form of rabbit muscle phosphofructokinase in glycylglycine buffer at pH 8.55 and 23 ± 1 °C. Results from these experiments reveal one active form with s_20,w = 12.2 ± 0.3 and 12.2 ± 0.3 S in a coupled enzyme and a pH-dependent dye linked system, respectively.     

Amino acid sequence at the citrate allosteric site of rabbit muscle phosphofructokinase

Previously, this laboratory has demonstrated [Colombo, G., & Kemp, R. G. (1976) Biochemistry 15, 1774-1780] that under appropriate conditions the citrate inhibitory binding site of rabbit skeletal muscle phosphofructokinase can be covalently modified by using pyridoxal phosphate and sodium borohydride. In the current study, phosphofructokinase was modified by [3H]pyridoxal phosphate and sodium borohydride with or without the addition of citrate to protect the ligand binding site. The modified proteins were digested with trypsin, and the peptides were separated by high-pressure liquid chromatography. A comparison of the tryptic chromatographic profiles showed that while the label was broadly distributed among nine peaks in the elution profile of the enzyme modified in the presence of the protective ligand, a single peptide contained 70% of the total radioactivity of the enzyme modified in the absence of citrate. This peptide was presumed to contain at least part of the citrate inhibitory site of the enzyme. The sequence of the peptide was determined and shown to match with positions 528-536 of phosphofructokinase with the modified residue being Lys-529. A comparison of the sequence with that of procaryotic phosphofructokinase indicated that a homologous residue in the enzyme from Bacillus stearothermophilis is critical to an allosteric site. A second peptide that was the most abundant labeled peptide in the digest of the enzyme modified in the presence of citrate was found to be identical with the second most abundant peptide of the digest from the unprotected enzyme. This peptide corresponded to residues 681-692 with the lysine at position 684 being the site of phosphopyridoxylation.(ABSTRACT TRUNCATED AT 250 WORDS)     

Characterisation of the catalytically active form of RecG helicase

Replication of DNA is fraught with difficulty and chromosomes contain many lesions which may block movement of the replicative machinery. However, several mechanisms to overcome such problems are beginning to emerge from studies with Escherichia coli. An important enzyme in one or more of these mechanisms is the RecG helicase, which may target stalled replication forks to generate a four-stranded (Holliday) junction, thus facilitating repair and/or bypass of the original lesion. To begin to understand how RecG might catalyse regression of fork structures, we have analysed what the catalytically active form of the enzyme may be. We have found that RecG exists as a monomer in solution as measured by gel filtration but when bound to junction DNA the enzyme forms two distinct protein–DNA complexes that contain one and two protein molecules. However, mutant inhibition studies failed to provide any evidence that RecG acts as a multimer in vitro. Additionally, there was no evidence for cooperativity in the junction DNA-stimulated hydrolysis of ATP. These data suggest that RecG functions as a monomer to unwind junction DNA, which supports an ‘inchworm’ rather than an ‘active rolling’ mechanism of DNA unwinding. The observed in vivo inhibition of wild-type RecG by mutant forms of the enzyme was attributed to occlusion of the DNA target and correlates with the very low abundance of replication forks within an E.coli cell, even during rapid growth.     

Subunit interface mutants of rabbit muscle aldolase form active dimers.

We report the construction of subunit interface mutants of rabbit muscle aldolase A with altered quaternary structure. A mutation has been described that causes nonspherocytic hemolytic anemia and produces a thermolabile aldolase (Kishi H et al., 1987, Proc Natl Acad Sci USA 84:8623-8627). The disease arises from substitution of Gly for Asp-128, a residue at the subunit interface of human aldolase A. To elucidate the role of this residue in the highly homologous rabbit aldolase A, site-directed mutagenesis is used to replace Asp-128 with Gly, Ala, Asn, Gln, or Val. Rabbit aldolase D128G purified from Escherichia coli is found to be similar to human D128G by kinetic analysis, CD, and thermal inactivation assays. All of the mutant rabbit aldolases are similar to the wild-type rabbit enzyme in secondary structure and kinetic properties. In contrast, whereas the wild-type enzyme is a tetramer, chemical crosslinking and gel filtration indicate that a new dimeric species exists for the mutants. In sedimentation velocity experiments, the mutant enzymes as mixtures of dimer and tetramer at 4 degrees C. Sedimentation at 20 degrees C shows that the mutant enzymes are > 99.5% dimeric and, in the presence of substrate, that the dimeric species is active. Differential scanning calorimetry demonstrates that Tm values of the mutant enzymes are decreased by 12 degrees C compared to wild-type enzyme. The results indicate that Asp-128 is important for interface stability and suggest that 1 role of the quaternary structure of aldolase is to provide thermostability.     

Salt-induced folding of a rabbit muscle pyruvate kinase intermediate at alkaline pH

The effect of alkaline denaturation on the structural and functional characteristics of rabbit muscle pyruvate kinase (PK) was investigated using enzymatic activity measurements and a combination of optical methods such as circular dichroism, fluorescence, and ANS binding. At a critical pH, 10.5, PK exists in an intermediate state (alkaline unfolded state) with predominant secondary structure along with some of the tertiary interactions and a strong binding to the hydrophobic dye ANS. This intermediate retains the enzymatic activity and corresponds to a dimeric state of the molecule. Above pH 10.5, a sudden fall in the spectral properties and enzymatic activity occurs suggesting the dissociation of the molecule followed by unfolding at very high pH. Addition of salts such as NaCl, KCl, and Na₂SO₄ to the alkali-induced state induces both secondary and tertiary structure to a level equivalent to that of native tetramer (salt-induced state). Chemical- and temperature-induced unfolding of the alkali-induced state as well as the salt-induced refolded state of PK reveal the presence of intermediate conformations in the unfolding pathway. The unfolding transition curves are noncoinciding and noncooperative along with ANS binding at intermediate concentrations of denaturants during unfolding. The observations presented in this paper suggest that the native pyruvate kinase tetramer dissociates to an active dimer around pH 10.5 and further to inactive monomer before attaining a completely unfolded monomeric conformation.     

A calorimetric study of the interaction of ATP with rabbit muscle phosphofructokinase.

The heat of interaction of ATP with phosphofructokinase from rabbit muscle was determined at 25 degrees C in 0.1 M potassium phosphate, pH 7.0 and 8.0. The limiting value of the enthalpy change at high ATP concentrations was found to be -11.5 kcal mol of enzyme polypeptide chains. Since phosphate and imidazole have very different heats of ionization (+0.8 and +7.5 kcal/mol, respectively), this suggests that the binding of at least two protons to the enzyme occurs concomitantly with the binding of ATP at the regulatory site.     

Self-association of rabbit muscle phosphofructokinase: effects of ligands

The effects of ligands on the self-association of rabbit muscle phosphofructokinase (PFK) were investigated by velocity sedimentation at pH 7.0 and 23 degrees C. The concentration dependence of the weight-average sedimentation coefficient was monitored in the presence of these ligands. The mode of association and equilibrium constants characterizing each association step were determined by theoretical fitting of the sedimentation data. The simplest mode of association for the PFK system is M in equilibrium M2 equilibrium M4 in equilibrium M16. Ligands and temperature would perturb the various equilibrium constants without altering the mode of association. The apparent equilibrium constants for the formation of tetramer, K4app, are increased in the presence of 0.1 mM ATP and 1.0 mM fructose 6-phosphate. The value of the sedimentation coefficient for the tetramer, S4 degrees, that would best fit the data is 12.4 S instead of 13.5 S determined in the absence of substrates, thus implying a structural change in the tetramer induced by substrates. Only an insignificant amount of dimer is present under the experimental conditions. The presence of activators, ADP or phosphate, enhances the formation of tetramers, and S4 degrees assumes a value of 13.5 S. Similar results are obtained with decreasing concentrations of proton. The presence of the inhibitor, citrate, however, favors the formation of dimers. The equilibrium constants determined as a function of ADP concentration were further analyzed by the linked-function theory derived by Wyman [Wyman, J. (1964) Adv. Protein Chem. 19, 224--285], leading to the conclusion that the formation of a tetramer involves the binding of two additional molecules of ADP per monomer. Similar analysis results in a conclusion that the formation of a dimer involves the binding of one additional molecule of citrate per phosphofructokinase subunit.