Kinetic characterization of rabbit skeletal muscle phosphorylase ab hybrid

Phosphorylase ab was prepared in vitro by partial phosphorylation of rabbit skeletal muscle phosphorylase b and was isolated by DEAE-Sephacel chromatography. Its phosphorylated and non-phosphorylated subunits could not be distinguished by different affinity to substrates, activators or inhibitors, indicating their coordinated function. In the absence of nucleotide activators, the Km values for Pi and glucose-1-P were 28 mM and 18 mM, respectively. Activity in the presence of 16 mM glucose-1-P was doubled by 10(-4) M AMP or 10(-3) M IMP, mainly by lowering the Km for glucose-1-P. Half-maximum activation was exerted by 2 microM AMP or 0.1 mM IMP. Activation by these nucleotides showed no cooperativity. Glucose exerted competitive inhibition with respect to glucose-1-P, while for the inhibition by glucose-6-P an allosteric mechanism is suggested; the appropriate Ki values were 4.5 mM and 1.5 mM, respectively. The Hill coefficient for glucose-1-P binding was about 1.0, even in the presence of glucose (up to 10 mM), but 10 mM glucose-6-P lowered it to 0.47, indicating a negative heterotropic cooperativity. Effective regulation of the activity of phosphorylase ab by physiological concentrations of Pi, AMP, IMP and glucose-6-P suggests its metabolic control under in vivo condition.     

A kinetic study of glycogen phosphorylase b from the mantle tissue of Mytilus galloprovincialis,Lmk

• 1.1. In order to assign a meaningful role to the phosphorolytic pathway in Mytilus glycogen metabolism the kinetic mechanism of phosphorylase b, and its allosteric control, were studied.
• 2.2. The kinetic parameters of phosphorylase b from the mussel Mytilus galloprovincialis were determined. Michaelis constants (K_m or S_0.5) were in the range of 0.32–2.49 mg/ml for glycogen, 7–16 mM for P_i and 114–423 μM for AMP. In the direction of glycogen synthesis, the K_m value for glucose-1-P was approximately 180 mM.
• 3.3. The enzyme displayed homotropic co-operativity towards the binding of co-substrate and AMP (Hill coefficients of 2 and 1.4, respectively) and heterotropic co-operativity between substrates and AMP.
• 4.4. The concentration of glycogen in the Mytilus mantle is between 38- and 125-fold higher than the apparent K_m of phosphorylase b; the concentration of AMP varies throughout the year from 10 to 175 μM, up to a value close to the apparent K_m for the effector.
• 5.5. The apparent K_m for P_i is close to the concentration found in the mantle. This ligand showed more important regulatory effects than the effector AMP.

     

Effect of ligands on Drosophila phosphorylase a as monitored by its enzymic inactivation

The dephosphorylation of Drosophila phosphorylase a with the catalytic subunit of fruit-fly protein phosphatase-1 was inhibited by AMP, IMP, ADP, ATP, glucose-6-P, glucose-1-P and UDPG. Glucose, caffeine and glycogen did not influence the reaction. The inhibitory effect of AMP was reduced by glucose and caffeine. The above ligands acted through the modification of phosphorylase a conformation. This conclusion was drawn from the ligands' effect on the dephosphorylation of phosphohistone by Drosophila phosphatase-1 and on the tryptic digestion of fruit-fly phosphorylase a.     

The binding of beta-glycerophosphate to glycogen phosphorylase b in the crystal

The binding of beta-glycerophosphate (glycerol-2-P) to glycogen phosphorylase b in the crystal has been studied by X-ray diffraction at 3 A resolution. Glycerol-2-P binds to the allosteric effector site in a position close to that of AMP, glucose-6-P, UDP-Glc, and phosphate. In this position, glycerol-2-P is stabilized through interactions of its phosphate moiety with the guanidinium groups of Arg 309 and Arg 310 which undergo conformational changes, and the hydroxyl group of Tyr 75, while the same residues and solvent are involved in van der Waals interactions with the remaining part of the molecule. Kinetic experiments indicate that glycerol-2-P partially competes with both the activator (AMP) and the inhibitor (glucose 6-phosphate) of phosphorylase b. A comparison of the positions of glycerol-2-P, AMP, glucose 6-phosphate, UDP-Glc, and Pi at the allosteric site is presented.     

Biosynthesis of bacterial glycogen. The nature of the binding of substrates and effectors to ADP-glucose synthase.

Kinetic studies with ADP-glucose synthase show that 1,6-hexanediol bisphosphate (1,6-hexanediol-P2) is an effective activator that causes the enzyme to have a higher apparent affinity for ATP- and ADP-glucose than when fructose-1,6-P2 is the activator. Furthermore, in the presence of 1,6-hexanediol-P2, substrate saturation curves are hyperbolic shaped rather than sigmoidal shaped. CrATP behaves like a nonreactive analogue of ATP. Kinetic studies show that it is competitive with ATP. CrATP is not a competitive inhibitor of ADP-glucose. However, the combined addition of CrATP and glucose-1-P inhibits the enzyme competitively when ADP-glucose is the substrate. In binding experiments, CrATP, ATP, and fructose-P2 appear to bind to only half of the expected sites in the tetrameric enzyme, while ADP-glucose, the activators, pyridoxal-P and 1,6-hexanediol-P2, and the inhibitor, AMP, bind to four sites/tetrameric enzyme. Fructose-P2 inhibits 1,6-hexanediol-P2 binding, suggesting competition for the same sites. Glucose-1-P does not bind to the enzyme unless MgCl2 and CrATP are present and binds to four sites/tetrameric enzyme. Alternatively, CrATP in the presence of glucose-1-P binds to four sites/tetrameric enzyme. Thus, there are binding sites for the substrates, activators, and inhibitor located on each subunit and the binding sites can interact homotropically and heterotropically. ATP and fructose-P2 binding is synergistic showing heterotropic cooperativity. ATP and fructose-P2 must also be present together to effectively inhibit AMP binding. A mechanism is proposed which explains some of the kinetic and binding properties in terms of an asymmetry in the distribution of the conformational states of the four identical subunits.     

An engineered liver glycogen phosphorylase with AMP allosteric activation

Liver and muscle glycogen phosphorylases, which are products of distinct genes, are both activated by covalent phosphorylation, but in the unphosphorylated (b) state, only the muscle isozyme is efficiently activated by the allosteric activator AMP. The different responsiveness of the phosphorylase isozymes to allosteric ligands is important for the maintenance of tissue and whole body glucose homeostasis. In an attempt to understand the structural determinants of differential sensitivity of the muscle and liver isozymes to AMP, we have developed a bacterial expression system for the liver enzyme, allowing native and engineered proteins to be expressed and characterized. Engineering of the single amino acid substitutions Thr48Pro, Met197Thr and the double mutant Thr48Pro, Met197Thr in liver phosphorylase, and Pro48Thr in muscle phosphorylase, did not qualitatively change the response of the two isozymes to AMP. These sites had previously been implicated in the configuration of the AMP binding site. However, when nine amino acids among the first 48 in liver phosphorylase were replaced with the corresponding muscle phosphorylase residues (L1M2-48L49-846), the engineered liver enzyme was activated by AMP to a higher maximal activity than native liver phosphorylase. Interestingly, the homotropic cooperativity of AMP binding was unchanged in the engineered phosphorylase b protein, and heterotropic cooperativity between the glucose-1-phosphate and AMP sites was only slightly enhanced. The native liver, native muscle and L1M2-48L49-846 phosphorylases were converted to the a form by treatment with purified phosphorylase kinase; the maximal activity of the chimeric a enzyme was greater than the native liver a enzyme and approached that of muscle phosphorylase a. From these results we suggest that tissue-specific phosphorylase isozymes have evolved a complex mechanism in which the N-terminal 48 amino acids modulate intrinsic activity (Vmax), probably by affecting subunit interactions, and other, as yet undefined regions specify the allosteric interactions with ligands and substrates.     

Characteristics of the dephosphorylated form of phosphorylase purified from rat liver and measurement of its activity in crude liver preparations.

The phosphorylated form of liver glycogen phosphorylase (alpha-1,4-glucan : orthophosphate alpha-glucosyl-transferase, EC 2.4.1.1) (phosphorylase a) is active and easily measured while the dephosphorylated form (phosphorylase b), in contrast to the muscle enzyme, has been reported to be essentially inactive even in the presence of AMP. We have purified both forms of phosphorylase from rat liver and studied the characteristics of each. Phosphorylase b activity can be measured with our assay conditions. The phosphorylase b we obtained was stimulated by high concentrations of sulfate, and was a substrate for muscle phosphorylase kinase whereas phosphorylase a was inhibited by sulfate, and was a substrate for liver phosphorylase phosphatase. Substrate binding to phosphorylase b was poor (KM glycogen = 2.5 mM, glucose-1-P = 250 mM) compared to phosphorylase a (KM glycogen = 1.8 mM, KM glucose-1-P = 0.7 mM). Liver phosphorylase b was active in the absence of AMP. However, AMP lowered the KM for glucose-1-P to 80 mM for purified phosphorylase b and to 60 mM for the enzyme in crude extract (Ka = 0.5 mM). Using appropriate substrate, buffer and AMP concentrations, assay conditions have been developed which allow determination of phosphorylase a and 90% of the phosphorylase b activity in liver extracts. Interconversion of the two forms can be demonstrated in vivo (under acute stimulation) and in vitro with little change in total activity. A decrease in total phosphorylase activity has been observed after prolonged starvation and in diabetes.     

Isolation of a single activating allosteric interaction in phosphofructokinase from Escherichia coli

Escherichia coli phosphofructokinase 1 (EcPFK) is a homotetramer with four active and four allosteric sites. Understanding of the structural basis of allosteric activation of EcPFK by MgADP is complicated by the multiplicity of binding sites. To isolate a single heterotropic allosteric interaction, hybrid tetramers were formed between wild-type and mutant EcPFK subunits in which the binding sites of the mutant subunits have decreased affinity for their respective ligands. The 1:3 (wild-type:mutant) hybrid that contained only one native active site and one native allosteric site was isolated. The affinity for the substrate fructose-6-phosphate (Fru-6-P) of a single wild-type active site is greatly decreased over that displayed by the wild-type tetramer due to the lack of homotropic activation. The free energy of activation by MgADP for this heterotropic interaction is -0.58 kcal/mol at 8.5 degrees C. This compares to -2.87 kcal/mol for a hybrid with no homotropic coupling but all four unique heterotropic interactions. Therefore, the isolated interaction contributes 20% of the total heterotropic coupling. By comparison, wild-type EcPFK exhibits a coupling free energy between Fru-6-P and MgADP of -1.56 kcal/mol under these conditions, indicating that the effects of MgADP are diminished by a homotropic activation equal to -1.3 kcal/mol. These data are not consistent with a concerted allosteric mechanism.     

Effect of polymyxins on glycogen phosphorylase

AMP-dependent activity of glycogen phosphorylase b is stimulated by the polymyxins A, B, D, and E. Kinetic studies indicate that these cyclic peptide antibiotics at low concentrations greatly enhance AMP-activation of the enzyme. The presence of polymyxins in the assay system leads to (a) partial desensitization of allosteric interactions toward AMP, (b) lowering of K_m for the substrates glucose-1-phosphate and glycogen, and (c) reversal of the glucose-6-phosphate inhibition. in contrast to phosphorylase b, neither AMP-phosphorylase b′ system nor phosphorylase a (with or without AMP) is considerably activated by polymyxins.     

Fructose 2,6-bisphosphate and AMP increase the affinity of the Ascaris suum phosphofructokinase for fructose 6-phosphate in a process separate from the relief of ATP inhibition

Kinetic data have been collected suggesting that heterotropic activation by fructose 2,6-bisphosphate and AMP is a result not only of the relief of allosteric inhibition by ATP but is also the result of an increase in the affinity of phosphofructokinase for fructose 6-phosphate. Modification of the Ascaris suum phosphofructokinase at the ATP inhibitory site produces a form of the enzyme that no longer has hysteretic time courses or homotropic positive (fructose 6-phosphate) cooperativity or substrate inhibition (ATP) (Rao, G.S. J., Wariso, B.A., Cook, P.F., Hofer, H.W., and Harris, B.G. (1987a) J. Biol. Chem. 262, 14068-14073). This form of phosphofructokinase is Michaelis-Menten in its kinetic behavior but is still activated by fructose 2,6-bisphosphate and AMP and by phosphorylation using the catalytic subunit of cyclic AMP-dependent protein kinase (cAPK). Fructose 2,6-bisphosphate activates by decreasing KF-6-P by about 15-fold and has an activation constant of 92 nM, while AMP decreases KF-6-P about 6-fold and has an activation constant of 93 microM. Double activation experiments suggest that fructose 2,6-bisphosphate and AMP are synergistic in their activation. The desensitized form of the enzyme is phosphorylated by cAPK and has an increased affinity for fructose 6-phosphate in the absence of MgATP. The increased affinity results in a change in the order of addition of reactants from that with MgATP adding first for the nonphosphorylated enzyme to addition of fructose 6-phosphate first for the phosphorylated enzyme. The phosphorylated form of the enzyme is also still activated by fructose 2,6-bisphosphate and AMP.     

Functions of the 5'-phosphoryl group of pyridoxal 5'-phosphate in phosphorylase: a study using pyridoxal-reconstituted enzyme as a model system

Pyridoxal-reconstituted phosphorylase was used as a model system to study the possible functions of the 5'-phosphoryl group of pyridoxal 5'-phosphate (PLP) in rabbit muscle glycogen phosphorylase. Kinetic study was conducted by using competitive inhibitors of phosphite, an activator, and alpha-D-glucopyranose 1-phosphate (glucose-1-P) to study the relationship between the PLP phosphate and the binding of glucose-1-P to phosphorylase. Fluorine-19 nuclear magnetic resonance (19F NMR) spectroscopy of fluorophosphate bound to pyridoxal phosphorylase showed that its ionization state did not change during enzymatic catalysis. Evaluation of the apparent kinetic parameters for the activation of pyridoxal phosphorylase with different analogues having varied pKa2 values demonstrated a dependency of KM on pKa2. Molybdate, capable of binding as chelates in a trigonal-bipyramidal configuration, was tested for its inhibitory property with pyridoxal phosphorylase. On the basis of the results in this study, several conclusions may be drawn: (1) The bound phosphite in pyridoxal phosphorylase and, possibly, the 5'-phosphoryl group of PLP in native phosphorylase do not effect the glucose-1-P binding. (2) One likely function of the 5'-phosphoryl group of PLP in native phosphorylase is acting as an anchoring point to hold the PLP molecule and/or various amino acid side chains in a proper orientation for effective catalysis. (3) The force between the PLP phosphate and its binding site in phosphorylase is mainly electrostatic; a change of ionization state during catalysis is unlikely. (4) Properties of the central atoms of different anions are important for their effects as either activators or inhibitors of pyridoxal phosphorylase.(ABSTRACT TRUNCATED AT 250 WORDS)     

On the detection of homotropic effects in enzymes of low co-operativity. Application to modified aspartate transcarbamoylase

In contrast with the ease of observing heterotropic effects in allosteric enzymes of low co-operativity, the detection of homotropic effects is often difficult. As a consequence, erroneous conclusions about the uncoupling of homotropic and heterotropic effects can result unless sensitive techniques are used for analyzing the kinetic data. Simulations of experiments as well as actual measurements on the allosteric enzyme, aspartate transcarbamoylase, of Escherichia coli and some of its modified forms, were performed in attempts to develop stringent diagnostic procedures for the detection of homotropic effects in enzymes of low co-operativity. The analyses show that direct saturation plots (velocity versus substrate concentration), double reciprocal plots, and Hill plots yield misleading results in that the co-operativity known to be present is not observed. In contrast, Eadie plots (velocity/substrate concentration versus velocity) are much more sensitive in revealing homotropic effects. Since the observed co-operativity depends on both the allosteric equilibrium constant, L, and the number of active sites, n, simulations were performed on the effect of those parameters. The maxima in the Eadie plots increased as L was lowered and conversely the maxima decreased as n was reduced. These changes were confirmed with a mutant aspartate transcarbamoylase which had the same specific activity as the wild-type enzyme and a lower value of L, and also with a hybrid enzyme containing fewer active sites and the same L value. Analogous experiments on nitrated aspartate transcarbamoylase derivatives of decreasing activity showed that Eadie plots were of value in distinguishing between the changes in L and n values resulting from the inactivation. Data from the literature were analyzed in the form of Eadie plots and in all cases homotropic effects were readily detectable for aspartate transcarbamoylase derivatives previously claimed to be devoid of co-operativity.     

The interplay between covalent and non-covalent regulation of glycogen phosphorylase. The role of different effectors of phosphorylase b on the phosphorylase b to a conversion rate.

Glycogen phosphorylase b is converted to glycogen phosphorylase a, the covalently activated form of the enzyme, by phosphorylase kinase. Glc-6-P, which is an allosteric inhibitor of phosphorylase b, and glycogen, which is a substrate of this enzyme, are already known to have respectively an inhibiting and activating effect upon the rate of conversion from phosphorylase b to phosphorylase a by phosphorylase kinase. In the former case, this effect is due to the binding of glucose-6-phosphate to glycogen phosphorylase b. In order to investigate whether or not the rate of conversion of glycogen phosphorylase b to phosphorylase a depends on the conformational state of the b substrate, we have tested the action of the most specific effectors of glycogen phosphorylase b activity upon the rate of conversion from phosphorylase b to phosphorylase a at 0 degrees C and 22 degrees C : AMP and other strong activators, IMP and weak activators, Glc-6-P, glycogen. Glc-1-P and phosphate. AMP and strong activators have a very important inhibitory effect at low temperature, but not at room temperature, whereas the weak activators have always a very weak, if even existing, inhibitory effect at both temperatures. We confirmed the very strong inhibiting effect of Glc-6-P at both temperatures, and the strong activating effect of glycogen. We have shown that phosphate has a very strong inhibitory effect, whereas Glc-1-P has an activating effect only at room temperature and at non-physiological concentrations. The concomitant effects of substrates and nucleotides have also been studied. The observed effects of all these ligands may be either direct ones on phosphorylase kinase, or indirect ones, the ligand modifying the conformation of phosphorylase b and its interaction with phosphorylase kinase. Since we have no control experiments with a peptidic fragment of phosphorylase b, the interpretation of our results remains putative. However, the differential effects observed with different nucleotides are in agreement with the simple conformational scheme proposed earlier. Therefore, it is suggested that phosphorylase kinase recognizes differently the different conformations of glycogen phosphorylase b. In agreement with such an explanation, it is shown that the inhibiting effect of AMP is mediated by a slow isomerisation which has been previously ascribed to a quaternary conformational change of glycogen phosphorylase b. The results presented here (in particular, the important effect of glycogen and phosphate) are also discussed in correlation with the physiological role of the different ligands as regulatory signals in the in vivo situation where phosphorylase is inserted into the glycogen particle.     

Studies on the role of adenosine 3':5'-monophosphate in the activation of liver phosphorylase.

Crude extracts of rabbit liver, preincubated to promote the dephosphorylation of enzymes or other regulatory proteins, were used to study the role of cyclic AMP in the activation of glycogen phosphorylase. Inasmuch as endogenous liver phosphorylase was irreversibly altered by the preincubation procedure, crystalline skeletal muscle phosphorylase was used as the substrate in these studies. In the presence of magnesium ions and ATP, phosphorylase b was converted to phosphorylase a, and in an apparent biphasic process the phosphorylase a formed was subsequently converted to phosphorylase b. In the presence of adenosine 3':5'-monophosphate the rate of phosphorylase a formation and the maximal amount of phosphorylase a formed were increased. The cyclic AMP effect was enhanced by glucose-6-P and required the presence of glycogen. The catalytic subunit of cyclic AMP-dependent protein kinase could replace cyclic AMP in the stimulation of phosphorylase a formation. The effects of cyclic AMP or the catalytic subunit were shown to be due to stimulation of phosphorylase kinase rather than to inhibition of phosphorylase phosphatase. Preliminary fractionation experiments showed that it is possible to separate phosphorylase kinase catalytic activity from a factor or factors required for stimulation of its activation by the catalytic subunit.     

The ammonium sulfate activation of phosphorylase b

The ammonium sulfate activation of phosphorylase b has been studied. Ammonium sulfate, when present in high concentrations, induces properties of phosphorylase a in phosphorylase b, such as an enhanced affinity for AMP, a reversal of the glucose-6-P inhibition and enzyme tetramerization. The data are consistent with the interpretation that sulfates bind to the Ser-14 site and the sulfate-protein interactions at this site are responsible for activation of phosphorylase b.     

The interaction of ligands with chemically modified phosphorylase b.

Phosphorylase b which had been inactivated with 5-diazo1H-tetrazole was specifically labelled with 4-iodoacetamidosalicylic acid (a fluorescent probe) or with N-(1-oxyl-2,2,6,6,-tetramethyl-4-piperidinyl)iodoacetamide (a spin label probe) so that the binding of ligands and accompanying conformational changes could be determined by fluorescence or electron spin resonance changes, respectively. The allosteric effector, AMP, causes conformational changes similar to those caused in the native enzyme. The affinity of binding of phosphate or AMP to the inhibited protein is the same as for the unmodified protein. The heterotropic interactions between glucose-1-phosphate or glycogen and AMP are much less in the inactivated enzyme than in unmodified phosphorylase. Using a light scattering assay, it is shown that the modified enzyme binds to glycogen less strongly than the native protein. Phosphorylase b which had been inactivated by carbodimide in the presence of glycine ethyl ester, resulting in the modification of one or more carboxyl groups, was labelled with the spin label probe described above. The modified enzyme has an affinity for AMP similar to that of the native enzyme. AMP binding to the modified enzyme is tightened by glycogen, weakened by glucose-6-phosphate and is unaffected by glucose-1-phosphate. The actions of 5-diazo-1H-tetrazole and carbodimide on phosphorylase are discussed in the light of the above observation.     

Effect of polycarboxylates on phosphorylase b.

Activation of phosphorylase b by AMP is stimulated by certain aliphatic and cyclic polycarboxylates. This stimulation was depended on the number and the position of the carboxyl groups, the stereochemistry and the size of the molecule, and was more pronounced at low AMP concentrations. Kinetic studies indicated that in the presence of polycarboxylates the affinity of the enzyme for AMP was enhanced, the cooperative binding of the nucleotide was removed, and the enzyme was no longer inhibited by glucose-6-phosphate. Although polycarboxylates have no effect on the sedimentation pattern of phosphorylase b in the absence of AMP, the partial association of the enzyme caused by AMP is greatly enhanced in the presence of the acids.     

Conformational changes of spin-labeled native and modified phosphorylase B

The phosphorylase B labelled with 2,2,6,6-tetramethyl-piperidine-1-oxyl-4-iodacetamide (phosphorylase I) and with 2,2,6,6-tetramethyl-piperidine-1-oxyl-4-ethylmaleinimide (phosphorylase II) was studied. It was shown that label I is characterized by a greater mobility with respect to the protein as compared to label II. In spin-labelled preparations of phosphorylase B the 1,5--2,0 SH-groups of the enzyme monomer having no effect on the enzyme activity were modified. The effects of AMP, glucose-1-phosphate and glucose-6-phosphate on the EPR spectrum of phosphorylase I were studied. The greatest changes in the spectrum (especially in the high field line) were found to occur in the presence of glucose-6-phosphate. These changes are due to the increase in the degree of anisotropic spin rotation. The experimental and theoretical spectra allowing to determine the correlation time for the protein moiety (tau b = 160 ns) were shown to be similar. The local conformation changes were found to occur in the vicinity of one of the two label-bound SH-groups of phosphorylase I. The EPR spectra demonstrate the S-shaped dependence of mobility of phosphorylase I label on concentration of glucose-6-phosphate (0,1--10 mM). In the presence of AMP no S-shaped dependence is observed. Reduced NaBH4 phosphorylase I does not reveal the S-shaped dependence of the label mobility on concentration of glucose-6-phosphate. The degree of the label immobilization in the apo-phosphorylase I--pyridoxal-5-chloromethylphosphonate complex in the presence of glucose-6-phosphate and AMP is the same as in cholophosphorylase I; however, in contrast to the choloenzyme it does not depend on glucose-6-phosphate (0,1--10,0 mM). The changes in the mobility of the spin label of apophosphorylase I and its complex with the AMP analog--adenosine-5'-chloromethylphosphonate--during the choloenzyme reconstruction by pyridoxalphosphate are indicative of participation of AMP and the phosphate group of AMP in the formation of the enzyme active center.     

Distinction between substrate- and enzyme-directed effects of modifiers of rabbit liver phosphorylase a phosphatases

The natural substrate (phosphorylase a) and two alternative ones (phosphorylated histone and a tetradecapeptide consisting of residues 5-18 of rabbit skeletal muscle phosphorylase a) were used to distinguish the modes of action of some physiologically important effectors of four different molecular forms of rabbit liver phosphorlase a phosphatases. In general, glucose, caffeine, AMP, ADP, Pi, and glucose-1-P showed substrate-directed effects for the holophosphatase forms, since they usually did not affect the activity on histone phosphate and, with one slight exception (Pi), never affected the activity on the tetradecapeptide phosphate. ADP, Pi, and glucose-1-P did affect directly the relative mass (Mr) 35,000 phosphatase, in addition to an inhibition mediated via phosphorylase a. ATP exerted both substrate- and enzyme-directed effects for the Mr 35,000 phosphatase and phosphatases 1 and 2A2, but only a substrate-directed effect for phosphatase 2A1, suggesting that the gamma-subunit of the type 2 phosphatases may prevent ATP binding to the phosphatase. Mg2+ showed substrate-directed effects for phosphatases 1, 2A1, and 2A2, and an additional enzyme-directed effect for the Mr 35,000 phosphatase form. Furthermore, Mg2+ could not abolish ATP inhibition of the tetradecapeptide phosphatase activity, but significantly overcame ATP inhibition of the phosphorylase a phosphatase activity, thus suggesting that its ability to reverse the ATP effect is by a substrate-directed mechanism. The substrate-directed effects seen for the different ligands on the different phosphatase forms strongly indicate the significance of this form of control in the regulation of phosphorylase a phosphatase activities and may serve to narrow the otherwise broad substrate specificities of the major phosphorylase a phosphatase activities in mammalian tissues: phosphatases 1 and 2A.     

Disentangling the web of allosteric communication in a homotetramer: heterotropic activation in phosphofructokinase from Escherichia coli

Phosphofructokinase from Escherichia coli (EcPFK) is a homotetramer with four active sites and four allosteric sites. Understanding the allosteric activation of EcPFK by MgADP has been complicated by the complex web of possible interactions, including active site homotropic interactions, allosteric site homotropic interactions, and heterotropic interactions between active and allosteric sites. The current work has simplified this web of possible interactions to a series of single heterotropic interactions by forming and isolating hybrid tetramers. Each of the four unique heterotropic interactions have independently been isolated and compared to a control that has all four of the unique heterotropic interactions. If the interactions are labeled with the distances between interacting ligands, the 45-A interaction contributes 20% +/- 1%, the 33-A interaction contributes 34% +/- 1%, the 30-A interaction contributes 21% +/- 1%, and the 23-A interaction contributes 25% +/- 1% with respect to the total free energy of MgADP/fructose 6-phosphate (Fru-6-P) activation in the control. The free energies of the isolated interactions sum to 100% +/- 2% of the total. Therefore, the four unique interactions are all contributors to activation, are nonequivalent, and are additive.