Structural Specificity of the Adenosine 5'-Phosphate Site on Glycogen Phosphorylase b

Structural mechanism for glycogen phosphorylase control by phosphorylation and AMP

The crystal structures of activated R state glycogen phosphorylase a (GPa) and R and T state glycogen phosphorylase b (GPb) complexed with AMP have been solved at 2.9 A, 2.9 A and 2.2 A resolution, respectively. The structure of R state GPa is nearly identical to the structure of sulphate-activated R state GPb, except in the region of Ser14, where there is a covalently attached phosphate group in GPa and a non-covalently attached sulphate group in GPb. The contacts made by the N-terminal tail residues in R state GPa at the subunit interface of the functionally active dimer are similar to those observed previously for T state GPa. The quaternary and tertiary structural changes on the T to R transition allow these interactions to be relayed to the catalytic site in R state GPa. The transition from the T state GPb structure to the R state GPa structure results in a change in the N-terminal residues from a poorly ordered extended structure that makes intrasubunit contacts to an ordered coiled conformation that makes intersubunit contacts. The distance between Arg10, the first residue to be located from the N terminus, in R state GPa and T state GPb is 50 A. One of the important subunit-subunit interactions in the dimer molecule involves contacts between the helix alpha 2 and the cap' (residues 35' to 45' that form a loop between the 1st and 2nd alpha helices, alpha 1' and alpha 2' of the other subunit. The prime denotes residues from the other subunit). The interactions made by the N-terminal residues induce structural changes at the cap'/alpha 2 helix interface that lead to the creation of a high-affinity AMP site. The tertiary structural changes at the cap (shifts 1.2 to 2.1 A for residues 35 to 45) are partially compensated by the quaternary structural change so that the overall shifts in these residues after the combined tertiary and quaternary changes are between 0.5 and 1.3 A. AMP binds to R state GPb with at least 100-fold greater affinity and exhibits four additional hydrogen bonds, stronger ionic interactions and more extensive van der Waals' interactions with 116 A2 greater solvent accessible surface area buried compared with AMP bound to T state GPb.(ABSTRACT TRUNCATED AT 400 WORDS)

AMP interaction sites in glycogen phosphorylase b. A thermodynamic analysis

The binding of AMP to activator site N and to inhibitor site I in glycogen phosphorylase b has been characterized by calorimetry, potentiometry and ultracentrifugation in the pH range 6.5-7.5 at 25 degrees C (mu = 0.1). Calorimetric titration data of phosphorylase b with adenosine 5'-phosphoramidate are also reported at pH 6.9 (T = 25 degrees C, mu = 0.1). Calorimetric curves have been analyzed on the basis of potentiometric and sedimentation velocity results to determine thermodynamic quantities for AMP binding to the enzyme. The comparison of calorimetric titration data of AMP and adenosine 5'-phosphoramidate at pH 6.9 supports the hypothesis previously suggested that the dianionic phosphate form of the nucleotide preferentially binds to the allosteric activator site. The thermodynamic parameters for AMP binding to site N are as follows: delta G0 = -22 kJ mol-1, delta H0 = -34 kJ mol-1 and delta S0 = -40 J mol-1 K-1. The binding of the nucleotide to site I was found to be strongly dependent on the pH. This behaviour may be explained in terms of coupled protonations of three groups having pKa values of 6.0, 6.0 and 6.1 in the unbound form and 7.0, 7.5 and 7.2 in the enzyme-nucleotide complex. The thermodynamic parameters for nucleotide binding to site I for the enzymatic form in which all the modified groups are completely deprotonated or protonated have been calculated to be: delta G0 = -7.7 kJ mol-1, delta H0 = -28 kJ mol-1 and delta S0 = -68 J mol-1 K-1 and delta G0 = -28 kJ mol-1, delta H0H = -10 kJ mol-1 and delta S0H = 61 J mol-1 K-1, respectively. These results suggest that attractive dispersion forces are of primary significance for AMP binding to activator site N, although electrostatic interactions act as a stabilizing factor in the nucleotide binding. The protonation states of those residues of which the pKa values are modified by AMP binding to site I highly influence the thermodynamic parameters for the nucleotide binding to this site.

Active form of pyridoxal phosphate in glycogen phosphorylase. Phosphorus-31 nuclear magentic resonance investigation

The substrate analogue alpha-D-glucopyranosyl cyclic 1,2-phosphate has been confirmed to be a good competitive inhibitor of glycogen phosphorylases a and b isolated from rabbit muscle. Effects of tertiary and quaternary structure of the enzyme have been shown to be similar to those induced by the substrate glucose 1-phosphate and different from those of the coincidently binding inhibitor glucose. This information was obtained from study of the ultracentrifugation patterns of the enzyme-inhibitor complex and by determination of its effect on the binding constant for the activator AMP. 31P NMR investigation of the binding of this inhibitor to the enzyme has demonstrated that it both tightens the binding of the nucleotide activator and shifts the resonance of the phosphate group of the pyridoxal phosphate residue to a broad signal around 0 ppm. This situation is further reinforced in the presence of the second substrate, maltopentaose, giving a fully potentiated, but inactive, enzyme-substrate complex. This has not been studied previously by 31 P NMR. The active form of the pyridoxal phosphate (PLP), in the presence of substrates or their analogues, is not therefore a mobile dianionic phosphate as has been previously proposed. It may represent a tightly bound and constrained dianionic phosphate or possible a protonated phosphate in intermediate exchange. The implications of this finding are discussed.

A model for the behaviour of phosphorylase b. The generation of different binding sites via intermediate enzymatic states

The model given in this paper can be applied to enzymatic systems which have more than two conformational states in equilibrium and which clearly exhibit heterogeneity in the binding of one ligand. The model we propose makes possible quantitative interpretation of our experimental results and of those of many other workers as well. In some cases calorimetric, dialysis and kinetic magnitudes, when plotted against ligand concentration, give multiregional or "stepwise" curves. We suggest that such a behaviour arises because total occupation of one class of binding sites completely moves the enzyme towards a different conformational state in which the affinity for the ligand is greatly increased by the formation of a new class of binding sites. Our calorimetric results for the interaction between some nucleotides and phosphorylase b closely conform to our model.

Thermodynamics of nucleotides binding to phosphorylase b

The effects of several chemical modifications in the AMP molecule on its interaction with phosphorylase b are examined by microcalorimetry, equilibrium dialysis, light scattering and ultracentrifuge experiments. In this work we report the results obtained for eight AMP analogues corresponding to different substituents in the puric base or in the ribose, or to different positions of the phosphate. The thermodynamic properties of the interaction between the phosphorylase b and the above mentioned nucleotides are also reported. The following conclusions were obtained: a) Except for IMP and 2'dIMP all the nucleotides studied clearly show two types of binding sites in the enzyme. b) The interaction of the nucleotide with its weaker affinity binding site is highly dependent upon chemical alterations in the puric base. c) Both the amino group in C(6) and the N(1) of the adenine in the AMP seem to play an important role in the conformational transitions induced by the nucleotide on the enzyme. d) The tetramerization of phosphorylase b in the presence of 10(-2) M AMP and in the conditions of the ultracentrifuge experiments is drastically affected by modifications in the ribose-phosphate part of the AMP molecule.

AMP analogs: their function in the activation of glycogen phosphorylase b

A series of AMP analogs has been selected in order to better understand the structural requirements (a) for the efficient binding of the activator molecule at the correct site on phosphorylase b from rabbit skeletal muscle and (b) for the activation which is observed. Two types of activation are known, according to Black and Wang [J. Biol. Chem. 243, 5892-5898 (1968)]: either a cooperative response with respect to the activator concentration (like the one which is obtained for AMP itself) or a non-cooperative response observed in the case of IMP. It is shown that the 5'-phosphate moiety is absolutely required for the analog to bind at the correct site (adenine or adenosine bind at another enzymic site), and that the free enthalpy, delta G, corresponding to the association process varies in a complex manner with respect to the substitution of the different positions of the AMP molecule. Moreover, the differences delta G (analog) - delta G (AMP) = delta G obtained for two types of substitution separately do not add up to the same energy difference as the one obtained when the two substitutions are made simultaneously on the AMP molecule. It appears that all the mononucleotides which have been tested up to now may be divided into two classes. Class I (AMP class) is characterized, apart from a strong activation, by the following features: (a) one molecule of analog expels two molecules of bound glucose 6-phosphate as it binds on the enzyme; (b) bound analog protects slowly one crucial cysteinyl residue against attack by 5,5'-dithio-bis(2-nitrobenzoic acid) at 4 degrees C; (c) association of two molecules of dimer is strengthened at 4 degrees C in the presence of the analog. Class II (IMP class) is associated with a weak activation and with the following set of properties: (a) a single molecule of bound glucose 6-phosphate is released as the first molecule of analog binds on the dimer; (b) two slowly reacting cysteinyl residues per subunit are immediately protected against 5,5'-dithio-bis(2-nitrobenzoic acid) by the binding of the analog at 4 degrees C; (c) the analog dissociates the low amount of tetramer which is present at 4 degrees C in the absence of AMP into two molecules of dimer. These results are discussed according to a plausible scheme of transconformations taking place in glycogen phosphorylase b, a model which has been derived earlier by relaxation studies.

Studies on allosteric phenomena in glycogen phosphorylase b

This article attempts to trace, from a personal point of view, the history of discoveries of allosteric phenomena in phosphorylase b and the later development of systematic attempts to fit the data into comprehensive theoretical models. Work from our own laboratory is emphasized, but we try to integrate this into the results from other investigators and show their contributions to our ideas and experiments. Finally, some recent unpublished data is presented together with some conclusions and predictions from a new hypothesis. The discoveries by Carl and Gerty Cori of the activation of phosphorylase by AMP, the inhibition of glucose and the enzymatic interconversion of two forms fo the enzyme with different control properties helped lay the foundations of our present understanding of allosteric mechanisms. The later discovery of the oligomeric nature of phosphorylase and its relationship to AMP binding served as a basis for many years of research into the structure-function relationships of phosphorylase and other enzymes. Data showing that AMP lowers the entropy of activation is discussed with respect to the role of the nucleotide and its binding close to the active site. The discovery of the control of phosphorylase b by common metabolites and the impetus this gave to the intensive kinetic studies of the last ten years, wherein fitting to theoretical models has been a common feature, is reviewed.