Immucillin-H binding to purine nucleoside phosphorylase reduces dynamic solvent exchange

Part-of-the-sites binding and reactivity in the homooligomeric enzymes - facts and artifacts

For a number of enzymes composed of several subunits with the same amino acid sequence, it was documented, or suggested, that binding of a ligand, or catalysis, is carried out by a single subunit. This phenomenon may be the result of a pre-existent asymmetry of subunits or a limiting case of the negative cooperativity, and is sometimes called "half-of-the-sites binding (or reactivity)" for dimers and could be called "part-of-the-sites binding (or reactivity)" for higher oligomers. In this article, we discuss molecular mechanisms that may result in "part-of-the-sites binding (and reactivity)", offer possible explanations why it may have a beneficial role in enzyme function, and point to experimental problems in documenting this behaviour. We describe some cases, for which such a mechanism was first reported and later disproved. We also give several examples of enzymes, for which this mechanism seems to be well documented, and profitable. A majority of enzymes identified in this study as half-of-the-sites binding (or reactive) use it in the flip-flop version, in which "half-of-the-sites" refers to a particular moment in time. In general, the various variants of the mechanism seems to be employed often by oligomeric enzymes for allosteric regulation to enhance the efficiency of enzymatic reactions in many key metabolic pathways.

Allosteric Communication Networks in Proteins Revealed through Pocket Crosstalk Analysis

The detection and characterization of binding pockets and allosteric communication in proteins is crucial for studying biological regulation and performing drug design. Nowadays, ever-longer molecular dynamics (MD) simulations are routinely used to investigate the spatiotemporal evolution of proteins. Yet, there is no computational tool that can automatically detect all the pockets and potential allosteric communication networks along these extended MD simulations. Here, we use a novel and fully automated algorithm that examines pocket formation, dynamics, and allosteric communication embedded in microsecond-long MD simulations of three pharmaceutically relevant proteins, namely, PNP, A2A, and Abl kinase. This dynamic analysis uses pocket crosstalk, defined as the temporal exchange of atoms between adjacent pockets, along the MD trajectories as a fingerprint of hidden allosteric communication networks. Importantly, this study indicates that dynamic pocket crosstalk analysis provides new mechanistic understandings on allosteric communication networks, enriching the available experimental data. Thus, our results suggest the prospective use of this unprecedented dynamic analysis to characterize transient binding pockets for structure-based drug design.

Structural determinants of the 5'-methylthioinosine specificity of Plasmodium purine nucleoside phosphorylase

Plasmodium parasites rely upon purine salvage for survival. Plasmodium purine nucleoside phosphorylase is part of the streamlined Plasmodium purine salvage pathway that leads to the phosphorylysis of both purines and 5'-methylthiopurines, byproducts of polyamine synthesis. We have explored structural features in Plasmodium falciparum purine nucleoside phosphorylase (PfPNP) that affect efficiency of catalysis as well as those that make it suitable for dual specificity. We used site directed mutagenesis to identify residues critical for PfPNP catalytic activity as well as critical residues within a hydrophobic pocket required for accommodation of the 5'-methylthio group. Kinetic analysis data shows that several mutants had disrupted binding of the 5'-methylthio group while retaining activity for inosine. A triple PfPNP mutant that mimics Toxoplasma gondii PNP had significant loss of 5'-methylthio activity with retention of inosine activity. Crystallographic investigation of the triple mutant PfPNP with Tyr160Phe, Val66Ile, andVal73Ile in complex with the transition state inhibitor immucillin H reveals fewer hydrogen bond interactions for the inhibitor in the hydrophobic pocket.

Immobilized purine nucleoside phosphorylase from Aeromonas hydrophila as an on-line enzyme reactor for biocatalytic applications

We described the development of a biochromatographic system which uses a purine nucleoside phosphorylase from Aeromonas hydrophila (AhPNP) for the evaluation of the substrate specificity on nucleoside libraries. AhPNP has been covalently immobilized on a fused silica Open Tubular Capillary (OTC) via Schiff base chemistry. The resulting bioreactor has been characterized by the determination of kinetic constants (Km and Vmax) for a natural substrate (inosine) and then assayed versus all natural purine (deoxy)ribonucleosides and a small library of 6-substituted purine ribosides. Characterization of the bioreactor has been carried out through a bidimensional chromatographic system with the sample on-line transfer from the bioreactor to the analytical column for the separation and quantification of substrate and product. Comparison with the soluble enzyme showed that the AhPNP-based bioreactor is reliable as the same ranking order, with respect to the standard activity assay, was obtained. The stability of the IMER was also assessed and the system was found to be stable up to 60 reactions.

Enzyme catalysis from improved packing in their transition-state structures

The binding of ligands to proteins can be enhanced through improved packing within the proteins that may, or may not, occur with conformational change. Enzymes can similarly improve their catalytic magic through better packing in the transition state (TS) for reaction. In principle, the improved packing demands no more than the minute shortening of non-covalent interactions throughout much of the structure of the protein (positively cooperative binding). Improved protein packing can account for the remarkably high biotin/streptavidin affinity, and perhaps also for a major part of the catalytic function of hypoxanthine-guanine phosphoribosyltransferase and purine nucleoside phosphorylase (PNP). As successive NAD(+) molecules bind to the glyceraldehyde phosphate dehydrogenase tetramer, they do so with positively cooperative binding (using the term as applied in crystallization and protein folding) that decreases at each step. This binding is negatively cooperative in the usage stemming from Monod and co-workers.

Conformational states of human purine nucleoside phosphorylase at rest, at work, and with transition state analogues

Human purine nucleoside phosphorylase (PNP) is a homotrimer binding tightly to the transition state analogues Immucillin-H (ImmH; K(d) = 56 pM) and DATMe-ImmH-Immucillin-H (DATMe-ImmH; K(d) = 8.6 pM). ImmH binds with a larger entropic penalty than DATMe-ImmH, a chemically more flexible inhibitor. The testable hypothesis is that PNP conformational states are more relaxed (dynamic) with DATMe-ImmH, despite tighter binding than with ImmH. PNP conformations are probed by peptide amide deuterium exchange (HDX) using liquid chromatography high-resolution Fourier transform ion cyclotron resonance mass spectrometry and by sedimentation rates. Catalytically equilibrating Michaelis complexes (PNP.PO(4).inosine <--> PNP.Hx.R-1-P) and inhibited complexes (PNP.PO(4).DATMe-ImmH and PNP.PO(4).ImmH) show protection from HDX at 9, 13, and 15 sites per subunit relative to resting PNP (PNP.PO(4)) in extended incubations. The PNP.PO(4).ImmH complex is more compact (by sedimentation rate) than the other complexes. HDX kinetic analysis of ligand-protected sites corresponds to peptides near the catalytic sites. HDX and sedimentation results establish that PNP protein conformation (dynamic motion) correlates more closely with entropy of binding than with affinity. Catalytically active turnover with saturated substrate sites causes less change in HDX and sedimentation rates than binding of transition state analogues. DATMe-ImmH more closely mimics the transition of human PNP than does ImmH and achieves strong binding interactions at the catalytic site while causing relatively modest alterations of the protein dynamic motion. Transition state analogues causing the most rigid, closed protein conformation are therefore not necessarily the most tightly bound. Close mimics of the transition state are hypothesized to retain enzymatic dynamic motions related to transition state formation.

Structural tightening and interdomain communication in the catalytic cycle of phosphoglycerate kinase

Changes in amide-NH chemical shift and hydrogen exchange rates as phosphoglycerate kinase progresses through its catalytic cycle have been measured to assess whether they correlate with changes in hydrogen bonding within the protein. Four representative states were compared: the free enzyme, a product complex containing 3-phosphoglyceric acid (3PG), a substrate complex containing ADP and a transition-state analogue (TSA) complex containing a 3PG-AlF(4)(-)-ADP moiety. There are an overall increases in amide protection from hydrogen exchange when the protein binds the substrate and product ligands and an additional increase when the TSA complex is formed. This is consistent with stabilisation of the protein structure by ligand binding. However, there is no correlation between the chemical shift changes and the protection factor changes, indicating that the protection factor changes are not associated with an overall shortening of hydrogen bonds in the protected ground state, but rather can be ascribed to the properties of the high-energy, exchange-competent state. Therefore, an overall structural tightening mechanism is not supported by the data. Instead, we observed that some cooperativity is exhibited in the N-domain, such that within this domain the changes induced upon forming the TSA complex are an intensification of those induced by binding 3PG. Furthermore, chemical shift changes induced by 3PG binding extend through the interdomain region to the C-domain beta-sheet, highlighting a network of hydrogen bonds between the domains that suggests interdomain communication. Interdomain communication is also indicated by amide protection in one domain being significantly altered by binding of substrate to the other, even where no associated change in the structure of the substrate-free domain is indicated by chemical shifts. Hence, the communication between domains is also manifested in the accessibility of higher-energy, exchange-competent states. Overall, the data that are consistent with structural tightening relate to defined regions and are close to the 3PG binding site and in the hinge regions of 3-phosphoglycerate kinase.

Methods in tubulin proteomics

New analytical methods are needed for the successful outcome of experiments aimed at characterizing mechanisms of microtubule dynamics and at understanding the effects of drugs on microtubules. The identification of tubulin isotypes and of regions of the microtubule involved in drug interactions has been advanced by proteomic methodologies. The diversity of tubulin sequences and posttranslational modifications (PTMs) can generate a complex mixture of heterodimers with unique molecular dynamics driving specific functions. Mass spectrometry (MS)-based approaches have been developed, and in combination with chromatographic and/or electrophoretic separation of tubulin polypeptides or peptides, they have contributed to our understanding of tubulin proteomics. We present protocols that we have used for the analysis of tubulin isotypes and PTMs present in tubulin isolated from cells in culture or tissues and for the identification of tubulin regions altered by microtubule-stabilizing agents. Tubulin proteomics complements structural and computer modeling information for a high-resolution view of microtubule dynamics and its alteration by drugs. These methodologies will help in providing insights into tubulin isotype-specific functions and in the design of drugs targeting either all tubulin heterodimers indiscriminately or only those containing specific isotypes.

Altered enthalpy-entropy compensation in picomolar transition state analogues of human purine nucleoside phosphorylase

Human purine nucleoside phosphorylase (PNP) belongs to the trimeric class of PNPs and is essential for catabolism of deoxyguanosine. Genetic deficiency of PNP in humans causes a specific T-cell immune deficiency, and transition state analogue inhibitors of PNP are in development for treatment of T-cell cancers and autoimmune disorders. Four generations of Immucillins have been developed, each of which contains inhibitors binding with picomolar affinity to human PNP. Full inhibition of PNP occurs upon binding to the first of three subunits, and binding to subsequent sites occurs with negative cooperativity. In contrast, substrate analogue and product bind without cooperativity. Titrations of human PNP using isothermal calorimetry indicate that binding of a structurally rigid first-generation Immucillin (K(d) = 56 pM) is driven by large negative enthalpy values (DeltaH = -21.2 kcal/mol) with a substantial entropic (-TDeltaS) penalty. The tightest-binding inhibitors (K(d) = 5-9 pM) have increased conformational flexibility. Despite their conformational freedom in solution, flexible inhibitors bind with high affinity because of reduced entropic penalties. Entropic penalties are proposed to arise from conformational freezing of the PNP.inhibitor complex with the entropy term dominated by protein dynamics. The conformationally flexible Immucillins reduce the system entropic penalty. Disrupting the ribosyl 5'-hydroxyl interaction of transition state analogues with PNP causes favorable entropy of binding. Tight binding of the 17 Immucillins is characterized by large enthalpic contributions, emphasizing their similarity to the transition state. Via introduction of flexibility into the inhibitor structure, the enthalpy-entropy compensation pattern is altered to permit tighter binding.

Determinants of sensitivity of human T-cell leukemia CCRF-CEM cells to immucillin-H

Immucillin-H (BCX-1777, forodesine) is a transition state analogue and potent inhibitor of PNP that shows promise as a specific agent against activated human T-cells and T-cell leukemias. The immunosuppressive or antileukemic effects of Immucillin-H (ImmH) in cultured cells require co-administration with deoxyguanosine (dGuo) to attain therapeutic levels of intracellular dGTP. In this study we investigated the requirements for sensitivity and resistance to ImmH and dGuo. (3)H-ImmH transport assays demonstrated that the equilibrative nucleoside transporters (ENT1 and ENT2) facilitated the uptake of ImmH in human leukemia CCRF-CEM cells whereas (3)H-dGuo uptake was primarily dependent upon concentrative nucleoside transporters (CNTs). Analysis of lysates from ImmH-resistant CCRF-CEM-AraC-8D cells demonstrated undetectable deoxycytidine kinase (dCK) activity, suggesting that dCK and not deoxyguanosine kinase (dGK) was the rate-limiting enzyme for phosphorylation of dGuo in these cells. Examination of ImmH cytotoxicity in a hypoxanthine-guanine phosphoribosyltransferase (HGPRT)-deficient cell line CCRF-CEM-AraC-8C, demonstrated enhanced sensitivity to low concentrations of ImmH and dGuo. RT-PCR and sequencing of HGPRT from the HGPRT-deficient CCRF-CEM-AraC-8C cells identified an Exon 8 deletion mutation in this enzyme. Thus these studies show that specific nucleoside transporters are required for ImmH cytotoxicity and predict that ImmH may be more cytotoxic to 6-thioguanine (6-TG) or 6-thiopurine-resistant leukemia cells caused by HGPRT deficiency.

Tryptophan-free human PNP reveals catalytic site interactions

Human purine nucleoside phosphorylase (PNP) is a homotrimer, containing three nonconserved tryptophan residues at positions 16, 94, and 178, all remote from the catalytic site. The Trp residues were replaced with Tyr to produce Trp-free PNP (Leuko-PNP). Leuko-PNP showed near-normal kinetic properties. It was used (1) to determine the tautomeric form of guanine that produces strong fluorescence when bound to PNP, (2) for thermodynamic binding analysis of binary and ternary complexes with substrates, (3) in temperature-jump perturbation of complexes for evidence of multiple conformational complexes, and (4) to establish the ionization state of a catalytic site tyrosine involved in phosphate nucleophile activation. The (13)C NMR spectrum of guanine bound to Leuko-PNP, its fluorescent properties, and molecular orbital electronic transition analysis establish that its fluorescence originates from the lowest singlet excited state of the N1H, 6-keto, N7H guanine tautomer. Binding of guanine and phosphate to PNP and Leuko-PNP are random, with decreased affinity for formation of ternary complexes. Pre-steady-state kinetics and temperature-jump studies indicate that the ternary complex (enzyme-substrate-phosphate) forms in single binding steps without kinetically significant protein conformational changes as monitored by guanine fluorescence. Spectral changes of Leuko-PNP upon phosphate binding establish that the hydroxyl of Tyr88 is not ionized to the phenolate anion when phosphate is bound. A loop region (residues 243-266) near the purine base becomes highly ordered upon substrate/inhibitor binding. A single Trp residue was introduced into the catalytic loop of Leuko-PNP (Y249W-Leuko-PNP) to determine effects on catalysis and to introduce a fluorescence catalytic site probe. Although Y249W-Leuko-PNP is highly fluorescent and catalytically active, substrate binding did not perturb the fluorescence. Thermodynamic boxes, constructed to characterize the binding of phosphate, guanine, and hypoxanthine to native, Leuko-, and Y249W-Leuko-PNPs, establish that Leuko-PNP provides a versatile protein scaffold for introduction of specific Trp catalytic site probes.

Cloning, expression, purification, and some properties of calf purine nucleoside phosphorylase

Calf spleen purine nucleoside phosphorylase (PNP) is considered a model enzyme for the trimeric PNPs subfamily. PCR amplification of the calf phosphorylase from the calf spleen library, cloning, overexpression of the recombinant PNP, its enzymatic activity and interactions with typical ligands of mammalian wild type PNP are described. Relative activity of the recombinant phosphorylase versus several substrates is similar to the respective values obtained for the enzyme isolated from calf spleen. As for the nonrecombinant calf PNP, the unusual fluorescence properties of the PNP/guanine complex were observed and characterized.

Remote mutations and active site dynamics correlate with catalytic properties of purine nucleoside phosphorylase

It has been found that with mutation of two surface residues (Lys(22) --> Glu and His(104) --> Arg) in human purine nucleoside phosphorylase (hPNP), there is an enhancement of catalytic activity in the chemical step. This is true although the mutations are quite remote from the active site, and there are no significant changes in crystallographic structure between the wild-type and mutant active sites. We propose that dynamic coupling from the remote residues to the catalytic site may play a role in catalysis, and it is this alteration in dynamics that causes an increase in the chemical step rate. Computational results indicate that the mutant exhibits stronger coupling between promotion of vibrations and the reaction coordinate than that found in native hPNP. Power spectra comparing native and mutant proteins show a correlation between the vibrations of Immucillin-G (ImmG):O5'...ImmG:N4' and H257:Ndelta...ImmG:O5' consistent with a coupling of these motions. These modes are linked to the protein promoting vibrations. Stronger coupling of motions to the reaction coordinate increases the probability of reaching the transition state and thus lowers the activation free energy. This motion has been shown to contribute to catalysis. Coincident with the approach to the transition state, the sum of the distances of ImmG:O4'...ImmG:O5'...H257:Ndelta became smaller, stabilizing the oxacarbenium ion formed at the transition state. Combined results from crystallography, mutational analysis, chemical kinetics, and computational analysis are consistent with dynamic compression playing a significant role in forming the transition state. Stronger coupling of these pairs is observed in the catalytically enhanced mutant enzyme. That motion and catalysis are enhanced by mutations remote from the catalytic site implicates dynamic coupling through the protein architecture as a component of catalysis in hPNP.

Towards the mechanism of trimeric purine nucleoside phosphorylases: Stopped-flow studies of binding of multisubstrate analogue inhibitor — 2-amino-9-[2-(phosphonomethoxy)ethyl]-6-sulfanylpurine

The binding of multisubstrate analogue inhibitor - 2-amino-9-[2-(phosphonomethoxy)ethyl]-6-sulfanylpurine (PME-6-thio-Gua) to purine nucleoside phosphorylase from Cellulomonas sp. at 20 degrees C, in 20 mM Hepes buffer with ionic strength adjusted to 50 mM using KCl, at several pH values between 6.5 and 8.2, was investigated using a stopped-flow spectrofluorimeter. The kinetic transients registered after mixing a protein solution with ligand solutions of different concentrations were simultaneously fitted by several association reaction models using nonlinear least-squares procedure based on numerical integration of the chemical kinetic equations appropriate for given model. It is concluded that binding of a PME-6-thio-Gua molecule by each of the binding sites is sufficiently well described by one-step process, with a model assuming interacting binding sites being more probable than a model assuming independent sites. The association rate constants derived from experimental data, assuming one step binding and independent sites, are decreasing with an increase in pH, changing from 30 to 6 microM(-1)s(-1) per binding site. The dissociation rate constants are in the range of 1-3 s(-1), and they are rather insensitive of changes in pH. Interestingly, for each pH value, the one-step binding model with interacting sites results in the association rate constant per site 1.5-4 times smaller for the binding of the first ligand molecule than that for the binding of the second one. Decrease of association constants with pH indicate that the enzyme does not prefer binding of the naturally occurring anionic form of the 6-thioguanine ring (pK(a) 8.7) resulting from a dissociation of N(1)-H. This finding supports the mechanism in which hydrogen bond interaction of N(1)-H with Glu204 (Glu 201 in mammalian PNPs) is crucial in the catalytic process. Results obtained also indicate that, in contrast to transition-state analogues, for which binding is followed by a conformational change, binding of multisubstrate analogue inhibitors to trimeric PNPs is a one-step process.

Probing the mechanism of purine nucleoside phosphorylase by steady-state kinetic studies and ligand binding characterization determined by fluorimetric titrations

Reversible reaction catalyzed by trimeric purine nucleoside phosphorylase (PNP) from Cellulomonas sp. with typical and non-typical substrates, including product inhibition patterns of both reaction directions, and interactions of the enzyme with bisubstrate analogue inhibitors, were investigated by the steady-state kinetic methods and fluorimetric titrations. The ligand chromophores exist most probably as neutral species, and not N(1)-H monoanions, in the complex with PNP, as shown by determination of inhibition constants vs. pH. This supports the mechanism in which hydrogen bond interaction of N(1)-H with Glu204 is crucial in the catalytic process. Stoichiometry of ligand binding, with possible exception of hypoxanthine, is three molecules per enzyme trimer. Kinetic experiments show that in principle the Michaelis-Menten model could not properly describe the reaction. However, this model seems to hold for certain experimental conditions. Data presented here are supported by earlier findings obtained by means of fluorimetric titrations and protective effects of ligands on thermal inactivation of the enzyme. All results are consistent with the following mechanism for trimeric PNPs: (i) random binding of substrates, (ii) potent binding and slow release of some reaction products leading to the circumstances that the chemical step is not the slowest one and that rapid-equilibrium assumptions do not hold, (iii) a dual role of phosphate--a substrate and also a reaction modifier.

Cooperativity in the self-assembly of porphyrin ladders

Cooperativity is a general feature of intermolecular interactions in biomolecular systems, but there are many different facets of the phenomenon that are not well understood. Positive cooperativity stabilizes a system as progressively more interactions are added, and the origin of the beneficial free energy may be entropic or enthalpic in origin. An "enthalpic chelate effect" has been proposed to operate through structural tightening that improves all of the functional group interactions in a complex, when it is more strongly bound. Here, we present direct calorimetric evidence that no such enthalpic effects exist in the cooperative assembly of supramolecular ladder complexes composed of metalloporphyrin oligomers coordinated to bipyridine ligands. The enthalpic contributions of the individual coordination interactions are 35 kJ.mol(-1) and constant over a range of free energies of self-assembly of -35 to -111 kJ.mol(-1). In rigid well defined systems of this type, the enthalpies of individual interactions are additive, and no enthalpic cooperative effects are apparent. The implication is that in more flexible, less well defined systems such as biomolecular assemblies, the enthalpy contributions available from specific functional group interactions are well defined and constant parameters.

Ligand Binding Energy and Enzyme Efficiency from Reductions in Protein Dynamics

Tetrameric rabbit muscle glyceraldehyde 3-phosphate dehydrogenase (GAPDH; EC 1.2.1.12) binds successively four molecules of its cofactor (NAD+) with affinities of ca 10(11) M(-1), 10(9) M(-1), 10(7) M(-1), and 10(5) M(-1). The reduction in the dynamics of the protein is greatest upon binding the first NAD+ molecule. Smaller reductions then occur upon binding the second and third NAD+ molecules, and the fourth NAD+ molecule binds without dynamic change. Reduction of the GAPDH dynamics, with consequent improvements in its internal bonding, can account for the increase in NAD+ binding affinity from 10(5) M(-1) to 10(11) M(-1). Evidence is provided that comparable fractions of the binding energy of other ligands, and of the catalytic efficiency of enzymes, may be derived in the same way.

Kinetic properties of Cellulomonas sp. purine nucleoside phosphorylase with typical and non-typical substrates: implications for the reaction mechanism

Phosphorolysis catalyzed by Cellulomonas sp. PNP with typical nucleoside substrate, inosine (Ino), and non-typical 7-methylguanosine (m7Guo), with either nucleoside or phosphate (Pd) as the varied substrate, kinetics of the reverse synthetic reaction with guanine (Gua) and ribose-1-phosphate (R1P) as the varied substrates, and product inhibition patterns of synthetic and phosphorolytic reaction pathways were studied by steady-state kinetic methods. It is concluded that, like for mammalian trimeric PNP, complex kinetic characteristics observed for Cellulomonas enzyme results from simultaneous occurrence of three phenomena. These are sequential but random, not ordered binding of substrates, tight binding of one substrate purine bases, leading to the circumstances that for such substrates (products) rapid-equilibrium assumptions do not hold, and a dual role of Pi, a substrate, and also a reaction modifier that helps to release a tightly bound purine base.

Understanding noncovalent interactions: ligand binding energy and catalytic efficiency from ligand-induced reductions in motion within receptors and enzymes

Noncovalent interactions are sometimes treated as additive and this enables useful average binding energies for common interactions in aqueous solution to be derived. However, the additive approach is often not applicable, since noncovalent interactions are often either mutually reinforcing (positively cooperative) or mutually weakening (negatively cooperative). Ligand binding energy is derived (positively cooperative binding) when a ligand reduces motion within a receptor. Similarly, transition-state binding energy is derived in enzyme-catalyzed reactions when the substrate transition state reduces the motions within an enzyme. Ligands and substrates can in this way improve their affinities for these proteins. The further organization occurs with a benefit in bonding (enthalpy) and a limitation in dynamics (cost in entropy), but does not demand the making of new noncovalent interactions, simply the strengthening of existing ones. Negative cooperativity induces converse effects: less efficient packing, a cost in enthalpy, and a benefit in entropy.

Insights into enzyme structure and dynamics elucidated by amide H/D exchange mass spectrometry

Conformational changes and protein dynamics play an important role in the catalytic efficiency of enzymes. Amide H/D exchange mass spectrometry (H/D exchange MS) is emerging as an efficient technique to study the local and global changes in protein structure and dynamics due to ligand binding, protein activation-inactivation by modification, and protein-protein interactions. By monitoring the selective exchange of hydrogen for deuterium along a peptide backbone, this sensitive technique probes protein motions and structural elements that may be relevant to allostery and function. In this report, several applications of H/D exchange MS are presented which demonstrate the unique capability of amide hydrogen/deuterium exchange mass spectrometry for examining dynamic and structural changes associated with enzyme catalysis.

Enzymatic transition states: thermodynamics, dynamics and analogue design

Kinetic isotope effects and computational chemistry have defined the transition state structures for several members of the N-ribosyltransferase family. Transition state analogues designed to mimic their cognate transition state structures are among the most powerful enzyme inhibitors. In complexes of N-ribosyltransferases with their transition state analogues, the dynamic nature of the transition state is converted to an ordered, thermodynamic structure closely related to the transition state. This phenomenon is documented by peptide bond H/D exchange, crystallography and computational chemistry. Complexes with substrate, transition state and product analogues reveal reaction coordinate motion and catalytic interactions. Isotope-edited spectroscopic analysis and binding specificity of these complexes provides information about specific enzyme-transition state contacts. In combination with protein dynamic QM/MM models, it is proposed that the transition state is reached by stochastic dynamic excursions of the protein groups near the substrates in the closed conformation. Examples from fully dissociated (D(N) *A(N)), hybrid (D(N)A(N)) and symmetric nucleophilic displacement (A(N)D(N)) transition states are found in the N-ribosyltransferases. The success of transition state analogue inhibitor design based on kinetic isotope effects validates this approach to understanding enzymatic transition states.

Crystal Structure of Calf Spleen Purine Nucleoside Phosphorylase with Two Full Trimers in the Asymmetric Unit: Important Implications for the Mechanism of Catalysis

The crystal structure of the binary complex of trimeric purine nucleoside phosphorylase (PNP) from calf spleen with the acyclic nucleoside phosphonate inhibitor 2,6-diamino-(S)-9-[2-(phosphonomethoxy)propyl]purine ((S)-PMPDAP) is determined at 2.3A resolution in space group P2(1)2(1)2(1). Crystallization in this space group, which is observed for the first time with a calf spleen PNP crystal structure, is obtained in the presence of calcium atoms. In contrast to the previously described cubic space group P2(1)3, two independent trimers are observed in the asymmetric unit, hence possible differences between monomers forming the biologically active trimer could be detected, if present. Such differences would be expected due to third-of-the-sites binding documented for transition-state events and inhibitors. However, no differences are noted, and binding stoichiometry of three inhibitor molecules per enzyme trimer is observed in the crystal structure, and in the parallel solution studies using isothermal titration calorimetry and spectrofluorimetric titrations. Presence of phosphate was shown to modify binding stoichiometry of hypoxanthine. Therefore, the enzyme was also crystallized in space group P2(1)2(1)2(1) in the presence of (S)-PMPDAP and phosphate, and the resulting structure of the binary PNP/(S)-PMPDAP complex was refined at 2.05A resolution. No qualitative differences between complexes obtained with and without the presence of phosphate were detected, except for the hydrogen bond contact of Arg84 and a phosphonate group, which is observed only in the former complex in three out of six independent monomers. Possible hydrogen bonds observed in the enzyme complexed with (S)-PMPDAP, in particular a putative hydrogen bonding contact N(1)-H cdots, three dots, centered Glu201, indicate that the inhibitor binds in a tautomeric or ionic form in which position N(1) acts as a hydrogen bond donor. This points to a crucial role of this hydrogen bond in defining specificity of trimeric PNPs and is in line with the proposed mechanism of catalysis in which this contact helps to stabilize the negative charge that accumulates on O(6) of the purine base in the transition state. In the present crystal structure the loop between Thr60 and Ala65 was found in a different conformation than that observed in crystal structures of trimeric PNPs up to now. Due to this change a new wide entrance is opened into the active site pocket, which is otherwise buried in the interior of the protein. Hence, our present crystal structure provides no obvious indication for obligatory binding of one of the substrates before binding of a second one; it is rather consistent with random binding of substrates. All these results provide new data for clarifying the mechanism of catalysis and give reasons for the non-Michaelis kinetics of trimeric PNPs.

Order Changes within Receptor Systems upon Ligand Binding: Receptor Tightening/Oligomerisation and the Interpretation of Binding Parameters

Recent hydrogen-deuterium exchange experiments have highlighted tightening and loosening of protein structures upon ligand binding, with changes in bonding (DeltaH) and order (DeltaS) which contribute to the overall thermodynamics of ligand binding. Tightening and loosening show that ligand binding respectively stabilises or destabilises the internal structure of the protein, i.e. it shows positive or negative cooperativity between ligand binding and the receptor structure. In the case of membrane-bound receptors, such as G protein-coupled receptors (GPCRs) and ligand gated ion channel receptors (LGICRs), most binding studies have focussed on association/dissociation constants. Where these have been broken down into enthalpic and entropic contributions, the phenomenon of "thermodynamic discrimination" between antagonists and agonists has often been noted; e.g. for a receptor where agonist binding is predominantly enthalpy driven, antagonist binding is predominantly entropy driven and vice versa. These data have not previously been considered in terms of the tightening, or loosening, of receptor structures that respectively occurs upon positively, or negatively, cooperative binding of ligand. Nor have they been considered in light of the homo- and hetero-oligomerisation of GPCRs and the possibility of ligand-induced changes in oligomerisation. Here, we argue that analysis of the DeltaH and DeltaS of ligand binding may give useful information on ligand-induced changes in membrane-bound receptor oligomers, relevant to the differing effects of agonists and antagonists.

Noncovalent interactions: defining cooperativity. Ligand binding aided by reduced dynamic behavior of receptors. Binding of bacterial cell wall analogues to ristocetin A

Changes in the relative populations of the monomer and asymmetric dimer forms of ristocetin A, upon binding of two molecules of ligand, suggest that ligand binding is negatively cooperative with respect to dimerization. However, strong hydrogen bonds formed in the binding sites of the ligands are reinforced in the dimer relative to the monomer, and the barrier to dissociation of the dimer is increased upon binding of the ligands. It is concluded that the interactions which are common in the binding of both ligands are made with positive cooperativity with respect to those involved in dimerization. The conclusions are relevant to the binding of ligands to proteins, where ligand binding energy can be derived from stabilization of the protein in its ligand-bound form.

Interactions of potent multisubstrate analogue inhibitors with purine nucleoside phosphorylase from calf spleen--kinetic and spectrofluorimetric studies

Dissociation constants and stoichiometry of binding for interaction of trimeric calf spleen purine nucleoside phosphorylase with potent multisubstrate analogue inhibitors were studied by kinetic and spectrofluorimetric methods.

Crystal structure of calf spleen purine nucleoside phosphorylase in a complex with multisubstrate analogue inhibitor with 2,6-diaminopurine aglycone

The crystal structure at 2.05 A resolution of calf spleen PNP complexed with stoichiometric concentration of acyclic nucleoside phosphonate inhibitor, 2,6-diamino-(S)-9-[2-(phosphonomethoxy)propyl]purine, in a new space group P2(1)2(1)2(1) which contains two full trimers in the asymmetric crystal unit is described.

Interactions of trimeric purine nucleoside phosphorylases with ground state analogues--calorimetric and fluorimetric studies

Binding enthalpies, dissociation constants and stoichiometry of binding for interaction of trimeric calf spleen and Cellulomonas sp. purine nucleoside phosphorylases with their ground state analogues (substrates and inhibitors) were studied by calorimetric and spectrofluorimetric methods. Data for all ligands, with possible exception of hypoxanthine, are consistent with three identical non-interacting binding sites.

Ligand binding energy and catalytic efficiency from improved packing within receptors and enzymes

Some small molecules bind to their receptors, and transition states to enzymes, so strongly as to defy current understanding. We show that in the binding of biotin to streptavidin, the streptavidin structure becomes better packed. We conclude that this contraction of the streptavidin structure promotes biotin binding. The improved packing is associated with positively cooperative binding, occurring with a benefit in enthalpy and a cost in entropy. Evidence indicating that catalytic efficiency can also originate via improved packing in some enzyme transition states, derived from the work of others, is presented. Negatively cooperative ligand binding is concluded to induce converse effects (less efficient packing, a cost in enthalpy, and a benefit in entropy). It applies to the binding of O(2) to haemoglobin, which indeed occurs with a hitherto unreported loosening of the amide backbones of the haemoglobin monomers.

Development of transition state analogues of purine nucleoside phosphorylase as anti-T-cell agents

Newborns with a genetic deficiency of purine nucleoside phosphorylase (PNP) are normal, but exhibit a specific T-cell immunodeficiency during the first years of development. All other cell and organ systems remain functional. The biological significance of human PNP is degradation of deoxyguanosine, and apoptosis of T-cells occurs as a consequence of the accumulation of deoxyguanosine in the circulation, and dGTP in the cells. Control of T-cell proliferation is desirable in T-cell cancers, autoimmune diseases, and tissue transplant rejection. The search for powerful inhibitors of PNP as anti-T-cell agents has culminated in the immucillins. These inhibitors have been developed from knowledge of the transition state structure for the reactions catalyzed by PNP, and inhibit with picomolar dissociation constants. Immucillin-H (Imm-H) causes deoxyguanosine-dependent apoptosis of rapidly dividing human T-cells, but not other cell types. Human T-cell leukemia cells, and stimulated normal T-cells are both highly sensitive to the combination of Imm-H to block PNP and deoxyguanosine. Deoxyguanosine is the cytotoxin, and Imm-H alone has low toxicity. Single doses of Imm-H to mice cause accumulation of deoxyguanosine in the blood, and its administration prolongs the life of immunodeficient mice in a human T-cell tissue xenograft model. Immucillins are capable of providing complete control of in vivo PNP levels and hold promise for treatment of proliferative T-cell disorders.

Calf spleen purine nucleoside phosphorylase: complex kinetic mechanism, hydrolysis of 7-methylguanosine, and oligomeric state in solution

The active enzyme form was found to be a homotrimer, no active monomers were observed. Only in the presence of an extremely high orthophosphate concentration (0.5 M) or at a low enzyme concentration (0.2 microg/ml) with no ligands present a small fraction of the enzyme is probably in a dissociated and/or non-active form. The specific activity is invariant over a broad enzyme concentration range (0.017 microg/ml-0.29 mg/ml). At concentrations below 0.9 microg/ml and in the absence of ligands the enzyme tends to loose its catalytic activity, while in the presence of any substrate or at higher concentrations it was found to be active as a trimer. In the absence of phosphate the enzyme catalyses the hydrolysis of 7-methylguanosine (m7Guo) with a catalytic rate constant 1.3x10(-3) x s(-1) as compared with the rate of 38 s(-1) for the phosphorolysis of this nucleoside. The initial pre-steady-state phase of the phosphorolysis of m7Guo, 70 s(-1), is almost twice faster than the steady-state rate and indicates that the rate-limiting step is subsequent to the glycosidic bond cleavage. Complex kinetic behaviour with substrates of phosphorolytic direction (various nucleosides and orthophosphate) was observed; data for phosphate as the variable substrate with inosine and guanosine, but not with their 7-methyl counterparts, might be interpreted as two binding sites with different affinities, or as a negative cooperativity. However, the titration of the enzyme intrinsic fluorescence with 0.2 microM-30 mM phosphate is consistent with only one dissociation constant for phosphate, K(d)=220+/-120 microM. Protective effects of ligands on the thermal inactivation of the enzyme indicate that all substrates of the phosphorolytic and the synthetic reactions are able to form binary complexes with the calf spleen purine nucleoside phosphorylase. The purine bases, guanine and hypoxanthine, bind strongly with dissociation constants of about 0.1 microM, while all other ligands studied, including 7-methylguanine and 7-methylhypoxanthine, bind at least 3 orders of magnitude less potently. Binding of guanine and hypoxanthine is about 10-fold weakened by the presence of phosphate. These observations are best interpretable by the complex kinetic mechanism of the phosphorolytic reaction involving (i) random substrate binding, (ii) unusually slow, hence strongly rate-limiting, dissociation of the products guanine and hypoxanthine, but not 7-methylguanine and 7-methylhypoxanthine, and (iii) dual function of the phosphate binding site with phosphate acting as a substrate and as a modifier helping in the release of a purine base after glycosidic bond cleavage.

Structural characterization of protein kinase A as a function of nucleotide binding. Hydrogen-deuterium exchange studies using matrix-assisted laser desorption ionization-time of flight mass spectrometry detection

Transient state kinetic studies indicate that substrate phosphorylation in protein kinase A is partially rate-limited by conformational changes, some of which may be associated with nucleotide binding (Shaffer, J., and Adams, J. A. (1999) Biochemistry 38, 12072-12079). To assess whether specific structural changes are associated with the binding of nucleotides, hydrogen-deuterium exchange experiments were performed on the enzyme in the absence and presence of ADP. Four regions of the protein are protected from exchange in the presence of ADP. Two regions encompass the catalytic and glycine-rich loops and are integral parts of the active site. Conversely, protection of probes in the C terminus is consistent with nucleotide-induced domain closure. One protected probe encompasses a portion of helix C, a secondary structural element that does not make any direct contacts with the nucleotide but has been reported to undergo segmental motion upon the activation of some protein kinases. The combined data suggest that binding of the nucleotide has distal structural effects that may include stabilizing the closed state of the enzyme and altering the position of a critical helix outside the active site. The latter represents the first evidence that the nucleotide alone can induce changes in helix C in solution.