How do enzymes work?

DNA enzymes

Biological catalysis is dominated by enzymes that are made of protein, but several distinct classes of catalytic RNAs are known to promote chemical transformations that are fundamental to cellular metabolism. Is biological catalysis limited only to these two biopolymers, or is DNA also capable of functioning as an enzyme in nature? To date, no DNA enzymes of natural origin have been found. However, an increasing number of catalytic DNAs, with characteristics that are similar to those of ribozymes, are being produced outside the confines of the cell. An assessment of the potential for structure formation by DNA leads to the conclusion that DNA might have considerable latent potential for enzymatic function.

The effect of ionic strength and specific anions on substrate binding and hydrolytic activities of Na,K-ATPase

The physiological ligands for Na,K-ATPase (the Na,K-pump) are ions, and electrostatic forces, that could be revealed by their ionic strength dependence, are therefore expected to be important for their reaction with the enzyme. We found that the affinities for ADP3-, eosine2-, p-nitrophenylphosphate, and V(max) for Na,K-ATPase and K+-activated p-nitrophenylphosphatase activity, were all decreased by increasing salt concentration and by specific anions. Equilibrium binding of ADP was measured at 0-0.5 M of NaCl, Na2SO4, and NaNO3 and in 0.1 M Na-acetate, NaSCN, and NaClO4. The apparent affinity for ADP decreased up to 30 times. At equal ionic strength, I, the ranking of the salt effect was NaCl approximately Na2SO4 approximately Na-acetate < NaNO3 < NaSCN < NaCl04. We treated the influence of NaCl and Na2SO4 on K(diss) for E x ADP as a "pure" ionic strength effect. It is quantitatively simulated by a model where the binding site and ADP are point charges, and where their activity coefficients are related to I by the limiting law of Debye and Hückel. The estimated net charge at the binding site of the enzyme was about +1. Eosin binding followed the same model. The NO3- effect was compatible with competitive binding of NO3- and ADP in addition to the general I-effect. K(diss) for E x NO3 was approximately 32 mM. Analysis of V(max)/K(m) for Na,K-ATPase and K+-p-nitrophenylphosphatase activity shows that electrostatic forces are important for the binding of p-nitrophenylphosphate but not for the catalytic effect of ATP on the low affinity site. The net charge at the p-nitrophenylphosphate-binding site was also about +1. The results reported here indicate that the reversible interactions between ions and Na,K-ATPase can be grouped according to either simple Debye-Hückel behavior or to specific anion or cation interactions with the enzyme.

Glycine residues provide flexibility for enzyme active sites

The high resolution refined structures of 23 enzymes were analyzed to determine the properties of amino acids involved in active site regions. These regions were found to be rich in G-X-Y or Y-X-G oligopeptides, where X and Y are polar and non-polar residues, respectively, that are small and with low polarity. Other regions of the enzyme molecules have significantly fewer of these sequences. These features suggest that glycine residues may provide flexibility necessary for enzyme active sites to change conformation, and the G-X-Y or Y-X-G oligopeptides may be a motif for the formation of enzyme active sites.

A perspective on biological catalysis

We have analysed enzyme catalysis through a re-examination of the reaction coordinate. The ground state of the enzyme-substrate complex is shown to be related to the transition state through the mean force acting along the reaction path; as such, catalytic strategies cannot be resolved into ground state destabilization versus transition state stabilization. We compare the role of active-site residues in the chemical step with the analogous role played by solvent molecules in the environment of the noncatalysed reaction. We conclude that enzyme catalysis is significantly enhanced by the ability of the enzyme to preorganize the reaction environment. This complementation of the enzyme to the substrate's transition state geometry acts to eliminate the slow components of solvent reorganization required for reactions in aqueous solution. Dramatically strong binding of the transition state geometry is not required.

Co-metabolism: is the emperor wearing any clothes?

Co-metabolism is a term used for biochemically undefined observations in catabolic enzyme substrate specificity, the interplay between enzyme specificity and metabolic regulation, the metabolic interdependence of microorganisms, and co-substrate requirements in the catabolism of xenobiotic compounds. Recent findings in these four areas of microbial biochemistry necessitate a re-evaluation of the widespread use of the term.

A general assay for antibody catalysis using acridone as a fluorescent tag

A simple and highly sensitive catalysis assay is demonstrated based on analyzing reactions with acridonetagged compounds by thin-layer chromatography. As little as 1 pmol of product is readily visualized by its blue fluorescence under UV illumination and identified by its retention factor (Rf). Each assay requires only 10 microliters of solution. The method is reliable, inexpensive, versatile, and immediately applicable in repetitive format for screening catalytic antibody libraries. Three examples are presented: (i) the epoxidation of acridone labeled (S)-citronellol. The pair of stereoisomeric epoxides formed is resolved on the plate, which provides a direct selection method for enantioselective epoxidation catalysts. (ii) Oxidation of acridone-labeled 1-hexanol to 1-hexanal. The activity of horse liver alcohol dehydrogenase is detected. (iii) Indirect product labeling of released aldehyde groups by hydrazone formation with an acridone-labeled hydrazide. Activity of catalytic antibodies for hydrolysis of enol ethers is detected.

Inhibition of phosphatidylinositol-specific phospholipase C: studies on synthetic substrates, inhibitors and a synthetic enzyme

Enzyme inhibition studies on phosphatidylinositol-specific phospholipase C (PI-PLC) from B. Cereus were performed in order to gain an understanding of the mechanism of the PI-PLC family of enzymes and to aid inhibitor design. Inhibition studies on two synthetic cyclic phosphonate analogues (1,2) of inositol cyclic-1:2-monophosphate (cIP), glycerol-2-phosphate and vanadate were performed using natural phosphatidylinositol (PI) substrate in Triton X100 co-micelles and an NMR assay. Further inhibition studies on PI-PLC from B. Cereus were performed using a chromogenic, synthetic PI analogue (DPG-PI), an HPLC assay and Aerosol-OT (AOT), phytic acid and vanadate as inhibitors. For purposes of comparison, a model PI-PLC enzyme system was developed employing a synthetic Cu(II)-metallomicelle and a further synthetic PI analogue (IPP-PI). The studies employing natural PI substrate in Triton X100 co-micelles and synthetic DPG-PI in the absence of surfactant indicate three classes of PI-PLC inhibitors: (1) active-site directed inhibitors (e.g. 1,2); (2) water-soluble polyanions (e.g. tetravanadate, phytic acid); (3) surfactant anions (e.g. AOT). Three modes of molecular recognition are indicated to be important: (1) active site molecular recognition; (2) recognition at an anion-recognition site which may be the active site, and; (3) interfacial (or hydrophobic) recognition which may be exploited to increase affinity for the anion-recognition site in anionic surfactants such as AOT. The most potent inhibition of PI-PLC was observed by tetravanadate and AOT. The metallomicelle model system was observed to mimic PI-PLC in reproducing transesterification of the PI analogue substrate to yield cIP as product and in showing inhibition by phytic acid and AOT.

Structure of a cyclic peptide with a catalytic triad, determined by computer simulation and NMR spectroscopy

We report the design of a cyclic, eight-residue peptide that possesses the catalytic triad residues of the serine proteases. A manually built model has been relaxed by 0.3 ns of molecular dynamics simulation at room temperature, during which no major changes occurred in the peptide. The molecule has been synthesised and purified. Two-dimensional NMR spectroscopy provided 35 distance and 7 torsion angle constraints, which were used to determine the three-dimensional structure. The experimental conformation agrees with the predicted one at the beta-turn, but deviates in the arrangement of the disulphide bridge that closes the backbone to a ring. A 1.2 ns simulation at 600 K provided extended sampling of conformation space. The disulphide bridge reoriented into the experimental arrangement, producing a minimum backbone rmsd from the experimental conformation of 0.8 A. At a later stage in the simulation, a transition at Ser3 produced more pronounced high-temperature behaviour. The peptide hydrolyses p-nitrophenyl acetate about nine times faster than free histidine.

Trypsin complexed with alpha 1-proteinase inhibitor has an increased structural flexibility

Mutant rat trypsin Asp189Ser was prepared and complexed with highly purified human alpha 1-proteinase inhibitor. The complex formed was purified to homogeneity and studied by N-terminal amino acid sequence analysis and limited proteolysis with bovine trypsin. As compared to uncomplexed mutant trypsin, the mutant enzyme complexed with alpha 1-proteinase inhibitor showed a highly increased susceptibility to enzymatic digestion. The peptide bond selectively attacked by bovine trypsin was identified as the Arg117-Val118 one of trypsin. The structural and mechanistic relevance of this observation to serine proteinase-substrate and serine proteinase-serpin reactions are discussed.

An in vitro model of aging: the influence of increasing physical density on enzyme activities of trypsin, xanthine oxidase and superoxide dismutase

The enzyme activities of trypsin (using an artificial substrate, Nalpha-benzoyl-L-arginine-ethylester = BAEE), xanthine oxidase (XOD) and superoxide dismutase (SOD) were measured in the absence and presence of various concentrations of the following inert, water-soluble polymer viscogens: polyvinylpyrrolidone (PVP-40), polyethyleneglycol (PEG-6000) and bovine serum albumin (BSA). Enzyme activities measured in the absence of viscogens were taken as 100%. In the presence of the viscogens, enzyme activities decreased considerably as follows: (i) Trypsin: to 2 or 12% in reaction mixtures containing 64 mg/ml PVP-40 or 481 mg/ml PEG-6000, respectively. (ii) XOD: to 29.3% in a reaction mixture containing 116 mg/ml PVP-40, to 68.9% in a medium containing 266 mg/ml PEG-6000, and 38.1% in the presence of 138 mg/ml BSA. (iii) SOD: to 40.0, 19.9 and 16.6% in the same media as listed for XOD, respectively. The observations are consistent with the predictions of the molecular enzyme kinetic model (MEKM), and are also of importance for the membrane hypothesis of aging, since the latter explains the loss of cell functions by an age-dependent increase of intracellular density which may cause serious enzyme inhibitions.

The effect of dimethylsulfoxide on the substrate site of Na+/K(+)-ATPase studied through phosphorylation by inorganic phosphate and ouabain binding

To obtain further information on the role of H2O at the substrate site of Na+/K(+)-ATPase, we have studied the enzymes reaction with P(i) and ouabain in 40% (v/v) Me2SO (dimethylsulfoxide). When the enzyme (E) was incubated with ouabain (O) for 5 min in a 40% (v/v) Me2SO-medium with 5 mM MgCl2 and 0.5 mM KCl (but no phosphate), ouabain was bound (as EO). Subsequent incubation with P(i) showed that E, but not EO, was rapidly phosphorylated (to EP). Long-time phosphorylation revealed that EO is also phosphorylated by P(i) albeit very slowly (t1/2 about 60 min) and that binding of ouabain to EP also is very slow. The EOP complex is stable, i.e., the t1/2 for the loss of P(i) is >> 60 min in contrast to about 1 min in water. These results in 40% Me2SO are distinctly different from what would be obtained in a watery milieu: ouabain would bind slowly and inefficiently in the absence of P(i), and ouabain would catalyse phosphorylation from P(i) rather than retard it. Equilibrium binding of [3H]ouabain to E and EP in water or 40% Me2SO confirmed these observations: Kdiss in water is 11 microM and 12 nM for EO and EOP, respectively, whereas in Me2SO they are 112 nM and 48 nM. It is suggested that the primary effect of the lowered water activity in 40% Me2SO is a rearrangement of the substrate site so that it also in the absence of P(i) attains a transition state configuration corresponding to the phosphorylated conformation. This would be sensed by the ouabain binding site and lead to high affinity ouabain binding in the absence of P(i).

Interpretations of cytochrome P450 mechanisms from kinetic studies

The catalytic mechanism of cytochrome P450 (P450) enzymes has generally been understood in terms of a classic cycle in which electron donation is often limiting and catalysis is understood in terms of hydrogen abstraction and rapid oxygen rebound. In the course of detailed investigations with kinetic hydrogen isotope effects we have studied two systems in which somewhat unusual isotope effects have been interpreted in terms of modifications of the general paradigm. The low isotope effects observed for N-demethylation reactions are in contrast to high values seen with P450-catalyzed C-hydroxylation and peroxidase-catalyzed N-demethylation and are consonant with a role for the P450 FeO2+ entity in base-catalyzed deprotonation of an aminium radical. With P450 2E1, kinetic deuterium isotope effects are seen on the apparent Km for the substrate (increased) but not on Vmax. The results are interpreted in terms of a mechanism where C-H bond cleavage is sensitive to deuterium substitution but a step following this is rate-limiting. This step may be product release.

Enzymes: chemistry and biochemistry

Basic principles underlying enzyme action are considered. Catalytic antibodies (abzymes), catalytic RNA (ribozymes), and non-biological counterparts of enzyme-catalyzed reactions are mentioned. Enzyme evolution is considered in terms of divergence, convergence, and lateral gene transfer.

The modulation of enzyme reaction rates within multi-enzyme complexes. 1. Statistical thermodynamics of information transfer through multi-enzyme complexes

There is now experimental evidence that association of different enzymes as a multi-enzyme complex may result in an alteration of the catalytic properties of the enzymes present in this complex. This effect is not related to the channelling of reaction intermediates between different active sites. It appears as a consequence of an information transfer that occurs within the multi-enzyme complex. A theory, based on statistical thermodynamics, has been developed which provides an understanding, on a physical basis, for how isologous as well as heterologous interactions between identical, or different, enzymes of the complex may modulate the catalytic properties of an oligomeric enzyme of that complex. The theory predicts three possible types of effects: an alteration, through heterologous interactions, of an already existing co-operativity of the oligomeric enzyme within the complex; a co-operativity, generated by heterologous interactions in the complex that could not occur if the oligomeric enzyme were isolated from the rest of the complex; a Michaelis-Menten character of the oligomeric enzyme within the complex, but with altered values of Vm and Km relative to what would have been observed with the naked enzyme. All these effects appear as a consequence of a transfer of information between different enzymes of the same multi-protein complex. The following paper in this journal shows how one can demonstrate and characterize experimentally these effects in a multi-enzyme complex containing ribulose bisphosphate carboxylase-oxygenase.

A thermodynamic study by laser-flash photolysis of plastocyanin and cytochrome c6 oxidation by photosystem I from the green alga Monoraphidium braunii

Plastocyanin and cytochrome c6 from the green alga Monoraphidium braunii reduce the photo-oxidized algal photosystem I (PSI) reaction center chlorophyll (P700) with similar kinetics, as expected from their functional equivalence. The observed P700+ reduction rate constants show a non-linear dependence on metalloprotein concentration, which indicates a (minimal) two-step kinetic mechanism involving complex formation prior to electron transfer. The dependence of the observed rate constants on NaCl concentration suggests that the electrostatic interaction forces between the negatively charged donor proteins and PSI are repulsive at neutral pH and relatively low ionic strength (I), although attractive dipole-dipole interactions may play a role at higher ionic strengths. Activation parameters for P700+ reduction by cytochrome c6 and plastocyanin have been determined by studying the temperature dependence of the respective rate constants at varying ionic strength and pH. Changes in NaCl concentration and pH induce significant changes in the activation free energy of the overall reaction, even though the corresponding values for activation enthalpy and entropy undergo changes in opposite directions. Such a compensation effect between enthalpy and entropy is observed with both cytochrome c6 and plastocyanin. Protein concentration dependencies of the observed rate constants at different temperatures has allowed an estimate of the free energy change during complex association, as well as the activation parameters for electron transfer, according to a two-step kinetic model.

X-ray crystal structures of cytosolic glutathione S-transferases. Implications for protein architecture, substrate recognition and catalytic function

Crystal structures of cytosolic glutathione S-transferases (EC 2.5.1.18), complexed with glutathione or its analogues, are reviewed. The atomic models define protein architectural relationships between the different gene classes in the superfamily, and reveal the molecular basis for substrate binding at the two adjacent subsites of the active site. Considerable progress has been made in understanding the mechanism whereby the thiol group of glutathione is destabilized (lowering its pKa) at the active site, a rate-enhancement strategy shared by the soluble glutathione S-transferases.

Thermodynamic predictions for biocatalysis in nonconventional media: theory, tests, and recommendations for experimental design and analysis

This article discusses the application of thermodynamic and related analysis to reaction systems for enzymic or whole cell catalysis, in which there are high proportions of organic liquid, gas, or supercritical fluid. A variety of predictions may be made, especially based on the partitioning of components between the different phases normally present. In many cases, observed behavior can be explained without invoking any direct molecular effects on the biocatalyst. The predictable changes should always be allowed for before seeking explanations for the residual effects, which are often very different from the crude observations. A summary of the general thermodynamics of multiphase systems is presented, and then the main classes of component that distribute between the phases are discussed in turn. Thermodynamic water activity (aw) determines the mass action effects of water on hydrolytic equilibria. It also describes the distribution of water between the various phases that can compete in binding water. Because catalytic activity is very sensitive to the hydration of the enzyme molecules, aw often predicts an unchanging optimum as other aspects of the system are changed. Hence the aw should be measured and/or controlled in these systems, whether the primary aim is to study the effects of water or of other changes. The methods available for measurement and control of aw are discussed. Adverse effects of organic solvents or similar nonpolar species partly reflect their tendency to partition into the relatively polar phase around the biocatalyst, especially when this is dilute aqueous. The well-established log P parameter is a measure of this. But other mechanisms of inactivation can occur: directly through contact of the biocatalyst with the phase interface, or indirectly via hydration changes. In these cases the molecular property log P is probably not the best solvent parameter. In low-water systems the biocatalyst remains in a separate phase even when water-miscible solvents are used. Hence, the categorization of solvents in terms of miscibility becomes less relevant. This accounts for the "two peak" dependence of catalytic activity on water content in some miscible systems. Differential solvation of reactants and products, as the bulk phase is altered, causes changes in concentration-based equilibrium constants and yields. These changes in solvation may be monitored through partition coefficient or solubility measurements. Reactant solvation can also account for differences in biocatalyst kinetics, whether or not partitioning into a dilute aqueous phase is involved. These predictable effects should be allowed for when studying effects of solvent or similar changes on activity or specificity.(ABSTRACT TRUNCATED AT 400 WORDS)

Comparative studies on species-specific reactivity between renin and angiotensinogen

The renin-angiotensin system (RAS) is the most important regulator of electrolyte homeostasis and blood pressure. Our recently generated transgenic mice carrying either the human renin (hREN) or human angiotensinogen (hANG) genes did not develop hypertension but dual gene strains obtained by cross-mating separate lines of mice exhibited a chronically sustained increase in blood pressure, suggesting the presence of species-specific reactivity between renin and angiotensinogen. In order to examine this specificity, the present study was designed to perform a strictly comparative study on hydrolysis of hANG by hREN and mouse submandibular renin (mREN) in vitro by using pure proteins. The recombinant hANG (rhANG) and the synthetic human-type tridecapeptide (hTDP), Asp-Arg-Val-Tyr-Ile-His-Pro-Phe-His-Leu-Val-Ile-His, corresponding to the N-terminal sequences of hANG, were used to determine the species specificity of recombinant hREN (rhREN) and mREN. While hTDP was cleaved by both rhREN and mREN with similar Km and with the same order of kcat, rhANG was cleaved by mREN with 16.7-fold higher Km and with 28.2-fold lower kcat than by rhREN. These results showed that kcat/Km value of mREN for rhANG was 468-fold lower than that for rhREN acting on rhANG.

Single peptide bond hydrolysis/resynthesis in squash inhibitors of serine proteinases. 1. Kinetics and thermodynamics of the interaction between squash inhibitors and bovine beta-trypsin

The substrate and inhibitory parameters are described for the interaction between Cucurbita maxima trypsin inhibitor I (CMTI I) and bovine beta-trypsin. The data are fully consistent with the reactive site hypothesis and the standard mechanism proposed for the protein inhibitor-serine proteinase interaction. The second-order association rate constant (k(on)) for the interaction of the intact inhibitor and trypsin is high, above 10(6) M-1 s-1. The same value is only 22-fold lower for the reactive site hydrolyzed inhibitor. This result implicates a very low transition-state barrier for the hydrolysis of the Arg5-Ile6 reactive site peptide bond. The equilibrium constant Ka (= 1/Km,f) and K(assoc) change by 6 orders of magnitude in the pH range 4.0-8.3. The steady-state parameters for the hydrolysis and resynthesis of the reactive site have been determined over the pH range 3.2-8.3. Catalytic rate constants, but not kcat/km, exhibit strong pH dependence. The dependence of the hydrolysis constant (Khyd) on pH fits the simplest form of the Dobry equation, indicating that after the hydrolysis of the reactive site, pK values of any preexistent groups are not perturbed. It is suggested that a major factor leading to high kcat/Km values is the presence of Arg or Lys residues at the P1 position. Low values of Km result from a conservation of the ground-state conformation of the inhibitor binding loop upon the complex formation. The crucial stage of the reactive site hydrolysis seems to be associated with a change of basic side-chain interactions within the S1 binding pocket.

Flavin dynamics in oxidized Clostridium beijerinckii flavodoxin as assessed by time-resolved polarized fluorescence

The time-resolved fluorescence characteristics of flavin in oxidized flavodoxin isolated from the anaerobic bacterium Clostridium beijerinckii have been examined. The fluorescence intensity decays were analyzed using the maximum-entropy method. It is demonstrated that there exist large differences in fluorescence behaviour between free and protein-bound FMN. Three fluorescence lifetime components are found in oxidized flavodoxin, two of which are not present in the fluorescence-intensity decay of free FMN. The main component is distributed at 30 ps, with relative contribution of 90%. Another minor component (4% contribution) is distributed at 0.5 ns. The third component is distributed at 4.8 ns (6%), coinciding with the main distribution present in the fluorescence decay of free FMN. The results allowed us to determine the dissociation constant, Kd = 2.61 x 10(-10) M (at 20 degrees C). Collisional fluorescence-quenching experiments revealed that the flavin moiety responsible for the longest fluorescence lifetime is, at least partially, exposed to the solvent. The shortest lifetime is not affected significantly, indicating that it possibly originates from an active-site conformation in which the flavin is more or less buried in the protein and not accessible to iodide. The fluorescence anisotropy behaviour of free and protein-bound FMN was examined and analyzed with the maximum-entropy method. It was found that an excess of apoflavodoxin is required to detect differences between free and protein-bound FMN. In free FMN one single distribution of rotational correlation times is detected, whereas in flavodoxin the anisotropy decay is composed of more than one distribution. Associative analysis of fluorescence anisotropy decays shows that part of the 4.8 ns fluorescence lifetime present in the flavodoxin fluorescence decay, is coupled to a rotational correlation time similar to that of free FMN in solution, while another part of this lifetime is coupled to a longer correlation time of about 1 ns. This finding is in accordance with earlier studies [Barman, B. G. & Tollin, G. (1972) Biochemistry 11, 4746-4754] in which it was proposed that the first binding step of the flavin to the protein involves the phosphate group rather than another part of the FMN. The two shortest fluorescence lifetimes, which do not carry information on the long-term rotational behaviour of the protein, seem nonetheless to be associated with a longer rotational correlation time which is comparable to overall protein tumbling. These lifetime components probably originate from a complex in which the flavin-ring system is more or less immobilized within the protein matrix.

Characterization of the backbone dynamics of an anti-digoxin antibody VL domain by inverse detected 1H-15N NMR: comparisons with X-ray data for the Fab

The dynamic behavior of the polypeptide backbone of a recombinant antidigoxin antibody VL domain has been characterized by measurements of 15NT1 and T2 relaxation times, 1H-15N NOE values, and 1H-2H exchange rates. These data were acquired with 2D inverse detected heteronuclear 1H-15N NMR methods. The relaxation data are interpreted in terms of model free spectral density functions and exchange contributions to transverse relaxation rates R2 (= 1/T2). All characterized residues display low-amplitude picosecond time-scale librational motions. Fifteen residues undergo conformational changes on the nanosecond timescale, and 24 residues have significant R2 exchange contributions, which reflect motions on the microsecond to millisecond time-scale. For several residues, microsecond to millisecond motions of nearby aromatic rings are postulated to account for some or all of their observed R2 exchange contributions. The measured 1H-2H exchange rates are correlated with hydrogen bonding patterns and distances from the solvent accessible surface. The degree of local flexibility indicated by the NMR measurements is compared to crystallographic B-factors derived from X-ray analyses of the native Fab and the Fab/digoxin complex. In general, both the NMR and X-ray data indicate enhanced flexibility in the turns, hypervariable loops, and portions of beta-strands A, B, and G. However, on a residue-specific level, correlations among the various NMR data, and between the NMR and X-ray data, are often absent. This is attributed to the different dynamic processes and environments that influence the various observables. The combined data indicate that certain regions of the VL domain, including the three hypervariable loops, undergo dynamic changes upon VL:VH association and/or complexation with digoxin. Overall, the 26-10 VL domain exhibits relatively low flexibility on the ps-ns timescale. The possible functional consequences of this result are considered.

Flavin dynamics in reduced flavodoxins. A time-resolved polarized fluorescence study

The time-resolved fluorescence and fluorescence anisotropy characteristics of reduced flavin mononucleotide in solution as well as bound in flavodoxins isolated from the bacteria Desulfovibrio gigas, Desulfovibrio vulgaris, Clostridium beijerinckii MP and Megasphaera elsdenii have been examined. All fluorescence and fluorescence anisotropy decays were analyzed by two different methods: (a) least-squares fitting with a sum of exponentials and (b) the maximum entropy method to yield distributed lifetimes and correlation times. The results of both approaches are in excellent agreement. The fluorescence decay of the free as well as protein-bound reduced flavin chromophore is made up of three components. The shortest component proves to be relatively sensitive to the environment and can therefore be used as a diagnostic tool to probe the microenvironment of the reduced isoalloxazine ring system. The other two longer fluorescence lifetime components are insensitive to the chromophore environment and seem therefore to be related to intrinsic, photophysical properties of the reduced chromophore. Fluorescence anisotropy decays show that the flavin mononucleotide in all four reduced flavodoxins is immobilized within the protein matrix, as indicated by the recovery of a single rotational correlation time, reflecting the rotation of the whole protein. No indications are found that rapid structural fluctuations occur in reduced flavodoxins, and the mechanism of electron transfer from flavodoxin to other redox proteins seems to involve immobilized reduced flavin.

Kinetics of intermolecular cleavage by hammerhead ribozymes

The hammerhead catalytic RNA effects cleavage of the phosphodiester backbone of RNA through a transesterification mechanism that generates products with 2'-3'-cyclic phosphate and 5'-hydroxyl termini. A minimal kinetic mechanism for the intermolecular hammerhead cleavage reaction includes substrate binding, cleavage, and product release. Elemental rate constants for these steps were measured with six hammerhead sequences. Changes in substrate length and sequence had little effect on the rate of the cleavage step, but dramatic differences were observed in the substrate dissociation and product release steps that require helix-coil transitions. Rates of substrate binding and product dissociation correlated well with predictions based on the behavior of simple RNA duplexes, but substrate dissociation rates were significantly faster than expected. Ribozyme and substrate alterations that eliminated catalytic activity increased the stability of the hammerhead complex. These results suggest that substrate destabilization may play a role in hammerhead catalysis.

Forces, bond lengths, and reactivity: fundamental insight into the mechanism of enzyme catalysis

Comparison of spectroscopic, kinetic, and thermodynamic data for a series of functioning acylserine proteases suggests that the observed variation in deacylation rates can be accounted for by changes in the properties of the acyl-enzyme's ground state. The acyl-enzyme's catalytically crucial acyl carbonyl group is probed by resonance Raman spectroscopy. Its spectral frequency is used to gauge both the carbonyl bond length and the strength of hydrogen bonding (originating from groups making up the oxyanion hole) to the carbonyl oxygen atom. As the deacylation rate increases 16,300-fold through the series, a shift in carbonyl frequency, vC = O, of -54 cm-1 corresponds to a carbonyl bond length increase of 0.025 A. The decrease in vC = O is also consistent with an increase in hydrogen bond donor enthalpy of -27 kJ mol-1. Interestingly, this value resembles closely the decrease in activation energy for deacylation through the series, 24 kJ mol-1, demonstrating that the hydrogen bonds to the carbonyl oxygen atom can provide sufficient energy to account for the observed rate accelerations.

Vibrationally enhanced tunneling as a mechanism for enzymatic hydrogen transfer

We present a theory of enzymatic hydrogen transfer in which hydrogen tunneling is mediated by thermal fluctuations of the enzyme's active site. These fluctuations greatly increase the tunneling rate by shortening the distance the hydrogen must tunnel. The average tunneling distance is shown to decrease when heavier isotopes are substituted for the hydrogen or when the temperature is increased, leading to kinetic isotope effects (KIEs)--defined as the factor by which the reaction slows down when isotopically substituted substrates are used--that need be no larger than KIEs for nontunneling mechanisms. Within this theory we derive a simple KIE expression for vibrationally enhanced ground state tunneling that is able to fit the data for the bovine serum amine oxidase (BSAO) system, correctly predicting the large temperature dependence of the KIEs. Because the KIEs in this theory can resemble those for nontunneling dynamics, distinguishing the two possibilities requires careful measurements over a range of temperatures, as has been done for BSAO.

Analysis of ground-state and transition-state effects in enzyme catalysis

"The entire and sole source of catalytic power is the stabilization of the transition state; reactant-state interactions are by nature inhibitory and only waste catalytic power". So reads a literature quote expressing the current view on enzyme catalysis proposed by Pauling over 40 years ago. Its validity is now examined by means of a "split-site" model in which an active site is subdivided into a region of binding and a region of reaction. Analysis of the resulting free energy levels clarifies several points of confusion regarding the nature of enzyme catalysis, including why enzyme/substrate complexes form if, indeed, they only "waste catalytic power". Circumstances are defined in which an evolving enzyme can both lower Km (i.e., enhance substrate binding) and improve the forward catalytic rate while never meddling with the transition structure at the reactive site. It is argued that this process is most advantageously viewed as a substrate destabilization embodying "conserved" interactions at the binding region. Classical transition-state stabilization and an "anti-Pauling" effect are both capable of inducing rate accelerations. In certain circumstances, the latter can predominate as it does with many enzyme-like intramolecular reactions. Behavioral modes discussed herein are applicable to the chemistry of catalytic host/guest and enzyme systems.

Human alpha-L-iduronidase. Catalytic properties and an integrated role in the lysosomal degradation of heparan sulphate

The kinetic parameters (Km and kcat) of human liver alpha-L-iduronidase were determined with a variety of heparin-derived disaccharide and tetrasaccharide substrates. More structurally complex substrates, in which several aspects of the aglycone structure of the natural substrates heparin and heparan sulphate were maintained, were hydrolysed with catalytic efficiencies up to 255 times that observed for the simplest disaccharide substrate to be hydrolysed. The major aglycone structure that influenced both substrate binding and enzyme activity was the presence of a C-6 sulphate ester on the residue adjacent to the iduronic acid residue being hydrolysed. Sulphate ions and a number of substrate and product analogues were potent inhibitors of enzyme activity. Human liver alpha-L-iduronidase activity towards 4-methylumbelliferyl alpha-L-iduronide at pH 4.8 had two Km values of 37 microM and 1.92 mM with corresponding kcat. values of 299 and 650 mol of product formed/min per mol of enzyme respectively, which may explain the wide range of Km values previously reported for alpha-L-iduronidase activity toward its substrate. Skin fibroblast alpha-L-iduronidase activity towards the heparin-derived oligosaccharides was influenced by the same substrate aglycone structural features as was observed for the human liver enzyme. A comparison was made of the effect of substrate aglycone structure upon catalytic activities of the enzymes which act to degrade the highly sulphated regions of heparan sulphate. A model was proposed whereby the substrate is directed from alpha-L-iduronidase to subsequent enzyme activities to ensure the efficient degradation of heparan sulphate.

Subtilisin from Bacillus subtilis strain 72. The influence of substrate structure, temperature and pH on catalytic properties

Kinetic constants for the hydrolysis of the series of p-nitroanilide peptide substrates catalyzed by subtilisin from Bacillus subtilis strain 72 have been determined. The series of N-protected p-nitroanilides of the Z-A2-A1-pNA, Z-A3-A2-A1-pNA, Z-A4-A3-A2-A1-pNA types (Z-, benzyloxycarbonyl-1; -pNA, p-nitroanilide; A1-An, amino acid residues of the L-configuration) have been used. Subsite S1 reveals a preference for hydrophobic amino acid residues, i.e., leucine and phenylalanine. A preference for Leu over Phe at this position is manifested at the catalytic step, but not during the binding process. The beta-branched (Val, Ile) and the basic (Arg) amino acid residues cannot interact with the S1 subsite and the hydrolysis of the corresponding peptides occurs exclusively at the A2-A1 bond. If S1/A1 interactions are weak (Ala, Nva, Nle), the amino acid residue A1 can interact with subsites S1 and S'1 resulting in the hydrolysis at two bonds (A1-pNA and A2-A1). The data obtained suggests that the S'1 subsite is of broad selectivity. Subsite S2 reveals a preference for small amino acid residues. At pH 5.5-9 and below 50 degrees C, the subtilisin study does not lose its activity. At higher temperatures a rapid thermoinactivation occurs. Substrate binding stabilizes the enzyme. The temperature dependences of the kinetic and thermodynamic parameters suggest that the enzyme exists in two, i.e., 'cold' and 'hot' forms. At 22 degrees C the 'cold' form turns into the 'hot' one possibly owing to a conformational change. The enzyme-substrate complex does not exhibit such behavior and exists in only one form in the whole temperature range studied. The activity of an uncomplexed enzyme is controlled by a group of pKa = 7.2 +/- 0.1, which probably belongs to the histidine imidazole.

Ab initio calculations of the pyrophosphate hydrolysis reaction

Ab initio quantum mechanical calculations were used to study the hydrolysis reaction H4P2O7 + H2O in equilibrium with 2H3PO4, as well as some molecular properties of the reactants and products. SCF calculations with several basis sets ranging from minimal to extended with polarization functions were used to look at the basis dependency of the reaction enthalpies and optimized geometries. Although the minimal basis sets yield erratic predictions of the enthalpy, when a more extended basis (3-21G*) was used for the geometry optimization, and the total energies of the reactants and products were computed with this and larger basis sets, we obtained more consistent predictions of the structural properties of the P-O-P bridge and of the heat of the hydrolysis reaction (delta E = -7.39 kcal/mol at the SCF/6-31G** level). A comparison is made with previous estimates performed with smaller basis sets and without taking into account the electron correlation effects, which are calculated in the present work. The inclusion of the zero point energy calculated using the harmonic approximation, and of the electronic correlation energy determined at the MBPT(2) level, raised the computed heat of the reaction to -3.83 kcal/mol, and when an estimate for the thermal energy was added, the value obtained was of -3.38 kcal/mol. In conclusion, we found that the hydrolysis of pyrophosphate should be exothermic in the gas phase. The implications of this result in relation to some recent theories about enzyme catalysis are discussed.