Exploring the specific features of interfacial enzymology based on lipase studies

Many enzymes are active at interfaces in the living world (such as in the signaling processes at the surface of cell membranes, digestion of dietary lipids, starch and cellulose degradation, etc.), but fundamental enzymology remains largely focused on the interactions between enzymes and soluble substrates. The biochemical and kinetic characterization of lipolytic enzymes has opened up new paths of research in the field of interfacial enzymology. Lipases are water-soluble enzymes hydrolyzing insoluble triglyceride substrates, and studies on these enzymes have led to the development of specific interfacial kinetic models. Structure-function studies on lipases have thrown light on the interfacial recognition sites present in the molecular structure of these enzymes, the conformational changes occurring in the presence of lipids and amphiphiles, and the stability of the enzymes present at interfaces. The pH-dependent activity, substrate specificity and inhibition of these enzymes can all result from both "classical" interactions between a substrate or inhibitor and the active site, as well as from the adsorption of the enzymes at the surface of aggregated substrate particles such as oil drops, lipid bilayers or monomolecular lipid films. The adsorption step can provide an alternative target for improving substrate specificity and developing specific enzyme inhibitors. Several data obtained with gastric lipase, classical pancreatic lipase, pancreatic lipase-related protein 2 and phosphatidylserine-specific phospholipase A1 were chosen here to illustrate these specific features of interfacial enzymology.     

Mechanistic studies of sodium pump

Sodium pump was the first ion pump discovered. A member of the family of active transporters that catalyze adenosine 5′-triphosphate hydrolysis by forming a phosphorylated enzyme intermediate, sodium pump couples the energy released to unequal countertransport of sodium and potassium ions. The ion gradient generated by the pump is important for a variety of secondary physiological processes ranging from metabolite transport to electrical excitation of nerve and muscle. Selected experiments relating structure to function are reviewed.     

An alginate lysate from Azotobacter vinelandii phage.

The alginate depolymerase associated with bacteriophage infection of Azotobacter vinelandii has been used in the analysis of sodium alginate. The enzyme degraded the polysaccharide to a series of oligouronides each containing a terminal 4-deoxy-alpha-L-erythro-hex-4-enopyranuronosyl residue. Analysis of these oligouronides, together with kinetic information, indicated that the enzyme was specific for mannuronic acid-containing regions of the polyuronide. The specificity of the enzyme made it possible to determine the primary structure of the macro-molecule. The phage-induced enzyme was shown to be distinct from the alginate lyase elaborated by the host organisms by its pH optimum, molecular weight, Michaelis constant and stability.     

Enzymology in monophasic organic media.

Over the past year, an important area of research has been directed towards the fundamental aspects of enzymes and new applications of enzymology in monophasic organic media. Much of this research has focused on the factors that influence enzymatic catalysis in monophasic organic solvents, including the importance of enzyme-associated water, and the effect of organic solvents on enzyme structure and thermodynamic features. From an applications perspective, new advances in the use of enzymes in organic and polymer syntheses and optical resolutions have been made.     

A new hat for an old enzyme: waste management

The history of research regarding secretory phospholipase A(2) (sPLA(2)) has often focused in one of two directions. Originally, the enzyme was studied biophysically in terms of its fundamental structure, enzymology, and the relationship between membrane physics and catalytic activity. More recently, a large and growing body of information has accumulated concerning regulatory factors, tissue distribution, and physiological/pathological roles of sPLA(2). Evidence is presented that suggests an additional function for the protein in which it helps to clear dead and damaged cells while avoiding digestion of those that are healthy. Apparently, the ability of the enzyme to discriminate between susceptible and resistant cells depends on physical properties of membrane lipids related to order, distribution, and neighbor/neighbor interactions. Investigations into this action of the enzyme offer the rare opportunity to apply biophysical approaches and principles to a physiological setting.     

gamma-Glutamylcysteine synthetase. Further purification, "half of the sites" reactivity, subunits, and specificity.

gamma-Glutamylcysteine synthetase was purified from rat liver by an improved method involving chromatography on Sepharose-aminohexyl-ATP to a specific activity of about 1600 units/mg, or approximately twice that previously obtained; it is thus the most active preparation of this enzyme thus far isolated. The earlier preparation, which is homogeneous on polyacrylamide gel electrophoresis, exhibits "half of the sites" reactivity in that it binds a maximum of 0.5 mol of the inhibitor L-methionine-S-sulfoximine phosphate per mol of enzyme. In contrast, the present enzyme preparation binds 1 mol of methionine sulfoximine phosphate per mol of enzyme; it also differs from the enzyme obtained earlier in exhibiting much less ATPase activity and less activity in catalyzing ATP-dependent cyclization of glutamate. gamma-Glutamylcysteine synthetase dissociates in sodium dodecyl sulfate into two nonidentical subunits of apparent molecular weights 74,000 and 24,000; after cross-linking with dimethyl-suberimidate, a species having a molecular weight of about 100,000 was found on sodium dodecyl sulfate-polyacrylamide gel electrophoresis. New information has been obtained about the interaction of the enzyme with glutamate analogs; thus, the enzyme is active with such glutamate analogs as beta-glutamate, N-methyl-L-glutamate, and threo-beta-hydroxy-L-glutanate, and it is effectively inhibited by cis-1-amino-1,3-dicarboxycyclonexane, 2-amino-4-phosphonobutyrate, and gamma-methylglutamate.     

Enzyme stabilization: state of the art

Enzyme stabilization is one of the most important fields in basic and applied enzymology. In basic enzymology, it is of particular relevance to understand enzyme stabilization principles first elucidating how and why the enzymes lose their biological activity and then deriving structure-stability relationships existing in enzymatic molecules. In applied enzymology, the most significant goal is to achieve useful compounds by biocatalysis. Enzymes are good catalysts in terms of high catalytic and specific activity with ability to function under mild conditions. However, they are not always ideal catalysts for practical applications because they are generally unstable and they inactivate rapidly through several mechanisms. In order to enhance enzyme stability, many strategies have been pursued in recent years. The present article is an attempt to provide detailed information about these strategies.     

Expression of guinea-pig liver transglutaminase cDNA in Escherichia coli. Amino-terminal N alpha-acetyl group is not essential for catalytic function of transglutaminase

Transglutaminases (EC 2.3.2.13) catalyze the formation of epsilon-(gamma-glutamyl)lysine cross-links and the substitution of a variety of primary amines for the gamma-carboxamide groups of protein-bound glutamine residues. These enzymes are involved in many biological phenomena. Transglutaminase reactions also have been shown to be suitable for applied enzymology. In this study, as a first step of studies to elucidate the structure/function relationship of transglutaminase, we constructed an expression plasmid, pKTG1, containing a cDNA of guinea-pig liver transglutaminase between the NcoI and PstI sites of an expression vector, pKK233-2, and produced the liver transglutaminase as an unfused protein in Escherichia coli. The purified recombinant enzyme was indistinguishable from natural liver transglutaminase in some structural properties such as molecular mass, amino acid composition, and amino- and carboxyl-terminal sequences. However, the alpha-amino group of the amino-terminal alanine residue of the recombinant transglutaminase was not acetylated as was that of the natural enzyme. Comparison of the recombinant enzyme with the natural one did not indicate significant differences in specific activity and apparent Km values for substrates in the histamine incorporation into acetyl alpha s1-casein. The sensitivity to activation by Ca2+ and the rate of catalyzed protein cross-linking were also similar between recombinant and natural transglutaminases. These results indicated that the N alpha-acetyl group in natural liver transglutaminase has not a particular role in the catalytic function of this enzyme.     

Digitalis-like activity in human plasma. Purification, affinity, and mechanism

A factor having digitalis-like characteristics has been isolated from human plasma and its mechanism of action compared with the commonly used cardenolide, ouabain. The purification scheme involved dialysis of human plasma, lyophilization of dialysate, extraction of methanol-soluble components, and flash evaporation, followed by preparative, semipreparative, and analytical scale reverse-phase chromatography. One peak of biologically active material was obtained and shown to possess digitalis-like activity in assays of sodium pump activity, receptor binding, and Na,K-ATPase activity. Results from (i) the determination of the ligand conditions supporting binding, (ii) kinetics of association and dissociation from the Na,K-ATPase, (iii) affinity titration, (iv) selectivity, and (v) competition studies, when taken together, show that the endogenous digitalis-like factor is a specific inhibitor of the sodium pump that stabilizes the E2P form of the enzyme in a manner analogous to ouabain. The endogenous digitalis-like factor binds competitively in or near the receptor site for cardiac glycosides with an apparent affinity 8-20-fold greater than any known cardioactive steroid. The presence of digitalis-like activity in the circulation of individuals with no known intake of these compounds suggests that the material characterized here is an endogenous counterpart to the cardenolides. This factor may regulate sodium pump activity and provide a rationale for the existence of gene and tissue-specific forms of the Na,K-ATPase having distinct sensitivity to the cardenolides.     

Glutamic acid 472 and lysine 480 of the sodium pump alpha 1 subunit are essential for activity. Their conservation in pyrophosphatases suggests their involvement in recognition of ATP phosphates.

P-type ATPases such as the Na+,K+-ATPase (sodium pump) hydrolyze ATP to pump ions through biological membranes against their electrochemical gradients. The mechanisms that couple ATP hydrolysis to the vectorial ion transport are not yet understood, but unveiling structures that participate in ATP binding and in the formation of the ionophore might help to gain insight into this process. Looking at the alpha- and beta-phosphates of ATP as a pyrophosphate molecule, we found that peptides highly conserved among all soluble inorganic pyrophosphatases are also present in ion-transporting ATPases. Included therein are Glu48 and Lys56 of the Saccharomyces cerevisiae pyrophosphatase (SCE1-PPase) that are essential for the activity of this enzyme and have been shown in crystallographic analysis to interact with phosphate molecules. To test the hypothesis that equivalent amino acids are also essential for the activity of ion-transporting ATPases, Glu472 and Lys480 of the sodium pump alpha 1 subunit corresponding to Glu48 and Lys56 of SCE1-PPase were mutated to various amino acids. Mutants of the sodium pump alpha1 subunit were expressed in yeast and analyzed for their ATPase activity and their ability to bind ouabain in the presence of either ATP, Mg2+, and Na+ or phosphate and Mg2+. All four mutants investigated, Glu472Ala, Glu472Asp, Lys480Ala, and Lys480Arg, display only a fraction of the ATPase activity obtained with the wild-type enzyme. The same applies with respect to their ability to bind ouabain, where maximum ouabain binding to the mutants accounts for only about 10% of the binding obtained with the wild-type enzyme. On the basis of our results, we conclude that Glu472 and Lys480 are essential for the activity of the sodium pump. Their function is probably to arrest the alpha- and beta-phosphate groups of ATP in a proper position prior to hydrolysis of the gamma-phosphate group. The identification of these amino acids as essential components of the ATP-recognizing mechanism of the pump has resulted in a testable hypothesis for the initial interactions of the sodium pump, and possibly of other P-type ATPases, with ATP.     

Protein-derived cofactors. Expanding the scope of post-translational modifications

Recent advances in enzymology, structural biology, and protein chemistry have extended the scope of the field of cofactor-dependent enzyme catalysis. It has been documented that catalytic and redox-active prosthetic groups may be derived from post-translational modification of amino acid residues of proteins. These protein-derived cofactors typically arise from the oxygenation of aromatic residues, covalent cross-linking of amino acid residues, or cyclization or cleavage of internal amino acid residues. In some cases, the post-translation modification is a self-processing event, whereas in others, another processing enzyme is required. The characterization of protein-derived cofactors and their mechanisms of biogenesis introduce a new dimension to our current views about protein evolution and protein structure-function relationships.     

To keep or not to keep? the question of crystallographic waters for enzyme simulations in organic solvent

The use of enzymes in non-aqueous solvents expands the use of biocatalysts to hydrophobic substrates, with the ability to tune selectivity of reactions through solvent selection. Non-aqueous enzymology also allows for fundamental studies on the role of water and other solvents in enzyme structure, dynamics, and function. Molecular dynamics simulations serve as a powerful tool in this area, providing detailed atomic information about the effect of solvents on enzyme properties. However, a common protocol for non-aqueous enzyme simulations does not exist. If you want to simulate enzymes in non-aqueous solutions, how many and which crystallographic waters do you keep? In the present work, this question is addressed by determining which crystallographic water molecules lead most quickly to an equilibrated protein structure. Five different methods of selecting and keeping crystallographic waters are used in order to discover which crystallographic waters lead the protein structure to reach an equilibrated structure more rapidly in organic solutions. It is found that buried waters contribute most to rapid equilibration in organic solvent, with slow-diffusing waters giving similar results.     

Insect Na(+)/K(+)-ATPase

Na(+)/K(+)-ATPase (sodium/potassium pump) is a P-type ion-motive ATPase found in the plasma membranes of animal cels. In vertebrates, the functions of this enzyme in nerves, heart and kidney are well characterized and characteristics a defined by different isoforms. In contrast, despite different tissue distributions, insects possess a single isoform of the alpha-subunit. A comparison of insect and vertebrate Na(+)/K(+)-ATPases reveals that although the mode of action and structure are very highly conserved, the specific roles of the enzyme in most tissues varies. However, the enzyme is essential for the function of nerve cells, and in this respect Na(+)/K(+)-ATPase appears to be fundamental in metazoan evolution.     

Effects of Ca2+ on the sodium pump observed in cardiac myocytes isolated from guinea pigs

It is presently unknown whether Ca2+ plays a role in the physiological control of Na+/K+-ATPase or sodium pump activity. Because the enzyme is exposed to markedly different intra- and extracellular Ca2+ concentrations, tissue homogenates or purified enzyme preparations may not provide pertinent information regarding this question. Therefore, the effects of Ca2+ on the sodium pump were examined with studies of [3H]ouabain binding and 86Rb+ uptake using viable myocytes isolated from guinea-pig heart and apparently maintaining ion gradients. In the presence of K+, a reduction of the extracellular Ca2+ increased specific [3H]ouabain binding observed at apparent binding equilibria: a half-maximal stimulation was observed when extracellular Ca2+ was lowered to about 50 microM. The change in [3H]ouabain binding was caused by a change in the number of binding sites accessible by ouabain instead of a change in their affinity for the glycoside. Ouabain-sensitive 86Rb+ uptake was increased by a reduction of extracellular Ca2+ concentration. Benzocaine in concentrations reported to reduce the rate of Na+ influx failed to influence the inhibitory effect of Ca2+ on glycoside binding. When [3H]ouabain binding was at equilibrium, the addition of Ca2+ decreased and that of EGTA increased the glycoside binding. Mn2+, which does not penetrate the cell membrane, had effects similar to Ca2+. In the absence of K+, cells lose their tolerance to Ca2+. Reducing Ca2+ concentration prevented the loss of rod-shaped cells but failed to affect specific [3H]ouabain binding observed in the absence of K+. These results indicate that a large change in extracellular Ca2+ directly affects the sodium pump in cardiac myocytes isolated from guinea pigs.     

Mechanisms of sodium pump regulation

TheNa⁺-K⁺-ATPase, or sodium pump, is themembrane-bound enzyme that maintains the Na⁺ andK⁺ gradients across the plasma membrane of animal cells.Because of its importance in many basic and specialized cellularfunctions, this enzyme must be able to adapt to changing cellular andphysiological stimuli. This review presents an overview of themany mechanisms in place to regulate sodium pump activity in atissue-specific manner. These mechanisms include regulation bysubstrates, membrane-associated components such as cytoskeletalelements and the -subunit, and circulating endogenous inhibitors aswell as a variety of hormones, including corticosteroids, peptidehormones, and catecholamines. In addition, the review considers theeffects of a range of specific intracellular signaling pathwaysinvolved in the regulation of pump activity and subcellulardistribution, with particular consideration given to the effects ofprotein kinases and phosphatases.

     

Porcine A blood group-specific N-acetylgalactosaminyltransferase. I. Purification from porcine submaxillary glands.

The membrane-bound N-acetylgalactosaminyltransferase from porcine submaxillary glands which provides A blood group specificity to mucin has been purified 38,000-fold by affinity chromatography on UDP-hesanolamine-agarose in aqueous Triton X-100. Design of a suitable purification procedure was developed by assessing the strength of interaction between enzyme and affinity adsorbent using batch desorption. The pure transferase has an apparent molecular weight of 100,000 as judged by zonal centrifugation and by sodium dodecyl sulfate polyacrylamide gel electrophoresis in the absence of a reducing agent. The reduced and carboxymethylated protein has an apparent molecular weight of 46,000 and 57,000 as judged by sedimentation equilibrium and sodium dodecyl sulfate polyacrylamide gel electrophoresis, respectively, suggesting that the native enzyme contains two subunits. It is a glycoprotein with a specific activity of 30 micronmol/min/mg of enzyme, which is 55,000 times that reported for the same enzyme isolated from human serum.     

Hepatitis C Virus Non-structural Protein 3 (HCV NS3): A Multifunctional Antiviral Target

Hepatitis C virus non-structural protein 3 contains a serine protease and an RNA helicase. Protease cleaves the genome-encoded polyprotein and inactivates cellular proteins required for innate immunity. Protease has emerged as an important target for the development of antiviral therapeutics, but drug resistance has turned out to be an obstacle in the clinic. Helicase is required for both genome replication and virus assembly. Mechanistic and structural studies of helicase have hurled this enzyme into a prominent position in the field of helicase enzymology. Nevertheless, studies of helicase as an antiviral target remain in their infancy.     

Dynamic model for enzyme action

Background: Protein thermodynamic structure theory is an integrated approach to the study of protein dynamics and the mechanisms of enzyme catalysis. In this paper, a hypothesis arising from this theory is examined. The timescale of an enzymatic reaction (TER) gives a key to characterizing enzyme conformational changes. The aspects of timescale important in our approach are: (i) it is logically related to internal motions of the main chain of a protein; (ii) it sets the upper limit on the size or scope of protein conformational changes. Feature (i) is linked to the dynamic properties of enzyme-reactant complexes. Feature (ii) is linked to the dynamic sites of the main chain (promoting motion) involved in enzyme activity. Conclusion: Our analysis shows that a comprehensive understanding of enzymology can be established on the basis of protein thermodynamic structure theory.     

Physicochemical properties of a lipase from Pseudomonas fluorescens.

The molecular weight of traicylglycerol lipase (EC 3.1.1.3) from Pseudomonas fluorescens is estimated to be approx. 33 000 by sodium dodecyl sulfate electrophoresis and Sephadex G-75 gel filtration. The lipase appears to be a single-chain protein and contains neither sugar nor lipid. The enzyme has a sedimentation coefficient (S20,w) of 3.06, an intrinsic viscosity of 3.0 g/ml and a partial specific volume of 0.730 g/ml, with an isoelectric point of pH 4.46. Amino acid analysis showed that the enzyme contained few sulfur-containing amino acid residues with no disulfide links. The N-terminal residue of the enzyme was found to be alanine and optical rotation dispersion analysis showed that about 20% of the enzyme structure was in a helicla configuration.