Comparative study on digestive lipase activities on the self emulsifying excipient Labrasol, medium chain glycerides and PEG esters

Labrasol is a lipid-based self-emulsifying excipient used in the preparation of lipophilic drugs intended for oral delivery. It is mainly composed of PEG esters and glycerides with medium acyl chains, which are potential substrates for digestive lipases. The hydrolysis of Labrasol by porcine pancreatic extracts, human pancreatic juice and several purified digestive lipases was investigated in the present study. Classical human pancreatic lipase (HPL) and porcine pancreatic lipase, which are the main lipases involved in the digestion of dietary triglycerides, showed very low levels of activity on the entire Labrasol excipient as well as on separated fractions of glycerides and PEG esters. On the other hand, gastric lipase, pancreatic lipase-related protein 2 (PLRP2) and carboxyl ester hydrolase (CEH) showed high specific activities on Labrasol. These lipases were found to hydrolyze the main components of Labrasol (PEG esters and monoglycerides) used as individual substrates, whereas these esters were found to be poor substrates for HPL. The lipolytic activity of pancreatic extracts and human pancreatic juice on Labrasol(R) is therefore mainly due to the combined action of CEH and PLRP2. These two pancreatic enzymes, together with gastric lipase, are probably the main enzymes involved in the in vivo lipolysis of Labrasol taken orally.     

Enzymatic assays for NAD-dependent deacetylase activities

The NAD-dependent deacetylases are a new class of enzymes responsible for the removal of acetyl groups from lysines on proteins. Instead of water, the NAD-dependent deacetylases use a highly reactive ADP-ribose intermediate as a recipient for the acetyl group. The products of the reaction are nicotinamide, acetyl-ADP-ribose, and a deacetylated substrate. Many assays have been developed for the measurement of NAD-dependent deacetylase activity. In this review we present assays based on each of the two reactions catalyzed by these enzymes, deacetylation and NAD hydrolysis. First we describe methods for the production of acetylated protein and peptide substrates for use in deacetylation reactions. Then we describe four methods for assaying deacetylation, three of which directly measure the loss of acetyl groups from a protein or peptide substrate, and one that measures acetate production. We also describe two indirect methods for following enzyme activity, NAD hydrolysis and a novel NAD-nicotinamide exchange reaction. Finally, a quantitative method using a monoacetylated peptide as a substrate and HPLC to measure products is described.     

α-Amylase structure and activity

Two computerized methods of predicting protein secondary structure from amino acid sequences are evaluated by using them on the α-amylase ofAspergillus oryzae, for which the three-dimensional structure has been determined. The methods are then used, with amino acid alignments, to predict the structures of other α-amylases. It is found that all α-amylases of known amino acid sequence have the same basic structure, a barrel of eight parallel stretches of extended chain surrounded by eight helices. Strong similarities are found in those areas of the proteins believed to bind an essential calcium ion and at that part of the active site that catalyzes bond hydrolysis in the substrates. The active site, as a whole, is formed mainly of amino acids situated on loops joining extended chain to the adjacent helix. Variations in the length and amino acid sequence of these loops, from one α-amylase to another, provide the differences in binding the substrates believed to account for the known variations in action pattern of α-amylases of different biological origins.     

Adsorption of cellulase on cellulose: Effect of physicochemical properties of cellulose on adsorption and rate of hydrolysis

In the cellulase-cellulose reaction system, the adsorption of cellulase on the solid cellulose substrate was found to be one of the important parameters that govern the enzymatic hydrolysis rate of cellulose. The adsorption of cellulase usually parallels the rate of hydrolysis of cellulose. The affinity for cellulase varies depending on the structural properties of cellulose. Adsorption parameters such as the half-saturation constant, the maximum adsorption constant, and the distribution coefficient for both the cellulase and cellulsoe have been experimentally determined for several substrates. These adsorption parameters vary with the source of cellulose and the pretreatment methods and are correlated with the crystallinity and the specific surface area of cellulose substrates. The changing pattern of adsorption profile of cellulase during the hydrolysis reaction has also been elucidated. For practical utilization of cellulosic materials, the cellulose structural properties and their effects on cellulase adsorption, and the rate of hydrolysis must be taken into consideration.     

Alteration of bond-cleavage pattern in the hydrolysis catalyzed by Saccharomycopsis alpha-amylase altered by site-directed mutagenesis.

The 210th lysine (K) residue in the Saccharomycopsis alpha-amylase (Sfamy) molecule was replaced by arginine (R) and asparagine (N) residues by site-directed mutagenesis. The influences of the replacements on the bond-cleavage pattern for several substrates were analyzed. Both mutant enzymes, K210R and K210N, cleave mainly the first glycosidic bond from the reducing end of maltotetraose (G4), while the native enzyme hydrolyzes mainly the second bond from the reducing end. We changed successfully the major cleavage point in the hydrolysis reaction of G4. The 8th subsite affinities of the K210R and K210N enzymes are calculated to be +2.52 and -0.01 kcal/mol, respectively, whereas that of the native enzyme is +3.32 kcal/mol as reported in the previous paper. These affinity values suggest that the K210 residue composes the 8th subsite, one of major subsites, and that a positively charged amino residue is necessary for the 8th subsite affinity. The K210N enzyme is found to be less active for short substrates like maltotetraose (G4) than for long substrates like amylose A (approximately G18). The reduced catalytic activity specifically for the short substrates is also attributable to the remarkable decrease in the affinity of the 8th subsite.     

Chromogenic and fluorogenic peptide substrates of proteolytic enzymes

The review describes approaches to designing chromogenic and fluorogenic substrates for proteolytic enzymes, mainly for assay of serine proteinases. Principles of substrate polypeptide chain construction and some methods for detection of chromogenic and fluorogenic products of their hydrolysis are considered. The use of these substrates for the study of blood clotting enzymes and for clinical diagnostics is briefly treated. Methodology of chemical synthesis of principal chromogenic and fluorogenic substrates is also discussed.     

Effect of salt composition of the medium and ethanol on cholinesterase hydrolysis of various substrates

Sodium chloride, phosphate buffer and ethanol were studied for their effect on butyryl cholinesterase hydrolysis rate of acetylcholine, acetylthiocholine, butyrylthiocholine and nonion substrate of indophenylacetate. The concentrations of 1.10(-2) = 1.10(-1) M of sodium chloride activated enzymatic hydrolysis of ion substrates at the concentrations lower than 1.10(-4) M but sodium chloride is a competitive inhibitor at higher concentrations. Phosphate buffer also activates substrates enzyme hydrolysis at the concentrations of 2.10(-4) M and lower, but it inhibits incompetitively the nonion substrate indophenylacetate hydrolysis. Ethanol activates butyrylthiocholine hydrolysis and is a competitive inhibitor in acetylthiocholine and indophenylacetate hydrolysis. The observed effects are discussed on the assumption of two forms of butyrylcholinesterase E' and E" existence. These two forms are determined by different kinetic parameters and are in equilibrium.     

The substrate requirements of phospholipase D

The hydrolysis rates of different diphosphates, compared with the one observed with natural phosphatidylcholine, are used to identify the molecular basis for phospholipase D (PLD) catalysis. Experimental data strongly support the idea that PLD is a rather generic phosphodiesterase with very wide substrate specificity and a net preference for lipophilic substrates. The presence of choline in the polar head is not required for activity although it improves hydrolysis efficiency. Choline esters are found to be substrates for PLD hydrolysis, but only with long chain fatty acids.     

Trypsin catalyzed hydrolysis of new chromogenic arginine substrates

Trypsin catalyzed hydrolysis of seven new chromogenic arginine substrates, N alpha-benzyloxycarbonyl-L-arginine-3-nitro-5X-anilide (X = H, CF3, SO2CH3, F, Cl, Br and I) were studied. These substrates are suitable for studying electronic effects on trypsin activity. The Km and kcat values for the hydrolysis of each substrate were determined and found to differ significantly for the various substrates. The Hammett plot of the catalytic rate constants gave a straight line with a negative rho value (-0.82) thus indicating that electron withdrawing substituents retard the trypsin catalyzed hydrolysis of the new anilide substrates.     

Interactions of derivatives of guanidinophenylalanine and guanidinophenylglycine with Streptomyces griseus trypsin

The rates of hydrolysis of the ester, amide and anilide substrates of p-guanidino-L-phenylalanine (GPA) by Streptomyces griseus trypsin (S. griseus trypsin) were compared with those of arginine (Arg) substrates. The specificity constant (kcat/km) for the hydrolysis of GPA substrates by the enzyme was 2-3-times lower than that for arginine substrates. The kcat and Km values for the hydrolysis of N alpha-benzoyl-p-guanidino-L-phenylalanine ethyl ester (Bz-GPA-OEt) by S. griseus trypsin are in the same order of magnitude as those of N alpha-benzoyl-L-arginine ethyl ester (Bz-Arg-OEt), although both values for the former when hydrolyzed by bovine trypsin are higher by one order of magnitude than those for the latter. The specificity constant for the hydrolysis of Bz-GPA-OEt by S. griseus trypsin is much higher than that for N alpha-benzoyl-p-guanidino-L-phenylglycine ethyl ester (Bz-GPG-OEt). As with the kinetic behavior of bovine trypsin, low values in Km and kcat were observed for the hydrolysis of amide and anilide substrates of GPA by S. griseus trypsin compared with those of arginine substrates. The rates of hydrolysis of GPA and arginine substrates by S. griseus trypsin are about 2- to 62-times higher than those obtained by bovine trypsin. Substrate activation was observed with S. griseus trypsin in the hydrolysis of Bz-GPA-OEt as well as Bz-Arg-OEt, whereas substrate inhibition was observed in three kinds of N alpha-protected anilide substrates of GPA and arginine. In contrast, no activation by the amide substrate of GPA could be detected with this enzyme.     

Ubiquitin receptors and ERAD: a network of pathways to the proteasome

The elimination of misfolded proteins, known as protein quality control, is an essential cellular process. Removal of misfolded proteins from the secretory pathway depends on their recognition in the endoplasmic reticulum (ER) followed by their retrograde transport into the cytosol for degradation. The AAA-ATPase Cdc48/p97 facilitates the translocation of misfolded ER-proteins into the cytosol. Cdc48/p97 can dock onto the ER-membrane via direct interaction with ER-membrane proteins and/or indirectly via its substrate-recruiting cofactors, which interact with the ubiquitylated substrates at the membrane. This tight interaction in conjunction with the conformational changes induced upon ATP hydrolysis within Cdc48/p97 is thought to provide the driving force for the translocation reaction. Subsequently, a series of protein-protein interactions between the Cdc48/p97 complex, its cofactors, and the ubiquitylated substrates is instrumental for the proper delivery of the ER substrates to the proteasome. These protein-protein interactions are governed mainly by ubiquitin-fold and ubiquitin-binding domains.     

Histochemical study of the phosphomonoesterases of cells producing steroid hormones]

The results of detection of phosphatases with different substrates in the cells forming steroid hormones in ovaries, testes and adrenals of newborn seals, ovaries of adult seals and adrenals of adult rabbits, dogs and man were compared. The first group of substrates includes sodium glycerophosphate, glucose-1-phosphate, nitrophenylphosphate (Gomori's sulfide method). The second group includes naphthol phosphates AS-BI, AS-MX and AS-BS, whose hydrolysis is determined by simultaneous and successive azocoupling with diazotized benzidine and stable diazotates by fast blue and fast cherry-coloured. Detection of phosphomonesterases in the cells forming steroid hormones with these two groups of substrates gives absolutely different results which are presented in the table. These results are thought to be associated with presence of the isoenzyme, intensively splitting azotholphosphates, but inhibited by the diazonium salt. This isoenzyme is found mainly in the cells producing steroid hormones.     

Simultaneous hydrolyses of esters and proteins at saturation levels

A direct titration method for the determination of proteolytic activity is discussed. This involves the potentiometric measurement of the volume of 0.08 N NaOH required to maintain a constant pH (8.0) during the time of the hydrolysis. It is a sensitive method which presents several advantages; viz., it measures simultaneously protease and esterase activity, it follows the hydrolysis very closely and from the first stages; the titration is continuous and on the same sample. This method determines a constant fraction of the groups titratable by formol titration. The ratio formol: direct titration is represented by a factor "f" which is presumed to be distinct for each protein-enzyme system. Kinetic studies, using this method, revealed that the rates of hydrolysis of mixtures casein-gelatin on one hand, casein-BAEE or gelatin-BAEE on the other, are always larger than those of the corresponding isolated substrates. In many cases the resulting rates are equal or nearly equal to the sum of the individual rates, even though the mentioned rates have been determined within the saturation zones for every substrate. The former observations are inconsistent with the theory of the formation of an intermediary enzyme-substrate compound, unless it is assumed that the enzyme has a specific active group for each substrate.     

Loss of endoplasmic reticulum membrane integrity: an image analysis of the glucose-6-phosphatase system in human hepatocyte.

Histochemical and cytochemical methods induce a loss of endoplasmic reticulum (ER) membrane integrity in hepatocytes. In order to evaluate the degree of ER membrane integrity, glucose-6-phosphatase (G6P-A) was localized in light and electron microscopy using glucose-6-phosphate (G6P) and mannose-6-phosphate (M6P) as substrates. In case of ER membrane alteration, M6P diffuses inside the ER and is hydrolysed by a non-specific phosphohydrolase. G6P and M6P hydrolysis was quantified with image analysis methods. In light microscopy, the ratio of reaction of M6P hydrolysis/G6P hydrolysis gave 75% of non specific reaction. In electron microscopic study this ratio was about 30%. These results showed that enzyme localization methods in electron microscopy produced less ER membrane alteration than light microscopic methods.     

Comparative studies of the specificities of α-chymotrypsin and subtilisin BPN′. Studies with flexible and `locked'' substrates

Subtilisin BPN' hydrolysed N-acetyl-l-3-(2-naphthyl)-alanine methyl ester, N-acetyl-l-leucine methyl ester and N-acetyl-l-valine methyl ester, faster than alpha-chymotrypsin. Of eight ;locked' substrates tested, only methyl 5,6-benzindan-2-carboxylate was hydrolysed faster by subtilisin, whereas the other esters were better substrates for chymotrypsin. Compared with the values for chymotrypsin, the stereospecific ratios during the hydrolysis of the optically active locked substrates by subtilisin were decreased by one and two orders of magnitude for bi- and tri-cyclic substrates respectively. The polar groups adjacent to the alpha-carbon atom of locked substrates did not contribute significantly to the reactivity of the more active optical isomers, but had a detrimental effect on the less active antipodes during hydrolysis by both the enzymes. These studies show that the binding site of subtilisin BPN' is longer and broader than that of alpha-chymotrypsin.     

A steady-state kinetic model of butyrylcholinesterase from horse plasma

The steady-state kinetics of the butyrylcholinesterase-catalysed hydrolysis of butyrylthiocholine and thiophenyl acetate were shown to deviate from Michaelis–Menten kinetics. The `best' empirical rate law was selected by fitting different rate equations to the experimental data by non-linear regression methods. The results were analysed in view of two alternative interpretations: (1) the reaction is catalysed by a mixture of enzymes, or (2) the activity is due to a single enzyme displaying deviations from Michaelis–Menten kinetics. It was concluded that the second alternative applies, and this conclusion was further supported by experiments involving simultaneous hydrolysis of alternative thiol ester substrates (butyrylthiocholine/thiophenyl acetate) as well as alternative thiol ester and oxygen ester substrates (butyrylthiocholine/phenyl acetate; thiophenyl acetate/butyrylcholine; acetylthiocholine/phenyl acetate). On the basis of the conclusion that a single enzyme is responsible for the activity, a molecular model is proposed. This model involves an acylated enzyme, and implies binding to the enzyme of one acyl group and one ester molecule, but not two ester molecules at the same time. Thus butyrylcholinesterase, which is structurally a tetramer, behaves functionally as a co-operative dimer, an interpretation in accordance with available data from active-site titrations.     

Myosin motor domain lever arm rotation is coupled to ATP hydrolysis

We have investigated coupling of lever arm rotation to the ATP binding and hydrolysis steps for the myosin motor domain. In several current hypotheses of the mechanism of force production by muscle, the primary mechanical feature is the rotation of a lever arm that is a subdomain of the myosin motor domain. In these models, the lever arm rotates while the myosin motor domain is free, and then reverses the rotation to produce force while it is bound to actin. These mechanical steps are coupled to steps in the ATP hydrolysis cycle. Our hypothesis is that ATP hydrolysis induces lever arm rotation to produce a more compact motor domain that has stored mechanical energy. Our approach is to use transient electric birefringence techniques to measure changes in hydrodynamic size that result from lever arm rotation when various ligands are bound to isolated skeletal muscle myosin motor domain in solution. Results for ATP and CTP, which do support force production by muscle fibers, are compared to those of ATPgammaS and GTP, which do not. Measurements are also made of conformational changes when the motor domain is bound to NDP's and PP(i) in the absence and presence of the phosphate analogue orthovanadate, to determine the roles the nucleoside moieties of the nucleotides have on lever arm rotation. The results indicate that for the substrates investigated, rotation does not occur upon substrate binding, but is coupled to the NTP hydrolysis step. The data are consistent with a model in which only substrates that produce a motor domain-NDP-P(i) complex as the steady-state intermediate make the motor domain more compact, and only those substrates support force production.     

Unexpected mode of action of sweet potato β-amylase on maltooligomer substrates

β-Amylase (EC 3.2.1.2), one of the main protein of the sweet potato, is an exo-working enzyme catalyzing the hydrolysis of α(1,4) glycosidic linkages in polysaccharides and removes successively maltose units from the non-reducing ends. The enzyme belongs to glycoside hydrolase GH14 family and inverts the anomeric configuration of the hydrolysis product. Multiple attack or processivity is an important property of polymer active enzymes and there is still limited information about the processivity of carbohydrate active enzymes. Action pattern and kinetic measurements of sweet potato β-amylase were made on a series of aromatic chromophor group-containing substrates (degree of polymerization DP 3-13) using HPLC method. Measured catalytic efficiencies increased with increasing DP of the substrates. Processive cleavage was observed on all substrates except the shortest pentamer. The mean number of steps without dissociation of enzyme–product complex increases with DP of substrate and reached 3.3 in case of CNPG11 indicating that processivity on longer substrates was more significant. A unique transglycosylation was observed on those substrates, which suffer processive cleavage and the substrates were re-built by the enzyme. Our results are the first presentation of a transglycosylation during an inverting glycosidase catalyzed hydrolysis. The yield of transglycosylation was remarkable high as shown in the change of the CNPG11 quantity. The CNPG11 concentration was doubled (from 0.24 to 0.54 mM) in the early phase of the reaction.     

The McrBC endonuclease translocates DNA in a reaction dependent on GTP hydrolysis.

McrBC specifically recognizes and cleaves methylated DNA in a reaction dependent on GTP hydrolysis. DNA cleavage requires at least two recognition sites that are optimally separated by 40-80 bp, but can be spaced as far as 3 kb apart. The nature of the communication between two recognition sites was analyzed on DNA substrates containing one or two recognition sites. DNA cleavage of circular DNA required only one methylated recognition site, whereas the linearized form of this substrate was not cleaved. However, the linearized substrate was cleaved if a Lac repressor was bound adjacent to the recognition site. These results suggest a model in which communication between two remote sites is accomplished by DNA translocation rather than looping. A mutant protein with defective GTPase activity cleaved substrates with closely spaced recognition sites, but not substrates where the sites were further apart. This indicates that McrBC translocates DNA in a reaction dependent on GTP hydrolysis. We suggest that DNA cleavage occurs by the encounter of two DNA-translocating McrBC complexes, or can be triggered by non-specific physical obstacles like the Lac repressor bound on the enzyme's path along DNA. Our results indicate that McrBC belongs to the general class of DNA "motor proteins", which use the free energy associated with nucleoside 5'-triphosphate hydrolysis to translocate along DNA.     

An enzymatic signal amplification system for calorimetric studies of cellobiohydrolases

The study of cellulolytic enzymes has traditionally been carried out using endpoint measurements by quantitation of reaction products using high-performance liquid chromatography (HPLC) or overall determination of produced reducing ends. To measure catalytic activity, model substrates such as solubilized cellulose derivates, soluble chromogenic, and flourogenic oligomeric substrates are often employed even though they do not reflect the natural insoluble substrate hydrolysis. Thermochemical methods using, for example, isothermal titration calorimetry (ITC) yield data where the primary observable is heat production. This can be converted to the rate of reaction and allows direct and continuous monitoring of the hydrolysis of complex substrates. To overcome the low molar enthalpy of the hydrolysis of the glycosidic bond, which is typically on the order of −2.5 kJ mol⁻¹, an enzymatic signal amplification method has been developed to measure even slow hydrolytically active enzymes such as cellobiohydrolases. This method is explained in detail for the amplification of the heat signal by more than 130 times by using glucose oxidase and catalase. The kinetics of this complex coupled reaction system is thoroughly investigated, and the potential use to generate kinetic models of enzymatic hydrolysis of unmodified cellulosic substrates is demonstrated.