Effect of 5-fluoro-2′-deoxyuridine and hydroxyurea on the phytohemagglutinin-induced increase of thymidine kinase,replicative DNA polymerase,deoxycytidylate deaminase and CDP reductase activities in human lymphocytes

Summary The inhibitors of DNA synthesis, 5-fluoro-2-deoxyuridine and hydroxyurea, caused an inhibition of thymidine kinase, replicative DNA polymerase and CDP reductase activities in stimulated lymphocytes when they were exposed to the inhibitors during the early transformation period (0–17 hr). However, the enzyme activities were unaffected when the inhibitors were added to cells stimulated for more than 17 hr. As opposed to these enzymes the deoxycytidylate deaminase activity was unaffected by the inhibitors during the entire transformation period (0–28 hr). This indicates a close regulatory mechanism in lymphocytes between DNA synthesis and induction of enzymes involved in DNA replication. The inhibitory mechanism exerted by the inhibitors is for the moment unknown. It might be independent of the well-known inhibition of the target enzymes, thymidylate synthetase and ribonucleoside diphosphate reductase, since there was no immediate apparent correlation in time between depletion of the pool sizes and the inhibition of the enzyme activities.     

Revisiting catalysis by chymotrypsin family serine proteases using peptide substrates and inhibitors with unnatural main chains.

Chymotrypsin family serine proteases play essential roles in key biological and pathological processes and are frequently targets of drug discovery efforts. This large enzyme family is also among the most advanced model systems for detailed studies of enzyme mechanism and structure/function relationships. Productive interactions between these enzymes and their substrates are widely believed to mimic the "canonical" interactions between serine proteases and "standard" inhibitors observed in numerous protease-inhibitor complexes. To test this central hypothesis we have synthesized and characterized a series of peptide analogs, based on model substrates and inhibitors of trypsin, that contain unnatural main chains. These results call into question a long accepted theory regarding the interaction of chymotrypsin family serine proteases with substrates and suggest that the canonical interactions observed between these enzymes and standard inhibitors may represent nonproductive rather than productive, substrate-like interactions.     

Isomeric derivatives of lupinine and epilupinine--organophosphorus inhibitors of cholinesterases

The isomeric-structure analysis data of anticholinesterase action of organophosphorous inhibitors with similar structure help in the search of specific effectors and detection of differences in reactivity of various animals' enzymes. This study compared the data of efficacy in respect of 4 mammal and 5 arthropoda cholinesterase preparations for 26 quinolizidine inhibitors, which molecules contain both the isomeric unbranched and branched alkoxyl radicals in the phosphoryl group, and the epimeric lupinine and epilupinine derivatives in the leaving group. The changes in the alkoxyl radical structure of inhibitor molecules act on their efficacy only with respect to the mammal enzymes ("group" inhibitor specificity). The differences between lupinine and epilupinine derivatives were revealed. Highly specific inhibitors of different enzymes were detected among the tested compounds.     

Ubiquitin-based anticancer therapy: Carpet bombing with proteasome inhibitors vs surgical strikes with E1, E2, E3, or DUB inhibitors

The proteasome inhibitor bortezomib remains the only ubiquitin pathway effector to become a drug (VELCADE?) and has become a successful treatment for hematological malignancies. While producing a global cellular effect, proteasome inhibitors have not triggered the catastrophe articulated initially in terms such as "buildup of cellular garbage". Proteasome inhibitors, in fact, do have a therapeutic window, although in the case of the prototype bortezomib it is small owing to peripheral neuropathy, myelosuppression and, as recently reported, cardiotoxicity [1]. Currently, several second-generation molecules are undergoing clinical evaluation to increase this window. An alternative strategy is to target ubiquitin pathway enzymes acting at non-proteasomal sites-E1, E2, and E3, associated with ubiquitin conjugation, and deubiquitylating enzymes ("DUBs")-that act locally on selected targets rather than on the whole cell. Inhibitors (or activators, in some cases) of these enzymes should be developable as selective antitumor agents with toxicity profiles superior to that of bortezomib. Various therapeutic hypotheses follow from known cellular mechanisms of these target enzymes; most hypotheses relate to cancer, reminiscent of the FDA-approved protein kinase inhibitors now marketed. Since ubiquitin tagging controls the cellular content, activity, or compartmentation of proteins associated with disease, inhibitors or activators of ubiquitin conjugation or deconjugation are predicted to have an impact on disease. For practical and empirical reasons, inhibitors of ubiquitin pathway enzymes have been the favored therapeutic avenue. In approximately the time that has elapsed since the approval of bortezomib in 2003, there has been some progress in developing potential anticancer drugs that target various ubiquitin pathway enzymes. An E1 inhibitor and inhibitors of E3 are now in clinical trial, with some objective responses reported. Appropriate assays and/or rational design may uncover improved inhibitors of these enzymes, as well as E2 and DUBs, for further development. Presently, it should become clear whether one or both of the two general strategies for ubiquitin-based drug discovery will lead to truly superior new medicines for cancer and other diseases. This article is part of a Special Issue entitled: Ubiquitin Drug Discovery and Diagnostics.     

Multi-target-directed design,syntheses, and characterization of fluorescent bisphosphonate derivatives as multifunctional enzyme inhibitors in mevalonate pathway

Background

Mevalonate pathway is an important cellular metabolic pathway present in all higher eukaryotes and many bacteria. Four enzymes in mevalonate pathway, including MVK, PMK, MDD, and FPPS, play important regulatory roles in cholesterol biosynthesis and cell proliferation.

Methods

The following methods were used: cloning, expression and purification of enzymes in mevalonate pathway, organic syntheses of multifunctional enzyme inhibitors, measurement of their IC₅₀ values for above four enzymes, kinetic studies of enzyme inhibitions, molecular modeling studies, cell viability tests, and fluorescence microscopy.

Results and conclusions

We report our multi-target-directed design, syntheses, and characterization of two blue fluorescent bisphosphonate derivatives compounds 15 and 16 as multifunctional enzyme inhibitors in mevalonate pathway. These two compounds had good inhibition to all these four enzymes with their IC₅₀ values at nanomolar to micromolar range. Kinetic and molecular modeling studies showed that these two compounds could bind to the active sites of all these four enzymes. The fluorescence microscopy indicated that these two compounds could easily get into cancer cells.

General significance

Multifunctional enzyme inhibitors are generally more effective than single enzyme inhibitors, with fewer side effects. Our results showed that these multifunctional inhibitors could become lead compounds for further development for the treatment of soft-tissue tumors and hypercholesteremia.     

Comparison among DNA polymerases 1, 2 and 3 from maize embryo axes. A DNA primase activity copurifies with DNA polymerase 2

Three DNA polymerase activities, named 1, 2 and 3 were purified from maize embryo axes and were compared in terms of ion requirements, optimal pH, temperature and KCl for activity, response to specific inhibitors and use of templates. All three enzymes require a divalent cation for activity, but main differences were observed in sensitivity to inhibitors and template usage: while DNA polymerases 1 and 2 were inhibited by N-ethyl maleimide and aphidicolin, inhibitors of replicative-type enzymes, DNA polymerase 3 was only marginally or not affected at all. In contrast, DNA polymerase 3 was highly inhibited by very low concentrations of ddTTP, an inhibitor of repair-type enzymes, and a 100-fold higher concentration of the drug was needed to inhibit DNA polymerases 1 and 2. Additionally, DNA polymerases 1 and 2 used equally or more efficiently the synthetic template polydA-oligodT, as compared to activated DNA, while polymerase 3 used it very poorly. Whereas DNA polymerases 1 and 2 shared properties of replicative-type enzymes, DNA polymerase 3 could be a repair-type enzyme. Moreover, a DNA primase activity copurified with the 8000-fold purified DNA polymerase 2, strenghtening the suggestion that polymerase 2 is a replicative enzyme, of the -type. This DNA primase activity was also partially characterized. The results are discussed in terms of relevant data about other plant DNA polymerases and primases reported in the literature.     

Acceptor specificities and selective inhibition of recombinant human Gal- and GlcNAc-transferases that synthesize core structures 1, 2, 3 and 4 of O-glycans

Background

Modifications of proteins by O-glycosylation determine many of the properties and functions of proteins. We wish to understand the mechanisms of O-glycosylation and develop inhibitors that could affect glycoprotein functions and alter cellular behavior.

Methods

We expressed recombinant soluble human Gal- and GlcNAc-transferases that synthesize the O-glycan cores 1 to 4 and are critical for the overall structures of O-glycans. We determined the properties and substrate specificities of these enzymes using synthetic acceptor substrate analogs. Compounds that were inactive as substrates were tested as inhibitors.

Results

Enzymes significantly differed in their recognition of the sugar moieties and aglycone groups of substrates. Core 1 synthase was active with glycopeptide substrates but GlcNAc-transferases preferred substrates with hydrophobic aglycone groups. Chemical modifications of the acceptors shed light on enzyme–substrate interactions. Core 1 synthase was weakly inhibited by its substrate analog benzyl 2-butanamido-2-deoxy-α-d-galactoside while two of the three GlcNAc-transferases were selectively and potently inhibited by bis-imidazolium salts which are not substrate analogs.

Conclusions

This work delineates the distinct specificities and properties of the enzymes that synthesize the common O-glycan core structures 1 to 4. New inhibitors were found that could selectively inhibit the synthesis of cores 1, 2 and 3 but not core 4.

General significance

These studies help our understanding of the mechanisms of action of enzymes critical for O-glycosylation. The results may be useful for the re-engineering of O-glycosylation to determine the roles of O-glycans and the enzymes critical for O-glycosylation, and for biotechnology with potential therapeutic applications.     

Functional evolution within a protein superfamily

The ability to predict and characterize distributions of reactivities over families and even superfamilies of proteins opens the door to an array of analyses regarding functional evolution. In this article, insights into functional evolution in the Kazal inhibitor superfamily are gained by analyzing and comparing predicted association free energy distributions against six serine proteinases, over a number of groups of inhibitors: all possible Kazal inhibitors, natural avian ovomucoid first and third domains, and sets of Kazal inhibitors with statistically weighted combinations of residues. The results indicate that, despite the great hypervariability of residues in the 10 proteinase-binding positions, avian ovomucoid third domains evolved to inhibit enzymes similar to the six enzymes selected, whereas the orthologous first domains are not inhibitors of these enzymes on purpose. Hypervariability arises because of similarity in energetic contribution from multiple residue types; conservation is in terms of functionality, with "good" residues, which make positive or less deleterious contributions to the binding, selected more frequently, and yielding overall the same distributional characteristics. Further analysis of the distributions indicates that while nature did optimize inhibitor strength, the objective may not have been the strongest possible inhibitor against one enzyme but rather an inhibitor that is relatively strong against a number of enzymes.     

The inter-ligand Overhauser effect: A powerful new NMR approach for mapping structural relationships of macromolecular ligands

NMR experiments that transfer conformational information from the bound to the uncomplexed state via exchange have been utilized for many years. It is demonstrated here that inter-ligand NOEs (ILOEs), which exist in ternary complexes with enzymes or other macromolecular receptors, can be transferred via exchange to pairs of uncomplexed ligands. This approach is illustrated by studies of glycolate + NAD⁺ in the presence of porcine heart lactate dehydrogenase, and by glucose-6-phosphate + NADPH in the presence of L. mesenteroides glucose-6-phosphate dehydrogenase. This strategy opens up a general methodology for exploring the active sites of enzymes and for the development of artificial ligands which can function as inhibitors, or more generally as modifiers of protein function.     

Analogs of diadenosine tetraphosphate (Ap4A)

This review summarizes our knowledge of analogs and derivatives of diadenosine 5',5"'-P1,P4-tetraphosphate (Ap4A), the most extensively studied member of the dinucleoside 5',5"'-P1,Pn-polyphosphate (NpnN) family. After a short discussion of enzymes that may be responsible for the accumulation and degradation of Np4)N's in the cell, this review focuses on chemically and/or enzymatically produced analogs and their practical applications. Particular attention is paid to compounds that have aided the study of enzymes involved in the metabolism of Ap4A (Np4N'). Certain Ap4A analogs were alternative substrates of Ap4A-degrading enzymes and/or acted as enzyme inhibitors, some other helped to establish enzyme mechanisms, increased the sensitivity of certain enzyme assays or produced stable enzyme:ligand complexes for structural analysis.     

Hydrolytic enzymes and their proteinaceous inhibitors in regulation of plant–pathogen interactions

This review considers the main groups of hydrolytic enzymes associated with plant pathogens, as well as proteinaceous inhibitors of these enzymes, acting as the components of plant defense system. The role of hydrolases is described in the development of a pathological process in plant tissues. Significance of hydrolase inhibitors in the development of plant resistance to pathogens is analyzed. It is proposed that specific interactions in the “host plant–pathogen” system, involving hydrolytic enzymes and their proteinaceous inhibitors, depend on the nutritional specialization of fungi.     

Evaluation of the activity of hydrolases and their inhibitors using substrates immobilized on agarose gel

A simple and convenient method for the quantitative evaluation of the activity of hydrolytic enzymes and their inhibitors has been proposed. This method is based on the immobilization of a substrate on agarose gel and the following evaluation of the enzyme activity by measuring the hydrolysis area around the well containing the enzyme solution. The method was shown to be applied to the evaluation of the activity of proteinases and amylases and the inhibitors of these enzymes in different biological objects.     

Interaction between various cholinesterases and reversible inhibitors of polymethylene-bis-(trimethylammonium) diiodide series

It is established that derivatives of polymethylene bistrimethylammonium (CH3)3N+(CH2)nN+(CH3)3 (n = 4-10) are reversible competitive and mixed action inhibitors with respect to acetylcholinesterase of human erythrocytes, butyryl cholinesterase of horse blood serum, cholinesterase of frog brain and Todarodes pacificus optical ganglion. In case of mammals and frog cholinesterase the inhibitors efficiency rises with n, but the activity of the Todarodes pacificus cholinesterase less sensitive of the inhibitors is characterized by a "step" dependence on the length of the polymethylene chain of the inhibitor molecule. Studies in sensitivity of cholinesterases to this type of inhibitors revealed differences between enzymes of the same type in different animals.     

Substrate-selective small-molecule modulators of enzymes: Mechanisms and opportunities

Small-molecule inhibitors of enzymes are widely used tools in reverse chemical genetics to probe biology and explore therapeutic opportunities. They are often compared with genetic knockdown or knockout and are expected to produce phenotypes similar to the genetic perturbations. This review aims to highlight that small molecule inhibitors of enzymes and genetic perturbations may not necessarily produce the same phenotype due to the possibility of substrate-selective or substrate-dependent effects of the inhibitors. Examples of substrate-selective inhibitors and the mechanisms for the substrate-selective effects are discussed. Substrate-selective modulators of enzymes have distinct advantages and cannot be easily replaced with biologics. Thus, they present an exciting opportunity for chemical biologists and medicinal chemists.     

Analysis of the kinetics of cyclic AMP hydrolysis by the cyclic GMP-stimulated cyclic nucleotide phosphodiesterase

The kinetics of cAMP hydrolysis by the purified calf liver cGMP-stimulated cyclic nucleotide phosphodiesterase were analyzed in the absence or presence of a number of competitive inhibitors of the methylxanthine type according to a two-site competitive model for allosteric enzymes. Methylxanthines were also classified by graphical analysis of classical competition kinetics at saturating cAMP. This treatment yielded Km/KI ratios which estimated the relative effectiveness of the binding of substrate and inhibitors to the "high affinity" (ES complex) state without establishing individual equilibrium-binding constants of cAMP and inhibitors for specific enzyme states. Individual binding constants for substrate and inhibitors were estimated directly by fitting primary data to the rate equation for the two-site competitive model. The equilibrium dissociation constants for cAMP to the "high" (KS) and "low affinity" (AKS) states were 2.4 +/- 0.8 and 410 +/- 140 microM, respectively. Dissociation constants for various inhibitors to the high (BKI) and low affinity (KI) states were also estimated. The ratio KS/BKI, which directly compared the equilibrium-binding constants of substrate and inhibitors to the high affinity state (ES complex), was in excellent agreement with Km/KI ratios derived from graphical analysis. Whereas a number of the methylxanthine analogues were more effective or as effective as cAMP in binding to the low affinity or "ligand-free" state, only isobutylmethylxanthine was effective as cAMP in binding to the high affinity state (1-methyl-3-isopropylxanthine, and 1,3-dipropylxanthine were somewhat less effective). These findings suggested that allosteric transitions might alter the topography of specific hydrophobic domains at cyclic nucleotide-binding sites and that structural determinants were more stringent for binding to the high affinity state than to the low affinity state.     

Dependence of anxiolytic effects of the dipeptide TSPO ligand GD-23 on neurosteroid biosynthesis

The elevated plus maze test showed that GD-23 (N-carbobenzoxy-L-tryptophanyl-L-isoleucine amide), an original dipeptide ligand of TSPO, exerted anxiolytic effect when injected intraperitoneally at a dose of 0.5 mg/kg. This effect was completely blocked by the selective neurosteroid synthesis inhibitors, enzymes trilostane and finasteride. The same inhibitors do not prevent the anxiolytic effects of the benzodiazepine tranquillizer diazepam. The results of the study indicate the selective neurosteroidogenic mechanism of the anxiolytic action of GD-23.     

Lysosomal enzyme phosphorylation. Recognition of a protein-dependent determinant allows specific phosphorylation of oligosaccharides present on lysosomal enzymes

We have investigated the basis for the specific recognition of lysosomal enzymes by UDP-GlcNAc:lysosomal enzyme N-acetylglucosaminylphosphotransferase. This enzyme is responsible for the selective phosphorylation of mannose residues on lysosomal enzymes. Two mammalian lysosomal enzymes, cathepsin D and uteroferrin, and two nonlysosomal glycoproteins were treated with endo-beta-N-acetylglucosaminidase H to remove those high mannose oligosaccharide units which are accessible on the native protein. These proteins were then tested as inhibitors of three different glycosyltransferases. The endo H-treated lysosomal enzymes were shown to be specific inhibitors of the phosphorylation of intact lysosomal enzymes. Proteolytic fragments of cathepsin D, including the entire light chain and heavy chain, did not retain the ability to be recognized by the N-acetylglucosaminylphosphotransferase. These findings indicate that the intact protein portion of lysosomal enzymes contains a specific recognition determinant which leads to high-affinity binding to the N-acetylglucosaminylphosphotransferase. The expression of this determinant appears to be dependent on the conformation of the protein.     

Influence of sugars on endoglucanase and β-xylanase activities of aBacillus strain

Summary ABacillus sp. screened from termite infested soils produced significant amount of endoglucanase and xylanase enzymes when grown on a lignocellulosic substrate, rice husk. Biosynthesis of these enzymes was significantly enhanced by the addition of 0.2% cellobiose or glucose for endoglucanase and xylose for -xylanase activities. In the actual hydrolyses, glucose and cellobiose at low concentrations acted as activitors of endoglucanase activity whereas cellobiose and xylose acted as inhibitors of -xylanase activity.     

Transport catalysis

Carrier linked solute transport through biomembranes is analysed with the viewpoint of catalysis. Different from enzymes, in carriers the unchanged substrate induces optimum fit in the transition state. The enhanced intrinsic binding energy pays for the energy required of the global conformation changes, thus decreasing the activation energy barrier. This "induced transition fit" (ITF) explains several phenomena of carrier transport, e.g., high or low affinity substrate requirements for unidirectional versus exchange, external energy requirement for "low affinity" transport, the existence of side specific inhibitors to ground states of the carrier, the requirement of external energy in active transport to supplement catalytic energy in addition to generate electrochemical gradients.