Phenylalanine ammonia-lyase: Mirror-image packing of d- and l-phenylalanine and d- and l-transition state analogs into the active site

The binding of substrate and product analogs to phenylalanine ammonia-lyase (EC 4.3.1.5) from maize has been studied by a protection method. The ligand dissociation constants, K_L, were estimated from the variation with [L] of the pseudo-first-order rate constants for enzyme inactivation by nitromethane. The phenylalanine analogs d- and l-2-aminooxy-3-phenylpropionic acid showed K_L, values over 20,000-fold lower than the K_m for l-phenylalanine. From these and other K_L values it is deduced that when the enzyme binds l-phenylalanine the structural free energy stored in the protein is higher than when it binds the superinhibitors. Models for binding d- and l-phenylalanine and the superinhibitors are described. The enantiomeric pairs are considered to have similar K_L values because they pack into the active site in a mirror-image relationship. If the elimination reaction approximates to the least-motion course deduced on stereoelectronic grounds, the mirror-image packing of the superinhibitors into the active site mimics the conformation inferred for a transition state in the elimination. It appears, therefore, that structural changes take place in the enzyme as the transition state conformation is approached causing stored free energy to be released. This lowers the activation free energy for the elimination reaction and accounts for the strong binding by the above analogs.     

Updates to Binding MOAD (Mother of All Databases): Polypharmacology Tools and Their Utility in Drug Repurposing

The goal of Binding MOAD is to provide users with a data set focused on high-quality x-ray crystal structures that have been solved with biologically relevant ligands bound. Where available, experimental binding affinities (K_a, K_d, K_i, IC₅₀) are provided from the primary literature of the crystal structure. The database has been updated regularly since 2005, and this most recent update has added nearly 7000 new structures (growth of 21%). MOAD currently contains 32,747 structures, composed of 9117 protein families and 16,044 unique ligands. The data are freely available on www.BindingMOAD.org. This paper outlines updates to the data in Binding MOAD as well as improvements made to both the website and its contents. The NGL viewer has been added to improve visualization of the ligands and protein structures. MarvinJS has been implemented, over the outdated MarvinView, to work with JChem for small molecule searching in the database. To add tools for predicting polypharmacology, we have added information about sequence, binding-site, and ligand similarity between entries in the database. A main premise behind polypharmacology is that similar binding sites will bind similar ligands. The large amount of protein–ligand information available in Binding MOAD allows us to compute pairwise ligand and binding-site similarities. Lists of similar ligands and similar binding sites have been added to allow users to identify potential polypharmacology pairs. To show the utility of the polypharmacology data, we detail a few examples from Binding MOAD of drug repurposing targets with their respective similarities.     

Functional studies with membrane-bound and detergent-solubilized α2-adrenergic receptors expressed in Sf9 cells

A chip-based biosensor technology using surface plasmon resonance (SPR) was developed for studying the interaction of ligands and G protein-coupled receptors (GPCRs). GPCRs, the fourth largest superfamily in the human genome, are the largest class of targets for drug discovery.We have expressed the three subtypes of α₂-adrenergic receptor (α₂-AR), a prototypical GPCR as functional fusion proteins in baculovirus-infected insect cells. The localization of the expressed receptor was observed in intracellular organelles, as detected by eGFP fluorescence. In addition, the deletion mutants of α_2B-AR, with a deletion in the 3rd intracellular loop, exhibited unaltered K_d values and enhanced stability, thus making them more promising candidates for crystallization. SPR demonstrated that small molecule ligands can bind the detergent-solubilized receptor, thus proving that α₂-AR is active even in a lipid-free environment. The K_d values obtained from the biosensor analysis and traditional ligand binding studies correlate well with each other. This is the first demonstration of the binding of a small molecule to the detergent-solubilized state of α₂-ARs and interaction of low-molecular mass-ligands in real time in a label-free environment. This technology will also allow the development of high throughput platform for screening a large number of compounds for generation of leads.     

Kinetic benefits and thermal stability of orotate phosphoribosyltransferase and orotidine 5′-monophosphate decarboxylase enzyme complex in human malaria parasite Plasmodium falciparum

We have previously shown that orotate phosphoribosyltransferase (OPRT) and orotidine 5′-monophosphate decarboxylase (OMPDC) in human malaria parasite Plasmodium falciparum form an enzyme complex, containing two subunits each of OPRT and OMPDC. To enable further characterization, we expressed and purified P. falciparum OPRT-OMPDC enzyme complex in Escherichia coli. The OPRT and OMPDC activities of the enzyme complex co-eluted in the chromatographic columns used during purification. Kinetic parameters (K_m, k_cat and k_cat/K_m) of the enzyme complex were 5- to 125-folds higher compared to the monofunctional enzyme. Interestingly, pyrophosphate was a potent inhibitor to the enzyme complex, but had a slightly inhibitory effect for the monofunctional enzyme. The enzyme complex resisted thermal inactivation at higher temperature than the monofunctional OPRT and OMPDC. The result suggests that the OPRT-OMPDC enzyme complex might have kinetic benefits and thermal stability significantly different from the monofunctional enzyme.     

Thermodynamic fingerprints of ligand binding to human telomeric G-quadruplexes

Thermodynamic studies of ligand binding to human telomere (ht) DNA quadruplexes, as a rule, neglect the involvement of various ht-DNA conformations in the binding process. Therefore, the thermodynamic driving forces and the mechanisms of ht-DNA G-quadruplex-ligand recognition remain poorly understood. In this work we characterize thermodynamically and structurally binding of netropsin (Net), dibenzotetraaza[14]annulene derivatives (DP77, DP78), cationic porphyrin (TMPyP4) and two bisquinolinium ligands (Phen-DC3, 360A-Br) to the ht-DNA fragment (Tel22) AGGG(TTAGGG)₃ using isothermal titration calorimetry, CD and fluorescence spectroscopy, gel electrophoresis and molecular modeling. By global thermodynamic analysis of experimental data we show that the driving forces characterized by contributions of specific interactions, changes in solvation and conformation differ significantly for binding of ligands with low quadruplex selectivity over duplexes (Net, DP77, DP78, TMPyP4; K_Tel22 ≈ <K_dsDNA) and for highly selective quadruplex-specific ligands (Phen-DC3, 360A-Br; K_Tel22 > K_dsDNA). These contributions are in accordance with the observed structural features (changes) and suggest that upon binding Net, DP77, DP78 and TMPyP4 select hybrid-1 and/or hybrid-2 conformation while Phen-DC3 and 360A-Br induce the transition of hybrid-1 and hybrid-2 to the structure with characteristics of antiparallel or hybrid-3 type conformation.     

pH Effects on the Activity and Regulation of the NAD Malic Enzyme

The NAD malic enzyme shows a pH optimum of 6.7 when complexed to Mg²⁺ and NAD⁺ but shifts to 7.0 when the catalytically competent enzyme-substrate (E-S) complex forms upon binding malate⁻². This is characteristic of an induced conformational change. The slope of the V_max or V_max/K_m profiles is steeper on the alkaline side of the pH optimum. The K_m for malate increases markedly under alkaline conditions but is not greatly affected by pH values below the optimum. The loss of catalysis on the acidic side is due to protonation of a single residue, pK 5.9, most likely histidine. Photooxidation inactivation with methylene blue showed that a histidine is required for catalytic activity. The location of this residue at or near the active site is revealed by the protection against inactivation offered by malate. Three residues, excluding basic residues such as lysine (which have also been shown to be vital for catalytic activity, must be appropriately ionized for malate decarboxylation to proceed optimally. Two of these residues directly participate in the binding of substrates and are essential for the decarboxylation of malate. A pK of 7.6 was determined for the two residues required by the E-S complex to achieve an active state, this composite value representing both histidine and cysteine suggests that both have decisive roles in the operation of the enzyme. A major change in the enzyme takes place as protonation nears the pH optimum, this is recorded as a change in the enzyme's intrinsic affinity for malate (K_{m pH6.7} = 9.2 millimolar, K_{m pH7.7} = 28.3 millimolar). Similar changes in K_m have been observed for the NAD malic enzyme as it shifts from dimer to tetramer. It is most likely that the third ionizable group (probably a cysteine) revealed by the V_max/K_m profile is needed for optimal activity and is involved in the association-dissociation behavior of the enzyme.     

Protein stabilization with a dipeptide‐mimic triazine‐scaffolded synthetic affinity ligand

Protein stabilization was achieved by a novel approach based on the adsorption and establishment of affinity‐like interactions with a biomimetic triazine‐scaffolded ligand. A synthetic lead compound (ligand 3′/11, K_a ≈ 10⁴ M^?1) was selected from a previously screened solid‐phase library of affinity ligands for studies of adsorption and stabilization of cutinase from Fusarium solani pisi used as a model system. This ligand, directly synthesized in agarose by a well‐established solid‐phase synthesis method, was able to strongly bind cutinase and led to impressive half‐lives of more than 8 h at 70 °C, and of approximately 34 h at 60 °C for bound protein (a 25‐ and 57‐fold increase as compared with the free enzyme, respectively). The ligand density in the solid matrix was found to be a determinant parameter for cutinase stabilization. It is conceivable that the highly stabilizing effect observed results from the binding of more than one ligand residue to the enzyme, creating specific macromolecular configurations that lock structural mobility thus improving molecular stability. Copyright © 2013 John Wiley & Sons, Ltd.     

Ligand-induced conformations of rat brain hexokinase: studies with hexoses, hexose 6-phosphates, and nucleoside triphosphates leading to development of a new model for the enzyme

Various ligands of rat brain hexokinase (ATP:d-hexose 6-phosphotransferase, EC 2.7.1.1) have been found to protect the enzyme against either (or both) chymotryptic digestion or inactivation by glutaraldehyde. Using this protective effect, the K_d for various enzyme-ligand complexes has been estimated: hexokinase-Glc, K_d = 0.24 ± 0.03mM (chymotryptic digestion), K_d = 0.26 ± 0.07mM (glutaraldehyde inactivation); hexokinase-Glc-6- P, K_d = 0.041 ± 0.005m M (glutaraldehyde inactivation); hexokinase-ATP, K_d = 1.01 ± 0.28mM (chymotryptic digestion); hexokinase-ATP-Mg ²⁺, K_d = 0.07-0.08mM (chymotryptic digestion). Other nucleoside triphosphates (UTP, ITP, GTP, and CTP) were much less effective than ATP at protecting against chymotrypsin. Various hexoses were tested for their ability to protect against glutaraldehyde. Only ?good” substrates (mannose, 2-deoxyglucose) protected; nonsubstrates (galactose, arabinose) and N-acetylglucosamine, a competitive inhibitor of Glc binding, were not effective. Various hexose 6-phosphates were tested for their ability to protect against glutaraldehyde inactivation. Glc-6-P was much more effective than were mannose-6-P, galactose-6-P, or fructose-6-P. It was observed that ?good” substrates (Glc, mannose) increased the effectiveness of Glc-6-P at solubilizing the mitochondrial form of the enzyme; galactose and N-acetylglucosamine had no effect on solubilization by Glc-6-P. These results are taken as an indication of enhanced Glc-6-P binding in the presence of Glc, as previously reported by Ellison et al. (J. Biol. Chem., 250, 1864–1871, 1975). Along with previous studies on ligand-induced conformations and kinetics of this enzyme, these results form the basis for a new model for brain hexokinase. This model specifically takes into account the ligand-induced conformations at various points in the catalytic cycle and specifically accounts for the ability of various hexoses to serve as substrates and hexose 6-phosphates to serve as inhibitors in terms of their ability to induce specific conformations of the enzyme. The properties of the various conformations involved in the model are designated by a four-letter code which facilitates comparison and discussion.     

Glucose-based spiro-isoxazolines: A new family of potent glycogen phosphorylase inhibitors

A series of glucopyranosylidene-spiro-isoxazolines was prepared through regio- and stereoselective [3+2]-cycloaddition between the methylene acetylated exo-glucal and aromatic nitrile oxides. The deprotected cycloadducts were evaluated as inhibitors of muscle glycogen phosphorylase b. The carbohydrate-based family of five inhibitors displays K_i values ranging from 0.63 to 92.5 μM. The X-ray structures of the enzyme–ligand complexes show that the inhibitors bind preferentially at the catalytic site of the enzyme retaining the less active T-state conformation. Docking calculations with GLIDE in extra-precision (XP) mode yielded excellent agreement with experiment, as judged by comparison of the predicted binding modes of the five ligands with the crystallographic conformations and the good correlation between the docking scores and the experimental free binding energies. Use of docking constraints on the well-defined positions of the glucopyranose moiety in the catalytic site and redocking of GLIDE-XP poses using electrostatic potential fit-determined ligand partial charges in quantum polarized ligand docking (QPLD) produced the best results in this regard.     

Crystal structure and molecular dynamics studies of purine nucleoside phosphorylase from Mycobacterium tuberculosis associated with acyclovir

Consumption has been a scourge of mankind since ancient times. This illness has charged a high price to human lives. Many efforts have been made to defeat Mycobacterium tuberculosis (Mt). The M. tuberculosis purine nucleoside phosphorylase (MtPNP) is considered an interesting target to pursuit new potential inhibitors, inasmuch it belongs to the purine salvage pathway and its activity might be involved in the mycobacterial latency process. Here we present the MtPNP crystallographic structure associated with acyclovir and phosphate (MtPNP:ACY:PO₄) at 2.10 Å resolution. Molecular dynamics simulations were carried out in order to dissect MtPNP:ACY:PO₄ structural features, and the influence of the ligand in the binding pocket stability. Our results revealed that the ligand leads to active site lost of stability, in agreement with experimental results, which demonstrate a considerable inhibitory activity against MtPNP (K_i = 150 nM). Furthermore, we observed that some residues which are important in the proper ligand’s anchor into the human homologous enzyme do not present the same importance to MtPNP. Therewithal, these findings contribute to the search of new specific inhibitors for MtPNP, since peculiarities between the mycobacterial and human enzyme binding sites have been identified, making a structural-based drug design feasible.     

Bupivacaine blocks N-type inactivating Kv channels in the open state: no allosteric effect on inactivation kinetics

Local anesthetics bind to ion channels in a state-dependent manner. For noninactivating voltage-gated K channels the binding mainly occurs in the open state, while for voltage-gated inactivating Na channels it is assumed to occur mainly in inactivated states, leading to an allosterically caused increase in the inactivation probability, reflected in a negative shift of the steady-state inactivation curve, prolonged recovery from inactivation, and a frequency-dependent block. How local anesthetics bind to N-type inactivating K channels is less explored. In this study, we have compared bupivacaine effects on inactivating (Shaker and K_v3.4) and noninactivating (Shaker-IR and K_v3.2) channels, expressed in Xenopus oocytes. Bupivacaine was found to block these channels time-dependently without shifting the steady-state inactivation curve markedly, without a prolonged recovery from inactivation, and without a frequency-dependent block. An analysis, including computational testing of kinetic models, suggests binding to the channel mainly in the open state, with affinities close to those estimated for corresponding noninactivating channels (300 and 280 μM for Shaker and Shaker-IR, and 60 and 90 μM for K_v3.4 and K_v3.2). The similar magnitudes of K_d, as well as of blocking and unblocking rate constants for inactivating and noninactivating Shaker channels, most likely exclude allosteric interactions between the inactivation mechanism and the binding site. The relevance of these results for understanding the action of local anesthetics on Na channels is discussed.     

Isolation and characterization of light- and dithiothreitol-modulatable glucose-6-phosphate dehydrogenase from pea chloroplasts

Glucose-6-phosphate dehydrogenase (D-glucose-6-phosphate: NADP oxidoreductase, EC 1.1.1.49) has been purified to electrophoretic homogeneity from pea chloroplasts. The enzyme, which has a Stokes radius of 52 Å, is a tetramer made up of four 56000 Da monomers. The pH optimum is around 8.2. The enzyme is absolutely specific for NADP. The apparent K_m(NADP) is 2.4 ± 0.1 μM. NADPH inhibition of the enzyme is competitive with respect to NADP (mean K_i, 18 ± 5 μM) and is mixed (K_p >K_m, V_max >V_p) with respect to glucose 6-phosphate (mean crossover point, 0.5 ± 0.1 mM). The apparent K_m(glucose 6-phosphate) is 0.37 ± 0.01 mM. The purified enzyme is inactivated in the light in the presence of dilute stroma and washed thylakoids, and by dithiothreitol. Enzyme which has been partially inactivated by treatment with dithiothreitol can be further inactivated in the light in the presence of dilute stroma and washed thylakoids and reactivated in the dark, but only to the extent of the reverse of light inactivation. Dithiothreitol-inactivated enzyme is not reactivated further by addition of crude stroma or oxidized thioredoxin. Dithiothreitol-dependent inactivation of the enzyme follows pseudo-first-order kinetics and shows rate saturation. The enzyme which has been partially inactivated by treatment with dithiothreitol does not differ from the untreated control with respect to thermal and tryptic inactivation. However, enzyme which has been partially light inactivated shows different thermal and tryptic inactivation patterns as compared to the dark control. These observations suggest that the changes in the enzyme brought about by light modulation are not necessarily identical with those brought about by dithiothreitol inactivation.     

Chemical modification of xylanase from alkalothermophilic Bacillus species: evidence for essential carboxyl group

The role of carboxyl group in the catalytic action of xylanase (M_r 35 000) from an alkalothermophilic Bacillus sp. was delineated through iinetic and chemical modification studies using Woodward's Reagent K. The kinetics of inactivation indicated that one carboxyl residue was essential for the xylanase activity with a second order rate constant of 3300 M⁻¹ min⁻¹. The spectrophotometric analysis at 340 nm revealed that the inhibition was correlated with modification of 24 carboxyl residues. In the presence of protecting ligand, modification of one carboxyl group was prevented. The pH profile showed apparent pK values of 5.2 and 6.4 for the free enzyme and 4.9 and 6.9 for enzyme-substrate complex. The pH dependence of inactivation was consistent with the modification of carboxyl group. The kinetic analysis of the modified enzyme showed similar K_m and lower k_cat values than the native enzyme indicating that catalytic hydrolysis and not the substrate binding was affected by chemical modification. The chemical modification of xylanase from alkalothermophilic Bacillus revealed the presence of tryptophans in the active site (Dehspande, V, Hinge, J. and Rao, M. (1990) Biochim. Biophys. Acta 1041, 172–177). This finding and present studies demonstrated the experimental evidence for the participation of carboxyl as well as tryptophan groups as essential residues of xylanase from alkalothermophilic Bacillus sp.     

Energetics of Glutathione Binding to Human Eukaryotic Elongation Factor 1 Gamma: Isothermal Titration Calorimetry and Molecular Dynamics Studies

The energetics of ligand binding to human eukaryotic elongation factor 1 gamma (heEF1γ) was investigated using reduced glutathione (GSH), oxidised glutathione (GSSG), glutathione sulfonate and S-hexylglutathione as ligands. The experiments were conducted using isothermal titration calorimetry, and the findings were supported using computational studies. The data show that the binding of these ligands to heEF1γ is enthalpically favourable and entropically driven (except for the binding of GSSG). The full length heEF1γ binds GSSG with lower affinity (K _d = 115 μM), with more hydrogen-bond contacts (ΔH = ?73.8 kJ/mol) and unfavourable entropy (?TΔS = 51.7 kJ/mol) compared to the glutathione transferase-like N-terminus domain of heEF1γ, which did not show preference to any specific ligand. Computational free binding energy calculations from the 10 ligand poses show that GSSG and GSH consistently bind heEF1γ, and that both ligands bind at the same site with a folded bioactive conformation. This study reveals the possibility that heEF1γ is a glutathione-binding protein.     

Evaluation of human microtubule affinity-regulating kinase 4 inhibitors: fluorescence binding studies,enzyme, and cell assays

Human microtubule affinity-regulating kinase 4 (MARK4) is considered as an encouraging drug target for the design and development of inhibitors to cure several life-threatening diseases such as Alzheimer disease, cancer, obesity, and type-II diabetes. Recently, we have reported four ligands namely, BX-912, BX-795, PKR-inhibitor, and OTSSP167 (hydrochloride) which bind preferentially to the two different constructs of human MARK4 containing kinase domain. To ensure the role of ubiquitin-associated (UBA) domain in the ligand binding, we made a newer construct of MARK4 which contains both kinase and UBA domains, named as MARK4-F3. We observed that OTSSP167 (hydrochloride) binds to the MARK4-F3 with a binding constant (K) of 3.16 × 10⁶, M^?1 (±.21). However, UBA-domain of MARK4-F3 doesn’t show any interaction with ligands directly as predicted by the molecular docking. To validate further, ATPase inhibition assays of all three constructs of MARK4 in the presence of mentioned ligands were carried out. An appreciable correlation between the binding experiments and ATPase inhibition assays of MARK4 was observed. In addition, cell-proliferation inhibition activity for all four ligands on the Human embryonic kidney (HEK-293) and breast cancer cell lines (MCF-7) was performed using MTT assay. IC₅₀ values of OTSSP167 for HEK-293 and MCF-7 were found to be 58.88 (±1.5), and 48.2 (±1.6), respectively. OTSSP167 among all four inhibitors, showed very good enzyme inhibition activity against three constructs of MARK4. Moreover, all four inhibitors showed anti-neuroblastoma activity and anticancer properties. In conclusion, OTSSP167 may be considered as a promising scaffold to discover novel inhibitors of MARK4.     

Interaction of folic acid and some matrix metalloproteinase (MMP) inhibitor folate-γ-hydroxamate derivatives with Zn(II) and human serum albumin

Human serum albumin binding of folic acid and its γ-hydroxamate/carboxylate derivatives was studied by ultrafiltration and spectrofluorimetry, and it was found that the ligands exhibit a moderate binding (K_D ~ 2-50 μM), and the folate-γ-phenylalanine represents the highest conditional binding constant towards albumin. This feature may have importance in the serum transport processes of these ligands. Interaction of folic acid and its derivatives with Zn(II) was investigated in aqueous solution to obtain the composition and stabilities of the complexes by the means of pH-potentiometry, ¹H NMR and electrospray ionization mass spectrometry, together with the characterization of the proton dissociation processes and the hydro-lipophilic properties of the ligands. The formation of mono-ligand complexes was demonstrated in all cases and the contribution of the glutamyl carboxylates to the coordination was excluded. Binding of folic acid and its γ-carboxylate derivatives to Zn(II) via the pteridine moiety is suggested, while the (O,O) coordination fashion of the folate-γ-hydroxamate ligands has importance in their inhibitory activity against Zn(II)-containing matrix metalloproteinases. It was found that the enzyme inhibition of these folate-γ-hydroxamate ligands is mainly tuned by other features, such as the lipophilic character rather than the Zn(II)-chelate stability.     

Folding of a Cyclin Box: LINKING MULTITARGET BINDING TO MARGINAL STABILITY,OLIGOMERIZATION, AND AGGREGATION OF THE RETINOBLASTOMA TUMOR SUPPRESSOR AB POCKET DOMAIN*

The retinoblastoma tumor suppressor (Rb) controls the proliferation, differentiation, and survival of cells in most eukaryotes with a role in the fate of stem cells. Its inactivation by mutation or oncogenic viruses is required for cellular transformation and eventually carcinogenesis. The high conservation of the Rb cyclin fold prompted us to investigate the link between conformational stability and ligand binding properties of the RbAB pocket domain. RbAB unfolding presents a three-state transition involving cooperative secondary and tertiary structure changes and a partially folded intermediate that can oligomerize. The first transition corresponds to unfolding of the metastable B subdomain containing the binding site for the LXCXE motif present in cellular and viral targets, and the second transition corresponds to the stable A subdomain. The low thermodynamic stability of RbAB translates into a propensity to rapidly oligomerize and aggregate at 37 °C (T₅₀ = 28 min) that is suppressed by human papillomavirus E7 and E2F peptide ligands, suggesting that Rb is likely stabilized in vivo through binding to target proteins. We propose that marginal stability and associated oligomerization may be conserved for function as a “hub” protein, allowing the formation of multiprotein complexes, which could constitute a robust mechanism to retain its cell cycle regulatory role throughout evolution. Decreased stability and oligomerization are shared with the p53 tumor suppressor, suggesting a link between folding and function in these two essential cell regulators that are inactivated in most cancers and operate within multitarget signaling pathways.     

Localization and characteristics of rat liver mitochondrial aldehyde dehydrogenases.

Two NAD-dependent aldehyde dehydrogenase enzymes from rat liver mitochondria have been partially purified and characterized. One enzyme (enzyme I) has molecular weight of 320,000 and has a broad substrate specificity which includes formaldehyde; NADP is not a cofactor for this enzyme. This enzyme has K_m values for most aldehydes in the micromolar range. The isoelectric point was found to be 6.06. A second enzyme (enzyme II) has a molecular weight of 67,000, a K_m value for most aldehydes in the millimolar range but no activity toward formaldehyde. NADP does serve as a coenzyme, however. The isoelectric point is 6.64 for this enzyme. By utilization of the different substrate properties of these two enzymes it was possible to demonstrate a time-dependent release from digitonin-treated liver mitochondria. The high K_m, low molecular weight enzyme (enzyme II) is apparently in the intermembrane space while the low K_m, high molecular weight enzyme (enzyme I) is in the mitochondrial matrix and is most likely responsible for oxidation of acetaldehyde formed from ethanol.     

Production, purification and characterization of laccase from Pleurotus ostreatus grown on tomato pomace

A strain of Pleurotus ostreatus was grown in tomato pomace as sole carbon source for production of laccase. The culture of P. ostreatus revealed a peak of laccase activity (147 U/L of fermentation broth) on the 4th day of culture with a specific activity of 2.8 U/mg protein. Differential chromatographic behaviour of laccase was investigated on affinity chromatographic matrices containing either urea, acetamide, ethanolamine or IDA as affinity ligands. Laccase exhibited retention on such affinity matrices and it was purified on a Sepharose 6B—BDGE—urea column with final enzyme recoveries of about 60%, specific activity of 6.0 and 18.0 U/mg protein and purification factors in the range of 14–46. It was also possible to demonstrate that metal-free laccase did not adsorb to Sepharose 6B—BDGE—urea column which suggests that adsorption of native laccase on this affinity matrix was apparently due to the specific interaction of carbonyl groups available on the matrix with the active site Cu (II) ions of laccase. The kinetic parameters (V _max, K _m , K _cat, and K _cat/K _m ) of the purified enzyme for several substrates were determined as well as laccase stability and optimum pH and temperature of enzyme activity. This is the first report describing the production of laccase from P. ostreatus grown on tomato pomace and purification of this enzyme based on affinity matrix containing urea as affinity ligand.     

α-d-Galactosidase immobilized on a soluble polymer

α-d-Galactosidase (α-d-galactoside galactohydrolase, EC 3.2.1.22) from green coffee beans has been immobilized by attachment to cyanogen bromide-activated Dextran T-70. Since this represents the first reported example of the preparation of a water-soluble derivative of an enzyme showing substrate inhibition, the kinetic properties, thermal stability and pH optima were investigated and compared with those of the free enzyme. The K_m, K_s, K_i, V_max, optimum substrate concentration and optimum pH were all lower than those of free enzyme. The enzyme conjugate showed greater resistance than the free enzyme to thermal inactivation. These data, although obtained with the synthetic substrate 4-nitrophenyl-α-d-galactoside, suggest some advantages in using the enzyme conjugate for the removal of terminal α-d-galactopyranosyl groups from the erythrocyte cell surface.