Photosensitization of skin fibroblasts and HeLa cells by three chlorin derivatives: Role of chemical structure and delivery vehicle

The chemical nature of the sensitizer and its selective uptake by malignant cells are decisive to choose an appropriate biocompatible carrier, able to preserve the photosensitizing characteristics of the dye. In this paper we demonstrate the photodynamic properties of three chlorins, derived from chlorophyll a, and the usefulness of liposomal carriers to design pharmaceutical formulations. The chlorins have been quantitatively incorporated into stable liposomes obtained from a mixture of L-alpha-palmitoyloleoylphosphatidylcholine and L-alpha-dioleoylphosphatidylserine in a 13.5:1.5 molar ratio (POPC/OOPS-liposomes). The chlorin uptake by skin fibroblasts increases steadily, reaching in all cases a plateau level dependent on both the chlorin structure and the vehicle employed. The photophysical properties of the three chlorins in THF are nearly identical and fulfill the requirements for a PDT photosensitizer. Incorporation of chlorins into liposomes induces important changes in their photophysics, but does not impair their cellular uptake or their cell photosensitization ability. In fact we observe in the cells the same photophysical behavior as in THF solution. Specifically, we demonstrate, by recording the near-IR phosphorescence of 1O2, that the chlorins are able to photosensitize the production of 1O2 in the cell membrane. The cell-photosensitization efficiency depended on the chlorin and cell line nature, the carrier, and the length of pre-incubation and post-irradiation periods. The high photodynamic activity of chlorin-loaded liposomes and the possibility to design liposomal carriers to achieve a specific target site favors this approach to obtain an eventual pharmaceutical formulation.     

Synergistic production of L-arabinose from arabinan by the combined use of thermostable endo- and exo-arabinanases from Caldicellulosiruptor saccharolyticus

The optimum conditions for the production of l-arabinose from debranched arabinan were determined to be pH 6.5, 75 °C, 20 g l⁻¹ debranched arabinan, 42 U ml⁻¹ endo-1,5-α-l-arabinanase, and 14 U ml⁻¹ α-l-arabinofuranosidase from Caldicellulosiruptor saccharolyticus and the conditions for sugar beet arabinan were pH 6.0, 75 °C, 20 g l⁻¹ sugar beet arabinan, 3 U ml⁻¹ endo-1,5-α-l-arabinanase, and 24 U ml⁻¹ α-l-arabinofuranosidase. Under the optimum conditions, 16 g l⁻¹l-arabinose was obtained from 20 g l⁻¹ debranched arabinan or sugar beet arabinan after 120 min, with a hydrolysis yield of 80% and a productivity of 8 g l⁻¹ h⁻¹. This is the first reported trial for the production of l-arabinose from the hemicellulose arabinan by the combined use of endo- and exo-arabinanases.     

Dielectric properties of two diastereoisomers of the arabinose and their equimolar mixture

Dielectric relaxation measurements were performed on two enantiomers, d- and l-arabinose and their equimolar mixture, and compared to dielectric data obtained for d-ribose. d-Arabinose differs from d-ribose by having the opposite configuration at C2. This study reveals that both d- and l- of arabinose exhibit α-relaxation peaks with the same shape for the same α-relaxation time τ_α, and the same steepness index for the T_g-scale T-dependence of τ_α. However, the two isomers have slightly different glass transition temperatures T_g’s, and their secondary γ-relaxation times also differ slightly from the previously observed γ-relaxation in d-ribose at the same temperature. However, when samples of both investigated monosaccharides are annealed at higher temperatures, their glass transition temperatures become nearly identical. This is an effect of the mutarotation process, which leads to the formation of pairs of the enantiomers and accordingly they should have the same physical properties. The width of the α-relaxation of d- and l-arabinose is broader than that of d-ribose, as reflected by the smaller stretch exponent in the Kohlrausch-Williams-Watts function used to fit the data of the former (β_KWW = 0.46 ± 0.01) than the latter (β_KWW = 0.55 ± 0.01). The width of the α-relaxation of racemic mixture of the d- and l-arabinose is slightly broader than that of the pure isomers. While the dielectric loss data of d-ribose in the glassy state at ambient and elevated pressures show an inflexion indicating the presence of the JG β-relaxation, the data of d- and l-arabinose show no such feature for identification of the supposedly universal JG β-relaxation. Nevertheless, on comparing the loss spectra of d-arabinose with that of d-ribose, the presence of the JG β-relaxation in d-arabinose has been rationalized.     

Crystal structures of D-tagatose 3-epimerase from Pseudomonas cichorii and its complexes with D-tagatose and D-fructose

Pseudomonas cichoriiid-tagatose 3-epimerase (P. cichoriid-TE) can efficiently catalyze the epimerization of not only d-tagatose to d-sorbose, but also d-fructose to d-psicose, and is used for the production of d-psicose from d-fructose. The crystal structures of P. cichoriid-TE alone and in complexes with d-tagatose and d-fructose were determined at resolutions of 1.79, 2.28, and 2.06 Å, respectively. A subunit of P. cichoriid-TE adopts a (β/α)₈ barrel structure, and a metal ion (Mn²⁺) found in the active site is coordinated by Glu152, Asp185, His211, and Glu246 at the end of the β-barrel. P. cichoriid-TE forms a stable dimer to give a favorable accessible surface for substrate binding on the front side of the dimer. The simulated omit map indicates that O2 and O3 of d-tagatose and/or d-fructose coordinate Mn²⁺, and that C3-O3 is located between carboxyl groups of Glu152 and Glu246, supporting the previously proposed mechanism of deprotonation/protonation at C3 by two Glu residues. Although the electron density is poor at the 4-, 5-, and 6-positions of the substrates, substrate-enzyme interactions can be deduced from the significant electron density at O6. The O6 possibly interacts with Cys66 via hydrogen bonding, whereas O4 and O5 in d-tagatose and O4 in d-fructose do not undergo hydrogen bonding to the enzyme and are in a hydrophobic environment created by Phe7, Trp15, Trp113, and Phe248. Due to the lack of specific interactions between the enzyme and its substrates at the 4- and 5-positions, P. cichoriid-TE loosely recognizes substrates in this region, allowing it to efficiently catalyze the epimerization of d-tagatose and d-fructose (C4 epimer of d-tagatose) as well. Furthermore, a C3-O3 proton-exchange mechanism for P. cichoriid-TE is suggested by X-ray structural analysis, providing a clear explanation for the regulation of the ionization state of Glu152 and Glu246.     

H, C NMR and UV spectroscopy studies of gold(III)-tetracyanide complex with l-cysteine, glutathione, captopril, l-methionine and dl-seleno-methionine in aqueous solution

Auricyanide [Au(CN)₄]⁻ interaction with biologically important thiols, thioether and selenoether were carried out and monitored using ¹H, ¹³C NMR and UV spectroscopy. These ligands include l-cysteine, glutathione, captopril, l-methionine and dl-seleno-methionine. Thiols show very strong affinity to be oxidized into the disulfide by auricyanide, which gets reduced to aurocyanide [Au(CN)₂]⁻. l-cysteine reaction mechanism with [Au(CN)₄]⁻ was found to be dependent on reactants mole ratio. While l-methionine was completely inert toward auricyanide, dl-Se-methionine showed some reactivity with [Au(CN)₄]⁻ after raising solution pH to 12 that facilitated cyanide exchange.     

Differential Assay of Human Pancreatic and Salivary α-Amylases with p-Nitrophenyl 65-O-β-D-Galacopyraosyl-α-maltopentaoside as the Substrate

p-Nitrophenyl 6⁵-O-β-D-galactopyraosyl-α-maltopentaoside (L⁶G5P) was synthesized by the sequential use of the transglycosylation and hydrolytic action of β-D-galactosidase from Bacillus circulans. The enzyme produced L⁶G5P (at a yield of 8.0% based on the amount of p-nitrophenyl α-maltopentaoside added) from lactose as the donor and p-nitrophenyl α-maltopentaoside as the acceptor. The frequency at which of human pancreatic α-amylase and salivary α-amylase catalyzed the cleavage of glycosidic linkages in L⁶G5P was calculated by analysis of the digests by high-pressure liquid chromatography. The modes of action of the two isozymes differed. Both hydrolyzed L⁶G5P and produced p-nitrophenyl α-maltoside and p-nitrophenyl α-D-glucopyranoside, but human pancreatic α-amylase produced more of the latter than human salivary α-amylase. Thus, L⁶G5P could be used to assay of the two enzymes differentially in serum.     

Bioconversion of ginsenosides Rb(1), Rb(2), Rc and Rd by novel β-glucosidase hydrolyzing outer 3-O glycoside from Sphingomonas sp. 2F2: cloning, expression, and enzyme characterization

A new β-glucosidase gene (bglSp) was cloned from the ginsenoside converting Sphingomonas sp. strain 2F2 isolated from the ginseng cultivating filed. The bglSp consisted of 1344 bp (447 amino acid residues) with a predicted molecular mass of 49,399 Da. A BLAST search using the bglSp sequence revealed significant homology to that of glycoside hydrolase superfamily 1. This enzyme was overexpressed in Escherichia coli BL21 (DE3) using a pET21-MBP (TEV) vector system. Overexpressed recombinant enzymes which could convert the ginsenosides Rb₁, Rb₂, Rc and Rd to the more pharmacological active rare ginsenosides gypenoside XVII, ginsenoside C-O, ginsenoside C-Mc₁ and ginsenoside F₂, respectively, were purified by two steps with Amylose-affinity and DEAE-Cellulose chromatography and characterized. The kinetic parameters for β-glucosidase showed the apparent K_m and V_max values of 2.9 ± 0.3 mM and 515.4 ± 38.3 μmol min⁻¹ mg of protein⁻¹ against p-nitrophenyl-β-d-glucopyranoside. The enzyme could hydrolyze the outer C3 glucose moieties of ginsenosides Rb₁, Rb₂, Rc and Rd into the rare ginsenosides Gyp XVII, C-O, C-Mc₁ and F₂ quickly at optimal conditions of pH 5.0 and 37 °C. A little ginsenoside F₂ production from ginsenosides Gyp XVII, C-O, and C-Mc₁ was observed for the lengthy enzyme reaction caused by the side ability of the enzyme.     

l-Lactate generates hydrogen peroxide in purified rat liver mitochondria due to the putative l-lactate oxidase localized in the intermembrane space

In order to ascertain whether and how mitochondria can produce hydrogen peroxide (H₂O₂) as a result of l-lactate addition, we monitored H₂O₂ generation in rat liver mitochondria and in submitochondrial fractions free of peroxisomal and cytosolic contamination. We found that H₂O₂ is produced independently on the respiratory chain with 1:1 stoichiometry with pyruvate, due to a putative flavine-dependent l-lactate oxidase restricted to the intermembrane space. The l-lactate oxidase reaction shows a hyperbolic dependence on l-lactate concentration and is inhibited by NAD⁺ in a competitive manner, being the enzyme different from the l-lactate dehydrogenase isoenzymes as shown by their pH profiles.     

Transport and metabolism of l-lactate occur in mitochondria from cerebellar granule cells and are modified in cells undergoing low potassium dependent apoptosis

Having confirmed that externally added l-lactate can enter cerebellar granule cells, we investigated whether and how l-lactate is metabolized by mitochondria from these cells under normal or apoptotic conditions.

(1)

l-lactate enters mitochondria, perhaps via an l-lactate/H⁺ symporter, and is oxidized in a manner stimulated by ADP. The existence of an l-lactate dehydrogenase, located in the inner mitochondrial compartment, was shown by immunological analysis. Neither the protein level nor the K_m and V_max values changed en route to apoptosis.

(2)

In both normal and apoptotic cell homogenates, externally added l-lactate caused reduction of the intramitochondrial pyridine cofactors, inhibited by phenylsuccinate. This process mirrored l-lactate uptake by mitochondria and occurred with a hyperbolic dependence on l-lactate concentrations. Pyruvate appeared outside mitochondria as a result of external addition of l-lactate. The rate of the process depended on l-lactate concentration and showed saturation characteristics. This shows the occurrence of an intracellular l-lactate/pyruvate shuttle, whose activity was limited by the putative l-lactate/pyruvate antiporter. Both the carriers were different from the monocarboxylate carrier.

(3)

l-lactate transport changed en route to apoptosis. Uptake increased in the early phase of apoptosis, but decreased in the late phase with characteristics of a non-competitive like inhibition. In contrast, the putative l-lactate/pyruvate antiport decreased en route to apoptosis with characteristics of a competitive like inhibition in early apoptosis, and a mixed non-competitive like inhibition in late apoptosis.

     

Substrate specificity of human glutamine transaminase K as an aminotransferase and as a cysteine S-conjugate beta-lyase

Rat kidney glutamine transaminase K (GTK) exhibits broad specificity both as an aminotransferase and as a cysteine S-conjugate β-lyase. The β-lyase reaction products are pyruvate, ammonium and a sulfhydryl-containing fragment. We show here that recombinant human GTK (rhGTK) also exhibits broad specificity both as an aminotransferase and as a cysteine S-conjugate β-lyase. S-(1,1,2,2-Tetrafluoroethyl)-l-cysteine is an excellent aminotransferase and β-lyase substrate of rhGTK. Moderate aminotransferase and β-lyase activities occur with the chemopreventive agent Se-methyl-l-selenocysteine. l-3-(2-Naphthyl)alanine, l-3-(1-naphthyl)alanine, 5-S-l-cysteinyldopamine and 5-S-l-cysteinyl-l-DOPA are measurable aminotransferase substrates, indicating that the active site can accommodate large aromatic amino acids. The α-keto acids generated by transamination/l-amino acid oxidase activity of the two catechol cysteine S-conjugates are unstable. A slow rhGTK-catalyzed β-elimination reaction, as measured by pyruvate formation, was demonstrated with 5-S-l-cysteinyldopamine, but not with 5-S-l-cysteinyl-l-DOPA. The importance of transamination, oxidation and β-elimination reactions involving 5-S-l-cysteinyldopamine, 5-S-l-cysteinyl-l-DOPA and Se-methyl-l-selenocysteine in human tissues and their biological relevance are discussed.     

Crystal structure of YihS in complex with D-mannose: structural annotation of Escherichia coli and Salmonella enterica yihS-encoded proteins to an aldose-ketose isomerase

The three-dimensional structure of a Salmonella enterica hypothetical protein YihS is significantly similar to that of N-acyl-d-glucosamine 2-epimerase (AGE) with respect to a common scaffold, an α₆/α₆-barrel, although the function of YihS remains to be clarified. To identify the function of YihS, Escherichia coli and S. enterica YihS proteins were overexpressed in E. coli, purified, and characterized. Both proteins were found to show no AGE activity but showed cofactor-independent aldose-ketose isomerase activity involved in the interconversion of monosaccharides, mannose, fructose, and glucose, or lyxose and xylulose. In order to clarify the structure/function relationship of YihS, we determined the crystal structure of S. enterica YihS mutant (H248A) in complex with a substrate (d-mannose) at 1.6 Å resolution. This enzyme-substrate complex structure is the first demonstration in the AGE structural family, and it enables us to identify active-site residues and postulate a reaction mechanism for YihS. The substrate, β-d-mannose, fits well in the active site and is specifically recognized by the enzyme. The substrate-binding site of YihS for the mannose C1 and O5 atoms is architecturally similar to those of mutarotases, suggesting that YihS adopts the pyranose ring-opening process by His383 and acidifies the C2 position, forming an aldehyde at the C1 position. In the isomerization step, His248 functions as a base catalyst responsible for transferring the proton from the C2 to C1 positions through a cis-enediol intermediate. On the other hand, in AGE, His248 is thought to abstract and re-adduct the proton at the C2 position of the substrate. These findings provide not only molecular insights into the YihS reaction mechanism but also useful information for the molecular design of novel carbohydrate-active enzymes with the common scaffold, α₆/α₆-barrel.     

Relationship between calcium release and NADPH oxidase inhibition in human neutrophils

The aim of this study was to investigate the possible relationship between NADPH oxidase activity and changes in cytosolic Ca²⁺ in response to different agonists. Treatment of neutrophils with leukotriene B4 (LTB₄) demonstrated characteristic changes to cytoslic Ca²⁺ yielding an EC₅₀ of 4 nM. The pA₂ values for the specific LTB₄ receptor (BLT) antagonists, U-75302 and LY-255283 were 6.32 and 6.38, respectively. Similarly, neutrophils treated with N-formyl-l-methionyl-l-leucyl-l-phenylalanine (FMLP) and platelet activating factor (PAF) exhibited changes in cytoslic Ca²⁺ in a dose dependant manner with pD₂ values of 9.0 and 9.9, respectively. The phorbol ester PMA prevented elevations in cytosolic Ca²⁺ in response to LTB₄, FMLP and PAF with IC₅₀ values of 5.88, 1.44 and 5.71 nM, respectively. In addition, potent NADPH oxidase inhibitors apocynin and diphenyleneiodonium (DPI) inhibited FMLP mediated cytosolic Ca²⁺ release. These results demonstrate that inhibition of the NADPH oxidase suppresses cytosolic Ca²⁺ release in FMLP activated human neutrophils.     

A comparative study of complex formation in the reactions of gold(III) with Gly-Gly, Gly-l-Ala and Gly-l-His dipeptides

Proton NMR spectroscopy was applied to study the reactions of the dipeptides glycyl-glycine (Gly-Gly) and glycyl-l-alanine (Gly-l-Ala) with hydrogen tetrachloridoaurate(III) (H[AuCl₄]). All reactions were performed at pH 2.0 and 3.0 and at 40 °C. The final products in these reactions were [Au(Gly-Gly-κ³N_G1,N_G2,O_G2)Cl] and [Au(Gly-l-Ala-κ³N_G,N_A,O_A)Cl] complexes. Tridentate coordination of the corresponding dipeptides and square-planar geometry of these Au(III) complexes was confirmed by NMR (¹H and ¹³C) spectroscopy. This study showed that at pH < 3.0 the Au(III) ion was able to deprotonate the amide nitrogen atom. However this displacement reaction was very slow and the total concentration of the corresponding Au(III)-peptide complex formed after 5 days was less than 60% for the Gly-l-Ala or 70% for the Gly-Gly dipeptide. The kinetic data of the reactions between the Gly-Gly and Gly-l-Ala dipeptides and [AuCl₄]⁻ were compared with those for the histidine-containing Gly-l-His dipeptide. The differences in the reactivity of these three dipeptides with the Au(III) ion are discussed.     

A new route to dTDP-6-deoxy-l-talose and dTDP-L-rhamnose: dTDP-L-rhamnose 4-epimerase in Burkholderia thailandensis

dTDP-l-rhamnose (dTDP-Rha)-synthesizing dTDP-6-deoxy-l-lyxo-4-hexulose reductase (4-KR) and dTDP-Rha 4-epimerase were characterized from Burkholderia thailandensis E264 by utilizing rmlD_Bth (BTH_I1472) and wbiB_Bth (BTH_I1476), respectively. Incubation of the recombinant WbiB_Bth with RmlA/RmlB/RmlC/Tal, which has previously been shown to generate dTDP-6-deoxy-l-talose (dTDP-6dTal) from α-d-glucose-1-phosphate, dTTP, and NADPH, produced dTDP-Rha. ¹H NMR measurements confirmed that both RmlA/RmlB/RmlC/Tal/WbiB_Bth and RmlA/RmlB/RmlC/RmlD produced dTDP-Rha. WbiB_Bth alone produced dTDP-Rha when incubated with dTDP-6dTal. This is the first report to demonstrate epimerase activity interconverting between dTDP-Rha and dTDP-6dTal.     

Production of L-xylose from L-xylulose using Escherichia coli L-fucose isomerase

l-Xylulose was used as a raw material for the production of l-xylose with a recombinantly produced Escherichia colil-fucose isomerase as the catalyst. The enzyme had a very alkaline pH optimum (over 10.5) and displayed Michaelis-Menten kinetics for l-xylulose with a K_m of 41 mM and a V_max of 0.23 μmol/(mg min). The half-lives determined for the enzyme at 35 °C and at 45 °C were 6 h 50 min and 1 h 31 min, respectively. The reaction equilibrium between l-xylulose and l-xylose was 15:85 at 35 °C and thus favored the formation of l-xylose. Contrary to the l-rhamnose isomerase catalyzed reaction described previously [14]l-lyxose was not detected in the reaction mixture with l-fucose isomerase. Although xylitol acted as an inhibitor of the reaction, even at a high ratio of xylitol to l-xylulose the inhibition did not reach 50%.     

The structures of L-rhamnose isomerase from Pseudomonas stutzeri in complexes with L-rhamnose and D-allose provide insights into broad substrate specificity

Pseudomonas stutzeril-rhamnose isomerase (P. stutzeri L-RhI) can efficiently catalyze the isomerization between various aldoses and ketoses, showing a broad substrate specificity compared to L-RhI from Escherichia coli (E. coli L-RhI). To understand the relationship between structure and substrate specificity, the crystal structures of P. stutzeri L-RhI alone and in complexes with l-rhamnose and d-allose which has different configurations of C4 and C5 from l-rhamnose, were determined at a resolution of 2.0 Å, 1.97 Å, and 1.97 Å, respectively. P. stutzeri L-RhI has a large domain with a (β/α)₈ barrel fold and an additional small domain composed of seven α-helices, forming a homo tetramer, as found in E. coli L-RhI and d-xylose isomerases (D-XIs) from various microorganisms. The β1-α1 loop (Gly60-Arg76) of P. stutzeri L-RhI is involved in the substrate binding of a neighbouring molecule, as found in D-XIs, while in E. coli L-RhI, the corresponding β1-α1 loop is extended (Asp52-Arg78) and covers the substrate-binding site of the same molecule. The complex structures of P. stutzeri L-RhI with l-rhamnose and d-allose show that both substrates are nicely fitted to the substrate -binding site. The part of the substrate-binding site interacting with the substrate at the 1, 2, and 3 positions is equivalent to E. coli L-RhI, and the other part interacting with the 4, 5, and 6 positions is similar to D-XI. In E. coli L-RhI, the β1-α1 loop creates an unique hydrophobic pocket at the the 4, 5, and 6 positions, leading to the strictly recognition of l-rhamnose as the most suitable substrate, while in P. stutzeri L-RhI, there is no corresponding hydrophobic pocket where Phe66 from a neighbouring molecule merely forms hydrophobic interactions with the substrate, leading to the loose substrate recognition at the 4, 5, and 6 positions.     

The influence of selected O-alkyl derivatives of cyclodextrins on the enzymatic decomposition of l-tryptophan by l-tryptophan indole-lyase

A series of O-alkyl derivatives of cyclodextrin: heksakis[2,3,6-tri-O-(2′-methoxyethyl)]-α-cyclodextrin; heksakis(2,3-di-O-methyl)-α-cyclodextrin; heptakis(2,3-di-O-methyl)-β-cyclodextrin; heksakis[2,3-di-O-methyl-6-O-(2′-methoxyethyl)]-α-cyclodextrin; heptakis[2,3-di-O-methyl-6-O-(2′-methoxyethyl)]-β-cyclodextrin; heksakis[2,3-di-O-(2′-methoxyethyl)]-α-cyclodextrin and heptakis[2,3-di-O-(2′-methoxyethyl)]-β-cyclodextrin have been synthesized. Purity and composition of the obtained substances were examined. The cyclodextrin derivatives listed above as well as (2-hydroxypropyl)-α-cyclodextrin and (2-hydroxypropyl)-β-cyclodextrin, the two commercially available ones, have been investigated as the additives in the course of enzymatic decomposition of l-tryptophan by l-tryptophan indole-lyase. It has been found that each of cyclodextrin derivatives causes the inhibition of enzymatic process, both competitive and non-competitive. The competitive inhibition is connected with the formation of inclusion complexes between cyclodextrins and l-tryptophan, related to the geometry of these complexes. The mechanism of the non-competitive inhibition is not so evident; it could be related to the formation of the cyclodextrin complexes on the surface of the enzyme, leading to the change in the flexibility of the enzyme molecule.     

Oxidation of methyl α-d-galactopyranoside by galactose oxidase: products formed and optimization of reaction conditions for production of aldehyde

The reaction conditions of galactose oxidase-catalyzed, targeted C-6 oxidation of galactose derivatives were optimized for aldehyde production and to minimize the formation of secondary products. Galactose oxidase, produced in transgenic Pichia pastoris carrying the galactose oxidase gene from Fusarium spp., was used as catalyst, methyl α-d-galactopyranoside as substrate, and reaction medium, temperature, concentration, and combinations of galactose oxidase, catalase, and horseradish peroxidase were used as variables. The reactions were followed by ¹H NMR spectroscopy and the main products isolated, characterized, and identified. An optimal combination of all the three enzymes gave aldehyde (methyl α-d-galacto-hexodialdo-1,5-pyranoside) in approximately 90% yield with a substrate concentration of 70 mM in water at 4 °C using air as oxygen source. Oxygen flushing of the reaction mixture was not necessary. The aldehyde existed as a hydrate in water. The main secondary products, a uronic acid (methyl α-d-galactopyranosiduronic acid) and an α,β-unsaturated aldehyde (methyl 4-deoxy-α-d-threo-hex-4-enodialdo-1,5-pyranoside), were observed for the first time to form in parallel. Formation of uronic acid seemed to be the result of impurities in the galactose oxidase preparation. ¹H and ¹³C NMR data of the products are reported for the α,β-unsaturated aldehyde for the first time, and chemical shifts in DMSO-d₆ for all the products for the first time. Oxidation of d-raffinose (α-d-galactopyranosyl-(1-6)-α-d-glucopyranosyl-(1-2)-β-d-fructofuranoside) in the same optimum conditions also proceeded well, resulting in approximately 90% yield of the corresponding aldehyde.     

Novel Characteristics of Selenomonas ruminantium Lysine Decarboxylase Capable of Decarboxylating Both L-Lysine and L-Ornithine

Lysine decarboxylase (LDC; EC 4.1.1.18) of Selenomonas ruminantium is a constitutive enzyme and is involved in the synthesis of cadaverine, which is an essential constituent of the peptidoglycan for normal cell growth. We purified the S. ruminantium LDC by an improved method including hydrophobic chromatography and studied the fine characteristics of the enzyme. Kinetic study of LDC showed that S. ruminanitum LDC decarboxylated both L-lysine and L-ornithine with similar K _m and the decarboxylase activities towards both substrates were competitively and irreversibly inhibited by DL-α-difluoromethylornithine, which is a specific inhibitor of ornithine decarboxylase (EC 4.1.1.17). We also showed a drastic descent of LDC activity owing to the degradation of LDC at entry into the stationary phase of cell growth.