Structure elucidation of two differentiation inducing factors (DIF-2 and DIF-3) from the cellular slime mould Dictyostelium discoideum.

Acylation of the aldehyde dehydrogenase.NADH complex by acetic anhydride leads to the production of acetaldehyde and NAD+. By monitoring changes in nucleotide fluorescence, the rate constant for acylation of the active site of the *enzyme.NADH complex was found to be 11 +/- 3 s-1. The rate of acylation by acetic anhydride at the group that binds aldehydes on the oxidative pathway is clearly rapid enough to maintain significant steady-state concentrations of the required active-site-acylated *enzyme.NADH intermediate despite the rapid hydrolysis of this *enzyme.acyl.NADH intermediate (5-10 s-1) [Blackwell, Motion, MacGibbon, Hardman & Buckley (1987) Biochem. J. 242, 803-808]. Hence reversal of the normal oxidative pathway can occur. However, although acylation of the aldehyde dehydrogenase.NADH complex by 4-nitrophenyl acetate also occurs rapidly with a rate constant of 10.9 +/- 0.6 s-1, even under the most extreme trapping conditions only very small amounts of acetaldehyde are detected [Loomes & Kitson (1986) Biochem. J. 235, 617-619]. Furthermore enzyme-catalysed hydrolysis of 4-nitrophenyl acetate is limited by the rate of deacylation of a group on the enzyme (0.4 s-1), which is an order of magnitude less than deacylation of the group at the active site (5-10 s-1). It is concluded that the enzyme-catalysed 4-nitrophenyl ester hydrolysis involves a group on the enzyme that is different from the active-site group that binds aldehydes on the normal oxidative pathway.     

The action of progesterone and diethylstilboestrol on the dehydrogenase and esterase activities of a purified aldehyde dehydrogenase from rabbit liver.

A steroid-sensitive aldehyde dehydrogenase (EC 1.2.1.3) was purified from rabbit liver and is homogeneous by the criterion of electrophoresis in polyacrylamide gels with or without sodium dodecyl sulphate. The enzyme is tetrameric, of subunit mo.wt. 48 300, and contains no tightly bound zinc. The fluorescence of the protein is decreased in the presence of progesterone, which is inhibitory to the reactions catalysed by the enzyme. When NADH is bound to the enzyme, the fluorescence of the coenzyme is augmented to an extent independent of the presence of steroids or acetaldehyde. The purified enzyme catalyses the oxidation of acetaldehyde and glucuronolactone, and the hydrolysis of 4-nitrophenyl acetate. Each of these reactions is inhibited by progesterone in such a manner as to suggest the formation of a catalytically active enzyme-hormone complex. Diethylstilboestrol inhibits the hydrolysis of esters by this enzyme, but stimulates the oxidation of aldehydes, except at low aldehyde concentrations; the ligand is then inhibitory. NADH inhibits the hydrolysis of 4-nitrophenyl acetate by the enzyme in a partially competitive fashion.     

High concentrations of aldehydes slow the reaction of cytoplasmic aldehyde dehydrogenase with thiol-group modifiers.

High concentrations of aldehydes slow the inactivation of cytoplasmic aldehyde dehydrogenase by disulfiram and also slow the reaction of the enzyme with 2,2'-dithiodipyridine. It is concluded that a low-affinity aldehyde-binding site is probably the site at which thiol-group modifiers react with aldehyde dehydrogenase, as well as being the active site for hydrolysis of 4-nitrophenyl acetate.     

On the physical properties and mechanism of action of arylsulfate sulfohydrolase II from Aspergillus oryzae.

Sedimentation equilibrium studies on arylsulfate sulfohydrolase II (EC 3.1.6.1) from Aspergillus oryzae under nondissociating conditions have resulted in a revised molecular weight of 94,900 ± 7100. Sedimentation equilibrium and gel electrophoresis data collected in the presence of the dissociating agents, urea and sodium dodecylsulfate demonstrate that the native enzyme is composed of two identical subunits as suggested by previous studies employing an irreversible inhibitor.The pH dependencies of the kinetic parameters V and $\text{V}\text{K}{}_{\mathrm{m}}$ for the enzymic hydrolysis of 4-nitrophenyl sulfate indicate that two groups of pK_a 4.7 and 6.0 control the activity of the enzyme. The product inorganic sulfate was shown to be a linear competitive inhibitor of the enzyme at pH 4.0, implying that it is a last released product along the reaction pathway. Inhibition by the phenol product was not observed. Enzymic hydrolysis of 4-nitrophenyl sulfate in ¹⁸O enriched water revealed that one atom of solvent oxygen is incorporated per molecule of inorganic sulfate, which is consistent with a mechanism featuring sulfur-oxygen bond cleavage. Evidence is presented based on stopped-flow kinetics, partitioning experiments in the presence of amine nucleophiles, and ¹⁸O exchange studies that collectively suggest that the breakdown of a covalent sulfuryl enzyme intermediate probably is not the rate-limiting step along the reaction pathway.The substrate specificity of the enzyme was examined by testing a variety of sulfate and phosphate esters as inhibitors of the hydrolysis of 4-nitrophenyl sulfate. The Cbz-l-Phe-l-Tyrosine-O-sulfate methyl ester serves as a substrate for the enzyme. Apparently substrate activity requires an aromatic sulfate ester whose binding is enhanced by incorporating the aromatic moiety in a hydrophobic matrix.     

Kinetic studies on the esterase activity of cytoplasmic sheep liver aldehyde dehydrogenase.

The hydrolysis of 4-nitrophenyl acetate catalysed by cytoplasmic aldehyde dehydrogenase (EC 1.2.1.3) from sheep liver was studied by steady-state and transient kinetic techniques. NAD+ and NADH stimulated the steady-state rate of ester hydrolysis at concentrations expected on the basis of their Michaelis constants from the dehydrogenase reaction. At higher concentrations of the coenzymes, both NAD+ and NADH inhibited the reaction competitively with respect to 4-nitrophenyl acetate, with inhibition constants of 104 and 197 micron respectively. Propionaldehyde and chloral hydrate are competitive inhibitors of the esterase reaction. A burst in the production of 4-nitrophenoxide ion was observed, with a rate constant of 12 +/- 2s-1 and a burst amplitude that was 30% of that expected on the basis of the known NADH-binding site concentration. The rate-limiting step for the esterase reaction occurs after the formation of 4-nitrophenoxide ion. Arguments are presented for the existence of distinct ester- and aldehyde-binding sites.     

Resonance Raman carbonyl frequencies and ultraviolet absorption maxima as indicators of the active site environment in native and unfolded chromophoric acyl-alpha-chymotrypsin

The imidazole of chromophoric p-(dimethylamino)benzoic acid, DABIm, reacts with the serine protease alpha-chymotrypsin in the pH range of 4-7 to form a stable acyl intermediate that gives very good resonance-enhanced Raman spectra. The resonance Raman and absorption spectra of the acyl enzyme intermediate have been compared with the spectra of simple model compounds such as the corresponding chromophoric methyl ester, aldehyde, and imidazole. The resonant Raman and ultraviolet absorption spectra of these simple chromophoric model compounds change considerably with the solvent. However, each of the model compounds exhibits a linear correlation between the maximum wavelength of absorption and the frequency of the carbonyl vibration. The observed values of the acyl intermediate do not fall on the line for the methyl ester but rather on the line for the aldehyde. This shows that the chromophoric serine ester of the acyl enzyme behaves differently than an ordinary ester, which cannot be explained as a solvent effect. Thermal unfolding of the acyl enzyme brings the spectroscopic parameters close to those of the model ester. We conclude that it is the specific conformation of the native enzyme and not solvent effects that change the spectroscopic properties of the acyl chromophore. It is reasonable that these changes arise from the same forces that cause the catalytic events. The carbonyl frequencies of a series of para-substituted benzoyl methyl esters show a remarkably linear correlation with the rate of deacylation of the corresponding acyl enzymes.     

Improved access to 2-O-monobenzyl ethers of beta-cyclodextrin as precursors of catalysts for organophosphoryl esters hydrolysis

A comparative study of reaction conditions was performed for the synthesis of a 2-O-monobenzyl ether of cyclomaltoheptaose (beta-CD). Optimal conditions involved sodium ethoxide in Me(2)SO and benzyl bromide. The methodology was extended to the preparation of various 2(I)-O-iodobenzyl and 2(I)-O-carboxymethylbenzyl derivatives of beta-CD including a 3-carboxymethyl-4-iodobenzyl derivative of interest as precursor of an enzyme mimic to degrade the organophosphoryl ester diethyl 4-nitrophenyl phosphate (paraoxon).     

A simple procedure for the photoregulation of chymotrypsin activity.

A convenient and rapid method for the photo-regulation of the proteolytic enzyme alpha-chymotrypsin is described. When alpha-chymotrypsin is coated with photolytic 1-(2-nitrophenyl)ethanol residues this not only markedly reduces the capability of the enzyme to digest both of the small substrates N-benzoyl-L-tyrosine ethyl ester and N-succinyl-L-phenylalanine p-nitroanilide, but also completely inhibits the enzyme's proteolytic activity. The inactivated alpha-chymotrypsin can then be reactivated under physiological conditions, when and where it is required, by exposure to UV-A light. These results further demonstrate that 1-(2-nitrophenyl)ethanol coated proteins can often be used as light sensitive biological switches as a simple alternative to site directed procedures.     

On the mechanism of action of bovine intestinal mucosa 5'-nucleotide phosphodiesterase. Stereochemical evidence for a nucleotidyl-enzyme intermediate

The diastereoisomers of adenosine 5'-O-phosphorothioate O-methyl ester have been synthesised. Only the Sp diastereoisomer is a substrate for the 5'-nucleotide phosphodiesterase from bovine intestinal mucosa. The previously unidentified enantiomer of 4-nitrophenyl phenyl phosphonothioate hydrolysed by the enzyme is shown to have the Sp configuration. Digestion of the Sp diastereoisomer of adenosine 5'-O-phosphorothioate O-methyl ester by the enzyme in 18O-labelled water gave 18O-labelled adenosine 5'-O-phosphorothioate which was stereochemically analysed by methylation and subsequent 31P-NMR spectroscopy and shown to possess the Sp configuration. Thus the enzyme-catalysed cleavage proceeded with retention of configuration at phosphorus, presumably via a double-displacement mechanism. This provides strong evidence for the existence of a nucleotidyl-enzyme intermediate on the reaction pathway.     

Hydrolysis of phosphonate esters catalyzed by 5'-nucleotide phosphodiesterase.

4-Nitrophenyl and 2-napthyl monoesters of phenylphosphonic acid have been synthesized, and an enzyme catalyzing their hydrolysis was resolved from alkaline phosphatase of a commerical calf intestinal alkaline phosphatase preparation by extensive ion-exchange chromatography, chromatography on L-phenylalanyl-Sepharose with a decreasing gradient of (NH4) 2SO4, and gel filtration. Detergent-solubilized enzyme from fresh bovine intestine was purified after (NH4)2SO4 fractionation by the same technique. The purified enzyme is homogeneous by polyacrylamide gel electrophoresis and sedimentation equilibrium centrifugation. It has a molecular weight of 108,000, contains approximately 21% carbohydrate, and has an amino acid composition considerably different from that reported from alkaline phosphatase from the same tissue. The homogeneous intestinal enzyme, an efficient catalyst of phosphonate ester hydoolysis but not of phosphate monoester hydrolysis, was identified as a 5'-nucleotide phosphodiesterase by its ability to hydrolyze 4-nitrophenyl esters of 5'-TMP but not of 3'-TMP. Also consistent with this identification was the ability of the enzyme to hydrolyze 5'-ATP to 5'-AMP and PPi, NAD+ to 5'-AMP and NMN, TpT to 5'-TMP and thymidine, pApApApA to 5'-AMP, and only the single-stranded portion of tRNA from the 3'-OH end. Snake venom 5'-nucleotide phosphodiesterase also hydrolyzes phosphonate esters, but 3'-nucleotide phosphodiesterase of spleen and cyclic 3',5'-AMP phosphodiesterase do not. Thus, types of phosphodiesterases can be conveniently distinguished by their ability to hydrolyze phosphonate esters. As substrates for 5'-nucleotide phosphodiesterases, phosphonate esters are preferable to the more conventional esters of nucleotides and bis(4-nitrophenyl) phosphate because of their superior stability and ease of synthesis. Furthermore, the rate of hydrolysis of phosphonate esters under saturating conditions is greater than that of the conventional substrates. At substrate concentrations of 1 mM the rates of hydrolysis of phosphonate esters and of nucleotide esters are comparable and both superior to that of bis(4-nitrophenyl) phosphate.     

Changing the efficiency and specificity of the esterase activity of human carbonic anhydrase II by site-specific mutagenesis.

Rates of hydrolysis of 4-, 3-, and 2-nitrophenyl acetate and 4-nitrophenyl propionate catalyzed by wild-type and mutant forms of human carbonic anhydrase II have been measured. The results show that the mutations Tyr7-->Phe and Ala65-->Leu lead to activity enhancements with all the investigated substrates, but there is no significant effect on the specificity. In contrast, some mutations at sequence position 200 have large effects on specificity. For example, while the mutation Thr200-->Gly results in a threefold increase of the rate of hydrolysis of 4-nitrophenyl acetate, the activity is enhanced 10 times with the meta-substituted substrate and 380 times with the ortho-substituted substrate. These results are interpreted in terms of the removal in the mutant of a steric interference between the 2-NO2 group, in particular, and the side chain of Thr200. Mutants involving residues lining a hydrophobic pocket near the catalytically essential zinc ion have also been investigated. The most pronounced effect on specificity was found for the Val143-->Gly mutant. This mutation leads to a sixfold decrease of the rate of hydrolysis of 4-nitrophenyl acetate but a 20-fold increase of the activity with the propionyl ester as substrate. These results suggest that the side chain of Val143 interferes sterically with the acyl moiety of 4-nitrophenyl propionate. Based on these results, we have constructed a hypothetical model of the location of these ester substrates in the enzymic active site.     

Guinea pig liver aldehyde oxidase as a sulfoxide reductase: Its purification and characterization

Guinea pig aldehyde oxidase was purified about 120-fold at a yield of 26% from liver cytosol by sequential column chromatography using DEAE-cellulose, FMN-Sepharose 4B, and Sephacryl S-300. The purified enzyme showed many similarities with the rabbit liver aldehyde oxidase reported by other workers with respect to its absolute spectra, molecular weight, and cofactor compositions of molybdenum, FAD, and nonheme iron. This enzyme efficiently utilized 2-hydroxypyrimidine and benzaldehyde as electron donors while N¹-methylnicotinamide was 40 times less effective than 2-hydroxypyrimidine. Diphenyl sulfoxide was reduced anaerobically to diphenyl sulfide in the presence of electron donors. This activity was highly susceptible to SKF 525-A as well as the known inhibitors for aldehyde oxidase such as menadione, estradiol, and potassium cyanide. This enzyme also reduced dibenzyl sulfoxide, phenothiazine sulfoxide, d-biotin methyl ester d-sulfoxide, and quinoline N-oxide, but not l-methionine sulfoxide, dimethyl sulfoxide, d-biotin methyl ester l-sulfoxide, and d-biotin d- and l-sulfoxides, as well as diphenyl sulfone. These results indicate that aldehyde oxidase in guinea pig liver functions as a sulfoxide reductase with selective substrate specificity under anaerobic conditions.     

Isolation of the Volatile Components of Fresh Onion by Thermal Desorption Cold Trap Capillary Gas Chromatography

A new esterase activity from Bacillus licheniformis was characterized from an Escherichia coli recombinant strain. The protein was a single polypeptide chain with a molecular mass of 81 kDa. The optimum pH for esterase activity was 8-8.5 and it was stable in the range 7-8.5. The optimum temperature for activity was 45°C and the half-life was 1 h at 64°C. Maximum activity was observed on p-nitrophenyl caproate with little activity toward long-chainfatty acid esters. The enzyme had a K_M of 0.52 mM for p-nitrophenyl caproate hydrolysis at pH 8 and 37°C. The enzyme activity was not affected by either metal ions or sulfydryl reagents. Surprisingly, the enzyme was only slightly inhibited by PMSF. These characteristics classified the new enzyme as a thermostable esterase that shared similarities with lipases. The esterase might be useful for biotechnological applications such as ester synthesis.     

Carboxymethyl-substituted bifunctional chelators: preparation of aryl isothiocyanate derivatives of 3-(carboxymethyl)-3-azapentanedioic acid, 3,12-bis(carboxymethyl)-6,9-dioxa-3,12-diazatetradecanedioic++ + acid, and 1,4,7,10-tetraazacyclododecane-N,N',N",N'-tetraacetic acid for use as protein labels

3-(Carboxymethyl)-3-azapentanedioic acid (NTA), 3,12-bis(carboxymethyl)-6,9-dioxa-3,12-diazatetradecanedioic acid (EGTA), and 1,4,7,10-tetraazacyclododecane-N,N',N",N'-tetraacetic acid (DOTA) structures having a 4-nitrophenyl substituent attached via an alkyl spacer to the methylene carbon atom of one carboxymethyl arm of the chelator were obtained by alkylation of 4-nitrophenylalanine with bromoacetic acid (NTA), by reductive alkylation of 1,8-diamino-3,6-dioxaoctane with (4-nitrophenyl)-pyruvic acid followed by alkylation with bromoacetic acid (EGTA), and by alkylation of the trimethyl ester of 1,4,7,10-tetraazacyclododecane-N,N',N"-triacetic acid with the methyl ester of alpha-bromo-4-(4-nitrophenyl)pentanoic acid and subsequent saponification (DOTA). The nitrophenyl-substituted chelators were converted to the corresponding amines by hydrogenation then reacted with thiophosgene to give the protein-reactive aryl isothiocyanate derivatives.     

N-Butyl-N-methyl-4-nitrophenyl carbamate as a specific active site titrator of bile-salt-dependent lipases

The effect of a series of synthetic carbamates on the human (milk or pancreatic) bile-salt-dependent lipase (cholesterol esterase) was examined. N-isopropyl-O-phenyl, N-methyl-O-phenyl, N-butyl-(4-nitrophenyl), N-phenyl-(4-nitrophenyl), N-butyl-N-methyl and N-pentyl-O-phenyl carbamates were inhibitors of the enzyme activity, while O-isopropyl-N-phenyl, O-methyl-N-phenyl, O-benzyl-N-isopropyl and O-cyclohexyl-N-phenyl carbamates were not even recognized by the enzyme. The N-alkyl chain length is essential for the enzyme inhibition and N-butyl-(4-nitrophenyl) or N-pentyl-O-phenyl carbamates are more potent inhibitors than N-methyl-O-phenyl or N-isopropyl carbamates. The inhibition by reactive carbamates fits the criteria for mechanism-based inhibition: the inhibition is first-order with time, shows saturation kinetics with increasing carbamate concentration and leads to an inactive stoichiometric enzyme-inhibitor complex; the enzyme activity can be protected by a competitive inhibitor. Evidence is shown that the enzymatic nucleophilic attack of carbamates is directed at the carbonyl carbon atom and not the nitrogen atom. The inhibition of bile-salt-dependent lipase does not occur consecutive to the formation of a reactive isocyanate derivative of carbamate but via a tetrahedral intermediate involving essential residues implicated in the enzyme catalytic site. This intermediate evolves by liberation of alcohol (or phenol) and formation of an inactive carbamyl enzyme. Among the carbamates tested, N-butyl-N-methyl-(4-nitrophenyl) carbamate specifically inhibits the bile-salt-dependent lipase; the release of 4-nitrophenol from this carbamate is directly proportional to the enzyme inhibition and it may be defined as a specific active-site titrator for bile-salt-dependent lipases.     

Activity of bile-salt-stimulated human milk lipase in the presence of liposomes and mixed taurocholate-phosphatidylcholine micelles

(1) The interaction of bile-salt-stimulated human milk lipase and liposomal membranes has been investigated in the presence or absence of sodium taurocholate. Freshly purified enzyme enhances the permeability of liposomal membranes but thermally inactivated enzyme does not. (2) The ability of the enzyme to catalyze the hydrolisys of a relatively hydrophilic substrate, 4-nitrophenyl acetate, and a more hydrophobic substrate, 4-nitrophenyl palmitate, has also been measured in media containing small unilamelar vesicles of egg phosphatidylcholine in both the absence and presence of taurocholate, and also in the presence of free taurocholate in the absence of liposomes. (3) The enzyme-catalyzed hydrolysis of 4-nitrophenyl acetate is enhanced in all of these systems, but 4-nitrophenyl palmitate is protected from enzymic attack in the phosphatidylcholine-bile salt systems. If free taurocholate be present in the system before 4-nitrophenyl palmitate is added, then, and only then, is enzymic activity observed. (4) These results have been interpreted in terms of the importance of the microenvironment around the substrate and the role played by the bile salt surfactant in stimulating the enzyme.     

Mechanism of ubiquitin carboxyl-terminal hydrolase. Borohydride and hydroxylamine inactivate in the presence of ubiquitin

Ubiquitin (Ub) carboxyl-terminal hydrolase (E) catalyzes the hydrolysis, at the Ub-carboxyl terminus, of a wide variety of C-terminal Ub derivatives. We show that the enzyme is inactivated by millimolar concentrations of either sodium borohydride or hydroxylamine, but only if Ub is present. We have interpreted these results on the assumption that the hydrolase mechanism is one of nucleophilic catalysis with an acyl-Ub-E intermediate. The borohydride-inactivated enzyme has the following properties. It is a stoichiometric complex of E and Ub containing tritium from sodium boro[3H]hydride. This complex is stable at neutral pH in 5 M urea and can be isolated on the basis of size on a sieving column, but a labeled product the size of Ub is released under more strongly denaturing conditions. The "Ub" released in acid is Ub-carboxyl-terminal aldehyde, based on the observations that: it contains the tritium present in the reduced complex and it is able to form the inactive enzyme from a stoichiometric amount of fresh enzyme, and inactivation is accompanied by E-Ub adduct formation; it has chemical properties expected of an aldehyde: after a second reduction of the Ub released with boro[3H]hydride and complete acid hydrolysis, tritium counts are found in ethanolamine (the carboxyl-terminal residue of Ub is glycine). These results suggest that enzyme and Ub combine in an equilibrium reaction to form an ester or thiol ester adduct (at the Ub-carboxyl terminus), and that this adduct is trapped by borohydride to give a very stable inactive E-Ub (thio) hemiacetal which is unable to undergo a second reduction step and which can release Ub-aldehyde in mild acid. Inactivation in the presence of hydroxylamine of hydrolase occurs once during hydrolysis of 1200 molecules of Ub-hydroxamate by the enzyme. The hydrolysis/inactivation ratio is constant over the range of 10-50 mM hydroxylamine showing that forms of E-Ub with which hydroxylamine and water react are different and not in rapid equilibrium. The inactive enzyme may be an acylhydroxamate formed from an E-Ub mixed anhydride generated from the E-Ub (thiol) ester inferred from the borohydride study. A direct radioactive assay for the hydrolase has been developed using the Ub-C-terminal amide of [3H]butanol-4-amine as substrate.     

Asymmetric reduction of 3-aryl-3-keto esters using Rhizopus species

Ethyl 3-aryl-3-oxopropanoates (aryl: phenyl, 2-fluorophenyl, 3-nitrophenyl, and 4-nitrophenyl) were reduced enantioselectively to the corresponding (S)-alcohols by the fungus Rhizopus arrhizus and other Rhizopus sp. The best results were generally obtained with Rhizopus arrhizus (wild type) and Rhizopus nivius NCIM 958 with 6h incubation. A longer incubation period led to ester hydrolysis followed by decarboxylation and microbial reduction for all the substrates especially the 3-nitrophenyl ester.     

Deleterious effect of Brij 35 on alkyl 2-pyrones and other hydrophobic inhibitors of human sputum and leucocyte elastase

Brij 35 significantly reduced the inhibitory activity of hydrophobic alkyl 2-pyrones, oleic acid and alkyl peptides towards human sputum and leucocyte elastase, whereas 4-methoxy-6-(2'-hydroxy-2'-(carbobutyloxy)-vinyl)-2-pyrone, alpha-1-proteinase inhibitor and a sulfated chitosan were unaffected. The effect of Brij 35 on elastase appeared to be irreversible, since dialysis against Brij-free buffer was not accompanied by a return to inhibitory activity by the first group of inhibitors. However, passage through an ionic-exchange column was effective in removing the detergent from the enzyme. Brij 35 is also an activator of the elastases: kcat for Boc-Ala-4-nitrophenyl ester and methylsuccinyl-Ala-Ala-Pro-Val-4-nitroanilide increased by 20% and 40%, respectively in the presence of 0.015% Brij 35. Binding of the substrates to the enzyme is unaffected, since Km is unchanged.     

High-performance liquid chromatographic determination of the polar metabolites of nifedipine in plasma, blood and urine

A relatively simple reversed-phase high-performance liquid chromatographic method for the determination of the polar metabolites of nifedipine in biological fluids is described. After conversion of 2-hydroxymethyl-6-methyl-4-(2-nitrophenyl)pyridine-3,5-dicarboxylic acid 5-methyl ester (IV) into 5,7-dihydro-2-methyl-4-(2-nitrophenyl)-5-oxofuro[3,4-b]pyridine-3-carboxylic acid methyl ester (V) by heating under acidic conditions, V was extracted with n-pentane—dichloromethane (7:3) and analysed on a C₁₈ column with ultraviolet detection. Subsequently, 2,6-dimethyl-4-(2-nitrophenyl)-3,5-pyridinedicarboxylic acid monomethyl ester (III) was extracted with chloroform and analysed on the same system. Limits of determination in blood were 0.1 μg/ml for III and 0.05 μg/ml for IV and V; these limits were two to ten times higher for urine. This inter-assay variability was always less than 7.5%.