Recombinant heteromeric phenylalanine monooxygenase and the oxygenation of carbon and sulfur substrates.

Objectives  The aim of this investigation was to provide in-vitro enzyme kinetic data to support the hypothesis that the in-vivo heterozygous dominant phenotype for phenylalanine monooxygenase (hPAH) was responsible for the S-oxidation polymorphism in the metabolism of S-carboxymethyl-l-cysteine reported in humans. Using a dual-vector expression strategy for the co-production of wild-type and mutant human hPAH subunits we report for the first time the kinetic parameters (K(m) , V(max) , CL(E) ) for the C-oxidation of l-phenylalanine and the S-oxidation of S-carboxymethyl-l-cysteine in homomeric wild-type, heteromeric mutant and homomeric mutant hPAH proteins in vitro. Methods  A PRO(TM) dual-vector bacterial expression system was used to produce the required hPAH proteins. Enzyme activity was determined by HPLC with fluorescence detection. Key findings  The heteromeric hPAH proteins (I65T, R68S, R158Q, I174T, R261Q, V338M, R408W and Y414C) all showed significantly decreased V(max) and CL(E) values when compared to the homomeric wild-type hPAH enzyme. For both substrates, all calculated K(m) values were significantly higher than homomeric wild-type hPAH enzyme, with the exception of I65T, R68S and Y414C heteromeric hPAH proteins employing l-phenylalanine as substrate. Conclusions  The net outcome for the heteromeric mutant hPAH proteins was a decrease significantly more dramatic for S-carboxymethyl-l-cysteine S-oxidation (1.0-18.8% of homomeric wild-type hPAH activity) when compared to l-phenylalanine C-oxidation (25.9-52.9% of homomeric wild-type hPAH activity) as a substrate. Heteromeric hPAH enzyme may be related to the variation in S-carboxymethyl-l-cysteine S-oxidation capacity observed in humans

A validated HPLC method for zanamivir and its application to in vitro permeability study in CACO-2 culture model

A simple HPLC method was developed and validated for the quantification of zanamivir in permeability studies using Caco-2 cell culture model. Chromatographic resolution was achieved using 98% (v/v) ultrapure water and 2% (v/v) acetonitrile as mobile phase with flow rate of 0.5 ml/min on a BDS Hypersil Cyano column (length 250 mm; internal diameter 4.6 mm; particle size 5 μm) and UV detection at 230 nm. The method was linear for the quantification of zanamivir at concentration ranging from 0.1-10 μg/ml with coefficient of determination greater than 0.999. The recovery of zanamivir was in the range of 99.76-105.08%. The relative standard deviations of the within-day precision and between-day precision were lower than 10.32 and 14.33%, respectively. The permeability of zanamivir was independent of the transport direction and zanamivir concentrations, indicating a passive transport of zanamivir across Caco-2 cells. With the absence of Ca 2+ in transport medium, the permeability values of zanamivir increased 56.21 and 57.20 fold in the directions of apical to basolateral and basolateral to apical, respectively. On the basis of these results, zanamivir was found to be predominantly transported across Caco-2 monolayers via the passive paracellular pathway

Phenylalanine 4-monooxygenase and the S-oxidation of S-carboxymethyl-L-cysteine by human cytosolic fractions.

The purpose of this investigation was to reaction phenotype the identity of the cytosolic enzyme responsible for the S-oxidation of S-carboxymethyl-L-cysteine (SCMC) in female human hepatic cytosolic fractions. The identity of this enzyme in the female Wistar rat hepatic cytosolic fraction was found to be phenylalanine 4-monooxygenase (PAH). In pooled female human hepatic cytosolic fractions the calculated K(m) and V(max) for substrate (SCMC) activated PAH was 16.22 +/- 11.31 mM and 0.87 +/- 0.41 nmoles x min(-1) mg(-1). The experimental data modelled to the Michaelis-Menten equation with noncompetitive substrate inhibition. When the cytosolic fractions were activated with lysophophatidylcholine the V(max) increased to 52.31 +/- 11.72 nmoles x min(-1) mg(-1) but the K(m) remained unchanged at 16.53 +/- 2.32 mM. A linear correlation was seen in the production of Tyr and SCMC R/S S-oxide in 20 individual female hepatic cytosolic fractions for both substrate and lysophosphatidylcholine activated PAH (r(s) > 0.96). Inhibitor studies found that the specific chemical and antibody inhibitors of PAH reduced the production of Tyr and SCMC R/S S-oxide in these in vitro PAH assays. An investigation of the mechanism of interaction of SCMC with PAH indicated that the drug was a competitive inhibitor of the aromatic C-oxidation of Phe with a calculated K(i) of 17.23 +/- 4.15 mM. The requirement of BH4 as cofactor and the lack of effect of the specific tyrosine hydroxylase, tryptophan hydroxylase and nitric oxide synthase inhibitors on the S-oxidation of SCMC all indicate that PAH was the enzyme responsible for this biotransformation reaction in human hepatic cytosolic fractions

Phenylalanine 4-monooxygenase and the S-oxidation of S-carboxymethyl-L-cysteine by human cytosolic fractions

The purpose of this investigation was to reaction phenotype the identity of the cytosolic enzyme responsible for the S-oxidation of S-carboxymethyl-L-cysteine (SCMC) in female human hepatic cytosolic fractions. The identity of this enzyme in the female Wistar rat hepatic cytosolic fraction was found to be phenylalanine 4-monooxygenase (PAH). In pooled female human hepatic cytosolic fractions the calculated K(m) and V(max) for substrate (SCMC) activated PAH was 16.22 +/- 11.31 mM and 0.87 +/- 0.41 nmoles x min(-1) mg(-1). The experimental data modelled to the Michaelis-Menten equation with noncompetitive substrate inhibition. When the cytosolic fractions were activated with lysophophatidylcholine the V(max) increased to 52.31 +/- 11.72 nmoles x min(-1) mg(-1) but the K(m) remained unchanged at 16.53 +/- 2.32 mM. A linear correlation was seen in the production of Tyr and SCMC R/S S-oxide in 20 individual female hepatic cytosolic fractions for both substrate and lysophosphatidylcholine activated PAH (r(s) > 0.96). Inhibitor studies found that the specific chemical and antibody inhibitors of PAH reduced the production of Tyr and SCMC R/S S-oxide in these in vitro PAH assays. An investigation of the mechanism of interaction of SCMC with PAH indicated that the drug was a competitive inhibitor of the aromatic C-oxidation of Phe with a calculated K(i) of 17.23 +/- 4.15 mM. The requirement of BH4 as cofactor and the lack of effect of the specific tyrosine hydroxylase, tryptophan hydroxylase and nitric oxide synthase inhibitors on the S-oxidation of SCMC all indicate that PAH was the enzyme responsible for this biotransformation reaction in human hepatic cytosolic fractions