Biotransformation of alkaloids.

Biotransformations of alkaloids over the last decade have continued to encompass a wide variety of substrates and enzymes. The elucidation of novel alkaloid biosynthetic and catabolic pathways will continue to furnish new biocatalysts for the synthetic organic chemist. Furthermore, an improved understanding of the genetic and biochemical basis of metabolic pathways will also permit the engineering of pathways in plants and other heterologous hosts for the production of therapeutically important alkaloids. The combination of increasing commercial interest and advances in molecular biology will facilitate the availability of robust biocatalysts which are a prerequsite to achieve economically feasible processes for the production of alkaloid-based therapeutics.

Engineering novel biocatalytic routes for production of semisynthetic opiate drugs.

The morphine alkaloids and their semisynthetic derivatives provide a diverse range of important pharmaceutical drugs. Current production of semisynthetic opiate drugs is by chemical means from naturally occurring morphine, codeine and thebaine. Although various microbial transformations of morphine alkaloids have been identified since the 1960s, more recently there has been considerable effort devoted to engineering biocatalytic routes for producing these important compounds. Such biocatalytic routes are attractive, as they would provide an alternative to the chemical production processes which suffer from limited supply of precursors, often low yields and toxic wastes. The biotransformation of morphine and codeine to the potent analgesic hydromorphone and the mild analgesic/antitussive hydrocodone, respectively, by recombinant Escherichia coli has been demonstrated and the problems encountered when engineering such a system will be discussed.

Degradation of explosives by nitrate ester reductases.

Explosive-contaminated land poses a hazard both to the environment and to human health. Microbial enzymes, either in their native or heterologous hosts, are a powerful and low-cost tool for eliminating this environmental hazard. As many explosives have only been present in the environment for 10 years, and with similar molecules not known in Nature, the origin of enzymes specialized for the breakdown of explosives is of particular interest. Screening of environmental isolates resulted in the discovery of flavoproteins capable of denitrating the explosives pentaerythritol tetranitrate (PETN) and glycerol trinitrate. These nitrate ester reductases are related in sequence and structure to Old Yellow Enzyme from Saccharomyces carlsbergenisis. All the members of this family have alpha/beta barrel structures and FMN as a prosthetic group, and reduce various electrophilic substrates. The nitrate ester reductases are, however, unusual in that they display activity towards the highly recalcitrant, aromatic explosive 2,4,6-trinitrotoluene, via a reductive pathway resulting in nitrogen liberation. We have embarked on a detailed study of the structure and mechanism of PETN reductase from a strain of Enterobacter cloacae. Work is focused currently on relating structure and function within this growing family of enzymes, with a view to engineering novel enzymes exhibiting useful characteristics.

Preliminary in vitro toxicological evaluation of a series of 2-pyridylcarboxamidrazone candidate anti-tuberculosis compounds III.

We have evaluated the cytotoxicity of a series of novel anti-tubercular 2-pyridyl carboxamidrazones through incubation with human mononuclear leucocytes (MNL), with and without a rat microsomal metabolising system. Isoniazid (INH), the closest structurally related agent, was used as a positive control. Incubation of the 3-benzyloxy-benzylidene, dimethylpropyl-benzylidene and 4-phenyl-benzylidene with MNL showed no significant toxicity in comparison with either INH or DMSO vehicle control. However, the 4-N,N-dimethylamino-1-naphthylidene derivative exerted more than sevenfold greater toxicity compared with INH, while the 4-N,N-dimethylamino-1-naphthylidene, 2-benzyloxy-3-methoxy-benzylidene, 2-t-butylthio-benzylidene and 4-i-propyl-benzylidene derivatives showed toxicity which ranged from five to fourfold that of INH. In the presence of either rat microsomes with or without NADPH, the 3-benzyloxy-benzylidene, dimethylpropyl-benzylidene and 4-phenyl-benzylidene derivatives showed no metabolically-mediated cytotoxicity. The latter two derivatives showed a combination of low toxicity and considerabe efficacy against Mycobacteria tuberculosis in vitro and show promise for future development.

Cofactor regeneration by a soluble pyridine nucleotide transhydrogenase for biological production of hydromorphone.

We have applied the soluble pyridine nucleotide transhydrogenase of Pseudomonas fluorescens to a cell-free system for the regeneration of the nicotinamide cofactors NAD and NADP in the biological production of the important semisynthetic opiate drug hydromorphone. The original recombinant whole-cell system suffered from cofactor depletion resulting from the action of an NADP(+)-dependent morphine dehydrogenase and an NADH-dependent morphinone reductase. By applying a soluble pyridine nucleotide transhydrogenase, which can transfer reducing equivalents between NAD and NADP, we demonstrate with a cell-free system that efficient cofactor cycling in the presence of catalytic amounts of cofactors occurs, resulting in high yields of hydromorphone. The ratio of morphine dehydrogenase, morphinone reductase, and soluble pyridine nucleotide transhydrogenase is critical for diminishing the production of the unwanted by-product dihydromorphine and for optimum hydromorphone yields. Application of the soluble pyridine nucleotide transhydrogenase to the whole-cell system resulted in an improved biocatalyst with an extended lifetime. These results demonstrate the usefulness of the soluble pyridine nucleotide transhydrogenase and its wider application as a tool in metabolic engineering and biocatalysis.

Mechanistic studies of morphine dehydrogenase and stabilization against covalent inactivation.

Morphine dehydrogenase (MDH) of Pseudomonas putida M10 catalyses the NADP(+)-dependent oxidation of morphine and codeine to morphinone and codeinone. This enzyme forms the basis of a sensitive detection and assay method for heroin metabolites and a biotransformation process for production of hydromorphone and hydrocodone. To improve these processes we have undertaken a thorough examination of the kinetic mechanism of MDH. Sequence comparisons indicated that MDH belongs within the aldose reductase enzyme family. MDH was shown to be specific for the pro-R hydrogen of NADPH. In steady-state kinetic studies, product inhibition patterns suggested that MDH follows a Theorell-Chance mechanism for codeinone reduction at pH 7, and a non-Theorell-Chance sequential ordered mechanism for codeine oxidation at pH 9.5. Residues corresponding to the catalytically important Tyr-48, Lys-77 and Asp-43 of aldose reductase were modified by site-directed mutagenesis, resulting in substantial loss of activity consistent with a catalytic role for these residues. Loss of activity of MDH in the presence of the reaction product morphinone was found to be due to the formation of a covalent adduct with Cys-80; alteration of Cys-80 to serine resulted in an enzyme with greatly enhanced stability.

A new amidrazone derivative with antimycobacterial activity.

Of a series of pyridine-2-carboxamidrazone derivatives with activity against mycobacteria, the N(1)-[4-(1,1-dimethylpropyl)benzylidene] derivative reported here, C(18)H(22)N(4), is one of the most active. The predicted E isomer about the C11=N12 double bond is confirmed and intramolecular hydrogen bonding involving both amino H atoms helps to keep the molecule flat. The same donor and acceptor atoms also form intermolecular hydrogen bonds.

Transformations of codeine to important semisynthetic opiate derivatives by Pseudomonas putida m10.

A biotransformation mixture which contained codeine and washed cells of Pseudomonas putida M10 gave rise to a number of transformation products that are of clinical importance which included hydrocodone, dihydrocodeine and 14beta-hydroxycodeine. Incubations with the same organism and codeinone gave rise to 14beta-hydroxycodeinone and 14beta-hydroxycodeine. Cell-free extracts and membrane fractions of P. putida M10 were shown to catalyse the 14beta-hydroxylation of codeinone. In addition, the potent analgesic oxycodone was shown to be produced from 14beta-hydroxycodeinone.

3-(Piperazinylpropyl)indoles: selective, orally bioavailable h5-HT1D receptor agonists as potential antimigraine agents.

Clinically effective antimigraine drugs such as Sumatriptan have similar affinity at h5-HT1D and h5-HT1B receptors. In the search for a h5-HT1D-selective agonist as an antimigraine agent, a novel series of 3-(propylpiperazinyl)indoles have been synthesized and evaluated at h5-HT1D and h5-HT1B receptors. This class of compounds has provided subnanomolar, fully efficacious h5-HT1D agonists with up to 200-fold selectivity for the h5-HT1D receptor over the h5-HT1B receptor. Unlike other h5-HT1D-selective series, several propylpiperazines demonstrate good oral bioavailability. The optimum compound was 1-(3-[5-(1,2, 4-triazol-4-yl)-1H-indol-3-yl]propyl)-4-(2-(3-fluorophenyl)ethyl)p ipe razine (7f) which has excellent selectivity for h5-HT1D receptors over other 5-HT receptor subtypes and good oral bioavailability in three species. Compound 7f has been selected for further investigation as a potential development candidate in the treatment of migraine.

Preliminary in vitro toxicological evaluation of a series of 2-pyridylcarboxamidrazone candidate anti-tuberculosis compounds.

We have investigated the toxicity of a series of 2-pyridylcarboxamidrazones in vitro using a rat liver metabolism system as well as human erythrocytes and mononuclear leucocytes (MNL) as target cells. Of the seven derivatives and four precursors tested, only minimal (<2.3%) metabolism-mediated methaemoglobin was formed by two analogues. However, one of these, a naphthylidene 2-pyridylcarboxamidrazone derivative (compound III), was also directly toxic to human MNLs. This toxicity was partially attenuated by the rat metabolising system and incubation of diethyldithiocarbamate or cimetidine together with compound III and the rat metabolising system suppressed the metabolism-dependent detoxification. This indicated that cytochrome P-450-mediated biotransformation of compound III was preventing its direct toxicity to the MNL. Of the seven derivatives tested, six were low in toxicity to MNL directly and in the presence of a metabolising system. The two compounds which were the most potent anti-mycobacterially, the dimethylpropyl and dimethylethyl benzylidene amidrazone derivatives, were also the least toxic to MNL and erythrocytes. This amidrazone series has shown promise for future development as antituberculosis drugs.

Synthesis and antimycobacterial activity of some heteroarylcarboxamidrazone derivatives.

A series of pyridine-2-, pyrazine-2- and quinoline-2-carboxamidrazone derivatives was prepared in an automated fashion and tested against Mycobacterium fortuitum in a rapid screen. Seven pyridine-2-carboxamidrazone derivatives were investigated further and four were found to have inhibitory activity with compound 4af being the most active. The structure activity implications are discussed.

Effect of plasma protein binding on in vivo activity and brain penetration of glycine/NMDA receptor antagonists.

A major issue in designing drugs as antagonists at the glycine site of the NMDA receptor has been to achieve good in vivo activity. A series of 4-hydroxyquinolone glycine antagonists was found to be active in the DBA/2 mouse anticonvulsant assay, but improvements in in vitro affinity were not mirrored by corresponding increases in anticonvulsant activity. Here we show that binding of the compounds to plasma protein limits their brain penetration. Relative binding to the major plasma protein, albumin, was measured in two different ways: by a radioligand binding experiment or using an HPLC assay, for a wide structural range of glycine/NMDA site ligands. These measures of plasma protein binding correlate well (r = 0.84), and the HPLC assay has been used extensively to quantify plasma protein binding. For the 4-hydroxyquinolone series, binding to plasma protein correlates (r = 0.92) with log P (octanol/pH 7.4 buffer) over a range of log P values from 0 to 5. The anticonvulsant activity increases with in vitro affinity, but the slope of a plot of pED50 versus pIC50 is low (0.40); taking plasma protein binding into account in this plot increases the slope to 0.60. This shows that binding to albumin in plasma reduces the amount of compound free to diffuse across the blood-brain barrier. Further evidence comes from three other experiments: (a) Direct measurements of brain/blood ratios for three compounds (2, 16, 26) show the ratio decreases with increasing log R. (b) Warfarin, which competes for albumin binding sites dose-dependently, decreased the ED50 of 26 for protection against seizures induced by NMDLA. (c) Direct measurements of brain penetration using an in situ brain perfusion model in rat to measure the amount of drug crossing the blood-brain barrier showed that compounds 2, 26, and 32 penetrate the brain well in the absence of plasma protein, but this is greatly reduced when the drug is delivered in plasma. In the 4-hydroxyquinolones glycine site binding affinity increases with lipophilicity of the 3-substituent up to a maximum at a log P around 3, then does not improve further. When combined with increasing protein binding, this gives a parabolic relationship between predicted in vivo activity and log P, with a maximum log P value of 2.39. Finally, the plasma protein binding studies have been extended to other series of glycine site antagonists, and its is shown that for a given log P these have similar protein binding to the 4-hydroxyquinolones, except for compounds that are not acidic. The results have implications for the design of novel glycine site antagonists, and it is suggested that it is necessary to either keep log P low or pKa high to obtain good central nervous system activity.

Biological profile of L-745,870, a selective antagonist with high affinity for the dopamine D4 receptor.

L-745,870,(3-([4-(4-chlorophenyl)piperazin-1-yl]methyl)-1H- pyrollo[2,3-b] pyridine, was identified as a selective dopamine D4 receptor antagonist with excellent oral bioavailability and brain penetration. L-745,870 displaced specific binding of 0.2 nM [3H] spiperone to cloned human dopamine D4 receptors with a binding affinity (Ki) of 0. 43 nM which was 5- and 20-fold higher than that of the standard antipsychotics haloperidol and clozapine, respectively. L-745,870 exhibited high selectivity for the dopamine D4 receptor (>2000 fold) compared to other dopamine receptor subtypes and had moderate affinity for 5HT2, sigma and alpha adrenergic receptors(IC50 < 300 nM). In vitro, L-745,870 (0.1-1 microM) exhibited D4 receptor antagonist activity, reversing dopamine (1 microM) mediated 1) inhibition of adenylate cyclase in hD4HEK and hD4CHO cells; 2) stimulation of [35S] GTPgammaS binding and 3) stimulation of extracellular acidification rate, but did not exhibit any significant intrinsic activity in these assays. Although standard antipsychotics increase dopamine metabolism or plasma prolactin levels in rodents, L-745,870 (

5-(Piperidin-2-yl)- and 5-(homopiperidin-2-yl)-1,4-benzodiazepines: high-affinity, basic ligands for the cholecystokinin-B receptor.

The design, synthesis, and biological activity of a series of high-affinity, basic ligands for the cholecystokinin-B receptor are described. The compounds, which incorporate a piperidin-2-yl or a homopiperidin-2-yl group attached to C5 of a benzodiazepine core structure, are substantially more basic (e.g., 9d, pKa = 9.48) than previously reported antagonists based on 5-amino-1,4-benzodiazepines (e.g., 5, pKa = 7.1) and have improved aqueous solubility. In view of their basicity, it would be tempting to speculate that the present series of compounds might be binding to the CCK-B receptor in their protonated form. Compounds such as 9d, e and 10d showed high affinity for this receptor (IC50 < 2.5 nM) and very good selectivity over CCK-A (CCK-A/CCK-B > 2000), even as the racemates. Additionally, a significantly improved in vivo half-life was observed for a selection of compounds compared to the clinical candidate L-365, -260 (1).

Structural studies on bioactive compounds. 28. Selective activity of triazenyl-substituted pyrimethamine derivatives against Pneumocystis carinii dihydrofolate reductase.

Triazenyl-substituted pyrimethamine derivatives 10a-s have been prepared by coupling diazotized 2,4-diamino-5-(3-amino-4-chlorophenyl)-6-ethyl pyrimidine (1c) with a series of secondary amines in aqueous sodium carbonate solution. The triazenes which are stable and poorly soluble as free bases form more soluble, but unstable, salts with alkanesulfonic acids. The lead dimethyltriazene 2,4-diamino-5[4-chloro-3-(3,3-dimethyltriazen-1-yl)phenyl]-6-et hylpyrimidine (4a) forms a crystalline ethanesulfonic acid salt (solvated with 2-propanol), which is protonated at the pyrimidine N-1 position, as determined by X-ray crystallography. The ability of these new triazenes to inhibit Pneumocystis carinii dihydrofolate reductase in vitro has been compared to that of triazene 4a. The most potent and selective compound, 2,4-diamino-5-[3-[3-[2-(acetyloxy)ethyl]-3-benzyltriazen-1-y l]-4- chlorophenyl]-6-ethylpyrimidine (14a), has an IC50 value of 0.17 microM against the microbial enzyme and potentially useful selectivity (rat liver IC50/P. carinii IC50 = 114).

Molecular analysis of the Rhodococcus sp. strain H1 her gene and characterization of its product, a heroin esterase, expressed in Escherichia coli.

The structural gene for heroin esterase was cloned from Rhodococcus sp. strain H1 and expressed in Escherichia coli BL21(DE3). The purified enzyme was found to be a tetramer with an M(r) of 137,000 and an apparent K(m) of 0.88 mM for 6-acetylmorphine. The G-x-S-x-G motif was observed in the deduced amino acid sequence, suggesting that the enzyme is a serin esterase.