Tropinone reductases, enzymes at the branch point of tropane alkaloid metabolism

Two stereospecific oxidoreductases constitute a branch point in tropane alkaloid metabolism. Products of tropane metabolism are the alkaloids hyoscyamine, scopolamine, cocaine, and polyhydroxylated nortropane alkaloids, the calystegines. Both tropinone reductases reduce the precursor tropinone to yield either tropine or pseudotropine. In Solanaceae, tropine is incorporated into hyoscyamine and scopolamine; pseudotropine is the first specific metabolite on the way to the calystegines. Isolation, cloning and heterologous expression of both tropinone reductases enabled kinetic characterisation, protein crystallisation, and structure elucidation. Stereospecificity of reduction is achieved by binding tropinone in the respective enzyme active centre in opposite orientation. Immunolocalisation of both enzyme proteins in cultured roots revealed a tissue-specific protein accumulation. Metabolite flux through both arms of the tropane alkaloid pathway appears to be regulated by the activity of both enzymes and by their access to the precursor tropinone. Both tropinone reductases are NADPH-dependent short-chain dehydrogenases with amino acid sequence similarity of more than 50% suggesting their descent from a common ancestor. Putative tropinone reductase sequences annotated in plant genomes other that Solanaceae await functional characterisation.     

Two Tropinone Reductases with Distinct Stereospecificities from Cultured Roots of Hyoscyamus niger

Tropinone is an alkamine intermediate at the branch point of biosynthetic pathways leading to various tropane alkaloids. Two stereospecifically distinct NADPH-dependent oxidoreductases, TR-I and TR-II, which, respectively, reduce tropinone to 3α-hydroxytropane (tropine) and 3β-hydroxytropane (ψ-tropine), were detected mainly in the root of tropane alkaloid-producing plants but not in nonproducing cultured root. Both reductases were purified to near homogeneity from cultured root of Hyoscyamus niger and characterized. The TR-I reaction was reversible, whereas the TR-II reaction was essentially irreversible, reduction of the ketone being highly favored over oxidation of the alcohol ψ-tropine. Marked differences were found between the two reductase in their affinities for tropinone substrate and in the effects of amino acid modification reagents. Some differences in substrate specificity were apparent. For example, N-propyl-4-piperidone was reduced by TR-II but not by TR-I. Conversely, 3-quinuclidinone and 8-thiabicyclo[3,2,1]octane-3-one were accepted as substrates by TR-I but hardly at all by TR-II. Both enzymes were shown to be class B oxidoreductases, which transfer the pro-S hydrogen of NAD(P)H to their substrates. Possible roles of these tropinone reductases in alkaloid biosynthesis are discussed.     

Molecular cloning and catalytic characterization of a recombinant tropine biosynthetic tropinone reductase from Withania coagulans leaf

Tropinone reductases (TRs) are small proteins belonging to the SDR (short chain dehydrogenase/reductase) family of enzymes. TR-I and TR-II catalyze the conversion of tropinone into tropane alcohols (tropine and pseudotropine, respectively). The steps are intermediary enroute to biosynthesis of tropane esters of medicinal importance, hyoscyamine/scopolamine, and calystegins, respectively. Biosynthesis of tropane alkaloids has been proposed to occur in roots. However, in the present report, a tropine forming tropinone reductase (TR-I) cDNA was isolated from the aerial tissue (leaf) of a medicinal plant, Withania coagulans. The ORF was deduced to encode a polypeptide of 29.34 kDa. The complete cDNA (WcTRI) was expressed in E. coli and the recombinant His-tagged protein was purified for functional characterization. The enzyme had a narrow pH range of substantial activity with maxima at 6.6. Relatively superior thermostability of the enzyme (30% retention of activity at 60 °C) was catalytic novelty in consonance with the desert area restricted habitat of the plant. The in vitro reaction kinetics predominantly favoured the forward reaction. The enzyme had wide substrate specificity but did not cover the substrates of other well-known plant SDR related to menthol metabolism. To our knowledge, this pertains to be the first report on any gene and enzyme of secondary metabolism from the commercially and medicinally important vegetable rennet species.     

The functional divergence of short-chain dehydrogenases involved in tropinone reduction

Tropane alkaloids typically occur in the Solanaceae and are also found in Cochlearia officinalis, a member of the Brassicaceae. Tropinone reductases are key enzymes of tropane alkaloid metabolism. Two different tropinone reductases form one stereoisomeric product each, either tropine for esterified alkaloids or pseudotropine that is converted to calystegines. A cDNA sequence with similarity to known tropinone reductases (TR) was cloned from C. officinalis. The protein was expressed in Escherichia coli, and found to catalyze the reduction of tropinone. The enzyme is a member of the short-chain dehydrogenase enzyme family and shows broad substrate specificity. Several synthetic ketones were accepted as substrates, with higher affinity and faster enzymatic turnover than observed for tropinone. C. officinalis TR produced both the isomeric alcohols tropine and pseudotropine from tropinone using NADPH + H(+) as co-substrate. Tropinone reductases of the Solanaceae, in contrast, are strictly stereospecific and form one tropane alcohol only. The Arabidopsis thaliana homologue of C. officinalis TR showed high sequence similarity, but did not reduce tropinone. A tyrosine residue was identified in the active site of C. officinalis TR that appeared responsible for binding and orientation of tropinone. Mutagenesis of the tyrosine residue yielded an active reductase, but with complete loss of TR activity. Thus C. officinalis TR presents an example of an enzyme with relaxed substrate specificity, like short-chain dehydrogenases, that provides favorable preconditions for the evolution of novel functions in biosynthetic sequences.     

Endothelial lipase mediates efficient lipolysis of triglyceride-rich lipoproteins

Triglyceride-rich lipoproteins (TRLs) are circulating reservoirs of fatty acids used as vital energy sources for peripheral tissues. Lipoprotein lipase (LPL) is a predominant enzyme mediating triglyceride (TG) lipolysis and TRL clearance to provide fatty acids to tissues in animals. Physiological and human genetic evidence support a primary role for LPL in hydrolyzing TRL TGs. We hypothesized that endothelial lipase (EL), another extracellular lipase that primarily hydrolyzes lipoprotein phospholipids may also contribute to TRL metabolism. To explore this, we studied the impact of genetic EL loss-of-function on TRL metabolism in humans and mice. Humans carrying a loss-of-function missense variant in LIPG, p.Asn396Ser (rs77960347), demonstrated elevated plasma TGs and elevated phospholipids in TRLs, among other lipoprotein classes. Mice with germline EL deficiency challenged with excess dietary TG through refeeding or a high-fat diet exhibited elevated TGs, delayed dietary TRL clearance, and impaired TRL TG lipolysis in vivo that was rescued by EL reconstitution in the liver. Lipidomic analyses of postprandial plasma from high-fat fed Lipg^-/- mice demonstrated accumulation of phospholipids and TGs harboring long-chain polyunsaturated fatty acids (PUFAs), known substrates for EL lipolysis. In vitro and in vivo, EL and LPL together promoted greater TG lipolysis than either extracellular lipase alone. Our data positions EL as a key collaborator of LPL to mediate efficient lipolysis of TRLs in humans and mice.     

Immunolocalisation of two tropinone reductases in potato (Solanum tuberosum L.) root, stolon, and tuber sprouts

Tropinone reductases (TRs) are essential enzymes in the tropane alkaloid biosynthesis, providing either tropine for hyoscyamine and scopolamine formation or providing pseudotropine for calystegines. Two cDNAs coding for TRs were isolated from potato (Solanum tuberosum L.) tuber sprouts and expressed in E. coli. One reductase formed pseudotropine, the other formed tropine and showed kinetic properties typical for tropine-forming tropinone reductases (TRI) involved in hyoscyamine formation. Hyoscyamine and tropine are not found in S. tuberosum plants. Potatoes contain calystegines as the only products of the tropane alkaloid pathway. Polyclonal antibodies raised against both enzymes were purified to exclude cross reactions and were used for Western-blot analysis and immunolocalisation. The TRI (EC 1.1.1.206) was detected in protein extracts of tuber tissues, but mostly in levels too low to be localised in individual cells. The function of this enzyme in potato that does not form hyoscyamine is not clear. The pseudotropine-forming tropinone reductase (EC 1.1.1.236) was detected in potato roots, stolons, and tuber sprouts. Cortex cells of root and stolon contained the protein; additional strong immuno-labelling was located in phloem parenchyma. In tuber spouts, however, the protein was detected in companion cells.     

Effects of different elicitors on yield of tropane alkaloids in hairy roots of Anisodus acutangulus

The four tropane alkaloids have played a pivotal role in controlling diseases such as the toxic and septic shock, the organophosphorus poison and the acute lung injury. Here, the elicitation effect of different elicitors on the production of tropane alkaloids and the molecular mechanism of enzyme genes in the pathway was firstly demonstrated in hairy roots of Anisodus acutangulus. The results showed ethanol, methyl jasmonate and Ag⁺ could improve the accumulation of tropane alkaloids up to 1.51, 1.13 and 1.08 times after 24 h treatment, respectively (P < 0.05), whereas salicylic acid decreased the average content of tropane alkaloids. Furthermore, expression profile analysis results revealed that up-regulation of hyoscyamine-6b-hydroxylase (AaH6H) and little regulation of tropinone reducase II (AaTR2) elicited by ethanol, increased expression of putrescine N-methyltransferase I (AaPMT1) elicited by Ag⁺, elevated expression of tropinone reducase I (AaTR1) elicited by methyl jasmonate, respectively, resulted in tropane alkaloids improvement. Our results showed that hairy root culture of A. acutangulus in combination with elicitors was a promising way for production of tropane alkaloids in the future.     

Bulge Formation in Escherichia coli Induced by l-Arabinose under Hypertonic Conditions with Sodium Chloride

A pseudotropine-forming tropinone reductase was extracted from root cultures of Hyoscyamus niger that produce the tropane alkaloids hyoscyamine and scopolamine. The enzyme stereospecifically reduces tropinone to pseudotropine, oxidizing NADPH. It has an approximate molecular weight of 84,000 and a pH optimum between 5.8 and 6.25. The Km value for tropinone is 35.1 μmol/l and for NADPH 21.1 μmol/l. Substrate specificity was tested for NADPH and several tropinone analogues.     

Calystegines as a new group of tropane alkaloids in Solanaceae

Calystegines are a new group of polyhydroxy alkaloids with a nortropane skeleton. They were detected in Atropa belladonna root cultures by chromatographic methods (TLC, GC) and identified by NMR and mass spectroscopy. Their occurrence was examined in several species of the Solanaceae. The biosynthesis of these compounds is suggested to proceed via the tropane alkaloid pathway, the first metabolite being pseudotropine. A pseudotropine-forming tropinone reductase was isolated and characterized from Atropa belladonna root cultures. Further evidence is given for the significance of tropinone and pseudotropine in calystegine formation by feeding experiments that increased calystegine formation. ¹⁵N-tropinone was shown to be incorporated into calystegines.Abbreviations GC gas chromatography - TBON 8-thiabicyclo[3.2.1]octan-3-one - TLC thin-layer chromatography     

Insight into the molecular evolution of two tropinone reductases

In tropane alkaloid biosynthesis, two tropinone reductases produce different stereoisomers from a common substrate, tropinone. The two enzymes share 64% of identical amino acids, and highly homologous proteins with variable substrate-binding residues have also been found in tropane alkaloid non-producing species. This exemplifies a simple evolutionary process that plants have taken to acquire a new secondary metabolic pathway.     

Two tropinone reductases, that catalyze opposite stereospecific reductions in tropane alkaloid biosynthesis, are localized in plant root with different cell-specific patterns

In the plant species that produce tropane alkaloids, two tropinone reductases (TRs) catalyze the stereospecific reductions of the 3-carbonyl group of tropinone. This reduction is a key branch point that determines the metabolite flow into the separate alkaloid groups, each with different stereospecific configurations. In this study, a specific antibody was prepared for each of the TRs by immunizing mice with recombinant TR protein and subsequent immuno-affinity purification of the antiserum. Immunoblot analyses revealed that accumulation of both TRs was highest in the lateral roots of Hyoscyamus niger throughout its development. In cultured roots, TR proteins were accumulated in a basal region but not in root apex. These patterns were similar to that of hyoscyamine 6 beta-hydroxylase (H6H), an enzyme that catalyzes a downstream step in the same biosynthetic pathway. However, an immunohistochemical analysis revealed that the two TRs and H6H were accumulated with different cell-specific patterns in the cultured root, suggesting transportation of the alkaloid intermediate(s) across the different cell layers.     

Site-directed mutagenesis of putative substrate-binding residues reveals a mechanism controlling the different stereospecificities of two tropinone reductases.

Two tropinone reductases (TRs) constitute a key branch point in the biosynthetic pathway of tropane alkaloids, which are mainly produced in several solanaceous plants. The two TRs share 64% identical amino acid residues and reduce the 3-carbonyl group of a common substrate, tropinone, but they produce distinct alcohol products with different stereospecific configurations. Previous x-ray crystallographic analysis has revealed their highly conserved overall folding, and the modeling of tropinone within the putative substrate-binding sites has suggested that the different stereospecificities may be determined solely by the different binding orientations of tropinone to the enzymes. In this study, we have constructed various mutant TRs, in which putative substrate-binding residues from one TR were substituted with those found in the corresponding positions of the other TR. Substitution of five amino acid residues resulted in an almost complete reversal of stereospecificity, indicating that the different stereospecificities are indeed determined by the binding orientation of tropinone. Detailed kinetic analysis of the mutant enzymes has shown that TR stereospecificity is determined by varying the contributions from electrostatic and hydrophobic interactions and that the present TR structures represent highly evolved forms, in which strict stereospecificities and rapid turnover are accomplished together.     

Incorporation of arginine, ornithine and phenylalanine into tropane alkaloids in suspension-cultured cells and aseptic roots of intact plants oi Atropa belladonna

Label from U-¹⁴C-arginine (Arg), -ornithine (Orn) and -phenylalanine(Phe) was incorporated into hyoscyam-ine and scopolamine byboth dissected roots of intact plants and homogeneous or aggregatingsuspension cultures of Atropa belladonna L. The early biosyntheticcompounds (hygrine, tropinone, tropanol) were found only inthe roots, and alkaloid synthesis proceeded as far as to scopolaminethere. In the synthesis of the tropane skeleton, Orn was usedmore efficiently than Arg. Phe was quickly metabolized bothin roots and suspension cultures, and the label was incorporatedinto both ethanol-insoluble compounds, particularly proteinsand different ethanol-soluble compounds, especially phenolics. When the callus, used to initiate suspension cultures, was repeatedlysubcultured, the degree of organization of the suspension-culturedcells (second suspension passage) grown in the presence of 2.5µM 2-naphthaleneacetic acid (NAA), changed first fromhomogeneous to aggregating and later to heavily rooty. Simultaneouslywith an increasing degree of organization, alkaloid synthesisdecreased. At first, the rate of incorporation of Arg and Phe,and later Orn into alkaloids decreased. In heavily rooty suspensionsneither hyoscyamine nor scopolamine were found, but traces oftropanol were detected. Hence, the synthesis of tropane alkaloidsseems to be regulated at the later biosynthetic steps. Key words: Arginine, Atropa, hyoscyamine, omithine, phenylalanine, roots, scopolamine, suspension culture, tropane alkaloids     

Identification and characterization of retinoid-active short-chain dehydrogenases/reductases in Drosophila melanogaster

Background

In chordates, retinoid metabolism is an important target of short-chain dehydrogenases/reductases (SDRs). It is not known whether SDRs play a role in retinoid metabolism of protostomes, such as Drosophila melanogaster.

Methods

Drosophila genome was searched for genes encoding proteins with ∼ 50% identity to human retinol dehydrogenase 12 (RDH12). The corresponding proteins were expressed in Sf9 cells and biochemically characterized. Their phylogenetic relationships were analyzed using PHYLIP software.

Results

A total of six Drosophila SDR genes were identified. Five of these genes are clustered on chromosome 2 and one is located on chromosome X. The deduced proteins are 300 to 406 amino acids long and are associated with microsomal membranes. They recognize all-trans-retinaldehyde and all-trans-3-hydroxyretinaldehyde as substrates and prefer NADPH as a cofactor. Phylogenetically, Drosophila SDRs belong to the same branch of the SDR superfamily as human RDH12, indicating a common ancestry early in bilaterian evolution, before a protostome–deuterostome split.

Conclusions

Similarities in the substrate and cofactor specificities of Drosophila versus human SDRs suggest conservation of their function in retinoid metabolism throughout protostome and deuterostome phyla.

General significance

The discovery of Drosophila retinaldehyde reductases sheds new light on the conversion of β-carotene and zeaxantine to visual pigment and provides a better understanding of the evolutionary roots of retinoid-active SDRs.     

Seasonal analysis of the tropane alkaloid ecgonine methyl ester and the occurrence of other highly-valued tropanes in the South African <Emphasis Type="Italic">Erythroxylum</Emphasis> trees

The coca family (Erythroxylaceae) consists of trees and shrubs sub-divided into four genera: Aneulophus, Nectaropetalum, Pinacopodium, and Erythroxylum, which include species with highly valuable medicinal compounds. E. delagoense, E. emarginatum, and E. pictum are endemic to southern Africa and have great pharmaceutical potential based on their traditional uses. Previous studies have shown certain inconsistencies in terms of the presence or absence of tropane alkaloids in these species, resulting in a need for further research and clarification. Therefore, the aim of this study was to determine the seasonal variation of the immediate biosynthetic precursor of cocaine, the tropane alkaloid, ecgonine methyl ester in the three South African Erythroxylum species by means of gas chromatography–mass spectrometry, as well as to conduct a phytochemical screening for observing the presence of other potential compounds and tropane alkaloids. We found significant differences in tropane concentrations from the seasonal variation study, explaining the discrepancies in previous reports on its presence/absence in these species. Furthermore, we report for the first time on the occurrence of selected highly valuable tropane alkaloids in E. emarginatum currently used in ‘blockbuster medicine’.