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Publikation

Jäckel, L.; Schnabel, A.; Stellmach, H.; Klauß, U.; Matschi, S.; Hause, G.; Vogt, T.; The terminal enzymatic step in piperine biosynthesis is co‐localized with the product piperine in specialized cells of black pepper (Piper nigrum L.) Plant J. 111, 731–747, (2022) DOI: 10.1111/tpj.15847

Piperine (1-piperoyl piperidine) is responsible for the pungent perception of dried black pepper (Pipernigrum) fruits and essentially contributes to the aromatic properties of this spice in combination with ablend of terpenoids. The final step in piperine biosynthesis involves piperine synthase (PS), which catalyzesthe reaction of piperoyl CoA and piperidine to the biologically active and pungent amide. Nevertheless, experimental data on the cellular localization of piperine and the complete biosynthetic pathway are missing. Not only co-localization of enzymes and products, but also potential transport of piperamides to thesink organs is a possible alternative. This work, which includes purification of the native enzyme, immunolocalization, laser microdissection, fluorescence microscopy, and electron microscopy combinedwith liquid chromatography electrospray ionization tandem mass spectrometry (LC-ESI-MS/MS), providesexperimental evidence that piperine and PS are co-localized in specialized cells of the black pepper fruit peri-sperm. PS accumulates during early stages of fruit development and its level declines before the fruits arefully mature. The product piperine is co-localized to PS and can be monitored at the cellular level by itsstrong bluish fluorescence. Rising piperine levels during fruit maturation are consistent with the increasingnumbers of fluorescent cells within the perisperm. Signal intensities of individual laser-dissected cells whenmonitored by LC-ESI-MS/MS indicate molar concentrations of this alkaloid. Significant levels of piperineand additional piperamides were also detected in cells distributed in the cortex of black pepper roots. Insummary, the data provide comprehensive experimental evidence of and insights into cell-specific biosyn-thesis and storage of piperidine alkaloids, specific and characteristic for the Piperaceae. By a combination offluorescence microscopy and LC-MS/MS analysis we localized the major piperidine alkaloids to specific cellsof the fruit perisperm and the root cortex. Immunolocalization of native piperine and piperamide synthasesshows that enzymes are co-localized with high concentrations of products in these idioblasts.
Publikation

Schnabel, A.; Cotinguiba, F.; Athmer, B.; Yang, C.; Westermann, B.; Schaks, A.; Porzel, A.; Brandt, W.; Schumacher, F.; Vogt, T.; A piperic acid CoA ligase produces a putative precursor of piperine, the pungent principle from black pepper fruits Plant J. 102, 569-581, (2020) DOI: 10.1111/tpj.14652

Black pepper (Piper nigrum L.) is known for the high content of piperine, a cinnamoyl amide derivative regarded as largely responsible for the pungent taste of this widely used spice. Despite its long history and worldwide use, the biosynthesis of piperine and related amides has been enigmatic up to now. In this report we describe a specific piperic acid CoA ligase from immature green fruits of P. nigrum. The corresponding enzyme was cloned and functionally expressed in E. coli. The recombinant enzyme displays a high specificity for piperic acid and does not accept the structurally related feruperic acid characterized by a similar C‐2 extension of the general C6‐C3 phenylpropanoid structure. The enzyme is also inactive with the standard set of hydroxycinnamic acids tested including caffeic acid, 4‐coumaric acid, ferulic acid, and sinapic acid. Substrate specificity is corroborated by in silico modeling which suggests a perfect fit of the substrate piperic acid to the active site of the piperic acid CoA ligase. The CoA ligase gene shows highest expression levels in immature green fruits, is also expressed in leaves and flowers, but not in roots. Virus‐induced gene silencing provided some preliminary indications that the production of piperoyl‐CoA is required for the biosynthesis of piperine in black pepper fruits.
Publikation

Rohde, B.; Hans, J.; Martens, S.; Baumert, A.; Hunziker, P.; Matern, U.; Anthranilate N-methyltransferase, a branch-point enzyme of acridone biosynthesis Plant J. 53, 541-553, (2008) DOI: 10.1111/j.1365-313X.2007.03360.x

Acridone alkaloids formed by acridone synthase in Ruta graveolens L. are composed of N ‐methylanthraniloyl CoA and malonyl CoAs. A 1095 bp cDNA from elicited Ruta cells was expressed in Escherichia coli , and shown to encode S‐ adenosyl‐l ‐methionine‐dependent anthranilate N ‐methyltransferase. SDS–PAGE of the purified enzyme revealed a mass of 40 ± 2 kDa, corresponding to 40 059 Da for the translated polypeptide, whereas the catalytic activity was assigned to a homodimer. Alignments revealed closest relationships to catechol or caffeate O ‐methyltransferases at 56% and 55% identity (73% similarity), respectively, with little similarity (∼20%) to N ‐methyltransferases for purines, putrescine, glycine, or nicotinic acid substrates. Notably, a single Asn residue replacing Glu that is conserved in caffeate O ‐methyltransferases determines the catalytic efficiency. The recombinant enzyme showed narrow specificity for anthranilate, and did not methylate catechol, salicylate, caffeate, or 3‐ and 4‐aminobenzoate. Moreover, anthraniloyl CoA was not accepted. As Ruta graveolens acridone synthase also does not accept anthraniloyl CoA as a starter substrate, the anthranilate N ‐methylation prior to CoA activation is a key step in acridone alkaloid formation, channelling anthranilate from primary into secondary branch pathways, and holds promise for biotechnological applications. RT‐PCR amplifications and Western blotting revealed expression of the N ‐methyltransferase in all organs of Ruta plants, particularly in the flower and root, mainly associated with vascular tissues. This expression correlated with the pattern reported previously for expression of acridone synthase and acridone alkaloid accumulation.
Publikation

Fellenberg, C.; Milkowski, C.; Hause, B.; Lange, P.-R.; Böttcher, C.; Schmidt, J.; Vogt, T.; Tapetum-specific location of a cation-dependent O-methyltransferase in Arabidopsis thaliana Plant J. 56, 132-145, (2008) DOI: 10.1111/j.1365-313X.2008.03576.x

Cation‐ and S ‐adenosyl‐l ‐methionine (AdoMet)‐dependent plant natural product methyltransferases are referred to as CCoAOMTs because of their preferred substrate, caffeoyl coenzyme A (CCoA). The enzymes are encoded by a small family of genes, some of which with a proven role in lignin monomer biosynthesis. In Arabidopsis thaliana individual members of this gene family are temporally and spatially regulated. The gene At1g67990 is specifically expressed in flower buds, and is not detected in any other organ, such as roots, leaves or stems. Several lines of evidence indicate that the At1g67990 transcript is located in the flower buds, whereas the corresponding CCoAOMT‐like protein, termed AtTSM1, is located exclusively in the tapetum of developing stamen. Flowers of At1g67990 RNAi‐suppressed plants are characterized by a distinct flower chemotype with severely reduced levels of the N  ′,N  ′′‐ bis‐(5‐hydroxyferuloyl)‐N  ′′′‐sinapoylspermidine compensated for by N1 ,N5 ,N10 ‐tris‐(5‐hydroxyferuloyl)spermidine derivative, which is characterized by the lack of a single methyl group in the sinapoyl moiety. This severe change is consistent with the observed product profile of AtTSM1 for aromatic phenylpropanoids. Heterologous expression of the recombinant protein shows the highest activity towards a series of caffeic acid esters, but 5‐hydroxyferuloyl spermidine conjugates are also accepted substrates. The in vitro substrate specificity and the in vivo RNAi‐mediated suppression data of the corresponding gene suggest a role of this cation‐dependent CCoAOMT‐like protein in the stamen/pollen development of A. thaliana .
Publikation

Clauß, K.; Baumert, A.; Nimtz, M.; Milkowski, C.; Strack, D.; Role of a GDSL lipase-like protein as sinapine esterase in Brassicaceae Plant J. 53, 802-813, (2008) DOI: 10.1111/j.1365-313X.2007.03374.x

The seeds of most members of the Brassicaceae accumulate high amounts of sinapine (sinapoylcholine) that is rapidly hydrolyzed during early stages of seed germination. One of three isoforms of sinapine esterase activity (BnSCE3) has been isolated from Brassica napus seedlings and subjected to trypsin digestion and spectrometric sequencing. The peptide sequences were used to isolate BnSCE3 cDNA, which was shown to contain an open reading frame of 1170 bp encoding a protein of 389 amino acids, including a leader peptide of 25 amino acids. Sequence comparison identified the protein as the recently cloned BnLIP2, i.e. a GDSL lipase‐like protein, which displays high sequence identity to a large number of corresponding plant proteins, including four related Arabidopsis lipases. The enzymes belong to the SGNH protein family, which use a catalytic triad of Ser‐Asp‐His, with serine as the nucleophile of the GDSL motif. The corresponding B. napus and Arabidopsis genes were heterologously expressed in Nicotiana benthamiana leaves and proved to confer sinapine esterase activity. In addition to sinapine esterase activity, the native B. napus protein (BnSCE3/BnLIP2) showed broad substrate specificity towards various other choline esters, including phosphatidylcholine. This exceptionally broad substrate specificity, which is common to a large number of other GDSL lipases in plants, hampers their functional analysis. However, the data presented here indicate a role for the GDSL lipase‐like BnSCE3/BnLIP2 as a sinapine esterase in members of the Brassicaceae, catalyzing hydrolysis of sinapine during seed germination, leading, via 1‐O ‐sinapoyl‐β‐glucose, to sinapoyl‐l ‐malate in the seedlings.
Publikation

Ziegler, J.; Voigtländer, S.; Schmidt, J.; Kramell, R.; Miersch, O.; Ammer, C.; Gesell, A.; Kutchan, T. M.; Comparative transcript and alkaloid profiling in Papaver species identifies a short chain dehydrogenase/reductase involved in morphine biosynthesis Plant J. 48, 177-192, (2006) DOI: 10.1111/j.1365-313X.2006.02860.x

Plants of the order Ranunculales, especially members of the species Papaver , accumulate a large variety of benzylisoquinoline alkaloids with about 2500 structures, but only the opium poppy (Papaver somniferum ) and Papaver setigerum are able to produce the analgesic and narcotic morphine and the antitussive codeine. In this study, we investigated the molecular basis for this exceptional biosynthetic capability by comparison of alkaloid profiles with gene expression profiles between 16 different Papaver species. Out of 2000 expressed sequence tags obtained from P. somniferum , 69 show increased expression in morphinan alkaloid‐containing species. One of these cDNAs, exhibiting an expression pattern very similar to previously isolated cDNAs coding for enzymes in benzylisoquinoline biosynthesis, showed the highest amino acid identity to reductases in menthol biosynthesis. After overexpression, the protein encoded by this cDNA reduced the keto group of salutaridine yielding salutaridinol, an intermediate in morphine biosynthesis. The stereoisomer 7‐epi ‐salutaridinol was not formed. Based on its similarities to a previously purified protein from P. somniferum with respect to the high substrate specificity, molecular mass and kinetic data, the recombinant protein was identified as salutaridine reductase (SalR; EC 1.1.1.248). Unlike codeinone reductase, an enzyme acting later in the pathway that catalyses the reduction of a keto group and which belongs to the family of the aldo‐keto reductases, the cDNA identified in this study as SalR belongs to the family of short chain dehydrogenases/reductases and is related to reductases in monoterpene metabolism.
Publikation

Milkowski, C.; Baumert, A.; Schmidt, D.; Nehlin, L.; Strack, D.; Molecular regulation of sinapate ester metabolism in Brassica napus: expression of genes, properties of the encoded proteins and correlation of enzyme activities with metabolite accumulation Plant J. 38, 80-92, (2004) DOI: 10.1111/j.1365-313X.2004.02036.x

Members of the Brassicaceae family accumulate specific sinapate esters, i.e. sinapoylcholine (sinapine), which is considered as a major antinutritive compound in seeds of important crop plants like Brassica napus , and sinapoylmalate, which is implicated in UV‐B tolerance in leaves. We have studied the molecular regulation of the sinapate ester metabolism in B. napus , and we describe expression of genes, some properties of the encoded proteins and profiles of the metabolites and enzyme activities. The cloned cDNAs encoding the key enzymes of sinapine biosynthesis, UDP‐glucose (UDP‐Glc):B. napus sinapate glucosyltransferase (BnSGT1) and sinapoylglucose:B. napus choline sinapoyltransferase (BnSCT), were functionally expressed. BnSGT1 belongs to a subgroup of plant GTs catalysing the formation of 1‐O‐hydroxycinnamoyl‐β‐d ‐glucoses. BnSCT is another member of serine carboxypeptidase‐like (SCPL) family of acyltransferases. The B. napus genome contains at least two SGT and SCT genes, each derived from its progenitors B. oleracea and B. rapa . BnSGT1 and BnSCT activities are subjected to pronounced transcriptional regulation. BnSGT1 transcript level increases throughout early stages of seed development until the early cotyledonary stage, and stays constant in later stages. The highest level of BnSGT1 transcripts is reached in 2‐day‐old seedlings followed by a dramatic decrease. In contrast, expression of BnSCT is restricted to developing seeds. Regulation of gene expression at the transcript level seems to be responsible for changes of BnSGT1 and BnSCT activities during seed and seedling development of B. napus . Together with sinapine esterase (SCE) and sinapoylglucose:malate sinapoyltransferase (SMT), activities of BnSGT1 and BnSCT show a close correlation with the accumulation kinetics of the corresponding metabolites.
Publikation

Hans, J.; Brandt, W.; Vogt, T.; Site-directed mutagenesis and protein 3D-homology modelling suggest a catalytic mechanism for UDP-glucose-dependent betanidin 5-O-glucosyltransferase from Dorotheanthus bellidiformis Plant J. 39, 319-333, (2004) DOI: 10.1111/j.1365-313X.2004.02133.x

In livingstone daisy (Dorotheanthus bellidiformis ), betanidin 5‐O‐glucosyltransferase (UGT73A5) is involved in the regiospecific glucosylation of betanidin and various flavonols. Based on sequence alignments several amino acid candidates which might be essential for catalysis were identified. The selected amino acids of the functionally expressed protein, suggested to be involved in substrate binding and turnover, were substituted via site‐directed mutagenesis. The substitution of two highly conserved amino acids, Glu378, located in the proposed UDP‐glucose binding site, and His22, located close to the N‐terminus, led to the complete loss of enzyme activity. A 3D model of this regiospecific betanidin and flavonoid glucosyltransferase was constructed and the active site modelled. This model was based on the crystallographic structure of a bacterial UDP‐glucose‐dependent glucosyltransferase from Amycolatopsis orientalis used as a template and the generated null mutations. To explain the observed inversion in the configuration of the bound sugar, semiempirical calculations favour an SN‐1 reaction, as one plausible alternative to the generally proposed SN‐2 mechanism discussed for plant natural product glucosyltransferases. The calculated structural data do not only explain the abstraction of a proton from the acceptor betanidin, but further imply that the reaction mechanism might also involve a catalytic triad, with similarities described for the serine protease family.
Publikation

Irmler, S.; Schröder, G.; St-Pierre, B.; Crouch, N. P.; Hotze, M.; Schmidt, J.; Strack, D.; Matern, U.; Schröder, J.; Indole alkaloid biosynthesis in Catharanthus roseus: new enzyme activities and identification of cytochrome P450 CYP72A1 as secologanin synthase Plant J. 24, 797-804, (2000) DOI: 10.1111/j.1365-313X.2000.00922.x

The molecular characterization of CYP72A1 from Catharanthus roseus (Madagascar periwinkle) was described nearly a decade ago, but the enzyme function remained unknown. We now show by in situ hybridization and immunohistochemistry that the expression in immature leaves is epidermis‐specific. It thus follows the pattern previously established for early enzymes in the pathway to indole alkaloids, suggesting that CYP72A1 may be involved in their biosynthesis. The early reactions in that pathway, i.e. from geraniol to strictosidine, contain several candidates for P450 activities. We investigated in this work two reactions, the conversion of 7‐deoxyloganin to loganin (deoxyloganin 7‐hydroxylase, DL7H) and the oxidative ring cleavage converting loganin into secologanin (secologanin synthase, SLS). The action of DL7H has not been demonstrated in vitro previously, and SLS has only recently been identified as P450 activity in one other plant. We show for the first time that both enzyme activities are present in microsomes from C . roseus cell cultures. We then tested whether CYP72A1 expressed in E. coli as a translational fusion with the C . roseus P450 reductase (P450Red) has one or both of these activities. The results show that CYP72A1 converts loganin into secologanin.
Publikation

Vogt, T.; Grimm, R.; Strack, D.; Cloning and expression of a cDNA encoding betanidin 5-O-glucosyltransferase, a betanidin- and flavonoid-specific enzyme with high homology to inducible glucosyltransferases from the Solanaceae Plant J. 19, 509-519, (1999) DOI: 10.1046/j.1365-313X.1999.00540.x

Based on protein sequence data and RT–PCR, a full length cDNA encoding betanidin 5‐O‐glucosyltransferase (5‐GT) was obtained from a cDNA library of Dorotheanthus bellidiformis (Burm.f.) N.E.Br. (Aizoaceae). 5‐GT catalyses the transfer of glucose from UDP‐glucose to the 5‐hydroxyl group of the chromogenic betanidin. Betanidin and its conjugates, referred to as betacyanins, are characteristic fruit and flower pigments in most members of the Caryophyllales, which fail to synthesise anthocyanins. The 5‐GT cDNA displayed homology to previously published glucosyltransferase sequences and exhibited high identity to sequences of several inducible glucosyltransferases of tobacco and tomato (Solanaceae). The open reading frame encodes a polypeptide of 489 amino acids with a calculated molecular mass of 55.24 kDa. The corresponding cDNA was expressed in Escherichia coli . The recombinant protein displayed identical substrate specificity compared to the native enzyme purified from D. bellidiformis cell suspension cultures. In addition to the natural substrate betanidin, ortho‐dihydroxylated flavonols and flavones were glycosylated preferentially at the B‐ring 4′‐hydroxyl group. 5‐GT is the first enzyme of betalain biosynthesis in plants, of which the corresponding cDNA has been cloned and expressed. The results are discussed in relation to molecular evolution of plant glucosyl‐ transferases.
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