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Publikation
Bile acids are important scaffolds in medicinal and supramolecular chemistry. However, the use of seco bile acids, i.e., bile acids with opened rings, as cores or building blocks for the assembly of complex peptide conjugates or macrocycles has remained elusive so far. A biomimetic approach to secocholanes, based on an oxidative ring-expansion/ring-opening sequence, offers efficient access to novel structures with tunable flexibility and functionality. The process preserves selected portions of the original stereochemical and functional information of the steroid, while additional structural elements are incorporated in further (diversity-generating) steps. The potential of these building blocks for peptide and macrocycle chemistry is exemplified by the attachment of relevant α-amino acids and by the production of various complex macrocycles obtained by conventional (e.g., macrolactonization and macrolactamization) and multicomponent (e.g., Ugi four-component) macrocyclizations. This combination of secocholanic skeleton manipulation with, e.g., varied types of macrocyclization protocols, produces high levels of skeletal diversity and complexity. Therefore, this approach may have applicability either for the synthesis of biologically active ligands or as artificial receptors (“hosts”).
Publikation
The putative two‐pore Ca2+ channel TPC1 has been suggested to be involved in responses to abiotic and biotic stresses. We show that AtTPC1 co‐localizes with the K+‐selective channel AtTPK1 in the vacuolar membrane. Loss of AtTPC1 abolished Ca2+‐activated slow vacuolar (SV) currents, which were increased in AtTPC1 ‐over‐expressing Arabidopsis compared to the wild‐type. A Ca2+‐insensitive vacuolar cation channel, as yet uncharacterized, could be resolved in tpc1‐2 knockout plants. The kinetics of ABA‐ and CO2‐induced stomatal closure were similar in wild‐type and tpc1‐2 knockout plants, excluding a role of SV channels in guard‐cell signalling in response to these physiological stimuli. ABA‐, K+‐, and Ca2+‐dependent root growth phenotypes were not changed in tpc1‐2 compared to wild‐type plants. Given the permeability of SV channels to mono‐ and divalent cations, the question arises as to whether TPC1 in vivo represents a pathway for Ca2+ entry into the cytosol. Ca2+ responses as measured in aequorin‐expressing wild‐type, tpc1‐2 knockout and TPC1 ‐over‐expressing plants disprove a contribution of TPC1 to any of the stimulus‐induced Ca2+ signals tested, including abiotic stresses (cold, hyperosmotic, salt and oxidative), elevation in extracellular Ca2+ concentration and biotic factors (elf18, flg22). In good agreement, stimulus‐ and Ca2+‐dependent gene activation was not affected by alterations in TPC1 expression. Together with our finding that the loss of TPC1 did not change the activity of hyperpolarization‐activated Ca2+‐permeable channels in the plasma membrane, we conclude that TPC1, under physiological conditions, functions as a vacuolar cation channel without a major impact on cytosolic Ca2+ homeostasis.
Publikation
Plant immune responses to pathogen attack include the hypersensitive response (HR), a form of programmed cell death occurring at invasion sites. We previously reported on Arabidopsis thaliana MYB30, a transcription factor that acts as a positive regulator of a cell death pathway conditioning the HR. Here, we show by microarray analyses of Arabidopsis plants misexpressing MYB30 that the genes encoding the four enzymes forming the acyl-coA elongase complex are putative MYB30 targets. The acyl-coA elongase complex synthesizes very-long-chain fatty acids (VLCFAs), and the accumulation of extracellular VLCFA-derived metabolites (leaf epidermal wax components) was affected in MYB30 knockout mutant and overexpressing lines. In the same lines, a lipid extraction procedure allowing high recovery of sphingolipids revealed changes in VLCFA contents that were amplified in response to inoculation. Finally, the exacerbated HR phenotype of MYB30-overexpressing lines was altered by the loss of function of the acyl-ACP thioesterase FATB, which causes severe defects in the supply of fatty acids for VLCFA biosynthesis. Based on these findings, we propose a model in which MYB30 modulates HR via VLCFAs by themselves, or VLCFA derivatives, as cell death messengers in plants.
Publikation
Three novel alkaloids (1−3), named pyriferines A−C, were isolated from fruiting bodies of Pseudobaeospora pyrifera. They possess an unusual eight-membered N/O-acetal ring, derived from l-glutamic acid, that is connected to an enolized 1,3-diketo moiety. The structures were determined by spectroscopic methods, and the absolute configuration of the glutamic acid moiety was established using GC-MS after Mosher-type derivatization.
Publikation
Natural variation of plant pathogen resistance is often quantitative. This type of resistance can be genetically dissected in quantitative resistance loci (QRL). To unravel the molecular basis of QRL in potato (Solanum tuberosum), we employed the model plant Arabidopsis thaliana for functional analysis of natural variants of potato allene oxide synthase 2 (StAOS2). StAOS2 is a candidate gene for QRL on potato chromosome XI against the oömycete Phytophthora infestans causing late blight, and the bacterium Erwinia carotovora ssp. atroseptica causing stem black leg and tuber soft rot, both devastating diseases in potato cultivation. StAOS2 encodes a cytochrome P450 enzyme that is essential for biosynthesis of the defense signaling molecule jasmonic acid. Allele non-specific dsRNAi-mediated silencing of StAOS2 in potato drastically reduced jasmonic acid production and compromised quantitative late blight resistance. Five natural StAOS2 alleles were expressed in the null Arabidopsis aos mutant under control of the Arabidopsis AOS promoter and tested for differential complementation phenotypes. The aos mutant phenotypes evaluated were lack of jasmonates, male sterility and susceptibility to Erwinia carotovora ssp. carotovora. StAOS2 alleles that were associated with increased disease resistance in potato complemented all aos mutant phenotypes better than StAOS2 alleles associated with increased susceptibility. First structure models of ‘quantitative resistant’ versus ‘quantitative susceptible’ StAOS2 alleles suggested potential mechanisms for their differential activity. Our results demonstrate how a candidate gene approach in combination with using the homologous Arabidopsis mutant as functional reporter can help to dissect the molecular basis of complex traits in non model crop plants.
Publikation
Ipecac alkaloids produced in the medicinal plant Psychotria ipecacuanha such as emetine and cephaeline possess a monoterpenoid-tetrahydroisoquinoline skeleton, which is formed by condensation of dopamine and secologanin. Deglucosylation of one of the condensed products N-deacetylisoipecoside (1α(S)-epimer) is considered to be a part of the reactions for emetine biosynthesis, whereas its 1β(R)-epimer N-deacetylipecoside is converted to ipecoside in P. ipecacuanha. Here, we isolated a cDNA clone Ipeglu1 encoding Ipecac alkaloid β-d-glucosidase from P. ipecacuanha. The deduced protein showed 54 and 48% identities to raucaffricine β-glucosidase and strictosidine β-glucosidase, respectively. Recombinant IpeGlu1 enzyme preferentially hydrolyzed glucosidic Ipecac alkaloids except for their lactams, but showed poor or no activity toward other substrates, including terpenoid-indole alkaloid glucosides. Liquid chromatography-tandem mass spectrometry analysis of deglucosylated products of N-deacetylisoipecoside revealed spontaneous transitions of the highly reactive aglycons, one of which was supposed to be the intermediate for emetine biosynthesis. IpeGlu1 activity was extremely poor toward 7-O-methyl and 6,7-O,O-dimethyl derivatives. However, 6-O-methyl derivatives were hydrolyzed as efficiently as non-methylated substrates, suggesting the possibility of 6-O-methylation prior to deglucosylation by IpeGlu1. In contrast to the strictosidine β-glucosidase that stereospecifically hydrolyzes 3α(S)-epimer in terpenoid-indole alkaloid biosynthesis, IpeGlu1 lacked stereospecificity for its substrates where 1β(R)-epimers were preferred to 1α(S)-epimers, although ipecoside (1β(R)) is a major alkaloidal glucoside in P. ipecacuanha, suggesting the compartmentalization of IpeGlu1 from ipecoside. These facts have significant implications for distinct physiological roles of 1α(S)- and 1β(R)-epimers and for the involvement of IpeGlu1 in the metabolic fate of both of them.
Publikation
The glandular trichomes (lupulin glands) of hop (Humulus lupulus) synthesize essential oils and terpenophenolic resins, including the bioactive prenylflavonoid xanthohumol. To dissect the biosynthetic processes occurring in lupulin glands, we sequenced 10,581 ESTs from four trichome-derived cDNA libraries. ESTs representing enzymes of terpenoid biosynthesis, including all of the steps of the methyl 4-erythritol phosphate pathway, were abundant in the EST data set, as were ESTs for the known type III polyketide synthases of bitter acid and xanthohumol biosynthesis. The xanthohumol biosynthetic pathway involves a key O-methylation step. Four S-adenosyl-l-methionine–dependent O-methyltransferases (OMTs) with similarity to known flavonoid-methylating enzymes were present in the EST data set. OMT1, which was the most highly expressed OMT based on EST abundance and RT-PCR analysis, performs the final reaction in xanthohumol biosynthesis by methylating desmethylxanthohumol to form xanthohumol. OMT2 accepted a broad range of substrates, including desmethylxanthohumol, but did not form xanthohumol. Mass spectrometry and proton nuclear magnetic resonance analysis showed it methylated xanthohumol to 4-O-methylxanthohumol, which is not known from hop. OMT3 was inactive with all substrates tested. The lupulin gland-specific EST data set expands the genomic resources for H. lupulus and provides further insight into the metabolic specialization of glandular trichomes.
Publikation
In plants, Rop/Rac GTPases have emerged as central regulators of diverse signalling pathways in plant growth and pathogen defence. When active, they interact with a wide range of downstream effectors. Using yeast two‐hybrid screening we have found three previously uncharacterized receptor‐like protein kinases to be Rop GTPase‐interacting molecules: a cysteine‐rich receptor kinase, named NCRK, and two receptor‐like cytosolic kinases from the Arabidopsis RLCK‐VIb family, named RBK1 and RBK2. Uniquely for Rho‐family small GTPases, plant Rop GTPases were found to interact directly with the protein kinase domains. Rop4 bound NCRK preferentially in the GTP‐bound conformation as determined by flow cytometric fluorescence resonance energy transfer measurements in insect cells. The kinase RBK1 did not phosphorylate Rop4 in vitro , suggesting that the protein kinases are targets for Rop signalling. Bimolecular fluorescence complementation assays demonstrated that Rop4 interacted in vivo with NCRK and RBK1 at the plant plasma membrane. In Arabidopsis protoplasts, NCRK was hyperphosphorylated and partially co‐localized with the small GTPase RabF2a in endosomes. Gene expression analysis indicated that the single‐copy NCRK gene was relatively upregulated in vasculature, especially in developing tracheary elements. The seven Arabidopsis RLCK‐VIb genes are ubiquitously expressed in plant development, and highly so in pollen, as in case of RBK2 . We show that the developmental context of RBK1 gene expression is predominantly associated with vasculature and is also locally upregulated in leaves exposed to Phytophthora infestans and Botrytis cinerea pathogens. Our data indicate the existence of cross‐talk between Rop GTPases and specific receptor‐like kinases through direct molecular interaction.
Publikation
In the search for non‐traditional seed oils, physicochemical parameters, fatty acid (FA) and triacylglycerol (TAG) profiles for five Botswana seed oils, obtained by Soxhlet extraction, were determined. GC–MS and 1H‐NMR analyses showed the FA profiles for mkukubuyo, Sterculia africana , and manketti, Ricinodendron rautanenii , seed oils dominated by linoleic and oleic acids, 26.1, 16.7 and 51.9, 24.4%, respectively, with S. africana containing significant amounts of cyclic FAs (19.9%). Mokolwane, Hyphaene petersiana , seed oil was typically lauric; 12:0 and 14:0 acids were 25.9 and 13.4%, respectively. Morama, Tylosema esculentum , seed oil resembled olive oil; 18:1 (47.3%) and 18:2 (23.4%) acids dominated. Moretologa‐kgomo, Ximenia caffra , seed oil had 45.8% of 18:1 FA, plus significant amounts of very long chain FAs: 26:1 (5.8%), 28:1 (13.9%), 30:1 (3.9%), and acetylenic acids, 9a‐18:1 (1.5%) and 9a, 11t‐18:2 (16.0%). TAG classes and regiochemistry were determined with ESI‐FTICR‐MS, and 13C‐NMR spectra, respectively. Morama showed seven major TAG classes with C54:4 and C54:3 dominating; mokolwane had 16 major classes with C32:0, C38:0 and C42:2 dominating; manketti had 11 major classes with C54:7, C54:6 and C54:4 dominating; mkukubuyo had 12 major classes with C52:4, C52:3 and C54:4 dominating; moretologa‐kgomo had 30 major TAG classes with C64:5, C64:3 and C62:3 dominating. Saturated FAs were generally distributed over the sn ‐1(3) position for morama, manketti, and moretologa‐kgomo but at the sn ‐2 position for mokolwane and mkukubuyo. These findings indicate that morama and manketti seed oils can be developed for food uses, whilst moretologa‐kgomo and mkukubuyo seed oils only for nonfood uses.
Publikation
In potato 12‐hydroxyjasmonic acid (12‐OH‐JA) is a tuber‐inducing compound. Here, it is demonstrated that 12‐OH‐JA, as well as its sulfated and glucosylated derivatives, are constituents of various organs of many plant species. All accumulate differentially and usually to much higher concentrations than jasmonic acid (JA).In wounded tomato leaves, 12‐OH‐JA and its sulfated, as well as glucosylated, derivative accumulate after JA, and their diminished accumulation in wounded leaves of the JA‐deficient mutants spr2 and acx1 and also a JA‐deficient 35S::AOCantisense line suggest their JA‐dependent formation.To elucidate how signaling properties of JA/JAME (jasmonic acid methyl ester) are affected by hydroxylation and sulfation, germination and root growth were recorded in the presence of the different jasmonates, indicating that 12‐OH‐JA and 12‐hydroxyjasmonic acid sulfate (12‐HSO4‐JA) were not bioactive. Expression analyses for 29 genes showed that expression of wound‐inducible genes such as those coding for PROTEINASE INHIBITOR2, POLYPHENOL OXIDASE, THREONINE DEAMINASE or ARGINASE was induced by JAME and less induced or even down‐regulated by 12‐OH‐JA and 12‐HSO4‐JA. Almost all genes coding for enzymes in JA biosynthesis were up‐regulated by JAME but down‐regulated by 12‐OH‐JA and 12‐HSO4‐JA.The data suggest that wound‐induced metabolic conversion of JA/JAME into 12‐OH‐JA alters expression pattern of genes including a switch off in JA signaling for a subset of genes.