Publications - Cell and Metabolic Biology

Increasing the meal and protein quality of winter rapeseed (Brassica napus L.) for food and feed purposes is gaining importance in rapeseed breeding programmes. Rapeseed meal has a high content of phenolic acid esters, mainly sinapate esters, which have been shown to cause a dark colour and a bitter taste in rapeseed meal and derived protein products. The aim of the present study was to analyse the genetic variation for individual and total sinapate ester content, to develop Near Infrared Reflectance Spectroscopic (NIRS) calibrations, and to identify genotypes with a low sinapate ester content after testing in the field. The following sinapate esters were analysed by HPLC: sinapoylcholine (sinapine), sinapoylglucose, and a minor group of ‘other sinapate esters’ which includes free sinapate. A genotypically diverse set of seed samples of winter oilseed rape (old and new cultivars, breeding lines, resynthesized rapeseed) from different years and locations was collected, their NIRS spectra recorded and the samples were further analysed by HPLC. The complete NIRS calibration seed sample set (n = 575) showed a large variation in total sinapate ester content, ranging from 3.2 to 12.7 mg sinapate equivalents per g seeds. The NIRS calibration equations showed high fractions of explained variances in cross validation () ranging from 0.75 (other sinapate esters) to 0.85 (sinapoylglucose). The standard errors of cross validation (SECV) ranged from 0.38 (other sinapate esters) to 0.70 mg/g seed (total sinapate esters). In validation and in independent validations the predicted results were not always acceptable, indicating that the NIRS calibrations need to be extended by analysing samples from new populations. Following replicated field experiments, a doubled haploid line obtained from the old Dutch cultivar Mansholts’ Hamburger Raps, and related DH lines from the cross DH Mansholts’ × Express were confirmed to have a 30–40% lower sinapate ester content compared to check cultivars.

The accumulation of apocarotenoids in arbuscular mycorrhizal (AM) roots suggests a dramatic reorganization of the plastids responsible for the biosynthesis of these compounds. This review describes the cytological and biochemical characterization of this phenomenon. The results presented suggest that plastids are key organelles for the establishment of the symbiotic interface of the AM symbiosis. In addition, a complex interplay of various plant cell components during the different functional phases of this interface is suggested. Arbuscule degradation appears to be of particular interest, as it correlates with the formation of the most extensive plastid structures and with apocarotenoid accumulation.

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Hydroxyproline-rich glycoproteins (HRGPs) are important plant cell wall components involved in plant defense response to pathogen attack. In the present study, a resistant pearl millet (Pennisetum glaucum) cultivar, IP18292, was compared with a susceptible cultivar, 7042S, to investigate the contribution of HRGPs in the successful defense against the phytopathogenic oomycete S. graminicola. Northern hybridization using MeHRGP cDNA, a heterologous probe from cassava, indicated steady accumulation of HRGP transcripts, from 2 h.p.i. onwards with a maximum at 6 h.p.i., in the resistant cultivar. This is followed by HRGPs accumulation at about 8 h.p.i. as revealed by Western-blot analysis. Immunocytochemical localization by tissue printing and confocal immunofluorescence microscopy indicated cell walls of parenchymatic cells and the vascular tissue of coleoptile as sites of HRGP deposition. In vitro studies in the presence of horseradish peroxidase and H2O2 showed cross-linking of pearl millet HRGPs, which occurred parallel to isodityrosine accumulation. Inducible high isodityrosine content was also observed in vivo in the resistant cultivar. Here, H2O2 was found to accumulate as twin burst at 1 and 6 h.p.i., whereas in the susceptible cultivar only an early single peak was detectable. Moreover, the amount of hydroxyproline in HRGPs was about twice as high in the resistant as in the susceptible cultivar. These results suggest that cell wall strengthening in S. graminicola-infected resistant pearl millet is brought about by a combination of polypeptide cross-linking of isodityrosine as well as by the high content of hydroxyproline in HRGPs, and H2O2, in contrast to the susceptible plant.

The involvement of jasmonates in the tuber development has been proved by the presence of many of these compounds in potato stolons, modification of their levels during the transition of the stolon into tuber, and induction of cell expansion upon exogenous jasmonates treatment. However, to date there is only little evidence of the presence of the jasmonic acid-biosynthetic enzymes in stolons or young tubers. As allene oxide cyclase represents the major control point for jasmonic acid biosynthesis, we studied the occurrence of allene oxide cyclase by immunological approaches in the early stages of tuber formation. In developing stolons, allene oxide cyclase as well as lipoxygenase were clearly detectable, but their levels did not change during development. Jasmonic acid treatment for 24 h, however, increased lipoxygenase and allene oxide cyclase protein levels in both developmental stages analyzed. In longitudinal sections of stolons of stages 1 and 2, allene oxide cyclase and lipoxygenase occurred in the apex and along the stolon axis. Allene oxide cyclase was clearly detectable in epidermal, cortical and pith parenchymatic cells, showing the highest levels in vascular tissues surrounding cells. Lipoxygenase was mainly located in the parenchymatic cortex cells. The occurrence of allene oxide cyclase in stolons together with the previous identification of jasmonates from developing stolons reveals that these organs are capable to synthesize and metabolize jasmonates.

The glucosinolate-myrosinase system found in plants of the order Brassicales is one of the best studied plant defense systems. Hydrolysis of the physiologically inert glucosinolates by hydrolytic enzymes called myrosinases, which only occurs upon tissue disruption, leads to the formation of biologically active compounds. The chemical nature of the hydrolysis products depends on the presence or absence of supplementary proteins, such as epithiospecifier proteins (ESPs). ESPs promote the formation of epithionitriles and simple nitriles at the expense of the corresponding isothiocyanates which are formed through spontaneous rearrangement of the aglucone core structure. While isothiocyanates are toxic to a wide range of organisms, including insects, the ecological significance of nitrile formation and thus the role of ESP in plant-insect interactions is unclear. Here, we identified ESP-expressing cells in various organs and several developmental stages of different Arabidopsis thaliana ecotypes by immunolocalization. In the ecotype Landsberg erecta, ESP was found to be consistently present in the epidermal cells of all aerial parts except the anthers and in S-cells of the stem below the inflorescence. Analyses of ESP expression by quantitative real-time PCR, Western blotting, and ESP activity assays suggest that plants control the outcome of glucosinolate hydrolysis by regulation of ESP at both the transcriptional and the post-transcriptional levels. The localization of ESP in the epidermal cell layers of leaves, stems and reproductive organs supports the hypothesis that this protein has a specific function in defense against herbivores and pathogens.

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Conifers produce terpenoid-based oleoresins as constitutive and inducible defenses against herbivores and pathogens. Much information is available about the genes and enzymes of the late steps of oleoresin terpenoid biosynthesis in conifers, but almost nothing is known about the early steps which proceed via the methylerythritol phosphate (MEP) pathway. Here we report the cDNA cloning and functional identification of three Norway spruce (Picea abies) genes encoding 1-deoxy-d-xylulose 5-phosphate synthase (DXS), which catalyzes the first step of the MEP pathway, and their differential expression in the stems of young saplings. Among them are representatives of both types of plant DXS genes. A single type I DXS gene is constitutively expressed in bark tissue and not affected by wounding or fungal application. In contrast, two distinct type II DXS genes, PaDXS2A and PaDXS2B, showed increased transcript abundance after these treatments as did two other genes of the MEP pathway tested, 1-deoxy-d-xylulose 5-phosphate reductoisomerase (DXR) and 4-hydroxyl 3-methylbutenyl diphosphate reductase (HDR). We also measured gene expression in a Norway spruce cell suspension culture system that, like intact trees, accumulates monoterpenes after treatment with methyl jasmonate. These cell cultures were characterized by an up-regulation of monoterpene synthase gene transcripts and enzyme activity after elicitor treatment, as well as induced formation of octadecanoids, including jasmonic acid and 12-oxophytodienoic acid. Among the Type II DXS genes in cell cultures, PaDXS2A was induced by treatment with chitosan, methyl salicylate, and Ceratocystis polonica (a bark beetle-associated, blue-staining fungal pathogen of Norway spruce). However, PaDXS2B was induced by treatment with methyl jasmonate and chitosan, but was not affected by methyl salicylate or C. polonica. Our results suggest distinct functions of the three DXS genes in primary and defensive terpenoid metabolism in Norway spruce.

This study describes a systematic screen for secondary product UDP-glycosyltransferases (UGTs; EC 2.4.1) involved in seed development of oilseed rape (Brassica napus) and was aimed at identifying genes related to UGT84A9 encoding UDP-glucose:sinapate glucosyltransferase (EC 2.4.1.120), a proven target for molecular breeding approaches to reduce the content of anti-nutritive sinapate esters. By RT-PCR with primers recognizing the conserved signature motif of UGTs, 13 distinct ESTs could be generated from seed RNA. Sequence analysis allowed to assign the isolated ESTs to groups B, D, E, and L of the UGT family. In an alternative approach, two open reading frames related to UGT84A9 were cloned from the B. napus genome and designated as UGT84A10 and UGT84A11, respectively. Functional expression of UGT84A10 revealed that the encoded enzyme catalyzes the formation of 1-O-acylglucosides (β-acetal esters) with several hydroxycinnamates whereas, in our hands, the recombinant UGT84A11 did not display this enzymatic activity. Semi-quantitative RT-PCR confirmed that the majority of potential UGTs specified by the isolated ESTs is differentially expressed. A pronounced transcriptional up-regulation during seed development was evident for UGT84A9 and one EST (BnGT3) clustering in group E of UGTs. UGT84A10 was highly induced in flowers and expressed to a moderate level in late seed maturation indicating a possible involvement in seed-specific sinapate ester biosynthesis.

The mutualistic interaction between plants and arbuscular mycorrhizal (AM) fungi is believed to be regulated from the plant side among other signals by the action of phytohormones. Evidences for this are based mainly on application experiments and determination of phytohormone levels in AM roots by comparison to non-mycorrhizal roots. In case of jasmonates, additional proof is given by reverse genetic approaches, which led to first insights into their putative role in the establishment and functioning of the symbiosis. This review summarizes the current data about phytohormone action in AM roots and the role of jasmonates in particular.