A Noninvasive Platform for Imaging and Quantifying Oil Storage in Submillimeter Tobacco Seed

Fuchs, Johannes; Neuberger, Thomas; Rolletschek, Hardy; Schiebold, Silke; Nguyen, Thuy H.; Borisjuk, Nikolai; Börner, Andreas; Melkus, Gerd; Jakob, Peter M.; Borisjuk, Ljudmilla

doi:10.1104/pp.112.210062

Cited by 31 publications

(25 citation statements)

References 54 publications

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“…If this transporter is highly abundant and in vivo reversible, the modulation of plastidial PEP levels by PKp can be thought to be propagated across the chloroplast envelope so that the feedback control can take place in the cytosol. Accordingly, the PEP/phosphate translocator has been ascribed an important role in lipid synthesis (Ruuska et al, 2002;Kubis et al, 2004), and its overexpression in tobacco seeds has been demonstrated to promote lipid accumulation (Fuchs et al, 2013).…”

Section: Complexity Of Subcellular Compartmentationmentioning

confidence: 99%

“…Metabolic flux studies with developing seeds have added a quantitative understanding of in vivo pathway usage in oilseeds (O'Grady et al, 2012). To modulate seed oil levels or composition, various attempts have been chosen, mostly relying on introducing specific enzymes (Weselake et al, 2008;Kelly et al, 2013) or metabolite transporters (Fuchs et al, 2013;Kim et al, 2013). A number of seed-specific transcription factors are known to affect oil storage capabilities (Le et al, 2010); their modulated expression as well as the introduction of engineered transcription factors can enable a more global modulation of oilseed metabolism (Century et al, 2008;Gupta et al, 2012;Singh et al, 2013).…”

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confidence: 99%

“…After 10 d of culture, embryos were weighed, freeze dried, and weighed again for the determination of fresh and dry weights. Embryo material was pulverized and used for the quantification of total lipid content (using time-domain NMR as described by Fuchs et al [2013]), fatty acid composition (using gas chromatography as described by Borisjuk et al [2013a]), and total protein content (measured as total nitrogen 3 5.64 using elemental analysis as described by Borisjuk et al [2013a]). This in vitro system has been used in former studies to describe flux distribution and pathway usage in central metabolism, which demonstrated that major aspects of in planta seed metabolism can be mimicked in vitro (Schwender et al, 2003(Schwender et al, , 2004(Schwender et al, , 2006Schwender, 2008).…”

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Quantitative Multilevel Analysis of Central Metabolism in Developing Oilseeds of Oilseed Rape during in Vitro Culture

et al. 2015

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Seeds provide the basis for many food, feed, and fuel products. Continued increases in seed yield, composition, and quality require an improved understanding of how the developing seed converts carbon and nitrogen supplies into storage. Current knowledge of this process is often based on the premise that transcriptional regulation directly translates via enzyme concentration into flux. In an attempt to highlight metabolic control, we explore genotypic differences in carbon partitioning for in vitro cultured developing embryos of oilseed rape (Brassica napus). We determined biomass composition as well as 79 net fluxes, the levels of 77 metabolites, and 26 enzyme activities with specific focus on central metabolism in nine selected germplasm accessions. Overall, we observed a tradeoff between the biomass component fractions of lipid and starch. With increasing lipid content over the spectrum of genotypes, plastidic fatty acid synthesis and glycolytic flux increased concomitantly, while glycolytic intermediates decreased. The lipid/starch tradeoff was not reflected at the proteome level, pointing to the significance of (posttranslational) metabolic control. Enzyme activity/flux and metabolite/flux correlations suggest that plastidic pyruvate kinase exerts flux control and that the lipid/starch tradeoff is most likely mediated by allosteric feedback regulation of phosphofructokinase and ADP-glucose pyrophosphorylase. Quantitative data were also used to calculate in vivo mass action ratios, reaction equilibria, and metabolite turnover times. Compounds like cyclic 39,59-AMP and sucrose-6-phosphate were identified to potentially be involved in so far unknown mechanisms of metabolic control. This study provides a rich source of quantitative data for those studying central metabolism.Seeds develop by absorbing nutrients from their mother plant and using these to synthesize a combination of starch, protein, and lipid. The size and number of seeds that finally develop determine the crop's yield, while their composition determines the end-use quality of the crop. The conversion of nutrients into storage products involves a complex network of metabolic reactions, many of which are subject to transcriptional, translational, and posttranslational regulation. Attempting to engineer seed composition clearly requires a firm understanding of these regulatory networks.The seed's central metabolism differs markedly from those of both a photosynthesizing leaf and a root. In most species, the immature seed is green for a period during its development, so during this phase it is regarded as being photoheterotrophic. A further level of complexity arises as a result of spatial heterogeneity within the seed (Rolletschek et al., 2011; Borisjuk et al.,

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Section: Complexity Of Subcellular Compartmentationmentioning

confidence: 99%

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confidence: 99%

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Quantitative Multilevel Analysis of Central Metabolism in Developing Oilseeds of Oilseed Rape during in Vitro Culture

et al. 2015

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“…However, recent developments in magnetic resonance imaging (MRI; Borisjuk et al, 2012) and mass spectrometry have begun to remove this limitation, thereby allowing for the spatial mapping of storage lipids (Neuberger et al, 2009;Fuchs et al, 2013) and their individual components (Horn et al, 2012). In this article, we designed an array of spatial high-resolution techniques, which allowed us not only to visualize steep gradients in oil deposition within the embryo of oilseed rape but also to define their spatial/ temporal relations to those established for the accumulation of starch and storage proteins, cellular growth, photosynthetic activity, and metabolite pattern.…”

Section: Introductionmentioning

confidence: 99%

Seed Architecture Shapes Embryo Metabolism in Oilseed Rape

et al. 2013

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Constrained to develop within the seed, the plant embryo must adapt its shape and size to fit the space available. Here, we demonstrate how this adjustment shapes metabolism of photosynthetic embryo. Noninvasive NMR-based imaging of the developing oilseed rape (Brassica napus) seed illustrates that, following embryo bending, gradients in lipid concentration became established. These were correlated with the local photosynthetic electron transport rate and the accumulation of storage products. Experimentally induced changes in embryo morphology and/or light supply altered these gradients and were accompanied by alterations in both proteome and metabolome. Tissue-specific metabolic models predicted that the outer cotyledon and hypocotyl/radicle generate the bulk of plastidic reductant/ATP via photosynthesis, while the inner cotyledon, being enclosed by the outer cotyledon, is forced to grow essentially heterotrophically. Under field-relevant highlight conditions, major contribution of the ribulose-1,5-bisphosphate carboxylase/oxygenase-bypass to seed storage metabolism is predicted for the outer cotyledon and the hypocotyl/radicle only. Differences between in vitro-versus in planta-grown embryos suggest that metabolic heterogeneity of embryo is not observable by in vitro approaches. We conclude that in vivo metabolic fluxes are locally regulated and connected to seed architecture, driving the embryo toward an efficient use of available light and space.

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“…Third harmonic generation microscopy (Débarre et al, 2006) and label-free coherent anti-Stokes Raman scattering microscopy (Paar et al, 2012) allow dyeless observation of LDs but require very specific equipment. Magnetic resonance imaging enables topographic analysis of lipid distribution in cereal grains (Neuberger et al, 2008) and in submillimeter-sized seeds like those of tobacco (Nicotiana tabacum; Fuchs et al, 2013). Nevertheless, the use of fluorescent dyes such as Nile Red (Greenspan and Fowler, 1985), BODIPY (Pagano et al, 1991), or LipidTOX (Invitrogen) associated with confocal microscopy is also a powerful way to monitor LDs in living organisms.…”

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Specialization of Oleosins in Oil Body Dynamics during Seed Development in Arabidopsis Seeds

et al. 2014

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Oil bodies (OBs) are seed-specific lipid storage organelles that allow the accumulation of neutral lipids that sustain plantlet development after the onset of germination. OBs are covered with specific proteins embedded in a single layer of phospholipids. Using fluorescent dyes and confocal microscopy, we monitored the dynamics of OBs in living Arabidopsis (Arabidopsis thaliana) embryos at different stages of development. Analyses were carried out with different genotypes: the wild type and three mutants affected in the accumulation of various oleosins (OLE1, OLE2, and OLE4), three major OB proteins. Image acquisition was followed by a detailed statistical analysis of OB size and distribution during seed development in the four dimensions (x, y, z, and t). Our results indicate that OB size increases sharply during seed maturation, in part by OB fusion, and then decreases until the end of the maturation process. In single, double, and triple mutant backgrounds, the size and spatial distribution of OBs are modified, affecting in turn the total lipid content, which suggests that the oleosins studied have specific functions in the dynamics of lipid accumulation.The seed is a complex, specific structure that allows a quiescent plant embryo to cope with unfavorable germinating conditions and also permits dissemination of the species. To achieve these functions, seeds accumulate reserve compounds that will ensure the survival of the embryo and fuel the growth of the plantlet upon germination. Accumulation of lipids occurs in many eukaryotic cells and is a rather common means of storing carbon and energy. Lipid droplets (LDs) can be found in all eukaryotes, such as yeast (Saccharomyces cerevisiae;

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A Noninvasive Platform for Imaging and Quantifying Oil Storage in Submillimeter Tobacco Seed

Cited by 31 publications

References 54 publications

Quantitative Multilevel Analysis of Central Metabolism in Developing Oilseeds of Oilseed Rape during in Vitro Culture

Quantitative Multilevel Analysis of Central Metabolism in Developing Oilseeds of Oilseed Rape during in Vitro Culture

Seed Architecture Shapes Embryo Metabolism in Oilseed Rape

Specialization of Oleosins in Oil Body Dynamics during Seed Development in Arabidopsis Seeds

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