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1.
Plant Biotechnol J ; 21(9): 1887-1903, 2023 09.
Article in English | MEDLINE | ID: mdl-37335591

ABSTRACT

Pennycress (Thlaspi arvense L.), a member of the Brassicaceae family, produces seed oil high in erucic acid, suitable for biodiesel and aviation fuel. Although pennycress, a winter annual, could be grown as a dedicated bioenergy crop, an increase in its seed oil content is required to improve its economic competitiveness. The success of crop improvement relies upon finding the right combination of biomarkers and targets, and the best genetic engineering and/or breeding strategies. In this work, we combined biomass composition with metabolomic and transcriptomic studies of developing embryos from 22 pennycress natural variants to identify targets for oil improvement. The selected accession collection presented diverse levels of fatty acids at maturity ranging from 29% to 41%. Pearson correlation analyses, weighted gene co-expression network analysis and biomarker identifications were used as complementary approaches to detect associations between metabolite level or gene expression and oil content at maturity. The results indicated that improving seed oil content can lead to a concomitant increase in the proportion of erucic acid without affecting the weight of embryos. Processes, such as carbon partitioning towards the chloroplast, lipid metabolism, photosynthesis, and a tight control of nitrogen availability, were found to be key for oil improvement in pennycress. Besides identifying specific targets, our results also provide guidance regarding the best timing for their modification, early or middle maturation. Thus, this work lays out promising strategies, specific for pennycress, to accelerate the successful development of lines with increased seed oil content for biofuel applications.


Subject(s)
Brassicaceae , Transcriptome , Transcriptome/genetics , Erucic Acids/metabolism , Plant Breeding , Brassicaceae/genetics , Brassicaceae/metabolism , Plant Oils/metabolism , Seeds/genetics
2.
Plant Biotechnol J ; 20(7): 1327-1345, 2022 07.
Article in English | MEDLINE | ID: mdl-35306726

ABSTRACT

Soybean oil is one of the most consumed vegetable oils worldwide. Genetic improvement of its concentration in seeds has been historically pursued due to its direct association with its market value. Engineering attempts aiming to increase soybean seed oil presented different degrees of success that varied with the genetic design and the specific variety considered. Understanding the embryo's responses to the genetic modifications introduced, is a critical step to successful approaches. In this work, the metabolic and transcriptional responses to AtWRI1 and AtDGAT1 expression in soybean seeds were evaluated. AtWRI1 is a master regulator of fatty acid (FA) biosynthesis, and AtDGAT1 encodes an enzyme catalysing the final and rate-limiting step of triacylglycerides biosynthesis. The events expressing these genes in the embryo did not show an increase in total FA content, but they responded with changes in the oil and carbohydrate composition. Transcriptomic studies revealed a down-regulation of genes putatively encoding for oil body packaging proteins, and a strong induction of genes annotated as lipases and FA biosynthesis inhibitors. Novel putative AtWRI1 targets, presenting an AW-box in the upstream region of the genes, were identified by comparison with an event that harbours only AtWRI1. Lastly, targeted metabolomics analysis showed that carbon from sugar phosphates could be used for FA competing pathways, such as starch and cell wall polysaccharides, contributing to the restriction in oil accumulation. These results allowed the identification of key cellular processes that need to be considered to break the embryo's natural restriction to uncontrolled seed lipid increase.


Subject(s)
Gene Expression Regulation, Plant , Glycine max , Carbohydrate Metabolism/genetics , Embryonic Development , Gene Expression Regulation, Plant/genetics , Plant Oils/metabolism , Plants, Genetically Modified/genetics , Seeds/genetics , Seeds/metabolism , Glycine max/genetics , Glycine max/metabolism , Transcription Factors/genetics
3.
Plant J ; 101(3): 653-665, 2020 02.
Article in English | MEDLINE | ID: mdl-31626366

ABSTRACT

In acidic soils, aluminum (Al) toxicity is a significant limitation to crop production worldwide. Given its Al-binding capacity, malate allows internal as well as external detoxification strategies to cope with Al stress, but little is known about the metabolic processes involved in this response. Here, we analyzed the relevance of NADP-dependent malic enzyme (NADP-ME), which catalyzes the oxidative decarboxylation of malate, in Al tolerance. Plants lacking NADP-ME1 (nadp-me1) display reduced inhibition of root elongation along Al treatment compared with the wild type (wt). Moreover, wt roots exposed to Al show a drastic decrease in NADP-ME1 transcript levels. Although malate levels in seedlings and root exudates are similar in nadp-me1 and wt, a significant increase in intracellular malate is observed in roots of nadp-me1 after long exposure to Al. The nadp-me1 plants also show a lower H2 O2 content in root apices treated with Al and no inhibition of root elongation when exposed to glutamate, an amino acid implicated in Al signaling. Proteomic studies showed several differentially expressed proteins involved in signal transduction, primary metabolism and protection against biotic and other abiotic stimuli and redox processes in nadp-me1, which may participate directly or indirectly in Al tolerance. The results indicate that NADP-ME1 is involved in adjusting the malate levels in the root apex, and its loss results in an increased content of this organic acid. Furthermore, the results suggest that NADP-ME1 affects signaling processes, such as the generation of reactive oxygen species and those that involve glutamate, which could lead to inhibition of root growth.


Subject(s)
Aluminum/toxicity , Arabidopsis Proteins/metabolism , Arabidopsis/enzymology , Malate Dehydrogenase (NADP+)/metabolism , Malates/metabolism , Arabidopsis/genetics , Arabidopsis/physiology , Arabidopsis Proteins/genetics , Loss of Function Mutation , Malate Dehydrogenase (NADP+)/genetics , Plant Roots/enzymology , Plant Roots/genetics , Plant Roots/physiology , Proteomics , Stress, Physiological
4.
Plant Mol Biol ; 107(1-2): 37-48, 2021 Sep.
Article in English | MEDLINE | ID: mdl-34333694

ABSTRACT

KEY MESSAGE: NADP-ME2 from Arabidopsis thaliana exhibits a distinctive and complex regulation by fumarate, acting as an activator or an inhibitor according to substrate and effector concentrations. In this work, we used molecular modeling approach and site-directed mutagenesis to characterized the NADP-ME2 structural determinants necessary for allosteric regulation providing new insights for enzyme optimization. Structure-function studies contribute to deciphering how small modifications in the primary structure could introduce desirable characteristics into enzymes without affecting its overall functioning. Malic enzymes (ME) are ubiquitous and responsible for a wide variety of functions. The availability of a high number of ME crystal structures from different species facilitates comparisons between sequence and structure. Specifically, the structural determinants necessary for fumarate allosteric regulation of ME has been of particular interest. NADP-ME2 from Arabidopsis thaliana exhibits a distinctive and complex regulation by fumarate, acting as an activator or an inhibitor according to substrate and effector concentrations. However, the 3D structure for this enzyme is not yet reported. In this work, we characterized the NADP-ME2 allosteric site by structural modeling, molecular docking, normal mode analysis and mutagenesis. The regulatory site model and its docking analysis suggested that other C4 acids including malate, NADP-ME2 substrate, could also fit into fumarate's pocket. Besides, a non-conserved cluster of hydrophobic residues in the second sphere of the allosteric site was identified. The substitution of one of those residues, L62, by a less flexible residue as tryptophan, resulted in a complete loss of fumarate activation and a reduction of substrate affinities for the active site. In addition, normal mode analysis indicated that conformational changes leading to the activation could originate in the region surrounding L62, extending through the allosteric site till the active site. Finally, the results in this work contribute to the understanding of structural determinants necessary for allosteric regulation providing new insights for enzyme optimization.


Subject(s)
Amino Acids/metabolism , Arabidopsis Proteins/chemistry , Arabidopsis Proteins/metabolism , Arabidopsis/enzymology , Malate Dehydrogenase (NADP+)/chemistry , Malate Dehydrogenase (NADP+)/metabolism , Signal Transduction , Allosteric Site , Fluorescence , Kinetics , Molecular Docking Simulation , Mutant Proteins/metabolism , Mutation/genetics
5.
Plant Mol Biol ; 81(3): 297-307, 2013 Feb.
Article in English | MEDLINE | ID: mdl-23242919

ABSTRACT

Arabidopsis thaliana is a plant species that accumulates high levels of organic acids and uses them as carbon, energy and reducing power sources. Among the enzymes that metabolize these compounds, one of the most important ones is malic enzyme (ME). A. thaliana contains four malic enzymes (NADP-ME 1-4) to catalyze the reversible oxidative decarboxylation of malate in the presence of NADP. NADP-ME2 is the only one located in the cell cytosol of all Arabidopsis organs providing most of the total NADP-ME activity. In the present work, the regulation of this key enzyme by fumarate was investigated by kinetic assays, structural analysis and a site-directed mutagenesis approach. The final effect of this metabolite on NADP-ME2 forward activity not only depends on fumarate and substrate concentrations but also on the pH of the reaction medium. Fumarate produced an increase in NADP-ME2 activity by binding to an allosteric site. However at higher concentrations, fumarate caused a competitive inhibition, excluding the substrate malate from binding to the active site. The characterization of ME2-R115A mutant, which is not activated by fumarate, confirms this hypothesis. In addition, the reverse reaction (reductive carboxylation of pyruvate) is also modulated by fumarate, but in a different way. The results indicate pH-dependence of the fumarate modulation with opposite behavior on the two activities analyzed. Thereby, the coordinated action of fumarate over the direct and reverse reactions would allow a precise and specific modulation of the metabolic flux through this enzyme, leading to the synthesis or degradation of C(4) compounds under certain conditions. Thus, the physiological context might be exerting an accurate control of ME activity in planta, through changes in metabolite and substrate concentrations and cytosolic pH.


Subject(s)
Arabidopsis/enzymology , Carboxylic Acids/metabolism , Fumarates/pharmacology , Malate Dehydrogenase/metabolism , Allosteric Regulation/drug effects , Allosteric Site , Amino Acid Substitution , Arabidopsis/drug effects , Arabidopsis/genetics , Arabidopsis Proteins/drug effects , Arabidopsis Proteins/genetics , Arabidopsis Proteins/metabolism , Cytosol/enzymology , Enzyme Activation/drug effects , Hydrogen-Ion Concentration , Kinetics , Malate Dehydrogenase/drug effects , Malate Dehydrogenase/genetics , Malates/metabolism , Mutagenesis, Site-Directed , NADP/metabolism , Protein Structure, Tertiary , Recombinant Fusion Proteins
6.
FEBS J ; 284(4): 654-665, 2017 02.
Article in English | MEDLINE | ID: mdl-28075062

ABSTRACT

NAD(P)-malic enzyme (NAD(P)-ME) catalyzes the reversible oxidative decarboxylation of malate to pyruvate, CO2 , and NAD(P)H and is present as a multigene family in Arabidopsis thaliana. The carboxylation reaction catalyzed by purified recombinant Arabidopsis NADP-ME proteins is faster than those reported for other animal or plant isoforms. In contrast, no carboxylation activity could be detected in vitro for the NAD-dependent counterparts. In order to further investigate their putative carboxylating role in vivo, Arabidopsis NAD(P)-ME isoforms, as well as the NADP-ME2del2 (with a decreased ability to carboxylate pyruvate) and NADP-ME2R115A (lacking fumarate activation) versions, were functionally expressed in the cytosol of pyruvate carboxylase-negative (Pyc- ) Saccharomyces cerevisiae strains. The heterologous expression of NADP-ME1, NADP-ME2 (and its mutant proteins), and NADP-ME3 restored the growth of Pyc- S. cerevisiae on glucose, and this capacity was dependent on the availability of CO2 . On the other hand, NADP-ME4, NAD-ME1, and NAD-ME2 could not rescue the Pyc- strains from C4 auxotrophy. NADP-ME carboxylation activity could be measured in leaf crude extracts of knockout and overexpressing Arabidopsis lines with modified levels of NADP-ME, where this activity was correlated with the amount of NADP-ME2 transcript. These results indicate that specific A. thaliana NADP-ME isoforms are able to play an anaplerotic role in vivo and provide a basis for the study on the carboxylating activity of NADP-ME, which may contribute to the synthesis of C4 compounds and redox shuttling in plant cells.


Subject(s)
Arabidopsis Proteins/genetics , Arabidopsis/enzymology , Malate Dehydrogenase (NADP+)/genetics , Malates/metabolism , NADP/metabolism , NAD/metabolism , Pyruvic Acid/metabolism , Saccharomyces cerevisiae/enzymology , Arabidopsis/genetics , Arabidopsis Proteins/metabolism , Carbon Dioxide/metabolism , Cloning, Molecular , Gene Expression , Genetic Complementation Test , Genetic Engineering , Glucose/metabolism , Isoenzymes/genetics , Isoenzymes/metabolism , Malate Dehydrogenase (NADP+)/metabolism , Plant Leaves/enzymology , Plant Leaves/genetics , Recombinant Proteins/genetics , Recombinant Proteins/metabolism , Saccharomyces cerevisiae/genetics , Transformation, Genetic , Transgenes
7.
PLoS One ; 11(6): e0158040, 2016.
Article in English | MEDLINE | ID: mdl-27347875

ABSTRACT

Malic enzymes (ME) catalyze the decarboxylation of malate generating pyruvate, CO2 and NADH or NADPH. In some organisms it has been established that ME is involved in lipids biosynthesis supplying carbon skeletons and reducing power. In this work we studied the MEs of soybean and castor, metabolically different oilseeds. The comparison of enzymatic activities, transcript profiles and organic acid contents suggest different metabolic strategies operating in soybean embryo and castor endosperm in order to generate precursors for lipid biosynthesis. In castor, the malate accumulation pattern agrees with a central role of this metabolite in the provision of carbon to plastids, where the biosynthesis of fatty acids occurs. In this regard, the genome of castor possesses a single gene encoding a putative plastidic NADP-ME, whose expression level is high when lipid deposition is active. On the other hand, NAD-ME showed an important contribution to the maturation of soybean embryos, perhaps driving the carbon relocation from mitochondria to plastids to support the fatty acids synthesis in the last stages of seed filling. These findings provide new insights into intermediary metabolism in oilseeds and provide new biotechnological targets to improve oil yields.


Subject(s)
Glycine max/enzymology , Malate Dehydrogenase/metabolism , Plant Proteins/metabolism , Ricinus communis/enzymology , Seeds/enzymology , Carbon/metabolism , Ricinus communis/growth & development , Lipid Metabolism , Plastids/metabolism , Seeds/growth & development , Glycine max/growth & development
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