Juan Jesús Molina-Rueda scite author profile

BackgroundGlutamine synthetase (GS) plays a central role in plant nitrogen assimilation, a process intimately linked to soil water availability. We previously showed that hybrid poplar (Populus tremula X alba, INRA 717-1B4) expressing ectopically a pine cytosolic glutamine synthetase gene (GS1a) display enhanced tolerance to drought. Preliminary transcriptome profiling revealed that during drought, members of the superoxide dismutase (SOD) family were reciprocally regulated in GS poplar when compared with the wild-type control, in all tissues examined. SOD was the only gene family found to exhibit such patterns.Results In silico analysis of the Populus genome identified 12 SOD genes and two genes encoding copper chaperones for SOD (CCSs). The poplar SODs form three phylogenetic clusters in accordance with their distinct metal co-factor requirements and gene structure. Nearly all poplar SODs and CCSs are present in duplicate derived from whole genome duplication, in sharp contrast to their predominantly single-copy Arabidopsis orthologs. Drought stress triggered plant-wide down-regulation of the plastidic copper SODs (CSDs), with concomitant up-regulation of plastidic iron SODs (FSDs) in GS poplar relative to the wild type; this was confirmed at the activity level. We also found evidence for coordinated down-regulation of other copper proteins, including plastidic CCSs and polyphenol oxidases, in GS poplar under drought conditions.ConclusionsBoth gene duplication and expression divergence have contributed to the expansion and transcriptional diversity of the Populus SOD/CCS families. Coordinated down-regulation of major copper proteins in drought-tolerant GS poplars supports the copper cofactor economy model where copper supply is preferentially allocated for plastocyanins to sustain photosynthesis during drought. Our results also extend previous findings on the compensatory regulation between chloroplastic CSDs and FSDs, and suggest that this copper-mediated mechanism represents a common response to oxidative stress and other genetic manipulations, as in GS poplars, that affect photosynthesis.

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Spatial distribution of cytosolic NADP+-isocitrate dehydrogenase in pine embryos and seedlings

Pascual

Molina-Rueda

Cánovas

et al. 2008

Tree Physiology

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Cytosolic NADP(+)-linked isocitrate dehydrogenase (NADP(+)-IDH) is considered the main enzyme catalyzing the production of 2-oxoglutarate for amino acid biosynthesis in plants. We characterized a full-length cDNA encoding the cytosolic NADP(+)-IDH in the gymnosperm Pinus pinaster Ait. The deduced amino acid sequence exhibited high homology with available sequences in angiosperms. Genomic analysis indicated that only one gene, or two genes with a high degree of homology, encodes the protein in P. pinaster. Cytosolic NADP(+)-IDH is up-regulated during embryo germination concomitantly with glutamine synthetase. Immunohistochemical analysis of germinating seeds and young seedlings showed a broad spatial pattern of NADP(+)-IDH expression. The protein was detected in vascular tissues of germinating embryo and seedling organs, as well as in other cellular types and tissues, including parenchyma and epidermal cells. The spatial pattern of NADP(+)-IDH expression in the embryo and seedling organs did not coincide with the reported spatial patterns for other key enzymes of nitrogen metabolism. Treatment of seedlings with phosphinothricin, an inhibitor of glutamine synthetase (GS), differentially affected GS and NADP-IDH in cotyledons. In response to herbicide treatment, GS was up-regulated in 0.5-cm-long cotyledons, whereas NADP(+)-IDH was up-regulated in 1.5-cm-long cotyledons, suggesting that 2-oxoglutarate is required to overcome the herbicide effect in tissues with a high demand for glutamate. The results indicated that cytosolic NADP(+)-IDH is a housekeeping enzyme that has not undergone functional specialization during evolution. Its spatial pattern in pine tissues suggests that it facilitates metabolism in different ways depending on the characteristics of the particular tissue and cellular type.

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A putative role for γ-aminobutyric acid (GABA) in vascular development in pine seedlings

Molina-Rueda

Pascual²,

Pissarra³

et al. 2014

Planta

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A model for GABA synthesis in stems of pine seedlings is proposed. The localization of GABA in differentiating tracheids suggests a link between GABA production and vascular development. γ-aminobutyric acid (GABA) is a non-proteinogenic amino acid present in both prokaryotic and eukaryotic organisms. GABA plays a fundamental role as a signal molecule in the central nervous system in animals. In plants, GABA has been correlated with cellular elongation, plant development, gene expression regulation, synthesis of ethylene and other hormones, and signaling. Considering the physiological importance of GABA in plants, the lack of works about GABA localization in this kingdom seems surprising. In this work, the immunolocalization of GABA in root and hypocotyl during seedling development and in bent stem showing compression xylem has been studied. In the seedling root, the GABA signal was very high and restricted to the stele supporting previous evidences indicating a potential role for this amino acid in root growth and nutrient transport. In hypocotyl, GABA was localized in vascular tissues, including differentiating xylem, ray parenchyma and epithelial resin duct cells, drawing also a role for GABA in vascular development, communication and defense. During the production of compression wood, a special lignified wood produced when the stem loss its vertical position, a clear GABA signal was found in the new differentiating xylem cells showing a gradient-like pattern with higher signal in less differentiated elements. The results are in accordance with a previous work indicating that glutamate decarboxylase and GABA production are associated to vascular differentiation in pine Molina-Rueda et al. (Planta 232: 1471-1483, 2010). A model for GABA synthesis in vascular differentiation, communication, and defense is proposed in the stem of pine seedlings.

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Transgenic poplar expressing the pine GS1a show alterations in nitrogen homeostasis during drought

Molina-Rueda

Kirby

2015

Plant Physiology and Biochemistry

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