Publicacións en colaboración con investigadores/as de Universidad de Salamanca (23)

2024

  1. Reduced precipitation can induce ecosystem regime shifts in lakes by increasing internal nutrient recycling

    Scientific reports, Vol. 14, Núm. 1, pp. 12408

  2. p63 controls metabolic activation of hepatic stellate cells and fibrosis via an HER2-ACC1 pathway

    Cell Reports Medicine, Vol. 5, Núm. 2

2020

  1. Pectic galactan affects cell wall architecture during secondary cell wall deposition

    Planta, Vol. 251, Núm. 5

2018

  1. Knockout mutants of Arabidopsis thaliana β-galactosidase. Modifications in the cell wall saccharides and enzymatic activities

    Biologia Plantarum, Vol. 62, Núm. 1, pp. 80-88

  2. Overexpression of Cicer arietinum βIII-Gal but not βIV-Gal in arabidopsis causes a reduction of cell wall β-(1,4)-galactan compensated by an increase in homogalacturonan

    Journal of Plant Physiology, Vol. 231, pp. 135-146

  3. Three members of Medicago truncatula ST family (MtST4, MtST5 and MtST6) are specifically induced by hormones involved in biotic interactions

    Plant Physiology and Biochemistry, Vol. 127, pp. 496-505

2014

  1. Coordinated action of β-galactosidases in the cell wall of embryonic axes during chickpea germination and seedling growth

    Plant Biology, Vol. 16, Núm. 2, pp. 404-410

  2. Organ accumulation and subcellular location of Cicer arietinum ST1 protein

    Plant Science, Vol. 224, pp. 44-53

  3. Timing of deglaciation and postglacial environmental dynamics in NW Iberia: The Sanabria Lake record

    Quaternary Science Reviews, Vol. 94, pp. 136-158

2013

  1. βiII-gal is involved in galactan reduction during phloem element differentiation in chickpea stems

    Plant and Cell Physiology, Vol. 54, Núm. 6, pp. 960-970

2011

  1. The βI-galactosidase of Cicer arietinum is located in thickened cell walls such as those of collenchyma, sclerenchyma and vascular tissue

    Plant Biology, Vol. 13, Núm. 5, pp. 777-783

2010

  1. Abscisic acid delays chickpea germination by inhibiting water uptake and down-regulating genes encoding cell wall remodelling proteins

    Plant Growth Regulation, Vol. 61, Núm. 2, pp. 175-183

  2. The immunolocation of XTH1 in embryonic axes during chickpea germination and seedling growth confirms its function in cell elongation and vascular differentiation

    Journal of Experimental Botany, Vol. 61, Núm. 15, pp. 4231-4238

2009

  1. Two cell wall Kunitz trypsin inhibitors in chickpea during seed germination and seedling growth

    Plant Physiology and Biochemistry, Vol. 47, Núm. 3, pp. 181-187

2008

  1. The accumulation of a Kunitz trypsin inhibitor from chickpea (TPI-2) located in cell walls is increased in wounded leaves and elongating epicotyls

    Physiologia Plantarum, Vol. 132, Núm. 3, pp. 306-317

2006

  1. Transcriptional profiling of cell wall protein genes in chickpea embryonic axes during germination and growth

    Plant Physiology and Biochemistry, Vol. 44, Núm. 11-12, pp. 684-692

2004

  1. Cloning and analysis of a cDNA encoding an endo-polygalacturonase expressed during the desiccation period of the silique-valves of turnip-tops (Brassica rapa L. cv. Rapa)

    Journal of Plant Physiology, Vol. 161, Núm. 2, pp. 219-227

  2. The final step of the ethylene biosynthesis pathway in turnip tops (Brassica rapa): Molecular characterization of the 1-aminocyclopropane-1- carboxylate oxidase BrACO1 throughout zygotic embryogenesis and germination of heterogeneous seeds

    Physiologia Plantarum, Vol. 121, Núm. 1, pp. 132-140

2002

  1. Biomonitoring of metal deposition in northern Spain by moss analysis

    Science of The Total Environment, Vol. 300, Núm. 1, pp. 115-127

  2. Cold and salt stress regulates the expression and activity of a chickpea cytosolic Cu/Zn superoxide dismutase

    Plant Science, Vol. 163, Núm. 3, pp. 507-514