Margarita Rodríguez-Kessler

Proline accumulation in two bean cultivars under salt stress and the effect of polyamines and ornithine

Proline accumulation in two different bean (Phaseolus vulgaris L.) cultivars, one drought-sensitive (Canario 60) and one drought-resistant (Pinto Villa) was investigated. Both tolerated salt concentrations up to 150 mM NaCl, but the sensitive Canario 60 did not survive at 400 mM NaCl. In response to salt stress, both cvs. accumulated proline in all the analyzed tissues, the lowest contents were detected in roots. Pinto Villa accumulated higher proline concentrations than Canario 60 only at 400 mM NaCl. The addition of polyamines or ornithine increased proline content in plant tissues without stress, while they decreased it under salt stress.

Effect of salt stress on the regulation of maize (Zea mays L.) genes involved in polyamine biosynthesis

A cDNA for spermidine synthase (SPDS), which converts putrescine to the higher polyamine spermidine using decarboxylated S-adenosylmethionine as a cofactor, was isolated from Zea mays leaves (Zmspds2A). Comparison of the deduced amino acid sequence revealed a high homology (81.9%) with Oryza sativa SPDS2. RT-PCR analyses showed that Zmspds2A was equally expressed in leaves, stem and roots. In contrast, transcripts of other genes related to polyamine biosynthesis (Zmodc, adc and samdc) showed tissue-specific regulation. The effect of salt stress on the expression of all these genes in maize leaves exposed to NaCl solutions of different concentrations was analysed. Our results showed that only Zmodc and Zmspds2A were up-regulated by salt stress; whereas the other two genes were barely affected by this treatment. In addition to Zmspds2A, a second transcript encoding a maize spermidine synthase (Zmspds2B) that also became up-regulated by salt stress, was identified. Comparison of partial cDNA sequences of transcripts Zmspds2A and Zmspds2B with the corresponding genomic DNA region revealed the existence of alternative splicing mechanism, opening a new aspect in plant polyamine biosynthesis modulation under abiotic stress.

Polyamine metabolism in maize tumors induced by Ustilago maydis

Alterations occurring in polyamine metabolism of maize in tumors formed during the interaction with the biotrophic pathogenic fungus Ustilago maydis were analyzed. During the process, a striking increase in maize polyamine biosynthesis, mainly free and conjugated putrescine occurred in the tumors induced by the fungus, and in the neighbor plant tissues. This increase correlated with an activation mainly of Adc, Samdc1, Zmsamdc2 and Zmsamdc3, but not of Zmodc, Zmspds1 and Zmspds2 genes, and an elevation in arginine decarboxylase activity, confirming a predominant role of this enzyme in the process. Evidences for a possible contribution of spermidine and spermine degradation by polyamine oxidase activity, probably related to cell wall stiffening or lignification during tumor growth, were also obtained. It is suggested that polyamines, mainly putrescine, might play an active role in the pathosystem maize-U. maydis.

The Epl1 and Sm1 proteins from Trichoderma atroviride and Trichoderma virens differentially modulate systemic disease resistance against different life style pathogens in Solanum lycopersicum.

Fungi belonging to the genus Trichoderma, commonly found in soil or colonizing plant roots, exert beneficial effects on plants, including the promotion of growth and the induction of resistance to disease. T. virens and T. atroviride secrete the proteins Sm1 and Epl1, respectively, which elicit local and systemic disease resistance in plants. In this work, we show that these fungi promote growth in tomato (Solanum lycopersicum) plants. T. virens was more effective than T. atroviride in promoting biomass gain, and both fungi were capable of inducing systemic protection in tomato against Alternaria solani, Botrytis cinerea, and Pseudomonas syringae pv. tomato (Pst DC3000). Deletion (KO) of epl1 in T. atroviride resulted in diminished systemic protection against A. solani and B. cinerea, whereas the T. virens sm1 KO strain was less effective in protecting tomato against Pst DC3000 and B. cinerea. Importantly, overexpression (OE) of epl1 and sm1 led to an increase in disease resistance against all tested pathogens. Although the Trichoderma WT strains induced both systemic acquired resistance (SAR)- and induced systemic resistance (ISR)-related genes in tomato, inoculation of plants with OE and KO strains revealed that Epl1 and Sm1 play a minor role in the induction of these genes. However, we found that Epl1 and Sm1 induce the expression of a peroxidase and an α-dioxygenase encoding genes, respectively, which could be important for tomato protection by Trichoderma spp. Altogether, these observations indicate that colonization by beneficial and/or infection by pathogenic microorganisms dictates many of the outcomes in plants, which are more complex than previously thought.

Differential expression of Phaseolus vulgaris genes induced during the interaction with Rhizoctonia solani

Common bean (Phaseolus vulgaris L.) is the most important grain legume for direct human consumption; however, bean production is affected by several diseases such as Rhizoctonia root rot. Few bean cultivars have been identified that effectively resist the attack of this fungus. Herein, we used the P. vulgaris Pv-2094 landrace, which is less susceptible to Rhizoctonia root rot, for the construction of a suppressive subtractive hybridization cDNA library in order to isolate plant defense-related genes. Total RNAs obtained after 8 and 16xa0h from inoculated and non-inoculated roots with R. solani Kühn, were used as the source of the “tester” and the “driver” samples, respectively. A total of 136 unigenes were obtained and classified into 12 functional categories. Six unigenes were selected to analyze for differential expression by qRT-PCR, including a receptor-like kinase (PvRK20-1), an acid phosphatase associated to defense (PA), a pathogenesis related protein (PR1), an ethylene responsive factor (ERF), a polygalacturonase inhibitor protein (PGIP), and an alpha-dioxygenase (α-DOX). These genes were found to be differentially expressed in a time-dependent manner in bean roots during the interaction with R. solani. Data generated from this study will contribute to the understanding of the molecular mechanisms associated with plant defense against root rot in common bean.

Genomic organization of plant aminopropyl transferases

Aminopropyl transferases like spermidine synthase (SPDS; EC 2.5.1.16), spermine synthase and thermospermine synthase (SPMS, tSPMS; EC 2.5.1.22) belong to a class of widely distributed enzymes that use decarboxylated S-adenosylmethionine as an aminopropyl donor and putrescine or spermidine as an amino acceptor to form in that order spermidine, spermine or thermospermine. We describe the analysis of plant genomic sequences encoding SPDS, SPMS, tSPMS and PMT (putrescine N-methyltransferase; EC 2.1.1.53). Genome organization (including exon size, gain and loss, as well as intron number, size, loss, retention, placement and phase, and the presence of transposons) of plant aminopropyl transferase genes were compared between the genomic sequences of SPDS, SPMS and tSPMS from Zea mays, Oryza sativa, Malus x domestica, Populus trichocarpa, Arabidopsis thaliana and Physcomitrella patens. In addition, the genomic organization of plant PMT genes, proposed to be derived from SPDS during the evolution of alkaloid metabolism, is illustrated. Herein, a particular conservation and arrangement of exon and intron sequences between plant SPDS, SPMS and PMT genes that clearly differs with that of ACL5 genes, is shown. The possible acquisition of the plant SPMS exon II and, in particular exon XI in the monocot SPMS genes, is a remarkable feature that allows their differentiation from SPDS genes. In accordance with our in silico analysis, functional complementation experiments of the maize ZmSPMS1 enzyme (previously considered to be SPDS) in yeast demonstrated its spermine synthase activity. Another significant aspect is the conservation of intron sequences among SPDS and PMT paralogs. In addition the existence of microsynteny among some SPDS paralogs, especially in P. trichocarpa and A. thaliana, supports duplication events of plant SPDS genes. Based in our analysis, we hypothesize that SPMS genes appeared with the divergence of vascular plants by a processes of gene duplication and the acquisition of unique exons of as-yet unknown origin.

Nodulin 41, a novel late nodulin of common bean with peptidase activity

BackgroundThe legume-rhizobium symbiosis requires the formation of root nodules, specialized organs where the nitrogen fixation process takes place. Nodule development is accompanied by the induction of specific plant genes, referred to as nodulin genes. Important roles in processes such as morphogenesis and metabolism have been assigned to nodulins during the legume-rhizobium symbiosis.ResultsHere we report the purification and biochemical characterization of a novel nodulin from common bean (Phaseolus vulgaris L.) root nodules. This protein, called nodulin 41 (PvNod41) was purified through affinity chromatography and was partially sequenced. A genomic clone was then isolated via PCR amplification. PvNod41 is an atypical aspartyl peptidase of the A1B subfamily with an optimal hydrolytic activity at pH 4.5. We demonstrate that PvNod41 has limited peptidase activity against casein and is partially inhibited by pepstatin A. A PvNod41-specific antiserum was used to assess the expression pattern of this protein in different plant organs and throughout root nodule development, revealing that PvNod41 is found only in bean root nodules and is confined to uninfected cells.ConclusionsTo date, only a small number of atypical aspartyl peptidases have been characterized in plants. Their particular spatial and temporal expression patterns along with their unique enzymatic properties imply a high degree of functional specialization. Indeed, PvNod41 is closely related to CDR1, an Arabidopsis thaliana extracellular aspartyl protease involved in defense against bacterial pathogens. PvNod41s biochemical properties and specific cell-type localization, in uninfected cells of the common bean root nodule, strongly suggest that this aspartyl peptidase has a key role in plant defense during the symbiotic interaction.

Zmspds2 maize gene: Coding a spermine synthase?

During the last decade, growing evidence has arisen referring the importance of the proper regulation of plant polyamine metabolism in the response to stress conditions. Being the activation of signaling pathways, the stabilization of anionic molecules and prevention of their degradation, as well as the free radical scavenger properties of polyamines some possible mechanisms exerted by these amines. Accumulation of polyamines (putrescine, spermidine and spermine) has been associated to plant tolerance to a wide array of environmental stresses. The synthesis of spermidine and spermine is mediated by aminopropyltransferases (spermidine and spermine synthases) which constitute a class of widely distributed enzymes that use decarboxylated S-adenosylmethionine as an aminopropyl donor, and putrescine or spermidine as an amino acceptor. We recently reported the effect of salt stress on the expression of aminopropyltransferase genes in maize seedlings. Our data revealed a time and NaCl dependent regulation of the Zmspds2 and Zmspds1 genes, possibly mediated by abscisic acid, since these genes were regulated at the transcriptional level by this plant hormone. In this addendum, we show that the Zmspds2 gene initially classified as spermidine synthase might encode a spermine synthase based on an in silico analysis. This is discussed in terms of protein homologies and specific amino acid substitutions between aminopropyltransferase enzymes.

Ustilago maydis induced accumulation of putrescine in maize leaves.

Polyamines are implicated in the regulation of many processes in the plant cell, including functioning of ion channels, DNA replication, gene transcription, mRNA translation, cell proliferation and programmed cell death. Plant polyamines occur either in free form, covalently bound to proteins, or conjugated to hydroxycinnamic acids forming phenol amides. Ustilago maydis is a dimorphic and biotrophic pathogenic fungus responsible for common smut or ‘‘huitlacoche’’ in maize; and it is considered an excellent model for the study of plant-pathogen interactions. Recently, we reported alterations in polyamine metabolism of maize tumors induced on leaf blades by Ustilago maydis infection. Our data revealed a striking increase in maize polyamine biosynthesis, mainly free and conjugated putrescine in the tumors and in the green plant tissue surrounding the tumor. In this addendum, we describe that changes in PA metabolism take place even in earlier stages of maize plant infection with Ustilago maydis.

Cloning and sequence analysis of ornithine decarboxylase gene fragments from the Ascomycota

Ornithine decarboxylase (ODC; EC 4.1.1.17) catalyzes the initial step in the biosynthesis of polyamines, the conversion of ornithine to putrescine. Based on the most conserved regions of fungal ODCs, we designed and synthesized oligonucleotides to amplify homologous fragments of three important plant pathogenic Pyrenomycete fungi (Ascomycota), Magnaporthe grisea, Colletotrichum lindemuthianum and Fusarium solani, and one insect pathogenic fungus Metarhizium anisopliae. Cloning and sequencing of the amplified fragments revealed homologies of between 37 to 88% with other fungal ODCs. The predicted peptide sequences were compared by Clustal analysis and conserved sequences corresponding to the substrate and cofactor binding sites were identified. Comparative analyses of the ODC fragments isolated in this study, revealed high homology between them (68.3–81.1%) and also with other Pyrenomycetes such as Neurospora crassa (order Sordariales; 68.6–72.9%) and Fusarium graminearum (order Hypocreales; 70.8–88.1%). Data obtained in this work revealed that these fungi constitute a compact group separated from other eukaryotic ODCs.