Priorización de áreas de conservación y protección de la biodiversidad vegetal de la Comunidad Valenciana (España).

Priorización de áreas de conservación y protección de la biodiversidad vegetal de la Comunidad Valenciana (España).

Cis-, trans-, transcriptional regulation of the Arabidopsis thaliana gene AtTrxo1 and its response upon germination and to salt

Plants contain several genes encoding thioredoxins (Trxs), small proteins involved in redox regulation of many enzymes in different cell compartments. Among them, mitochondrial Trxo has been described to have a response in plants grown under salinity but there is scarce information about its functional role in abiotic stress or its gene regulation. In this work, the transcriptional regulation of the mitochondrial AtTrxo1 gene has been studied for the first time, by identifying functionally relevant cis- elements in its promoter: two conserved motives were found as positive and one as negative regulators. Using them as baits for the screening of an arrayed yeast library containing Arabidopsis Transcription Factors (TF) ORFs, two TFs were selected that are now being validated at the molecular level. We have also studied the response of T-DNA insertion mutant plants for AtTrxo1 to salt stress. The K.O. AtTrxo1 mutants presented several phenotypic changes including the time required to reach 50% germination under salinity, without affecting the final germination percentage.

The nitrate-afterripening crosstalk is involved in the testa rupture of sisymbryum offinales seed

The loss of seed dormancy can occur by exposing the seed at low moisture storage conditions (afterripening; AR). Since a positive GA:ABA ratio play a key role in the reactivation of germination of non-dormant seeds, it seems obvious that a remarkable effect of AR is the decreasing of both ABA levels and sensitivity, as well as the increment of GA synthesis and sensitivity. ABA levels are regulated by control both of its biosynthesis thorough the 9-cis-epoxycarotenoid dioxygenase (NCED) encoding genes and its catabolism mediated mainly by ABA-8¿-hydroxylases (CYP707A). On the other hand, the last steps of the GA biosynthesis pathway should be involved to control its levels. Namely, GA20ox and GA3ox catalyzing the biosynthesis of active GA and GA2ox which catalyzes the GA inactivation. The presence of nitrate accelerates the sensu stricto germination of non-AR S. officinale seeds. Here, we demonstrate that in AR seeds nitrate also alters the expression pattern of key genes involved in ABA and GA metabolism and signalling (i.e. SoNCED6, SoNCED9, SoCYP707A2, SoABI5, SoGA3ox2, SoGA20ox6, SoGA2ox6 and SoRGL2). These results suggest that the nitrate signalling is also operative during imbibition of AR S. officinale seeds.

Transcription factors of the bzip factors of the BZIP family affecting arabidopsis thaliana germination sensu stricto

During seed germination, the endosperm cell walls (CWs) suffer an important weakening process mainly driven by hydrolytic enzymes, such are endo-?- mannanases (MAN; EC. 3.2.1.78) that catalyze the cleavage of ?1?4 bonds in the mannan-polymers. In Arabidopsis thaliana seeds, endo-?-mannanase activity increases during seed imbibition, decreasing after radicle emergence1. AtMAN7 is the most highly expressed MAN gene in seeds upon germination and their transcripts are restricted to the micropylar endosperm and to the radicle tip just before radicle emergence. Mutants with a T-DNA insertion in this gene (K.O. MAN7) have a slower germination rate than the wild type (t50=34 h versus t50=25 h). To gain insight into the transcriptional regulation of the AtMAN7 gene, a bioinformatic search for conserved non-coding cis-elements (phylogenetic shadowing) within the Brassicaceae orthologous MAN7 gene promoters has been done and these conserved motives have been used as baits to look for their interacting transcription factors (TFs), using as a prey an arrayed yeast library of circa 1,200 TFs from A. thaliana. The basic leucine zipper AtbZIP44, but not its closely related ortholog AtbZIP11, has been thus identified and its regulatory function upon AtMAN7 during seed germination validated by different molecular and physiological techniques, such are RT-qPCR analyses, mRNA Fluorescence in situ Hybridization (FISH) experiments, and by the establishment of the germination kinetics of both over-expression (oex) lines and TDNA insertion mutants in AtbZIP44. The transcriptional combinatorial network through which AtbZIP44 regulates AtMAN7 gene expression during seed germination has been further explored through protein-protein interactions between AtbZIP44 and other bZIP members. In such a way, AtbZIP9 has been identified by yeast two-hybrid experiments and its physiological implication in the control of AtMAN7 expression similarly established.

Biología programable: 18 FAQs sobre biología sintética de un informático

La biología como tecnología que se utiliza para fabricar dispositivos y sistemas biológicos sintéticos.

Caracterización funcional de los genes sgb (suppressors of agb1-2 susceptibility to pathogens): Nuevos reguladores de la respuesta de inmunidad innata de Arabidopsis thaliana

Un porcentaje importante de las pérdidas de la producción agrícola se deben a las enfermedades que causan en los cultivos los hongos necrótrofos y vasculares. Para mejorar la productividad agrícola es necesario tener un conocimiento detallado de las bases genéticas y moleculares que regulan la resistencia de las plantas a este tipo de patógenos. En Arabidopsis thaliana la resistencia frente a patógenos necrótrofos, como el hongo Plectosphaerella cucumerina BMM (PcBMM), es genéticamente compleja y depende de la activación coordinada de distintas rutas de señalización, como las reguladas por las hormonas ácido salicílico (SA), ácido jasmónico (JA), etileno (ET) y ácido abscísico (ABA), así como de la síntesis de compuestos antimicrobianos derivados del Triptófano y de la integridad de la pared celular (Llorente et al., 2005, Hernández-Blanco et al., 2007; Delgado-Cerezo et al., 2012). Uno de los componentes claves en la regulación de la resistencia de las plantas a patógenos (incluidos hongos necrótrofos y biótrofos) es la proteína G heterotrimérica, un complejo proteico formado por tres subunidades (Gα, Gβ y Gγ), que también regula distintos procesos del desarrollo vegetal. En Arabidopsis hay un gen que codifica para la subunidad α (GPA1), otro para la β (AGB1), y tres genes para la subunidad γ (AGG1, AGG2 y AGG3). El complejo GPA1-AGB1-AGG (1-3) se activa y disocia tras la percepción de una señal específica, actuando el dímero AGB1-AGG1/2 como un monómero funcional que regula las respuestas de defensa (Delgado-Cerezo et al., 2012). Estudios transcriptómicos y análisis bioquímicos de la pared celular en los que se comparaban los mutantes agb1-2 y agg1 agg2, y plantas silvestres (Col-0) revelaron que la resistencia mediada por Gβ-Gγ1/2 no es dependiente de rutas de defensa previamente caracterizadas, y sugieren que la proteína G podría modular la composición/estructura (integridad) de la pared celular (Delgado-Cerezo et al., 2012). Recientemente, se ha demostrado que AGB1 es un componente fundamental de la respuesta inmune mediada por Pathogen- Associated Molecular Patterns (PTI), ya que los mutantes agb1-2 son incapaces de activar tras el tratamiento con PAMPs respuestas de inmunidad, como la producción de especies reactivas de oxígeno (ROS; Liu et al., 2013). Dada la importancia de la proteína G heterotrimérica en la regulación de la respuestas de defensa (incluida la PTI) realizamos un escrutinio de mutantes supresores de la susceptibilidad de agb1-2 al hongo necrótrofo, PcBMM, para identificar componentes adicionales de las rutas de señalización reguladas por AGB1. En este escrutinio se aislaron cuatro mutantes sgb (suppressors of agb1-2 susceptibility to pathogens), dos de los cuales, sgb10 y sgb11, se han caracterizado en la presente Tesis Doctoral. El mutante sgb10 es un segundo alelo nulo del gen MKP1 (At3g55270) que codifica la MAP quinasa-fosfatasa 1 (Bartels et al., 2009). Este mutante presenta lesiones espontáneas en plantas adultas y una activación constitutiva de las principales rutas de defensa (SA, JA y ET, y de metabolitos secundarios, como la camalexina), que explicaría su elevada resistencia a PcBMM y Pseudomonas syringae. Estudios epistáticos sugieren que la resistencia mediada por SGB10 no es dependiente, si no complementaria a la regulada por AGB1. El mutante sgb10 es capaz de restablecer en agb1-2 la producción de ROS y otras respuestas PTI (fosforilación de las MAPK6/3/4/11) tras el tratamiento con PAMPs tan diversos como flg22, elf18 y quitina, lo que demuestra el papel relevante de SGB10/MKP1 y de AGB1 en PTI. El mutante sgb11 se caracteriza por presentar un fenotipo similar a los mutantes irregular xylem (e.g. irx1) afectado en pared celular secundaria: irregularidades en las células xilemáticas, reducción en el tamaño de la roseta y altura de planta, y hojas con un mayor contenido de clorofila. La resistencia de sgb11 a PcBMM es independiente de agb1-2, ya que la susceptibilidad del doble mutante sgb11 agb1-2 es intermedia entre la de agb1-2 y sgb11. El mutante sgb11 no revierte la deficiente PTI de agb1-2 tras el tratamiento con flg22, lo que indica que está alterado en una ruta distinta de la regulada por SGB10. sgb11 presenta una sobreactivación de la ruta del ácido abscísico (ABA), lo que podría explicar su resistencia a PcBMM. La mutación sgb11 ha sido cartografiada en el cromosoma III de Arabidopsis entre los marcadores AthFUS6 (81,64cM) y nga6 (86,41cM) en un intervalo de aproximadamente 200 kb, que comprende genes, entre los que no se encuentra ninguno previamente descrito como IRX. El aislamiento y caracterización de SGB11 apoya la relevancia de la proteína G heterotrimérica en la regulación de la interconexión entre integridad de la pared celular e inmunidad. ABSTRACT A significant percentage of agricultural losses are due to diseases caused by necrotrophic and vascular fungi. To enhance crop yields is necessary to have a detailed knowledge of the genetic and molecular bases regulating plant resistance to these pathogens. Arabidopsis thaliana resistance to necrotrophic pathogens, such as Plectosphaerella cucumerina BMM (PcBMM) fungus, is genetically complex and depends on the coordinated activation of various signaling pathways. These include those regulated by salicylic acid (SA), jasmonic acid (JA), ethylene (ET) and abscisic acid (ABA) hormones and the synthesis of tryptophan-derived antimicrobial compounds and cell wall integrity (Llorente et al., 2005, Hernández-Blanco et al., 2007; Delgado-Cerezo et al., 2012). One key component in the regulation of plant resistance to pathogens (including biotrophic and necrotrophic fungi) is the heterotrimeric G-protein. This protein complex is formed by three subunits (Gα, Gβ and Gγ), which also regulates various plant developmental processes. In Arabidopsis only one gene encodes for subunits α (GPA1) and β (AGB1), and three genes for subunit γ (AGG1, AGG2 y AGG3). The complex GPA1- AGB1-AGG(1-3) is activated and dissociates after perception of an specific signal, AGB1- AGG1/2 acts as a functional monomer regulating defense responses (Delgado-Cerezo et al., 2012). Comparative transcriptomic studies and biochemical analyses of the cell wall of agb1-2 and agg1agg2 mutant and wild plants (Col-0), showed that Gβ-Gγ1/2-mediated resistance is not dependent on previously characterized defense pathways. In addition, it suggests that G protein may modulate the composition/structure (integrity) of the plant cell wall (Delgado-Cerezo et al., 2012). Recently, it has been shown that AGB1 is a critical component of the immune response mediated by Pathogen-Associated Molecular Patterns (PTI), as agb1-2 mutants are unable to activate immune responses such as oxygen reactive species (ROS) production after PAMPs treatment (Liu et al., 2013). Considering the importance of the heterotrimeric G protein in regulation of defense responses (including PTI), we performed a screening for suppressors of agb1-2 susceptibility to the necrotrophic fungus PcBMM. This would allow the identification of additional components of the signaling pathways regulated by AGB1. In this search four sgb mutants (suppressors of agb1-2 susceptibility to pathogens) were isolated, two of which, sgb10 and sgb11, have been characterized in this PhD thesis. sgb10 mutant is a second null allele of MKP1 gene (At3g55270), which encodes the MAP kinase-phosphatase 1 (Bartels et al., 2009). This mutant exhibits spontaneous lesions in adult plants and a constitutive activation of the main defense pathways (SA, JA and ET, and secondary metabolites, such as camalexin), which explains its high resistance to Pseudomonas syringae and PcBMM. Epistatic studies suggest that SGB10- mediated resistance is not dependent, but complementary to the regulated by AGB1. The sgb10 mutant is able to restore agb1-2 ROS production and other PTI responses (MAPK6/3/4/11 phosphorylation) upon treatment with PAMPs as diverse as, flg22, elf18 and chitin, demonstrating the relevant role of SGB10/MKP1 and AGB1 in PTI. sgb11 mutant is characterized by showing a similar phenotype to irregular xylem mutants (e.g. irx1), affected in secondary cell wall: irregular xylems cells, rosette size reduction and plant height, and higher chlorophyll content on leaves. The resistance of sgb11 to PcBMM is independent of agb1-2, as susceptibility of the double mutant agb1-2sgb11 is intermediate between agb1-2 and sgb11. The sgb11 mutant does not revert the deficient PTI response in agb1-2 after flg22 treatment, indicating that is altered in a pathway different to the one regulated by SGB10. sgb11 presents an over-activation of the abscisic acid pathway (ABA), which could explain its resistance to PcBMM. The sgb11 mutation has been mapped on chromosome III of Arabidopsis, between AthFUS6 (81.64 cM) and nga6 (86.41 cM) markers, in 200 kb interval, which does not include previously known IRX genes. The isolation and characterization of SGB11 supports the importance of heterotrimeric G protein in the regulation of the interconnection between the cell wall integrity and immunity.

Simbiosis bacteriana y conservación de flora amenazada: el caso del Lupinus mariae-josephae.

Lupinus mariae-josephae H. Pascual es un altramuz endémico de un reducido número de sitios en la Comunidad Valenciana, donde coloniza sustratos de ?terra rossa? sobre afloramientos de lapiaz. Descrito en 2004 a partir de plantas cultivadas, no pudo localizarse en campo hasta 2006, y el hallazgo de sus poblaciones ha estado estrechamente ligado a topónimos relativos a su nombre popular, ?tramús? en valenciano. Se ha demostrado la clara independencia genética, y en consecuencia el valor como ?buen taxon? de esta especie. Hasta ahora se han caracterizado y censado cinco poblaciones silvestres en diferentes localidades, y en todas ellas se observan fuertes fluctuaciones interanuales de sus efectivos, a veces acompañadas de importantes diferencias de vigor de los ejemplares; tres de estas poblaciones están actualmente protegidas mediante sendas microrreservas de flora. Algunos de estos núcleos poblacionales se componen en años concretos de formas poco vigorosas, que a menudo sólo producen 1-2 frutos con 1-2 semillas; por el contrario, las formas más vigorosas pueden producir varias docenas de semillas. La emergencia de plántulas se produce con gran probabilidad tras años de progresiva escarificación de la cubierta de las semillas en el suelo, y probablemente se acelera por procesos de reducción de la cubierta vegetal como los incendios forestales. La germinación experimental ex situ sólo se consigue satisfactoriamente mediante el pretratamiento de escaldado de las semillas.

Vegetal preservation in the “Lo Hueco” fossil site (Cuenca, Spain)

Preservación Vegetal en el yacimiento Lo Hueco (Cuenca, España)

Census, reproductive biology, and germination of Astragalus gines-lopezii (Fabaceae), a narrow and endangered endemic species of SW Spain

Astragalus gines-lopezii Talavera, Podlech, Devesa & F.M.Vázquez (Fabaceae) is a threatened endemic species with a distribution restricted to a very small area in Badajoz Province (Extremadura Region, SW Spain) and only 2 populations are known. This species was catalogued in the ?Endangered? category in the 2008 Red List and the 2010 Threatened Spanish Vascular Flora List. Despite its status as an endangered species, at present very little is known about the distribution, census, and reproductive biology of this species. In this study we have carried out an exhaustive census of A. gines-lopezii , and we have evaluated the production of flowers, fruits, and seeds and the existence or not of intra- and interpopulation variability in seed germination. Results have highlighted the high reproductive capacity of this species on the basis of a high production of flowers, fruits, and seeds. Mechanical scarification of seeds was effective for increasing germination. Thus, initial germination (22%?60%) was increased to 97%?99% when seeds were rubbed with sandpapers. A high intra- and interpopulation variability in seed germination was found in this species. A. gines-lopezii produces seeds with different degrees of physical dormancy, varying this grade among different individuals within a population.

Uncovering cold disruption of the circadian clock in poplar

Dormancy is an adaptive mechanism that allows woody plants to survive at low temperatures during the winter. Disruption of circadian clock genes in winter or under low temperatures, both in long days as in short days, were described in our group few years ago (Ramos et al., 2005). Basic mechanisms of the circadian clock function are similar in herbaceous as well as in woody plants although there are differences in their response to low temperatures (Bieniawska et al., 2008). Woody plants growing in daylight conditions should have a specific transcriptional control above the circadian clock genes, which is responsible of their constitutive transcriptional activation observed under low temperatures conditions. In order to understand this regulatory process, we are analyzing the behavior of a circadian clock gene in poplar. To this aim, we have isolated its promoter region and fused to the luciferase reporter gene. This construct has been transformed into Populus tremula x P. alba 717-1B4 INRA clone. Here we present the characterization of these transgenic lines under different conditions of light and temperature.

Characterization of a glycosylase family gene specifically expressed during winter dormancy in woody plants

Winter dormancy is the strategy used by perennial plants to survive the harsh conditions of winter in temperate and cold regions. This complex mechanism is characterized by cessation of the meristems activity, which is accompanied by the budset, the acquisition of a high tolerance to the cold temperatures and, in the case of deciduous trees, by the senescence and leaf abscission. In long-lived forest species, the length of the dormancy period limits the growing season, affecting wood production and quality. A Suppression Subtractive Hybridization (SSH) enriched in genes overexpressed during the process of winter dormancy in chesnut stems identified a DNA glycosylase gene. In order to study its role in the establishment and maintenance of the winter dormancy, a molecular characterization and seasonal expression were performed. Furthermore, we have obtained poplar transgenic plantlets overexpressing the chesnut gene.