Genes implicados en la respuesta molecular al estrés hídrico en Pinus pinaster Ait

La presente tesis doctoral se centra en el estudio de la respuesta molecular de las coníferas mediterráneas al estrés hídrico. Para ello se ha escogido como especie modelo Pinus pinaster Ait., la conífera más abundante en España, y que habita un amplio rango de situaciones ecológicas, especialmente en lo relativo a la disponibilidad de agua. En primer lugar, se ha aplicado un estrés hídrico controlado en cultivo hidropónico y se ha generando una genoteca sustractiva con objeto de identificar los genes inducidos por el estrés, analizando su expresión en raíces, tallos y acículas. A continuación, se ha analizado, la expresión de los genes anteriormente obtenidos así como de otros seleccionados de las bases de datos disponibles, durante una sequía prolongada en tierra, similar a las que las plantas deben afrontar en la naturaleza. Se ha utilizado en este caso, además de P. pinaster, P. pinea, otra conífera mediterránea adaptada a las sequías recurrentes. Este trabajo ha permitido identificar genes candidato expresionales, presumiblemente comunes en la respuesta molecular de las coníferas al déficit hídrico. Se han detectado diferencias notables en la expresión de determinados genes, que podrían ser los responsables de las diferencias exhibidas por ambas especies en el comportamiento frente a la sequía. Entre los genes identificados como inducidos por el estrés hídrico se encuentran varios miembros de la familia de las deshidrinas. Trabajos previos han utilizado deshidrinas como genes candidato; no obstante, la falta de especificidad de ciertos fragmentos y marcadores utilizados, debido a la complejidad estructural de esta familia, resta fiabilidad a algunos de los resultados publicados. Por este motivo, se ha estudiado en detalle esta familia en P. pinaster, se han identificado y caracterizado 8 miembros y se ha analizado su patrón de expresión frente a sequía. Este estudio ha permitido describir por primera vez unos segmentos conservados en la secuencia de aminoácidos de las deshidrinas de pináceas, cuya presencia y número de repeticiones parece estar relacionado con su especificidad. Por último, se han escogido tres genes implicados en distintas fases de la respuesta al estrés hídrico para su análisis exhaustivo: una deshidrina, una nodulina y un factor de transcripción tipo AP2. Se ha caracterizado su estructura exón/intrón y secuenciado su región promotora. Además, se han obtenido líneas transformadas que sobreexpresan estos genes tanto de forma heteróloga, en la especie modelo Arabidopsis thaliana, como en el propio P. pinaster. Este material facilitará la realización de futuros estudios sobre la función y el mecanismo de actuación de estos genes en la respuesta al estrés hídrico. ABSTRACT This thesis focuses in the study of the molecular response to water stress in Mediterranean conifers. For this purpose, P. pinaster was selected as model species. It’s the most abundant conifer in Spain, living in a wide range of ecological conditions, especially regarding water availability. First, we have applied a controlled polyethylene glycol-induced water stress in hydroponic culture and obtained a suppression subtractive hybridization (SSH) library, with the aim of identifying genes induced by water stress, analysing their expression in roots, stems and needles. We have then analysed the expression patterns of the identified genes, together with other genes selected from public databases. This study was conducted throughout a prolonged drought stress in soil, similar to the ones plants have to face in nature. In this case not only P. pinaster was analysed but also P. pinea, another Mediterranean conifer well adapted to recurrent droughts. This work has enabled us to identify of reliable candidate genes, presumably shared with other conifers in the response to water stress. We observed remarkable differences in the expression of some genes, which could be involved in the differential behaviour that these species show in the water stress response. Within the genes induced by water stress, several members of the dehydrin gene family were identified. Due to the structural complexity of the family, certain ambiguities and inconsistencies have been detected in previous works that have used dehydrins as candidate genes. For this reason, we have analysed thoroughly this gene family in P. pinaster, and have identified and characterized eight different members, whose expression patterns during drought have also been assessed. This study has allowed us to identify for the first time novel conserved segments in the amino acids sequences of Pinaceae. The presence and number of repetitions of these segments could be associated with the functional specificity of these proteins. Finally, three genes involved in different steps of the water stress response were selected for an exhaustive analysis: a dehydrin, a nodulin and an AP2 transcription factor. For all of them, the exon/intron structure was established and their promoter region was sequenced. Also, transformed lines were obtained both in Arabidopsis thaliana and in P. pinaster for the constitutive overexpression of these genes. This material will facilitate the development of further studies to investigate the function of these genes during the water stress response

CO2 capture by absorption into aqueous tertiary amine solution

The aim of this research is to obtain the absorption rate of CO2 into aqueous solution of N,N- di methyl ethanolamine and into aqueous solution of Triethylene diamine and to demonstrate the importance of absorption of CO2 in nowadays by discussing global warming and greenhouse effect. It is also discussed the current situation of China focusing in the latest steps this country has recently made. In the experimental part of this work, the two tertiary amine solutions will absorb CO2 in a Lewis type cell, measuring the pressure change during the reactions take place. The temperature will be between 35 degree and 70 degree Celsius. The results of both solutions, concentrations of 0.5 and 1.0 mol per liter, are discussed and a single value of the rate constant is given for the first time along with some others parameters.

Unidad de deshidratación y unidad DOMGAS. Planta de licuación Gorgon LNG

In this Project, a preliminary design of a dehydration unit for domestic gas will be outlined. This unit that is the subject of the study belongs to a project named Gorgon. Such project is currently been developed by Chevron in Barrow Island, Australia. In order to conduct a proper design of such unit, characteristics of the natural gas that is being extracted shall be detailed, as well as proper specifications of the pipeline to which the gas will supply. After this, different techniques for dehydrating the gas are evaluated; the technique that fits better this Project is absorption by glycol and following such assumption will be chosen as the best one. More accurately, the most suitable type of glycol for this particular unit is triethilene glycol, considering that it fits better the conditions of the project. Once the method is chosen, a simulation shall be undertaken with the purpose of determining the number of stages required for the correct functioning of the unit, the glycol rate and its purity. Besides, it is needed to estimate its pressure and temperature and the dimensions that would then follow. In addition, pressures and temperatures are estimated at the regeneration glycol process, together with dimensions of some units. Furthermore, it is necessary to estimate pressure and temperature at which natural gas is leaving the dehydration unit. In addition, both compression needed to secure the flux at the pipeline and the resulting pressure at the reception shall be studied. Finally, an economic study is carried out in order to conclude whether or not this specific Project is feasible.