Growth rate and TRI5 gene expression profiles of Fusarium equiseti strains isolated from Spanish cereals cultivated on wheat and barley media at different environmental conditions

Fusarium equiseti is a toxigenic species that often contaminates ce real crops from diverse climatic regions such as Northern and Southern Europe. Previous results suggested the existence of two distinct populations within this species with differences in toxin pro file which largely corresponded to North and South Europe (Spain). In this work, growth rate profiles of 4 F. equiseti strains isolated from different cereals and distinct Spanish regions were determined on wheat and barley based media at a range of temperatures (15, 20, 25, 30, 35 and 40 °C) and water potentialregimens(−0.7,−2.8,−7.0,and −9.8MPa,correspondingto 0.99,0.98,0.95 and 0.93aw values).Growth was observed at all temperatures except at 40 °C, and at all the solute potential values except at−9.8 MPa when combined with 15 °C. Optimal growth was observed at 20– 30 °C and −0.7/−2.8 MPa. The effect of these factors on trichothecene biosynthesis was examined on a F. equiseti strain using a newly developed real time RT-PCR protocol to quantify TRI5 gene expression at 15, 25 and 35 °C and −0.7, −2.8, − 7.0 and −9.8 MPa on wheat and barley based media. Induction of TRI5 expression was detected between 25 and 35 °C and −0.7 and − 2.8 MPa, with maximum values at 35 °C and −2.8 MPa being higher in barley than in wheat medium. These results appeared to be consistent with a population well adapted to the present climatic conditions and predicted scenarios for Southern Europe and suggested some differences depending on the cereal considered. These are also discussed in relation to other Fusarium species co-occurring in cereals grown in this region and to their significance for prediction and control strategies of toxigenic risk in future scenarios of climate change for this region.

The family of DOF transcription factors in Brachypodium distachyon: phylogenetic comparison with rice and barley DOFs and expression profiling

ABSTRACT: Transcription factors (TFs) are proteins that have played a central role both in evolution and in domestication, and are major regulators of development in living organisms. Plant genome sequences reveal that approximately 7% of all genes encode putative TFs. The DOF (DNA binding with One Finger) TF family has been associated with vital processes exclusive to higher plants and to their close ancestors (algae, mosses and ferns). These are seed maturation and germination, light-mediated regulation, phytohormone and plant responses to biotic and abiotic stresses, etc. In Hordeum vulgare and Oryza sativa, 26 and 30 different Dof genes, respectively, have been annotated. Brachypodium distachyon has been the first Pooideae grass to be sequenced and, due to its genomic, morphological and physiological characteristics, has emerged as the model system for temperate cereals, such as wheat and barley. RESULTS: Through searches in the B. distachyon genome, 27 Dof genes have been identified and a phylogenetic comparison with the Oryza sativa and the Hordeum vulgare DOFs has been performed. To explore the evolutionary relationship among these DOF proteins, a combined phylogenetic tree has been constructed with the Brachypodium DOFs and those from rice and barley. This phylogenetic analysis has classified the DOF proteins into four Major Cluster of Orthologous Groups (MCOGs). Using RT-qPCR analysis the expression profiles of the annotated BdDof genes across four organs (leaves, roots, spikes and seeds) has been investigated. These results have led to a classification of the BdDof genes into two groups, according to their expression levels. The genes highly or preferentially expressed in seeds have been subjected to a more detailed expression analysis (maturation, dry stage and germination). CONCLUSIONS: Comparison of the expression profiles of the Brachypodium Dof genes with the published functions of closely related DOF sequences from the cereal species considered here, deduced from the phylogenetic analysis, indicates that although the expression profile has been conserved in many of the putative orthologs, in some cases duplication followed by subsequent divergence may have occurred (neo-functionalization).

Ensemble transcript interaction networks: A case study on Alzheimer's disease

Systems biology techniques are a topic of recent interest within the neurological field. Computational intelligence (CI) addresses this holistic perspective by means of consensus or ensemble techniques ultimately capable of uncovering new and relevant findings. In this paper, we propose the application of a CI approach based on ensemble Bayesian network classifiers and multivariate feature subset selection to induce probabilistic dependences that could match or unveil biological relationships. The research focuses on the analysis of high-throughput Alzheimer's disease (AD) transcript profiling. The analysis is conducted from two perspectives. First, we compare the expression profiles of hippocampus subregion entorhinal cortex (EC) samples of AD patients and controls. Second, we use the ensemble approach to study four types of samples: EC and dentate gyrus (DG) samples from both patients and controls. Results disclose transcript interaction networks with remarkable structures and genes not directly related to AD by previous studies. The ensemble is able to identify a variety of transcripts that play key roles in other neurological pathologies. Classical statistical assessment by means of non-parametric tests confirms the relevance of the majority of the transcripts. The ensemble approach pinpoints key metabolic mechanisms that could lead to new findings in the pathogenesis and development of AD

Genomic analyses of flowering transition and inflorescence development in grapevine = Análisis genómicos de la transición floral y del desarrollo de la inflorescencia en la vid

The general objective of this work is to analyze the regulatory processes underlying flowering transition and inflorescence and flower development in grapevine. Most of these crucial developmental events take place within buds growing during two seasons in two consecutive years. During the first season, the shoot apical meristem within the bud differentiates all the basic elements of the shoot including flowering transition in lateral primordia and development of inflorescence primordia. These events practically end with bud dormancy. The second season, buds resume shoot growth associated to flower formation and development. In grapevine, the lateral meristems can give rise either to tendril or inflorescence primordia that are homologous organs. With this purpose, we performed global transcriptome analyses along the bud annual cycle and during inflorescence and tendril development. In addition, we approach the genomic analysis of the MIKC type MADS-box gene family in grapevine to identify all its members and assign them putative biological functions. Regarding buds developmental cycle, the results indicate that the main factors explaining the global gene expression differences were the processes of bud dormancy and active growth as well as stress responses. Non dormant buds exhibited up-regulation in functional categories typical of actively proliferating and growing cells (photosynthesis, cell cycle regulation, chromatin assembly) whereas in dormant ones the main functional categories up-regulated were associated to stress response pathways together with transcripts related to starch catabolism. Major transcriptional changes during the dormancy period were associated to the para/endodormancy, endo/ecodormancy and ecodormancy/bud break transitions. Global transcriptional analyses along tendril and inflorescence development suggested that these two homologous organs share a common transcriptional program related to cell proliferation functions. Both structures showed a progressive decrease in the expression of categories such as cell-cycle, auxin metabolism/signaling, DNA metabolism, chromatin assembly and a cluster of five transcripts belonging to the GROWTH-REGULATING FACTOR (GRF) transcription factor family, that are known to control cell proliferation in other species and determine the size of lateral organs. However, they also showed organ specific transcriptional programs that can be related to their differential organ structure and function. Tendrils showed higher transcription of genes related to photosynthesis, hormone signaling and secondary metabolism than inflorescences, while inflorescences have higher transcriptional activity for genes encoding transcription factors (especially those belonging to the MADS-box gene family). Further analysis along inflorescence development evidenced the relevance of additional functions likely related to processes of flower development such as fatty acid and lipid metabolism, jasmonate signaling and oxylipin biosynthesis. The transcriptional analyses performed highlighted the relevance of several groups of transcriptional regulators in the developmental processes studied. The expression profiles along bud development revealed significant differences for some MADS-box subfamilies in relation to other plant species, like the members of the FLC and SVP subfamilies suggesting new roles for these groups in grapevine. In this way, it was found that VvFLC2 and VvAGL15.1 could participate, together with some members of the SPL-L family, in dormancy regulation, as was shown for some of them in other woody plants. Similarly, the expression patterns of the VvFLC1, VvFUL, VvSOC1.1 (together with VvFT, VvMFT1 and VFL) genes could indicate that they play a role in flowering transition in grapevine, in parallel to their roles in other plant systems. The expression levels of VFL, the grapevine LEAFY homolog, could be crucial to specify the development of inflorescence and flower meristems instead of tendril meristems. MADS-box genes VvAP3.1 and 2, VvPI, VvAG1 and 3, VvSEP1-4, as well as VvBS1 and 2 are likely associated with the events of flower meristems and flower organs differentiation, while VvAP1 and VvFUL-L (together with VvSOC1.1, VvAGL6.2) could be involved on tendril development given their expression patterns. In addition, the biological function ofVvAP1 and VvTFL1A was analyzed using a gene silencing approach in transgenic grapevine plants. Our preliminary results suggested a possible role for both genes in the initiation and differentiation of tendrils. Finally, the genomic analysis of the MADS-box gene family in grapevine revealed differential features regarding number and expression pattern of genes putatively involved in the flowering transition process as compared to those involved in the specification of flower and fruit organ identity. Altogether, the results obtained allow identifying putative candidate genes and pathways regulating grapevine reproductive developmental processes paving the way to future experiments demonstrating specific gene biological functions. RESUMEN El objetivo general de este trabajo es analizar los procesos regulatorios subyacentes a la inducción floral así como al desarrollo de la inflorescencia y la flor en la vid. La mayor parte de estos eventos cruciales tienen lugar en las yemas a lo largo de dos estaciones de crecimiento consecutivas. Durante la primera estación, el meristemo apical contenido en la yema diferencia los elementos básicos del pámpano, lo cual incluye la inducción de la floración en los meristemos laterales y el subsiguiente desarrollo de primordios de inflorescencia. Estos procesos prácticamente cesan con la entrada en dormición de la yema. En la segunda estación, se reanuda el crecimiento del pámpano acompañado por la formación y desarrollo de las flores. En la vid, los meristemos laterales pueden dar lugar a primordios de inflorescencia o de zarcillo que son considerados órganos homólogos. Con este objetivo llevamos a cabo un estudio a nivel del transcriptoma de la yema a lo largo de su ciclo anual, así como a lo largo del desarrollo de la inflorescencia y del zarcillo. Además realizamos un análisis genómico de la familia MADS de factores transcripcionales (concretamente aquellos del tipo MIKC) para identificar todos sus miembros y tratar de asignarles posibles funciones biológicas. En cuanto al ciclo de desarrollo de la yema, los resultados indican que los principales factores que explican las diferencias globales en la expresión génica fueron los procesos de dormición de la yema y el crecimiento activo junto con las respuestas a diversos tipos de estrés. Las yemas no durmientes mostraron un incremento en la expresión de genes contenidos en categorías funcionales típicas de células en proliferación y crecimiento activo (como fotosíntesis, regulación del ciclo celular, ensamblaje de cromatina), mientras que en las yemas durmientes, las principales categorías funcionales activadas estaban asociadas a respuestas a estrés, así como con el catabolismo de almidón. Los mayores cambios observados a nivel de transcriptoma en la yema coincidieron con las transiciones de para/endodormición, endo/ecodormición y ecodormición/brotación. Los análisis transcripcionales globales a lo largo del desarrollo del zarcillo y de la inflorescencia sugirieron que estos dos órganos homólogos comparten un programa transcripcional común, relacionado con funciones de proliferación celular. Ambas estructuras mostraron un descenso progresivo en la expresión de genes pertenecientes a categorías funcionales como regulación del ciclo celular, metabolismo/señalización por auxinas, metabolismo de ADN, ensamblaje de cromatina y un grupo de cinco tránscritos pertenecientes a la familia de factores transcripcionales GROWTH-REGULATING FACTOR (GRF), que han sido asociados con el control de la proliferación celular y en determinar el tamaño de los órganos laterales en otras especies. Sin embargo, también pusieron de manifiesto programas transcripcionales que podrían estar relacionados con la diferente estructura y función de dichos órganos. Los zarcillos mostraron mayor actividad transcripcional de genes relacionados con fotosíntesis, señalización hormonal y metabolismo secundario que las inflorescencias, mientras que éstas presentaron mayor actividad transcripcional de genes codificantes de factores de transcripción (especialmente los pertenecientes a la familia MADS-box). Análisis adicionales a lo largo del desarrollo de la inflorescencia evidenciaron la relevancia de otras funciones posiblemente relacionadas con el desarrollo floral, como el metabolismo de lípidos y ácidos grasos, la señalización mediada por jasmonato y la biosíntesis de oxilipinas. Los análisis transcripcionales llevados a cabo pusieron de manifiesto la relevancia de varios grupos de factores transcripcionales en los procesos estudiados. Los perfiles de expresión estudiados a lo largo del desarrollo de la yema mostraron diferencias significativas en algunas de las subfamilias de genes MADS con respecto a otras especies vegetales, como las observadas en los miembros de las subfamilias FLC y SVP, lo cual sugiere que podrían desempeñar nuevas funciones en la vid. En este sentido, se encontró que los genes VvFLC2 y VvAGL15.1 podrían participar, junto con algunos miembros de la familia SPL-L, en la regulación de la dormición. De un modo similar, los patrones de expresión de los genes VvFLC1, VvFUL, VvSOC1.1 (junto con VvFT, VvMFT1 y VFL) podría indicar que desempeñan un papel en la regulación de la inducción de la floración en la vid, como se ha observado en otros sistemas vegetales. Los niveles de expresión de VFL, el homólogo en vid del gen LEAFY de A. thaliana podrían ser cruciales para la especificación del desarrollo de meristemos de inflorescencia y flor en lugar de meristemos de zarcillo. Los genes VvAP3.1 y 2, VvPI, VvAG1 y 3, VvSEP1-4, así como VvBS1 y 2 parecen estar asociados con los eventos de diferenciación de meristemos y órganos florales, mientras que VvAP1 y VvFUL-L (junto con VvSOC1.1 y VvAGL6.2) podrían estar implicados en el desarrollo del zarcillo dados sus patrones de expresión. Adicionalmente, se analizó la función biológica de los genes VvAP1 y VvTFL1A por medio de una estrategia de silenciamiento génico. Los datos preliminares sugieren un posible papel para ambos genes en la iniciación y diferenciación de los zarcillos. Finalmente, el análisis genómico de la familia MADS en vid evidenció diferencias con respecto a otras especies vegetales en cuanto a número de miembros y patrón de expresión en genes supuestamente implicados en la inducción de la floración, en comparación con aquellos relacionados con la especificación de identidad de órganos florales y desarrollo del fruto. En conjunto, los resultados obtenidos han permitido identificar posibles rutas y genes candidatos a participar en la regulación de los procesos de desarrollo reproductivo de la vid, sentando las bases de futuros experimentos encaminados a conocer la funciones biológicas de genes específicos.

Caracterización de la necrosis sistémica inducida por la interacción sinérgica entre el Virus X de la patata y potyvirus en Nicotiana benthamiana

Los virus de plantas pueden causar enfermedades severas que conllevan serias pérdidas económicas a nivel mundial. Además, en la naturaleza son comunes las infecciones simultáneas con distintos virus que conducen a la exacerbación de los síntomas de enfermedad, fenómeno al que se conoce como sinergismo viral. Una de las sintomatologías más severas causadas por los virus en plantas susceptibles es la necrosis sistémica (NS), que incluso puede conducir a la muerte del huésped. Este fenotipo ha sido comparado en ocasiones con la respuesta de resistencia de tipo HR, permitiendo establecer una serie de paralelismos entre ambos tipos de respuesta que sugieren que la NS producida en interacciones compatibles sería el resultado de una respuesta hipersensible sistémica (SHR). Sin embargo, los mecanismos moleculares implicados en el desarrollo de la NS, su relación con procesos de defensa antiviral o su relevancia biológica aún no son bien entendidos, al igual que tampoco han sido estudiados los cambios producidos en la planta a escala genómica en infecciones múltiples que muestran sinergismo en patología. En esta tesis doctoral se han empleado distintas aproximaciones de análisis de expresión génica, junto con otras técnicas genéticas y bioquímicas, en el sistema modelo de Nicotiana benthamiana para estudiar la NS producida por la infección sinérgica entre el Virus X de la patata (PVX) y diversos potyvirus. Se han comparado los cambios producidos en el huésped a nivel genómico y fisiológico entre la infección doble con PVX y el Virus Y de la patata (PVY), y las infecciones simples con PVX o PVY. Además, los cambios transcriptómicos y hormonales asociados a la infección con la quimera viral PVX/HC‐Pro, que reproduce los síntomas del sinergismo entre PVX‐potyvirus, se han comparado con aquellos producidos por otros dos tipos de muerte celular, la PCD ligada a una interacción incompatible y la PCD producida por la disfunción del proteasoma. Por último, técnicas de genética reversa han permitido conocer la implicación de factores del huésped, como las oxilipinas, en el desarrollo de la NS asociada al sinergismo entre PVXpotyvirus. Los resultados revelan que, respecto a las infecciones con solo uno de los virus, la infección doble con PVX‐PVY produce en el huésped diferencias cualitativas además de cuantitativas en el perfil transcriptómico relacionado con el metabolismo primario. Otros cambios en la expresión génica, que reflejan la activación de mecanismos de defensa, correlacionan con un fuerte estrés oxidativo en las plantas doblemente infectadas que no se detecta en las infecciones simples. Además, medidas en la acumulación de determinados miRNAs implicados en diversos procesos celulares muestran como la infección doble altera de manera diferencial tanto la acumulación de estos miRNAs como su funcionalidad, lo cual podría estar relacionado con los cambios en el transcriptoma, así como con la sintomatología de la infección. La comparación a nivel transcriptómico y hormonal entre la NS producida por PVX/HC‐Pro y la interacción incompatible del Virus del mosaico del tabaco en plantas que expresan el gen N de resistencia (SHR), muestra que la respuesta en la interacción compatible es similar a la que se produce durante la SHR, si bien se presenta de manera retardada en el tiempo. Sin embargo, los perfiles de expresión de genes de defensa y de respuesta a hormonas, así como la acumulación relativa de ácido salicílico (SA), ácido jasmonico (JA) y ácido abscísico, en la interacción compatible son más semejantes a la respuesta PCD producida por la disfunción del proteasoma que a la interacción incompatible. Estos datos sugieren una contribución de la interferencia sobre la funcionalidad del proteasoma en el incremento de la patogenicidad, observado en el sinergismo PVX‐potyvirus. Por último, los resultados obtenidos al disminuir la expresión de 9‐LOX, α‐DOX1 y COI1, relacionados con la síntesis o con la señalización de oxilipinas, y mediante la aplicación exógena de JA y SA, muestran la implicación del metabolismo de las oxilipinas en el desarrollo de la NS producida por la infección sinérgica entre PVXpotyvirus en N. benthamiana. Además, estos resultados indican que la PCD asociada a esta infección, al igual que ocurre en interacciones incompatibles, no contiene necesariamente la acumulación viral, lo cual indica que necrosis e inhibición de la multiplicación viral son procesos independientes. ABSTRACT Plant viruses cause severe diseases that lead to serious economic losses worldwide. Moreover, simultaneous infections with several viruses are common in nature leading to exacerbation of the disease symptoms. This phenomenon is known as viral synergism. Systemic necrosis (SN) is one of the most severe symptoms caused by plant viruses in susceptible plants, even leading to death of the host. This phenotype has been compared with the hypersensitive response (HR) displayed by resistant plants, and some parallelisms have been found between both responses, which suggest that SN induced by compatible interactions could be the result of a systemic hypersensitive response (SHR). However, the molecular mechanisms involved in the development of SN, its relationship with antiviral defence processes and its biological relevance are still unknown. Furthermore, the changes produced in plants by mixed infections that cause synergistic pathological effects have not been studied in a genome‐wide scale. In this doctoral thesis different approaches have been used to analyse gene expression, together with other genetic and biochemical techniques, in the model plant Nicotiana benthamiana, in order to study the SN produced by the synergistic infection of Potato virus X (PVX) with several potyviruses. Genomic and physiological changes produced in the host by double infection with PVX and Potato virus Y (PVY), and by single infection with PVX or PVY have been compared. In addition, transcriptional and hormonal changes associated with infection by the chimeric virus PVX/HC‐Pro, which produces synergistic symptoms similar to those caused by PVX‐potyvirus, have been compared with those produced by other types of cell death. These types of cell death are: PCD associated with an incompatible interaction, and PCD produced by proteasome disruption. Finally, reverse genetic techniques have revealed the involvement of host factors, such as oxylipins, in the development of SN associated with PVX‐potyvirus synergism. The results revealed that compared with single infections, double infection with PVX‐PVY produced qualitative and quantitative differences in the transcriptome profile, mainly related to primary metabolism. Other changes in gene expression, which reflected the activation of defence mechanisms, correlated with a severe oxidative stress in doubly infected plants that was undetected in single infections. Additionally, accumulation levels of several miRNAs involved in different cellular processes were measured, and the results showed that double infection not only produced the greatest variations in miRNA accumulation levels but also in miRNA functionality. These variations could be related with transcriptomic changes and the symptomatology of the infection. Transcriptome and hormone level comparisons between SN induced by PVX/HCPro and the incompatible interaction produced by Tobacco mosaic virus in plants expressing the N resistance gene (SHR), showed some similarities between both responses, even though the compatible interaction appeared retarded in time. Nevertheless, the expression profiles of both defence‐related genes and hormoneresponsive genes, as well as the relative accumulation of salicylic acid (SA), jasmonic acid (JA) and abscisic acid in the compatible interaction are more similar to the PCD response produced by proteasome disruption. These data suggest that interference with proteasome functionality contributes to the increase in pathogenicity associated with PVX‐potyvirus synergism. Finally, the results obtained by reducing the expression of 9‐LOX, α‐DOX1 and COI1, related with synthesis or signalling of oxylipins, and by applying exogenously JA and SA, revealed that oxylipin metabolism is involved in the development of SN induced by PVX‐potyvirus synergistic infections in N. benthamiana. Moreover, these results also indicated that PVX‐potyvirus associated PCD does not necessarily restrict viral accumulation, as is also the case in incompatible interactions. This indicates that both necrosis and inhibition of viral multiplication are independent processes.

Transcriptional changes and oxidative stress associated with the synergistic interaction between potato virus X and potato virus Y and their relationship with symptom expression.

Many virus diseases of economic importance to agriculture result from mixtures of different pathogens invading the host at a given time. This contrasts with the relatively scarce studies available on the molecular events associated with virus---host interactions in mixed infections. Compared with single infections, co-infection of Nicotiana benthamiana with Potato virus X (PVX) and Potato virus Y (PVY) resulted in increased systemic symptoms (synergism) that led to necrosis of the newly emerging leaves and death of the plant. A comparative transcriptional analysis was undertaken to identify quantitative and qualitative differences in gene expression during this synergistic infection and correlate these changes with the severe symptoms it caused. Global transcription profiles of doubly infected leaves were compared with those from singly infected leaves using gene ontology enrichment analysis and metabolic pathway annotator software. Functional gene categories altered by the double infection comprise suites of genes regulated coordinately, which are associated with chloroplast functions (downregulated), protein synthesis and degradation (upregulated), carbohydrate metabolism (upregulated), and response to biotic stimulus and stress (upregulated). The expressions of reactive oxygen species?generating enzymes as well as several mitogen-activated protein kinases were also significantly induced. Accordingly, synergistic infection induced a severe oxidative stress in N. benthamiana leaves, as judged by increases in lipid peroxidation and by the generation of superoxide radicals in chloroplasts, which correlated with the misregulation of antioxidative genes in microarray data. Interestingly, expression of genes encoding oxylipin biosynthesis was uniquely upregulated by the synergistic infection. Virus-induced gene silencing of ?-dioxygenase1 delayed cell death during PVX?PVY infection.