Person: Solís González, María Teresa
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First Name
María Teresa
Last Name
Solís González
Affiliation
Universidad Complutense de Madrid
Faculty / Institute
Ciencias Biológicas
Department
Genética, Fisiología y Microbiología
Area
Fisiología Vegetal
Identifiers
3 results
Search Results
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Item Early markers of in vitro microspore reprogramming to embryogenesis in olive (Olea europaea L.)(Plant Science, 2008) Solís González, María Teresa; Pintos, Beatriz; Prado, María Jesús; Bueno, María Angeles; Raska, Ivan; Risueño, María Carmen; Sánchez Testillano, PilarMicrospore embryogenesis to form haploid and double-haploid embryos and regenerated plants is an efficient method of producing homozygous lines for crop breeding. In trees, the process is of special interest since classical methods are impractical in many cases, as in Olea europaea L. Recently, a convenient method has been developed for microspore embryogenesis induction by stress in olive isolated microspores in vitro cultures. In the present work, the switch of the microspore developmental pathway and the formation of microspore-derived multicellular proembryos have been achieved and a cytochemical and immunocytochemical analysis was performed in the early stages. The young microspore proembryos displayed defined features different to both, the in vivo gametophytic, and the in vitro non-responsive microspores. Reprogrammed microspores showed an absence of starch, the occurrence of a first symmetrical division and cytokinesis, the presence of an abundant ribosomal population, and changes in cellulosic and pectic cell wall components which constituted early markers of the embryogenic microspore process. They provided new insights on the molecular and cellular events associated with the microspore reprogramming of woody plants, and specifically in olive, providing interesting knowledge which could guide future selection and regeneration strategies in this fruit tree of high economic interest.Item DNA methylation dynamics and MET1a-like gene expression changes during stress-induced pollen reprogramming to embryogenesis(Journal of Experimental Botany, 2012) Solís González, María Teresa; Rodríguez-Serrano, María; Meijón, Monica; Cañal, María Jesús; Cifuentes, Alejandro; Risueño, María; Testillano, PilarStress-induced plant cell reprogramming involves changes in global genome organization, being the epigenetic modifications key factors in the regulation of genome flexibility. DNA methylation, accomplished by DNA methyltransferases, constitutes a prominent epigenetic modification of the chromatin fibre which is locked in a transcriptionally inactive conformation. Changes in DNA methylation accompany the reorganization of the nuclear architecture during plant cell differentiation and proliferation. After a stress treatment, in vitro-cultured microspores are reprogrammed and change their gametophytic developmental pathway towards embryogenesis, the process constituting a useful system of reprogramming in isolated cells for applied and basic research. Gene expression driven by developmental and stress cues often depends on DNA methylation; however, global DNA methylation and genome-wide expression patterns relationship is still poorly understood. In this work, the dynamics of DNA methylation patterns in relation to nuclear architecture and the expression of BnMET1a-like DNA methyltransferase genes have been analysed during pollen development and pollen reprogramming to embryogenesis in Brassica napus L. by a multidisciplinary approach. Results showed an epigenetic reprogramming after microspore embryogenesis induction which involved a decrease of global DNA methylation and its nuclear redistribution with the change of developmental programme and the activation of cell proliferation, while DNA methylation increases with pollen and embryo differentiation in a cell-type-specific manner. Changes in the presence, abundance, and distribution of BnMET1a-like transcripts highly correlated with variations in DNA methylation. Mature zygotic and pollen embryos presented analogous patterns of DNA methylation and MET1a-like expression, providing new evidence of the similarities between both developmental embryogenic programmes.Item The 5-methyl-deoxy-cytidine (5mdC) localization to reveal in situ the dynamics of DNA methylation chromatin pattern in a variety of plant organ and tissue cells during development(Physiologia Plantarum, 2012) Sánchez Testillano, Pilar; Solís González, María Teresa; Risueño, María del CarmenDNA methylation of cytosine residues constitutes a prominent epigenetic modification of the chromatin fiber which is locked in a transcriptionally inactive conformation leading to gene silencing. Plant developmental processes, as differentiation and proliferation, are accompanied by chromatin remodeling and epigenetic reprogramming. Despite the increasing knowledge gained on the epigenetic mechanisms controlling plant developmental processes, the knowledge of the DNA methylation regulation during relevant developmental programs in flowering plants, such as gametogenesis or embryogenesis, is very limited. The analysis of global DNA methylation levels has been frequently conducted by high performance capillary electrophoresis, and more recently also by ELISA-based assays, which provided quantitative data of whole organs and tissues. Nevertheless, to investigate the DNA methylation dynamics during plant development in different cell types of the same organ, the analysis of spatial and temporal pattern of nuclear distribution of 5-methyl-deoxy-cytidine (5mdC) constitutes a potent approach. In this work, immunolocalization of 5mdC on sections and subsequent confocal laser microscopy analysis have been applied for in situ cellular analysis of a variety of plant cells, tissues and organs with different characteristics, e.g. hardness, heterogeneity, cell accessibility, tissue compactness, etc.; the results demonstrated the versatility and feasibility of the approach for different plant samples, and revealed defined DNA methylation nuclear patterns associated with differentiation and proliferation events of various plant cell types and developmental programs. Quantification of 5mdC immunofluorescence intensity by image analysis software also permitted to estimate differences in global DNA methylation levels among different cells types of the same organ during development.