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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

The association of homeotic gene expression with stem cell formation and morphogenesis in cultured medicago truncatula

Chen, Shih-kuang January 2009 (has links)
Research Doctorate - Doctor of Philosophy (PhD) / Somatic embryogenesis (SE) can be induced in vitro in Medicago truncatula 2HA by auxin and cytokinin but not in wild type Jemalong. Wild-type Jemalong will only form callus in the presence of auxin and cytokinin and both Jemalong and 2HA will form roots in response to auxin alone. The F2 analysis of 2HA X Jemalong crosses suggest that a single gene may open the way to SE but additional genes are required to maximise the process. Auxin and cytokinin are required for 2-3 weeks for SE and for de novo root formation auxin is essential for about one week. Abscisic acid (ABA) and ethylene, both stress related hormones, enhance SE induction but inhibit callus and de novo root formation. The WUSCHEL (WUS) gene was investigated in M. truncatula (Mt) and identified by the similarity with Arabidopsis WUS in amino acid sequence, phylogeny, promoter element patterns, and expression patterns in planta. MtWUS is induced by cytokinin after 24-48 h in embryogenic cultures and maximum expression occurs after 1 week which coincides with totipotent stem cell induction. MtWUS expression, as illustrated by promoter-GUS studies, subsequently localises to the embryo and corresponds to the onset of MtCLV3 expression. RNAi studies show that MtWUS expression is essential for callus and somatic embryo production. There is evidence based on the presence of MtWUS promoter binding sites that MtWUS is required for the induction of MtSERF1 which appears to have a key role in the signalling required for SE induced in 2HA. MtWOX5, as for MtWUS, was identified by similarity to Arabidopsis WOX5 based on amino acid sequence, phylogeny, promoter element patterns, and expression patterns in planta. MtWOX5 expresses in the auxin induced root primordium and root meristem and appears to be involved in pluripotent stem cell induction. GA suppresses the MtWOX5 expression in the root apex and suppresses the root primordium induction, consistent with the importance of MtWOX5 in in vitro root formation. The evidence is discussed that the homeotic genes MtWUS and MtWOX5 are “hijacked for stem cell induction which is key to somatic embryo and de novo root induction. In relation to SE, a key role for WUS in the signalling involved in induction is discussed and a model developed.
2

Etude de la voie de signalisation et du complexe TOR (Target Of Rapamycin) chez Arabidopsis / Study of the TOR (Target Of Rapamycin) complex and signaling pathway in Arabidopsis

Dobrenel, Thomas 12 December 2012 (has links)
La protéine kinase TOR (Target Of Rapamycin) a été identifiée chez la levure et les mammifères comme participant à deux complexes protéiques qui servent de carrefour entre la perception des facteurs endogènes et exogènes et la stimulation de la croissance cellulaire. Depuis la découverte de la kinase AtTOR chez Arabidopsis thaliana, des études ont été menées afin de mieux caractériser son rôle chez les plantes et l’influence de son niveau d’expression sur la régulation du métabolisme et du développement.Au cours de ce travail, j’ai contribué à l’étude de cette kinase en étudiant l’influence de l’inactivation de TOR sur la composition du ribosome au niveau protéique et sur le niveau de phosphorylation de ces protéines, ainsi que sur l’organisation du méristème au niveau moléculaire et cytologique Au cours de cette étude, j’ai montré que certaines protéines constitutives du ribosome pourraient être des cibles de l’activité TOR au niveau de leur abondance et/ou de leur état de phosphorylation. Ainsi, l’inactivation de TOR entraine une diminution du niveau de phosphorylation des protéines RPS6 et pourrait influencer l’abondance des protéines acides constitutives du stalk ribosomal, une structure importante dans la régulation de la traduction. Les résultats obtenus suggèrent également que l’activité TOR est nécessaire au maintien du méristème à l’état fonctionnel en régulant les voies importantes contrôlant la division et la différentiation au sein de cette structure. / The TOR (Target Of Rapamycin) kinase has first been identified in yeast and mammals as being part of two different protein complexes that are implicated in the stimulation of cell growth in response to endogenous and exogenous stimuli. Since the discovery of this kinase in Arabidopsis, some studies have been led to characterize its role in plants and the influence of its expression level on the metabolism and development regulation.In this study, I worked on the influence of the TOR inactivation on the composition of the ribosome on its protein composition and on the phosphorylation status of these proteins and also on the organisation of the meristem at a molecular and cellular level.Regarding to the results I have obtained, I showed that TOR may regulate the abundance and/or the phosphorylation status of some proteins involved in the ribosome composition. Hence, TOR inactivation leads to a decrease of the phosphorylation level of RPS6 proteins and could regulate the abundance of acid proteins constitutive of the ribosomal stalk, a structure important for the translation regulation. The results obtained also suggest that TOR activity may be necessary to keep the meristem functional by the regulation of the main important pathways controlling division and differentiation in that structure.
3

Etude de la voie de signalisation et du complexe TOR (Target Of Rapamycin) chez Arabidopsis

Dobrenel, Thomas 12 December 2012 (has links) (PDF)
La protéine kinase TOR (Target Of Rapamycin) a été identifiée chez la levure et les mammifères comme participant à deux complexes protéiques qui servent de carrefour entre la perception des facteurs endogènes et exogènes et la stimulation de la croissance cellulaire. Depuis la découverte de la kinase AtTOR chez Arabidopsis thaliana, des études ont été menées afin de mieux caractériser son rôle chez les plantes et l'influence de son niveau d'expression sur la régulation du métabolisme et du développement.Au cours de ce travail, j'ai contribué à l'étude de cette kinase en étudiant l'influence de l'inactivation de TOR sur la composition du ribosome au niveau protéique et sur le niveau de phosphorylation de ces protéines, ainsi que sur l'organisation du méristème au niveau moléculaire et cytologique Au cours de cette étude, j'ai montré que certaines protéines constitutives du ribosome pourraient être des cibles de l'activité TOR au niveau de leur abondance et/ou de leur état de phosphorylation. Ainsi, l'inactivation de TOR entraine une diminution du niveau de phosphorylation des protéines RPS6 et pourrait influencer l'abondance des protéines acides constitutives du stalk ribosomal, une structure importante dans la régulation de la traduction. Les résultats obtenus suggèrent également que l'activité TOR est nécessaire au maintien du méristème à l'état fonctionnel en régulant les voies importantes contrôlant la division et la différentiation au sein de cette structure.
4

Transient Expression of BABY BOOM, WUSCHEL, and SHOOT MERISTEMLESS from Virus-Based Vectors in Cotton Explants: Can We Accelerate Somatic Embryogenesis to Improve Transformation Efficiency?

Alejos, Marcos 12 1900 (has links)
Upland cotton (Gossypium hirsutum L.) is the world's most prominent fiber crop. Cotton transformation is labor intensive and time consuming, taking 12 to 18 months for rooted T0 plants. One rate limiting step is the necessary production of somatic embryos. In other recalcitrant species, ectopic expression of three genes were shown to promote somatic embryogenesis: WUSCHEL (WUS), SHOOT MERISTEMLESS (STM), and BABY BOOM (BBM). WUS is responsible for maintaining stem-cell fate in shoot and floral meristems. STM is needed to establish and maintain shoot meristems. STM and WUS have similar functions but work in different pathways; overexpression of both together converts somatic cells to meristematic and embryogenic fate. BBM encodes an AP2/ERF transcription factor that is expressed during embryogenesis and ectopic expression of BBM reprograms vegetative tissues to embryonic growth. In prior studies, these genes were constitutively expressed, and cultures did not progress beyond embryogenesis because the embryogenic signal was not turned off. In our study, we set out to use these genes to increase the efficiency of cotton transformation and decrease the time it takes to regenerate a plant. A disarmed cotton leaf crumple virus (dCLCrV) vector delivers WUS, STM, or BBM into cotton tissue cultures through Agrobacterium tumefaciens infection. We propose that virus delivery of embryo-inducing genes is a better approach for transformation because A) inserts more than 800 nucleotides are unstable, and will spontaneously inactivate, B) virus DNA can migrate through plasmodesmata to cells around the infected cell, creating a gradient of embryonic potential, C) the virus DNA does not pass through the germ line and the seed will not contain virus. We propose this method of inducing embryogenesis will facilitate the stable transformation of cotton and will be beneficial to the cotton industry. Ectopic expression of AtBBM, AtSTM, and AtWUS GrWUS:meGFP from a constitutive CaMV 35S promoter produced plants with phenotypes similar to those described in previous studies overexpressing AtBBM, indicating that the AtBBM gene was functional. The cotton cotyledon infiltration of the pART27 constructs showed transformed cells in Coker 312 by GFP localization in the nucleus. Although GFP was detected, no visible embryos appeared from the cotyledon. Cotyledons infiltrated with Agrobacterium harboring overexpression vectors withered and aborted after ~2 weeks. The virus-based vector in tissue culture failed to increase transformation efficiency, resulting in no embryos. The combination of hormone concentration showed no contribution to increasing the transformation efficiency.
5

Interpreting Cytokinin Action as Anterograde Signaling and Beyond

Ikeda, Yoshihisa, Zalabák, David, Kubalová, Ivona, Králová, Michaela, Brenner, Wolfram G., Aida, Mitsuhiro 30 March 2023 (has links)
Among the major phytohormones, the cytokinin exhibits unique features for its ability to positively affect the developmental status of plastids. Even early on in its research, cytokinins were known to promote plastid differentiation and to reduce the loss of chlorophyll in detached leaves. Since the discovery of the components of cytokinin perception and primary signaling, the genes involved in photosynthesis and plastid differentiation have been identified as those directly targeted by type-B response regulators. Furthermore, cytokinins are known to modulate versatile cellular processes such as promoting the division and differentiation of cells and, in concert with auxin, initiating the de novo formation of shoot apical meristem (SAM) in tissue cultures. Yet how cytokinins precisely participate in such diverse cellular phenomena, and how the associated cellular processes are coordinated as a whole, remains unclear. A plausible presumption that would account for the coordinated gene expression is the tight and reciprocal communication between the nucleus and plastid. The fact that cytokinins affect plastid developmental status via gene expression in both the nucleus and plastid is interpreted here to suggest that cytokinin functions as an initiator of anterograde (nucleus-to-plastid) signaling. Based on this viewpoint, we first summarize the physiological relevance of cytokinins to the coordination of plastid differentiation with de novo shoot organogenesis in tissue culture systems. Next, the role of endogenous cytokinins in influencing plastid differentiation within the SAM of intact plants is discussed. Finally, a presumed plastid-derived signal in response to cytokinins for coupled nuclear gene expression is proposed.
6

Frameworks for reprogramming early diverging land plants

Pollak Williamson, Bernardo January 2018 (has links)
Plant form is a product of emergent processes of cell division, patterning and morphogenesis. These fundamental processes remain poorly characterised in plants. However, engineering approaches can provide new tools and frameworks for the study and manipulation of plant development. This dissertation describes the development of engineering frameworks for reprogramming of the early diverging land plant Marchantia polymorpha (Marchantia). I describe the generation of genomic and transcriptomic datasets for Marchantia, which has provided the basis for the compilation of a gene-centric registry of DNA parts for engineering (MarpoDB). I describe the development of Loop assembly, an efficient and standardised DNA assembly system based on Type IIS restriction enzymes for recursive fabrication of DNA circuits with high efficiency. MarpoDB was used to mine new DNA parts compatible with Loop assembly which were used to generate plant transformation vectors for labelling of cellular features to study aspects of growth and development. I performed image analysis of genetic markers for segmentation and quantification of cellular properties in germinating gemmae. I implemented high-efficiency Cas9-mediated mutagenesis in Marchantia for use in functional molecular genetics studies. Furthermore, I produced inducible systems for expression of heterologous elements by transactivation which showed negligible levels of basal activity. It was possible to use this system for induction of gene expression in single cells. Finally, these new frameworks were applied to study the gametophytic meristem in Marchantia gemmae. I mapped the expression of several putative candidate homologues for higher plant meristem regulators, performed overexpression and loss-of-function studies for homologues of WUSCHEL, CLAVATA3 and SHOOT MERISTEMLESS. A strategy for misregulation of endogenous genes was developed using inducible transactivation, and was used with cellular markers for WUSCHEL and CLAVATA3 homologues in Marchantia.
7

Multidisciplinary study of the role of calcium in plant in vitro embryogenesis

Calabuig Serna, Antonio 06 September 2023 (has links)
[ES] El calcio (Ca2+) es un catión esencial que juega un papel fundamental en todos los organismos vivos. Desde el punto de vista funcional, el Ca2+ actúa como un segundo mensajero que regula distintos procesos celulares. Trabajos anteriores indican que la señalización mediante Ca2+ podría estar implicada en las primeras etapas de la inducción de la embriogénesis in vitro de las plantas, pero el verdadero papel del Ca2+ en este proceso es aún desconocido. Por eso, el principal objetivo de la presente Tesis es el estudio del papel del Ca2+ en la embriogénesis in vitro mediante dos sistemas in vitro: la embriogénesis somática y la embriogénesis de microsporas. Para determinar la importancia de la homeostasis del Ca2+ en la inducción de la embriogénesis y las dinámicas de los niveles de Ca2+ durante la inducción y el establecimiento de embriones somáticos y derivados de microsporas, se utilizaron tratamientos químicos y se detectaron los niveles de Ca2+ mediante sondas fluorescentes y sensores cameleon codificados genéticamente, visualizados con microscopía fluorescente y confocal. Observamos que el aumento de Ca2+ es un marcador temprano en la inducción de la embriogénesis in vitro y que los niveles de Ca2+ durante la embriogénesis in vitro son dinámicos en todos los sistemas estudiados. Además, las oscilaciones en los niveles de Ca2+ podrían estar relacionadas con los procesos de diferenciación que ocurren en las células inducidas una vez une el Ca2+ a la calmodulina. Mostramos que un aumento de Ca2+ dentro de un rango definido de concentración tiene un efecto positivo, dependiendo del sistema, en la producción de embriones, siendo más sensibles aquellos sistemas basados en suspensiones de células aisladas que aquellos que usan tejidos como explantes. Finalmente, estudiamos el papel de la calosa durante la embriogénesis somática, observando que la inhibición de la deposición de calosa impide el desarrollo embrionario, lo que sugiere una relación entre la formación de una barrera de calosa y el establecimiento de la identidad embrionaria en las células somáticas. / [CAT] El calci (Ca2+) és un catió essencial que juga un paper fonamental en tots els organismes vius. Des del punt de vista funcional, el Ca2+ actua com a un segon missatger que regula diferents processos cel·lulars. Treballs anteriors indiquen que la senyalització mitjançant el Ca2+ podria estar implicada en les primeres etapes de la inducció de l'embriogènesi in vitro de les plantes, però el paper real del Ca2+ en aquest procés encara és desconegut. Per això, el principal objectiu de la present Tesi és l'estudi del paper del Ca2+ en l'embriogènesi in vitro mitjançant dos sistemes in vitro: l'embriogènesi somàtica i l'embriogènesi de micròspores. Per tal de determinar la importància de l'homeòstasi del Ca2+ en la inducció de l'embriogènesi i les dinàmiques dels nivells de Ca2+ durant la inducció i l'establiment d'embrions somàtics i derivats de micròspores, es van utilitzar tractaments químics i es van detectar els nivells de Ca2+ mitjançant sondes fluorescents i sensors de cameleon codificats genèticament, visualitzats amb microscòpia fluorescent i confocal. Vam observar que l'augment de Ca2+ és un marcador primerenc en la inducció de l'embriogènesi in vitro i que els nivells de Ca2+ durant l'embriogènesi in vitro són dinàmics en tots els sistemes estudiats. A més, les oscil·lacions en els nivells de Ca2+ podrien estar relacionades amb els processos de diferenciació que tenen lloc en les cèl·lules induïdes una vegada uneix el Ca2+ a la calmodulina. Vam mostrar que un augment de Ca2+ dins d'un rang definit de concentració té un efecte positiu, depenent del sistema, en la producció d'embrions, essent més sensibles aquells sistemes basats en suspensions de cèl·lules aïllades que aquells que usen teixits com a explants. Finalment, vam estudiar el paper de la cal·losa durant l'embriogènesi somàtica, i vam observar que la inhibició de la deposició de cal·losa impedeix el desenvolupament embrionari, la qual cosa suggereix una relació entre la formació d'una barrera de cal·losa i l'establiment de la identitat embrionària en les cèl·lules somàtiques. / [EN] Calcium (Ca2+) is an essential cation that plays fundamental roles in all living organisms. From a functional point of view, Ca2+ acts as a second messenger that regulates different cellular processes. Previous works point to the fact that Ca2+ signaling may be involved in the early stages of induction of in vitro plant embryogenesis, but the actual role of Ca2+ in this process remained unveiled. Thus, the main goal of the present Thesis is to study the role of Ca2+ in in vitro embryogenesis using two in vitro systems: somatic embryogenesis and microspore embryogenesis. Chemical treatments and detection of Ca2+ with fluorescent probes and genetically-encoded cameleon sensors imaged by fluorescence and confocal microscopy were performed to determine the importance of Ca2+ homeostasis for induction of embryogenesis and the dynamics of Ca2+ levels during the induction and establishment of somatic and microspore-derived embryos. We observed that Ca2+ increase is an early marker of induction of in vitro embryogenesis and Ca2+ levels during in vitro embryogenesis are dynamic in all the systems we studied. Moreover, Ca2+ oscillations might be related to the differentiation processes that take place in the induced cells upon binding to calmodulin. We showed that Ca2+ increase within a defined range has system-specific positive effects in embryo yield, being more sensitive those systems using isolated cell suspensions rather than those using tissues as explants. Finally, we studied the role of callose during somatic embryogenesis, and we observed that inhibiting callose deposition prevents embryo development, which suggests a relationship between the formation of a callose barrier and the establishment of embryo identity in somatic cells. / Calabuig Serna, A. (2023). Multidisciplinary study of the role of calcium in plant in vitro embryogenesis [Tesis doctoral]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/196022

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