Global ETD Search

41	Vývojová terminace aktivity apikálního meristému kořene / Development related termination of the root apical meristem activity Benešová, Šárka January 2016 (has links) Development Related Termination of the Root Apical Meristem Activity Abstract Root system architecture is modulated through growth and branching of individual roots, while the growth is strictly regulated via long term apical meristem (RAM) maintenance and cell elongation. RAM activity is not consistent during root on- togeny, which was shown in several dicotyledonous species as change in root meristem structure and decline in root growth rate during individual root development. This thesis is focused on changes in extent and arrangement of meristematic tissues and their derivatives within adventitious roots of Acorus calamus and Oryza sativa during long term cultivation. Changes in meristem and elongation zone length, the root cap length, radial tissue complexity, as well as the changes in root hair emergence, etc., are put into relation with quantified expression level of selected important regulatory elements taking part in RAM maintenance (WOX and SCR family transcription factors). Methodology and approach for future research in this field are outlined. Keywords: Root, Apical Meristem, Root System Architecture, RAM Termination
42	Contrôle spatial de la division cellulaire chez les plantes : rôle des protéines TRM6-TRM7-TRM8 d’Arabidopsis thaliana dans la formation de l’anneau de préprophase / Spatial control of cell division in plants : TRM6-TRM7-TRM8 proteins and the formation of preprophase band in Arabidopsis thaliana Schaefer, Estelle 13 March 2014 (has links) Les cellules végétales sont entourées d’une paroi pecto-cellulosique rigide, soudant les cellules les unes aux autres et empêchant toute migration. Lors de la mitose, le positionnement du plan de division est donc un processus fondamental dans l’organisation des tissus puisque les cellules nouvellement formées restent à leur position initiale après la cytokinèse. Chez les plantes terrestres, le plan de division est déterminé lors de la transition G2/M du cycle cellulaire par l’anneau de préprophase (PPB), une structure transitoire corticale de microtubules. Les mécanismes mis en jeu pour la formation de la PPB sont encore inconnus. L’équipe dans laquelle j’ai effectué ma thèse a identifié un complexe régulateur, le complexe TTP, composé de TON1, de la famille de protéines TON1-Recruiting-Motif (TRMs) et d’une phosphatase de type 2A où FASS est la sous-unité régulatrice. TON1 et FASS sont impliquées dans l’organisation des microtubules corticaux en interphase, et sont indispensables à la formation de la PPB. La famille des protéines TRMs, identifiée récemment, est composée de 34 membres, dont certains sont capables de se lier aux microtubules et de recruter TON1 et FASS au cytosquelette. Les profils d’expression des TRMs et les analyses génétiques préliminaires suggèrent que certaines auraient un rôle en interphase, alors que d’autres pourraient être impliquées dans la formation de la PPB. Mon projet était d’identifier et de caractériser, si elles existent, les TRMs impliquées spécifiquement dans la formation de la PPB. L’analyse des données de transcriptome a révélé qu’un des gènes de la famille TRM, le gène TRM7, présente un pic d’expression en mitose. Nous avons d'abord montré que TRM7 est spécifiquement exprimée dans les tissus en division. L’utilisation d’une fusion génomique TRM7-3xYpet indique d'autre part que la protéine TRM7 n’est exprimée qu’au stade G2/M. Elle est localisée à la PPB et disparaît en début de métaphase, peu après dépolymérisation de la PPB. TRM7 est ainsi le seul marqueur spécifique de la PPB identifié à ce jour chez les plantes, puisque toutes les autres protéines localisées à la PPB marquent également les autres structures mitotiques ou le cytosquelette d’interphase. TRM7 fait partie d’un sous-groupe de trois TRM partageant environ 74% de similarité de séquence. L’analyse phénotypique du mutant trm7, ainsi que celui du triple mutant trm6 trm7 trm8 a montré que ce sous-groupe de protéines joue un rôle majeur dans la formation de la PPB. Près de la moitié des cellules du mutant trm7 présentent un stade préprophase aberrant alors que 100% des cellules du triple mutant au stade G2/M sont affectées, la très grande majorité se divisant sans former de PPB. Étonnamment, la morphologie de ces mutants est peu perturbée et le phénotype n’est en rien comparable au syndrome développemental sévère des mutants ton1 ou fass dépourvus de PPB. De plus, les plans de division ne sont pas aléatoires comme c’est le cas pour les mutants ton1 et fass. Nos résultats permettent donc d'apporter une nouvelle lumière sur le rôle de la PPB dans la détermination du plan de division. Pour la première fois, grâce au triple mutant trm6 trm7 trm8, nous avons réussi à découpler les fonctions interphasiques de la fonction mitotique du complexe TTP, ce qui était jusqu’alors impossible chez les mutants ton1 ou fass où les défauts en interphase et les défauts dus à l’absence de PPB étaient indissociables. Tous les composants du complexe TTP partageant des similarités avec des protéines centrosomales animales faisant partie du même complexe, nous avons exploré dans un projet annexe, la conservation des interactions au sein du complexe animal. Nous avons pu mettre en évidence, grâce au système double-hybride chez la levure, des interactions entre protéines animales et protéines végétales. / Plant cells are embedded within a semi-rigid pecto-cellulosic cell wall that prevents cell migration. As a consequence, three-dimensional cellular organization of tissues mostly results from polarized cell division, since new cells remain in place after mitosis with no possibility for subsequent relocation. In land plants, the division plane is determined pre-mitotically, during the G2 to M phase transition by the preprophase band (PPB), a transient, premitotic microtubule array. The molecular pathways leading to preprophase band formation are still largely unknown. Our team has identified a regulatory complex, the TTP complex, composed of TON1, TRM and a Protein Phosphatase 2A complex with FASS as the regulatory subunit. Both TON1 and FASS have been shown to be involved in cortical microtubules organization during both interphase and PPB formation. The TRM super family is a newly identified protein family composed of 34 members, some of which are microtubule-associated proteins able to recruit TON1 and FASS to the microtubules. Based on TRM expression profiles and preliminary genetic analysis, we hypothesized that some TRMs could have a role in interphase, while others could be involved in PPB formation. My project was to identify and characterize TRMs specifically involved in PPB formation, if any. Transcriptomic analysis using the Genevestigator tool revealed that one TRM gene, TRM7, has a peak of expression at mitosis. TRM7 promoter GUS fusion analysis confirmed that TRM7 is expressed in all dividing tissues and in situ hybridizations of shoot apical meristems revealed a patchy pattern of expression, typical of cell cycle-regulated genes. Remarkably, the genomic TRM7-3xYFP fusion is only expressed at the G2/M transition where it localizes to the PPB, persists beyond PPB degradation until the beginning of metaphase and then disappears. To our knowledge, this makes TRM7 the only PPB-specific marker identified in plants so far, since all other PPB-associated markers label others structures as well, both interphasic or mitotic. TRM7 is part of the TRM6-7-8 sub-family, which share 74% of similarity. Phenotypic analysis of the trm7 and trm6 trm7 trm8 triple mutant revealed a major role of this sub-group in PPB formation. Almost half trm7 cells and all trm6 trm7 trm8 cells displayed an abnormal preprophase stage, the vast majority of the triple mutant cells dividing without PPB. Surprisingly, the triple mutant phenotype is rather mild compare to the severe developmental syndrome of PPB-lacking ton1 or fass plants. Moreover, although often shifted, division plane positioning is far from being fully randomized as in ton1 and fass mutants. Our results show that, for the first time, we have fully uncoupled the mitotic function of the TTP complex from its interphasic function, contrarily to other TTP mutants analyzed so far, where division and interphase defects are indistinguishable. Moreover, these findings question the central role of the PPB in division plane positioning. All TTP components share similarities with animal proteins assembled within a complex at the centrosome. In a side project, we studied the conservation of protein interactions within the animal complex and were able to find cross-interactions between animal and plant proteins in yeast two-hybrid experiments. Division cellulaire Microtubules Anneau de préprophase Arabidopsis Méristème Cell division Microtubules Preprophase band Arabidopsis Meristem
43	Endophytes in the buds of Scots pine (<em>Pinus sylvestris</em> L.) Mattila née Pirttilä, A. M. (Anna Maria) 27 June 2001 (has links) Abstract Although microbes are generally found as endophytes in many plant tissues, the plant shoot meristems have been considered virtually sterile. Plant tissue culture, which utilizes mostly the meristems, has nevertheless given numerous references to microbial existence in these tissues. Since the bud-derived tissue cultures of Scots pine (Pinus sylvestris L.) also become easily occupied by microbes, microbial presence was considered to be one potential cause of the low regeneration capacity of tissues from mature trees. The origin of the microbes occurring in tissue cultures of buds of Scots pine was established in this study. One of the microbes, classified as Hormonema dematioides (Ascomycota), was localized in the scale tissues of a bud. Several other microbes were detected, and were associated especially with the meristematic tissues of Scots pine buds. This group was comprised of the yeast Rhodotorula minuta, and bacteria belonging to Methylobacterium spp., the Pseudomonas fluorescens subgroup, and a Mycobacterium sp. These endophytes were located particularly in the outermost cells of meristems, in the epithelial cells of resin ducts, and in the cells of the developing stem, in the vicinity of the meristems. These endophytes were less frequently found in the vascular tissue or in the intercellular spaces of cells, which are typical locations for the previously known endophytic bacteria. The meristem-associated endophytes were discovered to affect growth of pine tissues, and some of them produced substances that are suitable as precursors for phytohormone synthesis. Additionally, pure cultures of both bacterial and fungal endophytes showed antagonism in vitro against pathogens. When the correlation between the presence endophytes and the degeneration of bud-derived tissue cultures of Scots pine was studied, it was discovered that the endophytes grew uncontrollably once a tissue culture was initiated from the bud. A high level of chitinase production was also detected in these tissue cultures, which was considered to be indicative of a defense reaction. However, the endophytes were not found to colonize excessively in every tissue, but all bud-derived tissue cultures of Scots pine eventually degenerate. Therefore, it was concluded that the endophytes may not exclusively be considered responsible for the degeneration of the cultures. biological control buds endophytes meristem regeneration capacity tissue culture Pinus sylvestris L.
44	Caractérisation de l’interaction des protéines IMA/MIF2 et CSN5 au niveau moléculaire et physiologique Leblond-Castaing, Julie 19 December 2011 (has links) Les plantes ont la capacité à former de nouveaux organes grâce à une croissance continue assurée par une réserve de cellules souches au sein de structures spécifiques, les méristèmes. Les méristèmes floraux diffèrent des méristèmes végétatifs par leur caractère déterminé aboutissant à la production des fleurs. Le gène IMA (INHIBITOR OF MERISTEM ACTIVITY) code une protéine contenant un motif «doigt à zinc» (MIF) régulant les processus développementaux de la fleur et des ovules chez la tomate. En effet, IMA inhibe la prolifération cellulaire au cours de la terminaison florale en agissant sur l’expression du gène WUSCHEL, responsable du maintien du pool de cellules souches et contrôle le nombre de carpelles (Sicard et al., 2008). De plus, les protéines IMA et son orthologue chez Arabidopsis, MIF2, modulent la réponse à certaines phytohormones. De manière identique à la protéine MIF1 (Hu and Ma, 2006), IMA/MIF2 régule négativement la réponse aux brassinostéroïdes, à l’auxine, aux cytokinines et aux gibbérellines mais positivement la réponse à l’acide abscissique suggérant une fonction commune des protéines MIF dans les voies de réponse aux phytohormones. Un criblage d’une banque d’ADNc par la technique de double hybride a permis de révéler l’interaction entre les protéines IMA/MIF2 et une sous-unité du complexe signalosome, CSN5. De façon intéressante, les plantes mutantes csn5 d’Arabidopsis montrent de nombreuses altérations phénotypiques telles qu’un aspect buissonnant résultant de la perte de la dominance apicale, et une altération de la réponse à l’obscurité et à l’auxine. Ces phénotypes sont fortement ressemblants aux phénotypes des plantes MIF1OE d’Arabidopsis (Hu and Ma, 2006) et des plantes IMAOE de tomate (Sicard et al., 2008). Les résultats obtenus au cours de ce projet montrent que la protéine IMA inhibe la fonction du complexe signalosome grâce à son interaction avec la protéine CSN5. / Plants have the ability to form new organs as a result of indeterminate growth ensured by specific regions of pluripotent cells, called meristems. Flowers are produced by the activity of floral meristems which differ from vegetative meristems in their determinate fate. The INHIBITOR OF MERISTEM ACTIVITY (IMA) gene encoding a Mini Zinc Finger (MIF) protein from tomato (Solanum lycopersicum) regulates the processes of flower and ovule development. IMA inhibits cell proliferation during floral termination, controls the number of carpels during floral development and acts as a repressor of the meristem organizing centre gene WUSCHEL (Sicard et al., 2008). We demonstrated that IMA and its Arabidopsis ortholog MIF2 is also involved in a multiple hormonal signalling pathway, as a putative conserved feature for plant MIF proteins (Hu and Ma, 2006). Alike Arabidopsis MIF1, IMA/MIF2 regulates negatively BR, auxin, cytokinin and gibberellin signalling and positively ABA signaling. Using yeast two-hybrid screening experiments, we identified a strong protein-protein interaction between IMA and the signalosome subunit 5 (CSN5). Interestingly the csn5 mutant in Arabidopsis displays pleiotropic developmental defects such as a bushy phenotype originating from the loss of apical dominance and the alteration in sensitivity to darkness and auxin signals. These phenotypes are strikingly similar to what was described for Arabidopsis MIF1 (Hu and Ma, 2006) and tomato IMA overexpressors plants (Sicard et al., 2008), respectively. Taken together our data strongly suggest that IMA may act as an inhibitor of CSN function through its physical interaction with SlCSN5. The observed converse effects of IMA/MIF2 overexpression or deregulation on plant development and the abundance of developmental marker genes further support the notion of a CSN inhibitory control, since the COP9 signalosome through the specific deneddylation activity of the CSN5 subunit regulates plant hormone signalling. Méristème floral Mini zinc finger Signalosome Phytohormones Floral meristem Mini zinc finger Signalosome Phytohormones
45	Characterization of NAM/CUC3-related genes from oil palm (Elaeis guineensis L.) and factors regulating their expression during in planta and in vitro development / Caractérisation des gènes NAM/CUC3 de palmier à huile (Elaeis guineensis L.) et des facteurs régulant leur expression au cours du developpemènt in planta et in vitro. Qadri, Rashad Waseem Khan 20 September 2011 (has links) Le développement des plantes repose sur le fonctionnement des méristèmes qui sont à la base de la production des organes durant toute la vie post-embryonnaire de la plante. Ce développement repose également sur la définition de frontières d'une part entre les méristèmes et les organes et d'autre part entre les organes. Les gènes NAM/CUC3 de la famille de facteur de transcription à domaine NAC et leur microARN régulateur miR164, jouent un rôle important dans de tels mécanismes chez les eudicotylédones. En plus de leur rôle dans la définition de frontières, ces gènes sont nécessaires à la formation du méristème apical durant l'embryogenèse, et au contrôle de l'architecture de la plante et de ses organes. Sur la base des connaissances acquises chez les eudicotylédones, se posait la question de la conservation de ces gènes et de leur régulation ainsi que leur implication dans le contrôle du développement chez les palmiers (Arecales, Arecaceae) et, de façon plus large, chez les monocotylédones. Dans ce contexte, trois gènes similaires aux gènes NAM/CUC3 ont été isolés chez le palmier à huile (Elaeis guineensis L.), EgNAM1, EgNAM2 et EgCUC3. Ces gènes sont exprimés dans les tissus méristématiques végétatifs et reproducteurs. Notre analyse a révélée une conservation du module de régulation NAM-miR164 chez cette espèce et une divergence en terme de domaine d'expression entre monocotylédones et eudicotylédones, qui pourrait être associée à des différences majeures des régions cis-régulatrices des gènes NAM. L'analyse des profils d'expression des gènes NAM/CUC3 au cours de l'embryogenèse somatique précoce indique des similarités entre le palmier à huile, le maïs et le riz, ainsi qu'une conservation de la régulation via l'auxine comme observé chez Arabidopsis thaliana. Cependant, même si une régulation post-transcriptionnelle via miR164 a été détectée au cours de l'embryogenèse somatique, la répression par l'auxine semble essentiellement transcriptionelle. / Plant development depends on functioning of meristems, which are at the base of organ production during the post-embryonic phase. The development depends also on the definition of boundaries between meristem and primordia but also between organs. NAM/CUC3 genes belonging to the NAC domain transcription factor family and their microRNA regulator miR164 play an important role in these mechanisms in eudicot species. In addition to their role in boundary definition, they are involved in the establishment of the shoot apical meristem during embryogenesis and in the control of the plant and organ architectures. On the basis of data from eudicot species, the conservation of these genes and their regulation, and their involvement in meristem functioning in palm species (Arecales, Arecaceae) and more generally in monocot species was still an open question. In this context, three NAM/CUC3-related genes have been isolated in oil palm (Elaeis guineensis L.), EgNAM1, EgNAM2 and EgCUC3. Theses genes are expressed in both vegetative and reproductive meristematic tissues. Our analysis revealed the conservation of the NAM-miR164 regulatory module in this species and a divergence in term of expression pattern between monocots and eudicots, which may be related to differences in cis-regulatory regions of NAM genes. In contrast the expression pattern of NAM/CUC3 during somatic embryogenesis indicates similarity in the timing of expression between oil palm, maize and rice and also a conservation of the auxin-dependent regulation of NAM genes during this developmental phase as observed in Arabidopsis thaliana. However, even if miR164-dependent post-transcriptional regulation of NAM genes was detected during somatic embryogenesis, auxin-dependent repression seems to be essentially through transcriptional regulation. Palmier à huile Méristème Embryogenèse MiR164 Nam/cuc3 Oil palm Meristem Embryogenesis MiR164 Nam/cuc3
46	Sinalização no ganho de competência para a conversão de meristemas apicais radiculares de Catasetum fimbriatum em gemas caulinares / Signalling events in the competence acquisition to root apical meristem conversion of Catasetum fimbriatum into buds. Maria Aurineide Rodrigues 24 October 2008 (has links) Durante esse trabalho de pesquisa verificou-se que a aquisição de competência para conversão de ápices radiculares de Catasetum fimbriatum em gemas caulinares aumentava à medida que as plantas envelheciam. Esse processo esteve relacionado ao estabelecimento do crescimento determinado das raízes e com a parada da atividade e re-organização estrutural do meristema apical radicular (MAR). Este, quando ainda jovem e destituído de competência para a conversão em gemas, apresentava uma organização do tipo fechada, ao passo que em estágios avançados do envelhecimento este padrão transformou-se em um tipo aberto, marcado pela diferenciação e predominância de células parenquimáticas. Tais alterações, aparentemente, ocorreram com a concomitante perda das características e funções do centro de quiescente (CQ). De maneira complementar, constatou-se que a aquisição de competência do MAR para conversão em gemas estava correlacionada a uma série de alterações metabólicas, as quais, supostamente, participaram de uma condição fisiológica favorável a esse processo. Com base no conjunto de dados obtidos, pode-se observar que os teores endógenos de importantes participantes na progressão de divisões celulares, tais como auxinas, citocininas e formas reduzidas de ascorbato e glutationa tenderam a diminuir durante o envelhecimento das raízes. Por outro lado, durante esse mesmo período, o conteúdo de alguns hormônios envolvidos na sinalização de condições de estresse ou diferenciação celular, tais como etileno, ácido abscísico e giberelinas tenderam a aumentar. As concentrações relativas de importantes sinalizadores secundários, tais como óxido nítrico e cálcio citossólico também apresentaram aumento conspícuo na região do MAR durante o envelhecimento. Agregando elementos a estas constatações, verificou-se que o transporte polar de auxina seria um importante sinal posicional para a manutenção das características e função do MAR, uma vez que o seu bloqueio em plantas jovens foi suficiente para causar a aquisição da competência do MAR, no entanto, o processo de conversão não era consolidado enquanto os ápices radiculares permaneceram ligados às plantas. A aplicação de etileno em plantas jovens, por sua vez, desencadeou efeitos similares; no entanto, além de induzir a competência, esse hormônio também proporcionou a conversão dos MARs em gemas via aumento nos teores endógenos de citocininas. O tratamento de ápices radiculares jovens com diferentes tipos de citocininas revelaram que citocininas do tipo isopenteniladenina (iP e iPR) mostraram-se mais de perto relacionadas à retenção de características radiculares, ao passo que as do tipo zeatina (Z e ZR) apresentou maior influência e presença em condições em que as características radiculares foram perdidas. Por outro lado, a aplicação de substâncias moduladoras do balanço redox em ápices radiculares jovens mostrou que o estresse oxidativo proporcionou a aquisição de competência do MAR para conversão em gemas. Essa mesma tendência foi observada com a aplicação de concentrações relativamente elevadas de substâncias indutoras da elevação dos teores de óxido nítrico e cálcio citossólico nos tecidos. Os ápices radiculares com competência parcialmente estabelecida, analisados logo nas primeiras horas após o isolamento, revelaram que sua separação da planta-mãe acelerava as mudanças morfológicas que naturalmente ocorrem no MAR em estágios avançados do envelhecimento. Durante esse mesmo período, verificou-se uma queda rápida nos teores endógenos de citocininas (principalmente do tipo iP), proporcionando a predominância de citocininas do tipo Z durante a maior parte do primeiro dia de isolamento dos explantes, a qual coincidiu com a mudança no padrão de organização do MAR do tipo intermediário-aberto para o totalmente aberto. O avanço das modificações no ápice radicular após esse período desencadeou o estabelecimento do meristema caulinar, cujo evento esteve relacionado a uma tendência de aumento nos teores de citocininas e de ascorbato após o primeiro dia de isolamento. Dessa forma, os estágios mais avançados do envelhecimento radicular, bem como a separação de ápices radiculares com competência parcialmente estabelecida, parecem desencadear e aumentar a competência do MAR para conversão por meio de modificações morfológicas e fisiológicas muito similares nos ápices radiculares. Essas alterações envolveram a perda das características radiculares, a qual parece depender de alterações no controle exercido pelo CQ sobre o desenvolvimento das demais células no MAR. Esses eventos na região do CQ se revelaram condição sine qua non para a complementação da aquisição de competência do MAR, sendo esta dependente da intensidade das perturbações sobre o controle da organização do MAR. Dessa forma, a conversão do meristema apical radicular de C. fimbriatum em gemas caulinares parece decorrer da formação de um novo grupo de células na antiga região do CQ do MAR alterado. Essas células pareceram competentes para responder a diferentes estímulos que as direcionariam a uma nova rota do desenvolvimento que, nesse caso, seria o estabelecimento de um meristema caulinar com conseqüente desenvolvimento de uma gema vegetativa. / During this research work, it was noticed that competence acquisition for the conversion of Catasetum fimbriatum root tips into buds was related to the plant ageing. This process seems to be coupled with the establishment of the determinate root growth and with the cessation in the activity and structural re-organization of the root apical meristem (RAM). Young and non-competent root tips showed a closed RAM architecture, and the ageing process stimulated the establishment of an open organization in the RAM, as indicated by a higher level of differentiation and a predominance of parenchymatic cells in the old root apices. These alterations were concomitant with the modifications on the characteristics and functions of quiescent center (QC). In agreement with these observations, the competence acquisition to the conversion of the MAR into buds was linked to a series of metabolic alterations, which probably play a role in this process. Based on the data obtained, it was observed that the endogenous levels of important components of the cell division progression, such as auxins, cytokinins and the reduced forms of ascorbate and glutathione showed a tendency of decrease during the root ageing. On the other hand, during this same period, the content of some hormones involved in signalling events of stress conditions or cellular differentiation, such as ethylene, abscisic acid and gibberellins exhibited a pattern of increase. The relative concentrations of important second messengers, such as nitric oxide and cytosolic calcium also displayed a marked increased in the RAM region during the ageing. Additionally, it was noticed that the auxin polar transport represents an important positional signal for the maintenance of the RAM characteristics and functions, once treatments that blocked the transport of this hormone promoted the MAR competence acquisition even in young plants, although, the conversion process did not complete while the root tips were maintained attached to the plants. The treatment of young plants with ethylene, on the contrary, caused similar effects; however, besides inducing the competence, this hormone also promoted the RAM conversion into buds via the elevation in the endogenous levels of cytokinins. The treatment of young root tips with different types of cytokinins indicated that iP-type cytokinins (iP and iPR) were more closely associated to the preservation of the root characteristics, while the Z-type cytokinins (Z and ZR) showed a higher importance when the root characteristics were lost. Furthermore, the treatment of young root apices with compounds that cause alterations in the cellular redox status indicated that the oxidative stress stimulated the competence acquisition for the RAM conversion into buds. This same tendency was observed with the application of relatively high concentrations of compounds that induce elevations in the levels of nitric oxide and cytosolic calcium in the tissues. The analyses carried out during the first hours after the isolation of partially competent root apices indicated that the detachment of the root tips from the original plants accelerated the morphological modifications that naturally occur at advanced stages of ageing. During this same period, it was observed a rapid decrease in the endogenous levels of cytokinins (specially of the iP-type), leading to a predominance of the Z-type cytokinins during the first day after the isolation of the explants, which coincided with the alteration of the RAM architecture from the intermediate-open type to the completely open type. After the first day of isolation, the progress in the root apices modifications resulted in the establishment of the shoot meristem, which was accompanied by an elevation in the endogenous levels of cytokinins and ascorbate. Therefore, advanced stages of root ageing, as well the isolation of the partially competent root apices, seem to increase the competence for the RAM conversion into buds via similar morphological and physiological changes in the root apices. These alterations involved the loss of the root characteristics, which possibly resulted from modifications in the control of the QC on the development of the other cells in the RAM. These events in the QC represent a sine qua non condition for the completion of the MAR competence acquisition, which is affected by the intensity of the perturbations on the control of the RAM organization. Therefore, the conversion of root apical meristem of C. fimbriatum into buds probably results from the formation of a new group of cells in the region of the QC of the altered RAM. These cells seem to be competent to respond to different stimulus that would directionate them to a new developmental route that, in this case, consists in the establishment of a shoot meristem. Hormônios vegetais Meristema apical radicular Organogênese Organogenesis Plant hormones Root apical meristem
47	Mitochondrial complex I dysfunction enhances in vitro plant organogenesis / L'inhibition du complexe I mitochondrial améliore l'organogenèse végétale in vitro Aissa Abdi, Fatima 28 May 2018 (has links) La régénération in vitro est un processus complexe largement utilisé pour la multiplication végétative ainsi qu'en recherche fondamentale pour étudier l'organogenèse. Malgré les diverses applications de la caulogenèse in vitro, les mécanismes de régulation impliqués restent mal caractérisés. Avant le début de mon doctorat, nous avons identifié un mutant d'Arabidopsis thaliana chez lequel un défaut du complexe I de la chaîne de transport d'électrons mitochondriale (CTEm) entraîne une augmentation du taux de régénération comparé au sauvage, mesurée sur des cals issus de protoplastes. Au début de mon projet doctoral, j'ai confirmé le lien entre le dysfonctionnement respiratoire et l'augmentation des taux de régénération en utilisant un inhibiteur spécifique du complexe I appelé roténone. Pour comprendre ce phénomène, j'ai étudié les mécanismes moléculaires et biochimiques liant la respiration mitochondriale et l'organogenèse in vitro. J'ai analysé différents mutants affectés dans l'activité du complexe I et conclu que le retard de croissance qui en découle est positivement corrélé avec le taux de régénération. Pour comprendre comment les perturbations de la CTEm affectent la formation des bourgeons, j'ai comparé les profils d'expression des gènes dans des tissus mutants du complexe I et dans des cals traités avec la roténone. Les résultats obtenus montrent, d’une part, que le profil d’expression des gènes est différent chez le sauvage et chez les mutants du complexe I et, d’autre part, que la roténone induit un stress oxydatif, inhibe la prolifération cellulaire et module les régulations hormonales. J'ai confirmé que la réponse oxydative induite par la roténone est rapidement relayée dans le cytosol en utilisant un bio-senseur de l’état redox cellulaire. Nos résultats suggèrent un lien de causalité entre un stress oxydatif induit par des perturbations respiratoires et la hausse du taux de régénération. Nos travaux pointent vers des méthodes alternatives pour améliorer l'efficacité de l'organogenèse in vitro par inhibition transitoire d'activités mitochondriales. / In vitro shoot regeneration is a complex process routinely used for vegetative propagation and to study plant organogenesis. Despite multiple applications of in vitro shoot initiation, the regulatory mechanisms involved remain poorly understood. Prior to the beginning of my PhD thesis, we identified an Arabidopsis thaliana mutant in which a defect in the complex I of the mitochondrial electron transport chain (mETC) results in a higher shoot regeneration rate compared to wild type, measured on protoplast-derived calli. At the beginning of my PhD project, I confirmed the link between the respiratory defect and the shoot regeneration boost with a specific complex I inhibitor called rotenone. To understand this phenomenon, I investigated the molecular and biochemical mechanisms linking mitochondrial respiration and shoot organogenesis. For this purpose, I analyzed different mutants affected in the complex I activity and concluded that the resulting growth retardation is positively correlated with the regeneration rate. To understand how mETC perturbations promote shoot regeneration, I compared gene expression profiles in complex I mutant tissues and in calli treated with rotenone. Our data show, on the one hand, that gene expression profiles are different in complex I mutants and, on the other hand, that rotenone induces an oxidative stress, inhibits cell proliferation, and modulate hormonal regulations. I confirmed that the oxidative response induced by rotenone is rapidly relayed in the cytosol with a redox- sensitive biosensor. Altogether, our results suggest a causal link between an oxidative stress caused by respiratory impairments and shoot regeneration enhancement. Our findings point to alternative methods to promote in vitro organogenesis via transient inhibition of mitochondrial activities. Arabidopsis thaliana Égénération Stress oxydatif Mitochondrie Bourgeon Arabidopsis thaliana Regeneration Oxydative stress Mitochondria, Shoot meristem
48	The role of LC and FAS in regulating floral meristem and fruit locule number in tomato Chu, Yi-Hsuan January 2017 (has links) No description available. Horticulture Plant Biology Tomato locule number LC FAS CLV3 WUS Near-Isogenic Lines floral meristem
49	Genome scale transcriptome analysis and development of reporter systems for studying shoot organogenesis in poplar Bao, Yanghuan 15 April 2008 (has links) Vegetative propagation allows the amplification of selected genotypes for research, breeding, and commercial planting. However, efficient in vitro regeneration and genetic transformation remains a major obstacle to research and commercial application in many plant species. Our aims are to improve knowledge of gene regulatory circuits important to meristem organization, and to identify genes that might be useful for improving the efficiency of in vitro regeneration. In this thesis, we have approached these goals in two ways. First, we analyzed gene expression during poplar (Populus) regeneration using an AffymetrixGeneChip® array representing over 56,000 poplar transcripts. We have produced a catalog of regulated genes that can be used to inform studies of gene function and biotechnology. Second, we developed a GUS reporter system for monitoring meristem initiation using promoters of poplar homologs to the meristem-active regulatory genes WUSCHEL (WUS) and SHOOTMERISTEMLESS (STM). This provides plant materials whose developmental state can be assayed with improved speed and sensitivity. For the microarray study, we hybridized cDNAs derived from tissues of a female hybrid poplar clone (INRA 717-1 B4, Populus tremula x P. alba) at five sequential time points during organogenesis. Samples were taken from stems prior to callus induction, at 3 days and 5 days after callus induction, and at 3 and 8 days after the start of shoot induction. Approximately 15% of the monitored genes were significantly up-or down-regulated based on both Extraction and Analysis of Differentially Expressed Gene Expression (EDGE) and Linear Models for Microarray Data (LIMMA, FDR<0.01). Of these, over 3,000 genes had a 5-fold or greater change in expression. We found a very strong and rapid change in gene expression at the first time point after callus induction, prior to detectable morphological changes. Subsequent changes in gene expression at later regeneration stages were more than an order of magnitude smaller. A total of 588 transcription factors that were distributed in 45 gene families were differentially regulated. Genes that showed strong differential expression encoded proteins active in auxin and cytokinin signaling, cell division, and plastid development. When compared with data on in vitro callogenesis from root explants in Arabidopsis, 25% (1,260) of up-regulated and 22% (748) of down- regulated genes were in common with the genes that we found regulated in poplar during callus induction. When ~3kb of the 5' flanking regions of close homologs were used to drive expression of the GUSPlus gene, 50 to 60% of the transgenic events showed expression in apical and axillary meristems. However, expression was also common in other organs, including in leaf veins (40% and 46% of WUS and STM transgenic events, respectively) and hydathodes (56% of WUS transgenic events). Histochemical GUS staining of explants during callogenesis and shoot regeneration using in vitro stems as explants showed that expression was detectable prior to visible shoot development, starting 3 to 15 days after explants were placed onto callus inducing medium. Based on microarray gene expression data, a paralog of poplar WUS was detectably up-regulated during shoot initiation, but the other paralog was not. Surprisingly, both paralogs of poplar STM were down-regulated 3- to 6-fold during early callus initiation, a possible consequence of its stronger expression in the secondary meristem (cambium) than in shoot tissues. We identified 15 to 35 copies of cytokinin response regulator binding motifs (ARR1AT) and one copy of the auxin response element (AuxRE) in both promoters. Several of the WUS and STM transgenic events produced should be useful for monitoring the timing and location of meristem development during natural and in vitro shoot regeneration. / Graduation date: 2008 Populus in vitro shoot organogenesis transcriptome auxin cytokinin transformation regeneration WUS STM meristem secondary meristem cambium promoter stem cells Poplar -- Genetics Poplar -- Regeneration Poplar -- Growth -- Regulation Plant genetic regulation Plant hormones Meristems
50	Studies on Molecular Targets and Pathways Regulated by Rice RFL for Flowering Transition and Panicle Development Goel, Shipra January 2016 (has links) (PDF) LFY of Arabidopsis is a member of a unique plant specific transcription factor family. It is involved in giving meristem a determinate floral fate by the activation of floral organ identity genes and preventing inflorescence meristem identity. RFL is a homolog of FLO/LFY in rice. Studies from our lab on rice RFL, based on the effects of knockdown or overexpression, showed its major functions are in timing the conversion of SAM to IM and to prevent the premature conversion of branch meristem to spikelets. Additionally roles in vegetative axillary meristem specification have been also been identified in laboratory. Here, we attempt to delineate molecular pathways directly regulated by RFL as a transcription factor controlling inflorescence and floral development in rice. Part I: Identification of global target genes bound by RFL in developing rice inflorescences We carried out ChIP sequencing of the DNA bound by RFL in panicles (01.-0.3cm stage) using anti-RFL antibody. DNA sequences in one library pool were analyses by the MACS algorithm (FDR<0.01), to find 8000 binding sites while the SPP algorithm identified 5000 enriched peaks. These mapped to 2500 or 2800 gene-associated loci respectively, 617 of which were common loci to both pipelines. Several RFL bound gene loci were homologs of Arabidopsis thaliana LFY gene targets. Such gene targets underscore conserved downstream targets for LFY-proteins in evolutionarily very distinct species. AtLFY is known to bind variants of CCANT/G cis element classified as primary, inflorescence or seedling type. We scanned for these three types of cis elements at 123 RFL bound genes with likely functions in flowering. For a few of these 123 rice loci we find one of these cis motifs (p-value<0.001) in RFL bound ChIP-seq data. To validate these targets of RFL, we adopted in vitro DNA-protein binding assays with bacterially purified RFL protein. We confirm RFL target interactions with some genes implicated in flowering time, others in photoperiod triggered flowering, circadian rhythm, gibberellin hormone pathway, inflorescence development and branching. The in vitro experiments hint different RFL-DNA binding properties as compared to Arabidopsis LFY. We report binding to sequences at rice gene loci that are unique targets. Part II: Pathways regulated by RFL for reproductive transition and panicle development To co-relate DNA binding of RFL to target loci with changes in their gene expression, expression studies were taken up for selected set of genes implicated in rice flowering transition and panicle architecture. To study in planta and tissue specific gene regulation by RFL we raised RFL dsRNAi transgenics. Comparative transcript analysis in these RFL partial knockdown lines and matched wild type tissues reveal that RFL is an activator for some genes and repressor for other gene targets. We also examined if the gene expression effects of RFL knockdown can be reversed by induced complementation with an RFL-GR protein. We raised transgenics plants with a T-DNA ubi:RFL-GR, 35S CaMV:amiR RFL for these experiments. In planta target gene transcript levels were assessed in various conditions conditions. These studies validate rice RFL as an activator of some panicle architecture genes. Part III: Analysis of endogenous RFL protein in WT rice tissues Studies in Arabidopsis and in petunia with LFY and AFL, respectively, implicate these some abnormal mobility as compared to their predicted molecular weight when overexpressed. We studied endogenous RFL protein abundance in planta, adopting western analysis with anti-RFL antibody. We consistently identify two prominent cross reacting bands in different tissues which can be also be pulled-down from whole nuclear extracts of panicle and axillary meristem tissues. We speculate on likely modifications and possible functions for the same. Rice RFL Flowering Transition Rice Inflorescences Axillary Meristem Rice Floral Development Rice Panicle Development Arabidopsis thaliana LFY RFL-Rice FLO-LFY Homolog Genetc Transcription Regulation Inflorescence Meristem Vegetative Axillary Meristems Cell Biology

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