Global ETD Search

11	Quantitative Analyse der Beteiligung genetisch verschiedener internaler Sprossscheitelschichten (L2, L3) an der Bildung des Blattmesophylls Monteiro, Octave William Ademola 31 July 2002 (has links) Die vorliegende Arbeit liefert neue Kenntnisse über das Konkurrenzverhalten der Sprossscheitelschichten bei der Blattmesophyllbildung und trägt dadurch zum Verständnis der Entwicklungsgeschichte höherer Pflanzen bei. Weißbunte Pflanzen von Peperomia serpens SW. LOUD, Sedum rubrotinctum R. T. CLAUSEN, Pedilanthus tithymaloides (L.) POIT. und Plectranthus coleoides BENTH wurden verwendet, um den Bau des Sprossscheitels und die chimärische Natur des Laubblattes zu analysieren. Durch die Untersuchungen zum Bau des Sprossscheitels und zur Blattanatomie wurden die Anzahl initialer Sprossscheitelschichten und die periklinalchimärische Natur der untersuchten Pflanzen bestätigt. Mit Hilfe von Mittelwertvergleichen der Mächtigkeit L2- und L3-bürtiger Mesophyllgewebe wurde die Beteiligung genetisch verschiedener internaler Sprossscheitelschichten an der Bildung des Blattmesophylls bei Sedum rubrotinctum, Pedilanthus tithymaloides und Peperomia serpens erfasst. Die Existenz histogenetisch grüner L2- oder L3-bürtiger Gewebe verursacht eine Zunahme der Blattquerschnittfläche (Sedum rubrotinctum) und eine Vergrößerung der Blattmesophyllhöhe (Peperomia serpens und Pedilanthus tithymaloides). Es wurden Regenerationsversuche an Blattstecklingen der Periklinalchimäre von Peperomia serpens und Sedum rubrotinctum durchgeführt. Durch In-vivo-Provozierung von Adventivsprossen an Blattstücken und achselknospenfreien Sprossen gelang es, die zwei untersuchten heterohistischen Musterpflanzen von Peperomia serpens ('GGW' und 'GWG') in grüne und weiße Nachkommen zu zerlegen. An Blattstecklingen bildeten sich in der Mehrzahl L3-bürtige Regenerate (ca. 75 %). Eine Beteiligung der L2-bürtigen Gewebe bei der Regeneration war an den Blattrandexplantaten zu beobachten. Das L1-bürtige Hypoderm konnte nur in der In-vitro-Blattregeneration deutlich seine Fähigkeit zur Adventivsprossbildung zeigen. Die Blattregenerationsergebnisse bei Peperomia serpens demonstrieren deutlich, dass sich alle drei Sprossscheitelschichten (L1, L2, L3) an der Blattmesophyllbildung beteiligen können. An Blattstecklingen von Periklinalchimären bei Sedum rubrotinctum bildeten sich grüne, weiße und neue chimärische Adventivsprosse. Aus den Regenerationsergebnissen lässt sich die entscheidende Rolle der L2-bürtigen Gewebe bei der Adventivsprossbildung ablesen. Die Regenerationsergebnisse sprechen dafür, dass die Bildung der Adventivsprosse durch die Beteiligung der L2- und L3-bürtigen Gewebe hervorgerufen wurde und die L1-bürtigen Gewebe an der Adventivsprossbildung nicht beteiligt sein konnten. Demzufolge sind tiefer liegende Gewebe (L2- und L3-bürtige) des Laubblattes beider Arten bei der Bildung der Adventivsprosse entscheidender als die L1-bürtige Epidermis. Das Ausmaß der Beteiligung an der Adventivsprossbildung bei Peperomia serpens und Sedum rubrotinctum wird nicht von der genetischen Herkunft (weiß oder grün) des L2- bzw. L3-bürtigen Gewebes gesteuert, sondern durch die Lage und damit durch die Abstammung der Gewebe aus der entsprechenden Sprossscheitelschicht bestimmt. Die abschließenden Untersuchungen an Plectranthus coleoides, dessen Chlorophyll- und Ploidiechimären quantitativ analysiert wurden, verdeutlichen die Erkenntnisse über die Beteiligung der Sprossscheitelschichten an der Bildung des Blattmesophylls. Es wurde deutlich, dass die Gewebekonkurrenz im Beisein einer doppelten Markierung nicht lagebedingt sein kann, sondern aufgrund verschiedener Ploidiestufen stattfindet. / The studies presented in this thesis provide new insights into the competitive reaction of the shoot apical layers during the foliar mesophyll formation and thus contribute to understanding of plant development. The variegated plants of Peperomia serpens SW. LOUD, Sedum rubrotinctum R. T. CLAUSEN, Pedilanthus tithymaloides (L.) POIT. and Plectranhus coleoides BENTH were used to analyse the cellular organisation of shoot apex and the histogenetic constitution of the leaf. Shoot apex and leaves structural analyses confirm the number of initial shoot apical layers and the periclinal chimeric nature of investigated plants. Quantitative analysis of foliar mesophyll of Sedum rubrotinctum, Peperomia serpens and Pedilanthus tithymaloides have been used to deduce patterns of meristem layers intercellular interaction during mesophyll formation. The expression of the histogenetic green meristem layer (L2 or L3) causes a increase of "mesophyll area" (Sedum rubrotinctum) and a enlargement of "mesophyll height" (Peperomia serpens and Pedilanthus tithymaloides) in leaves. Four periclinal chimeric forms of Peperomia serpens ('GGW' and 'GWG') and of Sedum rubrotinctum ('GGW' and 'GWG'), each of which possesses normal green cell layers but a genetically different chlorophyll-deficient cell layer, were utilized to study the effect of genotype on the ability of the cell layers of in vivo and in vitro leaf cutting to regenerate adventitious shoots and to analyse the competition between apical layers and their derivatives in the plant ontogeny. Among the in vivo adventitious shoots of the leaf cuttings and leaf of Peperomia serpens, shoots were green, white and variegated. The L3-derived cell layer is alone responsible for the formation of ca. 75 % of adventitious shoots. The relative significant contribution of L2-derived cell layers to mesophyll formation increases in margin of leaf. The L1-derived hypoderm in foliar mesophyll of Peperomia serpens were apparently incapable of shoot regeneration of in vivo leaf cutting, yet in both periclinal forms clearly produced green shoots in vitro. Results demonstrate that all initial apical meristem layers in Peperomia serpens can contribute with different ability to foliar mesophyll formation. Adventitious shoots were in vivo induced on leaf of periclinal chimeric plants of Sedum rubrotinctum. Plants derived from leaf culture were three types: green, white and variegated. Among the adventitious shoots of green- and white-margined leaf of Sedum rubrotinctum, most adventitious shoots (ca. 90 %) were L2-derived, a few were L3-derived. Results demonstrate that the L1 derivatives can not contribute to foliar mesophyll formation. According to these results the internal tissues (L2- and L3-derived cell layers) of leaf are more competitive than the epidermis. The lineage of adventitious shoot is not controlled by the genetic origin of L2- and L3-derived tissues, but by the position of these derived tissues according to the shoot apical meristem layer. The last experiments on Plectranthus coleoides which have combined quantitative analysis of variegated- leaf chimeras with quantitative analysis of cytochimeras have begun to shed more light on the contribution of apical meristem layers to foliar mesophyll formation. It has revealed how the ploidy degree of apical layers derivatives in a cytochimera control leaf cell fate more than their position in the meristem. Chimäre Sprossscheitel Blattmesophyllbildung Gewebekonkurrenz Adventivsprossbildung Shoot apical meristem Mesophyll formation Tissue competition Chimera Adventitious shoot formation 630 Landwirtschaft, Veterinärmedizin 39 Landwirtschaft, Garten ZC 23500 ddc:630
12	Caractérisation du lien entre croissance et patterning dans la morphogenèse chez Arabidopsis / Linking patterning to growth changes during morphogenesis in Arabidopsis shoot meristem Landrein, Benoit 14 March 2014 (has links) Le contrôle moléculaire du patterning au cours des processus développementaux est aujourd’hui bien décrit chez les organismes multicellulaires. A l’inverse, la contribution de la croissance dans l’émergence des patterns reste peu explorée, et est souvent réduite à un rôle passif. Au cours de cette thèse, j’ai étudié cette question en utilisant le méristème apical caulinaire (MAC) d’Arabidopsis comme modèle. Le méristème est un groupe de cellules en divisions situé à l’extrémité de toutes les tiges et les branches et qui génère tous les organes aériens de la plante selon un patron stéréotypé, aussi appelé phyllotaxie. Dans une première partie, j’ai étudié comment la croissance de la tige pouvait influencer le patron phyllotactique. Plus précisément, en découplant dépôt de la cellulose dans la paroi et l’orientation des microtubules, j’ai montré que le patron de phyllotaxie devenait bimodal en raison de l’induction d’une torsion lors de la croissance de la tige. Dans une seconde partie, j’ai analysé le lien entre forme du MAC et expression génétique. En particulier, j’ai pu corréler l’expression d’un gène maître : SHOOTMERISTEM LESS (STM) au degré de courbure dans le MAC. De plus, en utilisant des approches de micromécaniques, j’ai aussi pu montrer que l’expression de STM pouvait être induite par le patron de contraintes localement généré par la courbure. Pour finir, j’ai aussi étudié comment la taille du méristème influence la robustesse du pattern de phyllotaxie sur la tige en modulant la fréquence d’initiation des organes. L’ensemble de ce travail met ainsi en avant le rôle de la croissance dans le patterning, notamment via des mécanismes de rétrocontrôles géométriques et mécaniques. / The molecular mechanisms behind the emergence of patterns during developmental processes have been well described in multicellular organisms. However, the contribution of growth in patterning is still poorly understood; growth is often seen as a passive output of the activity of the patterning signals. In this PhD, I have studied the relation between growth and patterning using the shoot apical meristem of Arabidopsis as a model system. The meristem is a group of dividing cells located at the tip of every stems and branches that generates all the aerial organs of the plant following a typical spatio-temporal pattern also called phyllotaxis. In a first part, the influence of post-meristematic growth on phyllotaxis was assessed. More precisely, by uncoupling cellulose deposition from the orientation of the microtubule array, I showed that the resulting stem torsion induces the emergence of a new and robust bimodal phyllotactic pattern. In a second part, the relation between meristem shape and gene expression was analyzed. More precisely, I correlated the expression of a master regulatory gene: SHOOT MERISTEMLESS (STM) to tissue curvature in the boundary domain that separates the emerging organ from the meristem. Furthermore, I showed that STM expression can be induced by micromechanical perturbations thus suggesting that shape-derived mechanical stresses in the meristem boundary contribute to STM expression. Finally, I also studied how meristem size can influence the robustness of the pattern of phyllotaxis along the stem through a modulation of the frequency of organ initiation. Altogether, this work highlights the important contribution of growth in patterning, notably thanks to the existence of geometrical and mechanical feedbacks. Développement des plantes Patterning Croissance Stress mécanique Méristème apical caulinaire Phyllotaxie Paroi végétale Plant development Patterning Growth Mechanical stress Shoot apical meristem Phyllotaxis Plant cell wall 570
13	A Morphological and Anatomical Investigation of Shoot Apical Meristems Expressing Ring Fasciation in Clarkia tembloriensis TysonMayer, Kilian 26 November 2019 (has links) No description available. Botany Biology Plant Biology Plant Sciences fasciation Clarkia tembloriensis ring fasciation shoot apical meristem scanning electron microscopy light microscopy morphology anatomy
14	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. info:eu-repo/classification/ddc/570 ddc:570
15	Microarray Analysis of Differential Expression of Genes in Shoot Apex and Young Leaf of English Ivy (<i>Hedera helix</i> L. cv. Goldheart) Shin, Seung-Geuk 15 July 2010 (has links) No description available. Bioinformatics microarray analysis cross-species hybridization shoot apical meristem shoot apex Hedera helix Goldheart variegated ivy electronic Northerns eNorthern electronic fluorescent pictograph eFP GeneSpring shoot development
16	Contrôle épigénétique de la plasticité de l’appareil végétatif du peuplier en réponse à des variations de la disponibilité en eau / Epigenetic control of shoot phenotypic plasticity towards variations in water availability in poplar Lafon Placette, Clément 21 December 2012 (has links) Au vu de l’impact croissant du changement climatique global et en particulier de la sécheresse sur les forêts, il est nécessaire de comprendre les mécanismes de réponse des arbres face à des variations de disponibilité en eau. Ces dernières années, des études ont montré un contrôle épigénétique et notamment par la méthylation de l’ADN de la plasticité phénotypique des plantes en réponse aux variations environnementales. Dans ce contexte, cette thèse visait à évaluer le rôle de la méthylation de l’ADN des cellules du méristème apical caulinaire dans la plasticité développementale de la tige feuillée en réponse à des variations de disponibilité en eau chez le peuplier, un arbre modèle. A cette fin, le méthylome de la chromatine non condensée dans le méristème apical caulinaire de Populus trichocarpa a été caractérisé. Ensuite, l’impact de variations de disponibilité en eau sur la méthylation de l’ADN a été étudié dans l’apex caulinaire de différents hybrides (P. × euramericana). Les loci et les réseaux de gènes affectés pour leur expression et leur méthylation ont ainsi été identifiés. Ces travaux ont montré que dans le méristème apical caulinaire, la majorité des gènes étaient dans un état non condensé de la chromatine et méthylés dans leur corps. Ils ont également mis en évidence une forte variation de la méthylation globale de l’ADN selon les génotypes et en réponse à des variations de disponibilité en eau. De plus, des corrélations ont été établies entre les niveaux de croissance des arbres et de méthylation globale de l’ADN dans l’apex caulinaire. Enfin, les variations de la méthylation de l’ADN en réponse aux variations de la disponibilité en eau s’accompagnent de variations d’expression et ont ciblé particulièrement des gènes impliqués dans la signalisation par les phytohormones ou la morphogenèse. Ainsi, les travaux effectués lors de cette thèse suggèrent un rôle de la méthylation de l’ADN dans la plasticité phénotypique en réponse à des variations de disponibilité en eau chez le peuplier via le contrôle de l’expression de réseaux de gènes dans le méristème apical caulinaire. / Predicted climate changes and particularly drought represent a major threat to forest health. Therefore, understanding mechanisms that control trees response to variations in water availability is of great interest. These last years, epigenetic marks such as DNA methylation have been involved in plant phenotypic plasticity in response to environmental stresses. In this context, this work aimed at assessing the role of shoot apical meristem cells DNA methylation in the shoot developmental plasticity towards variations in water availability in poplar, a model tree. For this purpose, the methylome of non condensed chromatin in Populus trichocarpa shoot apical meristem was characterized. Then, the impact of variations in water availability on shoot apex DNA methylation in different hybrids (P. × euramericana) was studied. Loci and gene networks affected by DNA methylation and expression changes were thus identified. This work showed that in shoot apical meristem, most of the genes was in non condensed chromatin state with DNA methylation in their body. A strong variation in DNA methylation depending on genotypes and water availability was highlighted. Moreover, correlations between trees growth and shoot apex DNA methylation levels were established. Lastly, DNA methylation changes in response to variations in water availability correlated to expression variations were identified for genomic loci and gene networks. Thus, the work performed during this thesis suggests a role for DNA methylation in poplar phenotypic plasticity in response to variations in water availability through the control of gene networks transcription in the shoot apical meristem. Chromatine Disponibilité en eau Epigénétique Expression de gènes Méristème apical caulinaire Méthylation de l’ADN Morphogenèse Peuplier Plasticité phénotypique Sécheresse Variabilité génotypique Chromatin Water availability Epigenetics Gene expression Shoot apical meristem DNA methylation Morphogenesis Poplar Phenotypic plasticity Drought Genotypic variability
17	Genetic And Biochemical Studies On Genes Involved In Leaf Morphogenesis Aggarwal, Pooja 02 1900 (has links) Much is known about how organs acquire their identity, yet we are only beginning to learn how their shape is regulated. Recent work has elucidated the role of coordinated cell division & expansion in determining plant organ shape. For instance, in Antirrhinum, leaf shape is affected in the cincinnata (cin) mutant because of an alteration in the cell division pattern. CIN codes for a TCP transcription factor and controls cell proliferation. It is unclear how exactly CIN-like genes regulate leaf morphogenesis. We have taken biochemical and genetic approach to understand the TCP function in general and the role of CIN-like genes in leaf morphogenesis in Antirrhinum and Arabidopsis. Targets of CINCINNATA To understand how CIN controls Antirrhinum leaf shape, we first determined the consensus target site of CIN as GTGGTCCC by carrying out RBSS assay. Mutating each of this target sequence, we determined the core binding sequence as TGGNCC. Hence, all potential direct targets of CIN are expected to contain a TGGNCC sequence. Earlier studies suggested that CIN activates certain target genes that in turn repress cell proliferation. To identify these targets, we compared global transcripts of WT and cin leaves by differential display PCR and have identified 18 unique, differentially expressed transcripts. To screen the entire repertoire of differentially expressed transcripts, we have carried out extensive micro-array analysis using 44K Arabidopsis chips as well as 13K custom-made Antirrhinum chips. Combining the RBSS data with the results obtained from the micro-array experiments, we identified several targets of CIN. In short, CIN controls expression of the differentiation-specific genes from tip to base in a gradient manner. In cin, such gradient is delayed, thereby delaying differentiation. We also find that gibberellic acid, cytokinin and auxin play important role in controlling leaf growth. Genetic characterization of CIN-homologues in Arabidopsis Arabidopsis has 24 TCP genes. Our work and reports from other groups have shown that TCP2, 4 and 10 are likely to be involved in leaf morphogenesis. These genes are controlled by a micro RNA miR319. To study the role of TCP4, the likely orthologue of CIN, we generated both stable and inducible RNAi lines. Down-regulation of TCP4 transcript resulted in crinkly leaves, establishing the role of TCP4 in leaf shape. To study the function of TCP2, 4 & 10 in more detail, we isolated insertion mutants in these loci. The strongest allele of TCP4 showed embryonic lethal phenotype, indicating a role for TCP4 in embryo growth. All other mutants showed mild effect on leaf shape, suggesting their redundant role. Therefore, we generated and studied various combinations of double and triple mutants to learn the concerted role of these genes on leaf morphogenesis. To further study the role of TCP4 in leaf development, we generated inducible RNAi and miRNA-resistant TCP4 transgenic lines and carried out studies with transient down-regulation and up-regulation of TCP4 function. Upon induction, leaf size increased in RNAi transgenic plants whereas reduced drastically in miR319 resistant lines, suggesting that both temporal & spatial regulation of TCP4 is required for leaf development. Biochemical characterization of TCP domain To study the DNA-binding properties of TCP4, random binding site selection assay (RBSS) was carried out and it was found that TCP4 binds to a consensus sequence of GTGGTCCC. By patmatch search and RT-PCR analysis, we have shown that one among 74 putative targets, EEL (a gene involved in embryo development), was down regulated in the RNAi lines of TCP4. This suggests that EEL could be the direct target of TCP4. We have tested this possibility in planta by generating transgenic lines in which GUS reporter gene is driven by EEL upstream region with either wild type or mutated TCP4 binding site. GUS analysis of embryos shows that transgenic with mutated upstream region had significantly reduced reporter activity in comparison to wild type, suggesting that EEL is a direct target of TCP4. We have further shown that TCP4 also binds to the upstream region of LOX2, a gene involved in Jasmonic acid (JA) biosynthesis (in collaboration with D. Weigel, MPI, Tubingen, Germany). TCP domain has a stretch of basic residues followed by a predicted helix-loop-helix region (bHLH), although it has little sequence homology with canonical bHLH proteins. This suggests that TCP is a novel and uncharacterized bHLH domain. We have characterized DNA-binding specificities of TCP4 domain. We show that TCP domain binds to the major groove of DNA with binding specificity comparable to that of bHLH proteins. We also show that helical structure is induced in the basic region upon DNA binding. To determine the amino acid residues important for DNA binding, we have generated point mutants of TCP domain that bind to the DNA with varied strength. Our analysis shows that the basic region is important for DNA binding whereas the helix-loop-helix region is involved in dimerization. Based on these results, we have generated a molecular model for TCP domain bound to DNA (in Collaboration with Prof. N. Srinivasan, IISc, Bangalore). This model was validated by further site-directed mutagenesis of key residues and in vitro assay. Functional analysis of TCP4 in budding yeast To assess TCP4 function in regulation of eukaryotic cell division, we have introduced TCP4 in S. cerevisiae under the GAL inducible promoter. TCP4 induction in yeast cells always slowed down its growth, indicative of its detrimental effect on yeast cell division. Flow cytometry analysis of synchronized cells revealed that TCP4 arrests yeast cell division specifically at G1→S boundary. Moreover, induced cells showed distorted cell morphology resembling shmoo phenotype. Shmooing is a developmental process which usually happened when the haploid cells get exposed to the cells of opposite mating type and get arrested at late G1 phase due to the inhibition of cdc28-cln2 complex. This suggested that TCP4-induced yeast cells are arrested at late G1 phase probably by the inhibition of cdc28-cln2 complex. To further investigate how TCP4 induce G1→S arrest, we carried out microarray analysis and found expression of several cell cycle markers significantly altered in TCP4-induced yeast cells. Studies on crinkly1, a novel leaf mutant in Arabidopsis To identify new genes involved in leaf morphogenesis, we have identified crinkly1 (crk1), a mutant where leaf shape and size are altered. We observed that crk1 also makes more number of leaves compared to wild type. Phenotypic analysis showed that crk1 leaf size is ~5 times smaller than that of wild type. Scanning electron microscopy (SEM) showed that both cell size and number are reduced in the mutant leaf, which explains its smaller size. We have mapped CRK1 within 3 cM on IV chromosome. Leaf (plants) - Genetics Leaf (Plants) - Morphogenesis Leaf (plants) - Biochemistry Leaf (Plants) - Genes Crynkly1-Leaf Mutant TCP Genes Shoot Apical Meristem (SAM) Antimicrobial Peptides CINCINNATA (cin) Gene Antirrhinum Majus - Leaf Morphogenesis TCP Transcription Plant Biology
18	Contribution of mechanical stress to cell division plane orientation at the shoot apical meristem of Arabidopsis thaliana / Rôle des contraintes mécaniques dans l'orientation du plan de division des cellules du méristème apical caulinaire d'Arabidopsis thaliana Louveaux, Marion 02 October 2015 (has links) La morphogenèse des plantes repose sur deux mécanismes cellulaires : la division et l'élongation. Par ailleurs, la croissance est source de contraintes mécaniques qui affectent les cellules et guident la morphogenèse. Si les contraintes mécaniques influencent l'orientation du plan de division dans les cellules animales, rien n'est prouvé pour les cellules végétales. À l'heure actuelle, la forme de la cellule est proposée comme le facteur principal gouvernant l'orientation du plan dans les divisions symétriques : les cellules se divisent selon un des plans les plus courts. Cette règle géométrique a été validée dans des tissus à croissance ou courbure isotropes, mais les mécanismes moléculaires sous-jacents demeurent inconnus. Dans cette thèse, un pipeline a été mis au point pour analyser les divisions cellulaires dans les différents domaines du méristème apical caulinaire d'Arabidopsis thaliana et questionner l'application de la règle géométrique dans ce tissu. La zone frontière du méristème présente une proportion anormalement basse de plans de division très courts. Des simulations de tissus en croissance, dans lesquelles une règle de division mécanique a été implémentée, ont montrées le même biais sur les orientation des plans, comparé à la règle géométrique. Des ablations laser de quelques cellules de l'épiderme ont également été effectuées afin de perturber localement le patron de contraintes mécaniques. Les résultats montrent que l'orientation du plan des divisions postérieures à cette perturbation suit le nouveau patron de contraintes. Enfin, une nouvelle méthode quantitative, basée sur l'utilisation d'un micro-indenteur, a été mise au point pour quantifier la réponse du cytosquelette, et en particulier des microtubules, aux contraintes mécaniques. Le protocole de compression a été testé et validé sur les mutants katanin et spiral2, dans lesquels la réponse aux contraintes est respectivement faible ou amplifiée. / Morphogenesis during primary plant growth is driven by cell division and elongation. In turn, growth generates mechanical stress, which impacts cellular events and channels morphogenesis. Mechanical stress impacts the orientation of division plane in single animal cells; this remains to be fully demonstrated in plants. Currently, cell geometry is proposed to be the main factor determining plane orientation in symmetric divisions: cell divide along one the shortest paths. This geometrical rule was tested on tissues with rather isotropic shapes or growth and the corresponding molecular mechanism remains unknown, although it could involve tension within the cytoskeleton. To address these shortcomings, we developed a pipeline to analyze cell divisions in the different domains of the shoot apical meristem of Arabidopsis thaliana. We computed the probability of each possible planes according to cell geometry and compared the output to observed orientations. A quarter of the cells did not follow the geometrical rule. Boundary domain was enriched in long planes aligned with supracellular maximal tension lines. Computer simulations of a growing tissue following a division rule that relies on tension gave the most realistic outputs. Mechanical perturbations of local stress pattern, by laser ablations, further confirmed the importance of mechanical stress in cell division. To explore the role of microtubules in this process, we developed a microindenter-based protocol to quantify the cytoskeletal response to mechanical stress. This protocol was tested and validated in the katanin and spiral2 mutants, in which the response to stress is delayed or promoted respectively. Morphogenèse Cellules végétales -- Division Méristèmes apicaux Méristème apical caulinaire Arabidopsis thaliana Contraintes (mécanique) Biologie du développement Microtubules Anneau de préprophase Traitement d'images Morphogenesis Cell division Shoot apical meristem Arabidopsis thaliana Mechanical stress Developmental biology Microtubules Preprophase band Image analysis
19	Division et élongation cellulaire dans l'apex de la racine : diversité de réponses au déficit hydrique / Cell division and cell elongation in the growing root apex : diversity of drought-induced responses Bizet, François 10 December 2014 (has links) La capacité d’une plante à réguler sa croissance racinaire est une composante importante de l’acclimatation aux stress environnementaux. A l’échelle cellulaire, cette régulation est effectuée via le contrôle de la division et de l’élongation des cellules mais les rôles respectifs de chaque processus et leurs interactions sont peu connus. Notamment, l’activité de production de cellules du méristème apical racinaire (RAM) est trop souvent négligée. Dans cette thèse, l’analyse spatiale de la croissance le long de l’apex racinaire et l’analyse temporelle des trajectoires de croissance des cellules ont été couplées pour comprendre les liens existants entre division et élongation cellulaire. Pour cela, j’ai développé un système de phénotypage de la croissance à haute résolution spatio-temporelle qui a été appliqué à l’étude de racines d’un peuplier euraméricain (Populus deltoides × Populus nigra) en réponse à différents stress (stress osmotique, impédance mécanique). Une forte variabilité du taux de croissance racinaire entre individus ainsi que des variations individuelles cycliques de la croissance ont été observées malgré des conditions environnementales contrôlées. L’utilisation de cette variabilité couplée à la quantification de l’activité du RAM a mis en évidence l’importance du taux de production de cellules pour soutenir la croissance racinaire. Ces travaux analysent une nouvelle échelle de variations spatiales et temporelles de la croissance peu prise en compte jusqu’à présent. Hautement applicable à d’autres questions scientifiques, l’analyse du devenir des cellules une fois sortie du RAM est également discutée pour des conditions de croissance non stables / Regulation of root growth is a crucial capacity of plants for acclimatization to environmental stresses. At cell scale, this regulation is controlled through cell division and cell elongation but respective importance of these processes and interactions between them are still poorly known. Notably, the cell production activity of the root apical meristem (RAM) is often excluded. During this thesis, spatial analyses of growth along the root apex were coupled with temporal analyses of cell trajectories in order to decipher the links between cell division and cell elongation. This required the setup of a system for phenotyping root growth at a high spatiotemporal resolution which was applied to study the growth of roots from an euramerican poplar (Populus deltoides × Populus nigra) in response to different environmental stresses (osmotic stress or mechanical impedance). An important variability of root growth rate between individuals as well as individual cyclic variations of growth along time were observed despite tightly controlled environmental conditions. Use of this variability coupled with quantification of the RAM activity led us to a better understanding of the importance of the cell production rate for sustaining root growth. This work analyses a new spatiotemporal scale of growth variability poorly considered. Widely applicable to others scientific questioning, temporal analyses of cell fate once produced in the RAM is also discussed for non-steady growth conditions 3D Cinématique Croissance racinaire Division cellulaire Élongation cellulaire Impédance mécanique Infrarouge Méristème apical racinaire Peuplier Stress osmotique Trajectoire de croissance 3D Cell division Cell elongation Growth trajectory Infrared Kinematics Mechanical impedance Osmotic stress Poplar Root apical meristem Root growth 575.76
20	Etude du rôle de AHP6 dans le contrôle de la phyllotaxie chez la plante modèle Arabidopsis thaliana : robustesse et coordination spatio-temporelle au cours du développement de structures auto-organisées / Study of the role of AHP6 in the control of phyllotaxis in Arabidopsis thaliana : robustness and spatio-temporal coordination in the development of self-organized organisms Besnard, Fabrice 21 October 2011 (has links) En se développant, les plantes produisent des organes le long des tiges suivant des organisations stéréotypées, appelées phyllotaxies. Ces structures se forment dans les méristèmes, qui abritent une niche de cellules souches : les organes y sont produits successivement et leur positionnement dépendrait d'interactions dynamiques avec les organes pré-existants. Ces interactions seraient notamment dues à des champs inhibiteurs générés par le transport polaire de l'hormone végétale auxine. Afin de rechercher si d'autres facteurs que l'auxine contrôlent la phyllotaxie chez Arabidopsis thaliana, nous nous sommes intéressés au rôle possible des cytokinines, une autre hormone végétale. Nous avons développé des nouvelles méthodes statistiques pour analyser la structure de la phyllotaxie. Cette approche nous a permis d'identifier des anomalies de phyllotaxie chez des plantes mutantes pour le gène AHP6 (ARABIDOPSIS HISTIDINE PHOSPHOTRANSFER protein 6), un inhibiteur de la signalisation des cytokinines. Notre analyse suggérait des possibles perturbations du plastochrone, la période de temps séparant l'initiation de deux organes, ce que nous avons alors confirmé par imagerie confocale en temps réel. Nos données montrent que AHP6 contrôle la régularité du plastochrone, et suggèrent que les perturbations de phyllotaxies sont dues à l'initiation simultanée de deux à trois organes dans le méristème. De plus, AHP6 est exprimé dans les organes et sa protéine établit des champs qui inhibent la signalisation des cytokinines au delà des organes. Pour mieux comprendre les rôles possibles de ces champs, nous avons généré un modèle numérique théorique de la phyllotaxie. Notre étude suggère que le plastochrone pourrait être déstabilisé par du bruit affectant le seuil d'activation nécessaire aux cellules méristématiques pour se différencier en organe. Des champs inhibiteurs pourraient filtrer les effets de ce bruit en influant sur la cinétique d'émergence des organes. Les propriétés observées des champs de AHP6 sont en accord avec ce modèle et nos données expérimentales suggèrent en effet que AHP6 et les cytokinines peuvent moduler la signalisation auxine lors de l'émergence des organes. Nous proposons comme modèle que le transport et la signalisation de l'auxine positionnent de manière robuste les organes mais génèrent un plastochrone irrégulier en présence de bruit. Des champs inhibiteurs de cytokinines stabiliseraient le plastochrone, assurant un couplage plus robuste entre le temps et l'espace lors de l'établissement de la phyllotaxie. / During development, plant aerial organs are produced along the stems following stereotyped patterns. This so-called phyllotaxis is initiated at the shoot meristem, which contains the stem cell niche: organs are produced iteratively and their precise position is thought to depend on dynamic interactions with preexisting organs. These interactions would notably result from inhibitory fields generated by the polar transport of the plant hormone auxin. To investigate whether other factors than auxin regulate phyllotaxis, we studied the potential role of cytokinin signaling. We developed a new pipeline of methods based on statistics to analyze phyllotactic patterns. This approach allowed us to identify phyllotactic perturbations in mutants of the AHP6 (ARABIDOPSIS HISTIDINE PHOSPHOTRANSFER protein 6), an inhibitor of cytokinin signaling that suggested perturbations in the plastochron, the time between two organ initiations. This was further confirmed using confocal live-imaging. We demonstrated that AHP6 controls the regularity of the plastochron, and our results suggest that the defective phyllotaxis in ahp6 is caused by concomitant initiations of two or three organs in the meristem. Interestingly, AHP6 is expressed in organs and the protein can move beyond these domains, generating cytokinin signaling inhibitory fields. To explore further the putative role of these secondary fields, we generated a mathematical model of phyllotaxis. This suggested that plastochron instabilities could be caused by noise affecting the threshold at which meristematic cells are recruited into organs. Inhibitory fields generated by AHP6 could filter out the effect of noise by modifying the kinetics of early organ emergence. Consistently, the properties of AHP6 fields fit the model predictions and our experimental data show that AHP6 and cytokinin modulate auxin signaling during organ emergence. We thus propose a model in which auxin transport and signaling robustly control organ positioning but generates plastochron instablities in noisy backgrounds. In this scenario cytokinin inhibitory fields would stabilize the rhythmicity of organ initiation, ensuring a robust coupling of space and time during pattern formation. Phyllotaxie Méristème apical caulinaire Interactions auxine-cytokinine Arabidopsis Champs inhibiteur Bruit et robustesse Motifs de développement Modèle de systèmes dynamiques Analyses de motifs Phyllotaxis Shoot apical meristem Auxin-cytokinin crosstalk Arabidopsis Inhibitory fields Noise and robustness Developmental pattern Dynamical system model Pattern analysis

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