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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.
11

Endocytosis against the high turgor of guard cells

Meckel, Tobias. Unknown Date (has links)
Techn. University, Diss., 2004--Darmstadt.
12

Funkce komplexu exocyst v regulaci dynamiky průduchů / Functions of Exocyst Complex in the Regulation of Stomata Dynamics

Röder, Matěj January 2016 (has links)
Stomata are structures in plant epidermis which regulate contact between inner and outer environment of the plant by mediating their stomatal aperture. Many inner and outer signals contribute to the ontogenesis of the stomatal pattern. Guard cells undergo significant change of volume and surface during stomatal movement. This change of surface must be compensated by intracellular trafficking of membrane material because biological membrane has limited elasticity. Most of this trafficking takes place between plasma membrane and endosomal compartments. Complex exocyst is protein complex that ensures proper targeting of secretory vesicles to their destination on the plasma membrane. Function of this complex is essential for many cellular processes that require precise targeting of secretion. Mutation in gene Exo70B1 causes different development of the stomatal pattern. Plants with mutated Exo70B1 differ in stomatal size depending on the cultivation conditions more than wild type plant. Protein EXO70B1 is also directly involved in stomatal dynamics because mutants exo70B1 have retarded stomatal opening in response to light. This direct connection can be observed on the fluorescently labeled protein EXOB1 which significantly changes its localization during stomatal movements. None of these observed phenotypes is...
13

Biomechanics of Rhizomorph Development in <i>Armillaria mellea</i>

Yafetto, Levi 11 August 2008 (has links)
No description available.
14

Respostas de pêlos radiculares de tomateiro (Solanum lycopersicum L. cv Micro-Tom) submetidos a estresse por pH baixo e hipo-osmolaridade / Response of tomato (Solanum lycopersicum L. cv Micro-Tom) root hairs to low pH and hypo-osmotic stress

Sardinha, Elissena Chinaglia Zabotto 30 November 2010 (has links)
A acidez do solo é um dos principais fatores limitantes à produção vegetal. A toxicidade por alumínio, que ocorre apenas a pH baixo, tem sido extensamente investigada, enquanto o estresse causado pelo pH baixo tem recebido pouca atenção. Os estudos nesta área quase sempre presumem efeitos aditivos, e portanto independentes, da toxicidade por Al3+ e H+. Este provavelmente não é o caso, sendo que o pH baixo pode ser um fator de predisposição das células ao Al3+. As evidências indicam que o pH baixo causa desarranjos na parede de células em crescimento, gerando estresse que pode comprometer a sua funcionalidade e integridade. É provável que a susceptibilidade a este estresse deve ser dependente da pressão de turgor. Por sua vez, o metabolismo oxidativo e a geração de espécies reativas de oxigênio (ROS) na parede celular podem modular a sua extensibilidade por romper ou criar ligações dentro ou entre cadeias de polissacarídeo. Há grande interesse em se conhecer se, à semelhança do que ocorre em leveduras, as células vegetais possuem um sistema de percepção e resposta a estresse da parede. Os pêlos radiculares em crescimento são sensíveis a pH baixo e estresse hipo-osmótico e constituem um bom modelo experimental para estes estudos. Os objetivos deste trabalho foram: a) Otimizar um sistema experimental para o estudo de pêlos radiculares de tomateiro (Solanum lycopersicum L. cv Micro-Tom); b) Avaliar as respostas dos pêlos radiculares ao estresse por pH baixo e hipo-osmolaridade; c) Examinar o papel da modulação oxidativa da parede celular nestas respostas; e d) Avaliar a resposta de diferentes mutantes hormonais de Micro-Tom a estes fatores de estresse. Os principais parâmetros avaliados foram a taxa de alongamento (µm.min-1) e a freqüência de rompimento dos pêlos. Tanto o estresse por pH baixo quanto choques hipo-osmóticos resultaram em taxas de alongamento significativamente diminuídos e o rompimento de pêlos radiculares, mas os efeitos dos tratamentos hipo-osmóticos foram mais marcantes. Uma curva de resposta frente à osmolaridade da solução externa revelou que a taxa de alongamento aumentou com a diminuição da osmolaridade até alcançar um limiar em que houve redução drástica da taxa de alongamento e começou-se a observar o rompimento de pêlos. Também se observou uma interação entre hipo-osmolaridade e pH baixo. O emprego do inibidor difenileno iodônio não forneceu evidências do envolvimento de NADPH oxidases da membrana plasmática na resposta de pêlos radiculares a choque hipo-osmótico ou pH baixo. Já no caso do inibidor ácido salicilhidroxâmico, encontrou-se evidências do envolvimento de peroxidases da parede. Nos mutantes hormonais dgt (pouco sensível a auxina) e epi (super produtor de etileno), mas não em not (deficiente em ácido abscísico), os pêlos radiculares apresentaram uma melhor resposta de ajustamento a choque hipo-osmótico do que Micro-Tom, reduzindo o alongamento e o rompimento dos pêlos. Este trabalho fornece fortes evidências de que os pêlos radiculares possuem um mecanismo de percepção e resposta a estresse da parede visando à manutenção de sua integridade e que apresentam bom potencial como sistema modelo nesta linha de pesquisa / Soil acidity is a major factor limiting plant growth worldwide. Aluminum toxicity, which occurs only at low pH, has been extensively studied, whereas low pH stress has received much less attention. Studies on Al3+ and H+ toxicity make the underlying assumption that the effects of these stress factors are additive, and, therefore independent of each other. However, this is most likely not the case and low pH may be a factor which increases susceptibility to further injury by Al3+. There is evidence that low pH causes disruption in cell wall structure of growing cells, which might jeopardize cell wall functionality and integrity. It is likely that turgor pressure plays an important role in cell wall stress caused by low pH. The apoplastic metabolism of reactive oxygen species (ROS) can modulate cell wall extensibility by making or breaking bonds within and between cell wall polysaccharides. A major question is whether, similarly to yeast, plant cells have a cell wall integrity signaling and response system. Growing root hairs are sensitive to low pH and hypo-osmotic stress and are potentially good experimental systems for such investigations. The objectives of this study were: a) Optimize an experimental system to examine tomato (Solanum lycopersicum L. cv Micro-Tom) root hairs; b) Examine the response of root hairs to low pH and hypo-osmotic stress; c) Examine the role of oxidative modulation of the cell wall in these responses; and d) Evaluate the response of different hormonal mutants of Micro-Tom to these stress factors. Root hair elongation rates (µm.min-1) and the frequency of cell bursting were the major experimental parameters which were evaluated. Both low pH and, more markedly, hypo-osmotic stress caused significant reductions in elongation rates and the bursting of root hair tips. In a response curve to varying osmolarities of the external medium, root hair elongation rates increased with decreasing osmolarities until a threshold was reached and elongation rates decreased drastically and the bursting of root hairs began to be observed. Interactions between low pH and hypo-osmolarity were observed. The use of the inhibitor diphenylene iodonium (DPI) did not provide evidence for the involvement of plasma membrane NADPH in the response of root hairs to low pH and hypo-osmotic shock. However, a role for cell wall peroxidases was provided by use of the inhibitor salicylhydroxamic acid (SHAM). Root hairs of the hormonal mutants dgt (low sensitivity to auxin) and epi (ethylene super producer), but not not (deficient in abscisic acid), displayed a more effective response to hypo-osmotic shock than Micro-Tom, by decreasing elongation rates and cell bursting to a greater degree. This study provides strong evidence to suggest that root hairs have a cell wall integrity response system and that root hairs are potentially good cell model systems for such research
15

Respostas de pêlos radiculares de tomateiro (Solanum lycopersicum L. cv Micro-Tom) submetidos a estresse por pH baixo e hipo-osmolaridade / Response of tomato (Solanum lycopersicum L. cv Micro-Tom) root hairs to low pH and hypo-osmotic stress

Elissena Chinaglia Zabotto Sardinha 30 November 2010 (has links)
A acidez do solo é um dos principais fatores limitantes à produção vegetal. A toxicidade por alumínio, que ocorre apenas a pH baixo, tem sido extensamente investigada, enquanto o estresse causado pelo pH baixo tem recebido pouca atenção. Os estudos nesta área quase sempre presumem efeitos aditivos, e portanto independentes, da toxicidade por Al3+ e H+. Este provavelmente não é o caso, sendo que o pH baixo pode ser um fator de predisposição das células ao Al3+. As evidências indicam que o pH baixo causa desarranjos na parede de células em crescimento, gerando estresse que pode comprometer a sua funcionalidade e integridade. É provável que a susceptibilidade a este estresse deve ser dependente da pressão de turgor. Por sua vez, o metabolismo oxidativo e a geração de espécies reativas de oxigênio (ROS) na parede celular podem modular a sua extensibilidade por romper ou criar ligações dentro ou entre cadeias de polissacarídeo. Há grande interesse em se conhecer se, à semelhança do que ocorre em leveduras, as células vegetais possuem um sistema de percepção e resposta a estresse da parede. Os pêlos radiculares em crescimento são sensíveis a pH baixo e estresse hipo-osmótico e constituem um bom modelo experimental para estes estudos. Os objetivos deste trabalho foram: a) Otimizar um sistema experimental para o estudo de pêlos radiculares de tomateiro (Solanum lycopersicum L. cv Micro-Tom); b) Avaliar as respostas dos pêlos radiculares ao estresse por pH baixo e hipo-osmolaridade; c) Examinar o papel da modulação oxidativa da parede celular nestas respostas; e d) Avaliar a resposta de diferentes mutantes hormonais de Micro-Tom a estes fatores de estresse. Os principais parâmetros avaliados foram a taxa de alongamento (µm.min-1) e a freqüência de rompimento dos pêlos. Tanto o estresse por pH baixo quanto choques hipo-osmóticos resultaram em taxas de alongamento significativamente diminuídos e o rompimento de pêlos radiculares, mas os efeitos dos tratamentos hipo-osmóticos foram mais marcantes. Uma curva de resposta frente à osmolaridade da solução externa revelou que a taxa de alongamento aumentou com a diminuição da osmolaridade até alcançar um limiar em que houve redução drástica da taxa de alongamento e começou-se a observar o rompimento de pêlos. Também se observou uma interação entre hipo-osmolaridade e pH baixo. O emprego do inibidor difenileno iodônio não forneceu evidências do envolvimento de NADPH oxidases da membrana plasmática na resposta de pêlos radiculares a choque hipo-osmótico ou pH baixo. Já no caso do inibidor ácido salicilhidroxâmico, encontrou-se evidências do envolvimento de peroxidases da parede. Nos mutantes hormonais dgt (pouco sensível a auxina) e epi (super produtor de etileno), mas não em not (deficiente em ácido abscísico), os pêlos radiculares apresentaram uma melhor resposta de ajustamento a choque hipo-osmótico do que Micro-Tom, reduzindo o alongamento e o rompimento dos pêlos. Este trabalho fornece fortes evidências de que os pêlos radiculares possuem um mecanismo de percepção e resposta a estresse da parede visando à manutenção de sua integridade e que apresentam bom potencial como sistema modelo nesta linha de pesquisa / Soil acidity is a major factor limiting plant growth worldwide. Aluminum toxicity, which occurs only at low pH, has been extensively studied, whereas low pH stress has received much less attention. Studies on Al3+ and H+ toxicity make the underlying assumption that the effects of these stress factors are additive, and, therefore independent of each other. However, this is most likely not the case and low pH may be a factor which increases susceptibility to further injury by Al3+. There is evidence that low pH causes disruption in cell wall structure of growing cells, which might jeopardize cell wall functionality and integrity. It is likely that turgor pressure plays an important role in cell wall stress caused by low pH. The apoplastic metabolism of reactive oxygen species (ROS) can modulate cell wall extensibility by making or breaking bonds within and between cell wall polysaccharides. A major question is whether, similarly to yeast, plant cells have a cell wall integrity signaling and response system. Growing root hairs are sensitive to low pH and hypo-osmotic stress and are potentially good experimental systems for such investigations. The objectives of this study were: a) Optimize an experimental system to examine tomato (Solanum lycopersicum L. cv Micro-Tom) root hairs; b) Examine the response of root hairs to low pH and hypo-osmotic stress; c) Examine the role of oxidative modulation of the cell wall in these responses; and d) Evaluate the response of different hormonal mutants of Micro-Tom to these stress factors. Root hair elongation rates (µm.min-1) and the frequency of cell bursting were the major experimental parameters which were evaluated. Both low pH and, more markedly, hypo-osmotic stress caused significant reductions in elongation rates and the bursting of root hair tips. In a response curve to varying osmolarities of the external medium, root hair elongation rates increased with decreasing osmolarities until a threshold was reached and elongation rates decreased drastically and the bursting of root hairs began to be observed. Interactions between low pH and hypo-osmolarity were observed. The use of the inhibitor diphenylene iodonium (DPI) did not provide evidence for the involvement of plasma membrane NADPH in the response of root hairs to low pH and hypo-osmotic shock. However, a role for cell wall peroxidases was provided by use of the inhibitor salicylhydroxamic acid (SHAM). Root hairs of the hormonal mutants dgt (low sensitivity to auxin) and epi (ethylene super producer), but not not (deficient in abscisic acid), displayed a more effective response to hypo-osmotic shock than Micro-Tom, by decreasing elongation rates and cell bursting to a greater degree. This study provides strong evidence to suggest that root hairs have a cell wall integrity response system and that root hairs are potentially good cell model systems for such research
16

Balancing the Water Budget: the effect of plant functional type on infiltration to harvest ratios in stormwater bioretention cells

Krauss, Lauren Marie 19 January 2021 (has links)
Stormwater bioretention cells (BRCs) are a variety of green stormwater infrastructure with the potential to restore pre-urban water balance, provided they can be tailored to infiltrate and evapotranspire (i.e., harvest) urban runoff in proportions consistent with pre-urban hydrologic conditions. This paper evaluates their capacity to do so, focusing on evapotranspirative harvest, which is relatively understudied, and the capacity of CSR (Competitve, Stress-tolerant, and Ruderal) functional type to serve as an overarching framework characterizing the water use strategy of BRC plants. The goal is to determine if harvest (and therefore the ratio of urban runoff infiltrated to harvested; the I:H ratio) might be fine-tuned to meet pre-urban values in BRCs through informed manipulation of plant community composition. This study focuses on 3 critical plant water use traits, the turgor loss point, the point of incipient water stress, and maximum stomatal conductance. A global plant traits meta-analysis identified degree of plant competitiveness and stress tolerance as significant determinants of all three water use traits, with stem type (woody vs herbaceous) also being significant, but only for turgor loss point. Based on these results, six water use scenarios appropriate for plants with different CSR type/stem type combinations were developed. BRC plants spanning the range of CSR types necessary to actionize these scenarios were determined to be available in eight major climate zones of the coterminous US, suggesting that regulating plant water use in BRCs using CSR is likely feasible. Hydraulic simulations (Hydrus 1D) were conducted for each scenario in all eight climate zones and revealed significant differences in evapotranspirative harvest and I:H ratios in simulated BRCs. Competitive woody plants had the highest evapotranspiration and lowest I:H ratios; 1.5-1.8 times more evapotranspiration and a 1.6-2 times lower I:H ratio than stress tolerant herbaceous plants, on average, across climate zones. Despite these significant differences, no simulated BRC in any climate zone was capable of reproducing pre-urban I:H ratios, regardless of plant type. More water was infiltrated than harvested in all scenarios and climates with the inverse being true for all pre-urban conditions. This suggests that absent additional sources of harvest (e.g., use of BRC water for nonpotable purposes such as toilet flushing and outdoor irrigation, or adoption of novel BRC designs that promote lateral exfiltration, stimulating "extra" evapotranspiration from nearby landscapes), BRCs will be unable to restore pre-urban water balance on their own. If true, then using BRCs in combination with other green technologies (particularly those biased towards harvest), may be the best path forward for balancing urban water budgets. / Master of Science / Stormwater bioretention cells (BRCs) are a variety of green infrastructure designed to manage urban stormwater flows that can dramatically reduce the amount of stormwater that is rapidly (and unnaturally) conveyed from paved surfaces to ecosystems. Their ability to recreate natural flow conditions is dependent on them balancing rates of infiltration – slowly filtering water down to the water table – and evapotranspiration – letting plants capture and transpire water. This paper evaluates the extent to which different plant functional types (competitive, stress tolerant, and ruderal (weedy)) can be used to regulate this balance, bringing urban hydrologic conditions closer to pre-urban ones. Competitiveness and stress tolerance were found to significantly influence plant water use traits, as was plant stem type (woody vs herbaceous) to a lesser extent (i.e., managing water budgets using CSR functional type is theoretically possible). Published BRC vegetation guidelines in 8 major US climate zones were found to include both competitive and stress tolerant species (i.e., the range of functional types required to regulate BRC water balance exists, suggesting it is feasible). Finally, hydraulic simulations conducted under six plant water use scenarios (reflecting different CSR types and stem types) revealed significant differences in the ratio of water infiltrated to evapotranspired by BRCs (i.e., changing plant functional types can meaningfully influence BRC water balance). This said, the magnitude of this effect may be insufficient to return urban catchments to a pre-urban state. All BRCs infiltrated too much water in our simulations suggesting that absent additional sources of harvest (for instance., use of BRC water for nonpotable purposes such as toilet flushing or outdoor irrigation), BRCs will be unable to restore pre-urban water balance on their own. If true, then using BRCs in combination with other green technologies (particularly those biased towards harvest), may be the best path forward for balancing urban water budgets.
17

Mécanique du mouvement rapide de la plante carnivore Dionée : mesures élasto-hydrodynamiques à l'échelle de la cellule et du tissu - conséquences pour le mécanisme de fermeture / Mechanics of rapid motion in the Venus Flytrap

Colombani, Mathieu 22 July 2013 (has links)
Bien qu’elles ne disposent pas de muscles, les plantes ont réussi à développer un nombre remarquable de mécanismes permettant de créer des mouvements rapides, du repliement rapide des feuilles de mimosa pudica à la dispersion de graines par explosion. Parmi ces exemples spectaculaires qui ont depuis longtemps fasciné les scientifiques, la plante carnivore dionée, dont les feuilles se referment en une fraction de secondes pour capturer des insectes, fait figure de paradigme. Récemment, nous avons montré que ce mouvement met en jeu une instabilité de flambage élastique, due à la forme de coque mince des feuilles du piège. Cependant, l’origine microscopique du mouvement qui permet à la plante de franchir le seuil d’instabilité et de changer activement sa courbure reste méconnue. Dans cette thèse nous étudions ce mouvement actif en utilisant un dispositif micro-fluidique, la sonde de pression, qui donne accès directement aux paramètres élastiques et hydrodynamiques à l’échelle de la cellule (pression osmotique, perméabilité cellulaire, élasticité de la paroi, ...). Nos résultats remettent en question le rôle des flux d’eau d’origine osmotique souvent mis en avant pour expliquer la fermeture active du piège de la dionée. De plus, nous développons un dispositif de micro indentation original utilisant un rhéomètre, pour mesurer la réponse locale des tissus et les propriétés mécaniques des épidermes interne et externe. Nous mesurons une signature claire du mouvement actif de la dionée, et fournissons ainsi de nouveaux arguments pour discuter le mécanisme de fermeture, et plus généralement les mouvements rapides dans les plantes. / Although they lack muscle, plants have evolved a remarkable range of mechanisms to create rapid motion, from the rapid folding of sensitive plants to seed dispersal. Of these spectacular examples that have long fascinated scientists, the carnivorous plant Venus flytrap, whose leaves snap together in a fraction of second to capture insects, has long been a paradigm for study. Recently, we have shown that this motion involves a snap-buckling instability due to the shell-like geometry of the leaves of the trap. However, the origin of the movement that allows the plant to cross the instability threshold and actively bend remains largely unknown. In this study, we investigate this active motion using a micro-fluidic pressure probe that gives direct hydraulic and mechanical measurements at the cellular level (osmotic pressure, cell membrane permeability, cell wall elasticity). Our results challenge the role of osmotically-driven water flows usually put forward to explain Venus flytrap’s active closure. Moreover, we developp a micro-indentation original setup using a rheometer, to measure the local tissue response and mechanical properties of the lower and upper epidermis. Then, we detect a clear signature of the active movement in the Venus Flytrap, and thus provide new arguments to discuss this mechanism, and more generally the movements in plants.
18

Caracterização e possível papel da modulação oxidativa da parede celular em alterações na sensibilidade de células de tabaco cv. BY-2 a pH baixo durante a retomada do ciclo celular / Characterization and possible role of the oxidative modulation of the cell wall in changes in the sensitivity of tobacco BY-2 cells to low pH during restart of the cell cycle

Borgo, Lucelia 28 January 2011 (has links)
A acidez do solo é um dos principais fatores limitantes à produção vegetal. Apesar da toxicidade por alumínio ter sido extensamente investigada, pouca atenção tem sido dada ao estresse causado pelo baixo pH em si. Existem diferenças marcantes entre células quanto à sensibilidade ao pH baixo que dependem do seu estado de crescimento e desenvolvimento celular e que devem ser exploradas para se entender o que determina a sensibilidade e tolerância a pH baixo. Em alguns casos, a suscetibilidade a pH baixo está relacionada a desarranjos na parede de células em crescimento, chegando a causar o rompimento da célula, como já foi demonstrado em pêlos radiculares em expansão. Por outro lado, o metabolismo oxidativo e a geração de espécies reativas de oxigênio (ROS) na parede podem influenciar neste processo por romper ou criar ligações dentro ou entre cadeias de polissacarídeos, modulando assim a extensibilidade da parede celular. Em células de tabaco (Nicotiana tabacum) cv. BY-2, há um aumento acentuado na sensibilidade ao pH baixo no final da fase lag da cultura, que ocorrre entre 12 e 24 h de cultivo. Os objetivos deste trabalho foram: a) Investigar se a mudança na sensibilidade pH baixo ocorre durante a retomada do ciclo celular e determinar, com o uso de inibidores do ciclo celular, o período do ciclo em que isto ocorre; b) verificar se o aumento da sensibilidade a pH baixo está relacionado com a expansão celular ou com alterações no potencial osmótico da célula; c) examinar o efeito da aplicação de H2O2 ou ascorbato sobre a resposta de células sensíveis a pH baixo; d) testar a hipótese de que a sensibilidade a pH baixo pode ser revertida por meio de um choque hipo-osmótico prévio; e) avaliar o possível papel da modulação oxidativa da parede celular na reversão de sensibilidade das células a pH baixo expostas ao choque hipo-osmótico. A retomada do ciclo celular é necessária para que ocorra a alteração de sensibilidade a pH baixo, pois a remoção de auxina (2,4-D) ou a adição de bloqueadores de canais de K+ impediu ou atrasou, respectivamente, a alteração na sensibilidade a pH baixo. O uso de inibidores do ciclo celular demonstrou que as células de BY-2 se tornam mais sensíveis a pH baixo durante o final da fase G1 mas antes do ponto de checagem da transição G1/S do ciclo celular. A aplicação de H2O2, diminuiu a suscetibilidade das células a pH baixo, ao contrário da aplicação de ascorbato. Foi demonstrado que a aplicação prévia de tratamento hipo-osmótico por 60 min reverteu a sensibilidade de células a pH baixo. A aplicação de inibidores de NAPDH oxidase da membrana plasmática e de peroxidases revelou a participação destas enzimas na reversão de sensibilidade das células a pH baixo, indicando a possibilidade de geração de ROS e de modulação oxidativa da parede. Embora já tenha sido descrito que ocorre uma explosão oxidativa com choque hipo-osmótico, ainda não havia sido demonstrado a conseqüência disto. Este trabalho fornece indícios de que uma explosão oxidativa poderia modificar a parede tornando-a mais resistente e a célula menos suscetível a pH baixo / Soil acidity is a major factor limiting plant growth worldwide. Although aluminum toxicity, which occurs only at low pH, has been extensively studied, little attention has been given to stress caused by low pH. There are marked differences in the sensitivity of cells to low pH which are contingent on the growth and developmental stage of the cells. These differences should be explored to further the understanding of the factors governing sensitivity and tolerance to low pH. In at least some cases, the susceptibility of cells to low pH is related to derangements in the wall of growing cells, which can cause ruptures or bursting of the cells, as has been clearly demonstrated in expanding root hairs. On the other hand, the oxidative metabolism and generation of reactive oxygen species (ROS) can modulate cell wall extensibility by breaking or making bonds within and between cell wall polymers. In tobacco (Nicotiana tabacum) cv. BY-2 cells, there is a sharp increase in sensitivity to low pH at the end of the lag phase of the cell culture, which occurs between 12 and 24 h of subculture. The objectives of this study were: a) determine if the changes in sensitivity to low pH occurred during the restart of the cell cycle and, by employing cell cycle inhibitors, at which points of the cycle does this occur; b) examine if the changes in sensitivity to low pH are related to cell expansion or changes in osmotic potential of the cell; c) examine how the application of H2O2 or ascorbate affects the response of cells to low pH; d) test the hypothesis that sensitivity of cells to low pH can be reverted by the previous application of a hypo-osmotic shock; e) evaluate the possible role of oxidative modulation of the cell wall in hypo-osmotic-induced reversal of the sensitivity of cells to low pH. The restart of the cell cycle was shown to be necessary for the change in sensitivity to low pH occur, since the absence of auxin (2,4-D) or the addition of K+ channel blockers prevented or delayed this change, respectively. The use of cell cycle inhibitors demonstrated that BY-2 cells become sensitive to low pH at the end of G1 but before the G1/S transition restriction point of the cell cycle. Exogenous H2O2, but not ascorbate, reduced the effect of low pH on sensitive cells. Sensitive cells submitted to 60 min hypo-osmotic treatment became insensitive to low pH. This reversal of sensitivity depended on the activity of plasma membrane NADPH oxidase and peroxidase, as evidenced by the use of DPI and SHAM, inhibitors of these enzymes, respectively. This suggests that ROS is generated and that oxidative modifications of the cell wall occur. Although hypo-osmotic treatments have been shown to generate an oxidative burst, its purpose or implication has not yet been shown. This study provides evidence that an oxidative burst might modify and strengthen the cell wall, making cells less susceptible to low pH
19

Caracterização e possível papel da modulação oxidativa da parede celular em alterações na sensibilidade de células de tabaco cv. BY-2 a pH baixo durante a retomada do ciclo celular / Characterization and possible role of the oxidative modulation of the cell wall in changes in the sensitivity of tobacco BY-2 cells to low pH during restart of the cell cycle

Lucelia Borgo 28 January 2011 (has links)
A acidez do solo é um dos principais fatores limitantes à produção vegetal. Apesar da toxicidade por alumínio ter sido extensamente investigada, pouca atenção tem sido dada ao estresse causado pelo baixo pH em si. Existem diferenças marcantes entre células quanto à sensibilidade ao pH baixo que dependem do seu estado de crescimento e desenvolvimento celular e que devem ser exploradas para se entender o que determina a sensibilidade e tolerância a pH baixo. Em alguns casos, a suscetibilidade a pH baixo está relacionada a desarranjos na parede de células em crescimento, chegando a causar o rompimento da célula, como já foi demonstrado em pêlos radiculares em expansão. Por outro lado, o metabolismo oxidativo e a geração de espécies reativas de oxigênio (ROS) na parede podem influenciar neste processo por romper ou criar ligações dentro ou entre cadeias de polissacarídeos, modulando assim a extensibilidade da parede celular. Em células de tabaco (Nicotiana tabacum) cv. BY-2, há um aumento acentuado na sensibilidade ao pH baixo no final da fase lag da cultura, que ocorrre entre 12 e 24 h de cultivo. Os objetivos deste trabalho foram: a) Investigar se a mudança na sensibilidade pH baixo ocorre durante a retomada do ciclo celular e determinar, com o uso de inibidores do ciclo celular, o período do ciclo em que isto ocorre; b) verificar se o aumento da sensibilidade a pH baixo está relacionado com a expansão celular ou com alterações no potencial osmótico da célula; c) examinar o efeito da aplicação de H2O2 ou ascorbato sobre a resposta de células sensíveis a pH baixo; d) testar a hipótese de que a sensibilidade a pH baixo pode ser revertida por meio de um choque hipo-osmótico prévio; e) avaliar o possível papel da modulação oxidativa da parede celular na reversão de sensibilidade das células a pH baixo expostas ao choque hipo-osmótico. A retomada do ciclo celular é necessária para que ocorra a alteração de sensibilidade a pH baixo, pois a remoção de auxina (2,4-D) ou a adição de bloqueadores de canais de K+ impediu ou atrasou, respectivamente, a alteração na sensibilidade a pH baixo. O uso de inibidores do ciclo celular demonstrou que as células de BY-2 se tornam mais sensíveis a pH baixo durante o final da fase G1 mas antes do ponto de checagem da transição G1/S do ciclo celular. A aplicação de H2O2, diminuiu a suscetibilidade das células a pH baixo, ao contrário da aplicação de ascorbato. Foi demonstrado que a aplicação prévia de tratamento hipo-osmótico por 60 min reverteu a sensibilidade de células a pH baixo. A aplicação de inibidores de NAPDH oxidase da membrana plasmática e de peroxidases revelou a participação destas enzimas na reversão de sensibilidade das células a pH baixo, indicando a possibilidade de geração de ROS e de modulação oxidativa da parede. Embora já tenha sido descrito que ocorre uma explosão oxidativa com choque hipo-osmótico, ainda não havia sido demonstrado a conseqüência disto. Este trabalho fornece indícios de que uma explosão oxidativa poderia modificar a parede tornando-a mais resistente e a célula menos suscetível a pH baixo / Soil acidity is a major factor limiting plant growth worldwide. Although aluminum toxicity, which occurs only at low pH, has been extensively studied, little attention has been given to stress caused by low pH. There are marked differences in the sensitivity of cells to low pH which are contingent on the growth and developmental stage of the cells. These differences should be explored to further the understanding of the factors governing sensitivity and tolerance to low pH. In at least some cases, the susceptibility of cells to low pH is related to derangements in the wall of growing cells, which can cause ruptures or bursting of the cells, as has been clearly demonstrated in expanding root hairs. On the other hand, the oxidative metabolism and generation of reactive oxygen species (ROS) can modulate cell wall extensibility by breaking or making bonds within and between cell wall polymers. In tobacco (Nicotiana tabacum) cv. BY-2 cells, there is a sharp increase in sensitivity to low pH at the end of the lag phase of the cell culture, which occurs between 12 and 24 h of subculture. The objectives of this study were: a) determine if the changes in sensitivity to low pH occurred during the restart of the cell cycle and, by employing cell cycle inhibitors, at which points of the cycle does this occur; b) examine if the changes in sensitivity to low pH are related to cell expansion or changes in osmotic potential of the cell; c) examine how the application of H2O2 or ascorbate affects the response of cells to low pH; d) test the hypothesis that sensitivity of cells to low pH can be reverted by the previous application of a hypo-osmotic shock; e) evaluate the possible role of oxidative modulation of the cell wall in hypo-osmotic-induced reversal of the sensitivity of cells to low pH. The restart of the cell cycle was shown to be necessary for the change in sensitivity to low pH occur, since the absence of auxin (2,4-D) or the addition of K+ channel blockers prevented or delayed this change, respectively. The use of cell cycle inhibitors demonstrated that BY-2 cells become sensitive to low pH at the end of G1 but before the G1/S transition restriction point of the cell cycle. Exogenous H2O2, but not ascorbate, reduced the effect of low pH on sensitive cells. Sensitive cells submitted to 60 min hypo-osmotic treatment became insensitive to low pH. This reversal of sensitivity depended on the activity of plasma membrane NADPH oxidase and peroxidase, as evidenced by the use of DPI and SHAM, inhibitors of these enzymes, respectively. This suggests that ROS is generated and that oxidative modifications of the cell wall occur. Although hypo-osmotic treatments have been shown to generate an oxidative burst, its purpose or implication has not yet been shown. This study provides evidence that an oxidative burst might modify and strengthen the cell wall, making cells less susceptible to low pH
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Seasonal change in tangential strain on the inner bark in white birch (Betula platyphylla var. japonica)

YOSHIDA, Masato, 吉田, 正人, TAMAI, Yutaka, 玉井, 裕, SANO, Yuzou, 佐野, 雄三, TERAZAWA, Minoru, 寺沢, 実, OKUYAMA, Takashi, 奥山, 剛 12 1900 (has links) (PDF)
農林水産研究情報センターで作成したPDFファイルを使用している。

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