Modificações da parede celular de frutos do mamoeiro (Carica papaya L.) em diferentes estadios do desenvolvimento / Modifications of the cell wall of fruits of papaya (Carica papaya L.) at various stages of development

Cavalari, Aline Andreia

13 August 2018

Orientador: Marcos Silveira Buckeridge / Tese (doutorado) - Universidade Estadual de Campinas, Instituto de Biologia / Made available in DSpace on 2018-08-13T07:05:13Z (GMT). No. of bitstreams: 1 Cavalari_AlineAndreia_D.pdf: 2066715 bytes, checksum: 503395a4dfdc3832fc20cbf4193ea790 (MD5) Previous issue date: 2009 / Resumo: A parede celular é um componente particular dos tecidos vegetais e conhecer a composição dos polissacarídeos que a constituem e suas interações é essencial para compreender a textura dos alimentos e suas alterações pós-colheita, em especial em frutos climatérios, como é caso do mamão. A parede celular esta dividida por três domínios: o primeiro é formado por celulose e hemiceluloses, o segundo domínio é formado por pectinas e o terceiro um domínio composto por proteínas. As modificações dos polímeros e suas proporções nestes respectivos domínios são resultados de ações enzimáticas, que no caso dos frutos carnosos, leva ao amaciamento da polpa. Portanto, estudar as modificações nesses polímeros através da análise dos OXG obtidos por hidrolise com celulase, é um caminho importante para entender as alterações neste polissacarídeo ao longo do desenvolvimento de frutos. O presente trabalho teve como objetivo compreender as modificações da parede celular durante o desenvolvimento do fruto do mamoeiro. Foram utilizados frutos de Carica papaya L. cv. Sunrise solo, coletados diretamente do produtor (Caliman S/A- Unhares- ES). As amostras de frutos foram colhidas em intervalos de 30 dias, sendo os estádios analisados de 30 a 150 após a antese (dpa). Os resultados demonstram queda acentuada na proporção de parede celular em relação a outros compostos, como açúcares, por exemplo, o que é possivelmente uma indicação do processo de expansão celular e conseqüentemente uma alteração de textura da parede celular durante o desenvolvimento. Observou-se que o principal açúcar solúvel é a sacarose, sendo esta provavelmente a principal fonte energética para o desenvolvimento do fruto de mamão, uma vez que este não sintetiza amido. De maneira geral, a proporção de oligossacarídeos de xiloglucano menos ramificados diminuiu aos 120 dpa, enquanto que os de maior peso molecular e ou grau de ramificação (com fucose) aumentaram proporcionalmente. Estes resultados sugerem que xiloglucanos (ou parte das moléculas destes) pobremente ramificados com fucose, são retirados da parede celular, consequente enriquecimento de oligosasacarídeos fucosilados. Como estes últimos tornam o xiloglucano mais interativo com ele próprio e com a celulose, é possivel que estes sejam os principais efeitos que as transformações na parede promovam no fruto. As alterações na parede foram acompanhadas pelo aumento concomitante nas ativades de beta­galacosidase e beta-glucosidase, duas das principais hidrolases de xiloglucano. Concumitantemente, observou-se uma diminuição acentuada na proporção de celulose na parede. Com base nestas observações, sugere-se que as paredes celulares sofrem transformações importantes nos frutos do mamoeiro até os 120 dpa I sendo que a partir deste estádio a parede se torna mais acessível à hidrólise e denotando a preparação do fruto para o amadurecimento. / Abstract: The plant cell wall is a unique component of plant tissues and its polysaccharide composition essential to understand food texture and its changes during post-harvestingl especially of climateric fruits, as is the case of papaya. The plant cell wall is composed of three domains: the first is formed by cellulose and hemicelluloses, the second of pectins and the third of proteins. The changes in polymers and their proportions in these domains are a result of enzyme action, which in the case of fleshy fruits lead to the softening of the pulp. Hydrolysis of hemicelluloses such as xyloglucan can play important functions in cell expansion, cell growth and cell wall degradation. Therefore, studying the modifications in xyloglucan by looking at is fine structure (Le. oligosaccharide (OXG) pattern obtained after cellulase action) may be an important way to understand polysaccharide change during fruit development. The present work aimed at understanding the modifications in cell wall during the development of the papaya fruit. Fruits of Carica papaya L. Cv.Sunrise solol were collected directly by the producer (Calimanl SAI Unharesl Espirito Santol Brazil). Samples of fruits were harvested at intervals between 30 and 150 days after anthesis (daa). Our results showed that there were drastic changes in the cell wall of the mesocarp in relation to other compoundsl such as soluble sugars. This is probably an indication that cell expansion process is at least part of the cause of the changes in texture during development. We observed that the main soluble sugar found in fruits is sucrose, this being probably the principal source of energy for development of the organ, as no starch is synthesised in this fruit. In general, the proportion of less branched xyloglucan oligosaccharides decreased at 120 daa, whereas the OXG branched with fucose increased constantly during development up to the same stage. These results suggest that xyloglucans (or part of their molecules) that are poorely brached with fucose are retrieved from the cell wall. This seems to lead to enrichment of fucosylation of xyloglucan. As these OXG turn xyloglucan more interactive with itself and with cellulose, it is possible that these would be the principal effects that the cell walls provoke in the fruit. The changes in the wall were followed by a concomitant increase in activities of beta-galactosidase and betaglucosidase, both thought to be related to xyloglucan hydrolysis in vivo. At the same time, we observed a decrease in the proportion of cellulose in the walls during development. On the basis of these results, we suggest that the cell walls of papaya fruits undertake structural changes untill 120daa after which the wall becomes more accessible to hydrolases denoting the preparation of the papaya fruit for ripening. / Doutorado / Doutor em Biologia Vegetal

Mamão

Parede celular vegetal

Hidrolases

Oligossacarideos

Papaya

Plant cell wall

Hydrolases

Oligosaccharides

Proteome characterization of sugarcane primary cell wall / Caracterização do proteoma da parede celular primária de cana-de-açúcar

Maria Juliana Calderan Rodrigues

16 October 2012

This study provides information to support the use of plant cell wall, from sugarcane bagasse, to produce cellulosic ethanol. Therewith, cell wall proteins from sugarcane cells cultures, leaves and culms were identified. To do so, different protocols were used. Using two-month-old leaves and culms, the extractions were performed using a destructive method, based on griding the tissues, submitting them to a growing gradient of succrose and centrifugation, being the cell wall extract later isolated by washing on a nylon net. After that, the cell wall proteins were extracted using two salts, 0,2 M CaCl2 and 2 M LiCl. Using cultured cells, a similar protocol was used, but it had a previous step of separation of the cell wall through grinding and precipitation in glycerol 15%. Using culms of the same age, a nondestructive protocol was tested based on vacuum infiltration of the tissues in the same salts already described, 0,2 M CaCl2 and 2 M LiCl, and posterior centrifugation. Two replicates were used from two-month-old plants and three in the case of suspension cells. The complex samples were digested, fractionated and sequenced through mass spectrometry, using SYNAPT G2HDMS coupled to nanoACQUITY, both from Waters. Peptides were processed using ProteinLynx 2.5 Global Server against sugarcane translated-EST database. Using bioinformatic programs, such as Blast2GO, it was possible to find the annotation and classification of similar proteins. Only proteins equally found in all repetitions were considered in the main analysis. SignalP, WolfPSORT, TargetP, TMHMM and Predotar were used to predict the subcellular location, both from ESTs and blasted proteins, and only the proteins predicted to be secreted in two or more programs were considered as cell wall proteins. Altogether, 157 different SAS related to sugarcane cell wall were found. Among these, 101 different cell wall proteins were characterized from eight functional classes. The method based on vacuum infiltration seems to be the most efficient one, since it had almost half, 48,84% of the proteins predicted to be secreted, which is a good percentage when comparing to other studies. From secreted proteins most of them were related to lipid metabolism, as lipid-transfer proteins, oxido-reductases, such as peroxidases, cell wall modifying enzymes, like glycoside-hydrolases, proteases, proteins with interacting domains, signaling proteins and several others. Results are in agreement with the expected role of the extracellular matrix in polysaccharide metabolism and signaling phenomena. Therefore, this work provided valuable information about sugarcane cell wall that can lead to future studies to enhance cellulosic ethanol production. / Este estudo fornece informação para auxiliar o uso da parede celular vegetal, a partir do bagaço de cana, para a produção de etanol celulósico. Com isso, as proteínas da parede celular de folhas, colmos e células em suspensão foram identificadas. Para isso, foram utilizados diferentes protocolos. Utilizando folhas e colmos de cana-de-açúcar de dois meses de idade, as extracções foram realizadas por meio de método destrutivo, com base na trituração dos tecidos, submetendo-os a gradiente crescente de sacarose e centrifugação, sendo a parede da célula extraída e depois isolada por lavagem sobre uma rede de nylon. Depois disso, as proteínas de parede celular foram extraídas utilizando dois sais, 0,2 M de CaCl2 e 2 M de LiCl. Para células em suspensão, um protocolo semelhante foi utilizado, contendo, no entanto, um passo anterior de separação da parede celular por meio de maceração e precipitação em glicerol 15%. Usando colmos da mesma idade, dois meses, um protocolo não destrutivo foi testado com base na infiltração a vácuo dos tecidos nos mesmos sais já descritos, 0,2 M de CaCl2 e 2 M de LiCl, e posterior centrifugação. Duas repetições foram usadas nos experimentos com plantas de dois meses de idade, e três, no caso de células em suspensão. As amostras complexas foram digeridas, fracionadas e seqüenciadas por espectrometria de massas, utilizando o equipamento SYNAPT G2HDMS acoplado ao cromatógrafo nanoACQUITY, ambos da Waters. Os peptídeos foram processadas utilizando ProteinLynx 2,5 comparando com a base de dados de ESTs traduzidos da cana. Utilizando programas de bioinformática, como Blast2GO, foi possível encontrar a anotação e classificação de proteínas semelhantes. Apenas proteínas igualmente encontradas em todas as repetições foram consideradas na análise principal. SignalP, WolfPSORT, TargetP, TMHMM e Predotar foram softwares utilizados para prever a localização subcelular, tanto para ESTs como proteínas, e apenas as proteínas preditas para serem secretadas por dois ou mais programas foram consideradas como proteínas de parede celular. Ao todo, 157 SAS diferentes relacionados à parede celular da cana foram encontrados. Dentre eles, 101 diferentes proteínas de parede foram caracterizadas em oito classes funcionais. O método baseado na infiltração a vácuo mostrou-se o mais eficiente, uma vez que apresentou quase metade, 48,84%, das proteínas preditas para serem secretadas, o que é um bom valor quando comparado com outros estudos. A maioria das proteínas secretadas estava relacionada com o metabolismo lipídico, como proteínas de transporte de lípidos, oxido-redutases, tais como peroxidases, enzimas modificadoras da parede, como as glicosil-hidrolases, proteases, proteínas com domínios de interação, proteínas sinalizadoras, entre outras. Os resultados estão de acordo com o papel que se espera da matriz extracelular no metabolismo de polissacarídeos e fenômenos de sinalização. Portanto, este trabalho forneceu informações valiosas sobre a parede celular da cana, tornando possível a utilização desses dados em futuros estudos para otimizar a produção de etanol celulósico.

Cana-de-açúcar

Etanol

Parede celular vegetal

Proteínas

Ethanol

Plant Cell Wall

Proteins

Sugarcane

Caracterização do transcriptoma e parede celular de três espécies de Eucalyptus com importância industrial / Characterization of the transcriptome and cell wall of three Eucalyptus species with industrial importance

Salazar, Marcela Mendes, 1981-

08 February 2012

Orientador: Gonçalo Amarante Guimarães Pereira / Tese (doutorado) - Universidade Estadual de Campinas, Instituto de Biologia / Made available in DSpace on 2018-08-21T09:47:13Z (GMT). No. of bitstreams: 1 Salazar_MarcelaMendes_D.pdf: 4370521 bytes, checksum: 99869d0c9655d47c4e3b2c29de58a274 (MD5) Previous issue date: 2012 / Resumo: A celulose é o polímero mais abundante do planeta e está presente principalmente na parede secundária de células vegetais maduras. O conhecimento dos mecanismos moleculares envolvidos na sua biossíntese, bem como a regulação deste processo é recente e ainda elementar, apesar da sua grande importância. O Eucalyptus é o gênero florestal mais plantado no mundo, especialmente por ser matéria-prima para fabricação de celulose. Investimentos em pesquisas e desenvolvimento estão sendo realizados pelo setor florestal, no intuito de aumentar os ganhos de produtividade de celulose através da pesquisa na área da biologia molecular. Os dados analisados desmostram que a expressão gênica das espécies estudadas (E. globulus, E. grandis e E. urophylla) difere em genes essenciais para a formação dos compostos da parede celular e por fim da madeira. Os dados moleculares são condizentes com dados diferenciais aqui encontrados em relação à composição dos açúcares da parede. Os resultados gerados pela análise de composição da parede por diferentes técnicas, incluindo a recentemente desenvolvida "Perfil Glicômico" mostram uma grande diversidade e quantidade dos carboidratos da parede celular diferentemente distribuídos no xilema das espécies Eucalyptus globulus, grandis e urophylla, bem como em folha. Tais resultados apresentam um grande avanço para o entendimento da composição das paredes celulares de tais espécies. Assim, o objetivo do presente trabalho foi correlacionar os dados moleculares, com dados highthroughput do Perfil Glicômico para entender a composição e arquitetura da parece celular. Espera-se que esses dados possam contribuir para o entendimento da xilogênese e de como os genes trabalham para gerar árvores com características tão distintas, podendo direcionar o melhoramento das mesmas / Abstract: Cellulose is the most abundant polymer in the world and it is present mainly in secondary cell walls of plant mature cells. The knowledge of molecular mechanisms involved in biosynthesis and regulation of this process is recent despite its great importance. The Eucalyptus is the most planted forest genus in the world, especially for being raw material for pulp production. Investments in research and development, especially in the molecular biology field, are being carried out by the forestry sector in order to increase pulp productivity. The data analyzed showed that gene expression of the species the tree species studied here (E. globulus, E. grandis e E. urophylla) differs in essential genes of cell wall compounds formation. Molecular data are consistent with differential data found here in relation to the composition of cell wall sugars. The results generated by the wall composition analysis by various techniques, including the recently developed "Glycome Profiling", showed a wide diversity of carbohydrate of cell wall differently distributed in the xylem of the the Eucalyptus species. These results are a breakthrough in understanding the cell wall composition of these species. The objective of this study was to correlate molecular data with data highthroughput Glycome Profiling to understand the composition and architecture of the cell walls. It is hoped that these data will contribute to the understanding of wood formation and how genes work to generate trees with such different characteristics / Doutorado / Genetica Vegetal e Melhoramento / Doutor em Genetica e Biologia Molecular

Eucalipto

Madeira

Transcriptoma

Parede celular vegetal

Glicômica

Eucalyptus

Wood

Transcriptome

Plant cell walls

Glycomics

Vliv hliníkové toxicity na dynamiku rostlinných kortikálních mikrotubulů / The influence of aluminum toxicity on the dynamics of plant cortical microtubules

Pohl, Jana

January 2017

Aluminium toxicity is the main factor limiting plant growth on acid soils. Aluminium inhibits root growth within few minutes after aluminium treatment. The mechanism and primary target of his action is still unknown. In this diploma thesis the effect of aluminium toxicity on dynamics of cortical microtubules WT and pldα1 plants was studied using the EB1a-GFP marker. Polymerization rate in both the transition and the elongation zone increased immediately after the aplication of aluminium. Nevertheless, microtubules in the transition zone are much more sensitive to aluminium, because the aluminium-induced increase in the polymerization rate was higher than in the elongation zone. Plants lacking PLDα1 showed higher dynamics on plus ends of cortical microtubules compared to WT during aluminium stress, which enabled them to react faster to stress stimuli. Mutants showed lower sensitivity to aluminium and 100 μM concentration of aluminium ions has beneficial effect on root growth in pldα1. These results suggest that PLDα1 influences microtubule dynamics. Microtubules in pldα1 plants were more dynamic and they polymerized faster in the response to aluminium, which was accompanied by decreased sensitivity to aluminium stress compared to WT. Changes in microtubule dynamics may play a role in aluminium...

The role of polysaccharidases in acid wall loosening of epidermal tissue from young Phaseolus vulgaris L. hypocotyls

Keller, Christopher Philip

January 1987

The extension of frozen-thawed epidermal strips prepared from the first centimetre below the hypocotyl hook of six day old dark grown Phaseolus vulgaris seedlings while immersed in various buffers and under various tensions was characterized. This was done in an attempt to determine if the acid wall loosening phenomenon, which according to the Acid-growth theory (Taiz, 1984) is thought to mimic part of the auxin mechanism of action, is mediated by unspecified wall loosening enzymes. Epidermal strips were found to be significantly loosened by media pH 6.0 to pH 2.6 (0.05M citric acid-O.lOM disodium phosphate) relative to pH 7.5. A minimum stress between 1.6 and 7.6 grams was required for the acid-extension of strips 4.5±0.5 mm wide. Regardless of tension, extension by tissues in an acid medium was largely transient For example, tissues tensioned by a 16.0 gram load reached a maximum extension rate of 6.18 ±1.37% of initial length per hour (L°/hr) between 4 and 6 minutes after immersion in pH 4.8. The rate was 1.29±0.17% L°/hr between 55 and 60 minutes and 1.05±0.14% L°/hr between 220 and 240 minutes. Total acid-extension over four hours was 4.24±0.57% L°. The extension response was found to be stable; newly harvested tissues whether frozen or not performed similarly to strips aged up to 15 days at -12°C before being extended. The performance of strips immersed in unbuffered solutions indicated that tissues were self-buffering at an acid pH probably because of the fixed carboxyls within the wall. The capacity for acid-extension by epidermal strips was lost in mature tissues harvested 4-5 cm below the hypocotyl hook. Temperature coefficients from extension rates were determined at several pHs. The results were highly variable. The acid-extension of strips boiled 15 minutes in ethanol or extracted in 3M NaCl for 4 hours at 4°C or 6M LiCl for 8 hours was determined in several pHs. The impact of the treatments was largely a suppression of the initial burst of acceleration. Extension rates following the initial surge were relatively unaffected. Glycosidase activities in untreated, ethanol-boiled, or salt extracted strips were determined. β-glucosidase was found to be most active in untreated strips with lesser levels of β-galactosidase and β-xylosidase and a trace of α-galactosidase being detected. Ethanol-boiling and LiCl-extraction removed or deactivated all four activities from the strips and NaCl-extraction lowered all four activities 70-80%. NaCl proved to have solubilized most of the missing β-glucosidase and β-galactosidase when the extraction solution was assayed following desalting and concentration. LiCl solubilized most of β-xylosidase. It was concluded that glycosidases and any other similarly soluble enzyme cannot be responsible for long term acid wall loosening in bean epidermis. If an enzyme is involved, it must be extremely stable and tightly bound to the wall. The acid-extension performance of frozen-thawed longitudinally halved hypocotyl sections in comparison to epidermal strips, as well as other evidence was considered support for another hypothesized mechanism of acid wall loosening, the displacement of calcium bridges. / Science, Faculty of / Botany, Department of / Graduate

Phaseolus

Kidney bean

Cells -- growth & development

Cells -- Growth

Plant cell walls

Polysaccharides

Generating Molecular Biology Tools to Investigate the Ca2+ Binding Ability of Arabidopsis TON2

Shao, Danyang

08 1900

The position of the cell division plane in plants is determined by the position of the preprophase band. The pre prophase band (PPB) is a ring of microtubules centered around the nucleus on the inner side of plasma membrane that establishes the cortical division site. The PPB forms at the end of G2 and breaks down at the end of prophase leaving behind protein markers of its position that are collectively called the cortical division site. During cytokinesis the phragmoplast expands towards the cortical division site and mediates the fusion of the new cell plate with the mother cell at that position. Several proteins necessary for PPB formation in plants have been identified, including maize DCD1 and ADD1 and Arabidopsis TON2, which are all type 2A protein phosphatase (PP2A)B" regulatory subunits. DCD1, ADD1, and TON2 localize to the PPB and the cortical division site through metaphase. The PP2A subunits each have two EF-hand domains, which are predicted to bind calcium ions. Since calcium ions are important for some aspects of cell division, we designed a series of constructs to test if TON2 binds calcium. TON2 protein was cloned into expression vectors, pET42a, and expression of TON2 protein was confirmed via Western blotting and immunodetection using a GST antibody. Site directed mutagenesis was used to mutate the TON2 EF-hand domains and mutated cDNAs were also cloned into expression vectors. These were then expressed in bacterial systems. Finally, the GST tagged proteins were purified. In the future, wild-type and mutated proteins TON2 proteins will used in calcium binding assays to determine if TON2 binds calcium.

PPB

TONNEAU2

mutations

calcium binding

EF-hand

Cytokinesis.

Arabidopsis.

Calcium.

Plant cell walls.

Recherche et caractérisation de glycosyltransférases impliquées dans la biosynthèse des polysaccharides de la paroi chez Arabidopsis thaliana / Identification and characterization of glycosyltranserases from Arabidopsis thaliana that are involved in the biosynthesis of plant cell wall polysaccharides

Kousar, Sumaira

04 November 2011

La paroi végétale assure des fonctions biologiques majeures définissant la singularité des plantes ; elle est également à l'origine de multiples applications en tant que ressource agro-alimentaire, source de biomatériaux ou encore pour la production de biocarburants. Malgré cette importance fondamentale et pratique de la paroi végétale, la connaissance de sa biosynthèse apparaît à ce jour toujours très limitée. En effet, la faible abondance des glycosyltransférases (GTs) responsables de sa biosynthèse, l'absence de substrat spécifique et les difficultés à obtenir certains nucléotides-sucres nécessaires aux tests enzymatiques, a souvent rendu difficile les approches de biochimie classiques. Cependant, le séquençage de génomes (Arabidopsis thaliana, Oryza sativa, Poplar populus), la création de banques de mutants d'insertion et la classification des activités glycosyltransférases dans la base de données CAZy (www.cazy.org) sont autant d'outils récents ayant permis des avancées significatives vers la compréhension de la biosynthèse de la paroi des végétaux. Le CERMAV a participé à ce type d'avancée en 2009, en publiant une liste de 24 gènes candidats, nommés « NGT » pour « Nouvelles GlycosylTransférases », présentant des signatures caractéristiques des glycosyltransférases. Afin de démontrer l'implication des gènes NGT dans les processus d'édification de la paroi végétale, nous avons développé une approche de génomique fonctionnelle, analysant en parallèle des lignées mutantes d'Arabidopsis altérées pour les gènes NGT et testant l'activité GT de ces protéines exprimées en systèmes hétérologues. Durant mes travaux de thèse j'ai pu caractériser 15 lignées mutantes à l'état homozygote pour 7 des 24 gènes NGT. Ces lignées homozygotes ont été criblées afin de rechercher un phénotype d'altération du développement ou de la composition en sucres de leur paroi qui soit corrélé à l'altération des gènes NGT. Ce travail de criblage a conduit à s'intéresser plus particulièrement aux mutants ngt1-1 et ngt1-2 altérés pour le gène NGT1 (At5g28910). La caractérisation des lignées mutantes ngt1-1 et ngt1-2 a permis de quantifier un phénotype de croissance foliaire réduit de 38%, par comparaison au développement des feuilles de la plante sauvage. Par ailleurs, la caractérisation biochimique de la paroi des mutants a révélé des réductions significatives et quantitatives de l'arabinose, du galactose et du rhamnose dans la paroi des mutants, ainsi que des modifications qualitatives marquées principalement des arabinanes. L'altération des arabinanes a d'ailleurs pu être confirmée par microscopie après immuno-marquage de sections d'hypocotyle de mutants à l'aide des anticorps monoclonaux LM6 et LM13 dirigés contre des épitopes α-1,5-arabinanes. Il a pu être montré également que la complémentation des mutants par une construction 35S::NGT1 permet de restaurer un phénotype sauvage à ces mutants. Par ailleurs, de façon à tester l'activité glycosyltransférase de la protéine NGT1, nous avons réalisé son expression en système hétérologue. A ce jour, malgré des résultats préliminaires encourageants, il n'a pas été possible de déterminer des conditions de tests permettant d'observer une activité glycosyltransférase suffisante et reproductible pour la protéine NGT1, que ce soit une activité fucosyltransférase (correspondant à la signature de la séquence du gène) ou bien une activité arabinosyltransférase (correspondant au phénotype biochimique des mutants ngt1). / The plant cell wall not only defines the unique biology of the plants but also have practical applications as feedstock for biomaterials and for the production of biofuels. Plant primary cell wall is mainly composed of cellulose, hemicelluloses and pectins. Significant progress has been made recently in identifying the enzymes involved in plant cell wall biosynthesis, but only a handful of those have been involved in pectin biosynthesis. With the aim of identifying new putative glycosyltransferases (GTs), in lab Hansen et al 2009 designed a bioinformatic strategy and identified a new group of 24 genes called “NGT” for (Novel Glycosyltransferase) which were considered “strong” candidates for putative glycosyltransferase activities. In order to determine the putative role of these NGT genes in plant cell wall biosynthesis, we designed a functional genomics strategy, analysing in parallel Arabidopsis T-DNA mutant lines and performing heterologous expression of candidate genes. I have characterized 15 homozygous mutant lines among the group of 24 putative NGT genes through PCR. We analysed the homozygous mutants for phenotypic alteration such as dwarfing or organ malformation and found that some of mutant lines have narrow leaves as compared to Wild type plants. In parallel I have carried out the cell wall chemical analysis of 12 homozygous mutant lines and did not get any strong difference in neutral monosaccharide composition. The detailed and complete analysis (chemical, expression and microscopic analysis) of all the above mentioned genes could have been time consuming and an overwhelming work, so I focused on At5g28910 (named NGT1) which harbours a fucosyltransferase peptide signature and on At5g14550 (named P), a gene belonging to the DUF266 gene family. Homozygous T-DNA mutant lines ngt1-1 and ngt1-2 lines were analyzed and showed a reduced growth phenotype (leaf area). Leaf area was quantified at various development stages using ImageJ, and showed a 38% reduction in mutants. Additionally, biochemical characterization of the cell wall was performed showing a reduction in neutral monosaccharide contents, like arabinose, rhamnose and galactose in mutant cell wall. Furthermore glycosyl linkage analysis of mutant lines ngt1-1 and ngt1-2 has shown that 5-Arabinofuranose (5-Araf) and 3,5-Arabinofuranose (3,5-Araf ) contents were decreased as compared to Wild type Col0 cell wall. These results were also confirmed by immunolabeling of stem cross section of mutant and wild type plants. The complementation of the mutant plants through Agrobacterium transformation resulted in the complete restoration of plant phenotype. Taken together, these data suggest that NGT1 could be an arabinosyltransferase. In order to characterize its biochemical activity, the NGT1 protein was heterologously expressed in Pichia pastoris. The recombinant protein was used to perform in vitro activity tests, but we were unable to demonstrate any neither fucosyltransferase (on the basis of peptide signature) nor arabinosyltransferase activity. In parallel to this study, I contributed to the heterologous expression and characterization of two biochemically characterized Arabidopsis GTs involved in xyloglucan synthesis: the fucosyltransferase (AtFUT1) and xylosyltransferase (AtXT1). I have successfully expressed a truncated and active form of AtFUT1, which represents an essential step for further structural studies that will be undertaken in the lab.

Glycosyltransfèrase

Paroi végétale

Arabidopsis thaliana

Glycosyltransferase

Plant cell wall

Arabidopsis thaliana

Gene Expression Associated with Wound and Native Periderm Maturation in Potato Tubers

Neubauer, Jonathan David

January 2011

Potato (Solanum tuberosum L.) is the world's fourth largest food crop and large financial losses are incurred each year from wound and bruise related injuries. However, little is known about the coordinate induction of genes that may be associated with, or mark major wound-healing and periderm maturation events. Also, one of the key defense mechanisms for potato tubers is the robust barrier provided by the phellem (skin) of the native periderm. Many biological processes are involved in the formation of this stout tissue. However, little is known about induction of genes that may be associated with this process. The objectives of this research were to molecularly assess the processes of wound periderm development and maturation, and native periderm maturation in potato tubers. In this study, these processes were determined in coordination with expression profiles of selected genes. The cell cycle, cell wall protein, and pectin methyl esterase genes were determined from two diverse potato genotypes and two harvests NDTX4271-5R (ND) and Russet Burbank (RB) tubers; 2008 and 2009 harvests. Cell cycle genes encoding epidermal growth factor binding protein (StEBP), cyclin-dependent kinase B (StCDKB), and cyclin-dependent kinase regulatory subunit (StCKS1At) expression profiles were coordinated with related phellogen formation and the induction and cessation of phellem cell formation. Genes encoding the structural cell wall proteins extensin (StExt1) and extensin-like (StExtlk) expression profiles suggested involvement with closing layer formation and subsequent phellem cell layer formations. The coordinate induction and expression profile of StTLRP, a gene encoding a cell wall strengthening "tyrosine- and lysine-rich protein," suggested a role in the formation of the closing layer followed by phellem cell generation and lastly cell wall thickening in nonmeristematic phellogen cells. StPME and StPrePME expression increased during periderm development, implicating involvement in modifications for closing layer and phellem cell formation. Collectively, these results indicate that the genes monitored were involved in and their expression profiles markedly coordinated with periderm formation and the on-set of periderm maturation; results were more influenced by harvest than genotype. Importantly, StTLRP was the only gene examined that may be involved in phellogen cell wall strengthening or thickening after cessation of cell division.

Potatoes -- Wounds and injuries.

Potatoes -- Genetics.

Plant cell walls.

Plant gene expression.

Association Studies on Pre-Germination Flooding Tolerance and Cell Wall Components Related to Plant Architecture in Dry Bean

Walter, Katelynn

January 2018

Dry bean breeding programs have made significant advances in combating both abiotic and biotic stresses as well as improving plant architectural traits via selective breeding. Flooding can cause complete crop loss in dry bean. On the other hand, breeding for an upright architecture in dry bean has been a breeding target in several programs. However, the stem cell wall components underlying this change have yet to be studied. This research focused on analyzing the cell wall components that might be involved in dry bean architecture as well as pre-germination flooding tolerance in dry bean. For the plant architecture study, two significant genomic regions were identified on Pv07 and Pv08 associated with lignin accumulation in dry bean. For the pre-germination flooding study, one unpigmented seed coat genotype (Verano) and three pigmented seed coat genotypes (Indeterminate Jamaica Red, Durango, and Midnight) had germination rates similar to that of the tolerant check.

Dried beans – Breeding.

Beans -- Effect of stress on.

Beans -- Effect of water levels on.

Plant cell walls.

Role proteinu ARPC2 v rostlinné buňce / The role of ARPC2 in plant cells

Šlajcherová, Kateřina

January 2013

ARPC2 protein localization in a plant cell Kateřina Šlajcherová 1 Abstract Actin cytoskeleton is an ubiquitous structure which plays numerous irreplacable roles. Actin nucleation is, beside formins, performed by ARP2/3 complex (actin-related protein), comprising of seven subunits (ARP2, 3, C1-C5) and activated by protein SCAR/WAVE complex. ARP2/3 complex is attached to the membrane and branches existing microfilaments, apart from nucleating them de novo. ARP2/3 mutants in most organisms show severe defects. However, plant mutants exhibit only mild phenotype, for example, Arabidopsis thaliana ARPC2 mutant (dis2-1) has deformed trichomes and leaf epidermal cells, but its viability is not impaired. The aim of the thesis is to map ARPC2 localization within the cell and broaden our understanding of ARP2/3 complex role in plant cell morphogenesis. Tobacco ARPC2 (NtArpC2) subunit was visualized in Arabidopsis plants, using the GFP fusion protein as well as imunofluorescence and anti-ARPC2 antibody. Experiments were undertaken to collocalize the subunit with actin and microtubular cytoskeleton, with mitochondrions, endosomes and other membrane organelles. The specimens were observed in confocal and TIRF microscope. The GFP-NtARPC2 protein shows as motile dots; their movement, but not their existence, is dependent...