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Genetic manipulation of Grain storage protein digestibility in sorghum.Phuong Mai Hoang Unknown Date (has links)
Abstract Sorghum (Sorghum bicolor L. Moench) is the world’s fifth most common cereal crop and provides an important source of staple food in the semi-arid tropics and feed in many other countries. The plant has the ability to grow and yield in hot and dry climates. However, sorghum grain is less digestible than the other major staple crops such as rice, wheat and maize. Therefore, the aim of this project is to improve the nutritional quality of sorghum grain by applying cutting-edge biotechnologies which involve the use of tissue culture and genetic transformation. Recently, Agrobacterium has been used by many researchers to introduce foreign genes into the sorghum genome. This method has some advantages compared to particle bombardment, however, one limitation is the regeneration of transgenic tissues. In this study successfully transformed sorghum using Agrobacterium and regenerated transgenic plants via an organogenic tissue culture system is reported. The results of transformation efficiency were achieved with co-cultivation after 48 hours. Regeneration of the sorghum transgenic plants was improved by using organogenic tissues. The GUS reporter gene and the Hpt and bar selectable markers were used. Southern blots and PCR were used to confirm transgene presence in the T0 and T1 generations. In this study, stable transgenic sorghum plants have been produced. The factors found to most influence Agrobacterium transformation were the type of organogenic tissue from different genotypes. The genotypes and the period of co-cultivation, as well as the selectable marker gene and selection strategy used. However, the transformation efficiency from this method was low (1.12%) compared with the previous efficiencies published for Agrobacterium-mediated sorghum transformation. Therefore, to improve the transformation efficiency for this method further work may need to be done. Thioredoxin genes were transformed into the sorghum genotype 296B by particle bombardment. In the first experiment no transgenics over-expressing trx and ntr were confirmed by Southern blot. In subsequent experiments, a limited number of transgenics of the T1 generation were confirmed and used for further analysis. A transgenic line with both trx & ntr was created by crossing a trx line and a ntr line. The 2 genes in this line were confirmed and showed different levels of expression by Real Time PCR. Also, the level of expression in the T2 hybrid plants was higher compared to the T1 parents. The grains from the transgenic lines were different in gelatinization, viscosity, pasting properties and in-vitro digestibility. The ntr line was confirmed to be more digestible than the other transgenic lines and a non-transgenic line. There was a significant increase of 11% (P=0.02) in digestibility of the sorghum ntr line over the non-transgenic. However, the transgenic sorghum seeds did not germinate after storage for more than 6 months. Differences in the morphology of the starch granules and protein matrix of the transgenic lines when compared to non-transgenic were observed with Scanning Electron microscopy. The difference was observed from the transition to the central zone. Pores appeared in the starch granules of the sorghum transgenic lines, but not in the non-transgenic. This may be directly related to the changes in gelatinization, viscosity, pasting and digestibility. To find regulatory sequences which can direct expression of transgenes in developing endosperm, the β-kafirin promoter was identified and cloned. Two constructs of varying length were made to test tissue specificity of the promoter, by replacing the Ubi promoter of the pUBIGUS vector. The GUS gene was used as the marker gene under the control of the amplified β-kafirin promoter. The result was determined on different explants of sorghum by transient expression via particle bombardment. The result shows the successful identification of the β-kafirin promoter region and its effect on transient expression levels. Agrobacterium transformation of sorghum organogenic tissue was developed. The digestibility of grain sorghum was improved by over-expressing the thioredoxin genes. In conclusion, the sorghum grain digestibility can be improved by transforming sorghum with thioredoxin genes, via Agrobacterium-mediated transformation. Further experimentation is required to identify regulatory sequences to optimise transgene expression in sorghum endosperm. In order to determine the reason behind the difficulties of seed germination, larger numbers of independent transgenic lines need to be generated and tested to determine whether over-expression of trx & ntr always has detrimental effects on seed longevity and germination.
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Genetic manipulation of Grain storage protein digestibility in sorghum.Phuong Mai Hoang Unknown Date (has links)
Abstract Sorghum (Sorghum bicolor L. Moench) is the world’s fifth most common cereal crop and provides an important source of staple food in the semi-arid tropics and feed in many other countries. The plant has the ability to grow and yield in hot and dry climates. However, sorghum grain is less digestible than the other major staple crops such as rice, wheat and maize. Therefore, the aim of this project is to improve the nutritional quality of sorghum grain by applying cutting-edge biotechnologies which involve the use of tissue culture and genetic transformation. Recently, Agrobacterium has been used by many researchers to introduce foreign genes into the sorghum genome. This method has some advantages compared to particle bombardment, however, one limitation is the regeneration of transgenic tissues. In this study successfully transformed sorghum using Agrobacterium and regenerated transgenic plants via an organogenic tissue culture system is reported. The results of transformation efficiency were achieved with co-cultivation after 48 hours. Regeneration of the sorghum transgenic plants was improved by using organogenic tissues. The GUS reporter gene and the Hpt and bar selectable markers were used. Southern blots and PCR were used to confirm transgene presence in the T0 and T1 generations. In this study, stable transgenic sorghum plants have been produced. The factors found to most influence Agrobacterium transformation were the type of organogenic tissue from different genotypes. The genotypes and the period of co-cultivation, as well as the selectable marker gene and selection strategy used. However, the transformation efficiency from this method was low (1.12%) compared with the previous efficiencies published for Agrobacterium-mediated sorghum transformation. Therefore, to improve the transformation efficiency for this method further work may need to be done. Thioredoxin genes were transformed into the sorghum genotype 296B by particle bombardment. In the first experiment no transgenics over-expressing trx and ntr were confirmed by Southern blot. In subsequent experiments, a limited number of transgenics of the T1 generation were confirmed and used for further analysis. A transgenic line with both trx & ntr was created by crossing a trx line and a ntr line. The 2 genes in this line were confirmed and showed different levels of expression by Real Time PCR. Also, the level of expression in the T2 hybrid plants was higher compared to the T1 parents. The grains from the transgenic lines were different in gelatinization, viscosity, pasting properties and in-vitro digestibility. The ntr line was confirmed to be more digestible than the other transgenic lines and a non-transgenic line. There was a significant increase of 11% (P=0.02) in digestibility of the sorghum ntr line over the non-transgenic. However, the transgenic sorghum seeds did not germinate after storage for more than 6 months. Differences in the morphology of the starch granules and protein matrix of the transgenic lines when compared to non-transgenic were observed with Scanning Electron microscopy. The difference was observed from the transition to the central zone. Pores appeared in the starch granules of the sorghum transgenic lines, but not in the non-transgenic. This may be directly related to the changes in gelatinization, viscosity, pasting and digestibility. To find regulatory sequences which can direct expression of transgenes in developing endosperm, the β-kafirin promoter was identified and cloned. Two constructs of varying length were made to test tissue specificity of the promoter, by replacing the Ubi promoter of the pUBIGUS vector. The GUS gene was used as the marker gene under the control of the amplified β-kafirin promoter. The result was determined on different explants of sorghum by transient expression via particle bombardment. The result shows the successful identification of the β-kafirin promoter region and its effect on transient expression levels. Agrobacterium transformation of sorghum organogenic tissue was developed. The digestibility of grain sorghum was improved by over-expressing the thioredoxin genes. In conclusion, the sorghum grain digestibility can be improved by transforming sorghum with thioredoxin genes, via Agrobacterium-mediated transformation. Further experimentation is required to identify regulatory sequences to optimise transgene expression in sorghum endosperm. In order to determine the reason behind the difficulties of seed germination, larger numbers of independent transgenic lines need to be generated and tested to determine whether over-expression of trx & ntr always has detrimental effects on seed longevity and germination.
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Genetic variability and biotechnological studies for the conservation and improvement of Ensete ventricosum /Birmeta, Genet, January 2004 (has links) (PDF)
Diss. (sammanfattning) Alnarp : Sveriges lantbruksuniversitet, 2004. / Härtill 5 uppsatser.
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Genetic improvement of oil quality in Sesame (Sesamum indicum L.): assembling tools /Were, Beatrice Ang'iyo, January 2006 (has links) (PDF)
Diss. (sammanfattning) Alnarp : Sveriges lantbruksuniv. / Härtill 4 uppsatser.
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Post-translational regulation and evolution of plant gamma-glutamate cysteine ligaseGromes, Roland. January 2007 (has links)
Heidelberg, Univ., Diss., 2007. / Online publiziert: 2008.
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Transformation eines embryogenen Zellstammes von Digitalis lanata und Untersuchungen zur Expression der eingeführten Gene während der somatischen Embryogenese /Thomar, Steffen. January 1994 (has links) (PDF)
Universiẗat, Diss.--Halle, 1994.
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Analysis of plant gene expression responses to the pathogen and natural genetic engineer Agrobacterium tumefaciens /Ditt, Renata Fava. January 2004 (has links)
Thesis (Ph. D.)--University of Washington, 2004. / Vita. Includes bibliographical references (p. 84-109).
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The fate of T-DNA during vegetative and generative propagation crown gall and hairy root tissues of Nicotiana spp. /Peerbolte, Rindert. January 1986 (has links)
Thesis (Ph. D.)--Rijksuniversiteit te Leiden. / eContent provider-neutral record in process. Description based on print version record.
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Transformation génétique chez l'épinette noire et le peuplier hybride avec une chitinase de Trichoderma harzianum et évaluation de la résistance face aux champignons pathogènes /Noël, Andrée. January 1900 (has links)
Thèse (M.Sc.)--Université Laval, 2004. / Bibliogr.: f. 61-87. Publié aussi en version électronique.
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Expressão de uma quitinase de Metarhizium anisopliae em Nicotiana tabacum : obtenção de plantas transgênicas resistentes a doenças fúngicasKern, Marcelo Fernando January 2003 (has links)
A resistência a doenças em plantas transgênicas tem sido obtida por meio da expressão de genes isolados de bactérias, fungos micoparasitas e plantas. Neste trabalho, relatamos a utilização de um gene do fungo entomopatogênico Metarhizium anisopliae como modo de gerar resistência a doenças fúngicas em plantas. O gene chit1 codifica a quitinase CHIT42 (EC 3.2.1.14), pertencente a uma classe de glicosil-hidrolases capazes de converter quitina em oligômeros de N-acetil-glicosamina (NAcGlc). Quando presentes em tecidos vegetais, supõese que as quitinases ataquem especificamente a parede celular de fungos invasores, provocando danos às hifas e causando a morte por lise das células fúngicas. Deste modo, dois diferentes grupos de plantas transgênicas de Nicotiana tabacum foram produzidos: no primeiro deles, denominado chitplus, os indivíduos possuem o gene chit1 sob o controle do promotor CaMV 35S. O segundo grupo, demoninado chitless, consiste de plantas transformadas com um T-DNA não contendo o gene do fungo. Trinta e quatro plantas transgênicas resistentes à canamicina (17 de cada grupo) foram regeneradas a partir de discos de folhas infectados por Agrobacterium tumefaciens. A produção da quitinase em extratos protéicos de folhas foi analisada por zimogramas em SDS-PAGE contendo glicol-quitina e corados por calcoflúor branco, na forma de um screening dos transgênicos primários. As plantas transgênicas foram testadas, ainda, por meio de ensaios colorimétricos empregando oligômeros sintéticos de NAcGlc como substratos específicos, além de immunoblot e Western blot com soro anti-quitinase. A quantidade de enzima recombinante nas plantas chitplus variou desde nenhuma atividade detectável a elevados níveis de expressão da enzima. A hibridização de Southern blot demonstrou que o número de cópias do gene chit1 integradas no genoma vegetal foi estimado entre uma e quatro. A primeira geração de plantas transgênicas geradas por autofecundação de parentais portadores de duas cópias do transgene foi testada com relação à estabilidade da herança do transgene e em 43 de um total de 67 descendentes, originados de quatro cruzamentos independentes, o padrão de segregação não diferiu das proporções Mendelianas esperadas. Ensaios de resistência, desafiando as plantas transgênicas com o basidiomiceto Rhizoctonia solani foram realizados e uma evidente diminuição da área foliar contendo lesões fúngicas foi observada entre as linhagens transgênicas, embora variações na atividade quitinolítica tenham influenciado o nível de resistência. Nossos resultados sugerem uma relação direta entre a atividade específica de quitinase e ao aumento nos níveis de resistência às lesões causadas pela infecção por R. solani. / Plant resistance in transgenic plants has been obtained by expressing genes isolated from bacteria, mycoparasitic fungi and plants. Here we report the employment of a gene from the entomopathogenic fungus Metarhizium anisopliae as a tool to generate resistance to fungal diseases in plants. The chit1 gene encodes the chitinase CHIT42 (EC 3.2.1.14), belonging to a class of glicosyl-hydrolases able to convert chitin into N-acetyl-glucosamine (GlcNAc) oligomers. When present in plant tissues, chitinases are supposed to disrupt the invading fungal cell wall specifically, causing hyphae damage and leading to cell lysis. Hence two different groups of transgenic Nicotiana tabacum plants were produced. The first group was named chitplus, in which individuals harbour the chit1 gene under the control of the CaMV 35S promoter . The second group, named chitless, carried a T-DNA not containing the fungal gene. Thirty-four kanamicin resistant plants (17 of each group) were regenerated from leaf discs infected with Agrobacterium tumefaciens. Chitinase production in leaf protein extracts was analysed through zymograms in SDS-PAGE containing glycol-chitin and stained by calcofluor white, as a screening of primary transformants. Transgenic plants were also evaluated by colorimetric assays using synthetic GlcNAc oligomers as specific substrates besides immunoblot and Western blot probed with rabbit anti-chitinase sera. The amount of recombinant enzyme in chitplus plants ranged from no detectable chitinase activity to high levels of enzyme expression. Southern blot hybridisation revealed that chit1 copy number inserted into plant genomes varied from one to four. The first self pollinated generation of transgenic lines bearing two copies of the transgene was tested on inheritance stability and in 43 out of 67 descendants, derived from four independent crosses, the segregation pattern was discovered not to differ from the predicted Mendelian ratios. Resistance assays challenging transgenic plants with the basidiomycete Rhizoctonia solani were performed and a clear decrease in the foliar area containing fungal lesions was observed amongst transgenic lines, though variations in chitinase activity also reflected on the resistance level. Our results suggest a direct relationship between chitinase specific activity and the improvement in the resistance to lesions caused by infection.
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