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Profiling of gene expression in bread wheat (Triticum aestivum L.) line PI 137739 in response to Russian wheat aphid (Diuraphis noxia Mordvilco) feedingLacock, Lynelle 09 May 2005 (has links)
This thesis investigates the effect of Russian wheat aphid (RWA; Diuraphis noxia) infestation on the defence responses of the bread wheat line, PI 137739, on a molecular level. PI 137739 is known to contain the RWA resistance gene, Dn1. The study was conducted by utilising and combining a vast array of molecular biological techniques. Chapter 1 introduces the reader to a summary of the resistance responses observed within infested plants. A detailed description of the Russian wheat aphid follows and the genes responsible for RWA resistance in wheat is discussed. A brief report of research performed on the bread wheat genome is given and the biochemical defence responses of plants against insect infestation are discussed. This is followed by a concise description of resistance (R) genes and resistance gene categories in plants. The last discussion concerns microarray technology, a molecular tool utilised during this study. Chapter 2 aims at identifying genes involved in resistance against RWA infestation; specifically, genes containing the conserved nucleotide binding site¬leucine rich repeat (NBS-LRR) motif. Genomic, as well as complementary DNA (cDNA), was utilised in order to compare functional gene expression in wheat infested with the RWA. This was executed by employing PCR-based methods, single-pass sequencing and basic local alignment search tool (BLAST) analyses. Chapter 3 introduces suppression subtractive hybridisation (SSH) as a tool to further identify NBS-LRR or other resistance-related sequences in RWA infested wheat plants. SSH allows the comparative analysis of differential gene expression in RWA infested and uninfested wheat in order to identify resistance-¬related genes expressed in the infested, resistant wheat plants. The effect of RWA infestation on wheat resistance responses was examined further in chapter 4 through microarray analysis. The aim was the introduction and establishment of the microarray technique and to test the feasibility of using microarrays for differential gene expression and regulation studies. Microarray slides were assembled in order to monitor the up- and down¬regulation of genes at different time intervals - day 2, day 5 and day 8 - of RWA infestation. Clones isolated throughout this study were assembled on microarray slides and probed with control and RWA infested RNA. Differential gene regulation was assessed and further confirmed through Northern blot analyses, as well as quantitative real-time PCR. The thesis concludes with a general summary of the results obtained in chapter 5 and future prospects are outlined. / Thesis (PhD(Genetics))--University of Pretoria, 2005. / Genetics / unrestricted
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Comparing suppression subtractive hybridization and bioinformatics approaches for analyzing functional gene expression in Arabidopsis thaliana following a heat shock treatmentBhamjee, Rabia Ahmid 03 May 2012 (has links)
M.Sc. / Since plants are stationary, their immune systems have adapted to their environments to enable them to overcome or respond appropriately to various environmental, physical and physiological stresses that they may encounter by developing complicated defense mechanisms. The plant defense response activates complex biochemical and structural changes in plant cells. Heat stress per se, appears to be a priority stress response in plants, and increased disease susceptibility may be a result of this response. In this study, altered gene expression levels mediated by a heat treatment in Arabidopsis thaliana seedlings were analyzed. Seedlings were exposed to a heat stress of 42C for 30 minutes, followed by a 2.5 hour recovery period at 25ºC. RNA that was isolated from the heat stress treated plants as well as control plants (untreated) was used to perform suppression subtractive hybridization (SSH) in order to obtain a forward and a reverse DNA library. The forward SSH library represented the genes that were up-regulated due to the heat shock and the reverse SSH library represented the down-regulated genes. Sequenced clones from these libraries were BLAST against the A. thaliana genome using the Genbank database and the Accession numbers retrieved were then used for Bioinformatics analysis to obtain functionality of the genes found. The bioinformatics tools used were TAIR tools, DAG graphs and FatiGO and genes were categorized into the biological processes, molecular functions and cellular components. The TAIR tools and FatiGO were then used to analyze microarray data obtained for a similar study, in order to compare the genes identified with SSH. The genes coding for photosystem IID, serine-type peptidase, phospholipase D α, a S-locus protein kinase, regulator of chromosome condensation (RCC1) and Glucose-6-phosphate translocator are prominently up-regulated whilst other genes encoding photosystem I, plastocyanin-like mavicyanin, carbohydrate trans-membrane transporter MSS1, zinc finger C3HC4 ring family protein, ubiquitin conjugating enzyme 35 (UBC35) and integral membrane family proteins are significantly down-regulated. The FatiGO results helped to assign functionality to the genes that were found. For the SSH forward library, the cellular protein metabolic pathway was the most highly expressed term (19.21%), whereas in the microarray data, the term „positive regulation of response to stimulus‟ and membrane disassembly had a 100% expression. The reverse SSH data (down-regulation) found phosphate metabolic process as the most highly expressed term with an expression of 44.36% ix and the microarray data (negative fold-change) found the term photorespiration to be the most highly expressed with 93.54% expression. These high levels of negative expression indicate the down-regulation of these processes in the cell during heat shock. From these results it can be assumed that at the onset of a heat stress, the plant‟s immediate response is to activate pathways of regulation as a response to the stimulus as a self-protection mechanism, and repress other pathways such as photorespiration in order to preserve its energy such as ATP. These findings suggest that the plant is well equipped to overcome stress in its environment by activation/repression of specific organelles and pathways in the system, in order to maintain its equilibrium. Studies such as these can prove to be helpful to solve the interesting question of how a plant overcomes various environmental stresses in order to prevent disease susceptibility.
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MANAGING SOIL MICROBIAL COMMUNITIES WITH ORGANIC AMENDMENTS TO PROMOTE SOIL AGGREGATE FORMATION AND PLANT HEALTHLucas, Shawn T. 01 January 2013 (has links)
The effects of managing soil with organic amendments were examined with respect to soil microbial community dynamics, macroaggregate formation, and plant physio-genetic responses. The objective was to examine the possibility of managing soil microbial communities via soil management, such that the microbial community would provide agronomic benefits. In part one of this research, effects of three amendments (hairy vetch residue, manure, compost) on soil chemical and microbial properties were examined relative to formation of large macroaggregates in three different soils. Vetch and manure promoted fungal proliferation (measured via two biomarkers: fatty acid methyl ester 18:2ω6c and ergosterol) and also stimulated the greatest macroaggregate formation. In part two of this research, effects of soil management (same amendments as above, inorganic N fertilization, organic production) on soil chemical and microbial properties were examined relative to the expression of nitrogen assimilation and defense response genes in tomato (Solanum lycopersicum L.). Soil management affected expression of a nitrogen assimilation gene (GS1, glutamine synthetase) and several defense-related genes. The GS1 gene was downregulated with inorganic N fertilization, expression of the pathogenesis-related PR1b gene (which codes for the pathogenesis-related PR1b protein) was increased in plants grown in soil amended with compost, vetch, and N fertilizer, and expression of three other defense-related genes coding for chitinase (ChiB), osmotin (Osm), and β-1,3-glucanase (GluA) were decreased in plants from soil amended with manure and in plants from the organically managed soil. Differential expression of defense-related genes was inversely related to the relative abundance of Gram-negative bacteria. The relative abundance of the 18:1ω7c Gram‑negative bacterial biomarker was greatest in manure treated soil and in organically managed soil (which recieves seasonal manure applications). These treatments also had the lowest expression of ChiB, Osm, and GluA, leading to speculation that manure, through increases in Gram-negative bacteria, may have suppressed populations of soil organisms that induce a defense response in plants, possibly allowing for less-stressed plants. Outcomes of this research may be useful for those interested in developing management strategies for maintaining or improving soil structure as well as those interested in understanding management effects plant physio-genetic responses.
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QPRTase : a wound-induced defence gene in NicotianaSinclair, Steven J. January 2003 (has links)
Abstract not available
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Characterization of Pea (Pisum Sativum L.) genes implicated in arbuscular mycorrhiza formation and functionKuznetsova, Elena 21 October 2010 (has links) (PDF)
The arbuscular mycorrhizal (AM) association results from a successful interaction between the genomes of the two symbiotic partners. In this context, the aim of my research was to better characterize the role of the late stage symbiosis-related pea genes PsSym36, PsSym33 and PsSym40 in the functional AM (i) by investigating the effect of mutations in the three genes on fungal and plant gene responses and (ii) by creating conditions for the localization of two of the genes, PsSym36 and PsSym40, on the pea genetic map for future map-based cloning. The expression of a subset of ten fungal and eight plant genes,previously reported to be activated during mycorrhiza development, was compared in Glomus intraradices-inoculated roots of wild type and Pssym36, Pssym33 and Pssym40 mutant pea plants. Most of the fungal genes were down-regulated in roots of the Pssym36 mutant where arbuscule formation is defective, and several were upregulated with more rapid fungal development in roots of the Pssym40 mutant. Microdissection of mycorrhizal PsSym40 roots corroborated preferential expression of the three G. intraradices genes SOD, DESAT and PEPISOM in arbuscule-containing cells. Inactivation of PsSym36 also resulted in down regulation of plant genes whilst mutation of the PsSym33 and PsSym40 genes affected plant gene responses in a more time-dependent way. Results thus indicate an implication of the investigated pea SYM genes in the modulation of plant and fungal molecular interactions linked to signaling, nutrient exchange or stress response regulation during AM symbiosis formation and functioning. Conditions for localization of the PsSym36 and PsSym40 genes on the pea genetic map were developed for their future map-based cloning. Based on the molecular markers obtained, it was possible to conclude that localization of the PsSym40 gene most likely resides outside the linkage groups I, II, III or V of the genetic map of pea.
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Expression behaviour of primary carbon metabolism genes during sugarcane culm developmentMcCormick, Alistair James 04 1900 (has links)
Thesis (MSc)--University of Stellenbosch, 2004. / ENGLISH ABSTRACT: Despite numerous attempts involving a variety of target genes, the successful
transgenic manipulation of sucrose accumulation in sugarcane remains elusive. It is
becoming increasingly apparent that enhancing sucrose storage in the culm by
molecular means may depend on the modification of the activity of a novel gene
target. One possible approach to identify target genes playing crucial coarse
regulatory roles in sucrose accumulation is to assess gene expression during the
developmental transition of the culm from active growth to maturation. This study
has resulted in the successful optimisation of a mRNA hybridisation technique to
characterise the expression of 90 carbohydrate metabolism-related genes in three
developmentally distinct regions of sugarcane culm. A further goal of this work was
to extend the limited knowledge of the regulation of sucrose metabolism in sugarcane,
as well as to complement existing data from physiological and biochemical studies.
Three mRNA populations derived from the different culm regions were assayed and
their hybridisation intensities to the immobilised gene sequences statistically
evaluated. The relative mRNA transcript abundance of 74 genes from three differing
regions of culm maturity was documented. Genes exhibiting high relative expression
in the culm included aldolase, hexokinase, cellulase, alcohol dehydrogenase and
soluble acid invertase. Several genes (15) were demonstrated to have significantly
different expression levels in the culm regions assessed. These included UDP-glucose
pyrophosphorylase and UDP-glucose dehydrogenase, which were down-regulated
between immature and mature internodes. Conversely, sucrose phosphate synthase,
sucrose synthase and neutral invertase exhibited up-regulation in maturing internodal
tissue. A variety of sugar transporters were also found to be up-regulated in mature
culm, indicating a possible control point of flux into mature stem sink tissues.
Combined with knowledge of the levels of key metabolites and metabolic
intermediates this gene expression data will contribute to identifying key control
points of sucrose accumulation in sugarcane and assist in the identification of gene
targets for future manipulation by transgenic approaches. / AFRIKAANSE OPSOMMING: Ondanks verskeie pogings, waartydens verskeie gene geteiken is, is daar nog weinig
sukses behaal om sukrose-akkumulering te verhoog. Toenemend wil dit voorkom
asof suksesvolle genetiese manipulering van sukroseberging in die stingel van die
verandering van ‘n nuwe geen afhanklik sal wees. Een van die moontlike benaderings
wat gevolg kan word om potensiële teiken gene wat ‘n belangrike rol in die beheer
van sukrose-opberging speel te identifiseer, is om geen uitdrukkingspatrone in die
stingel tydens die omskakeling van aktiewe groei tot volwassenheid te karakteriseer.
In hierdie studie is ‘n metode gebaseer op die hibridisering van mRNA geoptimiseer
en suksesvol aangewend om die uitdrukkingspatrone van 90 verskillende
geselekteerde gene, wat vir sleutelensieme in die beheer van koolhidraatmetabolisme
kodeer, te bestudeer. Die doel met die ondersoek was om die beperkte kennis oor die
regulering van koolhidraatmetabolisme uit te brei en om die bestaande inligting
afgelei van fisiologiese en biochemiese-studies aan te vul. Drie verskillende mRNApopulasies,
verkry uit verskillende dele van die stingel, is ontleed deur verskillende
peilers te gebruik. Die gegewens is statisties ontleed en dit het afleidings oor die
verandering in uitdrukking van hierdie gene moontlik gemaak. Die relatiewe
konsentrasies van 74 verskillende gene is gedokumenteer. Gene wat sterk uitgedruk
word het aldolase, heksokinase, sellulase, alkoholdehidrogenase en ongebonde
suurinvertase ingesluit. Die uitdrukkingspatrone van 15 gene het tussen die
verkillende weefsels gevarieer. Gene waarvan die uitdrukking tydens die oorgang na
volwassenheid verlaag sluit in UDP-glukose pirofosforilase en UDP-glukose
dehidrogenase en waarvan die uitdrukking verhoog sukrosefosfaatsintase,
sukrosesintase en neutrale invertase in. Die uitdrukking van verskeie
suikertransporter gene verhoog tydens volwassewording. Hierdie inligting te same
met die huidige kennis oor heersende metabolietvlakke sal bydrae tot die
identifisering van geenteikens vir toekomstige genetiese manupulering.
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Characterization of Pea (Pisum Sativum L.) genes implicated in arbuscular mycorrhiza formation and function / Caractérisation de gènes de pois (Pisum sativum L.) impliqués dans la formation et le fonctionnement de la mycorhize à arbusculesKuznetsova, Elena Vladislavovna 21 October 2010 (has links)
L’association mycorhizienne à arbuscules (AM) est le résultat d’une interaction compatible entre les génomes des deux partenaires symbiotiques. Dans ce contexte, le but de mes recherches a été de mieux caractériser le rôle des gènes de pois liés aux stades tardifs de la symbiose, PsSym36, PsSym33 and PsSym40, dans le fonctionnement de la symbiose MA (i) en étudiant l’effet des mutations de ces trois gènes sur l’expression des gènes de la plante et du champignon, et (ii) en créant les conditions pour positionner deux de ces gènes, PsSym36 and PsSym40, sur la carte génétique afin d’envisager leur clonage futur. L’expression d’un groupe de dix gènes fongiques et de huit gènes de plante, déjà décrits pour être activés durant le développement de la mycorhize, a été comparée dans les racines de pois inoculées avec G. intraradices chez les plantes de génotypes sauvages, ou les mutants Pssym36, Pssym33 et Pssym40. L’expression de la plupart des gènes fongiques a été inhibée dans les racines du mutant Pssym36 où la formation des arbuscules est avortée, tandis que l’expression de plusieurs d’entre eux a été activée lorsqu’il existe un développement plus rapide du champignon dans les racines du mutant Pssym40. Des microdisséquats obtenus à partir de racines mycorhizées du mutant PsSym40 confirment l’expression préférentielle de trois gènes de G. intraradices (SOD, DESAT et PEPISOM) dans les cellules contenant les arbuscules. L’inactivation du gène PsSym36 provoque également une inhibition des gènes de plante alors que la mutation des gènes PsSym33 and PsSym40 affecte l’expression des gènes de plante plutôt de façon temporelle. Les résultats indiquent ainsi une implication des gènes SYM de pois dans la modulation des interactions moléculaires entre la plante et le champignon impliquées au niveau de la signalisation, des échanges nutritifs ou de la régulation des réponses au stress durant la formation et/ou le fonctionnement de la symbiose AM. Les conditions pour la localisation des gènes PsSym36 and PsSym40 sur la carte génétique du pois ont été développées pour leur clonage basé sur la cartographie. En utilisant les marqueurs moléculaires obtenus, il a été possible de conclure que la localisation du gène PsSym40 réside vraisemblablement à l’extérieur des groupes de liaison I, II, III ou V de la carte génétique du pois. / The arbuscular mycorrhizal (AM) association results from a successful interaction between the genomes of the two symbiotic partners. In this context, the aim of my research was to better characterize the role of the late stage symbiosis-related pea genes PsSym36, PsSym33 and PsSym40 in the functional AM (i) by investigating the effect of mutations in the three genes on fungal and plant gene responses and (ii) by creating conditions for the localization of two of the genes, PsSym36 and PsSym40, on the pea genetic map for future map-based cloning. The expression of a subset of ten fungal and eight plant genes,previously reported to be activated during mycorrhiza development, was compared in Glomus intraradices-inoculated roots of wild type and Pssym36, Pssym33 and Pssym40 mutant pea plants. Most of the fungal genes were down-regulated in roots of the Pssym36 mutant where arbuscule formation is defective, and several were upregulated with more rapid fungal development in roots of the Pssym40 mutant. Microdissection of mycorrhizal PsSym40 roots corroborated preferential expression of the three G. intraradices genes SOD, DESAT and PEPISOM in arbuscule-containing cells. Inactivation of PsSym36 also resulted in down regulation of plant genes whilst mutation of the PsSym33 and PsSym40 genes affected plant gene responses in a more time-dependent way. Results thus indicate an implication of the investigated pea SYM genes in the modulation of plant and fungal molecular interactions linked to signaling, nutrient exchange or stress response regulation during AM symbiosis formation and functioning. Conditions for localization of the PsSym36 and PsSym40 genes on the pea genetic map were developed for their future map-based cloning. Based on the molecular markers obtained, it was possible to conclude that localization of the PsSym40 gene most likely resides outside the linkage groups I, II, III or V of the genetic map of pea. / Формирование арбускулярной микоризы (АМ) является результатом успешного взаимодействия между геномами двух симбиотических партнёров. Целью моего исследования являлось изучение роли поздних симбиотических генов гороха PsSym36, PsSym33 и PsSym40 в формировании функционального АМ симбиоза. Для этого было проведено исследование эффекта мутаций в генах PsSym36, PsSym33 и PsSym40 на экспрессию грибных и растительных генов, предположительно (по литературным данным) вовлечённых в процессы формирования АМ, а так же проведена работа по локализации генов PsSym36 и PsSym40 на генетической карте гороха для последующего более точного картирования и позиционного клонирования данных генов. Экспрессия десяти грибных и восьми растительных генов была определена в корнях растений дикого типа и PsSym36, PsSym33 и PsSym40 мутантов, инокулированных G. intraradices. В корнях PsSym36 мутанта, имеющего дефект развития арбускул, большая часть грибных генов была супрессирована, в то время как в корнях PsSym40 мутанта, для которого характерна более быстрая по сравнению с диким типом микоризация, был отмечен более высокий уровень экспрессии грибных генов. Использование метода микродиссекций позволило выделить клетки, содержащие арбускулы, из микоризованных корней мутанта PsSym40 и подтвердить, что гены G. intraradices SOD, DESAT и PEPISOM преимущественно экспрессируются в клетках, содержащих арбускулы. Мутация в гене PsSym36 также привела к подавлению экспрессии большинства вовлечённых в анализ растительных генов, тогда как мутации в генах PsSym33 и PsSym40 оказали влияние на ксперессию растительных генов в меньшей степени. Полученные результаты свидетельствуют о роли исследуемых SYM генов гороха в контролировании растительно-грибных молекулярных взаимодействий, связанных с сигналингом, обменом питательными веществами и стрессовыми реакциями в процессе формирования и функционирования АМ симбиоза. Проведённое генетическое картирование не привело к локализации генов PsSym36 и PsSym40 на генетической карте гороха. Однако разработка и использование молекулярных маркеров для картирования позволили исключить локализацию гена PsSym40 в I, II, III и V группах сцепления с высокой долей вероятности.
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