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Статті в журналах з теми "Grapes Genetics"
Qu, Xianping, Jiang Lu, and Olusola Lamikanra. "Genetic Diversity in Muscadine and American Bunch Grapes Based on Randomly Amplified Polymorphic DNA (RAPD) Analysis." Journal of the American Society for Horticultural Science 121, no. 6 (November 1996): 1020–23. http://dx.doi.org/10.21273/jashs.121.6.1020.
Повний текст джерелаRahman, M. Atikur, Subramani P. Balasubramani, and Sheikh M. Basha. "Molecular Characterization and Phylogenetic Analysis of MADS-Box Gene VroAGL11 Associated with Stenospermocarpic Seedlessness in Muscadine Grapes." Genes 12, no. 2 (February 5, 2021): 232. http://dx.doi.org/10.3390/genes12020232.
Повний текст джерелаZhang, Zhan, Luming Zou, Chong Ren, Fengrui Ren, Yi Wang, Peige Fan, Shaohua Li, and Zhenchang Liang. "VvSWEET10 Mediates Sugar Accumulation in Grapes." Genes 10, no. 4 (March 28, 2019): 255. http://dx.doi.org/10.3390/genes10040255.
Повний текст джерелаMorris, J. R., W. A. Sistrunk, J. Junek, and C. A. Sims. "Effects of Fruit Maturity, Juice Storage, and Juice Extraction Temperature on Quality of ‘Concord’ Grape Juice." Journal of the American Society for Horticultural Science 111, no. 5 (September 1986): 742–46. http://dx.doi.org/10.21273/jashs.111.5.742.
Повний текст джерелаBowers, J. E., G. S. Dangl, R. Vignani, and C. P. Meredith. "Isolation and characterization of new polymorphic simple sequence repeat loci in grape (Vitis vinifera L.)." Genome 39, no. 4 (August 1, 1996): 628–33. http://dx.doi.org/10.1139/g96-080.
Повний текст джерелаGao, Huanhuan, Xiangtian Yin, Xilong Jiang, Hongmei Shi, Yang Yang, Chaoping Wang, Xiaoyan Dai, Yingchun Chen, and Xinying Wu. "Diversity and spoilage potential of microbial communities associated with grape sour rot in eastern coastal areas of China." PeerJ 8 (June 16, 2020): e9376. http://dx.doi.org/10.7717/peerj.9376.
Повний текст джерелаJabco, Jeffrey P., William B. Nesbitt, and Dennis J. Werner. "Resistance of Various Classes of Grapes to the Bunch and Muscadine Grape Forms of Black Rot." Journal of the American Society for Horticultural Science 110, no. 6 (November 1985): 762–65. http://dx.doi.org/10.21273/jashs.110.6.762.
Повний текст джерелаSims, Charles A., Richard P. Johnson, Robert P. Bates, and Linda F. Moore. "Harvest Method and Sulfur Dioxide Influence the Postharvest Quality of ‘Noble’ and ‘Stover’ Wine Grapes." Journal of the American Society for Horticultural Science 114, no. 1 (January 1989): 77–81. http://dx.doi.org/10.21273/jashs.114.1.77.
Повний текст джерелаKupe, Muhammed, Sezai Ercisli, Tatjana Jovanovic-Cvetkovic, Sadiye Eyduran, and Rayda Ayed. "Molecular characterization of wild grapes from northeastern part of Turkey." Genetika 53, no. 1 (2021): 93–102. http://dx.doi.org/10.2298/gensr2101093k.
Повний текст джерелаKarn, Avinash, Luis Diaz-Garcia, Noam Reshef, Cheng Zou, David C. Manns, Lance Cadle-Davidson, Anna Katharine Mansfield, Bruce I. Reisch, and Gavin L. Sacks. "The Genetic Basis of Anthocyanin Acylation in North American Grapes (Vitis spp.)." Genes 12, no. 12 (December 9, 2021): 1962. http://dx.doi.org/10.3390/genes12121962.
Повний текст джерелаДисертації з теми "Grapes Genetics"
Ross-Adams, Helen Esther. "The characterisation of selected grapevine cultivars using microsatellites." Thesis, Stellenbosch : Stellenbosch University, 2002. http://hdl.handle.net/10019.1/53092.
Повний текст джерелаENGLISH ABSTRACT: Grapevine supports one of the oldest industries in South Africa today, and is also of significant international importance. With increasing international trade and the transport of fruit and other grapevine-derived products between borders, it has become increasingly important for South African farmers and viticulturalists to ensure their products conform to strict international market requirements if they are to remain competitive. Such requirements include the correct and accurate identification of berries and wines according to cultivar. In light of this, 26 different wine, table grape and rootstock cultivars, as well as a number of clones from KWV's core germplasm collection were characterised at 16 microsatellite marker loci. Microsatellite markers are known for their high level of informativeness, reliability and reproducibility, and are widely used in the identification and characterisation of plant varieties, population analyses and forensic applications. Unique allelic profiles were obtained for all but two plants, which proved to be identical at all loci considered, and thus 'clones'. These profiles were collated to form a database, containing the DNA fingerprints of each sample at each locus. The relative levels of informativeness of each marker used were also determined, and compared with those found in the literature. Six markers proved to be highly informative, and are promising in the potential application of this technology to other cultivars. The applicability of microsatellite markers to such studies is confirmed; this approach could easily be extended to include any number of cultivars of national and international interest. The results of such an investigation would have important implications for both the farming and commercial industries alike.
AFRIKAANSE OPSOMMING: Wingerd ondersteun een van die oudste industriee in Suid-Afrika vandag, en is ook van groat intemasionale belang. Met die toenemende intemasionale ruilhandel en die vervoer van vrugte en ander wingerd produkte tussen grense, het dit toenemend belangrik geword vir SuidAfrikaanse wingerdboere om te. verseker dat hulle produkte voldoen aan die streng vereistes van die intemasional mark, indien hulle kompeterend wil bly. Hierdie vereistes sluit in die korrekte en akkurate identifisering van druiwe en wyn volgens kultivar. Met hierdie vereistes in ag geneem, is 26 verskillende wyn, tafeldruif en wortelstok kultivars, asook 'n aantal klone van die KWV se kern kiemplasma versameling, gekarakteriseer by 16 mikrosatelliet merker loki. Mikrosatelliet merkers word gekenmerk deur 'n hoe vlak van informatiwiteit, betroubaarheid en herhaalbaarheid en word wydverspreid gebruik in die identifisering en karakterisering van plant varieteite, populasie analises en forensiese toepassings. Unieke alleliese profiele is vir a1 die plante verkry, behalwe vir twee plante wat identiese resultate by alle loki opgelewer het en dus as "klone" beskou kan word. Hierdie profiele is bymekaar gevoeg om 'n databasis te vorm wat die DNA vingerafdrukke van elke monster by elke lokus bevat. Die relatiewe vlak van informatiwiteit van al die merkers is ook bepaal en vergelyk met merkers in die literatuur. Ses van die merkers blyk om hoogs informatief te wees en lyk belowend in die potensiele toepassing van hierdie tegnologie op ander kultivars. Die toepaslikheid van mikrosatelliet merkers op sulke studies is bevestig; hierdie benadering kan maklik aangepas word om enige aantal kultivars van nasionale en intemasionale belang in te sluit. Die resultate van s6 'n ondersoek sal belangrike implikasies inhou vir beide die boerdery en kommersiele industriee.
Espach, Yolandi. "The detection of mycoviral sequences in grapevine using next-generation sequencing." Thesis, Stellenbosch : Stellenbosch University, 2013. http://hdl.handle.net/10019.1/80025.
Повний текст джерелаENGLISH ABSTRACT: Metagenomic studies that make use of next-generation sequencing (NGS) generate large amounts of sequence data, representing the genomes of multiple organisms of which no prior knowledge is necessarily available. In this study, a metagenomic NGS approach was used to detect multiple novel mycoviral sequences in grapevine phloem tissue. Individual sequencing libraries of doublestranded RNA (dsRNA) from two grapevine leafroll diseased (GLD) and three shiraz diseased (SD) vines were sequenced using an Illumina HiScanSQ instrument. Over 3.2 million reads were generated from each of the samples and these reads were trimmed and filtered for quality before being de novo assembled into longer contigs. The assembled contigs were subjected to BLAST (Basic Local Alignment Search Tool) analyses against the NCBI (National Centre for Biotechnology Information) database and classified according to database sequences with which they had the highest identity. Twenty-six putative mycovirus species were identified, belonging to the families Chrysoviridae, Endornaviridae, Narnaviridae, Partitiviridae and Totiviridae. Two of the identified mycoviruses, namely grapevine-associated chrysovirus (GaCV) and grapevine-associated mycovirus 1 (GaMV-1) have previously been identified in grapevine while the rest appeared to be novel mycoviruses not present in the NCBI database. Primers were designed from the de novo assembled mycoviral sequences and used to screen the grapevine dsRNA used for sequencing as well as endophytic fungi isolated from the five sample vines. Only two mycoviruses, related to sclerotinia sclerotiorum partitivirus S and chalara elegans endornavirus 1 (CeEV-1), could be detected in grapevine dsRNA and in fungus isolates. In order to validate the presence of mycoviruses in grapevine phloem tissue, two additional sequencing runs, using an Illumina HiScanSQ and an Applied Biosystems (ABI) SOLiD 5500xl instrument respectively, were performed. These runs generated more and higher quality sequence data than the first sequencing run. Twenty-two of the putative mycoviral sequences initially detected were detected in the subsequent sequence datasets, as well as an additional 29 species not identified in the first HiScanSQ sequence datasets. The samples harboured diverse mycovirus populations, with as many as 19 putative species identified in a single vine. This indicates that the complete virome of diseased grapevines will include a high number of mycoviruses. Additionally, the complete genome of a novel endornavirus, for which we propose the name grapevine endophyte endornavirus (GEEV), was assembled from one of the second HiScanSQ sequence datasets. This is the first complete genome of a mycovirus detected in grapevine. Grapevine endophyte endornavirus has the highest sequence similarity to CeEV-1 and is the same virus that was previously detected in fungus isolates using the mycovirus primers. The virus was detected in two fungus isolates, namely Stemphylium sp. and Aureobasidium pullulans, which is of interest since mycoviruses are not known to be naturally associated with two distinctly different fungus genera. Mycoviral sequence data generated in this study can be used to further investigate the diversity and the effect of mycoviruses in grapevine.
AFRIKAANSE OPSOMMING: Metagenomiese studies, wat gebruik maak van volgende-generasie volgordebepalingstegnologie, het die vermoë om die genetiese samestelling van veelvoudige onbekende organismes te bepaal deurdat dit groot hoeveelhede data genereer. Die bogenoemde tegniek was in hierdie studie aangewend om aantal nuwe mikovirusse in die floëem weefsel van wingerd te identifiseer. Dubbelstring-RNS was gesuiwer vanuit twee druiwestokke met rolbladsiekte en drie met shirazsiekte en Illumina HiScanSQ instrument is gebruik om meer as 3.2 miljoen volgorde fragmente te genereer van elk van die monsters. Lae-kwaliteit volgordes was verwyder en die oorblywende kort volgorde fragmente was saamgestel om langer konstrukte te vorm wat met behulp van BLAST soektogte teen die NCBI databasis geïdentifiseer kon word. Ses-en-twintig mikovirus spesies, wat aan die families Chrysoviridae, Endornaviridae, Narnaviridae, Partitiviridae en Totiviridae behoort, was geïdentifiseer. Twee van die geïdentifiseerde mikovirusse, naamlik grapevine-associated chrysovirus (GaCV) en grapevine-associated mycovirus 1 (GaMV-1), was voorheen al in wingerd gekry terwyl die res nuwe mikovirusse is wat tans nie in die NCBI databasis voorkom nie. Inleiers was ontwerp vanaf die saamgestelde mikovirus basisvolgordes en gebruik om wingerd dubbelstring-RNS sowel as swamme wat vanuit die wingerd geïsoleer is te toets vir die teenwoordigheid van hierdie mikovirusse. Slegs twee mikovirusse, wat onderskeidelik verwant is aan sclerotinia sclerotiorum partitivirus S en chalara elegans endornavirus 1 (CeEV-1), kon deur middel van die inleiers in wingerd en swam isolate geïdentifiseer word. Twee addisionele volgordebepalingsreaksies, wat gebruik gemaak het van die Illumina HiScanSQ en ABI SOLiD 5500xl volgordebepalingsplatforms, was gebruik om die teenwoordigheid van mikovirusse in wingerd te bevestig. Groter hoeveelheid volgorde fragmente was geprodusser wat ook van hoër gehalte was as dié van die eerste volgordebepalingsreaksie. Twee-en-twintig mikovirus spesies kon weer geïdentifiseer word, sowel as 29 spesies wat nie in die eerste HiScanSQ basisvolgorde datastelle gevind was nie. Die wingerdstokke wat in hierdie studie ondersoek was, het hoë diversiteit van mikovirusse bevat aangesien daar tot 19 mikovirus spesies in enkele wingerdstok geïdentifiseer was. Dit is aanduiding dat volledige virus profiele van siek wingerdstokke aantal mikovirusse sal insluit. Die vollengte genoomvolgorde van voorheen onbekende endornavirus was saamgestel vanuit een van die tweede HiScanSQ volgorde datastelle. Dit is die eerste mikovirus wat in wingerd gevind word waarvan die volledige genoomvolgorde bepaal is en ons stel die naam grapevine endophyte endornavirus (GEEV) voor vir hierdie virus. Grapevine endophyte endornavirus is die naaste verwant aan CeEV-1 en is dieselfde virus wat voorheen in wingerd dubbelstring-RNS en swam isolate gevind was deur middel van die mikovirus inleiers. Swam isolate waarin GEEV gevind is, was geïdentifiseer as Stemphylium sp. en Aureobasidium pullulans. Dit is van belang dat GEEV in twee swam isolate gevind is wat aan verskillende genusse behoort aangesien hierdie verskynsel nog nie voorheen in die natuur gevind is nie. Mikovirus nukleiensuurvolgordes wat in hierdie studie bepaal was kan gebruik word in toekomstige studies om die verskeidenheid en impak van mikovirusse in wingerd verder te ondersoek.
National Research Foundation (NRF)
Stellenbosch University
Venter, Mauritz. "Isolation of grapevine promoters with special emphasis on the vacuolar pyrophosphatase." Thesis, Stellenbosch : University of Stellenbosch, 2004. http://hdl.handle.net/10019.1/16078.
Повний текст джерелаENGLISH ABSTRACT: Understanding the complex nature of grapevine molecular biology is of great importance for viticulturists. Progress in the elucidation of key events on a genetic level could provide further insight into the underlying cues responsible for the precise control of physiological and metabolic changes during a specific condition such as fruit development. The use and analysis of molecular ‘tools’, such as promoters controlling the site and level of gene activity, could assist in the understanding of grapevine biology and serve as a platform for the future design and development of recombinant DNA protocols and strategies for Vitis vinifera L. A high-throughput gene expression system, cDNA-AFLPs, was successfully used to analyse large-scale transcriptional activity during berry ripening. Candidate cDNA fragments were selected on the basis of desired expression patterns and/or known gene function for subsequent promoter isolation. From three candidate cDNAs selected, the promoter of a gene encoding vacuolar pyrophosphatase (V-PPase) was isolated for computational and comparative analyses. Promoter activity was evaluated on a transient level using the green fluorescent protein (GFP) reporter gene. Comparative integration has allowed for putative correlation of cis-elements, acting as receptors within promoter regions, to regulate V-PPase gene expression in response to development, environmental stress and tissue-specificity. In this study, integration of genetic data have advanced the understanding and transcriptional role of a key enzyme (V-PPase) during grape ripening. Although never a replacement for experimental verification, this integrative strategy of combining gene expression profiles with bioinformatics and regulatory data will greatly assist in further elucidation of various other key components and regulatory cues associated with grapevine molecular biology. This study has allowed us to use molecular tools that could assist in gaining further insight into genetic complexities and could serve as a platform for a more refined genetic manipulation strategy in Vitis vinifera L.
AFRIKAANSE OPSOMMING: Begrip van die komplekse aard van wingerd molekulêre biologie is van groot belang vir wingerdkundiges. Vooruitgang in die begrip van belangrike gebeurtenisse op ń genetiese vlak behoort verdere insig in die onderliggende instruksies vir die noukeurige beheer van fisiologiese en metaboliese veranderinge tydens ń spesifieke kondisie soos vrug rypwording te bevorder. Die gebruik en analise van molekulêre ‘instrumente’ soos promoters, wat die posisie en vlak van geen aktiwiteit beheer, kan bydra tot n beter begrip van wingerd biologie en sodoende dien as ń platform vir die toekomstige ontwerp en ontwikkeling van rekombinante DNS (deoksiribonukleiensuur) protokolle en strategieë vir Vitis vinifera L. ń Hoë-kapasiteit geen uitdrukkings sisteem, nl. kDNS-AFLPs (komplementêre deoksiribonukleiensuur- geamplifiseerde fragment lengte polimorfisme), is suksesvol gebruik vir die analise van grootskaalse transkripsionele aktiwiteit tydens druif rypwording. Kandidaat kDNS fragmente is geselekteer, gebaseer op verlangde uitdrukkings-patrone en/of bekende geen funksie vir daaropvolgende promoter isolering. Van drie geselekteerde kandidaat kDNS fragmente, is die promoter van ń geen wat vakuolêre pirofosfatase (V-PPase) kodeer geïsoleer vir rekenaar- en vergelykende analise. Promoter aktiwiteit is op ń nie-stabiele vlak deur die gebruik van ń groen-fluoresserende proteien (GFP) verklikker geen geëvalueer. Vergelykende integrering het dit moontlik gemaak om veronderstelde korrelasies van cis-elemente, wat as reseptore binne ń promoter area dien, en die regulering van V-PPase geen uitdrukking, in reaksie tot ontwikkeling, omgewings stres en weefsel-spesifisiteit, te maak. Tydens hierdie studie, het die integrering van genetiese data gehelp om die transkripsionele rol van ń belangrike ensiem (V-PPase) tydens druif rypwording beter te verstaan. Alhoewel dit nooit ń plaasvervanger vir eksperimentele bewyse sal wees nie, kan hierdie gëintegreerde strategie, wat die kombinasie van geen-uitdrukkingsprofiele met bioinformatika en regulatoriese data behels, grootliks bydra om verskeie ander belangrike komponente en regulatorieseaanwysings geassosieërd met wingerd molekulêre biologie te ontrafel. Hierdie studie het verdere insig in genetiese kompleksiteite verleen, en kan nou dien as ń platform vir ń meer presiese genetiese manipulering strategie in Vitis vinifera L.
Robson, Julia. "The construction of an expression vector for the transformation of the grape chloroplast genome." Thesis, Stellenbosch : Stellenbosch University, 2003. http://hdl.handle.net/10019.1/53621.
Повний текст джерелаENGLISH ABSTRACT: The genetic information of plants is found in the nucleus, the mitochondria, and the plastids. The DNA of plastids is comprised of multiple copies of a double-stranded, circular, prokaryoticallyderived genome of -150 kb. The genome equivalents of plastid organelles in higher plant cells are an attractive target for genetic engineering as high protein expression levels are readily obtained due to the high genome copy number per organelle. The resultant proteins are contained within the plastid organelle and the corresponding transgenes are inherited, in most crop plants, uniparentally, preventing pollen transmission of DNA. Plastid transformation involves the uniform modification of all the plastid genome copies, a process facilitated by homologous recombination and the non-Mendelian segregation of plastids upon cell division. The plastid genomes are in a continuous state of inter- and intra-molecular exchange due to their common genetic complement. This enables the site-specific integration of any piece of DNA flanked by plastid targeting sequences, via homologous recombination. The attainment of homoplasmy, where all genomes are transformed, requires the inclusion of a plastid-specific selectable marker. Selective pressure favouring the propagation of the transformed genome copies, as well as the random segregation of plastids upon cell division, make it feasible to acquire uniformity and hence genetic stability. From this, a complete transplastomie line is obtained where all plastid genome copies present are transgenic, having eliminated all wild-type genome copies. The prokaryotic nature of the chloroplast genetic system enables expression of multiple proteins from polycistronic mRNAs, allowing the introduction of entire operons in a single transformation. Expression cassettes in vectors thus include single regulatory elements of plastid origin, and harbour genes encoding selectable and screenable markers, as well as one or more genes of interest. Each coding region is preceded by an appropriate translation control region to ensure efficient translation from the polycistronic mRNA. The function of a plastid transformation vector is to enable transfer and stable integration of foreign genes into the chloroplast genomes of higher plants. The expression vector constructed in this research is specific for the transformation of the grape chloroplast genome. Vitis vinifera L., from the family, Vitaceae, is the choice species for the production of wine and therefore our target for plastid transformation. All chloroplast derived regulatory elements and sequences included in the vector thus originated from this species.
AFRIKAANSE OPSOMMING: Die genetiese inligting van plante word gevind in die kern, die mitochondria, en die plastiede. Die DNA van plastiede bestaan uit veelvuldige kopieë van 'n ~ 150 kb dubbelstring, sirkulêre genoom van prokariotiese oorsprong. Die genoomekwivalente van plastiede in hoër plante is 'n aantreklike teiken vir genetiese manipulering, aangesien die hoë genoom kopiegetal per organel dit moontlik maak om gereeld hoë vlakke van proteïenuitdrukking te verkry. Hierdie proteïene word tot die plastied beperk, en die ooreenstemmende transgene word in die meeste plante sitoplasmies oorgeërf, sonder die oordrag van DNA deur die stuifmeel. Plastied transformasie behels die uniforme modifikasie van al die plastied genoomkopieë, 'n proses wat deur homoloë rekombinasie en die nie-Mendeliese segregasie van plastiede tydens seldeling gefasiliteer word. As gevolg van die gemeenskaplike genetiese komplement, vind aanhoudende interen intra-molekulêre uitruiling van plastiedgenome plaas. Dit maak die setel-spesifieke integrasie, via homoloë rekombinasie, van enige stuk DNA wat deur plastied teikenvolgordes begrens word, moontlik. Vir die verkrying van homoplasmie, waar alle genome getransformeer is, word die insluiting van 'n plastiedspesifieke selekteerbare merker benodig. Seleksiedruk wat die vermeerdering van die getransformeerde genoomkopieë bevoordeel, en die lukrake segregasie van plastiede tydens seldeling, maak dit moontlik om genetiese stabiliteit en uniformiteit van die genoom te verkry. Dit kan op sy beurt tot die verkryging van 'n volledige transplastomiese lyn lei, waar alle aanwesige plastiedgenome transgenies is, en wilde tipe genoomkopieë geëlimineer is. Die prokariotiese aard van die chloroplas genetiese sisteem maak die uitdrukking van veelvuldige proteïene vanaf polisistroniese mRNAs moontlik, wat die toevoeging van volledige operons in 'n enkele transformasie toelaat. Uitdrukkingskassette in vektore bevat dus enkel regulatoriese elemente van plastied oorsprong, gene wat kodeer vir selekteerbare en sifbare merkers, asook een of meer gene van belang (teikengene). Voor elke koderingsstreek, is daar ook 'n toepaslike translasie beheerstreek om doeltreffende translasie vanaf die polisistroniese mRNA te verseker. Die funksie van 'n plastied transformasie vektor is om die oordrag en stabiele integrasie van transgene in chloroplasgenome van hoër plante moontlik te maak. Die uitdrukkingsvektor wat in hierdie studie gekonstrueer is, is spesifiek vir die transformasie van die druif chloroplasgenoom. Vitis vinifera L., van die familie Vitaceae, is die voorkeur species vir die produksie van wyn, en daarom die teiken vir plastied transformasie. Alle chloroplast-afgeleide regulatoriese elemente en volgordes wat in hierdie vektor ingesluit is, het huloorsprong vanaf VUis vinifera L.
Olivier, Abraham Jacobus. "Differential gene expression during berry ripening in Vitis vinifera (cv Chardonnay) : isolation of specific sequences through subtractive cloning." Thesis, Stellenbosch : Stellenbosch University, 2002. http://hdl.handle.net/10019.1/52802.
Повний текст джерелаENGLISH ABSTRACT: Grapevine is worldwide an agronomically important crop. Traditionally selective breeding has been used to improve existing cultivars. In the last ten years, however, the advent of biotechnology has shortened these breeding programmes by producing transgenic grapevine. Because this new technology is aimed at the possible genetic manipulation of the ripening process in grape berries, it is important to elucidate all the mechanisms that may be involved in ripening. The aim of the present study was the identification of genes that play an important role during the ripening process in grape berries. This was achieved by investigation of putative differentially expressed genes in ripening Chardonnay berries isolated through subtractive hybridisation. Two subtraction libraries, representing early and late ripening stages were constructed. Four of the ten genes analysed exhibited expression during berry ripening. One of the four genes was expressed in a tissue and stage specific manner. Further characterisation of eight of the DNA and protein sequences revealed that the putative translation products of these clones had homologues that are involved in amongst others cell wall structure in other species. These included UDP-glucose dehydrogenase, which is involved in the synthesis of hemicellulose precursors. The remaining seven clones encoded putative stress response proteins. These included two heat shock proteins, a vacuolar pyrophosphatase and a protein involved in cell division. It is suggested that specific grape mRNAs accumulate in response to stresses such as the storage of high concentrations of sugars and rapid cell expansion. These processes occur rapidly during the ripening of berries. Accumulation of specific mRNAs can be attributed to part of the normal ripening developmental programme.
AFRIKAANSE OPSOMMING: Druiwe is wêreldwyd 'n belangrike landbougewas en kultivars word tradisioneel deur middel van tydsame selektiewe teling verbeter. Die tyd wat hieraan bestee word, kan verkort word deur die implementering van biotegnologie en die produksie van transgeniese duiwe. Omdat hierdie nuwe tegnologie op die moontlike genetiese manipulering van die rypwordingsproses in druiwe gemik is, is dit belangrik dat alle meganismes betrokke by rypwording ondersoek en verstaan word. Die doel van hierdie studie was om gene wat moontlik tydens die rypwordingsproses in druiwe 'n rol kan speel, te identifiseer. Hierdie doel is bereik deurdat differensieel uitgedrukte gene uit die kultivar Chardonnay geïsoleer is met behulp van verrykingsbiblioteke vanuit jong en volwasse druiwekorrels. Vier van die tien gene wat geanaliseer is, word uitgedruk tydens die rypwordingsproses. Verder het een van die vier gene weefsel- en rypwordingstadium- spesifisiteit getoon. Volledige karakterisering van agt van die DNA- en proteïenvolgordes het aangedui dat die proteïenprodukte van hierdie gene homoloog is aan volgordes wat onder andere by selwandstruktuur betrokke is. Dit sluit UDP-glukose dehidrogenase in, wat betrokke is by die sintese van hemi-sellulose boustene. Die ander sewe gene kodeer vir moontlike spanningsproteïene. Twee hitteskokproteïene, 'n vakuolêre pirofosfatase en 'n proteïen wat betrokke is by selverdeling is geïdentifiseer. Daar word voorgestel dat druiwe mRNA versamel in reaksie op spanningsituasies soos die berging van hoë konsentrasies suikers en selvergroting. Hierdie prosesse vind baie vinnig plaas tydens rypwording. Versameling van spesifieke mRNAs kan toegeskryf word as 'n normale deel van die rypwordingsproses.
Rose, B. A. (Beverley Ann). "The characterisation and partial sequencing of the grapevine chloroplast genome." Thesis, Stellenbosch : Stellenbosch University, 2004. http://hdl.handle.net/10019.1/53763.
Повний текст джерелаENGLISH ABSTRACT: A number of proteins essential for the survival of a plant are encoded by the chloroplast genome. The characterization and sequencing of a number of algal and plant chloroplast genomes has facilitated researchers understanding of cellular functions and metabolism. Chloroplast DNA (cpDNA) has also been used to determine inter- and intraspecies evolutionary relationships and this organelle offers an alternative means of expressing foreign genes. Although a number of species' chloroplast genomes have been characterized and sequenced, no previous attempts of this kind have been made for a chloroplast genome of the family Vitaceae. In this study, attempts were made to characterize and partially sequence the chloroplast genome of Vilis vinifera. Chloroplast DNA was isolated from the Sultana and Sugra 1 cultivars and digested with restriction enzymes that produced cpDNA fragments of a suitable size for cloning. The fragments were shotgun-cloned into a plasmid vector and white colonies were screened by means of PCR and colony blotting. Three EcoRI-digested clones and one PstI-digested clone were obtained in this manner. Walking outwards from a previously sequenced grapevine rrn 16 gene region by means of PCR also allowed us to sequence a further -3310 bp region of the Sultana chloroplast genome. BAC clones containing V. vinifera cv L. Cabernet Sauvignon cpDNA inserts became available later in the project. It was decided to use these clones for further library construction instead of isolated cpDNA. The 5' and 3' end sequences of seven of the 24 BAC clones were obtained. These were compared to sequences found in the NCBI database to find - homologous chloroplast regions and determine the size of each BAC insert. One clone appeared to contain the entire grapevine chloroplast genome, apart from a 500 bp region. This clone was selected for further analysis. The BAC clone DNA was isolated and restriction-digested fragments were shotgun-cloned into a plasmid vector. White colonies were screened by isolating the plasmid DNA and digesting it with appropriate restriction enzy~es. The 5' and 3' ends of putative positive clones were sequenced and mapped onto the Atropa belladonna chloroplast genome. A total of 15 clones were obtained in this project. Five of these contain cpDNA isolated from grapevine leaves and 10 contain fragments sub-cloned from the BAC clone. The biggest problem encountered with both methods used for library construction was genomic DNA contamination. Genomic DNA either originated from the plant nuclear genome or from the bacterial host cells in which the BAC clones were maintained. Many of the clones screened contained genomic DNA, and these could only be identified and removed once the clones had been sequenced. Even when a commercial kit was used for BAC clone isolation, 31% of the clones screened contained genomic DNA. This kit was specifically designed for the isolation of genomic DNA-free large constructs. The clones obtained from the two strategies provided a good representation of the grapevine chloroplast genome. The only region not represented was the Small Single Copy (SSC) region. Approximately 40% of the grapevine chloroplast genome was covered by these clones. This provides a basis for further genome characterization, physical mapping and sequencing of the grapevine chloroplast genome.
AFRIKAANSE OPSOMMING: Die chloroplasgenoom kodeer VIr 'n hele aantal proteïene wat essensieel is VIr die voortbestaan van 'n plant. Die karakterisering en volgorde bepaling van 'n aantal alg en plant chloroplasgenome het dit. vir navorsers moontlik gemaak om sellulêre funksies en metabolisme van plante te ontrafel. Chloroplas DNA (cpDNA) is ook gebruik om intra- en interspecies evolusionêre verwantskappe vas te stel. Dié organel verskaf ook 'n alternatiewe manier vir die uitdrukking van transgene. Alhoewel die chloroplasgenome van 'n hele aantal species al gekarakteriseer is en die DNA volgorde daarvan bepaal is, is daar nog geen navorsing van bogenoemde aard op die chloroplasgenoom van die Vitaceae familie gedoen rue. In hierdie studie is beoog om die chloroplasgenoom van Vitis vinifera te karakteriseer en gedeeltelike volgordebepaling daarvan te doen. Chloroplas DNA is geïsoleer vanaf Sultana en Sugra 1 kultivars en restriksie-ensiem vertering is gedoen met ensieme wat cpDNA fragmente, met geskikte grootte vir klonering, produseer. Dié fragmente is in 'n plasmiedvektor gekloneer met die haelgeweer-metode en wit kolonies is gesif deur middel van PKR en die kolonieklad metode. Op hierdie manier is drie EcoRI-verteerde klone en een PstI-verteerde kloon verkry. Deur uitwaarts te loop, deur middel van PKR, vanaf 'n druif rrnl6 geenstreek, waarvan die volgorde voorafbepaal is, was dit vir ons moontlik om ook die volgorde te bepaal van 'n verdere ~3310 bp streek van die Sultana chloroplasgenoom. BAC klone wat V. vinifera cv L. Cabernet Sauvignon cpDNA fragmente bevat, het later in die projek beskikbaar geraak. Daar is besluit om hierdie klone, i.p.v. die geïsoleerde cpDNA, te gebruik vir verdere biblioteek konstruksie. Die 5' en 3' entpuntvolgordes van sewe uit die 24 BAC ~lone is verkry. Hierdie volgordes is vergelyk met volgordes in die NCB Idatabasis om homoloë chloroplas streke te identifiseer, en die grootte van elke BAC fragment te bepaal. Die het geblyk dat die hele druif chloroplasgenoom in een van die klone vervat is, behalwe vir 'n 500 bp streek. Die BAC-kloon DNA is geïsoleer en die restriksie-verteerde fragmente is in 'n plasmiedvektor gekloon d.m.V. die haelgeweer-metode. Wit kolonies is gesif deur die isolering van plasmied DNA en die vertering daarvan met geskikte restriksie-ensieme. Die volgorde van die 5' en 3' entpunte van skynbare positiewe klone is bepaal en gekarteer op die Atropa belladonna chloroplasgenoom. In hierdie studie is 'n totaal van 15 klone verkry. Vyf hiervan bevat cpDNA wat vanaf druifblare geïsoleer is, en 10 bevat fragmente wat vanaf die BAC-klone gesubkloneer is. Genorniese DNA kontaminasie was die grootste probleem wat ondervind is tydens beide metodes wat gebruik is vir biblioteek konstruksie. Genomiese DNA was afkomstig vanaf óf die plant nukleêre genoom óf die bakteriële gasheerselle waarin die BAC-klone gehou is. Baie van die klone wat gesif is, het genomiese DNA bevat, en dit kon eers geïdentifiseer en verwyder word nadat die volgorde van die klone bepaal is. Selfs al is 'n kommersiële produk vir BAC-kloon isolasie gebruik, het 31% van die gesifde klone steeds genomiese DNA bevat. Dié kommersiële produk is spesifiek vir die isolasie van groot konstrukte, wat genomiese DNA vry is, ontwerp. Die klone wat deur die twee strategeë verkry is, het 'n goeie verteenwoordiging van die druif chloroplasgenoom gegee. Die enigste streek wat die verteenwoordig is nie, was die Klein Enkelkopie (SSC) streek. Ongeveer 40% van die druif chloroplasgenoom is deur hierdie klone gedek. Dit verskaf 'n basis vir verdere genoomkarakterisering, fisiese kartering en volgordebepaling van die druif chloroplasgenoom.
Burger, Anita L. "The isolation and characterisation of a developmentally-regulated gene from Vitis vinifera L. berries." Thesis, Stellenbosch : University of Stellenbosch, 2004. http://hdl.handle.net/10019.1/15938.
Повний текст джерела152 Leaves printed single pages, preliminary pages i-xiv and 129 numberd pages. Includes bibliography. List of abbreviations.
ENGLISH ABSTRACT: Despite increased focus on ripening-related gene transcription in grapevine, and the large number of ripening-related cDNAs identified from grapes in recent years, the molecular basis of processes involved in grape berry ripening is still poorly understood. Moreover, little is known about the mechanisms involved in the ripening-related regulation of fruit-specific genes, since the isolation and characterisation of no ripening-related, fruit-specific promoter elements has been reported to date. This study was aimed at the isolation and characterisation of a fruit-specific, ripeningregulated gene from Vitis vinifera L. In the first phase of the work, gene transcription in ripening berries of Cabernet Sauvignon (a good quality wine cultivar) and Clairette blanche (a poor quality wine cultivar) were studied by Amplified Fragment Length Polymorphism analysis of complementary DNA (cDNA-AFLP analysis). Total RNA from immature (14-weeks post flowering, wpf) and mature (18-wpf) berries was used for the analysis. A total of 1 276 cDNA fragments were visualised, of which 175 appeared to be ripening related. Average pairwise difference of the fragments amplified from immature and mature Clairette and Cabernet berries, suggested that ripening-related gene transcription in these two phenotypically different cultivars is remarkably similar. Nevertheless, it was shown that seventy percent of the 175 ripening-related cDNA fragments were cultivar-specific. It was suggested that these differences should be targeted to identify genes related to the phenotypical differences between the two cultivars, but also to identify genes possibly involved berry quality. Moreover, the analysis illustrated the usefulness of cDNA-AFLPs for the analysis of ripening-related gene transcription during grape berry ripening. In the second phase of the work, one of the ripening-related cDNAs identified by the cDNA-AFLP analysis, was selected for further characterisation. This work highlighted the limitation placed on the isolation of a single specific sequence from a cDNA-AFLP gel, indicating the presence of multiple ripening-related genes in a single band excised from a cDNA-AFLP gel. Steps to overcome this limitation of cDNA-AFLP analysis to identify and clone a specific ripening-related gene, were implemented. In short, the band corresponding to the particular ripening-related cDNA was band was excised from the cDNA-AFLP polyacrylamide gel and re-amplified. Northern blot analysis using the re-amplified, uncloned product confirmed the ripening-related transcription demonstrated by cDNA-AFLP analysis. The re-amplified, uncloned product was then cloned. Sequence analysis of two randomly selected candidate clones revealed two distinctly different sequences, of which neither hybridised to messenger RNA from ripening grape berries. Furtheranalysis revealed an additional five cDNAs with terminal sequences corresponding to the selective nucleotides of the primers used for selective amplification, in the re-amplified, uncloned product. Of these, only two were abundantly expressed in ripening grape berries, accounting for the ripeningrelated transcription visualised by cDNA-AFLP analysis. All seven cDNAs identified from the particular excised band were shown to be ripening-regulated during berry development, although most were characterised by low levels of transcription during berry ripening. One of the clones, based on the relative high levels of the transcript and the initiation of gene transcription at the onset of véraison (10- to 12-wpf), was identified for isolation and characterisation of the full length coding sequence. In the third phase of the work, it was shown that this cloned sequence corresponded to a gene encoding a proline-rich protein (PRP) associated with ripening in Merlot and Chardonnay (mrip1, Merlot ripening-induced protein 1). It was shown that the gene is specifically transcribed in the fruit tissue, seed and bunchstems of grapes, from 10-wpf (véraison) to the final stages of berry ripening. The results showed that mrip1 encodes a distinct member of the plant PRP family. Most obvious is the central region of mrip1, which is comprised of eight consecutive repeats of 19 amino acid residues each. In comparison with other grapevine PRPs, mrip1 revealed single amino acid differences and deletion of one of the 19 amino acid residues repeats, all in the central region of mrip1. In situ hybridisation studies showed that accumulation of the mrip1 transcript in the ripening berry is limited to the mesocarp and exocarp cells of the ripening grape berry. No transcript with high sequences similarity to mrip1 could be detected in ripening strawberry or tomato fruit. Based on the properties and proposed function of PRPs, and the results obtained in this study, potential applications for the use of this gene in the control of cell wall architecture in fruits, were proposed. Furthermore, as manipulation of fruit properties in grape berries would be most important in the later stages of ripening, mrip1 was proposed an ideal candidate gene for the isolation of a fruit- and late-ripening-specific promoter to achieve transgene transcription in genetically modified grapevine. The final phase of the work was dedicated to the isolation and characterisation of the mrip1 promoter element. A 5.5 kb sequence corresponding to the mrip1 5’ untranslated (UTR) flanking region was isolated and characterised by sequence analysis. In the 2.8 kb sequence directly upstream of the mrip1 transcription initiation site, several putative cis-acting regulatory elements were identified. These include a spectrum of hormone-, light-, phytochrome-, sugar-and stressresponsive elements, as well as elements implicated in tissue-specific transcription. Analysis of the sequence further upstream (3.6 – 5.5 kb) of the mrip1 transcription initiation site (TIS), revealed the presence of another proline-rich protein directly upstream of mrip1. Sequence identity of this sequence (mprp2) to the mrip1 coding sequence was 88%. This information provided the first insight into the chromosomal organisation of grapevine PRPs. For functional analysis of the mrip1 promoter element, the 2.2 kb sequence directly upstream of the mrip1 TIS, was translationally fused to the sgfpS65T reporter gene. Functionality of the mrip1:sgfpS65T fusion was verified by transient expression in green pepper pericarp tissue, before introduction into tobacco by Agrobacteriummediated transformation. In transgenic tobacco, transcription of the mrip1:sgfpS65T fusion was developmentally-regulated and specific to the ovary and nectary-tissue of the developing flower. Whilst low in immature flowers, the green fluorescent protein (GFP) rapidly accumulated to the high level of expression visualised in the flower in full-bloom, followed by a decrease in the final stages of ovary development. These observations suggested that the 2.2 kb mrip1 promoter is functional and that this promoter region harbours cis-elements necessary for tissue- and developmental-specific regulation of GFP accumulation. It furthermore suggested that the transcriptional activation of mrip1 is mediated by developmental signals present in both grapevine berries and tobacco flowers. Results presented, suggest that the use of tobacco as heterologous system for the analysis of ripening-related promoters, can be more generally applied. Evidently, characterisation of the mrip1 promoter region contributes towards a better understanding of the regulatory mechanisms involved in non-climacteric fruit ripening, and forms a basis for future experiments defining the cis-acting elements necessary for tissue- and cell-specific gene regulation in fruit, more specifically in grapevine. Moreover, the mrip1 promoter is an ideal candidate for the ripening-related, tissue-specific regulation of transgene transcription in genetically modified grapevine.
AFRIKAANSE OPSOMMING: Ten spyte van toenemende fokus op rypwordings-verwante geentranskripsie in druiwe, en die groot aantal rypwordings-verwante komplimentere DNA (cDNA) fragmente wat gedurende die laaste paar jaar in druiwe geïdentifiseer is, word die molekulêre basis van prosesse betrokke by die rypwording van die druif, steeds swak begryp. Nog te meer, is baie min bekend oor die meganismes betrokke in the rypwordings-verwante regulering van vrugspesifieke gene, aangesien die isolering en karakterisering van nie een rypwordings-verwante, vrugspesifieke promoter tot dusver gerapporteer is nie. Die doel van hierdie studie was die isolering en karakterisering van ‘n vrugspesifieke, rypwordings-verwante geen uit druiwe (Vitis vinifera L). In die eerste fase van die werk, is geentranskripsie in rypwordende druiwekorrels van Cabernet Sauvignon (‘n goeie kwaliteit wyn kultivar) en Clairette blanche (‘n swak kwaliteit wyn kultivar) bestudeer deur middel van cDNA-AFLP vingerafdrukke. Totale RNA van onvolwasse (14-weke na blom vorming) en volwasse (18-weke na blom vorming) druiwekorrels was gebruik vir die analise. ‘n Totaal van 1 276 cDNA fragmente is gevisualiseer, waarvan 175 as rypwordings-verwant voorgekom het. Gemiddelde paarsgewyse verskille van die fragmente wat vanaf onvolwasse en volwasse Clairette en Cabernet druiwekorrels geamplifiseer is, het aangedui dat rypwordingverwante geentranskripsie in die twee kultivars, wat fenotipies baie van mekaar verskil, merkwaardig soortgelyk is. Nieteenstaande, is daar gewys dat sewentig persent van die 175 rypwordings-verwante cDNA fragmente, kultivar-spesifiek is. Daar is voorgestel dat hierdie spesifieke cDNAs verder geanaliseer word om gene betrokke by die fenotipiese verskille tussen die twee kultivars te identifiseer; maar ook om gene te identifiseer wat moontlik by die kwaliteit van die druiwekorrel betrokke is. Voorts, het die analise die bruikbaarheid van die cDNA-AFLP tegniek vir die karakterisering van rypwordings-verwante geentranskripsie in rypwordende druiwekorrels, geïllustreer. In die tweede fase van die werk, is een van die rypwordings-verwante cDNAs wat met die cDNAAFLP analise geïdentifiseer is, geselekteer vir verdere karakterisering. ‘n Aantal rypwordingsverwante cDNAs is in die enkele band wat uit die cDNA-AFLP gel gesny is, geïdentfiseer. Dit het die beperking wat geplaas word op die isolering van ‘n enkel, spesifieke cDNA uit die cDNA-AFLP gel, beklemtoon. Stappe om hierdie beperking te oorkom, en ‘n spesifieke rypwordings-verwante cDNA te identfiseer en te kloneer, is beskryf. In kort, die band oorstemmend met die spesifieke rypwordings-verwante cDNA, is uit die cDNA-AFLP poli-akrielamied gel gesny en gereamplifiseer. Noordelike klad analise waarin die ge-reamplifiseerde, ongekloneerde produk aspeiler gebruik is, het die rypwordings-verwante transkripsie soos deur cDNA-AFLP analise aangedui, bevestig. Die ge-reamplifiseerde, ongekloneerde produk is daarna gekloneer. Nukleotied volgorde bepaling van twee ewekansig geselekteerde kandidaat klone, het twee duidelik verskillende cDNAs aangetoon, waarvan nie een enige hibridisering met boodskapper RNA van rypwordende druiwekorrels getoon het nie. Verder analise het die teenwoordigheid van ‘n verder vyf cDNAs met terminale nukleotied volgordes ooreenstemmend met die selektiewe nukleotiede van die voorlopers wat gebruik is vir selektiewe amplifisering, aangetoon. Van hierdie, het slegs twee hoë vlakke van geentranskripsie in rypwordende druiwekorrels getoon; heel moontlik verteenwoordigend van die rypwordings-verwante geentranskripsie wat met die cDNA-AFLP analise gevisualiseer is. Die studie het gewys dat al sewe cDNAs rypwordings-verwant is, alhoewel die meeste van hierdie cDNAs baie lae vlakke van geentranskripsie tydens duiwekorrel rypwording getoon het. Gebaseer op relatief hoë vlakke van die transkrip, en die inisiering van geen transkripsie met die aanvang van vrugrypwording (véraison, 10- tot 12-weke na blomvorming), is een van die cDNAs geselekteer vir isolering en karakterisering van die vollengte koderings volgorde. In die derde fase van die werk, is dit aangetoon dat hierdie cDNA ooreenstem met ‘n geen wat vir ‘n proline-ryke proteïen (PRP), geassosieerd met vrugrypwording in Merlot en Chardonnay, kodeer. Hierdie geen is genoem Merlot rypwording-geïnduseerde proteïen 1 (mrip1). Die studie het verder aangetoon dat hierdie geen spesifiek in die weefsel van druiwekorrels, saad and stammetjies van die druiwetros getranskribeer word, vanaf 10-weke na blomvorming (véraison) tot 16-weke na blomvorming. Resultate het aangetoon dat mrip1 vir ‘n unieke lid van die plant PRP familie kodeer. Mees opvallend, is die sentrale gedeelte van mrip1, wat uit agt opeenvolgende herhalings van negentien aminosure elk bestaan. In vergelyking met ander druif PRPs, toon mrip1 enkel aminosuur verskille en ‘n delesie van een van die negentien aminosuur herhalings, alles in die sentrale gedeelte van mrip1. In situ hibridisering het getoon dat akkumulering van die mrip1 transkrip net in selle van die mesocarp en eksokarp van die rypwordende druif plaasvind. Geen transkip met hoë nukleotied gelyksoortigheid aan mrip1 kon in rypwordende aarbeie of tamatie vrugte aangetoon word nie. Gebaseer op die eienskappe en funksie van PRPs soos voorgestel in die literatuur, en die bevindinge van hierdie studie, is potensiële toepassings vir die gebruik van die geen in die beheer van selwand argitektuur in vrugte, voorgestel. Verder, aangesien die manipulering van vrugkwaliteit in die druif veral belangrik is vanaf die aanvang van vrugrypwording (véraison), is daar voorgestel dat mrip1 ‘n ideale kandidaat is vir die isolering van ‘n vrugspesifieke en rypwording-verwante promoter vir gebruik in geneties gemodifiseerde druiwe. Die laaste fase van die studie was gewy aan die isolering en karakterisering van die mrip1 promotor element. ‘n 5.5 kb fragment ooreenstemmend met die mrip1 5’ ongetransleerde area is geisoleer en gekarakteriseer deur middel van nukleotied volgorde bepaling. In die 2.8 kb area direk stroomop van die mrip1 transkripsie inisiasie punt (TIS), is verskeie moontlike cis-beherende regulatoriese elemente geïdentifiseer. Hierdie sluit in ‘n spektrum van hormoon-, lig-, fitochroom-, suiker- en stress-reagerende elemente, asook elemente geïmpliseer in weefselspesifieke geentranskripsie. Analise van die area verder stroomop (3.6 – 5.5 kb) van die mrip1 TIS, het die teenwoordigheid van ‘n ander PRP direk stroomop van mrip1 getoon. Nukleotied gelyksoortigheid van hierdie geen (MPRP2) aan die mrip1 koderingsgebied was slegs 88%. Hierdie inligting verskaf die eerste insig in die chromosomale organisasie van druif PRPs. Vir funksionele analise van die mrip1 promotor element, is die 2.2 kb area direk stroomop van die mrip1 TIS transkripsioneel verenig met die sgfpS65T merker geen. Funksionaliteit van die mrip1: sgfpS65T fusie is bevestig deur middel van kortstondige (transient) geenuitdrukking in die perikarp van groenrissie, voordat dit ingevoer is in tabak met Agrobacterium-bemiddelde genetiese transformasie. In transgeniese tabak was transkripsie van die mrip1:sgfpS65T fusie ontwikkelingsstadium-gereguleerd, en spesifiek in die ovarium en heuningsakkie (nektarium) van die ontwikkelende blomme. Terwyl die vlak van geenuitdrukking laag was in die jong blomme, het GFP baie vinnig akkumuleer tot die hoë vlakke wat in die blomme in volle-blom gevisualiseer is. Daarna het dit weer vinnig afgeneem tydens die finale stadiums van ovarium ontwikkeling. Hierdie waarnemings dui daarop dat die 2.2 kb mrip1 promotor element funksioneel is en dit al die nodige cis-beherende regulatoriese element bevat wat nodig is vir weefsel- en ontwikkelingsstadium-spesifieke regulering van GFP akkumulering. Dit dui verder daarop dat transkripsionele aktivering van mrip1 beheer word deur ontwikkelingsstadium seine teenwoordig in beide die druif en tabakblomme. Hierdie resultate stel voor dat tabak meer algemeen gebruik kan word as heteroloë sisteem vir die analise van rypwording-verwante promotors. Duidelik dra die karakterisering van die mrip1 promoter element by tot ‘n beter begrip van die regulatoriese meganismes betrokke by die rypwordingsproses van nie-klimateriese vrugte, en vorm die basis vir toekomstige eksperimente waarin die cis-beherende regulatoriese elemente vir vrug- en sel-spesifieke geen regulering, meer spesifiek die druif, bepaal sal word. Meer nog, is die mrip1 promotor ‘n ideale kandidaat vir weefsel-spefieke en rypwording-verwante regulering van transkripsie van die transgeen in geneties gemodifiseerde druiwe.
Van, Straten Celene Debra. "The construction of plant expression vectors for the introduction of leafroll disease resistance in grapevine." Thesis, Stellenbosch : Stellenbosch University, 2000. http://hdl.handle.net/10019.1/51950.
Повний текст джерелаENGLISH ABSTRACT: Grapevine leafroll is one of the most damaging viral diseases that affect many viticultural regions of the world. Numerous reports over the last few years have associated closterovirus-like particles with leafroll disease. To date, eight serologically distinct closteroviruses have been isolated from leafroll infected vines, of which grapevine leafroll associated closterovirus-3 (GLRaV-3) is the best characterized. Virus resistance in transgenic plants based on the expression of a virusderived gene is known as pathogen-derived resistance. The viral coat protein (CP) gene, which expresses a structural protein responsible for coating the virus particles, was used in the first demonstration of virus-derived resistance. Coat protein-mediated resistance is currently the most feasible and most widely used method to obtain virus resistance in crop plants. The CP gene of a South African isolate of GLRaV-3 infected grapevine was isolated, cloned and sequenced. Double stranded RNA (dsRNA) was extracted from GLRaV-3 infected material and a high molecular weight band, of -18 kb was identified from infected vines. The dsRNA was used as a template in a reverse transcription PCR together with GLRaV-3 CP gene specific primers for the amplification of the GLRaV-3 CP gene (975 bp). The GLRaV-3 CP gene was cloned into the pGem®-T Easy vector. Clones hosting the CP gene in the sense (pLR3CP+) and antisense (pLR3CP-) orientations respectively were obtained. The sequence obtained from these two clones showed 99.26 % similarity to the only other GLRaV-3 CP nucleotide sequence available. The GLRaV-3 CP gene was excised from pLR3CP+ and pLR3CP- and subcloned into a plant expression vector, pCAMBIA 3301 in the sense (pCamBLR3CP+) and antisense (pCamBLR3CP-) orientations respectively, therefore enabling sense and antisense gene expression in transgenic plants. The GLRaV-3 CP gene was also subcloned from pCamBLR3CP+ into another plant expression vector, pCAMBIA 2301 in the sense orientation and designated as pCVSLR3CP+. These three constructs were given to Dr. M. Vivier (Institute for Wine Biotechnology, Stellenbosch) for grapevine transformation experiments. Two of these constructs, pCamBLR3CP+ and pCamBLR3CP- as well as pCAMBIA 3301 were used to transform Nicotiana tabacum by Agrobacterium tumefaciens-mediated transformation. Plants were selected for their ability to withstand the herbicide, Basta. This resistance is due to the presence of a plant selectable marker gene on each of these constructs, known as the bar gene. PCR with GLRaV-3 CP gene specific primers showed no amplification of the GLRaV-3 CP gene in the plants transformed with pCamBLR3CP+ and pCamBLR3CP-. Southern blot analysis with the GLRaV-3 CP gene as hybridization probe showed no signal for these plants, thus confirming the PCR results. PCR with bar gene specific primers showed no amplification of the bar gene in the plants infected with pCAMBIA 3301. The plants transformed with pCamBLR3CP+ and pCamBLR3CP- were also screened for the presence of the bar gene. Three of the eight plants tested showed amplification of the -560 bp bar gene. This result suggests that these plants were transformed with pCAMBIA 3301 (vector without the ligated GLRaV-3 CP gene) and not pCamBLR3CP+ or pCamBLR3CP- as had been expected. This project provides preliminary work for the subsequent transformation of grapevine with the GLRaV-3 CP gene, in an attempt to impart virus resistance.
AFRIKAANSE OPSOMMING: Wingerd rolblaar is een van die mees beskadigende virale siektes wat baie wingerd areas in die wêreld aantas. In Aantal verslae oor die afgelope jare het closterovirus partikels met wingerd rolblaar geassosieer. Tot hede, is agt serologiese onderskeibare closterovirusse geïsoleer vanuit geaffekteerde wingerde, waarvan wingerd rolblaar geassosieerde closterovirus-3 (GLRaV-3) die beste gekarakteriseerd is. Virus bestandheid in transgeniese plante gebaseer op die uitdrukking van gene afkomstig vanaf virusse, staan bekend as patogeen-afgeleide weerstand. Die virale kapsule protein (CP) geen vervaardig In strukturele protein wat verantwoordelik is vir die bedekking van die virus partikel. Dié geen was gebruik in die eerste demonstrasie van patogeen-afgeleide weerstand. Kapsuul protein-bemiddelde weerstand is tans die mees praktiese en algemene gebruikte metode om virus weerstand in plant gewasse te verkry. Die CP geen van In Suid Afrikaanse isolaat van GLRaV-3 geïnfekteerde wingerde is geïsoleer, gekloneer en die volgorde is bepaal. Dubbelstring RNA (dsRNA) was uit GLRaV-3 geïnfekteerde materiaal geëkstraheer en In hoë molekulêre gewig band van -18 kb is geïdentifiseer. Die dsRNA is gebruik as In templaat vir In omgekeerde transkripsie PKR saam met GLRaV-3 CP geen spesifieke inleiers vir die amplifikasie van die GLRaV-3 CP geen (975 bp). Die GLRaV-3 CP geen is gekloneer in die pGem®-T Easy vektor. Klone met die CP geen in die sin (pLR3CP+) en teensin (pLR3CP-) oriëntasies respektiewelik is verkry. Die volgorde wat verkry is vanuit hierdie twee klone dui op In 99.26 % ooreenstemming met die enigste ander GLRaV-3 CP geen volgorde wat beskikbaar is. Die GLRaV-3 CP geen is uit pLR3CP+ en pLR3CP- gesny en is gesubkloneer in In plant ekspressie vektor, pCAMBIA 3301 in die sin (pCamBLR3CP+) en teensin (pCamBLR3CP-) oriëntasies respektiewelik, wat die sin en teensin geen ekspressie in transgeniese plante in staat stel. Die GLRaV-3 CP geen was ook gesubkloneer vanaf pCamBLR3CP+ in In ander plant ekspressie vektor, pCAMBIA 2301 in die sin orientasie en is as pCVSLR3CP+ benoem. Hierdie drie konstruksies is aan Dr. M. Vivier (Instituut vir Wyn Biotegnologie, Stellenbosch) gegee vir wingerd transformasie eksperimente. Twee van hierdie konstruksies, pCamBLR3CP+ en pCamBLR3CP- asook pCAMBIA 3301 is gebruik om Nicotiana tabacum deur middel van Agrobacterium tumefaciens-bemiddelde transformasie te transformeer. Plante is geselekteer vir hul vermoë om die onkruiddoder, Basta, te weerstaan. Die teenwoordigheid van die plant selekteerbare merker geen, bar, op elke konstruksie lui tot dié weerstand. Die plante wat getransformeer is met pCamBLR3CP+ en pCamBLR3CP- is deur PKR saam met die GLRaV-3 CP geen spesifieke inleiers getoets, en geen amplifikasie van die GLRaV-3 CP geen is getoon nie. Southern blot analise met die GLRaV-3 CP geen as hibridisasie peiler het geen sein gewys vir hierdie plante nie, wat die PKR resultate bevestig. Die plante wat getransformeer is met pCAMBIA 3301 is deur PKR saam met die bar geen spesifieke inleiers getoets, en geen amplifikasie van die bar geen is getoon nie. Die plante wat getransformeer is met pCamBLR3CP+ en pCamBLR3CP- is ook getoets vir die teenwoordigheid vir die bar geen. Drie van die agt plante wat getoets is, het amplifikasie van die -560 bp bar geen getoon. Hierdie onverwagte resultate stel voor dat dié plante met pCAMBIA 3301 (vektor sonder die geligeerde GLRaV-3 CP geen) en nie met pCamBLR3CP+ en pCamBLR3CPgetransformeer is nie. Hierdie projek verskaf voorlopige werk vir die daaropvolgende transformasie van wingerd met die GLRaV-3 CP geen in 'n poging om virus bestandheid te verskaf.
Van, Eeden C. (Christiaan). "The construction of gene silencing transformation vectors for the introduction of multiple-virus resistance in grapevines." Thesis, Stellenbosch : Stellenbosch University, 2004. http://hdl.handle.net/10019.1/53764.
Повний текст джерелаENGLISH ABSTRACT: Viruses are some of the most important pathogens of grapevines. There are no effective chemical treatments, and no grapevine- or other natural resistance genes have been discovered against grapevine infecting viruses. The primary method of grapevine virus control is prevention by biological indexing and molecular- and serological screening of rootstocks and scions before propagation. Due to the spread of grapevine viruses through insect vectors, and in the case of GRSPaV the absence of serological screening, these methods of virus control are not always effective. In the past several methods, from cross-protection to pathogen derived resistance (PDR), have been applied to induce plant virus resistance, but with inconsistent results. In recent years the application of post-transcriptional gene silencing (PTGS), a naturally occurring plant defense mechanism, to induce targeted virus resistance has achieved great success. The Waterhouse research group has designed plant transformation vectors that facilitate specific virus resistance through PTGS. The primary focus of this study was the production of virus specific transformation vectors for the introduction of grapevine virus resistance. The Waterhouse system has been successfully utilised for the construction of three transformation vectors with the pHannibal vector as backbone. Each vector contains homologous virus coat protein (CP) gene segments, cloned in a complementary conformation upstream and downstream of an intron sequence. The primary vector (pHann-SAScon) contains complementary CP gene segments of both GRSPaV and GLRaV-3 and was designed for the introduction of multiple-virus resistance. For the construction of the primary vector the GRSPaV CP gene was isolated from RSP infected grapevines. A clone of the GLRaV-3 CP gene was acquired. The second vector (pHann- LR3CPsas) contains complementary CP gene segments of GLRaV-3. The third vector (pHann-LR2CPsas) contains complementary CP gene segments of GLRaV-2. The cassette containing the complementary CP gene segments of both GRSPaV and GLRaV-3 was cloned into pART27 (pART27-HSAScon), and used to transform N tabacum cv. Petit Havana (SRI), through A. tumefaciens mediated transformation. Unfortunately potential transformants failed to regenerate on rooting media; hence no molecular tests were performed to confirm transformation. Once successful transformants are generated, infection with a recombinant virus vector (consisting of PYX, the GFP gene as screenable marker and the complementary CP gene segments of both GRSPaV and GLRaV-3) will be used to test for the efficacy of the vectors to induce resistance. A secondary aim was added to this project when a need was identified within the South African viticulture industry for GRSPaV specific antibodies to be used in serological screening. To facilitate future serological detection of GRSPaV, the CP gene was isolated and expressed with a bacterial expression system (pETI4b) within the E. coli BL2I(DE3)pLysS cell line. The expressed protein will be used to generate GRSPaV CP specific antibodies.
AFRIKAANSE OPSOMMING: Virusse is van die belangrikste patogene by wingerd. Daar bestaan geen effektiewe chemiese beheer nie, en geen wingerd- of ander natuurlike weerstandsgene teen wingerdvirusse is al ontdek nie. Die primêre metode van beheer t.o.v. wingerdvirusse is voorkoming deur biologiese indeksering, en molekulêre- en serologiese toetsing van onderstokke en entlote voor verspreiding. As gevolg van die verspreiding van wingerdvirusse deur insekvektore, en in die geval van GRSPa V die tekort aan serologiese toetsing, is dié metodes van virusbeheer nie altyd effektief nie. In die verlede is metodes soos kruis-beskerming en patogeen-afgeleide weerstand (PDR) gebruik om virusweerstand te induseer, maar met inkonsekwente resultate. In onlangse jare is post-transkripsionele geenonderdrukking (PTGS), 'n natuurlike plantbeskermingsmeganisme, met groot sukses toegepas om geteikende virusweerstand te induseer. Die Waterhouse-navorsingsgroep het planttransformasievektore ontwerp wat spesifieke virusweerstand induseer d.m.v. PTGS. Die vervaardiging van virus spesifieke tranformasievektore vir die indusering van wingerdvirusweerstand was die primêre doelwit van hierdie studie. Die Waterhouse-sisteem was gebruik vir die konstruksie van drie transformasievektore, met die pHannibal vektor as basis. Elke vektor bevat homoloë virus kapsiedproteïen (CP) geensegmente, gekloneer in 'n komplementêre vorm stroom-op en stroom-af van 'n intronvolgorde. Die primêre vektor (pHann-SAScon) bevat komplementêre CP geensegmente van beide GRSPaV en GLRaV-3, en was ontwerp vir die indusering van veelvoudige-virusweerstand. Die CP-geen van GRSPa V was vanuit RSP-geïnfekteerde wingerd geïsoleer, vir die konstruksie van die primêre vektor. 'n Kloon van die GLRa V-3 CP-geen was verkry. Die tweede vektor (pHann-LR3CPsas) bevat komplementêre CP geensegmente van GLRaV-3. Die derde vektor (pHann-LR2CPsas) bevat komplementêre CP geensegmente van GLRa V-2. Die kasset bestaande uit die komplementêre CP geensegmente van beide GRSPaV en GLRaV-3, was gekloneer in pART27 (pART27-HSAScon), en gebruik om N tabacum cv. Petit Havana (SRI) te transformeer d.m.v. A. tumefaciens bemiddelde transformasie. Ongelukkig het potensiële transformante nie geregenereer op bewortelingsmedia nie; gevolglik was geen molekulêre toetse gedoen om transformasie te bevestig nie. Na suksesvolle transformante gegenereer is, sal infeksie met 'n rekombinante-virusvektor (bestaande uit PYX, die GFP geen as waarneembare merker en die komplementêre CP geensegmente van beide GRSPa V en GLRa V-3) gebruik word om die effektiwiteit van die vektore as weerstandsinduseerders te toets. 'n Sekondêre doelwit is by die projek gevoeg toe 'n behoefte aan GRSPaV spesifieke teenliggame binne die Suid-Afrikaanse wynbedryf geïdentifiseer is, vir gebruik in serologiese toetsing. Om toekomstige serologiese toetsing van GRSPa V te bemiddel, was die CP-geen geïsoleer en in 'n bakteriële uitdrukkingsisteem (PETI4b) uitgedruk, in die E. coli BL21(DE3)pLysS sellyn. Die uitgedrukte proteïne sal gebruik word vir die vervaardiging van GRSPa V CP spesifieke antiliggame.
Brackenridge, Anika Elma. "Over-expression and analysis of two Vitis vinifera carotenoid biosynthetic genes in transgenic Arabidopsis." Thesis, Stellenbosch : University of Stellenbosch, 2006. http://hdl.handle.net/10019/508.
Повний текст джерелаКниги з теми "Grapes Genetics"
Adam-Blondon, Anne-Françoise. Genetics, genomics and breeding of grapes. Edited by Martínez-Zapater José M. Enfield, NH: Science Publishers, 2011.
Знайти повний текст джерелаInternational Grape Genomics Symposium (2005 St. Louis, Mo.). Proceedings, International Grape Genomics Symposium, July 12-14, 2005, St. Louis, Missouri, USA. Edited by Qiu Wenping 1965-, Kovacs Laszlo Gyorgy 1961-, International Grape Genome Program, and Missouri State University. Mountain Grove, MO: Missouri State University, Department of Fruit Science, 2005.
Знайти повний текст джерелаInternational Conference on Grape Genetics and Breeding (8th 2002 Keeskemét, Hungary). Proceedings of the 8th International Conference on Grape Genetics and Breeding: Keeskemét, Hungary, 26-31, August 2002. Edited by Botos E. P, Hajdú E, Borbás É, and International Society for Horticultural Science. Section Vine and Berry Fruits. Leuven, Belgium: International Society for Horticultural Science, 2003.
Знайти повний текст джерелаInternational Conference on Grape Genetics and Breeding (8th 2002 Keeskemét, Hungary). Proceedings of the 8th International Conference on Grape Genetics and Breeding: Keeskemét, Hungary, 26-31, August 2002. Edited by Botos E. P, Hajdú E, Borbás É, and International Society for Horticultural Science. Section Vine and Berry Fruits. Leuven, Belgium: International Society for Horticultural Science, 2003.
Знайти повний текст джерелаKönig, Helmut. Biology of Microorganisms on Grapes, in Must and in Wine. Berlin, Heidelberg: Springer Berlin Heidelberg, 2009.
Знайти повний текст джерелаInternational, Symposium on Grapevine Genetics and Breeding (7th 1998 Montpellier France). Proceedings of the Seventh International Symposium on Grapevine Genetics and Breeding: Montpellier, France, 6-10 July 1998. Leuven, Belgium: ISHS, Section Viticulture, Working Group on Environmental Physiology of Fruit Crops, Office International de la Vigne et du Vin, 2000.
Знайти повний текст джерелаInternational, Symposium on Grapevine Genetics and Breeding (7th 1998 Montpellier France). Proceedings of the Seventh International Symposium on Grapevine Genetics and Breeding: Montpellier, France, 6-10 July 1998. Leuven, Belgium: ISHS, Section Viticulture, Working Group on Environmental Physiology of Fruit Crops, 2000.
Знайти повний текст джерелаRoubelakis-Angelakis, Kalliopi A. Grapevine molecular physiology & biotechnology. 2nd ed. Dordrecht: Springer, 2009.
Знайти повний текст джерелаPuhal'skiy, Vitaliy. Introduction to Genetics. ru: INFRA-M Academic Publishing LLC., 2021. http://dx.doi.org/10.12737/1019851.
Повний текст джерелаBaniasadi, Pouya, Vladimir Ejov, Jerzy A. Filar, and Michael Haythorpe. Genetic Theory for Cubic Graphs. Cham: Springer International Publishing, 2016. http://dx.doi.org/10.1007/978-3-319-19680-0.
Повний текст джерелаЧастини книг з теми "Grapes Genetics"
Hammerstad, Sara Salehi, and Yaron Tomer. "Epidemiology and Genetic Factors in Graves’ Disease and Graves’ Ophthalmopathy." In Graves' Disease, 21–37. New York, NY: Springer New York, 2015. http://dx.doi.org/10.1007/978-1-4939-2534-6_3.
Повний текст джерелаBoller, Beat, and Stephanie L. Greene. "Genetic Resources." In Fodder Crops and Amenity Grasses, 13–37. New York, NY: Springer New York, 2010. http://dx.doi.org/10.1007/978-1-4419-0760-8_2.
Повний текст джерелаBaniasadi, Pouya, Vladimir Ejov, Jerzy A. Filar, and Michael Haythorpe. "Genetic Theory for Cubic Graphs." In Genetic Theory for Cubic Graphs, 1–26. Cham: Springer International Publishing, 2016. http://dx.doi.org/10.1007/978-3-319-19680-0_1.
Повний текст джерелаBaniasadi, Pouya, Vladimir Ejov, Jerzy A. Filar, and Michael Haythorpe. "Inherited Properties of Descendants." In Genetic Theory for Cubic Graphs, 27–59. Cham: Springer International Publishing, 2016. http://dx.doi.org/10.1007/978-3-319-19680-0_2.
Повний текст джерелаBaniasadi, Pouya, Vladimir Ejov, Jerzy A. Filar, and Michael Haythorpe. "Uniqueness of Ancestor Genes." In Genetic Theory for Cubic Graphs, 61–92. Cham: Springer International Publishing, 2016. http://dx.doi.org/10.1007/978-3-319-19680-0_3.
Повний текст джерелаLanford, Jeremiah W., and Lawrence H. Phillips. "Epidemiology and Genetics of Myasthenia Gravis." In Myasthenia Gravis and Related Disorders, 71–78. Totowa, NJ: Humana Press, 2008. http://dx.doi.org/10.1007/978-1-59745-156-7_4.
Повний текст джерелаNel, Melissa, and Jeannine M. Heckmann. "Epidemiology and Genetics of Myasthenia Gravis." In Myasthenia Gravis and Related Disorders, 71–84. Cham: Springer International Publishing, 2018. http://dx.doi.org/10.1007/978-3-319-73585-6_5.
Повний текст джерелаZhang, Qing-Guo, Hua-Yong Liu, Wei Zhang, and Ya-Jun Guo. "Drawing Undirected Graphs with Genetic Algorithms." In Lecture Notes in Computer Science, 28–36. Berlin, Heidelberg: Springer Berlin Heidelberg, 2005. http://dx.doi.org/10.1007/11539902_4.
Повний текст джерелаLefvert, Ann Kari, DeRen Huang, and Biying Xu. "Non-MHC Genetic Polymorphisms in Human Autoimmune Myasthenia Gravis." In Myasthenia Gravis, 105–15. Dordrecht: Springer Netherlands, 2000. http://dx.doi.org/10.1007/978-94-011-4060-7_10.
Повний текст джерелаYanagawa, Tatsuo, Tsuyoshi Kouki, and Leslie J. DeGroot. "CTLA-4 Gene in the Pathogenesis of Graves’ Disease." In The Genetics of Complex Thyroid Diseases, 103–7. Tokyo: Springer Japan, 2002. http://dx.doi.org/10.1007/978-4-431-67885-4_7.
Повний текст джерелаТези доповідей конференцій з теми "Grapes Genetics"
Харчук, Олег, Александр Будак, Георгий Скурту та Татьяна Давид. "Эффективность использования воды по ассимиляции СО2 и по урожаю". У VIIth International Scientific Conference “Genetics, Physiology and Plant Breeding”. Institute of Genetics, Physiology and Plant Protection, Republic of Moldova, 2021. http://dx.doi.org/10.53040/gppb7.2021.13.
Повний текст джерелаKavi, Deniz. "Towards Adversarial Genetic Text Generation." In 8th International Conference on Computer Science and Information Technology (CoSIT 2021). AIRCC Publishing Corporation, 2021. http://dx.doi.org/10.5121/csit.2021.110407.
Повний текст джерелаGoldberg, Leslie Ann. "Evolutionary Dynamics on Graphs." In FOGA '15: Foundations of Genetic Algorithms XIII. New York, NY, USA: ACM, 2015. http://dx.doi.org/10.1145/2725494.2725495.
Повний текст джерелаГинда, Елена, та Наталья Трескина. "Использование регуляторов роста растений для реализации продуктивного потенциала столового сорта винограда велика в зависимости от гидротермических условий периода вегетации". У VIIth International Scientific Conference “Genetics, Physiology and Plant Breeding”. Institute of Genetics, Physiology and Plant Protection, Republic of Moldova, 2021. http://dx.doi.org/10.53040/gppb7.2021.37.
Повний текст джерелаBranson, Luke, and Andrew M. Sutton. "Evolving labelings of graceful graphs." In GECCO '22: Genetic and Evolutionary Computation Conference. New York, NY, USA: ACM, 2022. http://dx.doi.org/10.1145/3512290.3528855.
Повний текст джерелаKayani, Saheeb Ahmed, and Muhammad Afzaal Malik. "Bond-graphs + genetic programming." In the 2008 GECCO conference companion. New York, New York, USA: ACM Press, 2008. http://dx.doi.org/10.1145/1388969.1389041.
Повний текст джерелаAtkinson, Timothy, Detlef Plump, and Susan Stepney. "Evolving graphs with horizontal gene transfer." In GECCO '19: Genetic and Evolutionary Computation Conference. New York, NY, USA: ACM, 2019. http://dx.doi.org/10.1145/3321707.3321788.
Повний текст джерела"Evaluation of stress resistance of grape remote hybrids, carrying Vitis rotundifolia Michx. introgressions." In Plant Genetics, Genomics, Bioinformatics, and Biotechnology. Novosibirsk ICG SB RAS 2021, 2021. http://dx.doi.org/10.18699/plantgen2021-217.
Повний текст джерелаAlexandrov, Eugeniu, and Boris Gaina. "Viticultura biologică - o necesitate a dezvoltării durabile." In VIIth International Scientific Conference “Genetics, Physiology and Plant Breeding”. Institute of Genetics, Physiology and Plant Protection, Republic of Moldova, 2021. http://dx.doi.org/10.53040/gppb7.2021.47.
Повний текст джерелаLupascu, Galina, Svetlana Gavzer, Angela Rudacova, and Ala Cherdivara. "Genotipuri noi de grâu comun de toamnă – productivitatea și calitatea boabelor." In VIIth International Scientific Conference “Genetics, Physiology and Plant Breeding”. Institute of Genetics, Physiology and Plant Protection, Republic of Moldova, 2021. http://dx.doi.org/10.53040/gppb7.2021.59.
Повний текст джерелаЗвіти організацій з теми "Grapes Genetics"
Perl, Avichai, Bruce I. Reisch, and Ofra Lotan. Transgenic Endochitinase Producing Grapevine for the Improvement of Resistance to Powdery Mildew (Uncinula necator). United States Department of Agriculture, January 1994. http://dx.doi.org/10.32747/1994.7568766.bard.
Повний текст джерелаReisch, Bruce, Pinhas Spiegel-Roy, Norman Weeden, Gozal Ben-Hayyim, and Jacques Beckmann. Genetic Analysis in vitis Using Molecular Markers. United States Department of Agriculture, April 1995. http://dx.doi.org/10.32747/1995.7613014.bard.
Повний текст джерелаMawassi, Munir, Baozhong Meng, and Lorne Stobbs. Development of Virus Induced Gene Silencing Tools for Functional Genomics in Grapevine. United States Department of Agriculture, July 2013. http://dx.doi.org/10.32747/2013.7613887.bard.
Повний текст джерелаReisch, Bruce, Pinhas Spiegel-Roy, and Aliza Vardi. Tissue Culture and Gene Transfer for Genetic Improvement of Grapes. United States Department of Agriculture, November 1991. http://dx.doi.org/10.32747/1991.7599656.bard.
Повний текст джерелаJuenger, Thomas, and Ed Wolfrum. The Genetics of Biofuel Traits in Panicum Grasses: Developing a Model System with Diploid Panicum Hallii. Office of Scientific and Technical Information (OSTI), July 2016. http://dx.doi.org/10.2172/1337332.
Повний текст джерелаGregurick, S. K. AB Initio Protein Tertiary Structure Prediction: Comparative-Genetic Algorithm with Graph Theoretical Methods. Office of Scientific and Technical Information (OSTI), April 2001. http://dx.doi.org/10.2172/834523.
Повний текст джерелаReisch, Bruce, Avichai Perl, Julie Kikkert, Ruth Ben-Arie, and Rachel Gollop. Use of Anti-Fungal Gene Synergisms for Improved Foliar and Fruit Disease Tolerance in Transgenic Grapes. United States Department of Agriculture, August 2002. http://dx.doi.org/10.32747/2002.7575292.bard.
Повний текст джерелаLichter, Amnon, Gopi K. Podila, and Maria R. Davis. Identification of Genetic Determinants that Facilitate Development of B. cinerea at Low Temperature and its Postharvest Pathogenicity. United States Department of Agriculture, March 2011. http://dx.doi.org/10.32747/2011.7592641.bard.
Повний текст джерелаWright, Adam, Marija Milacic, Karen Rothfels, Joel Weiser, Quang Trinh, Bijay Jassal, Robin Haw, and Lincoln Stein. Evaluating the Predictive Accuracy of Reactome's Curated Biological Pathways. Reactome, November 2022. http://dx.doi.org/10.3180/poster/20221109wright.
Повний текст джерелаThurston, Alison, Zoe Courville, Lauren Farnsworth, Ross Lieblappen, Shelby Rosten, John Fegyveresi, Stacy Doherty, Robert Jones, and Robyn Barbato. Microscale dynamics between dust and microorganisms in alpine snowpack. Engineer Research and Development Center (U.S.), March 2021. http://dx.doi.org/10.21079/11681/40079.
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