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The genetics of barley yellow dwarf virus resistance in barley and rice.Collins, Nicholas C. January 1996 (has links)
Barley yellow dwarf virus (BYDV), an aphid transmitted luteovirus, is the most widespread and economically damaging virus of cereal crops. The work in this thesis aims to characterise the basis of the naturally occurring resistance to BYDV in cereals in three ways: Firstly, by facilitating the isolation of the Yd2 gene for BYDV resistance from barley by a map-based approach. Secondly, by determining if a BYDV resistance gene in rice is orthologous to Yd2. Thirdly, by establishing if other BYDV resistance genes in non- Ethiopian barleys are allelic to Yd2. It is hoped that the information generated in this study will ultimately assist in the production of BYDV resistant cereal cultivars. A detailed genetic map of the Yd2 region of barley chromosome 3 was constructed, containing 19 RFLP loci, the centromere and the Yd2 gene. Yd2 mapped on the long arm, 0.5 cM from the centromere, and in the mapping population of 106 F2 individuals, perfectly cosegregated with the RFLP loci XYlp, and Xwg889. This map represents the first stage in a project to isolate the Yd2 gene by a map-based approach. The isolation of Yd2 could help to elucidate the molecular mechanism of the Yd2-mediated BYDV resistance, and may allow the production of BYDV resistant cereals by genetic transformation. The RFLP markers mapped closest to Yd2 could also be useful in barley breeding, by enabling selection for both the presence of Yd2 and the absence of agronomically undesirable traits known to be closely linked to Yd2. Genetically Directed Representational Difference Analysis (GDRDA) is a technique based on subtractive hybridisation, which can be used to identify RFLP markers closely linked to a gene of interest. Two GDRDA experiments were performed with the intention of generating additional RFLP markers close to Yd2. However, the first experiment yielded RFLP probes that were not derived from the barley genome, while the second experiment yielded probes that detected repetitive sequences. It was concluded that GDRDA is of limited use in generating further markers close to Yd2. To isolate the Yd2 gene by a map-based approach, a much larger mapping population will need to be analysed to genetically resolve markers tightly linked to Yd2. If the two morphological markers uzu dwarf and white stripe,,j flank Yd2, then they could assist in this task by enabling the visual identification of F2 seedlings resulting from recombination close to Yd2. However, in this study, both morphological markers were found to be located distal to Yd2. Therefore, these two morphological markers can not be used together to facilitate high resolution genetic mapping of the Yd2 locus. It may be possible to use large-insert genomic DNA clones from the relatively small genome of rice to generate further RFLP markers close to the Yd2 gene in barley, provided that the order of orthologous sequences in barley and rice is conserved close to the Yd2 locus. To assess the feasibility of this approach, RFLP probes used to identify loci close to Yd2 were mapped in rice using a segregating rice F2 population. Five of the RFLP loci mapped together and in the same order as RFLP loci mapped close to Yd2 in barley using the same probes. By comparing the location of RFLPs mapped by other researchers in rice using probes mapped close to Yd2, the region of conserved linkage between rice and the Yd2 region was tentatively identified as the central portion of rice chromosome 1. The collinearity shown by orthologous sequences in barley and rice indicated that it may indeed be possible to use rice to assist in generating RFLP markers close to Yd2. Of all the cereals, rice is the most amenable to map-based gene isolation, due to its small genome, well developed physical and genetic maps, and its ability to be genetically transformed with high efficiency. If a BYDV resistance gene that is orthologous to Yd2 could be identified in rice, this gene could be isolated with relative ease, and then used to identify barley cDNA clones corresponding to Yd2 gene by virtue of the sequence homology expected between these genes. To test if a BYDV resistance gene from an Italian rice line is orthologous to Yd2, recombinant-inbred rice lines previously characterised for this gene were analysed using probes mapped close to Yd2 in barley. No genetic linkage was detected between the RFLP loci and the BYDV resistance gene, indicating that the gene is unlikely to be orthologous to Yd2. BYDV resistance alleles at the Yd2 locus which are of a non-Ethiopian origin may show interesting differences to Ethiopian Yd2 resistance alleles. To identify barleys which may contain resistance alleles of Yd2, ten BYDV resistant barleys not known to contain Yd2 were assessed for their resistance to the PAVadel isolate of BYDV in the glasshouse. CI 1179, Rojo, Perry, Hannchen, Post and CI 4228 were found to be the most resistant under these conditions, and were analysed further. If the resistance from these barleys is controlled by alleles of Yd2, RFLP markers close to Yd2 will be expected to cosegregate with the resistance in F2 families derived from crosses between these resistant barleys and the BYDV susceptible barleys Atlas and Proctor. RFLPs suitable for use in these allelism tests were identified using probes mapped close to Yd2. However, time did not permit the analysis of these F2 populations. / Thesis (Ph.D.) -- University of Adelaide, Dept. of Plant Science, 1996
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Towards cloning Yd2 : a barley resistance gene to barley yellow dwarf virus / by Brendon James King.King, Brendon James January 2001 (has links)
Errata attached to inside front cover. / Bibliography: leaves [156-188] / vi, 155, [33] leaves, [48] leaves of plates : ill. (some col.) ; 30cm. / Title page, contents and abstract only. The complete thesis in print form is available from the University Library. / Thesis (Ph.D.)--University of Adelaide, Dept. of Plant Science, 2001
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The genetics of barley yellow dwarf virus resistance in barley and riceCollins, Nicholas C. January 1996 (has links) (PDF)
Includes bibliographical references. The thesis aims to characterise the basis of naturally occuring resistance to BYDV in cereals in three ways: i. A map-based approach to the isolation of the Yd2 gene for BYDV resistance from barley. -- ii. Determining if a BYDV resistance gene in rice is orthologous to Yd2. -- iii. Establishing if other BYDV resistance genes in non-Ethiopian barleys are allelic to Yd2.
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Aspects of luteovirus molecular biology in relation to the interaction between BYDV-PAV and the Yd2 resistance gene of barley / by John Paul Rathjen.Rathjen, John Paul January 1995 (has links)
Errata sheet pasted on front end-paper. / Includes bibliographical references. / v, 125, [99] leaves, [3] leaves of plates : ill. (chiefly col.) ; 30 cm. / Title page, contents and abstract only. The complete thesis in print form is available from the University Library. / Thesis (Ph.D.)--University of Adelaide, Dept. of Plant Science, (1995?)
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Mapping of chromosome regions associated with seed zinc accumulation in barleySadeghzadeh, Behzad January 2008 (has links)
[Truncated abstract] Zinc deficiency in crops is the most widespread micronutrient deficiency, with about 50% of the cereal-growing areas worldwide containing low levels of plant-available Zn. Zinc plays multiple key roles in different metabolic and physiological processes; its deficiency in crops reduces not only grain yield, but also the nutritional quality of grains. Insufficient micronutrient intake, particularly Zn and Fe, afflicts over 3 billion people in the world, mainly in developing countries. Increasing the amount of Zn in food crops can contribute to improving the Zn status of people. Furthermore, Zn-dense seeds have agronomic benefits, resulting in greater seedling vigour, bigger root system and higher crop yield when sowed to soils with low plant-available Zn. Enhancing nutrient content and nutritional quality of crops for human nutrition is a global challenge currently, but it was mostly ignored during the breeding process in the past. There is a significant genotypic variation for seed Zn accumulation in several crops (including barley) which could be exploited in the breeding programs to produce genotypes with higher seed Zn concentration and content. However, the progress in Zn efficiency until now has mainly relied on conventional plant breeding approaches that have had limited success. Therefore, reliable alternative methods are required. Enhancing mineral nutrition through plant biotechnology may be a sustainable and beneficial approach in developing Zn-dense seeds in the staple crops. ... This DNA band was sequenced and converted into a simple sequence-specific PCR-based marker, which was designated as SZnR1 (seed Zn-regulator1). The developed marker is very easy to score, is inexpensive to run and amenable for a large number of plant samples. The successful development of SZnR1 molecular marker linked to chromosome region associated with seed Zn concentration and content using MFLP in this study illustrates the advantage of this technique over some other DNA fingerprinting methods used for identification of molecular markers for marker-assisted selection (MAS). In conclusion, the greater Zn efficiency of Sahara over Clipper under sufficient Zn supply may be attributed to its higher uptake of Zn. It appears that soil-based pot experiments under controlled condition may offer potential improvements over field experiments in screening for seed Zn accumulation. Shoot and seed Zn concentration and content can be used to diagnose the Zn statues of barley genotypes, and may be a useful selection criterion for Zn efficiency in large populations like doubled-haploid populations aimed at developing molecular markers for Zn efficiency. Identified QTLs influencing seed Zn concentration were repeatable in the field and glasshouse conditions, suggesting their robustness across environments as well as their value in marker-assisted selection. The developed PCR-based marker SZnR1 and other molecular markers associated with the QTLs on the short and long arms of chromosome 2H have the potential to be used for marker-assisted selection in breeding for Zn-dense seed in barley.
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FR‐H3 : a new QTL to assist in the development of fall-sown barley with superior low temperature toleranceFisk, Scott P. 01 December 2011 (has links)
Fall-sown barley will be increasingly important in the era of climate change due to higher yield potential and efficient use of water resources. Resistance/tolerance to biotic and abiotic stresses will be critical. Low temperature is an abiotic stress of great importance. Resistance to barley stripe rust (incited by Puccinia striifomis f. sp. hordei) and scald (incited by Rhynchosporium secalis) will be important in higher rainfall areas. Simultaneous gene discovery and breeding will accelerate the development of agronomically relevant germplasm. The role of FR-H1 and FR-H2 in low temperature tolerance (LTT) has been well documented. However the question still remains: is LTT due only to FR-H1 and FR-H2 or are there other, undiscovered, determinants of this critical trait? We developed two doubled haploid mapping populations using two lines from the University of Nebraska (NE) with superior cold tolerance and one line from Oregon State University (OR) with good malting quality and disease resistance: NB3437f/OR71 (facultative x facultative) and NB713/OR71 (winter x facultative). Both were genotyped with a custom 384 oligonucleotide pool assay (OPA). QTL analyses were performed for LTT, vernalization sensitivity (VS), and resistance to barley stripe rust and scald. Disease resistance QTL were identified with favorable alleles from both NE and OR germplasm. The role of VRN-H2 in VS was confirmed and a novel alternative winter allele at VRN-H3 was discovered in the Nebraska germplasm. FR-H2 was identified as a determinant of LTT and a new QTL, FR-H3, was discovered on chromosome 1H that accounted for up to 48% of the phenotypic variation in field survival at St. Paul, Minnesota, USA. The discovery of FR-H3 is a significant advancement in barley LTT genetics and will assist in developing the next generation of fall-sown varieties. / Graduation date: 2012
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The genetic basis of barley black point formation.March, Timothy January 2008 (has links)
Black point of barley grain refers to a discolouration of the embryo end of the grain. Historically black point has been proposed to be due to fungal colonisation of the grain. However, Koch’s postulates have yet to be satisfied. The discolouration occurs during grain fill in response to high humidity or rainfall during the grain filling period. In wheat, which is also affected by black point, the discolouration has been proposed to be due to the oxidation of phenolic acids within the grain to form discoloured end products. Within this study, two approaches were investigated in order to understand the proteins and genes associated with this disorder. Firstly, a proteomics approach enabled the identification of individual proteins associated with black point. Two-dimensional gel electrophoresis was used to compare the proteome of the husk and whole grain tissue of mature black pointed and healthy grain. Very little watersoluble protein was extracted from the husk tissue. However, a significantly larger amount of protein was extracted using a salt extraction buffer, indicating the husk proteins were mostly cell wall bound. Due to the effect of residual salt and low protein concentrations these proteins were not conducive to analysis using two-dimensional gel electrophoresis. Further experiments using acid hydrolysis of the husk tissue and subsequent amino acid analysis revealed that the proteins were bound to the husk cell walls via covalent bonds. In contrast, large quantities of protein were obtained from the whole grain samples. This allowed statistically significant comparisons to be made between gels from healthy and black pointed grains. Two proteins were identified as being more abundant in black pointed grains. Mass spectrometry identified these as isoforms of barley grain peroxidase 1 (BP1). In addition, three proteins were identified as being more abundant in healthy grain. Mass spectrometry revealed these to be isoforms of the same protein with sequence similarity to a partial EST sequence from barley. Using 3' RACE the entire coding sequence of the gene was isolated which revealed that it encoded a novel putative late embryogenesis abundant (LEA) protein. Northern blot analysis was performed for BP1 and LEA and showed that gene expression differences could not account for the differences seen in protein quantities. Western blot analysis revealed that the LEA protein was biotinylated in vivo which is consistent with similar LEA proteins from other plant species. To further understand the role of these proteins in black point, antibodies were raised against the two proteins. Subsequent immunolocalisation studies indicated BP1 was present throughout all tissues of the grain whilst LEA was most abundant in the embryo and aleurone tissue. The second major area of investigation within this thesis was to further delineate the previously identified quantitative trait loci (QTL) associated with black point in barley. Previous studies have reported QTL for black point and kernel discolouration in both barley and wheat. Comparison of the published QTL revealed a locus on the short arm of chromosome 2H to be of particular interest. To identify genes underlying this QTL the genomes of barley, wheat and rice were compared. An in silico approach showed that the QTL shared macro-synteny with rice chromosomes 4 and 7. From the rice genome sequence, barley ESTs with sequence similarity were selected. In total, 20 ESTs were selected based on two main criteria: their putative role in black point and also being evenly spread across the region of the QTL length. These QTL were mapped within the Alexis x Sloop double haploid population. This approach revealed that there was some conservation of synteny but also identified clear boundaries where synteny between barley and rice had been lost since divergence. Significantly, the additional markers mapped to this region have enabled the initial black point QTL to be reduced from approximately 30cM to 20cM. In conclusion, this study has added significant knowledge our understanding of the genetics of black point in barley through the use of two approaches. The proteomics approach has aided in understanding the biochemical processes occurring within the grain in response to black point. The comparative genetics approach has aided in understanding the genetic control of an important region of the genome influencing black point susceptibility. Combined, these findings will direct future research endeavours aimed at producing black point resistant barley cultivars. / http://proxy.library.adelaide.edu.au/login?url= http://library.adelaide.edu.au/cgi-bin/Pwebrecon.cgi?BBID=1323053 / Thesis (Ph.D.) -- University of Adelaide, School of Agriculture, Food and Wine, 2008
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