Global ETD Search

41	Comparative Mapping of QTLs Affecting Oil Content, Oil Composition, and other Agronomically Important Traits in Oat (Avena sativa L.) Hizbai, Biniam T. January 2012 (has links) Groat oil content and composition are important quality traits in oats (Avena sativa L). These traits are controlled by many genes with additive effects. The chromosomal regions containing these genes, known as quantitative trait loci (QTL), can be discovered through their close association with markers. This study investigated total oil content and fatty acid components in an oat breeding population derived from a cross between high oil ('Dal') and low oil ('Exeter') parents. A genetic map consisting of 475 DArT (Diversity Array Technology) markers spanning 1271.8 cM across 40 linkage groups was constructed. QTL analysis for groat oil content and composition was conducted using grain samples grown at Aberdeen, ID in 1997. QTL analysis for multiple agronomic traits was also conducted using data collected from hill plots and field plots in Ottawa, ON in 2010. QTLs for oil content, palmitic acid (16:0), stearic acid (18:0), oleic acid (18:1), linoleic acid (18:2) and linolenic acid (18:3) were identified. Two of the QTLs associated with oil content were also associated with all of the fatty acids examined in this study, and most oil-related QTL showed similar patterns of effect on the fatty acid profile. These results suggest the presence of pleiotropic effects on oil-related traits through influences at specific nodes of the oil synthesis pathway. In addition, 12 QTL-associated markers (likely representing nine unique regions) were associated with plant height, heading date, lodging, and protein content. The results of this study will provide information for molecular breeding as well as insight into the genetic mechanisms controlling oil biosynthesis in oat. Oat (Avena sativa) DArT markers ACCase DGAT oil content fatty acid biosynthesis plant height heading date protein lodging marker assisted selection (MAS) Triacylglycerol (TAG) oil profile
42	Identification and Mapping of Resistance to Puccinia striiformis and Puccinia triticina in Soft Red Winter Wheat Carpenter, Neal Ryan 04 December 2017 (has links) Disease resistance is critical in soft red winter wheat (Triticum aestivum L.) cultivars. Leaf rust caused by Puccinia triticina Eriks and stripe rust caused by Puccinia striiformis Westend. f.sp. tritici Eriks. are destructive pathogens of wheat. From 2014 to 2015 phenotypic data was collected at diverse locations for resistance to leaf rust (North Carolina, Texas, and Virginia) and stripe rust (Arkansas, North Carolina, Georgia, Texas, and Virginia) in a Pioneer ‘25R47’ /‘Jamestown’ (P47/JT) population composed of 186 F5:9 recombinant inbred lines (RILs). Analysis of the P47/JT population identified two quantitative trait loci (QTL) for leaf rust resistance on chromosome 5B and two QTL for stripe rust resistance on chromosomes 3B and 6A. Phenotypic variation (%) explained by the putative leaf rust resistance QTL of Jamestown on 5B was as high as 22.1%. Variation explained by the putative stripe rust resistance QTL of Jamestown on 3B and 6A was as high as 11.1 and 14.3%, respectively. Jamestown is postulated to contain gene Lr18. Seedlings of 186 F5:9 recombinant inbred lines from the P47/JT population and 200 F2 seedlings from eight other crosses including Jamestown and/or the Lr18 host differential line RL6009 (Thatcher*6/Africa 43) were screened with P. triticina race TNRJJ. Genetic analysis of the populations was conducted to validate the presence of Lr18 in Jamestown. Results of linkage analysis identified SNP maker IWB41960 linked within 5 cM of gene Lr18 in all three populations. From 2016 to 2017 phenotypic data was collected at diverse locations for resistance to leaf rust (Illinois, North Carolina, and Virginia) in a ‘2013412’ (PI 667644) / VA10W-21 (PI 676295) population (412/21) composed of 157 doubled haploid (DH) lines. The 412/21 DH lines were genotyped via genotyping by sequence (GBS). Analysis of the 412/21 population identified one quantitative trait loci (QTL) region associated with adult plant resistance to leaf rust on chromosome 1B. Phenotypic variation (%) explained by the putative leaf rust resistance QTL of 2013412 on 1B was as high as 40.1%. Kompetitive allele-specific (KASP) markers KASP_S1B_8414614 and KASP_S1B_8566239 were developed as markers for use in marker assisted selection. / Ph. D. Triticum aestivum wheat adult plant resistance Puccinia triticina leaf rust Puccinia striiformis stripe rust QTL linkage mapping LOD marker-assisted selection
43	Development of intervarietal substitution lines in <i>Brassica napus</i> L. using marker assisted selection and mapping of QTL for agronomically important traits / Entwicklung von intervarietalen Substitutionslinien in <i>Brassica napus</i> L. mit Markergestützte Selektion und Kartierung von QTL für wichtige agronomische Merkmale Kebede, Berisso 19 July 2007 (has links) No description available. 630 Landwirtschaft Veterinärmedizin Agricultural Sciences Substitution lines marker assisted selection QTL <i>Brassica napus</i> rapeseed Substitutionslinien Markergestützte Selektion QTL <i>Brassica napus</i> Raps 48 Land- und Forstwirtschaft 48.58 Pflanzenzüchtung
44	Physiological and genetic analyses of post-anthesis heat tolerance in winter wheat (Triticum aestivum L.) Vijayalakshmi, Kolluru January 1900 (has links) Doctor of Philosophy / Agronomy / Allan K. Fritz / Bikram S. Gill / Gary M. Paulsen / Post-anthesis high temperature stress in wheat (Triticum aestivum L.) is a major cause of yield reduction. This process results in the loss of viable leaf area and a decrease in green leaf duration ultimately causing a yield loss. The objectives of this study were to (i) phenotype a recombinant inbred line population for heat tolerance traits, (ii) understand the genetic basis of heat tolerance by mapping quantitative trait loci (QTL) linked to yield-related traits under high temperature, (iii) model stay-green under high temperature stress and map the QTL linked to stay-green parameters, and (iv) validate the markers linked to QTL under field conditions. A filial6:7 (F6:7) recombinant inbred line (RIL) population was developed by crossing Ventnor, a heat-tolerant white winter wheat with Karl 92, a relatively heat susceptible hard red winter wheat. From 10 DAA to maturity, the treatments of optimum temperature or high temperature stress (30/25°C) were imposed on the RILs. The traits measured included grain filling duration (GFD), kernels per spike, thousand kernel weight (TKW), and grain filling rate (GFR). The stay-green traits calculated were: i) time between 75% and 25% green, ii) maximum rate of senescence, iii) time to maximum rate of senescence, and v) percent green at maximum senescence. Genetic characterization was performed using microsatellite (SSR), amplified fragment length polymorphism (AFLP) and a sequence tag site (STS) markers. GFD was positively correlated with TKW and negatively with GFR and maximum rate of senescence. Principle component analysis (PCA) showed kernels per spike, maximum rate of senescence, and TKW accounted for 98% of total variability among the genotypes for heat tolerance. The most significant QTL for yield traits co-localized with marker Xgwm296 for TKW, Xgwm356 for kernels per spike, and Xksum61 for GFR. The QTL for stay-green traits co-localized with markers P41/M62-107 on Chromosome 2A, Xbarc136 on Chromosome 2D, P58/MC84-146 on Chromosome 3B, P58/M77-343 on Chromosome 6A, and. P58/MC84-406 on Chromosome 6B. These results indicate that increased green leaf area duration has a positive effect on the grain yield under high temperature. Once the kernels per spike are established, GFD and TKW can be used as selection criteria for post-anthesis heat-tolerance. Heat Tolerance Wheat QTL mapping Senescence Grain-fill stress Marker assisted selection Agriculture, Agronomy (0285) Agriculture, General (0473) Biology, Biostatistics (0308) Biology, General (0306) Biology, Genetics (0369) Biology, Molecular (0307) Biology, Plant Physiology (0817)
45	Identification of Molecular Markers Associated with the <i>Rps</i>8 locus in Soybean and Evaluation of Microsporogenesis in <i>Rps</i>8/<i>rps</i>8 Heterozygous Lines Ortega, Maria Andrea January 2009 (has links) No description available. Plant Pathology Soybean Phytophthora sojae stem and root rot chromosome 13 segregation distortion microsporogenesis microcytes molecular mapping graphical genotype ssr genotyping snp genotyping marker assisted selection disease resistance oomycete r genes
46	Towards Cloning the Leaf Rust Resistance Gene Rph5 Mammadov, Jafar 23 August 2004 (has links) Leaf rust caused by Puccinia hordei is an important disease of barley (Hordeum vulgare) in many regions of the world. Yield losses up to 62% have been reported in susceptible cultivars. The Rph5 gene confers resistance to the most prevalent races (8 and 30) of barley leaf rust in the United States. Therefore, the molecular mapping of Rph5 is of great interest. Genetic studies were performed by analysis of 93 and 91 F2 plants derived from the crosses 'Bowman' (rph5) x 'Magnif 102' (Rph5) and 'Moore' (rph5) x Virginia 92-42-46 (Rph5), respectively. Linkage analysis positioned the Rph5 locus to the extreme telomeric region of the short arm of barley chromosome 3H at 0.2 cM proximal to RFLP marker VT1 and 0.5 cM distal from RFLP marker C970 in the Bowman x Magnif 102 population. Synteny between rice chromosome 1 and barley chromosome 3 was employed to saturate the region within the sub-centimorgan region around Rph5 using sequence-tagged site (STS) markers that were developed based on barley expressed sequence tags (ESTs) syntenic to the phage (P1)-derived artificial chromosome (PAC) clones comprising distal region of the rice chromosome 1S. Five rice PAC clones were used as queries to blastn 370,258 barley ESTs. Ninety four non-redundant EST sequences were identified from the EST database and used as templates to design 174 pairs of primer combinations. As a result, 10 EST-based STS markers were incorporated into the 'Bowman' x 'Magnif 102' high-resolution map of the Rph5 region. More importantly, six markers, including five EST-derived STS sequences, co-segregate with Rph5. Genes, represented by these markers, are putative candidates for Rph5. Results of this study demonstrate the usefulness of rice genomic resources for efficient deployment of barley EST resources for marker saturation of targeted barley genomic region. / Ph. D. Expressed Sequence Tag (EST) high resolution map Rph5 contig barley Bacterial Artificial Chromosome (BAC) leaf rust synteny comparative mapping molecular mapping marker-assisted selection gene pyramiding Resistance Gene Analog (RGA) rice physical mapping
47	EFFECT OF PHOTOPERIOD ON THE ADAPTATION OF CHICKPEA (CICER ARIETINUM L.) TO THE CANADIAN PRAIRIES 2015 September 1900 (has links) Chickpea (Cicer arietinum L.) was recently introduced to the Canadian prairies, a region which has a short growing season in which crop maturation often occurs under cool and wet conditions. To improve the yield of chickpea, crop duration must closely match the available growing season. The objectives of this study were to: i) examine the days to flowering of diverse chickpea accessions grown in either long or short-days; ii) examine the days to flowering of selected chickpea accessions grown in a range of thermal regimes combined with either long or short days and to examine the interaction between photoperiod and day and night temperatures on crop duration; iii) determine the timing and duration of the photoperiod-sensitive phase in selected chickpea accessions, and vi) determine the genetic basis of the association between flowering time and reaction to ascochyta blight in chickpea. A wide variation was observed in chickpea accessions for their response to flowering under long (16/8 hours day /night) and short days (10/14 hours day/night). Earlier flowering was observed under long photoperiod regimes compared with the short photoperiod regimes. Variability was detected among chickpea accessions for their flowering responses when different temperatures were combined with different photoperiods. Earlier flowering was observed under long days (16/8 hours day/night) coupled with high to moderate temperature regimes (24/16 ºC and 20/12 ºC, day and night respectively) compared to short-days (10/14 hours day and night) and moderate to low temperature regimes (20/12 ºC and 16/8 ºC day and night, respectively). Those chickpea accessions such as ICC 6821 and ICCV 96029 which originated from the lower latitudes of Ethiopia and India, respectively, flowered earlier compared to accessions such as CDC Corinne and CDC Frontier which originated from the higher latitudes and cooler temperate environments of western Canada. Photoperiod sensitivity phases were detected in chickpea accessions adapted to the cold environments of western Canada, whereas no photoperiod sensitivity phase was identified in the extra-early flowering cultivar ICCV 96029. The duration of the photoperiod sensitive phase in the chickpea accessions was longer under short days compared to long days. Field and growth chamber evaluation of a chickpea RIL population (CP-RIL-1) revealed the presence of variability among the lines and the two parents for their days to flowering and level of resistance to ascochyta blight. Broad sense heritability across different site-years for days to flower 0.45 to 0.78, plant height 0.48 to 0.78, ascochyta blight resistance 0.14 to 0.68, days to maturity 0.26, photoperiod sensitivity 0.83 and nodes number of first flowering 0.37 to 0.75 were estimated. Days to flower and photoperiod sensitivity were significantly r = -0.21 to -0.58 (P ≤ 0.05 to 0.001) and -0.28 to -0.41 (P ≤ 0.01 to 0.001), respectively and negatively correlated with ascochyta blight resistance in the CP-RIL-1 population. A genetic linkage map consisting of eight linkage groups was developed using 349 SNP markers. Seven QTLs were identified for days to flowering under growth chamber and field conditions on chromosomes 3, 5, 6 and 8 each and 3 QTLs on chromosome 4. The total phenotypic variation explained by QTLs for days to flowering ranged from 7 to 44%. Two QTLs for days to maturity were identified on chromosomes 3 and 8. Three QTLs, one each on chromosomes 3, 4 and 5 were identified for photoperiod sensitivity. The total phenotypic variation explained by each QTL for photoperiod sensitivity ranged from 7 to 41%. A total of three QTL for node of first flowering, one on chromosomes 3 and 8 each, and two on chromosome 4 were identified. The two QTL on chromosome 4 explained total phenotypic variations of 11 and 32%, respectively. Ten QTLs distributed across all chromosomes, except chromosomes 2 and 5, were identified for ascochyta blight resistance. The phenotypic variability explained by each QTL for ascochyta blight resistance ranged from 7 to 17%. The molecular markers associated with these QTLs have potential for use in chickpea breeding. Adaptation Ascochyta blight Chickpea Days to flower Days to maturity Broad sense heritability Long-days Linkage Group Marker Assisted Selection Short-days Thermal units Photoperiod Photo-thermal units Quantitative Trait Locus Restriction-site Associated DNA Recombinant Inbred Line Single Nucleotide Polymorphism
48	Untersuchung zur Gestaltung von Zuchtprogrammen in der Legehennenzucht / Studies on the design of breeding programs in the breeding of laying hens Tsehay, Fitsum 19 May 2005 (has links) No description available. 630 Landwirtschaft Veterinärmedizin Agricultural Sciences Zuchtprogramme Legehennen Inzucht Zuchtfortschritt Selektion Anpaarungsstrategien Simulation Markergestützte Selektion (MAS) QTL optimum genetic contribution OGC GENCONT Lohmann (LSL) Selection strategies mating systems layer breeding programs inbreeding selection response simulation marker assisted selection (MAS) QTL optimum genetic contribution theory OGC GENCONT Lohmann (LSL) 48.64 YF
49	Comparative Genomics of Gossypium spp. through GBS and Candidate Genes – Delving into the Controlling Factors behind Photoperiodic Flowering Young, Carla Jo Logan 16 December 2013 (has links) Cotton has been a world-wide economic staple in textiles and oil production. There has been a concerted effort for cotton improvement to increase yield and quality to compete with non-natural man-made fibers. Unfortunately, cultivated cotton has limited genetic diversity; therefore finding new marketable traits within cultivated cotton has reached a plateau. To alleviate this problem, traditional breeding programs have been attempting to incorporate practical traits from wild relatives into cultivated lines. This incorporation has presented a new problem: uncultivated cotton hampered by photoperiodism. Traditionally, due to differing floral times, wild and cultivated cotton species were unable to be bred together in many commercial production areas world-wide. This worldwide breeding problem has inhibited new trait incorporation. Before favorable traits from undomesticated cotton could be integrated into cultivated elite lines using marker-assisted selection breeding, the markers associated with photoperiod independence needed to be discovered. In order to increase information about this debilitating trait, we set out to identify informative markers associated with photoperiodism. This study was segmented into four areas. First, we reviewed the history of cotton to highlight current problems in production. Next, we explored cotton’s floral development through a study of floral transition candidate genes. The third area was an in-depth analysis of Phytochrome C (previously linked to photoperiod independence in other crops). In the final area of study, we used Genotype-By-Sequencing (GBS), in a segregating population, was used to determine photoperiod independence associated with single nucleotide polymorphisms (SNPs). In short, this research reported SNP differences in thirty-eight candidate gene homologs within the flowering time network, including photoreceptors, light dependent transcripts, circadian clock regulators, and floral integrators. Also, our research linked other discrete SNP differences, in addition to those contained within candidate genes, to photoperiodicity within cotton. In conclusion, the SNP markers that our study found may be used in future marker assisted selection (MAS) breeding schemas to incorporate desirable traits into elite lines without the introgression of photoperiod sensitivity. Genotype by Sequencing Cotton Gossypium Reduced Representation Marker Assisted Selection Loci Linkage Disequilibrium Photoperiodism Photoperiod Flowering Wild Germplasm Introgression GBS Targeted GBS Cotton Duplicate Gene Evolution Gene Conversion Gossypium Polyploidy Linkage Disequilibrium Candidate Gene SNP Orthologs Circadian Clock Paralogs Phytochrome Floral
50	Genetische Analysen für eine markergestützte Verbesserung der Trockenstresstoleranz von Winterackerbohnen / Genetic analysis for marker assisted improvement of drought tolerance in autumn sown Faba Bean Welna, Gregor Christian 13 May 2014 (has links) In dieser Arbeit zu genetischen Analysen für die Vorbereitung eine markergestützten Selek-tion auf Trockenstresstoleranz bei der Winterackerbohne wurden 196 Winterackerbohnen-Inzuchtlinien und vier Sommerackerbohnen-Inzuchtlinien genotypisiert. Diese Inzuchtlinien wurden außerdem hinsichtlich der Physiologie-Merkmale Spad-Wert, Membranstabilitäts-index, Blattwassergehalt, Gesamtgehalt löslicher Zucker sowie Prolin- und Glycinbetainge-halt in je einer Kontroll- und einer Stressbehandlung phänotypisiert. Anhand eines Verifika-tionssatzes von 40 der 196 Winterackerbohnen-Inzuchtlinien wurden korrelative Verbin-dungen zwischen den physiologischen Merkmalen sowie feldbasierten und züchterisch relevanten Merkmalen wie bspw. Ertrag gesucht. Diese feldbasierten Merkmale wurden mit Hilfe von Rain-Out-Sheltern an den Standorten Göttingen und Groß Lüsewitz in den Jahren 2010/2011, 2012 und 2012/2013 erfasst. Ferner wurden die Möglichkeiten einer Simulation von Trockenstressreaktionen anhand dieses Verifikationssatzes durch Sikkationsversuche mit Kaliumjodidapplikation untersucht. Es konnten keine eindeutigen Beziehungen zwi-schen der Stressreaktion induziert durch Wassermangel und durch Kaliumjodidapplikation ermittelt werden. Außerdem wurden keine eindeutigen Beziehungen der physiologischen Merkmale zu den feldbasierten Trockenstressresultaten gefunden. Mittels einer Kartierungspopulation von 101 RIL wurde eine genetische Karte der Acker-bohne mit zwölf Kopplungsgruppen bestehend aus insgesamt 1451 Markern und einer Län-ge von 1633,2 cM erstellt. Fünf dieser Kopplungsgruppen konnten als Fragmente identifi-ziert werden. Die verbleibenden sieben Kopplungsgruppen wurden mit den verwendeten SNP-Markern mittelbar den sechs Chromosomen der Ackerbohne zugeordnet. Hierbei stel-len z. B. die erste und vierte Kopplungsgruppe gemeinsam eine Kopplungsgruppe dar. Die so kartierten Marker wurden hinsichtlich ihres Spaltungsverhältnisses innerhalb des A-Satzes – bestehend aus 189 der 196 phänotypisierten Winterackerbohnen-Inzuchtlinien – überprüft und für eine Assoziationsanalyse mit den Physiologiemerkmalen ausgewählt. Das Gametenphasenungleichgewicht zwischen 323 610 Markerpaaren wurde ihrer jeweiligen Distanz auf der genetischen Karte gegenübergestellt. Es konnte gezeigt werden, dass in der Entstehungsgeschichte des untersuchten Materials das Gametenphasenungleichgewicht durch Rekombination stark abgebaut wurde. In die Assoziationsanalyse flossen insgesamt 1322 Marker ein. Mittels dieser molekularen Marker konnten insgesamt sechs QTL für Physiologie-Merkmale identifiziert werden. Dabei entfiel je ein QTL auf die Merkmale absolute Differenz im Glycinbetaingehalt zwischen Stress- und Kontrollbehandlung und Glycinbetaingehalt in der Kontrollbehandlung. Vier QTL konnten für die absolute Differenz zwischen dem Prolingehalt in der Stress- und Kontroll-behandlung identifiziert werden. Die gefundenen QTL können anhand der vorliegenden feldbasierten Verifikationsdaten nicht als markergestützte Selektionsmöglichkeit auf Tro-ckenstresstoleranz empfohlen werden. Der nächste Schritt ist demzufolge, mittels feldba-sierter Prüfungen der Inzuchtlinien in realen, relevanten Trockenstresslagen über ausrei-chend viele Orte und Jahre die Bedeutung der physiologischen Merkmale weiter zu prüfen. 630 Pflanzenzüchtung Ackerbohne Trockenstress Molekulare Marker Assoziationsanalyse SNP AFLP genetische Karte abiotischer Stress Gametenphasenungleichgewicht makergestützte Selektion plant breeding faba bean drought tolerance molecular marker association analysis SNP AFLP genetic map abiotic stress linkage disequilibrium marker assisted selection LD mapping Land- und Forstwirtschaft (PPN621302791)

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