Genetic Interactions Among Resistance Genes in Wheat (Triticum Aestivum L.) and Virulence Genes in the Hessian Fly [Mayetiola Destructor (Say)] in North America and Morocco PDF Download
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![Genetic Interactions Among Resistance Genes in Wheat (Triticum Aestivum L.) and Virulence Genes in the Hessian Fly [Mayetiola Destructor (Say)] in North America and Morocco PDF](https://books.google.com/books/content/images/frontcover/NsHmNwAACAAJ?fife=w150-h200)
Author: Mustapha El Bouhssini
Publisher:
ISBN:
Category :
Languages : en
Pages : 238
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![Genetic Interactions Among Resistance Genes in Wheat (Triticum Aestivum L.) and Virulence Genes in the Hessian Fly [Mayetiola Destructor (Say)] in North America and Morocco PDF](https://books.google.com/books/content/images/frontcover/NsHmNwAACAAJ?fife=w80-h100)
Author: Mustapha El Bouhssini
Publisher:
ISBN:
Category :
Languages : en
Pages : 238
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Author: Jimmy Howell Hatchett
Publisher:
ISBN:
Category :
Languages : en
Pages : 258
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Author: Robert L. Gallun
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ISBN:
Category : Hessian fly
Languages : en
Pages : 20
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Author: Robert L. Gallun
Publisher: Forgotten Books
ISBN: 9780364937426
Category : Business & Economics
Languages : en
Pages : 26
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Excerpt from Wheat Cultivars Resistant to Races of Hessian Fly Seven races of Hessian flies have been iso lated in the United States. The Great Plains race is most prevalent west Of central Kansas. Races A, B, C, D, and E are found in the eastern soft wheat region where race A is generally pre dominant, although races B and E are most prevalent in certain areas Of Indiana and Geor gia, respectively. Races B and E differ from one another in their ability to infest wheats having the Dawson, W38, and p.i. 94587 sources Of resistance. Race F, a new race capable Of infest ing wheats having the W38 resistance but not the Seneca type of resistance, has been bred in the laboratory. About the Publisher Forgotten Books publishes hundreds of thousands of rare and classic books. Find more at www.forgottenbooks.com This book is a reproduction of an important historical work. Forgotten Books uses state-of-the-art technology to digitally reconstruct the work, preserving the original format whilst repairing imperfections present in the aged copy. In rare cases, an imperfection in the original, such as a blemish or missing page, may be replicated in our edition. We do, however, repair the vast majority of imperfections successfully; any imperfections that remain are intentionally left to preserve the state of such historical works.
Author: Sandra Garcés Carrera
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ISBN:
Category :
Languages : en
Pages :
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The Hessian fly, Mayetiola destructor (Say), is a major pest of wheat, and is controlled mainly through deploying fly-resistant wheat cultivars. This study investigated five M. destructor populations collected from Texas, Louisiana, and Oklahoma, where infestation by Hessian fly has been high in recent years. Eight resistance genes including H12, H13, H17, H18, H22, H25, H26, and Hdic, were found to be highly effective against all tested M. destructor populations in this region, conferring resistance to 80% or more of plants containing one of these resistant genes. The frequency of biotypes virulent to resistant genes ranged from 0 to 45%. A logistic regression model was established to predict biotype frequencies based on the correlation between the percentages of susceptible plants obtained in a virulence test. In addition to the virulence test, the log-odds of virulent biotype frequencies were determined by a traditional approach to predict the logistic regression model. Characterization of a bacterial artificial chromosome (BAC) clone identified a gene encoding a protein with sequence similarity to bacterial levanases. Blast searching with the levanase-like protein identified 14 levanase/inulase-like genes or gene fragments. In this study, we determined the expression levels of these genes in different developmental stages and different tissues of 3-d old larvae of M. destructor. Sequence analysis revealed that six genes encode full length proteins, three were truncated at the 5' end, and five truncated at the 3' end. Sequences of putative proteins showed approximately 42% similarities to bacterial levanases or inulases, and 36% similarity to fungal levanases or inulases. No sequence similarities were found with any known animal or plant proteins. Comparative analysis of sequences among 14 levanase/inulase-like genes revealed that positions for intron/exon boundaries are conserved among different genes even though the length of each intron and exon varied among different genes. The expression patterns of the levanase/inulase-like genes were different among developmental stages and larval tissues of M. destructor. Interestingly, three genes presented alternative splicing bands in different developmental stages, and two genes exhibited splicing bands in different tissues of 3 d old M. destructor. This study would be useful for future studies of the characterization and function of levanase/inulase-like genes of these enzymes in plant-insect interactions.
Author:
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Category : Africa, North
Languages : en
Pages : 496
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Author: Tavin Marie Schneider
Publisher:
ISBN:
Category : Hessian fly
Languages : en
Pages :
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Wheat (Triticum aestivum L.) is one of the most important agricultural commodity crops in Washington. Each year, farmers face various production challenges, including Hessian fly [Mayetiola destructor (Say)], which can lead to devastating crop losses. Resistance genes are the most successful methods to manage and control this insect. Although there are at least 37 known Hessian fly resistance genes (HFR genes), few are deployed in the region, mostly due to a lack of molecular tools to support breeding efforts. Seahawk, a popular soft white spring wheat, contains resistance, but the gene identity is unknown. Using two recombinant inbred populations made from crossing soft white spring wheat cultivar Seahawk to spring club wheat cultivars JD and Melba, we set out to identify the source of resistance in Seahawk and to develop molecular markers that can be used to select for the gene in breeding populations. After acquiring the genetic marker information using Illumina’s 90K SNP technology, we were able to map the resistance gene to the distal end of the short arm of chromosome 6B and created three kompetitive allele specific PCR (KASP) markers that are effective in selecting for this gene in diverse backgrounds. Utilizing the Seahawk/JD population, we also studied how the wheat bread-making locus (wbm) affects the quality of soft white and club wheat. Soft white wheat and club wheat are produced and milled for their weak gluten properties and high starch contents that result in delicate crumb structures when baked. The wbm gene, however, is known to be associated with increased gluten strength properties and was identified in elite bread-making cultivars. At Washington State, the wbm gene is found at higher than expected frequencies among elite club and soft white wheat varieties. After testing the quality parameters of wbm isolines, we found that the locus does not negatively impact soft white wheat flour or dough properties.
Author: John B. Hartman
Publisher:
ISBN:
Category : Hessian fly
Languages : en
Pages : 166
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Author: Bing-huei Chen
Publisher:
ISBN:
Category : Hessian fly
Languages : en
Pages : 196
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Author: Anupama Joshi
Publisher:
ISBN:
Category :
Languages : en
Pages : 0
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H13, a dominant resistance gene transferred from Aegilops tauschii into wheat (Triticum aestivum), confers a high level of antibiosis against a wide range of Hessian fly (HF, Mayetiola destructor) biotypes. Previously, H13 was mapped to the distal arm of chromosome 6DS, where it is flanked by markers Xcfd132 and Xgdm36. A mapping population of 1,368 F2 individuals derived from the cross: PI372129 (h13h13) / PI562619 (Molly, H13H13) was genotyped and H13 was flanked by Xcfd132 at 0.4cM and by Xgdm36 at 1.8cM. Screening of BAC-based physical maps of chromosome 6D of Chinese Spring wheat and Ae. tauschii coupled with high resolution genetic and Radiation Hybrid mapping identified nine candidate genes co-segregating with H13. Candidate gene validation was done on an EMS-mutagenized TILLING population of 2,296 M3 lines in Molly. Twenty seeds per line were screened for susceptibility to the H13-virulent HF GP biotype. Sequencing of candidate genes from twenty-eight independent susceptible mutants identified three nonsense, and 24 missense mutants for CNL-1 whereas only silent and intronic mutations were found in other candidate genes. 5' and 3' RACE was performed to identify gene structure and CDS of CNL-1 from Molly (H13H13) and Newton (h13h13). Increased transcript levels were observed for H13 gene during incompatible interactions at larval feeding stages of GP biotype. The predicted coding sequence of H13 gene is 3,192 bp consisting of two exons with 618 bp 5'UTR and 2,260 bp 3'UTR. It translates into a protein of 1063 amino acids with an N-terminal Coiled-Coil (CC), a central Nucleotide-Binding adapter shared by APAF-1, plant R and CED-4 (NB-ARC) and a C-terminal Leucine-Rich Repeat (LRR) domain. Conserved domain analysis revealed shared domains in Molly and Newton, except for differences in sequence, organization and number of LRR repeat in Newton. Also, the presence of a transposable element towards the C terminal of h13 was indicative of interallelic recombination, recent tandem duplications and gene conversions in the CNL rich region near H13 locus. Comparative analysis of candidate genes in the H13 region indicated that gene duplications in CNL encoding genes during divergence of wheat and barley led to clustering and diversity. This diversity among CNL genes may have a role in defining differences in the recognition specificities of NB-LRR encoding genes. Allele mining for the H13 gene in the core collection of Ae. tauschii and hexaploid wheat cultivars identified different functional haplotypes. Screening of these haplotypes using different HF biotypes would help in the identification of the new sources of resistance to control evolving biotypes of HF. Cloning of H13 will provide perfect markers to breeders for HF resistance breeding programs. It will also provide an opportunity to study R-Avr interactions in the hitherto unexplored field of insect-host interaction.
