Spelling suggestions: "subject:"hypersensitivity response (HR)""
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Effect of harpinpss on lignin biosynthesis in tobacco leaves during hypersensitive responseJan, Jen-Ting 20 June 2003 (has links)
Harpinpss, a pathogenic protein, encoded by hrpZ in the hrp gene cluster from Pswudomonas syringae pv. syringae, can induce the hypersensitive response in tobacco (Nicotiana tabacum L. cv. Xanthi). The lesion area on the tobacco leaves was visible 6 h after inoculation with harpin, and was evident 12 h after inoculation. The lignin content in harpin-treated tobacco leaves was about 2.5-fold as compared with the controls 24 h after inoculation.
There were six isozymes of POD (pI 9.5, pI 8.7, pI 5.3, pI 4.4, pI 3.7, and pI 3.5) and seven isozymes of laccase (pI 9.4, pI 8.6, pI 7.8, pI 5.4, pI 4.5, pI 3.8, and pI 3.6) identified by isoelectric point in extracts of harpin-inoculated tobacco leaves. POD isozymes (pI 4.4, pI 5.3 and pI 8.7) and laccase isozyme (pI 7.8) only appeared in harpin-inoculated tissues. The increased POD isozymes (pI 4.4, pI 8.7, pI 9.5) are correlated with the rise of transcripts of these enzymes confirmed by the method of reverse transcriptase-polymerase chain reaction (RT-PCR).
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SEQUENCING-BASED GENE DISCOVERY AND GENE REGULATORY VARIATION EXPLORATION IN PEDIGREED POPULATIONSRobert Ebow McEwan (13175205) 29 July 2022 (has links)
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<p>Forward genetics discovery of the molecular basis of induced mutants has fundamentally contributed to our understanding of basic biological processes such as metabolism, cell dynamics, growth, and development. Advances in Next-Generation Sequencing (NGS) technologies enabled rapid genome sequencing but also come with limitations such as sequencing errors, dependence on reference genome accuracy, and alignment errors. By incorporating pedigree information to help correct for some errors I optimized variant calling and filtering strategies to respond to experimental design. This led to the identification of multiple causative alleles, the detection of pedigree errors, and an ability to explore the mutational spectrum of multiple mutagens in Arabidopsis. Similar to the problems in forward genetic discovery of mutant alleles, variation in genomes complicates the analysis of gene expression affected by natural variation. The plant hypersensitive response (HR) is a highly localized and rapid form of programmed cell death that plants use to contain biotrophic pathogens. Substantial natural variation exists in the mechanisms that trigger and control HR, yet a complete understanding of the molecular mechanisms modulating HR is lacking. I explored the gene expression consequences of the plant HR in maize using a semi-dominant mutant encoding a constitutively active HR-inducing Nucleotide Binding Site Leucine Rich Repeat protein, <em>Rp1-D21,</em> derived from the receptor responsible for perceiving certain strains of the common rust <em>Puccinia sorghi</em>. Differentially expressed genes (DEG) in response to <em>Rp1-D21</em> were identified in different genetic backgrounds and hybrids that exhibit divergent enhancing (NC350) or suppressing (H95, B73) effects on the visual manifestations of HR. To enable this analysis, I created anonymized reference genomes for each comparison, so that the reference genome induced less bias in the mapping steps. Comprehensive identification of DEG corroborated the visual phenotypes and provided the identities of genes influential in plant hypersensitive response for further studies. The locations of expression quantitative trait loci (eQTL) that determined the differential response of NC350 and B73 were identified using 198 F1 families generated by crossing B73 x NC350 RIL population and <em>Rp1-D21</em>/+ in H95. This identified 3514 eQTL controlling the variability in differential expression between mutant versus wild-type. <em>Trans-</em>eQTL were dramatically arranged in the genome and identified 17 hotspots with more than 200 genes influenced by each locus. A single locus significantly affected expression variation in 5700 genes, 5396 (94.7%) of which were DGE. An allele specific expression analysis of NC350 x H95 and B73 x H95 F1 hybrids with and without <em>Rp1-D21</em> identified <em>cis-</em>eQTL and ASE at a subset of these genes. Bias in the confirmation of eQTL by ASE was still present despite the anonymized reference genomes indicating that additional efforts to improve signal processing in these experiments is needed.</p>
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Transformation Of Tobacco (nicotiana Tabaccum) With Antimicrobial Pflp Gene And Analysis Of Transgenic PlantsTuncer, Taner 01 January 2006 (has links) (PDF)
The objective of this study was to transform sweet pepper ferredoxin-like protein (PFLP) gene, which has antimicrobial properties, to tobacco and investigate the disease resistance abilities of transgenic tobacco. This protein interacts with another protein, harpin that is produced by the bacteria which is invading the plant tissues, and stimulates hypersensitivity response in plants, thus the spreading of disease is limited.
Gene transfer was achieved to tobacco by Agrobacterium- mediated method and with indirect organogenesis / the explants were grown on selective media and then transferred to jars and pots respectively. Molecular and genetic analyses such as PCR, RT-PCR, Sequence Analysis and Northern Blot, were performed with plants which their seeds survived and grew on selective medium and also gave positive reactions for GUS histochemical assay.
Finally, with putative transgenic plants, some hypersensitive response assays were carried out with Pseudomonas syringae and it was observed that the recovered plants showed hypersensitive response (HR) in the preliminary tests. These results indicated that putative transgenic tobacco plants which carry pflp transgene, can be used in disease resistance studies.
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