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Environmental biosafety of genetically engineered crops: Flax (Linum usitatissimum L.) as a model systemJhala, Amitkumar 06 1900 (has links)
Flax (Linum usitatissimum L.) is considered as a model plant species for multipurpose uses with whole plant utilization for several purposes including industril, food, animal feed, fiber, nutraceutical, pharmaceutical, and bioproduct markets. Therefore, flax is in the process of genetic engineering to meet the market requirements. Prior to commercial release of genetically engineered (GE) flax, a risk assessment was conducted to determine intra- and inter-specific pollen-mediated gene flow and for quantifing and mitigating the adventitious presence (AP) of volunteer flax in canola (Brassica napus L.). The results of pollen-mediated gene flow study (crop-to-crop) suggest that about 1.85% outcrossing would occur in adjunct area, when two flax cultivars were grown in close proximity of 0.1 m apart. Some rare gene flow events were recorded maximum up to 35 m distance from the pollen source but at a very low frequency.
The genus Linum has several wild and weedy species, distributed in many parts of the world. A meta-analysis was conducted to determine the potential for gene introgression from GE flax to wild relatives, the occurrence, the phylogeny of flax wild relatives and reported interspecific hybridization. The results demonstrated that cultivated flax has ability to hybridize and form viable F1 plants with at least nine species of Linum; however, none of these species have been reported to occur in Canada. Hybridization of flax with many other wild relatives has either not been studied or reported. However, based on the evidence of reported work, gene flow from GE flax to wild or weedy relatives may occur elsewhere depending on species distribution, sympatry, concurrent flowering, ploidy level and sexual compatibility.
The results of the experiments to mitigate the adventitious presence of flax volunteers in canola suggest that combinations of pre-plant followed by post-emergence herbicides were most effective for reducing volunteer flax density and AP in glufosinate-resistant canola. Post-emergence application of imazamox+imazethapyr, however, was not effective for controlling volunteer flax in imidazolinone-resistant canola. Best management practices were developed to mitigate transgene movement from GE flax to ensure co-existance of GE, conventional and organic flax without market harm. / Plant Science
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Environmental biosafety of genetically engineered crops: Flax (Linum usitatissimum L.) as a model systemJhala, Amitkumar Unknown Date
No description available.
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Volunteer spring triticale (× Triticosecale Wittmack) seed persistence and controlRaatz, Lisa L Unknown Date
No description available.
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Synthesis Of Colloidal Silver Particles With Different Sizes By Seeding Approach For Surface Enhanced Raman Scattering (sers) StudiesSanci, Rukiye 01 October 2009 (has links) (PDF)
In this study, silver nanorods and nanospheroids were prepared both in aqueous solution and on the surface of glass slides through seed-mediated growth approach at room temperature and used as a surface enhanced Raman scattering (SERS) substrate. The synthesis of metallic nanorods was started with the production of silver nanospheres as seed utilizing sodium borohydride and trisodium citrate as reducing and capping agents, respectively. These seeds were then added to a growth solution containing additional silver salt, ascorbic acid and cetyltrimethylammonium bromide (CTAB.)
Nanorod preparation conditions were first optimized in solution phase. The plasmon absorption of the formed nanocrystals was monitored by UV-Visible spectrometry. The largest red shift in the longitudinal plasmon resonance absorption of silver nanostructures was tried to be achieved in order to realize the highest electromagnetic enhancement in Raman measurements. The images of the formed nanorods were recorded using field emission scanning electron microscopy (FE-SEM).
The optimized colloidal growth conditions were adopted for the growth of nanorods on the surface of the glass substrate. Sol-gel coated glass slides were used in order to increase the porosity on the surface for an effective seeding process. We reported the development of a novel SERS substrate prepared by growing silver nanorods directly on the surface of glass surface without using any linker molecule.
The SERS performances of the nanorod growth surfaces were evaluated with crystal violet (CV), brilliant cresyl blue (BCB) and benzoic acid (BA). Some modifications such as the increase in the AgNO3 concentration in the growth solution and the addition of hydrocarbons to the growth solution were investigated for the enhancement of the SERS signal. The intense spectra obtained for the model compounds demonstrated the efficiency of the prepared substrate for the SERS enhancement and its potential as a SERS detection probe for chemical and biological analysis.
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Metallic nanostructure synthesis using DNA origami moldsHelmi, Seham 14 September 2018 (has links)
The past decade has witnessed a breakthrough in the field of structural DNA nanotechnology, which utilizes DNA molecules as a construction material rather than as simple carriers of the genetic information. With the superior programmability of DNA, sub-nanometer precision in the self-assembly of various complex two- and three-dimensional nanostructures is achievable. It also allows a site-specific placement of different objects and functional groups onto the formed structures. This has enabled the assembly of highly sophisticated nanostructures for various applications. While the field of structural DNA nanotechnology has been astonishingly advancing, many nanoelectronics-relevant structures are made of inorganic materials, and DNA-based nanostructures have shown rather low conductivity. This has limited the use of DNA structures in nanoelectronics and reflected the need for a similar programmable route for the inorganic nanofabrication. A conceivable solution would use DNA nanostructures in a way that will precisely transfer the structural information of the DNA shapes into fabricated metallic nanostructures. One way to do that is to use the DNA nanostructures as templates for external material deposition onto the DNA surface. While this strategy has been effective in proving the concept of DNA-shape transfer, metallic nanostructures fabricated this way have shown some drawbacks, such as showing rough surface morphologies and lacking the required homogeneity for the fabricated metallic structures. An alternative strategy would be to design DNA mold structures that can dictate the shape of metal that is “cast” inside such a DNA container. The main topic of my thesis concerns the second strategy. To discuss this in detail, the structure and some of the important properties of DNA are introduced in section 1.1. In section 1.2 the main milestones in the development of the DNA-nontechnology field are discussed and section 1.3 focuses on previous fabrication approaches of DNA-based metallic nanostructures.
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