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An improved tissue culture and transformation system for switchgrass (Panicum virgatum L.)Burris, Jason Neil 01 December 2010 (has links)
Switchgrass (Panicum virgatum), a summer perennial grass native to North America, is currently being explored for its potential use in the production of biofuels. With these interests, genetic manipulation of switchgrass to produce plants that are easier to digest, have an increased resistance to diseases and stresses, and maintain viability longer in the field are required. Therefore, it was necessary to develop a reliable and efficient tissue culture system for the transformation of switchgrass. Current switchgrass tissue culture requires months for regeneration of transformants with relatively poor transformation efficiencies and are limited to derivatives of a single variety, Alamo. We have developed a tissue culture system, utilizing a novel media, LP9, which has demonstrated decreased time to the production of whole transgenic plants and with an increased efficiency. LP9 is not an MSO-based tissue culture system. It is comprised of both N6 macroelements and B5 microelements with the auxin, 2,4-D and does not include any cytokinin. After just 1 month on LP9 media, callus can be selected and used for Agrobacterium tumefaciens-mediated transformation or particle bombardment, and plants can be regenerated within 3 weeks of callus initiation. Our system is unique to previously explored MSO-based systems in that it is optimized for the production of type II callus, which has been shown to produce higher transformation efficiencies in other monocots. We have increased the transformation efficiency of switchgrass from to up to 4% to 34% efficiency by selecting for this type of callus.
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Changes in abscisic acid concentration during zygotic embryogenisis in loblolly pine (Pinus taeda) as determined by indirect ELISAKapik, Rene Howard 01 January 1994 (has links)
see pdf
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Identification, isolation, expression analysis and molecular characterization of nine genes key to late embryogenesis in Loblolly pineJones, Brande 22 January 2011 (has links)
A basic understanding of the molecular events occurring during zygotic embryogenesis is required to fully understand how and why only a very small percentage of somatic embryos develop past the late embryogeny phase of embryogenesis. In this work, we have identified genes that have been demonstrated to be required for late embryonic development in the model plant system Arabidopsis thaliana.
These genes were subsequently isolated and cloned from Loblolly pine embryos. These isolated clones were sequenced and analyzed to reveal significant homology to the known Arabidopsis ABA responsive genes ABI3, ABI4, and ABI5. Expression analyses of all three genes were completed, and compared to reported data of ABA accumulation, as well as, expression of other ABA responsive genes during the same stages of embryogenesis.
Six putative root development genes were isolated and cloned from Loblolly pine embryos. These isolated clones were sequenced and analyzed to reveal significant homology to the known Arabidopsis root development genes WOODENLEG, SHORT ROOT, SCARECROW, HOBBIT, BODENLOS, and MONOPTEROS. Full-length cDNAs were isolated and cloned for WOODENLEG, SHORT ROOT, SCARECROW and BODENLOS. Expression analyses of all six genes were completed throughout mid to late embryogenesis in Loblolly pine.
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Selenium redox cycling isolation and characterization of a stimulatory component from tissue of loblolly pine for multiplication of somatic embryos; development of an assay to measure l-phenylalanine concentration in blood plasma /DeSilva, Veronica January 2007 (has links)
Thesis (Ph.D)--Chemistry and Biochemistry, Georgia Institute of Technology, 2007. / Committee Chair: Sheldon May; Committee Members: Nicholas Hud, Stanley Pollock, James Powers, and Gerald Pullman. Part of the SMARTech Electronic Thesis and Dissertation Collection.
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Influence of micropropagation through somatic embryogenesis on somaclonal variation in coffee (Coffea arabica) : assessment of variations at the phenotypical, cytological, genetic and epigenetic levelBobadilla Landey, Roberto 09 July 2013 (has links) (PDF)
Influence of micropropagation through somatic embryogenesis on somaclonal variation in coffee (Coffea arabica): assessment of variations at the phenotypical, cytological, genetic and epigenetic level Somaclonal variation (SV) is a major concern in all micropropagation systems. It is described as the phenotypic variation displayed in in vitro-derived regenerants and it is believed to be originated from a large array of genetic and epigenetic mechanisms. Highly productive Coffea arabica hybrids are clonally disseminated in Meso-American region through somatic embryogenesis (SE). The objective of the present work in coffee is to evaluate the trueness-to-type of SE and to understand the mechanisms involved in SV. We assessed the variations in the propagated plants at the phenotypic, cytogenetic, genetic (mutations/AFLP, genetic transposition/S-SAP) and epigenetic (methylation/MSAP) level by using two complementary approaches. First, with 2 hybrids we studied industrial culture conditions expected to be weakly mutagenic thanks to the combined use of short term proliferation period (6 months) and low auxin supply (0-1.4 µM 2,4-D). Two proliferation systems i.e. secondary embryogenesis and embryogenic suspensions were compared, the latter being more productive and economic. AFLP and MSAP molecular analyses on 145 somatic seedlings showed that genetic and epigenetic polymorphisms between mother plants and emblings were extremely low, i.e. ranges of 0-0.003% and 0.07-0.18% respectively, with no significant difference between the proliferation systems. For the two hybrids tested, massive phenotypic observations in nursery and field plots showed very low levels of SV (0.9% from 800,000 plants). Cytological analysis showed abnormal chromosome numbers (41-43, 45) in most of coffee somaclonal variants and normal numbers (44) in phenotypically normal plants. Stressful experimental conditions were also applied by using extended proliferation periods (4, 12 and 27 months) for three independent embryogenic lines established for the Caturra var. in presence of high growth regulator concentrations (4.5 μM 2,4-D, 17.8 μM 6-BA) to understand the mechanisms of culture ageing on SV. The proliferation time strongly affected the SV frequency among the 180 regenerated plants and in a highly similar way with the three embryogenic lines. No variant was found after 4 months proliferation although 30% and 94% phenotypic variants were observed in plants derived from 12 and 27 month-old cultures, respectively. Regardless the culture age and the embryogenic line, no polymorphisms were found in the 124 plants analyzed and very limited methylation changes with MSAP markers (0.049-0.087%). However, similarly to plants derived from industrial conditions, phenotypic variants systematically showed abnormal chromosome numbers and normal plants systematically showed normal numbers. This work showed that SE based on embryogenic suspensions is reliable for true-to-type propagation of selected C. arabica varieties. It also demonstrated the importance of culture age on SV and hence the non random nature of this phenomenon. The genetic and epigenetic alterations are particularly limited during SE. The main change in most of phenotypic variants was aneuploidy showing that mitotic aberrations play a major role in SV in coffee.
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The evaluation of novel anti-inflammatory compounds in cell culture and experimental arthritis and identification of an inhibitor to early-stage loblolly pine somatic embryo growthLucrezi, Jacob 12 January 2015 (has links)
The interactions between the immune and nervous systems play an important role in immune and inflammatory conditions. Substance P (SP), the unidecapeptide RPKPQQFFGLM-NH2, is known to upregulate the production of pro-inflammatory cytokines such as tumor necrosis factor (TNF)-α. We report here that 5 (Acetylamino) 4 oxo-6-phenyl-2-hexenoic acid methyl ester (AOPHA-Me) and 4 phenyl 3 butenoic acid (PBA), two anti-inflammatory compounds developed in our laboratory, reduce SP stimulated TNF-α expression in RAW 264.7 macrophages. We also show that AOPHA Me and PBA both inhibit SP stimulated phosphorylation of JNK and p38 MAPK. Furthermore, molecular modeling studies indicate that both AOPHA Me and PBA dock at the ATP binding site of apoptosis signal regulating kinase 1 (ASK1) with predicted docking energies of -7.0 kcal/mol and 5.9 kcal/mol, respectively; this binding overlaps with that of staurosporine, a known inhibitor of ASK1. Taken together, these findings support the conclusion that AOPHA Me and PBA inhibition of TNF-α expression in SP-stimulated RAW 264.7 macrophages is a consequence of the inhibition JNK and p38 MAPK phosphorylation. We have previously shown that AOPHA-Me and PBA inhibit the amidative bioactivation of SP, which also would be expected to decrease formation of pro-inflammatory cytokines. It is conceivable that this dual action of inhibiting amidation and MAPK phosphorylation may be of some advantage in enhancing the anti-inflammatory activity of a therapeutic molecule.
We also encapsulated AOPHA-Me separately in polyketal and poly(lactic co glycolic acid) microparticles. The in-vitro release profiles of AOPHA-Me from these particles were characterized. We have also shown that AOPHA-Me, when encapsulated in PCADK microparticles, is an effective treatment for edema induced by adjuvant arthritis in rats.
In separate work, it was determined that myo inositol 1,2,3,4,5,6 hexakisphosphate is an inhibitor to early-stage Loblolly pine somatic embryo growth. In addition, it was determined that muco inositol 1,2,3,4,5,6 hexakisphosphate is not an inhibitor to early-stage Loblolly pine somatic embryo growth. These experiments demonstrate the stereochemical dependence of myo inositol 1,2,3,4,5,6 hexakisphosphates inhibitory activity.
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Induction Of Embryogenic Tissue And Development Of Somatic Embryos In Pinus Brutia Ten.Yildirim, Tolga 01 July 2005 (has links) (PDF)
Conifer species are subjected to major time constraints in tree improvement because of their long regeneration cycle and large sizes. However, integration of developing biotechnologies could significantly reduce this time limitation in tree breeding programs. In this regard, somatic embryogenesis (SE) offers a great potential in commercially important Turkish red pine (Pinus brutia TEN.) for rapid production of larger number of clones as well as capture of greater genetic gains. In this study, seven collections were done to sample precotyledonar zygotic embryos for induction of embryogenic tissue (ET) from 15 clones located in Antalya. Afterwards, abscisic acid, carbohydrates, polyethylene glycol (PEG), and gellan gum were tested to obtain mature somatic embryos in maturation experiments. Analyses of variance showed a significant variation among collection dates (43.1% of total variance) and clones studied (18.8% of total variance) for induction of ETs. Overall initiation frequency of ET in this study was 11.6% with clonal range of 4.7 & / #8211 / 24.1%. Of those tested maturation treatments, 80& / #956 / M ABA, sucrose and maltose at 3 and 6%, 3.75% PEG combined with 1% gellan gum were found to be suitable for maturation of somatic embryos in Turkish red pine. Sixty nine somatic embryos were obtained from Clone 22, which was one of tested clones. Induction frequencies could be further improved by using different basal media and/or manipulating media components, such as plant growth regulators. For proper maturation of somatic embryos, embryogenic lines need to be screened to find suitable lines, which are developmentally responsive to ABA treatment.
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Somatic embryogenesis for micropropagation of coconut (Cocos nucifera L.)Irina Antonova Unknown Date (has links)
Coconut (Cocos nucifera L.) is native to the regions between 20oN and 20oS of the Equator, where it plays a significant socioeconomic role in the local communities. There it is referred to as ’The Tree of Life’, a eulogistic epithet describing its versatile use - more than 100 edible and non-edible products can be produced from it. Therefore the coconut palm is grown in about 90 tropical countries on more than 10 millions ha of land (Hamon et al., 1999). Although coconut has a high local socioeconomic reputation, its production is experiencing many problems and consequently the area planted with this crop is declining. The conventional breeding approach using seed to replant land is very expensive due to the low production of seed for planting, and even when elite germplasm is available it takes decades to multiply up enough planting material for new areas (Adkins et al., 1999). Hence over the past 40 years research has been directed towards developing a new technique for the micropropagation of coconut using somatic embryogenic approach. Throughout this time however one conclusion is repeatedly made – coconut is very recalcitrant to somatic embryogenesis. And although the many obstacles to this are slowly being reduced, in order to successfully micropropagate coconut on a large scale bottlenecks in the protocol still exist, and those include inconsistency of the embryogenic response by explanted tissues, poor somatic embryo maturation and germination, low regeneration rate of the new plantlets and long time required to produce plants (1.5 years) (Samosir et al., 1998). These bottlenecks and other problems were researched in the present study with the aim of trying to speed up the efficiency of coconut somatic embryogenesis process. Hence this thesis had the objectives to identify a starting protocol for coconut somatic embryogenesis; to select an appropriate for aim that explant; to optimize the production of embryogenic callus; to increase the rate of initiating coconut somatic embryos; to improve the maturation of somatic embryos and their germination efficiency; and to optimize the regeneration rate of the new plantlets. In order to identify a starting protocol, preliminary work was conducted, where existing protocols for coconut somatic embryogenesis were compared in their efficiency to induce somatic embryos. The protocol that stood out as the best in producing most embryogenic callus and subsequently embryos, as well as having the least dead (in culture) explants, was that of Nikmatullah (2001). Therefore the latter was chosen to be used as a starting protocol for this study. New sources of explants were investigated during the current work as well, using tissues from different parts of in vitro derived 8 months old coconut plantlets. Those however have shown to be unsuitable for somatic embryogenesis, since only non-embryogenic callus was developed by some of the inoculated tissues. The immature inflorescence explants were superior in producing embryogenic callus and somatic embryos; therefore they were selected as the preferred explant source to use in the next steps of the current study. Optimizing the production of embryogenic callus was the first issue to address during the core work of this project. As a result of that the culture conditions were considerably improved by using vessels with larger headspace-medium ratio (3:1), as well as by selecting younger immature inflorescences and transversely segmenting the top half of the inflorescence spikes into smaller size (1 mm) sections. Further improvement was possible by studying the make up of the callus growth media. Amongst the administered for that purpose substances the applied together polyamines spermine (0.10 µM) and putrescine (7.5 mM) have proven to play a notably positive role in the induction of callus from coconut immature inflorescence explants. Thidiazuron (TDZ, 10 µM) too has shown a potential to improve the efficiency of the initial stage of coconut somatic embryogenesis, but only when applied in conjunction with other cytokinins (eg. BAP and 2iP). Smoke-saturated-water (SSW, 10 %) could only slightly diminish the amount of necrotising cultured explants, and high 2,4-D concentrations could not support the induction of callus from immature coconut inflorescences. Collectively taken, as a result of this current study the production of callus was improved by 300 %. The rate of coconut somatic embryos formation was as well significantly increased (over 300 %), by the simultaneous application of suspension culture step, spermine (0.01 µM), SSW (10 %) and high auxin concentration (500 µM). Nevertheless the presence of TDZ and other cytokinins in the medium, as well as the absence of activated charcoal, were found to be unable to positively influence the somatic embryogenesis process. Despite the considerable improvements made in the efficiency of inducing callus and initiating embryos, the poor maturation and germination (eg. 5 %, Verdeil et. al., 1999) of somatic embryos still remained a bottleneck to the whole somatic embryogenesis procedure. Therefore further work was conducted in that direction and discovered that embryo maturation and germination rate can be elevated to 55 % by administering ancymidol (30 µM) to the somatic embryo maturation medium. This plant retardant has exhibited here three potential modes of action towards the cultured coconut somatic embryos: a) as a promoter of somatic embryo maturation and germination; b) as a preventor of pre-germination death of the somatic embryos; and c) as a preserver of non-germinating somatic embryos, that still can possess the potential to germinate in the future. The work during the next step of the process – regeneration of the new plantlets – has shown that the omission of plant growth regulators from the media was crucial for the development of germinated embryos into new plantlets, where otherwise no plant regeneration occurred at all. The achieved here plantlet regeneration rate in the PGR-free medim was 56 %, which is higher than the previously reported 20 % regeneration rate (Verdeil et al., 1994) for coconut plantlets produced from immature inflorescences explants. As a result of this current work a new method was developed for somatic embryogenesis of coconut from immature inflorescences explants (Fig. 9.2). The overall efficiency of this protocol is over three times higher than that of the starting protocol (Nikmatullah, 2001) selected during the preliminary work. Furthermore, when using this new method the entire duration for regenerating clonal coconut plantlets (up to the stage of first root and shoot emerging) takes up to 8 months, which is the shortest reported time for producing coconut plantlets via somatic embryogenesis (eg. 36 months from inflorescences explants (Verdeil et. al., 1999) and 18 months from sliced zygotic explants (Samosir, 1999, Fig. 9.2), presenting an additional valuable advantage of this newly developed method, from the perspective of the potential to micropropagate coconut on a commercial scale.
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Somatic embryogenesis for micropropagation of coconut (Cocos nucifera L.)Irina Antonova Unknown Date (has links)
Coconut (Cocos nucifera L.) is native to the regions between 20oN and 20oS of the Equator, where it plays a significant socioeconomic role in the local communities. There it is referred to as ’The Tree of Life’, a eulogistic epithet describing its versatile use - more than 100 edible and non-edible products can be produced from it. Therefore the coconut palm is grown in about 90 tropical countries on more than 10 millions ha of land (Hamon et al., 1999). Although coconut has a high local socioeconomic reputation, its production is experiencing many problems and consequently the area planted with this crop is declining. The conventional breeding approach using seed to replant land is very expensive due to the low production of seed for planting, and even when elite germplasm is available it takes decades to multiply up enough planting material for new areas (Adkins et al., 1999). Hence over the past 40 years research has been directed towards developing a new technique for the micropropagation of coconut using somatic embryogenic approach. Throughout this time however one conclusion is repeatedly made – coconut is very recalcitrant to somatic embryogenesis. And although the many obstacles to this are slowly being reduced, in order to successfully micropropagate coconut on a large scale bottlenecks in the protocol still exist, and those include inconsistency of the embryogenic response by explanted tissues, poor somatic embryo maturation and germination, low regeneration rate of the new plantlets and long time required to produce plants (1.5 years) (Samosir et al., 1998). These bottlenecks and other problems were researched in the present study with the aim of trying to speed up the efficiency of coconut somatic embryogenesis process. Hence this thesis had the objectives to identify a starting protocol for coconut somatic embryogenesis; to select an appropriate for aim that explant; to optimize the production of embryogenic callus; to increase the rate of initiating coconut somatic embryos; to improve the maturation of somatic embryos and their germination efficiency; and to optimize the regeneration rate of the new plantlets. In order to identify a starting protocol, preliminary work was conducted, where existing protocols for coconut somatic embryogenesis were compared in their efficiency to induce somatic embryos. The protocol that stood out as the best in producing most embryogenic callus and subsequently embryos, as well as having the least dead (in culture) explants, was that of Nikmatullah (2001). Therefore the latter was chosen to be used as a starting protocol for this study. New sources of explants were investigated during the current work as well, using tissues from different parts of in vitro derived 8 months old coconut plantlets. Those however have shown to be unsuitable for somatic embryogenesis, since only non-embryogenic callus was developed by some of the inoculated tissues. The immature inflorescence explants were superior in producing embryogenic callus and somatic embryos; therefore they were selected as the preferred explant source to use in the next steps of the current study. Optimizing the production of embryogenic callus was the first issue to address during the core work of this project. As a result of that the culture conditions were considerably improved by using vessels with larger headspace-medium ratio (3:1), as well as by selecting younger immature inflorescences and transversely segmenting the top half of the inflorescence spikes into smaller size (1 mm) sections. Further improvement was possible by studying the make up of the callus growth media. Amongst the administered for that purpose substances the applied together polyamines spermine (0.10 µM) and putrescine (7.5 mM) have proven to play a notably positive role in the induction of callus from coconut immature inflorescence explants. Thidiazuron (TDZ, 10 µM) too has shown a potential to improve the efficiency of the initial stage of coconut somatic embryogenesis, but only when applied in conjunction with other cytokinins (eg. BAP and 2iP). Smoke-saturated-water (SSW, 10 %) could only slightly diminish the amount of necrotising cultured explants, and high 2,4-D concentrations could not support the induction of callus from immature coconut inflorescences. Collectively taken, as a result of this current study the production of callus was improved by 300 %. The rate of coconut somatic embryos formation was as well significantly increased (over 300 %), by the simultaneous application of suspension culture step, spermine (0.01 µM), SSW (10 %) and high auxin concentration (500 µM). Nevertheless the presence of TDZ and other cytokinins in the medium, as well as the absence of activated charcoal, were found to be unable to positively influence the somatic embryogenesis process. Despite the considerable improvements made in the efficiency of inducing callus and initiating embryos, the poor maturation and germination (eg. 5 %, Verdeil et. al., 1999) of somatic embryos still remained a bottleneck to the whole somatic embryogenesis procedure. Therefore further work was conducted in that direction and discovered that embryo maturation and germination rate can be elevated to 55 % by administering ancymidol (30 µM) to the somatic embryo maturation medium. This plant retardant has exhibited here three potential modes of action towards the cultured coconut somatic embryos: a) as a promoter of somatic embryo maturation and germination; b) as a preventor of pre-germination death of the somatic embryos; and c) as a preserver of non-germinating somatic embryos, that still can possess the potential to germinate in the future. The work during the next step of the process – regeneration of the new plantlets – has shown that the omission of plant growth regulators from the media was crucial for the development of germinated embryos into new plantlets, where otherwise no plant regeneration occurred at all. The achieved here plantlet regeneration rate in the PGR-free medim was 56 %, which is higher than the previously reported 20 % regeneration rate (Verdeil et al., 1994) for coconut plantlets produced from immature inflorescences explants. As a result of this current work a new method was developed for somatic embryogenesis of coconut from immature inflorescences explants (Fig. 9.2). The overall efficiency of this protocol is over three times higher than that of the starting protocol (Nikmatullah, 2001) selected during the preliminary work. Furthermore, when using this new method the entire duration for regenerating clonal coconut plantlets (up to the stage of first root and shoot emerging) takes up to 8 months, which is the shortest reported time for producing coconut plantlets via somatic embryogenesis (eg. 36 months from inflorescences explants (Verdeil et. al., 1999) and 18 months from sliced zygotic explants (Samosir, 1999, Fig. 9.2), presenting an additional valuable advantage of this newly developed method, from the perspective of the potential to micropropagate coconut on a commercial scale.
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Possibilities and limitations of vegetative propagation of Norway spruce /Högberg, Karl-Anders, January 2003 (has links) (PDF)
Diss. (sammanfattning) Uppsala : Sveriges lantbruksuniv., 2003. / Härtill 5 uppsatser.
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