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Publication Agrogentechnik und Biotechpflanzenproduktion : Entwicklung, Stand und Zukunftspotential(2016) Kuhn, EkkehardPflanzen sind die Nahrungsgrundlage für Mensch und Tier und werden es bleiben. Was unverfälschte Natur zu bieten hat, konnte nie befriedigen, doch war ein langer, weit in die vorchristliche Zeit zurückreichender Weg zurückzulegen, um von essbaren Wildpflanzen und einfachen Landrassen zu den heutigen Hochleistungssorten bei Getreide, Soja, Raps und anderen zu gelangen. Auch heute ist das Potential der klassischen Pflanzenzüchtung noch keineswegs erschöpft. Genomsequenzierung, auf molekulare Marker gestützte Identifizierung züchterisch wertvoller Merkmale und andere früher unbekannte Methoden können Züchtungsprogramme vereinfachen und die Sortenentwicklung beschleunigen. Es bleibt aber eine prinzipielle Schranke, welche die konventionelle Pflanzenzüchtung von wenigen Ausnahmen abgesehen nicht überwinden kann: Sie kann die Artgrenzen nicht überspringen und bleibt auf die Nutzung des arteigenen Genvorrats angewiesen. Das änderte sich um 1985, als es erstmals gelang, bakterielle Gene in dafür gut geeignete Modellpflanzen wie den Tabak einzuführen und zwar so, dass sie „exprimiert“ wurden, d. h. ein funktionelles Proteinprodukt lieferten und sich stabil an die sexuellen Nachkommen dieser ersten transgenen Pflanzen vererbten. Zehn Jahre später begann der kommerzielle Anbau von herbizidresistentem und wenig später insektenresistentem Mais in den USA und Kanada. Es war die Geburtsstunde der Agrogentechnik. Heute werden transgene Kulturpflanzen dort, wo ihre prinzipiellen Gegner weniger Einfluss haben als hierzulande, auf mehr als 180 Millionen ha Ackerland angebaut. Mehr als eine Milliarde Menschen und ein Mehrfaches an Nutztieren haben sich bis heute von „Genpflanzen“ und daraus hergestellten Nahrungs- und Futtermitteln ernährt. Der Grund für den Erfolg der neuen Technik liegt darin, dass sie messbare wirtschaftliche und ökologische Vorzüge hat, die sich in niedrigeren Umweltbelastungen, höheren Erträgen und deutlichen Einkommensverbesserungen der landwirtschaftlichen Betriebe niederschlagen. Während man die Vorteile der Agrogentechnik heute leicht erkennen kann, sind die ihr zugeschriebenen Risiken spekulativ geblieben. Es gibt weder zwingende theoretische Argumente noch praktische Erfahrungen, die dazu berechtigen, der gentechnischen Pflanzenzüchtung ein gegenüber traditionellen Verfahren größeres Gefahrenpotential zuzuschreiben. Ihre realisierbaren Anwendungen gehen über den gegenwärtig noch dominierenden Anbau herbizid- und insektenresistenter Ackerpflanzen weit hinaus. Sie umfassen Nahrungspflanzen mit erhöhter Krankheitsresistenz, verbesserter Trockentoleranz, besserer Verträglichkeit aus ihnen hergestellter Lebensmittel, ausgeglichenem Gehalt an Aminosäuren, Vitaminen und Spurenelementen ebenso wie Industriepflanzen zur Produktion von Grund- und Wirkstoffen für die Chemie- und Pharmaindustrie. An diesen Entwicklungen arbeiten öffentliche und private Forschungseinrichtungen überall in der Welt. Der Mangel an nutzbarem Ackerland, Trinkwasser und sich abzeichnende Folgen des Klimawandels für die Landwirtschaft erzeugen einen wachsenden Druck zur möglichst wirkungsvollen Nutzung aller verfügbaren Ressourcen. Zwar kann die Agrogentechnik das Welternährungsproblem ebensowenig dauerhaft lösen wie irgendeine andere Technik, solange das exponentielle Wachstum der Erdbevölkerung nicht zum Stillstand kommt. Sie vermag aber die Folgen der Übervölkerung abzumildern; denn sie leistet einen wesentlichen Beitrag zur Verbesserung der Grundversorgung und zu einer effizienteren, die Naturvorräte schonenden Landwirtschaft. Die Verdrängung der konventionellen Sorten durch transgene wird deshalb weitergehen. Transgene Ackerpflanzen der ersten Generation, die überwiegend nur ein transgenes Merkmal tragen, werden gegenwärtig rasch durch modernere Stapelsorten ersetzt, die zwei oder mehrere Transgene exprimieren. Sie sind oft herbizidtolerant und gleichzeitig gegen alle wichtigen Schädlinge resistent, die in den jeweiligen Anbaugebieten vorkommen. Gleichzeitig kommen immer mehr Sorten auf den Markt, die nicht nur für die Produzenten Vorteile haben sondern auch ernährungsphysiologisch wertvoller sind als ihre konventionellen Vorläufer. Am Ende dieser Entwicklung werden die konventionellen Sorten auf dem Agrarweltmarkt kaum noch eine Rolle spielen. Dieses Buch behandelt Geschichte, Methoden, Entwicklungsstand und Zukunftspotential der Agrogentechnik, beschreibt typische Vertreter dieses Kulturpflanzentyps und gibt anhand ausgewählter noch im Versuchsstadium stehender Prototypen einen Ausblick auf die kommende Entwicklung und ihre absehbaren Auswirkungen auf die Tier- und Pflanzenproduktion.Publication Effects of elevated atmospheric CO2 concentrations on insects and pathogens of spring wheat (Triticum aestivum L. cv. Triso) and oilseed rape(Brassica napus cv. Campino)(2012) Oehme, Viktoriya; Fangmeier, AndreasIt is suggested that plants, herbivore insects and pathogens will be affected by rising atmospheric CO2. The working hypothesis of this study was that elevated CO2 will affect plant composition and will thus exert influence on plant-insect interactions by changing the nutritive value for insects feeding on phloem sap. To test this hypothesis, experiments were carried out on wheat and oilseed rape in two different systems: controlled environment chambers (climate chamber system) and an open field exposure system with natural climatic and soil conditions (Mini FACE system). The abundance of detrimental insects from different feeding guilds and plant damage by parasitic organisms were examined in a Mini FACE system, while the consequences of elevated CO2 on aphid performance and potential correlations to phloem sap composition of host plants were observed in controlled environment chambers. The concentrations of amino acids and carbohydrates in the phloem of host plants were analysed by high?performance liquid chromatography (HPLC), using a fluorescence detector for amino acids and the evaporative light scattering detector for carbohydrates. In a Mini-FACE system, phenological development of spring wheat and OSR was not significantly changed due to CO2 enrichment. However, elevated CO2 induced changes in plant chemistry (increased carbon:nitrogen ratio and defensive compounds), which resulted in changes in population densities of some pest species. In order to monitor alterations in insect population density, two different methods were applied: direct counts (method 1) and using of yellow sticky traps (method 2). These methods showed both increases and decreases of insect numbers due to elevated CO2, depending on species and on the period of observation. Concerning plant pathogens, leaves of spring wheat were only slightly and not significantly damaged by Erysiphe graminis, Puccinia striiformis, Puccinia recondita and Septoria tritici during the 2006/2008 years in all treatments. Also the OSR was not significantly damaged by Peronospora parasitica. The frequency and severity of disease infestation on spring wheat and OSR was not significantly impacted by elevated CO2. In controlled-environment chambers, the phenology, above ground biomass and RGR of OSR were not significantly impacted due to elevated CO2. And although the phenology of spring wheat was not influenced by raised CO2, significant increases were observed for plant above ground biomass and RGR. The aphid presence significantly reduced the aboveground biomass and RGR of spring wheat, while no effects due to aphids were observed in OSR. High-CO2 treatment differently impacted the performance of aphids. Slight and non-significant increases due to elevated atmospheric CO2 conditions were observed for the aphid relative developmental stages and intrinsic rates of increase, while the weight and RGR were significantly increased for Rhopalosiphum padi and decreased for Myzus persicae. In order to clear CO2-impacts on the insect performance, phloem sap from host plants was analysed for the composition and concentration of amino acids and carbohydrates. In summary, although the phenological development of spring wheat and OSR was not affected due to elevated CO2, significant changes were found for the concentration of carbohydrates in the phloem sap of spring wheat and individual amino acids in both host plants. These alterations in plant chemistry affected the performance and abundance of herbivore insects.Publication Der Einfluss von Ölgehalt und Fettsäuremuster auf die Lagerfähigkeit von Saatgut(2007) Ghiasvand Ghiasi, Kambiz; Kruse, MichaelSeed storage with the objective of maintaining the quality for the later sowing is a constant challenge, not only in gene banks but also in agriculture, forestry and horticulture. In 1980 ELLIS and ROBERTS established ?The improved seed viability equation? for the prediction of the storability of seeds. With this equation the loss-of-germination-curve can be computed as a function of the initial seed germination, the storage temperature and the seed moisture content for each species. However, with oil-rich seeds the equation very often misses its aim. With this seeds, the variety and lot specific oil content considerably determines water activity and aging rate. Therefore the objective of the present work was to describe the influence of oil content on the aging behavior of seeds of the oil crops during storage quantitatively, to integrate this influence in the most reasonable way into the viability equation and to improve accuracy of its prediction. The investigation was carried out with storage experiments under controlled conditions in the laboratory at higher temperatures and running times between a few days and six months. First it was examined, whether the usually determined oil content of the entire seed is an informative parameter for water activity in the embryo axis. Experiments with sunflowers with an oil content between 28 and 48 % showed that oil-rich seeds need an about 1 % higher seed moisture content than seeds with lower oil content to have the same water activity in the embryonic axis. The storage of these seeds as well as the seeds of rape with oil contents between 39 and 50 % and flax with oil contents between 36 and 43 % showed that the loss of germination is more consistent with uniform water activity than with uniform seed moisture content. This has not been taken into account in the previous viability equation, so that its prediction contains systematic errors. Therefore extensive storage experiments were carried out with altogether 28 seed lots of rape, sunflower, flax and corn with different moisture contents and a uniform temperature of 45°C. Only for few of the stored lots the prediction of the seed viability equation was found to be correct. To include the oil content into the seed viability equation eight different suggestions were compiled. These were applied in three nonlinear regression models with different restrictions to the results of the storage experiments. The first model permitted the species specific determination of the weighing factors (constants) for the seed viability equation. The second model only allowed to determine the weighing factors for the absolute term and the seed moisture content specifically. Oil content was provided however with a species-nonspecific weighing factor. In the third model all weighing factors were species-nonspecific determined. All eight suggestions achieved better estimations for the aging rate in the species-specific models than the previous viability equation. Where this could be examined statistically, the improvements were significant. The same was found for the models with species-nonspecific weighting factors for the oil content. However, not all suggestions led to a converging result of the regression analysis. All examined species-nonspecific models did not improve the adjustment compared to the previous viability equation. The suggestions were then validated with a new and independent dataset with a storage temperature of seeds of 32°C. It was shown that the change of the temperature reduced the accuracy of the estimations of the nonlinear regression models. The new suggestions nevertheless corresponded better to the observed results than the previous viability equation. Based on these results a suggestion was then selected for the extension of the viability equation by ELLIS and ROBERT, which does not introduce a new weighing factor to the equation as the weighing factor might potentially contribute to a decrease of the precision of a prediction due to its standard error. Finally it was examined whether the fatty acid composition before storage in addition to the oil content affects the aging rate and whether the change of the fatty acid composition is directly connected to the loss of germination during storage. Only with rape, significant relations between the proportion of the fatty acid 14:0, 18:0, 20:0, 22:0 and the aging rate of the seed lots were determined. A uniform change of the fatty acid composition of all examined species could not be observed. Therefore this characteristic could not contribute to the further improvement of the prediction accuracy of the seed viability equation. To summarize, a suggestion to include the oil content into the viability equation was designed that clearly improves the accuracy of the prediction of the viability equation for oil-rich seeds and that contributes to a more appropriate and efficient storage of seeds.Publication Genotypische Variation der Überdauerungsneigung von transgenem und konventionell gezüchtetem Raps und Möglichkeiten der Beeinflussung durch Bodenbearbeitung als Beitrag zur Sicherheitsforschung bei transgenen Kulturpflanzen(2004) Gruber, Sabine; Claupein, WilhelmHigh losses during harvesting of oilseed rape in combination with secondary dormancy of the seeds can result in a large soil seed bank which may persist for several years. Volunteers emerging from this seed bank cannot be controlled completely, particularly when they develop in another rapeseed population. In addition to well known agricultural problems, the risk of temporal and spatial gene dispersal by persistent seeds and volunteers gets more significant. With regard to genetically modified (GM) cultivars, seed dormancy and persistence of oilseed rape volunteers have to be reconsidered. The aim of the current study was to investigate the chances for a reduction of seed persistence and gene dispersal by growing specific genotypes and by the implementation of appropriate tillage operations. Four publications describe and discuss experiments in the laboratory and the field on the aspects ?genotype? and ?soil tillage?. One central point was the characterisation of the genotypic variation of secondary dormancy and seed persistence in GM (herbicide tolerant) and conventionally bred oilseed rape. A gradual approach towards field conditions was performed by three experiments. The first experiment examined potential seed persistence by artificial induction of secondary dormancy in the laboratory. The second experiment was a burial of seeds in the soil for six months on a field. The third experiment examined persistence of seeds actually lost during harvest and exposed afterwards to different tillage operations in a field experiment. All three experiments showed a high genotypic variability in seed dormancy and persistence. In the laboratory the level of secondary dormancy of conventional cultivars was a total of 3?76% and of the GM cultivars 1?31%. The number of persistent seeds in the burial experiment was 7?90% in the conventional and 12?79% in the GM assortment. Seeds from the seed rain of the four conventionally bred cultivars in the field experiment persisted in the soil from 0?11% over six months. A significant, positive correlation was found between the laboratory results for cultivars from two crop years as well as between the results from laboratory and burial experiments. This is an indication for a genetic background of seed dormancy and persistence of oilseed rape. It has been demonstrated that a laboratory method for induction of secondary dormancy can describe differences of seed persistence in the field. This result gives a chance for screening new cultivars in the laboratory to identify desired, low persistent genotypes. The other focus of the study was the effect of various tillage treatments on seed persistence and seedling recruitment in the field. Four differently intensive tillage operations incorporated the seeds of two near-isogenic cultivars at different times and soil depths, or left the soil untilled. Winter wheat was sown as following crop in all treatments whereby no weed control was performed. The highest number of seeds generally entered the soil seed bank when seeds were incorporated into the soil by stubble tillage immediately. After six months 1?14% of the initial seed input was found again in the soil in these treatments, and in one isolated case about 28%. Delaying the stubble breaking, the soil seed bank was 0?3%. Leaving the seeds undisturbed on the soil surface until direct drilling resulted in a soil seed bank of 0?17%. Therefore, the first tillage operation after harvest of oilseed rape should be performed with some time delay to avoid large soil seed banks. Soil inversion by a mouldboard plough shifted the majority of seeds into deep soil horizons from where a successful germination was restricted. In contrast, primary tillage by a rigid tine cultivator or zero tillage mainly distributed the seeds within the upper soil layer. Thus the number of flowering volunteers in the first spring was highest in these treatments, with a maximum of one volunteer m-2. Gene dispersal from oilseed rape volunteers to other rape crops and feral relatives was possible because their flowering periods overlapped. The volunteers were able to produce viable seeds, despite high levels of damage by pests and diseases. Overall, a high genotypic variability was found for seed persistence of oilseed rape. Tillage operations, particularly the time of stubble tillage, can also influence seed persistence and the occurrence of volunteers. Combined with a thorough knowledge of the processes involved, the selection of low persistent genotypes and adequate tillage operations offer chances to limit or even to avoid undesired gene dispersal from oilseed rape volunteers, and to make gene dispersal a predictable factor.Publication Impacts of temperature increase and change in precipitation pattern on ecophysiology, biomass allocation and yield quality of selected crops(2023) Drebenstedt, Ireen; Högy, PetraClimate change poses a challenge for the production of crops in the twenty-first century due to alterations in environmental conditions. In Central Europe, temperature will be increased and precipitation pattern will be altered, thereby influencing soil moisture content, physiological plant processes and crop development in agricultural areas, with impacts on crop yield and the chemical composition of seeds. Warming and drought often occur simultaneously. The combination of multiple abiotic stresses can be synergistic, leading to additive negative effects on crop productivity. To date, little information is available from multi-factor experiments analyzing interactive effects of warming and reduced precipitation in an arable field. In addition, one major issue of studying climate change effects on crop development in the long-term is that weather conditions can vary strongly between years, e.g., with hot and dry summers in comparison to cool and wet ones, which directly affects soil moisture content and indirectly affects crop development. Thus, considering yearly weather conditions seems to be important for the analyses of climate change effects on aboveground biomass and harvestable yield of crops. The aim of the present work was to identify single and combined effects of soil warming (+2.5 °C), reduced summer precipitation amount (-25%), and precipitation frequency (-50%) on crop development, ecophysiology, aboveground biomass and yield as well as on yield quality of wheat, barley, and oilseed rape grown in the Hohenheim Climate Change (HoCC) field experiment. This thesis presents novel results from the HoCC experiment in the long-term perspective. Thus, aboveground biomass and yield data (2009-2018) of the three crops were analyzed with regard to their inter-annual variability, including annual fluctuations in weather conditions.This thesis consists of three publications. In the first and second publication a field experiment within the scope of the HoCC experiment was conducted with spring barley (Hordeum vulgare L. cv. RGT Planet) and winter oilseed rape (Brassica napus L. cv. Mercedes) in 2016 and 2017. The objective was to investigate the impacts of soil warming, altered precipitation pattern and their interactions on biomass production and crop yield. In addition, it was examined, whether the simulated climate changes affecting barley photosynthesis and the seed quality compounds of oilseed rape. In the third publication, long-term plant productivity data of wheat, barley, and oilseed rape were evaluated, including aboveground biomass and yield data from the field experiment in 2018 with winter wheat (Triticum aestivum L. cv. Rebell).Publication Management of volunteers derived from imidazolinone-tolerant oilseed rape(2016) Huang, Shoubing; Claupein, WilhelmOilseed rape (OSR) has become the second most important oilseed crop after soybean worldwide, producing 70.95 million tons of seed yield, and providing 13.4% of world supply of oilseeds in 2014. The demand for OSR is expected to increase due to protein meals/cakes used in animal feed and vegetable oils/fats for biodiesel and human consumption. With increasing cultivation area, concern over volunteer OSR is rising, particularly if the variety in question is tolerant to specific herbicides. Currently, the introduction of imidazolinone-tolerant OSR (commercially named Clearfield® OSR; CL OSR) into Europe poses new challenges for chemical control of CL OSR volunteers because of their tolerance to imidazolinone herbicides and other acetolactate synthase (ALS) inhibiting herbicides. Additionally, the potential of gene dispersal in time and space by persistent dormant seeds in the soil and by volunteers is increasing. Volunteers emerge from the soil seed bank, the volume of which is predominantly dependent on seed dormancy. Therefore, the objectives of this study were (i) to investigate seed dormancy and dormancy formation of CL OSR, and (ii) to find out suitable agricultural strategies to reduce volunteers by growing OSR genotypes with low potential for seed dormancy and seed survival, and by implementing appropriate tillage operations. Focusing on these aims, several experiments were carried out with different methods, namely field experiments, germination tests in the laboratory, and genomic analysis, providing data for three scientific articles. Experiment 1. A 3-year field trial in south-west Germany investigated dormancy dynamics during seed development (primary dormancy and potential secondary dormancy; tested with an existing standard method in the laboratory) of 10 non-CL OSR varieties (lines) in 2009 and 2010, and of five CL OSR varieties (hybrids) in 2014. Experiment 2. A total of 15 CL OSR genotypes grown at two locations in south-west Germany in 2012/2013, and eight genotypes (two CL genotypes included) grown at 12 locations across Germany in 2011/2012, were tested for potential secondary seed dormancy with the aim to investigate dormancy traits of CL OSR and maternal environmental effects on dormancy formation. Experiment 3. A 5-year experiment (2011–2015) was conducted in south-west Germany with non-CL OSR and CL OSR (two CL varieties: high dormant and medium dormant) in the same rotation (non-CL winter oilseed rape - winter wheat - CL winter oilseed rape - winter wheat - corn) to investigate OSR volunteer dynamics under different modes of tillage (inversion tillage, non-inversion tillage, no-till, with or without additional stubble tillage prior to primary tillage). Following hypotheses were tested: Experiment 1. (i) There is primary (innate) and secondary (induced) dormancy in oilseed rape; (ii) primary dormancy decreases during seed development, the potential secondary dormancy increases; (iii) at maturity, the level of the remaining primary dormancy and the varietal potential to secondary dormancy correlate. These hypotheses have been approved. Primary dormancy decreased from a high dormancy level (ca. 99%) at about 30 days after flowering (DAF) to a quite low level (< 15%) at late seed development. Embryo growth probably regulates the dynamics of primary dormancy, at least during early seed development. Depending on variety and year, potential secondary dormancy initially increased from nearly 0% to the highest level (up to 90%) at about 70 DAF, and then slightly decreased with further seed development. The correlation between primary dormancy and potential secondary dormancy was high at early seed development, but was quite low at late seed ripening. Experiment 2: (i) There is variation in potential seed dormancy of CL OSR; (ii) F1 (seeded) and F2 (harvested) generations of hybrid CL-OSR show similar dormancy levels although changes through environmental effects are known; (iii) the environment (location) during seed development and maturation has an effect on the potential dormancy. The hypotheses were approved. The CL OSR genotypes differed in potential secondary dormancy from 0.0 to 95.7% in the F1 generation and from 3.5 to 77.9% in their corresponding offspring (F2). Out of the 15 CL genotypes, nine were considered to be low dormant (<30% dormancy level). High correlation (r = 0.96) between F1 and F2 generations indicates a strong inheritance of seed dormancy. Precipitation during seed development is thought to be a contributor to dormancy formation, e.g. the higher the precipitation the higher the dormancy level. These results indicate that selection or breeding for low dormancy CL OSR is feasible. A direct comparison of varieties by dormancy is only possible if they have been grown and harvested at the same location, due to environmental effects. Experiment 3: (i) The soil seed bank size of OSR is determined by post-harvest tillage (particularly tillage time) and seed dormancy traits of the cultivated variety; (ii) the emergence of volunteers from the seed bank also depends on the mode of tillage; (iii) gene segregation in herbicide-tolerance might occur among CL volunteers. These hypotheses were partly approved. There was no significant effect of tillage on the soil seed bank, but the soil seed bank was visibly higher if stubble tillage was done prior to primary tillage (179 vs. 56 seeds m-2; treatments with stubble tillage vs. corresponding treatments without stubble tillage). There were significant effects of tillage in general on volunteers in the next crop. Non-inversion tillage resulted in 30 times more volunteers in the following winter wheat crop than inversion tillage due to shallow seed burial depth. A high dormancy OSR variety resulted in a significantly larger soil seed bank than a medium dormancy variety (147 vs. 58 seeds m−2) but in fewer volunteers (0.9 vs. 1.9 volunteers m−2) in the first following crop winter wheat, probably due to slow release of seeds from dormancy. Hypothetically speaking, seeds from low dormancy varieties seem to be released from dormancy more rapidly than seeds from high dormancy varieties. Gene segregation with 10 zygosities of the imidazolinone-tolerance genes PM1 and PM2 was detected in the CL volunteers in the first following crop winter wheat. Approximately 90% of sampled plants were homozygous for PM1 and PM2, still conferring a high tolerance to imidazolinones. Overall, a high variation in potential secondary dormancy was detected for CL OSR, which is similar to non-CL OSR. The contribution of seed dormancy to the soil seed bank was confirmed. During seed development, maternal environment can influence seed dormancy dynamics to some extent. Tillage operations, particularly tillage time, can also influence the soil seed bank and the emergence of volunteers. A very new aspect is that the disposition of seeds to release from dormancy (instead of induction of dormancy) should be considered in further studies. Sound strategies to control volunteers should include (1) the use of low dormancy varieties with a low potential to establish a seed bank and with a fast release from dormancy, and (2) a combination of different tillage operations in the years following OSR cultivation, e.g. delayed inversion tillage with a deep burial depth in the first year, followed by shallow non-inversion tillage in subsequent years. Combined with a thorough knowledge of seed dormancy, of the development of the soil seed bank and of the release from dormancy, the occurrence of CL volunteers in following crops can be reduced or even avoided by a scope of practical methods and approaches proposed in this study.Publication Nitrous oxide emissions and mitigation strategies in winter oilseed rape cultivation(2019) Kesenheimer, Katharina Anne; Müller, TorstenAfter carbon dioxide and methane, nitrous oxide, is the third most important greenhouse gas in the atmosphere. Nitrous oxide contributes to the greenhouse gas effect as well as to ozone depletion. The major portion of anthropogenic N2O emissions are stimulated by the use of nitrogen fertilizers in agriculture. The main processes for N2O production in soils are nitrification and denitrification. Various environmental and management factors such as precipitation, soil type, tillage, and crop residues affect these processes. N2O emissions can occur substantially in the post-harvest period. In Germany, approximately 50 % of the annual N2O emissions can occur during winter. This exhibits the importance and necessity of annual data sets which prevent misinterpretations instigated by investigations limited to the vegetation period. Winter oilseed rape is the most important raw material for biodiesel in Germany. As of 2018, the framework of the European Renewable Energy Directive requires that the use of biofuels achieve GHG savings of at least 50 % compared to fossil fuels. Feedstock production for biodiesel contributes more than half of the total GHG emissions. To close the nutrient cycle with renewable energy, digestate from biogas plants can be used as a substitute for mineral N fertilizer permitting the reduction of GHG emissions in the production process of synthetic fertilizers. When compared to other crops, OSR has a high N demand. The low N removal by the seeds results in inefficient use of nitrogen and therefore a high N surplus in the soil which is susceptible to gaseous or leaching losses to the environment. Another potential risk for N2O losses are crop residues after harvest. The type of soil cultivation can have both positive and negative implications on N2O emissions which depend, among other things, on tillage depth, soil type and moisture. Results from studies measuring N2O emissions from different tillage systems are contradicting and site dependent. This study aims to investigate the effect of (a) N fertilization (mineral and organic), (b) nitrification inhibitors, (c) crop residues and (d) tillage on direct N2O emissions and, inter alia, yield and soil nitrogen dynamics in OSR production. N2O emissions were monitored for three years over a range of N fertilization levels at five study sites chosen so as to best represent typical winter oilseed rape production in Germany. Furthermore, the effect of the nitrification inhibitor (NI) TZ+MP (1H-1,2,4-triazole and 3- methylpyrazole) with digestate is investigated. Additional experiments for 15N labelled crop residues, nitrification inhibitor DMPP (3,4-dimethylepyrazole phosphate) with mineral fertilizer and soil tillage were implemented. A high spatial and temporal variability in N2O fluxes over all sites was observed. At each site, increased N2O fluxes were often detected after N fertilization in conjunction with rainfall events. During the first six weeks after harvest we frequently observed increased N2O fluxes following rainfall. In this postharvest period of winter oilseed rape, nitrate contents in the top soil were generally elevated. There were no considerable N2O pulses observed during thawing of frozen soil. Winters were mild without any severe frost periods in all three surveyed years which could be a reason for the generally low N2O winter fluxes observed in this study. On all examined sites, increasing N fertilization significantly enhanced N2O flux rates. Data obtained during the study were used to augment an existing model, wherefrom a new emission factor for OSR can be calculated. Assuming a quantity of 200 kg N ha-1 the global fertilizer-related emission factor derived from the exponential model was 0.6 %. This factor is within the uncertainty range of the EF1 IPCC emission factor (0.3 % – 3.0 %), but about 40 % lower than the 1 % IPCC default. The nitrification inhibitor (NI) TZ+MP combined with digestate mitigated the N2O fluxes significantly across all study sites and experimental years. As already noted in the fertilizer experiment, a high spatial and temporal variability in N2O fluxes over all sites was observed. The magnitudes of the N2O fluxes also showed similar trends. Over the entire investigation, the application of the NI significantly reduced annual N2O emission by a factor of three. During the fertilization period this mitigation effect was six times significant. This clearly emphasizes the importance of annual data sets to avoid overestimating NI effects.Publication Nutrient seed treatments to improve abiotic stress tolerance in Brassica napus L.(2020) Mahmood, Asim; Neumann, GünterPoor germination and limitations during early plant growth are widespread constraints for oilseed rape (OSR; Brassica napus L.) with increasing importance due to a rising frequency of weather extremes related with global climate change. In this study, efforts have been made to improve health and stress resistance of OSR by exploring perspectives of cost-effective application techniques for micronutrients with stress- protective functions to cover increased demands of these nutrients under stress conditions. After preliminary screening experiments, special emphasis was placed on zinc (Zn) seed treatments including seed priming (SP) and seed dressing (SD). Effects on seedling performance during early growth were recorded at optimal conditions for plant growth in terms of temperature, nutrient and water supply and also under drought stress for winter OSR and under low root zone temperature (RZT) stress in spring OSR. Accordingly, both, ZnSP and ZnSD may offer practical, economically low-cost application methods to improve early seedling establishment particularly under challenging environmental conditions, to improve the perspectives for conversion into higher economic yields and could be equally attractive for small-scale on-farm use and rape seed industry.