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Variability among soybean (Glycine max (L.) Merr.) cultivars in response to genistein pre-incubated (Brady)rhizobium japonicumBelkheir, Ali Mohamed. January 1999 (has links)
No description available.
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Nitrogen fixation, transfer and competition in alfalfa-grass mixturesBurity, Helio Almeida. January 1986 (has links)
No description available.
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Studies of nodulation, nodule function, and nitrogen fixation of Vicia faba L. and Pisum sativum L.Herdina. January 1987 (has links) (PDF)
Typescript. Bibliography: leaves [137]-[157]
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Nitrogen Acquisition of Lentil (Lens culinaris Medic) Under Varied Fertility Treatments, No Tillage Duration and Nitrogen Regimes in SaskatchewanZakeri, Hossein 07 September 2011
High levels of soil nitrogen (N) can interfere with N2 fixation of lentil (Lens culinaris) and have variable effects on growth, yield and maturity of this indeterminate crop in Saskatchewan. In a series of field and greenhouse experiments during 2006 to 2008, response of the above-ground biomass (DW), plant N, N2 fixation, yield and days to maturity (DTM) of lentil to different N sources, time of N availability, and also to two no tillage (NT) durations were studied.
First, eight cultivars of lentil were grown under three fertility treatments of granular rhizobium inoculant, 50 kg N fertilizer ha-1 and a non-treated control in three environment-years at Saskatoon and Indian Head, SK. The fertility treatments, plant N status and N2 fixation did not alter lentil DTM, but weather did. On average, lentil matured 101 and 84 days after seeding with sufficient rain and with drought, respectively. Growth and yield of the lentil were identical in the inoculant and the N fertilizer treatments. The N fertilizer treatment occasionally restricted N2 fixation, but N shortage was compensated via more N uptake from soil. The greatest N accumulation of lentil occurred during podding to maturity and benefitted pod N content. By maturity, pod, stem and leaf had 60, 24 and 14% of total dry matter and 78, 9 and 13% of total plant N, respectively. Leaf N concentration, which closely resembled soil and plant N status, was reasonably predicted by SPAD chlorophyll meter observations after pod set.
Yield of five lentil cultivars was tested for the effects of 25-years (LN) versus 5-years (SN) of no tillage in the Black Soil Zone at Indian Head, SK in 2006, 2007 and 2008. In the same location, CDC Sedley was grown with four N fertilizer rates at the both LN and SN. Under terminal drought in 2006, average DW, N content and yield of the lentil cultivars in SN were greater than in LN, likely because of inhibited N2 fixation by the amplified soil N in the LN. In this year, 60 kg N fertilizer ha-1 reduced the yield difference of CDC Sedley in SN and LN. Lentil yield was identical or tended to be greater in LN than in SN with more rain in 2007 and 2008 that prolonged N mineralization and N uptake.
In the greenhouse study, applying N fertilizer from flowering until podding and until maturity increased DW, N content and yield, and delayed maturity of lentil compared to lentil relying on N2 fixation. Later flowering of one cultivar or greater N2 fixation in one soil medium diminished the variation of inoculated lentil with the post-flowering N treatments, suggesting N fixation could supply lentil N requirement.
Large-seeded cultivars produced greater yield than the small-seeded cultivars across environments in the fertility treatment study. Cultivar CDC Milestone produced comparable yield to high-yielding cultivars CDC Plato and CDC Greenland, but matured earlier. This cultivar showed promising results under both cool-wet and drought conditions. In contrast, CDC Sedley had lower on N2 fixation and HI values across the experiments. In the Black Soil Zone, CDC Milestone and CDC Robin performance was improved by improved HI and N2 fixation.
Overall, results of this thesis do not support the application of N fertilizer for inducing early maturity in lentil. Soil inoculation with commercial strains is suggested for Saskatchewan cropping systems. Applying N fertilizer is not required, unless soil test results suggest otherwise. In places like Indian Head, SK, cultivars with greater N2 fixation and higher HI can better fit the short growing season, cool temperature and high soil N content.
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Nitrogen Acquisition of Lentil (Lens culinaris Medic) Under Varied Fertility Treatments, No Tillage Duration and Nitrogen Regimes in SaskatchewanZakeri, Hossein 07 September 2011 (has links)
High levels of soil nitrogen (N) can interfere with N2 fixation of lentil (Lens culinaris) and have variable effects on growth, yield and maturity of this indeterminate crop in Saskatchewan. In a series of field and greenhouse experiments during 2006 to 2008, response of the above-ground biomass (DW), plant N, N2 fixation, yield and days to maturity (DTM) of lentil to different N sources, time of N availability, and also to two no tillage (NT) durations were studied.
First, eight cultivars of lentil were grown under three fertility treatments of granular rhizobium inoculant, 50 kg N fertilizer ha-1 and a non-treated control in three environment-years at Saskatoon and Indian Head, SK. The fertility treatments, plant N status and N2 fixation did not alter lentil DTM, but weather did. On average, lentil matured 101 and 84 days after seeding with sufficient rain and with drought, respectively. Growth and yield of the lentil were identical in the inoculant and the N fertilizer treatments. The N fertilizer treatment occasionally restricted N2 fixation, but N shortage was compensated via more N uptake from soil. The greatest N accumulation of lentil occurred during podding to maturity and benefitted pod N content. By maturity, pod, stem and leaf had 60, 24 and 14% of total dry matter and 78, 9 and 13% of total plant N, respectively. Leaf N concentration, which closely resembled soil and plant N status, was reasonably predicted by SPAD chlorophyll meter observations after pod set.
Yield of five lentil cultivars was tested for the effects of 25-years (LN) versus 5-years (SN) of no tillage in the Black Soil Zone at Indian Head, SK in 2006, 2007 and 2008. In the same location, CDC Sedley was grown with four N fertilizer rates at the both LN and SN. Under terminal drought in 2006, average DW, N content and yield of the lentil cultivars in SN were greater than in LN, likely because of inhibited N2 fixation by the amplified soil N in the LN. In this year, 60 kg N fertilizer ha-1 reduced the yield difference of CDC Sedley in SN and LN. Lentil yield was identical or tended to be greater in LN than in SN with more rain in 2007 and 2008 that prolonged N mineralization and N uptake.
In the greenhouse study, applying N fertilizer from flowering until podding and until maturity increased DW, N content and yield, and delayed maturity of lentil compared to lentil relying on N2 fixation. Later flowering of one cultivar or greater N2 fixation in one soil medium diminished the variation of inoculated lentil with the post-flowering N treatments, suggesting N fixation could supply lentil N requirement.
Large-seeded cultivars produced greater yield than the small-seeded cultivars across environments in the fertility treatment study. Cultivar CDC Milestone produced comparable yield to high-yielding cultivars CDC Plato and CDC Greenland, but matured earlier. This cultivar showed promising results under both cool-wet and drought conditions. In contrast, CDC Sedley had lower on N2 fixation and HI values across the experiments. In the Black Soil Zone, CDC Milestone and CDC Robin performance was improved by improved HI and N2 fixation.
Overall, results of this thesis do not support the application of N fertilizer for inducing early maturity in lentil. Soil inoculation with commercial strains is suggested for Saskatchewan cropping systems. Applying N fertilizer is not required, unless soil test results suggest otherwise. In places like Indian Head, SK, cultivars with greater N2 fixation and higher HI can better fit the short growing season, cool temperature and high soil N content.
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Regulation of Trichodesmium Nitrogen Fixation by Combined Nitrogen and Growth Rate: A Field and Culture StudyHoll, Carolyn Marie 21 November 2004 (has links)
Trichodesmium is a globally significant marine diazotroph responsible for supplying new nitrogen to the oligotrophic regions in which it is found. Though it has been studied for decades, our understanding of the ways in which environmental factors can affect its nitrogen fixation rate remains limited. A continuous culture of Trichodesmium was established in which steady state growth and nitrogen fixation were maintained at dilution rates ranging from 0.27 to 0.67 d-1. Our results clearly show that, as growth rate increased, biomass decreased linearly and nitrogen fixation rate increased linearly. C:N:P ratios remained constant over the range of growth rates studied, suggesting a tight coupling between macronutrient uptake and the maintenance of balanced growth at steady state. We used cultures at steady state to determine the impact of nitrate exposure and uptake on nitrogen fixation. Nitrate inhibits nitrogen fixation by up to 70% in a concentration-dependent manner at initial nitrate concentrations less than 10?? Nitrate uptake accounted for as much as 86% of total N uptake and, at initial nitrate concentrations greater than 2.5 ??more than made up for the observed inhibition of nitrogen fixation. A field study of this diazotroph shows that nitrogen fixation scales with light intensity from a maximum at 50% surface irradiance. Estimated areal nitrogen fixation rates in the Gulf of Mexico, based on vertical abundance profiles and the relationship between nitrogen fixation and surface irradiance, are comparable to measurements made in other oligotrophic regions. Stable isotopic composition of the particulate organic matter and the zooplankton confirms that Trichodesmium nitrogen and carbon are moving into the food chain and are important to higher trophic levels. As much as 60% of the zooplankton carbon was derived from Trichodesmium. Our work established that this diazotroph is ecologically important in the water column of the Gulf of Mexico, with important implications for nitrogen and carbon cycling. Findings from our field and culture studies can be added to models used to quantify the importance of Trichodesmium nitrogen fixation on an oceanic scale.
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Light dependant growth and nitrogen fixation rates in the Hemiaulus haukii and Hemiaulus membranaceus diatom-diazotroph associationsPyle, Amy Elizabeth 17 February 2012 (has links)
Nitrogen-fixation is an essential biochemical reaction involving the reduction of inert, atmospheric dinitrogen (N2) into biochemically accessible ammonia (NH3). Organisms that are capable of this process are collectively called “diazotrophs” and are ubiquitous in marine and terrestrial environments. Despite the wide distribution, little is known about the biological nature of the diverse groups of diazotrophs. This study was designed to address the influence of light and nutrients on nitrogen fixation and growth in several marine diazotrophic symbioses collectively termed “Diatom-Diazotroph Associations (DDAs).” The organisms of interest included the diatoms Hemiaulus haukii Grunow and Hemiaulus membranaceus Cleve, and their diazotrophic endosymbiont Richelia intracellularis Schmidt. The study included acetylene reduction assays, growth rate, and nutrient analysis experiments on both associations in order to better understand the similarities and differences within and between the two DDAs. The results indicate distinct differences in nitrogen fixation rates within and between the species. In the nitrogen addition experiment, the “no added nitrogen” treatment had the highest N2-fixation rate (N2-fixmax = 7.43 x 10-5 nmols N2 heterocyst-1min-1), followed by the added nitrate treatment (N2-fixmax = 6.49 x 10-5 nmols N2 heterocyst-1min-1) and the added ammonium treatment (N2-fixmax = 3.79 x 10-5 nmols N2 heterocyst-1min-1). The maximum growth rate occurred in the “added ammonium” treatment (0.42 divisions day-1), which had a higher percentage of asymbiotic cells than the two other treatments. The maximum recorded rate of N2-fixation for H. haukii was 7.43 x 10-5 nmol N2 heterocyst-1min-1 and the maximum value of N2-fixation for H. membranaceus was 1.88 x 10-4 nmol N2 heterocyst-1min-1. The maximum growth rate for H. haukii was 0.99 divisions day-1, and 1.06 divisions day-1 for H. membranaceus. Growth followed light saturation kinetics in H. haukii with a compensation light intensity (IC) of 10 µmol quanta m-2sec-1 and saturation light intensity (IK) of 100 µmol quanta m-2sec-1. H. haukii and H.membranaceus expressed light saturation kinetics in N2-fixation. N2-fixation was generally limited to the light period, with no evidence of a morning or evening enhancement. The DDAs grew solely on N2-fixation and did not use nitrate. This study contributes to current knowledge of DDAs and their role in global marine nitrogen fixation. / text
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ISOTOPIC NITROGEN FIXATION BY DESERT ALGAL CRUST ORGANISMSMayland, H. F. (Henry F.) January 1965 (has links)
No description available.
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Root nodule studies of a desert browse legume guajilla (Calliandra eriophylla Benth.)Tapia Jasso, Carlos, 1923- January 1965 (has links)
No description available.
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The effect of Puccinia Graminis pers. F. SP. Tritici Erikss. and E. Henn. infection on the nitrogen nutrition of seedlings of Triticum Compactum L. Var. Little Club.Ellis, C. R. January 1965 (has links)
Evidence to show that rusted wheat can fix elementary nitrogen was reported by d'Oliveira in 1939. If this be true the infection of this host by this parasite would have the rare property of fixing nitrogen in common with mycorrhiza, leguminous plants infected with root nodule bacteria and the few other possible associations. The fact that there is a short initial mutualistic symbiosis between rust and wheat makes this possibility of nitrogen fixation by the rusted wheat not entirely unlikely. However, d'0liveira's studies were admittedly preliminary ones, in which he used the Kjeldahl method of nitrogen analysis. [...]
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