Nodulation and nitrogen fixation in Purshia: inoculation responses and species comparisons

Summary Nitrogen fixing trees and shrubs may be useful in revegetation efforts. Speculation that insufficient endophyte populations in surface soils may limit non-leguminous symbiotic nitrogen fixation in marginal land was explored.Purshia tridentata andP. glandulosa seedlings were grown in greenhouse trials using ten soils from nativePurshia sites. Treatments include a control, an inoculated treatment, and six mmole nitrogen amendment. When inoculated with aP.tridentata crushed nodule inoculum, two of five non-nodulating soils and three sparsely nodulating soils produced well nodulated plants. Inoculation also increased nodule mass, total nitrogen, nitrogen content and shoot dry mass in plants from some of the soils. Of the three soils failing to produce nodulated plants when inoculated, one produced plants that responded well to nitrogen additions but failed to nodulate under low nitrogen conditions; another produced severely stunted plants indicating nutritional limitations on the host; and the third produced plants that were not nitrogen deficient. An application of nitrogen completely suppressed nodulation in all but one soil. The twoPurshia species were similar in nodulation, nitrogen fixation and growth, although important exceptions exist that indicate species may differ in adaptability to certain soil conditions.     

Genetic Regulation of Seed Dormancy in Purshia tridentata(Rosaceae)

Seeds of Purshia tridentata, a shrub of semi-arid North America,require chilling to become non-dormant. Using seeds producedfrom controlled crosses in a common garden, we examined effectsof ovule parent, pollen parent, and year of production on germinationpercentage in response to chilling for 2 weeks at 2°C. Differencesamong ovule parents accounted for most of the variance in chillingresponse, and these differences (2 to 83% germination) wereconsistent across years. Differences among pollen parents werealso significant, producing a two- to five-fold difference inmean germination percentage. Differences among years were significantbut small. Ovule parent by year interactions showed that among-yearvariation in ripening environment did not affect ovule parentsequally. There was no significant pollen parent by year interaction,suggesting that the effect of maturation environment was mediatedthrough maternal tissues. In reciprocal crosses, two plantsthat showed contrasting dormancy levels as ovule parents producedseeds with similar dormancy as pollen parents, indicating thatthe genetic difference between them was at the testa level.Two plants that produced seeds with contrasting dormancy aspollen parents showed a similar but stronger pattern of contrastas ovule parents, showing that the genetic difference betweenthem was at both embryo and endosperm or testa level. Testaor endosperm genotype was primarily responsible for chillingresponse of intact seeds, while embryo genotype affected chillingresponse and also exercised primary control over low temperaturegermination rate, whether of excised embryos or of intact seeds.Copyright 2000 Annals of Botany Company Antelope bitterbrush, bitterbrush, common garden study, germination     

Atmospheric nitrogen fixation by hydrocarbon-oxidizing bacteria

Microorganisms have been found which concomitantly convert hydrocarbons, selected naphthenic acids, and atmospheric nitrogen into cellular substance. Bacteria are included in the genera Pseudomonas, Mycobacterium, and Azotobacter. Carbon sources utilized include the hydrocarbons methane, n-butane, n-tetradecane, toluene, and a naphthenic acid, cyclohexane-carboxylate. Uptake of isotopic nitrogen was employed as a criterion of nitrogen fixation. The results indicate a rather wide prevalence in nature of hydrocarbon-oxidizing bacteria capable of fixing atmospheric nitrogen. Their occurrence helps explain the high concentration of organic nitrogen commonly found in soils exposed to gas leakage from pipelines or natural-gas seeps, and suggests further consideration of the possibility of applying selected petroleum residua to soils in order to increase the agricultural potential by nitrogen-fixing processes.     

Denitrification and nitrogen fixation by Azospirillum

A model system is described where Azospirillum and germinated wheat seeds were grown in association for a week and then assayed for nitrogen fixation (C₂H₂-reduction) and denitrification (N₂O-formation) activities. The association performed C₂H₂-reduction and N₂O-formation under microaerobic conditions. Both activities were measurable after already 3–5 h of incubation with substantial rates and were strictly dependent on the presence of both plants and bacteria. During the week of the growth of the association, the bacteria had lived exclusively from the carbon compounds supplied by the roots of the plants. C₂H₂-reduction activity by the association was more or less the same with all the Azospirillum brasilense strains, but lower with A. lipoferum and with the A. amazonense strains tested. Two nitrogenase negative mutants of Azospirillum brasilense showed virtually no activity in the association. C₂H₂-reduction activity was strongly dependent on the growth temperature of the association. Denitrification (N₂O-formation) was high also at higher temperatures and at pH-values in the medium around 7.8 but not at neutrality and was strictly dependent on nitrate. The Azospirillum strain used strongly determined the rate of the N₂O-formation in the association. It is suggested that Azospirillum may be beneficial to crops particularly under tropical conditions.Dedicated to Professor Dr. Gerhart Drews, Freiburg, on the occasion of his 60th birthday     

Ecological aspects of the distribution of different autotrophic CO2 fixation pathways

Autotrophic CO(2) fixation represents the most important biosynthetic process in biology. Besides the well-known Calvin-Benson cycle, five other totally different autotrophic mechanisms are known today. This minireview discusses the factors determining their distribution. As will be made clear, the observed diversity reflects the variety of the organisms and the ecological niches existing in nature.     

Growth and nitrogen fixation by immobilized cyanobacteria

Summary The nitrogen-fixing photosynthetic cyanobacteria have significant potential for utilization as a biological system for the production of reduced nitrogen compounds, either by industrial fermentation or in the environment as soil inocula. In either system, the ability to immobilize cyanobacteria on the external surface of fibrous substrata would significantly improve the ease of manipulation of the cells, control of growth, and product recovery without the complications inherent in immobilization by entrapment. We have shown that the filamentous heterocystous species Nostoc muscorum is naturally able to attach to a variety of different fibres, both natural and artificial. Attached cells are able to grow and fix nitrogen in both liquid and plate culture. Nitrogen-fixing cells attach to the fibres much more readily than do non-fixing cells, suggesting that the physiological and morphological changes accompanying heterocyst differentiation result in the production of specific attachment sites. Scanning electron microscopy of attached cells shows that heterocysts act as attachment sites and that the external cell wall material specifically synthesized around the heterocysts may be acting as the biological glue for this attachment.Journal Paper No. J-13259 of the Iowa Agriculture and Home Economics Experiment Station, Ames, Iowa, Project No. 2649     

Experiments on nitrogen fixation by nodulated lucerne

Summary Field experiments at five sites (two on clay loam, two on a sandy soil and one on chalky loam) compared dry-matter yields and nitrogen contents of lucerne and ryegrass. These tested Rhizobium inoculation and fertilizer treatments in an experimental design proposed by Vincent and Nutman (IBP 69(66), amended 57/68). The crop and inoculation treatments (using large inocula of effective or ineffective strains) were set out in strips across each site to minimise contamination, and the fertilizer treatments (nitrogen, limeetc.) distributed at random within strips. This proved satisfactory and allowed valid statistical analysis. The massive inoculation with the ineffective strain suppressed the few naturally occurring effectiveR. meliloti at some of the sites, and provided a basis of comparison for assessing the amounts of nitrogen fixed by the native strains and by the introduced effective strains. However, it did so only during the first year because the introduced ineffective strains were overgrown by effective strains in the second year. Hence, ryegrass without nitrogen fertilizer was a better measure of the amounts of nitrogen obtainable from the soil. Estimates of fixation ranged from 0 to more than 300 kg N ha⁻¹ at the different sites, treatment comparisons indicating the main factors limiting fixation. Parallel experiments were done using a soil core technique described by Vincent. These gave very similar results to the field trials in their first years. Studies of the changes in the populations ofR. meliloti in the field trial plots and soil cores gave information on the effects of crop and fertilizers on numbers and effectiveness of isolates and was useful in interpreting the results.     

Biological nitrogen fixation

And he gave it for his opinion, that whoever could make two ears of corn or two blades of grass to grow upon a spot of ground where only one grew before, would deserve better of mankind, and do more essential service to his country than the whole race of politicians put together. {Jonathan Swift, ‘Gulliver's Travels’, Voyage to Brobdingnag, Ch. 7.)     

The origin of endosymbiotic nitrogen fixation by Rhizobium

It is proposed, that current Rhizobia, able to fix nitrogen symbolically, developed from a bacterium, that was the common ancestor of Rhizobium and Agrobacterium tumefaciens, by the acquisition of a small plasmid or a small part of a bacterial genome, carrying a large part (but not all) of the genes necessary for the expression of nitrogen fixation.