Kerstin Huss-Danell

Presence and dispersal of infective Frankia in peat and meadow soils in Sweden

SummaryUse of the N2-fixing grey alder, Alnus incana (L.) Moench, as a short-rotation crop for energy production is currently being explored. To evaluate the need for inoculation of alders, the distribution of infective propagules of Frankia in the soil at potential sites for alder plantations was examined. Uninoculated grey alder seedlings were grown in three types of soil. Frequent nodulation was found in a meadow soil which had been free from actinorhizal plants for nearly 60 years, but the alder seedlings failed to nodulate in peat soil from two different bog sites. One of these bogs had been exploited for peat and the surface layer of the peat had been removed, so that the soil samples were taken from deep layers of the peat. At the other site, an area of cultivated peat, there were no infective propagules of Frankia in plots without alders; the infective Frankia was present in plots only where it had been introduced by inoculated alders. There was no detectable air-borne dispersal of Frankia. Instead, water movement might account for the dispersal of Frankia in peat. Although the apparent absence of Frankia in these peat soils necessitates inoculation of alder seedlings before planting out, this makes it possible to introduce and maintain Frankia strains with selected beneficial characteristics, since there is no competition from an indigenous Frankia flora.

Distribution of Frankia in soils from forest and afforestation sites in northern Sweden

The presence in soil ofFrankia, capable of forming nitrogen-fixing root nodules onAlnus incana (L.) Moench, was investigated. Intact soil cores from forested as well as disturbed sites were sampled and both alder-rich and alder-free sites were included in the study. Surface-sterilized alder seeds were sown in the soil cores which were kept in sterile culture tubes in a growth chamber. Root nodules with nitrogenase activity developed in soil cores from all sites studied. Thus, infective and effectiveFrankia was present in all of the soils sampled, even from sites free from actinorhizal plants and irrespective of pH and nitrogen content of the soils.

Lipid composition and nitrogenase activity of symbioticFrankia (Alnus incana) in response to different oxygen concentrations

SummaryThe role ofFrankia vesicle envelope lipids in regulating oxygen diffusion of symbiotic nitrogen fixation inAlnus incana was examined. Total lipids of symbioticFrankia (vesicle clusters) that had been adapted to oxygen tensions of 5,21, or 40 kPa were analyzed with a normal phase HPLC system. During the oxygen treatment, nitrogenase activity was measured as hydrogen evolution in an open flow-through system. When plants were transferred to low oxygen (5 kPa) or high oxygen (40 kPa), nitrogenase activity dropped initially. Activity recovered in both treatments with a rate comparable to the controls (21 kPa O2). Both lipid content and lipid composition of vesicle clusters were affected by the oxygen treatments. With increasing oxygen tension, the vesicle cluster lipid content increased. This correlated with structural data (fluorescence microscopy and TEM) which showed a thicker vesicle envelope at higher oxygen tension. Three hopanoid lipids, bacteriohopanetetrol (bht) and two isomers of phenylacetyl monoester of bht, made up approximately 80% of the vesicle cluster lipids. With changing oxygen concentrations, the ratio of the two bht esters changed whereas the relative proportion of bht remained fairly constant. Therefore, in theFrankia-Alnus incana symbiosis, adaptation to different ambient oxygen tensions occurs at least partly by increasing the thickness of theFrankia vesicle envelope and by changing its lipid composition.

River and lake sediments as sources of infective Frankia (Alnus)

Several Alnus species are commonly found growing along rivers and lakes. Alnus forms root nodules with N2-fixing Frankia. We used plant bioassays to detect presence of infective Frankia in river and lake sediments from northern Sweden and Alaska. Silty river water and superficial river and lake sediments from all sites contained infective and effective Frankia, but 100-3000 year old lake sediments did not produce nodulated plants. Action by streams, waves and changing water levels transport Frankia in superficial sediments and can provide an inoculum for Alnus roots.

Ammonium effects on function and structure of nitrogen-fixing root nodules of Alnus incana (L.) Moench

Cloned plants of Alnus incana (L.) Moench were inoculated and grown without combined nitrogen for seven weeks. The effects of ammonium on the function and structure of the root nodules were studied by adding 20 mM NH4Cl (20 mM KCl=control) for four days. Nitrogenase activity decreased to ca. 50% after one day and to less than 10% after two days in ammonium treated plants, but was unaffected in control plants. The results were similar at photon flux densities of 200 and 50 μmol m-2 s-1. At the higher light level the effect was concentration dependent between 2 and 20 mM NH4Cl. The recovery was slow, and more than 11 d were needed for plants treated with 20 mM ammonium to reach initial activity. The distribution of 14C to the root nodules after assimilation of 14CO2 by the plants was not changed by the ammonium treatment. Microscopical studies of root nodules showed high frequencies of endophyte vesicles being visually damaged in nodules from ammonium-treated plants, but not in nodules from control plants. When nitrogenase activity was restored, visually damaged vesicles were again few, whereas young developing vesicles were numerous. The slow recovery, the 14C-translocation pattern, and the structural changes of the endophyte indicate a more complex mechanism of ammonium influence than simply a short-term reduction in supply of carbon compounds to the nodules.

Intrageneric variation in nodulation of Alnus: consequences for quantifying Frankia nodulation units in soil

Abstract Methods based on amplification and recognition of Frankia -specific DNA have recently been developed to quantify Frankia in soil. But measuring numbers of infective Frankia in soil still requires bioassays involving nodulation of appropriate host plants. We compared three alder species, Alnus glutinosa (L.) Gaertn., A. incana (L.) Moench and A. rubra Bong, grown in two nutrient solutions under controlled conditions in a climate chamber. Plants were either kept in the same cultivation tube or, to remove most of the inoculum, they were moved into a new tube 2 weeks after inoculation. Soil dilution series prepared from a forest soil served as inocula. Roots were inspected for nodules weekly for 8 weeks and the number of nodulation units (NU) g −1 soil was calculated according to the most probable number (MPN) method and according to a nodulation capacity method. Alnus glutinosa required the longest time to nodulate. The number of NU detected was in the order A. rubra > A. incana > A. glutinosa in each of the nutrient solutions used. Eight weeks after inoculation, number of NU ranged from 5 to 400 as determined by the MPN-method, and from 10 to 380 as determined by the nodulation capacity method in the different species, solution and tube combinations used. The bioassay seems appropriate for comparisons between soils when the same plant genotypes are used under the same conditions, but otherwise comparisons should be made with caution. The MPN method and the nodulation capacity method essentially gave the same results. The MPN method is somewhat less labour intensive.

GROWTH, NITROGEN-FIXATION AND RELATIVE EFFICIENCY OF NITROGENASE IN ALNUS-INCANA GROWN IN DIFFERENT CULTIVATION SYSTEMS

SummaryThree cultivation systems were compared. In one system the alders were grown hydroponically. In the two other systems the alders were planted in gravel and either given water and nutrients at intervals or the nutrient solution was continuously supplied. Alders continuously supplied with nutrients and water showed a significantly more rapid growth, higher biomass production and higher nitrogen content than did alders given nutrients and water at intervals or alders hydroponically grown. Alders continuously supplied with water and nutrients had a constant RE (relative efficiency of nitrogenase) of about 0.80 throughout the experimental period while alders supplied with water and nutrients at intervals showed a slight decrease in RE at the end of the experimental period. No strict relationship was found between RE and nitrogen content or between RE and plant productivity.

Biomass production and nitrogen utilization by Alnus incana when grown on N2 or NH 4 (+) made available at the same rate.

A single clone of Alnus incana (L.) Moench was grown in a controlled-environment chamber. The plants were either inoculated with Frankia and fixed atmospheric nitrogen or were left uninoculated but received ammonium at the same rate as the first group fixed their nitrogen. Nitrogen fixation was calculated from frequenct measurements of acetylene reduction and hydrogen evolution. The diurnal variation of acetylene reduction was also taken into account. The relative efficiency of nitrogenase could be used in the calculations of fixed nitrogen since the Frankia used did not show any detectable hydrogenase activity. Alders fixing nitrogen developed more biomass, longer shoots, larger leaf areas and contained more nitrogen than alders receiving ammonium. In one experiment, almost all ammonium given to the non-nodulated alders was taken up and 15% of the nitrogen taken up was excreted. In the other experiment, 34% of the ammonium was left in the nutrient solution and 8% of the nitrogen taken up was excreted. Alders inoculated with Frankia did not excrete any detectable amount of nitrogen. It seems that the energy demand for nitrogen fixation is not so high that biomass production in alders is retarded. The symbiotic system of A. incana and Frankia seems to be more efficient in utilizing its nitrogen than non-symbiotic A. incana receiving ammonium.

Respiratory capacity, nitrogenase activity and structural changes ofFrankia, in symbiosis withAlnus incana, in response to prolonged darkness.

Plants ofAlnus incana (L.) Moench in symbiosis with a local source ofFrankia were exposed to prolonged darkness under controlled climate conditions.Frankia vesicle clusters were prepared from the root nodules, and the condition ofFrankia was measured as respiratory capacity by supplying the preparation with saturating amounts of four different substrates. During darkness, nitrogenase (EC 1.7.99.2) activity decreased in intact plants and in the vesicle-cluster preparations. The respiratory capacity ofFrankia also decreased. After 4 d in darkness most respiration was lost, though all nitrogenase activity was already lost after 3 d. When the dark treatment was ended after 2 d and normal light/dark conditions restored, nitrogenase activity immediately started to recover. The respiratory capacity continued to decrease and no recovery was observed until the third day after the end of the dark treatment. Whole-plant nitrogenase activity slowly increased at a rate similar to the rate of increase observed in untreated plants. Transmission electron micrographs of the root nodules showed that the cytoplasm of infected host cells and the cells ofFrankia were structurally degraded in response to dark treatment, while young vesicles were frequent during recovery. Growth and differentiation ofFrankia cells were apparently important for recovery of the enzyme activities studied.

Nitrogenase activity in root nodule homogenates of Alnus incana

Root nodule homogenates of actinorhizal plants may represent Frankia in a symbiotic stage but released from environmental influence of the host plant. Anaerobic homogenization with a blender in buffer supplied with sucrose, polyvinylpyrrolidone and reducing substances gave three times higher yields of nitrogenase activity (C2H2-reduction) than crushing the nodules in liquid nitrogen. The activity in the homogenates was very reproducible and was, on average, nearly twice as high as the activity in excised nodules and c. 10% of the activity in intact plants. The difference in activity between excised nodules and intact plants was, roughly by halves, due to removal of the root system from the pot and to excision of the nodules. The nitrogenase activity in the homogenates was slightly higher when nodule excision was done in Ar or under water as well as after treatment of the homogenate with toluene or Triton X-100 or osmotic shock. These gains in activity were considered too small to outweigh the increased complications of preparing homogenates for routine use. Due to the reproducible recovery of nitrogenase in the homogenates the technique seems useful for physiological studies on nitrogen fixation in Alnus incana.