A comparison of symbiotic nitrogen fixation in Scotland inAlnus glutinosa andAlnus rubra

Summary Alnus glutinosa andAlnus rubra growing in the field in Scotland show specific nitrogenase activities of the same order of magnitude. The period of maximum potential nitrogenase activity coincides with that of maximum growth in late Spring and Summer. It is suggested that the retention of nitrogenase activity into the Autumn when growth has virtually ceased may be important as a contribution to the nitrogenous reserves of the tree.Bioassay of different Scottish soils, all collected from the locality of natural stands ofAlnus glutinosa, showed wide variation in the nodulation of seedlings, although generally a soil poor for nodulation ofAlnus glutinosa generally gave poor nodulation ofAlnus rubra. Soils of pH 4.5 to 6.5, best suited for growth and nitrogen fixation of the two species, often gave nodules showing highest specific nitrogen fixing activity. Young (2 to 3 year old) plants in glasshouse or controlled environment cabinet, inoculated withAlnus glutinosa endophyte, differed from mature field grown plants, however, sinceAlnus rubra required a much larger (up to 2.5 times) mass of root nodules to fix a unit quantity of N. Microscopic comparison of the nodules of glasshouse plants showed that the proportion of cells containing the vesicular (nitrogen fixing) form of the endophyte was only slightly lower inAlnus rubra than inAlnus glutinosa and it is suggested that the differences in specific nitrogen fixing activity between the two species may reflect some incompatibility of function of theAlnus glutinosa endophyte when in symbiosis withAlnus rubra.     

Anaerobic stimulation of root exudates and disease of peas

Summary The relationships between root exudation, root disease and anaerobic root stresses were investigated. Sand culture and mist chamber studies demonstrated that low O₂ and high CO₂ reduced plant growth and increased the exudation of ethanol, amino acids, and sugars by pea roots. The relative loss of ethanol by roots was much greater in treatments with atmospheres of N₂ containing 30% CO₂ than in treatments of air containing 30% CO₂ or N₂. Ethanol was not detected in the nutrient solution of aerated plant roots. Atmospheres of N₂ plus 30% CO₂ caused 500% greater mycelial growth ofFusarium solani f. sp.pisi and 400% more disease of inoculated pea roots. Relative losses of four amino acids and four sugars were much greater in atmospheres of N₂ plus 30% CO₂ than in N₂ or air.     

Methods of isolation and cultivation of Frankia species from actinorhizas

A critical review is given about the isolation and cultivation methods of Frankia species fromAlnus glutinosa root-nodules. The best results so far are obtained with a combination of sucrose (60% w/v)-sedimentation of root-nodule homogenate and subsequent suspension in the top-layer of a doubleagar layer system. The top-layer needs to contain a suitable C-source, in this study often a lipid factor from an alcoholic root-extract and an organic N-source.The isolation and cultivation of Sp(–) and Sp(+) strains fromAlnus glutinosa root nodules and a Frankia from the root-nodules ofMyrica gale is reported. The regular observation of growing colonies appears to be very important for the interpretation of results. The latter was illustrated by the remarkable diauxic growth of the strains isolated fromAlnus glutinosa Sp(+) root nodules.     

Evolutionary implications of nucleotide sequence relatedness between Alnus nepalensis and Alnus glutinosa and also between corresponding Frankia microsymbionts

Frankia DNAs were isolated directly from root nodules of Alnus nepalensis and Alnus nitida collected from various natural sites in India. For comparison, a nodule sample from Alnus glutinosa was also collected from Tuebingen, Germany. Nucleotide sequence analyses of amplified 16S–23S ITS region revealed that one of the microsymbionts from Alnus nepalensis was closely related to the microsymbiont from Alnus glutinosa. A similar exercise on the host was also carried out. It was found that one sample of Alnus nepalensis was closely related to Alnus glutinosa sequence from Europe. Since both Frankia and the host sequences studied revealed proximity between Alnus glutinosa and Alnus nepalensis, it is hypothesised that the common progenitor of all the alders first entered into an association with Frankia, and the symbiotic association has evolved since.     

Effect of substrate nitrogen on the performance ofin vitro propagatedAlnus glutinosa clones inoculated with Sp+ and Sp− Frankia strains

The addition of combined nitrogen to substrate at an appropriate rate can stimulate N₂-fixation thus inreasing the efficiency of the Alnus-Frankia symbiosis. To examine how nitrogen additions can effect the peformance of different pairs of symbionts, growth and time course of N₂-fixation were studied in plants supplied with NH₄NO₃. Two cloned ofAlnus glutinosa (L.) Gaertn., propagatedin vitro, were inoculated with two strains ofFrankia (AVP3d and ACN14a) and grown in a greenhouse. Calcined montmorillonite (Totfaice^R) was used as growth substrate. Six N treatments were made up of varied amounts of NH₄NO₃ supplied in one single addition shortly before inoculation. Weekly measurements of shoot height and repeated measurements of nitrogenase activity (acetylene reduction) performed on intact root systems were used to monitor the development of the symbioses. Nitrogen treatments containing from 0.10 to 0.68 mg N g⁻¹ dry substrate stimulated N₂-fixation as well as growth. The relative performance of the two clones was different according to N treatment; one clone showed a greater benefit from the nitrogen input. Our results support the recommendation that selection of symbionts according to performance should be carried out with an input of combined nitrogen. This can provide optimum conditions for the development of each pair of symbionts.     

Growth and shoot: root ratio of seedlings in relation to nutrient availability

The influence of mineral nutrient availability, light intensity and CO₂ on growth and shoot:root ratio in young plants is reviewed. Special emphasis in this evaluation is given to data from laboratory experiments with small Betula pendula plants, in which the concept of steady-state nutrition has been applied.Three distinctly different dry matter allocation patterns were observed when growth was limited by the availability of mineral nutrients: 1, Root growth was favoured when N, P or S were the major growth constraints. 2, The opposite pattern obtained when K, Mg and Mn restricted growth. 3, Shortage of Ca, Fe and Zn had almost no effect on the shoot:root ratio. The light regime had no effect on dry matter allocation except at very low photon flux densities (< 6.5 mol m^-2 day^-1), in which a small decrease in the root fraction was observed. Shortage of CO₂, on the other hand, strongly decreased root development, while an increase of the atmospheric CO₂ concentration had no influence on dry matter partitioning. An increased allocation of dry matter to below-ground parts was associated with an increased amount of starch in the tissues. Depletion of the carbohydrate stores occurred under all conditions in which root development was inhibited. It is concluded that the internal balance between labile nitrogen and carbon in the root and the shoot system determines how dry matter is being partitioned in the plant. The consistency of this statement with literature data and existing models for shoot:root regulation is examined.     

Infectivity and effectivity of Frankia strains from the Rhamnaceae family on different actinorhizal plants

Ten strains of Frankia isolated from root nodules of plant species from five genera of the host family Rhamnaceae were assayed in cross inoculation assays. They were tested on host plants belonging to four actinorhizal families: Trevoa trinervis (Rhamnaceae), Elaeagnus angustifolia (Elaeagnaceae), Alnus glutinosa (Betulaceae) and Casuarina cunninghamiana (Casuarinaceae). All Frankia strains from the Rhamnaceae were able to infect and nodulate both T. trinervis and E. angustifolia. Strain ChI4 isolated from Colletia hystrix was also infective on Alnus glutinosa. All nodules showed a positive acetylene reduction indicating that the microsymbionts used as inoculants were effective in nitrogen fixation. The results suggest that Frankia strains from Rhamnaceae belong to the Elaeagnus-infective subdivision of the genus Frankia.     

Growth increment ofAlnus glutinosa upon dual inoculation with effective and ineffectiveFrankia strains

Investigations on the ecological function of ineffectiveFrankia strains and their behaviour in competition with effectiveFrankia strains indicated an enhanced plant growth upon dual inoculation with increasing amounts of effective (i.e. N₂-fixing)Frankia strains and simultaneous inoculation with a constant amount of an ineffectiveFrankia strain. Enhanced plant growth was measured as increase in plant height and total dry weight at constant shoot/root ratio. The stimulating effect of the ineffective strain was independent of the plant clone and was obtained with bothAlnus glutinosa clones W I and B II, which were resistant and susceptable, respectively, to the ineffective strain. Stimulation was also independent of the nodulation conditions. Short-term studies (7 weeks) under axenic conditions and greenhouse experiments during 3 months showed comparable results, not only in plant growth but also in nodule formation. Increment in plant growth was not necessarily correlated to higher nodule formation with the effectiveFrankia strains.     

Leaf gas exchange and nitrogen dynamics of N2-fixing, field-grown Alnus glutinosa under elevated atmospheric CO2

Few studies have investigated the effects of elevated CO₂ on the physiology of symbiotic N₂-fixing trees. Tree species grown in low N soils at elevated CO₂ generally show a decline in photosynthetic capacity over time relative to ambient CO₂ controls. This negative adjustment may be due to a reallocation of leaf N away from the photosynthetic apparatus, allowing for more efficient use of limiting N. We investigated the effect of twice ambient CO₂ on net CO₂ assimilation (A), photosynthetic capacity, leaf dark respiration, and leaf N content of N2-fixing Alnus glutinosa (black alder) grown in field open top chambers in a low N soil for 160 d. At growth CO₂, A was always greater in elevated compared to ambient CO₂ plants. Late season A vs. internal leaf p(CO₂) response curves indicated no negative adjustment of photosynthesis in elevated CO₂ plants. Rather, elevated CO₂ plants had 16% greater maximum rate of CO₂ fixation by Rubisco. Leaf dark respiration was greater at elevated CO₂ on an area basis, but unaffected by CO₂ on a mass or N basis. In elevated CO₂ plants, leaf N content (μg N cm^?2) increased 50% between Julian Date 208 and 264. Leaf N content showed little seasonal change in ambient CO₂ plants. A single point acetylene reduction assay of detached, nodulated root segments indicated a 46% increase in specific nitrogenase activity in elevated compared to ambient CO₂ plants. Our results suggest that N₂-fixing trees will be able to maintain high A with minimal negative adjustment of photosynthetic capacity following prolonged exposure to elevated CO₂ on N-poor soils.     

Effects of european alder (Alnus flutinosa (L.) Gaertn) rhizobacteria on nodular metabolism and root development

The effects of 3 Bacillus and 7 Pseudomonas strains on development of the root system and nodular metabolism, evaluating CO₂ production and acetylene reduction activity (ARA), of Alnus glutinosa, were studied. All experiments were done on nodulated plants (N) with the symbiont Frankia and on non-nodulated plants (NN).An increase in root length (RL) and root surface (RS) was detected when growth culture media from three different Bacillus free of bacteria were assayed, both in N and NN plants. However, Pseudomonas growth culture media reduced RS in N plants, and a decrease in RL parallel to an increase in RS in NN plants. Bacillus growth cultyre media caused an increase: and CO₂ production while Pseudomonas culture media caused lower ARA and a noticeable increase in nodular respiration. Results are discussed considering nutritional and/or hormonal (Bacillus) or phytotoxic factors (Pseudomonas).     

Isolation of infective and effective Frankia strains from root nodules of Alnus acuminata (Betulaceae)

Two Frankia strains were isolated from root nodules of Alnus acuminata collected in the Tucumano-oranense forest, Argentina. Monosporal cultures were obtained by plating a spore suspension of each strain and isolating a single colony. The strains (named AacI and AacIII) showed branched mycelia with polymorphic sporangia and NIR-vesicles. They differed in their ability to use carbon sources: the AacI strain grew well on pyruvate, while the AacIII strain grew on mineral medium supplemented with glucose or, alternatively, with sucrose. The two strains were sensitive to oleandomycin, erythromycin, kanamycin, penicillin G, streptomycin and chloramphenicol at 5 μg/ml. The AcIII strain exhibited a moderate resistance to rifampicin, ampicillin and vancomycin. The nitrogenase activity in vitro of the strains was significantly higher in basal medium without nitrogen than that determined in the presence of ammonium chloride. Both strains were infective on seedlings of Alnus glutinosa, inducing an approximately similar percentage of nodulated plants (80%), although strain AacIII produced a higher number of nodules per plant (≤15) than strain AacI (≤6). They were also effective for nitrogen fixation in planta, determined by the acetylene reduction assay. This revised version was published online in July 2006 with corrections to the Cover Date.     

Ion uptake and respiration of dry bean roots subjected to localized anoxia

Summary Ion uptake by dry bean root systems was examined during a three day treatment period. Three aeration treatments were applied to split root systems where both halves were aerated, both halves were nonaerated and one half aerated and the remaining half nonaerated (localized anoxia). Ion absorption was similar for the aerated control and localized anoxia treatments. The nonaerated control absorbed 2, 40, and 60 percent of the aerated control for K⁺, Ca⁺⁺, and NO₃ ⁻, respectively. Ion absorption by stressed plants appeared to increase directly with root growth in the aerated portions of the localized anoxia treatments. Localized anoxia resulted in greater potassium ion uptake per unit root weight and in greater root respiration rates of the aerated half of the Pinto III cultivar root system. Transpiration rates of Seafarer subjected to localized anoxia were 135% of the aerated control. The additional water use may have contributed to greater ion uptake, by mass flow, in the nonaerated portion of the localized anoxia treatment. Nutrient solutions of the nonaerated controls became more alkaline during stress than did the nonaerated portions of the localized anoxia treatments, indicating a possible direct or indirect effect of the aerated portions of the localized anoxia treatments on the corresponding nonaerated half. Compensation in ion uptake by dry bean roots subjected to localized anoxia appeared to be the result of increased root growth, greater respiration rates, greater transpiration rates and, for Pinto III, an increase in the ion uptake rate per unit root weight. This compensatory uptake of water and nutrients by the root system may be one mechanism by which roots overcome localized stress within a soil profile.     

Above- and belowground response of Populus grandidentata to elevated atmospheric CO2 and soil N availability

Soil N availability may play an important role in regulating the long-term responses of plants to rising atmospheric CO₂ partial pressure. To further examine the linkage between above- and belowground C and N cycles at elevated CO₂, we grew clonally propagated cuttings of Populus grandidentata in the field at ambient and twice ambient CO₂ in open bottom root boxes filled with organic matter poor native soil. Nitrogen was added to all root boxes at a rate equivalent to net N mineralization in local dry oak forests. Nitrogen added during August was enriched with ¹⁵N to trace the flux of N within the plant-soil system. Above-and belowground growth, CO₂ assimilation, and leaf N content were measured non-destructively over 142 d. After final destructive harvest, roots, stems, and leaves were analyzed for total N and ¹⁵N. There was no CO₂ treatment effect on leaf area, root length, or net assimilation prior to the completion of N addition. Following the N addition, leaf N content increased in both CO₂ treatments, but net assimilation showed a sustained increase only in elevated CO₂ grown plants. Root relative extension rate was greater at elevated CO₂, both before and after the N addition. Although final root biomass was greater at elevated CO₂, there was no CO₂ effect on plant N uptake or allocation. While low soil N availability severely inhibited CO₂ responses, high CO₂ grown plants were more responsive to N. This differential behavior must be considered in light of the temporal and spatial heterogeneity of soil resources, particularly N which often limits plant growth in temperate forests.     

Carbon cost of nitrogenase activity in Frankia–Alnus incana root nodules

The carbon cost of nitrogenase activity was investigated to determine symbiotic efficiency of the actinorhizal root nodule symbiosis between the woody perennial Alnus incana and the soil bacterium Frankia. Respiration (CO₂ production) and nitrogenase activity (H₂ production) by intact nodulated root systems were continuously recorded in short-term assays in an open-flow gas exchange system. The assays were conducted in N₂:O₂, thus under N₂-fixing conditions, in all experiments except for one. This avoided the declines in nitrogenase activity and respiration due to N₂ deprivation that occur in acetylene reduction assays and during extended Ar:O₂ exposures in H₂ assays. Two approaches were used: (i) direct estimation of root and nodule respiration by removing nodules, and (ii) decreasing the partial pressure of O₂ from 21 to 15% to use the strong relationship between respiration and nitrogenase activity to calculate CO₂/H₂. The electron allocation of nitrogenase was determined to be 0.6 and used to convert the results into moles of CO₂ produced per 2e^– transferred by nitrogenase to reduction of N₂. The results ranged from 2.6 to 3.4mol CO₂ produced per 2e^–. Carbon cost expressed as gC produced per gN reduced ranged from 4.5 to 5.8. The result for this actinorhizal tree symbiosis is in the low range of estimates for N₂-fixing actinorhizal symbioses and crop legumes. Methodology and comparisons of root nodule physiology among actinorhizal and legume plants are discussed.     

Growth characteristics and catalpol production in chinese foxglove (Rehmannia glutinosa Liboschitz) hairy roots transformed withAgrobacterium rhizogenes ATCC15834

Hairy root clones ofRehmannia glutinosa were established via transformation withAgrobacterium rhizogenes ATCC15834. To optimize the culturing conditions for both root growth and catalpol production, effects of various combinations of seven basal media, pH, and carbon sources were examined under darkness. The fastest root growth was obtained in an SH medium containing 4% sucrose (pH 5.8); the highest catalpol content (0.54% of dry weight) was achieved in a WPM medium supplemented with 4% sucrose (pH 5.8). Effects of plant growth regulators and chitosan were also investigated. IAA at 2 mg L^-1 significantly increased root lengths and the frequency of lateral roots. Chitosan (50 mg L^-1) and CA₃ (0.5 mg L^-1) induced catalpol production, with contents calculated at 0.7% dry weight and 0.65% dry weight, respectively.     

Growth,ionic balance,proton excretion,and nitrate reductase activity in Alnus and Hippophaë supplied with different sources of nitrogen

Summary Pre-cultivated, nodulated and non-nodulated plants of black alder (Alnus glutinosa) and sea buckthorn (Hippophaë rhamnoides ssp.rhamnoides) were grown on different N sources, with and without acidity control. Dry matter yields were lowest when plants were supplied with only NO ₃ ^– and were much greater when NH ₄ ⁺ was supplied either alone or in combination with NO ₃ ^– as long as the external pH was controlled; the final yields of the N₂-fixing plants were relatively low, especially withH. rhamnoides. Without acidity control, yields were greatly reduced in the presence of NH ₄ ⁺ .Proton or hydroxyl-ion effluxes, calculated on the basis of plant analyses, agreed well with measured excretion values. Without pH adjustment, the total proton efflux into the external solution was greater inA. glutinosa than inH. rhamnoides.Both species, but particularlyA. glutinosa, displayed the highest nitrate reductase activity in the roots.     

The physiology of spore-negative and spore-positive nodules ofMyrica gale

The physiology of spore-negative and spore-positive root nodules was investigated inMyrica gale L. grown in water culture in a growth chamber. Spore(–) nodules were induced withFrankia cultures and spore(+) nodules with crushed nodules. Gas exchange was measured in a flow-through system.The time course of acetylene reduction following addition of acetylene was essentially the same in both spore(–) and spore(+) nodules with a stable maximum between 2 and 4 minutes followed by a steep decline to a minimum (37% of the maximum) between 9 and 30 minutes depending on the plant. The minimum was followed by a partial recovery. Nodule CO₂ evolution showed a similar pattern but the minimum rate (83% of the maximum) was not nearly as low.Plants nodulated with one spore(–) and one spore(+) strain were compared at 6, 8 and 10 weeks after inoculation. At 6 weeks the spore(–) plants had 52% greater specific nitrogenase activity and 46% more biomass than the spore(+) plants. At 8 and 10 weeks, however, the differences between plants with spore(–) and spore(+) nodules became smaller.Plants nodulated with 4 spore(–) and 5 spore(+) strains were compared at 8 weeks after inoculation. Collectively the spore(–) plants exhibited a 32% greater specific nitrogenase activity, a 15% lower energy cost of nitrogenase activity (CO₂/C₂H₄), and invested 31% less biomass in nodules than the spore(+) plants. The spore(–) plants also produced 16% more biomass indicating that spore(–) strains are generally more desirable than spore(+) strains. However, two spore(+) strains were as effective as the spore(–) strains.     

Seasonal variations of the sexual reproductive growth and nitrogenase activity (C2H2) in matureAlnus glutinosa

Summary The seasonal variations of the growth of sexual reproductive organs and of the nitrogenase activity (acetylene reduction) of root nodules are surveyed in mature field alders (Alnus glutinosa). The growth of female catkins—pollinated in February-early March—takes place chiefly from June to August and the growth of immature male catkins from July to September. The nitrogenase activity steadily shows two periods of high rate—the first from late April to early June, the second in September–October-and a summer period of low rate when the female catkins and the seeds achieve the most part of their growth.The seasonal fluctuations of thein vitro/in vivo nitrogenase activity ratio showing the supply of metabolic factors in the root nodules as a likely cause of the variations of thein vivo nitrogenase activity, the possible competition for photosynthate allocation between the production of sexual organs and the nitrogen-fixing capacity in mature field alders is discussed.     

Study of the contribution of the shoot and/or root ofAlnus sp. in the compatibility between the host and a Sp+ Frankia strain using a grafting technique

Two alder species,Alnus glutinosa (L.) Gaertn. andAlnus incana (L) Moench, were inoculated with a Sp⁺ Frankia homogenate obtained fromA. incana root nodules. This inoculum formed effective nodules on the original host plant and ineffective nodules onA. glutinosa. Grafts between the two alder species were made to determine which part of the plant is involved in this phenomenon. The results obtained indicate that the compatibility between Alnus andFrankia is restricted to the root system.     

Nitrite utilization by Chaetoceros muelleri under elevated CO2 concentration

Chaetoceros muelleri (Lemn.) was cultured with nitrite (NO₂⁻) or nitrate (NO₃⁻) as the sole nitrogen source and aerated with air or with CO₂-enriched air. Cells of C. muelleri excreted into the medium nitrite produced by reduction of nitrate when grown with 100 μM NaNO₃ as nitrogen source. Accordingly, NO₂⁻ concentration reached 10.4 μM after 95 h at the low CO₂ condition (aerated with air); while the maximum NO₂⁻ concentration was only around 2.0 μM at the high CO₂ condition (aerated with 5% CO₂ in air), furthermore, after 30 h it decreased to no more than 1.0 μM. NO₂⁻ was almost assimilated in 80 h when C. muelleri was cultured at the high CO₂ condition with 100 μM NaNO₂ as sole nitrogen source. At the high CO₂ condition, after 3 h the activity of nitrite reductase was as much as 50% higher than that at the low CO₂ condition. It was indicated that enriched CO₂ concentration could inhibit nitrite excretion and enhance nitrite assimilation by cells. Therefore, aeration with enriched CO₂ might be an effective way to control nitrite content in aquaculture systems.