Effects of CaSO4 and NaCl on growth and nitrogen fixation ofLeucaena leucocephala

Effects and interactions of varying CaSO₄ and NaCl levels on growth and nitrogen fixation ofLeucaena leucocephala K8 were examined. Leucaena was grown in nutrient solution at four levels of CaSO₄ (0.5, 1.0, 2.5 and 5.0 mM) and NaCl (1, 25, 50 and 100 mM) in randomized blocks with five replications. While NaCl significantly reduced plant growth, additions of CaSO₄ increased plant height, leaf number, and biomass of salt treated plants. For the nonsaline treatments, high CaSO₄ levels slightly depressed growth, which contradicts suggestions that Leucaena has a high calcium requirement. A significant calcium/sodium interaction was not seen for nodule number or weight. Nodule number was significantly depressed by 100 mM NaCl and nodule weight of the salt stressed plants significantly increased as CaSO₄ concentration increased from 0.5 to 2.5 mM. Effects of NaCl and CaSO₄ on nitrogen content of plant parts were inconclusive. The promotion of Leucaena salinity tolerance by addition of CaSO₄ may be attributed to the effect of calcium in maintaing the selective permeability of membranes.     

The use of MES buffer in early nodulation studies with annual Medicago species

The usefulness of 2-(N-morpholino)ethanesulfonic acid (MES) to stabilize the pH of solutions in the range pH 5.5 to 7.0 during early growth and nodulation of annual Medicago (medic) species was investigated.In the first experiment, effects of MES concentrations (0, 1, 2, 5, 10 mM) on growth and nodulation of Medicago polymorpha L. and the stability of solution pH were investigated. In the second experiment we assessed the effect of MES on the growth and nodulation of three medic species (M. truncatula Gaernt., M. polymorpha and M. murex Willd.) at a range of starting pH levels (5.5, 6.0, 6.5 and 7.0) with different concentrations of MES buffer (0, 0.5, 10 mM). In a third experiment, the effects of the concentration of extra cations and the species (K-ion or Na-ion), used as hydroxide to bring solutions containing different MES concentrations to target pH were investigated.MES had no effect on growth at MES concentrations as high as 10 mM but nodule numbers were increased by concentrations of MES of 2 mM or greater. The presence of extra K-ion or Na-ion in solutions had no effect on plant growth or nodulation. With low MES concentrations (0.5 mM), solution pH stability was improved by daily titration and the use of a high nitrate to ammonium ratio (9 : 1) in solution. This combination of strategies maintained pH within a narrow range without effects on annual medic growth or nodulation.     

Effect of nodulation on the nitrate assimilation in vegetative soybean plants

Summary Nitrate assimilation in the first trifoliate leaf of vegetative soybean plants (Glycine max L. Merr, cv Hodgson) was studied in relation to nodulation. Nodulated and non-nodulated plants were grown in a nitrate medium (4 mM). As a control nodulated plants were grown in a nutrient medium without combined nitrogen. This study included measurements of the acetylene reduction activity of the whole plant and of thein vitro nitrate reductase, glutamine synthetase and glutamate dehydrogenase activities in the first leaf and of the nitrate concentration. Nitrate accumulation and nitrate reductase activity were depressed in nodulated plants; root growth was decreased in the presence of nitrate. The relationships between nitrate assimilation and nodulation are discussed.     

The effects of salinity on growth,nodulation and nitrogen fixation ofCasuarina equisetifolia

The growth, nodulation and nitrogen fixation ofCasuarina equisetifolia were compared at six levels (0–500mM NaCl) of salinity in sand culture. Dry weight of nodules, shoots and roots and N content of shoots increased at intermediate levels of salinity (50–100 mM) but decreased at 500 mM NaCl. Nodulation occurred at all NaCl levels, but at 500mM NaCl level, the nodule dry weight declined by 50% from the control. Increasing NaCl concentration of up to 200mM had little effect on the N₂-fixation rate, but at 500mM NaCl level the rate decreased to 40% of the control value.     

Sodium molybdate inhibits sulphate reduction in the anaerobic treatment of high-sulphate molasses wastewater

Summary Three concentrations (0.1 mM, 0.5 mM, and 1.0 mM) of sodium molybdate were added to continuously fed anaerobic upflow filters (1.01) treating a high-sulphate molasses wastewater which contained approximately 27.0 g chemical oxygen demand/l and 6.0 g sulphate/l. Sodium molybdate (0.1 mM) did not inhibit sulphate reduction by the filter. Higher concentrations (0.5 mM and 1.0 mM) inhibited sulphate reduction but methanogenesis was also slightly affected. The microflora of the filters adapted to the continuous presence of sodium molybdate (1.0 mM) and sulphate reduction was then evident. Addition of a higher concentration of sodium molybdate was then necessary to inhibit sulphate reduction but methanogenesis was also adversely affected.     

Involvement of cytokinin in the stimulation of nodulation by low concentrations of ammonium in Pisum sativum

Nodulation in pea (Pisum sativum L.) grown in hydroponic and sand culture systems is stimulated by low concentrations (<1.0 mM) of ammonium, but the physiological mechanisms underlying this stimulation are unknown. The current study involves a series of experiments, which investigate if the ammonium‐induced stimulation of nodulation involves changes in endogenous hormone (auxin and cytokinin) levels. P. sativum L. cv. Express was grown in growth pouches for 1 week with mineral N (0.5 and 2.0 mM NH₄⁺ or NO₃^–) or for 3 weeks exposed to exogenous indole‐3‐acetic acid (IAA) or 6‐benzylaminopurine (BAP) at a range of concentrations (10^‐9?10^‐5 M). Ammonium enhanced nodulation on the basis of both early whole plant (nodules plant^?1) and specific nodulation (nodules g^?1 root DW), especially in 0.5 mM treatment in which nodulation was approximately 4‐fold of the mineral‐N‐free control 1 week after inoculation. Correspondingly, the roots treated with ammonium contained much higher levels of t‐zeatin (Z) and lower t‐zeatin riboside (ZR) than that the control or nitrate‐treated plants. There was no significant difference in IAA levels between the control and ammonium treatments. Exogenous application of BAP for 3 weeks at concentrations of 10^‐7?10^‐5 M strongly inhibited nodulation. However, 10^?9 M BAP, but not IAA, significantly enhanced nodulation. These data support the theory that a relatively high ratio of cytokinin:auxin in roots is favourable for nodule initiation, but that an excessively high level of cytokinin inhibits nodulation. Based on these results we propose that stimulation of nodulation by low concentrations of ammonium may be mediated through increasing Z level in roots, which alters the balance of cytokinin and auxin, which in turn induces cortical cell divisions leading to nodule initiation.     

Metabolite effectors for short-term nitrogen-dependent enhancement of phosphoenolpyruvate carboxylase activity and decrease of net sucrose synthesis in wheat leaves

It has been demonstrated previously that field pea (Pisum sativum L. cv. Express) grown in hydroponic culture on a complete nutrient solution with low NH₄⁺ concentrations (<0.5 mM) will produce a larger than normal proliferation of nodules. Peas grown in the absence of mineral N in hydroponic culture have been shown to rapidly autoregulate nodulation, forming a static nodule number by 14 to 21 days after planting. The present study further characterizes the effect of NH₄⁺ concentration in hydroponic culture on nodulation and nodule growth. Peas were grown continually for 4 weeks at NH₄⁺ concentrations that were autoregulatory (0.0 mM), stimulatory (0.2 mM) or inhibitory (1.0 mM), or peas were transferred between autoregulatory or NH₄⁺ inhibited and stimulatory solutions after 2 weeks. The peas nodulated as expected when grown under constant autoregulatory, stimulatory or inhibitory concentrations of NH₄⁺. When peas were transferred from the inhibitory (1.0 mM) to the stimulatory solution (0.2 mM) a massive proliferation of nodule primordia over the entire root system was observed within 3 days of the transfer. When they were transferred from the autoregulatory (0.0 mM) to the stimulatory (0.2 mM) solution a 10-day delay occurred before a proliferation in nodule primordia occurred at distal regions of the root system. These findings support our hypothesis that low concentrations (<1.0 mM) of NH₄⁺ in hydroponic culture cause a suppression of autoregulation in pea. In addition, the temporal and spatial differences in nodule proliferation between transfer treatments demonstrate at a whole plant level that autoregulation and NH₄⁺ inhibition suppress early nodule development via different mechanisms.     

Soil moisture and potassium affect the performance of symbiotic nitrogen fixation in faba bean and common bean

Potassium (K) is reported to improve plant's resistance against environmental stress. A frequently experienced stress for plants in the tropics is water shortage. It is not known if sufficient K supply would help plants to partially overcome the effects of water stress, especially that of symbiotic nitrogen fixation which is often rather low in the tropics when compared to that of temperate regions. Thus, the impact of three levels of fertilizer potassium (0.1, 0.8 and 3.0 mM K) on symbiotic nitrogen fixation was evaluated with two legumes under high (field capacity to 25% depletion) and low (less than 50% of field capacity) water regimes. Plants were grown in single pots in silica sand under controlled conditions with 1.5 mM N (¹⁵N enriched NH₄NO₃). The species were faba bean (Vicia faba L.), a temperate, amide producing legume and common bean (Phaseolus vulgaris L.), a tropical, ureide producing species. In both species, 0.1 mM K was insufficient for nodulation at both moisture regimes, although plant growth was observed. The supply of 0.8 or 3.0 mM K allowed nodulation and subsequent nitrogen fixation which appeared to be adequate for respective plant growth. High potassium supply had a positive effect on nitrogen fixation, on shoot and root growth and on water potential in both water regimes. Where nodulation occurred, variations caused by either K or water supply had no consequences on the percentage of nitrogen derived from the symbiosis. The present data indicate that K can apparently alleviate water shortage to a certain extent. Moreover it is shown that the symbiotic system in both faba bean and common bean is less tolerant to limiting K supply than plants themselves. However, as long as nodulation occurs, N assimilation from the symbiotic source is not selectively affected by K as opposed to N assimilation from fertilizer.     

Ethyl-methane sulphonate (EMS) induced nodulation mutants of common bean (Phaseolus vulgaris L.) lacking effective nodules

Seed of white bean (Phaseolus vulgaris L. cv. OAC Rico) was treated with 0.04 M ethyl-methane sulphonate. Screening of the M₂ progeny from 175 M₁ lines in the presence of 1 mM nitrate revealed two nodulation mutants. One line was essentially non-nodulating in several tests, but small white nodules were observed occasionally in other tests with 16 separate Rhizobium strains. The other line formed tiny, creamy white, non-functional (ineffective) and tumor-like pseudo-nodules. The M₃ and M₄ progenies were fertile and bred true.     

Further investigation of the roles of auxin and cytokinin in the NH4+-induced stimulation of nodulation using white clover transformed with the auxin-sensitive reporter GH3:gusA

Although mineral N (nitrate and ammonium) is believed to have generally negative effects on nodulation in legume–rhizobia symbioses, previous studies have shown that low, static concentrations of ammonium stimulate nodulation in pea, and that this enhancement may be due to an elevation in cytokinin to auxin levels in roots. Here, the effects of ammonium (0.0, 0.1, 0.5 and 2.5 mM) on nodulation and auxin levels were investigated in wild‐type (WT) white clover (Trifolium repens cv. Haifa) and its transformants (lines 38 and 41) which contain the auxin‐sensitive reporter gene (GH3:gusA). The effects of exogenous application (10^?10, 10^?9 and 10^?8 M) of the cytokinin 6‐benzylaminopurine (BAP) were also assessed. Whole‐plant nodulation (nodules plant^?1) and dry weight (DW)‐specific nodulation (nodules g^?1 root DW) were stimulated (up to 49%) in all white clover lines by 0.1 mM NH₄⁺. This represents the first confirmation of an NH₄⁺‐induced stimulation of DW‐specific nodulation in a species other than pea. At 2.5 mM NH₄⁺, the effect was lost on whole‐plant nodulation and was inhibitory on DW‐specific nodulation. Rhizobial inoculation resulted in a decline in the expression of GH3:gusA in root tips as expected; however, ammonium treatment did not affect GH3 expression in any root zones. Exogenous application of BAP at 10^?9 and 10^?8 M stimulated whole‐plant and DW‐specific nodulation in wild‐type white clover to a similar degree as treatment with 0.1 mM NH₄⁺. These results support our previous hypothesis that the stimulation of nodulation by low concentrations of ammonium involves the alteration of the ratio of cytokinin to auxin, specifically by increasing cytokinin.     

Effects of substrate nitrate concentration on symbiotic nodule formation in actinorhizal plants

The response ofAlnus glutinosa, Casuarina cunninghamiana, Elaeagnus angustifolia andMyrica cerifera to a range of substrate nitrogen levels in solution, in relation to plant growth, infection, nodulation and root fine structure was studied. Nine concentrations of potassium nitrate ranging from 0.05 to 3.0 mM, were tested on each of the species. Plants were inoculated withFrankia pure cultures after a two week exposure to one of the nine levels of added nitrate. After six more weeks with constant exposure to nitrate, plants were harvested and assayed. With the exception of Myrica, regression analyses of whole plant dry weights as a function of added nitrate were highly significant. There was a tendency for nodulated plants grown at intermediate levels of added nitrate to exhibit higher relative growth rates, probably due to the additive effect of substrate nitrogen and fixation of atmospheric nitrogen. The mean numbers of nodules per plant were, with the exception of Alnus, significantly higher at intermediate levels of added nitrate, as were mean nodule dry weights. A highly significant inverse relationship between nodule weight as a percentage of whole plant weight was found in Elaeagnus and Myrica. The observed response of Elaeagnus to added nitrate compared to other actinorhizal plants appears to demonstrate that root hair infected plants are much more sensitive to the inhibitory effects of added nitrate than plants infected by intercellular penetration. A sharp reduction in the presence of root hairs at high concentrations of nitrate was observed. This indicates that the inhibition of nodulation in some actinorhizal plant species results from nitrate induced root hair suppression.     

Bacterial growth rate and growth pouch nodulation profile differences as possible ways of Bradyrhizobium japonicum strain screening for low P soils

This work studied the effects of P fertilization on nodulation of field-grown soybean by two Bradyrhizobium strains (SMGS₁ and THA₇), and checked if differences between strains were consistent with bacterial growth and growth pouch nodulation ability in response to P availability. In the field, nodule dry weight and nitrogen fixation activity of inoculated soybean were studied on typical acid soils of Thaïland at the flowering (R₁) stage and at the end of grain filling. Grain yield, growth and phosphorus content were recorded. The bradyrhizobial strains were cultivated in culture medium, and growth parameters recorded. Nodulation patterns were observed during growth pouch experiments: infective root cells were inoculated with strains cultivated at two P concentrations in their culture media, namely 1 M and 1 mM. Ten days after inoculation, the position of each nodule was measured relative to the root tip (RT) mark, expressed relative to the smallest emerging root hairs-RT distance in the nodulation frequency profile, and the consistency of responses was tested. In the field, on P deficient soils, dry weight of nodules was higher with Bradyrhizobium japonicum strain SMGS₁ than with strain THA₇. P supply increased the number and dry weight of nodules for both strains, with a higher dry weight response for THA₇ than for SMGS₁. It also had a positive effect on tissue phosphorus status and grain yield at R₈ stage. In growth media, significant differences were recorded between strains under P-limiting conditions: The growth rate was higher for strain SMGS₁, as well as the maximal number of bacterial cells supported. With growth pouch, inoculating plants with bacteria grown in P-deficient medium resulted in a less intense nodulation of roots by THA₇, and with nodules appearing earlier on roots than in the case of SMGS₁. At 1 mM P, there was no significant difference between strains. Thus, strain THA₇ is more affected by P deficiency than strain SMGS₁. Although P was not supplied in the same way in the soil and in the growth pouch experiments, this consistency of behaviour between work scales indicates that phosphorus availability is a key component for a successful inoculation. Furthermore, the study of bacterial growth rates and nodulation profile represents an interesting step for bacterial screening for low P soils. [-11pt]     

Effect of CaSO4 and NaCl on mineral content ofLeucaena leucocephala

The effects of varying CaSO₄ and NaCl levels on the nutrient content ofLeucaena leucocephala were established by examining the concentrations of Na, Ca, Cl, K and Mg in leucaena roots, stems and leaves. Leucaena was grown in nutrient solution at four levels of CaSO₄ (0.5, 1.0, 2.5 and 5.0 mM) and NaCl (1, 25, 50 and 100 mM), in randomized blocks with five replications. Leucaena excluded sodium from stems and leaves when NaCl concentration was 50 mM or less. Sodium uptake decreased as CaSO₄ concentration increased. Calcium uptake was affected by NaCl concentration when substrate CaSO₄ concentration was 0.5 mM. At this level, 100 mM NaCl caused a marked decrease in leaf calcium and a marked increase in leaf Cl. In all other treatments, Cl uptake was not affected by CaSO₄ concentration. Potassium uptake was strongly depressed as NaCl concentration increased at low Ca concentration, but this effect was offset at high Ca. Magnesium uptake decreased as CaSO₄ levels increased.     

Cinnamate toxicity expression on phenylalanine ammonia-lyase activity,germination and growth of cucumber (Cucumis sativis) seedlings

Low pH (5.2) decreased nodule number and acetylene reduction. Aluminium further depressed those parameters in theRhizobium leguminosarum-Pisum sativum associations examined. In the Al-treated plants nodule formation by strains 128C53 and 128C30 was not affected by 3 or 15 and 30 or 60 μM Al, respectively, as compared with the number of nodules on plants grown at pH 5.2 in the absence of Al. However, improved nodulation rates by those strains did not enhance plant dry weight or reduced nitrogen content. No differences in nitrogenase activity were found among strains of nodulating plants grown at the same aluminium level. These results suggest that Al-ions affected specifically nitrogenase activity and that this effect was primarily responsible for the reduction in plant growth.     

Influence of sulphur-containing compounds on the growth of Methanosarcina barkeri in a defined medium

Summary Optimal growth of Methanosarcina barkeri occurred in a defined medium containing methanol when 2.5–4 mM sodium sulphide was added giving a concentration of 0.04–0.06 mM dissolved sulphide (HS^–+S^2–. When the sulphide concentration was too low for optimal growth (e.g., 0.1 mM Na₂S added) the addition of the redox resin Serdoxit acted as a sulphide reservoir and caused a significant stimulation of growth. Furthermore it could be demonstrated that iron sulphide, zinc sulphide or L-methionine could also act as sulphur sources while the addition of sodium sulphate to sulphide-depleted media failed to restore growth. The amino acid L-cysteine (0.85 mM) stimulated growth but could not replace Na₂S.Under optimal cysteine-and sulphide concentrations the generation time of this strain was about 7–9 h during growth on methanol, giving a growth yield of about 0.14 g/g methanol consumed. Different M. barkeri strains were also able to grow under these conditions on acetate (30–50 h doubling time) without a significant lag-phase and with complete substrate consumption even though the inoculum was grown on methanol or H₂–CO₂. When methanol and acetate were present as a mixture in the medium both were used simultaneously.     

Selection of sulphur sources for the growth of Butyribacterium methylotrophicum and Acetobacterium woodii

Sulphide and cysteine inhibited growth of batch cultures of Butyribacterium methylotrophicum at moderate concentrations (above 0.5 mM) during growth on glucose (10 mM). The ability of several sulphur sources to replace sulphide was tested in cultures of B. methylotrophicum or Acetobacterium woodii. With sulphite (1 mM), thiosulphate (0.5 mM), elemental sulphur, and dithionite (1 mM), but not sulphate (1 mM), cultures of both organisms grew and produced some sulphide. With elemental sulphur as the sulphur source, toxic levels of sulphide accumulated. Optimal levels for the cultivation of B. methylotrophicum with sulphite were 0.5–2.0 mM, but at higher concentrations the growth rate decreased rapidly, while with dithionite up to 4.0 mM the growth rate was relatively unaffected. In chemostat cultures of B. methylotrophicum with dithionite (1 mM) as the sulphur source and glucose as the limiting substrate, dilution rates up to 0.40 h^–1 were obtained. Thiosulphate could only be used in batch cultures in combination with the reductant titanium(III)nitriloacetate, but in continuous cultures the addition of the reductant to the reservoir was not necessary, because once growth had started enough sulphide was produced to keep the fermentor reduced. The maximum growth rate of B. methylotrophicum with thiosulphate in batch and continuous culture was 0.26 h^–1. Both thiosulphate and dithionite are more convenient sulphur sources than sulphide, but dithionite is more versatile because of its reductive properties and the faster growth it allows.Offprint requests to: T. A. Hansen     

Effect of juglone on growthin vitro ofFrankia isolates and nodulation ofAlnus glutinosa in soil

Summary In vitro growth (total protein content) of 5Frankia isolates was significantly inhibited at 10^–4 M juglone (5-hydroxy-1, 4-napthoquinone) concentration, but the degree of inhibition varied with theFrankia isolate. Isolates fromAlnus crispa [Alnus viridis ssp.crispa (Ait.) Turril] were most tolerant of 10^–4 M juglone relative to controls, while an isolate fromPurshia tridentata (Pursh.) D.C. was most inhibited, displaying a dramatic decrease in growth and greatly altered morphology.Nodulation of black alder [Alnus glutinosa L. (Gaertn.)] in an amended prairie soil inoculated with aFrankia isolate from red alder (Alnus rubra Bong.) was significantly decreased by the addition of aqueous suspensions of 10^–3 M and 10^–4 M juglone. This decrease was partially independent of decreased plant growth. The addition of an equal volume of sand to the soil mixture further decreased nodulation of black alder.Frankia inoculation of the soil mixtures significantly increased the total number of nodules formed per seedling, and the degree of differences in seedling nodulation owing to juglone and soil treatments.     

Phosphorus-induced micronutrient disorders in hybrid poplar

The effect of calcium on the nodulation of lucerne was studied using EGTA, a specific calcium-chelator. First, the effects of the chelator were tested on hydroponically grown plants at pH 7.0. Optimal numbers of nodules were obtained in nutrient solution containing 0.2 mM CaCl₂. When 0.4 mM EGTA was given additionally, nodulation was completely inhibited. Nodulation was restored specifically with CaCl₂, but not with MgCl₂. For studies in an acid soil (pH-H₂O 5.2), lucerne seedlings were grown in rhizotrons. 67% of the seedlings became nodulated when the soil around the seed was neutralized locally with 1.0 μmol of K₂CO₃ in drops of 12 μL volume. When native calcium was removed with 2 μmol of EGTA, nodulation was reduced to 12%. However, addition of EGTA to soil resulted in a drop of pH from 6.1 to 5.2. A phosphate buffer could also not keep soil-pH sufficiently stable. Such pH-decreases could be avoided by placing agar blocks containing 6 μmol of EGTA for three hours on freshly developed roots. This treatment reduced nodulation from 87% to 32%, with soil-pH lowering only from 6.2 to 6.0. Nodulation could be restored by adding 2 μmol of CaCl₂. The depletion of soil-calcium could depress nodule formation only during the first day after inoculation.     

Salt resistance of chickpea genotypes in solutions salinized with NaCl or Na2SO4

Summary To assess the potential for developing a salt resistant cultivar of chickpea (Cicer arietinum L.) 160 genotypes were screened for percent survival after 9 weeks in greenhouse solution cultures, with 50 mM NaCl or 25 mM Na₂SO₄. All plants grew well in the sulfate treatment but only cv. L-550 survived the chloride treatment. Salt damage appeared and developed slowly. To check these apparent effects of cultivar and kind of anion, three genotypes including cv. L-550 were then grown in solutions with isoosmotic NaCl or Na₂SO₄ at three levels (−0.044, −0.088, and −0.132 MPa), and in a separate experiment cv. L-550 was grown with NaCl and Na₂SO₄ at four levels: 10, 20, 30 and 50 mM Na. Salt composition affected shoot weight less than salt level or cultivar did. Shoot dry weight was only slightly less in chloride treatments than in isoosmotic sulfate, and for the least sensitive cultivar (L-550) this held only at the highest salt level, corresponding to that in the screening trial. Further, sensitivity to sulfate and to chloride was equal when sodium concentrations in shoots were equal, regardless of anion compositions of media. Shoot Na concentration was a useful negative indicator of growth under salt stress regardles of cultivar, and may be a useful tolerance indicator also for other species that neither accumulate nor efficiently exclude Na.     

Increasing NaCl and CaCl2 concentrations in the growth medium of quince leaves: II. Effects on shoot regeneration

Summary The effects of NaCl and CaCl₂ on shoot regeneration from quince (Cydonia oblonga BA L29 clone) leaves were investigated. Caulogenesis was induced on in vitro-grown leaves treated for 2d in liquid Murashige and Skoog (MS) medium with 11.3 μM 2,4-dichlorophenoxyacetic acid and cultured on MS gelled medium supplemented with 4.5 μM thidiazuron and 0.5 μM naphthaleneacetic acid. Three experiments were performed: in the first, we compared the effects of NaCl at 0, 25, 50, 100, and 200 mM in factorial combination with 3, 9, and 27 mM CaCl₂. In the second, NaCl was tested at 0, 5, 10, 20, 40, and 80 mM with CaCl₂ at 0.3, 1.0, and 3.0 mM. The third experiment was carried out with the same experimental design as the second one but replacing NaCl with Na₂SO₄. Shoot regeneration was evaluated after 50 d of culturing: 25 in darkness and 25 in white light. In the first experiment, shoot regeneration was very poor and was observed only at the lower salt concentrations. In the second experiment, the percentages of caulogenic leaves were much higher, but decreased with increasing NaCl concentration. The more pronounced negative effect of the highest NaCl concentrations appeared to be partly mitigated by CaCl₂ at 1 and 3 mM. The presence of 3 mM CaCl₂, in the experiment with Na₂SO₄, appeared to be even more effective in reducing the adverse effect of sodium stress on caulogenesis. This result was attributed to the lower Cl⁻ concentration in the growth medium, which resulted from replacing NaCl with Na₂SO₄. NaCl applied at low concentrations (5 and 10 mM) in combination with 3 mM CaCl₂ exerted a favorable effect on adventitious shoot regeneration. As regards the Na⁺ and Ca²⁺ interaction, when the Na⁺/Ca²⁺ ratio was below roughly 35 and 20, with NaCl and Na₂SO₄, respectively, at least 60% of leaves showed regenerating capacity, but optimal values of this ratio were not derived.