Exogenous Nitrate as a Terminal Acceptor of Electrons in Rice (Oryza sativa) Coleoptiles and Wheat (Triticum aestivum) Roots under Strict Anoxia

To elucidate the physiological role of exogenous nitrate under anaerobic conditions, we studied the effect of 10 mM KNO₃ on the mitochondrial ultrastructure in rice (Oryza sativa L.) coleoptiles and in wheat (Triticum aestivum L.) roots, detached from four-day-old seedlings, under strict anoxia. In wheat roots, following 6-h-long anoxia in the absence of exogenous nitrate, the mitochondrial membranes were partially degraded and, after 9 h under anoxia, the mitochondrial membranes and the membranes of other organelles were completely destroyed. In rice coleoptiles, the partial membrane degradation was observed only after 24 h and their complete breakdown after 48 h of anaerobiosis. In the presence of exogenous nitrate, no membrane destruction was noticed even after 9 and 48 h of anaerobiosis in wheat roots and rice coleoptiles, respectively. These results indicate that exogenous nitrate exerts protective action as a terminal electron acceptor, alternative to the molecular oxygen. Our findings are compared with the results of other researchers concerning the adverse or favorable nitrate action on plant growth, metabolism, and energy status under anaerobic stress.     

Peroxisomes in Rice Coleoptiles Grown in Air and in Anoxia

Rice coleoptiles grow under anoxia. When the ultrastructure of anoxic coleoptile cells was examined, it was seen that most organelles maintain their integrity, with the exception of peroxisomes (unspecialized type). The lack of O₂ greatly reduced the number of these organelles and altered the ultrastructure of the remaining ones. To examine the effect of O₂ on peroxisome development in more detail, coleoptiles grown in air were transferred to N₂ and anoxic coleoptiles were transferred to oxygen. Marker enzyme activity was measured in entire coleoptiles as well as in the isolated organelles. As expected, anoxia greatly depressed enzyme activity when imposed from the beginning of the germination process, while it had a lesser effect when imposed for only two days on aerobic seedlings. When coleoptiles were grown constantly under N₂, the density of the organelles was 1.216 g/cm³, while the corresponding aerobic organelles showed a buoyant density of 1.241 g/cm³. When transferred to air the anoxic peroxisomes reached the intermediate density of 1.227 g/cm³. The results confirm the particular sensitivity of rice peroxisomes to O₂ availability.     

Effects of ethanol on growth of rice seedlings

Effects of ethanol, the end product of ethanolic fermentation, on the growth of rice (Oryza sativa L.) seedlings were determined as a means of evaluating growth responses under anoxia. The ethanol concentrations in roots and coleoptiles of the seedlings subjected to 48 h-anoxia, and in their culture medium were 23 and 32 µmol g^–1 fresh weight, and 19 µmol ml^–1, respectively. The growth of the roots and coleoptiles of the seedlings was restricted by exogenous ethanol at concentrations above 50 mM and 100 mM, respectively, suggesting that the roots are more sensitive to ethanol than the coleoptiles.     

Anoxia tolerance and α-amylase activity in four rice cultivars

The relationship between anoxia tolerance and reserved carbohydrate catabolism was investigated in four rice (Oryza sativa L.) cultivars subjected to a 48-h anoxic stress. The coleoptile elongation of all cultivars was suppressed by anoxic stress, however, the elongation of cvs Koshihikari and Awa-akamai was much greater than that of cvs Touzoumochi and Asahimochi. The anoxic coleoptiles of cvs Koshihikari and Awa-akamai contained about 2-fold as much ATP as those of cvs Touzoumochi and Asahimochi. Ethanol production in the anoxic coleoptiles of cvs Koshihikari and Awa-akamai was about 2-fold as much as that of cvs Touzoumochi and Asahimochi, which suggests that ethanolic fermentation is probably more active in cvs Koshihikari and Awa-akamai than in cvs Asahimochi and Touzoumochi. Activity of α-amylase, which catabolizes starch to soluble sugars, in endosperms of cvs Koshihikari and Awa-akamai was about 2-fold that of cvs Touzoumochi and Asahimochi, and soluble sugar concentration in the coleoptiles of cvs Koshihikari and Awa-akamai was about 3-fold greater than that of cvs Touzoumochi and Asahimochi. Soluble sugar concentration and ethanol production rate in the coleoptiles of rice seedlings were correlated well with α-amylase activity in their endosperms, which were also correlated well with anoxia tolerance with respect to the coleoptile elongation and ATP concentration in the coleoptiles. These results suggest that the ability to degrade starch to soluble sugar by α-amylase in endosperm may be important for the anoxia tolerance in rice coleoptiles and it may serve to distinguish the anoxia tolerance of rice coleoptiles.     

Mitochondrial Ultrastructure of Three Hygrophyte Species at Anoxia and in Anoxic Glucose-Supplemented Medium

Mitochondrial ultrastructure of excised roots of Alisma plantago-aqisaticaL., Lycopus europaeus L and Glyceria fluitans L. were electron-microscopicallystudied at anoxia and in anoxic glucose- supplemented mediumin order to find Out if the roots of the three hygrophytes growingon water-logged anaerobic soils have an increased resistanceto anoxia. Irreversible destruction of mitochondrial membranes and othersubcellular structures was shown to occur in the above plants'roots after 24 h at anoxia or in anoxic glucose-supplementedmedium. Only in roots of Glyceria had exogenous glucose a protectiveaction, yet in this case, too, a 48 h anacrobic exposure resultedin a deep-going degradation of cell ultrastructure. It is concluded that though the plants in question grow on soilsdevoid of O₂ their roots avoid anaerobiosis through translocationof O₂ from aerated parts, which appears to explain why theseplants have not developed a biochemical mechanism of adaptationto anaerobiosis in the process of evolution. Key words: Anaerobiosis, hygrophytes, mitochondrial ultrastructure     

Pyruvate metabolism in rice coleoptiles under anaerobiosis

Relative importance of ethanolic, lactate and alanine fermentation pathways was estimated in coleoptiles of rice seedlings (Oryza sativa L.) subjected to anoxic stress. The in vitro activities of alcohol dehydrogenase (ADH, EC 1.1.1.1), pyruvate decarboxylase (PDC, EC 4.1.1.1) and alanine aminotransferase (AlaAT, EC 2.6.1.2) in the coleoptiles increased in anoxia, whereas no significant increase was measured in lactate dehydrogenase (LDH, EC 1.1.1.27) activity. At 48 h, the ADH, PDC and AlaAT activities in anoxic coleoptiles were 62-, 15- and 7.6-fold greater, respectively, than those in the presence of oxygen. Ethanol and alanine in the coleoptiles accumulated rapidly under anoxia, increasing by 48 h, 57- and 5.6-fold compared with those in the presence of oxygen, respectively. However, lactate concentration did not increase and no initial burst of lactate production was detected. The relative ratio of carbon flux from pyruvate to ethanol, lactate and alanine in anoxic coleoptiles was estimated to be 92, 1 and 7% of the total carbon flux, respectively. These results suggest that the potential carbon flux from pyruvate to ethanol may be much greater than the potential flux from pyruvate to lactate and alanine in rice coleoptiles during anoxia.     

Evidence for down-regulation of ethanolic fermentation and K+ effluxes in the coleoptile of rice seedlings during prolonged anoxia.

Ethanolic fermentation, the predominant catabolic pathway in anoxia-tolerant rice coleoptiles, was manipulated in excised and 'aged' tissues via glucose feeding. Coleoptiles with exogenous glucose survived 60 h of anoxia, as evidenced by vigorous rates of K+ and phosphate net uptake and growth of roots and shoots when re-aerated. In contrast, coleoptiles without exogenous glucose showed net losses of K+ and phosphates starting 12 h after anoxia was imposed and these did not recover fully when re-aerated after 60 h of anoxia. Ethanol production (micromol x g(-1) FW x h(-1)) declined from about 7.5 during the first 12 h of anoxia to 5 or 2.2 after 48-60 h, in coleoptiles with or without exogenous glucose, respectively. Carbohydrate concentrations changed only slightly in anoxic coleoptiles with exogenous glucose due to net glucose uptake at 2.6 micromol x g(-1) FW x h(-1). Ethanolic fermentation, and therefore ATP production, may have been down-regulated after an initial period of acclimation to anoxia in coleoptiles with exogenous glucose. Maintenance requirements for energy were assessed to be 3.4-7.6-fold lower in these anoxic coleoptiles than published estimates for non-growing aerated leaf tissues. A modest part of the required economy in energy consumption would have been derived from diminished ion transport; anoxia reduced K+ and phosphate net uptake by 70-90% in these coleoptiles. K+ efflux was 10-fold lower in anoxic than in aerated coleoptiles with exogenous glucose. Using the unidirectional efflux equation, the membrane permeability to K+ was estimated to be 17-fold lower in anoxic than in aerated coleoptiles, presumably due to predominantly closed K+ channels.     

Root contribution to nitrate reduction in barley seedlings (Hordeum vulgare L.)

Summary The leaf and root nitrate reductase activities were measured in 7 day-old barley seedlings by anoxic nitrite accumulation in darkness, during 48h after the transfer from a N-starved medium to a 1.5 mM K¹⁵NO₃ medium. Thisin situ nitrate reduction was compared with the¹⁵N incorporation in the reduced N fraction of the whole seedlings.The nitrate reduction integrated fromin situ measurements was lower than the reduced¹⁵N accumulation. The rootin situ nitrate reductase activity seemed to account for only the third of the real root nitrate reduction, which may have been responsible for the overall underestimation. This discrepancy was partly explained by the ability of the root to reduce nitrite in an anoxic environment.These results suggest that, after correction of thein situ estimation of the nitrate reduction. the roots contribute to about 50% of the total assimilation.     

Effect of nitrate on water transfer across roots of nitrogen pre-starved maize seedlings

The addition of 10 mM KNO₃ to the solution bathing the roots of young nitrogen-starved seedlings of Zea mays L. enhanced root water transfer within 15 h, compared with 10 mM KCl addition. The free exudation flux was 2.2–3.9 times higher in excised KNO₃-treated roots than in KCl-treated ones. Cryo-osmometry data for xylem sap suggested that, compared with chloride, nitrate treatment increased the steady solute flux into the xylem, but did not modify the osmotic concentration of sap. Root growth was not significantly modified by nitrate within 15 h. Root hydraulic conductances were measured by using either hydrostatic-pressure or osmotic-gradient methods. During hydrostatic experiments, the conductance (k_p), which is thought to refer mainly to the apoplasmic pathway, was 1.6 times larger in KNO₃-than in KCl-treated plants. From experiments in which polyethylene glycol (PEG) 8000 was used as external osmolyte, osmotic conductances (k_s) were found to be smaller by 5–20 times than k_p for the two kinds of plants. The KCl-treated roots were characterized by a low k_s which was the same for influx or efflux of water. By contrast, KNO₃-treated roots exhibited two distinct conductances k_s1 and k_s2, indicating that influx of water was easier than efflux when the water flow was driven by the osmotic pressure gradient. Infiltration of roots with KNO₃ solution supported the idea that nitrate might enhance the efficiency of the cell-to-cell pathway. The low k_s value of KCl-treated roots and the existence of two contrasting k_s values (k_s1 and k_s2) for KNO₃-treated roots are discussed in terms of reversible closing of water channels.     

Effect of inorganic N on the population,in vitro colonization and morphology of Acetobacter diazotrophicus (syn. Gluconacetobacter diazotrophicus)

We investigated whether Acetobacter diazotrophicus (syn.Gluconacetobacter diazotrophicus) could be recovered only from sugarcane plants either with low or no application of fertiliser N. We report here the enrichment and enumeration of A. diazotrophicus from high N-fertilised samples where high heterotrophic populations reduce the numbers of A. diazotrophicus ultimately diminshing its isolation frequency as reported earlier. The growth medium of micropropagated sugarcane seedlings of the varieties Co 8021, Co 86249, Co 86010, Co 86032, and Co 87025 was amended with potassium nitrate, ammonium nitrate, ammonium chloride and urea. The colonisation and AR activity of A. diazotrophicus were affected in the presence of high levels (25 mM) of ammonium chloride and ammonium nitrate but remained unaffected in low levels of N (i.e 1/10th of MS liquid medium) and with high levels of potassium nitrate (25 mM) and urea (500 ppm). A. diazotrophicus was detected in the inoculated plants both at low and high levels of N based on the amplification of a specific 16S rRNA gene fragment using PCR based method targeting a stretch of 445 bp with primers AC and DI. High levels of N in the growth medium induced morphological changes on A. diazotrophicus cells resulting in long pleomorphic cells. The percentage of pleomorphic cells was in the decending order from NH₄NO₃, NH₄Cl, KNO₃, and urea. These changes were more prominent in ammonium chloride and ammonium nitrate than potassium nitrate, urea and N free medium. The morphological changes and the increased heterotrophic populations may play a role on the survival ofA. diazotrophicus in high N-fertilised samples/environments.     

Effect of nitrates and sucrose on the induction of nitrate reductase in etiolated seedling leaves from selected barley genotypes in darkness

The parental genotypes, cv. Aramir and R567 line, as well as the selected DH lines C23, C47/1, C41 and C55, growing in darkness differed significantly in the level of NR activity in crude leaf extracts independently of nitrate concentration in the medium. The highest activity of the enzyme was found in the line C23. When plants grew on the medium with 0.5 mM KNO₃, NR activity in that genotype was almost 10-fold higher than in the parents and lines C41, C55 and also 3.5-fold higher than in the line C47/1. An increase of nitrate concentration in the medium to 10 mM caused a significant increase of NR activity in all the genotypes under study. In the line C23 this enzyme activity was only 20% lower than that found previously in the green leaves of that genotype in light. NR from the leaves of C23 and C41 lines was thermally unstable under in vitro conditions. This enzyme in the leaf extracts from the line C23 was characterized by a considerably lower unstability. The lines DH C23 and C41 growing in the dark on the medium with 0.5 mM KNO₃ did not differ in nitrate accumulation in leaves, whereas a larger nitrate content was found in the leaves of the line C41 when it grew on the medium with 10 mM KNO₃. Independently of nitrate concentration in the medium, leaves of the line C23 were found to have a higher sucrose content than those of the line C41. Excised, etiolated leaves of barley treated with 0.5 and 10 mM KNO₃ in dark under conditions favorable to transpiration had a low NR activity. Leaf treatment with a solution containing 10 mM KNO₃ + 0.2 M sucrose caused, on the average, a 13-fold increase of NR activity in comparison to leaves treated only with 10 mM KNO₃ and about a 6-fold increase of this enzyme in comparison to leaves treated with 0.5 mM KNO₃ + 0.2 M sucrose.     

Influence of ammonium and nitrate nitrogen on nitrogenase activity of pea plants as affected by light intensity and sugar addition

Summary Addition of ammonium chloride or potassium nitrate to nodulated pea plants resulted in a decrease in acetylene-reducing activity. Both nodule growth and specific activity of the nodules were diminished. Acetylene-reducing activity of isolated bacteroids, treated with EDTA-toluene and supplied with ATP and dithionite, had not decreased after a 3-day treatment of the plants with NH₄Cl or KNO₃. The effect of combined nitrogen could be counteracted by raising the light intensity or by the addition of sucrose to the growth medium. The latter treatment reduced the nitrogen uptake by the plants. It is concluded that combined nitrogen affects symbiotic nitrogen fixation via the carbohydrate supply to the bacteroids.     

Enhanced In Vitro Plantlet Regeneration from Mature Embryo-derived Primary Callus of a Basmati Rice Cultivar Through Modification of Nitrate-nitrogen and Ammonium-nitrogen Concentrations

Mature-embryo derived primary calli of the basmati rice (Oryza sativa L.) cv Karnal Local showed significant enhancement in in vitro green-plantlet regeneration efficiency through modification of nitrogen content of the callusing medium. Using KNO₃ as the source of nitrate nitrogen and (NH₄)₂SO₄ as the source of ammonium nitrogen, forty-five media combinations involving 9 levels of KNO₃ (0–40 mM) and 5 concentrations (0–6.5 mM) of (NH₄)₂SO₄ were examined. The highest frequency of plantlet regeneration (100%) and a maximum number of green-plantlets (～ 7) per embryo-derived primary callus was obtained in calli derived from the medium having 35 mM KNO₃ and 5 mM (NH₄)₂SO₄. Higher concentrations of KNO₃ and/or (NH₄)₂SO₄ showed a decline in the regeneration efficiency. It was also observed that although the nitrogen content of the callus induction medium had a profound effect on the regenerability of the callus, the nitrogen composition of the regeneration medium also affected it significantly.     

The Response of Sugarcane (Saccharum officinarum) Cultured Cells to Anoxia and the Selection of a Tolerant Cell Line

The effect of anoxia on the sugarcane (Saccharum officinarum L.) cultured cells was studied in order to elaborate a technique for in vitro selection of cell lines, which would be tolerant to anaerobic stress. Inhibitory and lethal doses of anaerobic incubation were established from the state of the mitochondrial ultrastructure during the anaerobic incubation of cells either with or without exogenous glucose, as well as from the pattern of the post-anaerobic callus growth. An intact state of the mitochondrial ultrastructure and the viability of some cells in the presence of 3% glucose were shown to be maintained for at least 14 days of anaerobic incubation, while the index of post-anaerobic growth decreased by almost 50% even after 72-hour-long anaerobiosis. In the absence of exogenous glucose, a marked destruction of mitochondria and a twofold decrease in the callus growth index were observed as early as after six-hour-long anaerobic stress. A 48-hour-long incubation under these conditions resulted in the maintenance of the intact ultrastructure only in 7–10% of cells, while a 96-hour-long anaerobiosis brought about the complete degradation of the subcellular structure and cell death. A 48-hour-long anaerobiosis without exogenous glucose was chosen for selecting the anoxia-tolerant cell lines. After three cycles of selection, the anoxia tolerance of the selected cell line exceeded the respective index of the initial callus several-fold. In selected line, about 50% of cells retained viability and could resume growth even after 96-hour-long anaerobic incubation. The experimental results obtained were used to determine the possible causes of the heterogeneity of callus cells as regards their anoxia resistance.     

Anoxia tolerance in rice seedlings: exogenous glucose improves growth of an anoxia-'intolerant', but not of a 'tolerant' genotype

This study demonstrated that, in rice seedlings, genotypic differencein tolerance to anoxia only occurred when anoxia was imposedat imbibition, but not at 3 d after imbibition. When seeds wereimbibed and grown in anoxia, IR22 (anoxia-‘intolerant’)grew much slower and had lower soluble sugar concentrationsin coleoptiles and seeds than Amaroo (anoxia-‘tolerant’),while Calrose was intermediate. After 3 d in anoxia, the sugarconcentrations in embryos and endosperms of anoxic seedlingswere nearly 4-fold lower in IR22 than in Amaroo. Sugar deficitin the embryo of IR22 is presumably due to the limitation ofsugar mobilization rather than the capacity of transport asshown by similar sugar accumulation ratios of 1.8 between embryoand endosperm in IR22 and Amaroo at 3 d in anoxia. With 20 molm^–3 exogenous glucose, coleoptile extension and freshweight increments in anoxic seedlings of IR22 were much closerto those in the two other genotypes, nevertheless protein concentrationremained lowest on a fresh weight basis in the coleoptiles ofIR22; indicating that protein synthesis has a lower priorityfor energy apportionment during anoxia than processes crucialto coleoptile extension. In contrast to these responses to anoxiaimposed at imbibition, IR22 had nearly the same high toleranceto anoxia as Calrose and Amaroo, when anoxia was imposed onseedlings subsequent to 48 h aeration followed by 16 h hypoxicpretreatment. In fact, coleoptiles of anoxic IR22 had highersugar concentrations and grew faster than Calrose, and exogenousglucose had no effect on the coleoptile extension of IR22. Excisedcoleoptile tips of IR22 and Amaroo with exogenous glucose hadsimilar rates of ethanol production and were equally tolerantto anoxia. In conclusion, much of the anoxia ‘intolerance’of IR22 when germinated in anoxia could be attributed to limitedsubstrate availability to the embryo and coleoptile, presumablydue to slow starch hydrolysis in the endosperm. Key words: Anoxia, coleoptile, embryo, endosperm, ethanol production, germination, growth, Oryza sativa L., solute net uptake or loss, sugar availability.     

Effects of nitrogen source on crude oil biodegradation

Summary The effects of NH₄Cl and KNO₃ on biodegradation of light Arabian crude oil by an oil-degrading enrichment culture were studied in respirometers. In poorly buffered sea salts medium, the pH decreased dramatically in cultures that contained NH₄Cl, but not in those supplied with KNO₃. The ammonia-associated pH decline was severe enough to completely stop oil biodegradation as measured by oxygen uptake. Regular adjustment of the culture pH allowed oil biodegradation to proceed normally. A small amount of nitrate accumulated in all cultures that contained ammonia, but nitrification accounted for less than 5% of the acid that was observed. The nitrification inhibitor, nitrapyrin, had no effect on the production of nitrate or acid in ammonia-containing cultures. When the culture pH was controlled, either by regular adjustment of the culture pH or by supplying adequate buffering capacity in the growth medium, the rate and extent of oil biodegradation were similar in NH₄Cl- and KNO₃-containing cultures. the lag time was shorter in pH-controlled cultures supplied with ammonia than in nitrate-containing cultures.     

Anoxia tolerance and ethanol sensitivity of rice and oat coleoptiles

Anoxia tolerance and ethanol sensitivity of rice (Oryza sativa L.) and oat (Avena sativa L.) seedlings were evaluated to clarify their growth habit in anoxia. Anoxic stress inhibited elongation and dry weight gain of coleoptiles of the oat and rice seedlings; however, the inhibition of the oat coleoptiles was much greater than that of the rice coleoptiles. Anoxic stress increased endogenous ethanol concentration and alcohol dehydrogenase activity in oat and rice coleoptiles and their increases in the rice coleoptiles were much greater than those in the oat coleoptiles. At concentrations greater than 30 mM and 300 mM, exogenously applied ethanol inhibited the elongation and weight gain for the oat and the rice coleoptiles, respectively, and the inhibition was increased with increasing ethanol concentrations with marked inhibition being achieved on the oat coleoptiles. These results suggest that anoxia tolerance and induction of ethanolic fermentation in anoxia may be greater in rice than oat, and ethanol sensitivity of rice may be lower than that of oat.     

Nitrate assimilation during the anaerobic germination of rice: expression of ferredoxin-dependent glutamate synthase

Ferredoxin-dependent glutamate synthase (Fd-GOGAT; EC 1.4.7.1) is the last enzyme involved in the pathway of nitrate assimilation in higher plants. This paper describes the synthesis and expression of the enzyme in anaerobic coleoptiles of rice (Oryza sativa L.) and its regulation by exogenous nitrate. The activity of Fd-GOGAT was strongly inhibited by cycloheximide between 4 and 9 d of anaerobic germination. The addition of nitrate slightly increased, in the first 5 h, the specific activity of Fd-GOGAT as well as the amount of a 160-kDa protein specifically immunoprecipitated with anti-Fd-GOGAT serum. Northern blot analysis, performed with a specific riboprobe, showed the presence of mRNA of the expected size and the inductive effect of nitrate. The role of Fd-GOGAT is discussed in relation to the anaerobic assimilation of nitrate by rice coleoptiles.Abbreviations CHX cycloheximide - Fd ferredoxin - GOGAT glutamate synthase - GS glutamine synthetase - NiR nitrite reductase - NR nitrate reductase The authors wish to thank Dr. J. Turner (Rothamsted Experimental Station, Harpenden, UK) for providing Fd-GOGAT antibody and Dr. H. Sakakibara (Nagoya University, Nagoya, Japan) for Fd-GOGAT clone. This research was supported by the National Research Council of Italy, special project RAISA, sub-projekt N. 2, paper N. 2174.     

The root form of ferredoxin-NADP oxidoreductase is expressed in rice coleoptiles for the assimilation of nitrate

Two ferredoxin-dependent proteins, nitrite reductase and glutamate synthase, play a role in nitrate assimilation during the anaerobic germination of rice (Oryza sativa L.). This paper reports the expression of the root form of ferredoxin-NADP⁺ oxidoreductase (FNR), the protein responsible for providing reduced ferredoxin in rice coleoptiles. Using an antibody against FNR, a protein with the expected molecular mass for root FNR (35 kDa) was recognized by Western blot analysis in extracts from aerobic and anaerobic coleoptiles. The enzyme is synthesized de novo, as shown by immunoprecipitation of the radiolabeled 35-kDa protein from anaerobic seedlings grown in the presence of [³⁵S]methionine. Northern blot analysis with specific probes for root and leaf FNR showed the presence of mRNA for the root form but not for the leaf form, in both aerobic and anaerobic rice coleoptiles. The inductive effect of exogenous nitrate on the expression of FNR is further evidence for the presence of the root type of FNR in rice coleoptiles. The importance of the expression of root FNR during the anaerobic development of rice seedlings is discussed. Received: 7 October 1996 / Accepted: 22 January 1997