Influence of potassium and manganese on growth and uptake of magnesium by soybeans (Glycine max (L.) Merr. cv. Bragg)

Summary Soybean (Glycine max (L) Merr. cv. Bragg) seedlings were grown in nutrient solutions to evaluate the response to manganese nutrition as affected by potassium supply. In solutions containing 275 M manganese, increasing the solution concentration of potassium from 1 mM to 10 mM alleviated symptoms of manganese toxicity, decreased manganese concentrations in the leaves and increased dry matter yields of the plants. The reduction in manganese toxicity was brought about by a reduced rate of root absorption of manganese at high potassium supply levels.Increasing the supply of either potassium or manganese decreased the leaf concentration of magnesium although there were no apparent symptoms of magnesium deficiency in any treatment. The reduced concentration of magnesium in the leaves was due to effects of potassium and manganese on the rate of root absorption of magnesium.Under manganese deficiency conditions, growth was reduced and manganese concentrations in plant parts were very low; there was no effect of potassium supply when manganese was absent from the nutrient solution.     

Effect of silicon on manganese tolerance of bean plants (Phaseolus vulgaris L.)

Summary The effect of silicon on manganese tolerance of bean plants (Phaseolus vulgaris L. var. ‘Red Kidney’) grown in water culture was studied at different levels of manganese supply. Without silicon, growth depression and toxicity symptoms occurred already at 5 × 10⁻⁴ mM Mn in the nutrient solution. After addition of Aerosil (0.75 ppm Si), the plants tolerated 5 × 10⁻³ mM Mn and, at a higher silicon supply of 40 ppm, as much as 10⁻² mM Mn in the nutrient solution without any growth depression. This increase in manganese tolerance was not caused by a depressing effect of silicon on uptake or translocation of manganese but rather by an increase in the manganese tolerance of the leaf tissue. In absence of silicon, 100 ppm Mn was already toxic for the leaf tissue, whereas with a supply of 40 ppm Si, this ‘critical level’ in the leaves was increased to more than 1000 ppm Mn. At lower manganese levels in the leaf tissue, a molar ratio Si/Mn of 6 within the tissue was sufficient to prevent manganese toxicity. Above 1000 ppm Mn, however, even a much wider Si/Mn ratio (> 20) could not prevent growth depression by manganese toxicity. With⁵⁴Mn and autoradiographic studies, it could be demonstrated that, in absence of silicon, even at optimal manganese supply (10⁻⁴ mM), the distribution of manganese within the leaf blades was inhomogeneous and characterized by spot-like accumulations. In presence of silicon, however, the manganese distribution was homogeneous in the lower concentration range of manganese and still fairly homogeneous in the high concentration range. This effect of silicon on manganese distribution on the tissue level was also reflected on the cellular level. In the presence of silicon, a higher proportion of the leaf manganese could be found in the press sap,i.e., had been transported into the vacuoles, than in the absence of silicon. The increase in manganese tolerance of bean leaves by silicon therefore seems to be primarily caused by the prevention of local manganese accumulation within the leaf tissue which leads to local disorders of the metabolism and, correspondingly, growth depression.     

Manganese status,gut endogenous losses of manganese,and antioxidant enzyme activity in rats fed varying levels of manganese and fat

We hypothesized that manganese deficient animals fed high vs moderate levels of polyunsaturated fat would either manifest evidence of increased oxidative stress or would experience compensatory changes in antioxidant enzymes and/or shifts in manganese utilization that result in decreased endogenous gut manganese losses. Rats (females in Study 1, males in Study 2,n = 8/treatment) were fed diets that contained 5 or 20% corn oil by weight and either 0.01 or 1.5 μmol manganese/g diet. In study 2,⁵⁴Mn complexed to albumin was injected into the portal vein to assess gut endogenous losses of manganese. The manganese deficient rats:

Studies on chemical composition ofChenopodium album L.

Summary Field studies conducted at the Haryana Agricultural University, Hissar, India for two years revealed thatChenopodium album L. contained very high degree of nitrogen, phosphorus, potassium, calcium, magnesium, iron and manganese. Its nutrient content declined with advancement in age of the plant.     

The acquisition of phosphorus byLupinus albus L.

Summary It has been demonstrated by an agar film technique thatL. albus can cause the breakdown of colloids of iron/silicate, iron/phosphate, aluminium/silicate and aluminium phosphate and destabilise suspensions of manganese dioxide, calcium mono-hydrogen phosphate and ferric hydroxide. Dissolution of these compounds was most marked in areas adjacent to proteoid roots (dense clusters of secondary laterals of limited growth which develop on lateral roots) and parts of the tap root. Soil associated with these regions of the root system contained more reductants and chelating agents than the bulk soil. Soil from around the roots ofL. albus exhibited much greater reducing and chelating activity than that associated with the roots of rape and buckwheat.     

Manganese and iron interactions on their uptake and distribution in soybean (Glycine max (L.) Merr.)

Summary The uptake and distribution of iron and manganese were studied in a manganese-sensitive soybean cultivar (‘Bragg’) grown over a range of supply levels of these nutrients in solution culture. At high (90 and 275 μM) manganese levels, increasing the iron concentration in solution from 2 to 100 μM partially overcame the effects of manganese toxicity. Interactions between manganese and iron occurred for dry matter yields, rate of Mn absorption by the roots, and the proportions of manganese and iron transported to the tops. No interaction was observed for the rate of root absorption of iron. The percentage distribution of manganese in the plant top increased with increasing iron, despite a reduced rate of Mn uptake. On the other hand, iron uptake was independent of solution Mn concentration and increased with increasing solution Fe. Also more iron was retained in the roots at high Mn and/or Fe levels in solution. Concentrations of manganese and iron in roots, stems and individual leaves were affected independently by the manganese and iron supplyi.e. without any interaction occurring between the two elements. In general, the concentration in a plant part was related directly to the solution concentration. Symptoms resembling iron deficiency correlated poorly with leaf Fe concentrations whereas high levels of manganese were found in leaves displaying Mn toxicity symptoms.     

Role of leaf apoplast in silicon-mediated manganese tolerance of Cucumis sativus L.

Silicon (Si) supplied as sodium silicate (1·8 mm ) clearly decreased symptoms of manganese (Mn) toxicity in Cucumis sativus L. (cv. Chinesische Schlange) grown in nutrient solution with low to elevated Mn concentrations (0·5–1000 µm ). Despite approximately the same total Mn content in the leaves, plants not treated with Si had higher Mn concentrations in the intercellular washing fluid (IWF) compared with plants treated with Si, especially in the BaCl₂‐ and DTPA‐exchangeable fraction of the leaf apoplast. The Mn concentration of the IWF correlated positively with the severity of Mn‐toxicity symptoms and negatively with the Si supply. Furthermore, in Si‐treated plants less Mn was located in the symplast (< 10%) and more Mn was bound to the cell wall (> 90%) compared with non‐Si‐treated plants (about 50% in each compartment). Manganese present in Si‐treated plants is therefore less available and for this reason less toxic than in plants not treated with Si. It is concluded that Si‐mediated tolerance of Mn in C. sativus is a consequence of stronger binding of Mn to cell walls and a lowering of Mn concentration within the symplast. These results support the role of Si as an important beneficial element in plant nutrition.     

Inorganic carbon assimilation in the Isoetids,Isoetes lacustris L. and Lobelia dortmanna L.

Summary The inorganic carbon fixation patterns of Isoetes lacustris and Lobelia dortmanna from an oligotrophic Scottish loch have been examined by following titratable acidity changes in plant sap and light/dark ¹⁴CO₂ incorporation by roots and shoots. The diurnal pattern of titratable acidity changes in I. lacustris suggests crassulacean acid metabolism (CAM) while the lack of any change in titratable acidity in L. dortmanna suggests C₃ metabolism. Of the carbon fixed by L. dortmanna, 99.9% was taken up through the roots and fixation occurred primarily during the day. In Isoetes, CO₂ was taken up by both roots and shoots and during both day and night. Regardless of the site of CO₂ uptake, fixation occurred only in the shoots of both plants. Analysis of carbon isotope ratios of plant organic material was used to further investigate the photosynthetic mechanisms of these Isoetids. Considering the absence of a nighttime peak in titratable acidity in L. dortmanna, the ¹³C (=¹³C plant-¹³C source) value of the shoots of L. dortmanna (-14.2) is indicative of C₃ photosynthesis limited by the rate of CO₂ diffusion. The less negative of I. lacustris (-6.0) is consistent with both dark acidification of CAM and CO₂ limited C₃ photosynthesis. This is in contrast to the terrestrial Isoetes durieui which is shown to have a value which is similar to a terrestrial C₃ plant. The carbon fixation patterns of these Isoetids suggest that the CO₂ concentration in the loch may be growth limiting, and that root uptake and/or dark acidification are means of optimising CO₂ supply. However, in view of the relatively high levels of CO₂ in sediment and bulk water, it is suggested that low levels of nutrients may also limit growth in these plants.     

Redistribution of Potassium, Calcium, Magnesium, and Manganese in the Plant

The extent of redistribution in apple was described by calculating the fruit/leaf ratio of the cation content. It was found that the redistribution diminishes in the sequence K > Mg > Ca ～ Mn. These results are more or less in agreement with those found elsewhere. Investigations were made to see whether it was possible to account for the differences in redistribution by the phloem by means of the solubility of these cations in the sieve tube sap. As model plants Yucca flaccida and Ricinus communis were used, plants from which it was possible to obtain phloem sap in a rather pure state. It was found that the addition of potassium and magnesium as a chloride in the usual investigated range of concentrations did not give precipitation. With calcium and manganese, however, a precipitate soon occurred. Manganese was demonstrated to be less soluble than calcium. For Ricinus the maximum amount of calcium and manganese the sieve tube sap could contain before precipitation set in was higher than for Yucca sap. The results confirm the possibility that the redistribution of the different cations in the plant can be related inter alia to their solubility in the sieve tube sap. It was also found that the calcium in the phloem sap is present in ionic condition. Thus the normal laws of solubility should be applicable.     

Identification and evaluation of the role of the manganese efflux protein in <Emphasis Type="Italic">Deinococcus radiodurans</Emphasis>

Background  

Deinococcus radiodurans accumulates high levels of manganese ions, and this is believed to be correlated with the radiation resistance ability of this microorganism. However, the maintenance of manganese ion homeostasis in D. radiodurans remains to be investigated.     

In vitro culture of Vitis: the effects of light spectrum,manganese sulfate and potassium iodide on morphogenesis

The effects of blue and red light, manganese sulfate concentration (100 and 5 M), and potassium iodide (5 and 0 M) on shoot and root production from subcultured shoots of the Vitis hybrid Remaily Seedless were studied.Shoot production was greater in blue light. It was increased by lowering the manganese sulfate concentration. The response to manganese in blue light was greatest when there was no potassium iodide addition.Root production was decreased by red light and lower manganese concentration.The effects of manganese, iodide and light spectrum on morphogenesis are discussed in relation to their known effects on IAA metabolism.     

The effects of the metal ions Mn2+ and Co2+ on muscle contraction in the Norway lobster Nephrops norvegicus (L.)

The effects of the metal ions manganese and cobalt on force production by the abdominal superficial flexor muscle of the Norway lobster, Nephrops norvegicus, have been studied in response to both neuronal stimulation and electrical field stimulation applied to an isolated neuromuscular preparation, and by selectively blocking synaptic transmission with ivermectin. In response to both forms of stimulation, low concentrations of manganese added to the standard N. norvegicus saline increased the contractile force produced by the muscle, whereas higher concentrations of manganese inhibited both responses in a dose-dependent manner, until force was completely abolished at concentrations above 2.9 mM manganese. Cobalt ions produced similar effects, and no significant difference was found between the concentration of the two ions at 50% force inhibition (K_m) or between the two stimulation methods (manganese: 1.22 mM; cobalt: 1.29 mM, P = 0.86). This suggests that they have a similar mode of action, and a postsynaptic site of inhibition. These K_m values are considerably higher than the concentrations of these ions known to accumulate in the haemolymph of N. norvegicus under eutrophic conditions, and it therefore seems unlikely that accumulations of manganese or cobalt ions under such conditions would cause any significant inhibition of muscle contraction force. Accepted: 28 April 1999     

In Vitro DNA Synthesis by Chloroplasts Isolated from Marchantia polymorpha L. Cell Suspension Cultures

Lysate of chloroplasts prepared from liverwort Marchantia polymorpha L. cell suspension cultures incorporated [³H]-dTTP into acid insoluble materials when DNA was added exogenously as a template. The incorporation was highly dependent on the addition of template DNA, four deoxynucleoside triphosphates and magnesium ions (maximum incorporation at 5mM). Magnesium ions could be replaced by manganese ions. DNA synthesis inhibitors, N-ethylmaleimide (NEM) and ethidium bromide (EtBr), strongly inhibited the incorporation. Dideoxythymidine triphosphate (ddTTP), an inhibitor of DNA polymerases β and γ, inhibited the incorporation at the concentration of 50 μM (molar ratio of ddTTP/dTTP = 17). On the other hand, the incorporation by the chloroplast lysate was resistant to arabinofuranosyl cytosine triphosphate (araCTP) and aphidicolin as well as the RNA polymerase inhibitors, rifampicin and α-amanitin. The chloroplast lysate highly utilized denatured calf thymus DNA and bacteriophage ?X174 single-stranded DNA as templates when added exogenously, while a synthetic homopolymer, poly(rA)-oligo(dT)₁₂ ~ ₁₈, did not stimulate the incorporation at all. Autoradiographic analysis of DNA synthesized in isolated chloroplasts showed that the chloroplast DNA synthesis took place at several specific sites on the chloroplast DNA from cells of the liverwort, Marchantia polymorpha.     

Colonization,penetration and transformation of manganese oxide nodules by Aspergillus niger

In this study, the ability of the geoactive fungus Aspergillus niger to colonize and transform manganese nodules from the Clarion-Clipperton Zone in both solid and liquid media was investigated. Aspergillus niger was able to colonize and penetrate manganese nodules embedded in solid medium and effect extensive transformation of the mineral in both fragmented and powder forms, precipitating manganese and calcium oxalates. Transformation of manganese nodule powder also occurred in a liquid medium in which A. niger was able to remove the fine particles from suspension which were accumulated within the central region of the resulting mycelial pellets and transformed into manganese oxalate dihydrate (lindbergite) and calcium oxalate dihydrate (weddellite). These findings contribute to an understanding of environmental processes involving insoluble manganese oxides, with practical relevance to chemoorganotrophic mineral bioprocessing applications, and, to the best of our knowledge, represent the first demonstration of fundamental direct and indirect interactions between geoactive fungi and manganese nodules.     

Phytometric estimation of fertility of waterlogged rich-fen peats usingEpilobium hirsutum L.

Summary The above-ground net production of herbaceous vegetation in 16 stands of waterlogged rich fen in Broadland, Norfolk UK, has been compared with the growth ofEpilobium hirsutum seedlings (in controlled environment) on replicate peat samples from each site and with the chemical composition of extracts from sub-samples of each peat (Ca, Mg, Na, K, Fe, Mn, inorganic P, inorganic N). There were no consistent or significant relationships between measured concentrations of major nutrients (K, N, P) in peat samples and netin situ production of the vegetation or with growth ofE. hirsutum seedlings on each peat. There was a strong, significant (p<0.001) relationship between above ground productionin situ and growth ofE. hirsutum seedlings. Seedling growth thus provided a simple, sensitive phytometric measure of fertility of the waterlogged peats (pH range 6.0–7.0). One possible limitation is the apparent sensitivity ofE. hirsutum seedlings to high manganese concentrations.     

Genetic analysis of RFLPs, GATA microsatellites and RAPDs in a cross between L. esculentum and L. pimpinellifolium

A population of 257 BC₁ plants was developed from a cross between an elite processing line of tomato (Lycopersicon esculentum cvM82-1-7) and the closely related wild species L. pimpinellifolium (LA1589). The population was used to construct a genetic linkage map suitable for quantitative trait locus (QTL) analysis to be conducted in different backcross generations. The map comprises 115 RFLP, 3 RAPD and 2 morphological markers that span 1279 cM of the tomato genome with an average distance between markers of 10.7 cM. This map is comparable in length to that of the highdensity RFLP map derived from a L. esculentum x L. pennellii F₂ population. The order of the markers in the two maps is also in good agreement, however there are considerable differences in the distribution of recombination along the chromosomes. The segregation of six GATA-containing loci and 47 RAPD markers was also analyzed in subsets of the population. All of the microsatellite loci and 35 (75%) of the RAPDs mapped to clusters associated with centromeric regions.     

Effect of manganese on zinc-65 absorption by rice seedlings and its translocation within the plants

Summary Effect of manganese on absorption and translocation of zinc by rice seedlings was studied in a nutrient solution using radioactive zinc (Zn⁶⁵). With increase in manganese application, zinc uptake decreased in roots, but increased in shoots with an application upto 10 M manganese. Reduction in zinc absorption was more at low rates of zinc application. However, translocation of zinc from roots to shoots increased with manganese application upto 20 M but the increase was more pronounced with an application of 2M zinc only.     

Competitive interactions between Fucus spiralis L. and F. vesiculosus L. (Fucales,Phaeophyta)

Fucus spiralis forms a conspicuous belt in the upper intertidal on rocky shores of the NW Atlantic. The objective of this study was to determine whether competition among congeners plays a role in restricting the distribution of F. spiralis to the upper shore. A replacement series design was used to test the growth performance of F. spiralis and F. vesiculosus in monocultures and in mixtures set up in the mid shore level on an exposed rocky coast. For F. spiralis and F. vesiculosus, all individual and relative crowding coefficients were < 1 and > 1, respectively. Hence, F. vesiculosus succeeded relative to F. spiralis in all mixtures tested. This finding was confirmed by graphical analysis. Ratio diagrams showed that the outcome of long term interaction among the species is extinction of F. spiralis. The results lead to the conclusion that interaction among congeners is a major determinant of the restricted distribution of F. spiralis.     

Somatic embryogenesis and shoot regeneration from intact seedlings of Phaseolus acutifolius A., P. aureus (L.) Wilczek,P. coccineus L., and P. wrightii L.

A rapid, one-step procedure has been developed for inducing direct organogenesis and somatic embryogenesis in cultures of Phaseolus coccineus L., P. acutifolius A., P. aureus L. [Vigna radiata L. Wilczek] and P. wrightii L. Development of somatic embryos and shoot buds occurred within 6–8 weeks of culture from intact seedlings raised on MS (Murashige and Skoog 1962) medium supplemented with N⁶-benzylaminopurine (BAP). Shoot buds or embryoids originated from subepidermal tissue of the regions adjacent to the shoot apex, hypocotyl and cotyledonary axils. While P. acutifolius and P. aureus were regenerated via shoot formation and P. wrightii by somatic embryogenesis, both embryogenesis and shoot regeneration were observed in P. coccineus. Relatively higher levels of BAP, 50–80 M, were found to be optimal for inducing regeneration while lower concentrations were ineffective. About 40–70 shoots and 70–250 somatic embryos were produced per responding seedling. Regenerated shoots and somatic embryos developed into whole plants on a basal medium or the one supplemented with 1 M naphthaleneacetic acid.     

Combined Effects of Ammonia and Manganese on Astrocytes in Culture

Ammonia has been strongly implicated in the pathogenesis of hepatic encephalopathy (HE), and astrocytes appear to be the primary target of ammonia neurotoxicity. Recent work has shown that manganese also plays a role in the pathogenesis of HE and causes astrocyte morphologic and functional changes similar to ammonia. We therefore investigated whether a combination of these compounds could produce additive/synergistic effects. Cultured astrocytes treated with 5 mM ammonia (NH₄Cl) along with 100 M manganese acetate (MnAc) for 3 h showed a 55–65% increase in free radical production over ammonia or manganese alone (P < 0.05). There was also a 50% decrease in the mitochondrial membrane potential ( _m) at 24 h following treatment with NH₄Cl (5 mM) plus MnAc (50 M) Pt< 0.05), as compared to ammonia or manganese alone. Astrocytes treated with ammonia or manganese alone for 24 h showed no cell death, as determined by LDH release and light microscopic examination. However, cultures treated with ammonia plus manganese showed 80–90 necrotic cell death as estimated by light microscopy and 59 cell death as determined by LDH release. LDH release by ammonia plus manganese was blocked by the antioxidant superoxide dismutase (25 units/ml) as well as by the nitric oxide synthase inhibitor N-nitro-L-argininemethyl ester (500 M). In conclusion, ammonia plus manganese exert additive/synergetic effects on the induction free radicals, mitochondrial inner membrane depolarization and cellular integrity, which may contribute to the tissue injury associated with chronic forms of HE.Special issue dedicated to Lawrence. F. Eng.