Effect of Potassium Deficiency on C3 and C4 Cereals

C₄ cereals (Zea maya L. and Sorghum bicolor L. Moench) and C₃cereals (Triticum aestivum L. and Hordeum vulgare L) were grownin nutrient solutions with constant, interrupted, or absentpotassium supply. The lack of potassium retarded shoot growthand depressed the chlorophyll accumulation in all species ina similar way. After the renewal of potassium, the differencesin the compensation for growth retardation were not correlatedwith the photosynthetic system, but with the recovery of chlorophyllaccumulation in younger leaves. As important for the compensationof shoot growth retardation was a slower senescence of old leavescompared to plants with a constant potassium supply. This wasshown by the chlorophyll content and PEP carboxylase activity.In contrast to C₃ cereals, the C₄ cereals did not react withhigher chlorophyll contents to the same extent after the renewalof the postassium supply. The PEP carboxylase activity, however,was immediately raised higher than in control leaves. Chlorophylland PEP carboxylase activity increased simultaneously only inless aged leaves.     

Chlorophyll Metabolism in Higher Plants VI. Involvement of Peroxidase in Chlorophyll Degradation

The following phenolics were found to be essential for peroxidase-dependentchlorophyll bleaching: 2,4-dichlorophenol (DCP), p-coumaricacid (HCA), phenol, p-hydroxyphenylacetic acid, p-hydroxybenzoicacid, p-hydroxyacetophenone, resorcinol and umbelliferone. Mostof them are monophenols with electron-attracting groups at thep-position. The short-lived radicals generated by horseradishperoxidase (HRP)-phenolics-H₂O₂ reaction might be involved inthis reaction. Tobacco leaf enzyme preparation with peroxidaseactivity for guaiacol could also degrade chlorophyll with suchphenolics. In addition, tobacco leaf methanol extract couldsubstitute for chlorophyll bleaching as an electron donor inthe absence of phenolics. In place of free H₂O₂, the glycolate-glycolateoxidase (GOX) system could degrade chlorophyll in [peroxidase$phenolics]-dependentbleaching. This chlorophyll bleaching system was inhibited by peroxidaseinhibitors, radical scavengers, reducing reagents, and carotenoids.Ascorbate and glutathione stopped chlorophyll bleaching withGSSG reductase and NADPH. The role of ascorbate and glutathionein peroxidase activity for controlling the chlorophyll degradationrate is discussed. (Received January 28, 1985; Accepted July 23, 1985)     

Establishment and physiological analyses of photoautotrophic callus cultures of the fern Platycerium coronarium (Koenig) Desv. under CO2 enrichmen

Gametophyte-derived callus cultures of Platycerium coronariumcould be maintained under photoautotrophic conditions on Murashigeand Skoog medium supplemented with 2µM 2,4-dichlorophenoxyaceticacid (2,4-D) and with CO₂ enrichment. Progressive reductionof sucrose from the medium resulted in a reduction in growth,but an increase in total chlorophyll content. When subculturingwas delayed beyond 2 weeks, callus cells differentiated intogametophytes on the medium with 0.2 sucrose and no CO₂ enrichment.Enriching the photoautotrophic cultures on 2µM 2, 4-Dwith 1% CO₂ resulted in about 1.7-fold increase in fresh weightwithin 42 d. Total chlorophyll content was generally higherwith 1% CO₂ enrichment than with 10%. F_v/F_m ratio was higherfor callus on low levels of sucrose (>0.5%) than that onsucrose 1.0%. An increase in autofluorescence of chloroplasts,but not the size, was observed with decreasing sucrose levelsin the medium. Autofluorescence decreased with increase in CO₂from 0.03%. Our data are in agreement with the view that long-termexposure to high levels of decrease in photosynthetic capacity. Key words: Platycerium coronarium, stag's horn fern, autofluorescence of chloroplasts, confocal laser scanning microscope, F_v/F_m ratio, photoautotrophic callus     

Nutrient-limited growth rates: quantitative benefits of stress responses and some aspects of regulation

Young sunflower plants (Helianthus annuus L.) under stress oflow nitrate or phosphate availability exhibited increases inroot: shoot ratio and in kinetic parameters for uptake. Theyshowed no significant changes in photosynthetic utilizationof either nutrient. Increases in root: shoot ratio were achievedby early and persistent suppression of shoot growth, but notroot growth. Affinity for phosphate uptake, 1/K_m(P), increasedwith phosphate stress, as did affinity for nitrate uptake, 1/K_m(N),with nitrate stress. Maximal uptake rate, V_max, for phosphateuptake increased with phosphorus stress; V_max for nitrate didnot increase with nitrogen stress. Phosphate V_max was relatedstrongly to root nutrient status. Decreases in V_max with plantage were not well explained by changes in age structure of roots.Estimated benefits of acclimatory changes in root: shoot ratioand uptake kinetics ranged up to 2-fold increases in relativegrowth rate, RGR. The relation of RGR to uptake physiology followedpredictions of functional balance moderately well, with somesystematic deviations. Analyses of RGR using growth models implyno significant growth benefit from regulating Vmax, specifically,not from down-regulating it at high nutrient availability. Quantitativebenefits of increases in root: shoot ratio and uptake parametersare predicted to be quite small under common conditions whereinnutrient concentrations are significantly depleted by uptake.The root: shoot response is estimated to confer the smallestbenefit under non-depleting conditions and the largest benefitunder depleting conditions. Even then, the absolute benefitis predicted to be small, possibly excepting the case of heterogeneoussoils. Depleting and non-depleting conditions are addressedwith very different experimental techniques. We note that atheoretical framework is lacking that spans both these cases,other than purely numerical formulations that are not readilyinterpreted. Key words: Nutrient stress, nutrient uptake, nutrient use efficiency, relative growth rate, Helianthus annuus     

Der Einflu{beta} verschiedener Lichtqualitaten auf Chlorophyllgehalt und Wachstum von Gewebekulturen aus Crepis capillaris (L.) WALLR.

The influence of different light qualities on chlorophyll contentand growth of tissue cultures from Crepis capillaris (L.) WALLR. Tissue cultures from Crepis capillaris growing on media (M₁; M₂ ; M₂-E) formed chlorophyll and intact chloroplasts onlyin the short wave length region of the visible spectrum (350–550nm). In red light (600–700 nm) as well as in darknessthey lost their chlorophyll after 8–10 weeks. The growth of Crepis-cultures was strongly influenced by lightand the nitrogen of the medium. The highest increase in freshweight (425–485% increase in 3 weeks) was attained inred light or in darkness on M₂ by cultures which had lost theirchlorophyll completely. M₂ contains nitrates, ammonium saltsand amino acids. In contrast, the increase in fresh weight ofgreen cultures growing on M₂ in blue or white light was considerablylower (155–180% increase in 3 weeks). Omission of amino acids, (M₂-E), resulted in the reduction ofthe growth (increase of fresh weight in 3 weeks: 120%) of thechlorophyll-free cells growing in the dark. Green cultures behaveddifferently on M₂-E. In white light they attained an increasein fresh weight of 245%. This suggests that the growth promotingeffect of the amino acids can be replaced by light. Results with cultures growing on M₁, which contains neitherammonium salts nor amino acids, point in the same direction.Green cultures in white or blue light grew better (90–100%increase in fresh weight in 3 weeks) on this "deficient" mediumthan chlorophyll-free tissues in red light or in darkness (20–30%increase in fresh weight in 3 weeks). Some aspects of thesefindings which concern the effect of light on growth are discussed. (Received November 28, 1969; )     

Influence of putrescine, silver nitrate and polyamine inhibitors on the morphogenetic response in untransformed and transformed tissues of Cichorium intybus and their regenerants

The addition of 40 mM putrescine (Put) to Murashige and Skoog's (MS) medium resulted in increased shoot multiplication and shoot growth in untransformed plants relative to transformed plants of Cichorium intybus L. Put at a concentration of 40 mM also resulted in flowering in both systems on the 28th day, with elevated titers of endogenous conjugated Put and spermine (Spm) in both untransformed and transformed plants. The addition of 40 µM AgNO₃ to untransformed axillary buds of C. intybus L. cultured on MS media resulted in increased shoot multiplication (36.9DŽ.63 shoots per culture) and increased shoot growth (7.82ǂ.76 cm) as compared to transformed ones (11.6ǂ.89 shoots per culture; 3.20ǂ.24 cm). Moreover, cultures treated with 40 µM AgNO₃ showed in vitro flowering on the 28th day in both systems, with the endogenous levels of conjugated spermine being higher in untransformed plants than in transformed ones. The morphogenetic response and the endogenous conjugated pool of polyamines were lower following !-DL-difluromethylarginine and !-DL-difluromethylornithine treatments; the addition of put (40 mM) and AgNO₃ (40 µM) restored these to normal levels. Under exogenous put feeding, ethylene production was lower in both the untransformed and transformed cultures. We believe that an interplay between polyamine and ethylene biosynthesis is involved in regulating the morphogenetic response in both transformed and untransformed shoots of C. intybus. The response to AgNO₃ and Put treatment was not altered by the transformation process.     

Induction of atrazine resistance and somatic embryogenesis in Solanum melongena

 The effects of atrazine on cotyledon cultures of Solanum melongena were investigated with a view to establishing a system for in vitro selection of resistant mutants. At herbicide levels producing little growth inhibition some chlorophyll loss occurred associated with the production of albino shoots. At 15 mg/l bleaching was more pronounced and was accompanied by the development of necrotic spots; however, efficient bleaching was associated with severe suppression of growth. Mutagenesis with EMS resulted in herbicide-resistant mutants based on the embryogenic ability of mutagenised explants placed on medium containing selective levels of sucrose (0.2%) and atrazine (15 mg/l). Different morphogenetic responses were observed when the levels of sucrose (0.2–5%) were altered. Somatic embryogenesis was observed at low sucrose concentrations (0.2–0.5%). Both embryogenesis and shoot regeneration occurred in 1% sucrose. Shoot regeneration was maximum in 2% sucrose and the regenerating ability decreased with a further increase in sucrose concentration (3–5%). However, lowering of sucrose concentration from 2% to 0.2% caused complete bleaching, permitting the selection of herbicide-resistant mutants. Received: 26 November 1996 / Accepted: 20 December 1996     

Assimilate Partitioning in Red and White Clover Either Dependent on N2 Fixation in Root Nodules or Utilizing Nitrate Nitrogen

During vegetative growth in controlled environments, the patternof distribution of ¹⁴C-labelled assimilates to shoot and root,and to the meristems of the shoot, was measured in red and whiteclover plants either wholly dependent on N₂ fixation in rootnodules or receiving abundant nitrate nitrogen but lacking nodules. In experiments where single leaves on the primary shoot wereexposed to ¹⁴CO₂, nodulated plants of both clovers generallyexported more of their labelled assimilates to root (+nodules),than equivalent plants utilizing nitrate nitrogen, and thiswas offset by reduced export to branches (red clover) or stolons(white clover). The intensity of these effects varied with experiment.The export of labelled assimilate to growing leaves at the terminalmeristem of the donor shoot was not influenced by source ofnitrogen. Internode elongation in the donor shoot utilized nolabelled assimilate. Whole plants of white clover exposed to ¹⁴CO₂ on seven occasionsover 32 days exhibited the same effect on export to root (+nodules),which increased slightly in intensity with increasing plantage. Nodulated plants had larger root: shoot ratios than theirequivalents utilizing nitrate nitrogen. Trifolium repens, Trifolium pratense, red clover, white clover, nitrogen fixation, nitrate utilization, assimilate partitioning     

Effects of CO2 enrichment and intraspecific competition on biomass partitioning, nitrogen content and microbial biomass carbon in soil of perennial ryegrass and white clover

Seedlings of perennial ryegrass (Lolium perenne L. cv. Parcour)and white clover (Trifolium repens L. cv. Karina) grown at fivedifferent plant densities were exposed to ambient (390 ppm)and elevated (690 ppm) CO₂ concentrations. After 43 d the effectsof CO₂ enrichment and plant density on growth of shoot and root,nitrogen concentration of tissue, and microbial biomass carbon(C_mic) in soil were determined. CO₂ enrichment of Lolium perenneincreased shoot growth on average by 17% independent of plantdensity, while effects on root biomass ranged between -4% and+ 107% due to an interaction with plant density. Since tilernumber per plant was unaffected by elevated CO₂, the small responseof shoot growth to CO₂ enrichment was atributed to low sinkstrength. A significant correlation between nitrogen concentrationof total plant biomass and root fraction of total plant drymatter, which was not changed by CO₂ enrichment, indicates thatnitrogen status of the plant controls biomass partitioning andthe effect of CO₂ enrichment on root growth. Effects of elevatedCO₂ and plant density on shoot and root growth of Trifoliumrepens were not significantly interacting and mean CO₂-relatedincrease amounted to 29% and 66%, respectively. However, growthenhancement due to elevated CO₂ was strongest when leaf areaindex was lowest. Total amounts of nitrogen in shoots and rootswere bigger at 690 ppm than at 390 ppm CO₂. There was a significantincrease in C_mic in experiments with both species whereas plantdensity had no substantial effect. Key words: CO₂ enrichment, intraspecific competition, biomass partitioning, Lolium perenne, Trifolium repens, grassland     

METABOLISM OF GLUCOSE IN THE PROCESS OF "GLUCOSE-BLEACHING" OF CHLORELLA PROTOTHECOIDES

1. As previously demonstrated, normal cells of Chlorella protothecoidesare bleached with degeneration of chloroplasts when they areincubated, under aerobic conditions—either in the lightor in darkness—, in a glucose-containing medium withoutadded nitrogen source ("glucose-bleaching"). It was found inthe present study that under the atmosphere of N₂, neither bleachingnor growth of algal cells occurs in the dark, while in the lighta significant growth of cells takes place with formation ofa certain amount of chlorophyll.
2. Studies on the effects ofvarious inhibitors (ammonium ion,DNP, CMU, -hydroxysulphonates,arsenate, cyanide, azide, andantimycin A) under different conditionsshowed that oxidativephosphorylation is a necessary processfor the occurrence ofthe glucosebleaching as well as the assimilationof glucose(cellular growth). Under light-anaerobic conditionsin the presenceof glucose, assimilation of glucose (cellulargrowth) takesplace being supported by photophosphorylation,but no bleachingoccurs.
3. When the algal cells in the courseof bleaching were transferredto the glucose-free mineral medium,the cell growth ceased immediatelybut the cell bleaching proceededfor several hours before itscessation. The respiratory activity,which was high in the glucose-containingmedium, became loweron transferring the algal cells into theglucose-free medium.The lowered level of respiration was maintained,for more than8 hr after the transfer of cells to the glucose-freemedium.
4. When the cells in the course of bleaching were placed underthe atmosphere of N₂, the cell bleaching ceased almost instantaneously.
5. Based on these observations and other inhibition experiments,it was inferred that a certain intermediate(s) produced by theaerobic respiration of glucose is closely associated with theoccurrence of cell bleaching, and that an O₂-requiring stepmay be involved in the process of chlorophyll degradation.

(Received September 9, 1965; )     

Sugar Accumulation in Barley and Rice Grown in Solutions with low Concentrations of Oxygen

Barley and rice, at the early tillering stage, were grown inaerated nutrient solutions (> 7 mg O₂ l^–1) and transferredto solutions of low O₂ concentrations (< 0.5 mg l ^–1). For barley, low O₂ concentrations during the first 5 days severelyinhibited growth of seminal roots had less effect on nodal roots,and did not reduce shoot growth. Longer exposure to low O₂ concentrationsreduced shoot as well as root growth. Sugar concentrations inroots and shoots increased within 7 h after transfer of plantsto low O₂ concentrations. After 5 days at low O₂ concentrationssugar concentrations were very high in fast growing nodal rootsand in shoots, as well as in the slower growing seminal roots. In rice, low O₂ concentrations increased sugar levels of rootsduring summer, but not during winter. In summer, the highersugar levels at low O₂ concentrations persisted throughout adiurnal cycle. In root apices, sugar concentrations were increasedby low O₂ concentrations, even though the experiment was donein winter and the bulk of the root system showed no differencein sugar levels. The data indicate that sugar accumulation, at low O₂ concentrations,is caused by reduced growth and also that even apices of rootsgrown at low O₂ concentrations have sufficient substrates forrespiration. Hordeum vulgare L, barley, Oryza sativa L, rice, sugar accumulation, oxygen concentration     

Energetics of Plant Growth Under Anoxia: Metabolic Adaptations of Oryza sativa and Echinochloa phyllopogon

Unlike most plant species, Oryza sativa L. cv. S-201 and Echinochloaphyllopogon (Stev.) Koss germinate and grow under anaerobicconditions. In both species, the radicle or shoot emerged byday 3 when the seeds were germinated in air or N₂. Under eithercondition, shoot and/or root dry weight (d. wt) increased linearlyfrom day 3 to day 7, with a corresponding decrease in seed d.wt. In anaerobically grown O. sativa, d. wt accumulation wasreduced to 7% of that in air whereas d. wt lost from the seedwas reduced to only 37%. No root growth occurred during anaerobicgermination and shoot d. wt accumulation accounted for 10% ofthe d. wt lost from the seed. In E. phyllopogon, d. wt accumulationduring anoxia was 25% of that in air, but loss of d. wt fromthe seed was 44% of the aerobic rate. In air, 48% of the d.wt lost from the seed was converted to shoot or root d. wt.Like O. sativa, E. phyllopogon does not produce a root underN₂, but shoot growth accounted for 27% of the d. wt lost fromthe seed. Thus, either in air or N₂, E. phyllopogon was moreefficient at converting seed reserves to shoot/root structuraldry matter than O. sativa . Based on changes in metabolite pools,O. sativa appeared to shift exclusively to fermentation duringanaerobic growth. In E. phyllopogon, however, fermentation alonecannot satisfy the energy requirement for growth without O₂.Rather, fermentation, coupled with limited tricarboxylic acid(TCA) cycle operation could supply sufficient ATP for growthunder anaerobic conditions. An active oxidative pentose phosphatepathway and lipid synthesis were discussed as important mechanismsfor converting NADH to NAD, a necessary cofactor for fermentationand TCA cycle activity.Copyright 1994, 1999 Academic Press Anaerobiosis, Echinochloa phyllopogon, energetics model, fermentation, mitochondrial activity, Oryza sativa, rice, tricarboxylic acid cycle, watergrass     

Simultaneous changes in cell quotas of microcystin, chlorophyll a, protein and carbohydrate during different growth phases of a batch culture experiment with Microcystis aeruginosa

The cell quotas of microcystin (Q_mcyst), protein (Q_prot), chlorophylla (Q_chloro) and carbohydrate (Q_carbo), as well as the net productionrates of these parameters, were determined during the exponentialand stationary phases in nine batch cultures of Microcystisaeruginosa (CYA 228) at light regimes from 33 to 53 µmolphotons m^–2 s^–1. The following results were obtained.(i) A parallel pattern was found in the changes of Q_mcyst, Q_prot,Q_chloro and Q_carbo during the entire growth cycle and significantcorrelations were recorded between Q_mcyst and Q_prot, Q_chloroand Q_carbo. (ii) The net microcystin production rate (µ_mcyst)was positively correlated with the specific cell division rate(µ_c), the chlorophyll production rate (µ_chloro)and the protein production rate. (iii) A significant inverselinear relationship was found between µ_c and Q_mcyst, i.e.cultures with a positive µ_c had a Q_mcyst between 110 and400 fg microcystin cell^–1, while declining cultures hadQ_mcyst values >400 fg microcystin cell^–1. Maximum variationin Q_mcyst within cultures was 3.5-fold. Collectively, the resultsshow that cells produced microcystin at rates approximatingthose needed to replace losses to daughter cells during divisionand that microcystin was produced in a similar way to proteinand chlorophyll, indicating a constitutive microcystin production.     

Effects of Plant Growth Regulators and Nutrient Supply on Tiller Bud Outgrowth in Barley (Hordeum distichum L.)

Seedlings of spring barley were raised in 100 and 20% nutrientsolution and treated with a foliar application of Terpal, Cerone,TIBA, GA₃ or BAP. The growth of individual tiller buds and tillers,the main shoot and the root system was recorded over the following15 d. Terpal and Cerone stimulated tiller bud elongation within5 d at both nutrient levels and after 15 d the number of emergedtillers was increased at the higher nutrient level. Terpal characteristicallypromoted the growth of secondary tiller buds whereas Ceronepromoted the emergence of the coleoptile tiller; both thesePGRs also retarded the development of the main shoot. TIBA increasedthe number of elongating tiller buds but this did not resultin greater tillering. GA₃ reduced the number of elongating tillerbuds and restricted their growth, especially in the high nutrientregime; this was accompanied by an increase in main shoot elongation.The growth and development of tiller buds was reduced by BAPand the number of emerged tillers was reduced at 15 d in bothnutrient levels; main shoot dry weight and root elongation werealso reduced. The results are considered in relation to theoverall influence of hormonal factors and mineral supply ontiller bud outgrowth. Hordeum distichum, spring barley, tiller bud outgrowth, plant growth regulators, Terpal, Cerone, GA₃, BAP, nutrient supply, apical dominance, TIBA     

Temporal and Nutritional Influences on the Response to Elevated CO2 in Selected British Grasses

To investigate the duration of the CO₂ response and its interactionwith mineral nutrition, CO₂-enrichment experiments were performedon four British grasses of differing ecology and functionaltype: Arrhenatherum elatius (L.) Beauv., Festuca ovina L., Festucarubra L. and Poa annua L. Naturally-lit, glasshouse cabinetswere used, with a non-limiting water supply and a daytime meantemperature of 18 °C. Two CO₂ treatments were maintainedat nominal concentrations of 350 and 700 vpm and were combinedfactorially with two levels of balanced mineral nutrition atconductivities of 0·1 and 1 mS cm^-1. Harvests took placeat planting-out, and at 16, 37 and 58 d thereafter. Fitted curves were used to derive instantaneous values of totaldry weight, relative growth rate (RGR), shoot weight fraction(SWF) and unit shoot rate (USR) for all combinations of species,CO₂ level, nutrient level and time of harvesting. At the higher nutrient level there was a reasonably close agreementwith previous estimates of the CO₂ response in the four species.The response, if any, most often arose from an increase in USRbeing accompanied by a less than proportionate decline in SWF.Responses were sustained throughout the period studied. At thelower nutrient level, all species showed a CO₂ response initially,but this declined at a rate which was inversely related to theCO₂-responsiveness of the species at the higher nutrient level. The underlying ontogenetic drift appeared to be markedly towardsadjustment in SWF and away from that of USR. However, this driftwas retarded, suspended or even reversed by low-nutrient conditionsand/or by high CO₂ responsiveness in the species itself.Copyright1995, 1999 Academic Press Climate change, CO₂ enrichment, plant strategies, mineral nutrition, growth analysis, relative growth rate, shoot weight fraction, unit shoot rate, functional equilibria     

Intracellular Regime for the Assembly of the Chlorophyll-Protein Complex CPI in Cyanidium caldarium

Mass cultures of Cyanidium caldarium exhibit a developmentalstage of temporary bleaching during cultivation in permanentlight (Zagon and Brandt, 1985). This loss of chlorophyll a isnot accompanied by a loss of the CPI-apoprotein. This essentialthylakoid protein is also inserted into the thylakoid membranewithout the presence of chlorophyll a. Subsequent assembly withthe pigment, however, increases the intrinsic binding of theCPI-apoprotein. The temporary bleaching of C. caldarium canbe imitated essentially by addition of levulinic acid or cycloheximide,but not by chloramphenicol or streptomycin. The cooperationof the nucleocytoplasm and of the photosyn-thetically activecompartments with respect to the assembly of CPI is discussed. Key words: Assembly, chlorophyll-protein complex, Cyanidium caldarium, regulation     

An Experimental Study of Calcium Acquisition and its Effects on the Calcifuge Moss Pleurozium schreberi

In a field experiment to investigate the sources and effectson growth of Ca in the calcifuge moss Pleurozium schreberi,significant quantities of Ca reached the growing shoot apicesfrom a CaCO₃ layer placed on the mineral soil surface Top applicationsof 0.5 and 5 mol m^–3 CaCl₂ raised the exchangeable andintracellular Ca concentrations and displaced natural exchangeableK and Mg The 5 mol m^–3 CaCl₂ treatment also caused a significantreduction in intracellular Mg indicating that Mg uptake is dependenton an initial exchange step No growth differences were notedbetween treatments, possibly because ionic changes had not reacheda detrimental level within the 28 weeks of the experiment ina second experiment, shoot apices of Pleurozium schreberi, Pseudoscleropodiumpurum and Calliergon cuspidatum were grown on nylon gauze underintermittent distilled-water mist At weekly intervals the shootswere saturated with CaCl₂ solutions providing factorial combinationsof Ca and pH Growth of C cuspidatum and P purum from chalk soilwas reduced at high (0.01) Ca concentration whereas Pleuroziumschreberi and Pseudoscleropodium purum from acidic clay wereunaffected The pH treatments did not significantly affect mossgrowth Initial tissue levels of K and Mg were lower in the mossesfrom chalk and it is suggested that the CaCl₂ treatments causednutrient deficiencies in these plants Mosses from acidic soilcontained less exchangeable Ca than the chalk plants and grewpoorly in the absence of CaCl₂, perhaps due to the developmentof Ca deficiency Bryophyte growth, calcium uptake, pH, mineral nutrition, Pleurozium schreberi, Pseudoscleropodium purum, Calliergon cuspidatum     

Establishment of Isolated Root Cultures of Brassica Species and Regeneration from Cultured-root Segments of Brassica oleracea var. italica

Isolated root cultures which could be maintained over severalmonths by serial subculture were established from Brassica oleraceavar. italica cv. Green Comet F₁. A modified White's medium wasfound to be the best of several salt compositions tested. Theeffects on isolated root growth of the following were also examined;nutritional components, culture vessel type and closure, pHof the medium and auxin type and concentration. Using a mediumdevised for Green Comet, root cultures were established fromsix other B. oleracea, B. napus and B. campestris cultivars. It was possible to regenerate shoots from segments of culturedroots by incubation on agar-solidified media containing cytokininand auxin. The effects on regeneration of various auxins andcytokinins were investigated; the combination of Picloram withKN gave the highest frequency of shoot formation. It was demonstratedthat isolated roots retained their regenerative ability overa period of 5 months in culture. Brassica oleracea var. italica, Brassica napus, Brassica campestris, isolated root culture, shoot regeneration, organ culture     

Effect of silver nitrate on sugarcane cell suspension growth, protoplast isolation, ethylene production and shoot regeneration from cell suspension cultures

Silver nitrate (AgNO₃), an inhibitor of the physiological actionof ethylene, reduced cell growth, promoted ethylene production,increased the yield of protoplasts and reduced shoot regenerationfrom sugarcane heterogeneous cell suspension cultures. The increasein the rate of protoplast isolation from cultures treated withAgNO₃ (0 to 59 µM) correlate with an increase in endogenousethylene production by the cells. The addition to the culturemedium of chemicals that either inhibited (aminoethoxyvinylglycine,AVG) or promoted (aminocyclopropane-1-carboxylic acid, ACC)ethylene biosynthesis did not alter the number of protoplastsisolated from these cultures. However, protoplasts were isolatedwith AVG in combination with AgNO₃ even though ethylene productionwas inhibited. These results suggested that AgNO₃ may be havinganother more direct effect on protoplast release. One such sitemay be the cell wall or on cell metabolism conditioning cellsto release protoplasts after enzyme treatment. Key words: Sugarcane, cell suspension, protoplast, silver nitrate, ethylene     

Phase Change in Hedera helix L: II. THE POSSIBLE BOLE OF ROOTS AS A SOURCE OF SHOOT GIBBERELLIN-LIKE SUBSTANCES

When synthesis was estimated by the agar diffusion techniqueboth basal and lateral adventitious roots of Hedera helix L.in the juvenile growth phase were shown to synthesize gibberellin-likesubstances. Seedlings and cuttings from juvenile ivy could begrown in water culture for several weeks. When roots were excisedfrom these plants shoot growth was reduced in comparison withthat of intact plants. The stems, apices, and leaves of derootedseedlings and cuttings contained lower levels of extractablegibberellin-like substances than comparable organs of intactplants. The major zone of gibberellin-like activity in intactplants co-chromatographed with gibberellins A₁ and A₃. Whenthese gibberellins were applied to plants grown in culture theywere found to promote growth of intact but not derooted plants.These findings are discussed in relation to the role of rootfactors and particularly gibberellins in phase change.