The present investigations were designed to elucidate the linkage of medium acidification to metabolism and to study the influence of phytohormones (IAA, ABA) and fusieoccin (FC) on H+ extrusion from peeled leaf tissue of Vicia faba. H+ release, which was sensitive to the metabolic inhibitors sodium azide, vanadate, DCCD, and cycloheximide, was promoted by 5 to 50 μM IAA and 10 μ FC, but transiently diminished by 10 μM ABA. FC was a much more powerful inducer of H+ extrusion than IAA. Other weak acids such as acetate and citrate had no effect on H+ extruding activity of Vicia leaf tissue indicating that the IAA effect is specific. These results support the view that IAA and ABA control of cell growth can be attributed entirely to a modulation of H+ pump activity.

The rooting ability of 2 cm long shoots ofPisum sativum L., derived from differentin vitro shoot-tip cultures in two pea cultivars Bohatýr and Kleine Rheinländerin was evaluated. In three mutually independent experiments the full and half-strength Murashige-Skoog medium (containing full or half concentration of macro and microelements), with sucrose concentrations 10-30 g l-¹, and with various NAA and IAA combinations, was tested. The variant with half concentration of macro- and microelements, supplemented with 30 g l¹ sucrose, and with growth regulators in the quantity of 1 μM proved optimum.

High rates of oak shoot multiplication were achieved on low salt nutrient media (BTM, WPM) supplemented with adenine type cytokinin or BAP. Low concentration of (0.2-0.6 mg 1^-1) stimulated formation of a large number of axillary shoots and their elongation. Thidiazuron in very low concentration (0.001 - 0.002 mg 1^-1) promoted shoot proliferation, in high concentration stimulated formation of large callus. More than twelve thousand micropropagated shoots were rooted in low salt agar media supplemented with low concentration of auxin (IBA or NAA 0.2 - 0.5 mg 1^-1). High rooting percentages (81 %) were obtained. Survival of the mieropropagated plantlets transplanted into soil was high (78 %). Micropropagated trees planted in the field withstood severe winter frosts without significant losses. At the end of the fifth growing season trees attained considerable size.

The changes in cell division rate were studied in different components of the shoot apex ofChenopodium rubrum during short-day photoperiodic induction and after the inductive treatments. Induced and vegetative apices were compared. Accumulation of metaphases by colchicine treatment was used to compare the mean cell cycle duration in different components of the apex. A direct method of evaluating the increase in cell number obtained by anticlinal or periclinal divisions was applied if the corresponding components of induced and non-induced apices had to be compared. The short-day treatment prolonged the cell cycle more in the peripheral zone than in the central zone and still more in the leaf primordia. The importance of changing growth relations for floral transition was shown particularly if the induced plants were compared with the vegetative control with interrupted dark periods. Induced plants transferred to continuous light showed further changes in the rates of cell division. The cell cycle was shortened more in the central zone than in the peripheral zone,i.e. there was a further shift in growth relations within the apical dome. The cell cycle in the leaf and bud primordia was also shortened if compared with the vegetative control, the acceleration being stronger in the bud primordia. There was a subsequent retardation in cell division in the leaf primordia formed during and after the inductive treatment if the plants were fully induced. An inhibition of the oldest bud primordia was observed in fully induced apices, as well.

Plant growth and seed yield of mung bean were studied in sand culture at different levels of NaCl [0, 50, 100, 150, 200, 250 mM] in the root medium. Results showed that both dry matter yield and seed yield of plants grown for 14 weeks at 50 mM NaCl and 100 mM NaCl were around 60 % and 25 %, respectively of those for plants grown in control solution. Higher concentrations caused wilting and necrosis of leaves. Very effective exclusion of Na and Cl from salt grown mung bean seed was observed with concommitant high accumulation of Na and Cl in the stem. It is speculated that mung bean plant stem may act as a 'sink' for NaCl during the reproductive stage of the plant growth cycle.

Seedlings of spring barley,Hordeum vulgare L. cv. Mirena, were grown in complete mineral solution (Richter's solution: R) or in solution lacking either phosphorus (R-P) or nitrogen (R-N) at low (LI: 28 W m^-2) or high (HI: 122 W m^-2) irradiance. Plants were kept in controlled environment chamber with 16 h photoperiod and 20 °C/15 °C day/night temperature. The experiment was terminated after 15 days when plants grown under R -N nad HI conditions died. The content of chlorophyll was estimated during the plant growth and content of nitrogen and phosphorus was determined at the end of the experiment. Deficiency of N and P induced higher chlorophyll formation at low irradiance. The efficiency of nitrogen and phosphorus utilization,i.e. ratio of plant dry mass/weight of N and P, respectively, per plant, was higher at HI in all experimental variants. Extremely high value of P utilization was found in plants grown under P-deficiency (850) as compared to the control (80). Understanding of interactions between the irradiance and deficiency of mineral nutrients is necessary for optimization of fertilization and understanding the mechanisms of action of mineral substances on plant structures and functions.

A reduction in abscisic acid (ABA) content was not a pre-requisite for the breaking of dormancy of vegetative lateral buds of both field-grown trees and shoots of willow (Salix viminalis L.) maintained in controlled conditions. Similar variations in bud ABA levels were observed whether the shoots were stored in a warm (22 ± 1 °C) or cold (6 ± 0.5 °C) environment. Following transfer to a growth room the ABA content of chilled buds declined more rapidly than did that of non-chilled buds.

Ten centimeter long stem cuttings of sweet potato (Ipomoea batatas L. cv. Georgia Jet) with intact apex and leaves were cultured in distilled water as well as in varying concentrations of abscisic acid (ABA) in open top chambers at 364, 438 and 666 cm³ m{-3}CO₂. Low concentration of ABA promoted rooting and elongation of roots at 364 cm₃ m{-3} CO₂ while rooting was suppressed at enriched levels of CO₂. However, biomass production in shoots and roots was higher in 666 than in 364 cm³ m^-3 CO₂.

The effect of several plant growth regulators on the number of tumors developing on potato tuber discs (Solatium tuberosum L. cv. Radka) inoculated withAgrobacterium tumefaciens, strain C 58 was studied. The plant growth regulators used in appropriate range of concentrations stimulated the formation of tumors byA. tumefaciens.
Naphthaleneacetic acid (NAA) was most active in concentration of 10^-4 mg ml^-1. Kinetin gave a biphasic response with optimal promotions of tumor initiation at 10^-4 - 2 × 10^-3 mg ml^-1. High kinetin concentration (10^-1 mg ml^-1) inhibited the formation of tumors completely. Indoleacetic acid (IAA) stimulated the initiation of tumors in the same range of concentrations as kinetin, except that very high concentrations did not inhibit but enhanced tumor formation. 2,4-diehlorphenoxyacetic acid (2,4-D) showed a biphasic response with maxima in 10^-4 mg ml^-1 and 10^-1 mg ml^-1. All the tumors scored for nopaline production showed nopaline synthase activity independently whether their formation was stimulated by l0^-1 mg ml^-1 IAA or they were initiated without any treatment by plant growth regulators.

Trichoblasts ofGibasis geniculata andTradescantia, fluminensis were observedin vivo under the polarizing microscope with the first-order red plate of a retardation of 530 mµ. It was revealed that the cell wall's birefringence in plane view was negative with respect to the apicobasal axis of the cell in young cells before elongation, turning positive after elongation. Birefringence has never been observed when the cellular polarity was disturbed by colchicine. Therefore, it seems that the cellular polarity of root hair formation is controlled by anisotropic structures of the cell wall.

Net CO₂ exchange rates, stomatal and internal resistances for CO₂-transport were followed on fully expanded Witloof chicory leaves (Cichorium intybus L. cv. Foliosum) for several months during vegetative growth. Maximum net CO₂ exchange rate (P_max) stayed high with a sudden drastic drop at the end of the growing season largely due to an increase in internal diffusion resistance.
During an analogous growth period the H₂O vapour diffusion resistances of leaves for four selections were measured. The adaxial stomatal resistance was always higher than the abaxial one. Stomatal densities calculated for those selections showed higher values at the abaxial leaf side.

Genotypes of mustard (B. juncea) were evaluated for concurrent changes in leaf water potential (Ψ), leaf osmotic potential (π), leaf turgor potential (P) and leaf relative water content (RWC) during moisture stress at reproductive stage of growth. The slope 'b' in the regression between Ψ and π varied from 0.43 to 0.97 and was positively correlated with P and RWC. The genotypes with 'b' around 0.7 were able to maintain P of about 0.5 MPa at Ψ of - 2.5 MPa and thus such value of 'b' seems to provide enough degree of tolerance against drought.

The effect of the growth substances indol-3-ylbutyric acid (IBA), kinetin (Kn) and gibberellic acid (GA3) on the alkaloid content and recovery from the stress induced by removal of roots inNicotiana rustica L. plants have been studied. All treatments, mainly GA₃, overcome the stress more effectively than the controls. The alkaloid content was increased 2.5fold with GA₃. Treatment with Kn also increased the alkaloid content, but only in the absence of roots. In contrast, treatment with IBA slightly reduced the alkaloid content. The results of this investigation indicated that a degradation of stored alkaloids did not occur in spite of the stress.

Both axillary buds belonging to the cotyledons (cotyledonary buds) start to grow on decapitated pea seedlings, but one of them (the dominant shoot) prevails in growth over the other (the inhibited shoot). If the dominant' cotyledonary shoot is removed, the inhibited shoot is released from inhibition and starts to grow. This release from inhibition of the inhibited cotyledonary shoot is accompanied within two hours from the removal of the dominant cotyledonary shoot by a marked increase in the level of endogenous cytokinin-like substances and by a decrease in the level of endogenous IAA. By contrast, a significant increase in IAA level and a decreasing trend in the level of cytokinin-like substances occur in the originally inhibited cotyledonary shoot between hour 4 and hour 48 after the release from inhibition of the inhibited cotyledonary shoot. The level of gibberellin-like substances in the cotyledonary shoot released from inhibition steadily increases from the beginning of the release.

The effect of potassium administration in early germination of wheat (Triticum durum L., cv. Appulo) was studied by incubating isolated embryos at different viability levels with 1 mM KC1. The stimulation of germination and growth in aged embryos by K⁺ was accompanied by a significant increase in (³H) leucine incorporation into protein and in phospholipid synthesis as evidenced by TLC analysis of embryo phospholipids extracted after 24 h of imbibition. The metabolic improvement mediated by the cation would in turn repair aging damage occurring at subcellular sites including membranes.

Pollen embryogenesis occurred in anther cultures of two genotypes ofBrassica carinata A. Braun. Pretreatment of anthers at 35°C for 3 or 6 days was essential for the induction of androgenesis on growth regulator-free culture medium. A combination of sucrose and glucose was better than sucrose alone. None of the pollen embryos germinated normally. Full plants were raised through adventitious bud differentiation from their hypocotyl.

The study of in vitro growth of Crepis tectorum revealed 100 % callusing and 40 % plantlet regeneration. The root and leaf used as explants showed the normal diploid (2n=8) chromosome constitution. In one month old culture 95 % callus cells were diploid. The callus maintained in 2,4-D 1 mg 1-1 for two years showed 62 % diploid, 5 % tetraploid and 33 % hyperdiploid cells. The differentiation of shoot occurred in two year old calli after subeulturing in 2 mg I-1 BAP and the potentiality of regeneration was retained for more than one year. The leaf-tips of regenerated plants were homogeneous and identical to the donor plant both in number and morphology of chromosomes.

Daughter cells of the chlorococcal algaScenedesmus quadricauda were incubated under photosynthesizing conditions in a sulphur-free medium. The course of the cell cycle under these conditions was changed in daughter cells which differed in their stage of development. In absence of sulphur, advanced daughter cells with two nuclei and 2 or 4 genomes passed a cycle identical with that of control in sulphur containing medium. Each cell yielded eight binuclear daughter cells. With less advanced daughter cells (one nucleus and 1 or 2 genomes) restriction of RNA synthesis occurred near to the end of the cell cycle and protein synthesis ceased two hours later (practically at the time of the protoplast fission). The last round of DNA replication found in the control culture was not initiated in sulphur-starved culture and uninuclear daughter cells with one genome were released.
If the daughter cells coming from the starved populations were kept further in the sulphur-free medium, macromolecular syntheses were dramatically restricted. Only photosynthesis continued to produce starch at a similar rate as in normally grown cells. Thus, a very large amount of starch accumulated. Supported by these reserves, starved cells refed with sulphur passed an entire cell cycle in the dark and divided into eight daughter cells. In sulphur-supplied cells, both in the dark and in light, RNA, protein and DNA synthesis started without any delay in a similar way as in the control culture. Competition for sulphur reserves occurred between the growth and division processes; the former were preferred in the light and the latter in the dark.

Flag leaf removal at any stage of grain growth hastened senescence (reduction in chlorophyll content) of the sterile glumes whereas a removal of the latter did not alter senescence of the former. Kernel mass, grain mass per ear, harvest index and sink activity reduced more conspicuously by the removal of glumes than by the flag leaf removal. Removal of grains hastened senescence of the glumes only, although protein content increased at a later grain removal in the majority of source organs. Moisture contents of the developing grains were mostly reduced by the removal of either the flag leaf or the glumes, though flag leaf removal at anthesis affected it the most. Protein levels of the developing grains reduced at harvest only when the glumes were removed at anthesis but sugar levels in later phases always decreased irrespective of the time of removal and nature of the source organs.

Seedlings of spring barley,Hordeum vulgare L. cv. Mirena, were grown in a controlled environment chamber at high (HI: 122 Wm^-2) and low (LI: 28 Wm^-2) irradiance in the complete Richter's nutrient solution (R) or in solution lacking either phosphorus (R -P) or nitrogen (R -N). The experiment was terminated 15 days after sowing when plants (R-N) at HI ceased to grow. At that time the dry mass of one plant was 449.8 mg, 145.7 mg and 116.8mg at HI and 203.4 mg, 110.1 mg and 91.0 at LI for R, (R-P) and (R-N), respectively. Deficiency of P and especially N reduced the size of loaf area more under HI than under LI conditions. Specific dry mass of leaves was the highest in R-N plants. The values of relative growth rate and assimilation rate are presented. Interaction of the effects of deficiency of mineral nutrients and irradiance during cultivation should be analyzed in further experiments for determination of optimum conditions for utilization of mineral nutrients.

Festuca arundinacea Schreb. andDactylis glomerata L., which differ in their ecological requirements toward moisture conditions also express different levels of desiccation tolerance.F. arundinacea was less resistant to severe water stress, showing lower ability to avoid and to tolerate desiccation (according to Levitt's terminology, 1972). Growth stage of the leaves had no influence on the level of water deficits developed under the field conditions. It is concluded that adaptation ofF. arundinacea to growth in well watered environments might be associated with a decrease of desiccation resistance of its tissue.

The level of endogenous gibberellin-like and cytokinin-like substances was estimated in the plumule and the root of 2-to 3-day-old intact pea seedlings, in the plumule of seedlings from which the radicle was cut off, and in the root of seedlings from which the plumule was removed.
An increase in the level of gibberellin-like substances and a decrease in the level of cytokininlike substances in the plumule as a consequence of radicle amputation were observed within 48 h. Plumule amputation resulted in a decreased level of both gibberellin-like and cytokinin-like substances in the root in the same period.

Ultrastructural changes following increasing periods of water stress induced by means of polyethylene glycol 4000 (from 5 min to 18 h) were investigated in young epidermal cells of the primary roots ofZea mays. The sensitivity of the individual cell components to water stress was considered according to the time sequence in which their alterations appeared.
Endoplasmic reticulum (ER) and mitochondria proved to be the most sensitive cell components, their structure changing after 5 min of water stress. By 8 h of stress, the condensation of nuclear chromatin in some cells was apparent, preceding polyribosome degradation but not all the other changes of the stressed cells. Similar types of structural alterations appeared slightly earlier in the more differentiated epidermal cells. The rapid changes in the structure of ER and mitochondria coincided with the rapid decrease of water potential of the root tips and the immediate cessation of the root growth.

Dependence of the growth of this alga culture on temperature displays a wide interval of temperatures (from 4 °C to 30 °C) and the dependence of the sexual reproduction only a narrow one (from 18 °C to 25 °C). The optimum temperatures for both the processes are not so different (round 23 °C). Dependence of both the processes on irradiance displays a wide interval of irradiances in both eases (from 4 W m^t-2 to 80 W m^t-2 PhAR and higher). The optimum irradiances for these processes are very different (approx. 50 W m^t-2 PhAR for the growth and approx. 10 W m^t-2 PhAR for the sexual reproduction) under the experimental conditions used.

The quantitative changes of chlorogenic acid in shoots and leaves of two groups of grape vines differing in their flower- and fruit-formation have been studied. It was established that in most cases the acid level was lower in both shoots and leaves of grape vines with suppressed growth and intensified generative processes. The results obtained suggest that the lower content of chlorogenic acid is related to the reduced growth of shoots and acceleration of generative processes.

Fertilizer induced improvement of growth and yield of wheat (Triticum aestivum L. cv. Kalyan Sona), under salinity stress, was associated with an increase in the concentrations of nitrogen, phosphorus and potassium and a decrease in the level of chloride in the tissue. The concentration of chloride in grains was also reduced under high fertility as compared to low fertility condition. Results reveal that under both normal and saline conditions, nutritional improvement leads to higher chlorophyll concentration and increased efficiency of enzymes like nitrate reductase, ATPase, alkaline pyrophosphatase and amylase in the leaves. This imparts importance to fertilizer application under saline conditions.

An auxin binding protein fraction prepared by means of affinity chromatography on 2-OH-3,5-diiodobenzoic acid-Sepharose and gel filtration was used as antigen. The obtained rabbit antisera contained antibodies against the auxin, binding protein (ABP) and several contaminating proteins (nonABP). The nonABP could be separated on an appropriate affinity matrix omitting the TIBA analogue. After their immobilization on Sepharose antibodies directed towards contaminating, the proteins were isolated and immobilized, too. This IgGanti nonABP-Sepharose retains almost all contaminating proteins present in the specific eluates of the auxin affinity matrix. In a final affinity chromatography step on IgG-Sepharose a highly purified ABP could be eluted. This ABP was immobilized on Sepharose for the separation of monospecific antibodies against ABP (IgGanti abp). Using these antibodies the ABP could be localized within the outer epidermal cells of the coleoptile by immunofluorescence microscopy. From the inhibition of auxin induced elongation of coleoptile tissue by IgGanti abp it is concluded that the ABP is localized at the plasmalemma of the epidermal cells and that the ABP is involved in auxin action as a true hormone receptor.

Anodic oxidation of coumaric acid led to the inhibition of the process at the electrode due to a film which was formed after one-electron oxidation of the acid to phenoxy radical.By contrast, caffeic acid is oxidized in two steps-the phenoxy radical is formed in the first step, quinone in the second step. The inhibition of nitrate uptake by coumaric and caffeic acids is dependent on their concentration. 10^-4 M eaffeic acid totally inhibited nitrate uptake and the growth ofNicotiana tabacum cell suspension. 10^-6 M caffeic acid markedly inhibited nitrate uptake especially in the first three days after inoculation. 10^-6 M coumaric acid did not affect nitrate uptake and nitrate reductase activity, 10^-4 M coumaric acid inhibited nitrate uptake by day two after inoculation. Nitrate reductase synthesis correlated with the inhibition of nitrate uptake. Differential effects of coumaric and caffeic acids are explained on the basis of different products of their electrochemical oxidation.