Changes in macromolecule syntheses, especially RNA synthesis, and the energy providing system were investigated in seeds ofAgrostemma githago aged for different periods. In embryos of aged seeds all macromolecule syntheses start later and reach a lower level than young ones. It was found that the synthesis of rRNA in embryos of aged seeds is reduced whereas the synthesis of poly (A⁺) RNA in relation to the total RNA synthesis is highly increased as well as the amount of this RNA species with long poly (A) chains. The results are discussed in connection with the decreased protein synthesis and the reduced ATP content and ATP formation ability in embryos during the long time storage of seeds.

A NADH-ferricyanide reductase activity found in radish microsomes isolated from germinated seeds has been shown to be stimulated by pCMB and pCMBS which are both strong nactivators of many plant proteolytic enzymes. In the same preparation a leucine aminopeptidase was found while endoprotease and carboxypeptidase activities were not detected using exogenous substrates. The aminopeptidase, highly active at the same optimal pH-condition of FeCN reductase, was stimulated by CoCl₂ and non-polar detergents (Triton X-100 and Brij 35). It was inhibited by sulphydryl reagents. By gel filtration of microsomal detergent extract two peaks of activity were separated: red I coeluted with LeuAPase and red II, free of aminopeptidase. Red I, a protein, was inhibited by sulphydral reagents and stimulated by duroquinone. Red II, stimulated by pCMB, is not a protein because of the small size and the noninfluence of heating treatment on catalytic activity.

A binary vector system inA. tumefaciens for the introduction of foreign genes into the plant genome was developed. The first component is the Ri plasmid and the second component is a small vector plasmid, replicating inAgrobacterium, which carries the 25 bp terminal sequence of the Ti plasmid, theNos gene as the selectable marker and neighbouring sequences of the Ti plasmid. Functions necessary for integration are providedin trans by the virulence region of the Ri plasmid. Transformed cells are selected on the basis of hairy root tumor proliferation and agropine synthesis. They also showNos activity coded by the gene on the small part of Ti T-DNA.

Nuclei fromZea mays L. root tip meristematic cells were treated according to the conventional method for nuclear matrix isolation and according to a recently adapted procedure for isolation of nuclear shells from plant cells. In the first case, after high salt extraction of proteins and DNase I and RNase digestions, residual structures are obtained consisting of a periferal layer and an internal network. The obtained structures are very similar to the nuclear matrix preparations from animal cells. In case nuclei are swollen in EDTA first, digested with DNase II and RNase prior high salt treatment, structures devoid of internal network are obtained. The analogous residual structures were shown forPhaseolus vulgaris L. meristematic root cells nuclei (Galcheva-Gargovaet al. 1988). The morphology and the protein composition of the two types of residual structures suggest that the organization of scaffold structures from plant nuclei is very similar to the one from animal cell nuclei.

Twenty six winter wheat cultivars representing early maturing (Em), medium early maturing (Mm), and late maturing (Lm) cultivar groups were grown in the field for two growing seasons. The dates at which plants reached the double ridge (DR) and terminal spikelet (TS) stages were determined using anatomical analysis of shoot apices. Thereafter the dates of anthesis (AN) and full maturity (MA) were recorded. The length of the time spans between subsequent developmental stages was then expressed both chronologically (number of days, d) and in terms of thermal time (degree day, °C d) which was calculated with the basal temperature equalling to zero. The results obtained confirmed the suitability of the utilization of degree days for the description of the time course of plant development, because the great differences in the time between subsequent developmental stages recorded between the two growing seasons when expressed in terms of numbers of days markedly diminished when expressed in terms of degree days. For example the period DR-MA expressed in number of days amounted in the year 1986 only to 87 % when related to the number of days recorded in the year 1985, whereas the corresponding value expressed in terms of degree days amounted to 98 %. The utilization of degree days is especially suitable for the AN-MA period (956 and 937 degree days in the years 1985 and 1986, respectively) within which temperature is the main factor determining the rate of plant development. Further analyses of the effects of basal temperatures, vernalization, and daylength appear to be necessary for a better understanding of the length of the period to the DR stage and differences among groups of cultivars and among different cultivars.

It is shown that, contrary to what is generally found, treatment with abscisic acid (ABA) of potato leaf tissues resulted in an increase of K⁺ uptake. Comparison with other hormones was made: BAP induced an inhibition and GA₃ a stimulation of K⁺ uptake. The uptake was sensitive to several metabolic inhibitors, external pH and ATPase inhibitors while p-chloromercuribenzenesulfonic acid (PCMBS) had no effect. Uptake kinetics revealed the presence of both saturable and linear components which were both stimulated by ABA treatment. Our data are consistent with an effect of ABA on the active and passive components of K⁺ uptake. These results are discussed in relation to the action of ABA on foliar senescence and the action on ion partitioning in the whole plant.

Potassium (K⁺) and nitrogen (N) supply affect stomatal apertures within the daylength conditions. There is a negative proportion between potassium supply and stomatal pore area: the smallest pores were to be found in the plants with K⁺ surplus, whereas the plants in K⁺ shortage had the largest pores. This is interpreted as a reaction of the plant to get more ions by an increased transpiration stream. With different nitrogen concentrations in the supply solution a similar proportion could be found, with the exception of the condition "N shortage in shortday", and further testing is necessary. The ionic supply has a parallel effect in both daylengths.

Spring barley seedling were grown in the dark for 21 d and respiration rates of the whole plant (including the seed), of the shoots, and of the roots were determined. A function describing the growth and maintenance components of respiration was interpolated through the experimental points and its parameters in plants under different mineral nutrition were compared. The plants grown in a complete nutrient solution showed the highest growth rate in the initial phase of development and thus reached the maximum respiration rate earlier than plants in the other variants. The highest proportion of substrate was respired in the shoot. Plants grown under deficiency of phosphorus and magnesium had a slower respiration rate than plants grown in the complete nutrient solution (NP), whereas the amount of respired substrate in plant parts was similar to that recorded in the NP plants. Plants grown in distilled water showed the lowest growth efficiency and respirated the highest proportion of substrate in the root.

Aqueous salicylate solutions stimulated ethylene formation only when injurious, or potentially injurious, concentrations were exogenously supplied to soybean cuttings. Stimulation occurred via the biochemical sequence involving ACC as an intermediate, and was attributable to stimulation of ACC synthesis but not of EFE activity. Similar results were obtained by testing wound-induced ethylene, whereas the production of virus-induced ethylene was not affected by salicylate. Prolonged salicylate treatments which did not produce evident injurious effects inhibited soybean growth and rooting, probably through the moderate antiauxinic property attributable to salicylates. These findings are discussed in relation to other results obtained from similar or different plant materials.

Plasticity of the tobacco genome was studied by testing the DNAs of protoplast-derived regenerants with three different repetitive DNA sequences by the method of quantitative DNA/DNA hybridizations. A large population of 91 regenerants belonging to 35 different protoclones was analysed and a high degree of heterogeneity in the contents of the different DNA repeats was detected. The contents of middle repetitive sequences of two types were more stable or changed in the same direction, while the highly repetitive sequence varied independently and displayed a significant reduction in comparison with the two other sequences. Comparing the variation within the subpopulations of plants of the same clonal origin and the variation among the protoclones led to a conclusion that the pre-existing DNA variability in the starting plant material and/or thein vitro stress during the very early stages of protoclone regeneration played a decisive role in the formation of modified genomes in regenerants.

Extract of the seeds ofAnona reticulata, Camellia sinensis, Bauhinia acuminata, Cassia tomentosa, Malus sylvestris, Trigonella foenumgraecum, Cephalandra indica, Lawsonia inermis, Anacardium occidentale, Mangifera indica, Nephelium litchi, Citrus lemoni, Aegle marmelos, Quassia amara, Mimusops elengi, Achras sapota, Datura stramonium, Thevetia nerifolia, Persea americana andCycas circinalis, were screened for lectin activity by haemagglutination and haemagglutination inhibition assays. Lectin-like activity was detected only in the seeds ofMangifera indica and Perseaamericana. The conventional methods for the isolation of lectins could not separate the haemagglutinins from the extracts. The properties of these agglutinins suggest that they are not lectins.

Five days of suitable continuous light induced flowering in the majority ofChenopodium murale L. ecotype 197 plants as early as at the phase of the first pair of leaves. At the time of initiation of the 2nd to 4th pairs of leaves the capacity of plants to flower was reduced, the number of flowering plants being significantly lower under the same inductive light treatment. The capacity to flower increased again at the phase of the 5th and the 6th pairs of leaves. Inductive light treatment brought about a marked growth activation of organs present before induction, shoot apex elongation, precocious formation of new leaves and activation of axillary meristems. The course of these changes in plants of different age is demonstrated. The terminal flower developed during 5 short days following inductive light treatment. The paper shows similarities and differences between long-daymutale L. ecotype 197 and short-day C.rubrum L. ecotype 374 grown under practically uniform conditions.

Soil drenches containing 250 μg of paclobutrazol or uniconazol (50 ml of a 17 μM solution) reduced the height of both corn (Zea mays L. cv. How.Sweet It Is) and soybean (Glycine max (L.) Merr. cv. A2) seedlings. With corn, uniconazol was considerably more active than paclobutrazol in reducing height whereas with soybean both compounds had similar dwarfing effects. The compounds increased foliar chlorophyll content and leaf thickness in soybean but had no effect on these parameters in corn. The increase in leaf thickness with soybean was due primarily to an increase in the thickness of the palisade cell layer. Chloroplast size and ultrastructure of both species were unaffected by the compounds. The growth regulators increased root diameter in both corn and soybean because of increased size of cortical parenchyma cells and particularly in soybean because of radial rather than longitudinal growth of the first few layers of the cortical parenchyma.

Lemna gibba G3 is an ideal system for studying the chemical control of flowering in a photoperiodic plant due to its small size and aquatic growth habit which allow substances to be taken up continuously and rapidly distributed throughout the plant. Each of the known plant growth regulators has been tested onL. gibba G3 and only the gibberellins appear to be important for flowering, although they are not the limiting factor for flowering on short days. Salicylic acid (SA) and ferricyanide will both induce flowering inL. gibba G3 with ferricyanide being most effective on short days where flowering is daylength limited and SA most effective where flowering is limited by factors other than daylength. The ferricyanide action is probably due to HCN and it may act during photoperception or photoinduction. SA is most effective when reversing the inhibition caused by various parameters including copper and agar, and its effect is always strongly daylength dependent. It is postulated that SA may interact with the flowering stimulus to promote flowering and thus that SA acts at some point following photoinduction and the formation of the flowering stimulus.

Data on (1) permitivity and dielectric losses, (2) free radical concentrations, and (3) potassium, sodium, magnesium, calcium, nitrogen, and amino acid contents in tissues of nodal roots, internodes, and leaves of maize plant are presented in the paper. The participation of these factors in the transport phenomenon and the degree of their cooperation in the transport process are discussed.

Life span of the second leaf of wheat(Triticum aestivum L., cv. Grana) plants was studied from day 8 to day 50 of plant age in a variant with nitrogen (+N) and in a variant in which plant senescence was induced by the omission of nitrogen from the nutrient solution (-N). Seed protein was the sole source of nitrogen for these plants. Specific leaf mass (SLM) in the -N variant, and specific leaf area (SLA), the mass of fresh leaf, soluble protein content and total nitrogen content in the +N variant peaked by day 22 of plant age (that is by day 19 of leaf age). Dry matter content, leaf length and leaf area, and SLM in the +N variant peaked by day 29 of plant age (that is by day 26 of leaf age). The ontogeny of the second leaf in the variant with enhanced senescence was shorter by at least 14 days. Plants from this variant showed typical symptoms of N deficiency, that is yellowing of leaves, tip burn, and lack of tillering. However, the growth and biochemical characters studied did not indicate an earlier onset of the senescence of the second leaf of -N plants. Both +N and -N variants reached their peaks (with the exception of an earlier peak by day 12 in case of total nitrogen content in the -N variant) on the same day of leaf age. Thus the first part of the leaf life span from leaf growth initiation to full expansion was of the same length in both the control and N-def icient plants. The stage of the proper senescence of the second leaf of -N plants was very short; the leaf completely died away within 7 days after senescence onset.

In short-day plantChenopodium rubrum the photoperiodic requirement for flowering increases from one short day at the age of four days to two or three short days at the age of five to seven days. The photoperiodic requirement decreases again to one short day between the 10th and 12th day of cultivation. This feature, together with endogenous circadian rhythmicity of flowering, enabled us to test the effects of PGRs under different morphogenetic patterns. Representative PGR effects on flowering are quoted.

Potato plants were transformed by the A.tumefaciens vector which integrates into the plant genome two foreign genes only: pTi C58 T-DNA gene 4 (ipt) responsible for elevated synthesis of cytokinins and kanamycin resistance gene. Three teratoma clones studied showed approximately 3 times, 6 times and 9 times increased levels of zeatin riboside and zeatin in comparison with untransformed controls and slight increase of the IAA level. Shoots formed roots in agar cultures sporadically, if the increase of zeatin riboside and zeatin levels was not higher than 6 times the control level. The chlorophyll content and net photosynthetic rate decreased with increasing levels of zeatin and zeatin riboside.

Two classes of phosphonopeptides, those containing P-terminal 9-aminofluoren-9-ylphos-phonic acid and those of dialkyl 9-aminofluoren-9-ylphosphine oxides, influence plant growth according to different mechanisms. The effect of these compounds on the growth of several bacterial species, including the photosynthetic bacteriumRhodospirillum rubrum, as well as on the activity of photosystems 1 and 2 in isolatedPisum sativum andSpirodela oligorrhiza chloroplasts was studied. The peptides of free, unblocked 9-aminofluoren-9-ylphosphonic acid acted in a morphactin-like manner, whereas those of dialkyl 9-aminofluoren-9-ylphosphine oxides influenced photosynthesis indirectly.

Growth rate of leaves of winter barley (Hordeum vulgare L. cv. Efra) plant in thermal time correlated with the final length of the corresponding leaf (r = 0.66). The sum of effective temperatures corresponding to the time of growth of a particular leaf linearly increased with leaf insertion (r = 0.82). Phyllochron value in plants grown in the field with either natural or controlled photoperiod was dependent on phyllochron order, especially up to the double ridge stage (r = 0.89 and r = 0.74, respectively). The mean value of phyllochrons in the field variants showed a very good agreement with the value calculated on the basis of the change in day length at the time of seedling emergence.

Exogenoualy applicated indol-3-ylaeetic acid (IAA) is metabolized mainly to IAA aspartate in intact plants and plant segments and to IAA glucose in suspension cultures fromBeta vulgaris andChenopodium album.
Main metabolic product of D-tryptophan is N-malonyltryptophan in both suspension cultures and hypocotyl segments of both species. The turnover rate of L-tryptophan to IAA is comparatively low (0.1 %); inBeta the turnover rate is higher than inChenopodium. In sugar beets phenmedipham leads to a decrease in the IAA. biosynthesis rate in suspension cultures of both plant species. There is, however, an increase in the IAA content in all intact plants. The metabolic activity is substantially higher in suspension cultures than in intact plants and plant segments.

It is generally accepted that plant growth and development are regulated by the known plant hormones. Some objections to the functions of auxins and cytokinins in the induction of shoot and root primordia are reported. Instead of them oligopeptides of special amino acid sequences could be the endogenous signals. There exist structure relationships between auxins and parts of the α-helical oligopeptides of defined amino acid sequences. The same is true for cytokinins.
The most difficult part of this hypothesis is its verification. Using protonemata ofFunaria hygrometrica bud induction by various oligopeptides was investigated. The most active peptide tested is leucine-tryptophan. On the other hand endogenous oligopeptides containing [¹⁴C]-leucine in the moss protonemata during endogenous bud initiation were looked for. Three to four different oligopeptide spots seem to be related to bud induction.

The effect of GA₃, IAA and kinetin in concentration range from 5.10^-4 to 5. 10^-8M, single or in combination, was tested on the flowering of short-day plant (SDP)Chenopodium rubrum (selection 374). All substances were applied as a droplet (3 (μl) of water solution before the onset of inductive photoperiod which brought about a threshold level of induction. Flowering was enhanced only in the presence of GA₃ and the other two PGR decreased its effective concentration by one or two orders of magnitude. It is likely that the morphogenesis of the apical meristem was directly affected by such treatment. There is no need to assume that the ratio of employed plant growth regulators is important for the observed morphogenetic effects, but rather the actual concentrations are involved.

Lemon plants (Citrus limonum L. cv. Verna) were grown in the field under two different flood irrigation treatments. The dry treatment received four irrigations per year (March, July, September and November) and the wet treatment one monthly. The amounts of water applied per year for dry and wet treatments were 340.0 mm and 1020.0 mm, respectively. The effects of the two treatments on certain aspects of the plant water relations during the period between flowering and the end of rapid fruit growth (critical period) were studied. Soil matric potential (ψm) and leaf water potential (ψi) values in the dry treatment revealed development of water stress during the experimental period. The water supply in the wet treatment seems sufficient to achieve the crop water requirements. The g₁ values in July were higher in the wet than dry treatments. Pronounced oscillations in g₁ from sunrise to afternoon were found especially in the dry treatment.

The possibility that some of the variation in callus cultures involves epigenetic changes is examined in cultures established from the hypoootyls and roots ofEuphorbia heterophylla. It is shown that the responses of the cultures are affected by the light regimes under which they are grown and that in the dark and under short photoperiods, there are differences between the two types of culture with respect to pigmentation, auxin requirement, capacity to regenerate buds and roots and in certain isozyme patterns, whereas the two cultures are similar from the first passage under continuous light. However, these differences are only maintained for 2-3 passages, after which the root callus becomes similar to the hypoc otyl callus. Evidence is presented that these differences between cultures are epigenetic. Callus cultures established from the apical meristems of shoots and roots ofE. hetero phylla show similar differences to those observed between hypocotyl and root cultures and these differences are also lost after 3 passages. These results indicate that the cells of apical meristems are not totally uncommitted, but are determined as 'shoot' and 'root' meristem colls, respectively. The practical importance of a better understanding of epigenetic effects in plant cells is strassed.

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 phosphorus deficiency on the activity of acid phosphatase of the first, second and third leaves of maize plants was followed. The supernatant obtained by centrifuging the homogenate of plant tissue at 1500 ×g was further centrifuged at 18 000 ×g, the sediment marked as fraction II and the supernatant as fraction III. Acid phosphatase activity of fraction II of the first to third leaves was for the whole period of culture higher in plants grown in the nutrient solution without phosphate. In fraction III this relation was established in the first leaf, after 3 days of culture in the second leaf and after 5 days in the third leaf. In all leaves higher enzyme activity was unambiguously determined in fraction III when compared with fraction II. Higher acid phosphatase activity was established in those leaves which were younger in their development, particularly in the first days of culture. With the ageing of leaves the enzyme activity decreased.

Exogenous supply of Spd and Spin stimulated ethylone production in detached tobacco leaves kept in the light. Stimulation, that was first detected after 9 but not 6 h of treatment, linearly increased with concentration and was maintained for several h after returning treated leaves to deionized water. Stimulation of ethylene production was prevented by AVG and Co²⁺ and was accompanied by increased activity of ACC synthase and ethylene-forming enzyme. Put, and other diamines, did not give any stimulatory effect. Stimulation was not accompanied by apparent damage of plasmalomina nor was it reversed by Ca⁺ or Put, suggesting that the cationic properties of polyamines are probably not involved. Stimulation might be due to endogenous polyamine accumulation high enough to inhibit the activity of S-adenosylmethionine decarboxylase, so that all S-adenosyhnethionine might be committed to the ethylene pathway. The stimulatory effect of poly a nines acquires particular interest considering that they have so fur been doscribod to inhibit ethylone production in darkened plant tissues. This finding suggests that polyamines may play a regulatory role in plant development by modulating ethylene bio-synthesis under the control of light.

The accumulation of nitrogen and potassium by plant cells at undesirable concentrations manifests itself in changes in the osmotic phenomenon and finally in the transport process. Temperature gradient is another factor influencing the transport phenomenon. We have followed the changes in the electric diffusion potential and the heat transfer under the influence of these two factors on transport properties of roots of plants grown under conditions of either salinity or nutrient deficiency on the transport of KG solution through segments of the first node roots and of the primary root. Physical causes of the accumulation of the above mentioned ions were then studied by means of a mathematical model. The results obtained showed that high KNO₃ concentration in nutrient solution caused an inhibition of volume and heat flows, stimulated osmotic flow, and reduced electrical polarization of root cells. Cell polarization was slowed down when temperature gradient was increasing and enhanced when temperature gradient was decreasing. This indicates that the pressure difference between the exterior and the interior of root cells was levelled off by osmotic water flow but not by potassium ion flow.