Abscisic acid and gibberellic acid-regulated responses of embryos and aleurone layers isolated from dormant and nondormant barley grains

Dormant and nondormant isogenic barley grains were obtained by maturing grains under short day (SD) or long day (LD) growth conditions, respectively. Hormonal responses of isolated embryos and aleurone layers from these grains were studied. Addition of abscisic acid (ABA) reduced germination rate and percentage of embryos, and induced Rab (ABA-responsive) mRNA in aleurone layers from both types of grain. Embryos and aleurone layers from dormant grains responded stronger to ABA than those from nondormant grains. Gibberellic acid (GA₃) increased the germination rate and percentage of embryos from dormant grains and counteracted the ABA-induced inhibition of embryo germination. GA₃ did not affect the amount of Rab mRNA in aleurone layers, suggesting that expression of the Rab gene has no direct correlation with germination. The stronger response of embryos and aleurone layers from dormant grains to ABA may not be explained by higher endogenous ABA levels, but might be due to differences in hormone signal transduction. Aleurone protoplasts from dormant grains had a higher cytosolic pH than those from nondormant grains. To inhibit the ABA-induced Rab mRNA, a much higher concentration of weak acid was required for aleurone layers from dormant grains than for those from nondormant grains. A possible difference in ABA signal transduction between dormant and nondormant grains is discussed.     

Hypoxia interferes with ABA metabolism and increases ABA sensitivity in embryos of dormant barley grains

Two mechanisms have been suggested as being responsible for dormancy in barley grain: (i) ABA in the embryo, and (ii) limitation of oxygen supply to the embryo by oxygen fixation as a result of the oxidation of phenolic compounds in the glumellae. The aim of the present work was to investigate whether hypoxia imposed by the glumellae interferes with ABA metabolism in the embryo, thus resulting in dormancy. In dormant and non-dormant grains incubated at 20 degrees C and in non-dormant grains incubated at 30 degrees C (i.e. when dormancy is not expressed), ABA content in the embryo decreased dramatically during the first 5 h of incubation before germination was detected. By contrast, germination of dormant grains was less than 2% within 48 h at 30 degrees C and embryo ABA content increased during the first hours of incubation and then remained 2-4 times higher than in embryos from grains in which dormancy was not expressed. Removal of the glumellae allowed germination of dormant grains at 30 degrees C and the embryos did not display the initial increase in ABA content. Incubation of de-hulled grains under 5% oxygen to mimic the effect of glumellae, restored the initial increase ABA in content and completely inhibited germination. Incubation of embryos isolated from dormant grains, in the presence of a wide range of ABA concentrations and under various oxygen tensions, revealed that hypoxia increased embryo sensitivity to ABA by 2-fold. This effect was more pronounced at 30 degrees C than at 20 degrees C. Furthermore, when embryos from dormant grains were incubated at 30 degrees C in the presence of 10 microM ABA, their endogenous ABA content remained constant after 48 h of incubation under air, while it increased dramatically in embryos incubated under hypoxia, indicating that the apparent increase in embryo ABA responsiveness induced by hypoxia was, in part, mediated by an inability of the embryo to inactivate ABA. Taken together these results suggest that hypoxia, either imposed artificially or by the glumellae, increases embryo sensitivity to ABA and interferes with ABA metabolism.     

Modulation of germination of embryos isolated from dormant and nondormant barley grains by manipulation of endogenous abscisic acid

Dormant and non-dormant barley (Hordeum distichum L.) grains with identical genetic backgrounds were obtained by maturing grains under different climate conditions. When isolated embryos from dormant grains were incubated in a well containing a fixed volume of water (300 l), the germination rate and percentage were dependent on the embryo number per well. A higher embryo number per well was correlated with a lower germination rate and percentage. However, this was not the case for the embryos isolated from nondormant grains. During germination, the endogenous cis-abscisic acid (ABA) in isolated embryos from both dormant and nondormant grains was analyzed. The inhibitory effect on germination of a higher number per well of isolated dormant embryos was due to diffusion of endogenous ABA out of the embryos and accumulation of ABA in the incubation medium. Moreover, there was de-novo synthesis of ABA in embryos isolated from dormant grains during incubation but not in embryos isolated from nondormant grains. The inhibitory effect of ABA on germination of embryos isolated from dormant grains could be mimicked by addition of ABA or the medium in which dormant embryos had been placed. Embryos isolated from nondormant grains were insensitive to addition of ABA and medium from dormant embryos. Our results demonstrate that diffusion of endogenous ABA, de-novo ABA synthesis and ABA sensitivity play a role in the control of germination. It is proposed that dormancy-breaking treatments act via changes to these processes.Abbreviations ABA cis-abscisic acid - E/W embryo(s) per well Prof. K.R. Libbenga (Institute of Molecular Plant Sciences, Leiden University) is thanked for fruitful discussions. B.V.D. was partly supported by E.E.C. BIOTECH program PL 920175.     

Synthesis of abscisic Acid-responsive, heat-stable proteins in embryonic axes of dormant wheat grain

Germination of embryonic axes from dormant grain is inhibited by low concentrations of abscisic acid (ABA) compared with axes from nondormant grain. Incubation of dormant grain axes in 0.05 to 50 micromolar ABA caused the prolonged synthesis of a set of heat-stable proteins. Two of these proteins were identified as dehydrins. In nondormant grain axes, 100- to 1000-fold greater ABA concentrations were required to produce similar results. When embryonic axes of dormant wheat (Triticum aestivum) grain were imbibed without ABA, endogenous ABA levels increased 2.5-fold by 4 hours and then gradually declined. Heat-stable proteins were continuously synthesized for at least 18 hours. No increase in endogenous ABA was observed when nondormant grain axes were imbibed. Endogenous ABA levels in nondormant grain axes remained constant at 4 hours and then declined. The nondormant grain axes initially synthesized the heat-stable proteins, but that synthesis disappeared between 8 and 12 hours. These results showing the prolonged synthesis of ABA-responsive, heat-stable proteins by dormant grain axes, demonstrate that biochemical differences occur when axes from dormant compared with nondormant grains are imbibed.     

Grain Development Mutants of Barley ([alpha]-Amylase Production during Grain Maturation and Its Relation to Endogenous Gibberellic Acid Content)

Barley (Hordeum vulgare L. Himalaya) mutants with altered grain morphology were isolated to investigate whether defects in grain development, possibly involving gibberellins (GAs) and abscisic acid, would lead to altered patterns of [alpha]-amylase gene expression. Following treatment with sodium azide, 75 mutants, typically showing grain shriveling, were identified. At grain maturity 15 of the 75 mutants had higher [alpha]-amylase activities in shriveled grains compared with either phenotypically normal grains that developed on the same heterozygous plant or with grains of cv Himalaya. Studies of four of these mutants demonstrated increased levels of both high- and low-isoelectric point [alpha]-amylase isozymes midway through grain development. This category of mutant has been designated pga, for premature grain [alpha]-amylase. One such mutant (M326) showed an endosperm-determined inheritance pattern. When crossed into a (GA-deficient) dwarfing background there was a 10- to 20-fold reduction in [alpha]-amylase activity, suggesting a requirement for GA biosynthesis. Endogenous GAs and abscisic acid were quantified by combined gas chromatography-specific ion monitoring in normal and mutant grains of heterozygous M326 plants during the period of [alpha]-amylase accumulation. Mutant grains had significantly higher (5.8-fold) levels of the bioactive GA1 compared with normal grains but much lower (approximately 10-fold) levels of the 2[beta]-hydroxylated ("inactive") GAs, typical of developing barley grains (e.g. GA8, GA34, GA48). We propose that a reduced extent of 2[beta]-hydroxylation in the mutant grains results in an increased level of GA1, which is responsible for premature [alpha]-amylase gene expression.     

Molecular cloning and characterization of an inorganic pyrophosphatase from barley

A cDNA clone with sequence homology to soluble inorganic pyrophosphatase (IPPase) was isolated from a library of developing barley grains. The protein encoded by this clone was produced in transgenic Escherichia coli, and showed IPPase activity. In nondormant barley grains, the gene appeared to be expressed in metabolically active tissue such as root, shoot, embryo and aleurone. During imbibition, a continuous increase of the steady state mRNA level of IPPase was observed in embryos of non-dormant grains. In the embryos of dormant grains its production declined, after an initial increase. With isolated dormant and nondormant embryos, addition of recombinant IPPase, produced by E. coli, enhanced the germination rate. On the other hand, addition of pyrophosphate (PPi), substrate for this enzyme, appeared to reduce the germination rate. A role for this IPPase in germination is discussed.     

Studies on the Germination of Cereals 5. The Dormancy of Barley Grains during Ripening

The germinability of two barley varieties with different dormancycharacteristics has been determined during ripening, under fieldconditions on the plant, and under conditions of controlledhumidity after premature separation. In both cases, primarydormancy was lost more rapidly in the non-dormant variety (Domen)than in the dormant variety (Herta), and under conditions wherethere was an early reduction in the moisture content of thegrains. When the moisture content also fell to a lower levelthan in the field, primary dormancy in both varieties was almosteliminated by the normal time of harvest. Secondary dormancy,with recovery during dry storage, was induced in some grainsof the dormant variety, and also in a few of the non-dormantvariety, when their moisture content was increased by wet weatherat the harvest ripe stage. During the early stages of ripening, separation from the plantcaused an earlier reduction in the moisture content and an earlierincrease in the germinability of the grains of both varieties.The non-dormant variety, however, reached the same level ofgerminability, at the normal time of harvest, irrespective ofthe time of separation, whereas the dormant variety showed aprogressive decrease in germinability as the time of separationwas delayed. The condition of total primary dormancy during the initial growthof the grains was imposed by the covering layers, and therewas no varietal difference in the ability of the embryos togerminate when exposed. But when the moisture content of intactgrains was reduced at this stage, by separation from the plant,the same varietal difference in germinability became apparent.The possible effects of desiccation and the characteristicsof the two varieties are discussed in relation to the dormancyof grains when harvested.     

Some kinetic and steady-state properties of sodium channels after removal of inactivation

To study the kinetic and steady-state properties of voltage-dependent sodium conductance activation, squid giant axons were perfused internally with either pronase or N-bromoacetamide and voltage clamped. Parameters of activation, tau m and gNa(V), and deactivation, tau Na, were measured and compared with those obtained from control axons under the assumption that gNa oc m3h of the Hodgkin-Huxley scheme. tau m(V) values obtained from the turn-on of INa agree well with control axons and previous determinations by others. tau Na(V) values derived from Na tail currents were also unchanged by pronase treatment and matched fairly well previously published values. tau m(V) obtained from 3 x tau Na(V) were much larger than tau m(V) obtained from INa turn-on at the same potentials, resulting in a discontinuous distribution. Steady-state In (gNa/gNa max - gNa) vs. voltage was not linear and had a limiting logarithmic slope of 5.3 mV/e-fold gNa. Voltage step procedures that induce a second turn-on of INa during various stages of the deactivation (Na tail current) process reveal quasiexponential activation at early stages that becomes increasingly sigmoid as deactivation progresses. For moderate depolarizations, primary and secondary activation kinetics are superimposable. These data suggest that, although m3 can describe the shape of INa turn-on, it cannot quantitatively account for the kinetics of gNa after repolarization. Kinetic schemes for gNa in which substantial deactivation occurs by a unique pathway between conducting and resting states are shown to be unlikely. It appears that the rate-limiting step in linear kinetic models of activation may be between a terminal conducting state and the adjacent nonconducting intermediate.     

Dormancy of the barley grain is correlated with gibberellic Acid responsiveness of the isolated aleurone layer

The relationship between barley grain dormancy and gibberellic acid (GA₃) responsiveness of aleurone layers has been investigated. Barley (Hordeum distichum L. cvs Triumph and Kristina) grains were matured under defined conditions in a phytotron. Grains of Triumph plants grown under long-day/warm conditions had lower dormancy levels than grains of plants grown under short-day/cool conditions. Aleurone layers isolated from grains of long-day Triumph plants secreted more α-amylase and had a higher responsiveness to GA₃ as measured by α-amylase secretion. Storage of the grains increased both the percentage of germination and the responsiveness of the aleurone to GA₃. Use of different sterilization methods to break dormancy confirmed the correlation between germination percentage and aleurone layer GA₃ responsiveness. The response of embryoless Triumph grains to GA₃ was lower than that of the isolated aleurone layers, suggesting a role of the starchy endosperm in regulating the GA₃ response of the aleurone layer. Grains of the cultivar Kristina harvested from short day- and long day-grown plants lacked dormancy, and their isolated aleurone layers had a similar responsiveness to GA₃ as measured by α-amylase secretion. The data indicate that the physiological state of the aleurone layers contributes to the percentage germination of the grains.     

Involvement of phytohormones in germination of dormant and non-dormant oat (Avena sativa L.) seeds

Oat seeds are susceptible to high temperature dormancy. Dormant grainsdo not germinate at 30 °C unless afterripened, dry, for severalweeks. Isolated embryos of dormant grains do germinate, especially ifGA₃ is added to the germination medium. ABA inhibits germinationproportionally to the concentration applied and GA₃ can overcome theABA inhibitory effect. Measurements of endogenous ABA and several GAs revealedthat the initial levels of ABA in dormant and non-dormant grains were quitesimilar. But, endogenous ABA in non-dormant seeds almost disappeared within thefirst 16 h of imbibition, while the amount in dormant grains haddecreased by less than 24%. The level of GA₁₉ in non-dormant seedswas higher, and GA₁₉ appears to be converted to GA₂₀ within the first 16h. The GA₂₀ was converted to GA₁ at leastduring the first 48 h of the germination process. Bothphytohormones thus appear to be involved in the germination process ofnon-dormant seeds. ABA first declines, while GA₁ is producedduring the first 16 h of imbibition to allow proper germination.Indormant grains the level of ABA remained high enough to prevent germinationduring at least a week and precursor GAs were not converted to GA₁.     

Dormancy and enzyme levels in seeds of wild oats

Nine enzymes were compared in dry and steeped mature dormant and non-dormant seeds of wild oats. In dry seeds only glutamate-pyruvate transaminase and phosphoglycerate kinase were greater in non-dormant seeds. In steeped non-dormant seeds glucose-6-phosphate dehydrogenase activity doubled while the enzyme declined sharply in dormant seeds. Increases in isocitrate dehydrogenase, glutamate-oxaloacetate transaminase and acid phosphatase in non-dormant seeds, during steeping, are consistent with the hypothesis that the pentose phosphate and glycolysis-tricarboxylic acid pathways are involved in the control of dormancy of wild oat seed.     

Isolation and characterization of aleurone protoplasts from a malting variety of barley (Hordeum vulgare L.)

Summary A procedure has been developed to isolate protoplasts from mature aleurone layers of the malting variety Alexis and four other barley genotypes. It combines induction of endogenous cell wall degrading enzymes together with use of Onuzuka cellulase R 10 and driselase and results in better yields for two varieties than can be obtained with the huskless variety Himalaya. The viability of the freshly isolated protoplasts is greater than 90% and in spite of the presence of gibberellic acid during isolation procedures, most of the protoplasts are at an early developmental stage, as judged by ultrastructure. Gibberellic acid-induced changes in protoplast structure resemble those reported for Himalaya protoplasts. The protoplasts secrete both -amylase (EC 3.2.1.1) and (1-3, 1-4)--glucanase (EC 3.2.1.73) into the surrounding medium. Transfection studies using a low pI -amylase promoter to direct chloramphenicol acetyltransferase expression in aleurone protoplasts from Alexis and Himalaya revealed significant differences in their hormone responsiveness. In the absence of hormones, low levels of expression of the reporter enzyme were obtained in Alexis protoplasts, while high levels were characteristic for Himalaya protoplasts. An 8-fold increase in the expression of the reporter gene was induced by supplying the transfected Alexis protoplasts with gibberellin A₃, whereas expression in Himalaya protoplasts remained unchanged. When Himalaya protoplasts were isolated from aleurone layers that had not been incubated with GA₃ during the initial stages of protoplasting (the classical procedure), the hormone response of the promoter was 2.5-fold. It is thus possible to optimize the aleurone protoplast isolation procedure for different barley genotypes and mutants of interest in studies of transgenic gene expression and hormone induced secretion of proteins from this unique secretory plant tissue.Abbreviations ABA abscisic acid - APIM aleurone protoplast isolation medium - CAT chloramphenicol acetyltransferase - EDTA ethylenediamine tetraacetic acid - ER endoplasmic reticulum - GA₃ gibberellin A₃ - IgG immunoglobulin G - MES 2-(N-morpholino)-ethanesulfonic acid - PAGE polyacrylamide gel electrophoresis - PEG polyethylene glycol - pI isoelectric point - PIPES piperazine N,N-bis-(diethanesulfonic acid) - SDS sodium dodecyl sulfate     

Interaction of purified DNA with plant protoplasts of different cell cycle stage: The concept of a competent phase for plant cell transformation

Summary The polycation mediated attachment of purified tritiated DNA to plant protoplasts has been measured by quantitative microautoradiography. The automated grain counting technique used, also provides information on the cell cycle stage of individual protoplasts, which circumvents the need to synchronize the plant cell population before preparation of protoplasts. With protoplasts from asynchronously dividing suspension cultures of Nicotiana syhestris (NS-1), S-phase protoplasts appear to be inefficient binders of ³H-DNA, as compared with G₁ or G₂ protoplasts. Protoplasts derived from a tumour line of Crepis capillaris (CAPT) exhibit ³H-DNA binding at all cell cycle phases, but Sphase protoplasts appear to be preferential binders. These differences are discussed with reference to cell cycle kinetics, membrane charge variation and the possibility of increasing the efficiency of genetic transformation of higher plant cells in culture.     

Temperature dependence of K(+)-channel properties in human T lymphocytes.

We have used whole-cell patch clamp to determine the temperature dependence of the conductance and gating kinetics of the voltage-gated potassium channel in quiescent, human peripheral blood T lymphocytes. Threshold for activation, steady-state inactivation, and the reversal potential are the same at 22 degrees and 37 degrees C. However, the time-constants for activation, inactivation, deactivation, and release from inactivation are quite sensitive to temperature, changing by at least a factor of five in each case over this range of temperatures. The onset of cumulative inactivation at 22 degrees and 37 degrees C reflects the time-course of deactivation. Peak outward current is approximately twofold greater at 37 degrees C than at 22 degrees C; this increase is also manifest at the single channel level. Energies of activation for conductance, activation, inactivation, deactivation, and release from inactivation are 8.2, 22.1, 25.0, 36.2, and 42.2 kcal/mol, respectively. No new channels were observed at 37 degrees C, and there was no evidence for alteration of the K+ conductance by putative modulators at 22 or 37 degrees C.     

Dormancy, ABA content and sensitivity of a barley mutant to ABA application during seed development and after ripening.

Assessment of dormancy inception, maintenance and release was studied for artificially dried immature seeds harvested throughout seed development in the barley cv. Triumph and its mutant line TL43. Each was grown in Spain and Scotland under low and high dormancy inducing conditions, respectively. Both TL43 and Triumph followed a similar pattern of release from dormancy across the seasons, although seeds of TL43 were able to germinate at an earlier seed development stage. Abscisic acid (ABA) content was also studied in immature grains throughout the seed development period. Total amount of ABA in seeds of Triumph and TL43 was higher in plants grown in Scotland than in Spain. However, no clear genotypic differences in ABA pattern in the course of grain development could be detected whilst significant genotypic differences were observed for germination percentage (GP). Endogenous ABA content alone throughout grain development did not explain genetic differences in GP within environments. Environmental and genetic differences in dormancy were also observed on mature seeds throughout the after-ripening period. The initial germination (GP(0)) played a key role in the sensitivity to ABA of post-harvest mature seeds. For the same after-ripening stage, TL43 was more insensitive to exogenous ABA than Triumph. However, ABA responses in seeds of the two genotypes with similar GP(0) at different after-ripening stages were comparable. Therefore, differences in exogenous ABA sensitivity of post-harvest mature grain of these two genotypes seemed to be determined by, or coincident with, the initial germination percentage.     

Effects of Cutting Phenology (Non-dormant Versus Dormant) on Early Growth Performance of Three Willow Clones Grown Under Different Weed Treatments and Planting Dates

To assess the effects of cutting phenology on early growth performance of three willow clones grown under different weed treatments and planting dates, freshly harvested (non-dormant) and cold-stored (dormant) cuttings from willow clone Tora, Jorr, and Olof were planted in bucket experiment outdoors in central Sweden on five planting dates (May–June 2013) with or without a model weed (spring barley). Non-dormant cuttings sprouted faster than dormant cuttings when planted early in the season. For cuttings planted later in the season, bud sprouting was affected only by willow clone. Aboveground biomass production was affected by cutting phenology, planting date, clone, and weed treatment. When planted on May 3 and May 10, biomass produced from non-dormant and dormant cuttings did not differ, while willows grown from dormant cuttings produced 59% more aboveground biomass than willows grown from non-dormant cuttings when planted on May 24–June 16. Tora produced on average 12% more biomass than Jorr and Olof, and weed competition reduced aboveground biomass production on average with 36%. The ability of willow to suppress weeds (WSA) was 26 (non-dormant cuttings) and 12% (dormant cuttings) higher for willows planted on May 3 compared with WSA of willows grown from cuttings planted later in the season. The ability to tolerate competition from weeds (WT) was 51 and 52% lower for willows grown from non-dormant and dormant cuttings planted late in the season compared with WT of willows planted earlier in the season. We conclude that planting with long-term cold storage of willow cuttings can be replaced with planting freshly harvested cuttings when planting is performed in early season, and that weed competition strongly reduces biomass production. Weed control during the establishment phase is crucial in order to maximize willow biomass production.     

Abscisic Acid-Like Inhibitors and Cytokinins in the Developing Seeds of Dormant and Non-Dormant Varieties of Peanut (Arachis hypogea L.)

Abscisic acid-like inhibitors and cytokinin activities werestudied in the dormant and non-dormant peanut seeds during theirdevelopment from 20 to 50 d after anthesis. ABA-like inhibitorsincreased continuously from 20 to 50 d of seed development inthe dormant variety whereas in non-dormant seeds they increasedup to 40 d and then declined. Cytokinin-like compounds of boththe varieties increased from 20 to 30 d and then decreased upto maturity. Larger quantities of cytokinins were found at 30d of seed development in both the varieties. At the time ofmaturity dormant seeds contained greater amounts of ABA-likeinhibitors and less cytokinins than the non-dormant variety.     

Growth,sugar accumulation,and dark respiration of suspension cell cultures derived from contrasting alfalfa cultivars

Fall dormancy results in decumbent, slow shoot growth of alfalfa (Medicago sativa L.) in autumn and reduced shoot regrowth rates after herbage removal in summer. Although fall dormancy is used to predict alfalfa adaptation, we possess a poor understanding of the biological mechanisms underlying fall dormancy. Our objective was to examine growth and carbohydrate metabolism of suspension cell cultures derived from contrasting alfalfa cultivars that genetically differed in fall dormancy. Suspension cells were grown in B5h media containing 2% sucrose. Cells derived from fall non-dormant plants accumulated sugars more rapidly after transfer to fresh media and to higher concentrations than did cells derived from fall dormant alfalfa cultivars. Dark respiration rates of cells derived from non-dormant plants were similar to those derived from fall dormant plants when growth was limited at low cell sugar concentrations. However, both cell growth and dark respiration rates increased in cells derived from non-dormant cultivars in response to greater cell sugar concentrations. High growth rates of cells derived from rapid growing, fall non-dormant alfalfa cultivars were associated with rapid sugar uptake and higher cell respiration rates when compared to cells derived from dormant alfalfa cultivars.