The Role of Water Uptake in the Transition of Recalcitrant Seeds from Dormancy to Germination

In recalcitrant seeds of horse chestnut (Aesculus hippocastanum L.) maintaining a high water content during winter, dormancy is determined by the presence and influence of the seed coat, while the axial organs of the embryos excised from these seeds are not dormant. Such axial organs were capable for active water uptake and rapid fresh weight increase, so that their fresh weights exceeded those in intact seeds at the time of radicle protrusion. Fructose plays an essential role in the water uptake as a major osmotically active compound. ABA interferes with the water uptake by the axial organs and thus delays the commencement of their growth. The manifestation of seed response to ABA during the entire dormancy period indicates the presence of active ABA receptors and the pathways of its signal transduction. The content of endogenous ABA in the embryo axes doubled in the middle of dormancy period, which coincided with a partial suppression of water uptake by the axes. During seed dormancy release and imbibition before radicle protrusion, the level of endogenous ABA in axes declined gradually. Application of exogenous ABA can imitate dormancy by limiting water absorption by axial organs. Fusicoccin A (FC A) treatment neutralized completely this ABA effect. Endogenous FC-like ligands were detected in the seed axial organs during dormancy release and germination. Apparently, endogenous FC stimulates water uptake via the activation of plasmalemmal H⁺-ATPase, acidification of cell walls, their loosening, and turgor pressure reduction. FC can evidently counteract the ABA-induced suppression of water uptake by controlling the activity of H⁺-ATPase. It is likely that, in dormant intact recalcitrant seeds, axial organs, maintaining a high water content, are competent to elevate their water content and to start their preparation for germination under the influence of FC when coat-imposed dormancy becomes weaker.     

ULTRACYTOCHEMICAL AND BIOCHEMICAL STUDIES OF PLASMA MEMBRANE ATPASE IN THE INDIVIDUAL PARTS OF THE MATURE,DORMANT SEED OF PISUM SATIVUM

The location and activity of a K⁺-ATPase in mature, dormant peas were investigated using two ultracytochemical techniques, as well as biochemical assays of plasma membrane fractions from separate seed parts. Both the Wachstein and Meisel (1957) and the Ernst (1972) cytochemical methods showed plasma membrane-associated reaction product located primarily on the exterior surfaces of the entire pea embryo, except for the stem apex and tip-most cells of the radicle. No plasma membrane-assocated reaction product was found in the seed coat, which typically consists of cells with degenerating protoplasts. Biochemical results showed the highest specific K⁺-ATPase activity in the radicles (775 nmol Pi/mg protein/hr), followed by epicotyls (168 nmol Pi/mg protein/hr) and cotyledons (147 nmol Pi/mg protein/hr). It is proposed that the entire pea embryo may function in the active absorption of nutrients during the initial phases of germination. Additional functions of the enzyme may include cell wall loosening prior to cell elongation, regulation of cytoplasmic pH, and the generation of turgor.     

The possible role of redox-associated protons in growth of plant cells

The protons excreted by plant cells may arise by two different mechanisms: (1) by the action of the plasma membrane H⁺-ATPase and (2) by plasma membrane redox reactions. The exact proportion from each source is not known, but the plasma membrane H⁺-ATPase is, by far, the major contributor to proton efflux. There is still some question of whether the redox-associated protons produced by NADH oxidation on the inner side of the plasma membrane traverse the membrane in a 1 : 1 relationship with electrons generated in the redox reactions. Membrane depolarization observed in the presence of ferricyanide reduction by plasma membranes of whole cells or tissues or the lag period between ferricyanide reduction and medium acidification argue that only scalar protons may be involved. The other major argument against tight coupling between protons and electrons involves the concept of strong charge compensation. When ferricyanide is reduced to ferrocyanide on the outside of cells or tissues, an extra negative charge arises, which is compensated for by the release of H⁺ or K⁺, so that the total ratio of increased H⁺ plus K⁺ equals the electrons transferred by transmembrane electron transport. These are strong arguments against a tight coupling between electrons and protons excreted by the plasma membrane. On the other hand, there is no question that inhibitor studies provide evidence for two mechanisms of proton generation by plasma membranes. When the H⁺-ATPase activity is totally inhibited, the addition of ferricyanide induces a burst of extra proton excretion, orvice versa, when plasma membrane redox reactions are inhibited, the H⁺-ATPase can function normally. Since plasma membrane redox reactions and associated H⁺ excretion are related to growth, it is possible that in plants the ATPase-generated protons have a different function from redox-associated protons. The H⁺-ATPase-generated protons have been considered for many years to be necessary for cell wall expansion, allowing elongation to take place. A special function of the redox-generated protons may be in initiating proliferative cell growth, based on the presence of a hormone-stimulated NADH oxidase in membranes of soybean hypocotyls and stimulation of root growth by low concentrations of oxidants. Here we propose that this NADH oxidase and the redox protons released by its action control growth. The mechanism for this may be the evolution of protons into a special membrane domain, from which a signal to initiate cell proliferation may originate, independent of the action of the H⁺-ATPase-generated protons. It is also possible that both expansion and proliferative growth are controlled by redox-generated protons.     

Role of the plasma membrane H<Superscript>+</Superscript>-ATPase in auxin-induced elongation growth: historical and new aspects

This article will cover historical and recent aspects of reactions and mechanisms involved in the auxin-induced signalling cascade that terminates in the dramatic elongation growth of cells and plant organs. Massive evidence has accumulated that the final target of auxin action is the plasma membrane H⁺-ATPase, which excretes H⁺ ions into the cell wall compartment and, in an antiport, takes up K⁺ ions through an inwardly rectifying K⁺ channel. The auxin-enhanced H⁺ pumping lowers the cell wall pH, activates pH-sensitive enzymes and proteins within the wall, and initiates cell-wall loosening and extension growth. These processes, induced by auxin or by the "super-auxin" fusicoccin, can be blocked instantly and specifically by a voltage inhibition of the H⁺-ATPase due to removal of K⁺ ions or the addition of K⁺-channel blockers. Vice versa, H⁺ pumping and growth are immediately switched on by addition of K⁺ ions. Furthermore, the treatment of segments either with auxin or with fusicoccin (which activates the H⁺-ATPase irreversibly) or with acid buffers (from outside) causes an identical transformation and degradation pattern of cell wall constituents during cell-wall loosening and growth. These and other results described below are in agreement with the acid-growth theory of elongation growth. However, objections to this theory are also discussed.     

Congruence between PM H<Superscript>+</Superscript>-ATPase and NADPH oxidase during root growth: a necessary probability

Plasma membrane (PM) H⁺-ATPase and NADPH oxidase (NOX) are two key enzymes responsible for cell wall relaxation during elongation growth through apoplastic acidification and production of ˙OH radical via O₂˙^?, respectively. Our experiments revealed a putative feed-forward loop between these enzymes in growing roots of Vigna radiata (L.) Wilczek seedlings. Thus, NOX activity was found to be dependent on proton gradient generated across PM by H⁺-ATPase as evident from pharmacological experiments using carbonyl cyanide m-chlorophenylhydrazone (CCCP; protonophore) and sodium ortho-vanadate (PM H⁺-ATPase inhibitor). Conversely, H⁺-ATPase activity retarded in response to different ROS scavengers [CuCl₂, N, N’ –dimethylthiourea (DMTU) and catalase] and NOX inhibitors [ZnCl₂ and diphenyleneiodonium (DPI)], while H₂O₂ promoted PM H⁺-ATPase activity at lower concentrations. Repressing effects of Ca⁺² antagonists (La⁺³ and EGTA) on the activity of both the enzymes indicate its possible mediation. Since, unlike animal NOX, the plant versions do not possess proton channel activity, harmonized functioning of PM H⁺-ATPase and NOX appears to be justified. Plasma membrane NADPH oxidase and H⁺-ATPase are functionally synchronized and they work cooperatively to maintain the membrane electrical balance while mediating plant cell growth through wall relaxation.     

The immunolocalization of plasma membrane H+-ATPase in the transfer cell region of Brassica napus (Brassicaceae) ovules

Unfertilized mature ovules of Brassica L. contain an abundance of starch in the integument cells from the micropyle to a plane approximately at the level of the central cell polar nuclei. Inside the embryo sac central cell, in the coinciding region, there are transfer cell-like wall projections with plasma membranes appressed to their inner surfaces. H⁺-ATPase is present along the inner surfaces of the wall projections as indicated by reactivity with antibody raised against plasma membrane H⁺-ATPase. A number of mitochondria are in close association with wall projections in the region of the egg apparatus. Antibody raised against corn plasma membrane H⁺-ATPase cross reacts with a protein of the same size in extracts of Brassica napus indicating that the two species contain a similar plasma membrane H⁺-ATPase.     

Glucose-induced activation of H+-ATPase in Dunaliella salina and its role in hygromycin resistance

Dunaliella salina, a eukaryotic microalga, is known for its highly halophilic nature. The high level of salts in growth medium for this alga has made its genetic transformation a comparatively difficult procedure, particularly during the selection stage. The high salt content decreases the efficiency of most antibiotics which are being used as selection markers. Studies pertaining to the interrelationship between salt concentration and antibiotic sensitivity are scarce in Dunaliella. During our previous experiment at genetic transformation of Dunaliella, an inverse relationship between the amount of antibiotic hygromycin and sodium chloride in the medium was revealed. A possible link between plasma membrane activity and the hygromycin sensitivity was investigated in the present study by modulating plasma membrane H⁺-ATPase activity using glucose. Glucose-induced activation of H⁺-ATPase, reduced the tolerance of D. salina to the antibiotic hygromycin. Hygromycin concentration required for selection during genetic transformation of Dunaliella was lowered from 100 to 25 mg L^?1 in the presence of 10 mM glucose. Conversely, the inhibitors of the plasma membrane H⁺-ATPase, orthovanadate and diethylstilbestrol were found to inhibit the glucose activation at concentrations of 10 and 15 μM, respectively. The activation of H⁺-ATPase by glucose was further confirmed through H⁺-ATPase assay and medium acidification experiments. The results indicated that the sensitivity of Dunaliella to antibiotic is related to H⁺-ATPase and the possible involvement of pH gradient, created through H⁺-ATPase activation during drug transport.     

Apoplast Acidification in Growing Barley (Hordeum vulgare L.) Leaves

Apoplast acidification associated with growth is well documented in roots, coleoptiles, and internodes but not in leaves. In the present study, advantage was taken of the high cuticle permeability in the elongation zone of barley leaves to measure apoplast pH and growth in response to application of test reagents. The role of the plasma membrane H⁺-ATPase (PM-H⁺-ATPase) and K⁺ in this process was of particular interest. pH microelectrodes and an in vitro gel system with bromocresol purple as pH indicator were used to monitor apoplast pH. Growth was measured in parallel or in separate experiments using a linear variable differential transformer. Test reagents that blocked (vanadate) or stimulated (fusicoccin) PM-H⁺-ATPase or that reduced (Cs⁺, tetraethylammonium) K⁺ uptake were applied. Apoplast pH was lower in growing than in nongrowing leaf tissue and increased in the elongation zone with increasing apoplast K⁺. Vanadate increased apoplast pH and reduced growth, whereas fusicoccin caused the opposite effects. It is concluded that barley leaves exhibit acid-growth-type mechanisms in that apoplast pH is lower in elongating leaf tissue. Both growth and apoplast pH depend on the activity of the PM-H⁺-ATPase and K⁺ transport processes. However, not all of the growth displayed by leaves is dependent on a lower apoplast pH in the elongation zone; up to 50 % of growth is retained when apoplast pH in the elongation zone increases to a value observed in mature tissue.     

Growth cycle stage-dependent NaCl induction of plasma membrane H+-ATPase mRNA accumulation in de-adapted tobacco cells

A cDNA clone encoding an isoform of the plasma membrane H⁺-ATPase was isolated from Nicotiana tabacum. The steady-state plasma membrane H⁺-ATPase message levels were the same in unadapted tobacco cells and tobacco cells adapted to 428 mol m⁻³ NaCl. When cells adapted to 428 mol m⁻³ NaCl maintained in the absence of NaCl (deadapted) for an excess of 100 passages were exposed to 400 mol m⁻³ NaCl for 24 h, there was an increased accumulation of plasma membrane H⁺-ATPase message. The NaCl responsiveness of the deadapted cells was dependent upon the growth cycle stage. Alterations in the levels of plasma membrane FT-ATPase message during the growth cycle support a role for the H⁺-ATPase in cell growth. These results document the induction by NaCl of plasma membrane FT-ATPase message accumulation in tobacco cells, and suggest that enhanced expression of the plasma membrane FT-ATPase has a role in the short term response of cells of NaCl, but is not necessarily involved in long-term adaptation.     

Early carbon mobilization and radicle protrusion in maize germination

Considerable amounts of information is available on the complex carbohydrates that are mobilized and utilized by the seed to support early seedling development. These events occur after radicle has protruded from the seed. However, scarce information is available on the role of the endogenous soluble carbohydrates from the embryo in the first hours of germination. The present work analysed how the soluble carbohydrate reserves in isolated maize embryos are mobilized during 6-24 h of water imbibition, an interval that exclusively embraces the first two phases of the germination process. It was found that sucrose constitutes a very significant reserve in the scutellum and that it is efficiently consumed during the time in which the adjacent embryo axis is engaged in an active metabolism. Sucrose transporter was immunolocalized in the scutellum and in vascular elements. In parallel, a cell-wall invertase activity, which hydrolyses sucrose, developed in the embryo axis, which favoured higher glucose uptake. Sucrose and hexose transporters were active in the embryo tissues, together with the plasma membrane H(+)-ATPase, which was localized in all embryo regions involved in both nutrient transport and active cell elongation to support radicle extension. It is proposed that, during the initial maize germination phases, a net flow of sucrose takes place from the scutellum towards the embryo axis and regions that undergo elongation. During radicle extension, sucrose and hexose transporters, as well as H(+)-ATPase, become the fundamental proteins that orchestrate the transport of nutrients required for successful germination.     

Role of H+-ATPase and Alternative Oxidase in Regulation of Intracellular pH at Different Stages of Development of the Tobacco Male Gametophyte

In order to determine the role of the plasma membrane H⁺-ATPase and alternative oxidase (alternative pathway of respiration) in the regulation of intracellular pH during development of the tobacco male gametophyte, we studied the changes in pH due to the inhibition of these enzymes by orthovadanate and benzhydroxamic acid, respectively. The inhibition of these enzymes decreased the intracellular pH at all three studied stages of the male gametophyte development: middle and late binuclear pollen grains and activated mature pollen grain. The data obtained suggest that H⁺-ATPase and alternative oxidase are involved in the regulation of intracellular pH of the pollen grain during its differentiation and activation that precede germination. At the same time, during the recovery of intracellular pH after its acidification by propionic acid, it was found that other mechanisms, not related to the above mentioned, greatly contribute to the regulation of pH.     

GERMINATION AND SEEDLING GROWTH IN ECHINOCHLOA CRUS-GALLI VAR. ORYZICOLA UNDER ANOXIC CONDITIONS: STRUCTURAL ASPECTS

The morphological and cellular basis of anoxic germination in Echinochloa crus-galli var. oryzicola is reported. The embryo of E. crus-galli var. oryzicola is typically panicoid in its overall morphology, and is relatively large with a prominent coleoptile and mesocotyl. The response to anoxia is essentially the same in light and dark. Shoot growth occurs in both mesocotyl and coleoptile by cell elongation with no cell division. There is no emergence of the radicle without oxygen. Under anoxia the growth response is not the same as etiolation; there is no plumule elongation within the coleoptile, no protochlorophyll(ide) is found, and limited mesocotyl elongation occurs without oxygen. Air-dark treatment after anoxic germination results in a typical etiolated morphological response, including a resumption of mesocotyl growth, elongation of the plumule within the coleoptile, and initiation of pigment synthesis. These results indicate the effects of anoxia are not permanent but rather limiting and reversible.     

Yeast genes YOL002C and SUL1 are involved in neomycin resistance

In previous studies we suggested the importance of the control of plasma membrane H⁺-ATPase by a phosphatidylinositol-like pathway for cellular proton extrusion in Saccharomyces cerevisiae (Brandão et al. 1994; Coccetti et al. 1998). The observations that provided the model above include the inhibition of the glucose-induced activation of the plasma membrane H⁺-ATPase as well as the inhibition of the glucose-induced external acidification by neomycin, a known inhibitor of the phosphatidylinositol turnover in eukaryotic cells. In this work, using two libraries, we isolated two yeast clones that were able to prevent the inhibition of glucose-induced activation of the H⁺-ATPase by neomycin. We show that the YOL002C gene, which encodes a protein of unknown function, and the SUL1 gene, which is a sulphate transporter belonging to the major facilitator superfamily, suppress growth inhibition by neomycin. However, they are not required for glucose-induced activation of the plasma membrane H⁺-ATPase. The resistance of the clones to neomycin is probably related to the level and/or activity of proteins functioning as drug extrusion pumps.     

Abscisic acid and 14-3-3 proteins control K channel activity in barley embryonic root

Germination of seeds proceeds in general in two phases, an initial imbibition phase and a subsequent growth phase. In grasses like barley, the latter phase is evident as the emergence of the embryonic root (radicle). The hormone abscisic acid (ABA) inhibits germination because it prevents the embryo from entering and completing the growth phase. Genetic and physiological studies have identified many steps in the ABA signal transduction cascade, but how it prevents radicle elongation is still not clear. For elongation growth to proceed, uptake of osmotically active substances (mainly K(+)) is essential. Therefore, we have addressed the question of how the activity of K(+) permeable ion channels in the plasma membrane of radicle cells is regulated under conditions of slow (+ABA) and rapid germination (+fusicoccin). We found that ABA arrests radicle growth, inhibits net K(+) uptake and reduces the activity of K(+) (in) channels as measured with the patch-clamp technique. In contrast, fusicoccin (FC), a well-known stimulator of germination, stimulates radicle growth, net K(+) uptake and reduces the activity of K(+) (out) channels. Both types of channels are under the control of 14-3-3 proteins, known as integral components of signal transduction pathways and instrumental in FC action. Intriguingly, 14-3-3 affected both channels in an opposite fashion: whereas K(+) (in) channel activity was fully dependent upon 14-3-3 proteins, K(+) (out) channel activity was reduced by 14-3-3 proteins by 60%. Together with previous data showing that 14-3-3 proteins control the activity of the plasma membrane H(+)-ATPase, this makes 14-3-3 a prime candidate for molecular master regulator of the cellular osmo-pump. Regulation of the osmo-pump activity by ABA and FC is an important mechanism in controlling the growth of the embryonic root during seed germination.     

A water relations analysis of seed germination rates

Seed germination culminates in the initiation of embryo growth and the resumption of water uptake after imbibition. Previous applications of cell growth models to describe seed germination have focused on the inhibition of radicle growth rates at reduced water potential (Ψ). An alternative approach is presented, based upon the timing of radicle emergence, to characterize the relationship of seed germination rates to Ψ. Using only three parameters, a `hydrotime constant' and the mean and standard deviation in minimum or base Ψ among seeds in the population, germination time courses can be predicted at any Ψ, or normalized to a common time scale equal to that of seeds germinating in water. The rate of germination of lettuce (Lactuca sativa L. cv Empire) seeds, either intact or with the endosperm envelope cut, increased linearly with embryo turgor. The endosperm presented little physical resistance to radicle growth at the time of radicle emergence, but its presence markedly delayed germination. The length of the lag period after imbibition before radicle emergence is related to the time required for weakening of the endosperm, and not to the generation of additional turgor in the embryo. The rate of endosperm weakening is sensitive to Ψ or turgor.     

Boric acid stimulates the plasma membrane H+-ATPase of ungerminated lily pollen grains

The stimulation of the plasma membrane (PM) H⁺-ATPase by boric acid was studied on a microsomal fraction (MF) obtained from ungerminated, boron-dependent pollen grains of Lilium longiflorum Thunb. which usually need boron for germination and tube growth. ATP hydrolysis and H+ transport activity increased by 14 and 18%, respectively, after addition of 2-4 mM boric acid. The optimum of boron stimulation was at pH 6.5-8.5 for ATP hydrolysis and at pH 6.5-7.5 for H⁺ transport. No boron stimulation was detected when vanadate was added to the MF, whereas an increase of 10-20% in ATP hydrolysis and H⁺ transport was still measured in the presence of inhibitors specific for V -type ATPase (nitrate and bafilomycin) and F-type ATPase (azide), respectively. A vanadate-sensitive increase in ATP hydrolysis activity was also observed in partially permeabilized vesicles (0.001%[w/v] Triton X-100) suggesting a direct interaction between borate and the PM H⁺-ATPase rather than a weak acid-induced stimulation. Additionally, we measured the effect of boron on membrane voltage (V_m) of ungerminated pollen grains and observed small hyperpolarizations in 48% of all experiments. Exposing pollen grains to a more acidic pH of 4 caused a depolarization, followed in some experiments by a repolarization (21%). In the presence of 2 mM boron such hyperpolarizations, perhaps caused by an enhanced activity of the H⁺-ATPase, were measured in 58% of all tested pollen grains. The effects of boron on V_m may be reduced by additional stimulation of a K⁺ inward current of opposite direction to the H⁺-ATPase. All experiments indicate that boron stimulates an electrogenic transport system in the plasma membrane which is sensitive to vanadate and has a pH optimum around 7, i.e. the plasma membrane H⁺-ATPase. A boron-increased PM H⁺-ATPase activity in turn may stimulate germination and growth of pollen tubes.     

Summary

The plasma membrane H⁺-ATPase in higher plants has been implicated in nutrient uptake, phloem loading, elongation growth and establishment of turgor. Although a C-terminal regulatory domain has been identified, little is known about the physiological factors involved in controlling the activity of the enzyme. To identify components which play a role in the regulation of the plant H⁺-ATPase, a fusicoccin responsive yeast expressing Arabidopsis plasma membrane H⁺-ATPase AHA2 was employed. By testing the fusicoccin binding activity of yeast membranes, the C-terminal regulatory domain of AHA2 was found to be part of a functional fusicoccin receptor, a component of which was the 14–3-3 protein. ATP hydrolytic activity of AHA2 expressed in yeast internal membranes was activated by all tested isoforms of the 14–3-3 protein of yeast and Arabidopsis, but only in the presence of fusicoccin, and activation was prevented by a phosphoserine peptide representing a known 14–3-3 protein binding motif in Raf-1. The results demonstrate that the 14–3-3 protein is an activator molecule of the H⁺-ATPase and provides the first evidence of a protein involved in activation of plant plasma membrane H⁺-ATPase.     

Ascorbate and glutathione metabolism in embryo axes and cotyledons of germinating lupine seeds

Changes in ascorbate and glutathione contents and the activities and isoenzyme patterns of enzymes of the ascorbate-glutathione cycle were investigated in embryo axes and cotyledons of germinating lupine (Lupinus luteus L.) seeds. Ascorbate content was not significantly affected over the initial 12 h of imbibition in embryo axes, but afterwards increased, with the most rapid accumulation coinciding with radicle emergence. A somewhat similar trend was observed for glutathione with significant increase in embryo axes shortly before radicle protrusion followed by decline in the next hours. In cotyledons the ascorbate pool rose gradually during germination but the amount of glutathione showed fluctuations during a whole germination period. The activity of ascorbate peroxidase (APX) rose progressively in embryo axes, while activities of dehydroascorbate reductase (DHAR) and glutathione reductase (GR) showed transient increase during germination. New isoforms of APX and GR were synthesized, suggesting that they play a relevant role during germination. All analyzed enzymes were already present in dry seeds which allowed them to be active immediately after imbibition.     

Expansin-regulated cell elongation is involved in the drought tolerance in wheat

Water stress restrains plant growth. Expansin is a cell wall protein that is generally accepted to be the key regulator of cell wall extension during plant growth. In this study, we used two different wheat cultivars to study the involvement of expansin in drought tolerance. Wheat coleoptile was used as the material in experiment. Our results indicated that water stress induced an increase in acidic pH-dependant cell wall extension, which is related to expansin activity; however, water stress inhibited coleoptile elongation growth. The increased expansin activity was mainly due to increased expression of expansin protein that was upregulated by water stress, but water stress also resulted in a decrease in cell wall acidity, a negative factor for cell wall extension. Decreased plasma membrane H⁺-ATPase activity was involved in the alkalinization of the cell wall under water stress. The activity of expansin in HF9703 (a drought-tolerant wheat cultivar) was always higher than that in 921842 (a drought-sensitive wheat cultivar) under both normal and water stress conditions, which may be correlated with the higher expansin protein expression and plasma membrane H⁺-ATPase activity observed in HF9703 versus 921842. However, water stress did not change the susceptibility of the wheat cell wall to expansin, and no difference in this susceptibility was observed between the drought-tolerant and drought-sensitive wheat cultivars. These results suggest the involvement of expansin in cell elongation and the drought resistance of wheat.     

Growth and development of embryo parts during the germination of caryopses of the wild oat (Avena fatua L.)

Wild oat (Avena fatua L.) caryopses were germinated on moist filter paper and under water in the presence and absence of hydrogen peroxide (H₂O₂). The sequential growth and development of embryo parts were studied. Germination, as indicated by radicle emergence, was least and slowest in caryopses submerged in deoxygenated water. The coleorhiza in such caryopses elongated much earlier than the root, in contrast to the other treatments where the coleorhiza and the root emerged at about the same time. In caryopses incubated on moist filter paper all embryo parts showed considerable growth. In H₂O₂ treated caryopses only the epicotyl showed substantial growth over the experimental period. In all treatments the first mitotic peaks were noticed at the same period. The occurrence of these early nuclear divisions may be due to release of 4 C nuclei from inhibition by the uptake of water during caryopsis imbibition. The mitosis continued in the radicle of the embryo in those caryopses germinating on moist filter paper, indicating occurrence of DNA synthesis. In the other two treatments, however, few divisions were detected. Here the early growth of the root, causing caryopsis germination, was due to cell elongation, especially in the proximal part of the root.