The Effects of Phytohormones and 5-Azacytidine on Apoptosis in Etiolated Wheat Seedlings

The development of etiolated wheat (Triticum aestivum L.) seedlings is necessarily accompanied by apoptosis in their coleoptiles and first leaves. Internucleosome DNA fragmentation, which is characteristic of apoptosis, was detected in the coleoptile as soon as six days after germination. After eight days of germination, DNA fragmentation was clearly expressed in the coleoptile and was noticeable in the apical part of the first-leaf blade. Growing of intact seedlings or incubation of their shoots in the presence of such phytohormones as benzyladenine, gibberellin A₃, fusicoccin C, and 2,4-D at the concentration of 10^–5 M did not essentially affect DNA fragmentation in the coleoptile. As distinct from antioxidants, none of the phytohormones used prevented apoptosis in wheat seedlings. In contrast, ABA (10^–5 M) and an ethylene producer, ethrel (2-chloroethylphosphonic acid, 10^–2–10^–3 M), stimulated sharply DNA fragmentation in the coleoptile. An inhibitor of DNA methylation, 5-azacytidine, was very efficient in the stimulation of DNA fragmentation in the coleoptiles of eight-day-old seedlings at its concentration of 100 g/ml. Thus, some phytohormones can regulate apoptosis, and DNA methylation is involved in this process. Our results indicate that apoptosis activation by some phytohormones may be mediated by their regulation of DNA methylation/demethylation, which is responsible for the induction of genes encoding apoptogenic proteins and/or the repression of antiapoptotic genes.     

H1 Histone in Developing and Aging Coleoptiles of Etiolated Wheat Seedlings

It has been established that the DNA and H1 histone contents in aged coleoptile of 8-day-old etiolated wheat seedling are about 40 and 30%, respectively, lower than those in young seedlings. H1 histone in wheat seedlings is represented as six electrophoretically different subfractions. The ratios of H1 histone subfractions in wheat coleoptile and initial leaf are similar. In contrast to some animal cells, apoptosis in wheat coleoptile is not accompanied by changes in the set and ratios of H1 histone subfractions. Aging of coleoptiles is associated with a progressive diminution of the H1 histone and DNA contents. H1 histone/DNA ratio in aged coleoptile is 1.5-2-fold higher than that in the young organs. Therefore, the content of H1 histone in chromatin of coleoptile decreases with age more slowly than DNA content.     

White light‐induced sugar distribution controls growth and osmotic properties in the coleoptile and the first leaf in Zea mays seedlings

The correlation of white light‐induced changes in osmotic concentration in the coleoptile and the first leaf and the growth rate of these organs in maize seedlings, was examined in relation to sugar distribution and invertase activity. One hour irradiation with white light decreased the osmotic concentration in basal zones of the coleoptile and increased it in the apical zones of the first leaf. The change in the osmotic concentration was positively correlated with the growth rate of both organs. The amount of total osmotic solutes in each zone was highly correlated with that of soluble sugars. Light decreased the activity of wall‐bound invertase in the coleoptile, but increased it in the first leaf. A high correlation existed between the content of soluble sugars and invertase activity in both organs. During 1 h incubation in the light, ca 2 µmol of soluble sugars per seedling was lost from the coleoptile and gained in the first leaf. Light promoted sugar exudation from the excised coleoptile, but the amount of soluble sugar exuded represented 5% of sugar loss from the coleoptile in intact seedlings.
These results indicate that in maize seedlings white light controls the growth rate of the coleoptile and the first leaf through the osmotic concentration. Light may have an osmoregulatory function in the control of sugar distribution between the coleoptile and the first leaf by regulating the activity of wall‐bound invertase.     

Optimization of red light-induced elongation in Avena coleoptile sections and properties of the phytochrome-mediated growth response*

Abstract Optimal conditions for studying the elongation response to a 1 mmol m^?2, 2-min pulse of red light in subapical coleoptile sections from dark-grown oat (Avena sativa L. ev. Lodi) seedlings have been determined. A technique for obtaining standard-length coleoptile sections without exposing either seedlings or sections to any light has been developed, and is described. The optimal conditions found were: sampling time, 12 h after irradiation; buffer conditions, 5 mol m^?3 potassium phosphate with 5% (w/v) sucrose (pH 5.9). The optima were determined by obtaining the time course for light-induced growth under various conditions. The red light-induced growth response is linear until 12 h after irradiation, when it undergoes an interruption. Optimal incubation conditions were determined by varying the buffer contents systematically and measuring the responses at the optimal lime determined. The results indicate a distinct difference between auxin-induced and light-induced growth responses. Even with variations of basal growth rate and several incubation conditions, the red light-induced elongation appears to be of a constant magnitude, to persist for a constant time period. and to exhibit a constant lag period between irradiation and the onset of response. The use of sections that were produced and handled in complete darkness yielded an unusual response to fusicoccin. A linear, high growth rate in response to I mmol m^?3 FC was observed for more than 12 h, both in the irradiated sections and in the dark controls.     

Inhibitory action of red light on the growth of the maize mesocotyl: evaluation of the auxin hypothesis

Brief irradiation of 3-d-old maize (Zea mays L.) seedlings with red light (R; 180 J m^-2) inhibits elongation of the mesocotyl (70–80% inhibition in 8 h) and reduces its indole-3-acetic acid (IAA) content. The reduction in IAA content, apparent within a few hours, is the result of a reduction in the supply of IAA from the coleoptile unit (which includes the shoot apex and primary leaves). The fluence-response relationship for the inhibition of mesocotyl growth by R and far-red light closely resemble those for the reduction of the IAA supply from the coleoptile. The relationship between the concentration of IAA (1–10 M) supplied to the cut surface of the mesocotyl of seedlings with their coleoptile removed and the growth increment of the mesocotyl, measured after 4 h, is linear. The hypothesis that R inhibits mesocotyl growth mainly by reducing the IAA supply from the coleoptile is supported. However, mesocotyl growth in seedlings from which the coleoptiles have been removed is also inhibited by R (about 25% inhibition in 8 h). This inhibition is not related to changes in the IAA level, and not relieved by applied IAA. In intact seedlings, this effect may also participate in the inhibition of mesocotyl growth by R. Inhibition of cell division by R, whose mechanism is not known, will also result in reduced mesocotyl elongation especially in the long term (e.g. 24 h).Abbreviations FR far-red light - IAA indole-3-acetic acid - P_fr phytochrome in the far-red-absorbing form - P_r phytochrome in the red-absorbing form - R red light     

Effects of red light on the growth of intact wheat and barley coleoptiles

The final lengths of intact dark-grown coleoptiles vary with species and cultivar. The growth distribution pattern in the apical 25-mm growing zone and the absolute amount of growth in each zone depend on the age and species of the coleoptile. A comparative study of several cultivars of wheat, Triticum vulgare, and barley, Hordeum vulgare, indicates that the growth distribution pattern in 30- to 38-mm coleoptiles varies with the species and cultivar. In barley, there are two patterns of growth distribution among the several cultivars, whereas in wheat, all cultivars exhibit a common zonal growth pattern. The total growth of coleoptiles, initially 30 to 38 mm in length, during a 24-hour dark incubation period is the same in dark-grown coleoptiles as in those irradiated with 3 minutes of red (660 nm) light prior to the incubation period. The growth distribution pattern in the growing zone of this 30- to 38-mm coleoptile is, however, altered by red light. Growth of the apical 5-mm zone is stimulated by red light and the zonal growth 5 to 10 mm below the apex is only slightly affected, whereas growth in the zones 10 to 15 to 20, and 20 to 25 mm below the apex is inhibited. This growth distribution pattern in irradiated coleoptiles changes as the coleoptile increases in length. The response of a zone following exposure to red light is dependent upon the age of the seedlings irradiated. The over-all effect of red light on growth of the intact coleoptile varies with the length of the coleoptile. In young seedling 20 to 29 mm in length, the cells of the coleoptile can compensate for the effects of red light, with the over-all growth of the dark-grown and irradiated coleoptile about the same. As the seedling grows older, the cells of the coleoptile can no longer make up for the effects of red light, and the over-all effect changes from compensation to pronounced inhibition.     

Inhibition of the Coleoptile Growth in Avena sativa by Endosperm Removal--Changes in Auxin, Osmotica and Cell Wall

Removal of the endosperm from 84-h-old etiolated oat seedlingsstrongly retarded the subsequent growth of coleoptiles. Thecontribution of the endosperm to coleoptile growth was studied.Endosperm removal was found to: (1) decrease the endogenouslevel of indole-3-acetic acid (IAA) in the coleoptile tip. IAAapplied to the coleoptile tip stimulated coleoptile growth inseedlings with and without the endosperm. The sensitivity ofthe coleoptile to a suboptimal concentration of IAA was higherin seedlings without the endosperm than in intact ones. At theoptimal concentration of IAA, however, the final length of thecoleoptile was larger in intact seedlings than in those withoutthe endosperm. (2) decrease the concentration of the solublesugars and amino acids in the cell sap. (3) retard the increasein the amount of polysaccharides in the cell wall of the coleoptile,particularly noncellulosic ones. (4) make the cell wall mechanicallyrigid according to stress-relaxation analysis of the cell wall.(5) induce an increase in the osmotic potential of the coleoptilecell sap. From these results, it was concluded that the endosperm suppliesthe coleoptile with IAA, sugars and amino acids, thus promotingcoleoptile growth. (Received September 24, 1987; Accepted February 3, 1988)     

Incorporation of nitrate nitrogen in rice seedlings transferred to anaerobic conditions

Summary Incorporation of¹⁵NO₃- into amino acids was studied in 3-day-old aerobic rice seedlings (with coleoptile and root) subjected for 24h to anaerobic conditions. The incorporation of¹⁵N into glutamate, glutamine and alanine accounted for 89% and 84% of total incorporation in coleoptile and root, respectively. These findings indicate that, after the primary incorporation of¹⁵N into glutamate and glutamine, the main fate of nitrate nitrogen in rice seedlings subjected to anoxia is alanine.     

Ethylene and the growth of rice seedlings

Etiolated whole rice seedlings enclosed in sealed vials produced ethylene at a rate of 0.9 picomole per hour per seedling. When 2-centimeter-long shoots were subdivided into 5-millimeter-long sections, the sections containing the tip of the shoot evolved 37% of the total ethylene with the remaining 63% being produced along a gradient decreasing to the base of the shoot. The tip of the coleoptile also had the highest level of the ethylene precursor 1-aminocyclopropane-1-carboxylic acid and of the ethylene-forming enzyme activity. Ethylene is one of the factors controlling coleoptile elongation. Decapitation of the seedling reduced ethylene evolution to one-third its original level and inhibited coleoptile growth. In short-term experiments, the growth rate of decapitated seedlings was restored to almost that of intact seedlings by application of ethylene at a concentration of 10 microliters per liter. Apart from ethylene, O₂ also participates in the control of coleoptile growth. When rice seedlings were grown in a gas mixture of N₂ and O₂, the length of the coleoptiles reached a maximum at a concentration of 2.5% O₂. Lower and higher concentrations of O₂ reduced coleoptile growth. The effect of exogenous ethylene on coleoptile growth was also O₂ dependent.     

5,6-二氯吲哚乙酸对水稻幼苗芽鞘向地性的影响

5,6-Cl_2-IAA可以诱导水稻芽鞘产生斜向地性生长。其倾斜角度与外加5,6-Cl_2-IAA的剂量呈线性关系,其反应具有特异性(IAA,6-BA,ABA和BR均不能诱导这种反应)。反应可在2～3h后产生,它可作为5,6-Cl_2-IAA的生物检定依据。切除芽鞘顶尖或外加TIBA对这一反应无明显影响,另外乙烯生物合成抑制剂AVG也不能消除5,6-Cl_2-IAA诱导的斜向地性生长。     

Proline accumulation induced by weak acids and IAA in coleoptiles of wheat seedlings

Proline accumulation in coleoptiles of wheat seedlings or in excised coleoptile segments incubated under shaking for a 24 h period was studied. There was no increase of proline content of coleoptiles after incubation of the seedlings in 5 mM citric acid (a relatively strong and slowly penetrating organic acid) in a pH range from 4.5 to 7.0 and only a slight increase of proline content after incubation in phosphate buffer at pH 7.0 to 7.5 duo to the higher osmotic concentration of phosphate buffer in this pH range. Quite different results were obtained with seedlings incubated in 10 mM acetic acid, a weak and easily penetrating organic acid. With increasing proton concentrations, proline accumulation increased. Application of 400 mM mannitol or higher concentrations of IAA (more than 10⁻⁵M) additionally increased proline accumulation in the presence of 10 mM acetic acid in the pH range from 6.0 to 7.5 in which acetic acid alone was loss effective. It is suggested that a decrease of cytosolic pH causes stress—induced proline accumulation.     

Polyamines in Rice Seedlings under Oxygen-Deficit Stress

Incubation of 3-d-old seedlings of Oryza sativa L. cv Arborio under anaerobic conditions, leads to a large increase in the titer of free putrescine while aerobic incubation causes a slight decrease. After 2 days, the putrescine level is about 2.5 times greater without oxygen than in air. The rice coleoptile also accumulates a large amount of bound putrescine and, to a lesser extent, spermidine and spermine (mainly as acid-soluble conjugates). Accumulation of conjugates in the roots is severely inhibited by the anaerobic treatment. Feeding experiments with labeled amino acids showed that anoxia stimulates the release of ¹⁴CO₂ from tissues fed with [¹⁴C]arginine and that arginine is the precursor in putrescine biosynthesis. After 2 d of anoxia, the activity of arginine decarboxylase was 42% and 89% greater in coleoptile and root, respectively, than in the aerobic condition. The causes of the differences in polyamine metabolism in anoxic coleoptiles and roots are discussed.     

The effects of electric field on the growth of intact seedlings and coleoptile segments ofZea mays L.

The experiments were carried out with 96-h-old intact maize seedlings and 10 mm long coleoptile segments cut 4 mm below the tip. The electric fields were applied longitudinally along the seedlings. The electric field (15 V) caused inhibition of the elongation growth of intact seedlings which was dependent on both the polarity and the duration of the applied voltage. The growth inhibition was greater when the tip of the shoot was positive relative to the roots. The electric field also caused inhibition of indole-3-acetic acid (IAA) and fusicoccin (FC) induced growth of maize coleoptile segments excised from electrically treated seedlings. IAA-induced growth of coleoptile segments was greater when the tip of the shoot was negative to the roots (not in the case of FC-treated segments and intact seedlings). It was suggested that apart from the changes induced by electric field in transport system of auxin the electric field affected also the activity of plasmalemma proton pump.     

Metabolism of [14C]Indole-3-Acetic Acid by Coleoptiles of Zea mays L.

Reverse-phase high-performance liquid chromatography was usedto analyse [¹⁴C]-labelled metabolites of indole-3-acetic acid(IAA) in coleoptile segments of Zeo mays seedlings. After incubationfor 2 h in 10^–2 mol m^–3 [2-¹⁴C]IAA, methanolic extractsof coleoptiles contained between six and ten radioactive compounds,one of which co-chromatographed with IAA. The metabolic productsin coleoptile extracts appeared to be similar to those in rootextracts, with an oxindole-3-acetic-acid-like component as theprincipal metabolite, but the rate of metabolism was slowerin coleoptile than in root segments. Decarboxylation did notappear to play a major role in the metabolism of exogenous IAAduring the short incubation periods. Moreover, external IAAconcentration had little effect on the pattern of metabolism.Coleoptile segments were also supplied with [¹⁴C]IAA from agardonor blocks placed at the apical ends, and agar receiver blockswere placed at the basal ends. After incubation for 4 h, theidentity of the single radioactive compound in the receiverblocks was shown to be IAA by both reverse-phase high-performanceliquid chromatography and gas chromatography-mass spectrometrytechniques. Key words: Zea mays, Coleoptile, High-performance liquid chromatography, Indole-3-acetic acid     

On the impossibility of the incorporation of 5-methylcytosine and its nucleosides into higher plant DNA

No radioactivity was detected in 5-methylcytosine isolated from wheat DNA after incubation of wheat seedlings with 3H-labelled 5-methylcytosine, 5-methylcytidine and 5-methyldeoxycytidine. No label from 3H-5-methylcytosine was found in DNA of seedlings. After incubation of seedlings with 3H-labelled nucleosides of 5-methylcytosine, radioactivity was discovered only in thymine of DNA. Thus 5-methylcytosine and its nucleosides can not be used in plants as direct precursors of 5-methyl cytosine residues in DNA, but nucleosides of 5-methylcytosine may be deaminated to thymidine (or deoxythymidine) and subsequently incorporated into DNA.     

Asymmetric distribution of acetylcholinesterase in gravistimulated maize seedlings

Acetylcholinesterase (AChE) activity has previously been studied by this laboratory and shown to occur at the interface between the stele and cortex of the mesocotyl of maize (Zea mays L.) seedlings. In this work we studied the distribution of AChE activity in 5-d-old maize seedlings following a gravity stimulus. After the stimulus, we found an asymmetric distribution of the enzyme in the coleoptile, the coleoptile node, and the mesocotyl of the stimulated seedlings using both histochemical and colorimetric methods for measuring the hydrolysis of acetylthiocholine. The hydrolytic capability of the esterase was greater on the lower side of the horizontally placed seedlings. Using the histochemical method, we localized the hydrolytic capability in the cortical cells around the vascular stele of the tissues. The hydrolytic activity was inhibited 80 to 90% by neostigmine, an inhibitor of AChE. When neostigmine was applied to the corn kernel, the gravity response of the seedling was inhibited and no enzyme-positive spots appeared in the gravity-stimulated seedlings. We believe these results indicate a role for AChE in the gravity response of maize seedlings.     

Exposure of oat seedlings to blue light results in amplified phosphorylation of the putative photoreceptor for phototropism and in higher sensitivity of the plants to phototropic stimulation

Dark recovery of blue light-induced in vitro phosphorylation in oat (Avena sativa L.) seedlings after in vivo preirradiation with blue light revealed different recovery kinetics for the coleoptile base and tip. Although, in both cases, maximum in vitro phosphorylation was observed 90 min after in vivo blue light treatment, the phosphorylation levels for the entire base were about 3-fold higher than those found in nonpreirradiated plants. The tip response only slightly exceeded that of the dark controls. The fluence applied during preirradiation determined the extent of the increase in phosphorylation. Consequently, unilateral irradiation and subsequent dark incubation resulted in a more pronounced increase in phosphorylation in the irradiated than in the shaded side of the coleoptile base. Furthermore, blue light-irradiation conditions, known to induce neither first- nor second-positive curvature in nonpreirradiated plants, stimulated both asymmetric distribution of protein phosphorylation and second-positive phototropic curvature in the coleoptile base when administered to blue light-pretreated plants. Based on these data, we conclude that photosensitivity of the coleoptile base increases upon exposure to blue light in a time-and fluence-dependent manner, providing an excellent explanation of the invalidity of the Bunsen-Roscoe reciprocity law for second-positive phototropism.     

Effects of γ-irradiation on elongation and indole-3-acetic acid level of maize (Zea mays) coleoptiles

The effects of γ-irradiation on elongation and the level of indole-3-acetic acid (IAA) of maize (Zea mays) coleoptiles were investigated. When 3-day-old seedlings of maize were exposed to γ-radiation lower than 1 kGy, a temporal retardation of coleoptile elongation was induced. This retardation was at least partly ascribed to a temporal decrease in the amount of free IAA in coleoptile tips on the basis of the following facts: (1) the reactivity to IAA of the elongating coleoptile cells was not altered by irradiation; (2) endogenous IAA level in the tip of irradiated coleoptiles was at first unchanged, but then declined before returning to nearly the same level as that of the non-irradiated control; and (3) the amount of IAA that diffused from coleoptile tip sections showed a similar pattern to that of endogenous IAA. The rate of conversion between free and conjugated IAA was not significantly affected by irradiation. These results suggest that a temporal inhibition of maize coleoptile elongation induced by γ-irradiation can be ascribed to the reduction of endogenous IAA level in the coleoptile tip, and this may originate from the modulation in the rate of IAA biosynthesis or catabolism.     

Auxin Balance in the Avena Coleoptile

Coleoptiles of Avena possessed the capacity to degrade infiltrated indole-3-acetic acid (IAA). This activity decreased along the length of the coleoptile from apex to base on the bases of fresh weight, dry weight and protein; the apical 1 cm segment degraded more IAA than segments from other parts of the coleoptile. The naturally occurring inhibitor of the IAA oxidase activity increased in concentration up to 20 mm from the coleoptile apex; beyond, it decreased gradually towards the base. The spatial distribution of this inhibitor does not explain the gradient in IAA oxidase activity. Growth in length of the coleoptile and the IAA inactivating capacity of the apical 1 cm segment, increased 5- and 4,4-fold, respectively, between the ages of 70 and 130 h; but auxin secretion into agar platelets by the apical 2 mm of the coleoptile registered only a 2.7-fold increase. Deseeding and derooting the seedlings reduced the subsequent growth, diffusible auxin content and the IAA oxidase activity of the coleoptiles; derooting proved to be more deleterious than deseeding. A parallel reduction was evident in auxin content and IAA degrading activity following these treatments. Application of the cytokinin 6-benzylaminopurine (BAP) to coleoptiles of derooted seedlings failed to influence their capacity to degrade IAA. Nor was the activity of the aldehyde oxidase, which converts indole-3-acetaldehyde (IAAld) to IAA, affected by such treatment.     

A unique pantoyllactone glycoside system is activated in rice seedlings developing aerobically in the dark

Rice ( Oryza sativa L.) seedlings developing aerobically in the dark accumulated in the expanding coleoptile millimolar amounts of pantoyllactone glucoside (PLG) together with sugars and amino acids. Following leaf emergence and seedling development, the transformation of PLG into pantoyllactone primeveroside (PLP) was initiated inside the coleoptile, whose senescence was suspended in spite of the exhaustion of seed reserves and cessation of shoot growth. PLG, PLP and most of the sugars and amino acids remained inside the coleoptile. Light administration triggered shoot greening and coleoptile senescence that was accompanied by the conversion of PLG into the shoot-translocatable species PLP and by the utilization of the coleoptile-stored metabolites. Light-induced retrieval of amino acids and sugars from the coleoptile was 90% complete within 24 h while translocation of pantoyllactone glycosides started only 24–48 h after light administration. Conversely, no accumulation of PLG and PLP was detected in seedlings germinated and grown either aerobically in the light or in the dark under hypoxic conditions. The possible significance of the activation of the PLG-PLP system under specific environmental conditions is discussed.