Isolation and identification of a new growth inhibitor, raphanusanin, from radish seedlings and its role in light inhibition of hypocotyl growth

A neutral growth inhibitor, for which the name raphanusanin is proposed, has been isolated in crystalline form from light-exposed Sakurajima radish (Raphanus sativus var. hortensis f. gigantissimus Makino) seedlings and identified as a new compound, 3-methoxy-4-methylthio-2-piperithione by spectrometric analyses.

Applied raphanusanin inhibited the hypocotyl growth of etiolated radish and lettuce seedlings at concentrations higher than 1.5 × 10⁻⁶ molar.

The endogenous raphanusanin contents in cotyledons and hypocotyls of radish seedlings increased more under red light, but decreased or maintained the initial level in the dark. Its content in roots showed almost no change between the light and dark materials.

     

The Role of DNA Synthesis During Hypocotyl Elongation in Light and Dark

Fluorodeoxyuridine, an inhibitor of DNA synthesis, did not affectgermination and post-germinative growth in the aerial part oflettuce and Haplopappus gracilis seedlings when grown in thelight. In the dark, however, elongation of the hypocotyl wasinhibited by fluorodeoxyuridine, strikingly in lettuce and onlyslightly in Haplopappus gracilis. This could imply that thecontrolling mechanism of hypocotyl elongation is in some casesrelated to DNA synthesis, either because mitotic processes (oftenlittle taken into account in considering hypocotyl growth) areinvolved in the elongation of hypocotyls only when they aregrown in the dark, or because DNA synthesis affects cell elongationdirectly, or through the production of a greater number of endopolyploidcells in the dark. Using mainly autoradiographic and cytofluorimetricmethods, these possibilities were tested. Besides lettuce (Lactucasativa L. var. Great Lakes) and H. gracilis (Nutt.) Gray, radish(Raphanus sativus L. var. Tondo rosso quarantino) and soybean(Soya hyspida Sieb. and Zucc. var. Tokyo) seedlings were alsostudied. Fluorodeoxyuridine drastically inhibits cell elongation onlywhen it is preceded or accompanied by mitotic or endomitoticevents. Need for DNA synthesis during hypocotyl elongation,as well as during early post-germinative growth, seems to beof particular importance when endomitotic processes are involved. DNA synthesis, elongation, endoreduplication, fluorodeoxyuridine, Haplopappus gracilis (Nutt.) Gray, Lactuca sativa L., Raphanus sativus L., Soya hyspida Sieb and Zucc     

A growth inhibitor, 2-thioxothiazolidine-4-carboxylic acid from sakurajima radish seedlings

A new growth inhibitor isolated from an acetone extract of light-exposed seedlings of Sakurajima radish, was characterized as 2-thioxothiazolidine-4-ca     

Natural Inhibitors in Normal and Dwarf Peas

Extracts of light- and dark-grown, normal and dwarf pea seedlings(Pisum sativum L. cv. Alaska and Radio respectively) were purifiedby solvent partitioning, column, paper and thin layer chromatography.Conventional acid-base partitioning was modified because thelarge volumes of material processed caused considerable crosscontamination between neutral and acidic phases. At each stepof the purification, fractions were tested for inhibitory activitywith the wheat coleoptile and pea section tests. Recovery ofabscisic acid was monitored using ¹⁴C-abscisic acid. Estimatesof abscisic acid content were marie using gas-liquid chromatographyand the wheat coleoptile bioassay. Two main inhibitors were found; one of these was identifiedas (+)-abscisic acid, the other (inhibitor Y) has not been identifiedbut displays chromatographic properties which suggest that itis neutral in nature. Abscisic acid was found in both rootsand shoots of light- and dark-grown pea seedlings. InhibitorY was found in trace amounts in the roots of dark-grown plantsbut could not be detected in the shoots. Growth in light induceda manifold increase in inhibitor Y concentration compared withdark-grown plants. The level of Y was threefold greater in light-growndwarf shoots than in comparable light-grown tall shoots. Therewas, thus, a correlation between the concentration of inhibitorY and the light-induced inhibition of stem elongation.     

Control by Light of Hypocotyl Elongation and Levels of Endogenous Gibberellins in Seedlings of Lactuca sativa L.

Four 13-hydroxygibberellins, gibberellin A₁ (GA₁), 3-epi-GA₁,GA₁₉ and GA₂₀ were identified by full-scan GC/MS in extractsof lettuce seedlings (Lactuca sativa L. cv. Grand Rapids). Theresults suggest that the early-13-hydroxylation biosyntheticpathway to GA₁ functions in the lettuce seedlings. It was alsofound that GA₁ is active per se in the control of hypocotylelongation in lettuce seedlings. To investigate the relationshipbetween control by light of hypocotyl elongation and levelsof endogenous GAs in lettuce, endogenous levels of GAs werequantified by radioimmunoassay in seedlings that had been grownfor 5 days in the dark (5D) and in those that had been grownfor 4 days in the dark and then under white light for 1 day(4D1L). The endogenous level of GA₁ in the upper and lower partsof hypocotyls in 5D seedlings was about four times higher thanthat in 4D1L seedlings. The response of explants (hypocotylsegments with cotyledons) from dark-grown seedlings to GA₁ isknown to be similar in the dark and under white light when theexplants are treated with inhibitors of the biosynthesis ofGA. Therefore, the above information suggests that the highlevel of GA₁ in hypocotyls of dark-grown seedlings is responsiblefor the rapid elongation of hypocotyl, while irradiation bywhite light decreases the endogenous level of GA₁ in the hypocotylswith a resultant decrease in the rate of hypocotyl elongation. (Received March 13, 1992; Accepted May 21, 1992)     

Raphanusol A,a new growth inhibitor from sakurajima radish seedlings

A new growth inhibitor, raphanusol A, isolated from an acetone extract of light-exposed seedlings of Sakurajima radish, was characterized as 1-,β,4-di-O-(4-hydroxy-3,5-dimethoxycinnamoyl) gentiobiose by chemical methods and spectral data.     

Raphanusol A: a new growth inhibitor of light-grown radish seedlings

A neutral growth inhibitor, for which the name raphanusol Ais proposed, was isolated as a colorless powder (m.p. 137.0–138.0?C)from light-grown radish seedlings and partially characterizedas a phenolic compound which was different from known inhibitors.Raphanusol A inhibited the growth of etiolated radish and lettuceseedlings. Its content, determined by high pressure liquid chromatographyin light-grown radish seedlings, was twice as much as that indark-grown ones. (Received October 18, 1979; )     

Phototropism in Hypocotyls of Radish: IV. Flank Growth and Lateral Distribution of cis- and trans-Raphanusanins in the First Positive Phototropic Curvature

The first positive phototropic curvature induced by a pulse of unilateral white irradiation (0.1 watt per square meter, 30 seconds) of etiolated and de-etiolated Sakurajima radish (Raphanus sativus var hortensis f. gigantissimus Makino) hypocotyls was analyzed in terms of differential growth and growth inhibitor contents of the hypocotyls. In both etiolated and de-etiolated hypocotyls, the growth rates at the lighted sides were suppressed whereas those at the shaded ones showed no change. De-etiolation treatment induced a larger difference between the growth rates at the lighted and shaded sides of the hypocotyls, resulting in a larger curvature of de-etiolated seedlings than of etiolated ones. The contents of growth inhibitors, cis- and trans-raphanusanins, increased in the lighted but not in the shaded halves of the hypocotyls of etiolated seedlings. In de-etiolated seedlings, the two inhibitors increased due to the de-etiolation treatment. When de-etiolated seedlings were exposed to a pulse of unilateral irradiation the level of the two inhibitors remained high along the lighted side for 1 h following the light pulse, whereas at the shaded side the contents of the inhibitors abruptly decreased upon transfer to the dark, the difference between their amounts in the lighted and shaded sides being larger than in etiolated seedlings. Another growth inhibitor, raphanusamide, did not respond to the phototropic stimulus, although its amounts increased by the de-etiolation treatment. These data suggest that cis- and trans-raphanusanins are involved in the first positive phototropic response of radish hypocotyls, and that de-etiolation magnifies the phototropic response through induction of a larger lateral gradient of the raphanusanins in the hypocotyls by the phototropic stimulus.     

Blue light control of hypocotyl elongation in etiolated seedlings of Lactuca sativa (L.) cv. Grand Rapids related to exogenous growth regulators and endogenous IAA, GA3 and abscisic acid

Results of studies on the interaction of blue light (B) and exogenous applied plant hormones (IAA, GA3 and ABA) as well as inhibitors of their synthesis on the control of hypocotyl elongation in etiolated seedlings of Lactuca sativa (L.) cv. Grand Rapids are presented, and compared with endogenous GA3, IAA and ABA levels measured by capillary gas chromatography-mass spectrometry-selected ion monitoring (GC-MS-SIM). Hypocotyl elongation of etiolated seedlings was linearly inhibited by increasing the B fluence rate between 0 and 18.3 mol m–2 s–1. Both GA3 and IAA added to the incubation medium at different concentrations were able to eliminate partially the inhibition of growth caused by 7.2 mol m–2 s–1 B. When dark (D)-grown seedlings were treated with Ca-prohexadione, a specific inhibitor of gibberellin 3-hydroxylation, they showed a growth inhibition similar to under B. Also, a suppression of growth as in B was obtained when D-grown seedlings were treated with ABA 380 M. By lowering ABA levels with fluridone (an inhibitor of ABA synthesis) a partial reversion of hypocotyl growth inhibition was obtained in B-grown seedlings. While none of the growth promoters used were able to reverse completely the growth inhibition caused by B, a proper combination of GA3, IAA and (eventually) fluridone, abolished the B effects. Correspondingly, lower levels of GA3 and IAA and a higher concentration of ABA were measured by GC-MS-SIM in B-grown hypocotyls than in D-grown ones. These results support the hypothesis that hormones are implicated in mediation of B light-dependent inhibition of hypocotyl elongation, which seems to be the result of a balance among endogenous levels of growth promoting and growth inhibiting hormones.     

Effect of alternating magnetic field on the composition and level of lipids in radish seedlings

The effects of alternating magnetic field (AMF) with the frequency of 50 Hz on the dynamics of unfolding of cotyledon leaves, the composition and level of polar and neutral lipids and their component fatty acids (FA) were studied in 5-day-old radish seedlings (Raphanus sativus L. var. radicula D.L., cv. Rozovo-krasnyi s belym konchikom) grown in the light and in the dark. AMF weakened the inhibitory effect of light on unfolding of cotyledon leaves. In the light, the total content of lipids, as well as the level of polar and neutral lipids, in the seedlings in AMF was greater than in control material. In polar lipids, the total amount of glyco-and phospholipids increased; in neutral lipids, the level of triacylglycerols rose. The ratio between phospholipids and sterols (PhL/S) increased. In the dark, the total content of lipids and the level of neutral lipids in the seedlings in AMF were lower than in control material, and the ratio PhL/S decreased. In control material, there were no differences in the relative total content of unsaturated FA in the light and in the dark, whereas the level of linolenic acid was higher in the light than in the dark. AMF induced a decrease in the content of linolenic acid in the light and a rise in the dark; the level of erucic acid in the light decreased. The ratio between unsaturated and saturated FA decreased both in the light and in the dark. It was concluded that AMF with the frequency of 50 Hz was an adjusting agent considerably changing the content of lipids in the radish seedlings in the light and in the dark.     

Comparative transcriptional profiling-based identification of raphanusanin-inducible genes

Background  

Raphanusanin (Ra) is a light-induced growth inhibitor involved in the inhibition of hypocotyl growth in response to unilateral blue-light illumination in radish seedlings. Knowledge of the roles of Ra still remains elusive. To understand the roles of Ra and its functional coupling to light signalling, we constructed the Ra-induced gene library using the Suppression Subtractive Hybridisation (SSH) technique and present a comparative investigation of gene regulation in radish seedlings in response to short-term Ra and blue-light exposure.     

Natural growth inhibitors associated with the cotyledon effect in light-grown dwarf and tall beans

The contents of non-acidic, acidic and bound growth inhibitorsin hypocotyls and cotyledons were compared between dark- andlight-grown dwarf and tall beans by means of thin-layer chromatographyand bioassay. In the non-acidic fraction, one major inhibitoryactivity appeared on the chromatogram, but its Rf zone was differentbetween hypocotyls and cotyledons. In both the acidic and boundinhibitor fractions, one major inhibitory activity appearedat the Rf zone corresponding to ABA. The ABAIike substance whichwas the major inhibitor in the hypocotyl was more abundant inlight-gorwn than dark-grown ones, especially in the dwarf variety,but light irradiation did not cause its transport from cotyledonsto the hypocotyl. A larger amount of bound ABA-like substance,which was the major inhibitor in the cotyledon, was presentin the dwarf than the tall variety regardless of the light condition.Cotyldon-enhanced photoinhibition of hypocotyl growth couldnot be explained by the levels of the xanthoxinand ABA-likeinhibitors, or the transport of these free inhibitors from cotyledons. (Received September 8, 1977; )     

The Arabidopsis mutant alh1 illustrates a cross talk between ethylene and auxin

Ethylene or its precursor 1-aminocyclopropane-1-carboxylic acid (ACC) can stimulate hypocotyl elongation in light-grown Arabidopsis seedlings. A mutant, designated ACC-related long hypocotyl 1 (alh1), that displayed a long hypocotyl in the light in the absence of the hormone was characterized. Etiolated alh1 seedlings overproduced ethylene and had an exaggerated apical hook and a thicker hypocotyl, although no difference in hypocotyl length was observed when compared with wild type. Alh1 plants were less sensitive to ethylene, as reflected by reduction of ACC-mediated inhibition of hypocotyl growth in the dark and delay in flowering and leaf senescence. Alh1 also had an altered response to auxin, whereas auxin levels in whole alh1 seedlings remained unaffected. In contrast to wild type, alh1 seedlings showed a limited hypocotyl elongation when treated with indole-3-acetic acid. Alh1 roots had a faster response to gravity. Furthermore, the hypocotyl elongation of alh1 and of ACC-treated wild type was reverted by auxin transport inhibitors. In addition, auxin up-regulated genes were ectopically expressed in hypocotyls upon ACC treatment, suggesting that the ethylene response is mediated by auxins. Together, these data indicate that alh1 is altered in the cross talk between ethylene and auxins, probably at the level of auxin transport.     

Hormonal Regulation of Hypocotyl Elongation in Lactuca sativa L.: I. EVIDENCE AGAINST THE INVOLVEMENT OF GIBBERELLINS IN THE ELONGATION OF HYPOCOTYL IN SEEDLINGS GROWN IN THE DARK

The kinetics of extension induced by GA₃¹ in the hypocotyl ofintact seedlings of Lactuca sativa are similar in the dark andin the light, and differs fundamentally from the kinetics ofelongation in the dark without GA₃. Both in continuous lightand in the dark, GA₃-induced promotion starts 24 h after incubation.In the dark, even low concentrations of GA₃, which do not affectthe length measured after 6 d when the extension of hypocotylalmost ceases, remove the lag period of 48 h which precedesextension, and prolong the high rate of elongation. FollowingGA₃ supply the hypocotyl length in the dark and in the lightdoes not differ until 48 h; thereafter the rate of elongationin the light is less, so that the final length of the hypocotylis 40 per cent shorter than that of the dark-grown seedlingswithout GA₃. IAA supplied apically to light-grown seedlings induces a weakpromotion at a concentration of 1 mg l^–1 only. With anincreasing concentration of GA₃ supplied simultaneously, theconcentration of IAA inducing a significant promotion decreases.A combined supply of both these regulators, however, does notrestore the light-mediated inhibition of hypocotyl elongationcompletely. The maximum decrease in hypocotyl length induced by the growthretardants AMO-1618, CCC, and B-9 supplied from the beginningin the dark does not exceed 70 per cent. Saturating doses ofGA₃ supplied in combination with any one of the retardants compensateonly a fraction of the decrease. The results have been interpreted to show that native GAs arenot involved in extension growth in the dark.     

Genetic Variation of Hypocotyl Length in the Brussels Sprout

A study was made of variation in the hypocotyl length of twoinbred lines of Brassica oleracea gemmifera (Brussels sprout).The pattern of means and variances obtained from parental, F₁,F₂ and backcross generations suggested polygenic control ofhypocotyl length. Measurements of parental seed weights, embryocell numbers, and the growth of seedlings from seeds of knownweight support the view that variation between the lines inhypocotyl length, when the seedlings were exposed to light,was determined by differential extension rather than by initialdifferences in seed weight. The effect of reduction in lightintensity on hypocotyl extension was studied and the differencesbetween the lines was maintained under all light intensities.Differential reaction of the lines was only observed when theperiod allowed for growth was short. The inbred line with thelonger hypocotyl was shown to suppress the other under competitiveconditions.     

Osmotic relations during elongation growth in hypocotyls of Helianthus annum L.

The relationship between growth, change in cell osmotic pressure and accumulation of osmotic solutes was investigated in hypocotyls of sunflower (Helianthus annum L.) seedlings. During growth in darkness the osmotic pressure decreased by 50% between days 2 and 6 after sowing. After irradiation of dark-grown seedlings with continuous white light (WL) an inhibition of hypocotyl growth was measured, but the osmotic pressure of the growing cells was not lower than in the dark-grown control. Growth in darkness and after WL irradiation was accompanied by an increase in the amount of osmotic substances (soluble sugars) which was proportional to the increase in length of the organ. During growth in continuous WL the cell osmotic pressure decreased by 45 % between days 2 and 6 after sowing. The transfer of WL-grown seedlings to darkness (“re-etiolation”) resulted in a rapid acceleration of hypocotyl growth, but the cell osmotic pressure was the same as that of the WL grown control. Growth in continuous WL was accompanied by a corresponding accumulation of osmotic substances (soluble sugars). The transition from WL to darkness resulted in an enhanced accumulation of osmotica and an increase in cell-wall extensibility. The results indicate that the relative maintenance of cell osmotic pressure during rapid hypocotyl growth in darkness is caused by an enhanced accumulation of soluble sugars into the growing cells of the organ.     

Phototropism in Hypocotyls of Radish : I. Isolation and Identification of Growth Inhibitors, cis- and trans-Raphanusanins and Raphanusamide, Involved in Phototropism of Radish Hypocotyls

Three growth inhibitors which might be involved in phototropism of Sakurajima radish (Raphanus sativus var. hortensis f. gigantissimus Makino) hypocotyls, were isolated as crystalline forms from light-exposed radish seedlings and identified as cis- and trans-raphanusanins and 6-methoxy-2,3,4,5-tetrahydro-1,3-oxazepin-2-one (designated raphanusamide). The cis- and trans-raphanusanins inhibited growth of etiolated radish hypocotyls at concentrations higher than 1.5 micromolar, raphanusamide at concentrations higher than 20 micromolar.     

Evidence for two photoreceptors controlling growth in de-etiolated seedlings

The effect of blue light on hypocotyl extension in de-etiolated seedlings of lettuce, cucumber and tomato was investigated under conditions which precluded the involvement of phytochrome. Small but highly inhibitory amounts of blue light were added to a high intensity background illumination from low pressure sodium lamps. A log-linear response for inhibition of hypocotyl extension against the blue light fluence rate was obtained for lettuce and cucumber, and inhibition in tomato was also related to the blue light fluence rate. The added blue light did not alter phytochrome photostationary state and its effect was independent of the total fluence rate. Growth inhibition by Pfr could be demonstrated in tomato and cucumber but not in lettuce. The results indicate that two photoreceptors may normally be involved in the control of seedling growth but their relative importance varies greatly between species.Abbreviations HIR high irradiance reaction - Pfr far red absorbing form of phytochrome - Pr red absorbing form of phytochrome     

Growth and Dormancy in Lunularia cruciata (L.) Dum: VII. THE ISOLATION AND BIOASSAY OF LUNULARIC ACID

The extraction, purification, and isolation of the growth inhibitorpreviously postulated are described. Methanol extraction andseparation into acid, neutral, and basic fractions was followedby paper chromatography of the acid and neutral fractions withdistilled water, re-extraction with methanol, and thin-layerchromatography, the peak of inhibition being located at Rf 0.7–0.8(isopropanol: ammonia: water, 100:5:5), or Rf 0.3–0.4(chloroform: ethyl acetate: acetic acid, 60:40:5) Lunularia gemmae, grown directly on the chromatographic stripwith added nutrient solution, served as the most appropriateand direct bioassay. Area measurements after 5–10 days'growth yielded significant differences. Other bioassays included:Marchantia polymorpha gemmae, lettuce hypocotyl growth, cress-seedgermination, oat coleoptile, and radish cotyledon disc tests.An active inhibitor, i.e. dihydrohydrangeic acid, now named‘lunularic acid’, was isolated in crystalline form.Lunularic acid was found to increase with long-day treatmentof Lunularia thalli, though present even in short-day. Its concentrationcould be altered rapidly when daylength conditions were changed.The growth inhibition was linearly related to concentrationover the range from 0.1 to 10 ppm, very high concentrationsbeing lethal. Abscisic acid, though inhibitory to Lunulariain low concentrations, was not detected in extracts, and couldeasily be separated from lunularic acid.