Water uptake and distribution in non-dormant and dormant wild oat (Avena fatua L.) caryopses

The influence of seed coat modification and light quality onwater uptake and distribution in caryopses of dormant and non-dormantlines of wild oat (Avena fatua L.) was determined using NMRmicroimaging. Non-dormant seeds absorbed water more rapidlythan dormant seeds during imbibition on distilled water. Thiseffect was detected first in the embryo-scutellar region (8h) and later in the proximal endosperm (12 h). Cutting the testaand pericarp close to the embryo or scarification with KOH promotedrapid embryo/scutellum hydration and germination. Cutting atthe middle part of the caryopsis did not enhance embryo hydrationnor did it greatly improve germination. The sensitivity of waterdistribution to the phytochrome germination effect was examined.Significant differences in imbibitional water uptake by embryos-scutellumtissue were detected by 18 h following red-light (germinationpromoter) compared with far-red (germination inhibitor) treatment.The results indicated that both the rate and the sequence ofembryo/scutellum hydration were important in initiating germinationin dormant seeds. A refinement of the model that describes waterimbibition in wild oat seeds during the early stages of germinationis discussed. Key words: Water uptake, water distribution, Avena fatua, seed coat modification, light quality, dormant and non-dormant seeds     

Germination and Dormancy in Immature and Fresh-mature Lettuce Seeds

The effects of red light, far-red light, Gibberellin A₃, andethephon were studied on the germination of lettuce seeds cv.Grand Rapids harvested at different stages of development. Seeds did not become capable of germination until 8 days afteranthesis. Red light promoted seed germination from the age of8–9 days following anthesis up to the newly mature stage.Ten or 11 days following anthesis, a large percentage of seedsbecame capable of germination in the dark and therefore couldbe considered not dormant. They were affected by far-red light,but less so than the mature seeds. The effect of light on the germination of developing seeds appearedto be similar to the known light effect on mature lettuce seedgermination. Gibberellin A₃ and ethephon had no effect on immatureand fresh seed germination. Lactuca sativa L., Lettuce, germination, dormancy, red light, far-red light, gibberellin A₃, ethephon     

Factors affecting the induction and release of secondary dormancy in Kalanchoë seeds

Abstract. Several short daily R irradiations are required from the first day of incubation on water to induce germination of Kalanchoë seeds. When the same light treatment is given after a prolonged dark incubation period at 20°C, secondary dormancy prevents germination. Factors controlling the induction and breaking of secondary dormancy have been investigated. The induction of secondary dormancy is very temperature dependent. Locally puncturing the seed coat strongly delays it. Secondary dormancy is not induced in the presence of GA₃ during the first 10 d of dark incubation, although this growth substance cannot induce dark germination. Prolonged or cyclic daily R irradiations can relieve secondary dormancy of seeds kept on water, even after a dark period of 20 d. A 24 h treatment at 4°C restores responsiveness to short R exposures of slightly secondarily dormant seeds. The synergism between GA₃ and Pfr in non-dormant Kalanchoë seeds, leading to high effectiveness of even one short FR irradiation, still occurs in seeds made secondarily dormant before transfer to GA₃, but more R or FR irradiations, in combination with GA₃, are required for the release of secondary dormancy. A combination of red light and 6-benzyl-aminopurine is ineffective in removing dormancy.     

A Seed Coat Bedding Assay to Genetically Explore In Vitro How the Endosperm Controls Seed Germination in Arabidopsis thaliana

The Arabidopsis endosperm consists of a single cell layer surrounding the mature embryo and playing an essential role to prevent the germination of dormant seeds or that of nondormant seeds irradiated by a far red (FR) light pulse. In order to further gain insight into the molecular genetic mechanisms underlying the germination repressive activity exerted by the endosperm, a "seed coat bedding" assay (SCBA) was devised. The SCBA is a dissection procedure physically separating seed coats and embryos from seeds, which allows monitoring the growth of embryos on an underlying layer of seed coats. Remarkably, the SCBA reconstitutes the germination repressive activities of the seed coat in the context of seed dormancy and FR-dependent control of seed germination. Since the SCBA allows the combinatorial use of dormant, nondormant and genetically modified seed coat and embryonic materials, the genetic pathways controlling germination and specifically operating in the endosperm and embryo can be dissected. Here we detail the procedure to assemble a SCBA.     

Relationship between Colour, Phenolic Content and Impermeability in the Seed Coat of various Trifolium subterraneum L. genotypes

The relationship between seed colour, phenol content of thetesta and water impermeability in dark and light seeded genotypesof Trifolium subterraneum L. was investigated. The developmentof water impermeability and catechol oxidase activity in expandingseeds of two genotypes was monitored. The results show catecholoxidase activity decreases as seed colour changes from greento purple, but the potential to become impermeable with dehydrationis not acquired until later in seed development. Both waterpermeable and impermeable seeds of dark coloured genotypes containsubstantial amounts of phenol in the lumen of the Malpighiancells; light coloured testas do not. It is concluded that the darkening of the testa of Trifoliumsubterraneum is associated with oxidation of phenol by catecholoxidase but that development of impermeability is independentof this process. Trifolium subterraneum L., subterranean clover, seed coat impermeability, catechol oxidase, phenol, testa colour     

Quantal Response of Seed Germination in Brachiaria humidicola, Echinochloa turnerana, Eragrostis tef and Panicum maximum to Photon Dose for the Low Energy Reaction and the High Irradiance Reaction

Various daily photon doses (daily net number of photons perunit area), provided by varying both photon flux density andphotoperiod, were applied to dormant seed populations of fourgraminaceous species tested for germination in alternating-temperatureregimes on filter papers moistened with either water or a solutionof potassium nitrate. In all four species germination was dependentupon daily photon dose, the product of photon flux density andduration, and quantified by linear relations between the probitof percentage germination and the logarithm of the daily photondose determined by probit analysis. Photon flux density andphotoperiod only influenced germination indirectly as factorsof daily photon dose, except in Echinochloa turnerana (Domin)J.M. Black at high daily photon doses where lower germinationwas observed in continuous light than in 8 h d^–1 photoperiod.The low energy reaction, in which increasing dose promotes seedgermination, was observed in Echlnochloa turnerana and Eragrostistef(Zucc.) Trotter but not in the populations of Brachiariahumidicola (Rendle) Schwcickerdt and Panicum maximum Jacq. usedin this study. The high irradiance reaction, in which increasingthe photon dose reduces germination, was, however, observedin all four species. In Eragrostis tef potassium nitrate influencedthe response of seed germination to light, but in the remainingspecies its influence on this relationship was either additive(Panicum maximum) or nil (Brachiaria humidicola and Echinochloaturnerana) in the alternating-temperature regimes used in thisstudy. The implications of the quantal response to photon dosefor devising optimal light regimes to be applied in laboratorytests intended to maximize seed germination are discussed. Key words: Light, seed germination, seed dormancy, grasses     

Differentiation of a Functional Aleurone Layer Within the Seed Coat of Sinapis alba L.

The hitherto unresolved ontogenetic origin of the aleurone layerin mustard (Sinapis alba L.) seeds was investigated with lightand electron microscopy. Contrary to previous views, this layerof storage cells is neither derived from the endosperm nor fromthe nucellus, but from a particular cell layer within the innerintegument of the seed coat. These cells differentiate and becomefilled with storage protein and fat concurrently with the maturationof the embryo. They survive seed desiccation and become depletedof storage materials during seed germination. Temporally correlatedwith the germinating embryo, the aleurone cells produce microbodyenzymes, which are controlled by light in a similar fashionin both tissues. Sinapis alba L., mustard, aleurone layer, seed coat, seed formation, germination     

Effects of Repetitive Acid Immersion, Red Light, and Gibberellin A3 Treatments on Phytochrome-mediated Germination Control in Skotodormant Lettuce Seeds

Dry lettuce seeds (Lactuca sativa L. cv. Grand Rapids), whichreceived 5 min far-red light (FR) 0.5 h after the onset of waterimbibition, showed 17% and 50% germination without and withacid immersion treatment (pH 0.1) for 1 h and rinsing with water,respectively. The acid treatment caused only 6% germinationor less in FR-treated seeds held for 10 to 30 d in dark storage.The 10 to 30 d skotodormant seeds did not respond to red light(R) or gibberellin A₃ (GA₃) singly, but showed 84% or higherpercentage germination if 1 h acid immersion was given beforeR or GA₃. The 20 d skotodormant seeds, which received R treatmentat day 10 but remained dormant showed 89% germination with onlyacid treatment. Similar values were obtained with 30 d skotodormantseeds which received one or two R treatments at day 10 or 20,i.e. the only requirement for these R-treated dormant seedswas an acid immersion. This releases the skotodormancy and rendersthe seeds more sensitive to R or GA₃, but the skotodormancywas initiated again if no light or hormone treatments were givenimmediately. The repetitive R or GA₃ treatments, which did notcause skotodormant seeds to germinate, lessened the degree ofskotodormancy. The germination of these skotodormant seeds canonly be induced by the synergistic action of R and GA₃. In thisstudy, GA₃ caused higher germination percentages in R-treatedskotodormant seeds than R stimulated in GA3-treated seeds. Itis suggested that (i) repetitive R or Ga₃ treatments maintaina high endogenous level of the far-red-absorbing form of phytochrome(P_fr) and GA activity, respectively, (ii) the accumulated stableintermediates of phytochrome persist in fully-imbibed skotodormantseeds for up to 20 d, without phytochrome expressing its functionuntil the seeds are acidified and (iii) a model is formulatedto interpret the results of acidification, growth promotersand R effects on germination of light-sensitive lettuce seeds. Key words: Phytochrome, Latuca saliva, seed germination, dark reversion of phytochrome, gibberellin A₃, acidification, skotodormancy     

Effects of Photoperiod on Germination of Seeds of Talinum triangulare (Jacq.) Willd

Seed germination in Talinum triangulare as affected by photoperiod,with or without previous incubation in the dark in water at25 or 4 °C, was studied. The time course and quantity ofseed germination in photoperiods of 1 h and above were similarwith or without dark pretreatment, but the time to half maximumgermination was reduced from 12 days in non-dark pretreatedseeds to 4 days in seeds given 20 days in the dark at 25°C.A photoperiod of 0·25 h gave a lower rate and total germinationthan photoperiods of 1 h and above. Un-pretreated seeds required17 cycles of 24 h photoperiod for maximum germination as comparedwith 7 or less cycles if the seeds received more than 10 daysdark pretreatment at 25 °C. Both the rate and total germinationin light increased as the length of dark pretreatment at 25°C was increased from zero to 30 days. Incubation of theseeds in water in the dark at 4 °C for 5 to 30 days priorto illumination at 21 °C, reduced both the rate and quantityof seed germination in light as compared with those similarlyincubated in the dark at 25 °C. However, previous incubationin the dark for 30 days at 4 °C partially substituted forthe light requirement. The possible mechanism of breakage ofseed dormancy in Talinumis discussed in relation to these andother findings. Talinum triangulare (Jacq.), Willd, light, photoperiod, seed germination     

PHYSIOLOGY OF LIGHT-REQUIRING GERMINATION IN ERAGROSTIS SEEDS

The photorequirement for the germination of Eragrostis seedsdecreases with the progress of their after-ripening, and thegermination occurs whether in continuous light or in darknessat the final stage of after-ripening. The dehydration of seedsor the puncturing of seed coats also results in a decrease ofphotorequirement for germination. The rate of water absorptionof seeds increases with the germination capacity under continuousdark condition. However, there is no correlation between therespiration rate and the germination capacity; respiration isstimulated in the punctured seeds, but not in the after-ripenedseeds. The after-ripened or punctured seeds which no longer have aphotorequirement become light-sensitive again, when they areallowed to germinate in the air of low oxygen concentrations.The assumption is presented that the permeability to oxygenof the seed coat may be a factor controlling the seed germinationof this species. (Received August 21, 1964; )     

Seed Coat Dormancy in Two Species of Grevillea(Proteaceae)

The role played by the seed coat in seed dormancy of Grevillealinearifolia(Cav.) Druce and G. wilsonii(A. Cunn.) was testedby a series of manipulations in which the seed coat was dissectedand removed, dissected and returned to the decoated seed, ordissected, removed and given a heat shock, and returned to thedecoated seed. Germination of intact seeds of both species wasalso examined after exposure to heat shock, smoke, or heat shockand smoke combined. Water permeability of the seed coat wasinvestigated by examining imbibition. For intact seeds, virtuallyno germination occurred under any treatment (G. wilsonii), orgermination was increased by exposure to either heat or smoke(G. linearifolia). Removal of the seed coat led to germinationof all decoated seeds for G. linearifolia, or a proportion ofdecoated seeds for G. wilsonii. Inclusion of smoked water inthe incubation medium led to a higher proportion of decoatedseeds germinating for G. wilsonii. Returning the seed coat,either with or without heat shock to the seed coat, did notsignificantly affect germination in either species. Seed coatswere permeable to water in both species. For the two Grevilleaspecies, there were different dormancy mechanisms that werecontrolled by the seed coat (G. linearifolia) or by both theseed coat and embryo (G. wilsonii). Copyright 2000 Annals ofBotany Company Grevillea linearifolia, Grevillea wilsonii, dormancy, seed coat dormancy, seed coat permeability, smoke, heat shock, germination     

The Role of Germination Inhibitors and Oxygen in the Dormancy of the Light-densitive Seed of Betula spp.

Although unchilled, intact seeds of Betula pubescens and B.verrucosa require light for germination, isolated embryos germinateequally well in both light and darkness. An aqueous extract of these seeds has germination-inhibitoryproperties correlated with the presence of a non-fluorescent,single substance. The light requirement of isolated embryosis restored by the inhibitor. When intact seeds are leachedwith water to remove some inhibitor, it is found that the lightrequirement is reduced, short days and single light periodsthen eliciting greater germination than in unleached seeds. It has been found that scratching, pricking, and cutting theseed coat increases the germination of intact seeds in darkness,and that this is probably due to enhanced oxygen entry. Further,it has been found that germination in short days is increasedin oxygen-enriched atmospheres. It has been found that although the inhibitory effect of theseed coat in intact seeds is partially due to the reductionof the oxygen supply to the embryo, a low oxygen concentrationdoes not prevent germination of isolated embryos. Experimentalresults suggest that the inhibitor in the seed coat increasesthe oxygen requirement of the embryo.     

Effect of malformin on phytochrome- and Ethrel-mediated responses

On etiolated cuttings of Phaseolus vulgaris malformin inhibitedseveral phytochromemediated responses. This included hypocotylhook-opening, leaf expansion, and inhibition of stem elongation.Malformin also inhibited anthocyanin synthesis by sorghum, buthad no effect upon lettuce seed germination in the light ordark. Malformin alleviated Ethrel-induced hook-retention, inhibitionof stem elongation, and root curvatures, but not Ethrel-inducedstimulation of lettuce seed germination in the dark. (Received February 19, 1975; )     

The Induction of Seed Germination in Arabidopsis thaliana Is Regulated Principally by Phytochrome B and Secondarily by Phytochrome A

We examined whether spectrally active phytochrome A (PhyA) and phytochrome B (PhyB) play specific roles in the induction of seed germination in Arabidopsis thaliana (L.) Heynh., using PhyA- and PhyB-null mutants, fre1-1 (A. Nagatani, J.W. Reed, J. Chory [1993] Plant Physiol 102: 269-277) and hy3-Bo64 (J. Reed, P.Nagpal, D.S. Poole, M. Furuya, J. Chory [1993] Plant Cell 5: 147-157). When dormant seeds of each genotype imbibed in the dark on aqueous agar plates, the hy3 (phyB) mutant did not germinate, whereas the fre1 (phyA) mutant germinated at a rate of 50 to 60%, and the wild type (WT) germinated at a rate of 60 to 70%. By contrast, seeds of all genotypes germinated to nearly 100% when plated in continuous irradiation with white or red light. When plated in continuous far-red light, however, frequencies of seed germination of the WT and the fre1 and hy3 mutants averaged 14, nearly 0, and 47%, respectively, suggesting that PhyB in the red-absorbing form prevents PhyA-dependent germination under continuous far-red light. When irradiated briefly with red or far-red light after imbibition for 1 h, a typical photoreversible effect on seed germination was observed in the fre1 mutant and the WT but not in the hy3 mutant. In contrast, when allowed to imbibe in the dark for 24 to 48 h and exposed to red light, the seed germination frequencies of the hy3 mutant were more than 40%. Immunoblot analyses of the mutant seeds showed that PhyB apoprotein accumulated in dormant seeds of the WT and the fre1 mutant as much as in the seeds that had imbibed. In contrast, PhyA apoprotein, although detected in etiolated seedlings grown in the dark for 5 d, was not detectable in the dormant seeds of the WT and the hy3 mutant. The above physiological and immunochemical evidence indicates that PhyB in the far-red-absorbing form was stored in the Arabidopsis seeds and resulted in germination in the dark. Hence, PhyA does not play any role in dark germination but induces germination under continuous irradiation with far-red light. Finally, we examined seeds from a signal transduction mutant, det1, and a det1/hy3 double mutant. The det1 seeds exhibited photoreversible responses of germination on aqueous agar plates, and the det1/hy3 double mutant seeds did not. Hence, DET1 is likely to act in a distinct pathway from PhyB in the photoregulation of seed germination.     

Accelerating Strawberry Seed Germination by Fungal Infection

Germination of strawberry seed was accelerated by natural andartificial infections of Ulocladium charatarum and other fungi,including the Arthrinium state of Apiospora montagnei and aCladosporium sp. Germination was variously promoted by fungiboth in light and darkness, on damp filter paper, water andmalt agar plates and on horticultural compost. Germinated seedlingswere apparently undamaged by these infections, although whencultured on malt agar the seedlings were overgrown by the fungus.Several other fungi promoted germination, but three of themlater killed the seedlings. Germination of seed of all threecultivars that were tested was promoted by fungal infectionwhich probably promoted germination by hastening breakdown ofthe seed coat. Strawberry, Fragaria ananassa Duch., germination, fungus     

SUCCESSIVE PROCESSES INVOLVED IN THE GERMINATION RESPONSE OF NASTURTIUM SEEDS

1. The seeds ofNasturtium palustreDC. do not germinate, eitherin the light or darkness, at various constant temperatures,but require for their full germination a certain period of alow temperature (5°) applied immediately after light irradiation.These results indicate the existance of at least two processes,a light-dependent process and a low temperature-requiring process,in the initiation of germination ofNasturtiumseeds. Experimentalevidence indicated further that the light exposure causes twodifferent processes in the seed germination. 2. When a dark period at 23° was inserted between the lightirradiation and the low temperature treatment the germinationwas suppressed. The inhibitory effect of the inserted dark periodat 23° was eliminated by a short irradiation during thedarkness (light-break). 3. Prolonged exposure ofNasturtium seeds to any concentrationof gibberellin brought about no germination when exposure wasgiven in complete darkness. The germination was promoted onlywhen light irradiation was applied to the seeds. A short applicationof gibberellin at a fairly high concentration was, however,remarkably effective for the germination even in the darkness,and the germination was inhibited as the gibberellin applicationwas lengthened. It was considered that gibberellin could substitutefor the combined effect of light irradiation and low temperaturetreatment to induce the germination of Nasturtium seeds, andthat gibberellin was inhibitive toward the reactions followingthe above treatments which induced the germination (Received October 31, 1996; )     

Light Actions in the Germination of Cocklebur Seeds: IV. DISAPPEARANCE OF RED LIGHT-REQUIREMENT FOR THE GERMINATION OF UPPER SEEDS SUBJECT TO ANOXIA, CHILLING, CYANIDE OR AZIDEPRETREATMENT

Esashi, Y., Fuwa, Nn Kojima, K. and Hase, S. 1986. Light actionsin the germination of cocklebur seeds. IV. Disappearance ofred light-requirement for the germination of upper seeds subjectto anoxia, chilling, cyanide or azide pretreatmenL—J.exp. Bot. 37: 1652–1662. The effects on the germination of positively photoblastic uppercocklebur (X anthium pennsylvanicum Wallr.) seeds by pretreatingwith anoxia, chilling, cyanide or azide, which stimulates theirdark germination, were examined in relation to light actions.Prior to experiments, seeds were pre-soaked at 23 °C inthe dark for 1 or 2 weeks to remove the pre-existing Pfr. Whenthe prctreatment conditions were suboptimal for germinationinduction, the stimulating effects of the pretreatments on germinationduring a subsequent dark period at 23 °C were manifest onlywhen seeds were irradiated with red light before or after thepretreatment Red light promotion was reversed by blue or far-redlight treatment. However, both prc-chilling for 6 d at 8 °Cand prctreatment with 1· 5 mol m ^{– 3} NaN³ for 2d could induce full germination without red light exposure.On the other hand, both pre-exposure to anoxia for 8 d and pretreatmentwith 30 mol m^–3 KCN could induce the dark germinationonly when germination occurred at 33 °C which is known toaugment the ratio of an alternative respiration flux to a cytochromeone. Moreover, the dark germination in response to these inductionswere strongly inhibited by the inhibitors of alternative respiration,propyl gallate and benzohydroxamic acid, applied during a subsequentdark period. It was thus suggested that Pfr has some relationto the operation of two respiration systems of cocklebur seeds,but it is not indispensable to germination of this positivelyphotoblastic seed. Key words: Anoxia, azide, blue light, chilling cyanide, dark germination, far-red light, red light, seed germination, X anthium pennsylvanicum     

Callose Deposits make Clover Seeds Impermeable to Water

The permeability status of the seed from ten genotypes of subterraneanclover, determined by soaking, is shown to be related to callosedeposition in the seed coat. Large amounts of callose were foundin the nutrient (parenchyma) layer of impermeable but not permeableseeds. It is suggested that the nutrient layer controls permeabilityand thus the ease of germination of seeds. Trifolium subterraneum L., clover, seed coat impermeability, callose     

Cytochemical Localization of Phenolic Compounds in Columella Cells of the Root Cap in Seeds of Brassica napus--Changes in the Localization of Phenolic Compounds during Germination

Changes in the localization of phenolic compounds were investigatedin columella cells of embryonic roots in 1-year-old Brassicanapus seeds during 48 h of imbibition and germination. In dry,dormant seeds, phenolic compounds were located in the apoplasticcompartment between the cell wall and plasmalemma in the outermostlayer of the columella. These apoplastic phenolic deposits disappearedduring the activation processes associated with imbibition andgermination, but new deposits appeared successively in the nucleus,ER cisternae, protein bodies and on the outer surface of theroot cap. A large number of phenolic deposits were observedin the outermost part of the columella, becoming less frequenttowards the initial centre. Their appearance coincided withrestoration of the ER and immediately preceded cytological activation.After the primary root had emerged from the seed coat, depositsof phenolic compounds disappeared from the cytoplasm, but simultaneouslyappeared in the vacuoles. Copyright 1999 Annals of Botany Company Brassica napus var. oleifera, root columella, germination, phenolic compounds localization.     

Control of the Germination Responses of Amaranthus retroflexus L. Seeds by their Parental Photothermal Environment

Germination responses of the seeds of Amaranthus retroflexusL. were affected by the photoperiod, temperature, and levelof solar radiation experienced by their parent plants. Seedsfrom parents grown continuously in short days (SD, 8 h) lostpost-harvest dormancy more rapidly and had a higher dark germination,as well as a greater responsiveness (at 30?C) to pretreatmentsat low temperature (5 or 10?C) and to short illuminations, thanseeds from parents grown continuously in long days (LD, 16 h).Dark germination and responsiveness of the seeds to promotivetreatments were both higher when their parents were transferredat flowering from LD to SD than when grown continuously in LD.These responses were lower when their parents were similarlytransferred from SD to LD than when grown continuously in SD.The promotive effects of parental post-flowering SD on darkgermination (at 30?C) were enhanced by reduction of parentaltemperature (from 27/22?C to 22/17?C), but the responsivenessof the seeds to low temperature pretreatment was reduced. Inflorescencesdeveloping in LD produced seed with higher germinability whenfloweringwas not induced (LD throughout) than when it was induced (eitherby SD till flowering, or by three SD cycles when 4–5 leavesappeared). Reduced levels of solar radiation had opposite effectsin the different parental photoperiods: dark germination andthe responsiveness to low temperature pretreatments were reducedin LD, but were increased in SD. Differences in the germination responses resulting from differencesin the parental environment could not be correlated with differencesin seed coat thickness or seed dry weight.