Functional aspects of mature seed coat of theCannaceae

Cannaceae seeds have been analysed regarding seed coat structure, germination and macromolecular composition of the seed coats. Data of several mass spectrometric techniques were combined with those of microscopic and histochemical techniques to acquire insight into the functions of the seed coat.Cannaceae seeds have an exotestal layer of Malpighian cells with a hydrophobic and a hydrophilic part. The hydrophobic part is mainly responsible for the impermeability of the seed and contains silica, callose, lignin as water repellent substances. Water can only enter the seed after a certain temperature-induced opening of an imbibition lid. During imbibition the hydrophilic part of the Malpighian cells swells and the seed coat ruptures due to differences in pressure in the upper and lower part of the Malpighian cells.     

Cellular pathway of photosynthate transport in coats of developing seed of Vicia faba L. and Phaseolus vulgaris L. I. Extent of transport through the coat symplast

The extent of post-phloem solute transport through the coatsymplasts of developing seeds of Vicia faba L. and Phaseolusvulgaris L. was evaluated. For Vicia seed coats, the membrane-impermeantfluorochrome, CF, moved radially from the chalazal vein to reachthe chlorenchyma and thin-walled parenchyma transfer cell layers.Thereafter, the fluorochrome moved laterally in these two celllayers around the entire circumference of the seed coat. Transferof CF from the chalazal vein was inhibited by plasmolysis ofattached ‘empty’ seed coats. In contrast, the spreadof phloem imported CF was restricted to the ground parenchymaof Phaseolus seed coats. Fluorochrome loaded into the outermostground parenchyma cell layer was rendered immobile followingplasmolysis of excised seed-coat halves. Phloem-imported [¹⁴C]sucroseand the slowly membrane permeable sugar, L-[¹⁴C]glucose, werepartitioned identically between the vascular and non-vascularregions of intact Vicia seed coats. For ¹⁴C-photosynthates,these partitioning patterns in attached ‘empty’Vicia seed coats were unaffected by PCMBS, but inhibited byplasmolysis. Tissue autoradiographs of intact Phaseolus seedcoats demonstrated that a pulse of ¹⁴C-photosynthate moved fromthe veins to the grounds tissues. In excised Vicia seed coats,preloaded with ¹⁴C-photosynthates, the cellular distributionof residual ¹⁴C-label was unaffected by PCMBS. In contrast,PCMBS caused the ¹⁴C-photosynthate levels to be elevated inthe veins and ground parenchyma relative to the branch parenchymaof Phaseolusseed coat halves. Based on the above findings, itis concluded that the phloem of Vicia seed coats is interconnectedto two major symplastic domains; one comprises the chlorenchyma,the other the thin-walled parenchyma plus thin-walled parenchymatransfer cells. For Phaseolusseed coats, the phloem forms amajor symplastic domain with the ground parenchyma. Key words: Phaseolus vulgaris L, phloem unloading, photosynthate transport, seed coat, symplast, Vicia faba L     

Seed Coat Retention and Hypocotyl Hook Development in Mutants of Arabidopsis thaliana L.

Germination and growth of wild-type and two mutant strains (aux-1and Dwf) of Arabidopsis thaliana L. have been examined. Seedlingsof aux-1 exhibit agravitropic roots whereas Dwf display bothagravitropic roots and shoots. Wild-type seedlings retained the seed coat at the root-hypocotyltransition zone and developed hypocotyl hooks. In contrast,aux-I and Dwf seedlings did not retain their seed coats andlacked hypocotyl hooks. A positive gravitropic response of theroots was essential for the retention of the seed coat at theroot—hypocotyl transition zone by the attachment of roothairs to the seed coat. The development of the hypocotyl hookwas aided by the retention of the seed coat. The apical regionof the hypocotyl apparently remained agravitropic during formationand maintenance of the hypocotyl hook. Arabidopsis thaliana L., auxins, gravitropism, hypocotyl hook, mutants, peg formation, germination     

Production of a Fungistat and the Role of Fungi during Germination of Digitalis purpurea L.cv. Gloxiniaflora Seeds

The seed coats of Digitalis purpurea L. cv. Gloxiniaflora werecultured for indigenous fungi. Alternaria alternata (Fries)was identified as the sole fungus on seeds freshly harvestedfrom unopened capsules, whereas A. alternata, Rhizopus arrhizus(Fischer), Penicillium sp. and other fungi appeared on storedseeds. The appearance of fungi in seed cultures was seasonal,being more frequent in winter and early spring than in summerand autumn. Alternaria grew well on autoclaved seeds, on dehiscentseed coats, or on seed coats separated from the embryos of ungerminatedseeds. Rhizopus did not grow on these but grew weakly on theculture medium from viable seeds. A. alternata appears to functionas a degradation agent for the seed coat subsequent to germination.Neither fungus was found to be essential to germination of Digitalisseeds. Bioassay of the culture medium from germinating seedsshowed that a fungistat effective against both Alternaria andRhizopus is produced coincident with germination. Based on chromatographicanalysis, the fungistat appears to be a cardenolide. Alternaria alternata (Fries), cardenolides, Digitalis purpurea L. cv, Gloxiniaflora, fungistats, germination, Rhizopus arrhizus (Fischer)     

Characteristics of Sugar, Amino Acid and Phosphate Release from the Seed Coat of Developing Seeds of Vicia faba and Pisum sativum

After removal of the embryo from developing seeds of Vicia fabaL. and Pisum sativum L., the ‘empty’ ovules werefilled with a standard solution (pH 5.5). Seed coat exudatesof both species were collected during relatively long experiments(up to about 12 h) and the concentration of sugar (mainly sucrose),amino acids and phosphate in the exudate measured. A discussionis presented on the amino acid/sugar ratio and the phosphate/sugarratio in the seed coat exudate. A pretreatment (15 min) withp-chloromercuribenzenesulphonic acid (PCMBS) reduced the releaseof sugar, amino acids and phosphate from broad bean seed coats.After excision of ‘empty’ ovules of Vicia faba andPisum sativum from the maternal plant, 2–4 h after thistreatment a strong difference became visible between sucroserelease from excised seed coats and sucrose release from attachedseed coats. Similarly, when the rate of phloem transport ofsucrose into an ‘empty’ ovule of Vicia faba or Pisumsativum was reduced by a sub-optimal mannitol concentrationin the solution, a reduced rate of sugar release from the seedcoat could be observed. Excision and treatment with a sub-optimalmannitol concentration reduced the release of amino acids toa lesser extent than for sucrose. These treatments did not reducethe rate of phosphate release from the seed coat. Key words: Seed development, Seed coat exudate, Phloem transport     

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     

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.     

The Role of the Oxygen Permeability of the Seed Coat in the Dormancy of Seed of Xanthium pennsylvanicum Wallr

A method for direct identification and quantitative measurementsof mixed or pure gases diffusing through seed coats was devisedto test the hypothesis that the dormancy of Xanthium pennsylvanicumseeds is caused by oxygen-impermeable seed coats. The diffusionof oxygen through seed coats of X. pennsylvanicum was shownto obey Fick's first law. Oxygen diffused through the lowerand upper seed coats at the same rate. Imbibed lower and upperseeds showed essentially equal oxygen uptake rates before radicleemergence. This uptake was lower than the rate at which oxygencan diffuse into the seed. Therefore upper seeds are not dormantbecause of seed coat restriction of oxygen diffusion. The relationshipsof oxygen with other factors involved in seed dormancy are discussed.     

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     

Structure and Histochemistry of Embryo Envelope Tissues in the Mature Dry Seed and Early Germination of Phacelia tanacetifolia

The embryo envelope tissues in both mature dry seed and duringearly germination of Phacelia tanacetifolia were investigatedby bright-field and fluorescence light microscopy and scanningelectron microscopy. The ruminate seed had an irregularly reticulatesurface owing to the presence of polygonal areas, correspondingto the cells of the seed coat. The raised margins of these cellsjoined at the lobe tips, where radially arranged thickeningsoccurred. The unitegmic seed coat was made up of three distinctlayers: the frayed outer layer, the middle layer with portionsrising outwards to form the radial thickenings, and the innerlayer, the thickness of which was greatest in the micropylarzone. The endosperm tissue had two regions, the micropylar andthe lateral endosperm, which differed in polysaccharide composition,thickness and metachromasy intensity, and presence (in the lateralendosperm) or absence (in the micropylar endosperm) of birefringenceof the cell walls. Moreover, in the micropylar region, wherethe embryo suspensor remnant was found, Ca-oxalate crystalswere scarce or absent. The presence of a partially permeablecuticle covering the seed endosperm was observed. Incubationof seeds in Lucifer Yellow CH indicated that water was ableto penetrate quickly into the seed coat along the pathway formedby the radial thickenings, the raised margins of the polygonalcells and the middle layer. Afterwards, LY-CH readily infiltratedthe apical portions of the seed lobes and then the whole endosperm.Following imbibition, morphological changes were found in themicropylar endosperm, such as the initial digestion of proteinbodies. In addition, both in the seed coat and in the endosperm,a weaker fluorescence, probably due to leaching of polyphenolicsubstances, was observed. Once the seed coat was broken at themicropylar end of the seed, the endosperm cap surrounding theradicle tip had to be punctured by it so that complete germinationcould occur. Weakening and rupture of the micropylar endospermare briefly discussed. Copyright 2000 Annals of Botany Company Phacelia tanacetifolia, seed coat, micropylar endosperm, endosperm cap, early germination, structure, histochemistry     

Proteomic Profiling of the Aleurone Layer of Mature Arabidopsis thaliana Seed

The aleurone layer of mature Arabidopsis thaliana seed plays important roles in seed germination and dormancy. However, the proteomic profile of this cell layer is unknown partly because it is difficult to separate this thin cell layer from the mature seeds. In this study, we have used a simple technique to separate the aleurone layer along with the seed coat following germination of seeds and determined for the first time the putative protein composition of this cell layer. By subjecting the total proteins extracted from the seed coat to 2D gel electrophoresis followed by liquid chromatography/tandem mass spectrometry, we identified four AGI loci, AT4G28520, AT5G44120, AT1G03880, and AT1G03890; all of which belong to the seed storage family of proteins. Because in Arabidopsis the diploid aleurone cells of the seed coat perform protein storage functions similar to that of triploid endosperm of other plant species, it is assumed that the above AGI loci are associated with the aleurone layer of the seed coat.     

The Interaction of Heat and Smoke in the Release of Seed Dormancy in Seven Species from Southwestern Western Australia

Exposure to high temperatures (40–60 °C) over severaldays to months (simulating summer soil conditions) or to extremelyhigh temperatures (80–120 °C) for periods rangingfrom minutes to several days (simulating the heat of an extremefire) promoted germination in five (including one legume species)of the seven species tested from southwestern Australia. Heat,a collective term for high temperature (HT) and extremely hightemperature (EHT), has previously been used to promote germinationin species with impermeable seed coats (many of which are legumes).If heat is found to promote germination in species with permeableseed coats, it could be of use in the release of dormancy forcommercial development of native plants. Here we report thatelevated storage temperatures (50 °C for 45 and 90 d or60 °C for 45 d) and EHT (100 °C for 3 h and 120 °Cfor 30 min) alone, and in addition to smoke, directly promotegermination of the refractory species Actinotus leucocephalus,Anigozanthos manglesii, Gompholobium knightianum, Loxocaryastriatus and Stylidium affine. Germination of Sowerbaea laxifloraseed was not improved with heat alone but was improved by thecombination of heat and smoke. Seed of Schoenus unispiculatusdid not germinate in response to any of the treatments. Interactionsbetween the effect of temperature, the duration of heat exposureor smoke were detected in all species. Whilst most species demonstratedan interaction between heat and time, not all species were affectedby smoke alone. This was illustrated by an interaction betweensmoke and HT found only in Actinotus leucocephalus, Anigozanthosmanglesii and Stylidium affine or smoke and EHT in A. manglesiiandS. affine . Smoke and exposure time to heat influenced thegermination of Actinotus leucocephalus,Anigozanthos manglesiiand L. striatus in response to HT and only S. affine appearedto demonstrate an interaction between smoke and EHT. The variationsfound in the interactions between treatments suggest that germinationevents occur over a range of conditions both spatially and temporallywhich may facilitate seedling survival and limit competitionbetween emergents. Copyright 2001 Annals of Botany Company Smoke, heat, fire, seedbank, seed dormancy, seed germination, Western Australia     

Effect of Potassium on Sucrose and Amino Acid Release from the Seed Coat of Developing Seeds of Pisum sativum

After removal of the embryo from developing seeds of Pisum sativum,the ‘empty’ ovules (seed coats without enclosedembryo) were filled with a solution (pH 5.5) containing mannitol(usually 400 mM) to which various salts were added. A solutioncontaining two isotopes ((a) [²H]-sucrose/[–¹⁴C]aminoisobutyricacid (AIB) or (b) [³H]valine/[₁₄C]asparagine mixture) was administeredto the plant via the petiole subtending the fruiting node, and[²H]solute and [¹⁴C]solute unloading from the seed coat wasmeasured, in pulse-labelling experiments of about 5 h. The presenceof 25 or 50 mM K⁺ in the ‘empty’ ovule enhancedthe release of sucrose from the seed coat particularly duringthe first hours of the experiment, but the stimulating effectof K⁺ on the release of labelled solutes derived from aminoacids was much smaller. The presence of 25 mM CaCl₂ did notaffect the release of sucrose or amino acids from the seed coat.The effect of K⁺ on sucrose and amino acid release is explainedas an inhibition of sucrose and amino acid resorption from theseed coat apoplast into seed coat cells, after unloading fromthe seed coat unloading sites. It is suggested that amino acidrelease is much less affected by K⁺ than sucrose release, becausefar less resorption of amino acids by seed coat parenchyma cellstakes place during amino acid transport into the seed coat cavity. Pisum sativum, pea, assimilate transport, assimilate unloading, seed-coat exudate, seed development, sucrose resorption, surgical treatment     

The Importance of Genetically Determined Seed Coat Characteristics to Seed Quality in Grain Legumes

Comparisons of five pairs of isogenk lines of peas, differingonly in the A gene for seed coat colour showed that white seeds(genotype aa) imbibed more rapidly than coloured seeds (AA),suffered greater imbibition damage revealed by dead tissue onthe cotyledons, and higher solute leakage. Seed-coat pigmentationwas closely associated with slow water uptake, since when expressionof the A gene was suppressed by the recessive pollens gene,the resulting white seeds {palpal AA) imbibed rapidly. The slowwater uptake by coloured seeds was not due to the restrictionof water entry by the seed coat since the differences in imbibitionrate were maintained when a portion of the seed coat was removedand seeds were imbibed with the exposed cotyledon in contactwith moist filter paper. Imbibition of similarly treated seedsby immersion in polyethylene glycol solutions (1–4%) whichincreased the seed/solution wettability, had little effect onthe water uptake of coloured seeds compared to imbibition inwater whereas that of white seeds increased in the first 10mins imbibition. Poor wettability of the inner surface of colouredseed coats did not therefore explain the slow imbibition ofthese seeds. The white seed coats loosened rapidly during imbibitionwhilst the coloured seed coats remained closely associated withthe cotyledons suggesting that the adherence of the seed coatto the cotyledons and therefore the ease of access of waterbetween the testa and cotyledons determines the rate of imbibition.The rapid water uptake by white-coated seeds and the subsequentimbibition damage may explain the high incidence of infectionof these seeds by the soil-bome fungus Pythhan after 2 d insoil. Improved seed quality and emergence may therefore be achievedby breeding for seed coat characteristics leading to reducedrates of imbibition Pisum sativum, isogenic lines, A gene, seed coat colour, imbibition, imbibition damage, wettability, pollens gene, seed quality, grain legumes     

'Callose' in the Impermeable Seed Coat of Sesbania punicea

Dry legumes of Sesbania punicea (Cav.) Benth. contain impermeableseeds which are either beige-greenish or reddish. When keptin water for over one year they do not swell. Quick imbibitionwas induced by a deep cut, abrasion with coarse abrasive paper,immersion in concentrated sulphuric acid, in boiling water andin boiling KOH solutions. Neither lipid solvents (acetone, chloroform,cyclohexane, diethyl ether, ethanol, xylene), nor, at room temperature,KOH solutions up to 50% per cent, permeabilized the seeds. Astrong barrier to water entry appeared to be located in thepalisade layer which showed ‘light points’ in places,and which seemed to be transversal thickenings. In the testa,‘ callose’, which may play a role in the impermeabilityof the Sesbania punicea seed, was detected. Sesbania punicea, germination, seed dormancy, seed coat impermeability, ‘callose’     

Carpology, Seed Anatomy and Taxonomic Relationships ofGalbulimima(Himantandraceae)

The fruit and seed anatomy and morphology ofGalbulimima belgraveana(F.Muell.) Sprague, a solitary species of the monotypic genus inthe Himantandraceae, have been studied in an effort to clarifyits systematic position. The indehiscent fleshy multicarpellary,two- or three-ranked capsetum ofGalbulimimaconsists of follicles(capseoles) with lignified fibrous five- or six-layered endocarp.Such construction of the himantandraceous capsetum suggestsderivation from free cone-like fruits similar to those of Annonaceaeand Magnoliaceae. Seeds ofGalbulimimaare relatively large, flattened,winged, with a solitary vascular bundle extending to the micropyle,and a cup of hypostase. They are abundantly albuminous and havea small dicotyledonous embryo. The seed coat ofGalbulimimaismesotestal with testal-tegmic ruminations and unspecializedtwo- or three-layered tegmen; a single-layered exotesta representedby thin-walled tanniniferous cells; a two (–three)-layeredmesotesta, composed of thick-walled lignified longitudinal fibres;and an endotesta composed of two or three layers of unspecializedaerenchymatous parenchyma. Evidence, mainly from seed morphologyand anatomy of seed coats, emphasizes the anomaly of the traditionalaffiliation of Himantandraceae with MagnolialessensuTakhtajan,being quite distinct in spermoderm structure and origin fromboth Magnoliaceae and Degeneriaceae in particular. Furthermore,seed anatomy does not confirm any relationships with Myristicaceaeor Canellaceae. Among all Magnoliidae, the structure of theseed coats ofGalbulimimais similar to that of some advancedAnnonaceae and Eupomatiaceae. It is suggested that Himantandraceaetogether with Eupomatiaceae and Annonaceae constitute a distinctrelic blind branch of magnoliid ancestry. On the basis of availabledata of seed coat anatomy, it is appropriate to remove Himantandralesfrom the order Magnolialessensu stricto, and to place it intoits own monotypic order, Himantandralesord. nov.,grouping togetherwith orders Eupomatiales and Annonales in Magnoliidae.Copyright1998 Annals of Botany Company Galbulimima belgraveana(F. Muell.) Sprague; carpology; pericarp; seed anatomy; systematics; phylogenetic relationships; Himantandraceae; Magnoliaceae; Eupomatiaceae; Degeneriaceae; Annonaceae; Liriodendraceae; Myristicaceae; Canellaceae.     

Structural Changes During the in vitro Germination of Vanilla planifolia (Orchidaceae)

A study is reported of histogenesis and organogenesis duringthe processes leading up to seedling formation in cultures ofVanilla planifolia. Prior to germination, all cells of the embryoincreased in size rupturing the seed coat and initiating theprotocorm stage. The cells of the protocorm were heavily ladenwith starch grains. Although all of the cells of the matureembryo were heavily laden with protein bodies, these were confinedto the terminal cell descendents on emergence of the embryofrom the seed coat, and they disappeared during differentiationof the meristem, indicating that some reserves were mobilizedand utilized during germination. The terminal locus of embryonal axis did not differentiate intoa cotyledon and epicotyl as in other angiosperm embryos butformed a thick meristematic layer. Bipolar differentiation withinthe meristem produced the shoot, and after a few leaves hadbeen formed, the first root differentiated endogenously fromthe base of the meristem. Subsequent roots, however, appearedto originate more superficially. The chain of events appearsto be quite unique to Vanilla amongst the angiosperms. Vanilla planifolia, protocorm, starch grains, protein bodies     

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; )     

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     

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