An Ultrastructural Investigation of Protein and Lipid Reserves in the Endosperm of Pinus pinea L.

Proteins and lipids are the two main storage substances in theendosperm of Pinus pinea L. In imbibed seeds, lipid and proteinbodies almost completely fill the cell volume and only a fewpoorly structured organelles can be detected. During germinationthe storage substances are reabsorbed whilst plastids, roughendoplasmic reticulum, ribosomes and polysomes, microbodies(glyoxysomes, most likely) become evident. Starch is also formed.When the cotyledons emerge completely from the endosperm envelopethe latter shows highly vacuolate cells but still rich in cytoplasmicorganelles, lipids, protein bodies and starch grains. Different patterns of protein body degradation are discussed. Pinus pinea, endosperm, ultrastructure, protein, lipid, stored reserves     

Expression of a boiling-stable protein (BsCyp) in response to heat shock, drought and ABA treatments in Sorghum bicolor

The effect of heat stress, drought and abscisic acid (ABA) on the induction of boiling-stable proteins were studied in 12 h germinated sorghum embryos and endosperm. SDS-PAGE revealed the heat shock induction of one major 97 kDa boiling-stable protein both in embryos and endosperm. Western blotting analysis, using polyclonal antibodies raised against a 20 kDa Arabidopsis thaliana cyclophilin, revealed the induction of a cross-reacting band (97 kDa, BsCyp) in both embryos and endosperm in a time dependent manner. The BsCyp boiling-stable polypeptide was also regulated by exogenous application of ABA, indicating its role in water stress adaptation. Drought stress also resulted in a significant induction of boiling-stable protein (BsCyp) in both embryos and endosperm. Based upon these observations the possible role of BsCyp in water stress tolerance is discussed.     

Protein Body Inclusions in Developing Wheat Endosperm

Endosperm tissue of two wheat cultivars, Maris Freeman and Mardlerwas examined by light and electron microscopy from early stagesof development until maturity. Spherical electron-dense inclusionswere first seen embedded in the periphery of endosperm proteinbodies of both cultivars 11 days after anthesis. The inclusions,which gave a positive histochemical reaction for both proteinand lipid, persisted throughout endosperm development and werepresent in the protein matrix of mature grain. Two types ofmembranous inclusions were found. In Maris Freeman and Mardler,vesicles and myelin whorls were associated with the surfaceof the protein mass during development and maturation. In MarisFreeman, membrane lattices of branched tubules with a basiccubic repeat unit of 44.8 nm were found in close contact withthe protein mass, but these were not present in mature grain. Triticum aestivum L., wheat, endosperm, protein body inclusions, ultrastructure     

Genetic Variation in Sorghum for the Inhibition of Maize Pollen Tube Growth

Aniline blue fluorescence was used to study the growth of maizepollen tubes in the stigmas of 13 diverse sorghum accessions.In 12, only short maize pollen tubes were formed, but in thesingle exception (Sorghum nervosum Nr481) maize pollen tubesgrew at least as far as the base of the style. The S. bicolorgenotypes S9B and CMS (a cytoplasmic male sterile line) werehybridized with Nr481, and analysis of maize pollen tube growthin F₁ plants, and BC₁ plants using Nr481 as the recurrent parent,suggested that differences in inhibition of pollen tube growthwere due to variation at a single locus, which we propose todesignate lap (Inhibition of alien pollen tubes). AccessionNr481 appears to be homozygous for a recessive allele permittingmaize pollen tube growth. Attempts were made to produce sorghumx maize hybrids using Nr481 and CMS derivatives which were knownto allow maize pollen tube growth to the base of the style.A putative hybrid endosperm was obtained in one Nr481 x Seneca60 maize cross, but this was not repeatable and no hybrid plantswere produced. A fundamental problem may be the large size ofthe maize pollen tube, which could have difficulty growing throughthe sorghum ovary and in entering the micropyle. Sorghum bicolor spp. bicolor (L.) Moench, Zea mays L, sorghum, maize, pollen tube growth, hybridization barriers     

Protein Body Degradation in the Starchy Endosperm of Germinating Sorghum

Taylor, J. R. N., Novellie, L. and Liebenberg, N. v. d. W. 1985.Protein body degradation in the starchy endosperm of germinatingsorghum.—J. exp. Bot. 36: 1287–1295. Transmission electron micrographs of starchy endosperms of germinatingsorghum indicate that the protein bodies are degraded predominantlyby progressive hydrolysis of prolamin from their surface. Theappearance of holes within partially degraded protein bodiesindicates that some internal hydrolysis also takes place. Chemicalanalyses of protein bodies isolated at different stages duringgermination showed that their amino acid composition and electrophoreticpattern remained relatively unchanged during hydrolysis. Theend result of protein body degradation was that the organellescompletely disappeared leaving empty starchy endosperm cells.The protein bodies did not swell prior to or during degradation.This mode of protein body degradation differs from that in germinatingdicotyledonous seeds and in the aleurone layer and embryo ofcereal seeds but was identical to the mode of prolamin proteinbody degradation in the starchy endosperm of germinating riceseeds. Key words: Sorghum bicolor, protein body degradation, prolamin     

Viability and Germination of the Pollen of Sorghum [Sorghum bicolor (L.) Moench]

Previous studies have demonstrated that pollen of sorghum [Sorghumbicolor (L.) Moench] loses capacity to both germinate in vitroand to set seed in vivo soon after being shed. The current studyevaluates the capacity for dehydrated pollen to effect in vitrogermination, reduce tetrazolium chloride, and set seed on cytoplasmicmale sterile plants. Morphological changes during pollen germinationwere examined by scanning electron microscopy (SEM). Close to70% of the pollen germinated in 5 min, or less, when collectedat 80% relative humidity (RH) and stored in sealed glass vials.Pollen tubes elongated autotropically with atmospheric humidityapparently being a controlling factor in the process. Pollendehydrated at 50% RH and 25°C for 15-30 min neither germinatedin vitro, reduced tetrazolium chloride, nor set seed on malesterile plants. Rehydrating the pollen did not restore the capacityfor germination. SEM micrographs demonstrated that elongatingpollen tubes encircled the pollen grain and were contiguousto the surface. A fibrillar-like material existed on the exineof separated pollen grains at the point where the grains hadbeen previously attached.Copyright 1994, 1999 Academic Press Sorghum pollen, germination, seed-set, viability, scanning electron microscopy, Sorghum bicolor (L.) Moench     

Amaranthus hypochondriacus: Seed Structure and Localization of Seed Reserves

The mature seed of Amaranthus hypochondriacus L. consists ofa peripheric embryo surrounding the nutritive tissue which isthe perisperm. Endosperm remnants are close to the root tip.Cytochemical analysis revealed that the embryo and endospermcells had a quite homogenous internal organization, with proteinbodies embedded in a lipid matrix. The embryo, however, appearsvariable in tissue organisation, due to the differentiationof the three primary meristematic tissues: the procambium appearsas a single bundle in the embryonic axis or as small bundlesthroughout the cotyledons length, these provascular cells aresmall and elongated and with fewer reserves and more cellularorganelles than the large protoderm and ground meristem cells.These latter cells have more protein bodies, and they show ahigher number of larger globoid crystal inclusions than theothers. The perisperm is a starchy tissue, and its cells havethin walls and are full of angular starch grains.Copyright 1994,1999 Academic Press Amaranth, Amaranthus hypochondriacus, seed structure, seed reserves     

Partially Fertile Line with Apospory Obtained from Tissue Culture of Male Sterile Plant of Sorghum (Sorghum bicolor L. Moench)

A partial restoration of male fertility has been revealed inthree among 20 regenerants from callus cultures obtained fromthe panicle fragments of the sorghum plant with cytoplasmicmale sterility. Induced fertility is retained under self-pollinationfor eight generations. The pollen fertility level in every generationvaries in different plants (0-70%) and depends on the environmentalfactors, rather than on plant genotype. A high positive correlation(r = 0·90; P < 0·01) has been revealed betweenthe pollen fertility level and the total rain precipitationduring the microgametophytogenesis. Cytoembryological investigationof this line has shown the presence of structures similar toaposporous embryo sacs (ESs), which have developed in the ovulesalong with the sexual ESs. The ovules with aposporous formationshave been observed almost in all of the studied plants in severalgenerations, however, their frequency varied (2-53%). Parthenogeneticproembryos and endosperm nuclei without signs of pollen tubepenetration have been found in some of such ESs. The natureof the instability observed in a number of generations in maleand female generative structures is discussed.Copyright 1995,1999 Academic Press Cytoplasmic male sterility, fertile revertants, apomixis, somaclonal variability, Sorghum bicolor L. (Moench)     

Isolation and characterization of oat aleurone and starchy endosperm protein bodies

To compare oat (Avena sativa L. cv Froker) aleurone protein bodies with those of the starchy endosperm, methods were developed to isolate these tissues from mature seeds. Aleurone protoplasts were prepared by enzymic digestion and filtration of groat (caryopsis) slices, and starchy endosperm tissue was separated from the aleurone layer by squeezing slices of imbibed groats followed by filtration. Protein bodies were isolated from each tissue by sucrose density gradient centrifugation. Ultrastructure of the isolated protein bodies was not identical to that of the intact organelles, suggesting modification during isolation or fixation. Both aleurone and starchy endosperm protein bodies contained globulin and prolamin storage protein, but minor differences in the protein-banding pattern by sodium dodecyl sulfate-polyacrylamide gel electrophoresis were evident. The amino acid compositions of the protein body fractions were similar and resembled that of oat globulin. The aleurone protein bodies contained phytic acid and protease activity, which were absent in starchy endosperm protein bodies.     

Rates of Cell Division in Developing Barley Endosperms

Counts of nuclei in enzyme digested endosperms of barley cultivarBomi show that the final number of cells, 170000, is reachedbetween 18 and 21d after anthesis. Based on the number of cellprofiles in transverse mid-grain sections, starchy endospermcells divide up to day 14. Thereafter, cell proliferation isrestricted to the aleurone layer. Hordeum vulgare, starchy endosperm, aleurone, mitotic activity, light microscopy     

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     

Secondary Sporangium Formation in Phytophthora Palmivora (Butl.) Butl

Very few sporangia of Phytophthora palmivora germinated directlyand produced secondary sporangia in distilled water and in solutionsof amino acids and carbohydrates at 30 °C. Although 1.0per cent (w / v) peptone and yeast-extract stimulated a highpercentage of germination by formation of germ tubes, less than1.0 per cent of the germinated sporangia produced secondarysporangia. Secondary sporangium formation was induced by transferringgerminated primary sporangia from a nutrient medium of sufficientlyhigh concentration to either distilled water or dilute solutionsof organic and inorganic compounds immediately after emergenceof the germ tubes. The percentage of germinated sporangia formingsecondary sporangia was influenced by both the nature and concentrationof the medium into which they were transferred. The secondarysporangia were significantly smaller than the primary sporangia. Phytophthora palmivora, germination, sporangium, Theobroma cacao L., cocoa     

Early Stages in Wheat Endosperm Formation and Protein Body Initiation

The early stages of endosperm formation and protein body initiationare described for hard red winter wheat using light and transmissionelectron microscopy. Two days after flowering (DAF) the endospermwas a thin layer of coenocytic cytoplasm lining the embryo sac.By 4 DAF the endosperm had cellularized and completely filledthe embryo sac. Enough differentiation had occurred by 6 DAFto distinguish cells destined to become the aleurone layer,sub-aleurone region and central endosperm. Protein bodies wereinitiated at about 6–7 DAF and were first found near theGolgi apparatus. Wheat was ready for combine harvest at 34 DAF.Enlargement of the small protein bodies near the Golgi apparatusoccurred by several mechanisms: (1) fusion with one or moreof the dense Golgi vesicles or fusion with other protein bodies,(2) fusion with small electron-lucent Golgi-derived vesicles,(3) pinocytosis of a portion of the adjacent cytoplasm intothe developing protein body and (4) fusion of large proteinbodies with one another at later stages of grain development.Of the four mechanisms described, the pinocytotic vesicles andfusion of protein bodies were the most frequent and consistentprocesses observed. Direct connections between rough endoplasmicreticulum (RER) and protein bodies were not observed. The resultssuggest a rôle for the Golgi apparatus in the initiationof protein bodies. Also, the lack of RER derived vesicles suggestsa soluble mode of secretion of storage proteins involved inthe enlargement of protein bodies. Triticum aestivum, wheat endosperm, protein bodies Golgi apparatus     

The cellular pathway of photosynthate transfer in the developing wheat grain. III. A structural analysis and physiological studies of the pathway from the endosperm cavity to the starchy endosperm

The cellular pathway of sucrose transfer from the endosperm cavity to the starchy endosperm of developing grains of wheat (Triticum turgidum) has been elucidated. The modified aleurone and sub-aleurone cells exhibit a dense cytoplasm enriched in mitochondria and endoplasmic relicilium. Significantly, the sub-aleurone cells are characterized by secondary wall ingrowths. Numerous plasmodesmata interconnect all cells between the modified aleurone and starchy endosperm. The pro-tonophore carbonylcyanide-m-chlorophenyl hydrazone (CCCP) slowed [¹⁴C]sucrose uptake by grain tissue slices enriched in modified aleurone and sub-aleurone cells but had no effect on uptake by the starchy endosperm. The fluorescent weak acid sulphorhodamine G (SRG) was preferentially accumulated by the modified aleurone and sub-aleurone cells, and this uptake was sensitive to CCCP. The combined plasma membrane surface areas of the modified aleurone and sub-aleurone cells appeared to be sufficient to support the in vivo rates of sucrose transfer to the starchy endosperm. Plasmolysis of intact excised grain inhibited [¹⁴C]sucrose transfer from the endosperm cavity to the starchy endosperm. The sulphydryl group modifier p-chloromercuribenzenesulphonie acid (PCMBS) decreased [¹⁴C]sucrose uptake by the modified aleurone and sub-aleurone cells but had little effect on uptake by the starchy endosperm. In contrast, when PCMBS and [¹⁴C]sucrose were supplied to the endosperm cavity of intact excised grain, PCMBS slowed accumulation by all tissues equally. Estimates of potential sucrose fluxes through the interconnecting plasmodesmata were found to be within the published range. It is concluded that the bulk of sucrose is accumulated from the endosperm cavity by the modified aleurone and sub-aleurone cells and subsequently transferred through the symplast to the starchy endosperm.     

Turgor Differences and Water Stress in Maize and Sorghum Leaves During Drought and Recovery

The pressure potentials (turgor pressure) in leaves of maize(Zea mays L.) and grain sorghum (Sorghum vulgare Pers.) plantssubjected to water stress in a controlled environment were estimatedfrom measurements of water and osmotic potentials. Changes inturgor pressure were larger in sorghum than in maize duringthe development of water stress and after re-watering. It issuggested that this indicates a lower cell wall elasticity insorghum than in maize. This fact may affect some of the physiologicalactivities of sorghum     

Linear Relations between Carbon Dioxide Concentration and Rate of Development Towards Flowering in Sorghum, Cowpea and Soyabean

Negative linear relations were detected (P < 0·005)between the rate of progress from sowing to panicle initiationand CO₂ concentration (210-720 µmol CO₂ mol^-1 air) fortwo genotypes of sorghum [Sorghum bicolor (L.) Moench]. Relationsbetween CO₂ concentration and the rate of progress from sowingto first flowering were also negative in soyabean [Glycine max(L.) Merrill] (P < 0·025), but positive in cowpea[Vigna unguiculata (L.) Walp.] (P < 0·025), albeitthat in both grain legumes sensitivity was much less than insorghum. Thus CO₂ elevation does not delay flowering in allshort-day species. The considerable effect of CO₂ concentrationon times to panicle initiation resulted in large differencesamong the sorghum plants at this developmental stage; with increasein CO₂ concentration, plants were taller with slightly moreleaves and more pronounced apical extension. At the same timeafter sowing however, sorghum plants were heavier (P < 0·05)at 210 than at 360 µmol CO₂ mol^-1 air. In contrast, relationsbetween the dry masses of the soyabean and cowpea plants andCO₂ concentration were positive and curvilinear (P < 0·05).It is suggested that the impact of global environmental changecould be severe for sorghum production in the semi-arid tropics.Copyright1995, 1999 Academic Press Sorghum bicolor (L.) Moench., sorghum, Glycine max (L.) Merrill, soyabean, Vigna unguiculata (L.) Walp., cowpea, development, flowering, CO₂, dry matter accumulation, environmental change     

The dynamics of protein body formation in developing wheat grain

Wheat is a major source of protein in the diets of humans and livestock but we know little about the mechanisms that determine the patterns of protein synthesis in the developing endosperm. We have used a combination of enrichment with ¹⁵N glutamine and NanoSIMS imaging to establish that the substrate required for protein synthesis is transported radially from its point of entrance in the endosperm cavity across the starchy endosperm tissues, before becoming concentrated in the cells immediately below the aleurone layer. This transport occurs continuously during grain development but may be slower in the later stages. Although older starchy endosperm cells tend to contain larger protein deposits formed by the fusion of small protein bodies, small highly enriched protein bodies may also be present in the same cells. This shows a continuous process of protein body initiation, in both older and younger starchy endosperm cells and in all regions of the tissue. Immunolabeling with specific antibodies shows that the patterns of enrichment are not related to the contents of gluten proteins in the protein bodies. In addition to providing new information on the dynamics of protein deposition, the study demonstrates the wider utility of NanoSIMS and isotope labelling for studying complex developmental processes in plant tissues.