Transport of assimilates in the developing caryopsis of rice (Oryza sativa L.)

The movement of water in the dorsal region of the developing rice caryopsis was studied using solutions of the heavy metals lanthanum and uranium. In the electron microscope electron-opaque deposits were confined to the cell walls of the pigment strand indicating that this is the main route for the water which enters and leaves the caryopsis during grain filling. The pathway of assimilates into the developing caryopsis was examined using isolated caryopses which had taken up solutions of fluorescent dyes and also by autoradiography of caryopses which had transported ¹⁴C-labelled assimilates in vivo. The results show that assimilates unloaded from the phloem move through the pigment strand and circumferentially via cells of the nucellus before entering the endosperm. A scheme is presented for the interrelations of water and assimilate transport during grain filling     

Is The Barley Endosperm a Water Reservoir for the Embryo When Germinating Seeds Are Dried?

The water content of germinating seeds fluctuates in response to water potential changes in the surrounding environment. We tested the hypothesis that the endosperm functions as a water reservoir when imbibed seeds experience drying, and we characterized water uptake and movement within barley (Hordeum vulgare cv. Triumph) caryopses (hereafter referred to as seeds). Water movement into and through germinating barley seeds during imbibition and drying was determined gravimetrically and with the fluorescent dye trisodium 8-hydroxy-1,3,6-pyrenetrisulfonate (PTS). During imbibition, embryo tissues hydrated more rapidly and reached a higher water content (g H20/g dry weight) than did the endosperm, although the endosperm eventually contained nine times as much total water. When barley seeds that had imbibed for 12 h were exposed to moderate (-4 MPa) drying, PTS solution moved from the endosperm into the shoot meristem, radicle, and scutellum, but not vice versa. Radicle emergence and elongation proceeded for up to 8 h. With harsh (-150 MPa) drying, PTS concentrated almost exclusively in the radicle. These data illustrate that the endosperm is at least a temporary water storage compartment external to the embryo itself. We speculate that water supplied by the endosperm may be important in reducing the harmful effects of drying during the critical transition period when a germinating seed changes from a desiccation-tolerant to a desiccation-intolerant organism.     

Effects of partial endosperm removal on embryo dormancy breaking and salt tolerance of <Emphasis Type="Italic">Hordeum spontaneum</Emphasis> seeds

Seed damage is a common phenomenon in nature and in agricultural production. In this experiment, partial endosperm removal from wild barley (Hordeum spontaneum) caryopses, sampled from three ecotypes originated from xeric environments in Israel, was conducted. The aim was to examine seed dormancy and germination states in damaged caryopses and salt tolerance of young seedlings derived from them. Six treatments were made: (1) control seeds with intact caryopses; (2–4) removal of 0.25, 0.5, and 0.75 of the length of intact caryopses; (5) transection at the points, at which the endosperm and embryo meet; and (6) slitting of endosperm opposite the embryo. A significant negative correlation was found between germination percentage (dormancy release) and the relative distance from the dissection point to embryo. Partial removal of the endosperm could accelerate dormancy release. Seedling salt tolerance was assessed by the ratio of root or coleoptile length in a seedling grown in 100 or 200 mM NaCl solution to that of a seedling grown in water. The seedling salt tolerance was positively correlated with the removed portion of the seed endosperm. For each level of endosperm removal, the salt tolerance to 200 mM NaCl of the seedlings derived from the Dead Sea ecotype was higher than those from both the Sede Boker and the Mehola ecotypes. The results suggest that partial damage to seed endosperms in natural conditions may play a role in increasing the phenotypic plasticity of germination and salt tolerance.     

Endosperm cell number in cultivars of barley differing in grain weight

The number of endosperm cells in caryopses 30 ‘days’ after anthesis was determined and a positive correlation was found between endosperm cell number and 1000 grain weight, and between endosperm cell number and dry grain volume in a number of cultivars of field-grown barley. The genetic factors influencing grain weight are discussed in relation to these results and to observations made on transverse sections of immature caryopses.     

Nonstructural carbohydrates in dormant and afterripened wild oat caryopses

Nonstructural carbohydrates were determined in both embryo and endosperm of dormant (nongerminating) and afterripened (germinating) intact caryopses of wild oat ( Avena fatua L.). No changes in endosperm starch or soluble sugar were observed at the onset of germination (18 h). No changes in glucose, fructose, sucrose or starch within dormant or afterripened embryos correlated with onset of visual germination. In afterripened embryos, depletion of raffinose (18 h), stachyose (18 h) and galactose (24 h) was correlated with germination. In contrast, raffinose-family oligosaccharide levels in dormant embryos remained constant for 7 days following imbibition. Germination of isolated dormant embryos on 88 m M galactose-containing media was accompanied by decreased endogenous levels of raffinose and stachyose. Isolated embryos from dormant caryopses incorporated ¹⁴C from ¹⁴C-fructose into both raffinose and stachyose during 24 h of imbibition. In contrast, no ¹⁴C incorporation into stachyose was observed in embryos from afterripened caryopses. No ¹⁴C incorporation into raffinose was observed at 18 and 24 h. When in vitro activities of α galactosidase were measured, no temporal differences between dormant or afterripened caryopses were detected in either embryo or endosperm tissue. Although the mechanism associated with differences in utilization of raffinose and stachyose is yet unidentified, alterations in raffinose-family oligosaccharide metabolism in the embryo appear to be a unique prerequisite for afterripening-induced germination.     

Regularly aligned mitochondria in aleurone and sub-aleurone layers of developing rice caryopses

Abstract. Mitochondria were found to be aligned along the upper periclinal walls of aleurone and endosperm cells in developing rice caryopses. The significance of this distribution is discussed in relation to previous studies of solute transport in rice.     

黄顶菊的大孢子发生、雌配子体与胚胎发育

用常规石蜡制片对黄顶菊(Flaveria bidentis(L.) Kuntze)大孢子发生、雌配子体和胚胎的发育过程进行了观察.黄顶菊雌蕊柱头二裂,2心皮,1室,单胚珠,基生胎座,单珠被,薄珠心,倒生胚珠,具发达的珠被绒毡层.珠心表皮下分化出孢原细胞,孢原细胞直接发育为大孢子母细胞,大孢子母细胞减数分裂形成直列四分体...     

Water uptake and splitting of wild oat caryopsis

Imbibition and germination experiments were conducted on the caryopses of wild oats (Avena fatua L.). The embryo envelopes, pericarp and aleurone layer, which completely cover the embryo-endosperm, do not form barriers against water uptake. The initial uptake of water is passive and the water moves across the pericarp with ease as it contains cracks; it is, however, transported across the aleurone layer through its cell walls into the endosperm and embryo of the caryopsis. The starchy endosperm enlarges due to water uptake causing the pericarp to rupture, thus exposing the aleuronelayer-covered seed. The aleurone layer is structurally heterogenous consistings of radially compressed irregular cells and cuboidal or radiallys tretched cells; the latter contains thicker walls. The former type is present along the abaxial side of the embryo and in the crease on the adaxial side of the caryopsis; the latter type covers the endosperm. The physical distention of the endosperm due to water uptake causes the rupture of the pericarp and the aleurone layer, and facilitates the emergence of the radicle and coleorhiza of the embryo during caryopsis germination.     

Factors influencing seed dormancy and germination in sand,and seedling survival under desiccation,of Psammochloa villosa (Poaceae), inhabiting the moving sand dunes of Ordos,China

Psammochloa villosa (Trin.) Bor. (Poaceae), is distributed primarily in moving sand dunes of the Ordos Plateau, China. Freshly harvested caryopses (seeds) are in non-deep physiological dormancy (non-deep PD). Germination is slow and low and only over a narrow temperature range. A treatment of four weeks cold stratification at 3 to 5 °C in darkness was required to break non-deep PD, allowing germination to reach high percentages at higher temperatures and without light requirement. Rate and percentages of germination were increased by scarifying the caryopsis coat and by artificial removal of different proportions of the endosperm. However, seedling dry weight and increases in root and shoot lengths, were significantly influenced by the proportion of the endosperm that remained on the caryopses. Higher percentages of seedling emergence were obtained from the shallowly buried caryopses, ranging from 0.5–2.0 cm, and the depth of the caryopses in the sand affected the time of germination. The deeper the caryopses were buried, the more that remained ungerminated and in enforced dormancy. The caryopses germinated when the upper sand layer was removed and buried caryopses were at a suitable sand depth for germination, or when the sand was aerated. In natural habitats, germinated seedlings may be wholly exposed to the air by sand erosion and thus be exposed to drought stress. However, young seedlings have the ability to tolerate desiccation and to recover after rehydration. Root length at the `point of no return' is 4 mm.     

小蓬草的胚胎学研究

对小蓬草(Conyza canadensis)大小孢子发生、雌雄配子体形成、受精、胚及胚乳发育过程进行了研究,主要结果如下:花药四室,药壁由表皮、药室内壁、中层和绒毡层组成.表皮退化;药室内壁宿存,细胞柱状伸长,纤维状加厚;中层细胞退化较早,在小孢子母细胞减数分裂开始时仅存残迹;绒毡层于小孢子母细胞减数第一次分裂前期开始原位变形退化,属于腺质型绒毡层;小孢子母细胞减数分裂为同时型,四分体的排列方式主要为四面体形和左右对称形;成熟花粉粒多为3细-胞花粉粒,偶见2细-胞花粉粒.子房下位,2心皮,1室,单胚珠,基生胎座;单珠被,薄珠心,倒生胚珠,具发达的珠被绒毡层.珠心表皮下分化出大孢子孢原细胞,孢原细胞直接发育为大孢子母细胞,大孢子母细胞减数分裂形成4个大孢子直线形排列,仅合点端的大孢子发育成功能大孢子母细胞,胚囊发育为蓼型.两个极核在受精前融合为次生核,珠孔受精.胚乳发育属于核型,胚胎发育为紫菀型;具胚乳吸器.     

Studies on the early development of zygotic and synergid embryo and endosperm in polyembryonic rice ApIII

A morphological, cytological and embryological investigation was conducted on the early development of embryo and endosperm in polyembryonic rice (Oryza sativa L.) ApIII. We found that the percentage of single-, twin- and triple-seedlings from mature caryopses was 82.4–85.6%, 11.3–14.6% and 2.0–3.8%, respectively. From twin-seedlings one of the plants and in the triple-seedlings usually two seedlings were very weak having a mortality of about 50–60% and over 95%, respectively, and most of the dead seedlings were haploid. In addition, among 674 young caryopses the percentage of single-, double- and triple-embryo sacs was 77.60%, 18.10% and 4.30%, respectively. The development of both embryo and endosperm was observed in the embryo sacs of 653 young caryopses, while embryo development occurred in absence of endosperm in the embryo sacs of 21 ones. Furthermore, after pollen tube penetration, frequently one, rarely two, additional embryos arise via apogamy from the typical specialized synergid of normal egg apparatus with a collapsed cap-neck region that had a damaged filiform apparatus at the micropylar end. Finally, the formation of a strikingly degenerated endosperm cell region is a specialized functional structure that serves for the active transport of metabolites from endosperm to the developing embryo. Taken together, these results suggest that synergid apogamy seems to be the unique reason of polyembryony, poor growth and high mortality of many seedlings may be due to haploidy, and high genetic stability of polyembryony occurs in rice ApIII.     

Effect of gibberellin on protein and non-structural carbohydrate in dormant Avena fatua caryopses

Application of gibberellic acid (GA₃) to dormant Avena fatua L. caryopses resulted in the termination of dormancy within 24 h as indicated by germination between 24 and 48 h. During the period of imbibition from 0 to 24 and 24 to 48 h changes occurred in protein and carbohydrate metabolism in GA-treated and untreated caryopses. Germination did not occur in untreated caryopses, therefore physiological changes in these caryopses were not associated with the termination of dormancy. GA-treatment increased the concentration of soluble and SDS-extractable protein in the endosperm tissue by 4 and 5%, respectively, over the 24 h untreated material; no changes were apparent when the protein profiles of GA-treated and untreated tissues were compared by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) 0, 24 and 48 h after imbibition. The concentration of hexose and sucrose in the GA-treated endosperm tissue increased 189 and 151 μmol, respectively, over the untreated material at 24 h. Gibberellic acid had no effect on starch metabolism in the endosperm tissue in the first 24 h, the period associated with the termination of dormancy. The concentration of hexose increased by 57 μmol and starch decreased by 80 μmol in the GA-treated embryo tissue within 24 h. Our results demonstrate that exogenously applied GA influences sucrose and hexose metabolism in the endosperm tissue. The specific effect of GA on starch and hexose metabolism in the dormant A. fatua caryopsis embryo tissue may be associated with the termination of dormancy.     

Liberation of Nuclei and Achromatic Figures from Maize Endosperm

To study nuclear structure and comparative size in cells of sugary maize endosperm, a method was devised for simultaneously liberating and staining their nuclei. It consists of excising from caryopses the endosperm which is then placed in aceto-carmine solution and broken into fragments with a blunt rod. After removing coarse fragments, the suspension is brought to boiling and subsequently centrifuged to separate nuclei and mitotic figures from other cell remains. Once satisfactorily stained the material is washed, dehydrated and mounted in diaphane. The nuclei and mitotic figures so derived are favorable objects for study, being free of obscuring cytoplasm.     

Sucrose transport into barley seeds: molecular characterization of two transporters and implications for seed development and starch accumulation

In order to understand sucrose transport in developing seeds of cereals at the molecular level, we cloned from a caryopses library two cDNAs encoding sucrose transporters, designated HvSUT1 and HvSUT2. Sucrose uptake activity was confirmed by heterologous expression in yeast. Both transporter genes are expressed in maternal as well as filial tissues. In a series of in situ hybridizations we analysed the cell type-specific expression in developing seeds. HvSUT1 is preferentially expressed in caryopses in the cells of the nucellar projection and the endospermal transfer layer, which represent the sites of sucrose exchange between the maternal and the filial generation and are characterized by transfer cell formation. HvSUT2 is expressed in all sink and source tissues analysed and may have a general housekeeping role. The rapid induction of HvSUT1 gene expression in caryopses at approximately 5-6 days after fertilization coincides with increasing levels of sucrose as well as sucrose synthase mRNA and activity, and occurs immediately before the onset of rapid starch accumulation within the endosperm. Starch biosynthesis requires sucrose to be imported into the endosperm, as direct precursor for starch synthesis and to promote storage-associated processes. We discuss the possible role of HvSUT1 as a control element for the endospermal sucrose concentration.     

The cellular pathway of photosynthate transfer in the developing wheat grain. I. Delineation of a potential transfer pathway using fluorescent dyes

A potential cellular pathway for photosynthate transfer between the crease phloem and the starchy endosperm of the developing wheat grain has been delineated using fluorescent dyes. Membrane permeable and impermeable dyes have been introduced into the grain through the crease phloem, the endosperm cavity or the dorsal surface of the starchy endosperm. The movement of the symplastic tracer 5-(6)-6-carboxyfluorescein (CF) derived from 5-(6)-6-carboxyfluorescein diacetate (CFDA), from either direction between the crease phloem and the endosperm cavity, indicated that the symplastic pathway was operative from the crease phloem to the nucellar projection. Furthermore, the inward movement of apoplastic tracer trisodium, 3-hydroxy-5,8,10-pyrentrisulphonate (PTS) from the endosperm cavity and that of CF following plasmolysis showed that there was a high resistance to solute transfer within the apoplast of the pigment strand. All dyes entered the modified aleurone and adjacent sub-aleurone bordering the endosperm cavity. Subsequent movement of the symplastic tracers CF and sulphorhodamine G (SRG) into and through the endosperm was rapid. However, the movement of apoplastic tracers PTS and Calcofluor White (CFW) was relatively slow and with tissue plasmolysis, CF was confined to the cytoplasm of the modified aleurone and subaleurone cells. Together, these results demonstrate that there is a high resistance to solute movement within the apoplast of the cells bordering the endosperm cavity. We propose that photosynthate transfer is via the symplast to the nucellar projection where membrane exchange to the endosperm cavity occurs. Uptake from the cavity is by the modified aleurone and small endosperm cells prior to transfer through the symplast to and through the starchy endosperm.