Dynamics of storage reserve deposition during Brassica rapa L. pollen and seed development in microgravity

Pollen and seeds share a developmental sequence characterized by intense metabolic activity during reserve deposition before drying to a cryptobiotic form. Neither pollen nor seed development has been well studied in the absence of gravity, despite the importance of these structures in supporting future long-duration manned habitation away from Earth. Using immature seeds (3-15 d postpollination) of Brassica rapa L. cv. Astroplants produced on the STS-87 flight of the space shuttle Columbia, we compared the progress of storage reserve deposition in cotyledon cells during early stages of seed development. Brassica pollen development was studied in flowers produced on plants grown entirely in microgravity on the Mir space station and fixed while on orbit. Cytochemical localization of storage reserves showed differences in starch accumulation between spaceflight and ground control plants in interior layers of the developing seed coat as early as 9 d after pollination. At this age, the embryo is in the cotyledon elongation stage, and there are numerous starch grains in the cotyledon cells in both flight and ground control seeds. In the spaceflight seeds, starch was retained after this stage, while starch grains decreased in size in the ground control seeds. Large and well-developed protein bodies were observed in cotyledon cells of ground control seeds at 15 d postpollination, but their development was delayed in the seeds produced during spaceflight. Like the developing cotyledonary tissues, cells of the anther wall and filaments from the spaceflight plants contained numerous large starch grains, while these were rarely seen in the ground controls. The tapetum remained swollen and persisted to a later developmental stage in the spaceflight plants than in the ground controls, even though most pollen grains appeared normal. These developmental markers indicate that Brassica seeds and pollen produced in microgravity were physiologically younger than those produced in 1 g. We hypothesize that microgravity limits mixing of the gaseous microenvironments inside the closed tissues and that the resulting gas composition surrounding the seeds and pollen retards their development.     

Structural and cytochemical aspects of <Emphasis Type="Italic">Brassica rapa</Emphasis> L. embryogenesis under clinorotation

The results of study of embryo development in B. rapa plants as well as rate and character of nutrient substance accumulation in their cells under slow horizontal clinorotation and the laboratory control were presented. Significant similarity in the peculiarities of embryo differentiation and character of nutrient substance accumulation in both variants was established. The cases of different deviations during embryo differentiation, quantity of reserve nutrient substances, and the rate of their accumulation in the cells were revealed under clinorotation in comparison with the laboratory control.     

Pollination and embryo development in Brassica rapa L. in microgravity

Plant reproduction under spaceflight conditions has been problematic in the past. In order to determine what aspect of reproductive development is affected by microgravity, we studied pollination and embryo development in Brassica rapa L. during 16 d in microgravity on the space shuttle (STS-87). Brassica is self-incompatible and requires mechanical transfer of pollen. Short-duration access to microgravity during parabolic flights on the KC-135A aircraft was used initially to confirm that equal numbers of pollen grains could be collected and transferred in the absence of gravity. Brassica was grown in the Plant Growth Facility flight hardware as follows. Three chambers each contained six plants that were 13 d old at launch. As these plants flowered, thin colored tape was used to indicate the date of hand pollination, resulting in silique populations aged 8-15 d postpollination at the end of the 16-d mission. The remaining three chambers contained dry seeds that germinated on orbit to produce 14-d-old plants just beginning to flower at the time of landing. Pollen produced by these plants had comparable viability (93%) with that produced in the 2-d-delayed ground control. Matched-age siliques yielded embryos of equivalent developmental stage in the spaceflight and ground control treatments. Carbohydrate and protein storage reserves in the embryos, assessed by cytochemical localization, were also comparable. In the spaceflight material, growth and development by embryos rescued from siliques 15 d after pollination lagged behind the ground controls by 12 d; however, in the subsequent generation, no differences between the two treatments were found. The results demonstrate that while no stage of reproductive development in Brassica is absolutely dependent upon gravity, lower embryo quality may result following development in microgravity.     

Influence of microgravity on ultrastructure and storage reserves in seeds of Brassica rapa L.

Successful plant reproduction under spaceflight conditions has been problematic in the past. During a 122 d opportunity on the Mir space station, full life cycles of Brassica rapa L. were completed in microgravity in a series of three experiments in the Svet greenhouse. Ultrastructural and cytochemical analyses of storage reserves in mature dry seeds produced in these experiments were compared with those of seeds produced during a high-fidelity ground control. Additional analyses were performed on developing Brassica embryos, 15 d post pollination, which were produced during a separate experiment on the Shuttle (STS-87). Seeds produced on Mir had less than 20% of the cotyledon cell number found in seeds harvested from the ground control. Cytochemical localization of storage reserves in mature cotyledons showed that starch was retained in the spaceflight material, whereas protein and lipid were the primary storage reserves in ground control seeds. Protein bodies in mature cotyledons produced in space were 44% smaller than those in the ground control seeds. Fifteen days after pollination, cotyledon cells from mature embryos formed in space had large numbers of starch grains, and protein bodies were absent, while in developing ground control seeds at the same stage, protein bodies had already formed and fewer starch grains were evident. These data suggest that both the late stage of seed development and maturation are changed in Brassica by growth in a microgravity environment. While gravity is not absolutely required for any step in the plant life cycle, seed quality in Brassica is compromised by development in microgravity.     

Cytochemical Localization of Reserves during Seed Development in Arabidopsis thaliana under Spaceflight Conditions

Successful development of seeds under spaceflight conditionshas been an elusive goal of numerous long-duration experimentswith plants on orbital spacecraft. Because carbohydrate metabolismundergoes changes when plants are grown in microgravity, developingseed storage reserves might be detrimentally affected duringspaceflight. Seed development in Arabidopsis thaliana plantsthat flowered during 11 d in space on shuttle mission STS-68has been investigated in this study. Plants were grown to therosette stage (13 d) on a nutrient agar medium on the groundand loaded into the Plant Growth Unit flight hardware 18 h priorto lift-off. Plants were retrieved 3 h after landing and siliqueswere immediately removed from plants. Young seeds were fixedand processed for microscopic observation. Seeds in both theground control and flight plants are similar in their morphologyand size. The oldest seeds from these plants contain completelydeveloped embryos and seed coats. These embryos developed radicle,hypocotyl, meristematic apical tissue, and differentiated cotyledons.Protoderm, procambium, and primary ground tissue had differentiated.Reserves such as starch and protein were deposited in the embryosduring tissue differentiation. The aleurone layer contains alarge quantity of storage protein and starch grains. A seedcoat developed from integuments of the ovule with gradual changein cell composition and cell material deposition. Carbohydrateswere deposited in outer integument cells especially in the outsidecell walls. Starch grains decreased in number per cell in theintegument during seed coat development. All these characteristicsduring seed development represent normal features in the groundcontrol plants and show that the spaceflight environment doesnot prevent normal development of seeds in Arabidopsis. Arabidopsis ; spaceflight; embryo; endosperm; seed coat; storage reserves     

Modification of reproductive development in Arabidopsis thaliana under spaceflight conditions

Reproductive development in Arabidopsis thaliana (L.) Heynh. cv. Columbia plants was investigated under spaceflight conditions on shuttle mission STS-51. Plants launched just prior to initiation of the reproductive phase developed flowers and siliques during the 10-d flight. Approximately 500 flowers were produced in total by the 12 plants in both the ground control and spaceflight material, and there was no significant difference in the number of flowers in each size class. The flower buds and siliques of the spaceflight plants were not morphologically different from the ground controls. Pollen viability tests immediately post-flight using fluorescein diacetate indicated that about 35% of the pollen was viable in the spaceflight material. Light-microscopy observations on this material showed that the female gametophytes also had developed normally to maturity. However, siliques from the spaceflight plants contained empty, shrunken ovules, and no evidence of pollen transfer to stigmatic papillae was found by light microscopy immediately post-flight or by scanning electron microscopy on fixed material. Short stamen length and indehiscent anthers were observed in the spaceflight material, and a film-like substance inside the anther that connected to the tapetum appeared to restrict the release of pollen from the anthers. These observations indicate that given appropriate growing conditions, early reproductive development in A. thaliana can occur normally under spaceflight conditions. On STS-51, reproductive development aborted due to obstacles in pollination or fertilization.     

Analysis of influences of spaceflight on chemical constituents in licorice by HPLC–ESI-MS/MS

Focusing on the variations of chemical constituents in licorice root, influences of exposure to physical factors of spaceflight on licorice (Glycyrrhiza uralensis Fisch.) seeds were investigated. Licorice seeds obtained from two different producing areas were flown on a recoverable satellite for 18 days. After returning to earth, the seeds carried by the satellite and the parallel ground control were cultivated to maturity under the same condition. Chromatographic fingerprint of 1 year licorice root analyzed by high performance liquid chromatography with diode-array detection not only displayed the contents of glycyrrhizic acid and liquiritin increasing in the spaceflight samples but showed the variation of the kinds of chemical constituents. The main components in the root extract were identified by high performance liquid chromatography coupled with electrospray ionization multi-tandem mass spectrometry. The changes in the kind of secondary metabolites of licorice root after spaceflight were firstly reported. A total of 26 components which included 9 flavonoids, 16 triterpene saponins and 1 coumarin were identified according to their mass spectra determined in both negative and positive ion modes. The research provided the scientific data for spaceflight breeding of medicinal plant and indicated that the technology of spaceflight may be a new effective method for the breeding and cultivation of licorice.     

AAP1 regulates import of amino acids into developing Arabidopsis embryos

The embryo of Arabidopsis seeds is symplasmically isolated from the surrounding seed coat and endosperm, and uptake of nutrients from the seed apoplast is required for embryo growth and storage reserve accumulation. With the aim of understanding the importance of nitrogen (N) uptake into developing embryos, we analysed two mutants of AAP1 (At1g58360), an amino acid transporter that was localized to Arabidopsis embryos. In mature and desiccated aap1 seeds the total N and carbon content was reduced while the total free amino acid levels were strongly increased. Separately analysed embryos and seed coats/endosperm of mature seeds showed that the elevated amounts in amino acids were caused by an accumulation in the seed coat/endosperm, demonstrating that a decrease in uptake of amino acids by the aap1 embryo affects the N pool in the seed coat/endosperm. Also, the number of protein bodies was increased in the aap1 endosperm, suggesting that the accumulation of free amino acids triggered protein synthesis. Analysis of seed storage compounds revealed that the total fatty acid content was unchanged in aap1 seeds, but storage protein levels were decreased. Expression analysis of genes of seed N transport, metabolism and storage was in agreement with the biochemical data. In addition, seed weight, as well as total silique and seed number, was reduced in the mutants. Together, these results demonstrate that seed protein synthesis and seed weight is dependent on N availability and that AAP1-mediated uptake of amino acids by the embryo is important for storage protein synthesis and seed yield.     

Gravity independence of seed-to-seed cycling in Brassica rapa

 Growth of higher plants in the microgravity environment of orbital platforms has been problematic. Plants typically developed more slowly in space and often failed at the reproductive phase. Short-duration experiments on the Space Shuttle showed that early stages in the reproductive process could occur normally in microgravity, so we sought a long-duration opportunity to test gravity's role throughout the complete life cycle. During a 122-d opportunity on the Mir space station, full life cycles were completed in microgravity with Brassica rapa L. in a series of three experiments in the Svet greenhouse. Plant material was preserved in space by chemical fixation, freezing, and drying, and then compared to material preserved in the same way during a high-fidelity ground control. At sampling times 13 d after planting, plants on Mir were the same size and had the same number of flower buds as ground control plants. Following hand-pollination of the flowers by the astronaut, siliques formed. In microgravity, siliques ripened basipetally and contained smaller seeds with less than 20% of the cotyledon cells found in the seeds harvested from the ground control. Cytochemical localization of storage reserves in the mature embryos showed that starch was retained in the spaceflight material, whereas protein and lipid were the primary storage reserves in the ground control seeds. While these successful seed-to-seed cycles show that gravity is not absolutely required for any step in the plant life cycle, seed quality in Brassica is compromised by development in microgravity. Received: 3 August 1999 / Accepted: 27 August 1999     

Analyses to determine the role of embryo immaturity in dormancy maintenance of yellow cedar (Chamaecyparis nootkatensis) seeds: synthesis and accumulation of storage proteins and proteins implicated in desiccation tolerance

Development of yellow cedar seeds is completed by about 17-21 months after pollination. Following dispersal from the parent plant, the seeds exhibit a low capacity for germination and typically require an additional year to meet their moist chilling requirements and break dormancy. Biochemical analyses were undertaken in order to address whether seed dormancy is imposed and maintained because the embryo or megagametophyte is immature at the time of seed shedding and hence requires time to complete developmental events before dormancy can be terminated. Major protein reserves of the embryo and megagametophyte are the buffer-insoluble crystalloid (legumin) storage proteins and the water-soluble albumin proteins. SDS-PAGE, fluorography of in vivo synthesized proteins and Western blot analyses showed that the greatest increase in protein reserve synthesis and accumulation occurred between the first and second years of development; deposition of soluble and insoluble storage protein was largely completed in seeds of second-year cones by August, 2-3 months prior to seed dispersal. The period associated with greatest accumulation of storage proteins was accompanied by an increased accumulation of two ER-resident proteins associated with post-translational maturation of storage proteins (binding protein and protein disulphide isomerase). Accumulation of proteins implicated in the acquisition of desiccation tolerance (dehydrins and the tonoplast intrinsic protein, -TiP) occurred between the first and second years of development. Several heat-stable proteins and some of the proteins associated with late development continued to be synthesized after seed shedding and in 13 d moist-chilled mature seeds. However, this did not include the major dehydrin-like protein of yellow cedar seeds. Further, the continued synthesis of heat-stable proteins does not appear to be a factor preventing the germination of yellow cedar seeds following dispersal from the parent plant; rather, the mechanism of dormancy is primarily coat-imposed.     

Reserve accumulation in legume seeds

The accumulation of seed reserves is the result of distinct processes occurring in parallel in the main seed compartments of either maternal (seed coats) or zygotic (embryo, endosperm) origin. With the development of legume genomic resources, recent advances have been made toward understanding the metabolic control of seed filling and the regulatory network underlying reserve accumulation. Genetic variability for seed composition has been studied along with the environmental factors influencing reserve accumulation. Nutrient availability and sink strength were both found to be limiting for reserve accumulation. Genes and/or QTL controlling seed protein content and sulfur-amino acid levels have been identified. These new findings will support our attempts to engineer legume seed composition for added end user value.     

Spaceflight reduces somatic embryogenesis in orchardgrass (Poaceae)

Somatic embryos initiate and develop from single mesophyll cells in in vitro cultured leaf segments of orchardgrass ( Dactylis glomerata L.). Segments were plated at time periods ranging from 21 to 0·9 d (21 h) prior to launch on an 11 d spaceflight (STS-64). Using a paired t -test, there was no significant difference in embryogenesis from preplating periods of 14 d and 21 d. However, embryogenesis was reduced by 70% in segments plated 21 h before launch and this treatment was significant at P = 0·0001. The initial cell divisions leading to embryo formation would be taking place during flight in this treatment. A higher ratio of anticlinal:periclinal first cell divisions observed in the flight compared to the control tissue suggests that microgravity affects axis determination and embryo polarity at a very early stage. A similar reduction in zygotic embryogenesis would reduce seed formation and have important implications for long-term space flight or colonization where seeds would be needed either for direct consumption or to grow another generation of plants.     

Comparison between somatic and zygotic embryo development in Quercus robur L.

ABSTRACT

Somatic embryogenesis from juvenile explants as an efficient way for oak clonal propagation is drastically limited by the low rate of embryo germination. A comparison of the development of immature somatic and zygotic embryos, and a study of the changes in sugar content and lignin accumulation during somatic versus zygotic embryo development were conducted in view of understanding the effect of reserve substance deficiency upon somatic embryo maturation. A morphological comparison of somatic and zygotic embryos led to the identification of 4 to 7 similar developmental stages in both types of embryos, thus indicating that the accumulation phase in both zygotic and somatic embryos occurs at the same stage, when the cotyledons became thicker and opaque. Carbohydrate analysis showed the presence of glycerol, inositol, mannitol, galactose, trehalose, xylose, arabinose, glucose, fructose and sucrose in all stages of zygotic and somatic embryo development, but in different amounts. The amount of glycerol, inositol, glucose and sucrose during the early stages is larger in zygotic embryos than in somatic ones, but the time course of their accumulation is similar in both types of embryos. Lignin content, which increased continuously during development, showed a similar behaviour in zygotic and somatic embryos. In somatic embryos which were able to germinate, lignin content was higher than in nongerminating embryos at the same stage.     

Polyembryony in Citrus. Accumulation of seed storage proteins in seeds and in embryos cultured in vitro.

Citrus exhibits polyembryonic seed development, an apomictic process in which many maternally derived embryos arise from the nucellus surrounding the developing zygotic embryo. Citrus seed storage proteins were used as markers to compare embryogenesis in developing seeds and somatic embryogenesis in vitro. The salt-soluble, globulin protein fraction (designated citrin) was purified from Citrus sinensis cv Valencia seeds. Citrins separated into two subunits averaging 22 and 33 kD under denaturing sodium dodecyl sulfate-polyacrylamide gel electrophoresis. A cDNA clone was isolated representing a citrin gene expressed in seeds when the majority of embryos were at the early globular stage of embryo development. The predicted protein sequence was most related to the globulin seed storage proteins of pumpkin and cotton. Accumulation of 33-kD polypeptides was first detected in polyembryonic Valencia seeds when the majority of embryos were at the globular stage of development. Somatic Citrus embryos cultured in vivo were observed to initiate 33-kD polypeptide accumulation later in embryo development but accumulated these peptides at only 10 to 20% of the level observed in polyembryonic seeds. Therefore, factors within the seed environment must influence the higher quantitative levels of citrin accumulation in nucellar embryos developing in vivo, even though nucellar embryos, like somatic embryos, are not derived from fertilization events.     

Seed structure, germination, and reserve mobilization in Butia capitata (Arecaceae)

Butia capitata is a palm tree endemic to the Cerrado biome of Brazil and has significant potential for ornamental and food uses. In this work, we characterized the structures of the seeds and seedlings of this species to identify anatomical aspects related to its pronounced dormancy and determine the processes involved in reserve mobilization. Intact seeds, and seeds from which the operculum had been removed, were allowed to germinate and their morphology, physiology, anatomy, and histochemistry, together with those of the seedlings, were followed for 30 days. The seed coat was found to be rich in phenolic compounds and not lignified. The endosperm contains abundant protein and lipidic reserves, and the embryo has additional starch reserves. Germination occurred only in seeds with their opercula removed and involved the elongation of the cotyledon cells and meristematic activity in the “M zone” located between the embryonic axis and the proximal extremity of the embryo. The mobilization of embryonic reserves initiates during the first phase of imbibition, while the mobilization of endosperm reserves represents a post-germination event associated with the formation of a secretory epidermis and aerenchyma and the vascularization of the haustorium. Seeds with intact opercula did not germinate, but demonstrated embryonic reserve mobilization and cell elongation, indicating that dormancy in B. capitata is related to the incapacity of the embryo to dislocate the operculum.     

Spaceflight induces changes in splenocyte subpopulations: effectiveness of ground-based models

Spaceflight produces changes in the immune system. The mechanisms for the alterations in immune function after spaceflight remain unclear due in part to the difficulties associated with conducting spaceflight research. The purpose of the following studies, therefore, was to create a ground-based protocol that can reproduce the immunological changes found after spaceflight, i.e., changes in splenic lymphocyte populations. Rats were exposed to either flight aboard the Space Shuttle Endeavor (STS-77) or ground-based simulations of various components of the spaceflight experience. The ground-based mock spaceflight was comprised of exposure to launch and landing loads and unloading of the hindlimbs. In addition, each component of this ground-based mock spaceflight was tested separately. The results were that spaceflight reduced splenic CD4(+) T (helper/inducer) cells and CD11b(+) (neutrophils/macrophages) cells. The ground-based simulations of spaceflight did not reproduce the same pattern of splenocyte changes. In fact, exposure to landing loads alone increased splenic CD4(+) T (helper/inducer) cells. These findings support the conclusion that the ground models tested did not induce similar changes in the immune system as did spaceflight. It is possible, therefore, that stressors/factors unique to the spaceflight experience impact the immune system in ways that cannot be currently, fully modeled on the ground.     

Endogenous abscisic acid signaling towards storage reserve filling in developing seed tissues of castor bean (Ricinus communis L.)

Abscisic acid (ABA; free form) is a naturally occurring physiological growth hormone of higher plants. A detailed study involving the time course growth of developing seed tissues associated with endogenous levels of free ABA were investigated using a novel enzyme-linked immunosorbent assay. Seed filling in castor (Ricinuc communis L.) endosperm, embryo, and pod is marked with a rapid increase in fresh weight during the mid-developmental stages [21–42 days after pollination (DAP)], followed by a steady decline at the maturation stages (42–63 DAP) accompanied with a rapid lipid synthesis (in endosperm and embryo) during the same period, except for in pod. Endogenous ABA levels in endosperm (0.001–0.32 μg/g) and embryo (0.003–0.13 μg/g) followed a concurrent pattern with seed reserve filling, showing a rapid increase during the mid-developmental stages 21–42 DAP, whereas ABA levels in seed pod (0.2–22.9 μg/g) showed a different accumulation pattern with rapid increase and decline during the early-mid developmental stages, preceded by the maximal increase during the maturation stage (63 DAP). Together, our results provide evidence for the association of endogenous ABA in seed filling as well as in reserve deposition and provides clue for the effective usage of exogenous ABA concentrations in developing seeds with a focus, on improving seed reserve complex in castor.     

玉米种子发育过程中直链淀粉积累规律的分析

淀粉是玉米种子的主要组成成分,它包括直链淀粉和支链淀粉。支链淀粉的合成需要淀粉合成酶、分支酶和脱支酶的共同作用,而直链淀粉的合成则是在颗粒结合型淀粉合成酶的作用下进行的。颗粒结合型淀粉合成酶基因的突变造成玉米种子的腊质（糯性）表型。与支链淀粉合成的分子机制的研究相比,目前对玉米种子中直链淀粉合成的分子机制了解相对较少。以野生型黄早4玉米自交系和突变体糯玉米为实验材料,研究了种子不同发育时期直链淀粉的积累规律。通过碘染色的方法,观察了玉米种子发育过程中淀粉积累的形态变化。定量分析表明,从授粉后10d至25d,黄早4种子中直链淀粉的含量逐渐增加,同时颗粒结合型淀粉合成酶（GBSS）的活性逐渐提高;而在糯玉米中,直链淀粉和GBSS活性均未检测到。进而,通过RT-PCR方法,从黄早4种子中分离出编码GBSSI的cDNA片段。在授粉后10d至25d的玉米胚乳中均可检测到GBSSI的表达,而在胚中直到授粉后25d才检测到该基因表达的微弱信号。在糯玉米种子中没有检测到该基因的表达。研究结果表明,在玉米种子发育过程中,GBSSI基因的表达通过控制GBSS的合成,最终控制直链淀粉的合成。研究工作为理解玉米种子中直链淀粉合成的分子机制提供了重要信息。