Physiological Studies with Heavy Water. II. Germination and Growth Inhibition of Barley by D2O

Seed germination and barley seedling growth in various D₂O concentrations have been studied. It was observed that the emergence of root and shoot was delayed, there being greater delay in shoot than in root emergence. A complete block was observed in germination in pure D₂O and the germination rate was slowed down significantly in lower concentrations. An initial germination delay by different D₂O concentrations seemed to cause a subsequent retardation in the growth measured as shoot and root length. A comparison of root and shoot length with their respective dry weights suggested that the growth by cell division/elongation might have been affected more than the transport of food materials from the endosperm to the embryo. Analysis of the total sugars of the endosperm and the embryo at 8 hour intervals showed that while the hydrolysis of starch to sugars was progressively decreased by increasing D₂O concentrations, the transport rate from endosperm to embryo showed a sharp inhibition in 50% D₂O and above. This indicated that the inhibition in the transport of materials, besides less hydrolysis of reserve food materials, may also be a causal factor of germination and growth inhibition in D₂O.     

Dormancy in Seeds of Charlock: I. DEVELOPMENTAL ANATOMY OF THE SEED

The anatomy of the embryo, endosperm, and testa throughout thedevelopment of charlock seeds is described. In mature seedsthe embryos are morphologically fully differentiated. Each embryoconsists of a shoot meristem with two large cotyledons but noleaf primordia, and a root meristem with a root cap. The embryois surrounded by a single layer of aleurone-like cells derivedfrom the endosperm and enclosed within the testa. Mucilagesand phenols which could greatly retard the diffusion of oxygeninto the tissues of the embryo are found in the testa. Dormancy,which appears to be induced by a shortage of oxygen, is probablyassociated with the presence of these covering layers.     

Developmental mutants showing abnormal organ differentiation in rice embryos

Summary Zygotes of rice (Oryza sativa L. cv Taichung 65) were treated with 1.0 mM solution of the chemical mutagen N-methyl-N-nitrosourea. Out of 1420 M₂ lines, 28 single-locus recessive mutants on embryogenesis were identified. Among them, we analyzed 11 mutants in the present study, which differentiated the shoot (plumule) and/or root (radicle) with abnormality. Of the 11 mutants, two showed no shoot differentiation with normal root. On the other hand, we could not detect any mutant which exhibited a normal shoot without a root. This suggests that shoot and root are genetically controlled by different loci and that the alleles associated with shoot formation mutate more frequently than do those of the root. Five mutants showed aberrant morphology of shoot when both the shoot and root developed. One of them, odm 5 (organ differententiation mutant 5) was germinable, but produced many fine and twisted leaves. This mutant was, however, lethal at the early post-germination stage under the usual cultural conditions. In another mutant (odm 4), shoot differentiation seemed to be initiated at an arbitrary position, resulting in a very abnormal morphology of the shoot when the position fronted the endosperm. The other two mutants showed abnormal morphology of both the shoot and root. One (odm 11) of the remaining two mutants showed a wide variation of abnormalities including no organ differentiation, either shoot or root differentiation and the development of both shoot and root with abnormalities. The last one (odm 16) was unique. It had an embryo with normal shoot and root but the embryo size was only one-third to one-half of normal embryos in length. Of course, the shoot and root are also small but viable. Therefore, odm 16 is considered to be a mutant in the size regulation of the embryo. Although an allelism test has not yet been done, most of these mutants are probably non-allelic, as the phenotypic abnormality differs largely with each one. In rice, the shoot and root highly differentiate in contrast to dicotyledonous embryo. Accordingly, these developmental mutants are very useful materials for investigating the regulatory mechanism of gene expression in organ differentiation.     

WOX gene phylogeny in Poaceae: a comparative approach addressing leaf and embryo development

The phylogeny based on the homeodomain (HD) amino acid sequence of the WOX (WUSCHEL-related homeobox gene family) was established in the 3 major radiations of the Poaceae family: Pooideae (Brachypodium distachyon), Bambusoideae (Oryza sativa), and Panicoideae (Zea mays). The genomes of all 3 grasses contain an ancient duplication in the WOX3 branch, and the cellular expression patterns in maize and rice indicate subfunctionalization of paralogues during leaf development, which may relate to the architecture of the grass leaf and the encircling of the stem. The use of maize WOX gene family members as molecular markers in maize embryo development for the first time allowed us to visualize cellular decisions in the maize proembryo, including specification of the shoot/root axis at an oblique angle to the apical-basal polarity of the zygote. All molecular marker data are compatible with the conclusion that the embryonic shoot/root axis comprises a discrete domain from early proembryo stages onward. Novel cell fates of the shoot and the root are acquired within this distinct morphogenic axis domain, which elongates and thus separates the shoot apical meristem and root apical meristem (RAM) anlagen in the maize embryo.     

Olive embryo in vitro germination potential: role of explant configuration and embryo structure among cultivars

The in vitro germination of excised embryos can break dormancy rapidly and shorten the time required to produce seedlings, speeding up olive breeding programmes as well as rootstock production. In this study, the in vitro germination potential of four Sicilian olive cultivars was evaluated during two years of experiments, using explants with three different morphological configurations that represent three different degrees of embryo exposure: (1) intact stoneless seeds containing the embryo, the endosperm and the seed coat (Emb+En+SC), (2) seeds without the seed coat (Emb+En) and (3) naked, isolated embryos (seed coat and endosperm both removed: Emb). Differences were found in the germination percentages and timing due to both genotype and explant type. The root and shoot meristems, the radicle-hypocotyl axis, the provascular tissues and embryo storage reserves were identified as embryo anatomical structures which could influence germination capacity. Observation of these structures, however, indicated similar germination potential among cultivars, suggesting possible differences in other dormancy factors. In spite of variation in cultivar performance, after 60 days of in vitro culture all cultivars demonstrated the highest germination of naked embryos (explant type 3) and lowest for stoneless seeds (explant type 1); stoneless seeds without the seedcoat (explant type 2) showed intermediate germination percentages.     

Is the wild oat embryo monocotylous?

The embryogeny of the wild oat (Avena fatua L.) was studied in detail. The pattern of embryo development was observed to be similar to the other investigated grass taxa, conforming to thePoa variation of the Asterad type. The embryogeny and anatomy of young seedlings showed that the embryo of the wild oat was not monocotylous, but dicotylous. The scutellum of the embryo, as reported for other grasses, was regarded as the first cotyledon, and the first leaf primordium, which developed later into a photosynthesizing leaf and situated opposite the scutellum, was interpreted as the second cotyledon. Observations indicated that the cotyledons of the embryo were placed lateral to the shoot apical meristem, which was terminal in position. The cotyledons were found to be dimorphic in structure and function. The scutellum, a modified cotyledon, functioned as a suctorial organ, transporting nutrients from the endosperm to the embryo axis. The second cotyledon or the first true leaf supplied nutrients directly to the embryo axis through the process of photosynthesis.     

中国睡莲科植物种子胚及其营养组织的研究

研究了中国睡莲科的3属3种即芡（Euryale ferox Salisb.）、睡莲（Nymphaea tetragona Georgi）和萍蓬草（Nuphar pumilum (Hoffm.) DC.）的胚、胚乳及外胚乳。它们的胚的共同特点是苗端发育良好,特别是胚芽具2～4枚胚芽叶,而根端滞育。三个种皆既有胚乳,又有外胚乳,但在成熟种子中作为胚的营养组织则胚乳弱育而外胚乳发达。最后对上述特点在系统发生中的意义进行了讨论。     

Microsurgery reveals regional capabilities for pattern reestablishment in somatic carrot embryos

The extent to which regions of a somatic embryo were committed to a particular developmental fate was explored by surgically removing portions of somatic embryos and observing patterns of regeneration. Through a variety of excisions that resulted in tissue slices ranging from less than 10% to nearly 90% of the original embryo mass, we observed only a few cases where such isolates completely abandoned preexisting patterns of organized growth. Instead, most subcultured portions of the embryonic axis restored all, or part of, a missing complement of the organism. At the shoot apex, a single lost cotyledon was replaced by new cotyledonary structures, although these usually occurred as multiple pairs of cotyledons. If both cotyledons were removed, secondary axes, each with its own cotyledons, typically formed at the embryo midlength. When embryos were divided into shoot and root pieces, the shoot pole usually regenerated a new root, while the original root and rapidly elongated and matured days earlier than uncut controls. Surprisingly, cotyledon regeneration from excised root sections occurred at much greater frequency when the root piece comprised only 10-25% of the embryo mass; larger portions of the root pole rarely produced recognizable shoot structures. These studies indicate that several discrete regions of the embryo are committed to specific types of patterned growth, and that continuity between certain of these regions is required for the maintenance of axial polarity.     

Thioredoxin and germinating barley: targets and protein redox changes

The endosperm and embryo of barley ( Hordeum vulgare L.) grain were investigated to relate thioredoxin h and disulfide changes to germination and seedling development. The disulfide proteins of both tissues were found to undergo reduction following imbibition. Reduction reached a peak 1 day earlier in the embryo than in the endosperm, day 1 vs. day 2. The profile in both cases resembled those observed with wheat and rice, i.e., the reduction of the storage proteins increased initially and then declined during the period of seedling growth. The extent of the increase in reduction observed with barley endosperm was, however, less pronounced than with the other cereals. Also, unlike wheat and rice, the storage proteins of the endosperm were highly reduced in the dry seed and the sulfhydryl content of glutelins showed no appreciable change during this period. The relative abundance of thioredoxin h during germination and early seedling growth differed in the embryo and endosperm: a progressive decrease in the endosperm (as seen with wheat) vs. an increase in the embryo. Thioredoxin h was found in the major seed tissues in characteristic forms. Three forms were found in the scutellum and aleurone, whereas two, which may represent isoforms, were identified in the root and the shoot. Using a recently developed strategy based on two-dimensional gel electrophoresis, several proteins were identified as specific targets for thioredoxin in the embryo following oxidation with H(2)O(2), among them barley embryo globulin 1, peroxiredoxin and acidic ribosomal protein P(3). The results confirm earlier findings with the endosperm of other cereals and extend the importance of thioredoxin-linked redox change to the germinating embryo for functions that potentially include dormancy, protection against reactive oxygen species, translation and the mobilization of storage proteins.     

Anatomical Investigation of Abscissed Avocado Flowers and Fruitlets

The anatomy of abscissed avocado fruitlets of the Hass varietywas compared with that of actively growing control fruitletsto investigate the reason for abscission. Control fruitletshad a small embryo (4–14 cells) and numerous endospermcells by seven days after pollination. Cotyledon developmenthad commenced by 21 days and a root/shoot axis was present at28 days. Over 90 per cent of the fruitlets which abscissed during thefirst week after the end of flowering were unfertilized and18 per cent were abnormal. By the fourth week after the endof flowering all abscissed fruitlets were fertilized and noneabnormal. Abnormalities included ovaries with more than oneembryosac or ovule, with an immature embryo-sac, with an ovulein an abnormal position or with a deficiency in ovule structure.In a few fertilized abscissed fruitlets either the embryo orendosperm had ceased development first. In the majority of casesembryo and endosperm were anatomically normal. The majorityof fertilized abscissed fruitlets had reached a stage correspondingto 14 days after pollination of the control tree. Degenerationwas often observed in both unfertilized and fertilized abscissedfruitlets. It is suggested that this degeneration occurred inthe period between the cessation of development and abscissionof the fruit. This period was approximately one week. The proportion of abnormal ovaries was too low to significantlyaffect yields, and sufficient flowers had been fertilized togive an adequate crop. No anatomical reason for the high rateof fruitlet abscission was observed. Persea americana Mill, avocado, abscission, embryo-sac, embryo, endosperm     

ZEA MAYS EMBRYO SACS IN CULTURE. I. PLANT REGENERATION FROM 1 DAY AFTER POLLINATION EMBRYOS

One day after pollination, embryo sacs of Zea mays, containing zygotes and a few endosperm nuclei, were partially isolated and grown in culture. The zygotes underwent normal embryo development, and 40% germinated on a modified Murashige and Skoog medium with 0.1 mg/liter 6-benzylaminopurine. After the appearance of a root and a shoot, individual plantlets were transferred to soil and grown to sexual maturity. The techniques for partial mechanical isolation and successful growth to maturity of such young embryos provide the tools necessary for the recovery of plants from in vitro-fertilìzed embryo sacs.     

Glutamine improves shoot morphogenesis in chickpea (Cicer arietinum L.)

The use of glutamine has been shown to increase the frequency of organogenesis and regeneration in the in vitro culture of several plants. The effect of glutamine on hormone-induced multiple shoot formation in desi and kabuli genotypes of chickpea (C-235 and PUSA-1053) were evaluated. Embryo axes with or without attached cotyledons were cultured in thidiazuron (TDZ) or 6-benzylaminopurine (BAP)-containing medium, respectively, with various concentrations of glutamine. Glutamine improved and prolonged the multiple shoot regeneration ability of the embryo axis. Chickpea embryo axis with attached cotyledon and cultured in TDZ-containing medium showed improved and prolonged shoot regeneration with 5 mM glutamine, while embryo axis without cotyledon and cultured in BAP-containing medium showed prolonged regeneration ability in 10 mM glutamine. Glutamine, however, did not serve as a substitute for cotyledon. Desi genotype (C-235) showed better response for multiple shoot formation as compared to the kabuli genotype (PUSA-1053). Glutamine at a concentration of 5 mM also improved root formation in excised in vitro shoots.     

Zygotic embryogenesis in Anthurium (Araceae)

Morphological, anatomical, and histochemical aspects of zygotic embryogenesis by Anthurium andraeanum Lind. were investigated from 4 to 24 wk postpollination. Anatomical features were correlated with morphology of the spadix and capacity of embryos to germinate in vitro. Development from a single-cell zygote to fully mature seed takes 24 wk. The suspensor was two ranked and obvious during the early stages of embryogeny. It was apparent by week 8, substantial until week 14, and diminished rapidly until its absence by week 22. Differentiation of the shoot apex, cotyledon, and protoderm occurs at 14 wk. The embryo starts to derive nutrition from the endosperm at this time, and germination of cultured ovules reached 56%. By 20 wk the shoot apex had visible leaf primordia and the root apex was clearly defined. The cotyledon was well developed and surrounded the shoot tip. The storage of protein and starch was at its greatest in the endosperm and embryo. Furthermore, 100% germination of cultured ovules and embryos occurred at 20 wk and thereafter. Fully mature embryos at 24 wk are green and contain protoxylem elements.     

Allometric relationships between seed mass and seedling characteristics reveal trade-offs for neotropical gap-dependent species

A seed size–seed number trade-off exists because smaller seeds are produced in greater number but have a lower probability of establishment. This reduced establishment success of smaller-seeded species may be determined by biophysical constraints imposed by scaling rules. Root and shoot diameter, root growth extension rate (R _GER) and shoot length at death for dark-grown seedlings are predicted to scale with the cube root of seed embryo and endosperm mass (m). We confirmed this expectation for ten neotropical gap-dependent tree species with an embryo and endosperm dry mass >1 mg. However, for nine smaller seeded species (m < 1 mg) with photoblastic germination, root and shoot diameters were larger than expected, and consequently, R _GER was slower than expected. The maximum shoot thrust of seedlings from seeds with masses ≥1 mg was comparable to the estimated force required to displace overlying litter, supporting the hypothesis that photoblastic behaviour only occurs in seeds with insufficient shoot thrust to displace overlying leaves. Using the model soil water, energy and transpiration to predict soil drying in small and large gaps, we showed that: (1) gaps that receive a significant amount of direct sunlight will dry more quickly than small gaps that do not, (2) compared to the wet-season, soil that is already dry at depth (i.e. the dry-season) will dry faster after rainfall (this drying would most likely kill seedlings from small seeds) and (3) even during the wet-season, dry periods of a few days in large gaps can kill shallow-rooted seedlings. We conclude that the smaller the seed, the more vulnerable its seedling would be to both covering by litter and soil drying because it can only emerge from shallow depths and has a slow R _GER. Consequently, we suggest that these allometrically related factors contribute to the reduced establishment success of smaller-seeded species that underpins the seed size–seed number trade-off.     

The asymmetric division of the Arabidopsis zygote: from cell polarity to an embryo axis

During plant embryogenesis, a simple body plan consisting of shoot and root meristem that are connected by the embryo axis is set up by the first few rounds of cell divisions after fertilization. Postembryonically, the elaborate architecture of plants is created from stem cell populations of both meristems. Here, we address how the main axis (apical-basal) of the plant embryo is established from the single-celled zygote and the role that the asymmetric division of the zygote plays in this process. We will mainly draw on examples from the model plant Arabidopsis, for which several key regulators have been identified during the last years.     

A structural study of germination in celery (Apium graveolens L.) seed with emphasis on endosperm breakdown

Germination of celery seed occurred after 6 d of imbibition in light. During this time the embryo enlarged at the expense of the adjacent endosperm cells and at the time of germination was 2–3 times as long as in the dry seed. Breakdown of the endosperm cells near the root cap preceeded radicle emergence. None of these changes occurred in darkness.Endosperm digestion began adjacent to the embryo and spread radially. In degrading cells, the aleurone grains often became larger and fewer in number. The cell walls were modified and appeared to undergo partial degradation. Ultimately the cells seemed to lose their contents. In cells adjacent to the root cap, similar changes occurred except there was a transient appearance of starch grains. Radial progression of endosperm breakdown also occurred in isolated endosperm treated with gibberellin A₄₊₇.The results indicate that (1) the stimulus for breakdown of celery endosperm emanates from the embryo in response to light; (2) the stimulus may be a gibberellin because changes in endosperm cells and the sequence of endosperm digestion during germination resemble the responses of isolated endosperm to gibberellin; and (3) the radial progression of endosperm breakdown during germination may be the result of a sequential response of cells to a uniformly applied stimulus rather than the result of gradual embryo expansion.