Tobacco embryogenesis: Storage-protein-accumulating cells of embryo, suspensor, and endosperm are able to undergo cytokinesis

Summary It is widely accepted that seed storage proteins accumulate only in cells which have entered the cell expansion phase and do not continue to divide. Here we present data indicating that the accumulation of storage globulins in tobacco begins already during early embryogenesis in a period of sustained mitotic activity. Western blot analysis revealed that polypeptides of the legumin-like 12S globulins (M_r 60000, 40000, 20000) appear at mid/late globular stage, whereas the vicilin-like 7S globulin (M_r 50000) follows during the transition from heart to torpedo stage. The accumulation of legumin-like polypeptides begins first in the endosperm during the mid globular stage followed in the embryo-suspensor complex during the heart-shaped stage. The vicilin-related fraction appears first in the endosperm and three days later in the embryo. Examination of individual cells from squash preparations revealed that protein bodies are not confined to intermitotic cells, but are also present in cells undergoing mitosis. Protein bodies of dividing cells situated outside the mitotic apparatus are not metabolized during cytokinesis. The only cell type which loses its protein bodies completely prior to the first mitotic division is the primary hypophysis cell. Our finding that storage proteins can occur in dividing cells independent of their origin and developmental capacity indicates that the cell expansion hypothesis of storage protein accumulation has to be revised.     

石香薷（唇形科）的胚胎学研究

石香薷(Mosla chinensis Buch.-Ham.ex Maxim.)花药壁发育属双子叶型。花药具4个小孢子囊;腺质绒毡层,细胞具2～4核,有3至数个核仁;初生造孢细胞直接行小孢子母细胞的功能,在小孢子囊中成单列。花粉母细胞减数分裂后胞质分裂为同时型;小孢子四分体呈四面体形,也有左右对称形,成熟花粉具2细胞。胚珠倒生,单珠被,薄珠心,大孢子四分体线形排列,功能性大孢子位于合点端,少数为合点端第二个细胞。胚囊发育属蓼型,珠孔区近卵圆形,比合点区稍短,合点区较狭窄。胚胎发生属柳叶菜型。细胞型胚乳,珠孔吸器为单孢3核,合点吸器为单孢2核。种子无胚乳,种皮由珠被发育。石香薷雌雄配子体的发育、胚胎发生及胚乳形成,与紫苏属的Perilla ocimoides几乎完全一致。不同点仅在于石香薷在2-细胞花粉时,药室内壁细胞切向伸长,壁尚未发生纤维状加厚(P.ocimoides药室内壁细胞径向伸长,胞壁纤维状加厚),珠孔吸器为单孢3核(P.ocimoides为单孢4核)。胚胎学显示石荠苎属与紫苏属有密切的亲缘关系。     

Degree of pectin methyl esterification in endosperm cell walls is involved in embryo bending in Arabidopsis thaliana

The endosperm is a transitory structure involved in proper embryo elongation. The cell walls of mature seed endosperm are generally composed of a uniform distribution of cellulose, unesterified homogalacturonans, and arabinans. Recent studies suggest that changes in cell wall properties during endosperm development could be related to embryo growth. The degree of methyl esterification of homogalacturonans may be involved in this endosperm tissue remodelling. The relevance of the degree of homogalacturonan methyl esterification during seed development was determined by immunohistochemical analyses using a panel of probes with specificity for homogalaturonans with different degrees of methyl esterification. Low-esterified and un-esterified homogalacturonans were abundant in endosperm cells during embryo bending and were also detected in mature embryos. BIDXII (BDX) could be involved in seed development, because bdx-1 mutants had misshapen embryos. The methyl esterification pattern described for WT seeds was different during bdx-1 seed development; un-esterified homogalacturonans were scarcely present in the cell walls of endosperm in bending embryos and mature seeds. Our results suggested that the degree of methyl esterification of homogalacturonans in the endosperm cell wall may be involved in proper embryo development.     

Purification, characterization, and cDNA structure of isoamylase from developing endosperm of rice

Isoamylase (EC 3.2.1.68) in rice (Oryza sativa L.) was efficiently purified within a day to homogeneity, as confirmed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE), from developing endosperm by sequential use of Q Sepharose HP anion- exchange chromatography, ammonium sulfate fractionation, and TSKgel G4000SW_XL and G3000SW_XL gel filtration chromatography. Although the protein exhibited a molecular size of ca. 83 kDa on SDS-PAGE, the apparent size of the native enzyme was approximately 340 and 490 kDa on TSKgel G3000SW_XL and G4000SW_XL gel filtration chromatograms, respectively, suggesting that rice isoamylase exists in a homo-tetramer to homo-hexamer form in developing endosperm. The purified rice isoamylase was able to debranch glycogen, phytoglycogen and amylopectin but could not attack pullulan. The optimum pH and temperature for isoamylase activity were found to be pH 6.5 to 7.0 and 30 °C, respectively. The enzyme activity was completely inhibited by HgCl₂ and p-chloromercuribenzoate at 1 mM. These results indicate that rice isoamylase possesses properties which are distinct from those reported for bacterial isoamylase. Complementary-DNA clones for rice endosperm isoamylase were isolated with a polymerase-chain-reaction product as probe which was generated by primers designed from nucleotides conserved in cDNA for maize Sugary-1 isoamylase (M.G. James et al., 1995, Plant Cell 7: 417–429) and a Pseudomonas amyloderamosa gene encoding isoamylase (A. Amemura et al., 1988, J Biol Chem 263: 9271–9275). The nucleotide sequence and deduced amino acid sequence of the longest clone showed a high similarity to those of maize Surgary-1 isoamylase, but a lesser similarity to those of Pseudomonas amyloderamosa isoamylase. Southern blot analysis and gene mapping analysis indicated that the isoamylase gene exists as a single copy in the rice genome and is located on chromosome 8 of cv. Nipponbare which belongs to the Japonica rice group. Phylogenetic analysis indicated that isoamylases from maize and rice are more closely related to a number of glgX gene products of the blue green alga Synechocystis and various bacteria than to isoamylases from Pseudomonas and Flavobacterium. Hence, it is proposed that glgX proteins are classified as isoamylase-type debranching enzymes. Our tree also showed that all starch- and glycogen-debranching enzymes from plants and bacteria tested can be classified into two distinct types, an isoamylase-type and a pullulanase-type. Received: 29 October 1998 / Accepted: 10 December 1998     

Uses and usefulness of endosperm balance number

 The Endosperm Balance Number (EBN) hypothesis was developed in the early ’80s to explain the basis for normal seed development after intra- and inter-specific crosses, first in the potato and then in several other crop species. According to this hypothesis, each species has a genome-specific effective ploidy, the EBN, which must be in a 2 : 1 maternal to paternal ratio in the hybrid endosperm for normal development of the endosperm itself. This paper reviews how the EBN may act as a powerful isolating mechanism in sexual reproduction, maintaining the genome integrity of the species and playing an important role in the speciation of polyploids from diploids. We also provide further evidence that EBN is more important than chromosome ploidy in determining the success or failure of interspecific crosses. In fact, results from inter-ploidy and inter-EBN crosses to infuse 1EBN Solanum commersonii into 4EBN S. tuberosum demonstrated that the knowledge and manipulation of EBN is a useful tool in designing breeding schemes and in predicting the offspring ploidy and EBN. In this paper we also discuss the exceptions to the 2 : 1 EBN ratio, and report the evidence for endomitosis in the polar nuclei to explain exceptions to the EBN model in the potato. Received: 22 December 1997 / Accepted: 19 May 1998     

Post-zygotic gametic selection due to endosperm balance number explains unusual chromosome numbers of 3×× 2× progeny in Solanum

 Crosses between triploid and diploid genotypes are usually the best sources of trisomics in potato as well as in several other crop species. However, 3×× 2× crosses between triploid (2n=3×=36; 2EBN) Solanum commersonii-S. tuberosum hybrids and diploid (2n= 2×=24; 2EBN) genotypes gave progenies with a high number of extra chromosomes, 29–36, suggesting that only eggs with 17–24 chromosomes produced embryos that reached full development. Our hypothesis is that although triploids produce eggs with a range of chromosome numbers, 3×× 2× crosses involving a 2×(2EBN) parent favor eggs with a high chromosome number. These eggs have higher probabilities of possessing the same endosperm balance number (EBN) value (i.e. 1) of gametes produced by the 2EBN diploid parent to give the required 2:1 maternal to paternal EBN ratio in the hybrid endosperm. Under this model, trisomics are produced only if the diploid parent has an EBN of 1. Based on our results and those reported in the literature, it is proposed that in 3×(2EBN) × 2×(2EBN) crosses the endosperm balance number exercises negative selection for gametes with a low chromosome number, and a corresponding low EBN, and positive selection for gametes with a high chromosome number and EBN. Received: 2 April 1998 / Revision accepted: 27 October 1998     

The Development of Embryo and Endosperm of Nelumbo nucifera Gaertn

The development of the embryo and endosperm of Nelumbo nucifera Gaertn can be summarized as follows: 1. Embryogenesis of N. nucifera belongs to Solanad type; the 1st mitotic division of the zygote takes place later than that of the primary endosperm nucleus. 2. The development of endosperm basically conforms to the Helobial endosperm. After fertilization, the primary endosperm nucleus divides first transversely. This division results in the formation of two cells. The wall of this division is a little oblique to the longitudinal axis of the embryo sac. In accordance with the character of the endospermic development, it can be divided into, three stages: (1) two-celled endosperm stage, (2) multicellular endosperm stage, and (3) the stage of the endospermic nutrition being absorbed and cells atrophy. The developments of the embryo and endosperm are well correlated. This relation is relatively stable. 3. The cotyledons of the mature embryo are comparatively developed, but the radicle is extremely reduced. 4. As the seed is ripening, a thin membrane remains outside the plumule, which is the remainder of the endosperm. Therefore, the seed of N. nucifera is exalbuminous.     

Unilateral and bilateral hybridization barriers in inter-series crosses of 4x 2EBN Solanum stoloniferum, S. pinnatisectum, S. cardiophyllum, and 2x 2EBN S. tuberosum haploids and haploid-species hybrids

Wild Mexican potato species are an important untapped source of useful variation for potato improvement. Introgression methods such as 2n gametes, chromosome doubling, and crossing with disomic 4x 2 endosperm balance number (EBN) bridge species have been used to overcome post-zygotic endosperm failure according to the EBN hypothesis. Stylar barriers can prevent zygote formation, bilaterally when zygote formation is blocked in both directions of the cross or unilaterally when zygote formation is blocked in self incompatible (SI) × self compatible (SC) crosses. In several Solanaceae species, the S-locus for SI has been implicated in interspecific incompatibility. The objectives of this research were to determine if: (1) disomic 4x 2EBN Solanum stoloniferum can be used as a bridge species for introgression of the Mexican 2x 1EBN species Solanum cardiophyllum and Solanum pinnatisectum, (2) pre- and/or post-zygotic barriers limit hybridization among EBN compatible Solanum inter-series crosses, and (3) reproductive barriers act unilaterally or bilaterally. Fruit formation and seed set was recorded for inter-pollinations of S. stoloniferum, 4x 2EBN chromosome doubled S. cardiophyllum and S. pinnatisectum, and 2x 2EBN S. tuberosum haploids (HAP) or haploid-species hybrids (H-S). In vivo pollen tube growth was analyzed for each cross combination with fluorescence microscopy. Attempts to create bridge hybrids between S. stoloniferum, and S. cardiophyllum or S. pinnatisectum were not successful. Pre- and post-zygotic barriers prevented seed formation in crosses involving S. cardiophyllum and S. pinnatisectum. Self compatibility in S. stoloniferum and S. pinnatisectum suggests that the S-locus does not contribute to the stylar barriers observed with these species. Alternatively, the presence of functional and nonfunctional (SC) S-alleles may explain interspecific incompatibility in intra- and inter-ploidy crosses. A non-stylar unilateral incongruity was discovered in H-S/HAP × S. stoloniferum crosses, indicating either a post-zygotic barrier, or a pre-zygotic barrier acting at or within the ovary. Furthermore, lack of S. stoloniferum pollen rejection may occur through absence of S. stoloniferum pollen-active genes needed to initiate pollen rejection, or through competitive interaction in S-locus heterozygous S. stoloniferum pollen. Introgression strategies using these species would benefit potato breeding by introducing genetic diversity for several traits simultaneously through co-current introgression.     

Fusion of oil bodies in endosperm of oat grains

Few microscopical studies have been made on lipid storage in oat grains, with variable results as to the extent of lipid accumulation in the starchy endosperm. Grains of medium- and high-lipid oat (Avena sativa L.) were studied at two developmental stages and at maturity, by light microscopy using different staining methods, and by scanning and transmission electron microscopy. Discrete oil bodies occurred in the aleurone layer, scutellum and embryo. In contrast, oil bodies in the starchy endosperm often had diffuse boundaries and fused with each other and with protein vacuoles during grain development, forming a continuous oil matrix between the protein and starch components. The different microscopical methods were confirmative to each other regarding the coalescence of oil bodies, a phenomenon probably correlated with the reduced amount of oil-body associated proteins in the endosperm. This was supported experimentally by SDS-PAGE separation of oil-body proteins and immunoblotting and immunolocalization with antibodies against a 16 kD oil-body protein. Much more oil-body proteins per amount of oil occurred in the embryo and scutellum than in the endosperm. Immunolocalization of 14 and 16 kD oil-body associated proteins on sectioned grains resulted in more heavy labeling of the embryo, scutellum and aleurone layer than the rest of the endosperm. Observations on the appearance of oil bodies at an early stage of development pertain to the prevailing hypotheses of oil-body biogenesis.