Summary
The endosperm of cereal grains develops as a multinucleate mass of wall-less cytoplasm (syncytium) that lines the periphery of the central cell before becoming cellular. The pattern of initial wall formation is precisely oriented and is followed by a round of precisely oriented formative cell division that gives rise to initials for the two tissues of endosperm. The initial anticlinal walls form at boundaries of nuclear-cytoplasmic domains (NCDs) defined by radial microtubules emanating from nuclei in the syncytium. Polarized growth of the NCDs in axes perpendicular to the embryo sac wall and centripetal elongation of the anticlinal walls results in a single layer of open ended alveoli overtopped by the remaining syncytial cytoplasm. This arboreal stage, so named because the elongate nucleate columns of cytoplasm resemble an orchard of trees, predicts the division polarity of the imminent formative division. Mitosis occurs as a wave which, like polarization, moves in both directions from ventral to dorsal. Spindles are oriented parallel to the long axis of the alveoli and cell plates give rise to periclinal walls. The outer daughter nuclei (aleurone initials) are thus completely enclosed by walls and the inner nuclei (starchy endosperm initials) are in alveoli adjacent to the central vacuole.
This is a preview of subscription content, log in via an institution to check access.
References
Antropova EN, Petrova TF, Bogdanov YuF (1970) Cytophotometric studies of histone and DNA in the mitotic cycle of tulip endosperm nuclei. Caryologia 23: 396–403
Bechtel DB, Pomeranz Y (1980) The rice kernel. In: Pomeranz Y (ed) Advances in cereal science and technology, vol. 3. American Association of Cereal Chemists, St Paul, MN, pp 73–113
Bennett MD, Smith JB, Barclay I (1975) Early seed development in the Triticeae. Philos Trans R Soc Lond Biol 272: 199–227
Bosnes M, Harris E, Ailgeltinger L, Olsen O-A (1987) Morphology and ultrastructure of 11 barley shrunken endosperm mutants. Theor Appl Genet 74: 117–187
—, Weidemann F, Olsen O-A (1992) Endosperm differentiation in barley wild-type and sex mutants. Plant J 2: 661–674
Brown RC, Lemmon BE (1995) Methods in plant immunolight microscopy. Methods Cell Biol 49: 85–107
— —, Mullinax JB (1989) Immunofluorescent staining of microtubules in plant tissues: improved embedding and sectioning techniques using polyethylene glycol (PEG) and Steedman's wax. Bot Acta 102: 54–61
— —, Olsen O-A (1994) Endosperm development in barley: microtubule involvement in the morphogenetic pathway. Plant Cell 6: 1241–1252
Engell K (1989) Embryology of barley: time course and analysis of controlled fertilization and early embryo formation based on serial sections. Nord J Bot 9: 265–280
— (1994) Embryology of barley. IV. Ultrastructure of the antipodal cells ofHordeum vulgare L. cv. Bomi before and after fertilization of the egg cell. Sex Plant Reprod 7: 333–346
Fineran BA, Wild DJC, Ingerfeld M (1982) Initial wall formation in the endosperm of wheat.Triticum aestivum: a reevaluation. Can J Bot 60: 1776–1795
Folsom MW, Cass DD (1989) Embryo sac development in soybean: ultrastructure of megasporogenesis and early megagametogenesis. Can J Bot 67: 2841–2849
Gunning BES, Wick SM (1985) Preprophase bands, phragmoplasts, and spatial control of cytokinesis. J Cell Sci Suppl 2: 157–179
—, Hughes JE, Hardham AR (1978) Formative and proliferative cell divisions, cell differentiation, and developmental changes in the meristem ofAzolla roots. Planta 143: 121–144
Hause G, Hause B, Van Lammeren AAM (1992) Microtubular and actin filament configurations during microspore and pollen development inBrassica napus cv. Topas. Can J Bot 70: 1369–1376
Hepler P (1981) The structure of the endoplasmic reticulum revealed by osmium tetroxide-potassium ferricyanide staining. Eur Cell Biol 26: 102–110
Juliano BO, Bechtel DB (1985) The rice grain and its gross composition. In: Juliano BO (ed) Rice: chemistry and technology, 2nd edn. American Association of Cereal Chemists, St Paul, MN, pp 17–57
Mahlberg PG, Sabharwal PS (1967) Mitosis in the non-articulated laticifer ofEuphorbia marginata. Am J Bot 54: 465–472
Mansfield SG (1993) Endosperm development. In: Bowman J (ed)Arabidopsis, an atlas of morphology and development. Springer, Berlin Heidelberg New York Tokyo, pp 385–398
Olsen O-A, Brown RC, Lemmon BE (1995) Pattern and process of wall formation in developing endosperm. BioEssays 17: 803–812
Postek MP, Tucker SC (1976) A new short chemical dehydration method for light microscopy preparations of plant material. Can J Bot 54: 872–875
St. Johnston D, Nüsslein-Volhard C (1992) The origin of pattern and polarity in theDrosophila embryo. Cell 68: 201–219
Terasaka O, Niitsu T (1990) Unequal cell division and chromatin differentiation in pollen grain cells. II. Microtubule dynamics associated with the unequal cell division. Bot Mag Tokyo 103: 133–142
Wang S, Hazelrigg T (1994) Implications for bcd mRNA localization from spatial distribution of exu protein inDrosophila oogenesis. Nature 369: 400–403
Zaki M, Kuijt J (1994) Ultrastructural studies on the embryo sac ofViscum minimum: II. Megagametogenesis. Can J Bot 72: 1613–1628
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Brown, R.C., Lemmon, B.E. & Olsen, O.A. Polarization predicts the pattern of cellularization in cereal endosperm. Protoplasma 192, 168–177 (1996). https://doi.org/10.1007/BF01273889
Received:
Accepted:
Issue Date:
DOI: https://doi.org/10.1007/BF01273889