Abstract
This last portion of our developmental study ofPinus sylvestris L. pollen grains extends from just prior to the first microspore mitosis to the microsporangial dehiscence preparatory to pollen shedding. In nine years of collecting each day the duration of the above period was 7 to 11 days. Tapetal cells extended into the loculus and embraced microspores during the initial part of the above period. Thereafter tapetal cells receded, became parallel to parietal cells and so imbricated that there appeared to be two or three layers of tapetal cells. Tapetal cells were present up to the day before pollen shedding, but only rER and some mitochondria appeared to be in good condition at that time. A callosic layer (outer intine) was initiated under the endexine before microspore mitosis. After the first mitosis the first prothallial cell migrated to the proximal wall and was covered on the side next to the pollen cytoplasm by a thin “wall” joining the thick outer intine. There are plasmodesmata between pollen cytoplasm and the prothallial cell. After the second mitosis the second prothallial cell became enveloped by the outer intine. The inner intine appears after formation of the two prothallial cells but before the third mitosis. During this two-prothallial cell period before the third mitosis, plastids had large and complex fibrillar assemblies shown to be modified starch grains. After the third mitosis plastids of the pollen cytoplasm contained starch and the generative cell (antheridial initial), the product of that mitosis, is enveloped by the inner intine. On the day of pollen shedding cells are removed from the microsporangial wall by what appears to be focal autolysis. The tapetal and endothecial cells for 10–15 µm on each side of the dehiscence slit are completely removed. One or more epidermal cells are lysed, but both a thin cuticle and the very thin sporopollenin-containing peritapetal membrane remain attached to the undamaged epidermal cells bordering the dehiscence slit. Our study terminates on the day of pollen shedding with mature pollen still within the open microsporangium. At that time there is no longer a clear morphological distinction between the outer and inner intine but, judging by stain reactions, there is a chemical difference. The exine of shed pollen grains was found to be covered by small spinules on the inner surface of alveoli. These had the same spacing as the Sporopollenin Acceptor Particles (SAPs) associated with exine initiation and growth.
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References
Baldi B. G., Franceschi V. R., Loewus F. A. (1986) Dissolution of pollen intine and release of sporoplasts. In: Mulcahy D. L., Bergamini Mulcahy G., Ottaviano E. (eds.) Biotechnology and ecology of pollen. Springer, New York, pp. 77–82.
Chen Z-K., Wang F-H., Zhou F. (1987) Investigation of the ultrastructure of the tapetum inPinus bungeana. Acta Bot. Sinica 29: 486–491.
Dickinson H. G. (1970) The fine structure of a peritapetal membrane investing the microsporangium ofPinus banksiana. New Phytol. 69: 1065–1068.
Gorska-Brylass A. (1970) The “callose” stage of the generative cells in pollen grains. Grana 10: 21–30.
Hanaichi T., Sato T., Moshina M., Mizuno N. (1986) A stable lead stain by modification of Sato's method. Proc. 11 Int. Cong. Electron Micros., Kyoto; pp. 2181–2182.
Hepler P. K. (1982) Endoplasmic reticulum in the formation of the cell plate and plasmodesmata. Protoplasma 111: 121–133.
Huysmans S., El-Ghazaly G., Smets E. (1998) Orbicules in angiosperms: morphology, function, distribution, and relation with tapetum types. Bot. Rev. 64: 240–272.
Karnovsky M. J. (1965) A formaldehyde-glutaraldehyde fixative of high osmolarity for use in electron microscopy. J. Cell Biol. 27: 137A.
Latta H., Johnston W. H., Stanley T. M. (1975) Sialoglycoproteins and filtration barriers in the glomerular capillary wall. J. Ultrastruct. Res. 51: 354–376.
Loewus F. A., Baldi B. G., Franceschi V. R., Meinert L. D., McCollum J. J. (1985) Pollen sporoplasts: dissolution of pollen walls. Plant Physiol. 78: 652–654.
Lugardon B. (1978) Comparison between pollen and pteridophytes spore walls. IVth International Palynological Conference, Lucknow, 1976–77, Proceedings, 1: 199–206.
Luomajoki A. (1986) Timing on microsporogenesis in tree with reference to climatic adaptation. A review. Acta Forestalia Fennica: 196: 1–32.
Martens P., Waterkeyn L. (1962) Structure du pollen “ailé” chez les Conifères. La Cellule 62: 171–228.
Martens P., Waterkeyn L., Huyskens M. (1967) Organization and symmetry of microspores and origin of intine inPinus sylvestris. Phytomorph. 17: 114–118.
Oryol L. I., Golubeva E. A. (1982) The acetolysis-resistant wall of tapetal cells in sporophylls ofPinus sylvestris (Pinaceae). Botanicheski Zhurn. 67: 49–60.
Pacini E., Franchi G. G., Ripaccioli M. (1999) Ripe pollen structure and histochemistry of some gymnosperms. Plant Syst. Evol. 217: 81–99.
Pettitt J. M. (1966) Exine structures in some fossil and recent spores and pollen as revealed by light and electron microscopy. Bull. Brit. Mus. (Nat. Hist.) Geol. 13: 221–257.
Rowley J. R. (1990) Are exine reception systems ofFagus andPinus structurally the same? Diversity in exine development. J. Palynol. 91: 323–344.
Rowley J. R. (1995) Cycles of hyperactivity in tapetal cells. Plant Syst. Evol. (Suppl.) 7: 23–27.
Rowley J. R., Walles B. (1985a) Cell differentiation in microsporangia ofPinus sylvestris. II. Early pachytene. Nord. J. Bot. 5: 241–254.
Rowley J. R., Walles B. (1985b) Cell differentiation in microsporangia ofPinus sylvestris. III. Late pachytene. Nord. J. Bot. 5: 255–271.
Rowley J. R., Walles B. (1987) Origin and structure of Ubisch bodies inPinus sylvestris. Acta Soc. Bot. Poloniae 56: 215–227.
Rowley J. R., Walles B. (1988) Cell differentiation in microsporangia ofPinus sylvestris. IV. Diplotene and the diffuse stage. Ann. Sci. Nat. (Bot.) 9: 1–28.
Rowley J. R., Walles B. (1993) Cell differentiation in microsporangia ofPinus sylvestris. V. Diakinesis and tetrad formation. Nord. J. Bot. 13: 67–82.
Rowley J. R., Skvarla J. J., Walles B. (1999) Microsporogenesis inPinus sylvestris. VII. Exine expansion and tapetal development. Taiwania 44: 325–344.
Rowley J. R., Skvarla J. J., Walles B. (2000) Microsporogenesis inPinus sylvestris. VI. Exine and tapetal development during the tetrad period. Nord. J. Bot. (in press).
Singh H. (1978) The Embryology of gymnosperms. Borntraeger, Berlin Stuttgart, p. 302.
Stanley R. G., Linskens H. F. (1974) Pollen: biology, biochemistry, management. Springer, Berlin Heidelberg New York, p. 307.
Tarlyn N. M., Franceschi V. R., Everard J. D., Loewus F. A. (1993) Recovery of exines from mature pollen and spores. Plant Sci. 90: 219–224.
Unzelman J. M., Healey P. L. (1974) Development, structure, and occurrence of secretory trichomes ofPharbitis. Protoplasma 80: 285–303.
Willemse M. T. M. (1971a) Morphological and quantitative changes in the population of cell organelles during microsporogenesis ofPinus sylvestris L. III. Morphological changes during the tetrad stage and in the young microspore. A quantitative approach to the changes in the population of cell organelles. Acta Bot. Neerl. 20: 498–623.
Willemse M. T. M. (1971b) Morphological changes in the tapetal cell during microsporogenesis ofPinus sylvestris L. Acta Bot. Neerl. 20: 611–623.
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Rowley, J.R., Skvarla, J.J. & Walles, B. Microsporogenesis inPinus sylvestris L. VIII. Tapetal and late pollen grain development. Pl Syst Evol 225, 201–224 (2000). https://doi.org/10.1007/BF00985468
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DOI: https://doi.org/10.1007/BF00985468