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Daylength and development in four species of Ceramiaceae (Rhodophyta)

Helgoländer wissenschaftliche Meeresuntersuchungen volume 32pages 213–227 (1979)Cite this article

Abstract

Developmental patterns in four species of Ceramiaceae were determined using excised thallus apices grown under a range of light periods. Models of thallus development and organization based on these patterns are presented. Increased rates of apical cell division, greater growth of apical fragments and increased average cell size were found with increasing number of hours light per day between 8–16 and 16–8 h. No aspect of growth investigated was associated with photoperiodic phenomena, and growth occuring during the light break (8-7.5-1-7.5 h) was intermediate between that in 8–16 and 12–12 h. Three patterns of cell elongation were found in the four species in which (1) cell age, (2) cell age and position and (3) cell age, cell position and light period determined cell length at different axial cell positions. Elongation was followed within cells, along axes ofAntithamnion spirographidis for plants grown under different day lengths. Three regions of development were found along main axes: (1) an apical region in which basipetal expansion was greater than acropetal expansion. (2) a zone of stability with equal elongation in apical and basal growth region of cells, and (3) a basal region with greater acropetal expansion. With increasing daylength, the zone of stability was extended to greater ranges of cell length.

Literature Cited

  • Chapman, A. R. O. & Burrows, E. M., 1970. Experimental investigations into the controlling effects of light condition on the development and growth ofDesmarestia aculeata (L.) Lamour. Phycologia9, 103–108.

    Google Scholar 

  • Dixon, P. S., 1958. The morphology, ecology and taxonomy of certain Florideae. Br. phycol. Bull.1, 32–33.

    Google Scholar 

  • —, 1963. Variation and speciation in marine Rhodophyta. In: Speciation in the sea. Ed. by J. P. Harding & N. Tebble. Systematics Ass., London, 51–62.

    Google Scholar 

  • —, 1966. On the form of the thallus in the Florideophyceae. In: Trends in plant morphogenesis. Ed. by E. G. Cutter. Longmans, Green & Co., London. 45–63.

    Google Scholar 

  • —, 1970. The Rhodophyta, some aspects of their biology. II. Oceanogr. mar. Biol.8, 307–352.

    Google Scholar 

  • —, 1971. Cell enlargement in relation to the development of thallus form in Florideophyceae. Br. phycol. J.6, 195–205.

    Google Scholar 

  • —, 1973. Biology of the Rhodophyta. Oliver & Boyd, Edinburgh, 285 pp.

    Google Scholar 

  • — & Richardson, W. N., 1970. Growth and reproduction in red algae in relation to light and dark cycles. Ann. N. Y. Acad. Sci.175, 764–777.

    Google Scholar 

  • Duffield, E. C. S., Waaland, S. D. & Cleland, R. 1972. Morphogenesis in the red alga,Griffithsia pacifica: Regeneration from single cells. Planta105, 185–195.

    Article  Google Scholar 

  • Garbary, D. J. 1975. The genus Ceramium: taxonomic, morphological and cultural investigations. M. Sc. thesis, Acadia University, Nova Scotia, 181 pp.

    Google Scholar 

  • —, Grund, D. & McLachlan, J. 1978. The taxonomic status ofCeramium rubrum (Huds.) C. Ag. (Ceramiales, Rhodophyceae) based on culture experiments. Phycologia17, 85–94.

    Google Scholar 

  • Konrad-Hawkins, E. 1964. Developmental studies on regenerates ofCallithamnion roseum Harvey. Part II. Analysis of apical growth. Regulation of growth and form. Protoplasma58, 60–74.

    Article  Google Scholar 

  • Murray, S. N. & Dixon, P. S. 1973. The effect of light intensity and light period on the development of thallus form in the marine red algaPleonosporium squarrulosum (Harvey) Abbott (Rhodophyta: Ceramiales). I. Apical cell division-main axes. J. exp. mar. Biol. Ecol.13, 15–27.

    Article  Google Scholar 

  • — 1975. The effects of light intensity and light period on the development of thallus form in the marine red algaPleonosporium squarrulosum (Harvey) Abbott (Rhodophyta: Ceramiales). II. Cell enlargement. J. exp. mar. Biol. Ecol.19, 165–176.

    Article  Google Scholar 

  • Provasoli, L. 1968. Media and the prospects for the cultivation of marine algae. In: Cultures and collection of algae. Ed. by A. Watanabe & Hattori, Proc. U.S.-Japan Conf. of the Jap. Soc. Plant Physiol., Hakone,1966, 63–75.

  • Stosch, H. A. von, 1964. Wirkung von Jod und Arsenit auf Meeresalgen in Kultur. Proc. int. Seaweed Symp.4, 142–150.

    Google Scholar 

  • Waaland, S. D. & Cleland, R. 1972. Development in the red algaGriffithsia pacifica. Control by internal and external factors. Planta105, 196–204.

    Article  Google Scholar 

  • —— & Waaland, J. R. 1975. Analysis of cell elongation in red algae by fluorescent labelling. Planta126, 127–138.

    Article  Google Scholar 

  • — & Cleland, R. 1972. A new pattern of plant cell elongation: bipolar band growth. J. Cell Biol.54, 184–190.

    Article  PubMed  Google Scholar 

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Author notes

  1. D. Garbary

    Present address: Department of Botany, University of British Columbia, V6T 1W5, Vancouver, B.C., Canada

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  1. Department of Botany, Liverpool University, P.O. Box 147, L69 3BX, Liverpool, U.K.

    D. Garbary

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  1. D. Garbary
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Garbary, D. Daylength and development in four species of Ceramiaceae (Rhodophyta). Helgolander Wiss. Meeresunters 32, 213–227 (1979). https://doi.org/10.1007/BF02189898

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  • DOI: https://doi.org/10.1007/BF02189898

Keywords

Helgoland Marine Research

ISSN: 1438-3888

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