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The biology Of Laminaria hyperborea IX. Growth pattern of fronds

Published online by Cambridge University Press:  11 May 2009

Joanna M. Kain
Affiliation:
Department of Marine Biology, University of Liverpool, Port Erin, Isle of Man
N.S. Jones
Affiliation:
Department of Marine Biology, University of Liverpool, Port Erin, Isle of Man

Extract

INTRODUCTION

In the genus Laminaria the origin of the growth of the frond (blade, lamina) is known to be the meristematic transition zone between frond and stipe. Parke (1948) showed, by observing holes punched in the frond, that the fastest rate of growth in length in L. saccharina (L.) Lamour. was in the proximal 25 mm. However, during measurements of the rate of growth of fronds of plants of known age on previously cleared areas (Kain, 1976), it was noted that in L. hyperborea (Gunn.) Fosl. the maximum rate of elongation occurred at some distance from the transition zone. This led to an investigation of the whole pattern of growth, in terms of elongation, increase in area, decrease in thickness and change in cell size and numbers over the surface of the frond at different stages.

Type
Research Article
Copyright
Copyright © Marine Biological Association of the United Kingdom 1976

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References

Black, W. A. P., 1948. Seasonal variation in chemical constitution of some common British Laminariales. Nature, London, 161, 174.CrossRefGoogle Scholar
Cosson, J., 1967. Étude d'une population de Laminaria digitata, Lam. (biométrie, croissance, régénération). Bulletin de la Societé linnéenne de Normandie, 10e Série, 8, 246—281.Google Scholar
Cribb, A. B., 1954. Macrocystis pyrifera (L.) Ag. in Tasmanian waters. Australian Journal of Marine and Freshwater Research, 5, 134.Google Scholar
Fritsch, F. E., 1945. The Structure and Reproduction of the Algae, vol. 11. 939 pp. Cambridge: University Press.Google Scholar
Hayashida, F., 1966. A few experimental notes on the growth of the young fronds of Eisenia bicyclis. Journal of the Faculty of Oceanography, Tokai University, 1, 123134.Google Scholar
Kain, J. M., 1975 a. Algal recolonization of some cleared subtidal areas. Journal of Ecology, 63, 739765Google Scholar
Kain, J. M., 1975 b. The biology of Laminaria hyperborea. VII. Reproduction of the sporophyte. Journal of the Marine Biological Association of the United Kingdom, 55, 567582.Google Scholar
Kain, J. M., 1976. The biology of Laminaria hyperborea. VIII. Growth on cleared areas. Journal of the Marine Biological Association of the United Kingdom, 56, 267290.Google Scholar
Kawashima, S., 1972. A study of life history of Laminaria angustata Kjellm. var. longissima Miyabe by means of concrete block. In Contributions to the Systematics of Benthic Marine Algae of the North Pacific (ed. Abbott, I. A. and Kurogi, M.), pp. 93107. Kobe, Japan: Japanese Society of Phycology.Google Scholar
Killian, K., 1911. Beiträge zur Kenntnis der Laminarien. Zeitschrift für Botanik, 3, 433494.Google Scholar
Norton, T. A. & Burrows, E. M., 1969. Studies on marine algae of the British Isles. 7. Saccorhiza polyschides (Lightf.) Batt. British Phycological Journal, 4, 1953.Google Scholar
Parke, M., 1948. Studies on British Laminariaceae. I. Growth in Laminaria saccharina (L.) Lamour. Journal of the Marine Biological Association of the United Kingdom, 27, 651709.Google Scholar
Sasaki, S., 1969. An ecological study of Laminaria angustata var. longissima (M.) Miyabe on the coast of Kushiro Prov., Hokkaido. I. On the life of winter populations. Scientific Reports of the Hokkaido Fisheries Experimental Station, 10, 1—42.Google Scholar
Sauvageau, C., 1918. Recherches sur les laminaires des côtes de France. Mémoires de l' Académie des sciences de l'lnstitut de France, 56, 233 pp.Google Scholar
Steinbiss, H. -H.. & Schmitz, K., 1973. CO2-Fixierung und Stofftransport in benthischen marinen Algen. V. Zur autoradigraphischen Lokalisation der Assimilattransportbahren im Thallus von Laminaria hyperborea. Planta, 112, 253263.Google Scholar
Steinbiss, H. -H. & Schmitz, K., 1974. Zur Entwicklung und funktionellen Anatomie des Phylloids von Laminaria hyperborea. Helgoländer wissenschaftliche Meeresuntersuchungen, 26, 134152.CrossRefGoogle Scholar
Sundene, O., 1964. The ecology of Laminaria digitata in Norway in view of transplant experiments. Nytt magasin for botanikk, 11, 83107.Google Scholar
Svendsen, P. & Kain, J. M., 1971. The taxonomic status, distribution and morphology of Laminaria cucullata sensu Jorde and Klavestad. Sarsia, 46, 122.Google Scholar