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http://dx.doi.org/10.5657/KFAS.2011.0290

Field and Culture Studies on the Growth and Reproduction of Campylaephora hypnaeoides  

Yoo, Hyun-Il (Faculty of Biological Science and Institute of Basic Sciences, Wonkwang University)
Kim, Ji-Hwan (Jeollanam-do Provincial Government Ocean & Fisheries Science Institute)
Choi, Han-Gil (Faculty of Biological Science and Institute of Basic Sciences, Wonkwang University)
Publication Information
Korean Journal of Fisheries and Aquatic Sciences / v.44, no.3, 2011 , pp. 290-297 More about this Journal
Abstract
The phenology of Campylaephora hypnaeoides J. Agardh and optimal conditions for carpospore release, growth and reproduction were examined in the field and in the laboratory from January to December 2007. In the field population of C. hypnaeoides, approximately 50% of the plants were vegetative during the study period. Additionally, the percentages of carposporophytes and tetrasporophytes were maximal in April (37%) and June (57%), respectively. Maximum growth in plant length, dry weight, and hook number coincided with the tetrasporophyte reproductive peak in the field. In culture, carpospore release, sporeling growth and reproduction were affected by environmental factors such as daylength, temperature, and salinity. The liberation of carpospores was maximum under continuous light and at a combination of $15^{\circ}C$ and $10\;{\mu}mol$ photons $m^{-2}\;s^{-1}$. Maximum growth of tetrasporophyte sporelings occurred at a combination of $20\;{\mu}mol$ photons $m^{-2}\;s^{-1}$ of constant light and $25^{\circ}C$. However, the growth of gametophyte sporelings was maximal under $40\;{\mu}mol$ photons $m^{-2}\;s^{-1}$ of constant light and in a combination of $20^{\circ}C$ and 35 psu. The tetrasporophyte sporelings were grew faster than gametophytes, indicating that gametophyte- and tetrasporophyte-sporelings have different physiological responses to irradiance and temperature. Tetrasporangial branches and cystocarps of C. hypnaeoides were produced from carpospores and tetraspores within 1 month, and they were stimulated at high temperature and irradiance levels. In conclusion, C. hypnaeoides should be seeded using carpospores during early winter (November-December) because cystocarps are easily identified by fishermen, and tetrasporophytes grow faster than gametophytes.
Keywords
Campylaephora hypnaeoides; Growth; Reproduction; Spore release;
Citations & Related Records
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1 Friedlander M and Dawes CJ. 1984. Studies on spore release and sporeling growth from carpospores of Gracilaria foliifera (Førsskäl) Børgesen var. angustissima (Harvey) Taylor. I. Growth responses. Aquatic Bot 19, 221-232.   DOI
2 Gonzalez J and Meneses I. 1996. Differences in the early stages of development of gametophytes and tetrasporophytes of Chondracanthus chamissoi (CAg) Kützing from Puerto. Aldea, Northern Chile. Aquaculture 143, 91-107.   DOI
3 Guzman-Uriostegui A and Robledo D. 1999. Factors affecting sporulation of Gracilaria cornea (Gracilariales, Rhodophyta) carposporophytes from Yucatan, Mexico. Hydrobiologia, 398/399, 285-90.
4 Han T and Kain JM. 1996. Effect of photon irradiance and photoperiod on young sporophytes of four species of the Laminariales. Eur J Phycol 31, 233-240.   DOI
5 Subba Rangaiah G. 1985. Influence of temperature on diurnal periodicities of tetraspores of some members of Gigartinales (Rhodophyta). Seaweed Res Utiln 8, 23-27.
6 Umamaheswara Rao M and Kaliaperumal N. 1983. Effects of environmental factors on the liberation of spores from some red algae of Visakhapatnam coast. J Exp Mar Biol Ecol 70, 45-53.   DOI
7 Vasquez JA and Vega JMA. 2001. Chondracanthus chamissoi (Rhodophyta, Gigartinales) in northern Chile: ecological aspects for management of wild populations. J Appl Phycol 13, 267-277.   DOI
8 White EB and Boney AD. 1969. Experiments with some endophytic and endozoic Acrochaetium species. J Exp Mar Biol Ecol 3, 246-274.   DOI
9 Yoo HI. 2009. Cultivation trial of Campylaephora hypnaeoides in laboratory and field. Master Degree Thesis. Wonkwang University, Iksan, Korea.
10 Yoo HI, Kim JH and Choi HG. 2010. Effects of sediment (silt), water movement, and light intensity on the survival and growth of sporelings of epiphytic Campylaephora hypnaeoides. Kor J Fish Aquat Sci 43, 239-245.   과학기술학회마을   DOI
11 Choi HG, Kim YS, Kim JH, Lee SJ, Park EJ, Ryu J and Nam KW. 2006. Effects of temperature and salinity on the growth of Gracilaria verrucosa and G. chorda, with the potential for mariculture in Korea. J Appl Phycol 18, 269-277.   DOI
12 Boo SM. 1991. A Biosystematic Study on the Genus Campylaephora J. Agardh Rhodophyta. Ministry of Science and Technology Report, 1-51.
13 Boo SM, Fredriksen S, Rueness J and Lee IK. 1991. Field and culture studies on the life history of Campylaephora crassa (Okamura) Nakamura (Ceramiaceae, Rhodophyta). Bot Mar 34, 437-45.   DOI
14 Chapman ARO and Burrows EM. 1970. Experimental investigations into the controlling effects of light conditions on the development and growth of Desmarestia aculeata (L.) Lamour. Phycol 9, 103-108.   DOI
15 Luning K. 1990. Seaweeds. Their Environment, Biogeography, and Ecophysiology. Wiley, New York, U.S.A., 1-527.
16 Kain JM and Norton TA. 1990. Marine Ecology. In: Biology of the Red Algae. Cole, K.M. and R.G. Sheath, eds. Cambridge University Press, Cambridge, U.K., 377-422.
17 Kang JW. 1968. Illustrated Encyclopedia of Fauna and Flora of Korea. Vol. 8. Marine algae. Sam Hwa Press, Seoul, Korea, 1-465.
18 Kirihara S, Notoya M and Aruga Y. 1990. Cultivation of Campylaephora hypnaeoides J. Agardh (Ceramiales, Rhodophyta). Jpn J Phycol 38, 377-382.
19 Matsui T. 1969. Studies on the liberation and germination of spores in Gloiopeltis tenax (Turn.) J. Ag. and G. furcata et. Rupr. J Shimonoseki Univ Fish 17, 185-231.
20 NFRDI. 2007. Korea Oceanographic Data Center. Retrieved from http://kodc.nfrdi.re.kr
21 Notoya M. 1979. Life history of Campylaephora hypnaeoides J. Agardh (Ceramiaceae, Rhodophyta) in culture and environmental regulation of reproduction. Jpn J Phycol 27, 201-204.
22 Pizarro A and Santelices B. 1993. Environmental variation and large scale Gracilaria production. Hydrobiologia 260/261, 357-363.
23 Santos R and Nyman M. 1998. Population modelling of Gelidium sesquipedale (Rhodophyta, Gelidiales). J Appl Phycol 10, 261-272.   DOI
24 Provasoli L. 1968. Media and prospects for the cultivation of marine algae. In: Cultures and Collections of Algae. Watanabe, A. and A. Hattorc, eds. Proceedings of a United States-Japan Conference held at Hakone. 1966. 63-75.
25 Rueness J and Tananger T. 1984. Growth in culture of four red algae from Norway with potential for mariculture. Hydrobiologia 116, 303-307.   DOI
26 Santelices B. 1990. Patterns of reproduction, dispersal and recruitment in seaweeds. Oceanogr Mar Biol Ann Rev 28, 177-276.
27 Destombe C, Godin J, Nocher M, Richerd S and Valero M. 1993. Differences in response between haploid and diploid isomorphic phases of Gracilaria verrucosa (Rhodophyta: Gigartinales) exposed to artificial environmental conditions. Hydrobiologia 260/261, 131-137.
28 Do JR, Kim EM, Koo GK and Jo KS. 1997. Dietary fiber contents of marine algae and extraction condition of the fiber. J Kor Fish Soc 30, 291-296.   과학기술학회마을
29 Druehl LD, Cabot EL and Lloyd KE. 1987. Seasonal growth of Laminaria groenlandica as a function of plant age. Can J Bot 65, 1599-1604.   DOI
30 Fletcher RL and Callow ME. 1992. The settlement, attachment and establishment of marine algal spores. Br Phycol J 27, 303-329.   DOI
31 Fonck E, Venegas M, Tala F and Edding M. 1998. Artificial induction of sporulation in Lessonia (Phaeophyta, Laminariales). J Appl Phycol 10, 399-403.   DOI