ISSN:
1573-5176
Schlagwort(e):
agar
;
C:N ratio
;
chemostat
;
Gelidium
;
nitrogen
;
phycobiliproteins
Quelle:
Springer Online Journal Archives 1860-2000
Thema:
Biologie
Notizen:
Abstract Gelidium sesquipedale is the most important raw material used for extraction of agar in Spain. Based on chemostats, a system of culture for macroalgae with a continuous flow of culture medium has been developed. A stressed morphotype from the South of Spain was cultured, and the effects of different rates of NO 3 − flow on growth and internal constituents were investigated in the laboratory. Cultivation was successful after optimizing factors affecting growth, such as irradiance level, renewal rate and water movement. Mass production was dependent on N supply. With a flow of 35 μmol NO3 − g−1 DW d−1, optimal values of growth (2.1% d−1) and biomass yield were obtained. In these conditions, biomass yield resembled the values observed in natural populations (about 500 g DW m−2 y−1). When the flow of N was reduced to 15 μmol NO 3 − g−1 DW d−1, growth rate and biomass yield were reduced three-fold, and were null when N was supplied as 7 μmol NO 3 − g−1 DW d−1. C:N ratio was an index of the physiological status of the tissue, remaining low when N was sufficient and raised to critical values when N supply was limited. Phycobiliproteins, kept at a constant irradiance level, were affected by N supply, acting as an internal nitrogen reserve, unlike chlorophylla. An effective phycobiliprotein synthesis took place when the flow of N was sufficient. Agar yield, on dry weight basis, was similar as a function of N flow, whereas agar yield of the culture was higher when N was sufficient as a result of growth not being limited by N. This system of culture, commonly used in microalgal studies, may have an important use in macroalgae as a system to obtain biomass of high quality as well as a good tool for physiological studies in conditions of continuous and controlled flow of nutrients.
Materialart:
Digitale Medien
URL:
http://dx.doi.org/10.1007/BF02182733
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