Effects of salinity, light intensity and sediment on growth, pigments, agar production and reproduction in Gracilaria tenuistipitata from Songkhla Lagoon in Thailand
The effects of salinity, light intensity and sediment on Gracilaria tenuistipitata C.F. Chang & B.M. Xia on growth, pigments, agar production, and net photosynthesis rate were examined in the laboratory under varying conditions of salinity (0, 25 and 33 psu), light intensity (150, 400, 700...
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| Main Authors: | , |
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| Format: | Article |
| Language: | English |
| Published: |
2016
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| Subjects: | |
| Online Access: | http://kb.psu.ac.th/psukb/handle/2016/15022 |
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| Institution: | Prince of Songkhla University |
| Language: | English |
| Summary: | The effects of salinity, light intensity and sediment on
Gracilaria tenuistipitata C.F. Chang & B.M. Xia on
growth, pigments, agar production, and net photosynthesis
rate were examined in the laboratory under varying
conditions of salinity (0, 25 and 33 psu), light intensity
(150, 400, 700 and 1000 mmol photons m-2 s-1) and
sediment (0, 0.67 and 2.28 mg L-1). These conditions
simulated field conditions, to gain some understanding
of the best conditions for cultivation of G. tenuistipitata.
The highest growth rate was at 25 psu, 700 mmol
photons m-2 s-1 with no sediments, that provided a 6.7%
increase in weight gain. The highest agar production
(24.8 3.0 %DW) was at 25 psu, 150-400 mmol
photons m-2 s-1 and no sediment. The highest pigment
contents were phycoerythrin (0.8 0.5 mg g-1FW) and
phycocyanin (0.34 0.05 mg g-1 FW) produced in low
light conditions, at 150 mmol photons m-2 s-1. The
highest photosynthesis rate was 161.3 32.7 mg O2
g-1 DW h-1 in 25 psu, 400 mmol photons m-2 s-1 without
sediment in the short period of cultivation, (3 days) and
60.3 6.7 mg O2 g-1 DW h-1 in 25 psu, 700 mmol
photons m-2 s-1 without sediment in the long period of
cultivation (20 days). The results indicated that salinity
was the most crucial factor affecting G. tenuistipitata
growth and production. This would help to promote the
cultivation of Gracilaria cultivation back into the lagoon
using these now determined baseline conditions.
Extrapolation of the results from the laboratory study to
field conditions indicated that it was possible to obtain
two crops of Gracilaria a year in the lagoon, with good
yields of agar, from mid-January to the end of April (dry
season), and from mid-July to the end of September (first
rainy season) when provided sediment was restricted.important raw materials for producing agar and they are
relatively easy to farm. Gracilaria species contribute
50% of the world’s agar, which has a world market
value of US$ 82.2 million (McHugh, 2003) In Thailand,
although wet and dry Gracilaria production has
reached 80 tons and 20 tons per year, respectively, the
commercial requirement is for more than 2400 tons
(Tachanaravong and Daroonchoo, 1988). Songkhla
Lagoon, which is mesotrophic and the largest natural
lagoon in Thailand, is an important source of Gracilaria,
especially the harvests from both wild and planted beds
at Koh Yor. However, in recent times the yields of
Gracilaria have declined because of developments in
and near the lagoon, which have dramatically changed
the salinity and turbidity (Angsupanich & Rakkheaw
1997; Angsupanich & Kuwabara 1999; Panapitukkul
et al. 2005).
Salinity is an important factor for photosynthesis,
respiration, and growth of Gracilaria spp (Israel et al.
1999; Li-hong et al. 2002). Lower salinities often
inhibit growth of seaweeds, affect branching patterns
and promote changes in their chemical composition
(Ekman et al. 1991; Choi et al. 2006). Light intensity is
also important for photosynthesis, and ultimately for all
their biological processes. The quality and quantity of
light depends on the depth, the density of particles in the
water (turbidity) and day length (Lobban et al. 1985).
The ability of seaweeds to absorb light energy varies,
depending on their quantity of pigment and density of
their photosynthetic units (Darley 1982). Adaptation is
always important for the algae populations at all depths.
Red algae adapt well to variations in light. The ratio of
phycoerythrin increases with increased depth or low light
intensities, and is a good example of chromatic adaptation
(Beer & Levy 1983; Carnicas et al. 1999).
An increase of sediment load has been recognized as
a major threat to marine biodiversity on a global scale. |
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