With regard to FA composition, it c

With regard to FA composition, it could be deduced from
Table 1 and Fig. 4 that cultures under 4 light intensity levels provided
similar categories of FAs, mostly including C14:0, C16:0,
C18:0, C18:1 and C18:2. However, cases under 320 lmol/m2 s provided
more TFA and simultaneously, the contents of most kind of
FAs were improved, especially the characteristic ones such asC16:0 and C18:1. Particularly, the TFA content of microalgae cultivated
under 320 lmol/m2 s were much more than those achieved
under 80 lmol/m2 s, indicating that low light intensity promoted
the generation of polar lipids, especially membrane lipid, which
was related to chloroplast. On the other hand, high light intensity
facilitated the generation of neutral lipids, especially triacylglycerol
(Brown et al., 1996; Napolitano, 1994; Sukenik et al., 1989;
Yakovleva, 2005). It could be explained that sufficient light and
chlorophyll were conducive for the generation of NADPH which
could enhance the activity of ACCase, the key enzyme for FA synthesis
during the lipid production process in the chloroplast, thus
leading to the formation of more FA and lipids (Livne and
Sukenik, 1992; Thelen and Ohlrogge, 2002). FA desaturation was
considered as an important factor for improving microalgae tolerance
against strong light by expediting the synthesis of D1 protein
(Gombos et al., 1997), which was in good agreement with our
research and thus, explained why more UFA was generated underhigher light intensity. Similarly, Fabregas’s study showed that low
light intensity (40 lmol/m2 s) contributed to the generation of UFA
of Nannochloropsis sp., in which An UFA/TFA ratio up to 67.43% was
achieved while a higher light intensity of 480 lmol/m2 s brought
the ratio down to 51.22% (Fábregas et al., 2004).
Besides, different cultures were found to significantly affect FA
contents (Fig. 4 and Table 1). Extra N added cultures such as NM
and NPM provided rather low UFA and TFA content, indicating that
overmuch N was disadvantageous for FA generation. It could be
explained by Sukenik’s research that N limitation would stop the
cell division so as to promote the production of lipids (Sukenik
and Livne, 1991). In our research, sufficient N reduced the lipid
accumulation as well as FA content (Table 1), probably because
the division of algae was so vigorous that the lipid accumulation
was suppressed. Flynn implied that under low light intensity
(40 lmol/m2 s), sufficient N could enhance the activity of fatty acid
desaturase, thus resulting in higher ratio of UFA/TFA ratio comparing
to other cultures, which was in keeping with our experiment
conducted under 80 lmol/m2 s although the influence of extra N
was weaken by higher light intensity (Flynn et al., 1992). CM provided
the highest UFA content of 7.476% and UFA/TFA ratio under
320 lmol/m2 s, suggesting that the condition was beneficial for the
production of UFA.
On the other hand, phosphorus, as another important element
which could promote the generation of NADPH and ATP, was found
to be positive for FA accumulation. However, the activity of FA
desaturase could be inhibited probably ascribing to excess P, by
which the pH was increased from 7 to 8 (data not shown), resulting
in lower UFA/TFA ratio than those of other cultures