N. Zou et A. Richmond, Light-path length and population density in photoacclimation of Nannochloropsis sp (Eustigmatophyceae), J APPL PHYC, 12(3-5), 2000, pp. 349-354
Photoacclimation in the marine eustigmatophyte Nannochlropsis sp., used ext
ensively as a food chain component in aquaculture, was studied both in the
laboratory and outdoors. Cell-chlorophyll and carotenoids were used as mark
ers to assess photoacclimation to strong light, as well as to decreasing gr
owth irradiance due to cell proliferation. Focusing on practical aspects in
volved in mass cultivation, three different approaches were used as follows
: (a) cultures initially exposed to low light (150 mu mol photon m(-2) s(-1
)) then transferred to strong light (1000 to 3000 mu mol photon m(-2) s(-1)
); (b) initially low cell density cultures grown in reactors of different l
ight-paths, exposed to strong PFD, in the laboratory and outdoors; (c) init
ially low or high cell density cultures exposed to strong light. As has alr
eady been established in many reports, cell-chlorophyll represented a sensi
tive parameter in assessing cell response to changes in the intensity of th
e light source as well as to modifications in the light regime to which the
cells were exposed. Cell-chlorophyll concentration sharply decreased initi
ally upon transferring the culture from low PFD cell(-1) to high PFD cell(-
1) due to either culture dilution (i.e. decrease in cell density and mutual
shading) or to an increase in PFD. After some 7 days of photoacclimating t
o 2000 and 3000 mu mol photon m(-2) s(-1), chlorophyll a content began to r
ise at a much faster rate than cell number, which also increased in respons
e to the higher irradiance. Cell-chlorophyll in the culture exposed to 2000
mu mol photon m(-2) s(-1) increased after acclimation earlier and at a fas
ter rate than in the culture exposed to 3000 mu mol photon m(-2) s(-1), ind
icating the later irradiance affected a stronger stress. The length of the
reactor's light path exerted a decisive effect on cell response to strong l
ight through its influence on the light regime in the culture. Upon a sharp
increase in PFD, carotenoids in the 1-cm reactor increased in much higher
rate than chlorophyll, compared with the 3-cm light path reactors. This mar
ked difference in cell response to a shift-up in light was attributed to th
e vast variations in the light regime associated with differences in the le
ngth of the light path and areal density. Growth of low cell density cultur
es ceased temporarily upon transfer to strong light, in contrast with high
cell density cultures transferred to strong light, which continued growth w
ithout a lag.