Cell cycle of symbiotic dinoflagellates: variation in G(1) phase-duration with anemone nutritional status and macronutrient supply in the Aiptasia pulchella-Symbiodinium pulchrorum symbiosis
Gj. Smith et L. Muscatine, Cell cycle of symbiotic dinoflagellates: variation in G(1) phase-duration with anemone nutritional status and macronutrient supply in the Aiptasia pulchella-Symbiodinium pulchrorum symbiosis, MARINE BIOL, 134(3), 1999, pp. 405-418
The metabolite exchange in alga-invertebrate symbioses has been the subject
of extensive research. A central question is how the biomass of the algal
endosymbionts is maintained within defined limits under a given set of envi
ronmental conditions despite their tremendous growth potential. Whether alg
al growth is actively regulated by the animal cells is still an open questi
on. We experimentally evaluated the effect of inorganic nutrient supply and
host-animal nutritional status on the biomass composition, growth and cell
-cycle kinetics of the endosymbiotic dinoflagellate Symbiodinium pulchrorum
(Trench) in the sea anemone Aiptasia pulchella. Dinoflagellates in anemone
s starved for 14 d exhibited lower growth rates, chlorophyll content and hi
gher C:N ratios than in anemones fed Artemia sp. (San Francisco brand #6503
4) nauplii every 2 d, indicating N-limitation of the algae during starvatio
n of the host animal. Manipulation of the dissolved inorganic nutrient supp
ly through ammonium and phosphate additions induced a rapid recovery (half
time, t(1/2) similar to 2 d) in the C:N ratio of the dinoflagellate cells t
o levels characteristic of N-sufficient cells. The mitotic index and popula
tion growth rate of the dinoflagellate symbionts subjected to this enrichme
nt did not recover to the levels exhibited in fed associations. Flow cytome
tric analysis of dinoflagellate cell size and DNA content revealed that the
duration of the G(1) phase (first peak of DNA content: 70 to 100 relative
fluorescence units, rfu) of their cell cycle lengthened dramatically in the
symbiotic state, and that the majority of algal biomass increase occurred
during this phase. Covariate analysis of dinoflagellate cell size and DNA-c
ontent distributions indicated that the symbiotic state is associated with
a nutrient-independent constraint on cell progression from G(1) through the
S phase (intermediate DNA content: 101 to 139 rfu). This analysis suggests
that the host-cell environment may set the upper limit on the rate of dino
flagellate cell-cycle progression and thereby coordinate the relative growt
h rates of the autotrophic and heterotrophic partners in this symbiotic ass
ociation.