Al Essential(nmole NAD(P) min Symbiotic control Apo-symbiotic host 46611 (12) 9166 (18)+mg) 2161 (12) 2162 (20) F1,30 = 0.026 p.0.(pmole mg) 75612 (12) 9568 (21) F1,31 = 2.231 p.0.250620 (12) 271611 (21) F1,31 = 0.004 p.0.F1,28 = 12.948 p,0.Essential amino acids followed the definition applied to the sea anemone Aiptasia pulchella [19]. Enzyme activities were determined as the amount of NAD(P)H (in nmol) converted to NAD(P) by 1 mg of protein in 1 min. Numbers in parentheses represent the number of colony replicates, and data are the mean6S.E. doi:10.1371/journal.pone.0046406.tFigure 5. Multi-dimensional scaling (MDS) ordination of arc cosine-transformed free amino acid concentrations (mole ) in tissue extracts from symbiotic, bleached, and bleached coral with nutrient supplementation. (A) Isopora palifera (stress = 0.11); (B) Stylophora pistillata. (stress = 0.14). Data labels represent the treatment for coral (1, symbiotic control; 2, bleached coral; 3, bleached coral with nutrient A supplement; 4, bleached coral with nutrient B supplement). doi:10.1371/journal.pone.0046406.gMenthol-Induced Aposymbiotic Coral PerformanceWhen depleting Symbiodinium from a cnidarian host, a cessation in the supply of photosynthate released from the algal symbiont would greatly upset the host physiology and metabolism. Although respiration rates of some corals (Montastraea annularis, Agarwia lamarcki, Porites compressa, and Montipora capitata) decreased when Symbiodinium algae were depleted [47,48], those of freshly bleached Isopora and Stylophora did not significantly differ from the symbiotic counterparts (Fig. 4). No differences in respiration rates between symbiotic and aposymbiotic corals were found in the temperate coral Astrangia danae, which was interpreted as holozoic feeding in the aposymbiotic coral possibly compensating for the energy loss from the deprivation of photosynthate release by Symbiodinium [49]. Because no food sources are available in ASW, energy sources for the bleached Stylophora and Isopora to balance the loss from lack of photosynthate release by Symbiodinium might be derived from consuming previous reserves or digestion of impaired Symbiodinium. Depletion of symbiotic algae would also result in significant changes in nitrogen metabolism of the host [25,34,50]. For example, GDH, a key enzyme for assimilating (or releasing) ammonium into (or from) amino acids, increases in alga-depleted corals and sea anemones [34]. FAAs, especially the so-called essential amino acids, in the host homogenates were also found to have decreased by nearly half after depletion of symbiotic algae [25,50]. In this study, the responses of coral nitrogen metabolism to algal depletion Sermorelin site differed between Stylophora and Isopora. Algal depletion caused significant decreases in Isopora GDH activity and FAA contents but not in Stylophora. However, supplementation of the aposymbiotic Isopora with nutrients containing SC-1 manufacturer glycerol, a host mimic FAA mixture, and vitamins reverted the nitrogen metabolicindices back to a level and composition comparable to the symbiotic counterpart (Table 2, Fig. 5A). This result is similar to previous findings in Aiptasia [25,50]. Therefore, aposymbiotic coral generated by expelling Symbiodinium alive during bleaching would need to be fed a proper nutrient supplement before being subjected to physiological studies. With the nutrient A supplement, we successfully maintained Isopora for the test of reinfection with heterogenic Symbiodin.Al Essential(nmole NAD(P) min Symbiotic control Apo-symbiotic host 46611 (12) 9166 (18)+mg) 2161 (12) 2162 (20) F1,30 = 0.026 p.0.(pmole mg) 75612 (12) 9568 (21) F1,31 = 2.231 p.0.250620 (12) 271611 (21) F1,31 = 0.004 p.0.F1,28 = 12.948 p,0.Essential amino acids followed the definition applied to the sea anemone Aiptasia pulchella [19]. Enzyme activities were determined as the amount of NAD(P)H (in nmol) converted to NAD(P) by 1 mg of protein in 1 min. Numbers in parentheses represent the number of colony replicates, and data are the mean6S.E. doi:10.1371/journal.pone.0046406.tFigure 5. Multi-dimensional scaling (MDS) ordination of arc cosine-transformed free amino acid concentrations (mole ) in tissue extracts from symbiotic, bleached, and bleached coral with nutrient supplementation. (A) Isopora palifera (stress = 0.11); (B) Stylophora pistillata. (stress = 0.14). Data labels represent the treatment for coral (1, symbiotic control; 2, bleached coral; 3, bleached coral with nutrient A supplement; 4, bleached coral with nutrient B supplement). doi:10.1371/journal.pone.0046406.gMenthol-Induced Aposymbiotic Coral PerformanceWhen depleting Symbiodinium from a cnidarian host, a cessation in the supply of photosynthate released from the algal symbiont would greatly upset the host physiology and metabolism. Although respiration rates of some corals (Montastraea annularis, Agarwia lamarcki, Porites compressa, and Montipora capitata) decreased when Symbiodinium algae were depleted [47,48], those of freshly bleached Isopora and Stylophora did not significantly differ from the symbiotic counterparts (Fig. 4). No differences in respiration rates between symbiotic and aposymbiotic corals were found in the temperate coral Astrangia danae, which was interpreted as holozoic feeding in the aposymbiotic coral possibly compensating for the energy loss from the deprivation of photosynthate release by Symbiodinium [49]. Because no food sources are available in ASW, energy sources for the bleached Stylophora and Isopora to balance the loss from lack of photosynthate release by Symbiodinium might be derived from consuming previous reserves or digestion of impaired Symbiodinium. Depletion of symbiotic algae would also result in significant changes in nitrogen metabolism of the host [25,34,50]. For example, GDH, a key enzyme for assimilating (or releasing) ammonium into (or from) amino acids, increases in alga-depleted corals and sea anemones [34]. FAAs, especially the so-called essential amino acids, in the host homogenates were also found to have decreased by nearly half after depletion of symbiotic algae [25,50]. In this study, the responses of coral nitrogen metabolism to algal depletion differed between Stylophora and Isopora. Algal depletion caused significant decreases in Isopora GDH activity and FAA contents but not in Stylophora. However, supplementation of the aposymbiotic Isopora with nutrients containing glycerol, a host mimic FAA mixture, and vitamins reverted the nitrogen metabolicindices back to a level and composition comparable to the symbiotic counterpart (Table 2, Fig. 5A). This result is similar to previous findings in Aiptasia [25,50]. Therefore, aposymbiotic coral generated by expelling Symbiodinium alive during bleaching would need to be fed a proper nutrient supplement before being subjected to physiological studies. With the nutrient A supplement, we successfully maintained Isopora for the test of reinfection with heterogenic Symbiodin.