The Nutrition of the Freshwater Dinoflagellate Ceratium hirundinella*

A defined medium was devised for a freshwater isolate of the dinoflagellate Ceratium hirundinella. Highest cell yields were produced at 7,700–10,000 lux. The optimum pH range was between 7.0 and 7.5: the optimum temperature 21°C. Ceralium hirundinella tolerated a wide range (per liter) of Ca (0.1–100 mg) and Mg (0.1–50 mg) ion concentrations. The optimum range for growth was 20–30 rns Ca and 10–30 mg Mg. Cells cultured in media lacking Ca often became teratological yet motilp and viable. Variations in the Ca:Mg ratio had little effect on cell yield if the sum of the concentrations of the 2 ions remained the same. Organic as well as inorganic sources of N and P were utilized. NH₄ sources became toxic at elevated levels (7 mg N liter^-1). Methionine was not used as N source. Cells could not be completely depleted of P, but concentrations ≤ 0.01 mg P liter^-1 resulted in poor growth. Vitamin B₁₂, but not thiamine or biotin, was required. Highest cell yields were at a PII-metals concentration of 30 ml liter^-1; a t 100-ml liter^-1 cell yield was very low. Additions (per liter) of Fe (0.5 mg) and Mo (0.1 mg) to the basal medium produced higher cell yields, but Cu (0.1 mg) and V (0.1 mg) inhibited growth.     

Inhibition of the mold phase of Coccidioides immitis by beta-ionine and dimethoxane

The mold phase ofCoccidioides immitis was exposed to varying concentrations of beta-ionone and dimethoxane in Sabouraud'sl Glucose Agar and the inhibitory concentration of each compound was determined. Beta-ionone demonstrated an inhibitory effect at 0.2 % or less, but completely inhibited the growth ofC. immitis above 0.2 %. Its mouse LD₅₀ was 4.4 × 10⁴ mg. Because of its great toxicity for mice, it could not be considered a possible candidate for chemotherapy. However, results suggested its use as a selective additive for an isolation medium. Dimethoxane demonstrated complete inhibition ofC. immitis at concentrations of 0.55 % and higher and some fungistatic effects at lower concentrations. Because the mouse IP toxicity dose was found to be rather low (0.65 mg/kg), it may have potential as a chemotherapeutic agent for coccidioidomycosis.     

THE CONCHOCELIS PHASE OF THREE SPECIES OF PORPHYRA IN CULTURE

The Conchocelis phases of Porphyra perforata f. patens, P. cuneiformis and P. nereocystis were cultured from spores in a sterile artificial medium at 12 C and with 25 ft-c illumination for 10 hr daily. The cultures showed differences in duration of the vegetative phase, sporulation, liberation of spores, and the return to the leafy phase. Morphological differences were also noticed. Since the 3 species were grown under identical conditions, it is inferred that these characteristics are probably different for the 3 species studied.     

KINETIC ANALYSIS OF INTERACTIVE EFFECTS OF CADMIUM AND NITRATE ON GROWTH OF THALASSIOSIRA FLUVIATIUS (BACILLARIOPHYCEAE)1,2

The effect of cadmium on growth rates of Thalassiosira fluviatilis Hustedt and Isochrysis galbana Parke at non-limiting nutrient concentrations is described by the lerusalimskii equation. At limiting nitrate concentrations, the effect of Cd on growth rate of T fluviatilis is described by analogy to the general equation of enzyme inhibition in which the reaction involves a single intermediate. When cells are stressed by Cd, not only is the maximum growth rate reduced, but the half-saturation growth parameter is increased. The value of log (k₁/k₂) can be used to describe the type and degree of interaction between a nutrient and an inhibitor, k, and k₂ate the inhibitor concentrations resulting in 50% growth inhibition as nutrient concentration approaches zero and an infinitely large value respectively. Results show that for T fluviatilis, the degree of inhibition by Cd is more severe at low than at high NO₃-levels but the difference in seventy diminishes at Cd concentration increases.     

Relationship of soil hydrogen sulfide level to net carbon assimilation ofPanicum hemitomon andSpartina patens

Panicum hemitomon Schult andSpartina patens (Ait) Muhl. plants from Louisiana Gulf Coast fresh and brackish marshes were subjected to hydrogen sulfide under controlled sediment redox conditions. Net carbon assimilation responses of both species to the combined sediment anaerobiosis and hydrogen sulfide concentrations was measured.Panicum hemitomon was more sensitive to hydrogen sulfide as compared toSpartina patens. Initiation of reduction in net carbon assimilation inP. hemitomon began when H₂S concentrations of soil solution exceeded 0.22 mgl^-1. Reductions in net carbon assimilation inS. patens were also noted at H₂S concentrations exceeding 0.34 mgl^-1. The reduction in net carbon assimilation of both species measured at elevated H₂S concentrations suggests that extreme anaerobiosis and elevated sulfide could contribute to the growth reduction of these species under certain conditions. However based on H₂S concentration in fresh and brackish marsh soil profiles, levels were too low to cause any adverse effects ofPanicum hemitomon. In brackish marsh soils containing hydrogen sulfide of 3.4 mgl^-1 in soil solution, sulfide could be a major factor limiting growth ofS. patens.     

PHYCOBILIN CONTENT OF THE CONCHOCELIS PHASE OF ALASKAN PORPHYRA (BANGIALES,RHODOPHYTA) SPECIES: RESPONSES TO ENVIRONMENTAL VARIABLES1

Variations of pigment content in the microscopic conchocelis stage of four Alaskan Porphyra species were investigated in response to environmental variables. Conchocelis filaments were cultured under varying conditions of irradiance and nutrient concentrations for up to 60 d at 11°C and 30 psu salinity. Results indicate that conchocelis filaments contain relatively high concentrations of phycobilins under optimal culture conditions. Phycobilin pigment production was significantly affected by irradiance, nutrient concentration, and culture duration. For Porphyra abbottiae V. Krishnam., Porphyra sp., and Porphyra torta V. Krishnam., maximal phycoerythrin (63.2–95.1 mg · g dwt^?1) and phycocyanin (28.8–64.8 mg · g dwt^?1) content generally occurred at 10 μmol photons · m^?2 · s^?1, f/4–f/2 nutrient concentration after 10–20 d of culture. Whereas for Porphyra hiberna S. C. Lindstrom et K. M. Cole, the highest phycoerythrin (73.3 mg · g dwt^?1) and phycocyanin (70.2 mg · g dwt^?1) content occurred at 10 μmol photons · m^?2 · s^?1, f nutrient concentration after 60 d in culture. Under similar conditions, the different species showed significant differences in pigment content. P. abbottiae had higher phycoerythrin content than the other three species, and P. hiberna had the highest phycocyanin content. P. torta had the lowest phycobilin content.     

Germination and production ofMacrophomina phaseolina microsclerotia as affected by oxygen and carbon dioxide concentration

Summary Germination of microsclerotia ofMacrophomina phaseolina was observed at O₂ concentrations of 16% or higher in autoclaved soil. Germination was delayed but otherwise unaffected as O₂ decreased from 21 to 16% and was in all cases complete in 32 hours. Laboratory-produced microsclerotia consistently germinated more rapidly and seemed more independent of O₂ concentrations within the range that permitted germination than naturallyproduced microsclerotia.Population changes in soil as measured by microsclerotial counts were inversely correlated with depth of interment and reduced O₂ concentration. Our inability to detect significantly growth responses ofM. phaseolina in non autoclaved soil was apparently related to limited O₂ although other possibilities are discussed.Contribution of the Missouri Agricultural Experiment Station Scientific Journal Series No. 9124.     

Simultaneous measurements on the effect of oxygen concentration on water vapor and carbon dioxide exchange in leaves

Summary Transpiration rate was unaffected by O₂ concentration in the range 1–80% when illuminated leaves ofAtriplex patula andA. rosea were kept at low CO₂ concentrations. Moreover, the marked increase in the rate of light-saturated photosynthesis that takes place in many plant species when O₂ concentration is reduced from 21% to a few percent was not accompanied by any change in transpiration rate inA. patula andSolanum dulcamara. The results indicate that higher plant photosynthesis in normal air and saturating light is not determined by physical barriers to gas diffusion alone but that it is markedly limited by biochemical processes.C.I.W.-D.P.B.Publ. No. 454.     

Embryonic nutrition,growth and energetics inZoarces viviparus L. as indication of a maternal-fetal trophic relationship

Summary The embryos ofZoarces viviparus (L.) show linear growth during their intraovarian development. In early gestation before hatching, the embryos take up very small amounts of low molecular tracer compounds such as glucose, glycine or taurine. Later in gestation (two months after hatching), the embryos accumulate substantial amounts of the tracer compounds. The uptake rates of the tracer compounds in vitro are correlated with ambient concentrations of unlabelled compounds within the natural concentration range of the ovarian fluid. The highest uptake rates are found for glucose and the lowest for taurine. Release of¹⁴CO₂ and dissolved organic carbon (DO¹⁴C) from assimilated tracers in the embryos is low. Oxygen uptake and body weight of the embryos appear to be linearly correlated, and the average oxygen uptake is 4.20 (SD 0.73) mol O₂ g^–1 h^–1 WW at 11°C. The contribution of glucose respiration to total aerobic respiration is 13.9%. A growth to respiration ratio of 0.91 indicates a relatively high efficiency for converting food to growth.Symbols and abbreviations DW dry weight - WW wet weight - DO ¹⁴ C dissolved organic carbon (¹⁴C-labelled) - t _1/2 half life time - turnover time (replacement time)     

Glucose regulation in captive Pongo pygmaeus abeli,P. p. pygmaeus,andP. p. abeli x P. p. pygmaeus orangutans

Intravenous glucose tolerance tests (IVGTT) were performed on 30 anesthetized, captive Sumatran (Pongo pygmaeus abeli), Bornean (P. p. pygmaeus), and hybrid (P. p. ablie x P. p. pygmaeus) orangutans, and fasted blood samples were taken from two additional juvenile orangutans in 11 U.S. zoos from 1989 to 1997. The age range of animals was 3.5 to 40.5 years. Plasma and serum samples were assayed for glucose and insulin concentrations. Glucose disappearance rate (K_G), an index of glucose tolerance, was calculated, as were the early (acute) and second phase insulin responses to administered glucose. The mean ± SE (and median) fasting glucose and insulin concentrations were 113 ± 16 mg/dL (90 mg/dL) and 45 ± 7 μU/mL (27 μU/mL), respectively. Two animals previously suspected to be diabetic were easily identified by their markedly elevated fasting glucose concentrations (380 and 562 mg/dL) and relatively low fasted insulin concentrations (21 and 14 μU/mL); their insulin responses during the IVGTTs were also low or non‐detectable. Without these diabetics, the mean ± SE (median) fasting glucose concentration was 92 ± 18 mg/dL (89 mg/dL). Two animals, ages 18 and 40, were identified as potentially pre‐diabetic based on age, adiposity, elevated fasted glucose (116 and 137 mg/dL, respectively), and elevated fasted insulin concentrations (114 and 217 μU/mL, respectively). In addition, nearly half of the animals of varying ages, all sub‐species and both sexes exhibited delayed or attenuated acute insulin responses during the IVGTTs, resulting in lower K_G (P < 0.04) and suggesting propensity for glucose intolerance in captive orangutans. Glucose and insulin concentrations and insulin responses to glucose did not differ between females on hormonal contraception regimes and those not receiving treatment. Zoo Biol 19:193–208, 2000. © 2000 Wiley‐Liss, Inc.     

NUTRITIONAL REQUIREMENTS OF THE CHYTRID KARLINGIA ASTEROCYSTA,AN OBLIGATE CHITINOPHILE

The nonfilamentous chytrid, Karlingia asterocysta, has been isolated in pure culture on chitin media and the nutritional requirements of a single-spore clone investigated. The fungus displayed an absolute requirement for chitin or preformed N-acetyl-d -glucosamine. This requirement could only be relieved partially by glucose in the presence of limiting acetyl glucosamine concentrations. Under similar conditions other carbohydrates were not utilized. Sulfate was used as a sulfur source and either nitrate or ammonium ion served as nitrogen sources, though growth was better with amino acids. The organism had a very low phosphate optimum (5 × 10^–5 m ) and was inhibited by concentrations at or above 1 × 10^–3 m . The optimal pH range extended from 6.0 to 7.5 and growth decreased rapidly at higher or lower pH values. Thiamine was required at a very low concentration; only 2 μg thiamine-HCl/liter were required for optimal growth. In a rich, agitated medium K. asterocysta completed a single growth cycle (i.e., plant generation) in 70 hr at 25 C.     

Aerotolerant growth inAzospirillum brasilense induced by dihydroxyphenyl iron-binding compound

High concentrations of phosphate drastically inhibited the aerobic growth ofAzospirillum brasilense in liquid medium having a limiting concentration of combined nitrogen. No growth inhibition occurred if a high concentration of combined nitrogen was present. Aerobic growth occurred only in the presence of a very low amount of phosphate and this could be enhanced by adding norepinephrine. Addition of norepinephrine enhanced the O₂ uptake by cell suspensions by almost a factor of 3. All of the intermediates of the tricarboxylic acid metabolic cycle were actively oxidized in cell-free extracts and their rate of oxidation increased in the presence of norepinephrine.     

Effects of solution pH and bicarbonate on the growth and nodulation of a range of grain legume species

Defining plant adaptation to soil conditions is critical for the successful introduction of grain legume species into farming systems. This nutrient solution study examined the effects of pH (4, 5, 6, 7 and 8) and bicarbonate (5 mM KHCO₃) on the growth and nodulation of 14 grain legume species supplied with N or reliant on N₂-fixation. Species includedPisum sativum L.,Cicer arietinum L.,Lens culinaris Med., and a range ofLupinus, Vicia andLathyrus species. Species differed greatly in response to solution pH. For both N-fertilized and N₂-fixing plants, shoot growth ofL. culinaris was very sensitive to low pH (pH < 7), whereas shoot growth ofLupinus angustifolius L. andLupinus albus L. was sensitive to higher pH (pH ≥ 6). Other species had a broader optimal pH range for growth when supplied with N, but were generally sensitive to low pH (pH < 7 forC. arietinum andVicia sativa L., pH < 6 forP. sativum, Vicia faba L.,Lathyrus sativus L. andLathyrus cicera L., and pH < 5 forVicia benghalensis L. andVicia narbonensis L.) when reliant on N₂-fixation. For these other species, symbiotic N₂-fixation appeared to be more sensitive than host plant growth to low pH. This finding was supported by lower nodule numbers and mass, and lower N concentrations in shoots of sensitive species at low pH relative to higher pH. ForL. culinaris, nodule numbers and mass were relatively unaffected by pH 5–8, N concentrations in shoots were high at low pH and plants developed symptoms relating to H⁺ toxicity at pH as high as 7. These results indicate that host plant growth ofL. culinaris is more sensitive to low pH than theRhizobium symbiosis. ForL. albus andL. angustifolius, both host plant growth and symbiotic N₂-fixation appeared to be equally sensitive to pH ≥ 6.Lupinus pilosus Murr. was more tolerant of high pH than the otherLupinus species. At pH 4, two genotypes ofC. arietinum had better early nodulation than other species.Vicia ervilia L. nodulated poorly at all levels of solution pH, indicating that the commercial Group E inoculum (Rhizobium leguminosurum bv.viceae SU303) may not be effective for this species in solution culture. Addition of bicarbonate decreased shoot growth, nodulation and N concentrations in shoots of most species. Early nodulation (nodule number) ofLathyrus ochrus (L.) DC was not affected by the bicarbonate treatment.     

EFFECTS OF NITROGEN SOURCES ON P-LIMITED GROWTH OF ANABAENA FLOS-AQUAE1

The effects of N₂, nitrate and ammonia as N sources were investigated in P-limited and nutrient-sufficient cultures of Anabaena flos-aquae (Lyngb.) Bréb. The maximum growth rate (μ_m) was highest at 1.34 d^?1 with ammonia, compared to 1.18 with nitrate and 0.95 d^?1 with N₂. There was no difference in P requirement between N₂ and nitrate cultures. Under P-limited conditions, the increase in cell P with growth rate (μ) was identical. With N₂ as the N source, cell-N concentrations in P-limited cells increased with μ as did cell P, and the cellular N:P ratio remained the same (14) within the range of μ examined. With nitrate, however, cell N concentrations were high and independent of n, except at a low μ. It appears that this organism fixes atmospheric N₂ only at the minimum concentration required to maintain a μ. The acetylene reduction rate increased with μ in both N_2- and nitrate-grown cells, but the rate was lower in nitrate. Under P-limitation, there was no difference in net C-fixation rate per cell between N₂ and nitrate cultures at a given μ. However, the rate per unit of chlorophyll a (chl a) was higher in N₂ than in nitrate cultures, and the rate was independent of μ with N₂ but was a linear function of nitrate supplied. The maximum C-fixation rate in nutrient sufficient cells was highest with ammonia, followed by nitrate and N₂. The cellular chl a concentration was correlated with the total cell-N concentrations regardless of H and the source of N.     

Filamentous algae in fish ponds of the Třeboň Biosphere Reserve-ecophysiological study

Filamentous algae in eutrophic carp ponds in South Bohemia (Central Europe) were studied from 1988 to 1990. High biomass (490 g DW m^-2) was attained by Cladophora fracta (O. F. Müll. ex Vahl) Kütz. after two months of growth. This marked growth depleted inorganic carbon in the water, but did not decrease the concentration of tissue nutrients. Laboratory measurements of final pH indicate that all the filamentous algae studied, except for Tribonema, are very efficient HCO₃ ^- users. An extremely high pH of 11.6 and oxygen concentration of 32 mg l^-1 were measured in the algal mats. High pH resulted in CaCO₃ precipitation, visible as white incrustations on algal filaments. The amount of precipitated CaCO₃ reached 134 kg ha^-1. After reaching peak biomass, 90% of the Cladophora decomposed over the next 95 days.The highest net photosynthetic rate in C. fracta was measured between pH range 8.5–10.0 and oxygen concentrations of 7–12 mg l^-1. Optimum temperature for photosynthesis was between 17–22°C.     

Cytotoxicity of Synthetic Fuel Products on Tetrahymena pyriformis. I. Phenol*

SYNOPSIS. Phenol is the major organic constituent of coal-conversion scrub water and is therefore a potential environmental contaminant. After Tetrahymena pyriformis strain GL-C, syngen 1 was exposed to phenol, its behavior, cytology, respiration, and growth rates were examined. Concentrations ≥ 75 mg/liter alter cell motility, shape, and contractile vacuole activity. O₂ uptake was abruptly reduced within 3 min of exposure to phenol in concentrations as low as 10 mg/liter. Concomitantly there was an increase in the electron density of the mitochondrial matrix. Recovery to normal rates of O₂ consumption was paralleled by a return to normal matrix density. Alterations of mucocysts, pellicle, and glycogen were also observed. The length of lag phase growth curves increased generally in proportion to concentration of toxicant. Phenol, however, did not affect the rate of cell multiplication during the exponential growth phase. The potential use of this system to examine the effects of other possible organic pollutants is discussed.     

Microbially Available Phosphorus in Boreal Forests: Effects of Aluminum and Iron Accumulation in the Humus Layer

Soil microorganisms play an important role in the mobilization of phosphorus (P), and these activities may be beneficial for plant P utilization. We investigated the effects on microbial P availability of different combinations of aluminum and iron (Al + Fe) concentrations and different P pools in humus soils from boreal forest ecosystems. We measured respiration rates in laboratory incubations before and after additions of glucose plus (NH₄)₂SO₄ (Glu+N), with or without a small dose of KH₂PO₄. Glu+N was added in excess so that the availability of the inherent soil P would be growth-limiting for the microorganisms. The exponential increases observed in microbial growth after substrate additions (Glu+N) was slower for humus soils with high Al+Fe concentrations than for humus soils with low Al+Fe concentrations. Adding a small dose of KH₂PO₄ to humus soils with high Al+Fe concentrations did, however, increase the exponential growth, measured as the slope of the log-transformed respiration rates, by more than 200%. By contrast, the average increase in exponential growth was only 6% in humus soils with low Al+Fe concentrations. Almost eight times more carbon dioxide (CO₂) was evolved between the substrate additions and the point at which the respiration rate reached 1 mg CO₂ h^–1 for soils with high Al+Fe concentrations compared to humus soils with low Al+Fe concentrations. The amount of CO₂ evolved was positively related to the Al+Fe concentration of the humus soils (r ² = 0.86, P < 0.001), whereas the slope was negatively related to Al+Fe concentration (r ² = 0.70, P < 0.001). Easily available P forms were negatively related to the Al+Fe concentration, whereas organic P showed a strong positive relationship to Al+Fe (r ² = 0.85, P < 0.001), suggesting that other forms of P, as well as inorganic P, are affected by the increased sorption capacity. The results indicate that P mobilization by microorganisms is affected by the presence of sorption sites in the humus layer, and that this capacity for sorption may relate not only to phosphate but also to organic P compounds.     

Thede novo Formation of Buds and Plantlets from Various Explants ofAilanthus altissima Mill. Culturedin vitro

The hypocotyls, cotyledons, leaf blades, whole leaves and petioles of seedlings ofAilanthus altissima are capable of producing callus and budsin vitro. Buds and callus were also obtained from whole leaves and internodes of 2-years old plantlets grownin vitro. From the calli buds differentiated and later, both from buds developing directly without a callus phase and alsovia a callus phase, well developed shoots were formed. The cultures were mainained on MS medium in 2 combinations: A) IAA - 0.2 mg 1⁻¹, BAP - 1 mg 1⁻¹, GA₃ - 0.5 mg 1⁻¹, thiamine - 4 mg 1⁻¹ and sucrose 3 %; B) BAP - 0.5 mg 1⁻¹, IAA - 1 mg 1⁻¹, casein hydrolysate 400 mg 1⁻¹, thiamine 4 mg 1⁻¹ and sucrose 3 %. Excised shoots, which had developedde novo in culture, produced roots when incubated on the basic mineral medium of MS with the addition of IAA. The regenerative potential ofA. altissima is very high and this woody species seems to be an ideal object for various morphogenetic studies.     

CHLOROPHYLL,NITROGEN, AND PHOTOSYNTHETIC PATTERNS DURING GROWTH AND SENESCENCE OF TWO BLUE-GREEN ALGAE1,2

A standardized, multiflask, batch culture system was developed to study the processes of algal senescence in Anacystis nidulans and Phormidium molle Gom, var. tenuior W. et G. West. Growth data over a 3-year period gave reproducible and comparable time-course curves. Although A. nidulans is unicellular and P. molle filamentous, the patterns of change with age were similar. Mean logarithmic doubling times and carbon yields were, respectively, 6.9 hr and 390 mg C/liter for A. nidulans and 7.2 hr and 710 mg C/liter for P. molle. Chlorophyll concentration and photo-synthetic capacity per unit carbon rose rapidly during the logarithmic phase to maximum levels in either late log phase (P. molle) or early linear phase (A. nidulans), then fell throughout the declining growth phase to low levels in the stationary phase. Nitrate was rapidly exhausted from the medium during the period of logarithmic growth and stoichiometrically converted to particulate organic form; very little subsequent fixation of molecular nitrogen occurred. The phycocyanins were rapidly destroyed during the logarithmic phase while the carotenoids remained relatively constant throughout the whole growth period and then slowly declined. Preliminary electron micrographs showed a progressive deterioration in cellular ultrastructure, especially a reduction in the number of photosynthetic thylakoids, commenting in the linear growth phase. Analysis of the results suggests that occurrence of linear growth kinetics and termination of culture growth were caused by exhaustion of nitrate. The observed decreases in chlorophylls, phycocyanins, and photosynthetic capacity during active culture growth show that senescence effects may not be, as assumed, restricted to the stationary phase of growth.     

Anatoxin-a concentration inAnabaena andAphanizomenon under different environmental conditions and comparison of growth by toxic and non-toxicAnabaena-strains — a laboratory study

Anatoxin-a-concentration in cells ofAnabaena- andAphanizomenon-strains and in their growth media were studied in the laboratory in batch cultures at different temperatures, light fluxes, orthophosphate and nitrate concentrations and with different nitrogen sources for growth. Toxin concentrations were detected by HPLC. Also, the growth of the toxicAnabaena-strains was compared to that of a non-toxic one. The non-toxicAnabaena was never found to produce anatoxin-a. The amount of toxin in the cells of the toxic strains was high, often exceeding 1% of their dry weight. High temperature decreased the amount of the toxin regardless of growth. Growth limiting low and growth inhibiting high light decreased the amount of the toxin in the cells ofAnabaena-strains. The highest light flux studied did not limit the growth or decrease the level of the toxin in the cells ofAphanizomenon. Growth in N-free medium (i.e. N₂ fixation) showed that the cells contained more toxin than growth in N-rich medium. Orthophosphate concentration had no effect on toxin levels, although the lowest concentrations limited the growth of all strains studied. The toxic strains tolerated higher temperatures than the non-toxic one, but the non-toxic strain seemed to be more adjustable to high irradiance than the toxic ones. The yields (dry weight) of non-toxic and toxic strains differed significantly in different phosphate concentrations.