Effect of phosphorus on the toxicity of zinc to the microalga Raphidocelis subcapitata

RODGHER, SUZELEI; CONTADOR, THAIS M.; ROCHA, GISELI S.; ESPINDOLA, EVALDO L.G.

doi:10.1590/0001-3765202020190050

Abstract

The aim of this study was to evaluate the effect of phosphorus (P) on the toxicity of zinc (Zn) for the alga Raphidocelis subcapitata. P was provided in three concentrations: 2.3 x 10^-4 mol L^-1, 2.3 x 10^-6 mol L−¹ and 1.0 x 10^-6 mol L−¹. Algal cells were acclimated to the specific P concentrations before the start of the experiment. The chemical equilibrium software MINEQL⁺ 4.61 was employed to calculate the Zn²⁺ concentration. After acclimated, the algal cells were inoculated into media containing different Zn concentrations (0.09 x 10^-6 mol L^-1 to 9.08 x 10^-6 mol L^-1). The study showed that besides the reduction in algal growth rates, phosphorus had an important influence on the toxicity of zinc for microalga. The inhibitory Zn²⁺ concentration values for R. subcapitata were 2.74 x 10^-6 mol L^-1, 0.58 x 10^-6 mol L^-1 and 0.24 x 10^-6 mol L^-1 for the microalgae acclimated at P concentrations of 2.3 x 10^-4 mol L^-1, 2.3 x 10^-6 mol L^-1 and 1.0 x 10^-6 mol L^-1, respectively. Ecotoxicological studies should consider the interaction between metal concentrations and varying P values to provide realistic data of what occurs in phytoplankton communities in environments.

Key words
Algal density; free zinc; green algae; nutrient

INTRODUCTION

Eutrophication and the introduction of toxic materials such as metals are considered major types of degradation of aquatic systems (Wang & Dei 2006WANG WX & DEI RCH. 2006. Metal stoichiometry in predicting Cd and Cu toxicity to a freshwater green alga Chlamydomonas reinhardtii. Environ Pollut 142: 303-312., Dirszowsky & Wilson 2016DIRSZOWSKY RW & WILSON KM. 2016. Biogeochemical evidence of eutrophication and metal contamination of Frame Lake, City of Yellowknife, Northwest Territories, Canada. Environ Earth Sci 75: 76., Albano et al. 2018ALBANO PG, GALLMETZER I, HASELMAIR A, TOMAŠOVÝCH A, STACHOWITSCH M & ZUSCHIN M. 2018. Historical ecology of a biological invasion: the interplay of eutrophication and pollution determines time lags in establishment and detection. Biol Invasions 20: 1417-1430.). Ecological concern about phosphorus is caused by its important role in biological metabolism and the low concentrations of this element in water bodies (Wetzel 2001WETZEL RG. 2001. Limnology: lake and river ecosystems. San Diego: Academic Press, 1006 p.). Phosphorus controls the biological productivity of algae in the greater part of the aquatic environment (Grossman 2000GROSSMAN A. 2000. Acclimation of Chlamydomonas reinhardtii to its nutrient environment. Protist 151: 201-224., Hessen et al. 2002HESSEN DO, FAERØVIG PJ & ANDERSEN T. 2002. Light, nutrients, and P:C ratios in algae: grazer performance related to food quality and quantity. Ecology 83: 1886-1898., Esteves 2011ESTEVES FA. 2011. Fundamentos de Limnologia, 3 ed., Rio de Janeiro: Interciência, 826 p.). However, agro-industrial and domestic sewage discharges may insert excess P into freshwater and marine ecosystems, resulting eutrophication (Zeng & Wang 2009ZENG J & WANG WX. 2009. The importance of cellular phosphorus in controlling the uptake and toxicity of cadmium and zinc in Microcystis aeruginosa, a freshwater cyanobacterium. Environ Toxicol Chem 28: 1618-1626., Schindler et al. 2016SCHINDLER DW, CARPENTER SR, CHAPRA SC, HECKY RE & ORIHEL DM. 2016. Reducing phosphorus to Curb Lake eutrophication is a success. Environ Sci Technol 50: 8923-8929.). The potential effects of eutrophication on aquatic environments include changes in the biodiversity, drinking water treatment problems and a reduction in recreational use (Tundisi & Tundisi 2008TUNDISI JG & TUNDISI TM. 2008. Limnologia. São Paulo: Oficina de Textos, 631 p., Pereira et al. 2010PEREIRA LCC, MONTEIRO MC, GUIMARÃES DO, MATOS JB & DA COSTA RM. 2010. Seasonal effects of wastewater to the water quality of the Caeté river estuary. Brazilian Amazon. An Acad Bras Cienc 82: 467-478., Costa et al. 2014COSTA SM, APPEL E, MACEDO CF & HUSZA VLM. 2014. Low water quality in tropical fishponds in southeastern Brazil. An Acad Bras Cienc 86: 1181-1195.).

Some metals, such as zinc, are essential nutrients for prokaryotic and eukaryotic organisms. Zn is a component of many enzymes and guarantees biological stability of the genetic material and of biological structures, such as the ribosomes and cytoplasmic membranes (Eisler 1981EISLER R. 1981. Trace metal concentrations in marine organisms, New York: Pergamon Press, Inc: New York Elmsford, 687 p.). Currently, zinc is employed in coating other metals, inorganic medicines, and the manufacture of aesthetic products and non-corrosive alloys interfering (Tsushima et al. 2010TSUSHIMA K, NAITO W & KAMO M. 2010. Assessing ecological risk of zinc in Japan using organism- and population-level species sensitivity distributions. Chemosphere 80: 563-569.). This element is one of the most important metals in the economic improvement of China (Xueyi et al. 2010XUEYI G, JUYA Z, YU S & QINGHUA T. 2010. Substance flow analysis of zinc in China. Resour Conserv Recy 54: 171-177.), Korea (Jeong & Kim 2018JEONG S & KIM K. 2018. Pre-Concentration of Iron-Rich Sphalerite by Magnetic Separation. Minerals 8: 1-13.) and Poland (Lewicka & Burkowicz 2017LEWICKA E & BURKOWICZ A. 2017. The changes in the structure of mineral raw materials needs in Poland between 2011−2015. Gospod Surowcami Min 33: 5-28.). In 2017, the U.S. Geological Survey (2018)U.S. GEOLOGICAL SURVEY. 2018. Mineral commodity summaries. Washington: U.S. Geological Survey, 200 p. estimated the global zinc mining production as 13 million tons, with 5% increase compared to the previous year. Due to concern about the potential effects of zinc on the biota of aquatic systems, zinc is receiving attention from the regulatory environmental agencies in European Union and Japan (Bodar et al. 2005BODAR CMW, PRONK MEJ & SIJM DTHM. 2005. The European Union risk assessment on zinc and zinc compounds: the process and the facts. Integr Environ Asses 1: 301-319., Van Sprang et al. 2009VAN SPRANG PA, VERDONCK FAM, VAN ASSCHE F, REGOLI L & DE SCHAMPHELAERE KAC. 2009. Environmental risk assessment of zinc in European freshwaters: A critical appraisal. Sci Total Environ 407: 5373-5391., Naito et al. 2010NAITO W, KAMO M, TSUSHIMA K & IWASAKI Y. 2010 Exposure and risk assessment of zinc in Japanese surface waters. Sci Total Environ 408: 4271-4284., Tsushima et al. 2010TSUSHIMA K, NAITO W & KAMO M. 2010. Assessing ecological risk of zinc in Japan using organism- and population-level species sensitivity distributions. Chemosphere 80: 563-569.).

Zinc is an essential element for phytoplankton, being required in both photosynthetic processes and energy storage (Cao et al. 2015CAO D, XIE P, DENG J, ZHANG H, MA R, LIU C, LIU R, LIANG Y, LI H & SHI X. 2015. Effects of Cu2+ and Zn2+ on growth and physiological characteristics of green algae, Cladophora. Environ Sci Pollut Res 22: 16535-16541.). However, values above trace amounts can be dangerous, modifying cell volumes and inhibiting the growth rate and photosynthesis of microalgae (Guanzon Jr et al. 1994, Mallick & Mohn 2003MALLICK N & MOHN FH. 2003. Use of chlorophyll fluorescence in metal-stress research: a case study with the green microalga. Scenedesmus. Ecotox Environ Safe 55: 64-69., Machado et al. 2015MACHADO MD, LOPES AR & SOARES EV. 2015. Responses of the alga Pseudokirchneriella subcapitata to long-term exposure to metal stress. J Hazard Mater 296: 82-92.). On the other hand, the presence of phosphorus in the aquatic metabolism is of concern to ecologists because this element can regulate algal productivity, causing eutrophication and affecting biological diversity. In the natural aquatic environment, organisms are continually confronted with simultaneous physical and chemical perturbations (Chia et al. 2017CHIA MA, LOMBARDI AT, MELÃO MGG & PARRISH CC. 2017. Phosphorus levels determine changes in growth and biochemical composition of Chlorella vulgaris during cadmium stress. J Appl Phycol 29: 1883-1891., Van Regenmortel et al. 2017VAN REGENMORTEL T, NYS C, JANSSEN CR, LOFTS S & DE SCHAMPHELAERE KAC. 2017. Comparison of four methods for bioavailability-based risk assessment of mixtures of Cu, Zn, and Ni in freshwater. Environ Toxicol Chem 36: 2123-2138., Kong et al. 2018KONG P, CHENG X, SUN R & CHEN L. 2018. The synergic characteristics of surface water pollution and sediment pollution with heavy metals in the Haihe River Basin, Northern China 1. Water 10: 1-17., Roy et al. 2018ROY B, CHANDRASEKARAN H, KRISHNAN SP, CHANDRASEKARAN N & MUKHERJEE A. 2018. UVΑ pre-irradiation to P25 titanium dioxide nanoparticles enhanced its toxicity towards freshwater algae Scenedesmus obliquus. Environ Sci Pollut Res 25: 16729-16742.). As a consequence, chemical compounds interacting with each other in antagonistic and synergistic manners can alter their toxic action to microalgae (Bere et al. 2012BERE T, CHIA MA & TUNDISI JG. 2012. Effects of Cr III and Pb on the bioaccumulation and toxicity of Cd in tropical periphyton communities: Implications of pulsed metal exposures. Environ Pollut 163: 184-191., Zhang et al. 2015ZHANG R, XU ZZ, FAN WH, JIANG YY, ZHAO J & TANG SC. 2015. Biological effect of cadmium in Daphnia magna: influence of nitrogen and phosphorus. Fresen Environ Bull 21: 2891-2895., Mansano et al. 2017MANSANO AS, MOREIRA RA, DORNFELD HC, FREITAS EC, VIEIRA EM, SARMENTO H, ROCHA O & SELEGHIM MHR. 2017. Effects of diuron and carbofuran and their mixtures on the microalgae Raphidocelis subcapitata. Ecotox Environ Safe 142: 312-321.).

Studies about the interactions between metallic ions and nutrients have highlighted the influence of nutrients in culture media on the sensitivity of phytoplankton to metals. The toxicities of arsenic (Wang et al. 2013WANG NX, LI Y, DENG XH, MIAO AJ, JI R & YANG LY. 2013. Toxicity and bioaccumulation kinetics of arsenate in two freshwater green algae under different phosphate regimes. Water Res 47: 2497-2506.), cadmium (Zeng & Wand 2009, Webster et al. 2011WEBSTER RE, DEAN AP & PITTMAN JK. 2011. Cadmium exposure and phosphorus limitation increases metal content in the freshwater alga Chlamydomonas reinhardtii. Environ Sci Technol 45: 7489-7496.), copper (Serra et al. 2010SERRA A, GUASCH H, ADMIRAAL W, VAN DER GEEST HG & VAN BEUSEKOM AM. 2010. Influence of phosphorus on copper sensitivity of fluvial periphyton: the role of chemical, physiological and community-related factors. Ecotoxicology 19: 770-780., Rocha et al. 2016ROCHA GS, LOMBARDI AT & MELÃO MGG. 2016. Influence of phosphorus on copper toxicity to Selenastrum gracile. Ecotoxicol Environ Saf 128: 30-35.) and chromium (Qian et al. 2013QIAN H, SUN Z, SUN L, JIANG Y, WEI Y, XIE J & FU Z. 2013. Phosphorus availability changes chromium toxicity in the freshwater alga Chlorella vulgaris. Chemosphere 93: 885-891.) to cyanobacterium and green microalgae have increased in response to the reduction of phosphorus in the environment. To the contrary, a decrease in the toxicity of Zn to green microalgae under limiting phosphate conditions was described by Gao et al. (2016)GAO C, DE SCHAMPHELAERE KAC & SMOLDERS E. 2016 Zinc toxicity to the alga Pseudokirchneriella subcapitata decreases under phosphate limiting growth conditions. Aquat Toxicol 173: 74-82.. The variable data obtained from research about the interaction between phosphorus and metal exposure to algae could be related to the different procedures adopted in the experiments (Gao et al. 2016GAO C, DE SCHAMPHELAERE KAC & SMOLDERS E. 2016 Zinc toxicity to the alga Pseudokirchneriella subcapitata decreases under phosphate limiting growth conditions. Aquat Toxicol 173: 74-82.), including the absence of metabolic acclimation of algae to changes in the phosphorus concentration. According to the literature, excess P in the environment is incorporated in the algae as polyphosphate vesicles, which reduces the toxicity of metallic ions by way of detoxifying processes when the ions bind to the polyphosphates (Jensen et al. 1982JENSEN TE, BAXTER M, RACHLIN JW & JANI V. 1982. Uptake of heavy metals by Plectonema boryanum (Cyanophyceae) into cellular components, especially polyphosphate bodies: an X-ray energy dispersive study. Environ Pollut 27: 119-112., Twiss & Nalewajko 1992TWISS MR & NALEWAJKO C. 1992. Influence of phosphorus nutrition on copper toxicity to three strains of Scenedesmus Acutus (Chlorophyceae). J Phycol 28: 291-298.). Hence, previous studies about the interaction between phosphorus and metal exposures have reinforced the need for acclimation processes when the algae are exposed to different supplies of phosphorus, to assure that their metabolisms express that condition (Lombardi & Maldonado 2011LOMBARDI AT & MALDONADO MT. 2011. The effects of copper on the photosynthetic response of Phaeocystis cordata. Photosynth Res 108: 77-87., Chia et al. 2017CHIA MA, LOMBARDI AT, MELÃO MGG & PARRISH CC. 2017. Phosphorus levels determine changes in growth and biochemical composition of Chlorella vulgaris during cadmium stress. J Appl Phycol 29: 1883-1891., Rocha et al. 2018ROCHA GS, PARRISH CC, LOMBARDI AT & MELÃO MGG. 2018. Biochemical and physiological responses of Selenastrum gracile (Chlorophyceae) acclimated to different phosphorus concentrations. J Appl Phycol 30: 2167-2177.).

The intensification of eutrophication in freshwater systems justifies the need for studies about the interaction between metals and phosphorus, due to the influence of these elements on the physiology of autotrophic microorganisms (Reynolds 2006REYNOLDS CS. 2006. Ecology of Phytoplankton. Cambridge: Cambridge University Press, 535 p., Chia et al. 2013aCHIA MA, LOMBARDI AT & MELÃO MGG. 2013b. Growth and biochemical composition of Chlorella vulgaris in different growth media. An Acad Bras Cienc 85: 1427-1438., Gormley-Gallagher et al. 2016GORMLEY-GALLAGHER AM, DOUGLAS RW & RIPPEY B. 2016. Metal to phosphorus stoichiometries for freshwater phytoplankton in three remote lakes. Peer J 4: 1-28.). Ecotoxicological tests are helpful tools to estimate the combined toxic effects of chemicals in aquatic systems. Of the unicellular algal species, the Chlorophyceae Raphidocelis subcapitata (previously named Pseudokirchneriella subcapitata) is one of the most suitable for carrying out toxicity tests, due to its high sensitivity to a variety of contaminants, adequately maintainable in laboratory conditions (Wei et al. 2006WEI D, KISUNO A, KAMEYA T & URANO K. 2006. A new method for evaluating biological safety of environmental water with algae, daphnia and fish toxicity ranks. Sci Total Environ 371: 383-390., Yan et al. 2015YAN Z, WANG W, ZHOU J, YI X, ZHANG J, WANG X & LIU Z. 2015. Screening of high phytotoxicity priority pollutants and their ecological risk assessment in China’s surface waters. Chemosphere 128: 28-35., Lewis & Thursby 2018LEWIS M & THURSBY G. 2018. Aquatic plants: test species sensitivity and minimum data requirement evaluations for chemical risk assessments and aquatic life criteria development for the USA. Environ Pollut 238: 270-280.) and for being a characteristic species of oligotrophic and eutrophic freshwater systems (Blaise & Vasseur 2005BLAISE C & VASSEUR P. 2005. Algal microplate toxicity test. In: Blaise C and Férard JF (Eds), Small-scale freshwater toxicity investigations, Dordrecht: Springer, Dordrecht, The Netherlands, p. 137-180.).

The main objective of this study was to evaluate the effects of various phosphorus/zinc combinations on the toxicity of the metal on the green alga Raphidocelis subcapitata. The choice of the phosphorus concentrations tested reflected the natural conditions of freshwater aquatic environments, including low and high concentrations of the element (Zeng & Wang 2009ZENG J & WANG WX. 2009. The importance of cellular phosphorus in controlling the uptake and toxicity of cadmium and zinc in Microcystis aeruginosa, a freshwater cyanobacterium. Environ Toxicol Chem 28: 1618-1626., Chia et al. 2017CHIA MA, LOMBARDI AT, MELÃO MGG & PARRISH CC. 2017. Phosphorus levels determine changes in growth and biochemical composition of Chlorella vulgaris during cadmium stress. J Appl Phycol 29: 1883-1891.). In this research, the microalga R. subcapitata was exposed to three phosphorus concentrations for several generations up to constant growth rates, to guarantee that their physiology would reflect the nutrient concentrations (Rocha et al. 2016ROCHA GS, LOMBARDI AT & MELÃO MGG. 2016. Influence of phosphorus on copper toxicity to Selenastrum gracile. Ecotoxicol Environ Saf 128: 30-35.). Thus, the toxicity tests with zinc were carried out after acclimation of the microalgae. The results generated in this work represent an important contribution to research related to the effect of zinc on aquatic systems with different trophic states, with emphasis on the physiology of autotrophic microorganisms.

MATERIALS AND METHODS

Algal culture and acclimation experiments

The green alga Raphidocelis subcapitata was obtained from the algal culture collection of the Botany Department of the Federal University of São Carlos (São Carlos, SP, Brazil). Stock cultures of the R. subcapitata were maintained in L.C. Oligo medium (AFNOR 1980AFNOR - ASSOCIATION FRANÇAISE DE NORMALISATION. 1980. Essais dês eause. Norme experimentale T90-304. Determination de I’inhibition de Scenesdesmus subspicatus croissance par une substance. Paris: AFNOR.). The microalga was grown in 100 mL sterile culture medium with a photoperiod of 16:8 h light: dark cycle, light intensity of 60 µmol m^-2 s^-1 and temperature of 23 ± 1 °C.

The toxicity tests were conducted with the green algae acclimated to the three nominal phosphorus concentrations. The nutrient was provided as dibasic potassium phosphate (K₂HPO₄): 2.3 x 10^-4 mol L^-1 (Control, L.C. Oligo medium), 2.3 x 10^-6 mol L^-1 and 1 x 10^-6 mol L^-1. These P values were selected after preliminary experiments, where we did not verified algal growth in values lower than 1 x 10^-6 mol P L^-1. Acclimation of the green algae was carried out by transferring algal cells in the exponential growth phase with an initial density of 5 x 10⁵ cells mL^-1, into semi-continuous cultures with specific phosphorus concentrations. The algal cells were maintained for 5 weeks under these conditions, keeping the algal cell density at 5 x 10⁵ cells mL^-1. Algal cells were collected every 168 h and the number of cells in the cultures quantified using a Neubauer-Improved Chamber to determine the growth rate (Rocha et al. 2016ROCHA GS, LOMBARDI AT & MELÃO MGG. 2016. Influence of phosphorus on copper toxicity to Selenastrum gracile. Ecotoxicol Environ Saf 128: 30-35., Chia et al. 2017CHIA MA, LOMBARDI AT, MELÃO MGG & PARRISH CC. 2017. Phosphorus levels determine changes in growth and biochemical composition of Chlorella vulgaris during cadmium stress. J Appl Phycol 29: 1883-1891.). The growth rate values were evaluated according to Fogg (1975)FOGG GE. 1975. Algal cultures and phytoplankton ecology, 2nd ed., United States: University of Wisconsin Press.. The algal cells were maintained under distinct phosphorus concentrations for 35 days, allowing for the finding of at least three constant growth rate values (statistically similar values, p>0.05). Under this condition, the microalga was considered acclimated and its metabolism expressed the P values in the culture medium (Rocha et al. 2016ROCHA GS, LOMBARDI AT & MELÃO MGG. 2016. Influence of phosphorus on copper toxicity to Selenastrum gracile. Ecotoxicol Environ Saf 128: 30-35.). The experiments were carried out with 3 replicates per treatment. The acclimated algal cells were employed in the toxicity tests with zinc, but the microalgae were not acclimated to the metal.

All the laboratory materials used in the culture and acclimatization experiments were washed with 10% HNO₃ for 7 days and then rinsed with deionized water before use.

Toxicity tests

Phosphorus acclimated and exponentially growing R. subcapitata cells were exposed for 96 h to a range of zinc concentrations. Based on the results of the preliminary toxicity tests, seven metal concentrations were prepared: 1 (Medium L.C. Oligo - Control); 1.53; 3.06; 6.12; 12.2; 24.5; 48.9 and 97.9 x 10^-7 mol Zn L^-1. Zinc was provided as ZnCl₂.4H₂O (Titrisol, Merck, Germany). As the bioavailability and toxicity of essential metals to microorganisms are influenced by the free metal concentrations (Meylan et al. 2004MEYLAN SB, BEHRA R & SIGG L. 2004. Influence of metal speciation in natural freshwater on bioaccumulation of copper and zinc in periphyton: a microcosm study. Environ Sci Technol 38: 3104-3111.), the chemical equilibrium software MINEQL⁺ 4.61 (MINEQL+ version 4.61, 2009MINEQL. 2009. Chemical equilibrium modeling system for Windows, version 4.61. Environmental Research Software, Hollowell.) was used to calculate the Zn²⁺ and Zn₃(PO₄)₂ concentrations under different P conditions. The P concentrations in the growth media were determined using the ascorbic acid method (APHA/AWWA/WCF 1995APHA/AWWA/WCF - AMERICAN PUBLIC HEALTH ASSOCIATION/AMERICAN WATER WORK ASSOCIATION/WATER CONTROL FEDERATION. 1995. Standard methods for examination of water and wastewater, 19th ed., Washington: American Public Health Association, 1360 p.).

The experiments were carried out in 250 mL polycarbonate flasks containing 100 mL of medium, to which suitable volumes of metal were added. The green algae cells were inoculated into the flasks to provide initial cell densities of 10⁵ cells mL^-1. The toxicity tests were carried out with three replicates per treatment and the environmental conditions used for the experiments were the same as those delineated for the algal cultures (ABNT 2011ABNT - ASSOCIAÇÃO BRASILEIRA DE NORMAS TÉCNICAS. 2011. Toxicidade crônica. Método de ensaio com algas (Chlorophyceae) ABNT NBR12648, 2 nd ed, Rio de Janeiro: ABNT, 27 p.). After 96 h of metal exposure, 2 mL were taken from each test flask, fixed with acid Lugol’s iodine solution (ABNT 2011ABNT - ASSOCIAÇÃO BRASILEIRA DE NORMAS TÉCNICAS. 2011. Toxicidade crônica. Método de ensaio com algas (Chlorophyceae) ABNT NBR12648, 2 nd ed, Rio de Janeiro: ABNT, 27 p.) and used to determine the cell density. The cells were counted using an Improved Neubauer-Bright Line hemocytometer under an optical microscope (Carl Zeiss, Standard model 25). The cell density (cell mL^-1) was used to obtain the 50% inhibitory concentration for zinc.

Data analysis

The growth rate was analyzed using the One-way ANOVA and Tukey’s post hoc test to identify significant differences between the control treatment and the metal concentrations. Statistical analyses were carried out with a significance level of 0.05 using the BioEstat 4.0 program (Ayres et al. 2007AYRES M, AYRES M JR, AYRES DL & SANTOS ASS. 2007. BioEstat 4.0: aplicações estatística nas áreas das Ciências Bio-Médicas, 5 ed, Sociedade Civil Mamirauá, MCT, Impressa Oficial do Estado do Paraná, 364 p.). The Trimmed Spearman-Karber method was used to estimate the Zn concentration that reduces the cell density to 50 % of control treatment (IC 50) (Hamilton et al. 1977HAMILTON M, RUSSO RC & THURSTON RV. 1977. Trimmed Spearman-Karber method for estimating median lethal concentrations in toxicity bioassays. Environ Sci Technol 11: 714-719.).

RESULTS

Metal speciation (MINEQL⁺ 4.61) showed that approximately 93% of the total zinc added remained available to the algae in the test media with the three P conditions tested, corresponding to free initial zinc ion concentrations of 0.09; 0.14; 0.28; 0.57; 1.13; 2.30; 4.54; and 9.08 x 10^-6 mol L^-1. The chemical equilibrium model predicted that 1% of the total Zn added precipitated as Zn₃(PO₄)₂, and in this study, there was low zinc precipitation by phosphorus in the L.C. Oligo medium. The values of the nutrient (P) measured in the algal culture medium were 2.1 x 10^-4, 2.2 x 10^-6 mol L^-1 and 0.8 x 10^-6 mol L^-1.

The results of the algal acclimation are shown in table I When the R. subcapitata inoculum was added to a culture medium containing 2.3 x 10^-4 mol P L^-1, the algal growth rate was not significantly different during the acclimation period for that treatment. In relation to the treatment with 2.3 x 10^-6 mol P L^-1, the algal cells were considered acclimated after 28 days. The acclimation of the microalgae to 1.0 x 10^-6 mol P L^-1 took 36 days. A significant decrease in the algal growth rate was verified with a limitation of phosphorus in the culture medium (Tukey test, p<0.05).

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Table I
Mean growth rate values (days^-1) for R. subcapitata in the acclimation experiments. Values with the same letters are not statistically different (Tukey’s Test, p>0.05). Values are means of three replicates (± Standard deviation).

In the algal toxicity tests, the values for the coefficient of variation amongst the replicates of the control treatments were less than or equivalent to 20 %, complying with the acceptability criteria proposed by the ABNT guidelines (ABNT 2011ABNT - ASSOCIAÇÃO BRASILEIRA DE NORMAS TÉCNICAS. 2011. Toxicidade crônica. Método de ensaio com algas (Chlorophyceae) ABNT NBR12648, 2 nd ed, Rio de Janeiro: ABNT, 27 p.). Table IIshows the results for the algal density values verified after the exposure of R. subcapitata to Zn. The algal cells acclimated to the highest phosphorus value showed the highest cell density (4.49 x 10⁶ cells mL^-1) for the control treatment in comparison with the medium (2.24 x 10⁶ cells mL^-1) and low (1.77 x 10⁶ cells mL^-1) P concentrations (Tukey test, p<0.05), thus more phosphorus contributed to higher algal cell densities. A decrease in algal cell numbers was verified as the Zn concentrations increased in the test medium for the three P concentrations tested. The algal cells acclimated to 2.3 x 10^-4 mol L^-1 P showed the highest algal densities for all the phosphorus/zinc combinations tested (Tukey test, p<0.05).

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Table II
Mean algal density values (10⁶ cells mL^-1) after 96 h of exposure to the phosphorus and zinc treatments. Values with the same letters are not statistically different (Tukey Test, p>0.05). Values are means of three replicates (± Standard deviation).

Figure 1 shows the results for the IC 50 based in cell density at 96 h Zn exposure. The zinc IC 50 values for R. subcapitata were 0.24 x 10^-6 mol L^-1, 0.58 x 10^-6 mol L^-1 and 2.74 x 10^-6 mol L^-1 of free Zn²⁺ for the species acclimated at concentrations of 1.0 x 10^-6 mol L^-1; 2.3 x 10^-6 mol L^-1 and 2.3 x 10^-4 mol L^-1 of P, respectively, indicating that metal toxicity to the microorganism was reduced by the addition of phosphorus to the test medium (Tukey test, p<0.05).

Figure 1
IC 50 values for the R. subcapitata acclimated to the phosphorus concentrations. Bars with the same letters are not significantly different (Tukey’s test, p>0.05). Values are means of three replicates (± Standard deviation).

DISCUSSION

Interactions amongst environmental components control the growth and maintenance of algal communities. In this study, the chlorophyta R. subcapitata showed a reduction in density as a function of the decrease in P and increase in Zn in the test medium. Similarly, the cell densities of Chlamydomonas reinhardtii (Webster et al. 2011WEBSTER RE, DEAN AP & PITTMAN JK. 2011. Cadmium exposure and phosphorus limitation increases metal content in the freshwater alga Chlamydomonas reinhardtii. Environ Sci Technol 45: 7489-7496.), Selenastrum gracile (Rocha et al. 2016ROCHA GS, LOMBARDI AT & MELÃO MGG. 2016. Influence of phosphorus on copper toxicity to Selenastrum gracile. Ecotoxicol Environ Saf 128: 30-35.) and Chlorella sp. (Ji & Sherrel 2008JI Y & SHERRELL RM. 2008. Differential effects of phosphorus limitation on cellular metals in Chlorella and Microcystis. Limnol Oceanogr 53: 1790-1804., Chia et al. 2017CHIA MA, LOMBARDI AT, MELÃO MGG & PARRISH CC. 2017. Phosphorus levels determine changes in growth and biochemical composition of Chlorella vulgaris during cadmium stress. J Appl Phycol 29: 1883-1891.) significantly declined in response to phosphorus limitation in the growth medium. Zinc values above those considered essential can cause oxidative stress (Hamed et al. 2017HAMED SM, ZINTA G, KLÖCK G, ASARD H, SELIM S & ABDELGAWAD H. 2017. Zinc-induced differential oxidative stress and antioxidant responses in Chlorella sorokiniana and Scenedesmus acuminatus. Ecotox Environ Safe 140: 256-263.), inhibition of photosynthesis and cell division in green microalgae (Omar 2002OMAR HH. 2002. Adsorption of zinc ions by Scenedesmus obliquus and Scenedesmus quadricauda and its effect on growth and metabolism. Biol Plant 45: 261-266.). In the present study, after exposing R. subcapitata for 96 h to metal values of 0.14 x 10^-6 mol Zn²⁺ L^-1 (10^-6 mol P L^-1) and 2.27 x 10^-6 mol Zn²⁺ L^-1 (2.3 x 10^-4 mol P L^-1), the algal density was reduced. The data obtained corroborate those of Muyssen & Janssen (2001)MUYSSEN BTA & JANSSEN C. 2001. Zinc acclimation and its effect on the zinc tolerance of Raphidocelis subcapitata and Chlorella vulgaris in laboratory experiments. Chemosphere 45: 507-514. and Canli (2005)CANLI M. 2005. The transfer of zinc in two linked trophic levels in fresh water and its effect on the reproduction of Daphnia magna. J Freshw Ecol 20: 269-276. who showed inhibition of the growth of Pseudokirchneriella subcapitata in the presence of 0.6 x 10^-6 mol L^-1 and 10^-6 mol L^-1 of dissolved Zn, respectively.

The present study showed that besides the reduction in the algal growth rates, phosphorus had an important influence on the toxicity of zinc to R. subcapitata. The combination of a limited P supply and the presence of Zn was in the additive form, which implies that the two treatments inhibited the algal density more than their isolated effects. The IC 50 values for Zn²⁺ varied from 0.24 x 10^-6 mol L^-1 with limited nutrient to 2.74 x 10^-6 mol L^-1 with high supply of P. The value of 96 for the IC 50 registered for the treatment with the lowest P value tested (10^-6 mol L^-1) was 88% lower than the value obtained in the treatment with the highest P supply (2.3 x 10^-6 mol L^-1). The results of the present study agree with data in the literature about the interaction of metals and P for phytoplankton. Chia et al. (2017)CHIA MA, LOMBARDI AT, MELÃO MGG & PARRISH CC. 2017. Phosphorus levels determine changes in growth and biochemical composition of Chlorella vulgaris during cadmium stress. J Appl Phycol 29: 1883-1891. showed that the density of Chlorella vulgaris decreased with increasing Cd concentrations and decreasing P concentrations (2.3 x 10−⁴ to 6.0 x 10−⁷ mol L−¹). Rocha et al. (2016)ROCHA GS, LOMBARDI AT & MELÃO MGG. 2016. Influence of phosphorus on copper toxicity to Selenastrum gracile. Ecotoxicol Environ Saf 128: 30-35., evaluating the effect of P concentrations on copper toxicity for the chlorophyta Scenedesmus gracile, found that algal cells acclimated to low P values (2.3 x 10^-6 mol L^-1) were more sensitive to the metal. Qian et al. (2013)QIAN H, SUN Z, SUN L, JIANG Y, WEI Y, XIE J & FU Z. 2013. Phosphorus availability changes chromium toxicity in the freshwater alga Chlorella vulgaris. Chemosphere 93: 885-891. reported the inhibitory effect of chromium on the growth of Chlorella vulgaris with limitation P values (10^-9 mol L^-1). According to the authors, the tolerance of microalgae to metal toxicity with a high P supply is probably because microorganisms supplied with this nutrient resist metal toxicity better in comparison with algal cells under severely limited P conditions. In a phosphorus-rich environment, it has been reported that microalgae incorporate phosphorus as polyphosphate granules and these granules can bind metals, protecting the microorganisms from metal toxicity (Twiss & Nalewajko 1992TWISS MR & NALEWAJKO C. 1992. Influence of phosphorus nutrition on copper toxicity to three strains of Scenedesmus Acutus (Chlorophyceae). J Phycol 28: 291-298., Rai et al. 2001RAI LC & GAUR JP. 2001. Algal adaptation to environmental stresses: physiological, biochemical and molecular mechanisms, 6th ed., Berlin: Springer, 421 p., Lavoie et al. 2016LAVOIE M, RAVEN JA, JONES OAH & QIAN H. 2016. Energy cost of intracellular metal and metalloid detoxification in wild-type eukaryotic phytoplankton. Metallomics 2016: 1097-1109.). Also high phosphorus levels may alter the biochemical composition of the microalgae, promoting the synthesis of protective molecules such as phytochelatins (Hashemi et al. 1994HASHEMI F, LEPPARD GG & KUSHNER DJ. 1994. Copper resistance in Anabaena variabilis Effects of phosphate nutrition and polyphosphate bodies. Microb Ecol 27: 159-176., Wang et al. 2015WANG Y, WANG S, XU P, LIU C, LIU M, WANG Y, WANG C, ZHANG C & GE Y. 2015. Review of arsenic speciation, toxicity and metabolism in microalgae. Rev Environ Sci Biotechnol 14: 427-451.).

The growth of R. subcapitata was simultaneously regulated by phosphorus and zinc. It has been reported that under limited phosphate conditions, algae can produce the alkaline phosphatase enzyme, which plays an important role in the use of dissolved organic phosphate by phytoplankton (Rengefors et al. 2003RENGEFORS K, RUTTENBERG KC, HAUPERT CL, TAYLOR C & ANDERSON DM. 2003. Experimental investigation of taxon-specific response of alkaline phosphatase activity in natural freshwater phytoplankton. Limnol Oceanogr 48: 1167-1175., Ji & Sherrel 2008, Huang et al. 2009HUANG Z, LI L, HUANG G, YAN Q, SHI B & XU X. 2009. Growth-inhibitory and metal-binding proteins in Chlorella vulgaris exposed to cadmium or zinc. Aquat Toxicol 91: 54-61). According to Ji & Sherrel (2008), Zn is a necessary cofactor for APase activity. Thus the cellular uptake of zinc probably tends to increase when the algae manifest high APase activity, which could improve the access of metal into the cell and induce toxic cell alterations to the membrane system and photosynthetic apparatus (Cao et al. 2015CAO D, XIE P, DENG J, ZHANG H, MA R, LIU C, LIU R, LIANG Y, LI H & SHI X. 2015. Effects of Cu2+ and Zn2+ on growth and physiological characteristics of green algae, Cladophora. Environ Sci Pollut Res 22: 16535-16541.).

Concerning the comparison of the present data with that found in the literature, a variability of the effects of zinc on microalgae under different phosphorus conditions was found. Kamaya et al. (2004)KAMAYA Y, TAKADA T & SUZUKI K. 2004. Effect of medium phosphate levels on the sensitivity of Selenastrum capricornutum to chemicals. Bull Environ Contam Toxicol 73: 995-1000. observed no effects of P (0.6 x 10^-6 – 6 x 10^-6 mol L^-1) on Zn toxicity to Selenastrum capricornutum after 72 hours exposure. Gao et al. (2016)GAO C, DE SCHAMPHELAERE KAC & SMOLDERS E. 2016 Zinc toxicity to the alga Pseudokirchneriella subcapitata decreases under phosphate limiting growth conditions. Aquat Toxicol 173: 74-82. verified increasing zinc toxicity to P. subcapitata with a high cell P quota (1.7% P cell dry weight) in 24 h toxicity tests. The chemical equilibrium model MINEQL⁺ was used in the present study to calculate the free Zn ion concentrations and little zinc precipitation was credited to the phosphorus. In the present research, the evaluation of Zn toxicity to the microalgae was based on the free metal ion concentrations, while the authors mentioned above using nominal metal concentrations (Kamaya et al. 2004KAMAYA Y, TAKADA T & SUZUKI K. 2004. Effect of medium phosphate levels on the sensitivity of Selenastrum capricornutum to chemicals. Bull Environ Contam Toxicol 73: 995-1000.) and lower metal exposure times in their experiments (Kamaya et al. 2004KAMAYA Y, TAKADA T & SUZUKI K. 2004. Effect of medium phosphate levels on the sensitivity of Selenastrum capricornutum to chemicals. Bull Environ Contam Toxicol 73: 995-1000., Gao et al. 2016GAO C, DE SCHAMPHELAERE KAC & SMOLDERS E. 2016 Zinc toxicity to the alga Pseudokirchneriella subcapitata decreases under phosphate limiting growth conditions. Aquat Toxicol 173: 74-82.). Before the beginning the toxicity tests, the R. subcapitata cells were acclimated to the specific phosphorus treatment for four weeks. The acclimation period was necessary to guarantee that the physiology of the algae would reflect the nutrient starvation condition in the test medium and reduce the polyphosphate reserve (Rocha et al. 2016ROCHA GS, LOMBARDI AT & MELÃO MGG. 2016. Influence of phosphorus on copper toxicity to Selenastrum gracile. Ecotoxicol Environ Saf 128: 30-35., Chia et al. 2017CHIA MA, LOMBARDI AT, MELÃO MGG & PARRISH CC. 2017. Phosphorus levels determine changes in growth and biochemical composition of Chlorella vulgaris during cadmium stress. J Appl Phycol 29: 1883-1891.). Thus it was considered that the methodological differences amongst the studies could lead to different data and conclusions to the combined effect of the Zn and P supplies to green microalgae.

Many culture media have been employed to cultivate microalgae in ecotoxicological studies. The growth media used in this study was L.C.Oligo, which is recommended by the Brazilian standards (ABNT) for ecotoxicological assays with microalgae, and is considered to be cost effective with other culture media (Chia et al. 2013bCHIA MA, LOMBARDI AT, MELÃO MGG & PARRISH CC. 2013a. Lipid composition of Chlorella vulgaris (Trebouxiophyceae) as a function of different cadmium and phosphate concentrations. Aquat Toxicol 128-129: 171-182.). The present research showed that phosphorus limitation in a synthetic culture medium resulted in greater sensibility of R. subcapitata to metals. In the natural environment, phosphorus is the first element to regulate biological productivity and the least available in comparison to other nutrients (Bolier et al. 1992BOLIER G, DE KONINGH MCJ, SCHMALE JC & DONZE M. 1992. Differential luxury phosphate response of planktonic algae to phosphorus removal. Hydrobiologia 243/244: 113-118., Wetzel 2001WETZEL RG. 2001. Limnology: lake and river ecosystems. San Diego: Academic Press, 1006 p.). High production rates in laboratory-grown microalgae cultures depend on an appropriate supply of vitamins, trace elements and macronutrients, as well as other conditions, such as light, pH and temperature stability (Mostert & Grobbelaar 1997MOSTERT ES & GROBBELAAR JU. 1987. The influence of nitrogen and phosphorus on algal growth and quality in outdoor mass algal cultures. Biomass 13: 219-233.). Defined culture media are more appropriate in terms of the standardization of algal culture and testing conditions. However, standard algal toxicity bioassays using artificial culture media under controlled conditions may have little environmental applicability since the complex chemistry of natural waters differs from that of algal culture media (Ward et al. 2002WARD TJ, RAUSINA GA, STONEBRAKER PM & ROBINSON WE. 2002. Apparent toxicity resulting from the sequestering of nutrient trace metals during standard Selenastrum capricornutum toxicity tests. Aquat Toxicol 60: 1-16.). Besides, artificial culture media contain nutrients in higher quantities than are found in natural aquatic systems. In ecotoxicological studies, the choice of an algal culture medium requires a compromise between standardization on one hand and its ability to predict the real process, for a better understanding of algal responses to metals in environments with different trophic levels.

Ultimately, it is essential to consider that the methods employed in risk assessments for the regulation of metals may not be adequate for the protection of aquatic species. For example, Conama Resolution 357 established a limit of 2.75 x 10^-6 mol Zn L^-1 for the protection of aquatic biota in Brazilian aquatic ecosystems. However, this Brazilian guideline does not take into consideration the influence of phosphorus on metal toxicity to establish safe limits of zinc for aquatic life. It was demonstrated here that zinc values below the limits defined by the Brazilian guidelines (CONAMA 2005CONAMA - CONSELHO NACIONAL MEIO AMBIENTE. 2005. Resolução n° 357, de 17 de março de 2005. “Resolução do CONAMA para a classificação dos corpos de água para o seu enquadramento, bem como estabelecimento das condições e padrões de lançamento de efluentes”, Brasília, seção I, p. 58-63.) in aquatic environments with a low supply of phosphorus may well upset phytoplanktonic communities. Ecotoxicological investigations should consider the association between metal concentrations and different phosphorus conditions to provide more realistic data of what directly occurs in phytoplankton communities and indirectly in herbivorous consumers that depend on the microalgae in natural waters.

ACKNOWLEGMENTS

The authors are grateful to the grants # 2015/23951-6, 2015/19415-1 and 2016/22620-9 of the Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP).

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Publication Dates

Publication in this collection
06 Nov 2020
Date of issue
2020

History

Received
17 Jan 2019
Accepted
8 Apr 2019

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] ABNT - ASSOCIAÇÃO BRASILEIRA DE NORMAS TÉCNICAS. 2011. Toxicidade crônica. Método de ensaio com algas (Chlorophyceae) ABNT NBR12648, 2 nd ed, Rio de Janeiro: ABNT, 27 p.

[2] AFNOR - ASSOCIATION FRANÇAISE DE NORMALISATION. 1980. Essais dês eause. Norme experimentale T90-304. Determination de I’inhibition de Scenesdesmus subspicatus croissance par une substance. Paris: AFNOR.

[3] ALBANO PG, GALLMETZER I, HASELMAIR A, TOMAŠOVÝCH A, STACHOWITSCH M & ZUSCHIN M. 2018. Historical ecology of a biological invasion: the interplay of eutrophication and pollution determines time lags in establishment and detection. Biol Invasions 20: 1417-1430.

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Generation	2.3 x 10^-4 mol P L^-1	2.3 x 10^-6 mol P L^-1	1.0 x 10^-6 mol P L^-1
1	0.68^a ± 0.04	0.60^a ± 0.02	0.16^c ± 0.01
2	0.67^a ± 0.08	0.46^b ± 0.03	0.15^c ± 0.04
3	0.59^a ± 0.02	0.42^b ± 0.03	0.06^d ± 0.01
4	0.64^a ± 0.02	0.42^b ± 0.02	0.03^d± 0.00
5	0.60^a ± 0.02	0.46^b ± 0.03	0.04^d ± 0.02

Zn²⁺ (10^-6 mol L^-1)	Phosphorus (mol L^-1)
Zn²⁺ (10^-6 mol L^-1)	2.3 x 10^-4	2.3 x 10^-6	1 x 10^-6
0.09 (Control)	4.49 ± 0.9^a	2.24 ± 0.05^d,^h	1.77 ± 0.07^h
0.14	-	2.16 ± 0.17^d	1.16 ± 0.2ⁱ
0.28	-	1.75 ± 0.08^e	0.75 ± 0.13^j
0.57	3.90 ± 0.1^a,^b	1.13 ± 0.01^e,^l	0.62 ± 0.05^j,^l
1.13	3.88 ± 0.1^a,^b	0.12 ± 0.05^f,^m	0.59 ± 0.01^j,^m
2.27	2.55 ± 0.04^b	0.06 ± 0.02^f,^g,^k	0.05 ± 0.06^k
4.54	0.42 ± 0.01^c	0.05 ±0.01^f,^g	-
9.08	0.08 ± 0.01^c	0.01 ± 0.0^g	-

Brasil