Effect of arsenate on germination and early development parameters of three forage leguminous plants

Authors

  • Cristina V. Alvarez Gonçalvez Universidad de Buenos Aires. Facultad de Ciencias Veterinarias. Cátedra de Química Orgánica de Biomoléculas. Buenos Aires, Argentina http://orcid.org/0000-0002-6692-3911
  • Magali Rodriguez Universidad de Buenos Aires. Facultad de Ciencias Veterinaria. Centro de Estudios Transdisciplinarios del Agua (CETA). Buenos Aires, Argentina.
  • Alicia Fernández Cirelli Universidad de Buenos Aires. Facultad de Ciencias Veterinaria. Centro de Estudios Transdisciplinarios del Agua (CETA). Buenos Aires, Argentina1Instituto de Investigaciones en Producción Animal (INPA), CONICET-UBA. Av. Chorroarín Nº 280 C1427CWO. Ciudad de Buenos Aires, Argentina.
  • Alejo Leopoldo Pérez Carrera Universidad de Buenos Aires. Facultad de Ciencias Veterinaria. Centro de Estudios Transdisciplinarios del Agua (CETA). Buenos Aires, Argentina1Instituto de Investigaciones en Producción Animal (INPA), CONICET-UBA. Av. Chorroarín Nº 280 C1427CWO. Ciudad de Buenos Aires, Argentina.

DOI:

https://doi.org/10.5965/223811711922020236

Keywords:

arsenic, forage, seeds

Abstract

The Chacopampean plain is one of the most arsenic affected areas in Argentina, especially in groundwater, used both for animal drinking and forage irrigation. The main objective of this study was to determine the effect of arsenic (As) present in irrigation water on the germination parameters of red clover (Trifolium pratense L.), white clover (Trifolium repens L.), and alfalfa (Medicago sativa L.) seeds exposed to different concentrations of As(V). The germination and viability parameters of seeds from the three species were not affected by elevated concentrations of As. However, As significantly reduced the radicle and hypocotyl lengths of the three forage specimens. The inhibition level of the plants increased with the increase in the  concentration of As. Regarding to hypocotyl length/radicle length ratio, the results evidenced that both the hypocotyl and radicle of clover species are affected in the same degree, while alfalfa radicles seemed more affected than hypocotyls at higher concentrations of As. Our results showed that irrigation with solutions containing As affect seedling growth parameters differently in the three species, and the effect of As is mostly evidenced when in high concentrations.

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References

AHMED FRS et al. 2006. Influences of arbuscular fungus Glomus mosseae on growth and nutrition of lentil irrigated with arsenic contaminated water. Plant and soil 283: 33-41.

ALARCÓN-HERRERA MT et al. 2013. Co-occurrence of arsenic and fluoride in groundwater of semi-arid regions in Latin America: Genesis, mobility and remediation. Journal of Hazardous Materials 262: 960-969.

ALONSO DL et al. 2014. Environmental occurrence of arsenic in Colombia: A review. Environmental Pollution 186: 272-281.

AMARAL CD et al. 2013. Sample preparation for arsenic speciation in terrestrial plants - a review. Talanta 15: 291-299.

BATISTA BL et al. 2014. Identification and quantification of phytochelatins in roots of rice to long-term exposure: evidence of individual role on arsenic accumulation and translocation. Journal of Experimental Botany 65: 1467-1469.

BECH J et al. 1997. Arsenic and heavy metal contamination of soil and vegetation around a copper mine in Northern Peru. Science of The Total Environment 203: 83-91.

BHATTACHARJEE P et al. 2013. Role of genomic instability in arsenic-induced carcinogenicity. A review. Environment International 53: 29-40.

BROCATO J et al. 2015. A Potential New Mechanism of Arsenic Carcinogenesis: Depletion of Stem-Loop Binding Protein and Increase in Polyadenylated Canonical Histone H3. 1 mRNA. Biologial Trace Elemement Research 166: 72-81.

BUNDSCHUH J et al. 2008. IBEROARSEN: Distribución de arsénico en las Regiones Ibérica e Iberoamericana. Buenos Aires: CYTED. 230p.

BUNDSCHUH M et al. 2012. ‘One century of arsenic exposure in Latin America: a review of history and occurrence from 14 countries’, Science of The Total Environment 429: 2-35.

CARBONELL-BARRACHINA AA et al. 1998. Response of bean micronutrient nutrition to arsenic and salinity. Journal of Plant Nutricion 21: 1287-1299.

CARRASCO JA et al. 2005. Isolation and characterization of symbiotically effective Rhizobium resistant to arsenic and heavy metals after the toxic spill at the Aznalcóllar pyrite mine. Soil Biology and Biochemistry 37: 1131-1140.

CHAMORRO D et al. 2016. Reproductive output, seed anatomy and germination under water stress in the seeder Cistus ladanifer subjected to experimental drought. Environmental and Experimental Botany 123: 59-67.

CHEN BD et al. 2007. The arbuscular mycorrhizal fungus Glomus mosseae gives a contradictory effect on phosphorous and arsenic acquisition by Medicago sativa Linn. Science of The Total Environment 379: 226-234.

CHEN LR et al. 2016. Recent development in arsenic speciation and toxicity reduction of inorganic arsenic in food. European Journal of BioMedical Research 2: 27-31.

CHRISTOPHERSEN HM et al. 2012. Unraveling the influence of arbuscular mycorrhizal colonization on arsenic tolerance in Medicago: Glomus mosseae is more effective than G. intraradices, associated with lower expression of root epidermal Pi transporter genes. Frontiers in physiology 3: 91.

COHEN SM et al. 2013. Evaluation of the carcinogenicity of inorganic arsenic. Critical Reviews in Toxicology 43: 711-752.

DONG Y et al. 2008. Arbuscular mycorrhiza enhanced arsenic resistance of both white clover (Trifolium repens Linn.) and ryegrass (Lolium perenne L.) plants in an arsenic-contaminated soil. Environmental Pollution 1585: 174-181.

GREENE JC et al. 1988. Protocols for short term toxicity screening of hazardous waste sites. EPA 600/3. Washington: Environmental Protection Agency.

ESTEBAN E et al. 2003. High-affinity phosphate/arsenate transport in white lupin (Lupinus albus) is relatively insensitive to phosphate status. New Phytologist 158: 165-173.

FARIAS SS et al. 2003. Natural contamination with arsenic and other trace elements in ground waters of Argentine Pampean Plain. Science of The Total Environment 309: 187-199.

FARNESE FS et al. 2014. Effects of adding nitroprusside on arsenic stressed response of Pistia stratiotes L. under hydroponic conditions. International Journal Phytoremediaion 16: 123-137.

FU Y et al. 2011. Occurrence of arsenic in brown rice and its relationship to soil properties from Hainan Island, China. Environmental Pollution 159: 1757-1762.

HAMILTON MA et al. 1977. Trimmed Spearman-Karber Method for estimating median lethal concentrations in toxicity bioassays. Environmental Science and Technology 11: 714-719.

HARTLEY W & LEPP NW 2008. Effect of in situ soil amendments on arsenic uptake in successive harvests of ryegrass (Lolium perenne cv Elka) grown in amended As-polluted soils. Environmental Pollution 156: 1030-1040.

HUANG TL et al. 2012. Transcriptomic changes and signalling pathways induced by arsenic stress in rice roots. Plant Molecular Biology 80: 587-608.

IBRAHIM EA. 2016. Seed priming to alleviate salinity stress in germinating seeds. Journal of Plant Physiology 192: 38-46.

IRIEL et al. 2015. Effect of arsenic on reflectance spectra and chlorophyll fluorescence of aquatic plants. Chemosphere 119: 697-703.

ISLAM E et al. 2015. Biochemical mechanisms of signaling: Perspectives in plants under arsenic stress. Ecotoxicology and Environmental Safety 114: 126-133.

KHAN MS et al. 2009. Role of plant growth promoting rhizobacteria in the remediation of metal contaminated soils Environmental Chemestry Letters 7: 1-19.

LA FUENTE A et al. 2010. Reduced nodulation in alfalfa induced by arsenic correlates with altered expression of early nodulins. Journal of Plant Physiology 167: 286-291.

LARA-NUÑEZ A et al. 2015. Phytotoxicity of Sicyos deppei during tomato germination and its effects on the role of ABA and cell wall enzymes. Botanical Sciences 93(4): 771-781.

LI CX et al. 2007. Effects of arsenic on seed germination and physiological activities of wheat seedlings. Journal of Environmental Science 19: 725-732.

LI N et al. 2016. Arsenic uptake and translocation in plants. Plant and Cell Physiology 57: 4-13.

LI W et al. 2005. Effects of heavy metals on seed germination and early seedling growth of Arabidopsis thaliana. Plant Growth Regulation 46: 45-50.

LIU Q et al. 2008. Effect of As on As uptake, speciation and nutrient uptake by winter wheat (Triticum aestivum L.) under hydroponic conditions. Journal of Environmental Sciences 20: 326-331.

LOMAX C et al. 2012. Methylated arsenic species in plants originate from soil microorganisms. The New Phytologist 193: 665-672.

LUAN ZQ et al. 2008. Individual and combined phytotoxic effects of cadmium, lead and arsenic on soy bean in Phaeozem. Plant Soil and Environment 54: 403-411.

MA JF et al. 2008. Transporters of arsenite in rice and their role in arsenic accumulation in rice grain. Proceedings of the National Academy of Sciences of the United States of America 105: 9931-9935.

MA LQ. 2001. A fern that hyperaccumulates arsenic. Nature 411: 579.

MA QF et al. 2009. Effects of arsenic on seed germination and seedling growth in three green manure seeds. Guangxi Agricultural Sciences 40: 1577-1581.

MACUR RE et al. 2001. Microbial populations associated with the reduction on enhanced mobilization of arsenic in mine tailings. Environmental Science Technology 35: 3676-3682.

MARQUEZ AP et al. 2007. Effect of arsenic, lead and zinc on seed germination and plant growth in black nightshade (Solanum nigrum L.) vs. clover (Trifolium incarnatum L.). Fresenius Environmental Bulletin 16: 896-903.

MARQUEZ-GARCIA R et al. 2012. Arsenic speciation in soils and Erica andevalensis Cabezudo & Rivera and Erica australis L. from São Domingos Mine area, Portugal. Journal of Geochemical Exploration 119-120: 51-59.

MASCHER R et al. 2002. Arsenate toxicity: effects on oxidative stress response molecules and enzymes in red clover plants. Plant Science 163: 961-969.

MITEVA E. 2002. Accumulation and effect of arsenic on tomatoes. Journal of Communications in Soil Science and Plant Analysis 33: 1917-1926.

NICOLLI HB et al. 1989. Groundwater contamination with arsenic and other trace elements in an area of the Pampa, Province of Córdoba, Argentina. Environmental Geology and Water Sciences 14: 3-16.

PAJUELO E et al. 2008. Toxic effects of arsenic on Sinorhizobium - Medicago sativa symbiotic interaction. Environmental Pollution 154: 203-211.

PÉREZ-CARRERA AL & FERNÁNDEZ-CIRELLI A. 2013. Niveles de arsénico y vanadio en aguas naturales en el Departamento de Unión, sudeste de la provincia de Córdoba, Argentina. Augm Domus 5: 19-28

PÉREZ-CARRERA AL & FERNÁNDEZ-CIRELLI A. 2014. Arsenic biotransference to alfalfa (Medicago sativa). International Journal of Environment and Health 7: 31-40.

RAHMAN MA & HASEGAWA H. 2011. Aquatic arsenic: phytoremediation using floating macrophytes. Chemosphere 83: 633-646.

RAI A et al. 2011. Arsenic tolerances in rice (Oryza sativa) have a predominant role in transcriptional regulation of a set of genes including sulphur assimilation pathway and antioxidant system. Chemosphere 82: 986-995.

SEREGIN IV & KOZHEVNIKOVA AD. 2005. Distribution of Cadmium, Lead, Nickel, and Strontium in Imbibing Maize Caryopsis. Russian Journal of Plant Physiology 52: 565-569.

SHAIBUR MRK et al. 2008. Critical toxicity of arsenic and elemental composition of arsenic induced chlorosis in hydroponic Sorghum. Water Air Soil Pollution 191: 279-292.

SHRI M et al. 2009. Effect of arsenic on growth, oxidative stress, and antioxidant system in rice seedlings. Ecotoxicology and Environmental Safety 72: 1102-1110.

SMEDLEY PL & KINNIBURGH DG. 2002. A review of the source, behaviour and distribution of arsenic in natural waters. Applied Geochemistry 17: 517-568.

SMITH SE et al. 2010. Arsenic uptake and toxicity in plants: integrating mycorrhizal influences. Plant and Soil 327: 1-21.

SRIVASTAVA M et al. 2005. Antioxidant responses of hyperaccumulator and sensitive fern species to arsenic. Journal of Experimental Botany 56: 1335-1342.

TALUKDAR D. 2011. Effect of arsenic-induced toxicity on morphological traits of Trigonella foenum-graecum L. and Lathyrus sativus L. during germination and early seedling growth. Current Research Journal of Biological Sciences 3: 116-123.

UPADHYAYA H et al. 2014. Arsenic Induced Changes in Growth and Physiological Responses in Vigna radiata Seedling: Effect of Curcumin Interaction. American Journal of Plant 5: 3609-3618.

USEPA. 1999. United States Environmental Protection Agency. Trimmed Spearman-Karber estimation of LC50 Values Users’ Manual. Athens: Ecosystems Research Division.

VAZQUEZ ALDANA BR et al. 2013. Germination response of endophytic Festuca rubra seeds in the presence of arsenic. Grass and Forage Science 69: 462-469.

WAALKES MP et al. 2004. Mechanisms underlying arsenic carcinogenesis: hypersensitivity of mice exposed to inorganic arsenic during gestation. Toxicology 198: 31-38.

XU XY et al. 2008. Growing rice aerobically markedly decreases arsenic accumulation. Environmental Science Technology 42: 5574-5579.

YOON Y et al. 2015. Phytotoxicity of arsenic compounds on crop plant seedlings. Environmental Science and Pollution Research International 22: 11047-11056.

ZAR JH et al. 1996. Biostatistical analysis, Third ed., Prentice Hall, Inc. New Jersey.

ZHANG W et al. 2015. Biotransformation and detoxification of inorganic arsenic in Bombay oyster Saccostrea cucullata. Aquatic Toxicology 158: 33-40.

ZHAO FJ et al. 2009. Arsenic uptake and metabolism in plants. The New Pythologist 181: 777-794.

ZHAO FJ et al. 2010. Arsenic as a food chain contaminant: mechanisms of plant uptake and metabolism and mitigation strategies. Annual Review of Plant Biology 61: 535-559.

ZHU YG et al. 2014. Earth Abides Arsenic Biotransformations. Annual Review of Earth and Planetary Sciences 42: 443-467.

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Published

2020-06-30

How to Cite

ALVAREZ GONÇALVEZ, Cristina V.; RODRIGUEZ, Magali; FERNÁNDEZ CIRELLI, Alicia; PÉREZ CARRERA, Alejo Leopoldo. Effect of arsenate on germination and early development parameters of three forage leguminous plants. Revista de Ciências Agroveterinárias, Lages, v. 19, n. 2, p. 236–244, 2020. DOI: 10.5965/223811711922020236. Disponível em: https://revistas.udesc.br/index.php/agroveterinaria/article/view/15838. Acesso em: 23 nov. 2024.

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Section

Research Note - Science of Plants and Derived Products