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RESEARCH ARTICLE
Contents Vol 69(8)

Fluoride hyperaccumulation in Gastrolobium species (Fabaceae) from Western Australia

Farida Abubakari https://orcid.org/0000-0002-2669-5854 A , Philip Nti Nkrumah A , Jonty Flottmann A , Arezu Alizadeh B and Antony van der Ent A *
+ Author Affiliations
- Author Affiliations

A Centre for Mined Land Rehabilitation, Sustainable Minerals Institute, The University of Queensland, Saint Lucia, Qld, Australia.

B Faculty of Natural Resources, Department of Range Management, Sari Agricultural Sciences and Natural Resources University, Mazandaran Province, Sari, Iran.

* Correspondence to: a.vanderent@uq.edu.au

Handling Editor: Garry Cook

Australian Journal of Botany 69(8) 516-526 https://doi.org/10.1071/BT21037
Submitted: 13 March 2021  Accepted: 13 July 2021   Published: 7 October 2021

© 2021 The Author(s) (or their employer(s)). Published by CSIRO Publishing

Abstract

Members of the Australian endemic plant genus Gastrolobium (Fabaceae) naturally accumulate fluoride (F) in the form of fluoroacetate when growing on soils with very low F status. However, it is unknown how Gastrolobium species respond to higher soil F concentrations, and what the interactions are between cations (Na+, Mg2+, K+, Ca2+) and anions (Cl, F, SO42−) in their leaves. In this study, we exposed G. bilobum, G. parviflorum and G. parvifolium to soils with different levels of soluble F (as sodium fluoride solution applied to soil at 0, 1, 10, 50, 100 μg F g−1). The plants were grown for a period of 12 months before being harvested and acid- and water-extractable F in shoots analysed using ion chromatography. Gastrolobium leaves accumulated extremely high F with highest concentrations in young leaves in the highest treatment level. In G. parviflorum, the mean concentration of F in young leaves was >8000 μg g−1 for both methods of extraction, whereas G. parvifolium had 6940 and 3630 μg g−1 in young leaves for the water-soluble and acid extraction methods respectively. In young leaves of G. bilobum, the concentration of F was 1840 and 7970 μg g−1 for the water-soluble and acid extraction methods respectively. This study further revealed significant amounts of Cl and SO42− in foliage of the studied species. Moreover, we found F and SO42− to be positively correlated in young leaves of G. bilobum, but inversely related in its old leaves. These findings have shown for the first time the potential of Gastrolobium species to accumulate F in soils with high F concentrations, highlighting potential for applications in phytoremediation.

Keywords: chemical defence, contaminated soils, Fabaceae, fluoride, fluoroacetate, Gastrolobium, phytoremediation.


References

Aplin T (1969) Poison plants of Western Australia: the toxic species of the genera Gastrolobium and Oxylobium: Champion Bay poison (G. oxylobioides Benth.), sandplain poison (G. microcarpum Meissn.), cluster poison (G. bennettsianum CA Gardn.), Hutt River poison (G. propinquum CA Gardn.), gilbernine poison (G. rotundifolium Meissn.). Journal of the Department of Agriculture, Western Australia, Series 4 10, 248–257.

Aplin T (1971) Poison plants of Western Australia: the toxic species of the genera Gastrolobium and Oxylobium: thick-leaf poison (Gastrolobium crassifolium Benth.), narrow-leaf poison (Gastrolobium stenophyllum Turcz.), mallet poison (Gastrolobium densifolium CA Gardn.), wall-flower poison (Gastrolobium grandifolorum F. Muell). Journal of the Department of Agriculture, Western Australia, Series 4 12, 12–18.

Arnesen A (1997) Availability of fluoride to plants grown in contaminated soils. Plant and Soil 191, 13–25.
Availability of fluoride to plants grown in contaminated soils.Crossref | GoogleScholarGoogle Scholar |

Arnesen A (1998) Effect of fluoride pollution on pH and solubility of Al, Fe, Ca, Mg, K and organic matter in soil from Årdal (western Norway). Water, Air, and Soil Pollution 103, 375–388.
Effect of fluoride pollution on pH and solubility of Al, Fe, Ca, Mg, K and organic matter in soil from Årdal (western Norway).Crossref | GoogleScholarGoogle Scholar |

Baunthiyal M, Ranghar S (2015) Accumulation of fluoride by plants: potential for phytoremediation. Clean – Soil, Air, Water 43, 127–132.
Accumulation of fluoride by plants: potential for phytoremediation.Crossref | GoogleScholarGoogle Scholar |

Baunthiyal M, Bhatt A, Ranghar S (2014) Fluorides and its effects on plant metabolism. International Journal of Agricultural Technology 10, 1–27.

Bell A, Newton L, Everist S, Legg J (1955) Acacia georginae poisoning of cattle and sheep. Australian Veterinary Journal 31, 249–257.
Acacia georginae poisoning of cattle and sheep.Crossref | GoogleScholarGoogle Scholar |

Chandler GT, Crisp MD, Cayzer LW, Bayer RJ (2002) Monograph of Gastrolobium (Fabaceae: Mirbelieae). Australian Systematic Botany 15, 619–739.
Monograph of Gastrolobium (Fabaceae: Mirbelieae).Crossref | GoogleScholarGoogle Scholar |

Cronin S, Manoharan V, Hedley M, Loganathan P (2000) Fluoride: a review of its fate, bioavailability, and risks of fluorosis in grazed‐pasture systems in New Zealand. New Zealand Journal of Agricultural Research 43, 295–321.
Fluoride: a review of its fate, bioavailability, and risks of fluorosis in grazed‐pasture systems in New Zealand.Crossref | GoogleScholarGoogle Scholar |

Davison A (1983) Uptake, transport and accumulation of soil and airborne fluorides by vegetation In ‘Fluorides: effects on vegetation, animals and humans’. (Eds JL Shupe, HB Peterson, NC Leone) pp. 61–82. (Paragon Press: Salt Lake City, UT, USA)

Davison A, Takmaz-Nisancioglu S, Bailey IF (1985) The dynamics of fluoride accumulation by vegetation. In ‘Fluoride toxicity’. (Ed. AK Susheela) pp. 30–46. (ISFR: New Delhi, India)

De Oliveira MM (1963) Chromatographic isolation of monofluoroacetic acid from Palicourea marcgravii St. Hil. Experientia 19, 586–587.

del Socorro Santos-Díaz M, Zamora-Pedraza C (2010) Fluoride removal from water by plant species that are tolerant and highly tolerant to hydrogen fluoride. Fluoride 43, 150–156.

Domingos M, Klumpp A, Rinaldi M, Modesto I, Klumpp G, Delitti W (2003) Combined effects of air and soil pollution by fluoride emissions on Tibouchina pulchra Cogn., at Cubatão, SE Brazil, and their relations with aluminium. Plant and Soil 249, 297–308.
Combined effects of air and soil pollution by fluoride emissions on Tibouchina pulchra Cogn., at Cubatão, SE Brazil, and their relations with aluminium.Crossref | GoogleScholarGoogle Scholar |

Elloumi N, Abdallah FB, Mezghani I, Rhouma A, Boukhris M, Tunisia S (2005) Effect of fluoride on almond seedlings in culture solution. Fluoride 38, 193–198.

Foy C, Chaney RT, White M (1978) The physiology of metal toxicity in plants. Annual Review of Plant Physiology 29, 511–566.
The physiology of metal toxicity in plants.Crossref | GoogleScholarGoogle Scholar |

Gardner CA, Bennetts HW (1956) ‘The toxic plants of Western Australia.’ (West Australian Newspapers: Perth, WA, Australia)

Garrec J, Letourneur L (1981) Fluoride absorption by the root and foliar tissues of the horse-bean (calicole) and lupin (calcifuge). Fluoride 14, 30–80.

Gautam R, Bhardwaj N (2010) Bioaccumulation of fluoride in different plant parts of Hordeum vulgare (barley) var. RD-2683 from irrigation water. Fluoride 43, 57–60.

Haidouti C, Chronopoulou A, Chronopoulos J (1993) Effects of fluoride emissions from industry on the fluoride concentration of soils and vegetation. Biochemical Systematics and Ecology 21, 195–208.
Effects of fluoride emissions from industry on the fluoride concentration of soils and vegetation.Crossref | GoogleScholarGoogle Scholar |

Hall RJ (1972) The distribution of organic fluorine in some toxic tropical plants. New Phytologist 5, 855–871.

Horntvedt R (1997) Accumulation of airborne fluorides in forest trees and vegetation. European Journal of Forest Pathology 27, 73–82.
Accumulation of airborne fluorides in forest trees and vegetation.Crossref | GoogleScholarGoogle Scholar |

Jacobson JS, Weinstein LH, McCune D, Hitchcock A (1966) The accumulation of fluorine by plants. Journal of the Air Pollution Control Association 16, 412–417.
The accumulation of fluorine by plants.Crossref | GoogleScholarGoogle Scholar | 5945836PubMed |

Kabata-Pendias A (2010) ‘Trace elements in soils and plants’, 4th edn. (CRC Press: Boca Raton, FL, USA)

Keighery G (1982) Bird pollinated plants in Western Australia and their breeding systems. In ‘Pollination and evolution’. pp. 77–89. (Royal Botanic Gardens: Sydney, NSW, Australia)

Kronberger W, Halbwachs G, Richter H (1978) Distribution of fluoride in Zea mays grown near an aluminum plant. Fluoride 12, 129–135.

Lee ST, Cook D, Pfister JA, Allen JG, Colegate SM, Riet-Correa F, Taylor CM (2014) Monofluoroacetate-containing plants that are potentially toxic to livestock. Journal of Agricultural and Food Chemistry 62, 7345–7354.
Monofluoroacetate-containing plants that are potentially toxic to livestock.Crossref | GoogleScholarGoogle Scholar | 24724702PubMed |

Leone IA, Brennan E, Daines R (1956) Atmospheric fluoride: its uptake and distribution in tomato and corn plants. Plant Physiology 31, 329
Atmospheric fluoride: its uptake and distribution in tomato and corn plants.Crossref | GoogleScholarGoogle Scholar | 16654894PubMed |

MacLean D, Hansen K, Schneider R (1992) Amelioration of aluminium toxicity in wheat by fluoride. New Phytologist 121, 81–88.
Amelioration of aluminium toxicity in wheat by fluoride.Crossref | GoogleScholarGoogle Scholar |

Macuch P, Hluchan E, Mayer J, Able E (1969) Air pollution by fluoride compounds near an aluminium factory. Fluoride 2, 28–32.

McEwan T (1964) Isolation and identification of the toxic principle of Gastrolobium grandiforum. Queensland Journal of Agricultural Science 21, 1–14.

Medeiros R, Neto S, Barbosa RC, Lima EF, Riet-Correa F (2002) Sudden bovine death from Mascagnia rigida in Northeastern Brazil. Veterinary and human toxicology 44, 286–288.

Nwude N, Parsons L, Adaudi A (1977) Acute toxicity of the leaves and extracts of Dichapetalum barteri (Engl.) in mice, rabbits and goats. Toxicology 7, 23–29.
Acute toxicity of the leaves and extracts of Dichapetalum barteri (Engl.) in mice, rabbits and goats.Crossref | GoogleScholarGoogle Scholar | 402711PubMed |

Oelrichs P, McEwan T (1961) Isolation of the toxic principle in Acacia georginae. Nature 190, 808–809.
Isolation of the toxic principle in Acacia georginae.Crossref | GoogleScholarGoogle Scholar | 13730334PubMed |

Peacock DE, Williams BD, Christensen PE (2007) ‘Total fluorine’ analysis of seed of Australian Gastrolobium spp. showing temporal, spatial and morphological variation. Journal of Fluorine Chemistry 128, 631–635.
‘Total fluorine’ analysis of seed of Australian Gastrolobium spp. showing temporal, spatial and morphological variation.Crossref | GoogleScholarGoogle Scholar |

Peters R, Hall R, Ward P, Sheppard N (1960) The chemical nature of the toxic compounds containing fluorine in the seeds of Dichapetalum toxicarium. Biochemical Journal 77, 17
The chemical nature of the toxic compounds containing fluorine in the seeds of Dichapetalum toxicarium.Crossref | GoogleScholarGoogle Scholar |

Peters R, Shorthouse M (1964) Fluoride metabolism in plants. Nature 202, 21
Fluoride metabolism in plants.Crossref | GoogleScholarGoogle Scholar | 14166713PubMed |

Reddy MP, Kaur M (2008) Sodium fluoride induced growth and metabolic changes in Salicornia brachiata Roxb. Water, Air, and Soil Pollution 188, 171–179.
Sodium fluoride induced growth and metabolic changes in Salicornia brachiata Roxb.Crossref | GoogleScholarGoogle Scholar |

Romell LG (1941) Localized injury to plant organs from hydrogen fluoride and other acid gases. Svensk Botanisk Tidskrift 35, 271–286.

Ruan J, Ma L, Shi Y, Han W (2003) Uptake of fluoride by tea plant (Camellia sinensis L.) and the impact of aluminium. Journal of the Science of Food and Agriculture 83, 1342–1348.
Uptake of fluoride by tea plant (Camellia sinensis L.) and the impact of aluminium.Crossref | GoogleScholarGoogle Scholar |

Ruan J, Ma L, Shi Y, Han W (2004) The impact of pH and calcium on the uptake of fluoride by tea plants (Camellia sinensis L.). Annals of Botany 93, 97–105.
The impact of pH and calcium on the uptake of fluoride by tea plants (Camellia sinensis L.).Crossref | GoogleScholarGoogle Scholar | 14644914PubMed |

Stevens D, McLaughlin MJ, Alston A (1995) Limitations of acid digestion techniques for the determination of fluoride in plant material. Communications in Soil Science and Plant Analysis 26, 1823–1842.
Limitations of acid digestion techniques for the determination of fluoride in plant material.Crossref | GoogleScholarGoogle Scholar |

Stevens D, McLaughlin MJ, Alston A (1997) Phytotoxicity of aluminium–fluoride complexes and their uptake from solution culture by Avena sativa and Lycopersicon esculentum. Plant and Soil 192, 81–93.
Phytotoxicity of aluminium–fluoride complexes and their uptake from solution culture by Avena sativa and Lycopersicon esculentum.Crossref | GoogleScholarGoogle Scholar |

Stevens D, McLaughlin MJ, Alston A (1998) Phytotoxicity of the fluoride ion and its uptake from solution culture by Avena sativa and Lycopersicon esculentum. Plant and Soil 200, 119–129.
Phytotoxicity of the fluoride ion and its uptake from solution culture by Avena sativa and Lycopersicon esculentum.Crossref | GoogleScholarGoogle Scholar |

Takmaz‐Nisancioglu S, Davison A (1988) Effects of aluminium on fluoride uptake by plants. New Phytologist 109, 149–155.
Effects of aluminium on fluoride uptake by plants.Crossref | GoogleScholarGoogle Scholar |

Telesinski A, Snioszek M, Smolik B, Malinowska K, Mikiciuk M, Cichocka J, Zakrzewska H (2011) Fluoride uptake in hydroponic culture by different clones of basket willow, Salix viminalis L. Fluoride 44, 255

Twigg L (2014) Fluoroacetate, plants, animals and a biological arms race. In ‘Plant life on the sandplains in Southwest Australia: a global biodiversity hotspot’. (Ed. H Lambers) pp. 225–240. (UWA Publishing: Crawley, WA, Australia)

Twigg LE (1994) Occurrence of fluoroacetate in Australian plants and tolerance to 1080 in indigenous Australian animals. In ‘Proceedings, science workshop on 1080. The Royal Society of New Zealand Miscellaneous Series 28’, 12–14 December 1993, Christchurch, New Zealand. (Eds AA Seawright, CT Eason) pp. 97–115. (Royal Society of New Zealand: Wellington, New Zealand)

Twigg L, Socha L (1996) Physical versus chemical defence mechanisms in toxic Gastrolobium. Oecologia 108, 21–28.

Twigg LE, King DR (1991) The impact of fluoroacetate-bearing vegetation on native Australian fauna: a review. Oikos 61, 412–430.
The impact of fluoroacetate-bearing vegetation on native Australian fauna: a review.Crossref | GoogleScholarGoogle Scholar |

Twigg LE, King DR, Bowen LH, Wright GR, Eason CT (1996) Fluoroacetate content of some species of the toxic Australian plant genus, Gastrolobium, and its environmental persistence. Natural Toxins 4, 122–127.
Fluoroacetate content of some species of the toxic Australian plant genus, Gastrolobium, and its environmental persistence.Crossref | GoogleScholarGoogle Scholar | 8743933PubMed |

van der Ent A, Pollard AJ, Echevarria G, Abubakari F, Erskine PD, Baker AJ, Reeves RD (2021) Exceptional uptake and accumulation of chemical elements in plants: extending the hyperaccumulation paradigm. In ‘Agromining: farming for metals. Mineral resource reviews’. (Eds A van der Ent, AJ Baker, G Echevarria, MO Simonnot, JL Morel) pp. 99–131. (Springer: Cham, Switzerland).
| Crossref |

Venkateswarlu P, Armstrong W, Singer L (1965) Absorption of fluoride and chloride by barley roots. Plant Physiology 40, 255
Absorption of fluoride and chloride by barley roots.Crossref | GoogleScholarGoogle Scholar | 14285019PubMed |

Vike E, Håbjørg A (1995) Variation in fluoride content and leaf injury on plants associated with three aluminium smelters in Norway. Science of the Total Environment 163, 25–34.
Variation in fluoride content and leaf injury on plants associated with three aluminium smelters in Norway.Crossref | GoogleScholarGoogle Scholar |

Weinstein L, Alscher-Herman R (1982) Physiological responses of plants to fluorine. In ‘Effects of gaseous pollutants in agriculture and horticulture’. (Eds MH Unsworth, DP Ormrod) pp. 139–167. (Butterworths: London, UK)

Weinstein LH (1977) Fluoride and plant life. Journal of Occupational and Environmental Medicine 19, 49–78.
Fluoride and plant life.Crossref | GoogleScholarGoogle Scholar |

Yang Y, Liu Y, Huang C-F, de Silva J, Zhao F-J (2016) Aluminium alleviates fluoride toxicity in tea (Camellia sinensis. Plant and Soil 402, 179–190.
Aluminium alleviates fluoride toxicity in tea (Camellia sinensis.Crossref | GoogleScholarGoogle Scholar |

Zimmerman P, Hitchcock A, Gwirtsman J (1957) Fluorine in food with special reference to tea. Contributions from Boyce Thompson Institute 19, 49–53.