Accumulation of cadmium, copper and zinc in selected natural Viola taxa in Turkish Mediterranean serpentine soils

Yıl 2021, Cilt: 5 Sayı: 2, 138 - 143, 15.11.2021

Ahmet Aksoy

https://doi.org/10.30616/ajb.999023

Cited By: 1

Öz

Currently, 55 serpentine areas have been determined in Turkey. More than 60 Ni-accumulators and more than 43 serpentine-endemics are known from these areas. Within our field studies in the Mediterranean phytogeographic region, 8 Viola taxa distributed in serpentine areas and their respective soil samples were collected. Cd, Cu, and Zn concentrations of the soil and plant samples were investigated. After the plant and soil samples were digested in the microwave, metal measurements were made using a ICP-OES device. As a result of the Cd, Cu, and Zn measurements, none of the 8 Viola taxa collected from different localities were found to be hyperaccumulators. However, it was determined that Viola kizildaghensis has an accumulator feature in terms of Zn.

Anahtar Kelimeler

accumulator, serpentine soil, Viola taxa, Zinc

Destekleyen Kurum

Scientific Research Projects Coordination Unit of Akdeniz University .

Proje Numarası

FBA-2016-1982

Teşekkür

This work was part of a project supported by the Scientific Research Projects Coordination Unit of Akdeniz University (Project number: FBA-2016-1982). I would like to thank Jale Çelik and Uğurcan Baran for their help and Aylin Güney for language editing.

Türkiye Akdeniz serpantin topraklarında seçilmiş doğal viola taksonlarının kadmiyum, bakır ve çinko akümülasyonu

Öz

Ülkemizde 55 serpantin alan belirlenmiş ve bu alanlarda 60’dan fazla Ni akümülatörü ve 43’den fazla sayıda serpantin endemiği olduğu tespit edilmiştir. Akdeniz fitocoğrafik bölgesinde yapmış olduğumuz arazi çalışmalarında serpantin alanlarda yayılış gösteren 8 Viola taksonu ve bunların yetiştiği toprak örnekleri toplandı. Toplanan 8 Viola taksonunun yetiştiği topraklar ve bitkilerdeki Cd, Cu, ve Zn konsantrasyonları araştırılmıştır. Bitki ve toprak örnekleri mikrodalgada çözüldükten sonra metal ölçümleri ICP-OES cihazında yapılmıştır. Farklı lokalitelerden toplanan 8 Viola taksonunda yapılan Cd, Cu, ve Zn ölçümleri sonucunda hiçbir bitkide hiperakümülatör özelliği tespit edilememiştir. Ancak, Viola kizildaghensis bitkisinin Zn yönünden akümülator özelliğinin olduğu belirlenmiştir.

Anahtar Kelimeler

akümülatör, çinko, serpantin topraklar, Viola taksonları

Proje Numarası

FBA-2016-1982

Kaynakça

• Adıgüzel N, Reeves RD (2012). Important serpentine areas of Turkey and distribution patterns of serpentine endemics and nickel accumulators. Bocconea 24: 7-17.
• Aksoy A, Leblebici Z, Prasad MNV (2015). Metal accumulating plants from serpentine habitats of Kızıldağ, Konya Province of Turkey. Australian Journal of Botany 63(3-4): 372-378.
• Aksoy A, Öztürk M (1997). Nerium oleander L. as a biomonitor of lead and other heavy metal pollution in Mediterranean environments. The Science of the Total Environment 205: 145-150.
• Altınözlü H, Karagöz A, Polat T, Ünver İ (2012). Nickel hyperaccumulation by natural plants in Turkish serpentine soils. Turkish Journal of Botany 36: 269-280.
• Bačeva K, Stafilov T, Matevski V (2014). Bioaccumulation of heavy metals by endemic Viola species from the soil in the vicinity of the As-Sb-TI mine “Alchar”, Republic of Macedonia. International Journal of Phytoremediation 16: 347-365.
• Baker AJM, McGrath SP, Reeves RD, Smith JAC (2000). Metal hyperaccumulator plants: A review of the ecology and physiology of a biological resource for phytoremediation of metal-polluted soils. In: Terry N, Banuelos G (eds.). Phytoremediation of contaminated soil and water, Boca Raton: Lewis publishers, pp. 85-107.
• Brooks RR (1998). Geobotany and hyperaccumulators. In: Brooks RR (ed). Plants that hyperaccumulate heavy metals. Wallingford: CAB International, pp.55-94.
• Coode MJE, Cullen J (1965). Viola L. In: P.H. Davis (ed.). Flora of Turkey and the East Aegean Islands, vol. I, Edinburgh: Edinburgh Univ. Press, pp. 524-533.
• Çelik J, Aksoy A, Leblebici Z (2018). Metal hyperaccumulating Brassicaceae from the ultramafic area of Yahyalı in Kayseri province, Turkey. Ecological Research 33: 705-713.
• Davis PH, Mill RR, Tan K (1988). Flora of Turkey and the East Aegean Islands. Vol: 10, Edinburgh: Edinburgh University Press.
• Dinç M (2012). Viola L. Şu kitapta: Güner A, Aslan S, Ekim T, Vural M, Babaç MT. (eds.) Türkiye Bitkileri Listesi (Damarlı Bitkiler). İstanbul: Nezahat Gökyiğit Botanik Bahçesi ve Flora Araştırmaları Derneği Yayını.
• Düşen O, Göktürk RS, Kaya E, Sarpkaya U ve Gürcan B (2018). Morphological and molecular determination of a new Viola species (Violaceae) from Turkey. Phytotaxa 369(1): 37-46.
• Hyperaccumulators.org. https://hyperaccumulators.org/ [accessed accessed 08.10. 2021].
• Jedrzejczyk M, Rostański A, Malkowski A (2002). Accumulation of zinc and lead in selected taxa of the genus Viola l. Acta Biologica Cracoviensia Series Botanica 44: 49-55.
• Knoche G, Marcussen T (2016). Viola barhalensis (Violaceae), a new species from northeastern Turkey. Phytotaxa 275(1): 14-22.
• Kramer Ü (2010). Metal hyperaccumulation in plants. Annual Review of Plant Biology 61: 517-534.
• Kurt L, Ozbey BG, Kurt F, Ozdeniz E. Bolukbaşı A (2013). Serpentine Flora of Turkey. Biological Diversity and Conservation 6(1): 134-152.
• Lei M, Chen TB, Huang ZC, Wang YD, Huang YY (2008). Simultaneous compartmentalization of lead and arsenic in co-hyperaccumulator Viola principis H. de Boiss.: an application of SRXRF microprobe. Chemosphere 72: 1491-1496.
• Liu W, Shu WS, Lan CY (2004). Viola baoshanensis, a plant that hyperaccumulates cadmium. Chinese Science Bulletin 49: 29-32.
• Marcussen T, Heier L, Brysting AK, Oxelman B, Jakobsen KS (2015) From gene trees to a dated allopolyploid network: insights from the angiosperm genus Viola (Violaceae). Systematic Biology 64: 84-101.
• Özdeniz E, Özbey BG, Kurt L, Bölükbaşı A (2017). Serpantin ekolojisi ve Türkiye serpantin florasına katkılar. Toprak Bilimi ve Bitki Besleme Dergisi 5(1): 22-33.
• Peng JS, Guan, YH, Lin, XJ, Xu XJ, Xiao L, Wang HH, Meng S (2020). Comparative understanding of metal hyperaccumulation in plants: a mini-review. Environmental Geochemistry and Health 42(2): 1-9.
• Prasad MNV (2005). Nickelophilous plants and their significance in phytotechnologies. Brazilian Journal of Plant Physiology 17: 113-128.
• Reeves RD (1988). Nickel and zinc accumulation by species of Thlaspi L., Cochlearia L. and other genera of the Brassicaceae. Taxon 37: 309-318.
• Reeves RD, Adıgüzel N (2004). Rare plants and nickel accumulators from Turkish serpentine soils, with special reference to Centaurea species. Turkish Journal of Botany 28: 147-153.
• Reeves RD, Adıgüzel N (2008). The nickel hyperaccumulating plants of the serpentines of Turkey and adjacent areas: a review with new data. Turkish Journal of Botany 32: 143-153.
• Reeves RD, Adıgüzel N, Baker AJM (2009). Nickel hyperaccumulation in Bornmuellera kiyakii Aytaç & Aksoy and associated plants of the Brassicaceae from Kızıldağ Derebucak (Konya), Turkey. Turkish Journal of Botany 33: 33-40.
• Reeves RD, Baker AJ, Jaffré T, Erskine PD, Echevarria G, & van der Ent A (2018). A global database for plants that hyperaccumulate metal and metalloid trace elements. New Phytologist 218(2): 407-411.
• Reeves RD, Brooks RR, Dudley TR. 1983. Uptake of nickel by species of Alyssum, Bornmuellera and other genera of Old World Tribus Alysseae. Taxon 32: 184-192.
• Reeves RD, Kruckeberg AR, Adıgüzel N, Kramer U (2001). Studies on the flora of serpentine and other metalliferous areas of western Turkey. South African Journal of Science 97: 513-517.
• Remigio AC, Chaney RL, Baker AJM, Edraki M, Erskine PD, Echevarria G, van der Ent A, (2020). Phytoextraction of high value elements and contaminants from mining and mineral wastes: Opportunities and limitations. Plant and Soil 449: 11-37.
• Stevanović B, Drazic G, Tomović G, Sinzar-Sekulic J, Melovski L, Novovic I, Markovic DM (2010). Accumulation of arsenic and heavy metals in some Viola species from an abandoned mine, Alchar, Republic of Macedonia (Fyrom). Plant Biosystems 144(3): 644-655.
• Sychta K, Słomka A, Suski S, Fiedor E, Gregoraszczuk E, Kuta E (2018). Suspended cells of metallicolous and nonmetallicolous Viola species tolerate, accumulate and detoxify zinc and lead. Plant Physiology and Biochemistry 132: 666-674.
• Tomović G, Đurović S Buzurović U, Niketić M, Milanović D, Mihailović N, and Jakovljević K (2021). Accumulation of potentially toxic elements in Viola L. (sect. Melanium Ging.) from the ultramafic and non-ultramafic soils of the Balkan peninsula. Water Air and Soil Pollution 23(46): 1-18.
• Tonin C, Vandenkoornhuyse P, Joner EJ, Straczek J, Leyval C (2001). Assessment of arbuscular mycorrhizal fungi diversity in the rhizosphere of Viola calaminaria and effect of these fungi on heavy metal uptake by clover. Mycorrhiza, 10: 161-168.
• Van der Ent A, Baker AJM, Reeves RD, Pollard AJ, Schat H (2013). Hyperaccumulars of metal and metalloid trace elements: facts and fiction. Plant Soil 262: 319-324.
• Wei L, Wensheng S, Chongyu L (2004). Viola boashanensis, a plant that hyperaccumulates cadmium. Chinese Science Bulletin 49(1): 29-32.
• Wu C, Liao B, Wang SL, Zhang J, Li JT (2010). Pb and Zn Accumulation in a Cd-Hyperaccumulator (Viola boashanensis). International Journal of Phytoremediation 12: 574-585.
• Yıldırımlı Ş (2000). Viola L. in: A Güner, N Özhatay, T Ekim and KHC Başer (eds.), Flora of Turkey and the East Aegean Islands, v. 11. Edinburgh: Edinburgh Univ. Press, pp. 43-44.