The ecological impacts of tin mining activities in the Bangka island is the presence of heavy metal contamination that accumulated in the environment. One of the heavy metals that was often found in post-tin mining areas is lead (Pb). Mycoremediation is a method that can be used to reduce lead pollution in post-tin mining areas. This study aimedto isolate, resistance test and identify to Pb-resistant soil fungi (rhizosphere) in the post-tin area of Bangka. The research methods included isolation, test of fungal resistance to Pb metal (Control, 150ppm, 250ppm, 350ppm, 500ppm, 1,000ppm, 5,000ppm and 10,000ppm), macroscopic and microscopic identification. The results showed that 9 isolates tested, there were 6 isolates that were resistant to Pb up to the concentration of 5,000 ppm, namely isolates I1(Rhizoctonia), I2(Penicilllium sp1), I5(Papulaspora), I6(Penicillium sp2), I7(Penicillium sp3) and I9 (Sclerotium). Three isolates of soil fungus were not resistant to Pb up to a concentration of 5,000 ppm, namely isolates I4 (Sclerotium), I8(Microsporum), and I10(Cladosporium). All isolates did not grow anymore at a concentration of 10,000 ppm of Pb.

Micoremediation; Pb metal,; Resistance; Soil fungi; Tin mining

Ahmad, R.Z. (2018). Mikoremediasi Menghilangkan Polusi Logam Berat pada Lahan Bekas Tambang untuk Lahan Peternakan. WARTAZOA 28 (1) : 041-050.

Aishwarya, S. Venkateswarulunagam. Netala, V.R. Tartte, V. (2017). Screening and Identification of Heavy Logam Metal-Tolerant Endophytic Fungi Lasiodiplodia theobromae from Boswella ovalifoliolata An Endemic Plant of Tirumala Hills. Asian Journal of Pharmaceutical and Clinical Research 10(3) : 488-491.

Amaral, J.H. Rezende, B. Quintana, S.M. Gerlach, R.F. Barbosa, F. Tanus-Santos, J.E. (2010). The Relationship betweenBlood and Serum Lead Levels in Peripartum Women and Their Respective Umbilical Cords. Basic & Clinical Pharmocology & Toxicology 107 (6) : 971-975.

Amatussalam, A. Abubacker, N.M. Rajendran, R.B. (2011). In situ Carica papaya Stem Matrix and Fusarium oxysporum (NCBT-156) Mediated Bioremediation of Chromium. Indian J. Exp. Biol. 49: 925-31.

Anahid, S. Yaghmaei, S. Ghobadinejad, Z. (2011). Heavy Metal Tolerance Of Fungi. Sci Iran 18 : 502-508.

Arunasri, P. Chalam, T.V. Reddy, N.P.E. Reddy, S.T. Reddy, R. (2011). Investigation on Fungicide Selectivity of Trichoderma spp and Sclerotium rolfsii (collar rot pathogen) in Crossandra. Int. J. Appl. Biol. Pharm. Technol 2: 290-293.

Asiriuwa, O.D. Ikhuoria, J.U. Ilor, E.G. (2013). Mycoremediation Potential Of Heavy Metals From Contaminated Soil. Bull Environ Pharmacol Life Sci 2 : 16-22.

Ed-har, A.A. Widyastuti, R. Djajakirana, G. (2017). Isolasi dan Identifikasi Mikroba Tanah Pendegradasi Selulosa dan Pektin dari Rhizosfer Aquilaria malasccensis. Buletin Tanah dan Lahan 1(1) : 58-64

Ekawati, A.Y. (2019). Optimalisasi Biosorpsi oleh Fungi Endofit Akar Tridax procumbens dari TanahTercemar Tembaga (Cu) di Pertambangan Minyak, Bojonegoro Jawa Timur. [Skripsi]. Malang : Universitas Islam Negeri Maulana Malik Ibrahim Malang.

Fashola, M.O. Ngole-Jeme, V.M. Babola, O.O. (2016). Heavy Metal Pollution from Gold Mines : Environmental Effects and Bacterial Strategies for Ressistance. Int. J. Environ. Res. Public Health 13 : 1047.

Guimarães JB, Chambel L, Melzoch K, Pereira P, Tenreiro R. 2011 – Cladosporium sp. from phyloplane: a diversity evaluation on a Continental ecosystem. Mycosphere 2(3): 191–201.

Indrawati I, SD Fakhrudin. 2016. isolasi dan identifikasi jamur patogen pada air sumur dan air sungai di pemukiman warga desa karangwangi, cianjur, jawa barat. J Biodjati. 1 (1): 27-38.

Iram, S. Uzma. Gul. R.S. Ara. T. (2013a). Bioremediation of Heavy Metals Using Isolates of Filamentous Fungus Aspergillus fumigatus Collected from Polluted Soil of Kasur. Pakistan. Int Res J Biol Sci 2 : 1-6.

Iram, S. Waqar, K. Shuja, N. Perveen, K. Akhtar, I. Ahmad, I. (2013b). Tolerance Potential of Different Species of Aspergillus as Bioremediation Tool-Comparative Analysis. J Biodivers Environ Sci 3 : 1-10.

Jaiswal, S. 2011. Role of Rhizobacteria in Reduction of Arsenic Uptake by Plants: A Review. J. Bioremed. Biodegrad 2(4) : 1-5.

Kredics, L. Doczi, I. Antal, Z. Manczringer, L. (2001). Isolation and Characterization of Heavy Metal Resistant Mutants from Mycoparasitic Trichoderma strains. Biological Control of Fungal and Bacterial Plant Pathogens 24(3) : 233-236.

Kurniawan, A. Mustikasari, D. (2019). Review: Mekanisme Akumulasi Logam Berat Di Ekosistem Pascatambang Timah. Jurnal Ilmu Lingkungan 17 (3): 408-415.

Kurniawan, A. Oedjijono. Tamad. Sulaeman, U. (2019). The Pattern of Heavy Metals Distribution in Time Chronosequence of Ex-Tin Mining Ponds in Bangka Regency, Indonesia. Indonesian Journal of Chemistry 19(1):254-261.

Lotlikar, N.P. (2019). Physiological Response of Fungi from Marine Habitats to Heavy Metals. CSIR-National Institute of Oceanography.

Maini ZAN, Aribal KMJ, Narag RMA, Melad JKLT, Frejas JAD, Arriola LAM, Gulpeo PCG, Navarrete IA and Lopez CM. 2019. Lead (II) Tolerance and Uptake Capacities of Fungi Isolated from a Polluted Tributary in the Philippines. Applied Environmental Biotechnology 4(1) : 18-29. http://doi.org/10.26789/AEB.2019.01.004.

Olaniran, A.O. Boglobind, A. Pillay, B. (2013). Bioavaibility of Heavy Metals in Soil : Impact on Microbial Biodegradation of Organic Compounds and Possible Improvement Strategies. Int.J.Mol.Sci 14 : 10197-10228.

Rose, K.P. Devy, R. (2018). Heavy Metal Tolerance and Adaptability Assessment of Indigenous Filamentous Fungi Isolated from Industrial Wastewater and Sludge Samples. Journal of Basic and Applied Sciences 7 : 688–694.

Rossiana, N. Supriatun, T. Sumiarsa, D. Rescho, A.S. Dhahiyat, Y. (2015). Decreasing of Lead and Cadmium by Cladosporium and Albizia (Paraserianthes falcataria l. nielsen) Mycorrhizal on Oil Sludge Phytoremediation. J Microbiol Exp 2(6) : 181-184.

Sana, N. Shoaib, A. Javaid, A. (2015). Growth of A Soil-Borne Plant Pathogen Sclerotium rolfsii Under Chromium(Iii) Stress. Pak. J. Phytopathol 27(1): 55-60.

Siddiquee, S. Aishah, S.N. Azad, S.A. Shafawati, S.N. Naher, L. (2013). Tolerance and Biosorption Capacity of Zn2+, Pb2+, Ni3+, and Cu2+ by Filamentous Fungi (Trichoderma harzianum, T. aureoviride, and T. virens). Adv Biosci Biotechnol 4 : 570-583.

Suryati,T. (2017). Studi Fungi Mikoriza Arbuskula di Lahan Pasca Tambang Timah Kabupaten Bangka Tengah. Jurnal Teknologi Lingkungan 18(1): 45-53.

Tian , D. Jiang, Z. Jiang, L. Su, M. Feng, Z. Zhang, L. Wang, S. Li, Z. Hu, S. (2018). A New Insight Into Lead (Ii) Tolerance of Environmental Fungi Based on A Study of Aspergillus niger and Penicillium oxalicu. Environmental Microbiology 21(1) : 471-479.

Watanabe, T. (2010). Pictorial Atlas of Soil and Seed Fungi Morphologies of Cultured Fungi and Key to Species : Third Edition. Florida : CRC Press

Wijaya, N. (2018). Kemampuan Isolat Jamur Asal BatangToru Tapanuli Selatan dalam Menyerap Timbal. [Skripsi]. Medan : Universitas Sumatera Utara

Yang, T. Wang, X.Y. Wang, L.Y. Chen, M.L. Wang, J.H. (2016). Biological Cells in The Speciation Analysis of Heavy Metals. Analytical Methods 8(47) : 825-826.

Yanti, N. Samingan. Mudatsir. (2016). Uji Aktivitas Antifungi Ekstrak Etanol Gal Manjakani (Quercus infectoria) terhadap Candida albicans. Jurnal Ilmiah Mahasiswa Pendidikan Biologi 1(1) : 1-9.