POTENSI Trichoderma asperellum TERHADAP PERTUMBUHAN DAN HASIL  TANAMAN KEDELAI TERINFEKSI SOYBEAN MOSAIC VIRUS

Indah Hafidhotun Nisa; Herfandi Lamdo; Yanto Yanto

doi:10.23960/ja.v24i1.10105

Authors

Indah Hafidhotun Nisa Departemen Budidaya Pertanian, Fakultas Teknologi Pertanian, Universitas Satu Nusa Lampung
Herfandi Lamdo Departemen Budidaya Pertanian, Fakultas Teknologi Pertanian, Universitas Satu Nusa Lampung
Yanto Yanto Departemen Budidaya Pertanian, Fakultas Teknologi Pertanian, Universitas Satu Nusa Lampung

DOI:

https://doi.org/10.23960/ja.v24i1.10105

Abstract View: 270

Abstract

Soybean Mosaic Virus (SMV) is a species in the Potyvirus genus, which is a plant RNA virus known to attack important agricultural crops. Infection by SMV during early growth can reduce productivity by 25.48% to 93.84% in soybean plants. Trichoderma plays a role through the contact of spores on root surfaces, leading to the production of plant defenses such as peptides and proteins, and assisting in nutrient absorption, thereby allowing Trichoderma to control pathogen growth and enhance plant growth and yield. This research aims to determine the effect of Trichoderma asperellum doses on the growth and yield of soybean plants infected with Soybean Mosaic Virus. The study was conducted from June to September 2024 using an experimental method with a randomized block design consisting of 4 replications and 6 treatment levels: T0 = 0 ml (control), T1 = 10 ml, T2 = 20 ml, T3 = 30 ml, T4 = 40 ml, T5 = 50 ml per plant with each 1 ml containing spore count of T. asperellum = 46.5 x 10² spores). The results showed that the dose of Trichoderma asperellum had a real effect on the growth and yield of soybean plants infected with Soybean Mosaic Virus. The application of Trichoderma asperellum was able to increase plant height by 36.33%, the number of leaves by 42.36%, the wet weight of the plant by 48.97%, the dry weight of the plant by 48.03%, the dry weight of the roots by 64.43%, and the number of pods by 34.26% in soybean plants compared to no application of Trichoderma asperellum. Administration of Trichoderma asperellum 50 ml dose obtained the best growth and results.

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References

Andayanie, W. R. 2012. Diagnosis penyakit mosaik (Soybean mosaic virus) terbawa benih kedelai. Jurnal Hama Dan Penyakit Tumbuhan Tropika, 12(2), 185–191.

Apzani, W., Baharuddin, Arifin, Z., Hidayah, M., & Sunandi, I. 2024. Uji dosis tricokompos (hasil fermentasi Trichoderma spp.) Dalam memacu pertumbuhan tiga varietas padi (Oryza sativa L.) Pada sistem tanam benih langsung (tabela). Jurnal Ganec Swara, 18(1), 348–357.

Fitri, R. Y., Ardian, A., & Isnaini, I. (2017). Pemberian Vermikompos pada Pertumbuhan Bibit Tanaman Kakao (Theobroma Cacao L.). Jurnal Online Mahasiswa Fakultas Pertanian Universitas Riau, 4(1), 1–15.

Gardner, F. P., Pearce, R. B., & Mitchell, R. L. (1991). Fisiologi Tanaman Budidaya. UI Press.

Hajimorad, M. R., Domier, L. L., Tolin, S. A., Whitham, S. A., & Saghai Maroof, M. A. (2018). Soybean mosaic virus: a successful potyvirus with a wide distribution but restricted natural host range. Molecular Plant Pathology, 19(7), 1563–1579.

Harman, G. E., Howell, C. R., Viterbo, A., Chet, I., & Lorito, M. (2004). Trichoderma species — opportunistic, avirulent plant symbionts. Nature Reviews Microbiology, 2(1), 43–56. https://doi.org/10.1038/nrmicro797

Hill, J. H., & Whitham, S. A. (2014). Chapter Seven - Control of Virus Diseases in Soybeans. In G. Loebenstein & N. Katis (Eds.), Advances in Virus Research (Vol. 90, pp. 355–390). Academic Press. https://doi.org/https://doi.org/10.1016/B978-0-12-801246-8.00007-X

Irna, A., Hafsan, H., & Alfian, A. (2023). Introduksi Trichoderma sp. pada tanaman cabai (Capsicum frutescens). Teknosains: Media Informasi Sains Dan Teknologi, 17(1), 108–115.

Koning, G., TeKrony, D. M., & Ghabrial, S. A. (2003). Soybean Seedcoat Mottling: Association with Soybean mosaic virus and Phomopsis spp. Seed Infection. Journal Plant Disease, 87(4), 413–417. https://doi.org/10.1094/PDIS.2003.87.4.413

Oktapia, E. (2021). Respons pertumbuhan tanaman cabai rawit (Capsicum frutescens L.) terhadap pemberian jamur Trichoderma sp. Jurnal Indobiosains, 3(1), 17–25.

Pandya, U., & Saraf, M. (2010). Role of single fungal isolates and consortia as plant growth promoters under saline conditions. Research Journal of Biotechnology, 5(3), 5–9.

Pratama, R. E., Mardhiansyah, M., & Oktorini, Y. (2015). Waktu Potensial Aplikasi Mikoriza Dan Trichoderma Spp. Untuk Meningkatkan Pertumbuhan Semai Acacia mangium. Jurnal Online Mahasiswa Fakultas Pertanian Universitas Riau, 2(1), 1–11.

Rahmah, A., Izzati, M., & Parman, S. (2014). Pengaruh pupuk organik cair berbahan dasar limbah sawi putih (Brassica chinensis L.) Terhadap pertumbuhan tanaman jagung manis (Zea mays L. var. Saccharata). Buletin Anatomi Dan Fisiologi, 22(1), 65–71.

Rizal, S., Novianti, D., & Septiani, M. (2019). Pengaruh jamur Trichoderma sp terhadap pertumbuhan tanaman tomat (Solanum lycopersicum L.). Jurnal Indobiosains, 1(1), 14–21.

Salisbury, F. B., & Ross, C. W. (1995). Fisiologi Tumbuhan Jilid I (Edisi Keempat). Penerbit ITB. Bandung.

Sartika, S., Ali, M., & Elfina, Y. (2017). Uji Beberapa Dosis Biofungisida Berbahan Aktif Trichoderma Koningii Rifai terhadap Penyakit Virus Kompleks, Pertumbuhan dan Produksi Cabai Merah (Capsicum Annuum L.). Jurnal Online Mahasiswa Fakultas Pertanian Universitas Riau, 4(1), 1–8.

Semangun, H. (2000). Pengantar Ilmu Penyakit Tumbuhan. UM Press.

Sutrisno, D. K., Hartatik, S., & Dewanti, P. (2022). Peranan Trichoderma terhadap Pertumbuhan dan Hasil Tanaman Kedelai (Glycine max) pada Kondisi Cekaman Kekeringan. Jurnal Agrinika : Jurnal Agroteknologi Dan Agribisnis, 6(1), 76. https://doi.org/10.30737/agrinika.v6i1.2339