Effect of Liquid Biofertilizer BRE4 and Organic Fertilizer on Soil Nematode Diversity in Arabica Coffee Plantation

Pengaruh Pupuk Hayati Cair BRE4 dan Pupuk Organik Terhadap Keragaman Nematoda Tanah Pada Lahan Kopi Arabika

Authors

  • Iis Nur Asyiah Universitas Jember
  • Mudakir Imam Program Studi Pendidikan Biologi, Fakultas Keguruan dan Ilmu Pendidikan, Universitas Jember, Indonesia
  • Pradana Ankardiansyah Pandu Program Studi Proteksi Tanaman, Fakultas Pertanian, Universitas Jember, Indonesia
  • Budiman Aris
  • Nugroho Dwi
  • Nordiana Laeli Program Studi Pendidikan Biologi, Fakultas Keguruan dan Ilmu Pendidikan, Universitas Jember, Indonesia

DOI:

https://doi.org/10.25181/jppt.v24i3.3313

Abstract

This research aims to determine the influence of liquid biofertilizer BRE4 and organic fertilizer on soil nematode diversity in Arabica coffee plantations. The study was conducted in smallholder Arabica coffee farms in the Ijen Bondowoso region, Indonesia. The research utilized a Randomized Complete Block Design with the following treatments: P1= 30 ml of liquid biofertilizer BRE4 per ton of manure, P2= 60 ml of liquid biofertilizer BRE4 per ton of manure, P3= 90 ml of liquid biofertilizer BRE4 per ton of manure, P4= 120 ml of liquid biofertilizer BRE4 per ton of manure, K- = Without liquid biofertilizer and manure, K+1= 60 ml of liquid biofertilizer, and K+2= 5L of manure without liquid biofertilizer. The results showed that the P4 treatment reduced the population of parasitic nematodes and increased the diversity of free-living nematodes better than other treatments. A total of 18 genera of soil nematodes were identified, with the bacterial-feeding nematode genus (bacteriovore) being the most abundant compared to other trophic groups. The application of BRE4 and manure improved the soil ecosystem based on the nematode diversity level.  

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References

Asyiah, I. N., Mudakir, I., Hoesain, M., Pradana, A. P., Djunaidy, A., & Sari, R. F. (2020). Consortium of endophytic bacteria and rhizobacteria effectively suppresses the population of Pratylenchus coffeae and promotes the growth of Robusta coffee. Biodiversitas Journal of Biological Diversity, 21(10).

Asyiah, I. N., PRIHATIN, J., Hastuti, A. D., Winarso, S., Widjayanthi, L., Nugroho, D., Firmansyah, K., & Pradana, A. P. (2021). Cost-effective bacteria-based bionematicide formula to control the root-knot nematode Meloidogyne spp. on tomato plants. Biodiversitas Journal of Biological Diversity, 22(6).

Asyiah, I. N., Tristaningtyas, D. H., Prihatin, J., Winarso, S., Widjayanthi, L., Nugroho, D., Firmansyah, K., & Pradana, A. P. (2022). The Efficacy of Cost-Effective Bionematicide against Potato Cyst Nematode Globodera Rostochiensis. Pakistan Journal of Phytopathology, 34(2), 173–185.

Asyiah, I. N., Wiryadiputra, S., Fauzi, I., & Harni, R. (2015). Populasi Pratylenchus coffeae (Z.) dan Pertumbuhan Bibit Kopi Arabika Akibat Inokulasi Pseudomonas diminuta L. dan Bacillus subtilis (C.)[Population of Pratylenchus coffeae (Z.) and Growth of Arabica Coffee Seedling Inoculated by Pseudomonas diminuta L. a.

Bongers, T., & Bongers, M. (1998). Functional diversity of nematodes. Applied Soil Ecology, 10(3), 239–251.

Bongers, T., van der Meulen, H., & Korthals, G. (1997). Inverse relationship between the nematode maturity index and plant parasite index under enriched nutrient conditions. Applied Soil Ecology, 6(2), 195–199.

Bulluck Iii, L. R., Barker, K. R., & Ristaino, J. B. (2002). Influences of organic and synthetic soil fertility amendments on nematode trophic groups and community dynamics under tomatoes. Applied Soil Ecology, 21(3), 233–250.

Ferris, H., & Bongers, T. (2009). Indices developed specifically for analysis of nematode assemblages. In Nematodes as environmental indicators (pp. 124–145). CABI Wallingford UK.

Ferris, H., Bongers, T., & de Goede, R. G. M. (2001). A framework for soil food web diagnostics: extension of the nematode faunal analysis concept. Applied Soil Ecology, 18(1), 13–29.

Hindersah, R., Asyiah, I. N., Harni, R., Rahayu, D. S., & Fitriatin, B. N. (2022). Formulation of Soil Beneficial Microbes Solid Inoculant for Controlling Nematode in Coffee. Jurnal Penelitian Pertanian Terapan, 22(1), 58–66.

Jiang, Y., Qian, H., Wang, X., Chen, L., Liu, M., Li, H., & Sun, B. (2018). Nematodes and microbial community affect the sizes and turnover rates of organic carbon pools in soil aggregates. Soil Biology and Biochemistry, 119, 22–31.

Liu, T., Yu, L., Xu, J., Yan, X., Li, H., Whalen, J. K., & Hu, F. (2017). Bacterial traits and quality contribute to the diet choice and survival of bacterial-feeding nematodes. Soil Biology and Biochemistry, 115, 467–474.

McSorley, R., & Frederick, J. J. (1999). Nematode population fluctuations during decomposition of specific organic amendments. Journal of Nematology, 31(1), 37.

Neher, D. A., & Olson, R. K. (1999). Nematode communities in soils of four farm cropping management systems.

Renčo, M., & Kováčik, P. (2012). Response of plant parasitic and free living soil nematodes to composted animal manure soil amendments. Journal of Nematology, 44(4), 329.

Sagita, L., Siswanto, B., & Kurniatun, H. (2014). Studi keragaman dan kerapatan nematoda pada berbagai sistem penggunaan lahan di Sub DAS Konto. Jurnal Tanah Dan Sumberdaya Lahan, 1(1), 51–60.

Sieriebriennikov, B., Ferris, H., & de Goede, R. G. M. (2014). NINJA: An automated calculation system for nematode-based biological monitoring. European Journal of Soil Biology, 61, 90–93.

Stirling, G. R. (2018). Biological control of plant-parasitic nematodes. In Diseases of nematodes (pp. 103–150). CRC Press.

Sulistyowati, E. (2012). Aplication of Paecilomyces lillacinus to Induce Resistance of Coffe Plant against Pratylenchus coffeae: Efectivity of Paecilomyces lillacinus strain 251 to Pratylenchus coffeae. Proceeding of InSINas.

Swibawa, I. G. (2014). Komunitas nematoda pada tanaman kopi (Coffea canephora var robusta) muda di Kabupaten Tanggamus Lampung. Agrotrop, 4(2), 141–150.

Tarjan, A., Esser, R., & Chang, S. (2014). Interactive diagnostic key to plant parasitic, free-living, and predaceous nematodes. University of Nebraska, Lincoln, Nematology Laboratory.

Tomar, V. V. S., Baniyamuddin, M., & Ahmad, W. (2010). Distribution of Bacterivorous nematodes along the distance gradient from a thermal power station. Ekológia (Bratislava), 29(1), 47–54.

Ugarte, C. M., Zaborski, E. R., & Wander, M. M. (2013). Nematode indicators as integrative measures of soil condition in organic cropping systems. Soil Biology and Biochemistry, 64, 103–113.

Yeates, G. W., Ferris, H., Moens, T., & Putten, W. H. van der. (2009). The role of nematodes in ecosystems. In Nematodes as environmental indicators (pp. 1–44). CABI Wallingford UK.

Zhang, W., Villarini, G., & Vecchi, G. A. (2019). Impacts of the Pacific meridional mode on rainfall over the maritime continent and Australia: potential for seasonal predictions. Climate Dynamics, 53, 7185–7199.

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Published

2024-09-21

How to Cite

Asyiah, I. N., Imam, M., Ankardiansyah Pandu , P., Aris, B., Dwi, N., & Laeli, N. (2024). Effect of Liquid Biofertilizer BRE4 and Organic Fertilizer on Soil Nematode Diversity in Arabica Coffee Plantation: Pengaruh Pupuk Hayati Cair BRE4 dan Pupuk Organik Terhadap Keragaman Nematoda Tanah Pada Lahan Kopi Arabika. Jurnal Penelitian Pertanian Terapan, 24(3), 321-328. https://doi.org/10.25181/jppt.v24i3.3313

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