UTILIZATION OF DOMINANT AND OPORTUNISTIC TAXA OF MACROBENTHIC ASSEMBLAGES INHABITING SEDIMENTS UNDER FISH FARMS FOR THE ENVIRONMENTAL STATUS ASSSESSMENT

Authors

  • Sapto P. Putro Center of Marine Ecology and Biomonitoring for Sustainable Aquaculture, Diponegoro University, Tembalang 50275, Semarang, Indonesia https://orcid.org/0000-0002-2837-6881
  • Nuke Hawarizqi Department of Biology, Faculty of Science and Mathematics, Diponegoro University, Tembalang 50275, Semarang, Indonesia https://orcid.org/0000-0003-1493-3656
  • Widowati - Department of Mathematics, Faculty of Science and Mathematics, Diponegoro University, Tembalang 50275, Semarang, Indonesia
  • Satriyo Adhy Department of Informatics, Faculty of Science and Mathematics, Diponegoro University, Tembalang 50275, Semarang, Indonesia

DOI:

https://doi.org/10.11113/jurnalteknologi.v84.18319

Keywords:

Macrobenthic assemblages, opportunistic taxa, dominant taxa, environmental status, and biomonitoring

Abstract

This study aimed to analyse the environmental quality based on opportunistic taxa and dominant taxa of macrobenthic assemblages, comparing sediment under the IMTA-aquaculture  and the reference site, Karimunjawa National Park. Sediments were sampled between May and October 2019, in two sampling times at the IMTA cages in which star pomfret (Trachinotus blochii) and tiger grouper (Epinephelus fuscoguttatus) were farmed with 3 stations. The reference area was located 1 km away from the fish farm zone.  Transformed data of macrobenthic abundance was correlated to abiotic variables using BIO-ENV using Primer V.6.1.5 software.  The dominant taxa at IMTA sites were Diala semistriata, Rissoina ambigua, Stilifer ovoideus, Acteocina fusiformis, Cerithium punctatum, Allorchestes compressa and Capitella capitata, whilst those at the reference sites were dominated by Barbatia lima, Acteocina candei, Cerithium punctatum, Owenia fusiformis, and Anaspides spinulae. Further analyses on the selected dominant and opportunistic taxa of macrobenthic assemblages between the IMTA area (M = 10.18, SE = 2.056) and the reference area (M = 3.18, SE = 0.732) still showed a significant difference (t(42) = 3.207, p = 0.003), indicating a consistency of the results of parametric statistical tests, both using the complete and the selected data set. The use of selected and dominant taxa is effective in determining environmental status and level of disturbance, and speed up the identification process and monitoring time.

References

Januardi, R., Hartoko, A., Purnomo, P. W. 2016. Analisis Habitat dan Perubahan Luasan Terumbu Karang di Pulau Menjangan Besar, Kepulauan Karimunjawa Menggunakan Citra Satelit. Journal of Maquares. 5: 302-310. DOI: https://doi.org/10.14710/marj.v5i4.14435.

Effendi, H. 2004. Telaah Kualitas Air Bagi Pengelolaan Sumberdaya dan Lingkungan Perairan. Cetakan Kelima. Yogyakarta: Kanisisus.

Asli, W. T., Malik, A. A., Kahiruddin, Harsani. 2019. Pengaruh Padat Tebar pada Sistem Polikultur Terhadap Pertumbuhan Sintasan, Konversi Pakan, Produksi Udang Vannamei (Litopenaeusvannamei) dan Benih Ikan Nila (Oreochromis niloticus). Jurnal Ecosystem. 19: 238-243.

Putro, S. P., Widowati., Febria, I. J., Muhammad, F., Suhartana., Suminto., Sudaryono, A., dan Koshio, S. 2016. Environmental Assessment Of Polyculture Farming Practice Based On Macrobenthic Assemblages: A Study Case At Coastal Area Of Kaliwungu, Kendal (Central Java, Indonesia). Jurnal Teknologi. 78(4-2): 199-205. DOI: https://doi.org/10.11113/jt.v78.8206.

Putro, S. P. 2010. Environmental Quality Assessment of Fish Farming: Solutions toward Sustainable Aquaculture. Lambert Academic Publishing (LAP): Saarbrucken, Germany. 197.

Reid, G. K., Chopin, T., Robinson, S. M. C., Azevedo, P., Quinton, M., & Belyea, E. 2013. Weight Ratios of the Kelps, Alaria Esculenta and Saccharina Latissima, Required to Sequester Dissolved Inorganic Nutrients and Supply Oxygen for Atlantic Salmon, Salmo Salar, in Integrated Multi-Trophic Aquaculture Systems. Aquaculture. 508-409, 34-46. DOI: https://doi.org/10.1016/j.aquaculture.2013.05.004.

Troell, M., Halling, C., Neori, A., Chopin, T., Buschmann, A. H., Kautsky, N. & Yarish, C. 2003. Integrated Mariculture: Asking the Right Questions. Aquaculture. 226: 69-90. DOI: https://doi.org/10.1016/S0044-8486(03)00469-1.

Pawhestri, S. W., Hidayat, J. W., Putro, S. P., 2015. Assessment of Water Quality Using Macrobenthos as Bioindicator and Its Application on Abundance-Biomass Comparison (ABC) Curves. International Journal of Science and Engineering. 8(2): 84-87. DOI: https://doi.org/10.12777/ijse.8.2.84-87.

Putro, S. P. 2014. Metode Sampling Penelitian Makrobenthos dan Aplikasinya. Graha Ilmu. Yogyakarta. 176-177.

Rakocinski, C. F., Brown, S. S., Gaston, G. R., Heard, R. W., Walker, W. W., & Summers, J. K. 2000. Species-abundance-biomass Responses by Estuarine Macrobenthos to Sediment Chemical Contamination. Journal of Aquatic Ecosystem: Stress and Recovery. 7(3): 201-214.

Clarke, K. R., & Gorley, R. N. 2006. Primer. PRIMER-e, Plymouth. 866.

Farantika, R., Putro, S. P., Hadi, M., Triarso, I. 2020. Study on Water Quality Physical-chemical Parameters Aquaculture Areas in Menjangan Besar Island, Kepulauan Karimunjawa, Jepara, Indonesia. J. Phys.: Conf. Ser. 1524: 012136. DOI: https://doi.org/10.1088/1742-6596/1524/1/012136.

Boon, A. R. and van Dalfsen, J. 2022. Long-term Changes in the Macrobenthic Assemblages at a Harbour Sediment Disposal Site in the Southern North Sea. Marine Environmental Research. 178(105663): 1-12. DOI: https://doi.org/10.1016/j.marenvres.2022.105663.

Rizal, A. C., Ihsan, Y. N., Afrianto, E., & Juliadi, L. P. S. 2017. Pendekatan Status Nutrien Pada Sedimen untuk Mengukur Struktur Komunitas Makrozoobentos di Wilayah Muara Sungai dan Pesisir Pantai Rancabuaya, Kabupaten Garut. Jurnal Perikanan Kelautan. 8(2).

Menteri Lingkungan Hidup. 2004. Peraturan No. 51: Standar Air Laut [Decree of Ministry of Environment. No. 51: Marine Water Standard].

Dahuri, R., Rais, J., Ginting, S. P., &Sitepu, M. J. 2008. Pengelolaan Sumberdaya Pesisir dan Lautan Secara Terpadu. Pradnya Paramitha Press.

Kadim, M. K., Pasisingi, N. and Paramata, A. R. 2017. Kajian Kualitas Perairan Teluk Gorontalo dengan Menggunakan Metode STORET. Depik. 6(3): 235-241.

Affan, J. M. 2010. Analysis of Marine Resource Potential and Water Quality based on Physical and Chemical Parameters in the East Coast of Kabupaten Bangka Tengah. Jurnal Spektra. 10(2): 99-113.

Widiadmoko, W. 2013. Pemantauan Kualitas Air Secara Fisika dan Kimia di Perairan Teluk Hurun Bandar Lampung. Balai Besar Pengembangan Budidaya Laut (BBPBL). Bandar Lampung: Politeknik Negeri Lampung.

Erari, S. S., Mangimbulude, J., dan Lewerissa, K. 2012. Pencemaran Organik di Perairan Pesisir Pantai Teluk Youtefa Kota Jayapura, Papua. Prosiding Seminar Nasional Kimia Unesa 2012. C327-C340.

Putro, S. P., Ramadhon, M. F., & Widowati, S. A. 2021. Comparison Structure of Life-Form Hard Corals at Aquaculture and Non-Aquaculture Sites as Biomonitoring at Karimunjawa Islands, Indonesia. International Journal of Innovation, Creativity and Change. 15(9): 247-260.

Nurrachmi, I., & Marwan. 2012. Kandungan Bahan Organik Sedimen dan Kelimpahan Makrozoobenthos sebagai Indikator Pencemaran Perairan Pantai Tanjung Uban Kepulauan Riau. Laporan Penelitian, LIPI Universitas Riau. Pekanbaru.

Prahmawaty, R. F., Putro, S. P., Biologi, D., Sains, F., Diponegoro, U., Terpadu, L. 2018. Struktur Komunitas Makrobentos Pada Kawasan Budidaya dan Non Budidaya di Pulau Tembelas Kabupaten Karimun Kepuluan Riau. Bioma. 20(1).

Chapman, Deborah. 1996. Water Quality Assessments - A Guide to Use of Biota, Sediments and Water in Environmental Monitoring. Second Edition. F & FN Spon. London. 75-97.

Riniatsih, I., & Kushartono, E., W. 2009. Substrat Dasar dan Parameter Oseanografi sebagai Penentu Keberadaan Gastropoda dan Bivalvia di Pantai Sluke Kabupaten Rembang. Ilmu Kelautan. 14(1): 50-59. DOI: https://doi.org/10.14710/ik.ijms.14.1.50-59.

Anhwange, B, A., Agbaji., E, B and Gimba., E, C. 2012. Impact Assessment of Human Activities and Seasonal Variation on River Benue, within Makurdi Metropolis. J. Sci. Technol. 2: 248-254.

Clarke, K. R., Gorley, R. N., Somerfield, P. J., Warwick, R. M. 2014. Change in Marine Communities: An Approach to Statistical Analysis and Interpretation. 3rd edn. Plymouth, Primer-E Ltd. 256.

Pearson, T. H. and Rosenberg, R. 1978. Macrobenthic Succession in Relation to Organic Enrichment and Pollution of the Marine Environment. Oceanogr. Mar. Biol. Ann. Rev. 16: 229-311.

DOI: https://www.researchgate.net/publication/243785865.

Brito, R. M., Pompolo, S. D. G., Magalhães, M. F. M., De Barros, E. G., Sakamoto-Hojo, E. T. 2005. Cytogenetic Characterization of Two Partamona Species (Hymenoptera, Apinae, Meliponini) by Fluorochrome Staining and Localization of 18S rDNA Clusters by FISH. Cytology. 70: 373-380. DOI: https://doi.org/10.1508/cytologia.70.373.

Kristensen, E. 2000. Organic Matter Diagenesis at the Oxic/anoxic Interface in Coastal Marine Sediments, with Emphasis on the Role of Burrowing Animals. Hydrobiology. 426: 1-24. DOI: https://doi.org/10.1007/978-94-011-4148-2_1.

Rosenberg, R. 2001. Marine Benthic Faunal Successional Stages and Related Sedimentary Activity. Scientia Marina. 65(Suppl. 2): 107-119. DOI: https://doi.org/10.3989/scimar.2001.65s2107.

Pandey, V., Thiruchitrambalam, G. 2019. Spatial and Temporal Variability of sandy intertidal macrobenthic Communities and their Relationship with Environmental Factors in a Tropical Island. Estuarine Coast. Shelf Sci. 224: 73-83. DOI: https://doi.org/10.1016/j.ecss.2019.04.045.

Dauvin, J.,Pezy, J.-P., Baffreau, A., Bachelet, Q., Baux, N., Méar, Y., Murat, A., Poizot, E. 2020. Effects of a Salmon Fish Farm on Benthic Habitats in a High-energy Hydrodynamic System: The Case of the Rade Cherbourg (English Channel). Aquaculture. 518: 734832. DOI: https://doi.org/10.1016/j.aquaculture.2019.734832.

Putro, S. P., & Muhammad, F. 2019. The Comparison of Distribution Patterns of Macrobenthic Assemblages Adjacent Floating Net Cage Areas at Karang Lebar Island, Jakarta: A Multivariate Approach. Journal of Physics: Conference Series. 1217(1): 012131

Putro, S. P., Sharani, J., & Adhy, S. 2020. Biomonitoring of the Application of Monoculture and Integrated Multi-Trophic Aquaculture (IMTA) Using Macrobenthic Structures at Tembelas Island, Kepulauan Riau Province, Indonesia. Journal of Marine Science and Engineering. 8(11): 942.

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Published

2022-09-25

Issue

Vol. 84 No. 6: November 2022

Section

Science and Engineering

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How to Cite

UTILIZATION OF DOMINANT AND OPORTUNISTIC TAXA OF MACROBENTHIC ASSEMBLAGES INHABITING SEDIMENTS UNDER FISH FARMS FOR THE ENVIRONMENTAL STATUS ASSSESSMENT . (2022). Jurnal Teknologi, 84(6), 171-179. https://doi.org/10.11113/jurnalteknologi.v84.18319