POPULATION ASSEMBLAGES OF A TERMITE SPECIES, Macrotermes gilvus HAGEN (BLATTODEA: TERMITIDAE) AT DIFFERENT LAND USES
Abstract
Several studies were conducted on the distribution of Macrotermes gilvus Hagen (Blattodea: Termitidae) especially in northern part of Peninsular Malaysia. However, information on distribution of this termite species in different type of landscapes was scarcely reported. Therefore, a study was conducted to investigate the M. gilvus population and distribution in different land uses as well as the variation of mound size based on different areas. Four areas of different land use in Universiti Putra Malaysia, Selangor, Malaysia; oil palm plantation, landscaped garden, farmland, and urban area were selected to survey the quantity and size of their mounds as well as the population of M. gilvus. For each area, three M. gilvus mounds from three size categories: small (height of 1 to 20 cm; diameter of 1 to 50 cm), medium (height of 21 to 40 cm; diameter of 51 to 80 cm), and large (height of 41 to 60 cm; diameter of 81 to 120 cm) were randomly selected. The result of this study shows that oil palm plantation has the highest number of mounds and population density of M. gilvus (51.4% and 845882.35 individual per ha), followed by landscaped area (35.5% and 401940.00 individual per ha). The farmland recorded the lowest number of mound and population density (13.1% and 164385.59 individual per ha), meanwhile the species was absent in urban area. All areas except the urban setup were significantly dominated with large size of mounds, followed by medium size mounds and the least was small size of mounds. This study concluded that the species preferred to inhabit the shaded area, dense-canopy cover with less human activities and buildings, which provided the species a good area to build mound and foraging for food.
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Abe, S.S., Watanabe, Y., Onishi, T., Kotegawa, T. & Wakatsuki, T. 2011. Nutrient storage in termite (Macrotermes bellicosus) mounds and the implications for nutrient dynamics in a tropical savanna Ultisol. Soil Science and Plant Nutrition 57: 786 – 795
Abe, T., Bignell, D.E. & Higashi, M. 2000. Termites: Evolution, Sociality, Symbioses, Ecology. United States of America: Springer Science Business Media.
Aiman Hanis, J., Abu Hassan, A., Nurita, A.T. & Che Salmah, R.W. 2014. Community structure of termites in a hill dipterocarp forest of Belum- Temengor Forest Complex, Malaysia: Emergence of pest species. The Raffles Bulletin of Zoology 62: 3 – 11.
Alia Diyana, M.H., Suganthi, A. & Nivaarani, A. 2020. Termite species and structural pest identification in selected rural area of Kelantan, Malaysia. IOP Conference Series: Earth and Environmental Science 549: 1 – 7.
Andi Saputra, Madihah, H., Nur-Atiqah, J., Izfa Riza, H. & Faszly, R. 2017. Effects of day time sampling on the activities of termites in oil palm plantation at Malaysia-Indonesia. Serangga 22(1): 23 – 32.
Arinana, A., Aldina, R., Nandika, D., Rauf, A., Harahap, I.S., Sumertajaya, I.M. & Bahriar, E.T. 2016. Termite diversity in urban landscape, South Jakarta, Indonesia. Insects 7(2): 20.
Dhang, P. 2011. A preliminary study on elimination of colonies of the mound building termite Macrotermes gilvus (Hagen) using a chlorfluazuron termite bait in the Philippines. Insects 2(4): 486 – 490.
Davies, A.B., Parr, C.L. & Eggleton, P. 2021. A global review of termite sampling methods. Insectes Sociaux 68(1): 1 – 12.
Egan, B., Nethavhani, Z. & van Asch, B. 2021. Overview of the genetic diversity of African Macrotermes (Termitidae: Macrotermitinae) and implications for taxonomy, ecology and food science. Insects 12(6): 518.
Jones, D.T., Verkerk, R. & Eggleton, P. 2005. Methods for sampling termites. In Leather, S. (ed). Insect Sampling in Forest Ecosystems, pp. 221 – 253. United Kingdom: Blackwell Publishing.
Jouquet, P., Chaudhary, E. & Kumar, A.R.V. 2017. Sustainable use of termite activity in agro-ecosystems with reference to earthworms. A review. Agronomy for Sustainable Development 38(1): 3.
Helmiyetti, Darmi, & Rezan, O.W. 2021. The species and abundance of Subterranean termites (Insecta: Isoptera) in the area of University of Bengkulu. Advance in Biological Research 14: 158 – 164.
Lee, C.C., Neoh, K.B. & Lee, C.Y. 2012. Caste composition and mound size of the subterranean termite Macrotermes gilvus (Isoptera: Termitidae: Macrotermitinae). Annals of the Entomological Society of America 105(3): 427 - 433.
Miyagawa, S., Koyama, Y., Kokubo, M., Matsushita, Y., Adachi, Y., Sivilay, S., Kawakubo, N. & Oba S. 2011. Indigenous utilization of termite mounds and their sustainability in a rice growing village of the central plain of Laos. Journal of Ethnobiology and Ethnomedicine 7(1): 24.
Neoh, K.B. & Lee,C.Y. 2009. Flight activity of two sympatric termite species, Macrotermes gilvus and Macrotermes carbonarius (Termitidae: Macrotermitinae). Environmental Entomology 38(6): 1697 - 1706.
Naeem, I., Lahiru, S.W. & Evans, T.A. 2017. Bait station preferences in two Macrotermes species. Journal of Pest Science 90: 217 – 225.
Nyagumbo, I., Munamati, M., Mutsamba, E.F., Thierfelder, C., Cumbane, A. & Dias, D. 2015. The effects of tillage, mulching and termite control strategies on termite activity and maize yield under conservation agriculture in Mozambique. Crop Protection 78: 54 – 62.
Odeyakun, A.V., Anikwe, J.C., Okelana, F.A., Mokwunye, I.U. & Azeez, O.M. 2011. Pesticidal efficacy of three tropical herbal plants’ leaf extracts against Macrotermes bellicosus, an emerging pest of cocoa, Theobroma cacao L. Journal of Biopesticides 4(2): 131 – 137.
Pearce, M.J. 1997. Termites: Biology and Pest Management. United Kingdom: Cambridge University Press.
Roonwal, M.L. 1970. Termites of the oriental region. In Krishna, K. (ed.). Biology of Termites pp. 315 - 391. New York: Academic Press.
Rouland-Lefevre, C. 2010. Termites as pests of agriculture. In Bignell, D.E., Roisin, Y. & Lo N. (eds). Biology of Termites: A Modern Synthesis, pp. 499 – 517. United Kingdom: Springer.
Silva, I.S., Lucena, E.F., Moura, F.M.S. & Vasconcellos, A. 2021. Termite flights seasonally promote nutrient pulses in the Caatinga dry forest in northeastern Brazil. Applied Soil Ecology 166: 104066.
Stiegler, C., June, T., Markwitz, C., Camarretta, N., Ashehad A.A. & Knohl, A. 2023. Wind regimes above and below a dense oil palm canopy: Detection of decoupling and its implications on CO2 flux estimates. Agricultural and Forest Meteorology 341(7): 1 – 57.
Subekti, N. & Mar’ah, R. 2019. Estimating population size for Macrotermes gilvus Hagen (Blattodea: Termitidae) in Indonesia. Journal of Physics: Conference Series 1321: 1 – 4.
Tasaki, E., Mitaka, Y., Takahashi, Y., Waliulla, A.S.M., Tamannaa, Z., Sakamoto, T., Ariful, I., Kamiya, M., Sato, T., Aramaki, S., Kikushima, K., Horikawa, M., Nakamura, K., Kahyo, T., Takata M., Setou, M. & Matsuura. K. 2023. The royal food of termites shows king and queen specificity. PNAS Nexus 2(7): 222.
Tho, Y.P. 1992. Subfamily Macrotermitinae. In Kirton, L.G. (ed). Termites of peninsular Malaysia, pp. 126 – 132. Kuala Lumpur: Forest Research Institute Malaysia (FRIM).
Vesala, R., Niskanen, T., Liimatainen, K., Boga, H., Pellikka, P. & Rikkinen, J. 2017. Diversity of fungus-growing termites (Macrotermes) and their fungal symbionts (Termitomyces) in the semiarid Tsavo Ecosystem, Kenya. Biotropica 49(3): 402 – 412.
Veera, S., Ahmad Sofiman, O. & Chow Yang, L. 2017. Phylogeography of the termite Macrotermes gilvus and insight into ancient dispersal corridors in Pleistocene Southeast Asia. Plos One 12(11): 1 – 22.
Zadji, L., Baimey, H., Afouda, L., Moens M., & Decraemer W. 2014. Characterization of biocontrol traits of heterorhabditid entomophatogenic nematode isolates from South Benin targeting the termite pest Macrotermes bellicosus. BioControl 59: 333 – 344.
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