Changes in Tetragnatha Spider Abundance and Web Characteristics Throughout Rice Field Development

Authors

  • Venus Saksongmuang Department of Biology, Faculty of Science, Prince of Songkla University, Songkhla 90110, THAILAND
  • Booppa Petcharad Department of Biotechnology, Faculty of Science and Technology, Thammasat University, Pathum Thani Province, 90112, THAILAND
  • Sara Bumrungsri Department of Biology, Faculty of Science, Prince of Songkla University, Songkhla 90110, THAILAND

DOI:

https://doi.org/10.58837/tnh.24.1.260791

Keywords:

rice stage, Tetragnatha spider, vegetation complexity, web trait

Abstract

Vegetation change is one of the major drivers affecting web-building spider species, causing them to vary in abundance and to adapt their web traits accordingly. Rice ecosystems are among the most important agricultural areas, and understanding the influence of vegetation complexity throughout rice development on common Tetragnatha spiders is crucial to developing sustainable management practices. Six sympatric species of Tetragnatha spiders, T. javana, T. mandibulata, T. maxillosa, T. nitens, T. praedonia and T. virescens, were found in rainfed lowland rice fields in southern Thailand. The abundance, web diameter and web height of each species were measured and compared across rice developmental stages. Overall, the number of Tetragnatha spiders was significantly higher in the tillering stage than the flowering stage, while abundance during the booting stage was not significantly different from either. The numbers of T. javana, T. mandibulata and T. maxillosa were higher than those of T. nitens, T. praedonia, and T. virescens during all rice stages. Throughout the rice growing season, vegetation complexity increased continuously while both web diameter and web height exhibited hump-shaped patterns for all spider species (i.e., webs were larger and built higher above ground level during the middle of the growing season). The diameter and height of Tetragnatha webs varied by species, but only web diameter was positively related to spider body length for almost all spider species. Our findings confirm that changes in vegetation complexity during rice development, as well as spider body length, affect the functional traits of Tetragnatha webs in rice ecosystems.

References

Altieri, M.A. 1999. The ecological role of biodiversity in agroecosystems. Invertebrate Biodiversity as Bioindicators of Sustainable Landscapes, 19–31.

Anis Joseph, R. and Premila, K.S. 2016a. A study on the richness of spider fauna in rice ecosystem. Journal of Entomology and Zoology Studies, 4(2): 425–430.

Anis Joseph, R. and Premila, K. S. 2016b. Species Composition and Quantitative Analysis of Tetragnathid Spiders, Tetragnathidae (Araneae) in Rice Fields. International Journal of Fauna and Biological Studies 2016, 3(3): 158–160.

Ávila, A.C., Stenert, C., Rodrigues, E.N.L. and Maltchik, L. 2017. Habitat structure determines spider diversity in highland ponds. Ecological Research, 32(3): 359–367.

Baba, Y.G., Kusumoto, Y. and Tanaka, K. 2018. Effects of agricultural practices and fine-scale landscape factors on spiders and a pest insect in Japanese rice paddy ecosystems. BioControl, 63 (2): 265–275.

Bambaradeniya, C.N.B., Edirisinghe, J.P., De Silva, D.N., Gunatilleke, C.V.S., Ranawana, K.B. and Wijekoon, S. 2004. Biodiversity associated with an irrigated rice agro-ecosystem in Sri Lanka. Biodiversity and Conservation, 13 (9): 1715–1753.

Bambaradeniya, C.N. and Edirisinghe, J.P. 2008. Composition, structure and dynamics of arthropod communities in rice agroecosystem. Ceylon Journal of Science, 37(1): 23–48.

Bao, L., Ginella, J., Cadenazzi, M., Castiglioni, E. A., Martínez, S., Casales, L., Caraballo, M. P., Laborda, Á. and Simo, M. 2018. Spider assemblages associated with different crop stages of irrigated rice agroecosystems from eastern Uruguay. Biodiversity data journal, 6: e24974.

Barrion, A.T. and Litsinger, J.A. 1995. Riceland Spiders of South and Southeast Asia. CABI and IRRI, Manila, Philippines, 700 pp.

Barton, K. 2018. MuMIn: Multi-Model Inference. R package version 1.40.4. Available from:https://CRAN.R-project.org/ package=MuMIn (accessed 20 June, 2023)

Bell, J.R., Bohan, D.A., Shaw, E.M. and Weyman, G.S. 2005. Ballooning dispersal using silk: World fauna, phylogenies, genetics and models. Bulletin of Entomological Research, 95: 69–114.

Blackledge, T.A., Binford, G.J. and Gillespie, R. G. 2003. Resource use within a community of Hawaiian spiders (Araneae: Tetragnathidae). Annales Zoologici Fennici, 40: 293–303.

Candek, K., Agnarsson, I., Binford, G.J. and Kuntner, M. 2021. Biogeography of Long-Jawed Spiders Reveals Multiple Colonization of the Caribbean. Diversity. 13: 622.

Cinar, O., Umbanhowar, J., Hoeksema, J.D. and Viechtbauer, W. 2021. Using information-theoretic approaches for model selection in meta-analysis. Research Synthesis Methods, 12(4): 537–556.

Cooper J.E., 2011. Anesthesia, Analgesia, and Euthanasia of Invertebrate. ILAR journal, 52(2): 196–204.

Cotoras, D.D., Murray, G.G. R., Kapp, J., Gillespie, R.G., Griswold, C.E., Simison, W.B., Green, R.E. and Shapiro, B. 2017. Ancient DNA resolves the history of Tetragnatha (Araneae, Tetragnathidae) spiders on Rapa Nui. Genes, 8: 403.

Diehl, E., Mader, V.L., Wolters, V. and Birkhofer, K. 2013. Management intensity and vegetation complexity affect web building spiders and their prey. Oecologia, 173(2): 579–589.

Dzulhelmi, M.N., Goh, T.G., Bakri, A., Rahim, F., Mohamed, Z. and Yusoff, N.R. 2017. Web characteristics determine niche partitioning for orb-web spiders (Araneae, Tetragnathidae) in Malaysia. Oriental Insects, 51(3): 262–275.

Dzulhelmi, M.N., Goh, T.G. and Suriyanti, S. N. P. 2018a. Coexistence of four orb-web spiders in an oil palm plantation in Peninsular Malaysia. Turkish Journal of Entomology, 42(4): 295–303.

Dzulhelmi, M.N., Goh, T.G., Zulqarnain, M. and Norma-Rashid, Y. 2018b. Relationships between morphology and web characteristics of four spider species (Araneae: Tetragnathidae) in Malaysia. Taiwanese Journal of Entomology Study, 3 (1): 1–11.

Garamszegi, L.Z. 2011. Information-theoretic approaches to statistical analysis in behavioural ecology: an introduction. Behavioral Ecology and Sociobiology, 65: 1–11.

Glover, N. 2013. The habitat preferences of web building spiders. The Plymouth Student Scientist, 6(1): 363–375.

Gong, T., Yang, K., Lin, Z., Fang, S., Wu, X., Zhu, R. and Peng, Y. 2021. Remote estimation of leaf area index (LAI) with unmanned aerial vehicle (UAV) imaging for different rice cultivars throughout the entire growing season. Plant Methods, 17(88). https://doi.org/10.1186/s13007-021-00789-4

Guo, X., Li, K., Shao, Y., Wang, Z., Li, H., Yang, Z., Long, L. and Wang, S. 2018. Inversion of Rice Biophysical Parameters Using Simulated Compact Polarimetric SAR C-Band Data. Sensors. 18(7): 2271.

Guthery, F.S., Burnham, K.P. and Anderson, D.R. 2003. Model Selection and Multimodel Inference: A Practical Information-Theoretic Approach. The Journal of Wildlife Management, 67(3): 655.

Henaut, Y., Garcia-Ballinas, J.A. and Alauzet, C. 2006. Variations in web construction in Leucauge venusta (Araneae, Tetragnathidae). Journal of Arachnology, 34 (1): 234–240.

Herberstein, M.E. and Elgar, M.A. 1994. Foraging strategies of Eriophora transmarina and Nephila plumipes (Araneae: Araneoidea): nocturnal and diurnal orb-weaving spiders. Austral Ecology, 19: 451–457.

Jayakumar, S. and Sankari, A. 2010. Spider population and their predatory efficiency in different rice establishment techniques in Aduthurai, Tamil Nadu. Journal of Biopesticides, 3: 20–27.

Kennedy, S., Lim, J.Y., Clavel, J., Krehenwinkel, H. and Gillespie, R.G. 2019. Spider webs, stable isotopes and molecular gut content analysis: Multiple lines of evidence support trophic niche differentiation in a community of Hawaiian spiders. Functional Ecology, 33: 1722–1733.

Kiritani, K.S., Kawahara, S., Sasaba, T. and Nakasuji, F. 1972. Quantitative evaluation of predation by spiders on the green rice leafhopper Nephotettix cincticeps Uhler, by a sight count method. Researches on Population Ecology, 13(2): 187–200.

Landis, D.A., Wratten, S.D. and Gurr, G. M. 2000. Habitat management to conserve natural enemies of arthropod pests in agriculture. Annual Review of Entomology, 45: 175–201.

Langellotto, G.A. and Denno, R.F. 2004. Responses of in-vertebrate natural enemies to complex structured habitats: a meta analytical synthesis. Oecologia, 139(1): 1–10.

Lawler, S.P. 2001. Rice fields as temporary wetlands: A review. Israel Journal of Zoology, 47(4): 513–528.

Losey, J.E. and Denno, R.F. 1998. Positive predator–predator interactions: enhanced predation rates and synergistic suppression of aphid populations. Ecology, 79(6): 2143–2152.

Ludy, C. 2007. Prey selection of orb web spiders (Araneidae) on field margins. Agriculture, Ecosystems and Environment, 119(3-4): 368–372.

Leitão, S., Pinto, P., Pereira, T. and Brito, M.F. 2007. Spatial and temporal variability of macroinvertebrate communities in two farmed Mediterranean rice fields. Aquatic Ecology, 41(3): 373–386.

Macfadyen, S., Kramer, E.A., Parry, H.R. and Schellhorn, N.A. 2015. Temporal change in vegetation productivity in grain production landscapes: linking landscape complexity with pest and natural enemy communities. Ecological Entomology, 40: 56–69.

Malumbres-Olarte, J., Vink, C.J., Ross, J.G., Cruickshank, R.H. and Paterson, A.M., 2012. The role of habitat complexity on spider communities in native alpine grasslands of New Zealand. Insect Conservation and Diversity, 6(2): 124–134.

McNett, B.J. and Rypstra, A.L. 2000. Habitat selection in a large orb weaving spider: vegetation complexity determines site selection and distribution. Ecological Entomology, 25(4): 423–432.

Michalko, R., Pekar, S. and Entling, M. H. 2019. An updated perspective on spiders as generalist predators in biological control. Oecologia, 189: 21–36.

Michalko, R., Košulič, O., Wongprom, P., Songsangchote, C., Saksongmuang, V. and Trisurat, Y., 2021. Reforestations of Tropical Forests Alter Interactions Between Web-Building Spiders and Their Prey. Ecosystems, 24(8): 1962–1975.

Mishra, A., Kumar, B. and Rastogi, N. 2020. Predation potential of hunting and web-building spiders on rice pests of Indian subcontinent. International Journal of Tropical Insect Science, 41(2): 1027–1036.

Mithali, M.H. and Pai, I. 2018. Distribution, Diversity and Ecology of Spider Species at Two Different Habitats. International Journal of Environmental Sciences and Natural Resources 0164. 8(5): 555–747.

Okuma, C. 1988a. A Revision of the Genus Tetragnatha Latreille (Araneae, Tetragnathidae) of Asia, Part I. Journal of the Faculty of Agriculture Kyushu University, 32(3.4): 165–181.

Okuma, C. 1988b. A Revision of the Genus Tetragnatha Latreille (Araneae, Tetragnathidae) of Asia, Part II. Journal of the Faculty of Agriculture Kyushu University, 32(3.4): 183–213.

Radermacher, N., Hartke, T. R., Villareal, S. and Scheu, S. 2020. Spiders in rice-paddy ecosystems shift from aquatic to terrestrial prey and use carbon pools of different origin. Oecologia, 192(3): 801–812.

Rattanapun, W. 2012. Diversity and population dynamics of pests and predators in irrigated rice fields with treated and untreated pesticide. Communications in agricultural and applied biological sciences, 77(4): 601–609.

Richardson, M.L. and Hanks, L.M. 2009. Partitioning of Niches Among Four Species of Orb-Weaving Spiders in a Grassland Habitat. Environmental Entomology, 38(3): 651–656.

Saksongmuang, V., Miyashita, T., Maneerat, T. and Bumrungsri, S. 2020. Population dynamics and prey composition of Tetragnatha spiders (Araneae: Tetragnathidae) in semi-organic rice fields, Songklanakarin Journal of Science and Technology, 42(4): 725–733.

Saksongmuang, V., Michalko, R., Petcharad, B. and Bumrungsri, S. 2024 Changes in vegetation complexity during the development of rice ecosystems affect orb-weaving spider-prey trophic networks. Agricultural and Forest Entomology, 1–13.

Sensenig, A.T., Agnarsson, I. and Blackledge, T. A. 2011. Adult spiders use tougher silk: ontogenetic changes in web architecture and silk biomechanics in the orb-weaver spider. Journal of Zoology, 285: 28-38.

Settle, W.H., Ariawan, H., Astuti, E.T., Cahyana, W., Hakim, A.L. amd Hindayana, D., 1996. Managing tropical rice pests through conservation of generalist natural enemies and alternative prey. Ecology, 77(7): 1975–1988.

Skaug, H., Fournier, D., Nielsen, A., Magnusson, A.and Bolker, B., 2018. glmmADMB: Generalized linear mixed models using AD model builder. R package version 0.8.3.4 Available from: http://glmmadmb.r-forge.r-proje ct.org/ (accessed 20 June, 2023).

Song, D.X., Zhu, M.S. and Chen, J. 1999. The spiders of China. Hebei Science and Technology Publishing House Shijiazhuang, 640 pp.

Takada, M. B., Kobayashi, T., Yoshioka, A., Takagi, S. and Washitani, I. 2013. Facilitation of ground dwelling wolf spider predation on mirid bugs by horizontal webs built by Tetragnatha spiders in organic paddy fields. Journal of Arachnology, 41(1): 31–35.

Tahir, H. M. and Butt, A. 2008. Activities of spiders in rice fields of central Punjab, Pakistan. Acta Zoologica, 54(4):701–711.

Tahir, H. M., Butt, A. and Sherawat, S. M. 2009. Foraging strategies and diet composition of two orb web spiders in rice ecosystems. Journal of Arachnology, 37(3): 357–362.

Tahir, H. M., Butt, A. and Alam, I. 2010. Relationships of web characteristics and body measures of Leucauge decorate (Araneae: Tetragnathidae). Pakistan Journal of Zoology, 42(3): 261–265.

Tahir, H. M., Butt, A., Mukhtar, M. K., Bilal, M. and Khan, S. Y. 2012. Co-existence of Four Orb Weaving Spiders in the Rice Ecosystem. Pakistan Journal of Zoology, 44(6): 1521–1528.

Tew, N.E. and Hesselberg, T. 2018. Web asymmetry in the tetragnathid orb spider Metellina mengei (Blackwell, 1869) is determined by web inclination and web size. Journal of Arachnology, 46(2): 370–372.

Tsutsui, M.H., Tanaka, K., Baba, Y.G. and Miyashita, T. 2016. Spatiotemporal dynamics of generalist predators (Tetragnatha spider) in environmentally friendly paddy fields. Applied Entomology and Zoology, 51(4): 631–640.

Tsutsui, M.H., Kobayashi, K. and Miyashita, T. 2018. Temporal trends in arthropod abundances after the transition to organic farming in paddy fields. PLoS ONE 13(1): e0190946.

Uetz, G.W., Jonso, A.D. and Schemske, D.S. 1978. Web placement, web structure, and prey capture in orb-weaving spiders. Bulletin of the British Arachnological Society, 4: 141–148.

Vungsilabutr, W. 1988. The spider genus Tetragnatha in the paddy fields of Thailand (Araneae: Tetragnathidae). Thai Journal of Agricultural Science, 21: 63–74.

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Published

2024-06-20

How to Cite

[1]
Saksongmuang, V. , Petcharad, B. and Bumrungsri, S. 2024. Changes in Tetragnatha Spider Abundance and Web Characteristics Throughout Rice Field Development. Tropical Natural History. 24, 1 (Jun. 2024), 128–136. DOI:https://doi.org/10.58837/tnh.24.1.260791.