Effects of fish herbivory on seagrass meadows of Guang-guang, Mati City, Philippines

Authors

  • Edison D. Macusi Faculty of Agriculture and Life Sciences (FALS), Davao Oriental State University (DOrSU), Mati City, Philippines - Fisheries Catch Assessment Project, Davao Oriental State University (DOrSU), Mati City, Philippines https://orcid.org/0000-0002-9714-1074
  • Norjan T. Masagnay Faculty of Agriculture and Life Sciences (FALS), Davao Oriental State University (DOrSU), Mati City, Philippines
  • Ivy M. Nallos Faculty of Agriculture and Life Sciences (FALS), Davao Oriental State University (DOrSU), Mati City, Philippines - Fisheries Catch Assessment Project, Davao Oriental State University (DOrSU), Mati City, Philippines https://orcid.org/0000-0003-3752-4847

DOI:

https://doi.org/10.47193/mafis.3632023010902

Keywords:

Davao Oriental, fish grazing, herbivore exclusion, plant-herbivory interactions, Siganus fuscescens, Thalassia hemprichii

Abstract

This study provides information on the effects of fish grazing on a seagrass bed that was dominated by Thalassia hemprichii in Guang-guang, Dahican, Mati City, Davao Oriental, Philippines. We tested the assumption that herbivore exclusion keeps the growth of seagrass shoots up to a minimum length. Fish visual census was used to count the abundance of fish in the area during high tide at a distance of 5 m away from the treatment cages with a 15 m transect length. Among all species, Siganus fuscescens was the most abundant (499) followed by S. guttatus (153), while Thalassoma jansenii was the less abundant (13). The result of the weekly fish count in the seagrass bed showed highly significant variations in the number and census of species present in the area (df = 11, MS = 2.88, F = 30.10, p < 0.001). Analysis of shoot length measurement in treatment cages also exhibited highly significant differences throughout the sampling period (df = 11, MS = 726.71, F = 1,633.10, p < 0.001). Comparison between initial and final shoot counts also showed significant differences, with a higher shoot count in the full cage (X2 = 8, df = 2, p = 0.018; FC > PC > OP). This study raises clear evidence to support the assumption that herbivore exclusion positively influences the growth of T. hemprichii in this area.

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References

Abreo NAS, Macusi ED, Jimenez LA. 2018. A survey of subtidal anthropogenic marine debris (AMD) in Mayo Bay, Mati City, Davao Oriental, Philippines. Philipp J Sci. 147: 597-600.

Abreo NAS, Siblos SKV, Macusi ED. 2020. Anthropogenic marine debris (AMD) in mangrove forests of Pujada Bay, Davao Oriental, Philippines. J Mar Isl Cult. 9: 38-53.

Alcoverro T, Mariani S. 2000. The effects of the sea urchin grazing on the Thalassodendron ciliatum seagrass beds of a Kenyan lagoon. Mar Ecol Prog Ser. 226: 255-263.

Azzurro E, Fanelli E, Mostarda E, Catra M, Andaloro F. 2007. Resource partitioning among early colonizing Siganus luridus and native herbivorous fish in the Mediterranean: an integrated study based on gut-content analysis and stable isotope signatures. J Mar Biol Assoc UK. 87: 991-998.

Bariche M. 2006. Diet of the Lessepsian fishes, Siganus rivulatu, and S. luridus (Siganidae) in the eastern Mediterranean: a bibliographic analysis. Cybium. 30: 41-49.

Bjork M, Short FT, McLeod E, Beer S. 2008a. Managing seagrasses for resilience to climate change. Gland: IUCN Resilience Science Group Working Paper Series. 3. 56 p.

Burkepile DE, Hay ME. 2006. Herbivore vs. nutrient control of marine primary producers: context-dependent effects. Ecology. 87: 3128-3139.

Burkepile DE, Hay ME. 2007. Predator release of the gastropod Cyphoma gibbosum increases predation on gorgonian corals. Oecologia. 154: 167-173.

Campos WL, del Norte A, Campos GC, McManus JW. 1994. Yield estimates, catch, effort and fishery potential of the reef flat in Cape Bolinao, Philippines. J Appl Itchthyol. 10: 82-95.

Cebrian J. 2002. Variability and control of carbon consumption, export, and accumulation in marine communities. Limnol Oceanogr. 47: 11-22.

Cheal A, Emslie M, Miller I, Sweatman H. 2012. The distribution of herbivorous fishes on the Great Barrier Reef. Mar Biol. 159: 1143-1154.

De Troch M, Melgo JL, Jimenez L, Gheerardyn H, Vincx M. 2008. Diversity and habitat selectivity of harpacticoid copepods from seagrass beds in Pujada Bay, The Philippines. J Mar Biol Assoc UK. 88: 515-526

Duarte CM. 2002. The future of seagrass meadows. Environ Conserv. 29: 192-206.

Duarte CM, Hemminga MA. 2000. Seagrass ecology. Cambridge: Cambridge University Press. 312 p.

Duarte CM, Middelburg J, Caraco N. 2005. Major role of marine vegetation on the oceanic carbon cycle. Biogeosciences. 2: 1-8.

Drifmeyer JE. 1981. Urchin Lytechinus variegatus grazing on Eelgrass, Zostera marina. Estuaries. 4: 374-375.

Fortes MD. 1995. Seagrass of East Asia: environmental and management perspectives. RCU/EAS Technical Report Series No. 6. Bangkok: UNDEP. 79 p.

Fortes MD. 2004. Wetland conservation and management in the Philippines: where are we now? the case of seagrass and mangrove. In: Wong MH, editor. Wetlands ecosystems in Asia. Amsterdam: Elsevier. p. 233-262.

Fox RJ, Bellwood DR. 2008. Remote video bioassays reveal the potential feeding impact of the rabbitfish Siganus canaliculatus (f: Siganidae) on an inner-shelf reef of the Great Barrier Reef. Coral Reefs. 27 (3): 605-615.

Froese R, Pauly D, editors. 2020. FishBase. [accessed 2020 Feb]. https://www.fishbase.org.

Gruner DS, Smith JE, Seabloom EW, Sandin SA, Ngai JT, Hillebrand H, Bolker BM. 2008. A cross‐system synthesis of consumer and nutrient resource control on producer biomass. Ecol Lett. 11 (7): 740-755.

Heck KL, Valentine JF. 2006. Plant-herbivore interactions in seagrass meadows. J Exp Mar Biol Ecol. 330: 420-436.

Hoey AS, Brandl SJ, Bellwood DR. 2013. Diet and cross-shelf distribution of rabbitfishes (f. Siganidae) on the northern Great Barrier Reef: implications for ecosystem function. Coral Reefs. 32 (4): 973-984.

Hughes AR, Stachowicz JJ, 2004. Genetic diversity enhances the resistance of a seagrass ecosystem to disturbance. Proc Natl Acad Sci USA. 101: 8998-9002.

Irawan A, Nganro NR. 2016. Distribution of seagrass in Inner Ambon Bay. J Trop Mar Sci Technol. 8 (1): 99-114.

Jimenez LA. 2016. Guide to common seagrass in Pujada Bay. Davao Oriental State College of Science and Technology. Mati City, Davao Oriental, Philippines, Regional Integrated Coastal Resource Management Center (RIC-XI). [accessed 2023 Mar]. http://kulturalink.nlp.gov.ph/cgi-bin/koha/opac-detail.pl?biblionumber=6860.

Jumawan-Nanual B, Metillo EB. 2008. Population structure and reproductive biology of Siganus fuscescens Houttuyn 1782 (Perciformes, Siganidae) in Pujada Bay, Southeastern Mindanao, Philippines. Philipp Sci. 45: 62-79.

Koch E. 2001. Beyond light: physical, geological and geochemical parameters as possible submersed aquatic vegetation habitat requirements. Estuaries. 24: 1-17.

Koike I, Mukai H, Nojima S. 1987. The role of the sea urchin, Tripneustes gratilla (Linnaeus), in decomposition and nutrient cycling in a tropical seagrass bed. Ecol Res. 2: 19-29.

Latuconsina H, Affandi R, Kamal MM, Butet NA. 2020a. Spatial distribution of white-spotted rabbitfish Siganus canaliculatus Parak, 1797 on different seagrass beds habitat of the Inner Ambon Bay. J Trop Mar Sci Technol. 12 (1): 89-106. Indonesian. DOI: https://doi.org/10.29244/jitkt.v12i1.27908

Latuconsina H, Affandi R, Kamal MM, Butet NA. 2020b. On the assessment of white-spotted rabbitfish (Siganus canaliculatus Park, 1797) stock in the Inner Ambon Bay, Indonesia. AACL Bioflux. 13 (4): 1827-1835.

Latuconsina H, Ambo-Rappe R. 2013. Daily variability of fish community in seagrass beds of Tanjung Tiram-Inner Ambon Bay. J Indones Ichthyol. 13 (1): 35-53. Indonesian.

Levinton JS. 2001. Marine biology: function, biodiversity, ecology. Oxford: Oxford University Press.

Lieske E, Myers R. 2002. Coral reef fishes: Indo-Pacific and Caribbean. Princeton: Princeton University Press.

Macusi ED. 2010. Effect of different herbivore guilds on the abundance and distribution patterns of autotrophs on a semi-exposed tropical rocky shore, Hong Kong. Philipp Sci. 47: 173-203.

Macusi ED. 2012. Grazing drives spatial variation in the abundance and distribution patterns of autotrophs in tropical rocky shore. Philipp J Sci. 141: 141-156.

Macusi ED, Katikiro RE, Deepananda KHMA, Jimenez LA, Conte AR, Fadli N. 2011. Human induced degradation of coastal resources in Asia-Pacific and implications on management and food resources. J Nat Stud. 9/10: 13-28.

Macusi ED, Tipudan CD. 2020. Effects of bioturbation of fiddler crabs in relation to the growth of mangrove saplings (Rhizophora apiculata) in a mangrove reforested area. J Mar Isl Cul. 9 (2): 1-10.

McGlathery KJ. 1995. Nutrient and grazing influences on a subtropical seagrass community. Mar Ecol Prog Ser. 122: 239-252.

Madduppa H, Margaretha MK, Bramandito A, Prartono T, Subhan B, Arafat D, Anggraini MP. 2019. Intraspecific genetic diversity and population subdivision of rabbitfish (Siganidae: Siganus canaliculatus) in urbanized reefs of Jakarta Bay, Indonesia. Biodiversitas. 20 (10): 2897-2902. DOI: https://doi.org/10.13057/biodiv/d201017

Maynawang IS, Macusi ED. 2023. Catch assessment of commercially important gastropods in Guang-Guang, Mati City, Davao Oriental, Philippines. Acad Biol. 1 (1). DOI: https://doi.org/10.20935/AcadBiol6029

McSkimming C, Tanner JE, Russell BD, Connell SD. 2015. Compensation of nutrient pollution by herbivores in seagrass meadows. J Exp Mar Biol Ecol. 471: 112-118.

Metillo EB, Cadelinia EE, Hayashizaki KI, Tsunoda T, Nishida S. 2016. Feeding ecology of two sympatric species of Acetes (Decapoda: Sergestidae) in Panguil Bay, the Philippines. Mar Freshwater Res. 67: 1420-1433.

Mumby PJ, Dahlgren CP, Harborne AR, Kappel CV, Micheli F, Brumbaugh DR, Holmes KE, Mendes JM, Broad K, Sanchirico JN, et al. 2006. Fishing, trophic cascades, and the process of grazing on coral reefs. Science. 311: 98-101.

Nagelkerken I, Dorenbosch M, Verberk WCEP, de la Moriniere CE, van der Velde G. 2000. Day-night shifts of fishes between shallow-water biotopes of a Caribbean Bay, with emphasis on the nocturnal feeding of Haemulidae and Lutjanidae. Mar Ecol Prog Ser. 194: 55-64.

Nallos IM, Macusi ED. 2023. Behavior and diet composition of fiddler crabs in Guang-guang, Dahican, Mati City, Davao Oriental, Philippines. Mar Fish Sci. 36 (2): 137-147. DOI: https://doi.org/10.47193/mafis.3622023010506

Noya YA, Purba M, Koropitas AF, Prartono T. 2016. Cohesive sediment transport modeling on Inner Ambon Bay. J Trop Mar Sci Technol. 8 (2): 671-687. Indonesian. DOI: https://doi.org/10.29244/jitkt.v8i2.15834

Peterson BJ, Rose CD, Rutten LM, Fourqurean JW. 2002. Disturbance and recovery following catastrophic grazing: studies of a successional chronosequence in a seagrass bed. Oikos. 97: 361-370.

Pickholtz SM, Kiflawi M, Friedlander AM, Belmaker J. 2018. Habitat utilization by an invasive herbivorous fish (Siganus rivulatus) in its native and invaded range. Biol Invasions. 20: 3499-3512.

Quinn GP, Keough MJ. 2002. Experimental design and data analysis for biologists. Cambridge: Cambridge University Press.

Randall JE, Kulbicki M. 2005. Siganus woodland, new species of rabbitfish (Siganidae) From New Caledonia. Cybium. 29: 185-189.

Salita JT, Ekau W, Saint-Paul U. 2003. Field evidence on the influence of seagrass landscapes on fish abundance in Bolinao, northern Philippines Mar Ecol Prog Ser. 247: 183-195.

Serio D, Alongi G, Catra M, Cormaci M, Furnari G. 2006. Changes in the benthic algal flora of Linosa island (Straits of Sicily, Mediterranean Sea). Bot Mar. 49: 135-144.

Shears NT, Babcock RC. 2002. Marine reserves demonstrate top-down control of community structure on temperate reefs. Oecologia. 132: 131-142.

Simora RMC, Trafalgar RFM, Legario FS. 2015. Characterization of extracellular enzymes from culturable autochthonous gut bacteria in rabbitfish (Siganus guttatus). ELBA Bioflux. 7: 67-76.

Smulders FOH, Becker ST, Campbell JE, Bakker ES, Boässon MJ, Bouwmeester MM, Vonk JA, Christianen MJA. 2022. Fish grazing enhanced by nutrient enrichment may limit invasive seagrass expansion. Aquat Bot. 176: 103464.

Soliman VS, Mendoza Jr. AB, Yamaoka K. 2008. Seaweed-associated fishes of Lagonoy Gulf of Bicol, the Philippines, with emphasis on siganids (Teleostei: Siganidae). Kuroshio Science. 2: 67-72.

Steneck RS, Hacker SD, Dethier MN. 1991. Mechanism determining competitive dominance between crustose coralline algae: a herbivore-mediated reversal. Ecology. 72: 938-950.

Taquet M, Dagorn L, Gaertner JC, Girard C, Aumerruddy R, Sancho G, Itano D. 2007. Behavior of dolphinfish (Coryphaena hippurus) around drifting FADs as observed from automated acoustic receivers. Aquat Living Resour. 20: 323-330.

Terayama K, Mizuno K, Tabeta S, Sakamoto S, Sugimoto Y, Sugimoto K, Fukami H, Sakagami M, Jimenez LA. 2022. Cost-effective seafloor habitat mapping using a portable speedy sea scanner and deep-learning-based segmentation: a sea trial at Pujada Bay, Philippines. Methods Ecol Evol. 13 (2): 339-345.

Teresa A, Simone M. 2002. Effects of sea urchin grazing on seagrass (Thalassodendron ciliatum) beds of a Kenyan lagoon. Mar Ecol Prog Ser. 226: 255-263.

Valentine JF, Heck KL. 2005. Perspective review of the impacts of overfishing on coral reef food web linkages. Coral Reefs. 24: 209-213.

Valentine JFV, Heck Jr KL. 1999. Seagrass herbivory: evidence for the continued grazing of marine grasses. Mar Ecol Prog Ser. 176: 291-302.

Verges A, Becerro MA, Alcoverro T, Romero J. 2007. Variation in multiple traits of vegetative and reproductive seagrass tissues influences plant-herbivore interactions. Oecologia. 151: 675-686.

Vinueza LR, Branch GM, Branch ML, Bustamante RH. 2006. Top-down herbivory and bottom-up El niño effects on Galapagos rocky shore communities. Ecol Monogr. 76: 111-131.

Vonk JA, Pijnappels MHJ, Stapel J. 2008. In situ quantification of Tripneustes gratilla grazing and influences on a mixed-species tropical seagrass meadow. Mar Ecol Prog Ser. 360: 107-114.

von Westernhagen H. 1973. The natural food of the rabbitfish Siganus oramin and S. striolata. Mar Biol. 22 (4): 367-370.

Wilson SK, Bellwood DR, Choat JH, Furnas MJ. 2003. Detritus in the epilithic algal matrix and its use by coral reef fishes. Oceanogr Mar Biol Annu Rev. 41: 279-309.

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Published

2023-05-05

How to Cite

Macusi, E. D., Masagnay, N. T. and Nallos, I. M. (2023) “Effects of fish herbivory on seagrass meadows of Guang-guang, Mati City, Philippines”, Marine and Fishery Sciences (MAFIS), 36(3), pp. 219–232. doi: 10.47193/mafis.3632023010902.

Issue

Vol. 36 No. 3 (2023): Marine and Fishery Sciences (MAFIS)

Section

Original Research Papers

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Copyright (c) 2023 Edison D. Macusi, Norjan T. Masagnay, Ivy M. Nallos

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