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Species composition and habitat preferences of benthic ostracod and foraminifera in seagrass and non-seagrass systems within a tropical estuary

Published online by Cambridge University Press:  10 December 2020

Chandran Raynusha ,
Mohammad Rozaimi Open the ORCID record for Mohammad Rozaimi [Opens in a new window] ,
Ramlan Omar ,
Noraswana Nor Faiz ,
Nur Munirah Hesan ,
Syarifah Nor Hanis ,
Siti Aisyah Abdullah  and
Eizyan Izzati
Chandran Raynusha
Affiliation:
Department of Earth Sciences and Environment, Faculty of Science and Technology, Universiti Kebangsaan Malaysia, 43600 UKM Bangi, Selangor, Malaysia
Mohammad Rozaimi*
Affiliation:
Department of Earth Sciences and Environment, Faculty of Science and Technology, Universiti Kebangsaan Malaysia, 43600 UKM Bangi, Selangor, Malaysia
Ramlan Omar
Affiliation:
Department of Earth Sciences and Environment, Faculty of Science and Technology, Universiti Kebangsaan Malaysia, 43600 UKM Bangi, Selangor, Malaysia
Noraswana Nor Faiz
Affiliation:
Department of Earth Sciences and Environment, Faculty of Science and Technology, Universiti Kebangsaan Malaysia, 43600 UKM Bangi, Selangor, Malaysia
Nur Munirah Hesan
Affiliation:
Department of Earth Sciences and Environment, Faculty of Science and Technology, Universiti Kebangsaan Malaysia, 43600 UKM Bangi, Selangor, Malaysia
Syarifah Nor Hanis
Affiliation:
Department of Earth Sciences and Environment, Faculty of Science and Technology, Universiti Kebangsaan Malaysia, 43600 UKM Bangi, Selangor, Malaysia
Siti Aisyah Abdullah
Affiliation:
Department of Earth Sciences and Environment, Faculty of Science and Technology, Universiti Kebangsaan Malaysia, 43600 UKM Bangi, Selangor, Malaysia
Eizyan Izzati
Affiliation:
Department of Earth Sciences and Environment, Faculty of Science and Technology, Universiti Kebangsaan Malaysia, 43600 UKM Bangi, Selangor, Malaysia
*
Author for correspondence: Mohammad Rozaimi, E-mail: mdrozaimi@ukm.edu.my
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Abstract

Ostracods and foraminifera are excellent indicators of environmental change and can act as proxies for the presence of seagrass meadows. These proxies have been under-utilized in vulnerable coastal ecosystems in South-east Asia, and the fundamental habitat and environmental parameters required for such application in environmental monitoring have not yet been established. We investigated the habitat preferences of ostracods and foraminiferal species in seagrass and non-seagrass habitats within Sungai Pulai Estuary (Johor, Malaysia), a system currently undergoing major coastal changes. Samples consisted of surficial and downcore sediments collected from two seagrass meadows and a non-seagrass habitat. Multivariate analysis determined the variations in spatial and depth distribution of the meiofauna. Species dominance, abundance and distribution varied between sites, whereas diversity and community structure varied with sediment depth. We found fewer ostracod individuals (N = 1133) than foraminifera (N = 7242). Ostracods were more species-diverse (H′ = 3.34) in the non-vegetated area compared with seagrass areas (H′ = 2.74), whereas foraminifera species were most diverse (H′ = 3.60) in seagrass areas. Opportunistic species, such as Loxoconcha lilljeborgii, Asterorotalia pulchella, Murrayinella globosa, Ammonia tepida and Elphidium neosimplex dominated the meiofaunal assemblages. The presence of Nummulitidae and Paracyprididae in downcore samples provided information related to rare species and families. Salinity, organic matter and percentage of sand explained much of the meiofaunal distribution. Our findings provide new insight into the factors influencing the presence and distribution of ostracods and foraminifera in the estuary, comprising baseline information for understanding the vulnerability of such habitats to anthropogenic changes.

Keywords

Environmental changemeiofaunamultivariate analysisSungai Pulai Estuary
Type
Research Article
Information
Journal of the Marine Biological Association of the United Kingdom , Volume 100 , Issue 8 , December 2020 , pp. 1229 - 1246
Copyright
Copyright © The Author(s), 2020. Published by Cambridge University Press on behalf of Marine Biological Association of the United Kingdom

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References

Alonso Aller, E, Eklöf, JS, Gullström, M, Kloiber, U, Linderholm, HW and Nordlund, LM (2019) Temporal variability of a protected multispecific tropical seagrass meadow in response to environmental change. Environmental Monitoring and Assessment 191, 774.10.1007/s10661-019-7977-zCrossRefGoogle ScholarPubMed
Alvarez Zarikian, CA, Blackwelder, PL, Hood, T, Nelsen, TA and Featherstone, C (2000) Ostracods as indicators of natural and anthropogenically induced changes in coastal marine environments. In Coasts at the Millennium. Proceedings of the 17th International Conference of The Coastal Society. Portland: The Coastal Society, pp. 896905.Google Scholar
Alve, E (1995) Benthic foraminiferal responses to estuarine pollution: a review. Journal of Foraminiferal Research 25, 190203.10.2113/gsjfr.25.3.190CrossRefGoogle Scholar
Alve, E and Murray, JW (1994) Ecology and taphonomy of benthic foraminifera in a temperate mesotidal inlet. Journal of Foraminiferal Research 24, 1827.10.2113/gsjfr.24.1.18CrossRefGoogle Scholar
Alves, AS, Adão, H, Patrício, J, Neto, JM, Costa, MJ and Marques, JC (2009) Spatial distribution of subtidal meiobenthos along estuarine gradients in two southern European estuaries (Portugal). Journal of the Marine Biological Association of the United Kingdom 89, 15291540.10.1017/S0025315409000691CrossRefGoogle Scholar
Alves Martins, MV, Hohenegger, J, Frontalini, F, Dias, JMA, Geraldes, MC and Rocha, F (2019) Dissimilarity between living and dead benthic foraminiferal assemblages in the Aveiro Continental Shelf (Portugal). PLoS ONE 14, 147.10.1371/journal.pone.0209066CrossRefGoogle Scholar
Arias-Ortiz, A, Serrano, O, Masqué, P, Lavery, PS, Mueller, U, Kendrick, GA, Rozaimi, M, Esteban, A, Fourqurean, JW, Marbà, N, Mateo, MA, Murray, K, Rule, MJ and Duarte, CM (2018) A marine heatwave drives massive losses from the world's largest seagrass carbon stocks. Nature Climate Change 8, 338344.CrossRefGoogle Scholar
Attrill, MJ, Strong, JA and Rowden, AA (2000) Are macroinvertebrate communities influenced by seagrass structural complexity? Ecography 23, 114121.10.1111/j.1600-0587.2000.tb00266.xCrossRefGoogle Scholar
Benito, X, Trobajo, R, Ibáñez, C, Cearreta, A and Brunet, M (2015) Benthic foraminifera as indicators of habitat change in anthropogenically impacted coastal wetlands of the Ebro Delta (NE Iberian Peninsula). Marine Pollution Bulletin 101, 163173.10.1016/j.marpolbul.2015.11.003CrossRefGoogle Scholar
Benito, X, Trobajo, R, Cearreta, A and Ibáñez, C (2016) Benthic foraminifera as indicators of habitat in a Mediterranean delta: implications for ecological and palaeoenvironmental studies. Estuarine, Coastal and Shelf Science 180, 97113.10.1016/j.ecss.2016.06.001CrossRefGoogle Scholar
Bhaumik, AK, Kumar, S, Ray, S, Vishwakarma, GK, Gupta, AK, Kumar, P and Sain, K (2017) Stable carbon and oxygen isotope study on benthic foraminifera: implication for microhabitat preferences and interspecies correlation. Journal of Earth System Science 126, 115.10.1007/s12040-017-0840-0CrossRefGoogle Scholar
Boomer, I and Eisenhaur, G (2002) Ostracod faunas as palaeoenvironmental indicators in marginal marine environments. In Holmes, JA and Chivas, AR (eds), The Ostracoda: Applications in Quaternary Research. Washington, DC: American Geophysical Union, pp. 135149.10.1029/131GM07CrossRefGoogle Scholar
Brasier, MD (1975) An outline history of seagrass communities. Palaeontology 18, 681702.Google Scholar
Buosi, C, Frontalini, F, Da Pelo, S, Cherchi, A, Coccioni, R and Bucci, C (2010) Foraminiferal proxies for environmental monitoring in the polluted Lagoon of Santa Gilla (Cagliari, Italy). Present Environment and Sustainable Development 4, 91103.Google Scholar
Caporaletti, M (2017) Ostracods and stable isotopes: proxies for palaeoenvironmental reconstructions. Joannea Geologie und Paläontologie 11, 345359.Google Scholar
Che Cob, Z, Arshad, A, Wan Muda, WL and Abd. Ghaffar, M (2008) Gastropod and bivalve molluscs associated with the seagrass bed at Merambong Shoal, Johor Straits, Malaysia. In Mohamed, CAR, Sahrani, FK, Ali, MM, Cob, ZC and Ahmad, N (eds), Research and Information Series of Malaysian Coasts, Vol. 2 UKM Bangi, MY: Marine Ecosystem Research Centre (ECOMAR), pp. 8999.Google Scholar
Darroch, SAF (2012) Carbonate facies control on the fidelity of surface-subsurface agreement in benthic foraminiferal assemblages: implications for index-based paleoecology. Palaios 27, 137150.10.2110/palo.2011.p11-027rCrossRefGoogle Scholar
Darroch, SAF, Locatelli, ER, Mccoy, VE, Clark, EG, Anderson, RP, Tarhan, LG and Hull, PM (2016) Taphonomic disparity in foraminifera as a paleo-indicator for seagrass. Palaios 31, 242258.10.2110/palo.2015.046CrossRefGoogle Scholar
Debenay, J, Beneteau, E, Zhang, J, Geslin, E, Redois, F and Fernandez-gonzalez, M (1998) Ammonia beccarii and Ammonia tepida (Foraminifera): morphofunctional arguments for their distinction. Marine Micropaleontology 34, 235244.CrossRefGoogle Scholar
de Boer, WF (2007) Seagrass-sediment interactions, positive feedbacks and critical thresholds for occurrence: a review. Hydrobiologia 591, 524.10.1007/s10750-007-0780-9CrossRefGoogle Scholar
Duarte, CM, Terrados, J, Agawin, NSR, Fortes, MD, Bach, S and Kenworthy, WJ (1997) Response of a mixed Philippine seagrass meadow to experimental burial. Marine Ecology Progress Series 147, 285294.10.3354/meps147285CrossRefGoogle Scholar
Duarte, B, Martins, I, Rosa, R, Matos, AR, Roleda, MY, Reusch, TBH, Engelen, AH, Serrão, EA, Pearson, GA, Marques, JC, Caçador, I, Duarte, CM and Jueterbock, A (2018) Climate change impacts on seagrass meadows and macroalgal forests: an integrative perspective on acclimation and adaptation potential. Frontiers in Marine Science 5, 190.10.3389/fmars.2018.00190CrossRefGoogle Scholar
Duffy, JP, Pratt, L, Anderson, K, Land, PE and Shutler, JD (2018) Spatial assessment of intertidal seagrass meadows using optical imaging systems and a lightweight drone. Estuarine, Coastal and Shelf Science 200, 169180.10.1016/j.ecss.2017.11.001CrossRefGoogle Scholar
Dutertre, M, Hamon, D, Chevalier, C and Ehrhold, A (2013) The use of the relationships between environmental factors and benthic macrofaunal distribution in the establishment of a baseline for coastal management. ICES Journal of Marine Science 70, 294308.10.1093/icesjms/fss170CrossRefGoogle Scholar
Faiz, NN, Mohamed, KR, Omar, R and Ahmad, ZA (2017) Diversity and abundance of foraminifera at surface sediment along Sungai Kelantan Delta, Malaysia. Sains Malaysiana 46, 17091719.10.17576/jsm-2017-4610-06CrossRefGoogle Scholar
Faiz, NN, Mohamed, KR, Omar, R and Malek, MNA (2018) Benthic foraminiferal assemblages in the Pahang River Delta (Pahang, Malaysia). Thalassas 34, 6579.10.1007/s41208-017-0039-9CrossRefGoogle Scholar
Field, J, Clarke, K and Warwick, R (1982) A practical strategy for analysing multispecies distribution patterns. Marine Ecology Progress Series 8, 3752.10.3354/meps008037CrossRefGoogle Scholar
Forsey, GF (2016) Ostracods as proxies for past seagrass: a review. Palaeogeography, Palaeoclimatology, Palaeoecology 447, 2228.10.1016/j.palaeo.2016.01.028CrossRefGoogle Scholar
Frenzel, P and Boomer, I (2005) The use of ostracods from marginal marine, brackish waters as bioindicators of modern and Quaternary environmental change. Palaeogeography, Palaeoclimatology, Palaeoecology 225, 6892.CrossRefGoogle Scholar
Heiri, O, Lotter, A and Lemcke, G (2001) Loss on ignition as a method for estimating organic and carbonate content in sediments: reproducibility and comparability of results. Journal of Paleolimnology 25, 101110.10.1023/A:1008119611481CrossRefGoogle Scholar
Hidayah, N, Tahirin, SA, Fairoz, M and Rozaimi, M (2019) Carbon stock and δ 13C data of sediment samples collected from a tropical seagrass meadow in Malaysia. Plant Science Today 6, 132136.10.14719/pst.2019.6.2.489CrossRefGoogle Scholar
Hirst, JA and Attrill, MJ (2008) Small is beautiful: an inverted view of habitat fragmentation in seagrass beds. Estuarine, Coastal and Shelf Science 78, 811818.10.1016/j.ecss.2008.02.020CrossRefGoogle Scholar
Hiruta, S and Kakui, K (2016) Three new brackish-water thalassocypridine species (Crustacea: Ostracoda: Paracyprididae) from the Ryukyu Islands, southwestern Japan. Zootaxa 4169, 515539.10.11646/zootaxa.4169.3.6CrossRefGoogle ScholarPubMed
Hohenegger, J (2000) Remarks on West Pacific Nummulitidae (Foraminifera). Journal of Foraminiferal Research 30, 328.10.2113/0300003CrossRefGoogle Scholar
Horne, DJ and Boomer, I (2000) The role of Ostracoda in saltmarsh meiofaunal communities. In Sherwood, BR, Gardiner, BG and Harris, T (eds), British Saltmarshes. Cardigan: Forrest Text, for the Linnean Society of London.Google Scholar
Hossain, MS, Hashim, M, Bujang, JS, Zakaria, MH and Muslim, AM (2018) Assessment of the impact of coastal reclamation activities on seagrass meadows in Sungai Pulai estuary, Malaysia, using Landsat data (1994–2017). International Journal of Remote Sensing 40, 35713605.10.1080/01431161.2018.1547931CrossRefGoogle Scholar
Hussain, SM, Rajeshwara Rao, N and Mahalakshmi, P (2012) A comparative study on the distribution of foraminifera and ostracoda in the inner shelf off Pulicat and Palar, Tamil Nadu, Southeast Coast of India. Gondwana Geological Magazine 13, 153162.Google Scholar
Ishimura, T, Tsunogai, U, Hasegawa, S, Nakagawa, F, Oi, T, Kitazato, H, Suga, H and Toyofuku, T (2012) Variation in stable carbon and oxygen isotopes of individual benthic foraminifera: tracers for quantifying the magnitude of isotopic disequilibrium. Biogeosciences (Online) 9, 43534367.10.5194/bg-9-4353-2012CrossRefGoogle Scholar
Jorissen, F (1988) Benthic foraminifera from the Adriatic Sea: principles of phenotypic variation. Utrecht Micropaleontological Bulletins 37, 174.Google Scholar
Jorissen, FJ and Wittling, I (1999) Ecological evidence from live-dead comparisons of benthic foraminiferal faunas off Cape Blanc (Northwest Africa). Palaeogeography, Palaeoclimatology, Palaeoecology 149, 151170.10.1016/S0031-0182(98)00198-9CrossRefGoogle Scholar
Kamiya, T (1989) Functional morphology of ostracoda in seagrass beds: with special reference to the copulatory behaviour. Benthos Research 35/36, 7588.10.5179/benthos1981.1989.75CrossRefGoogle Scholar
Kandratavicius, N, Muniz, P, Venturini, N and Giménez, L (2015) Meiobenthic communities in permanently open estuaries and open/closed coastal lagoons of Uruguay (Atlantic coast of South America). Estuarine, Coastal and Shelf Science 163, 4453.10.1016/j.ecss.2015.05.030CrossRefGoogle Scholar
Kennedy, AD and Jacoby, CA (1999) Biological indicators of marine environmental health: meiofauna, a neglected benthic component? Environmental Monitoring and Assessment 54, 4768.CrossRefGoogle Scholar
Kettler, TA, Doran, JW and Gilbert, TL (2010) Simplified method for soil particle-size determination to accompany soil-quality analyses. Soil Science Society of America Journal 65, 849.CrossRefGoogle Scholar
Kidwell, SM (2007) Discordance between living and death assemblages as evidence for anthropogenic ecological change. Proceedings of the National Academy of Sciences USA 104, 1770117706.CrossRefGoogle ScholarPubMed
Kneer, D, Asmus, H and Jompa, J (2013) Do burrowing callianassid shrimp control the lower boundary of tropical seagrass beds? Journal of Experimental Marine Biology and Ecology 446, 262272.CrossRefGoogle Scholar
Koskeridou, E, Thivaiou, D, Giamali, C, Agiadi, K and Mantzouka, D (2019) Seagrass-associated molluscan and fish communities from the Early Pleistocene of the Island of Rhodes (Greece). IOP Conference Series: Earth and Environmental Science 221, art. 012050.CrossRefGoogle Scholar
Koukousioura, O, Dimiza, M, Triantaphyllou, M and Hallock, P (2011) Living benthic foraminifera as an environmental proxy in coastal ecosystems: a case study from the Aegean Sea (Greece, NE Mediterranean). Journal of Marine Systems 88, 489501.CrossRefGoogle Scholar
Kowalewski, M, Carroll, M, Casazza, L, Gupta, N, Hannisdal, B, Hendy, A, Krause, R, LaBarbera, M, Lazo, D, Messina, C, Puchalski, S and Rothfus, T (2003) Quantitative fidelity of brachiopod-mollusk assemblages from modern subtidal environments of San Juan Islands, USA. Journal of Taphonomy 1, 4365.Google Scholar
Legendre, P and Legendre, L (2012) Matrix algebra: a summary. In Legendre, P and Legendre, L (eds), Numerical Ecology: Developments in Environmental Modelling. Amsterdam: Elsevier, pp. 59107.CrossRefGoogle Scholar
Loeblich, AR and Tappan, H (1988) Generic taxa erroneously regarded as foraminifers. In Loeblich, AR and Tappan, H (eds), Foraminiferal Genera and their Classification. Boston, MA: Springer, pp. 726730.CrossRefGoogle Scholar
Maddocks, RF (1988) New species and review of the genus Paracypris (Ostracoda). Crustaceana 55, 5370.CrossRefGoogle Scholar
Magno, MC, Bergamin, L, Finoia, MG, Pierfranceschi, G, Venti, F and Romano, E (2012) Correlation between textural characteristics of marine sediments and benthic foraminifera in highly anthropogenically-altered coastal areas. Marine Geology 315–318, 143161.CrossRefGoogle Scholar
Malek, MNA, Omar, R and Faiz, NN (2014) The distribution of benthic foraminifera on selected marine sediments in Pahang River estuary, Pahang, Malaysia: identification using SEM images. Malaysian Journal of Microscopy 10, 4146.Google Scholar
Mateu-Vicens, G, Khokhlova, A and Sebastián-Pastor, T (2014) Epiphytic foraminiferal indices as bioindicators in Mediterranean seagrass meadows. Journal of Foraminiferal Research 44, 325339.CrossRefGoogle Scholar
Meldahl, KH (1987) Sedimentologic and taphonomic implications of biogenic stratification. Palaios 2, 350.CrossRefGoogle Scholar
Murray, JW (2000) The niche of benthic foraminifera, critical thresholds and proxies. Marine Micropaleontology 41, 112.CrossRefGoogle Scholar
Murray, JW (2014) Ecology and Paleoecology of Benthic Foraminifera. New York, NY: Routledge.CrossRefGoogle Scholar
Nash, GJ, Binnie, MN and Cann, JH (2010) Distribution of foraminifera and ostracods in the Onkaparinga estuary, South Australia. Australian Journal of Earth Sciences 57, 901910.CrossRefGoogle Scholar
Ozawa, H, Ishii, T and Nakao, Y (2014) Pore distributional patterns of Loxoconcha ikeyai (Crustacea: Ostracoda: Loxoconchidae) from the Lower Pleistocene Kakio Formation in Kanagawa Prefecture, central Japan. Bulletin of the National Museum of Nature and Science Series C (Geology & Paleontology) 40, 19.Google Scholar
Pati, P and Patra, PK (2012) Benthic foraminiferal responses to coastal pollution; a review. International Journal of Geology, Earth and Environmental Sciences 2, 4256.Google Scholar
Pielou, EC (1975) Ecological Diversity. New York, NY: Wiley.Google Scholar
Pieri, V, Martens, K, Stoch, F and Rossetti, G (2009) Distribution and ecology of non-marine ostracods (Crustacea, Ostracoda) from Friuli Venezia Giulia (NE Italy). Journal of Limnology 68, 115.CrossRefGoogle Scholar
Poong, S-W, Lim, P-E, Phang, S-M, Sunarpi, H, West, JA and Kawai, H (2013) A molecular-assisted floristic survey of crustose brown algae (Phaeophyceae) from Malaysia and Lombok Island, Indonesia based on rbcL and partial cox1 genes. Journal of Applied Phycology 26, 12311242.CrossRefGoogle Scholar
Potouroglou, M, Bull, JC, Krauss, KW, Kennedy, HA, Fusi, M, Daffonchio, D, Mangora, MM, Githaiga, MN, Diele, K and Huxham, M (2017) Measuring the role of seagrasses in regulating sediment surface elevation. Scientific Reports 7, 111.CrossRefGoogle ScholarPubMed
Pusceddu, A, Gambi, C, Corinaldesi, C, Scopa, M and Danovaro, R (2014) Relationships between meiofaunal biodiversity and prokaryotic heterotrophic production in different tropical habitats and oceanic regions. PLoS ONE 9, e91056.CrossRefGoogle ScholarPubMed
Ravelo, AC and Hillaire-Marcel, C (2007) The use of oxygen and carbon isotopes of foraminifera in paleoceanography. Developments in Marine Geology 1, 735764.Google Scholar
Reich, S (2014) Gastropod associations as a proxy for seagrass vegetation in a tropical, carbonate setting (San Salvador, Bahamas). Palaios 29, 467482.CrossRefGoogle Scholar
Reich, S, Di Martino, E, Todd, JA, Wesselingh, FP and Renema, W (2015) Indirect paleo-seagrass indicators (IPSIs): a review. Earth-Science Reviews 143, 161186.CrossRefGoogle Scholar
Rodriguez-Lazaro, J and Ruiz-Muñoz, F (2012) A general introduction to ostracods. In Horne, DJ, Holmes, JA, Rodriguez-Lazaro, J and Viehberg, FA (eds), Ostracoda as Proxies for Quaternary Climate Change. Amsterdam: Elsevier, pp. 114.Google Scholar
Rohling, EJ and Cooke, S (1999) Stable oxygen and carbon isotopes in foraminiferal carbonate shells. In Rohling, EJ and Cooke, S (eds), Modern Foraminifera. Dordrecht: Springer, pp. 239258.CrossRefGoogle Scholar
Rosli, N, Leduc, D, Rowden, AA, Clark, MR, Probert, PK, Berkenbusch, K and Neira, C (2016) Differences in meiofauna communities with sediment depth are greater than habitat effects on the New Zealand continental margin: implications for vulnerability to anthropogenic disturbance. PeerJ 4, 139.CrossRefGoogle ScholarPubMed
Rozaimi, M, Fairoz, M, Hakimi, TM, Hamdan, NH, Omar, R, Ali, MM and Tahirin, SA (2017) Carbon stores from a tropical seagrass meadow in the midst of anthropogenic disturbance. Marine Pollution Bulletin 119, 253260.Google ScholarPubMed
Ruiz, F, González-Regalado, ML, Borrego, J, Abad, M and Pendón, JG (2004) Ostracoda and foraminifera as short-term tracers of environmental changes in very polluted areas: the Odiel Estuary (SW Spain). Environmental Pollution 129, 4961.CrossRefGoogle Scholar
Sabri, S, Said, M, Azman, S and Goto, M (2013) Seagrass at south western coast of Johor. Journal of Sustainability Science and Management 8, 7379.Google Scholar
Sen Gupta, BK (1999) Foraminifera in marginal marine environments. In Sen Gupta, BK (ed.), Modern Foraminifera. Boston, MA: Kluwer, pp. 141159.Google Scholar
Sen Gupta, BK (2002) Systematics of modern foraminifera. In Sen Gupta, BK (ed.), Modern Foraminifera. Boston, MA: Kluwer, pp. 736.Google Scholar
Shaari, H, Shazili, NAM, Abdullah, LI, Abdullah, NA, Husain, ML and Tahir, NM (2017) Geochemistry and clay minerals of surface sediments of Southwestern Johor, Malaysia. Malaysian Journal of Analytical Science 21, 312322.Google Scholar
Shi, GW, Ghaffar, MA, Ali, MM and Cob, ZC (2014) The Polychaeta (Annelida) communities of the Merambong and Tanjung Adang Shoals, Malaysia, and its relationship with the environmental variables. Malayan Nature Journal 66, 168183.Google Scholar
Simstich, J, Stanovoy, V, Bauch, D, Erlenkeuser, H and Spielhagen, RF (2004) Holocene variability of bottom water hydrography on the Kara Sea shelf (Siberia) depicted in multiple single-valve analyses of stable isotopes in ostracods. Marine Geology 206, 147164.CrossRefGoogle Scholar
Soil Science Division Staff (2017) Examination and description of soils. In Ditzler, C, Scheffe, K and Monger, HC (eds), Soil Survey Manual. USDA Handbook 18. Washington, DC: Government Printing Office, pp. 83233.Google Scholar
Somerfield, PJ, Yodnarasri, S and Aryuthaka, C (2002) Relationships between seagrass biodiversity and infaunal communities: implications for studies of biodiversity effects. Marine Ecology Progress Series 237, 97109.CrossRefGoogle Scholar
Sreenivasulu, G, Praseetha, BS, Daud, NR, Varghese, TI, Prakash, TN and Jayaraju, N (2019) Benthic foraminifera as potential ecological proxies for environmental monitoring in coastal regions: a study on the Beypore Estuary, Southwest Coast of India. Marine Pollution Bulletin 138, 341351.CrossRefGoogle Scholar
Suokhrie, T, Saraswat, R and Nigam, R (2017) Foraminifera as bio-indicators of pollution: a review of research over the last decade. In Kathal, PK, Nigam, R and Talib, A (eds), Micropaleontology and its Applications. Jodhpur: Scientific Publishers, pp. 265284.Google Scholar
Szarek, R, Kuhnt, W, Kawamura, H and Kitazato, H (2006) Distribution of recent benthic foraminifera on the Sunda Shelf (South China Sea). Marine Micropaleontology 61, 171195.Google Scholar
Tan, PL, Lim, PE, Lin, SM and Phang, SM (2018 a) Halymenia johorensis sp. nov. (Halymeniaceae, Rhodophyta), a new foliose red algal species from Malaysia. Journal of Applied Phycology 30, 187195.CrossRefGoogle Scholar
Tan, YM, Saunders, JE and Yaakub, SM (2018 b) A proposed decision support tool for prioritising conservation planning of Southeast Asian seagrass meadows: combined approaches based on ecosystem services and vulnerability analyses. Botanica Marina 61, 305320.CrossRefGoogle Scholar
Tjia, HD and Sharifah Mastura, SA (2013) Sea Level Changes in Peninsular Malaysia: A Geological Record. Bangi, Selangor: Penerbit Universiti Kebangsaan Malaysia.Google Scholar
Tomašových, A and Kidwell, SM (2009) Fidelity of variation in species composition and diversity partitioning by death assemblages: time-averaging transfers diversity from beta to alpha levels. Paleobiology 35, 94118.CrossRefGoogle Scholar
Toruan, LNL, Risamasu, FJL and Paulus, CA (2017) Shannon–Wiener diversity index on benthic foraminifers is less effective to approximating coral reef ecosystem quality in Kupang Bay. In National Seminar on Marine and Fisheries Seminar IV. Kupang: Nusa Cendana University, pp. 167173.Google Scholar
Trabelsi, R, Elloumi, J, Hamza, A, Ayadi, N, Zghal, I and Ayadi, H (2018) Variability of foraminifera associations in seagrass ecosystems in shallow water during winter (Kerkennah – Southern Tunisian coasts). Journal of the Marine Biological Association of the United Kingdom 98, 19451954.CrossRefGoogle Scholar
Unsworth, RKF, van Keulen, M and Coles, RG (2014) Seagrass meadows in a globally changing environment. Marine Pollution Bulletin 83, 383386.CrossRefGoogle Scholar
Uthicke, S and Nobes, K (2008) Benthic foraminifera as ecological indicators for water quality on the Great Barrier Reef. Estuarine, Coastal and Shelf Science 78, 763773.CrossRefGoogle Scholar
Valls, L, Zamora, L, Rueda, J and Mesquita-Joanes, F (2016) Living and dead ostracod assemblages in a coastal Mediterranean wetland. Wetlands 36, 19.CrossRefGoogle Scholar
Vonk, JA, Kneer, D, Stapel, J and Asmus, H (2008) Shrimp burrow in tropical seagrass meadows: an important sink for litter. Estuarine, Coastal and Shelf Science 79, 7985.CrossRefGoogle Scholar
Wilson, B, Hayek, L-AC and Bowles, SM (2018) Intertidal foraminifera in the Spartina patens floral zone of the LaHave Estuary, Canada: a baseline for assessing organic pollution remediation. Estuarine, Coastal and Shelf Science 213, 230235.CrossRefGoogle Scholar
Woeger, J, Briguglio, A, Kinoshita, S and Hohenegger, J (2016) First results of a long-term cultivation experiment of different species of Nummulitidae (Foraminifera) from the island of Sesoko (Okinawa, Japan). Proceedings of the 13th International Coral Reefs Symposium. International Society for Reef Studies, Honalulu, pp. 195206.Google Scholar
Wukovits, J, Bukenberger, P, Enge, AJ, Gerg, M, Wanek, W, Watzka, M and Heinz, P (2018) Food supply and size class depending variations in phytodetritus intake in the benthic foraminifer Ammonia tepida. Biology Open 7, bio030056.CrossRefGoogle ScholarPubMed
Zaleha, K, Diyana, F, Suhaili, A and Amirudin, A (2009) Benthic community of the Sungai Pulai seagrass bed, Malaysia. Malaysian Journal of Science 28, 143159.Google Scholar
Zaleha, K, Nasiratul_Shahida, MN, Siang, HY and Kamaruzzaman, BY (2016) Trend of meiobenthos density and composition in Karah Island, South China Sea. Sains Malaysiana 45, 10191024.Google Scholar
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