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Distribution and abundance of turritelline gastropods (Cerithioidea: Turritellidae) in Hong Kong and the English Channel: implications for a characteristic fossil assemblage

Published online by Cambridge University Press:  28 December 2020

Caren P. Shin*
Affiliation:
Paleontological Research Institution, Ithaca, NY, USA Department of Earth and Atmospheric Sciences, Cornell University, Ithaca, NY, USA
Warren D. Allmon
Affiliation:
Paleontological Research Institution, Ithaca, NY, USA Department of Earth and Atmospheric Sciences, Cornell University, Ithaca, NY, USA
Brendan M. Anderson
Affiliation:
Paleontological Research Institution, Ithaca, NY, USA Department of Earth and Atmospheric Sciences, Cornell University, Ithaca, NY, USA
Bridget T. Kelly
Affiliation:
Department of Earth Sciences, University of California, Riverside, CA, USA
Keith Hiscock
Affiliation:
The Marine Biological Association of the United Kingdom, The Laboratory, Citadel Hill, Plymouth, UK
Paul K.S. Shin
Affiliation:
Department of Biology and Chemistry (now Department of Chemistry), City University of Hong Kong, Hong Kong
*
Author for correspondence: Caren P. Shin, E-mail: cps257@cornell.edu

Abstract

Abundant species are typically also viewed as ecologically dominant, and are frequently used to characterize the communities in which they live. Such characteristic assemblages may also be used as indicators of environmental conditions, such as relative stability. Fossil and modern turritelline gastropods are often the most abundant species in the marine assemblages and communities in which they occur, forming ‘turritelline-dominated assemblages’ (TDAs). We use data on modern Turritella bacillum from waters around Hong Kong as a case study to analyse fluctuations in abundance over 25 years. While turritellines were not always dominant in the area surveyed (~1650 km2), populations were notably persistent, and rebound after decline of abundances occurred within ~5 years at some sites. δ18O sclerochronology suggests that individuals were ~1–2 years old. It is also notable that T. bacillum was found to be abundant at salinities as low as 10–15 psu, despite the general characterization of turritellines as fully marine. Comparison with data on modern T. communis in the western English Channel corroborates this pattern, as localized sites of high abundance also appear transient. These results have implications for the interpretation of TDAs in the fossil record: they may signify the cumulative result of short-lived, spatially restricted populations, possibly resulting from essentially stochastic larval settlement. This suggests that the palaeoenvironmental setting of fossil TDAs does not always control their occurrence on short temporal scales.

Type
Research Article
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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Footnotes

*

Present address: Geosciences Department, Baylor University, Waco, TX, USA.

References

Allmon, WD (1988) Ecology of living turritelline gastropods (Prosobranchia, Turritellidae): current knowledge and paleontological implications. Palaios 3, 259284.CrossRefGoogle Scholar
Allmon, WD (1992) Role of nutrients and temperature in extinction of turritelline gastropods in the northwestern Atlantic and northeastern Pacific. Palaeogeography, Palaeoclimatology, Palaeoecology 92, 4154.Google Scholar
Allmon, WD (2007) Cretaceous marine nutrients, greenhouse carbonates, and the abundance of turritelline gastropods. Journal of Geology 115, 509524.CrossRefGoogle Scholar
Allmon, WD (2011) The natural history of turritelline gastropods (Cerithiodea: Turritellidae): a status report. Malacologia 54, 159202.CrossRefGoogle Scholar
Allmon, WD, Jones, DS and Vaughan, N (1992) Observations on the biology of Turritella gonostoma Valenciennes (Prosobranchia, Turritellidae) from the Gulf of California. The Veliger 35, 5263.Google Scholar
Allmon, WD, Jones, DS, Aiello, RL, Gowlett-Holmes, K and Probert, PK (1994) Observations on the biology of Maoricolpus roseus (Quoy and Gaimard) (Prosobranchia: Turritellidae) in New Zealand and Australia. The Veliger 37, 267279.Google Scholar
Anderson, BM and Allmon, WD (2020) High calcification rates and inferred metabolic trade-offs in the largest turritellid gastropod, Turritella abrupta (Neogene). Palaeogeography, Palaeoclimatology, Palaeoecology 544, 109623.CrossRefGoogle Scholar
Anderson, BM, Hendy, A, Johnson, EH and Allmon, WD (2017) Paleoecology and paleoenvironmental implications of turritelline gastropod-dominated assemblages from the Gatun Formation (Upper Miocene) of Panama. Palaeogeography, Palaeoclimatology, Palaeoecology 470, 132146.CrossRefGoogle Scholar
Arnold, TE, Brenner, M, Curtis, JH, Dutton, A, Baker, SM, Escobar, JH and Ortega, CA (2014) Application of stable isotopes (δ18O) to determine growth patterns of the invasive gastropod Pomacea maculata in Florida lakes. Florida Science 77, 126143.Google Scholar
Blay, J Jr and Dongdem, F (1996) Preliminary observations on the benthic macrofauna of a polluted coastal lagoon in Ghana (West Africa). Tropical Ecology 37, 127133.Google Scholar
Buchanan, JB and Moore, JJ (1986) A broad review of variability and persistence in the Northumberland benthic fauna – 1971–85. Journal of the Marine Biological Association of United Kingdom 66, 641657.CrossRefGoogle Scholar
Burnham, KP and Anderson, DR (2002) Model Selection and Multimodel Inference: A Practical Information-Theoretical Approach, 2nd Edn. New York, NY: Springer.Google Scholar
Capasso, E, Jenkins, SR, Frost, M and Hinz, H (2010) Investigation of benthic community change over a century-wide scale in the western English channel. Journal of the Marine Biological Association of United Kingdom 90, 11611172.CrossRefGoogle Scholar
Chau, KW (2004) A three-dimensional eutrophication modeling in Tolo Harbour. Applied Mathematical Modelling 28, 849861.CrossRefGoogle Scholar
CPSL (CityU Professional Services Ltd) (2006) Final Report on Provision of Services for Species Identification and Data Analysis of Epibenthic Organisms from Hong Kong Marine Waters (Tender Ref. WP 06-091 for Environmental Protection Department, HKSAR Government).Google Scholar
CPSL (CityU Professional Services Ltd) (2010) Final Report on Provision of Services for Species Identification and Data Analysis of Epibenthic Organisms from Hong Kong Marine Waters (Tender Ref. WP 09-104 for Environmental Protection Department, HKSAR Government).Google Scholar
CPSL (CityU Professional Services Ltd) (2013) Final Report on Provision of Services for Species Identification and Data Analysis of Epibenthic Organisms from Hong Kong Marine Waters (Tender Ref. WP 12-01185 for Environmental Protection Department, HKSAR Government).Google Scholar
Dimitriadis, C, Koutsoubas, D, Garyfalou, Z and Tselepides, A (2014) Benthic molluscan macrofauna structure in heavily trawled sediments (Thermaikos Gulf, North Aegean Sea): spatiotemporal patterns. Journal of Biological Research – Thessaloniki 21, 10.CrossRefGoogle ScholarPubMed
EPD (Environmental Protection Department, Hong Kong S.A.R.) (2019) Marine Water Quality Data. https://cd.epic.epd.gov.hk/EPICRIVER/marine/?lang=en (Accessed 6.1.2019).Google Scholar
Fishelson, L (1971) Ecology and distribution of the benthic fauna in the shallow waters of the Red Sea. Marine Biology 10, 113133.CrossRefGoogle Scholar
Fleddum, A, Cheung, SG, Hodgson, P and Shin, PKS (2011) Impact of hypoxia on the structure and function of benthic epifauna in Tolo Harbour, Hong Kong. Marine Pollution Bulletin 63, 221229.CrossRefGoogle ScholarPubMed
Ford, E (1923) Animal communities of the level sea-bottom in the waters adjacent to Plymouth. Journal of the Marine Biological Association of the United Kingdom 13, 164224.CrossRefGoogle Scholar
Gibbs, PE, Nott, JA, Nicolaidou, A and Bebianno, MJ (1998) The composition of phosphate granules in the digestive glands of marine prosobranch gastropods: variation in relation to taxonomy. Journal of Molluscan Studies 64, 423433.CrossRefGoogle Scholar
Gogina, M, Nygård, H, Blomqvist, M, Daunys, D, Josefson, AB, Kotta, J, Maximov, A, Warzocha, J, Yermakov, V, Gräwe, U and Zettler, ML (2016) The Baltic Sea scale inventory of benthic faunal communities. ICES Journal of Marine Science 73, 11961213.CrossRefGoogle Scholar
Göransson, P (2002) Petersen's benthic macrofauna stations revisited in the Öresund area (southern Sweden) and species composition in the 1990s – signs of decreased biological variation. Sarsia: North Atlantic Marine Science 87, 263280.CrossRefGoogle Scholar
Graham, A (1938) On a ciliary process of food-collecting in the gastropod Turritella communis Risso. Proceedings of the Zoological Society of London 108, 543563.Google Scholar
Grossman, EL and Ku, TL (1986) Oxygen and carbon isotope fractionation in biogenic aragonite: temperature effects. Chemical Geology (Isotope Geosciences Section) 59, 5974.CrossRefGoogle Scholar
Hammer, Ø, Harper, DAT and Ryan, PD (2001) PAST: Paleontological statistics software package for education and data analysis. Palaeontologia Electronica 4. https://palaeo-electronica.org/2001_1/past/past.pdf.Google Scholar
Harzhauser, M and Landau, B (2019) Turritellidae (Gastropoda) of the Miocene Paratethys Sea with considerations about turritellid genera. Zootaxa 4681, 1136.CrossRefGoogle ScholarPubMed
Herbert, D (2013) Turritella declivis Adams & Reeve, in Reeve, 1849 (Mollusca: Gastropoda) – a South African not an Australian species, and a characteristic component of the Agulhas Bank benthos. African Zoology 48, 412417.Google Scholar
Hiscock, K and Oakley, J (2005) English Channel towed sledge seabed images. Phase 2: Analysis of selected tow images. Report to the Joint Nature Conservation Committee from the Marine Biological Association. Plymouth: Marine Biological Association. JNCC Contract F90-01-784.Google Scholar
Holme, NA (1950) The bottom fauna of Great West Bay. Journal of the Marine Biological Association of the United Kingdom 29, 163183.CrossRefGoogle Scholar
Holme, NA (1961) The bottom fauna of the English Channel. Journal of the Marine Biological Association of the United Kingdom 41, 397461.CrossRefGoogle Scholar
Horikoshi, M and Thompson, G (1980) Distribution of subtidal molluscs collected by trawling in Tolo Harbour and Tolo Channel, Hong Kong, with special reference to habitat segregation in two venerid bivalves. In Morton, B (ed.), Proceedings, First International Workshop on the Malacofauna of Hong Kong and Southern China, 23 March – 8 April 1977, Hong Kong. Hong Kong: Hong Kong University Press, pp. 149162.Google Scholar
Jones, DS and Allmon, WD (1995) Records of upwelling, seasonality and growth in stable-isotope profiles of Pliocene mollusk shells from Florida. Lethaia 28, 6174.CrossRefGoogle Scholar
Kennedy, JJ (1995) The courtship, pseudo-copulation behaviour and spermatophore of Turritella communis Risso 1826 (Prosobranchia: Turritellidae). Journal of Molluscan Studies 61, 421434.CrossRefGoogle Scholar
Khan, A, Manokaran, S, Lyla, S and Nazeer, Z (2010) Biodiversity of epibenthic community in the inshore waters of southeast coast of India. Biologia 65, 704713.CrossRefGoogle Scholar
King, G (1989) Unifying Political Methodology: The Likelihood Theory of Statistical Inference. New York, NY: Cambridge University Press.Google Scholar
Kwan, BKY, Cheung, SG, Chan, AKY and Shin, PKS (2018) Trophic and growth baseline of dominant subtidal gastropods in contrasting subtropical marine environments. Marine Pollution Bulletin 127, 396405.CrossRefGoogle ScholarPubMed
Langston, WJ, Burt, GR and Pope, ND (1999) Bioavailabillity of metals in sediments of the Dogger Bank (Central North Sea): a mesocosm study. Estuarine, Coastal and Shelf Science 48, 519540.CrossRefGoogle Scholar
Leung, KF and Morton, B (2000) The 1998 resurvey of the subtidal molluscan community of the southeastern waters of Hong Kong, six years after dredging began and three since it ended. In Morton, B (ed.), The Marine Flora and Fauna of Hong Kong and Southern China V. Proceedings of the Tenth International Marine Biological Workshop: The Marine Flora and Fauna of Hong Kong and Southern China, Hong Kong, 1998. Hong Kong: Hong Kong University Press, pp. 553617.Google Scholar
Leung, KF and Morton, B (2003) Effects of long-term anthropogenic perturbations on three subtidal epibenthic molluscan communities in Hong Kong. In Morton, B (ed.), Perspectives on Marine Environmental Changes in Hong Kong and Southern China, 1977–2001, Proceedings of an International Workshop Reunion Conference, Hong Kong, 21–26 October. Hong Kong: Hong Kong University Press, pp. 654717.Google Scholar
Li, Y, Du, F, Gu, Y, Ning, J and Wang, L (2016) Relationship between macrobenthic fauna community and environmental factors in Southeast Leizhou Peninsula of the South China Sea. South China Fisheries Science 12, 3341. (in Chinese with English abstract)Google Scholar
Lie, AA, Wong, K, Lam, JY, Liu, JH and Yung, YK (2011) Changes in the nutrient ratios and phytoplankton community after declines in nutrient concentrations in an eutrophic semi-enclosed bay in Hong Kong. Marine Environmental Research 71, 178188.CrossRefGoogle Scholar
Lu, Z-H, Zhu, W-B, Xu, K-D, Zhou, Y-D, Dai, Q and Lu, K-E (2018) Community structure of snails and its relationship with environmental factors along Zhejiang coast in spring. Acta Hydrobiologica Sinica 42, 606615. (in Chinese with English abstract)Google Scholar
Lui, KKY, Ng, JSS and Leung, KMY (2007) Spatio-temporal variations in the diversity and abundance of commercially important Decapoda and Stomatopoda in subtropical Hong Kong waters. Estuarine, Coastal and Shelf Science 72, 635647.CrossRefGoogle Scholar
Marwick, J (1957) Generic revision of the Turritellidae. Proceedings of the Malacological Society of London 32, 144166.Google Scholar
McKnight, DG (1969) Infaunal benthic communities of the New Zealand continental shelf. New Zealand Journal of Marine and Freshwater Research 3, 409444.CrossRefGoogle Scholar
Morton, B (1982) An introduction to Hong Kong's marine environment with special reference to the north-east New territories. In Morton, B and Tseng, CK (eds), Proceedings of the First International Marine Biological Workshop: The Marine Flora and Fauna of Hong Kong and Southern China, Hong Kong, 1980. Hong Kong: Hong Kong University Press, pp. 2553.Google Scholar
Morton, B (1989) Pollution of the coastal waters of Hong Kong. Marine Pollution Bulletin 20, 310318.CrossRefGoogle Scholar
Morton, B (1996) The subsidiary impacts of dredging (and trawling) on a subtidal benthic molluscan community in the southern waters of Hong Kong. Marine Pollution Bulletin 32, 701710.CrossRefGoogle Scholar
Morton, B and Wu, RSS (1975) The hydrology of the coastal waters of Hong Kong. Environmental Research 10, 319347.CrossRefGoogle ScholarPubMed
Morton, B and Morton, JE (1983) The Sea Shore Ecology of Hong Kong. Hong Kong: Hong Kong University Press, 350 pp.Google Scholar
Morton, B and Blackmore, G (2001) South China Sea. Marine Pollution Bulletin 42, 12361263.CrossRefGoogle ScholarPubMed
Naughton, F, Bourillet, JF, Goñi, MFS, Turon, JL and Jouanneau, JM (2007) Long-term and millennial-scale climate variability in northwestern France during the last 8850 years. The Holocene 17, 939953.CrossRefGoogle Scholar
Nephin, J, Juniper, SK and Archambault, P (2014) Diversity, abundance and community structure of benthic macro- and megafauna on the Beaufort shelf and slope. PLoS ONE 9, e101556.CrossRefGoogle ScholarPubMed
Ng, TPT, Cheng, MCF, Ho, KKY, Lui, GCS, Leung, KMY and Williams, GA (2017) Hong Kong's rich marine biodiversity: the unseen wealth of South China's megalopolis. Biodiversity and Conservation 26, 2336.CrossRefGoogle Scholar
Paul, VI, Radhakrishnan, MV and Hemalatha, S (1999) Turritella attenuata (Kasinathan): as biological indicator of marine pollution – a trace metal analytical study. Indian Journal of Experimental Biology 37, 11511153.Google ScholarPubMed
Petersen, CGJ (1913) Valuation of the Sea II. The animal communities of the sea-bottom and their importance for marine zoogeography. Report from the Danish Biological Station 21, 168.Google Scholar
Petersen, CGJ (1915) On the animal communities of the sea bottom in the Skagerak, the Christiana Fjord and the Danish waters. Report from the Danish Biological Station 23, 128.Google Scholar
Petuch, EJ (1976) An unusual molluscan assemblage from Venezuela. The Veliger 18, 322325.Google Scholar
R Core Team (2019) R: A Language and Environment for Statistical Computing. Vienna: R Foundation for Statistical Computing. http://www.R-project.org/Google Scholar
Ryan, TH, Rodhouse, PG, Roden, CM and Hensey, MP (1986) Zooplankton fauna of Killary Harbour: the seasonal cycle of abundance. Journal of the Marine Biological Association of the United Kingdom 66, 731748.CrossRefGoogle Scholar
Sang, S, Friend, DS, Allmon, WD and Anderson, BM (2019) Protoconch enlargement in Western Atlantic turritelline gastropod species following the closure of the Central American Seaway. Ecology and Evolution 9, 53095323.CrossRefGoogle ScholarPubMed
Shin, PKS and Thompson, GB (1982) Spatial distribution of the infaunal benthos of Hong Kong. Marine Ecology Progress Series 10, 3747.CrossRefGoogle Scholar
Shin, PKS and Ellingsen, KE (2004) Spatial patterns of soft-sediment benthic diversity in subtropical Hong Kong waters. Marine Ecology Progress Series 276, 2535.CrossRefGoogle Scholar
Shu, L, Chen, P, Li, X, Yu, J and Feng, X (2015) Species composition and seasonal variation of macrobenthic fauna in Zhelin Bay and adjacent waters. Journal of Applied Oceanography 34, 124132. (in Chinese with English abstract)Google Scholar
Steven, GA (1930) Bottom fauna and the food of fishes. Journal of the Marine Biological Association of the United Kingdom 16, 677706.CrossRefGoogle Scholar
Tamaki, A and Takeuchi, S (2016) Persistence, extinction, and recolonization of an epibenthic gastropod population on an intertidal sandflat: 35-y contingent history of a key species of the benthic community in metapopulation and metacommunity contexts. Journal of Shellfish Research 35, 921967.CrossRefGoogle Scholar
Taylor, JD (1992) Long-term changes in the gastropod fauna of Tolo Channel and Mirs Bay, Hong Kong: the 1989 survey. In Morton, B (ed.), The Marine flora and Fauna of Hong Kong and Southern China III. Proceedings of the Fourth International Marine Biological Workshop: The Marine Flora and Fauna of Hong Kong and Southern China, Hong Kong, 11–29 April 1989. Hong Kong: Hong Kong University Press, pp. 557573.Google Scholar
Taylor, JD (1994) Sublittoral benthic gastropods from the southern waters of Hong Kong. In Morton, B (ed.), The Malacofauna of Hong Kong and Southern China, III. Proceedings of the Third International Workshop on the Malacofauna of Hong Kong and Southern China, Hong Kong, 1992. Hong Kong: Hong Kong University Press, pp. 479495.Google Scholar
Taylor, JD and Shin, PKS (1990) Trawl surveys of sublittoral gastropods in Tolo Channel and Mirs Bay; a record of change from 1976–1986. In Morton, B (ed.), Proceedings of the Second International Marine Biological Workshop: The Marine Flora and Fauna of Hong Kong and Southern China, Hong Kong, 1986. Hong Kong: Hong Kong University Press, pp. 857881.Google Scholar
Teusch, KP, Jones, DS and Allmon, WD (2002) Morphological variation in a turritellid gastropod from the Pleistocene to Recent of Chile: associations with upwelling intensity. Palaios 17, 366377.2.0.CO;2>CrossRefGoogle Scholar
Thompson, GB, Wu, RSS and Phillips, DJH (1982) A trawl survey of the benthos of Tolo Harbour and Tolo Channel in 1978. In Morton, BS and Tseng, CK (eds), Proceedings of the First International Marine Biological Workshop: The Marine Flora and Fauna of Hong Kong and Southern China, Hong Kong, 1980. Hong Kong: Hong Kong University Press, pp. 745760.Google Scholar
Thorson, G (1957) Bottom communities. Memoirs – Geological Society of America 67, 461534.CrossRefGoogle Scholar
Tittensor, DP, Mora, C, Jetz, W, Lotze, HK, Ricard, D, Berghe, EV and Worm, B (2010) Global patterns and predictors of marine biodiversity across taxa. Nature 466, 10981101.CrossRefGoogle ScholarPubMed
Trott, LB and Fung, AYC (1973) Marine pollution in Hong Kong. Marine Pollution Bulletin 4, 1315.CrossRefGoogle Scholar
Waite, R and Allmon, WD (2013) Observations on the biology and sclerochronology of Turritella leucostoma (Valenciennes, 1832; Cerithioidea: Turritellidae) from the Gulf of California. American Malacological Bulletin 31, 297310.CrossRefGoogle Scholar
Watts, JCD (1973) Further observations on the hydrology of the Hong Kong territorial waters. Hong Kong Fisheries Bulletin 3, 935.Google Scholar
Wu, RSS (1982) Periodic defaunation and recovery in a subtropical epibenthic community, in relation to organic pollution. Journal of Experimental Marine Biology and Ecology 64, 253269.CrossRefGoogle Scholar
Wu, RSS and Richards, J (1981) Variations in benthic community structure in a sub-tropical estuary. Marine Biology 64, 191198.CrossRefGoogle Scholar
Xu, Y, Li, X, Ma, L, Dong, D, Kou, Q, Sui, J, Gan, Z and Wang, H (2017) Seasonal and spatial variations of macro- and megabenthic community characteristics in two sections of the East China Seas. Chinese Journal of Oceanography and Limnology 35, 11521164.CrossRefGoogle Scholar
Yonge, CM (1946) On the habits of Turritella communis Risso. Journal of the Marine Biological Association of the United Kingdom 26, 377380.CrossRefGoogle Scholar
Zhang, SR, Lu, XX, Higgitt, DL, Chen, CTA, Sun, HG and Han, JT (2007) Water chemistry of the Zhujiang (Pearl River): natural processes and anthropogenic influences. Journal of Geophysical Research 112, F010.CrossRefGoogle Scholar
Zhang, J, Gao, Y, Shi, X and , X (2017) Species composition and diversity of marine organisms from benthic trawling in Daya Bay of the northern South China Sea. Biodiversity Science 25, 10191030. (in Chinese with English abstract)CrossRefGoogle Scholar
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