Abstract
The snail Nereina punctulata has been observed performing amphidromous migrations (salt to freshwater migration, post-larval settlement) in the Caribbean, with small- and medium-sized snails achieving maximum fitness at the mid- and high altitudes, but they may be restricted by energy stores. Large snails show no difference in fitness across altitude, but their previous migration history dictates their high-altitude placement in watersheds. The factors determining the rate of migration have not yet been studied. In this study, we sought to understand how migration rate changes with shell size and altitude. We used mark–recapture to track individual snails across seven sites of varying altitude in a single watershed on Dominica and measured the shell length of randomly collected snails at sites. Volunteers were assisted with data collection in both cases. Shell length was positively correlated with distance from river mouth, although smaller snails were more frequently found at high altitude, high flow sites. Snails closer to the river mouth had faster upstream migration rates than those at mid-altitude. While we found large snails at higher altitude sites, there was no significant relationship between migration rate and shell size. Our findings suggest that large snails do not migrate at maximal rates allowed by energy stores. We also observed erosion of the outer shell periostracum and calcium carbonate underneath, which was seen significantly more often on larger shells. We hypothesise that this erosion is a product of exposure of the structural calcium carbonate to low alkalinity in Dominican streams, following an initial chipping of the periostracum.
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References
Amortegui-Torres V, Taborda-Marin A, Blanco JF (2013) Edge effect on a Neritina virginea (Neritimorpha, Neritinidae) population in a black mangrove stand (Magnoliopsidae, Avicenniaceae: Avicennia germinans) in the Southern Caribbean. Pan-Am J Aquat Sci 8(2):68–78
Blanco JF, Scatena FN (2007) The spatial arrangement of Neritina virginea (Gastropoda:Neritidae) during upstream migration in a split-channel reach. River Res Appl 23:235–245
Blanco-Libreros JF, Arroyave-Rincó A (2009) Daños por depredación y tamaño de concha del caracol diádromo Neritina virginea (Gastropoda: Neritidae) en el Río Mameyes, Puerto Rico. Rev Biol Trop (Int J Trop Biol) 57(4):1069–1080
Brasher AM (1993) Life history characteristics of the native Hawaiian stream snail Neritina granosa (hihiwai) [technical report]. Cooperative National Park Resources Studies Unit, University of Hawai’i at Manoa
Cockell CS, Herrera A (2008) Why are some microorganisms boring? Trends Microbiol 16(3):101–106
Craig AK (1967) Lithophagic snail from southern British Honduras. Science 158(3802):795–796
Crandall ED, Taffel JR, Barber PH (2010) High gene flow due to pelagic larval dispersal among South Pacific archipelagos in two amphidromous gastropods (Neritomorpha: Neritidae). Heredity 104:563–572
Engman AC, Kwak TJ, Cope WG (2018) Do postlarval amphidromous fish transport marine-derived nutrients and pollutants to Caribbean streams? Ecol Freshw Fish 27:847–856
Golubic S, Friedmann EI, Schneider J (1981) The lithobiontic ecological niche, with special reference to microorganisms. J Sediment Res 51(2):475–478
Gorbach KR, Benbow ME, McIntosh MD, Burky AJ (2012) Dispersal and upstream migration of an amphidromous neritid snail: implications for restoring migratory pathways in tropical streams. Freshw Biol 57(8):1643–1657
Hodges MH, Allendorf FW (1998) Population genetics and pattern of larval dispersal of the endemic Hawaiian freshwater amphidromous gastropod Neritina granosa (Prosobranchia: Neritidae). Pac Sci 52(3):237–249
Kahle D, Wickham H (2013) ggmap: spatial visualization with ggplot2. R J 5(1):144–161
Kano Y (2009) Hitchhiking behaviour in the obligatory upstream migration of amphidromous snails. Biol Lett 5:465–468
Lucas MC, Baras E, Thom TJ, Duncan A, Slavík O (2001) Migration of freshwater fishes. Blackwell Science, Oxford
Maciolek JA (1978) Shell character and habitat of nonmarine Hawaiian neritid snails. Micronesica 14(2):209–214
March JG, Pringle CM, Townsend MJ, Wilson AI (2002) Effects of freshwater shrimp assemblages on benthic communities along an altitudinal gradient of a tropical island stream. Freshw Biol 47:377–390
McDowall RM (2010) Why be amphidromous: expatrial dispersal and the place of source and sink population dynamics? Rev Fish Biol Fisher 20:87–100
Michaud JP, Warienga M (2005) Estimating discharge and stream flows. Washington State Department of Ecology, 05-10-070
MolluscaBase (2018a) Clypeolum latissimum (Broderip, 1833). World Register of Marine. http://marinespecies.org/aphia.php?p=taxdetails&id=873723. Accessed 22 June 2018
MolluscaBase (2018b) Nereina punctulata (Lamarck, 1816). World Register of Marine. http://marinespecies.org/aphia.php?p=taxdetails&id=873793. Accessed 22 June 2018
Pyron M, Covich AP (2003) Migration patterns, densities, and growth of Neritina punctulata snails in Rio Espiritu Santo and Rio Mameyes, northeastern Puerto Rico. Caribb J Sci 39(3):338–347
Rodolpho-Metalpa R, Houlbrèque F, Tambutté É, Boisson F, Baggini C, Patti FP, Jeffree R, Fine M, Foggo A, Gattuso J-P, Hall-Spencer JM (2011) Coral and mollusc resistance to ocean acidification adversely affected by warming. Nat Clim Change 1:308–312
Schneider DW, Frost TM (1986) Massive upstream migrations by a tropical freshwater neritid snail. Hydrobiologia 132:153–157
Schneider DW, Lyons JL (1993) Dynamics of upstream migration in two species of tropical freshwater snails. J N Am Benthol Soc 12(1):3–16
Smith AL, Roobol MJ, Mattioli GS, Fryxell JE, Daly GE, Fernandez LA (2013) The volcanic geology of Dominica, Lesser Antilles: the surface expression of an island-arc batholith. Geol S AM S 496
Taylor JD, Kennedy WJ (1969) The influence of periostracum on the shell structure of bivalve molluscs. Calcif Tissus Res 3:274–283
Trussell GC, Johnson AS, Rudolph SG, Gilfillan ES (1993) Resistance to dislodgement: habitat and size-specific differences in morphology and tenacity in an intertidal snail. Mar Ecol Prog Ser 100:135–144
Waldbusser GG, Steenson RA, Green MA (2011) Oyster shell dissolution rates in estuarine waters: effects of pH and shell legacy. J Shellfish Res 30(3):659–669
Zydlewski J, Wilkie MP (2013) Freshwater to seawater transitions in migratory fishes. In: McCormick S, Farrell A, Brauner C (eds) Fish physiology: euryhaline fishes, 1st edn. Elsevier, Oxford, pp 253–326
Acknowledgements
The authors thank volunteers and research staff with Operation Wallacea (http://www.opwall.com/) who greatly assisted in data collection. Charlotte Palmer (Operation Wallacea) enabled the data collection to be undertaken with relative logistical ease and Jem Winston also assisted in field logistics. Benjamin Padilla aided with statistical analysis. Three anonymous reviewers provided helpful critique of the initial draft. Dominica’s Ministry of Agriculture and Fisheries provided research permits.
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Villeneuve, A.R., Thornhill, I. & Eales, J. Upstream migration and altitudinal distribution patterns of Nereina punctulata (Gastropoda: Neritidae) in Dominica, West Indies. Aquat Ecol 53, 205–215 (2019). https://doi.org/10.1007/s10452-019-09683-7
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DOI: https://doi.org/10.1007/s10452-019-09683-7