Book contents
- Frontmatter
- Contents
- Preface
- List of Contributors
- The Hudson River Estuary
- 1 The Hudson River Estuary: Executive Summary
- GEOLOGICAL, PHYSICAL, AND CHEMICAL SETTING OF THE HUDSON
- PRIMARY PRODUCTION, MICROBIAL DYNAMICS, AND NUTRIENT DYNAMICS OF THE HUDSON
- HUDSON RIVER COMMUNITIES, FOOD WEBS, AND FISHERIES
- 12 Larval Migrations Between the Hudson River Estuary and New York Bight
- 13 The Diadromous Fish Fauna of the Hudson River: Life Histories, Conservation Concerns, and Research Avenues
- 14 Fisheries of the Hudson River Estuary
- 15 The Role of Tributaries in the Biology of Hudson River Fishes
- 16 Ecology of the Hudson River Zooplankton Community
- 17 Submersed Macrophyte Distribution and Function in the Tidal Freshwater Hudson River
- 18 Long-Term and Large-Scale Patterns in the Benthic Communities of New York Harbor
- 19 The Benthic Animal Communities of the Tidal-Freshwater Hudson River Estuary
- 20 Tidal Wetlands of the Hudson River Estuary
- 21 Alien Species in the Hudson River
- CONTAMINANTS AND MANAGEMENT ISSUES OF THE HUDSON RIVER ESTUARY
- Index
- Plate section
- References
12 - Larval Migrations Between the Hudson River Estuary and New York Bight
Published online by Cambridge University Press: 06 January 2010
Book contents
- Frontmatter
- Contents
- Preface
- List of Contributors
- The Hudson River Estuary
- 1 The Hudson River Estuary: Executive Summary
- GEOLOGICAL, PHYSICAL, AND CHEMICAL SETTING OF THE HUDSON
- PRIMARY PRODUCTION, MICROBIAL DYNAMICS, AND NUTRIENT DYNAMICS OF THE HUDSON
- HUDSON RIVER COMMUNITIES, FOOD WEBS, AND FISHERIES
- 12 Larval Migrations Between the Hudson River Estuary and New York Bight
- 13 The Diadromous Fish Fauna of the Hudson River: Life Histories, Conservation Concerns, and Research Avenues
- 14 Fisheries of the Hudson River Estuary
- 15 The Role of Tributaries in the Biology of Hudson River Fishes
- 16 Ecology of the Hudson River Zooplankton Community
- 17 Submersed Macrophyte Distribution and Function in the Tidal Freshwater Hudson River
- 18 Long-Term and Large-Scale Patterns in the Benthic Communities of New York Harbor
- 19 The Benthic Animal Communities of the Tidal-Freshwater Hudson River Estuary
- 20 Tidal Wetlands of the Hudson River Estuary
- 21 Alien Species in the Hudson River
- CONTAMINANTS AND MANAGEMENT ISSUES OF THE HUDSON RIVER ESTUARY
- Index
- Plate section
- References
Summary
abstract Gaining insight into the causes of temporal and spatial variation in larval recruitment to estuaries is an important goal of fisheries biologists who ultimately aim to accurately predict year class strength of recreationally and commercially important species. I present essential information about the most abundant invertebrates and fishes that develop in the Hudson River Estuary and New York Bight during the summer and how their larvae migrate between these areas. This was accomplished by conducting an oceanographic research program that blended four approaches: 1) extensive larval surveys from the upper estuary to the edge of the continental shelf, 2) intensive hourly sampling of larvae over consecutive light-dark and tidal cycles and multiple depths, 3) a comparative hypothesis testing approach using passive eggs and swimming larvae, and 4) comparisons of larval production and settlement. Depending on the species, larvae remained in the estuary, migrated from the estuary to the continental shelf, or migrated from the shelf to the estuary. Interspecific differences in larval behavior enabled larvae to complete these different migration patterns. Moreover, the coupling of simple behaviors with conservative oceanographic features may have enabled larvae to reliably migrate between adult habitats and larval nursery areas regardless of how far larvae traveled. Thus, larvae undertake true migrations that may return them to natal populations more reliably than previously believed, which has important implications for the management of estuarine resources and the evolution of marine life histories. Additional research is needed to track larval movements, determine how postlarvae cross the continental shelf, and document how fish larvae are distributed and transported in the lower Hudson River Estuary.
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- Information
- The Hudson River Estuary , pp. 157 - 170Publisher: Cambridge University PressPrint publication year: 2006
References
Anastasia, J. C. 1999. Plasticity and the cost of dispersal by estuarine crab larvae. Doctoral dissertation. State University of New York, Stony Brook, New York
, , and 1998. Tagging crustacean larvae: assimilation and retention of trace elements. Limnology and Oceanography 43:362–8CrossRefGoogle Scholar
1955. Ecological control of the occurrence of barnacles in the Miramichi estuary. Bulletin of the National Museum of Canada 137: 1–69Google Scholar
1989. Demersal schooling prior to settlement of larvae of the naked goby. Environmental Biology of Fishes 26:97–103CrossRefGoogle Scholar
, and 1998. Estuarine immigration by crab postlarvae: mechanisms, reliability and adaptive significance. Marine Ecology Progress Series 174:51–65CrossRefGoogle Scholar
, and 1986. Vertical migration cycles of crab larvae and their role in larval dispersal. Bulletin of Marine Science 39: 192–201Google Scholar
1988. Dispersal strategies of two species of swimming crabs on the continental shelf adjacent to Delaware Bay. Marine Ecology Progress Series 49:243–8CrossRefGoogle Scholar
and 2001. Larval transport on the Atlantic continental shelf of North America: a review. Estuarine Coastal and Shelf Science 52:51–77CrossRefGoogle Scholar
, , and 1988. Dispersal and recruitment of fiddler crab larvae in the Delaware river estuary. Marine Ecology Progress Series 43:181–8CrossRefGoogle Scholar
, , and 1984. Dispersal and recruitment of blue crab larvae in the Delaware Bay. Estuarine Coastal and Shelf Science 18:1–12CrossRefGoogle Scholar
, and 1994. Photoresponses of crab megalopae in offshore and estuarine waters: implications for transport. Journal of Experimental Marine Biology and Ecology 182:183–92CrossRefGoogle Scholar
, and 1992. Dispersal of juveniles and variable recruitment in sessile marine species. Nature 360:579–80CrossRefGoogle Scholar
, , and 2001. Pre- and post-settlement factors as determinants of juvenile blue crab (Callinectes sapidus) abundance: results from the north-central Gulf of Mexico. Marine Ecology Progress Series 222:163–76CrossRefGoogle Scholar
, and 1997. Planktivory as a selective force for reproductive synchrony and larval migration. Marine Ecology Progress Series 157:79–95CrossRefGoogle Scholar
Hunter, J. R. 1981. Feeding ecology and predation of marine fish larvae, in (ed.), Marine Fish Larvae: Morphology, Ecology and Relation to Fisheries. Washington Sea Grant Program, University of Washington, Seattle, pp. 34–77Google Scholar
, and 1977. Larval development of the spider crab, Libinia emarginata (Majidae). Fishery Bulletin 75:831–41Google Scholar
, , , , , and 2002. Sensory environments, larval abilities and local self-recruitment. Bulletin of Marine Science 70:309–40Google Scholar
, and 1992. Swimming velocities and behavior of blue crab (Callinectes sapidus Rathbun) megalopae in still and flowing water. Estuaries 15:186–92CrossRefGoogle Scholar
, , and 1963. Distribution of larvae of the naked goby, Gobiosoma bosci, in the York River. Chesapeake Science 4:120–5CrossRefGoogle Scholar
Morgan, S. G. 1995. Life and death in the plankton: larval mortality and adaptation, in (ed.), Ecology of Marine Invertebrate Larvae. Boca Raton, FL: CRC Press, pp. 279–321Google Scholar
Morgan, S. G. 2001. The larval ecology of marine communities, in , , and (eds), Marine Community Ecology, Sunderland, MA: Sinauer Associates, pp. 158–81Google Scholar
, , , and 1996. Population regulation of blue crabs, Callinectes, in the northern Gulf of Mexico: postlarval supply. Marine Ecology Progress Series 133:73–88CrossRefGoogle Scholar
, , , and 1996. Density-dependent settler-recruit-juvenile relationships in blue crabs. Ecological Monographs 66:277–300CrossRefGoogle Scholar
, , , and 2000. Explaining advection: do larval bay anchovy (Anchoa mitchilli) show selective tidal-stream transport?. ICES Journal of Marine Science 57:360–71CrossRefGoogle Scholar
Shanks, A. L. 1995. Mechanisms of cross-shelf dispersal of larval invertebrates and fishes, in (ed.), Ecology of Marine Invertebrate Larvae. Boca Raton, FL: CRC Press, pp. 323–67Google Scholar
Strathmann, R. R. 1982. Selection for retention or export of larvae in estuaries, in (ed.) Estuarine Comparisons. New York: Academic Press, pp. 521–36Google Scholar
, , , , , , and 2002. Evolution of self-recruitment and its consequences for marine populations. Bulletin of Marine Science 70:377–96Google Scholar
, , , and 1980. The behavioral basis of larval recruitment in the crab, Callinectes sapidus Rathbun: a laboratory investigation of the ontogenetic changes in geotaxis and barokinesis. Biological Bulletin 159:402–417CrossRefGoogle Scholar
, , , , , , , and 2002. Quantifying larval retention and connectivity in marine populations with artificial and natural markers: can we do it right?. Bulletin of Marine Science 70: 273–90Google Scholar
1950. Reproductive and larval ecology of marine bottom invertebrates. Biological Review 25:1–45CrossRefGoogle ScholarPubMed
1984. Shrimps, Lobsters, and Crabs of the Atlantic Coast of the Eastern United States, Maine to Florida. Smithsonian Institution, Washington, D.C.Google Scholar
1995. New options in physiological and behavioural ecology through multichannel telemetry. Marine Ecology Progress Series 193:257–75Google Scholar
1990. Larval ecology of marine invertebrates: a sesquicentennial history. Ophelia 32:1–48CrossRefGoogle Scholar
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