Marine larval ecology
Marine larval ecology is the study of the factors influencing dispersing larvae, which many marine invertebrates and fishes have. Marine animals with a larva typically release many larvae into the water column, where the larvae develop before metamorphosing into adults.
Marine larvae can disperse over long distances, although determining the actual distance is challenging, because of their size and the lack of a good tracking method. Knowing dispersal distances is important for managing fisheries, effectively designing marine reserves, and controlling invasive species.
- 1 Theories on the evolution of a biphasic life history
- 2 Larval development strategies
- 3 Predator Defense
- 4 Dispersal and settlement
- 5 Larval Sensory Systems
- 6 Self-recruitment
- 7 Conservation
- 8 Implications
- 9 See also
- 10 References
Theories on the evolution of a biphasic life historyEdit
Larval dispersal is one of the most important topics in marine ecology, today. Many marine invertebrates and many fishes have a bi-phasic life cycle with a pelagic larva or pelagic eggs that can be transported over long distances, and a demersal or benthic adult. There are several theories behind why these organisms have evolved this biphasic life history:
- Larvae use different food sources than adults, which decreases competition between life stages.
- Pelagic larvae can disperse large distances, colonize new territory, and move away from habitats that has become overcrowded or otherwise unsuitable.
- A long pelagic larval phase can help a species to break its parasite cycles.
- Pelagic larvae avoid benthic predators.
Dispersing as pelagic larvae can be risky. For example, while larvae do avoid benthic predators, they are still exposed to pelagic predators in the water column.
Larval development strategiesEdit
Marine larvae develop via one of three strategies: Direct, lecithotrophic, or planktotrophic. Each strategy has risks of predation and the difficulty of finding a good settlement site.
Direct developing larvae look like the adult. They have typically very low dispersal potential, and are known as “crawl-away larvae,” because they crawl away from their egg after hatching. Some species of frogs and snails hatch this way.
Lecithotrophic larvae have greater dispersal potential than direct developers. Many fish species and some benthic invertebrates have lecithotrophic larvae, which have yolk droplets or a yolk sac for nutrition during dispersal. Though some lecithotrophic species can feed in the water column, too. But many, such as tunicates, cannot, and so must settle before depleting their yolk. Consequently, these species have short pelagic larval durations and do not disperse long distances.
Planktotrophic larvae feed while they are in the water column and can be over a long time pelagic and so disperse over long distances. This disperse ability is a key adaptation of benthic marine invertebrates. Planktotrophic larvae feed on phytoplankton and small zooplankton, including other larvae. Planktotrophic development is the most common type of larval development, especially among benthic invertebrates.
Because planktotrophic larvae are for a long time in the water column and recruit successfully with low probability, early researchers developed the “lottery hypothesis”, which states that animals release huge numbers of larvae to increase the chances that at least one will survive, and that larvae cannot influence their probability of success. This hypothesis views larval survival and successful recruitment as chance events, which numerous studies on larval behavior and ecology have since shown to be false. Though it has been generally disproved, the larval lottery hypothesis represents an important understanding of the difficulties faced by larvae during their time in the water column.
Predation is a major threat to marine larvae, which are an important food source for many organisms. Invertebrate larvae in estuaries are particularly at risk because estuaries are nursery grounds for planktivorous fishes. Larvae have evolved strategies to cope with this threat, including direct defense and avoidance.
Direct defense can include protective structures and chemical defenses. Most planktivorous fishes are gape-limited predators, meaning their prey is determined by the width of their open mouths, making larger larvae difficult to ingest. One study proved that spines serve a protective function by removing spines from estuarine crab larvae and monitoring differences in predation rates between de-spined and intact larvae. The study also showed that predator defense is also behavioral, as they can keep spines relaxed but erect them in the presence of predators.
Larvae can avoid predators on small and large spatial scales. Some larvae do this by sinking when approached by a predator. A more common avoidance strategy is to become active at night and remain hidden during the day to avoid visual predators. Most larvae and plankton undertake diel vertical migrations between deeper waters with less light and fewer predators during the day and shallow waters in the photic zone at night, where microalgae is abundant. Estuarine invertebrate larvae avoid predators by developing in the open ocean, where there are fewer predators. This is done using reverse tidal vertical migrations. Larvae use tidal cycles and estuarine flow regimes to aid their departure to the ocean, a process that is well-studied in many estuarine crab species.
An example of reverse tidal migration performed by crab species would begin with larvae being released on a nocturnal spring high tide to limit predation by planktivorous fishes. As the tide begins to ebbs, larvae swim to the surface to be carried away from the spawning site. When the tide begins to flood, larvae swim to the bottom, where water moves more slowly due to the boundary layer. When the tide again changes back to ebb, the larvae swim to the surface waters and resume their journey to the ocean. Depending on the length of the estuary and the speed of the currents, this process can take anywhere from one tidal cycle to several days.
Dispersal and settlementEdit
The most widely accepted theory explaining the evolution of a pelagic larval stage is the need for long-distance dispersal ability. Sessile and sedentary organisms such as barnacles, tunicates, and mussels require a mechanism to move their young into new territory, since they cannot move long distances as adults. Many species have relatively long pelagic larval durations on the order of weeks or months. During this time, larvae feed and grow, and many species metamorphose through several stages of development. For example, barnacles molt through six naupliar stages before becoming a cyprid and seeking appropriate settlement substrate.
This strategy can be risky. Some larvae have been shown to be able to delay their final metamorphosis for a few days or weeks, and most species cannot delay it at all. If these larvae metamorphose far from a suitable settlement site, they perish. Many invertebrate larvae have evolved complex behaviors and endogenous rhythms to ensure successful and timely settlement.
Many estuarine species exhibit swimming rhythms of reverse tidal vertical migration to aid in their transport away from their hatching site. Individuals can also exhibit tidal vertical migrations to reenter the estuary when they are competent to settle.
As larvae reach their final pelagic stage, they become much more tactile; clinging to anything larger than themselves. One study observed crab postlarvae and found that they would swim vigorously until they encountered a floating object, which they would cling to for the remainder of the experiment. It was hypothesized that by clinging to floating debris, crabs can be transported towards shore due to the oceanographic forces of internal waves,[clarification needed] which carry floating debris shoreward regardless of the prevailing currents.
Once returning to shore, settlers encounter difficulties concerning their actual settlement and recruitment into the population. Space is a limiting factor for sessile invertebrates on rocky shores. Settlers must be wary of adult filter feeders, which cover substrate at settlement sites and eat particles the size of larvae. Settlers must also avoid becoming stranded out of water by waves, and must select a settlement site at the proper tidal height to prevent desiccation and avoid competition and predation. To overcome many of these difficulties, some species rely on chemical cues to assist them in selecting an appropriate settlement site. These cues are usually emitted by adult conspecifics, but some species cue on specific bacterial mats or other qualities of the substrate.
Larval Sensory SystemsEdit
Although with a pelagic larva, many species can increase their dispersal range and decrease the risk of inbreeding, a larva comes with challenges: Marine larvae risk being washed away without finding a suitable habitat for settlement. Therefore, they have evolved many sensory systems:
Far from shore, larvae are able to use magnetic fields to orient themselves towards the coast over large spatial scales. There is additional evidence that species can recognize anomalies in the magnetic field to return to the same location multiple times throughout their life. Though the mechanisms that these species use is poorly understood, it appears that magnetic fields play an important role in larval orientation offshore, where other cues such as sound and chemicals may be difficult to detect.
Vision and non-visual light perceptionEdit
Phototaxis (ability to differentiate between light and dark areas) is important to find a suitable habitat. Phototaxis evolved relatively quickly and taxa that lack developed eyes, such as schyphozoans, use phototaxis to find shaded areas to settle away from predators.
Phototaxis is not the only mechanism that guides larvae by light. The larvae of the annelid Platynereis dumerilii do not only show positive and negative phototaxis over a broad range of the light spectrum, but swim down to the center of gravity when they are exposed to non-directional UV-light. This behavior is a UV-induced positive gravitaxis. This gravitaxis and negative phototaxis induced by light coming from the water surface form a ratio-metric depth-gauge. Such a depth gauge is based on the different attenuation of light across the different wavelengths in water. In clear water blue light (470 nm) penetrates the deepest. And so the larvae need only to compare the two wavlength ranges UV/violet (< 420 nm) and the other wavelengths to find their preferred depth.
Species that produce more complex larvae, such as fish, can use full vision to find a suitable habitat on small spatial scales. Larvae of damselfish use vision to find and settle near adults of their species.
Marine larvae use sound and vibrations to find a good habitat where they can settle and metamorphose into juveniles. This behavior has been seen in fish as well as in the larvae of scleractinian corals. Many families of coral reef fish are particularly attracted to high-frequency sounds produced by invertebrates, which larvae use as an indicator of food availability and complex habitat where they may be protected from predators. It is thought that larvae avoid low frequency sounds because they may be associated with transient fish or predators and is therefore not a reliable indicator of safe habitat.
The spatial range at which larvae detect and use sound waves is still uncertain, though some evidence suggests that it may only be reliable at very small scales. There is concern that changes in community structure in nursery habitats, such as seagrass beds, kelp forests, and mangroves, could lead to a collapse in larval recruitment due to a decrease in sound-producing invertebrates. Other researchers argue that larvae may still successfully find a place to settle even if one cue is unreliable.
Many marine organisms use olfaction (chemical cues in the form of scent) to locate a safe area to metamorphose at the end of their larval stage. This has been shown in both vertebrates and invertebrates. Research has shown that larvae are able to distinguish between water from the open ocean and water from more suitable nursery habitats such as lagoons and seagrass beds. Chemical cues can be extremely useful for larvae, but may not have a constant presence, as water input can depend on currents and tidal flow.
Human Impacts on Sensory SystemsEdit
Recent research in the field of larval sensory biology has begun focusing more on how human impacts and environmental disturbance affect settlement rates and larval interpretation of different habitat cues. Ocean acidification due to anthropogenic climate change and sedimentation have become areas of particular interest.
Ocean acidification has been shown to alter the way that pelagic larvae are able to process information and production of the cues themselves. Acidification can alter larval interpretations of sounds, particularly in fish, leading to settlement in suboptimal habitat. Though the mechanism for this process is still not fully understood, some studies indicate that this breakdown may be due to a decrease in size or density of their otoliths. Furthermore, sounds produced by invertebrates that larvae rely on as an indicator of habitat quality can also change due to acidification. For example, snapping shrimp produce different sounds that larvae may not recognize under acidified conditions due to differences in shell calcification.
Hearing is not the only sense that may be altered under future ocean chemistry conditions. Evidence also suggests that larval ability to process olfactory cues was also affected when tested under future pH conditions. Red color cues that coral larvae use to find crustose coralline algae, with which they have a commensal relationship, may also be in danger due to algal bleaching.
Sediment runoff, from natural storm events or human development, can also impact larval sensory systems and survival. One study focusing on red soil found that increased turbidity due to runoff negatively influenced the ability of fish larvae to interpret visual cues. More unexpectedly, they also found that red soil can also impair olfactory capabilities.
Marine ecologists are often interested in the degree of self-recruitment in populations. Historically, larvae were considered passive particles that were carried by ocean currents to faraway locations. This led to the belief that all marine populations were demographically open, connected by long distance larval transport. Recent work has shown that many populations are self-recruiting, and that larvae and juveniles are capable of purposefully returning to their natal sites.
Researchers take a variety of approaches to estimating population connectivity and self-recruitment, and several studies have demonstrated their feasibility. Jones et al. and Swearer et al., for example, investigated the proportion of fish larvae returning to their natal reef. Both studies found higher than expected self-recruitment in these populations using mark, release, and recapture sampling. These studies were the first to provide conclusive evidence of self-recruitment in a species with the potential to disperse far from its natal site, and laid the groundwork for numerous future studies.
Ichthyoplankton have a high mortality rate as they transition their food source from yolk sac to zooplankton. It is proposed that this mortality rate is related to inadequate zooplankton as well as an inability to move through the water effectively at this stage of development, leading to starvation. Many ichthyoplankton use suction to feed. Turgidity of water impairs the organisms’ ability to feed even when there is a high density of prey. Reducing these hydrodynamic constraints on cultivated populations could lead to higher yields for repopulation efforts and has been proposed as a means of conserving fish populations by acting at the larval level.
A network of marine reserves has been initiated for the conservation of the world’s marine larval populations. These areas restrict fishing and therefore increase the number of otherwise fished species. This leads to a healthier ecosystem and affects the number of overall species within the reserve as compared to nearby fished areas; however, the full effect of an increase in larger predator fish on larval populations is not currently known. Also, the potential for utilizing the motility of fish larvae to repopulate the water surrounding the reserve is not fully understood. Marine reserves are a part of a growing conservation effort to combat overfishing; however, reserves still only comprise about 1% of the world’s oceans. These reserves are also not protected from other human-derived threats, such as chemical pollutants, so they cannot be the only method of conservation without certain levels of protection for the water around them as well.
For effective conservation, it is important to understand the larval dispersal patterns of the species in danger, as well as the dispersal of invasive species and predators which could impact their populations. Understanding these patterns is an important factor when creating protocol for governing fishing and creating reserves. A single species may have multiple dispersal patterns. The spacing and size of marine reserves must reflect this variability to maximize their beneficial effect. Species with shorter dispersal patterns are more likely to be affected by local changes and require higher priority for conservation because of the separation of subpopulations.
The principles of marine larval ecology can be applied in other fields, too whether marine or not. Successful fisheries management relies heavily on understanding population connectivity and dispersal distances, which are driven by larvae. Dispersal and connectivity must also be considered when designing natural reserves. If populations are not self-recruiting, reserves may lose their species assemblages. Many invasive species can disperse over long distances, including the seeds of land plants and larvae of marine invasive species. Understanding the factors influencing their dispersal is key to controlling their spread and managing established populations.
- Grosberg, R.K. and D.R. Levitan. 1992. For adults only? Supply-side ecology and the history of larval biology. Trends Ecol. Evol. 7: 130-133.
- Swearer, S. E., J. S. Shima, M. E. Hellberg, S. R. Thorrold, G. P. Jones, D. R. Robertson, S. G. Morgan, K. A. Selkoe, G. M. Ruiz, and R. R. Warner. 2002. Evidence of self-recruitment in demersal marine populations. Bull. Mar. Sci. 70(1) Suppl.: 251-271.
- Strathmann, R. R., T. P. Hughes, A. M. Kuris, K. C. Lindeman, S. G. Morgan, J. M. Pandolfi, and R. R. Warner. 2002. Evolution of local recruitment and its consequences for marine populations. Bull. Mar. Sci. 70(1) Suppl.: 377-396.
- Thorson, G. 1950. Reproductive and larval ecology of marine bottom invertebrates. Biol. Rev. Cambridge Philos. Soc. 25: 1-45.
- Roughgarden, J., Y. Iwasa, and C. Blaxter. 1985. Demographic theory for an open population with space-limited recruitment. Ecology 66: 54-67.
- Caley, M.J., M.H. Carr, M.A. Hixon, T.P. Hughes, G.P. Jones, and B. Menge. 1996. Recruitment and the local dynamics of open marine populations. Evolution 35: 1192-1205.
- Kingsford, M. J., J. M. Leis, A. Shanks, K. C. Lindeman, S. G. Morgan, and J. Pineda. 2002. Sensory environments, larval abilities, and local self-recruitment. Bull. Mar. Sci. 70(1) Suppl.: 309-340.
- Lindquist, Niels; Hay, Mark E. (1996-02-01). "Palatability and Chemical Defense of Marine Invertebrate Larvae". Ecological Monographs. 66 (4): 431–450. doi:10.2307/2963489. ISSN 1557-7015. JSTOR 2963489.
- Devries, Dennis R.; Stein, Roy A.; Bremigan, Mary T. (1998-11-01). "Prey Selection by Larval Fishes as Influenced by Available Zooplankton and Gape Limitation". Transactions of the American Fisheries Society. 127 (6): 1040–1050. doi:10.1577/1548-8659(1998)127<1040:psblfa>2.0.co;2. hdl:1811/45384. ISSN 1548-8659.
- Morgan, S. G. 1989. Adaptive significance of spination in estuarine crab zoeae. Ecology 70: 462-482.
- Zaret, T.M. and J.S. Suffern. 1976. Vertical migration in zooplankton as a predator avoidance. Limnol. Oceanogr. 21: 804-813.
- Cronin, T.W. and R.B. Forward, Jr. 1979. Tidal vertical migration: An endogenous rhythm in estuarine crab larvae. Science 205: 1020-1022.
- Tankersley, R.A. and R.B. Forward, Jr. 1994. Endogenous swimming rhythms in estuarine crab megalopae: implications for flood-tide transport. Mar. Biol. 118: 415-423.
- Zeng, C. and E. Naylor. 1996. Endogenous tidal rhythms of vertical migration in field collected zoea-1 larvae of the shore crab Carcinus maenas: implications for ebb-tide offshore dispersal. Mar. Ecol. Prog. Ser. 132: 71-82.
- DiBacco, C., D. Sutton, and L. McConnico. 2001. Vertical migration behavior and horizontal distribution of brachyuran larvae in a low-inflow estuary: implications for bay-ocean exchange. Mar. Ecol. Prog. Ser. 217: 191-206.
- Forward, R.B. Jr, and R.A. Tankersley. 2001. Selective tidal-stream transport of marine animals. Oceanogr. Mar. Biol. Annu. Rev. 39: 305-353.
- Strathmann, Richard R. (1978-12-01). "THE EVOLUTION AND LOSS OF FEEDING LARVAL STAGES OF MARINE INVERTEBRATES". Evolution. 32 (4): 894–906. doi:10.1111/j.1558-5646.1978.tb04642.x. ISSN 1558-5646. PMID 28567936.
- Treml, Eric A.; Roberts, Jason J.; Chao, Yi; Halpin, Patrick N.; Possingham, Hugh P.; Riginos, Cynthia (2012-10-01). "Reproductive Output and Duration of the Pelagic Larval Stage Determine Seascape-Wide Connectivity of Marine Populations". Integrative and Comparative Biology. 52 (4): 525–537. doi:10.1093/icb/ics101. ISSN 1540-7063. PMID 22821585.
- Brothers, E.B., D.M. Williams, and P.F. Sale. 1983. Length of larval life in twelve families of fishes at “One Tree Lagoon,” Great Barrier Reef, Australia. Mar. Biol. 76: 319-324.
- Scheltema, R.S. 1986. On dispersal and planktonic larvae of benthic invertebrates: an eclectic overview and summary of problems. Bull. Mar. Sci. 39: 290-322.
- Jones, L. W. G.; Crisp, D. J. (1954-02-01). "The larval stages of the Barnacle Balanus improvisus Darwin". Proceedings of the Zoological Society of London. 123 (4): 765–780. doi:10.1111/j.1096-3642.1954.tb00203.x. ISSN 1469-7998.
- Gebauer, P., K. Paschke, and K. Anger. 2004. Stimulation of metamorphosis in an estuarine crab, Chasmagnathus granulata (Dana, 1851): temporal window of cue receptivity. J. Exp. Mar. Biol. Ecol. 311: 25-36.
- Goldstein, J.S., M.J. Butler IV, and H. Matsuda. 2006. Investigations into some early-life history strategies for Caribbean spiny lobster and implications for pan-carib connectivity. J. Shellfish Res. 25: 731.
- Christy, J.H. and S.G. Morgan. 1998. Estuarine immigration by crab postlarvae: mechanisms, reliability and adaptive significance. Mar. Ecol. Prog. Ser. 174: 51-65.
- Shanks, Alan L. 1985. Behavioral basis of internal-wave-induced shoreward transport of megalopae of the crab Pachygrapsus crassipes. Marine Ecol. Prog. Series 24: 289-295.
- Crisp, D.J. and P.S. Meadows. 1962. The chemical basis of gregariousness in cirripedes. Proc. Roy. Soc. Lond. B158: 364-387.
- Pawlik, J.R. 1986. Chemical induction of larval settlement and metamorphosis in the reef building tube worm; Phragmatopoma californica (Sabellidae: Polychaeta). Mar. Biol. 91: 51-68.
- Elliott, J.K., J.M. Elliott, and R.N. Mariscal. 1995. Host selection, location, and association behaviors of anemonefishes in field settlement experiments. Mar. Biol. 122: 377-390.
- Pechenik, Jan (February 1999). "On the advantages and disadvantages of larval stages in benthic marine invertebrate life cycle". Marine Ecology Progress Series. 177: 269–297. doi:10.3354/meps177269.
- Kingsford, Michael J.; Leis, Jeffrey M.; Shanks, Alan; Lindeman, Kenyon C.; Morgan, Steven G.; Pineda, Jesús (2002-01-01). "Sensory environments, larval abilities and local self-recruitment". Bulletin of Marine Science. 70 (1): 309–340.
- O'Connor, Jack; Muheim, Rachel (2017-08-15). "Pre-settlement coral-reef fish larvae respond to magnetic field changes during the day". Journal of Experimental Biology. 220 (16): 2874–2877. doi:10.1242/jeb.159491. ISSN 0022-0949. PMID 28576824.
- Jékely, Gáspár (2009-10-12). "Evolution of phototaxis". Philosophical Transactions of the Royal Society of London B: Biological Sciences. 364 (1531): 2795–2808. doi:10.1098/rstb.2009.0072. ISSN 0962-8436. PMC 2781859. PMID 19720645.
- Svane, Ib; Dolmer, Per (1995-04-18). "Perception of light at settlement: a comparative study of two invertebrate larvae, a scyphozoan planula and a simple ascidian tadpole". Journal of Experimental Marine Biology and Ecology. 187 (1): 51–61. doi:10.1016/0022-0981(94)00171-9. ISSN 0022-0981.
- Jékely, Gáspár; Colombelli, Julien; Hausen, Harald; Guy, Keren; Stelzer, Ernst; Nédélec, François; Arendt, Detlev (20 November 2008). "Mechanism of phototaxis in marine zooplankton". Nature. 456 (7220): 395–399. doi:10.1038/nature07590. PMID 19020621.
- Randel, Nadine; Asadulina, Albina; Bezares-Calderón, Luis A; Verasztó, Csaba; Williams, Elizabeth A; Conzelmann, Markus; Shahidi, Réza; Jékely, Gáspár (27 May 2014). "Neuronal connectome of a sensory-motor circuit for visual navigation". eLife. 3. doi:10.7554/eLife.02730. PMC 4059887. PMID 24867217.
- Gühmann, Martin; Jia, Huiyong; Randel, Nadine; Verasztó, Csaba; Bezares-Calderón, Luis A.; Michiels, Nico K.; Yokoyama, Shozo; Jékely, Gáspár (August 2015). "Spectral Tuning of Phototaxis by a Go-Opsin in the Rhabdomeric Eyes of Platynereis". Current Biology. 25 (17): 2265–2271. doi:10.1016/j.cub.2015.07.017. PMID 26255845.
- Verasztó, Csaba; Gühmann, Martin; Jia, Huiyong; Rajan, Vinoth Babu Veedin; Bezares-Calderón, Luis A.; Piñeiro-Lopez, Cristina; Randel, Nadine; Shahidi, Réza; Michiels, Nico K.; Yokoyama, Shozo; Tessmar-Raible, Kristin; Jékely, Gáspár (29 May 2018). "Ciliary and rhabdomeric photoreceptor-cell circuits form a spectral depth gauge in marine zooplankton". eLife. 7. doi:10.7554/eLife.36440. PMC 6019069. PMID 29809157.
- Nilsson, Dan-Eric (31 August 2009). "The evolution of eyes and visually guided behavior". Philosophical Transactions of the Royal Society B: Biological Sciences. 364 (1531): 2833–2847. doi:10.1098/rstb.2009.0083. PMC 2781862. PMID 19720648.
- Nilsson, Dan-Eric (12 April 2013). "Eye evolution and its functional basis". Visual Neuroscience. 30 (1–2): 5–20. doi:10.1017/S0952523813000035. PMC 3632888. PMID 23578808.
- Lythgoe, John N. (1988). Light and Vision in the Aquatic Environment. Sensory Biology of Aquatic Animals. pp. 57–82. doi:10.1007/978-1-4612-3714-3_3. ISBN 978-1-4612-8317-1.
- Lecchini, David; Shima, Jeffrey; Banaigs, Bernard; Galzin, René (2005-03-01). "Larval sensory abilities and mechanisms of habitat selection of a coral reef fish during settlement". Oecologia. 143 (2): 326–334. doi:10.1007/s00442-004-1805-y. ISSN 0029-8549. PMID 15647903.
- Vermeij MJ, Marhaver KL, Huijbers CM, Nagelkerken I, Simpson SD (May 2010). "Coral larvae move toward reef sounds". PLOS ONE. 5 (5): e10660. doi:10.1371/journal.pone.0010660. PMC 2871043. PMID 20498831.
- Simpson, S.D.; Meekan, M.G.; Jeffs, A.; Montgomery, J.C.; McCauley, R.D. (2008). "Settlement-stage coral reef fish prefer the higher-frequency invertebrate-generated audible component of reef noise". Animal Behaviour. 75 (6): 1861–1868. doi:10.1016/j.anbehav.2007.11.004.
- Kaplan MB, Mooney TA (August 2016). "Coral reef soundscapes may not be detectable far from the reef". Scientific Reports. 6 (1): 31862. doi:10.1038/srep31862. PMC 4994009. PMID 27550394.
- Rossi, Tullio; Connell, Sean D.; Nagelkerken, Ivan (2017). "The sounds of silence: regime shifts impoverish marine soundscapes". Landscape Ecology. 32 (2): 239–248. doi:10.1007/s10980-016-0439-x.
- Igulu, M. M.; Nagelkerken, I.; Beek, M. van der; Schippers, M.; Eck, R. van; Mgaya, Y. D. (2013-11-20). "Orientation from open water to settlement habitats by coral reef fish: behavioral flexibility in the use of multiple reliable cues". Marine Ecology Progress Series. 493: 243–257. doi:10.3354/meps10542. ISSN 0171-8630.
- Atema, Jelle; Kingsford, Michael J.; Gerlach, Gabriele (2002-10-04). "Larval reef fish could use odour for detection, retention and orientation to reefs". Marine Ecology Progress Series. 241: 151–160. doi:10.3354/meps241151. ISSN 0171-8630.
- Dumas, Pascal; Tiavouane, Josina; Senia, Jocelyn; Willam, Andrew; Dick, Lency; Fauvelot, Cecile (2014). "Evidence of early chemotaxis contributing to active habitat selection by the sessile giant clam Tridacna maxima". Journal of Experimental Marine Biology and Ecology. 452: 63–69. doi:10.1016/j.jembe.2013.12.002.
- Havel, Lisa N.; Fuiman, Lee A. (2016). "Settlement-Size Larval Red Drum (Sciaenops ocellatus) Respond to Estuarine Chemical Cues". Estuaries and Coasts. 39 (2): 560–570. doi:10.1007/s12237-015-0008-6.
- Leis, J. M.; Siebeck, U.; Dixson, D. L. (2011). "How Nemo Finds Home: The Neuroecology of Dispersal and of Population Connectivity in Larvae of Marine Fishes". Integrative and Comparative Biology. 51 (5): 826–843. doi:10.1093/icb/icr004. PMID 21562025.
- Ashur MM, Johnston NK, Dixson DL (July 2017). "Impacts of Ocean Acidification on Sensory Function in Marine Organisms". Integrative and Comparative Biology. 57 (1): 63–80. doi:10.1093/icb/icx010. PMID 28575440.
- Rossi T, Connell SD, Nagelkerken I (March 2016). "Silent oceans: ocean acidification impoverishes natural soundscapes by altering sound production of the world's noisiest marine invertebrate". Proceedings: Biological Sciences. 283 (1826): 20153046. doi:10.1098/rspb.2015.3046. PMC 4810867. PMID 26984624.
- Castro JM, Amorim MC, Oliveira AP, Gonçalves EJ, Munday PL, Simpson SD, Faria AM (2017). "Painted Goby Larvae under High-CO2 Fail to Recognize Reef Sounds". PLOS ONE. 12 (1): e0170838. doi:10.1371/journal.pone.0170838. PMC 5268378. PMID 28125690.
- Bignami S, Enochs IC, Manzello DP, Sponaugle S, Cowen RK (April 2013). "Ocean acidification alters the otoliths of a pantropical fish species with implications for sensory function". Proceedings of the National Academy of Sciences of the United States of America. 110 (18): 7366–70. doi:10.1073/pnas.1301365110. PMC 3645591. PMID 23589887.
- Devine, B. M.; Munday, P. L.; Jones, G. P. (2012). "Rising CO2 concentrations affect settlement behaviour of larval damselfishes". Coral Reefs. 31 (1): 229–238. doi:10.1007/s00338-011-0837-0.
- Foster, T.; Gilmour, J. P. (2016-11-09). "Seeing red: Coral larvae are attracted to healthy‑looking reefs". Marine Ecology Progress Series. 559: 65–71. doi:10.3354/meps11902. ISSN 0171-8630.
- O’Connor, J. Jack; Lecchini, David; Beck, Hayden J.; Cadiou, Gwenael; Lecellier, Gael; Booth, David J.; Nakamura, Yohei (2016-01-01). "Sediment pollution impacts sensory ability and performance of settling coral-reef fish" (PDF). Oecologia. 180 (1): 11–21. doi:10.1007/s00442-015-3367-6. hdl:10453/41685. ISSN 0029-8549. PMID 26080759.
- Jones, G. P., M. J. Milicich, M. J. Emslie and C. Lunow. 1999. Self-recruitment in a coral reef fish population. Nature 402: 802-804.
- Swearer, S. E., J. E. Caselle, D. W. Lea, and R. R. Warner. 1999. Larval rentention and recruitment in an island population of a coral-reef fish. Nature 402: 799-802.
- Levin, L. 2006. Recent progress in understanding larval dispersal: new directions and digressions. Int. Comp. Biol. 46: 282-297.
- Voss, Rüdiger; Hinrichsen, Hans-Harald; Wieland, Kai (2001-11-19). "Model-supported estimation of mortality rates in Baltic cod (Gadus morhua callarias L.) larvae: the varying impact of 'critical periods'". BMC Ecology. 1: 4. doi:10.1186/1472-6785-1-4. ISSN 1472-6785. PMC 60663. PMID 11737879.
- China, V., and R. Holzman. 2014. Hydrodynamic starvation in first-feeding larval fishes. PNAS doi:10.1073/pnas.1323205111.
- Bohnsack, J. A. 1992. Reef resource habitat protection: the forgotten factor. Marine Recreational Fisheries 14: 117-129.
- Jones, G. P., M. Srinivasan, and G. R. Almany. 2007. Conservation of marine biodiversity. Oceanography 20: 100-111.