The role of the lateral line and vision on body kinematics and hydrodynamic preference of rainbow trout in turbulent flow

James C. Liao

doi:10.1242/jeb.02487

journal article Oct 15, 2006

The role of the lateral line and vision on body kinematics and hydrodynamic preference of rainbow trout in turbulent flow

James C. Liao

Journal of Experimental Biology Vol. 209 No. 20 pp. 4077-4090 · The Company of Biologists

View at Publisher Save 10.1242/jeb.02487

Abstract

SUMMARYThe ability to detect water flow using the hair cells of the lateral line system is a unique feature found in anamniotic aquatic vertebrates. Fishes use their lateral line to locate prey, escape from predators and form cohesive schooling patterns. Despite the prevalence of complex flows in nature, almost nothing is known about the function of the lateral line and its relationship to other sensory modalities for freely swimming fishes in turbulent flows. Past studies indicate that under certain conditions the lateral line is not needed to swim steadily in uniform flow. This paper examines how the lateral line and vision affect body kinematics and hydrodynamic habitat selection of rainbow trout (Oncorhynchus mykiss) exposed to vortices generated behind a cylinder. Trout Kármán gaiting (i.e. exploiting vortices to hold station in a vortex street) with a pharmacologically blocked lateral line display altered kinematics; body wavelength and wave speed increase compared to control animals. When visual cues are withheld by performing experiments in the dark, almost all Kármán gait kinematics measured for fish with and without a functional lateral line are the same. The lateral line, rather than vision, plays a larger role in affecting body kinematics when trout hold station in a vortex street. Trout show a preference to Kármán gait in the light but not in the dark, which may be attributed to physiological state rather than hydrodynamic or sensorimotor reasons. In the dark, trout both with and without a functional lateral line hold station near the downstream suction region of the cylinder wake (i.e. entraining) and avoid the vortex street. Vision therefore plays a larger role in the preference to associate with a turbulent vortex street. Trout in the light with a blocked lateral line show individual variation in their preference to Kármán gait or entrain. In the dark, entraining trout with an intact lateral line will alternate between right and left sides of the cylinder throughout the experiment, showing an ability to explore their environment. By contrast, when the lateral line is blocked these fish display a strong fidelity to one side of the cylinder and are not inclined to explore other regions of the flow tank. Both entraining and Kármán gaiting probably represent energetically favorable strategies for holding station relative to the earth frame of reference in fast flows. The ability to decipher how organisms collect and process sensory input from their environment has great potential in revealing the mechanistic basis of how locomotor behaviors are produced as well as how habitat selection is modulated.

Topics

No keywords indexed for this article. Browse by subject →

References

61

[1]

Baker, C. F. and Montgomery, J. (1999). The sensory basis of rheotaxis in the blind Mexican cavefish, Astyanax fasciatus.J. Comp. Physiol. A184,519-527. 10.1007/s003590050351

[2]

Beal, D. N., Hover, F. S., Triantafyllou, M. S., Liao, J. C. and Lauder, G. V. (2006). Passive propulsion in vortex wakes. J. Fluid Mech.549,385-402. 10.1017/s0022112005007925

[3]

Bell, C. C. (2001). Memory-based expectations in electrosensory systems. Curr. Opin. Neurol.11,481-487. 10.1016/s0959-4388(00)00238-5

[4]

Blaxter, H. S. and Fuiman, L. A. (1989). Function of the free neuromasts of marine teleost larvae. In The Mechanosensory Lateral Line: Neurobiology and Evolution (ed. S. Coombs, P. Gorner and H. Munz). New York: Springer.

[5]

Bose, N. and Lien, J. (1990). Energy absorption from ocean waves: a free ride for cetaceans. Proc. R. Soc. Lond. B Biol. Sci.240,591-605.

[6]

Breder, C. M. (1965). Vortices and fish schools. Zoologica50,97-114. 10.5962/p.206663

[7]

Chagnaud, B. P., Bleckmann, H. and Engelmann, J.(2006). Neural responses of goldfish lateral line afferents to vortex motions. J. Exp. Biol.209,327-342. 10.1242/jeb.01982

[8]

Conley, R. A. and Coombs, S. (1998). Dipole source localization by mottled sculpin. III. Orientation after site-specific,unilateral denervation of the lateral line system. J. Comp. Physiol. A183,335-344.

[9]

Coombs, S., Gorner, P. and Munz, H. (1989). The Mechanosensory Lateral Line: Neurobiology and Evolution. New York: Springer-Verlag. 10.1007/978-1-4612-3560-6

[10]

Coombs, S., Braun, C. B. and Donovan, B.(2001). The orienting response of Lake Michigan mottled sculpin is mediated by canal neuromasts. J. Exp. Biol.204,337-348. 10.1242/jeb.204.2.337

[11]

Dijkgraaf, S. (1963). The functioning and significance of the lateral-line organs. Biol. Rev. Camb. Philos. Soc.38,51-105. 10.1111/j.1469-185x.1963.tb00654.x

[12]

Dijkgraaf, S. (1973). A method for complete and selective surgical elimination of the lateral line system in the codfish, Gadus morhua.Experientia29,737-738. 10.1007/bf01944809

[13]

Douglas, R. H., Bowmaker, J. K. and Kunz-Ramsay, Y. W.(1989). Ultraviolet vision in fish. In Seeing Contour and Colour (ed. J. J. Kulikowski, C. M. Dickinson and I. J. Murray), pp. 601-616. Oxford: Pergamon Press.

[14]

The effect of turbulence on the cost of swimming for juvenile Atlantic salmon (Salmo salar)

Eva C Enders, Daniel Boisclair, André G Roy

Canadian Journal of Fisheries and Aquatic Sciences 10.1139/f03-101

[15]

Engelmann, J., Hanke, W., Mogdans, J. and Bleckmann, H.(2000). Hydrodynamic stimuli and the fish lateral line. Nature408,51-52. 10.1038/35040706

[16]

Engelmann, J., Hanke, W. and Bleckmann, H.(2002). Lateral line reception in still- and running water. J. Comp. Physiol. A188,513-526.

[17]

Engelmann, J., Krother, S., Bleckmann, H. and Mogdans, J.(2003). Effects of running water on lateral line responses to moving objects. Brain Behav. Evol.61,195-212. 10.1159/000070703

[18]

Etkin, B., Korbacher, G. K. and Keefe, R. T.(1957). Acoustic radiation from a stationary cylinder in a fluid stream (Aeolian tones). J. Acoust. Soc. Am.29, 30-36. 10.1121/1.1908673

[19]

Fausch, K. D. (1993). Experimental analysis of microhabitat selection by juvenile steelhead (Oncorhynchus mykiss)and coho salmon (O. kisutch) in a British Columbia stream. Can. J. Fish. Aquat. Sci.50,1198-1207. 10.1139/f93-136

[20]

Fernald, R. D. and Wright, S. E. (1985). Growth of the visual system in the African cichlid fish, Haplochromis burtoni.Vision Res.25,163-170. 10.1016/0042-6989(85)90109-9

[21]

Gerstner, C. L. (1998). Use of substratum ripples for flow refuging by Atlantic cod, Gadus morhua. Environ.Biol. Fishes51,455-460. 10.1023/a:1007449630601

[22]

Grillner, S. (1985). Neurological bases of rhythmic motor acts in vertebrates. Science228,143-149. 10.1126/science.3975635

[23]

Hawryshyn, C. W. and Harosi, F. I. (1994). Spectral characteristics of visual pigments in rainbow trout (Oncorhynchus mykiss). Vision Res.34,1385-1392. 10.1016/0042-6989(94)90137-6

[24]

Heggenes, J. (1988). Effects of short-term flow fluctuations on displacement of, and habitat use by, brown trout in a small stream. Trans. Am. Fish. Soc.117,336-344. 10.1577/1548-8659(1988)117<0336:eosffo>2.3.co;2

[25]

Heggenes, J. (2002). Flexible summer habitat selection by wild, allopatric brown trout in lotic environments. Trans. Am. Fish. Soc.131,287-298. 10.1577/1548-8659(2002)131<0287:fshsbw>2.0.co;2

[26]

Hinch, S. G. and Rand, P. S. (2000). Optimal swimming speeds and forward-assisted propulsion: energy-conserving behaviours if upriver-migrating adult salmon. Can. J. Fish. Aquat. Sci.57,2470-2478. 10.1139/f00-238

[27]

Hobson, E. S., McFarland, W. N. and Chess, J. R.(1981). Crepuscular and nocturnal activities of Californian nearshore fishes, with consideration of their scotopic visual pigments and the photic environment. Fish. Bull.79, 1-30.

[28]

Ingle, D. (1971). Vision: the experimental analysis of visual behavior. In Fish Physiology: Sensory Systems and Electric Organs. Vol. 5 (ed. W. S. Hoar and D. J. Randall), pp. 347. New York: Academic Press.

[29]

Janssen, J. (2000). Toxicity of Co2+:implications for lateral line studies. J. Comp. Physiol. A186,957-960. 10.1007/s003590000148

[30]

Janssen, J. and Corcoran, J. (1993). Lateral line stimuli can override vision to determine sunfish strike trajectory. J. Exp. Biol.176,299-305. 10.1242/jeb.176.1.299

[31]

Kanter, M. J. and Coombs, S. (2002). Rheotaxis and prey detection in uniform currents by Lake Michigan mottled sculpin(Cottus bairdi). J. Exp. Biol.206, 59-70.

[32]

Karlsen, H. E. and Sand, O. (1987). Selective and reversible blocking of the lateral line in freshwater fish. J. Exp. Biol.133,249-262. 10.1242/jeb.133.1.249

[33]

Lewis, D. M. and Pedley, T. J. (2001). The influence of turbulence on plankton predation strategies. J. Theor. Biol.210,347-365. 10.1006/jtbi.2001.2310

[34]

Liao, J. C. (2004). Neuromuscular control of trout swimming in a vortex street: implications for energy economy during the Karman gait. J. Exp. Biol.207,3495-3506. 10.1242/jeb.01125

[35]

Fish Exploiting Vortices Decrease Muscle Activity

James C. Liao, David N. Beal, George V. Lauder et al.

Science 10.1126/science.1088295

[36]

The Kármán gait: novel body kinematics of rainbow trout swimming in a vortex street

James C. Liao, David N. Beal, George V. Lauder et al.

Journal of Experimental Biology 10.1242/jeb.00209

[37]

Encounter rates and swimming behavior of pause‐travel and cruise larval fish predators in calm and turbulent laboratory environments

Brian R. MacKenzie, Thomas Kiørboe

Limnology and Oceanography 10.4319/lo.1995.40.7.1278

[38]

Fictive Swimming Motor Patterns in Wild Type and Mutant Larval Zebrafish

Mark A. Masino, Joseph R. Fetcho

Journal of Neurophysiology 10.1152/jn.01248.2004

[39]

McLaughlin, R. L. and Noakes, D. L. G. (1998). Going against the flow: an examination of the propulsive movements made by young brook trout in streams. Can. J. Fish. Aquat. Sci.55,853-860. 10.1139/f97-308

[40]

Mogdans, J. and Bleckmann, H. (1998). Responses of the goldfish trunk lateral line to moving objects. J. Comp. Physiol. A182,659-676. 10.1007/s003590050211

[41]

Montgomery, J. and Coombs, S. (1998). Peripheral encoding of moving sources by the lateral line system of a sit-and-wait predator. J. Exp. Biol.201,91-102. 10.1242/jeb.201.1.91

[42]

The lateral line can mediate rheotaxis in fish

John C. Montgomery, Cindy F. Baker, Alexander G. Carton

Nature 10.1038/40135

[43]

Montgomery, J. C., McDonald, F., Baker, C. F., Carton, A. G. and Ling, N. (2003). Sensory integration in the hydrodynamic world of rainbow trout. Proc. R. Soc. Lond. B Biol. Sci.270,S195-S197. 10.1098/rsbl.2003.0052

[44]

Nauen, J. C. and Lauder, G. V. (2002). Quantification of the wake of rainbow trout (Oncorhynchus mykiss)using three-dimensional stereoscopic digital particle image velocimetry. J. Exp. Biol.205,3271-3279. 10.1242/jeb.205.21.3271

[45]

New, J. G. and Bodznick, D. (1990). Medullary electrosensory processing in the little skate. II. Suppression of self-generated electrosensory interference during respiration. J. Comp. Physiol. A167,295-307.

[46]

Partridge, B. L. and Pitcher, T. J. (1980). The sensory basis of fish schools: relative roles of the lateral line and vision. J. Comp. Physiol.135,315-325. 10.1007/bf00657647

[47]

Pavlov, D. S., Lupandin, A. I. and Skorobogatov, M. A.(2000). The effects of flow turbulence on the behavior and distribution of fish. J. Ichthyol.40,S232-S261.

[48]

Pitcher, T. J., Partridge, B. L. and Wardle, C. S.(1976). A blind fish can school. Science194,963-965. 10.1126/science.982056

[49]

ANALYZING TABLES OF STATISTICAL TESTS

William R. Rice

Evolution 10.1111/j.1558-5646.1989.tb04220.x

[50]

Roeser, T. and Baier, H. (2003). Visuomotor behaviors in larval zebrafish after GFP-guided laser ablation of the optic tectum. J. Neurosci.23,3726-3734. 10.1523/jneurosci.23-09-03726.2003

Showing 50 of 61 references

Cited By

143

Lateral-line activity during undulatory body motions suggests a feedback link in closed-loop control of sea lamprey swimming

A. Ayali, S. Gelman · 2009

Canadian Journal of Zoology

Kármán vortex street detection by the lateral line

Boris P. Chagnaud, Horst Bleckmann · 2007

Journal of Comparative Physiology A

Metrics

143

Citations

61

References

Details

Published: Oct 15, 2006
Vol/Issue: 209(20)
Pages: 4077-4090

Authors

J

James C. Liao

Department of Organismic and Evolutionary Biology, Harvard University, Cambridge, MA 02138, USA

Cite This Article

James C. Liao (2006). The role of the lateral line and vision on body kinematics and hydrodynamic preference of rainbow trout in turbulent flow. Journal of Experimental Biology, 209(20), 4077-4090. https://doi.org/10.1242/jeb.02487

The role of the lateral line and vision on body kinematics and hydrodynamic preference of rainbow trout in turbulent flow

You May Also Like