Post on 01-Feb-2016
description
The Importance of Chemical Cues in Aquatic Animals
Presented by: Leah McIntire
Advisor: Brian Wisenden
Outline
IntroductionChemical cues
Predator/prey interactions Migration Shoaling tendencies Agonistic encounters
Conclusion
Introduction
Chemical Cues
Predator Prey
Disturbance Damage
Mucus Cell Alarm Substance Cell
Minnow Skin
Epidermis
Scale
Photo taken by R. Jan F. Smith
Alewife
American Shad
Shortnose Sturgeon
Blueback Herring
Gizzard Shad
Atlantic Salmon
American Eel
Sea Lamprey
Striped bass http://www.fws.gov/R5CRc/Salmon/workbook/
fish_facts_answers.gif
http://www.flickr.com/photos/hazy_jenius/2370892732/
Shoal of Red Sea Fusillier
http://caspar.bgsu.edu/~Huberlab/private/Images/Meralspread2.jpg
Example of agonistic behavior in lobsters
Chemical cues Predator/prey interactions Migration Shoaling tendencies Agonistic encounters
Chemosensory assessment of predation risk by slimy sculpins (Cottus cognatus):
responses to alarm, disturbance, and predator cues
Pamela J. Bryer, Reehan S. Mirza, and
Douglas P. Chivers
Journal of Chemical Ecology (2001) Vol. 27, No. 3
Methods and MaterialsSlimy Sculpin (Cottus cognatus)
http://www.unb.ca/fredericton/science/biology/Fish_key/Cottidae/sculpin_air_Gray.jpg
http://www.uaex.edu/cengle/CaneyBayou/images/backpa1.jpg
http://farm4.static.flickr.com/3403/3318280707_92c519c19c.jpg
Brook trout
http://www.cttrout.org/Images/Burton_Brook-CT_Brookie.jpg
Gravitational flow-through test apparatus
Stimulus added
Testing chamber
Experiment 1:Responses of Sculpins to Alarm, Disturbance, and Predator Cues
Chemical cues from…
1) Predatory brook trout
2) Injured sculpins
3) Disturbed sculpins (chased)
4) Injured swordtails
5) Undisturbed sculpins
6) Model fish predator
*all tests x 20
http://www.heathland.net/Tropical/Livebearers/Swordtail.jpg
Results
Results
Distilled Sculpin Pellet Brine Brine shrimp + water shrimp injured sculpin
A
rea
Use
Num
ber
of S
hort
Mov
es
S
helte
r U
se
Discussion
Sculpins respond to… predator chemicals damage-released alarm cues cues of disturbed conspecifics
Chemical cues Predator/prey interactions Migration Shoaling tendencies Agonistic encounters
Laboratory assessment of the role of a larval pheromone and natural stream odor
in spawning stream localization by migratory sea lamprey (Petromyzon
marinus)
Lance A. Vrieze and Peter W. Sorensen
CJFAS (2001) Vol. 58 Pg. 2374-2385
Methods and MaterialsSea Lamprey
http://www.glaucus.org.uk/sea-lamprey-Petromyzon-mari.jpg
Experiment 1a: determining whether and how migratory lamprey are attracted to the odor of
natural stream waters
Cheboygan River Water
Lake Huron Water
2 treatments:•Nasopores blocked•Nasopores not blocked
Results
Nasopores blockedNasopores clear
Experiment 2a: Are waters from streams with larval populations naturally more attractive than
those lacking larvae?
Larvae Containing River Water
Nonlarvae Containing River Water
Results
Experiment 2d: Is the pheromone complimented by other odorous cues in stream water?
Nagel Creek Water / Lake Huron
Larvae Induced Water
Results
Discussion
Sea lamprey use chemical cues to detect rivers bile acids from larvae natural river odors
Chemical cues Predator/prey interactions Migration Shoaling tendencies Agonistic encounters
Habitat-specific chemical cue influence association preferences and shoal
cohesion in fishM.M. Webster,
J. Goldsmith,
A. J. W. Ward, and P. J. B. Hart
Behavioral Ecology and Sociobiology (2007) 62:273-280
Methods and Materials
Threespine stickleback
http://pond.dnr.cornell.edu/nyfish/Gasterosteidae/threespine_stickleback.jpg
Part 1: How long do association preferences based upon habitat chemical cues take to break
down and build up?
Results
Time (minutes) exposure to different habitat
0 30 120 240
Pro
port
ion
of T
ime
Sho
alin
g
0.6
0.3
0
-0.3
-0.6
Part 2: Do habitat specific chemical cues influence shoal cohesion?
Results
Mixed All Freshwater All Blackwater All Saline Water
Habitat origin of individuals within shoal
Nea
rest
nei
ghbo
ur in
bod
y le
ngth
s
1.5
0.5
0
1
Discussion
Experiment 1 4 hours for habitat cues to wear off allows fish to switch
Experiment 2 same habitats shoals more cohesive increases forging efficiency communicate better
Chemical cues Predator/prey interactions Migration Shoaling tendencies Agonistic encounters
Individual and status recognition in the crayfish, Orconectes rusticus: the effects
of urine release on fight dynamics
Rebecca A. Zulandt Schneider, Robert Huber,
and Paul A. Moore
Behavior (2001) 138: 137-153
Methods and MaterialsCrayfish
http://www.ncwildlife.org/Wildlife_Species_Con/nccrayfishes/o_rusticus/mainphoto.jpg
Experiment 2: Urine Release
Two groupsUrine presentUrine blocked
Duration of fightMaximum Intensity
(0) no fighting(1) threat postures(2) claw lock(3) strike and rip
Discussion
First fights, longer duration, equal intensity Winner and loser effects Status recognition
Fights without urine, longer, more intense urine provides critical cue to end an encounter
Conclusion
http://www.alaska-in-pictures.com/data/media/5/jumping-
sockeye-salmon_6397.jpg
References
Bryer, P. J., Mirza, R. S., and Chivers, D. P. (2001). Chemosensory assessment of predation risk by slimy sculpins (Cottus cognatus): responses to alarm, disturbance, and predator cues. Journal of Chemical Ecology, 27(3).
Vrieze, L. A. and Sorensen, P. W. (2001). Laboratory assessment of the role of larval pheromone and natural stream odor in spawning stream localization by migratory sea lamprey (Petromyzon marinus). Can J Fish Aquat Sci, 58, 2374-2385
Webster, M. M., Goldsmith, J., Ward, A. J. W., and Hart, P. J. B. (2007). Habitat-specific chemical cues influence association preferences and shoal cohesion in fish. Behav Ecol Sociobio, 62, 273-280.
Zulant Schneider, R. A., Huber, R., and Moore, P. A. (2001). Individual and status recognition in the crayfish, Oronectes rusticus: the effects of urine release on fight dynamics. Behavior, 138, 137-153
More References
Petranka, J. W., Kats, L. B., and Sih, A. (1987). Predator-prey interactions among fish and larval amphibians: use of chemical cues to detect predatory fish. Anim Behav, 35:420-425.
Huber, M. E. and Delago, A. (1998). Serotonin alters decisions to withdraw in fighting crayfish, Astacus astucus: the motivational concept revisited. J Comp Phys A, 182: 573-583.