Ethology and Signaling in Animals Member Names: Responding to

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Ethology and Signaling in Animals
Member Names:
Responding to environmental stimuli is one of the fundamental principles that define living
organisms. For animals, the ability to detect and respond to stimuli is critical because an incorrect
response can mean death for an individual. The type of environmental stimuli that animals respond to
include abiotic or non-living stimuli like the rising or setting of the sun, changing seasons and in marine
organisms, the movement of the tides. Animals also respond to biotic or living environmental stimuli.
Biotic stimuli can include, but are not limited to, the presence of predators, food, mates or other family
members. For this laboratory we will analyze and quantify the behaviors exhibited between crayfish and
their environment and between two crayfish competitors.
It is always in the best interest for two animals, upon meeting, to “decide” which one of the two is
superior (i.e. dominant, stronger, territory holder) and without a significant physical altercation. The
behaviors that animals use to decide these meetings are classified as agonistic behaviors, which can
include dominant or submissive behaviors. By deciding which of the two individuals is superior without
a physical altercation, the fitness of both individuals is increased because their probability of survival is
increased; even the winner in a fight may be injured or mortally wounded in the combat. Information that
is sent from one individual to another may be classified as “honest” or “dishonest”.
An honest signal is one that cannot be faked or copied in any way. For instance male red deer,
Cervus elaphus, compete for mates by roaring; the male making the deepest and longest roar is the winner
and gains access to the females in the herd. In this example small males cannot fake a loud, deep call
because a larger healthy male (with greater lung capacity) will always win roaring contests. This is why
the signal is called “honest.” There are many types of honest signals in the animal kingdom including
special coloration or plumage in birds and manes or distinct fur in mammals. In contrast to an honest
signal, a dishonest signal as the term implies, is falsehood or “bluff”. This strategy must be employed
sparingly during specific times of their lives because it is based on a lie. An example of a dishonest
signal may be seen in some crustaceans, like the American lobster Homarus americanus. The lobster, like
all crustaceans, must molt to grow. The postmolt period (shortly after an individual has molted and lost
its shell) in the life of a lobster is one in which the newly molted individual is particularly vulnerable,
even if they are large. Just minutes after a lobster has molted the postmolt animal may look like a hard
shell lobster (they may be a bit pale and look a bit “off”), but if that postmolt lobster is picked up by a
person the lobster could literally be squished. An older postmolt lobster (approximately 3 hrs to several
weeks after completing the molting process) still has a very soft shell and a poorly developed musculature
to support its claws and the rest of the body. As a result, any physical altercation that a postmolt lobster
enters into will almost certainly result in a combat loss and even death. Lobsters in this state (postmolt
status) adopt behaviors that account for their vulnerability. One way to do this is to present their
opponent with a dishonest signal or a bluff.
When two lobsters meet for the first time and one lobster is postmolt (soft shell) and the other is a
hard shell animal (also known as intermolt or premolt status) then competitive bouts are different than in
interactions between two hard shell lobsters. The postmolt individual will often forego a characteristic
series of agonistic behaviors and will rapidly escalate an encounter. As an aside we will explore this
series of behaviors in the laboratory with the crayfish Procambarus clarksii. This strategy presents the
other combatant (the hard shell combatant) with a choice to escalate the fight with a potentially larger
individual or retreat. If the hard shell combatant retreats, then the bluff was a success. If the hard shell
combatant continues the fight, then the postmolt (soft) lobster retreats quickly. Experimental evidence
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has demonstrated that this is indeed what postmolt individuals choose to do: rapidly escalate and if faced
with further combat, retreat as quickly as possible. It is always better to run or, in this case, swim away,
from a fight so that you survive to fight another day.
carapace
length
Figure 1 – external anatomy and morphology of a male crayfish Procambarus clarksii. Figures 1A and B
illustrate the dorsal and ventral views respectively. Carapace length (cl) is defined as the distance
between the eye socket and then end of the carapace (Figure A). Please note that in figure 1B, the paired
first swimmeret of the male is stout and is used as a modified penis. In the female the first pair of
swimmeret is soft and identical to swimmerets 3 to 5. You should use the presence/absence of this
structure to determine the sex of the study individuals. http://crayfish.byu.edu/crayfish_biology.htm
For this laboratory exercise we will study the freshwater crayfish Procambarus clarksii, a close
relative of the American lobster. Both are members of the decapod crustaceans, or individuals with 10
walking legs (5 pairs on each side). They both have a hard exterior shell known as an exoskeleton that
covers their cephalothorax, walking legs and abdominal segments. The cephalothorax is the anteriormost portion of the body and includes the eyes, mouth and the antennae at the front of the animal.
Individual size is defined as the distance between one eye socket and the end of the cephalothorax, is
called the carapace length (cl) and is expressed in millimeters. Below the cephalothorax are 5 pair of
chelate walking legs, the first pair (also known as the claw or merus) is larger than the other four pairs.
The final four pairs of walking legs are and identical to one another with the last pair of legs being located
just in front of the abdomen. The abdomen or tail area is a broad, segmented section at the posterior of
the animal and terminates (ends) with a single pair of uropods on either side of a central telson (See
Figure 1).
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Laboratory Procedure
Getting to Know the Animal:
The first thing to do is to get to know the crayfish and observe the important anatomy of the
animal. First, focus on the anterior region where much of the sensory information is gathered by the
animal. You should see eyes, antennae and mouth parts. The eyes are paired and found on either side of
a central rostrum, or horn. The eyes are stalked and each eye has several hundred individual eyes or
ommatidia. Having so many individual eyes allows the individual to survey its environment and avoid
being eaten from behind.
How many pairs of antennae do you see on the animal?
What is the difference between the different antennae?
Which of the two antennae pair are used for mechnaoreception
Which of the two antennae pair are used for olfaction?
Describe the difference between the maxillipeds that you can see.
How many pairs of legs does the crayfish have?
Are the legs similarly/different shaped?
What is different between the legs?
What is the sex of the study organism
Male or
What is the carapace length of the study organism?
Remember to record your observation in millimeters!
Female?
mm.
Developing a Crayfish Ethogram:
In its simplest form, an ethogram is a quantitative description of an animal’s behavior.
The scientist hopes that the behavior being observed is “natural” but it should be noted that the
simple act of observing an animal may influence the behavior of the animal. When you are
conducting your observations, make sure to speak softly to your colleagues, to make your
observations from a distance and to move around as little as possible. The objective of this
section of the laboratory is to recognize and differentiate between crayfish behaviors. Finally
we want you to be able to quantify the frequency, duration and potentially the order in which
behaviors take place. We will start this with a simple situation, one crayfish and one object.
Place the object in the aquarium and leave it there for several minutes (no more than 5 minutes).
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Take note of whether the crayfish encounters or manipulates the object. If the object is
manipulated, record how it is manipulated (for instance which appendages are being used) and
how long the manipulation lasts. Remove the first object and replace it with a second object.
Repeat the steps above.
Object 1 – _________
Describe what the crayfish did with the object.
Object 2 -- __________
Describe what the crayfish did with the second object.
Crayfish Response to Stimuli:
Crayfish are epibenthic inhabitants of the freshwater community and can live in many
different environments including rivers, lakes and streams. Because of the diversity of their
habitats and their general size (just more than a mouthful for many predators) it is critical for a
crayfish to detect and respond to threats from a variety of different sources. The three most
effective nonhuman predators on crayfish are fish, birds and mammals (e.g. raccoons). Using
the materials you have at your desk, fashion a model of one of the three predators that were just
mentioned. After you have built your model move it to a set distance (e.g. 1 meter) and note the
orientation of the crayfish. If the crayfish is already responding to the model, then move the
model away until it does not respond to the model’s presence. Move the model directly toward
the crayfish at a slow and even speed. Make sure to record the approximate distance between the
crayfish and the model when the crayfish first reacts to the model.
How far did the model have to move for the first response to occur?
Is the response of the crayfish similar or different than the response of crayfish to the objects
placed in the aquarium earlier today?
If they are different, what did the crayfish do differently?
Do this several times (three) remembering to record the total distance to the crayfish, the
response of the crayfish and if the intensity of the behavioral response has increased or
decreased. Finally, change the orientation or speed of the model in relation to the crayfish.
Document the response that the crayfish has exhibited using the new orientation and compare it
to the first series.
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Agonistic Interactions:
For this next set of experiments you will match a resident crayfish with an intruder
crayfish and document the behavioral interactions between the two individuals. To do a test such
as this, you could control for things including the size, health, molt status and sex of the
combatants. We are going to vary size and status of the combatants. Before the combat record
the color(s) of the marks on the carapace, the sex and measure the carapace length of the
intruder and resident. Each crayfish has three marks with the most anterior mark in position 1,
and so on. Make sure to record all the colors of all three marks on the carapace!
BOUT 1
Resident
Intruder
Position
Position
1 / 2 / 3
1 / 2 / 3
CL (mm)
CL (mm)
The laboratory group of four people should have two watches and two datasheets. One
pair of students will observe the resident crayfish and the other pair will watch the intruder.
Place the intruder crayfish in the middle of the aquarium and move your hand and body away
quickly. For the next 10 minutes one pair of experimenters will record the type and duration of
behaviors for the dominant crayfish while the other pair of experimenters will record the type
and duration of behaviors by the intruder crayfish. See Table 1 to describe each behavior for
this section of the experiment. Be careful that you do not get so close to the aquarium that the
crayfish begin to react to you and not each other! At the end of 10 minutes, carefully remove the
intruder crayfish and place it into the “intruder holding” aquarium. We want to let this crayfish
rest and remain in a solitary aquarium for the time being. Let the resident crayfish recover for 10
minutes. During this recovery time for the resident crayfish, try not to disturb the animal at all.
It is best to back away from the aquarium entirely. As a group you should share your data and
then decide the following:
Who won the combat?
What type of behaviors did you observe most frequently?
dominant
submissive
Which behaviors were most frequently observed?
Were some behaviors more “important” in you decision than other behaviors?
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BOUT 2
Resident
Position
1 / 2 / 3
CL (mm)
Intruder
Position
1 / 2 / 3
CL (mm)
Next, get another intruder crayfish and record the sizes of the resident and new intruder. Repeat
your experimental observations for 10 minutes.
Who won the combat?
What type of behaviors did you observe most frequently?
dominant
submissive
Which behaviors were most frequently observed?
How was the second combat different from the first?
Was the winner the same in this combat?
After this trial return the second intruder to its holding aquarium and wait 5 minutes to give the
resident crayfish time to recover.
BOUT 3
Resident
Position
1 / 2 / 3
CL (mm)
Intruder
Position
1 / 2 / 3
CL (mm)
Take the first intruder crayfish and return it to the combat arena. Repeat your agonistic
analysis in the same manner that you did for the first two fights for 10 minutes.
Who won the combat?
What type of behaviors did you observe most frequently?
Which behaviors were most frequently observed?
How was the second combat different from the first?
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dominant
submissive
Was the winner the same in Bout #3 as Bout #1?
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Table 1 – Agonistic behaviors and the descriptions seen in crayfish, Procambarus clarksii.
Aggressive
Submissive
Upright posture – Cephalothorax lifted off
substrate with abdomen extended
Antennae waving (fast / slow)
Declined posture – Cephalothorax lifted off
substrate with abdomen retracted or extended
Antennae waving (fast / slow)
Maxilliped moving (fast / slow)
Maxilliped moving (fast / slow)
Approach – crayfish moves directly toward
the competitor
Abdomen bent – crayfish retracts its abdomen
beneath the cephalothorax
Hold – one crayfish grabs or holds an
appendage of the competitor
Retreat – directional movement away from the
competitor.
Push – one crayfish extends its cheliped and
contacts the competitor for an extended period
Tail flip – rapid contraction of the abdomen
resulting in a crayfish rapidly swimming away.
Strike – one crayfish uses a portion of its body
(e.g. cheliped) to contact the competitor in a
short burst
Cheliped retracted – moving the cheliped
below the anterior-most portion of the
cephalothorax
Table 2 – a generalized version of a data collections table. For each bout you will make a new
data table and label each one “Bout 1”, “Bout 2” or “Bout 3”.
BOUT #
Resident / Intruder MARKS 1/2/3
Resident / Intruder MARKS 1/2/3
Time
Behavior
Duration
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Time
Behavior
Duration
REMEMBER TO INCLUDE DATA TABLES FOR BOUTS 1, 2 AND 3 WHEN YOU
HAND THIS PROJECT IN!
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