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First published online February 27, 2009
Journal of Experimental Biology 212, 853-858 (2009)
Published by The Company of Biologists 2009
doi: 10.1242/jeb.024547
Costs and benefits of increased weapon size differ between sexes of the slender crayfish, Cherax dispar
1 School of Integrative Biology, The University of Queensland, St Lucia, QLD,
4072 Australia
2 The Ecology Centre, The University of Queensland, St Lucia, QLD, 4072
Australia
3 Department of Biomolecular and Sport Sciences, Coventry University, Coventry,
CV1 5FB, UK
4 School of Biological Sciences, A08, The University of Sydney, Sydney, NSW,
2006 Australia
* Author for correspondence (e-mail: r.wilson{at}uq.edu.au)
Accepted 17 December 2008
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Summary |
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 TOP Summary INTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONReferences |
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Key words: dishonest signals, physical performance, signals of strength, weapon size
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INTRODUCTION |
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TOPSummaryINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONReferences |
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). He suggested such traits could evolve by increasing a
male's access to mates, either via male competition or female choice.
Theory predicts that these elaborate signals are reliable indicators of a
male's quality and/or resource holding potential (RHP)
(Maynard Smith and Harper,
2003). The reliability of these sexual signals is believed to be
ensured via two main pathways (indices and handicaps)
(Andersson, 1994), although
other mechanisms have been suggested
(Searcy and Nowicki, 2005).
`Indices' are signals that are reliable because they cannot be faked
(Maynard Smith and Harper,
1995; Hughes,
2000) and their intensity is causally related to the quality being
signalled [performance-based signal
(Enquist, 1985)]. `Handicaps'
are reliable because they are costly to produce and/or have costly
consequences such as increased predation
(Zahavi, 1975;
Adams and Mesterton-Gibbons,
1995).
Males of many species possess specialised weapons that are often displayed
to resolve territorial disputes without direct physical contact. For most
organisms, signals of weapon size appear to be accurate or reliable predictors
of strength or fighting ability (e.g.
Dawkins and Guilford, 1991;
Vye et al., 1997;
Sneddon et al., 2000;
Malo et al., 2005;
Vanhooydonck et al., 2005),
although not all studies have directly measured weapon performance (see also
Sneddon et al., 2000;
Huyghe et al., 2005;
Lappin et al., 2006). However,
there are a few reported cases of unreliable (or dishonest) signals of both
fighting ability and mate choice signals
(Steger and Caldwell, 1983;
Backwell et al., 2000;
Wilson et al., 2007).
Unreliable signals of potential fighting ability are considered to be
problematic for signalling theory as it is not clear how these signals are
maintained as a stable strategy within a population
(Maynard Smith and Harper,
2003). Current theory predicts unreliable signalling of weapon
strength should be rare or absent in nature
(Maynard Smith and Harper,
1988; Gardner and Morris,
1989; Dawkins and Guilford,
1991; Adams and
Mesterton-Gibbons, 1995). However, Számadó provides
a model that predicts some level of dishonesty during symmetrical aggressive
signalling can be maintained as a stable strategy within a population
(Számadó,
2000).
Signals of weapon strength should be expected to be physiologically linked
to competitive ability so that animals of low competitive ability cannot
produce the signal of an animal with high competitive ability
(Wiley, 1983;
Maynard Smith and Harper,
1988) [i.e. indices of RHP
(Maynard Smith and Harper,
2003)]. In contrast with theoretical predictions, males of the
Australian slender crayfish (Cherax dispar) routinely use unreliable
signals of weapon strength during agonistic interactions
(Wilson et al., 2007) whereas
females use reliable signals of strength
(Bywater et al., 2008). Both
males and females of the slender crayfish use the size of their enlarged front
claws (chelae) as signals of dominance during aggressive encounters
(Wilson et al., 2007). Most
disputes between competing individuals are resolved before they escalate into
physical fights (Wilson et al.,
2007) and the relative size of the chelae is usually used as a
means of determining whether an individual engages in a fight or retreats. At
least for males, only individuals closely matched for chela size engage in
physical combat and the winners of these disputes are those individuals with
the strongest chelae (Wilson et al.,
2007) [see also Seebacher and Wilson for Cherax
destructor (Seebacher and Wilson,
2006)].
In this study, we examined both the functional benefits and costs of
possessing larger chelae (weapons) for males and females of the Australian
slender crayfish (Cherax dispar Riek 1951). Firstly, we examined the
benefits of possessing larger weaponry for chela strength. Given that chela
size is an unreliable signal of strength for males
(Wilson et al., 2007) and a
reliable signal for females (Bywater et
al., 2008), we expected that males would display greater variation
in chela strength for a given chela size than females. We also provided a
detailed investigation of the in vitro contractile performance of
chela muscle for both males and females. Finally, we investigated the
possibility of functional trade-offs in weapon size (handicap) by assessing
the relationship between chela size and maximum escape swimming performance
for both males and females. We predicted that the larger chelae of males would
lead to slower escape performance than females and males with larger chelae
would display relatively slower swimming speeds.
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MATERIALS AND METHODS |
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TOPSummaryINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONReferences |
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). All experimental protocols were in accordance with the UQ
Animal Ethics Committee and Queensland National Parks and Wildlife Service
guidelines. All crayfish used in experiments were more than three days outside
the pre- or post-moult stage. For analyses of the benefits of large chelae, we
measured chela size and maximum chela closing force for 97 male and 60 female
crayfish [male body length, 53.2±0.7 mm; female body length,
51.1±0.6 mm (t=–2.23; P=0.027)]. In addition,
we compared the in vitro performance of chela muscle from males
(N=7) and females (N=7) of C. dispar. Finally, we
assessed the relationships between chela size and strength and escape swimming
speed for 41 males and 28 females. All performance and behavioural tests were
performed at 25°C. All individual crayfish were housed in individual
5-litre plastic containers filled with natural creek water and a 2 cm base
layer of gravel. Crayfish were fed daily on pellets and maintained in the
laboratory for 72 h before use in experiments.
Chela size and strength
Chela size was determined from images of the left and right chela recorded
with a digital camera and analysed with morphometric software (SigmaScan 5.0,
San Jose, CA, USA). For each chela, seven measures were taken to quantify
size: total chela length, wrist depth, maximum chela depth, dactylus length,
dactylus depth, propodus depth and propodus length (see
Wilson et al., 2007). Because
these variables were highly correlated, we used principal components analyses
(PCA) to derive a single measure of mean chela size for our analysis. A
separate analysis was conducted for each chela. Both analyses yielded a
principal component that described over 90% of the variation in the seven
variables. As both chelae are approximately symmetrical and equally used
during agonistic encounters, we used mean PCA scores for both chelae of an
individual for subsequent analyses.
Maximum strength of the left and right chela was measured for each individual crayfish using a custom-built apparatus consisting of two flat pieces of metal (0.7 mm thick) separated by a third piece of metal (1.7 mm thick), with one strain gauge (RS Components, Smithfield, NSW, Australia) glued onto the outer side of each of the 0.7 mm-thick pieces. When force was applied to each side of the apparatus, the 0.7 mm-thick metal pieces would bend at a rate proportional to the force applied. Each strain gauge could quantify the amount of bending in the metal plate and was connected to bridge amplifiers (BridgePod, AD Instruments, Sydney, Australia) via a custom-made Wheatstone bridge. The force applied to each side of the metal was recorded using a PowerLab (AD Instruments) system connected to a laptop and force measurements from each strain gauge were added together. At least five chela grabs were recorded for each chela for each individual crayfish and the greatest force measured for each chela was used as their maximum performance. Total chela force was calculated from the sum of both left and right chelae for each individual.
In vitro chela muscle performance
We built upon earlier analyses of the in vitro performance of
C. dispar chela muscle (Wilson et
al., 2007) using more detailed analyses of in vitro
muscle performance from seven males and seven females. Crayfish were
euthanased prior to dissection. The propodal process was removed to free the
dactyl from the rest of the propodus, whilst leaving the chela closer muscle
intact. Dissection was performed at 25°C in an aerated saline solution
with the following composition (in mmol l–1): NaCl, 205; KCl,
5.4; MgCl2 2.7; glucose 10; HEPES 10.0; CaCl2, 13.5; pH
7.4 at 20°C. The dactyl was clamped in a crocodile clip attached to a
force transducer (Dynamometer UF1, Pioden Controls Ltd, Newport, Isle of
Wight, UK) and the propodus was clamped in a crocodile clip attached to a
servomotor (V201, Ling Dynamic Systems, Royston, Herts, UK). The muscle
preparation was placed inside a temperature-controlled perspex bath with
circulating saline solution saturated with air and maintained at
20±0.5°C.
A series of twitches was used to determine the stimulation amplitude and muscle length that generated the greatest isometric twitch force. Stimuli of 1.5 ms in duration were delivered via two parallel platinum wire electrodes placed on either side of the muscle. A 200 ms train of stimuli was then delivered to the muscle to elicit a tetanic contraction and the frequency of stimulation was adjusted to maximise the height of the tetanus (90–100 Hz). A resting period of 5 min was provided between each tetanic response. The experimental apparatus was controlled and data were collected using the Testpoint software package (CEC, Boston, MA, USA). Data were then exported and analysed in Microsoft Excel (Redmond, WA, USA). The maximal force produced by each muscle was corrected for propodus size, enabling us to compare muscle quality/stress between genders.
Trade-offs between chela size and maximum swimming performance
We determined the maximum burst swimming speed of 41 males (body lengths,
55.93±1.05 mm) and 28 females (body lengths, 51.90±0.78 mm)
(body length; t=–4.95; P<0.05) by filming five
startle responses for each individual with a high-speed digital camera
recording at 250 Hz. We elicited swimming responses by placing crayfish into
the centre of a swimming arena (glass aquarium 0.3x0.2x0.1 m deep)
and gently touching the end of their chelae. Only responses from a stationary
position that led to a powerful backwards swimming stroke with limited
vertical movement (as observed during filming) were analysed. We used a pair
of metallic tongs to always touch the front chelae of each crayfish by
approaching them from a frontal direction. Individuals were given five minutes
rest between each recorded stimulus response and they displayed no signs of
fatigue across the trials. Three types of escape tailflicks have been
described in crayfish and lobsters: the medial giant tailflick (MG), the
lateral giant tailflick (LG) and the non-giant tailflick (NonG)
(Wine and Krasne, 1972;
Edwards et al., 1999;
Finley and MacMillan, 2002;
Herberholz et al., 2004).
Distinguishing among these three different types of escape responses can be
difficult when observing freely moving crayfish
(Jackson and MacMillan, 2000).
Both the MG and NonG usually result in linear backwards swimming responses
whereas the LG tailflick results in the crayfish pitching forwards and upwards
away from the simuli. The MG tailflicks are initiated by the receptive field
at the anterior end of the animal and are activated by visual or tactile
stimuli. Given we elicited responses that resulted in linear backwards
swimming with one powerful backwards stroke and crayfish were stimulated by
touching their chelae, we expect most of our observed responses were the more
powerful MG type tailflicks. Although we cannot be certain an MG response was
recorded in each case (rather than a NonG response), we only used the fastest
recorded swim speed for each individual as a measure of their maximum
performance.
We filmed swimming sequences by recording the image captured off a mirror
angled at 45 deg. to the bottom of the glass-bottomed aquarium with a
high-speed digital camera (Redlake Imaging Corporation, Tallahassee, FL, USA).
The accompanying Redlake software package was used for analysis of the startle
responses. We replayed sequences frame-by-frame and the centre rostrum region
of the head (i.e. between the eyes) was digitised. We determined the distance
moved by individual crayfish between each successive frame for each startle
response sequence. We then calculated instantaneous measures of velocity by
differentiating distance data that had been subjected to a three-point moving
average filter (Walker, 1998;
Wilson and Franklin, 1999).
Smoothing filters are commonly utilised to minimise and control for
measurement error during frame-by-frame analyses of high-speed video
recordings when calculating instantaneous measures of speed (see
Walker, 1998). The three-point
moving average filter is one of the simplest algorithms that controls for this
potential measurement error. From each startle response, we calculated maximum
burst velocity and the total distance moved throughout the initial 120 ms
response period. We used the fastest of the swimming sequences analysed for
each individual as a measure of its maximum burst swimming performance (see
Oufiero and Garland,
2007).
Statistical analyses
Chela shape was described by the residuals of the linear regressions of all
original seven morphological variables on the estimate of `chela size' (first
component of PCA). These regressions were significant
(R2>0.8) and homogeneity of slopes allowed statistical
analyses on these residual values. Thus, analyses comparing the shape of chela
morphology between males and females were performed on residuals (relative
differences) to remove the overall effects of chela size from individual
traits. The relationship between body length/chela size and maximum chela
force was compared between sexes using a general linear model with one
continuous (body length/chela size) and one categorical factor (sex).
Correlations between measures of swimming performance, chela force and chela
size were performed on body length- or chela size (first component of PCA of
chela size) residuals using the Pearson's product moment correlation. Negative
correlations between measures of performance and morphological traits indicate
a functional (i.e. performance) trade-off. Some authors suggest that utilising
residuals to examine relationships among continuous variables whilst holding a
third factor constant may result in the loss of degrees of freedom (d.f.) (see
Garcia-Berthou, 2001).
Alternative methodologies utilise partial regression coefficients to express
the correlation between two variables whilst maintaining other variables
constant (Kachigan, 1991). In
our study, both methodologies produced similar results and only those results
using residual analyses are reported for continuity and graphical
representation of the data. However, to demonstrate the rigour of the negative
relationship between chela size and swimming speed for males, both analyses
are reported. All results are presented as means ± s.e.m. Significance
was taken at the level of P<0.05.
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RESULTS |
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TOPSummaryINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONReferences |
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Post-hoc tests revealed that the relative size of several chela dimensions (based on residual scores against chela size) differed significantly between sexes (Table 1). Males possessed greater wrist depths (F1,66=7.80; P=0.007) and maximum chela depths (F1,66=7.96; P=0.006) than females whereas females had greater propodus (F1,66=7.80; P=0.0048) and dactylus (F1,66=7.80; P=0.007) lengths than males (Fig. 2). Females with greater wrist depths (N=37, rp=0.40; P=0.01) and maximum chela depths (N=37, rp=0.46; P=0.004) possessed relatively stronger chela forces whereas females with greater propodus (N=37, rp=–0.42; P=0.01) lengths possessed weaker chela forces. Females with greater dactylus lengths also had a tendency to possess weaker chela forces but this was not statistically significant (N=37, rp=–0.32; P=0.06). Males with greater wrist depths did not have stronger chela forces (N=25, rp=0.20; P=0.33) but those with greater maximum chela depths possessed stronger chelae (N=25, rp=0.58; P=0.003). Males with greater propodus (N=25, rp=–0.48; P=0.01) and dactylus (N=25, rp=–0.52; P=0.008) lengths also possessed weaker chela forces.
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In vitro chela muscle performance
Maximum absolute tetanic force of male chela muscle was significantly
greater than females (P<0.001)
(Table 2). Twitch activation
and relaxation times were significantly faster in females than males, being
41% faster to peak twitch force (Table
2) (P<0.05). Tetanus activation and relaxation times
tended to be faster in females than in males, being 34% faster in time to half
peak tetanus and 25% faster in time from last stimulus to half tetanus
relaxation (Table 2)
(P<0.05).
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Trade-offs between chela size and maximum swimming speed
Females possessed greater absolute (t=–5.67, d.f.=67;
P<0.001) and body length-specific (t=–6.04,
d.f.=55; P<0.001) escape swimming speeds than males of C.
dispar. The burst swimming speed of females was 142±4.1 cm
s–1 (27.5±0.94 BL s–1)
whereas males only reached a peak speed of 107±4.2 cm
s–1 (19.1±1.0 BL s–1). In
addition, swimming speed was negatively correlated with chela size in males of
C. dispar (N=41, rp=–0.57;
P<0.01) (partial correlation coefficient=–0.45;
P=0.003) (Fig. 3A). By
contrast, swimming speed and chela size for females of C. dispar were
not significantly correlated (Fig.
3B) (N=28, rp=–0.26;
P=0.18). Swimming speed and chela force were not significantly
correlated in either males (N=15, rp=–0.29;
P=0.30) or females (N=29, rp=0.057;
P=0.77).
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DISCUSSION |
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TOPSummaryINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONReferences |
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; Bywater et al.,
2008). Females of C. dispar displayed less variation in
strength for a given chela size, which supports the suggestion that displays
of chela for females during agonistic encounters are reliable signals of
strength (Bywater et al.,
2008).
The effects of variation in chela morphology on force generation during
chela closing have been studied in a variety of crab species
(Schenk and Wainwright, 2001;
Levinton and Allen, 2005).
Essentially, the force generated is dependent on mechanical advantage of the
chela, the mean angle of pennation, physiological cross-sectional area and
maximal stress of the chela closer muscle. The mechanical advantage of the
chela can be increased by reducing the length of the dactyl or increasing the
distance from the dactyl pivot point to the point of chela closer muscle
attachment. In our study, the combined effects of relatively greater chela
depth and shorter dactyl length of males could support their greater chela
force than females. Similarly, our analysis of individual variation in chela
morphology with strength demonstrated that a decrease in dactyl and propodus
length and an increase in chela depth all improved strength.
Most studies of weapon displays suggest they are commonly reliable signals
of RHP (Maynard Smith and Harper,
2003). For example, the gaping displays of adult male collared
lizards (Crotaphytus collaris) provide a good example of an honest
and accurate index of weapon (bite) performance. Male collared lizards expose
the major jaw–adductor muscle complex to rivals
(Lappin et al., 2006), which
is correlated with the biting force of individual male collared lizards and is
a good predictor of the number of females within their home range and mating
success (Lappin and Husak,
2005). However, a few theoretical models
(Adams and Mesterton-Gibbons,
1995; Számadó,
2000) and empirical analyses
(Steger and Caldwell, 1983;
Backwell et al., 2000;
Wilson et al., 2007) indicate
that some degree of dishonesty can be supported within natural populations.
Newly moulted individuals of the stomatopod Gonodactylus bredini
continue to give threat displays to opponents, despite their soft cuticle that
impairs their fighting capacity (Steger
and Caldwell, 1983; Adams and
Caldwell, 1990). Interestingly, some of the most convincing
examples of unreliable signals of strength are from studies of weapons among
crustaceans (Steger and Caldwell,
1983; Backwell et al.,
2000; Wilson et al.,
2007). Although displays of chelae during agonistic encounters by
crustaceans are obvious examples of signals of weaponry, their exoskeleton
does not allow a direct visual assessment of the total muscle held, and thus
strength, within the chelae. This provides an ideal prerequisite for the
development of unreliable signals of strength and a possible mechanism for why
crustaceans may have a greater predisposition for unreliable signals of
weaponry.
The larger chelae of males were associated with decreased escape swimming
performance. These costs for possessing larger chelae for males were not
associated with chela strength and appeared to be directly related to the size
of the chela rather than the size of the internal muscle. This negative
correlation between swim speed and chela size does not necessarily mean a
causative link. It is also possible that other variables may contribute to
this pattern if they also covary with residual measures of chela size.
However, further evidence suggesting larger chela directly reduced escape swim
speed was the faster swim speeds of females than males, even though females
possessed slightly smaller overall body lengths. Across the size range
displayed by females, swim speed was unaffected by chela size. For crayfish
with small chelae for their given body size, there appeared to be no
difference in maximum swim speed between males and females. However, given
male swim speed decreased with increasing chela size, there was a large
disparity between the swim speeds of large chela males with all females.
Decreases in swimming speed that are associated with increased weapon size in
male C. dispar but unrelated to weapon strength suggest there may be
important fitness costs for growing larger chelae. The mechanisms underlying
this reduction in swim speed with larger chelae may be due to increased drag
coefficients during swimming or resource-based costs caused by the diversion
of energy away from the production of tail muscle to the chelae. The fitness
costs are presumably associated with a decreased capacity to escape predators
and an increase in overall energetic expenditure and can operate as a reliable
handicap signal of possessing larger chelae. However, this does not take into
consideration any possible compensatory changes in anti-predator behaviour
that may minimise any potential fitness costs. For example, juveniles of the
american lobster (Homarus americanus) possess chelae that are a
smaller proportion of the body mass than their large abdominal muscles and
they primarily rely on escape tailflicks when attacked by a predator
(Lang et al., 1977). By
contrast, adult H. americanus possess chelae that are a larger
proportion of their body mass than the abdominal muscles and they utilise a
raised claw threat display when confronted by predators
(Lang et al., 1977).
Although weapons are usually considered indices of RHP
(Maynard Smith and Harper,
2003), we found that weapon size of male C. dispar was
not always a good predictor of chela strength and is thus not an incorruptible
signal of performance. Furthermore, there were substantial locomotor costs
associated with the development of large chelae for male C. dispar,
suggesting the reliability of large chela size as a signal of quality may be
ensured via a handicap. We suggest signals in intraspecific
communication need not be exclusively classified as either indices or
handicaps. Instead, some weapons may function as a combination of both types
of signals that jointly ensure the reliability of indicators of individual
quality (Maynard Smith and Harper,
2003). Thus, increases in weapon size for C. dispar may
not only indicate an increased probability of greater weapon strength
(`index'), which may be corruptible to some degree but may also have negative
fitness consequences via a handicap. Combined signals of indices and
handicaps (and other alternatives) (see
Searcy and Nowicki, 2005), may
ensure the reliability of the quality of individual males producing the signal
during mate choice. We suggest the enlarged chelae of slender crayfish may act
as both indices and handicaps, which may also explain the greater propensity
for unreliable signals of strength among males of this species.
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Footnotes |
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