Eric E.
Flores1,
Martin
Stevens2,
Allen J.
Moore1,3,
Jonathan D.
Blount1,*
1Centre for
Ecology and Conservation, College
of Life & Environmental
Sciences, University of Exeter , Penryn ,
UK
2Department of
Zoology, University of Cambridge , Cambridge ,
UK
3Department of
Genetics, University of Georgia , Athens ,
GA , USA
Functional
Ecology Article first published online: 5 MAR 2013
DOI: 10.1111/1365-2435.12084
Summary
Many prey
species are chemically defended and have conspicuous appearance to deter
predators (i.e. aposematism). Such warning signals work because
predators pay attention to the colour and size of signals, which they associate
with unprofitability.
Paradoxically,
in early life stages, aposematic species are often warningly coloured, but
their chemical defences are lacking because they have yet to be acquired through the
diet or synthesized endogenously. This state of being conspicuous yet
poorly defended must place individuals at increased risk of predation, but how
they minimize this risk during development is unclear.
We reared
larval green and black poison frogs (Dendrobates auratus) on a relatively low
or a higher food supply and tested the hypothesis that individuals with more
resources should grow larger while reducing their investment in warning signals
at metamorphic completion. We also assayed markers of oxidative balance
(malondialdehyde, superoxide dismutase and total antioxidant capacity) to
ascertain whether there were resource-allocation trade-offs that differed with
diet treatments.
Low-food
froglets were relatively small, and their body size and signal luminance
(perceived brightness) were positively correlated. In contrast, in high-food
froglets body size and warning signal luminance were negatively correlated,
suggesting either a resource-allocation trade-off or alternatively a
facultative reduction in luminance exhibited by larger froglets.
The reduction
in luminance in relatively large, high-food froglets did not appear to arise
because of oxidative stress: signal luminance and markers of oxidative stress
were positively correlated in high-food froglets, but were negatively
correlated in low-food froglets suggesting a trade-off.
Our results
highlight developmental plasticity in body size and coloration as affected by
resource (i.e. food) supply. Such plasticity seems likely to minimize predation
risk during the vulnerable period early in life when individuals are warningly
coloured and must make the transition from an undefended phenotype to a mature
aposematic state.
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