Insect Colouration: A Defensive Adaptation (BIOL2306 Lecture)

Summary

This lecture explores insect coloration as a defensive adaptation. It investigates the mechanisms of crypsis, mimicry, and aposematism. The lecture also touches upon the principles of predator-prey interactions and coevolution.

Full Transcript

Case study:
Is insect colouration a
defensive adaptation?

Ecology & Evolution BIOL2306
Dr. Benoit Guénard
 Preys and Predators
Preys and predators have divergent
interests
- Prey: not being eaten by predator
- Predator: eat the prey

Unbalanced outcome - pressure on
prey much intense than on predator
Praying mantis feeding on a beetle
Why?

Life-dinner principle: A prey may loose its
life, while the predator may loose a meal
 Predator-prey coexistence
Data from
MacLulich 1937 Predators in nature usually remain in
'balance' with their prey and rarely
drive them to extinction, but can exert
a top-down control
Note also the importance of bottom-up
control
Both population-level mechanisms
From Ricklefs 2008. The Economy of Nature

Predator-prey coexistence result from defensive adaptations arising
from strong selective pressure on preys to improve their defences
 Terms and definitions
Tetraponera sp.
Protective adaptations: against hostile
physical & chemical factors in the
environment
e.g. dark colouration of this arboreal ant being
an adaptation against high UVB radiations
Polyrhachis sp.
Defensive adaptations: against attacks
by other organisms (usually predators)
Defensive
e.g. adaptations
spines present are very
on thorax diversebeing
and petiole (e.g.an
morphological,
adaptation againstchemical,
predatorsbehavioural…)
(birds, reptiles)
because each prey must defend itself against
@ Francois Brassard
a range of predators
 Evolutionary implications
In defensive adaptations, the agents shaping adaptations are of
biological nature (living organisms)
Biological factors stimulate mutual evolutionary responses in the
traits of interacting populations. In contrast, protective adaptations
do not trigger reciprocal effect on the environment

In defensive adaptations, biological agents foster diversity of
adaptations, rather than promoting similarity
In contrast, protective adaptations tend to lead to
Long legs
in desert convergence in response to similar physical
ants stresses in the environment
 Evolutionary implications
Coevolution: Sequence of evolutionary responses resulting directly
from the interaction between the two populations (e.g. prey and its
predator). Adaptations in one population (e.g. prey species)
promote the evolution of adaptations in the other (e.g. predator
species) – note coevolution is not specific to predator/prey
interactions
Coloration is an example of a trait
that can evolve in prey under
Chameleon
selection from predators, and
Katydid sometimes lead to coevolutionary
interactions
 The “defensive arsenal” of preys
Most species are both consumers (primary/secondary) and preys
Primary defences act regardless of whether predator is present or
the prey is aware of it
Either the predator does not distinguish the prey from its
background (crypsis in cryptic insects) or the prey is detected but
not recognized as edible food (mimicry in mimetic insects)
Crypsis & mimicry = primary defences Biston robustum presents
both visual and chemical
mimicry
Crypsis and mimicry can be visual,
audio, thermic or chemical in function of
cues used by the predator for detection
 Cryptic insects

Cryptic predators
 The “defensive arsenal” of preys
Secondary defences are used when prey is detected and identified
as potential food by predator - when primary defences failed – and
can take different forms:
- Escape behaviour (e.g. run, flight)
- Chemical release or injection (e.g. sting)
- Mechanical defences (e.g. bites, kick) Bombardier beetle
Wasp

Stick insect
 Aposematic insects
Species with good secondary defences (e.g. chemical
defences) and which advertise them with bright
colours or patterns – colour is the primary defence:
warning colouration = aposematism
Aposematic: appearance that warns
off enemies because it denotes
something unpleasant or dangerous
Predators learn to avoid them or in some cases have
evolved innate aversion
But, production of chemicals or their absorption
from plants is energetically costly
Aposematic insects: Monarch butterfly
Toxic as larva (caterpillar) and adult
due to secondary compounds
(cardenolides) ingested and stored from
milkweed (Asclepias genus) during
larval stage

Higher concentrations
of cardenolides
decrease performance
in adults (e.g. decrease
migration success)
Danaus plexippus
Aposematic insects Dasymutilla asteria

Contrast of a prey's
colours against a
background
Limacodidae
Opposite of crypsis

Aposematic display Dasymutilla gloriosa
often associated
with other sensory
modality: sound,
smell, tastes or
texture -
Harmonia axyridis Reinforce the signal
 What is the evidence for survival value of
crypsis?

Initially, some observational data were compiled: direct
observations and analysis of gut contents (for vertebrates)

Controversial due to lack of standardization and lack of data on
relative abundance of cryptic vs. non-cryptic insects

Need for testing hypotheses about the adaptive value of insect
defences. E.g. Are cryptic insects eaten less often than non-cryptic
insects?
Need for experiments
 Industrial melanism
Peppered moth: Biston betularia
typica morph: only form reported by 1850
carbonaria morph reported after 1850 in
areas near industries (heavy pollution) typica morph

Non-polluted areas Polluted areas

carbonaria morph

See Brakefield 2009 book chapter
 Industrial melanism
Polluted Unpolluted
Released of marked typica and carbonaria
morphs in woods near Birmingham (polluted)

carbonaria

typica
typica carbonaria
typica
Local population frequencies
carbonaria

Bird predation experiment in polluted &
unpolluted areas (same number of individuals)
Recapture frequencies

Kettlewell 1955, 1956, 1973
 Other experiments on crypsis
Stick insect: Timema cristinae. Polyrmorphic
herbivorous insect
On plants,
predation of grey
morph is higher
On the ground,
predation of green
morph is higher
Green morph more cryptic on foliage
Predation by lizard in function Grey morph more cryptic on ground
of background substrate Sandoval 1994
 Limitations of crypsis
Need to select the proper
background / habitat
- Conspicuous on wrong
background
Constrains the insect to a sedentary life
style at least during daylight / limit habitats
exploitable
Need for secondary defences when primary
defences fail or when not efficient against
particular predators (e.g. using non-visual
cues)
 Evolution and
maintenance of
aposematism

https://www.nickybay.com/page/2/
 Defensive benefits of aposematism
Predators must learn characteristics of aposemete (i.e. association
of colours with 'unpleasantness' & learn to avoid aposemete)
Important for aposemetes to not be
killed or injured during learning
process: e.g. hard cuticule, stinger,
reflex bleeding, early predator
detection
Complete avoidance is not necessary for aposematism to work;
aposematism merely has to provide lower mortality than crypsis
for the warning signal to be beneficial
 Survival value of aposematism
Warning signals need to be easy to detect, discriminate and
memorize by the predators
Survival value of
aposematism may depend on
predators’ ability to learn
(vertebrates only?)
Innate avoidance of bright colours by some vertebrates
Aposematic colours increase the speed and durability of avoidance
learning, elicit avoidance in naive predators, and the probability of
recognition in already experienced predators
 Survival value of aposematism
Heliconius erato
Manipulative experiment:
Altering the colour pattern of the forewing
Control: add black paint on the forewing
without altering the red pattern. Why?
Treatment
Average survival of altered (black wings) Control
individuals was decreased by 40% (31.7 vs.
52.4 days)
Frequency of major damages observed on
altered individuals much higher
 Limitations of aposematism
Risk of death (or injury) during the predators’ learning period
defence can never be 100% effective
Aposematism is more likely to evolve in species that are abundant:
this reduces the per capita risk of an individual of being sacrificed
to inexperienced predators

It is more advantageous to be cryptic if rare (i.e. population density
is low), or if predators have poor memory (or can't learn)

But there are other possibilities…
 Forms of Mimicry
Mimicry: resemblance of one species of insect/animal (the mimic)
to another (the model) so that a third species (the predator) is
deceived by the similarity & confuses the two (mimic & model)
Chrysomelidae Prosoplecta sp.

Beetle – the model Cockroach- the mimic
@ Gernot Kunz

Müllerian mimicry
Batesian mimicry Peckhamian mimicry for some
myrmecomorph spiders
Müllerian mimicry
Among aposemetes with similar warning
colouration (i.e. have same ‘signal’) – all
species are unpalatable

Can engage hundreds of species across
vast regions, e.g. Velvet ants (which are
wasps of the Mutillidae family)

Thus each species individually does not
have to be abundant to wear aposematic
coloration
 Batesian mimicry
A palatable species -the mimic- gains a degree of protection from
predators by resembling an unpalatable species - the model

Non palatable species

Palatable species

Timmermans et al. 2014, Proc B
Condylodera tricondyloides
Grasshopper (mimic)

Tigger Beetle
Cicindelinae (model)

Amazing case of a Batesian
mimicry between tiger beetles
(model) and a grasshopper
(mimic)
 Batesian mimicry in Hong
Kong

Butterflies
Ants (model) and jumping spiders
(mimics – Salticidae)
Mimic
(shape and
behaviour)

Model
 Survival value of Batesian mimicry
1) Give live bumblebees to naïve toad
Then give robber flies (Asilidae) to trained
toad (experimental treatment)

Predator

Model Mimic
Brower et al. 1960. The American Naturalist
 Survival value of Batesian mimicry
1) Give live bumblebees to naïve toad.
Then give robber flies (Asilidae) to trained
toad (experimental treatment)
2) Give dead bumblebees with stinger
Predator removed to naïve toad. Then give robber flies
(Asilidae) to toad (control treatment)

Model Mimic
Brower et al. 1960. The American Naturalist
 Limitations of Batesian mimicry
Batesian mimics generally require the presence of the model to
gain significant protection

The relative abundances of models and mimics influence the mean
rates of predation on these types. Experiments shown that as the
ratio models/mimics increases then the attack rates on both models
and mimics on encounter with predators tends to decrease
The mimic species must not become too common relative to the
model, then the predators will learn of their presence and tend to
increase their attacks
But there is a solution for the mimic to increase in abundance…
Batesian mimicry promotes polymorphism
Mimic species will use multiple models for mimicry – thus
generating polymorphism within the same species

Batesian mimics often
have several morphs (=
colour forms) in one sex
(sometimes both sexes)
within the same species
mimicking different
species of aposematic
models
Timmermans et al. 2014, Proc B
So is colouration all about predator defence?
Not only. Colouration is also selected by other factors
- Intraspecific sexual communication (e.g. spiders)
- Social interactions facilitation (e.g. wasps)
- Thermoregulation
- UV protection (e.g. melanism)
- Parasite defence

These different selection pressures can
show convergent or divergent directions

For some species (nocturnal/ subterranean/ troglodytic) the role of
colouration can be minimal (no light to reflect colours)
 References
Benson W. 1972. Natural selection for Müllerian mimicry in Heliconius erato
in Costa Rica. Science 176: 936 939
Brower & Glazier 1975. Localization of Heart Poisons in the Monarch
Butterfly. Science 188: 19–25.
Ruxton G. 2009. Non-visual crypsis: a review of the empirical evidence for
camouflage to senses other than vision. Phil. Trans. R. Soc. B 364, 549–557.
Ruxton G. D., W. L. Allen, T. N. Sherratt, and M. P. Speed. 2018. Avoiding attack: the
evolutionary ecology of crypsis, aposematism, and mimicry, 2nd edition. Oxford University
Press, 277 pages. First edition available online through the library
Sandoval C. 1994. Differential visual predation on morphs of Timema cristinae
(Phasmatodeae: Timemidae) and its consequences for host range. Biological Journal of the
Linnean Society 52: 341–356.
Wilson J. et al. 2015. North American velvet ants form one of the world’s largest known
Müllerian mimicry complexes. Current Biology 25: 704–706.