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First published online May 26, 2006
Journal of Experimental Biology 209, 2368-2376 (2006)
Published by The Company of Biologists 2006
doi: 10.1242/jeb.02183
Review Article: Phenotypic Plasticity in Evolution |
Phenotypic plasticity, sexual selection and the evolution of colour patterns
Department of Ecology and Evolution, University of Chicago, Chicago, IL 60637, USA
e-mail: pricet{at}uchicago.edu
Accepted 21 February 2006
Summary
When a population comes to occupy a new environment, phenotypically plastic responses alter the distribution of phenotypes, and hence affect both the direction and the intensity of selection. Rates of evolution can be accelerated or retarded compared to what would happen in the absence of plasticity. Plastic responses in one trait result in novel selection pressures on other traits, and this can lead to evolution in completely different directions than predicted in the absence of plasticity. In this paper I use the concept of the adaptive surface in order to identify conditions under which the various different outcomes are expected. I then discuss differences between sexually and naturally selected traits. Sexually selected traits are often expected to be plastic in their expression, with individuals in high condition developing greater elaboration. As examples of sexually selected traits I review the evolution of colour patterns in birds with a view to assessing the magnitude of plastic responses in their development, and to ask how such responses may have influenced genetic evolution. The common colour pigments in birds are carotenoids and melanins. Both are used in social signaling, and consequently are expected to evolve to be phenotypically plastic indicators of an individual's quality. Perhaps partly because they are condition indicators, the quantity of carotenoids in the plumage can be strongly influenced by diet. Examples are described where alterations of carotenoids in the diet are thought to have altered the phenotype, driving genetic evolution in novel directions. Melanin patterns seem to be less affected by diet, but the intensity of melanization after moult is affected by social interactions during the moult and by raising birds in humid conditions. Hormonal manipulations can have dramatic effects on both the kinds of melanin produced (eumelanin or phaeomelanin) as well as the patterns they form. Differences between species in melanin patterns resemble differences produced by environmental manipulations, as well as those produced by simple modulations of parameters in computer simulations of pattern formation. While phenotypic plasticity is one way that genetic change in plumage patterns (and other traits) could be driven, there are others, including the appearance of major mutations and selection on standing variation whose distribution is not altered in the new environment. I consider some evidence for the different alternatives, and ask when they might lead to qualitatively different evolutionary outcomes.
Key words: carotenoid, colour pattern, melanin, plasticity, sexual selection
Introduction
Phenotypic plasticity is defined as an organism's ability to express
different phenotypes depending on its environment
(Agrawal, 2001
;
Garland, Jr and Kelly, 2006).
It may take the form of a flexible behaviour that changes over a few seconds
or a developmental switch that permanently affects the adult form. Phenotypic
plasticity has two potential roles to play in driving genetic changes. First,
once a population becomes established in a new environment, plasticity may be
essential for that population to survive and persist
(Baldwin, 1896;
Morgan, 1896;
Robinson and Dukas, 1999).
Second, the plastic response itself also sets the context whereby selection
pressures drive evolution (Pigliucci and
Murren, 2003; Price et al.,
2003; West-Eberhard,
2003). For example, a population of sharp-beaked ground finches
Geospiza difficilis in the Galápagos feed extensively on blood
from boobies, and this population has a particularly sharp bill
(Schluter and Grant, 1984).
The interpretation is that behavioural change – blood feeding –
has precipitated novel selection pressures favoring increased efficiency on
this resource, resulting in evolution of beak shape.
Sexually selected traits are theoretically expected to be phenotypically
plastic indicators of an individual's condition or quality (e.g.
Nur and Hasson, 1984;
Grafen, 1990;
Qvarnström and Price,
2001). This is because advertising at high levels reaps higher
benefits in terms of high mating success, but only those individuals in good
condition are able to bear the costs of carrying an exaggerated version of the
trait. Similar principles apply to traits used in other social contexts, for
example in threat displays (Hurd and
Enquist, 2001) or mate stimulation after pair formation
(Wachtmeister, 2001). The way
by which such plasticity might influence evolution of socially selected traits
does not seem to have been widely discussed
(West-Eberhard, 2003). In this
paper I investigate the role of phenotypic plasticity in affecting the
expression of colour patterns in birds, and consider examples where plastic
responses may have been evolved in affecting directions of genetic evolution.
The paper is in two parts. (1) I review the general mechanism whereby
plasticity influences genetic evolution. (2) I ask how plasticity and novel
selection pressures interact to drive the evolution of colour patterns in
birds.
Genetic differentiation
Probably the most important way by which plastic traits become genetically
based lies in the process known as genetic assimilation
(Waddington, 1953;
Waddington, 1959;
Waddington, 1961;
Waddington, 1965;
Pigliucci and Murren, 2003;
Price et al., 2003). In this
case the plastic response to the new environment is incomplete. There is
therefore directional selection favouring extreme phenotypes in the novel
environment and hence some genetic evolution of the trait (e.g.
Waddington, 1959). Plasticity
may be reduced as part of the selection regime, but this is not part of
genetic assimilation as it was originally defined [e.g.
(Waddington, 1961), p. 289].
For example, in one experiment
(Waddington, 1959), Waddington
investigated the magnitude of a phenotypically plastic response to altered
salt conditions in larvae of Drosophila melanogaster (described in
Price et al., 2003). When
Waddington raised a population in high salt he found that the area between the
anal papillae increased. After maintaining the population in high salt for
20 generations, he found the area between the anal papillae in normal
salt was similar to the phenotypic response to high salt at the beginning of
the experiment. The trait had been genetically assimilated, but plasticity was
not reduced, because when the pupae were raised in high salt conditions the
area was reduced still further.
Genetic assimilation is one of a number of ways whereby evolution in
response to selection is precipitated by phenotypically plastic changes
(West-Eberhard, 2003). These
alternatives have been extensively reviewed by West-Eberhard, who classes them
all in the term `genetic accommodation'
(West-Eberhard, 2003). A
particularly important additional class is when plastic responses in one
trait, e.g. a foraging behavior, lead to genetic changes in other traits, e.g.
morphology. A second way arises if phenotypically plastic changes produce
maladaptive responses, resulting in genetic evolution that restores the mean
phenotype (Grether, 2005).
Grether labels this process `genetic compensation'
(Grether, 2005), and in this
case geographic uniformity in phenotype masks underlying geographical
variation in genotype.
A simple way to model genetic accommodation is via the adaptive
surface (Price et al., 2003).
The concept of the adaptive surface was introduced by Sewall Wright to model
changes in gene frequencies (e.g. Wright,
1959). It was extended to phenotypic evolution in a verbal model
(Simpson, 1953), and this
model was subsequently mathematically addressed using quantitative genetic
theory (Lande, 1976). Suppose
each individual in a population is measured for a trait of interest, e.g. its
colour, and each individual is also assigned a fitness value (e.g. the number
of young it produces over its lifetime). The adaptive surface is a plot of how
the average fitness of all the individuals in the population would change as a
function of the average value of the trait, provided the variability in the
population is held constant (Lande,
1976; Fear and Price,
1998) (an example is in Fig.
1). In theoretical work, the main purpose of the adaptive surface
is to model directions and rates of evolution. Given several critical
assumptions (Wright, 1959;
Lande, 1976;
Fear and Price, 1998), the
average value of a trait evolves to a position determined by a peak in the
adaptive surface, and then remains there. Because the population may become
stuck at a low peak, a central question in evolutionary theory has been how
valleys in the adaptive surface are crossed
(Wright, 1959;
Coyne et al., 1997;
Fear and Price, 1998).
Phenotypic plasticity is one method of crossing valleys.
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The adaptive surface model can be used to illustrate when alternative
outcomes such as genetic assimilation and genetic compensation are to be
expected (Fig. 1). If in a new
environment plasticity is small, a population remains stuck near the original
peak. In this case selection results in evolution back towards the original
peak (genetic compensation). The ancestral and derived populations have
similar phenotypes, but the derived population evolves a different mean
genotype to compensate for the plastic response, and differences should be
revealed if populations are raised in a common environment. If plasticity is
very large the population may move to the other peak, but here there will be
no genetic change, because the population is already close to the optimal
value. The absence of genetic response in the presence of much plasticity has
been labeled the `Bogart effect' and is discussed further elsewhere
(Huey et al., 2003). An
intermediate level of plasticity places a population on the other side of the
valley, and results in selection for increased efficiency, hence genetic
assimilation.
Price et al. studied these alternative outcomes using computer simulations
(Price et al., 2003). If
environments fluctuate randomly through time there is a threshold value of
plasticity that is optimal for the maximal amount of genetic change. A run of
extreme environments results in the population being held just across the
valley for a series of generations. Each generation there is selection and
evolution towards the higher peak. Then, even if there is a run in more mild
environments, a reduction in the plastic response is insufficient for the
population to come back into the realm of the lower peak, and evolution
towards the higher peak continues.
There are several other ways by which populations can traverse adaptive
surfaces (Wright, 1959;
Coyne et al., 1997;
Fear and Price, 1998). Two of
the most common are likely to be environmental variation in both space and
time that changes the form of the surface itself, and major mutations that
bring a population into the realm of attraction of another peak
(Fear and Price, 1998). Often
the adaptive surface is likely to be complex, with many peaks and valleys. In
this case phenotypic plasticity may result in exploration of the adaptive
surface that results in adaptive change not realized through these alternative
ways, such as when new behaviors result in genetic evolution of other traits.
One example might be the way by which the woodpecker-niche in birds has been
occupied. Although woodpeckers (family Picidae) themselves occupy this niche
in most places of the world they have not colonized remote areas, and in their
absence other species have evolved mechanisms to exploit grubs in trees. In
the Galápagos islands, the woodpecker finch, Camarhynchus
pallidus, uses a twig to extract grubs from crevices, whereas in the
extinct New Zealand Huai, Heteralocha acutirostris, males and females
had very different beaks, one for probing and one for mandibulating prey [on
Madagascar and New Guinea, mammals, the aye aye Daubentonia
madagascariensis and a marsupial Dactylopsila palapator,
respectively, have elongated digits used for extracting grubs
(Soligo, 2005)]. Such unusual
mechanisms are most likely to have been driven, at least in part, by
behavioural changes, and it seems less likely that major mutation or different
selection regimes driven by unusual environments were the primary factors
behind these unusual solutions to extracting grubs.
Sexually selected traits
The peak shift model is most suited to model the evolution of naturally
selected traits. This is for at least two reasons. First, sexually selected
traits are subject to frequency dependent selection. The absolute level of
advertising is likely to be less important than the level relative to other
individuals displaying in the population. For example, under sexual selection,
provided all females mate, the average mating success (i.e. mean fitness) of a
male never changes. This means that the adaptive surface describing the
relationship between average mating success and the mean value of the male
trait is flat, with no peaks and valleys. Thus, with frequency dependence,
formal models of peak shifts become imprecise or cannot be used at all.
Nevertheless the adaptive surface is still a useful heuristic concept: when
there is frequency dependence, Wright described a surface depicting different
optimal values and sketches of evolutionary trajectories towards these optima
as a `selective surface' (Wright,
1959). A second reason why sexual selection may be less well
modeled by the adaptive surface than natural selection is because many
examples of sexual selection indicate that extreme values are often the most
attractive (bigger, brighter, louder)
(Ryan and Keddy-Hector, 1992;
Price, 1998). At first sight
this implies that there are no true peaks in the surface, and all optima lie
at infinity. However, when naturally selected costs are included there should
be intermediate optima (e.g. being bigger, brighter or louder attracts
predators) and there may well be a great diversity of different optima.
Different environments impose different costs and as well as benefits
(Endler, 1992;
Schluter and Price, 1993;
Slabbekoorn and Smith, 2002),
and even in the same environment there are likely to be multiple solutions to
the same problem. For example, two closely related species of warbler
occupying very similar habitats sing songs of similar length and complexity,
but different structure (Irwin,
2000).
It appears that the concept of the adaptive surface can be applied, at least for hueristic purposes, to the evolution of sexually selected traits. Few studies have explicitly investigated the importance of plasticity in driving the evolution of sexually selected traits from one peak to another on such a surface, but there are many studies that can be used to assess the plausibility of the process. Here I review studies on the evolution and plasticity of colour patterns, primarily of birds.
Diet, social behaviours and pigmentation
Many experimental and correlative studies have demonstrated the importance
in social interactions of plumage patterns in birds
(Rohwer, 1982;
Andersson, 1994;
Jawor and Breitwisch, 2003).
Unlike the other main socially selected trait in birds, vocalizations, colour
patterns have clearly identifiable environmental and genetic bases. The size
and brightness of a colour patch is often correlated with the condition and/or
social status of the individual (Rohwer,
1982; Andersson,
1994; Johnstone,
1995; Pryke et al.,
2002; Alonso-Alvarez et al.,
2004). I focus on two major classes of pigment in birds,
carotenoids and melanins, and consider some examples where these effects have
contributed to population divergence.
Carotenoids
Different kinds of carotenoids are responsible for most of the red, orange
and yellow colours in birds (Brush,
1990). They may also cause the occasional blue and violet
(Völker, 1953), but this
needs to be confirmed with modern analyses.
Carotenoid coloration is phenotypically plastic. Carotenoid-free diets
result in very little colour in normally pigmented species, such as the house
finch, Carpodacus mexicanus (reviewed by
Hill, 1994a;
Hill, 2002;
Hudon, 1994) and great tit
Parus major (see Figs
2,
3). Canaries are fed cayenne
pepper and other additives to improve their feather colouration
(Vriends, 1992). Manipulation
of carotenoids also affects the colour of pigmented bare parts, such as the
beak of the zebra finch, Taeniopygia guttata
(McGraw and Ardia, 2003;
Alonso-Alvarez et al., 2004).
In natural populations, quantitative differences in carotenoid concentrations
in different localities have been related to the presence of specific food
plants (Ryan et al., 1994;
Slagsvold and Lifjeld, 1985).
In the great tit the carotenoid-based yellow in the breast plumage has been
demonstrated to be a result of phenotypic plasticity via a
cross-fostering experiment, and related to the quantity of caterpillars in the
diet (Fig. 3)
(Slagsvold and Lifjeld, 1985).
In this species, nestling coloration is strongly affected by food provisioning
in the first few days of nestling development
(Fitze et al., 2003;
Tschirren et al., 2003). In
the related blue tit Parus caeruleus, provisioning of mothers with
extra carotenoids resulted in brighter yellow plumage of their offspring
(Biard et al., 2005).
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The presence of carotenoids in the diet and their deposition in the plumage
has led to genetic evolution. Thus, in many species carotenoids are modified
biochemically after ingestion, including modifications that change yellow
pigments to red (Brush, 1990;
McGraw et al., 2004). Breeding
experiments and analysis of hybrids have demonstrated genetic differences
among species and populations in the quantity, colour and location of
carotenoids deposited in the plumage (reviewed by
Brush, 1990). For example, two
closely related species of tanagers differ in having red or yellow rumps, and
the hybrid is intermediate. In this case colour differences result from
differences in the quantity (not type) of a single carotenoid, lutein,
deposited in the feathers (Brush,
1990). In many species, genetically determined colour in the
plumage may have originally resulted from ingestion of carotenoids, followed
by genetic evolution. In doves, the only species containing carotenoid
pigments in their plumage are those that are frugivorous: carotenoid
pigmentation has independently evolved three times in association with
frugivory, but never appears in granivores
(Mahler et al., 2003). This
result is general: across species, availability of carotenoids in the diet is
associated with the presence of carotenoids in the plumage; however, such an
association has not been detected with respect to coloured bare parts (e.g.
beaks, wattles, etc) (Olson and Owens,
2005).
Three examples of sexually selected carotenoid coloration have been
reviewed (Grether, 2005),
where some aspects of the colour (e.g. the brightness) are geographically
rather invariant, even though the quantity or type of carotenoid available is
geographically variable. Two are from different fish species, salmon
Oncorhynchus nerka and guppy Poecilia reticulata, and one
from a bird, the western tanager Piranga ludoviciana. The invariance
is attributed to genetic compensation, and in the two fish examples, fish from
geographically different locations were raised on common diets, clearly
revealing underlying genetic differences despite phenotypic similarity.
A final example of genetic evolution comes from Hill's work on the size of
the red breast patch of the male house finch
(Hill, 1993;
Hill, 1994b;
Hill, 2002). Subspecies from
Mexico and Michigan have similar patch colours, but the Mexican subspecies has
a smaller patch (Fig. 4). Using
morphological and biogeographical evidence, Hill estimated phylogenetic
relationships among the subspecies (Hill,
1994b; Hill,
2002), and concluded that the Mexican subspecies was the derived
one (however, the direction of evolution is not critical for the argument).
Hill found that carotenoid manipulated diets prior to moult affected patch
colour of both subspecies, but the size of the patches was not affected
(Fig. 2)
(Hill, 1993;
Hill, 1994b). A hybrid between
the two had an intermediate patch size, suggesting that size is genetically
determined. Colour is a sexually selected trait and females from both
populations prefer small red patches over large drab ones
(Hill, 1994b). In the Mexican
population Hill argues that a carotenoid deficient diet would have initially
led to large drab patches (Hill,
1994b). Subsequently there was sexual selection favoring the
sequestering of carotenoids over a smaller area of feathers, thereby
increasing its brightness. In this way the patch evolves to a smaller size as
a consequence of a direct environmental influence on the development of patch
colour. The adaptive surface is illustrated in
Fig. 5.
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). Hill brings
several lines of circumstantial evidence that this is indeed the case
[(Hill, 2002), chapter 11],
including the finding of lower carotenoid concentrations in the diet of the
Mexican population, as determined from gut contents.
Melanins
Melanins are the other major pigment in bird plumage, and are responsible
for blacks, browns, many reds and occasional greens and yellows
(Brush, 1978;
Jawor and Breitwisch, 2003).
Melanin pigments are formed very differently from carotenoids, being
synthesized from the amino acid tyrosine as precursor. Dietary differences can
affect the amount of melanin deposited
(Sage, 1962), but the effects
are not as striking as they are with respect to carotenoids.
Many species show geographical variation in melanin pigmentation. According
to `Gloger's rule', darker birds live in more humid environments; e.g. darker
birds live in the Pacific north-west, and lighter ones in the Arizona deserts
(Zink and Remsen, 1986). The
rule is extremely strongly supported: in a survey of North American birds the
association was found in 50/52 cases (Zink
and Remsen, 1986). Underlying causes are poorly understood, but
camouflage is the usual explanation (Zink
and Remsen, 1986). Although the general intensity of pigmentation
may be driven by naturally selected pressures, melanin patterns are widely
used in social interactions. For example, painting experiments manipulating
the size of many melanin-based patches have affected male dominance
(Rohwer, 1982;
Senar and Camerino, 1998;
Jawor and Breitwisch,
2003).
Wood thrushes Catharus mustelinus, white-throated sparrows
Zonotrichia albicollis and Inca doves Columbina inca were
raised in extremely humid conditions indoors
(Beebe, 1907), and after moult
they all became much darker. In the white-throated sparrow the increase in
melanin was associated with the appearance of a dark breast spot; such a spot
is present in juveniles of this species, as well as in adults of the closely
related American tree sparrow, Spizella arborea. After six moults,
one Inca dove had become almost entirely black. Of particular interest was the
development of a metallic sheen on the upperparts of this bird: such a sheen
is present in the closely related scaled dove, Columbina squammata.
Beebe also demonstrated changes in the size of pigmented patches in the tail
and wing feathers of the Inca doves that matched and in later moults exceeded
geographical variation.
Melanins are synthesized in specialized cells, melanocytes, and then
transferred to growing feather cells. The interaction between the melanocyte
and growing feather can result in a rich variety of alternative patterns, as
has been demonstrated by introducing melanocytes from different breeds of
chickens into the feather ectoderm of other breeds
(Rawles, 1948). Such patterns
can be easily altered experimentally. Particularly striking examples are shown
in Fig. 6. In these examples
injection of thyroxin (Lillie,
1932) or removal of the thyroid gland
(Voitkevich, 1966) resulted in
novel patterns. The modulations may result from effects on either the
melanocyte or the feather, including growth rates, and can be mimicked by
altering these parameters in computer simulations
(Prum and Williamson, 2002)
(see Fig. 6).
|
). The male house
sparrow Passer domesticus has a large melanin-based breast patch.
Individuals injected with testosterone develop larger patches after moult
(Evans et al., 2000). McGraw
et al. maintained 14 triads of three male house sparrows each in captivity
through the Autumn moult, and recorded the number of aggressive interactions
the sparrows engaged in (McGraw et al.,
2003). They found that triads engaging in more interactions
amongst themselves on average grew larger black patches, and suggested a
direct causal link between aggressive interactions, which lead to elevated
testosterone levels, and the subsequent increased patch size
(McGraw et al., 2003). There
are many other examples where an individual's condition and/or dominance
status is correlated with the size of melanin patches
(Jawor and Breitwisch,
2003).
Thus, it seems possible that the establishment of genetically based
geographical variation and species differences in melanin patterns could be
aided through environmental effects on both melanin intensity and pattern.
However, genetic accommodation requires that plasticity affects many
individuals, across several generations, so that selection can sort among them
(Price et al., 2003). Many
environmental variants in melanin patterns of large effect in nature seem to
be confined to a single individual and disappear with that individual. Often,
they are haphazard, asymmetrically placed patches of pigmented or unpigmented
plumage that do not resemble differences seen between species
(Sage, 1962). There are
examples of more symmetrical patches as well as completely melanistic and
albinistic individuals, but these often seem to be a result of genetic
mutations of large effect, some of which may occasionally rise to high
frequency (Sage, 1962).
In several carefully studied examples of melanism a single mutation of
large effect has clearly driven divergence between populations
(Mundy, 2005). Among
bananaquit Coereba flaveola populations on the West Indies, an
all-black form inhabits the humid highlands of two islands (Grenada and St
Vincent). In the lowlands on each island the melanic type is replaced by the
typical form. The gene responsible for the melanism has been identified and
sequenced (Theron et al.,
2001). The difference between the two forms appears to be due to a
mutation at a single base position, so in this case differentiation is best
attributed to a major mutation, and plasticity is unlikely to have played much
of a role. It is worth noting, however, that in other cases of melanism
invoking the MC1R gene, multiple base substitutions do seem to be involved
(Mundy, 2005). This points to
more continuous variation, and environmental effects could presumably have
greater influence on this variation.
Discussion
Sexually selected traits are theoretically expected to be phenotypically plastic indicators of condition. Given that sexually selected traits are phenotypically plastic, this plasticity must affect rates and directions of evolution. In this discussion I ask whether such plasticity causes evolution in directions that would not otherwise be reached by other modes of evolution (specifically, selection in response to changing environments, or in response to the appearance of a major mutation).
Foraging behaviours are probably the best example whereby plasticity
triggers new directions of evolution, which are unlikely to be achieved in
other ways (Price et al.,
2003). There are at least three differences between colour
patterns and foraging behaviours that make directions of evolution in
colouration likely to be less strongly influenced by plasticity. First,
whereas novel foraging behaviours likely affect survival and persistence of
populations in novel environments (Sol et
al., 2005), sexually selected traits by the nature of their strong
frequency dependence are likely to have much weaker influences on population
survival. For example, it has been generally difficult to detect an effect of
plumage dichromatism in birds on extinction
(Morrow and Pitcher, 2003). A
number of studies did find that plumage dichromatism reduced the probability
of that species becoming established in new locations following introductions
by humans (McLain et al.,
1999; Bessa-Gomes et al.,
2003). However, the most recent analyses based on a large dataset,
and controlling for introduction effort, did not find such an association.
Instead, measures of foraging flexibility were found to be the only important
variables affecting introduction success
(Cassey et al., 2004;
Sol et al., 2005).
The second difference between color patterns and foraging behaviors is that
it seems likely that genetic variation underlying development of form
(including colour patterns) lies along roughly the same axis as phenotypically
induced environmental variation. More generally, phenocopies, whereby
environmental perturbations mimic genetic mutations, are a common feature of
development, attributed to the fact that genetic and environmental influences
affect similar developmental processes (Zuckerkandl and Villet, 1998;
West-Eberhard, 2003). An
example is that the colour of the European great tit raised in captivity (e.g.
Fig. 3) resembles that of the
great tit from India (Gompertz,
1968). This means that although plasticity affects rate of
evolution it will have less effect on directions of evolution. Finally, major
mutations affecting color that differentiate species have been discovered
(Price, 2002). In particular
the MC1R gene affects both intensity and pattern of melanization in a number
of groups. Melanism itself can be produced by a single point mutation
(Mundy, 2005), suggesting that
in this case at least, mutation was the driving force behind the origin of the
melanic plumage.
In a specific example of the evolution of melanin-based patterns, Yeh
studied a tail pattern in the dark-eyed junco Junco hyenalis
determined by the presence/absence of melanin in patches of the outer tail
feathers (Yeh, 2004). She
studied different populations that had been separated for only about ten
generations, but one population (occupying a novel environment) had 20% less
white in the tail than the other. She raised juveniles from an early age in
outdoor aviaries and found that the differences in the amount of white in the
tail were retained through successive moults. The change therefore appears to
have been a result of genetic evolution, and there is little evidence that
plasticity in the amount of white in the tail has played any role in the
evolution of mean levels of white. However, plasticity in behavioural traits,
including number of clutches laid in the season
(Yeh and Price, 2004) and
territorial responses to song playback
(Newman et al., 2006), have
likely generated novel selection pressures on the tail pattern (P. J. Yeh and
T.D.P., unpublished observations). Thus in this study plasticity in
behavioural traits is invoked as being an important cause of the reduction in
tail pattern, by influencing directions and intensity of selection.
Although phenotypic plasticity must play a critical role in some cases of population differentiation, natural and sexual selection will also operate in the absence of any plastic responses. This makes it difficult to ascribe a definite role to plasticity in any particular case, even striking examples such as the tool-using behaviour of the woodpecker finch. In the case of colour patterns, the large influence of diet on carotenoids implies that entry into a novel environment should cause simultaneous developmental changes in many individuals, implying that plasticity likely plays some role in driving further genetic differentiation. Such influences of diet are not so apparent for melanin patterns, and environmental perturbations that produce large changes may perhaps be confined to single individuals and die out with them. Here genetic mutations that produce similar phenotypes may play a more direct role in generating population differentiation.
Acknowledgments
I thank G. Hill for discussion, an anonymous reviewer and Ted Garland for comments on the manuscript.
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