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14
A Role for Relaxed Selection
in the Evolution of
the Language Capacity
TerrenCe W. DeACon
explaining the extravagant complexity of the human language and our
competence to acquire it has long posed challenges for natural selec-
tion theory. To answer his critics, Darwin turned to sexual selection to
account for the extreme development of language. Many contemporary
evolutionary theorists have invoked incredibly lucky mutation or some
variant of the assimilation of acquired behaviors to innate predispositions
in an effort to explain it. recent evodevo approaches have identified
developmental processes that help to explain how complex functional
synergies can evolve by Darwinian means. interestingly, many of these
developmental mechanisms bear a resemblance to aspects of Darwin’s
mechanism of natural selection, often differing only in one respect (e.g.,
form of duplication, kind of variation, competition/cooperation). A com -
mon feature is an interplay between processes of stabilizing selection and
processes of relaxed selection at different levels of organism function.
These may play important roles in the many levels of evolutionary pro-
cess contributing to language. surprisingly, the relaxation of selection at
the organism level may have been a source of many complex synergistic
features of the human language capacity, and may help explain why so
much language information is “inherited” socially.
Department of Anthropology, University of California, Berkeley, CA 94720. e-mail: deacon@
berkeley.edu.
���
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L
anguage is both a social and biological phenomenon. The capacity
to acquire and use it is a unique and distinctive trait that evolved
in only one species on earth. its complexity and organization are
like nothing else in biology, and yet it is also unlike any intentionally
designed social convention. short of appealing to divine intervention or
miraculous accident, we must look to some variant of natural selection
to explain it. By paying attention to the way Darwin’s concept of natural
selection can be generalized to other systems, and how variants on this
process operate at different interdependent levels of organism function,
explaining the complexity of language and the language adaptation can
be made more tractable.
Darwin’s theory of natural selection is based on three widely acceptable
characteristics of organism reproduction. in the early winter of 1838, after
reading Thomas Malthus’ “essay on Population,” Charles Darwin wrote
the following lines in his e notebook: “Three principles will account for
all: (1) Grandchildren like grandfathers; (2) Tendency to small change . . .
especially with physical change; (3) Great fertility in proportion to support
of parents” (Darwin, 1838, p. 58).
in the most general terms, these correspond to duplication-multiplication,
spontaneous variation from the original, and the surfeit of reproduction
that will inevitably reduce this variety via competition for scare resources.
Darwin’s final refinement was to recognize that, given inevitable cull -
ing, the conditions of survival (and particularly, reproduction) would
differentially reduce this variety in a way that favored variant traits best
suited for that context—adaptation. Darwin recognized that irrespective
of the mechanisms involved, if these conditions are present, a lineage will
tend to become adapted to local conditions if given sufficient time and
generations. This was a remarkably simple recipe for biological change,
and yet its implications were enormous and counterintuitive. As one critic
of On the Origin of Species (Darwin, 1859) was to write: “in the theory with
which we have to deal, Absolute ignorance is the artificer; so that we may
enunciate as the fundamental principle of the whole system, that, in order
to make a perfect and beautiful machine, it is not requisite to know how
to make it” (MacKenzie, 1868, p. 217).
Adaptation is the natural counterpart to functional design, but the
idea that exquisite biological design might be achieved in the absence of
any information about the context of use seemed absurd. Deeply ingrained
intuitions, gained through the difficult experience of designing and con -
structing even simple artifacts and machines, made it unquestionable that
only considerable planning and knowledge about the relevant properties
of the materials and tasks involved could yield reliable functional out -
comes. Moreover, the difficulties encountered multiply geometrically with
increasing complexity because of the way that changing one component
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Relaxed Selection in the Evolution of the Language Capacity / ���
can interfere with the relationships to others. Given the fact that organisms
are constituted by vastly many complicated systems of chemical and cel-
lular interactions, this difficulty has led critics to conclude that precisely
because it is a blind and mindless mechanism it should be less capable of
giving rise to adaptive functionality the more complex the system. Thus,
such highly complex functional capacities as human cognition and lan-
guage would intuitively seem to be the least evolvable of life’s products.
indeed, so-called “intelligent design” critiques of Darwinism have focused
on far simpler molecular and cellular mechanisms to make their argu -
ment that the complexity of organism design is not evolvable, indirectly
implying that our vastly more complex cognitive abilities are all the more
beyond the explanatory power of natural selection theory.
For these reasons, since Darwin’s time, the human language capacity
has been a perennially cited paragon of extreme complexity that defies
the explanatory powers of natural selection. And it is not just critics of
Darwinism who have argued that this most distinctive human capacity
is problematic. Alfred russel Wallace—the codiscoverer of natural selec-
tion theory—famously argued that the human intellectual capacity that
makes language possible is developed to a level of complexity that far
exceeds what is achievable through natural selection alone. While fiercely
defending natural selection theory with respect to the traits of other spe -
cies, he argued that in the case of humans, “natural selection could only
have endowed the savage with a brain a little superior to that of an ape”
(Wallace, 1869, p. 392). And Charles lyell—who personally promoted
Darwin’s work and generally supported the evolutionary perspective—
also worried that language was just too complex to have evolved by natu -
ral means (lyell, 1863; Bynum, 1984). The vast vocabulary and baroquely
structured grammar and syntax of even the simplest of natural languages
is orders of magnitude more complex than any other species’ communica-
tion system, and the capacity this provides for expressing highly esoteric
concepts and conveying aesthetic experiences seems far removed from
anything with direct adaptive consequence.
Despite the unimpeachable success of Darwinian theory in the 150
years that have elapsed since the publication of On the Origin of Species
(Darwin, 1859), language still poses challenges for evolutionary biology.
The challenge is probably best exemplified by how language origin is still
being explained by many highly respected theorists. Take for example
noam Chomsky, who is arguably the most influential linguist of the
20th century. he has reasoned that human language competence could
not have been the product of natural selection, even though he believes
that it evolved as an inherited biological trait. its special features, such
as its recursive organization, and the often-baroque ways this property
is reflected in the various acceptable and unacceptable syntactic opera -
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tions of a given language, do not, according to him, facilitate any com -
municative function (Chomsky, 1986). indeed they seem on the surface
to be reflections of a tendency for systematization of language-unique
principles of structural coherence and systemic consistency that may have
more to do with the generativity of thought than with communication
(Chomsky, 2005). Few if any of these features can be justified in terms of
any direct contribution to reproductive benefit.
of course, nonadaptive traits, functional compromises, and ineffi-
ciency are also common to other biological adaptations. so this does not
in itself disqualify the human language faculty as a biological adapta -
tion honed by natural selection. But an innate capacity that appears to
be highly complex in ways that mostly tend to impede functional utility
requires special explanation.
Chomsky’s nonadaptationist view is not, however, widely accepted,
even by those who otherwise promote his strong nativist approach to lin-
guistic theory. For example, steven Pinker (1994) has eloquently argued
that the structural complexity of language implicitly demands a natu -
ral selection explanation. he echoes the general assumption that only
the process of natural selection can generate such well-fitted functional
complexity in biology. no mere side effect or accidental genetic damage
can be expected to exhibit anywhere near the complexity and utility of
language or the human predisposition to acquire it. The very complexity
of this capacity is thus taken as evidence of the operation of extensive
natural selection.
Darwin himself fretted over the possibility that natural selection alone
might be incapable of accounting for exaggerated functional complexity in
nature. in a letter he wrote to Asa Gray shortly after the publication of On
the Origin of Species (Darwin, 1859), he admits that “the sight of a feather in
a peacock’s tail, whenever i gaze at it, makes me feel sick!” (Darwin, 1860).
Despite the spectacular and elaborately formed details of this adornment,
it was a burden that negatively impacted health and survival and so could
not have been subject to natural selection with respect to the environment.
But it was the extravagance of traits such as this, despite their lack of util -
ity, which suggested to Darwin an approach to the challenge of explaining
human mental capacities.
in the case of the peacock tail, and other similar traits, Darwin real -
ized that, indeed, something other than natural selection with respect to
environmental conditions was responsible. recognizing that reproduc-
tion rather than individual survival was the critical factor in evolution,
he argued that competition with respect to reproductive access (sexual
selection) could result in runaway selection on certain traits, indepen -
dent of their environmental suitability. Darwin argued that a display
feature or fighting ability that led an individual to outcompete others in
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Relaxed Selection in the Evolution of the Language Capacity / ���
gaining access to mates would also favor proliferation and evolutionary
exaggeration of these traits, even at some cost to individual health and
survival. Analogously, he postulated that selection with respect to sex
might also explain such extravagant and highly divergent traits as human
language. in his book The Descent of Man and Selection in Relation to Sex
(Darwin, 1871a)—which is typically referred to by only the first half of its
title—Darwin argues that language and other human traits that appear
exaggerated beyond survival value can be explained as consequences of
sexual selection. so, for example, he imagines that language might have
evolved from something akin to birdsong, used as a means to attract
mates, and that the ability to produce highly elaborate vocal behaviors
was progressively exaggerated by a kind of arms-race competition for the
most complex vocal display.
Unfortunately, Darwin’s speculations in this respect were most effec -
tively criticized by the worst of all possible opponents: the codiscoverer
of natural selection, Alfred russel Wallace. Wallace was scandalized by
Darwin’s sexual selection theory, considering it Darwin’s greatest error,
because it appeared to admit a subjective factor into evolutionary theory.
indeed, it appeared to elevate aesthetic appreciation to the status of a
significant factor in evolution. Wallace’s alternative theory to account for
exaggerated display traits relied instead on explanations that invoked
incidental physiological mechanisms in males and the need to suppress
their effects in females, to avoid predation. But when combined with his
strong anti-lamarckian views, Wallace’s denial of Darwin’s sexual selec-
tion account of these extreme human traits appeared to leave him with
no other conceivable mechanism capable of explaining them. he instead
abandoned a physical account altogether and infamously invoked a spiri -
tual influence, suggesting that “some intelligent power has guided or
determined the development of man” (Wallace, 1870a, p. 350).
Wallace was of course wrong in his denial of the plausibility of sexual
selection, although not completely wrong to doubt that aesthetic apprecia -
tion or combative prowess were the primary factors. it took a century to
recognize that the theory needed to be based instead on asymmetries of
parental investment in offspring care between the sexes (Trivers, 1972).
Today, sexual selection theory is again considered an important adjunct to
the theory of natural selection; however, its reinstatement has not resus -
citated the power of Darwin’s account of language origins.1 even though
Wallace’s critique of sexual selection has been answered and its power to
explain the evolution of certain exaggerated traits is now recognized, there
1 There are, nevertheless, contemporary theorists who have offered variants on Darwin’s
proposed sexual selection account of language origins [see, e.g., G. Miller (1999), Burling
(2005), and locke and Bogin (2006)].
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are strong reasons for doubting its relevance to this most distinctive of
human traits. This is because sexual selection inevitably produces comple-
mentary divergence of male and female traits, as is exemplified by peacock
tails and moose antlers, which are exhibited only by males. Though there
are indeed a few highly divergent traits distinguishing women from men
(e.g., patterns of fat deposition in breasts and hips, etc.), the sexes differ
only very subtly in their intellectual and language abilities. Therefore,
accounting for the extravagant complexity of language in terms of sexual
selection requires explaining why it lacks this otherwise ubiquitous mark
of extreme sexual dimorphism.
For the most part, however, worries about the sufficiency of natu -
ral selection theory to account for our language capacity have simply
been ignored by contemporary theorists. some of the more prominent
approaches to the origins of language avoid the issue of selection alto -
gether by attributing this ability to an astonishingly lucky accident of
genetic mutation. Previously, it was noted that Chomsky has attributed
this unique capacity to a salutatory event in which this ability arose sud-
denly and irrespective of honing by natural selection. But archeologists
such as Mellars (1996) and Klein (2002), noting the explosion of cultural
variations of stone tool technologies and the first appearance of decorative
and representational forms (such as beads, carvings, and cave paintings)
between 60,000 and 30,000 years ago, have argued that a sudden major
change in brain function (a mutational accident that Klein has character-
ized as “the brain’s Big Bang”) could explain this apparent appearance of
recognizably modern human activities.
This willingness to appeal to lucky accident as the primary explana-
tion for this distinctive trait is in many respects a symptom of the problem,
not an explanation. Worse, it is an approach that could easily backfire. The
appeal to pure accident (e.g., a “hopeful monster” mutation) to explain
the evolution of such a highly complex and distinctive trait is the biologi -
cal equivalent of invoking a miracle. Although neo-Darwinism is indeed
based on the assumption that accidental genetic changes contribute to the
phylogenetic diversification of traits, this does not imply that complex
functional organization arises by accident. This overemphasis on the cre -
ative role of variation reflects a tendency to downplay the fact that what
varies must be generated by processes of reproduction and development.
it is the spontaneous variation of these generative processes that provides
the raw material from which natural selection sculpts, so to speak, and so
the properties of these generative mechanisms must also be considered.
This expansion of focus has given rise to a view of the evolutionary process
often called evodevo, because it specifically takes account of the constrain -
ing and biasing influences of these generative processes. highlighting this
aspect of the evolutionary process will be the focus of this essay.
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Relaxed Selection in the Evolution of the Language Capacity / ���
To explain the origin of the highly structured human-unique adapta -
tion inevitably requires addressing Wallace’s challenge concerning the
complexity and apparent nonadaptive aspects of these features. it is sig-
nificant, then, that theorists who view language functions as products of
natural selection have turned to a somewhat indirect variant of the theory
to account for the many details of language structure. Most commonly, this
is involves an appeal to what has come to be called the “Baldwin effect”
after one of its late 19th-century architects, James Mark Baldwin (1896). 2
This was a variant of natural selection theory that theoretically might lead
to pseudo-lamarckian effects, such that the functional utility of a specific
acquired habit of behavior (e.g., a language behavior) could eventually
come to be replaced by a fortuitously arising (e.g., via chance mutation)
innate analog. The appeal to this theoretical variant of natural selec -
tion—which is still a subject of debate concerning both its distinctiveness
and presumed efficacy [e.g., Deacon (2003), Federici (2003), Christiansen
et al. (2006), yamauchi (2007)]—exemplifies the special problems that the
extravagant complexity of language poses for natural selection.
A variant of this argument is proposed in Deacon (1997), where it is
suggested that the regular use of prelinguistic symbolic communication
(or protolanguage) created what amounts to a socially constructed arti -
ficial niche that in turn imposed novel cognitive demands on hominid
brains. This early articulation of what has come to be called “niche con -
struction” theory (odling-smee et al., 2003) argues that, analogous to the
evolution of beaver aquatic adaptations in response to a beaver-generated
aquatic niche, a constellation of learning biases and changes of vocal con-
trol evolved in response to the atypical demands of this distinctive mode
of communication. To the extent that this mode of communication became
important for successful integration into human social groups and a criti -
cal prerequisite for successful reproduction, it would bring about selection
favoring any traits that favored better acquisition and social transmission
of this form of communication. Unlike Baldwinian arguments for the
genetic assimilation of grammatical and syntactic features of language,
however, the niche construction approach does not assume that acquired
language regularities themselves ever become innate. rather it impli-
cates selection that favors any constellation of attentional, mnemonic, and
sensorimotor biases that collectively aid acquisition, use, and transmission
of language. Although this could conceivably consist of innate language-
specific knowledge, Deacon (1997, 2003) argues that this is less likely than
more general cognitive biases that facilitate reliable maintenance of this
extrinsic niche. Baldwinian selection can only occur if there is a consistent
2 Two other theorists are credited with independently proposing the same theory in the
same year: Conwy lloyd Morgan (1896) and henry Fairfield osborn (1896, 1897).
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and nondistributed genotype–phenotype relationship from person to per-
son and from generation to generation, as well as a significant reproduc-
tive consequence of this specific linkage as opposed to others (Federici,
2003; yamauchi, 2007). Because the particular way that a grammatical
category relation or a syntactic operation is instantiated in a given lan-
guage is arbitrary (e.g., a class of words, word order constraints, inflec -
tional modifications), the evolvability of innate grammatical principles
should be only slightly better than for innate words. Thus a recent study
by Christiansen et al. (2006) demonstrates that selection affecting the most
generic and ubiquitous demands associated with language use, acquisi -
tion, and transmission inevitably trumps the weak selection for arbitrarily
instantiated language-specific features.
Therefore, although it seems beyond doubt that the human language
capacity must have evolved due to extensive selection affecting multiple
levels of adaptive mechanisms, both the form of the variant of natu -
ral selection that was involved and the nature of the cognitive capacity
that it produced remain topics of intense debate in evolutionary biology.
Whatever account is given, however, it must explain the evolution of
the complex interdependence of the neurological, behavioral, and social
transmission features of language. To the extent that we can identify gen -
erative biological processes that increase the probability of the expression
of synergistic relationships among traits, then, these processes are likely
to be relevant to language evolution. We turn to these next.
EVOLUTION-LIKE PROCESSES IN DEVELOPMENT
Understanding how and why natural selection produces complexity
has been significantly advanced by recognizing how Darwinian-like pro -
cesses that take place at other levels of development and scale contribute.
one developmental mechanism that is particularly relevant to the evolu-
tion of cognitive complexity is the selection-like process that fine-tunes
axonal connection patterns in the developing nervous system. The global
organization of mammal brains exhibits a deep conservatism, with com -
mon epigenetic mechanisms responsible for their segmental organization
and the determination of large-scale connection patterns between regions
(striedter, 1997; o’leary and nakagawa, 2002; Mallamaci and stoykova,
2006). But complementary to this underlying commonality of architecture
generated in the early phases of embryogenesis, there is also a later plastic,
and more-or-less “regressive” phase of brain development, that contrib-
utes to the variations on this general theme (Purves and lichtman, 1980;
Cowan et al., 1984; Wilczynski, 1984; Finlay et al., 1987; Deacon, 1990).
The fine-tuning of neural circuitry to match specific body architecture and
sensory specializations, and their variations within and between species,
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Relaxed Selection in the Evolution of the Language Capacity / ���
involves a sculpting logic that is loosely analogous to natural selection
in a number of ways. The establishment of neural connections by axonal
outgrowth and invasion initially involves a somewhat nonspecific phase
where axonal guidance is largely controlled by highly conservative attrac-
tion, repulsion, and adhesion mechanisms, largely the result of local gene
expression effects. This process appears to be fairly species-general, with
many mechanisms shared by a wide range of vertebrates.
Although slight tweaks of this species-general brain architecture likely
play important roles in producing the structural and functional differences
of different species’ brains, a significant contribution also comes from
selection-like processes that incorporate both intra- and extraorganismic
information into the fine-tuning of neural circuitry. The species-general
global pattern of connectivity that is under strong but low-resolution
genetic guidance becomes the scaffolding for subsequent connectional
differentiation in response to signal-mediated activity-dependent compe -
tition for synaptic stability (Krubitzer and Kaas, 2005). These competitive
interactions appear to follow a hebbian signal-correlation logic that is
characterized by the mnemonic “neurons that fire together wire together.”
in many systems, the competitive culling of connections is also correlated
with neuronal apoptosis (“programmed” cell death). This process pro -
duces the fine-scale precision of connection patterns that match the neural
populations and topographies of interdependent brain and peripheral
structures.
This reflects one of life’s general strategies for dealing with the prob -
lem of getting a vast array of organism features to achieve good functional
integration with one another—effectively adapted to complement one
another—with maximum flexibility and minimum design information.
A precursor to this idea was proposed in the 1890s by the influential
Darwinian and embryologist August Weismann, who is remembered
mostly because of his success at repudiating the concept of lamarckian
inheritance. To provide an alternative explanation for features that
lamarckians had assumed would require a use-inheritance process, he
suggested that there might be an intraselection process occurring in what
amounts to the ecosystem of the body (Weismann, 1894). Though dif-
fering from what Weissman originally intended, the axonal selection
process is indeed a sort of intraorganismic selection process, although
its logic differs from natural selection in one important respect: selection
of this sort is confined to differential preservation only, not differential
reproduction. in this respect, it is like one generation of the operation of
natural selection. This more general way of characterizing the distinctive
logic of natural selection was characterized by an early advocate of this
generalization of Darwinism, Donald T. Campbell (1965), with the phrase
“blind variation with selective retention.”
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This is relevant to the problem of evolvability. in general, the more
highly complex, interconnected, and functionally integrated the system,
the more likely it will be functionally degraded by structural variation.
This is why no one imagines that computer design will be improved
by randomly sampling alternative circuit plans. To maintain functional
continuity despite local structural changes should require compensatory
reorganization throughout. Thus if brain circuits were fully prespecified
genetically, they would likely be too fragile to be evolvable.
The role that this intraselection process plays in the adaptive evolution
of the brain is exemplified by the brain of the blind mole rat, Spalax (Doron
and Wollberg, 1994). This fossorial species has vestigial eyes. in its brain,
the lateral geniculate nucleus (the thalamic visual nucleus) is “invaded”
during development by brainstem auditory and somatic projections that
outcompete the sparse projections coming from the small retinas. The
projections from the thalamus to the posterior cortex that in other mam-
mals would subserve visual processing instead subserves somatic and
auditory functions. experimental manipulations in other species, in which
projections from one sensory modality are reduced in early development,
likewise exhibit analogous takeover effects (Frost, 1981; sur et al., 1988),
and manipulations of the sensory periphery likewise demonstrate that
intraselection adapts neural functional topography with respect to func-
tional experience. This is a significant contribution to brain evolvability
and a general mechanism available for natural selection to recruit. These
mechanisms are almost certainly relevant to human brain evolution for
language, especially considering that language is such a significant con-
tributor to early experience.
This neuroepigenetic variant of selection logic is only one among many
processes that might more generally be described as intraevolutionary
mechanisms—that is, intraorganismic morphogenetic processes that par-
allel attributes characteristic of phylogenetic evolution. Although they
each differ in certain respects from natural selection, they all share certain
attributes that distinguish them from “design” processes, analogous to the
way that natural selection is distinguished from intelligent or end-directed
design. First, they involve processes that produce functional integration
and/or adaptation even though they are generated by mechanisms that
are dissociated from this consequence. second, they all involve the gen-
eration of redundant variant replicas of some prior form (gene, cell, con-
nection, antibody, etc.) brought into interaction with each other and with
an external context in a way that allows these differences to affect their
subsequent distribution. And third, their preservation and expression are
dependent on correlation with context. This highly abstracted analogy to
Darwinian logic will be demonstrated by examples to follow, but it can be
summarized as this: the replication, variation, and differential preserva -
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TABle 14.1 Parallels Between evolution-like Processes Between and Within organisms
interorganism intraorganism
1. reproduction and development 1. Duplication of structure and/or
function
2. Divergence via mutation, 2. Degeneracy and/or dedifferentiation
recombination, and/or drift
3. environment-correlated preservation 3. Function-correlated preservation via
via superior fittedness complementation or synergy
tion that together characterize natural selection have their counterparts
in the redundancy, degeneracy, and functional interdependencies that
characterize intraorganismic processes. This parallelism is summarized
in Table 14.1.
These intraorganismic parallels to evolutionary processes can be gen-
erally distinguished with respect to the level at which selection acts and
how this interacts with processes generating functional redundancy. All
take advantage of the power of the replicative dynamic of life, expressed
in growth and body maintenance as well as in reproduction, because of
the redundancy that this produces.
CASE 1. INTERNAL REDUNDANCY
The paradigm example of a replication–variation–selection dynamic
occurring internal to the organism is gene duplication. This intragenomic
duplication process has played a critical role in the evolution of organism
complexity, and is widely accepted to be a fundamental source of func -
tional synergies at all levels of the organism, from molecular complexes
and their interactions to body appendages and their coordination (ohno,
1970; li, 1983; ohta, 1994; Walsh, 1995; Zhang, 2003a). The Darwinian
parallels of this intragenomic process are, however, seldom noted. in this
process too, duplication allows variants to evolve, but largely because the
presence of a redundant copy can relax selection that otherwise would
tend to eliminate variant forms with mutations that alter critical functions.
Where a redundant copy is not itself a source of maladaptation, single
nucleotide substitutions and other noncatastrophic modifications to its
sequence tend to progressively and incrementally degrade the functions
of its protein product over evolutionary time.
Consider the well-documented case of the hemoglobins (Goodman et
al., 1987; hardison, 1999). spontaneous duplication of the ancestral hemo-
globin gene into the alpha and beta forms allowed each to accumulate
mutations that, while maintaining their oxygen-binding function, modified
other features of tertiary structure. independent variations in each form
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would originally have accumulated in the population, but sexual recom -
binations of different forms would have exposed any interaction effects
between variants, increasing variants that in combination would have in
some way augmented function. The one favorable interaction effect that
ultimately evolved to fixation was a complementarity in tertiary shapes
that increased the probability of the two variants binding to each other into
a 2 × 2 tetrameric form with an improved oxygen-carrying capacity. This
synergistic effect thus emerged from a duplication, independent variation,
and eventual selection based on fittedness to context (which in this case is
the context consisting of the other hemoglobin variant).
in placental mammals the beta hemoglobin was further subject to
multiple duplication mutations over the course of evolution. The resulting
relaxation of selection has allowed two of these duplicates to degrade to
pseudogene status. Four others, however, with slightly variant oxygen-
binding characteristics, appear to have been coselected with respect to
the different oxygenation demands of fetal life at different stages of ges -
tation, with different variants expressed early and late in fetal develop-
ment. This different sort of synergy—expressed diachronically rather than
synchronically—was also facilitated by relaxed selection, and the way it
increased the probability of interaction effects being expressed and thus
becoming subject to selection, over and above the function of component
genes.
The relaxation of selection that is created by the functional redun -
dancy consequent to gene duplication enables what amounts to a ran -
dom walk away from the gene’s antecedent function. But because a
random walk produces incremental deviation, there is a significant non -
zero probability that one or more of the increasingly variant forms within
a population of organisms will “wander” into a related interaction rela -
tionship with some duplicate counterpart, and again become subject to
selection for any interactive deleterious or synergistic effects. it is no
surprise, then, that gene families descended from a common ancestral
gene often form synergistic functional complexes.
The logic of gene duplication is exactly inverted in one respect to
that of natural selection. The relaxation of selection produced by internal
redundancy reduces competitive elimination, and instead favors pres -
ervation of variant forms, thus increasing the random exploration of
what might be called adjacent function space. As a result, it increases the
probability of encountering both deleterious interactions and synergistic
complementarities. Unlike axonal culling or the selective amplification of
immune cell replication with respect to antigen presentation, this process
occurs phylogenetically rather than ontogeneticically, but the replication,
variation, and context-dependent selection takes place within as well as
between organisms.
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This pattern of duplication, relaxation of selection, functional deg -
radation, and the potential emergence of selection favoring new seren-
dipitous synergistic interactions is replicated at many levels of organism
complexity. For example, the duplication and differentiation of regulatory
genes, such as the well-studied homeobox-containing genes that control
segmental organization in insects and vertebrates via their regulation of
the expression of a diverse range of other genes, enables duplication–
degradation–complementation at the phenotypic level (Garcia-Fernàndez,
2005; Martindale, 2005). The generation of structural redundancy of body
parts (e.g., limbs) via segmental duplication similarly relaxes selection
on some with respect to others. Again, this increases the probability that
random-walk degradation will expose synergistic possibilities (e.g., of
locomotor function) that will become subject to selective stabilization in
their own right.
CASE 2. EXTERNAL REDUNDANCY
Functional duplication that has its origin external to the organism is
analogous to gene duplication in influence, but can lead to very different
consequences. Without the reliability of internal redundancy, irreversible
degradation often follows and can lead to displacement of selection onto
other loci that incidentally contribute some role in stabilizing access to
the extrinsic source.
Consider the example of the loss of endogenous ascorbic acid (vita-
min C) synthesis that has evolved in a few vertebrate lineages. Most ver-
tebrates synthesize ascorbic acid endogenously, because of its important
antioxidant functions, but anthropoid primates, fruit bats, guinea pigs, and
many birds have lost this capacity (Chatterjee, 1973). Among the primates,
all prosimians except Tarsiers also synthesize ascorbic acid endogenously.
We, along with other monkeys and apes, must regularly acquire vitamin C
from dietary sources: principally fruit. And yet the human genome includes
a pseudogene for the final enzyme in the ascorbic acid synthesis pathway:
1-gulono-gamma lactone oxidase (GULO) (nishikimi et al., 1994). The
human GULO gene (as a likely exemplar of its other anthropoid homologs)
has accumulated many randomly distributed substitutions, deletions, and
at least one major frame shift effect, which resulted in catastrophic loss of
function (ohta and nishikimi, 1999).
Presumably, this drift toward degradation of function was a con-
sequence of a change in diet of the ancestors of modern anthropoids to
include significant and reliable quantities of fruit. regular dietary substi-
tution of ascorbic acid from fruit relaxed selection that would otherwise
have regularly eliminated mutational variants with reduced ascorbic acid
synthesis. relaxation of this stabilizing selection allowed functional degra-
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dation of the GULO gene without negative reproductive consequences. But
this loss of function resulted in the analog to a form of dietary addiction.
Because this essential nutrient was only available extrinsically, selection to
maintain its antioxidant function shifted to any sensory biases, behavioral
tendencies, and digestive-metabolic mechanisms that increased the prob -
ability of obtaining it. What was once selection focused on a single gene
locus became fractionally distributed across a great many loci instead.
one striking and plausible correlate is the evolution of three-pigment
color vision in anthropoid primates, which coincidentally also involves
gene duplication effects, the first of which appears to have occurred just
before the divergence of old and new World primates (shyue et al., 1995;
nei et al., 1997).
CASE 3. GLOBAL EXTERNAL REDUNDANCY
(E.G., DOMESTICATION)
in the rare cases where species enter domains with minimal direct
competition (such as invasive founder species) or are otherwise minimally
exposed to reproductive and survival limitations (e.g., domestication), the
relaxation of selection this produces can result in global dedifferentiation
effects. in such conditions, not only should we expect to see redistribution
of functional determination, such as characterize cases of specific extrinsic
redundancy, but it should be a more or less generalized effect. This should
be particularly well exemplified in long-domesticated species such as the
domestic dog.
An example of domestication that might shed light on the language
origins issue involves domestication of a songbird known as the white-
backed munia (honda and okanoya, 1999; okanoya, 2004). its domes-
ticated cousin is known as the Bengalese finch, which has been bred for
coloration in Japan for roughly 250 years. interestingly, although as far as
is known, it was never specifically bred for singing ability (and does not
have a particularly sonorous song), the Bengalese finch has a very different
singing ability than its wild cousin. Bengalese finches acquire their songs
via social learning by copying a particular adult singer or singers. As a
result, their songs are highly variable within and between individuals. in
contrast, the white-backed munia does not learn its song from others and
has an autonomously developed and highly rigid song.
Birdsong, like other forms of display complexity, are generally assumed
to be the result of sexual selection, where it contributes to competition for
mates, territory, nest sites, etc. in this case, however, it appears to have
complexified in conditions where selection on song function has been
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Relaxed Selection in the Evolution of the Language Capacity / ���
completely relaxed.3 variability can simply be a correlate of degradation
of control, and this would indeed be an expected consequence of relax-
ation of selection; however, the shift from autonomously developed to
socially acquired song requires a bit more explanation. in addition, socially
acquired song requires the contribution of a significantly larger number
of forebrain nuclei and their interconnections than does the production
of a mostly innately prespecified song (Jarvis, 2004). This difference also
distinguishes the Bengalese finch from the white-backed munia.
Generally, it is assumed than an increase in behavioral complexity
and flexibility and an increase in the complexity of neural interactions
that support it can only have come about due to intense natural or sexual
selection. in this case, however, increased complexity appears to have
arisen in the context of global relaxation of selection, and in a remarkably
brief period. This apparent paradox can be resolved if we understand the
transition in terms of the dedifferentiation and redistribution effects of
relaxed selection.
Although data are not currently available to delineate what mecha -
nism generated this difference, its association with an apparent global
relaxation of selection suggests the following hypothesis.
By removing the stabilizing effects of natural and sexual selection
on song production, the almost exclusive control of song structure by a
forebrain nucleus designated rA (robust nucleus of the archistriatum)
degraded, as genes maintaining this behavioral template acquired degrad-
ing mutations that were not eliminated by selection. As constraints on song
generation degraded with prolonged domestication, other neural systems
that previously were too weak to have an influence on song structure
could now have an effect. These include systems involved in motor learn -
ing, conditionally modifiable behaviors, and auditory learning. Because
sensory and motor biases can be significantly affected by experience, song
structure could also become increasingly subject to auditory experience
and the influence of social stimuli. in this way, additional neural circuit
involvement and the increased importance of social transmission in the
determination of song structure can be reflections of functional dediffer-
entiation, and yet can also be sources of serendipitous synergistic effects
as well. The result is a tendency to shift control of a previously innate and
localized function onto a distributed array of systems that each now only
fractionally influences that function. This effectively offloads a significant
3 Although it is possible that song complexity was inadvertently selected either by
unconscious bias during breeding or because of linkage, epistatic, or pleiotropic association
with the genetics of coloration, no evidence for such a coupling exists. And in addition,
each of these theories makes unusual assumptions that are not required for the relaxed
selection account. Genetic analysis will be required to ultimately choose between these
mechanisms.
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��0 / Terrence W. Deacon
degree of genetic control onto epigenetic processes, and because of their
openness to experiential modification, it increasingly opens the door to
the influence of social transmission (Deacon, 2009).
There are a number of features that distinguish the neurology of
linguistic communication from that of the major forms of vocal com -
munication in other primates (and mammals in general) that appear to
have parallels in the finch/munia case. These include (i) a significant
decrease in the specific arousal-coupling of vocal behaviors; ( ii) minimi-
zation of constraint on the ordering and combinations of vocal sounds;
(iii) reduction, simplification of the innate call repertoire; ( iv) subordina-
tion of innate call features to a secondary role in emotional tone expression
via speech prosody; (v) a significantly increased role of auditory learn-
ing via social transmission; (vi) widely distributed synergistic forebrain
control of language compared with highly localized subcortical control
of innate vocalizations; and, of course, (vii) an increased social-cognitive
regulation of the function of vocal communication (Deacon, 2009).
This raises an obvious question: Could humans be a self-domesticated
species—that is, a degenerate ape? The munia/finch analogy suggests
that genetic dedifferentiation affecting the nervous system may have
contributed to functional complexity in human language evolution. has
there been more widespread degeneration as well? if so, it might help
explain the extensive human cognitive–social–emotional flexibility com -
pared with other mammalian species. Could human mental plasticity,
cultural variability, aesthetic and religious sensibilities, and susceptibility
to social control and conformity be an expression of cognitive–emotional
dedifferentiation?
PUTTING HUMPTY DUMPTY TOGETHER AGAIN
This exploration of intraorganism parallels to evolutionary processes
of selection and drift has highlighted a number of mechanisms by which
remarkably complex synergistic relationships can emerge serendipitously
in the course of evolution. These processes are not exclusive of the effects of
natural and sexual selection, and in many ways provide auxiliary sources
of complex synergy subject to these Darwinian processes. They are almost
certainly crucial to the evolvability of highly complex synergistic adapta-
tions, such as human language. recognition of the potential contributions
of each of these processes to evolvability should warn against monolithic
natural selection accounts of language evolution that ignore the contribu -
tions of these interlinked levels of selection and drift processes.
But language evolution includes one additional twist that may in fact
mitigate some fraction of what biological evolutionary mechanisms must
explain. language itself exhibits an evolutionary dynamic that proceeds
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Relaxed Selection in the Evolution of the Language Capacity / ���
irrespective of human biological evolution. Moreover, it occurs at a rate
that is probably many orders of magnitude faster than biological evolution
and is subject to selective influences that are probably quite alien from
any that affect human brains or bodies. Darwin recognized this analogi-
cal process, although he did not comment on its implications for human
brain evolution.
“A struggle for life is constantly going on amongst the words and
grammatical forms in each language. The better, the shorter, the easier
forms are constantly gaining the upper hand, and they owe their success
to their own inherent virtue” (Darwin, 1871a, p. 91).
The environment that is the source of selection affecting the reproduc-
tion and selective elimination of language features is human cognitive
limitation and communicative requirements. For this reason, a given lan-
guage should reflect selection favoring learnability, early acquisition, and
ease of use concerning which features are retained or lost over the course
of its historical change. in this respect it is an oversimplification to expect
that all of the universal design features of language require a biological
evolutionary account. so as brains have adapted to the special demands
of language processing over hundreds of thousands of years, languages
have been adapting to the limitations of those brains at the same time, and
a hundred times faster (Deacon, 1997). This means that brain functions
selected for the special cognitive, perception, and production demands of
language will reflect only the most persistent and invariant demands
of this highly variable linguistic niche. This is another reason to expect
that the synergistic constellation of human brain adaptations to language
will not include specific grammatical content, and to suspect that much
of the rich functional organization of any language is subject to influences
on this extragenomic form of evolution. in other words, the differential
reproduction of language structures through history will be dependent
on the fidelity and fecundity of their transmission. not only will this
process be subject to selection with respect to semiotic and pragmatic
demands of symbolic communication, it will also favor structures that are
more easily acquired by immature brains undergoing activity-dependent
intraselection of neural circuitry. indeed, just as evolvability is aided by
evolution-like processes involved in ontogenesis, we should expect that
the social evolution of language should itself exhibit analogous processes
due to redundancy, degeneracy, and functional interdependency.
language is too complex and systematic, and our capacity to acquire it
is too facile, to be adequately explained by cultural use and general learn -
ing alone. But the process of evolution is too convoluted and adventitious
to have produced this complex phenomenon by lucky mutation or the
genetic internalization of language behavior. These metaphors are more
suited to the analysis of a designed artifact. The robusticity of the language
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acquisition process, the deep integration of language and human cogni -
tion, and the involvement and synergistic interaction of widespread and
diverse brain systems in language processes together imply that there has
been long-term adaptation involving a very broad suite of genetic loci and
the involvement of many levels of intraevolutionary mechanisms. We are
more likely to succeed at solving this mystery if we approach it with the
expectation that nature produces her most complex works by a logic that
is vastly more subtle, and entirely unlike the methods of a watchmaker
or computer scientist.
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