CUP_JBS_1600002 15..30


J. Biosoc. Sci., (2017) 49, 15–30, © Cambridge University Press, 2016. This is an Open Access
article, distributed under the terms of the Creative Commons Attribution licence (http://
creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction
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doi:10.1017/S002193201600002X First published online 9 Feb 2016

SOME USES OF MODELS OF QUANTITATIVE
GENETIC SELECTION IN SOCIAL SCIENCE

MICHAEL D. WEIGHT1 AND HENRY HARPENDING

Department of Anthropology, University of Utah, Salt Lake City, UT, USA

Summary. The theory of selection of quantitative traits is widely used in
evolutionary biology, agriculture and other related fields. The fundamental
model known as the breeder’s equation is simple, robust over short time
scales, and it is often possible to estimate plausible parameters. In this paper
it is suggested that the results of this model provide useful yardsticks for the
description of social traits and the evaluation of transmission models. The
differences on a standard personality test between samples of Old Order
Amish and Indiana rural young men from the same county and the decline of
homicide in Medieval Europe are used as illustrative examples of the overall
approach. It is shown that the decline of homicide is unremarkable under a
threshold model while the differences between rural Amish and non-Amish
young men are too large to be a plausible outcome of simple genetic selection
in which assortative mating by affiliation is equivalent to truncation selection.

Introduction

In genetics quantitative traits like stature, body weight, milk yield in cattle, yield per acre of a
field crop or the outcomes of pencil and paper tests for cognitive ability or personality, are
traits that can be measured on a continuous scale. The theory of the evolution of quantitative
traits under selection is well established in plant and animal breeding and in evolutionary
biology (Lande, 1976; Falconer, 1981; Walsh & Lynch, 2015). The origin of quantitative
genetic theory is R. A. Fisher (1919), who modelled a quantitative trait as the additive effects
of a large number of genetic loci, allowing for dominance within each locus, and random
environmental effects. Fisher’s paper ended the controversy between Mendelians and
Biometricians, the two competing approaches to understanding the transmission of heritable
traits in the early twentieth century. Many regard this paper, after Darwin’s Origin of
Species, as the beginning of modern evolutionary biology (Provine, 2001).

In practice Fisher’s basic model is simple and robust despite potential complications
and elaborations. Sufficient conditions for the key results are the stochastic

1 Corresponding author. Email: michael.weight@utah.edu

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independence of genotypes and environments, the absence of dominance and epistasis
(non-additive interactions between genes at different genomic locations) and a linear
regression of genotypic values on phenotypes (Nagylaki, 1992). Under these
assumptions the breeder’s equation relates the change in the average value of some
quantitative trait in response to selection as:

r=h2s:

In this equation r, the response to selection, is the difference between the average
phenotype of parents and the average phenotype of offspring after a single generation of
selection. The term h2 is the narrow-sense heritability, or the fraction of phenotypic
variance in the population attributable to the additive effects of genes. Finally, the
selection differential, s, denotes the difference between the average phenotype in the
population and the average phenotype of parents of the next generation.

Given two terms of the breeder’s equation, one can estimate the third. Agriculture
favours estimating heritability through selection experiments. Breeders or experimenters fix
the selection differential by choosing parents from the population under study. The
response r is obtained by measuring the offspring after selection. The heritability of the trait
h2 immediately follows from the breeder’s equation. Such experiments cannot be done in
the social sciences. Instead, heritability is estimated from similarities among relatives.

Complications can occur in the simple theory. For example, epistatic interactions
between loci violate the simple set of assumptions. Remarkably, these tend to cancel
each other over time. Crow (2010) suggested that natural selection generally favours
changes that lead to the simple additive model given by the breeder’s equation.

Complexities have cast doubt over human heritability estimates. For example, a
standard source of data has been pairs of identical and fraternal twins. Heritability
estimates then assumed that identical twins separated at birth are genetically identical
and raised in random environments. Challenges to this assumption arise from many
sources: shared uterine environment of identical twins before birth, non-random
placement of adopted twins and others (Kamin & Goldberger, 2002).

Data from the Human Genome Project render many criticisms of twin studies moot.
Identical twins were of interest because they shared more or less the same genome, but
suspicions of shared environment persisted. Today the state of technology is to type
approximately a million single nuclear polymorphisms (SNPs) in a large sample of subjects
and measure the relationship between individuals by the number of SNPs they share.
Realized kinship to the order of second cousins and lower is assessed for tens of thousands of
typed subjects. This technology renders studies of real pedigree relationship nearly obsolete
while simultaneously validating the conclusions about human heritability estimates that had
been so widely denounced in the twentieth century (see Visscher et al., 2008; Yang et al.,
2010; Davies et al., 2011; and Lee & Chow, 2014, for further discussion).

Thought experiment

Assortative mating can be equivalent to directional selection. Assortment for a trait
generates either distinct groups or a continuum: those with more of the trait at one

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extreme and those with less of the trait at the other, within a population. To illustrate
this consider a simple thought experiment about assortative mating for stature in a
population. Assign average stature of 175.26 cm for males and 162.56 cm for females,
each with a standard deviation of 7.62 cm. These figures are close to observed values in
North America. Suddenly assortative mating by height occurs such that those taller than
the population mean mate only with others also above the mean while those shorter than
the mean mate only with others shorter than the mean.

First, it is assumed that the differences between male and female stature reflect fixed
differences in the development of the two sexes. The data can then be normalized for
each sex and stature in standard deviation units (SDs) measured. The pooled population
has a mean of zero and a standard deviation of 1.0. The new units, called Z-scores, are
obtained by subtracting the population mean from everyone’s stature (175.26 cm from
each male, 162.56 cm from each female) and dividing by the standard deviation of
7.62 cm. After imposition of the mating rule the population separates into two
populations: talls and shorts. With this normal distribution assumption the overall
normal distribution has been split into two distributions. The mean of a left half-normal
distribution is −0.8 SDs and that of the right half + 0.8 SDs. The difference in population
means is therefore 1.6 SDs, or 12.19 cm in the original units.

The new subpopulations mate at random within themselves. The two sets of parents
differ by 1.6 SDs. After reproduction, assuming an additive heritability of 0.80 for
stature, the group difference will be, following the breeder’s equation, 0.8 × 1.6 = 1.28
SDs, corresponding to 1.28 × 7.62 = 9.75 cm. After the first generation of reproduction
the genotypic group means differ by 9.75 cm without further movement between groups.

Before the new mating system the overall variance of stature was 1.0. After a single
generation of the new mating system the between-subpopulation variance is 0.642 or
0.41 on the standard deviation scale. The fraction of stature variance that is between
groups is now 41%. The variance of stature within each of the two subpopulations is the
complement or 0.59. Back on the scale of centimetres, the standard deviation within
populations is the square root of 0.59 (0.773), corresponding to 5.9 cm.

Richard Lewontin (1972) famously estimated the fraction of genic variance among
continental human groups to be about 15% for a collection of presumably neutral
genetic markers. That estimate of the ratio of between-group to total variance has
remained constant as the number of loci available to estimate it grew from dozens to
hundreds of thousands. After a single generation of this thought experiment the stature
variance between groups at genetic loci influencing stature is between two and three
times as great as the overall neutral genic variance among major human populations.
Yet there is absolutely no selection in this thought experiment. Everything is selectively
neutral. On the other hand, from the perspective from within subpopulations, there has
been strong selection imposed by the mating rule allocating persons to groups according
to stature. The mechanism of selecting according to a threshold is called truncation
selection. It is, for example, the most common selection rule in animal and plant
breeding. Here, the threshold was at the mean height of the overall population.

It is worth pointing out that after assortative mating the genetic variance within each
group is somewhat smaller than what it otherwise could be as a result of negative linkage
disequilibrium between causal sites (Bulmer, 1980). This may seem somewhat
paradoxical because of the overall positive linkage disequilibrium between causal sites

Models of selection 17

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in the total population (including both talls and shorts) induced by the assortative
mating itself (Fisher, 1919; Crow & Felsenstein, 1968; Nagylaki, 1982). The reader may
consult Lee and Chow (2013) for an intuitive explanation of the so-called Bulmer effect
of negative disequilibrium. If random mating prevails within each group after
assortment, then the Bulmer effect decays; the genetic variance within each group will
thus increase. The most important feature of the genetics to keep in mind is that the
classical increase in the overall genetic variance due to assortative mating, first described
by Fisher himself, corresponds to the divergence in means between the two groups
formed by the assortment process.

The mating rule in this thought experiment about the effects of truncation selection acted
on a biometric trait. Suppose, instead, individuals in the population were similarly partitioned
according to a threshold along a behavioural trait. Bailey (1998) pointed out that behavioural
traits like religiosity, extraversion, neuroticism and even divorce are all moderately heritable.
Indeed, Eric Turkheimer in an essay titled ‘Three laws of behaviour genetics and what they
mean’ (Turkheimer, 2000) gives ‘all human behavioural traits are heritable’ as his first law of
behaviour genetics. Rejecting the null hypothesis that behaviours are not heritable is therefore
no longer of much interest (Bailey, 1998; Turkheimer, 2011). The genetic effects of the mating
rule in the thought experiment on behavioural traits therefore mirror those illustrated using
height. Despite this, the social sciences have generally neglected quantitative genetic models
even though many other quantitative traits like IQ (Herrnstein & Murray, 1994; Jensen,
1998), the propensity to develop mental illnesses like bipolar disorder and schizophrenia
(Owen & O’Donovan, 2003; Barnett & Smoller, 2009; Wray & Visscher, 2010), aggression
and antisociality (Barker et al., 2009) and other behavioural traits have significant social and
economic consequences.

If the rule had its origin as a purely culturally transmitted preference then the effect
on the genome would be exactly the same as those described in the thought experiment.
Purely learned preferences or socially imposed assortments would ‘pick up’ any relevant
genes, giving an identical genetic effect. Pervasive social transmission of these
preferences would therefore probably amplify the heritability of behavioural traits.
Consider new popular social traits that rapidly spread like a new religious movement,
tofu consumption or crack cocaine use. Initially there may be no genetic basis for the
cultural success of these traits, but suppose the trait fostered reproductive success.
Standing genetic variation favouring the trait is then subject to selection. Consequently,
the traits would become more heritable as initially rare genes present within the
population became more common.

An older example of this effect is due to Waddington (1956). He found that flies
treated with ether were prone to develop a second thorax. Without the ether treatment
the trait, bithorax, was absent. However, bithorax began to appear even in the absence
of ether after 20 generations of selection for flies vulnerable to the ether treatment.
Alleles that slightly increased the probability of bithorax, but not enough to bring out
this phenotype without the large effect of the ether treatment, were apparently positively
selected during this experiment. Selection then raised their frequencies high enough to
trigger bithorax in the absence of ether. The observed heritability of bithorax increased
through a process that Waddington called genetic assimilation. Though superficially
like Lamarckian inheritance of acquired characteristics, genetic assimilation has a
well-studied quantitative genetic basis.

18 M. D. Weight and H. Harpending

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Genetic accommodation (West-Eberhard, 2003; Braendle & Flatt, 2006) is a
generalization of genetic assimilation. Even if the hypothetical examples of tofu or crack
fostered reproductive success through purely social mechanisms, individuals whose
biochemistry was congenial to the new trait would participate more easily and their
genotypes would increase in frequency. The preference would become heritable even though it
was not initially. The idea that cultural adaptation renders genetic adaptation irrelevant is
widespread in anthropology. Instead, genetic accommodation suggests that the pervasiveness
of cultural transmission in our species has increased overall rates of genetic adaptation (see e.g.
Hawks et al., 2007; Cochran & Harpending, 2009; Laland et al., 2010; Richerson et al., 2010,
for further discussion of cultural pressures increasing the rate of human genetic adaptation).

The Old-Order Amish

Assortative mating

Are there concrete ethnographic examples of assortative mating about a trait
analogous to height with the above kind of strong effect? There are several candidates.
Cochran et al. (2006) proposed that a similar mechanism operated in the evolution of
European Ashkenazi Jews during the Middle Ages: the Ashkenazim were a population
closed to immigration, but with the possibility of emigration, that experienced strong
selection for economic and managerial success. The Parsi of India, a closed class of
managers, scholars, musicians and other economically and culturally successful
individuals (Nelson, 2012), are another distinct population in which assortment may
have been important in their evolution. Recently Charles Murray in Coming Apart
(2013) proposed that assortative mating by education, socioeconomic status and IQ is
splitting America into distinct and different classes – the ‘coming apart’ of the title.

The Old-Order Amish, an Anabaptist sect in North America, also follow the pattern
of negligible inward, but significant outward, gene flow, making them a potential
candidate for selection by assortment. A model is described in which there is an
underlying trait that we call AQ (Amish Quotient) by analogy with IQ derived from
cognitive tests. It is postulated in this model that AQ predicts the probability of an
individual remaining in the community when adolescents decide to remain and be
baptized or to decline membership and emigrate. Specifically the measure of AQ is a
personality measure associated with the plain and simple lifestyle of the Amish,
postulated to indicate an individual’s underlying affinity for membership in the
community. Under the proposed mechanism of selection the AQ within the Amish
population would increase each generation as those with lower AQs are truncated each
generation through ‘boiling-off’ or defection. It is therefore predicted that declining
boiling-off rates over time (see below) are a consequence of this selection mechanism
increasing overall population AQ each generation within the Amish population.

The model performs well relative to alternative models of Amish defection and
retention (see Ericksen et al., 1980; Meyers, 1991, 1994; and Greksa, 2002, for review).
While Old-Order endogamy is well described and understood, the trade-offs and
constraints of defection are unclear. Reductions in defection rates over the last century
(Meyers, 1991, 1994; Hostetler, 1993; Greksa, 2002) need explanation. Previous models
of Amish defection emphasize rapid population growth in regions with finite resources,

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particularly expensive farm land, and the resulting trade-off between culturally
sanctioned high fertility and the ability of families to support their own farms
(Markle & Pasco, 1977; Ericksen et al., 1979, 1980; Wasao & Donnermeyer, 1996).
Other models focus on the effects of occupational shifts consequent to economic
constraints on farming. These models predict that increasing exposure to non-Amish
lifestyles may tempt youth into defection or interfere with parents’ ability to transmit
Amish identity (Meyers, 1991; Greksa, 2002). Unfortunately predictions of these more
familiar approaches to Amish defection are difficult to quantify and corroborate.

Endogamy

As the most traditional and ‘plain’ Anabaptist group, the Old-Order Amish are pacifists
who reserve baptism for believing adults and have strict shunning practices of deviant
church members (Hostetler, 1977, 1993; Roth, 2002). Such non-hostile ethnocentrism and
social solidarity introduce a near absolute boundary that culturally uncouples the Amish
from the ‘English’, their word for non-Amish (Huntington, 1957; Savells, 1988). Familiar
Amish norms like carrying out intragroup discussions in Pennsylvania Dutch, favouring
horse-and-buggy over automobiles, traditional ‘humble’ clothing, absolute pacifism and
forsaking appliances like telephones, televisions, refrigerators and indoor toilets, are means
to signal this uncoupling from their broader society (Fuchs et al., 1990; Kraybill, 2001).
Genealogical and genetic analysis reveals the Amish have been significantly isolated since
Old-Order founding populations immigrated in the 18th and 19th centuries (Hostetler,
1993; Kraybill, 2001; Pollin et al., 2007; Hurst & McConnell, 2010; Lee et al., 2010).
Arguably the Old-Order Amish are the most culturally and reproductively isolated
Anabaptist group in the United States (Nolt, 1992; Hostetler, 1993; Kraybill, 2001).

Following this isolation, the Old-Order substitute communal aid for secular public
support. Initiatives like welfare, Social Security, life insurance, barn insurance (Hurd,
personal communication), government agricultural subsidies or public schools (if Amish
schools are available) are therefore prohibited or strongly discouraged (Hostetler, 1969,
1993; Fuchs et al., 1990; Hurst & McConnell, 2010; Kraybill, 2011) in the interests of
communal self-reliance. Amish substitutes for institutional support are primarily
mediated through kin networks so extended families bear the emotional and financial
burden of the welfare of their members (Hurd, 1983; Hostetler, 1993; Hurst &
McConnell, 2010). Children, especially males, rely on kin support to start businesses and
farms when they begin their own families (Ericksen et al., 1979, 1980; Hurd, 1981;
Wasao & Donnermeyer, 1996). Highly fertile Amish mothers draw on relatives to help
with their large families (Hewner, 1998; Kraybill, 2001). Costs of disabled, ill, and senior
members are mitigated by family and community support (Hewner, 1998). The Amish
are a healthy population with low incidence of infectious disease, low infant and adult
mortality rates, high fertility and high standards of living (McKusick et al., 1964a, b;
Cross, 1969; Cross & McKusick, 1970; Fuchs et al., 1990; Hewner, 1998; Greksa, 2002).

The 16PF

Wittmer (1970) reported the results of a personality questionnaire administered to 25
Amish and 25 non-Amish, 18- to 20-year-old men from Daviess County, Indiana.

20 M. D. Weight and H. Harpending

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The questionnaire was a widely used personality assessment called 16PF (for sixteen
personality factors) developed in the 1940s by Raymond Cattell and others at the
University of Illinois (Cattell & Eber, 1972). It went through several revisions over the
years. Each form has 180 questions that are scored to yield sixteen numbers, or factors,
supposed to represent the subjects’ sixteen dimensions of personality. These are listed in
Table 1 along with the adjectives in common use that supposedly describe each trait.

No use is made of the details of the traits in this paper: the sixteen numbers for each
person in the study are simply regarded as self-reports of interesting characteristics. The
test and the scoring system are designed to maximize the independence of the factors so
the scores are not redundant indicators of the same trait. In some of the literature factor
B is not reported nor used since it assesses intelligence rather than a personality trait.
Here B is included since these data are treated in the same way as genetic markers like
SNPs would be treated, i.e. the authors are agnostic about the interpretation and
meaning of the factors.

To make sense out of the array of scores for the Amish and non-Amish sample a
conventional method for data reduction is used called principal components analysis
(PCA). This provides a least-squares best two-dimensional picture of differences among
subjects and differences (i.e. correlations) among variables.

The process used is analogous to that of estimating IQ. An important finding from
cognitive testing is that cognitive ability is essentially one-dimensional. For example,
people with high mathematical ability also have large vocabularies. One empirical result
of this is that almost anything constructed to test ability functions as a suitable proxy for
a proper IQ test. SATs, GREs, MCATs and AFQTs are, for example, nearly
interchangeable with IQ tests (Frey & Detterman, 2004; Beaujean et al., 2006).
In addition, the United States General Social Survey (GSS) surveys a large sample of
Americans every few years. The results are conveniently available on the web (General

Table 1. Factors assessed in the 16F questionnaire

Trait label High Low

A Outgoing, Warmhearted Reserved, Detached
B Abstract thinking, Fast learner Concrete thinking, Slow learner
C Unemotional, Calm Emotional, Changeable
E Assertive, Dominant Humble, Co-operative
F Cheerful, Lively Sober, Taciturn
G Conscientious, Persistent Expedient, Undisciplined
H Venturesome, Socially bold Shy, Retiring
I Tough-minded, Self-reliant Tender-minded, Sensitive
L Suspicious, Sceptical Trusting, Accepting
M Imaginative, Bohemian Practical, Conventional
N Shrewd, Discreet Forthright, Straightforward
O Guilt-prone, Worrying Resilient, Self-assured
Q1 Radical, Experimental Conservative, Traditional
Q2 Self-sufficient, Resourceful Group-dependent, Affiliative
Q3 Controlled, Compulsive Undisciplined, Lax
Q4 Tense, Driven Relaxed, Tranquil

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Social Survey, 2012). Each round of the survey presents each respondent with ten words,
asks for their definitions, and then tabulates the variable WORDSUM that varies from
0 to 10 for that subject. WORDSUM is a useful proxy for IQ in the sense that differences
among groups along the variable replicate reported differences among the same groups
(Jensen, 1998) from more elaborate tests. The PCA of the results from Wittmer’s study
may reveal an analogous one-dimensional personality trait corresponding to the AQ.

Scattergrams along principal components (groups) and principal co-ordinates (traits)
from the 16PF results are shown in Figs 1 and 2. Figure 1 shows patterns among group
means, the Amish and non-Amish from Wittmer’s study, along with a collection of other
populations culled from the literature. Details are given in the caption of Fig. 1. The
scatter of traits in the left panel is not very informative. There is no clear pattern,
presumably reflecting the design goal of independence among the sixteen factors. The
scatter among groups, in the right panel, is more interesting. There are three groups that
are on the edge of the scatter: Amish, Chinese nurses and candidates for high-level
management positions in the UK. The outstanding (AN) and ordinary (EN) Chinese
nurses (see Zhang et al., 2013, for data) are nearly identical to each other on these first
two dimensions. Generic English (UK), according to data taken from Bartram (1992),
are more similar to Indiana rural young men than they are to high-level managers in the
UK. Figure 1 shows a broad perspective on group differences, especially the difference
between the British norms and the non-Amish Indiana rural males.

Fig. 1. Principal components analysis (PCA) of 16PF score differences among groups
of 18- to 20-year-old Indiana men. The left panel portrays similarities (i.e.
correlations) among the sixteen traits listed in Table 1. The right panel portrays
differences among means of several large samples. AM are young Amish males from
Indiana; IN are non-Amish males from the same Indiana county; AN and EN are
outstanding and ordinary Chinese nurses, respectively; MK are candidates for high-
level manager jobs in the UK; and UK are British norms of the 16PF test. Notice the
lack of pattern in the left panel, indicating the relative independence of the sixteen
traits. Several of the labels have been nudged on the figure to avoid overlaps.

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The 16PF test itself is proprietary and widely used in personnel selection.
Comparable data in the literature are scarce, accounting for this strange choice of
Chinese nurses and UK managers. They were simply chosen by convenience to convey a
sense of the magnitude of group differences. Even more dismaying is that a standard way
to present 16PF results is to normalize everyone in a sample to a fixed mean.
Consequently much of the published 16PF data are not comparable between groups.

The interest in Fig. 2 is to show individual differences among young rural Indiana
men. The scatter shows a nearly complete separation of the Amish and non-Amish along
the horizontal axis (the first principal component). The UK mean is shown for
comparison in the right panel as a diamond. Remarkably, the overall UK mean is near
the centre of the non-Amish scatter, implying that they are not very different. The Amish
are strongly different. In a genetic model the differences are partially the accumulated
effects of Amish voluntary endogamy along with boiling-off of the young Amish in each
generation who decide to leave the Amish community.

The scatter of traits in the left panel of Fig. 2 helps identify those traits distinguishing
the Amish and non-Amish along the horizontal axis. Traits G, Q3 and I on the extreme
left of the horizontal axis are in the space of those with the highest AQ. The 16PF scores
show that Amish describe themselves, albeit indirectly, as conscientious and persistent (G),

Fig. 2. Principal components analysis (PCA) of individual 16PF scores of 18- to
20-year-old Indiana men. The left panel portrays similarities among traits, and the
right panel among individuals along with the overall UK population. Trait labels are
given in Table 1. Amish young men are shown as circles, non-Amish as squares and
the large diamond shows the centroid of the UK standard for comparison. The two
panels are dual, so proximity between a trait in the left panel and a subject in the
right indicates a high value of that trait in that subject. For example the Amish
subjects have high values of 16PF trait G, which is called ‘conscientiousness’ and
‘persistence’ in the literature. Non-Amish young Indiana males have relatively higher
scores on trait Q1, called ‘radical’ and ‘experimental’.

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tough-minded and self-reliant (I), and controlled (Q3). Correspondingly they describe
themselves as low in Q1 and E, scoring respectively as conservative/traditional and
humble/co-operative. These imputed self-characterizations agree remarkably well with
stereotypes of the Amish that they hold themselves according to ethnographies. The
authors are agnostic about the meaning and uses of the 16PF and other similar tests except
as indirect self-descriptions by subjects.

A model of (self-)selection

Under this model the horizontal axis in Fig. 2 is a numeric scale of a trait AQ
identifying where an individual is in a suite of traits differentiating young Amish men
from their non-Amish neighbours. Movement out of the Amish community is open to
anyone, especially around adolescence. What would be the consequences for the Amish
community if individuals on the low end of AQ were especially prone to leaving the
population?

It is informative to bring a quantitative genetics model to the phenomenon as a well
understood baseline for evaluating competing models. In this spirit it is assumed that AQ
is a partially heritable quantitative trait. There are enough data on behavioural or
psychological trait heritabilities to sensibly estimate the additive heritability of AQ,
written h2, at 0.5. It can be seen below that the conclusions are unaltered if the
heritability is set to either a plausible limit of 0.25 or 0.75. Boiling-off rates vary among
communities but 0.10 (i.e. 10% of youth choose to leave per generation) is a reasonable
contemporary value.

Following standard practice in quantitative genetics it is now assumed that AQ has an
underlying normal or Gaussian distribution in the Amish population. The 10% boiling-off
rate is equivalent to losing the bottom 10% of that distribution each generation. It is also
assumed that the boiling-off mechanism is equivalent to truncation selection, but other
selection schemes will have some equivalent alternative truncation point.

With 10% with the lowest AQ leaving each generation, the average AQ of those who
remain is 0.20 standard deviations if the population mean before emigration was 0. In
other words this amount of self-selective emigration leaves behind a population whose
average AQ is 0.2 standard deviations greater than it was before the emigration. Assume
that mating occurs exclusively within the Amish. Fixing the heritability of AQ at 0.5
means that the offspring will regress halfway back to their parental mean.

The next generation of children will therefore have an average AQ of 0.10 standard
deviations greater than their parents did before emigration. The process of selective
emigration repeats each generation, increasing the mean Amish AQ by one-tenth of a
standard deviation per generation. With 25 years per generation, ‘Amishness’ will
increase by a full standard deviation in ten generations, or 250 years, unless changes in
gene frequency lead to changes in heritability. This is substantial social evolution on a
time scale of a few centuries.

The modelled AQ of an individual is simply the value of that individual along the
x-axis of the right panel of Fig. 2. The computed standard deviations of AQ for the
Amish and non-Amish subjects are 1.33 and 1.31 respectively, giving the within-group
standard deviation to be 1.32 units. Interestingly the variances within groups, i.e. the
squared within-group standard deviations, differ very little. It is not an unusual finding

24 M. D. Weight and H. Harpending

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in experiments that selection has only small effects on the variance of a selected
population. Falconer and Mackay (1995) discussed the outcome of experiments at length
in their chapter 12.

The means of the two groups are − 1.4 (Amish) and 1.4 (non-Amish) units. Their
difference, corresponding to the distance between the two group means, is 2.8 units. Our
model implies a difference of this magnitude requires 28 generations, or 700 years, which
is substantially longer than the Amish have been in the United States. This may suggest
that the heritability of AQ is higher than the assumed 0.5, that the boiling-off rate was
higher in the past (for which there is support), or that the process has been going on
longer than ten generations. This last possibility is unlikely. Currently no Old-Order
exist in Europe. Persecution and political sanctions in the 17th and 18th centuries had
spread European Amish families too far apart to form cohesive communities, forcing
early European Amish to eventually assimilate with non-Amish (Gascho, 1937;
Hostetler, 1977; Crowley, 1978; Nolt, 1992; Roth, 2002). Thus the magnitude of
Amish endogamy was probably negligible in Europe compared with Amish endogamous
mating in the United States. If correct, this suggests the Old-Order tenure in Europe did
not contribute to the differences reported here.

Taking the results shown in Fig. 2 at face value implies the between-group difference
(2.8 standard deviations) is too large to be attributable to just simple genetic change with
a predicted difference of 1.0 standard deviations, or 1.5 standard deviations if
heritability is assumed to be as high as 0.75. The best conclusion from comparing the
data with the simple genetic model is that other social forces, e.g. family transmission,
are mostly responsible for the difference between the Amish and non-Amish young men.

Homicide decline in European history

Much of quantitative genetics is about some measurable metric character in a
population. A convenient and useful way to study many discrete characters is to treat
them as threshold characters that only manifest when an underlying hidden quantitative
trait exceeds some threshold. Cleft palate, for example, is a failure of the palate to close
at the midline during intrauterine development. There is an underlying metric trait in the
model that is the strength of the mechanism leading to midline fusion. Fusion fails for
trait values below a threshold strength of this mechanism. The model further specifies
what the incidence should be in relatives of varying degree. It predicts cleft palate risk in
relatives of those affected quite closely (Fraser, 1970).

Cloninger et al. (1975b) proposed a threshold model for the prevalence of sociopathy
and hysteria in humans. In their model both disorders reflect the same underlying
heritable trait but the sociopathy liability threshold in females is higher than the male
threshold. They consider hysteria to be a less deviant form of sociopathy in women
whose liability is above the male, but below the female, threshold. Sociopathy prevalence
in the general population, the higher proportion of sociopathy among relatives of female
sociopaths, and the clustering of both male and female sociopaths within families closely
fit the predictions of the model (Cloninger et al., 1975a, b).

Eisner (2001) tabulated the historical decline in homicide rates, excluding war deaths,
in several European countries from the fourteenth to the twentieth century. A typical

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finding is that homicide rates fell from 40 per 100,000 people in 1300 to 1 per 100,000 in
1900, a forty-fold decline. This striking social change seems ‘large’. A threshold model is
considered to sharpen this intuition.

This simple model posits that the propensity to murder is a normally distributed trait
in the population. Individuals with high propensity will murder while those with low
propensity will not. Following Eisner the threshold for homicide is placed at 40/100,000.
Tables of the standard normal distribution show that this threshold corresponds to the
right tail of the propensity distribution beyond 3.35 standard deviations. After 600 years
the rate declined to 1 in 100,000, corresponding to the tail beyond 4.26 standard
deviations. If the whole distribution moved with no change in the variance, as expected
with the simple Fisher model, the shift was just 4.26 − 3.35≈0.9 standard deviation. On a
stature scale in which the standard deviation is 7.26 cm this corresponds to a change in
mean stature of 6.53 cm in 600 years. This amount of change in 600/25 or 24 generations
amounts to just over 1/4 cm per generation. This is in the order of known changes in
stature in European history. From this perspective the decline in homicide is not
especially remarkable at all and plausibly reflects genetic change. This is not to claim
that genetic change accounts for most of the decline in homicide. However, it does
suggest that this model is an informative yardstick for measuring how substantially
homicide rates declined.

Modifying the assumptions of this plausible quantitative genetics model yields some
insight into its robustness. Assume, for example, that murderers have a variable number
of victims and that the average number of victims is two. Since the average number of
homicides per murderer is two, the thresholds are estimated by a decline from 20 to 0.5,
rather than 40 to 1, per 100,000 people. These numbers correspond to 3.54 and 4.42
standard deviations on the right of normal curves. The change is therefore about 0.9
standard deviation – the same result found in the simple model. The qualitative
conclusion of unremarkable change in 600 years remains the same.

A perhaps more realistic elaboration of the model is that murderers murder other
murderers. The homicide rate under these conditions reflects not the density, but the
square of the density, of murderers assuming a mass action rate of random encounters
between murderers. In this case the change in the square root of the homicide rates is
looked at so that the tails of this distribution in 1300 and 2000 are respectively at 2.73
and 2.05 standard deviations to the right of the mean. This elaborated model predicts a
shift in the distribution of just 0.7 standard deviation, even less than in the simple model.
It is concluded that the simple quantitative genetic model is fairly robust to
perturbations. Frost and Harpending (2014) examined English homicide and
execution rates, in addition to death rates of murderers awaiting trial, during this
period in more detail. They also concluded that genetic transmission could account for
much of the social change.

Conclusions

In this paper an index was constructed from responses to a personality questionnaire
that distinguishes Old-Order Amish from their non-Amish neighbours. The associated
genetic model posited that the differences between the two populations are a

26 M. D. Weight and H. Harpending

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consequence of selective ‘boiling-off’ of Amish individuals over time. This process is
equivalent to truncation selection from the viewpoint of the Amish population since
those who found the community least congenial left. This example illustrates that groups
in particular demographic or occupational niches with reproductive assortment can
undergo genetic change that significantly differentiates them from other groups.

The data suggest that the simple model incompletely accounts for the observed group
differences. Even if the heritability of AQ is high, differences accumulate under genetic
transmission at about 0.1 standard deviations per generation. The difference between the
group means is 2.8 standard deviations. If this difference were a consequence of purely
genetic change such a difference would require 28 generations, or 56 generations with a
more reasonable heritability estimate of 0.25. Historical evidence suggests that the pattern
is no older than ten generations. The implication is that the cultural difference between the
Amish and their neighbours reflects mostly strong cultural transmission. Unfortunately,
previous cultural transmission models of Amish defection proposed by Markle and Pasco
(1977), Ericksen et al. (1979, 1980), Meyers (1991, 1994), Wasao and Donnermeyer (1996)
and Greksa (2002) give only plausibility arguments that are difficult to quantify and falsify.
On the other hand, quantitative genetic theory is well established in agriculture and other
areas of biology like biometrics and conservation biology. The present study illustrates the
utility of quantitative genetic models as a useful yardstick for describing social traits and
evaluating transmission models, suggesting that quantitative genetics deserves more
attention and use in human evolutionary biology.

The historical decline in European homicide rates since the fourteenth century was
also considered. Gregory Clark (2007) described this decline as part of a larger heritable
change in Europe leading up to the Industrial Revolution. Several variants of a simple
model of selection against homicide indicate such genetic change is entirely plausible.

Acknowledgments

The authors thank Adrian Bell, Stephen Beckerman, Elizabeth Cashdan, Gregory
Cochran, James Lee, Alan Rogers and Ryan Schacht for their comments and criticisms,
which substantially improved this paper.

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	Some Uses of Models of Quantitative Genetic Selection in Social Science
	Introduction
	Thought experiment
	The Old-Order Amish
	Assortative mating
	Endogamy
	The 16PF

	Table 1Factors assessed in the 16F questionnaire
	Fig. 1Principal components analysis (PCA) of 16PF score differences among groups of 18- to 20-year-old Indiana men. The left panel portrays similarities (i.�e. correlations) among the sixteen traits listed in Table�1. The right panel portrays differences 
	Fig. 2Principal components analysis (PCA) of individual 16PF scores of 18- to 20-year-old Indiana men. The left panel portrays similarities among traits, and the right panel among individuals along with the overall UK population. Trait labels are given in
	A model of (self-)selection

	Homicide decline in European history
	Conclusions
	Acknowledgments
	ACKNOWLEDGEMENTS
	References