untitled


Proc. R. Soc. B (2011) 278, 2519–2527

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*rer3@e

Electron
10.1098

doi:10.1098/rspb.2010.2504

Published online 12 January 2011

Received
Accepted
Religion, fertility and genes: a dual
inheritance model

Robert Rowthorn*

Faculty of Economics, Cambridge University, Sidgwick Avenue, Cambridge CB3 9DD, UK

Religious people nowadays have more children on average than their secular counterparts. This paper

uses a simple model to explore the evolutionary implications of this difference. It assumes that fertility

is determined entirely by culture, whereas subjective predisposition towards religion is influenced by gen-

etic endowment. People who carry a certain ‘religiosity’ gene are more likely than average to become

or remain religious. The paper considers the effect of religious defections and exogamy on the religious

and genetic composition of society. Defections reduce the ultimate share of the population with religious

allegiance and slow down the spread of the religiosity gene. However, provided the fertility differential

persists, and people with a religious allegiance mate mainly with people like themselves, the religiosity

gene will eventually predominate despite a high rate of defection. This is an example of ‘cultural hitch-

hiking’, whereby a gene spreads because it is able to hitch a ride with a high-fitness cultural practice.

The theoretical arguments are supported by numerical simulations.

Keywords: religion; fertility; evolution; genetic predisposition; cultural hitch-hiking; evolution
1. INTRODUCTION
It is widely agreed that religion has biological

foundations—that belief in the supernatural, obedience

to authority or susceptibility to ceremony and ritual

depend on genetically based features of the human

brain [1 – 6]. However, there is a disagreement about the

extent to which causality also flows in the opposite direc-

tion, from religion to biology. One view is that religion is a

‘spandrel’—a cultural phenomenon based on features of

the brain that were already in existence in their present

form when religion first appeared (e.g. [7 – 12]). Another

view is that the existence of religion promotes the evol-

ution of genes that predispose people towards religious

belief or behaviour. The latter view rests upon two plaus-

ible assumptions: (i) individuals have diverse endowments

of the genes that predispose humans towards religion; and

(ii) religion-induced selection is strong enough to have an

appreciable impact within the relevant time-frame on the

frequency of such genes.

The fact that religion has a genetic basis of great

antiquity does not imply that genetic variation has

disappeared. Koenig & Bouchard [13] survey twin studies

that quantify the genetic and environmental determinants

of what they call the ‘traditional moral triad’ of auth-

oritarianism, conservatism and religiousness. In most

cases, 40 to 60 per cent of the observed variation in

such personality traits is explained by genotypic variation.

The authors argue that these are large genetic effects in

comparison with typical findings in the social sciences.

There is no direct evidence regarding the speed with

which religion affects genetic evolution. However, there

is evidence that the rise of complex human culture in gen-

eral has greatly accelerated the pace of genetic evolution,

by altering the frequency of long-standing genes in the
con.cam.ac.uk

ic supplementary material is available at http://dx.doi.org/
/rspb.2010.2504 or via http://rspb.royalsocietypublishing.org.

18 November 2010
14 December 2010 2519
global population and by spreading or preserving new

mutations [14 – 19].

For religion to influence genetic evolution it must convey

some kind of selective advantage. Such an effect might

come about through social bonding via ritual, formation

of group identity through myth, honest signalling through

participation in costly ceremonies and adherence to social

norms through love or fear of God [20 –24]. In most

cases, religious individuals gain personal advantage from

their activities or beliefs. However, religion may also

induce behaviour that has a fitness cost to the individual

but is beneficial to the group. If group selection is strong,

this should favour the emergence of a type of religion that

induces adherence to pro-social norms, which in turn

should favour the evolution of genes that predispose

individuals towards this type of religion [25– 27].

Another channel through which religion might influ-

ence genetic evolution is via its impact on fertility. The

link between religion and fertility has been extensively dis-

cussed by demographers, but, as Bouchard [28] notes,

the potential genetic implications of this link have been

largely ignored by evolutionary theorists.
(a) Religion and fertility

In the modern world, religious people, even controlling

for income and education, have more children on average

than people without religion [29,30]. The reasons are cul-

tural in the broad sense, and include social norms and the

influence exerted by religious organizations [31 – 34]. The

more devout people are, the more children they are likely

to have. The World Values Survey for 82 nations over the

period 1981 – 2004 reveals that adults attending divine

service more than once a week averaged 2.5 children,

those attending once per month averaged 2.01 and

those never attending averaged 1.67 (cited in [12]). Similar

findings for a variety of European countries are reported by

Philipov & Berghammer [35]. Sects such as the Amish,

the Hutterites and Haredi (‘ultra-orthodox’) Jews have
This journal is q 2011 The Royal Society

mailto:rer3@econ.cam.ac.uk
http://dx.doi.org/10.1098/rspb.2010.2504
http://dx.doi.org/10.1098/rspb.2010.2504
http://dx.doi.org/10.1098/rspb.2010.2504
http://rspb.royalsocietypublishing.org
http://rspb.royalsocietypublishing.org


2520 R. Rowthorn Religion, fertility and genes

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1 
total fertility rates three to four times greater than the

secular average [36,37].

Modern fertility differentials partly reflect diverse

responses to the ‘demographic transition’. Global birth

rates have fallen dramatically in recent times and in a

number of countries, including Japan and most of

Europe, they are now well below replacement [38 – 40].

However, the transition to lower fertility has been

slower and less complete among religious people than

among those without religion, since it is driven partly by

individualistic values of self-fulfilment that are inimical

to traditional religious teaching [32,41]. The pace and

extent of the transition also vary across religions and

denominations [42 – 44]. Some religious groups have

been largely unaffected by the demographic transition

and still have extremely high birth rates, which explains

why there is now such an enormous fertility gap between

them and the rest of the population.

The impact of differential fertility on the religious

composition of society depends on the scale of switching

between religious groups, and between them and the

secular population. With no defections at all, ultra-high

fertility groups would rapidly outgrow the rest of the

population and soon become a majority. In practice,

there may be limits to their expansion. As they get

larger, their members may come into closer contact

with other members of society and acquire secular

values, causing them to have fewer children [45]. Some

members may leave to join a less strict group, whereas

others may give up religion altogether. For example, the

Old Order Amish have a total fertility rate of 6.2, whereas

the more modern New Order Amish have a somewhat

lower total fertility rate of 4.8 (p. 36 in [37]). What will

happen in the future is a matter of speculation. Kaufmann

[37] argues that the stricter religious groups will continue

to exhibit high fertility and will also be effective at trans-

mitting their beliefs to their children, so that relatively few

of them will defect in later life. This would represent a

continuation of recent history, which has seen the

number of Amish in the USA rise from 123 000 in

1991 to 249 000 in 2010—due almost entirely to internal

growth [46]. Sustained growth at this rate would take the

Amish population to almost 7 million by the end of the

century and 44 million by 2150. Rapid fertility-driven

growth has also been observed among other groups

such as Hutterites and Haredi Jews [36,37]. If growth at

such rates were to continue, it would speedily turn what

is currently a tiny fraction of the population into a

majority. Indeed, this will inevitably happen unless the

forces of secularism constrain the growth of these

groups by reducing their birth rates or increasing their

defection rates.
(b) Genetic implications

There are two channels through which a high fertility

group can influence the composition of the overall gene

pool: internal growth and defection. If most of the chil-

dren born within a high fertility group remain in the

group when they grow up, the size of this group will

increase rapidly and its share of the overall gene pool

will rise accordingly. Conversely, if most of the children

eventually leave, this will limit the size of the group. How-

ever, such defections will also spread the group’s genes
Proc. R. Soc. B (2011)
into the surrounding population, thereby increasing

their share in the overall gene pool. The role of defection

in this context is similar to that of migration in Sewall-

Wright’s [47] shifting balance theory of evolution,

whereby a mutation may spread outwards from a high-

fitness group to the rest of the population. These two

channels—internal growth and diffusion through defec-

tion—may have radically different implications for the

eventual size of the high fertility group, but their long-

run genetic implications may be similar. In each case,

the genes associated with the high-fertility group may

eventually predominate in the overall gene pool. The pic-

ture is further complicated by the existence of conversion,

whereby individuals join the high-fertility group, and by

exogamy, whereby individuals remain in the group but

marry an outsider who does not convert.

To explore these issues we shall consider some simple

mathematical models. These models are in the gene-culture

tradition [19] and draw heavily on the work of Boyd &

Richerson [48] regarding direct bias, vertical transmission

and the natural selection of cultural variants. The models

are of the dual inheritance type, in which children inherit

both their genes and their initial religious (or non-reli-

gious) allegiance from their parents. They retain their

genes throughout their lives, but they may eventually

change their allegiance. Children who are brought up as

religious may abandon religion when they grow up,

whereas those brought up without religion may later con-

vert and become religious. The probability of switching

allegiance in our models depends on the genetic endow-

ment of the individual concerned. A child who is

genetically predisposed towards religion is more likely

than other children to remain or become religious as an

adult. Throughout the analysis we shall assume that ferti-

lity is an entirely cultural phenomenon: genes affect the

likelihood that particular individuals will be religious,

but do not directly influence their reproductive behaviour.

All religious adults (‘believers’) have the same fertility

irrespective of their genes; likewise non-believers have

the same fertility irrespective of their genes. There is

some evidence from a Danish twin study that genes

have an independent influence on the desire of people

to have children [49], but we shall ignore this compli-

cation. We initially assume complete assortative mating,

whereby religious people mate only with other religious

people. One or both of the partners may be converts,

but there are no truly mixed couples in which the partners

retain distinct allegiances. This assumption is realistic for

ultra-high-fertility Jewish and Christian groups [50], and

also for Muslims in general [51], but is less realistic for

mainstream Christian Churches whose members nowa-

days frequently marry members of other Churches or

people of no religion at all. We later consider how the

existence of mixed marriages between religious and

non-religious people affects the results.

We begin with a haploid model in which the rules of

genetic transmission are simple and rates of religious

defection and conversion are fixed. This model is later

modified to allow for more complex genetic transmission

and for variable rates of defection and conversion. Such

modifications do not affect the qualitative results,

although they may have important quantitative impli-

cations. In all of the models we consider, religious

predisposition (‘religiosity’ for short) is determined by a



Religion, fertility and genes R. Rowthorn 2521

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single gene. This is unlikely to be true in practice, but

without this simplification the analysis would be

intractable.
2. A HAPLOID MODEL OF DUAL INHERITANCE
Society is divided into two distinct allegiance groups

indexed by i ¼ r, n. Members of group r are religious

‘believers’ whereas members of group n are ‘non-believ-

ers’. All individuals have two cultural parents who are

also their genetic parents. Individuals live for two periods.

They acquire their genes from their parents and during

the first period as children they acquire their initial alle-

giance from their parents. They then become adults and

choose whether to retain or modify their allegiance.

Next they have children of their own, bring them up

and then die. The probability that a child will switch alle-

giance on becoming an adult depends on its genetic

endowment, which is specified by a single gene at a

specific locus. Each individual carries exactly one copy

of this gene. The gene comes in two forms (‘alleles’)

that are indexed by j ¼ R, N. The ‘religiosity’ allele

R codes for religious predisposition and allele N codes

for non-religious predisposition. Thus, there are four

distinct types in the population:

ðr; RÞ;ðr; NÞ;ðn; RÞ;ðn; NÞ:

Dynamics depend on fertility and mating. We assume

that adults mate only with adults from the same allegiance

group. Each couple in group i has 2ci (.0) children.

These children initially have the same allegiance as their

parents, and the genetic endowment of each child is

inherited with equal probability from either parent.

Let X ij ðtÞ be the number of adults at time t with allegiance
i and allele j. Every adult of type (i, j) gives rise to ci chil-

dren of type (i, j). For example, if two adults of type (r, R)

mate they will have 2cr children of type (r, R), which is

equivalent to cr children of this type for each parent. If

an adult of type (r, R) mates with an adult of type

(r, N) they will on average have cr children of type

(r, R). The total number of children of type (r, R) is

therefore cr X
r
RðtÞ.

The genetic composition of an individual is fixed for

life, but there may be a change of allegiance when a

child reaches adulthood. This will alter the distribution

of adult types in the next period. Let srjð j ¼ R; NÞ be
the probability that a child of type (r, j) will switch

allegiance to type (n, j) as an adult. Likewise, snj is the

probability that a child of type (n, j) will switch to type

(r, j) as an adult. In principle, these switching parameters

could vary through time as a result of wider social

trends or they might be density-dependent. For the

moment we shall assume they are constant. Taking

switches into account, the number of adults of each

type in the next period is given by the system of difference

equations

X rRðt þ 1Þ¼ ð1 � s
r
RÞcr X

r
RðtÞþ s

n
RcnX

n
RðtÞ;

X nRðt þ 1Þ¼ s
r
Rcr X

r
RðtÞþð1 � s

n
RÞcnX

n
RðtÞ;

X rNðt þ 1Þ¼ ð1 � s
r
NÞcr X

r
NðtÞþ s

n
N cnX

n
NðtÞ

and X nNðt þ 1Þ¼ s
r
N cr X

r
NðtÞþð1 � s

n
NÞcnX

n
NðtÞ

9>>>=
>>>;
:

ð2:1Þ
Proc. R. Soc. B (2011)
The right-hand side of each equation contains two com-

ponents. One component denotes individuals who have

retained their childhood allegiance and the other denotes

newcomers who have switched allegiance from the other

group.

For any type (i, j) define the fraction of this type in the

adult population as follows:

pijðtÞ¼
X ij ðtÞP
l;m X

l
mðtÞ

:

Thus, pijðtÞ is the fraction of the adult population who
belong to group i(¼ r, n) and carry allele j(¼R, N). Also,

define

piðtÞ¼ piRðtÞþ p
i
NðtÞ for i ¼ r; n

and

pjðtÞ¼ prjðtÞþ p
n
j ðtÞ for j ¼ R; N:

Thus, p
i
(t) is the fraction of the adult population who

belong to group i and pj(t) is the fraction who carry allele j.

Note that p
r
(t) þ pn(t) ¼ pR(t) þ pN(t) ¼ 1.
(a) Modelling predisposition

The religiosity allele R codes for a genetic

predisposition towards religion. In the present context,

this means that at least one of the following conditions

must hold:

— Among children who are brought up without

religion, those who carry allele R are more likely

to become religious in adult life than those with

allele N.

— Among children who are brought up as

religious, those who carry allele R are less likely to

abandon their religion in adult life than those with

allele N.

To express the above conditions mathematically we

impose the following conditions on the switching

parameters:

snR � s
n
N and s

r
R � s

r
N; ð2:2Þ

with at least one strict inequality. These conditions are

symmetric. If R codes for a predisposition towards mem-

bership of group r then allele N codes for a predisposition

towards membership of group n. The above definition of

predisposition is similar to that of Lumsden &

Wilson [52].
(b) Long-run behaviour

We can now state a simple but powerful result. We assume that

0 , sij , 1 for all i; j and also pRð0Þ¼ prRð0Þþ pnRð0Þ . 0;
pNð0Þ¼ prNð0Þþ pnNð0Þ . 0: Thus, for each type there is a
non-zero switching between groups and both alleles are

initially present in the population.

Proposition 2.1. Suppose that the predisposition

conditions (2.2) are satisfied. Suppose further that members

of group r have more children than those of group n, such that

cr . cn: ð2:3Þ



Table 1. Effect of fertility on the evolution of religion and genes. This table illustrates how differential fertility affects social

and genetic evolution. The table assumes that srR ¼ 0:3; srN ¼ 0:4; snR ¼ 0:004; snN ¼ 0:003. All trajectories begin at the point
prRð0Þ¼ 0:005; prNð0Þ¼ 0; pnRð0Þ¼ 0; pnNð0Þ¼ 0:995.

differential fertility

generations elapsed

0 10 20 100 500 1

cr/cn share of population who are religious ¼ p
r

3.0 0.005 0.500 0.545 0.552 0.552 0.552
2.0 0.005 0.143 0.347 0.406 0.406 0.406

1.5 0.005 0.026 0.035 0.135 0.147 0.147
1.3 0.005 0.014 0.014 0.014 0.024 0.038
1.1 0.005 0.009 0.009 0.009 0.009 0.017

cr/cn frequency of religiosity allele R ¼ pR
3.0 0.005 0.782 0.955 1.000 1.000 1.000

2.0 0.005 0.226 0.754 1.000 1.000 1.000
1.5 0.005 0.034 0.076 0.905 1.000 1.000
1.3 0.005 0.015 0.019 0.038 0.414 1.000
1.1 0.005 0.007 0.007 0.008 0.011 1.000

2522 R. Rowthorn Religion, fertility and genes

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Then, in the long-run, the distribution of types in the

population will converge to a limit of the following kind:

lim
t!1

prRðtÞ¼ p̂
r
R . 0;

lim
t!1

pnRðtÞ¼ p̂
n
R . 0;

lim
t!1

prNðtÞ¼ 0

and

lim
t!1

pnNðtÞ¼ 0:

Hence

lim
t!1

pRðtÞ¼ 1 and lim
t!1

pNðtÞ¼ 0: ð2:4Þ

Proof. See the electronic supplementary material. B

Thus, if religious allegiance is associated with a higher-

than-average birth rate, and there is an allele that

predisposes individuals towards religion, this allele will

eventually predominate. The fraction of individuals who

are ‘believers’ will stabilize at less than 100 per cent and

there will remain a finite percentage of adults who are

without religion. In the limit, all of the latter will carry

the religiosity allele R. It must be stressed that this

result is contingent on the assumption that cr . cn.

In the opposite case (cr , cn), allele N would eventually

predominate.

(c) Role of the predisposition conditions

To understand the role of the predisposition conditions

(2.2), consider what happens when these conditions do

not hold. Suppose the probability of switching between

groups is positive and independent of a person’s geno-

type, so that snR ¼ snN and srR ¼ srN: Suppose also that
both alleles are initially present in the population. In

this case, the system will eventually settle down to a

stable genetic polymorphism in which the genetic compo-

sition of groups r and n is identical, and alleles R and N

coexist in finite proportions. The ultimate frequency of

these alleles in the population as a whole will depend on

the starting point.

The outcome is different if the predisposition con-

ditions (2.2) hold. These conditions establish a bias in
Proc. R. Soc. B (2011)
the pattern of inter-group flows and ensure that, irrespec-

tive of starting point, allele R will eventually become

over-represented in the high fertility group r. From then

onwards R will enjoy a growth advantage over allele N,

whose share in the overall gene pool will converge to

zero. The correlation between cultural phenotype (alle-

giance r) and genotype (allele R) is endogenous and is

subject to forces that ensure that, in the long run, this

correlation is positive. This is an example of ‘cultural

hitch-hiking’, whereby a gene spreads because it is able

to hitch a ride with a high-fitness cultural practice [18].
(d) Fertility and the pace of evolution

The pace of evolution and the eventual share of religion in

the population both depend on the fertility differential

between religious and non-religious people. This is illus-

trated in table 1. When the relative fertility of the

religious group is ultra-high (cr/cn ¼ 3), the pace of

change is extremely fast. Within 10 generations, the

share of adults with a religion rises from 0.5 to 50 per

cent and the share of the religiosity allele R in the overall

gene pool rises to more than 95 per cent. With cr/cn ¼ 2,

the pace of change is still fast. Within 10 generations,

the share of adults with religion rises from 0.5 initially

to 14.3 per cent and the share of allele R in the gene

pool rises to 22.6 per cent. As relative fertility is further

reduced, the pace of change slows down dramatically

and the eventual share of religion is much lower. With

cr/cn ¼ 1.3, the share of adults with a religion is only 1.4

per cent after 100 generations and the share of allele

R is only 3.8 per cent. It takes 500 generations for the

share of R to surpass 40 per cent.
(e) Ultra-high fertility sects

The rate of expansion of ultra-high fertility sects depends

on their ability to retain their membership. If all of their

children were to remain members for life and had the

same ultra-high fertility as their parents, then within just

a few generations these sects would dominate the social

landscape. If a large number of children leave these

sects on reaching adulthood, this will limit their expan-

sion. However, it will not prevent the spread of the



0

0.5

1.0(a)

2 4 6 8 10 12 14 16 18 200

0.5

1.0

generations elapsed

(b)

Figure 1. How religious defections influence social and gen-
etic evolution. The diagrams refer to an ultra-high-fertility
religious group. (a) Share of believers; (b) share of allele R.
A high defection rate reduces the eventual share of religious
believers (group r) in the population. Whatever the defection
rate, the religiosity allele R eventually tends to fixation. The
diagram assumes: both variants: cr/cn ¼ 3.0; pR

r
(0)¼0.005,

p
r
N (0)¼0, pR

n
(0)¼0, pN

n
(0)¼0.995; low defection:

sR
r
¼0.05, sN

r
¼0.07, sR

n
¼0, sN

n
¼0; high defection: sR

r
¼0.5,

sN
r
¼0.07, sRn¼0, sN

n
¼0. Line without diamonds, low

defection; Line with diamonds, high defection.

Religion, fertility and genes R. Rowthorn 2523

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genes that predispose individuals towards religion

(assuming such genes exist).

Figure 1 provides a numerical illustration of a closed

ultra-high fertility sect that recruits no one from the out-

side. The birth rate of its members is three times as high

as that of outsiders. The membership of the sect is

initially 0.5 per cent of the adult population. All members

of the sect carry the religiosity allele R, whereas initially

no one outside the sect carries this allele. What happens

in the course of time depends on the ability of the sect

to retain its members. Two scenarios are shown in

figure 1. In the low defection scenario, 5 per cent of

adult members leave the sect each generation. This is

the observed defection rate for Old Order Amish children

born in the 1960s [53]. In the high defection scenario, the

figure is 50 per cent. The most striking feature of the low

defection scenario is the pace of change. Within four gen-

erations, one fifth of the adult population belong to the

sect and after 10 generations its share stabilizes at

92 per cent. By then almost every adult in the population

carries allele R, and the other allele is well on the way to

oblivion. Under the high defection scenario, the pace of

change is much slower and the eventual share of the

population who are religious is much lower. Even so,

after 20 generations, the vast majority of the population

carry allele R. Such a situation comes about because in

each generation a large number of adults who are carrying

R abandon their religion and feed this allele into the non-

religious population. This example illustrates the

paradoxical role of secularization in spreading the religios-

ity allele. Secularization reduces the growth rate of the

ultra-high fertility sect, but it does so by importing into

the non-religious population a large number of people

who carry the religiosity allele. Religion may be kept in

check by defections from the sect, but this does not

prevent the ultimate triumph of the religiosity allele.
3. A DIPLOID MODEL
The above analysis can be extended to the diploid case in

which individuals carry two alleles rather than one. In this

version, there are three genetic types and two cultural

types, which can be combined as follows:

ðr; RRÞ;ðr; RNÞ;ðr; NNÞ;ðn; RRÞ;ðn; RNÞ;ðn; NNÞ:

We assume that adults mate at random with adults

from the same group and that one gene is inherited

with equal probability from each parent. Each type

(i, jk) has a given probability sijk of switching to the

other allegiance group. Note that sijk ¼ sikj . The difference
equations are more complicated than in the haploid case

(see the electronic supplementary material).

In the diploid case, allele R codes for a genetic predis-

position towards r provided the following inequalities are

satisfied:

snRR; s
n
RN � s

r
NN and s

r
RR; s

r
RN � s

r
NN; ð3:1Þ

with at least one strict inequality. The level of dominance

is specified by the equations

srRN ¼ h
r srRR þð1 � h

rÞsrNN
and snRN ¼ h

nsnRR þð1 � h
nÞsnNN

)
: ð3:2Þ
Proc. R. Soc. B (2011)
If 1 � hr, hn � 0, then

snRR � s
n
RN � s

r
NN and s

r
RR � s

r
RN � s

r
NN; ð3:3Þ

with at least one strict inequality. Allele R is completely

dominant if h
r
¼ h

n
¼ 1 and completely recessive if h

r
¼

h
n
¼ 0. The properties of the diploid version were

explored by simulation, using 2700 distinct parameter

combinations for R dominant and the same number for

R recessive, together with a further 2700 for the inter-

mediate case h
r
¼ h

n
¼ 0.5. All of these parameter

combinations satisfy the predisposition conditions (3.3)

and in all of them cr . cn. Initial gene frequencies

are prRð0Þ¼ 0; prNð0Þ¼ 0:005; pnRð0Þ¼ 0:005 and
pnNð0Þ¼ 0:99: Thus only a very small proportion of the
adult population are initially religious and all of these

individuals carry allele N. Even so, in every case, the

gene R eventually takes over and the other allele goes to

oblivion. This is identical to the result obtained in the

haploid case. However, the pace of convergence is

slower in the diploid case, especially when R is recessive.

Figure 2 shows what happens to the overall frequency of R

in one particular example.
(a) Density dependence

The decision to switch may depend on the relative size

of the two groups. We model this by assuming that, for

i ¼ r, n and j, k ¼ R, N

sijk ¼ max½slow; minða
i
jk½1 þ b

i piðtÞ�; shighÞ�; ð3:4Þ

where aijk and b
i

are constant and 0 , aijk; slow; shigh , 1.
These assumptions ensure that 0 , sijk , 1.

If b
i
. 0, the probability of defecting from group i

increases as this group gets larger. In the case of religion,

this could occur because the religious group becomes

‘softer’ and less able to police its boundaries as its relative

size increases. The group may also become less isolated as



5 10 15 20 25 30 35 400

0.1

0.2

0.3

0.4

0.5

0.6

0.7

0.8

0.9

1.0

generations elapsed

Figure 2. What happens to the share of allele R in the hap-
loid and diploid versions of the model. R achieves fixation
fastest in the haploid version of the model and slowest in
the recessive diploid version. The diagram assumes: all var-

iants: cr/cn ¼ 3.0; pR
r

(0)¼0.005, pN
r

(0)¼0, pR
n

(0)¼0, pN
n

(0)¼0.995; haploid: sR
r
¼0.3, sN

r
¼0.6, sR

n
¼0.05, sN

n
¼0.05;

diploid: sRR
r
¼0.3, sNN

r
¼0.6, sRR

n
¼0.05, sNN

n
¼0.05; R domi-

nant: sRN
r
¼sRR

r
, sRN

n
¼sRR

n
; R recessive: sRN

r
¼sNN

r
, sRN

n
¼sNN

n
.

Line with circles, diploid þ R dominant; line with dia-
monds, diploid þ R recessive; line without circles or
diamonds, haploid.

0
0.1
0.2
0.3
0.4
0.5
0.6(a)

(b)

2 4 6 8 10 120

0.5

1.0

generations elapsed

Figure 3. The evolutionary effects of a constraint on the

growth of a high-fertility religious group. Defections
increase as the group gets bigger, which limits the eventual
size of this group. However, large-scale defections spread
the religiosity allele R into the rest of the population. The
diagram assumes: both variants: cr/cn ¼ 3.0; pR

r
(0)¼0.005,

pN
r

(0)¼0, pR
n

(0)¼0, pN
n

(0)¼0.995; aRR
r
¼aRN

r
¼0.3,

aNN
r
¼0.4, aRR

n
¼aRN

n
¼aNN

n
¼0; b

n
¼0; no constraint: b

r
¼0,

constraint: b
r
¼220. Note: sjk

i
(t)¼ajk

i
[12b

i
p

i
(t)]. Line

without diamonds, no constraint; line with diamonds,

constraint.

2524 R. Rowthorn Religion, fertility and genes

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1 
it gets larger and a greater fraction of its members come

into contact with the secular world [45].

If b
i
,0, the probability of defecting from group i

decreases as this group gets larger. This could be because

group i becomes a world unto itself as it gets larger, so

that individuals from this group have fewer contacts

with outsiders and, in consequence, are less frequently

exposed to ideas or pressures that subvert their allegiance.

For R to code for a predisposition towards religion, the

following conditions must be satisfied:

anRR; a
n
RN � a

r
NN and a

r
RR; a

r
RN � a

r
NN; ð3:5Þ

with at least one strict inequality.

(b) Simulations

The simulations reported in the online material indicate

that proposition (2.1) holds even in the diploid model

with density-dependent behaviour. The allele R will even-

tually take over, provided it satisfies the relevant

predisposition conditions and cr . cn. Moreover, the

share of the religious group r will eventually stabilize at

less than 100 per cent. Figure 3 provides an illustration

in which the growth of the religious group is severely con-

strained by defection as it gets larger, so that it never

attains more than 5.5 per cent of the total population.

Even so, because of this group’s high birth rate, there is

a stream of defectors who take the religiosity allele R

with them into the non-religious population.

(c) Mixed marriages

The discussion has so far assumed strict endogamy within

the two allegiance groups. The partners in a couple may

come from different backgrounds, but they have a

common allegiance by the time they mate. In this section,

we consider briefly what happens if there are mixed mar-

riages in which the two partners retain distinct
Proc. R. Soc. B (2011)
allegiances. Our approach draws on the biology literature

on imprinting (especially [54], but also [55,56]). We

make the following assumptions. A constant fraction ai
of adults from allegiance group i will only mate with

someone from their own group. This preference is unre-

lated to their genetic type. The remaining adults are

indifferent towards the allegiance of their partner and

they mate randomly with each other. Some of them find

a partner from their own group and some a partner

from the other group. Mixed couples have 2cm children,

of which a fraction fr receives a religious upbringing.

The relevant difference equations are derived in the

electronic supplementary material.

The evolution of the system was explored numerically

for a number of parameter combinations. The con-

clusions are as follows. Provided the religious group has

higher fertility than the non-religious group, there is

always a cultural polymorphism: the population share of

each group will eventually stabilize at a non-zero level.

If mixed marriages are ruled out, as in the preceding sec-

tions of this paper, allele R always tends to fixation.

However, if mixed marriages are permitted, there are

some parameter combinations for which the frequency

of allele R tends to 0. These are characterized by a low

preference for endogamy, combined with a low-to-

medium fertility advantage for the religious group. This

can be seen in the examples shown in rows (9), (13),

(17), (18), (21) and (22) of table 2. In most cases, even

where mixed marriages occur, R tends to fixation. More-

over, the greater is the preference for endogamy, as

indicated by the a parameters, the faster is the approach

to fixation. This can be seen from the penultimate

column of the table. The effect of mixed marriages in

these examples is to slow down the fixation of R and

sometimes prevent fixation of this allele altogether. Simi-

lar effects were observed in other simulations not reported

here. None of these simulations gave rise to a stable

genetic polymorphism.



Table 2. The effect of endogamy on the evolution of genes. This table illustrates how preferences for endogamy influence the

overall frequency pR of allele R in the adult population. The fraction of religious (non-religious) adults with a preference for
endogamy is ar (an). The number of children per mixed marriage is 2cm of which a fraction fr receive a religious upbringing;
couples in which both partners are religious (non-religious) have 2cr (cn) children. The table assumes that
srRN ¼ srRR ¼ 0:3; srNN ¼ 0:6; snRN ¼ snRR ¼ snNN ¼ 0:05: Trajectories all start from the point prRð0Þ¼ 0:005; prNð0Þ¼ pnRð0Þ¼ 0;
pnNð0Þ¼ 0:995.

row ar an fr cr/cn cm/cn pR(0) pR(20) pR(10
6
)

(1) 0 0 1 3 2 0.005 0.024 1.000
(2) 0.4 0.4 1 3 2 0.005 0.474 1.000

(3) 0.8 0.8 1 3 2 0.005 0.724 1.000
(4) 1 1 1 3 2 0.005 0.780 1.000
(5) 0 0 0 3 2 0.005 0.005 0.997
(6) 0.4 0.4 0 3 2 0.005 0.072 1.000

(7) 0.8 0.8 0 3 2 0.005 0.773 1.000
(8) 1 1 0 3 2 0.005 0.780 1.000
(9) 0 0 1 2 1.5 0.005 0.003 0.000
(10) 0.4 0.4 1 2 1.5 0.005 0.003 1.000
(11) 0.8 0.8 1 2 1.5 0.005 0.304 1.000

(12) 1 1 1 2 1.5 0.005 0.495 1.000
(13) 0 0 0 2 1.5 0.005 0,004 0.000
(14) 0.4 0.4 0 2 1.5 0.005 0.010 1.000
(15) 0.8 0.8 0 2 1.5 0.005 0.191 1.000
(16) 1 1 0 2 1.5 0.005 0.495 1.000

(17) 0 0 1 1.2 1.1 0.005 0.001 0.000
(18) 0.4 0.4 1 1.2 1.1 0.005 0.003 0.000
(19) 0.8 0.8 1 1.2 1.1 0.005 0.007 1.000
(20) 1 1 1 1.2 1.1 0.005 0.012 1.000
(21) 0 0 0 1.2 1.1 0.005 0.003 0.000

(22) 0.4 0.4 0 1.2 1.1 0.005 0.003 0.000
(23) 0.8 0.8 0 1.2 1.1 0.005 0.007 1.000
(24) 1 1 0 1.2 1.1 0.005 0.012 1.000

Religion, fertility and genes R. Rowthorn 2525

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4. DISCUSSION
This paper assumes that there exist genetic differences

between individuals that affect their predisposition

towards religion. In the same cultural environment,

some individuals are for genetic reasons more likely to

become or remain religious than others. It also assumes

that religious people have more children on average than

secular people. This gap may currently be quite small in

the case of mainstream Churches, but there are some reli-

gious groups that have fertility rates several times larger

than their secular counterparts. They also have high

rates of endogamy. If individuals from these groups

marry outsiders they must normally either leave the

group or else their partner must convert. Some of these

groups have been growing rapidly for the past century

but their future is uncertain. There are several possible

scenarios. Such groups may continue on their present tra-

jectory for the rest of this century and beyond, leading to

a spectacular and ultimately unsustainable increase in

their numbers. Or maybe their growth rates will slow

down quite soon because they experience more defections

as members leave to join more liberal religious groups or

give up religion altogether. Or perhaps their fertility will

decline as they absorb secular values or face practical

obstacles to expansion. These scenarios have different

implications for the genetic evolution of society. If reli-

gious people continue to have a higher birth rate on

average than secular people and they are sufficiently endo-

gamous, then any genes which predispose people towards

religion will spread. This may be true even if mainstream

religions shrink or become increasingly secular in their
Proc. R. Soc. B (2011)
breeding habits. Provided a core of high-fertility sects

continues to exist, and those sects remain highly endoga-

mous, they will transform the genetic composition of

society through either internal growth or defection. This

has been demonstrated in the present paper using a

single gene for religiosity. In reality, a phenomenon as

complex as religious predisposition is likely to be influ-

enced by many different genes, but this does not alter

the main argument.

One issue of interest in this context is genetic poly-

morphism. Such a phenomenon is widespread in

nature. It may arise through genetic drift if some trait is

selectively neutral or because different variants enjoy

selective advantage in different environments. It may

also arise because heterozygotes have superior fitness

when compared with homozygotes. Alternatively, an

observed polymorphism may be transitory and scheduled

to disappear as some particular variant eventually tri-

umphs. In the case of religion, heritability studies

suggest there is currently significant variation in genetic

predisposition towards religion [13]. There are several

possible explanations for this. Religious predisposition

may be associated with genes that were, or still are, differ-

entially advantageous in specific natural or social

environments. The current variation in predisposition

may simply reflect environmental diversity. To the

extent that religious predisposition is the result of group

selection, variation is to be expected, since group selec-

tion requires variation to operate. Or perhaps we are

living in a transitional era in which selective forces will

eventually marginalize certain variants. This is one



2526 R. Rowthorn Religion, fertility and genes

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possible interpretation of the analysis presented in this

paper. However, even within our framework, there are

several avenues through which a stable polymorphism

could arise. If there is a convergence of religious and

non-religious birth rates, the share of the religiosity

allele R will eventually stabilize at less than unity. Or

there might be some form of heterozygote advantage,

whereby heterozygotes have a stronger religious predis-

position than homozygotes. This will be the case within

our framework if h
r
, h

n
. 1. Simulations not reported

here suggest that even a modest effect of this kind will

generate a stable polymorphism and allow N to survive.

However, heterozygote advantage is merely a theoretical

possibility and there is currently no evidence to support

it. The most plausible mechanism that could generate a

stable polymorphism is a future convergence of religious

and non-religious birth rates.

Some of the present fertility differentials are so large

that, if they persist, they may have a significant genetic

effect within the space of a few generations. This may

not be because of an increase in the share of individuals

who are actively religious. If high fertility rates are com-

bined with high defection rates, the share of the

population who belong to high-fertility religious groups

may stabilize at quite a low level. However, defections

from such groups will spread religiosity genes to the rest

of society. There will be an increasing number of people

with a genetic predisposition towards religion but who

lead secular lives. It is interesting to speculate how such

a predisposition might manifest itself in a secular context.

The findings of Koenig & Bouchard [13] suggest that a

genetic predisposition towards religion is associated with

obedience to authority and conservatism. If this is correct,

then the diffusion of religiosity genes into the rest of

society should see an increase in the number of secular

people who are genetically inclined towards such values.

The implications of such a development are beyond the

scope of this paper to consider.
I should like to thank Samuel Bowles, Herbert Gintis, Peter
Richerson, Paul Seabright and two anonymous referees for
their comments on a draft of this paper; also seminar
participants at the Santa Fe Institute and the University of Siena.
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	Religion, fertility and genes: a dual inheritance model
	Introduction
	Religion and fertility
	Genetic implications

	A haploid model of dual inheritance
	Modelling predisposition
	Long-run behaviour
	Role of the predisposition conditions
	Fertility and the pace of evolution
	Ultra-high fertility sects

	A diploid model
	Density dependence
	Simulations
	Mixed marriages

	Discussion
	I should like to thank Samuel Bowles, Herbert Gintis, Peter Richerson, Paul Seabright and two anonymous referees for their comments on a draft of this paper; also seminar participants at the Santa Fe Institute and the University of Siena.
	REFERENCES