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7/31/2019 Lactose Digestion And The Evolutionary Genetics of Lactase Persistance - Ingram Et Al 2009 Human Genetics
1/13
Hum Genet (2009) 124:579591
DOI 10.1007/s00439-008-0593-6
123
REVIEW ARTICLE
Lactose digestion and the evolutionary genetics of lactase
persistence
Catherine J. E. Ingram Charlotte A. Mulcare
Yuval Itan Mark G. Thomas Dallas M. Swallow
Received: 6 August 2008 / Accepted: 6 November 2008 / Published online: 26 November 2008
Springer-Verlag 2008
Abstract It has been known for some 40 years that lactase
production persists into adult life in some people but not in
others. However, the mechanism and evolutionary signiW-
cance of this variation have proved more elusive, and con-
tinue to excite the interest of investigators from diVerent
disciplines. This genetically determined trait diVers in fre-
quency worldwide and is due to cis-acting polymorphism
of regulation of lactase gene expression. A single nucleo-
tide polymorphism located 13.9 kb upstream from the lac-
tase gene (C-13910 > T) was proposed to be the cause, and
the 13910*Tallele, which is widespread in Europe was
found to be located on a very extended haplotype of 500 kb
or more. The long region of haplotype conservation reXects
a recent origin, and this, together with high frequencies, is
evidence of positive selection, but also means that
13910*T might be an associated marker, rather than
being causal of lactase persistence itself. Doubt about func-
tion was increased when it was shown that the original SNP
did not account for lactase persistence in most African
populations. However, the recent discovery that there are
several other SNPs associated with lactase persistence in
close proximity (within 100 bp), and that they all reside in a
piece of sequence that has enhancer function in vitro, does
suggest that they may each be functional, and their occur-
rence on diVerent haplotype backgrounds shows that sev-
eral independent mutations led to lactase persistence. Here
we provide access to a database of worldwide distributions
of lactase persistence and of the C-13910*Tallele, as well
as reviewing lactase molecular and population genetics and
the role of selection in determining present day distribu-
tions of the lactase persistence phenotype.
Introduction
Lactase, the small intestinal enzyme responsible for cleav-
ing lactose into its constituent absorbable monosaccharides,
glucose and galactose, is essential for the nourishment of
newborn mammals, whose sole source of nutrition is milk,
in which lactose is the major carbohydrate component. In
adult mammals other than humans lactase production
decreases signiWcantly in quantity following weaning (Bul-
ler et al. 1990; Lacey et al. 1994; Sebastio et al. 1989).
Although individual diVerences in the ability of human
adults to digest milk had been remarked upon in Roman
times, variation in expression of lactase was not established
as a genetically determined trait until the second half of the
twentieth century. Indeed before this, expression of high
levels of lactase in adulthood was considered by people of
European descent to be the normal state of aVairs, and
widespread deWciency of lactase in adults was only appreci-
ated in the early 1960s (Auricchio et al. 1963; Dahlqvist
et al. 1963).
Here, we review all aspects of this polymorphism from
description of phenotype to molecular and evolutionary
Electronic supplementary material The online version of this
article (doi:10.1007/s00439-008-0593-6) contains supplementary
material, which is available to authorized users.
C. J. E. Ingram C. A. Mulcare Y. Itan M. G. Thomas
D. M. Swallow (&)
Department of Genetics Evolution and Environment,
University College London, Wolfson House,
4 Stephenson Way, London NW1 2HE, UK
e-mail: d.swallow@ucl.ac.uk
Y. Itan
Centre for Mathematics and Physics in the Life Sciences
and Experimental Biology, CoMPLEX,
University College London, Wolfson House,
4 Stephenson Way, London NW1 2HE, UK
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genetics. Since we had noted that the population distribu-
tion data available in many literature reviews contained
anomalous information (as will be discussed below) we
also provide access to a newly constructed database of phe-
notypic data taken from source publications.
Determination of lactase persistence status
People whose lactase persists at high levels throughout
adult life are said to be lactase persistent while those with
little lactase as adults are described as lactase non-persis-
tent (also referred to in the literature as primary adult hypo-
lactasia). Since taking intestinal biopsies from healthy
people is invasive and not acceptable unless the person is
having other investigations, lactase persistence status is
often inferred by a method depending on lactose digestion.
This allows people to be classiWed as lactose digesters and
maldigesters. This diVerence in digestion is measured by a
test traditionally known as a lactose tolerance test and
thus the terms tolerant and intolerant are sometimes used,
though this can be confused with dietary intolerance.
The lactose tolerance test usually involves giving a lac-
tose load after an overnight fast and then measuring blood
glucose or breath hydrogen. A baseline measurement of
blood glucose or breath hydrogen is taken before ingestion
of the lactose, and then at various time intervals thereafter.
An increase in blood glucose indicates lactose digestion
(glucose produced from the lactose hydrolysis is absorbed
into the bloodstream), and no increase, or a Xat line is
indicative of a lactose maldigester (probable lactase non-
persistent) phenotype. An increase in breath hydrogen indi-
cates maldigestion and reXects colonic fermentation of the
lactose, as described in the following section. In both cases
somewhat arbitrary cut-oV points have to be set for distin-
guishing the two phenotypes and both methods inform
upon the persons ability to digest lactose rather than the
given individuals lactase expression. It must therefore be
borne in mind that there will be an underlying error rate,
leading to both false negatives and false positives. The rela-
tive eYciency of the tests has been examined in more than
one study, and the breath hydrogen method was found the
most accurate (Mulcare et al. 2004; Newcomer et al 1975;
Peuhkuri 2000). It is also convenient and cheap. Lactase
levels can, however, be secondarily reduced by gastrointes-
tinal disease, leading to secondary lactose intolerance and
also some people fail to produce hydrogen. In the clinical
setting there are ways of improving the quality of the test.
These include retesting, and giving a dose of a non-digestible
carbohydrate, lactulose, to test for the presence of hydrogen
producing bacteria (see section below), and investigation of
other causes of the lactose intolerance, which might include
examination of biopsy material.
Symptoms of lactose intolerance
Undigested lactose passing through the small intestine
into the colon has two physiological eVects. First, an
osmotic gradient is set up across the gut wall, which
results in an inXux of water, causing symptoms of diar-
rhoea. Second, the lactose can be fermented by colonic
bacteria, to produce fatty acids and gaseous by-products(including hydrogen, used in the tolerance test), poten-
tially causing discomfort, bloating and Xatulence. How-
ever most lactase non-persistent individuals can tolerate
small amounts of lactose (as in tea or coVee), and some
can consume a lot without ill eVects (Scrimshaw and
Murray 1988; Suarez et al. 1997). Variation in the com-
position of the gut Xora between individuals (Hertzler
et al. 1997; Hertzler and Savaiano 1996), as well as a
psychosomatic component (Briet et al. 1997; Peuhkuri
et al. 2000; Saltzman et al. 1999) may account for some
of the interindividual variation in symptoms.
Worldwide distribution of lactase persistence
Surveys of lactase persistence phenotype frequencies
have been carried out in many populations over the
years, so that the global distribution of lactase persis-
tence is now fairly well characterised (Flatz 1987; Swal-
low and Hollox 2000; Table 1 supplementary
information; Fig. 1a). This reveals that lactase non-per-
sistence is the most common phenotype in humans (65%
if one takes into account population census size as
shown in Table 2 of the supplementary information),
with lactase persistence being common only in certain
populations with a long history of pastoralism and milk-
ing (McCracken 1971; Simoons 1970). Lactase persis-
tence is at highest frequency in north-western Europe,
with a decreasing cline to the south and east. On the
Indian subcontinent the frequency of lactase persistence
is higher in the north-west than elsewhere, and further
east than India the lactase persistence frequency is gen-
erally low. In Africa, the distribution is patchy, with
some pastoralist nomadic tribes having high frequencies
of lactase persistence compared with neighbouring
groups living in the same country (Bayoumi et al. 1981,
1982), with a similar pattern observed between Bedouin
and neighbouring populations in the Middle East (Fig. 2,
Cook and al-Torki 1975; Dissanyake et al. 1990; Snook
et al. 1976).
The noted correlation of lactase persistence phenotype
with the cultural practise of milking generated the hypothe-
sis that this trait has been subject to strong positive selec-
tion (Aoki 1986; Holden and Mace 1997; McCracken 1971;
Simoons 1970, 1978).
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Hum Genet (2009) 124:579591 581
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Fig. 1 Interpolated maps of the
old world showing the distri-
bution of (a) lactase persistence
data taken from the literature
(Supplementary data Table 1),
(b) -13910*Tdistribution (c)
lactase persistence frequency
predicted from -13910*Tdistri-
bution, using the data collection
to be found in Supplementary
data Table 3. Maps were
generated using PYNGL (http://
www.pyngl.ucar.edu). Only
includes individuals over
12 years of age, who are
unrelated, and literature for
which the original publications
have been located and checked.
Articles in which there was clear
selection bias, and recent
immigrant populations are ex-
cluded, but the data can be found
in Supplementary data Table 1.
The Americas are excluded fromall maps because of the paucity
of data. Most data were obtained
from lactose tolerance tests
using either breath hydrogen or
blood glucose, though in some
cases enzyme assay data were
available. Locations were either
as described precisely in the
publication, or taken from
capital cities or central points of
a country or region where
precise location is not
mentioned. Where more than
one data set was available
weighted averages of the datawere taken. Predicted frequency
taken to bep2 + 2pq, wherep is
the frequency of13910*T.
Data points are shown as dots. It
should be noted that the
interpolation is inaccurate where
there are few data points. A
colour version of this Wgure can
be found in the electronic
supplementary information
(a)
(b)
(c)
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Identifying the causes of lactase persistence
By the early 1970s it was established that the lactase persis-
tence polymorphism in humans has a genetic cause, and is
inherited in an autosomal dominant manner (Ferguson andMaxwell 1967; Metneki et al. 1984; Sahi 1974). Further
evidence that lactase persistence is a genetic trait, and more
speciWcally that it is caused by a cis-acting element, was
produced in the early 1980s. Ho et al. reported a trimodal
distribution of sucrase:lactase ratios in intestinal samples
from British adults of northern European ancestry. The tri-
modal distribution was interpreted as attributable to groups
of individuals homozygous for lactase persistence (highest
lactase activity), heterozygotes with mid-level activity and
non-persistent homozygotes with low lactase activity (Ho
et al. 1982), and similar results were subsequently obtained
in individuals of German ancestry (Flatz 1984). The inter-mediate lactase activity observed in the heterozygotes indi-
cated that only one copy of the lactase gene was being fully
expressed. Evidence for transcriptional regulation (Escher
et al. 1992) and conWrmatory evidence for the cis-acting
nature of this (Wang et al. 1995) was obtained from mRNA
studies.
Sequencing ofLCTand the immediate promoter region
in Europeans showed no nucleotide changes that were
absolutely associated with persistence/non-persistence(Boll et al. 1991; Lloyd et al. 1992; Poulter et al. 2003).
However, several polymorphisms do exist across the 50 kb
LCT gene and association studies revealed that very few
haplotypes occur in most of the human populations tested,
although greater diversity was observed in African popula-
tions (Hollox et al. 2001). One combination of alleles
designated the A haplotype (Fig. 3) is particularly common
in northern Europe and is associated with lactase persis-
tence (Harvey et al. 1998). A putative causative single
nucleotide polymorphism (C-13910 > T) was subsequently
identiWed 13.9 kb upstream of theLCTtranscription initia-
tion site (Enattah et al. 2002) (Fig. 3). It is located in anintron of an adjacent gene,MCM6, and occurs exclusively
on the background of the A haplotype (Poulter et al. 2003).
The 13910*Tallele was found to associate completely
with lactase persistence, ascertained directly by enzyme
Fig. 2 Examples of countries/
geographic regions in which
individual ethnic groups display
large diVerences in lactose
absorption capacity. See
Supplementary data (Table 1)
for details
0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
Beja Jaali Baggara Nilotes Fulani Hausa Ibo Yoruba Jordanian
Bedouin
Non-Bedouin
Jordanians
Saudi
Bedouin
Non-Bedouin
Saudis
Middle EastNigeriaSudan
Lactosed
igesterfrequency
Fig. 3 Diagrammatic representation of the genes MCM6 and LCT.
The arrow indicates the location of13910*T, and the other alleles
shown more recently to be associated with lactase persistence. Loca-
tions of SNPs used forLCTcore haplotype analysis are shown, with the
possible allelic combinations of the four common worldwide 11 SNP
haplotypes described in Hollox et al. (2001). The open circles indicate
an ancestral allele andWlled circles denote the derived allele at a locus.
SNPs used for assessing haplotype background of the lactase persis-
tence associated variants in our own studies are 4, 6, 9 and 10
LCTMCM6
U
A
BC
1 2 3 4 5 6 7 10 118 9
-14010*C
-13915*G
-13910*T
-13907*G
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Hum Genet (2009) 124:579591 583
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activity in 196 Finnish individuals, and subsequent studies
have conWrmed a tight but not absolute association between
13910*Tand lactase persistence as judged by lactose tol-
erance testing in populations of northern European ancestry
(Bernardes-Silva et al. 2007; Hogenauer et al. 2005; Kerber
et al. 2007; Poulter et al. 2003) and there was also a correla-
tion, but not absolute, between genotypes and enzymatic
activity (Poulter et al. 2003). However the A haplotypeextends far beyond the 50 kbLCTgene region, with carri-
ers of the13910*Tallele having almost identical chromo-
somes extending for nearly 1 Mb (Bersaglieri et al. 2004;
Poulter et al. 2003).
Evidence for function of13910*T
In vitro studies provided evidence that the 13910*Tallele
increases transcription in promoterreporter construct
assays in cell lines (Lewinsky et al. 2005; Olds and Sibley
2003; Troelsen et al. 2003), suggesting that it may have
enhancer activity in vivo. A transcription factor, Oct-1, was
identiWed which bound more strongly to the 13910*T
containing motif than to the alternative C allele, providing a
possible mechanism for up-regulation ofLCT (Lewinsky
et al. 2005), and suggesting that the cause of lactase persis-
tence had been identiWed (Rasinpera et al. 2004), although
many questions remain unanswered.
Population distribution of13910*T:13910*Tdoes
not account for lactase persistence worldwide
and is rare in sub-Saharan African populations
Using carefully checked primary source literature data
(Supplementary Table 1) we failed to obtain the tight corre-
lation of13910*Twith published worldwide lactase per-
sistence phenotype frequency reported elsewhere (Enattah
et al. 2007), but it is clear that in Europe the frequency dis-
tribution of 13910*T is in broad agreement with that
expected from distribution of the phenotype (Fig. 1).
Figure 1a shows an interpolated contour map depicting the
distribution of lactase persistence, prepared from pheno-
typic data taken from all the available literature, in which
we were conWdent of the phenotypic testing, and from
which children, family members, patients selected for
likely intolerance, and twentieth/twenty-Wrst century immi-
grant status were excluded. Figure 1b shows the distribu-
tion of13910*Tand details of the worldwide 13910*T
data can be found in the supplementary information (Sup-
plementary Table 3). Figure 1c showspredictedlactose tol-
erance distribution taken from 13910*T frequencies,
assuming that 13910*Tis the sole cause of lactase persis-
tence and is dominant (p2 + 2pq).
In contrast to the high frequency in Europe, 13910*T
is rare in sub-Saharan African populations (Fig. 1b) even in
those populations where lactase persistence frequency is
reported to be high (Mulcare et al. 2004), and it is also rare
in the Bedouins of the Arabian peninsula, who are also fre-
quently lactose digesters (Ingram et al. 2007). The allele
was also absent from all but one of a series of phenotyped
individuals of Sudanese ancestry (Ingram et al. 2007). Anobvious interpretation was that -13910*Tis not truly causal
of lactase persistence, but is a very strongly associated
marker of the causal element, which appeared on the lactase
persistence carrying (A haplotype) chromosome after
humans had spread out of Africa. However there was also
no association with A haplotype in this African group and
subsequent research indicated genetic heterogeneity.
New variants in intron 13 ofMCM6, and multiple
causes of lactase persistence in Africa
Three studies revealed several new sequence variants in
very close proximity (Figs. 3, 4; Table 1) to 13910*T
(Enattah et al. 2008; Ingram et al. 2007; TishkoV et al.
2007), two of which are clearly associated with lactase per-
sistence in diVerent parts of East Africa (13915*G and
14010*C). One of these, 13915*G, was also shown to
be associated with high lactase expression in Saudi Arabia
(Imtiaz et al. 2007). A third SNP, 13907*G, showed
much weaker evidence, but was found in several studies
(Enattah et al. 2008; Ingram 2008; Ingram et al. 2007;
TishkoV et al. 2007), and there were several other candi-
dates found in lactase persistent or milk drinking people
(Enattah et al. 2008; Ingram et al. 2007; Ingram 2008; Tag
et al. 2007; TishkoV et al. 2007). However, even taking
these additional variants into account, and supposing them
all to be functional, association with phenotype was not
complete. Although the occurrence of a few individuals
who carried an allele but were lactose maldigesters could
be explained by secondary lactase loss, individuals who
were digesters but carried no putative causative allele in
this genomic region still had to be explained, indicating that
there may be more, as yet unidentiWed, causal variants. The
genomic region may be particularly susceptible to muta-
tions, and these recent derived variants might simply be
markers of a causal element elsewhere. However, the three
newly described SNPs all occur on diVerent haplotype
backgrounds from each other (using our old nomenclature:
13907*G, on A,13915*G, on C, and14010*Cproba-
bly on B) (Enattah et al. 2008; Ingram et al. 2007; Ingram
2008; TishkoV et al. 2007), although 13907*G is on the
same haplotype as 13910*T. In each case the haplotypes
extend well beyond the 14 kb allele in both directions,
showing clearly that the derived alleles cannot simply be
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584 Hum Genet (2009) 124:579591
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markers for a single shared causal variant, and that there
must be several independent causes of lactase persistence.
Each of the alleles has a diVerent geographic distribution,
and the preliminary data suggest that -13915*G arose in the
Middle East, while 13907*G and 14010*C arose in
eastern Africa.
Evidence of function for the alleles identiWed in Africa
It is important to critically evaluate the evidence for func-
tion of these recently described alleles. Footprint analysis,
to determine DNAprotein binding sites, of sequence
encompassing the intron 13 region revealed transcription
factor recognition sequences for Cdx-2, GATA, HNF3/
Fox and HNF4 along with Oct-1 (Lewinsky et al. 2005).
Two of the newly identiWed SNPs are located within the
Oct-1 binding site (Fig. 4). Electrophoretic mobility shift
assays (EMSAs) used to ascertain the eVect of the new alle-
les on Oct-1 binding showed that only the original allele,
13910*T containing oligonucleotide probes bound
strongly to Oct-1, -13907*G bound to a much lesser extent
(Enattah et al. 2008; Ingram et al. 2007), and that binding
of the other alleles was less still or undetectable. It can
therefore be concluded that the simple change in binding of
the protein Oct-1 to this site is unlikely to play a critical
role in causing lactase persistence. The identiWcation of the
other associated allele, 14010*C, (TishkoV et al. 2007),
situated 100 bp away from the predicted Oct-1 binding site
would appear to conWrm this.
In vitro promoter/reporter analysis of the newly identi-
Wed MCM6 intron 13 variant alleles however, lends some
support to the idea that they do aVect enhancer activity.
Transcriptional activity of the LCT core promoter was
enhanced up to tenfold by addition of sequences from
MCM6 intron 13 (Lewinsky et al. 2005; Olds and Sibley
2003; TishkoVet al. 2007) which include the ancestral vari-
ant. This activity increased further (by up to 25% more)
when one of the variant alleles (14010*C, 13907*G or
13915*G) was present (TishkoV et al. 2007). This eVect
is in fact small and the authors did not include 13910*T
as a positive control (previously shown to enhance tran-
scription activity a further 80% compared to the ancestral
allele (Troelsen et al. 2003). Although a recent paper of
Enattah et al. (2008) does conWrm an eVect for 13915*G,the results are hard to evaluate because additional
sequences are included in the construct, and the control
13910*Tshows very little eVect in this study. However,
in the Enattah et al. (2008) paper the Caco-2 cells were not
diVerentiated, as they had been in some of the previous
studies (Troelsen et al. 2003). This also Xags the problem of
the appropriateness of the cell model. Caco-2 is a colon cell
line, and the only line known to express lactase and has fea-
tures more comparable with fetal small intestine (Hauri
et al. 1985).
The predictive value of these in vitro functional studies
with respect to the eVect exerted in vivo by particular alle-
les is therefore uncertain, but the observations, together
with those made previously (Lewinsky et al. 2005; Olds
and Sibley 2003; Troelsen et al. 2003) do suggest, though
do not conWrm that this region is important in regulation of
LCT expression. But how it allows low expression in
fetuses, high expression in babies and then down-regulation
in some but not other people is currently hard to envisage.
Studies in mice Xag the complexities of interpretation of in
vitro studies, and indeed in vivo studies highlight the sub-
tleties of tissue and developmental control (Bosse et al.
2006a, b, 2007; van Wering et al. 2004). Unfortunately
there are severe restrictions to animal models in elucidating
this uniquely human polymorphism.
The role of other factors inXuencing lactase expression
The immediate promoter ofLCTis moderately well charac-
terised in rat, pig and human (Fang et al. 2000, 2001;
Krasinski et al. 2001; Lee et al. 2002; Mitchelmore et al.
2000; Spodsberg et al. 1999; Troelsen et al. 1994, 1997;
Fig. 4 Sequence of the enhancer region in intron 13 ofMCM6show-
ing the positions of characterised transcription factor binding sites
(Lewinsky et al. 2005) and the SNPs that have been shown to associate
with lactase persistence. Note that the protein binding region13926
to13909 is comprised of two partially overlapping sites (Oct-1 and
GATA6as indicated). Several other SNPs that have been identiWed by
ourselves and others, in this region, including 13913T > C are not
shown since, as yet, no evidence of association with phenotype is avail-
able
TTTATGTAACTGTTGAATGCTCATACGACCATGGAATTCTTCCCTTTAAAGAGCTTGGTAAGCATTTGAGTGTAGTTGTTAGACGGAGACGATCACGTC
ATAGTTTATAGAGTGCATAAAGAC TAAGTTACCATTTAATACCTTTCATTCAGGAAAAATGTACTTAGACCCTACAATGTACTAGTAGGCCTCTGCGCT
GGCAATACAGATAAGATAA GTAG CC TGGCCTCAAAGGAACTCTCCTCCTTAGGTTGCATTTGTATAATGTTTGATTTTTAGATTGTTCTTTGAGCCCT
GCATTCCACGAGGATAGGTCAGTGGGTATTAACGAGGTAAAAGGGGAGTAGTACGAAAGGGCATTCAAGCGTCCCATCTTCGCTTCAACCAAAGCAGCCC
TGCTTTTTCCTAGTTTTATTAATAGGTTTGATGTAAGGTCGTCTTTGAAA
C
G
T
G
C
T
C
G
Cdx-2
GATA6
Oct-1
HNF3/Fox HNF4
-13684
-14133
-14034
-13934
-13833
-13733
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Hum Genet (2009) 124:579591 585
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van Wering et al. 2004; Wang et al. 2006), and there are
several allelic variants within the Wrst kilobase of human
sequence (Harvey et al. 1995; Hollox et al. 1999; Lloyd
et al. 1992). Although none of them is causal of persistence,
it is just possible that variations in these SNPs aVect expres-
sion under certain circumstances or at certain developmen-
tal stages: one study shows that the allele -958*T
(characteristic of the B haplotype) reduces binding to anuncharacterised transcription factor (Hollox et al. 1999).
Whilst it has been well established that regulation ofLCTis
predominantly under genetically determined transcriptional
control there is evidence that other factors inXuence inter-
individual diVerences in expression of the enzyme. Hetero-
geneity of the lactase non-persistence phenotype was
reported by a number of research groups in their early studies.
Some investigators observed individuals who show slower/
abnormal processing of their lactase protein (Sterchi et al.
1990; Witte et al. 1990) which may imply variation in post-
translational controls such as proteolytic cleavage, glyco-
sylation and/or transport to the cell surface, which are
involved in the normal processing of lactase (Jacob et al.
1994, 1995, 1996, 2002; Naim and Lentze 1992). Others
have made observations suggestive of epigenetic regulation
(Maiuri et al. 1991, 1994). Although most non-persistent
individuals show no staining for lactase in the jejunal biop-
sies of the small intestine (concordant with low lactase
activity and transcriptional regulation ofLCT), some indi-
viduals show patchy expression of the enzyme in the intes-
tinal epithelia (Maiuri et al. 1991, 1994). This mosaic
expression pattern might be attributable to somatic cell
changes in methylation, or histone acetylation but curiously
this is not attributable to an inherited change in expression
pattern from a single stem cell, since in that case ribbons
of positively stained cells would be expected.
Evolutionary considerations
The original observations in the 1970s and 1980s of a posi-
tive correlation between lactase persistence frequencies and
milk drinking led to the widely held notion that lactase per-
sistence has been subject to positive selection. In the inter-
vening years molecular evidence has accumulated which
would appear to corroborate this hypothesis. Our group Wrst
reported on the unusual pattern of lactase gene haplotype
diversity across populations (Hollox et al. 2001). We found
only four common 50 kb haplotypes outside Africa, with
many more within Africa, and a very high frequency of the
A haplotype in northern Europe, and suggested that the
very diVerent haplotype frequencies observed in N. Europe-
ans as compared to other populations are most probably
explained by a combination of genetic drift and strong pos-
itive selection for lactase persistence (Hollox et al. 2001).Table1
DetailsofSNPsknowntobeassociatedwithlactasepersistenceasofJuly2008
NotethatweandothershaveidentiWedatotaloftenotheralleles(including-139
13*C)withinthe130bpregion-13,9
00to-14,0
30forwhichstudiesoftheirassociation
andfunctionareongoing
Positionof
SNP(inbps
upstreamo
fLCT)
Substitution
(ancestralallele
Wrst,
fromc
omparison
withchimp)
rsNumber
Evidenceofassociationwith
lactasepersistence
Evidenceoffunction
Haplotype
(Holloxetal.2000
nomenclature)
Ge
ographiclocationof
hig
hestobservedfrequency
14,0
10
G
>C
Notincluded
indbSNP
TishkoV
etal.(2007)
TishkoV
etal.(2007)
B
Ke
nya/Tanzania
13,9
15
T>G
rs41380347
Ingrame
tal.(2007),
TishkoV
etal.(2007),
Imtiazetal.(200
7)
TishkoV
etal.(2007),Enattahetal.(2008)
C
SaudiArabia
13,9
10
C
>T
rs4988235
Enattahetal.(2002
)
Troelsenetal.(2003),OldsandSibley(2003),
Lewinskyetal.(2005)
A
Eu
rope
13,9
07
C
>G
rs41525747
TishkoV
etal.(2007)
Ingram(
2008)
TishkoV
etal.(2007),Enattahetal.(2008)
A
Ethiopia/Sudan
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More recently it has been shown that 13910*Toccurs
on an unusually extended haplotype background, which is
present in the northern European population at very high
frequency (Bersaglieri et al. 2004; Poulter et al. 2003). This
is consistent with a model of recent positive selection, in
which alleles surrounding the causal variant hitch-hike
rapidly to high frequency due to strong positive selection,
and haplotype length is exaggerated, indicating a recent
mutation event where recombination has not decayed the
allelic associations in the region (reviewed in Sabeti et al.
2006). The 13910*T carrying chromosome is a real
outlier in the context of molecular signatures of selection
compared with the rest of the human genome (HapMap
Consortium 2003). Decreased diversity of microsatellite
polymorphisms (STRs) that occurs in the region ofLCT
and MCM6 was also found for the 13910*T carrying
chromosomes, indicating that this allele has risen in fre-
quency quickly and recently (Coelho et al. 2005; Mulcare
2006) (Fig. 5).
In our own study (Mulcare 2006) we used a marker for
A haplotype chromosomes so that we could compare A
haplotype chromosomes which carry the 13910*Twith A
haplotype chromosomes which do not, thus reducing the
eVect of pooling haplotypes of totally diVerent lineages.
Interestingly, we can see from this that the microsatellite
haplotype that carries 13910*Tis also the most frequent
Fig. 5 Pie charts showing microsatellite LCT/MCM6 haplotypes on
chromosomes of diVerent SNP haplotype background: A haplotypecarrying 13910*T, A haplotype carrying 13910*Cand non-A hap-
lotype chromosomes. 5579*C(rs2278544), SNP 10 in Fig. 3, used as
a marker for A haplotype and 5579*Tas a marker for non-A haplotype,
and the A haplotype chromosomes are subdivided into those that do
and do not carry 13910*T. The lactase persistence associated SNP,
22018*A (rs182549), originally described in Enattah et al. (2002)
was tested on all samples and 22018*A correlated in all but one
sample with 13910*T. Data taken from families and the haplotypes
inferred from family structure. Data sets from: Irish n = 65 chromo-
somes, English n = 64, German, n = 60, French, n = 38, Ashkenazi
Jews n = 96, Armenian, n = 88, Kuwaiti, n = 28, Algerian, n = 20,Ethiopian, Amharic n = 118; n values for main charts shown. The inset
small charts show Ethiopian chromosomes only; n = 93 for non-A hap-
lotype; n = 25 for A haplotype. It can be seen that both groups of A-
haplotype chromosomes share the same modal haplotype as do both
groups of non-A chromosomes. The microsatellites tested are located
in intron 16 ofMCM6, intron 1, 2 and 13 ofLCT, respectively at posi-
tions 13840816, 136804355, 136798196, 136763409, from the Human
Genome Browser (http://genome.cse.ucsc.edu/cgi-bin/hgGateway
July 2003 freeze (colour in online)
-13910*TA haplotype
-13910*CA haplotype,
-13910*Cnon-A haplotype
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Hum Genet (2009) 124:579591 587
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of the ancestral A haplotype chromosomes in Europeans,
and also in non-Europeans. It can also be seen that within
the non-A lineages there is a fairly frequent microsatellite
haplotype which occurs in Europeans as well as non-Euro-
peans (Fig. 5). It is associated with the B core haplotype in
Europeans, and non-persistence. These observations sug-
gest demographic factors additional to selection for one
particular allele, as proposed previously (Hollox et al.2001). Indeed, in the case of European lactase persistence,
recent demic computer simulations indicate that the spread
of farming from the near east during the Neolithic transition
may have contributed to the high frequencies and genetic
homogeneity of lactase persistence on the continent
(Y. Itan, M. Thomas et al. manuscript in preparation).
Historical origins of lactase persistence; dating
of the lactase persistence associated alleles
Each of the microsatellite diversity studies used the micro-
satellites to attempt to date the expansion of the 13910*T
allele and the date ranges were 7,45012,300 (Coelho et al.
2005), and 7,40010,200 years ago (Mulcare 2006), and
this agrees with date estimates obtained from extended hap-
lotypes of 2,18820,650 years ago (Bersaglieri et al. 2004).
These dates are consistent with models of selection for lac-
tase persistence along with the recent practise of dairying,
approximately 9,000 years ago in Europe. Ancient DNA
data obtained from human bones has shown that the
13910*Tallele was either absent, or present at low fre-
quencies, in early Neolithic Europeans. This is consistent
with the -13910*T allele age estimates and supports a
model whereby the cultural trait of dairying was adopted
prior to lactase persistence becoming frequent (Burger et al.
2007).
The newly discovered 14010*Callele is also reported
to occur as part of an unusually extended haplotype, sug-
gesting that Africans too carry these signatures of recent
positive selection for lactase persistence. In this case the
allele is estimated to be between 1,200 and 23,200 years
old (TishkoVet al. 2007).
The identiWcation of the newly associated alleles them-
selves suggests that lactase persistence has arisen and been
selected for independently in several diVerent human popu-
lations, thus the ability to digest milk has been extremely
advantageous, at least for some, in the last few thousand
years.
What were the evolutionary forces?
Because of the worldwide distribution of lactase persis-
tence and the generally coinciding pattern of historically
milk-drinking populations, Simoons and McCracken inde-
pendently suggested, more than 30 years ago, that milk
dependence created strong selection for lactase persistence
(McCracken 1971; Simoons 1970). This has become
known as the culture historical hypothesis, and suggests
that the rise in lactase persistence co-evolved alongside the
cultural adaptation of milk drinking, and its associated
nutritional beneWts. Nevertheless, the correlation is notabsolute and there are exceptions in both directions. For
example there are some ethnic groups who rely heavily on
milk products and for whom cows or camels play a very
important role in their lifestyle, but who have a low
reported frequency of lactase persistence, for example, the
Dinka and Nuer in Sudan (Bayoumi et al. 1982) and the
Somali in Ethiopia (Ingram 2008). Statistical modelling
shows that an incomplete correlation can be accommodated
if some lactase persistent populations have recently stopped
milking or conversely have only recently adopted the habit,
therefore allowing insuYcient time for lactase persistence
to be driven to high frequency (Aoki 1986). Population
migration may also have played an important role. In addi-
tion the cultural practise of milk fermentation (e.g. to
yoghurt or cheese) reduces lactose content allowing non-
persistent individuals to beneWt from milk products.
Holden and Mace using regression analyses and correct-
ing for relatedness of diVerent populations claimed that lac-
tose digestion capacity had most likely evolved as an
adaptation to dairying, and concluded that high frequency
lactose digestion capacity had never evolved without the
prior presence of milking (Holden and Mace 1997). Other
evidence suggested to be in support of the culture-historical
hypothesis has been provided by the observation that high-
intra allelic diversity of cattle milk protein genes in Europe
coincides with the geographic incidence of lactase persis-
tence, which is consistent with large herd sizes kept for
dairying and selection for high milk yields (Beja-Pereira
et al. 2003).
However, it is noteworthy that at least in the Somali, one
of us (CI) has obtained data to suggest that signiWcant quan-
tities of fresh milk are consumed by many who are lactase
non-persistent (Ingram 2008) apparently without any
adverse eVects, and it seems likely that adaptation of the
colonic bacterial Xora allows digestion of lactose by these
people. This means that under normal circumstances lactase
persistence is unlikely to be under very strong selection in
this population, and Wts with the hypothesis that dairying
and milk drinking can emerge before the genetic adapta-
tion. It is likely that only at certain times and under more
extreme circumstances, such as drought and famine, that
the strong selective force operates. This is an extension of
the arid climate hypothesis, Wrst suggested by Cook and
al-Torki (1975). These authors speculated that in desert
climates (i.e. Middle and Near East) where water and food
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were scarce, nomadic groups could survive by utilizing
milk as a food source, and in particular, as a source of
clean, uncontaminated Xuid (Cook and al-Torki 1975). This
scenario is particularly pertinent to desert nomads whose
major source of milk is obtained from camels, as these ani-
mals are able to survive up to 2 weeks without food and
water by metabolising the fat contained in their humps. The
beneWts to persistent individuals may have become morepronounced during outbreaks of diarrhoeal disease, when
non-persistent individuals would be unable to utilize milk
as a water source without exacerbating their condition.
More recent research sought to address the question of
why some populations and not others had adopted the cul-
tural habit of milk drinking. The frequencies of lactose mal-
absorption were greater in populations where environmental
conditions, such as extremes of climate or high incidence of
endemic cattle disease, made it impossible to raise livestock
(Bloom and Sherman 2005). The exceptions to the general
distribution were a number of African groups with high lac-
tase persistence frequency who managed to circumvent
harsh environmental conditions by adopting a pastoralist
way of life (Bloom and Sherman 2005).
Obviously, the beneWts of milk drinking cannot be
explained by the arid climate hypothesis in Northern
Europe. Here, the advantage of improved calcium absorp-
tion has been suggested to explain the distribution of the
trait (Flatz and Rotthauwe 1973). The low light levels expe-
rienced at high latitudes are associated with an increased
risk of developing rickets and osteomalacia due to a lack of
vitamin D production (which is synthesized by the skin in
the presence of sunlight). Vitamin D is involved in the gut
absorption of calcium, which is itself an essential mineral
required for bone health. In addition, calcium may help to
prevent rickets by impairing the breakdown of vitamin D in
the liver (Thacher et al. 1999). Although lactase non-persis-
tent individuals could obtain calcium from yoghurt or
cheese, dairy foods that contain reduced lactose, milk pro-
teins and lactose are believed to facilitate the absorption of
calcium (for review see Gueguen and Pointillart 2000).
Hence the ability to drink fresh milk which contains both
calcium and components that stimulate its uptake (includ-
ing small amounts of vitamin D) may have provided an
advantage to persistent individuals.
Just one hypothesis has been put forward which suggests
selection for lactase non-persistence. Since lactase non-per-
sistence is the ancestral state, the need to invoke selection
for non-persistence is counter-intuitive, but should not be
ignored. In this proposal the selective agent is thought to be
malaria (Anderson and Vullo 1994). This proposal came
from the observations of high frequency of lactase non-per-
sistence in regions where malaria is endemic, and that indi-
viduals with Xavin deWciency are at a slightly reduced risk
of infection by malaria. The consumption of milk, which is
rich in riboXavins, was therefore proposed to be unfavour-
able since it would keep Xavin levels in the bloodstream
high. There is currently no support for this hypothesis
(Meloni et al. 1998), and it seems unlikely to contribute to
the current distribution of lactase persistence.
Present day health and medical considerations
Lactose malabsorption can readily be confused with milk
protein allergy, which has quite diVerent causes (reviewed
in Crittenden and Bennett 2005), and in recent times lactose
intolerance has been blamed for causing a variety of sys-
temic conditions, often without clear evidence (Campbell
and Matthews 2005; Matthews et al. 2005). Nonetheless it
does appear that consumption of milk and milk products by
those who cannot digest lactose is a relatively common
cause of irritable bowel syndrome in Europe and the USA
(Vesa et al. 2000). Many commercial dairy products and
other foods (including yoghurts) contain high concentra-
tions of lactose introduced in manufacturing, so that lactose
is more widespread in the diet than it was for that same per-
sons ancestors. Lactose tolerance testing can be a useful way
of detecting lactose malabsorption and enabling avoidance of
the cause, but DNA testing is not yet useful, particularly for
non-Europeans (Swallow 2006; Tag et al. 2008; Weiskir-
chen et al. 2007). In countries such as Finland, where there
is a high frequency of lactase non-persistence in compari-
son with the rest of northern Europe, commercial low
lactose products are readily available (Harju 2003).
Many association studies have attempted to demonstrate
the health beneWts of milk consumption in lactase persistent
people, e.g. by providing protection against osteoporosis
(Enattah et al. 2005a, b; Meloni et al. 2001; Obermayer-
Pietsch et al. 2004), and others have claimed adverse eVects
of lactase persistence and associated high milk consump-
tion (e.g. cataracts, ovarian cancer and diabetes) (Enattah
et al. 2004; Larsson et al. 2006; Meloni et al. 2001; Meloni
et al. 1999; Villako and Maaroos 1994). The often-contra-
dictory Wndings are diYcult to evaluate because of the high
risk of confounding eVects such as mixed ancestry, dietary
intake and variation in gut Xora.
Conclusion
Lactase persistence has been one of the leading examples of
natural selection in humans, and also one of the Wrst clear
examples of polymorphism of a regulatory element. Further
investigation of the molecular mechanisms as well as the
evolutionary forces is however needed to fully understand
this normal variation, which is providing an important
model for understanding gene/culture co-evolution and
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Hum Genet (2009) 124:579591 589
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disease susceptibility. The information accrued so far
already illustrates the limitations of disease association
studies and SNP tagging to Wnd functional genetic variation
attributable to multiple mutations, even if they are located
in a single gene, and highlights the potential importance of
distant regulatory elements.
Acknowledgments CJEI and CAM were funded by BBSRC CASEstudentships and YI was funded by UCL Graduate school, UCL ORS
and Bnai Brith/Leo Baeck London Lodge scholarships. We thank
Neil Bradman, The Centre for Genetic Anthropology, UCL, for access
to samples and Melford Charitable Trust for funding.
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