• We are sorry, but NCBI web applications do not support your browser and may not function properly. More information
Logo of plosgenPLoS GeneticsSubmit to PLoSGet E-mail AlertsContact UsPublic Library of Science (PLoS)View this Article
PLoS Genet. Jul 2010; 6(7): e1001015.
Published online Jul 1, 2010. doi:  10.1371/journal.pgen.1001015
PMCID: PMC2895656

The Importance of Imprinting in the Human Placenta

Anne C. Ferguson-Smith, Editor

Abstract

As a field of study, genomic imprinting has grown rapidly in the last 20 years, with a growing figure of around 100 imprinted genes known in the mouse and approximately 50 in the human. The imprinted expression of genes may be transient and highly tissue-specific, and there are potentially hundreds of other, as yet undiscovered, imprinted transcripts. The placenta is notable amongst mammalian organs for its high and prolific expression of imprinted genes. This review discusses the development of the human placenta and focuses on the function of imprinting in this organ. Imprinting is potentially a mechanism to balance parental resource allocation and it plays an important role in growth. The placenta, as the interface between mother and fetus, is central to prenatal growth control. The expression of genes subject to parental allelic expression bias has, over the years, been shown to be essential for the normal development and physiology of the placenta. In this review we also discuss the significance of genes that lack conservation of imprinting between mice and humans, genes whose imprinted expression is often placental-specific. Finally, we illustrate the importance of imprinting in the postnatal human in terms of several human imprinting disorders, with consideration of the brain as a key organ for imprinted gene expression after birth.

Introduction

Pronuclear transfer experiments in mice in the early 1980s showed that maternal and paternal genetic contributions were non-equivalent and that both were indispensable for normal development [1], [2]. The introduction of reciprocal translocations into mice, creating regions of uniparental disomy, showed that discrete areas of the mouse genome were subject to differential parental regulation [3]. In parallel with this fascinating mouse work, it was observed that several non-Mendelian human syndromes showed similar inheritance to phenotypes seen in the disomic mice [4]. The mapping of deletions causative in Prader Willi (PWS) and Angelman (AS) syndromes, for example, permitted localisation of parentally non-equivalent genomic regions in humans [4]. In 1991, the first endogenous imprinted genes were identified [5][7]. This parent-of-origin, monoallelic gene expression, with its associated differential DNA methylation (first shown in 1993, [8]) became defined as genomic imprinting.

Genomic imprinting, found predominantly in eutherian mammals, is an epigenetic phenomenon whose evolution may be linked to a dichotomy between paternal and maternal resource allocation. This is potentially powerful enough to promote evolution of unequal gene expression between selected parental alleles. Parental-specific monoallelic expression thus balances fetal growth to the equal benefit of both parental genomes, in spite of the resulting potentially damaging haploinsufficiency [9].

The canonical example of allelic expression of imprinted genes balancing growth is evident with the paternally expressed Igf2 and maternally expressed Igf2r genes [5], [7], [10]. Igf2 is a potent enhancer of fetal growth and inappropriate expression disturbs normal growth in mice [10]. A reduction in Igf2 expression leads to growth restriction, whereas biallelic expression and the subsequent increase in the number of Igf2 transcripts leads to overgrowth [11], [12]. Maternally expressed Igf2r has the opposite effect on growth, as the Igf2r protein acts as a negative regulator of Igf2 by binding to the Igf2 protein, reducing its bioavailability and targeting it for lysosomal degradation [13][16]. Monoallelic expression of imprinted genes is controlled by allelic DNA methylation, added differentially to the imprinting control regions (ICRs) of parental germlines [17], [18]. The paternal allelic expression of murine Igf2 is also found in humans, and in both species monoallelic expression is mediated in cis by maternal DNA methylation at the H19 ICR, the differentially methylated domain (H19 DMD) [19][22].

IGF2 is also an important growth enhancer in humans, and its expression and subsequent phenotypic effects may be similarly impacted by dysregulation of imprinting. A loss of methylation at the H19 DMD in humans is found in a subset of Silver Russell syndrome (SRS) cases [23]. The main phenotype of SRS is severe intrauterine growth restriction (IUGR) that could be caused by a reduction in IGF2 transcription as a result of a loss of methylation at the H19 DMD [23]. Hypermethylation at the H19 DMD is found in 30% cases of Beckwith Wiedemann syndrome (BWS) [24], and the overgrowth macroglossia and organomegaly associated with this disorder may be caused by an increase in IGF2 transcription as a result of its biallelic expression. IGF2R imprinting in the human, in contrast, is polymorphic, rare, and most likely restricted to the placenta [25]. Recent evidence of a potential human orthologue of the murine ncRNA Air, responsible in the mouse for paternal Igf2r silencing, indicates that some key features of reciprocal murine Igf2/Igf2r imprinting may be present in humans [26].

Human Placental Development

The placenta, particularly the invasive trophoblast lineages, is an important focus for potential parental conflict. It is directly responsible for bringing maternal and fetal blood supplies into contact, facilitating nutrient exchange and determining resource allocation (Figure 1) [27].

Figure 1
The human fetus and placenta.

Human embryos implant interstitially in a highly invasive manner. Leading edge trophoblast cells fuse to form a syncytium, resulting in a two layered structure of multinucleated syncytiotrophoblast and cellular cytotrophoblast. Protusions of syncytiotrophoblast interdigitate into the decidualised endometrium, forming contacts with the maternal blood supply (Figure 1). Extravillous cytotrophoblast, which may be analogous to the endoreduplicated murine giant cells, form columns from the tips of anchoring villae, attached to the basal plate, and extend through the syncytium. Invasive cells break away from these columns and migrate to colonise maternal spiral arteries. Interstitial trophoblast cells invade to expand the placenta from its edge outwards [28]. Invasion is partly controlled by the decidua, which expresses proteins, including a wide variety of IGF binding proteins, balancing invasion and fetal provision [29], [30]. Perturbation of this is evident in ectopic pregnancy, when invasion is far more extensive in the absence of the decidua [31].

Genomic Imprinting in the Human Placenta

The physiological importance of genomic imprinting in humans can be demonstrated by the diseases resulting from mutations or epimutations in imprinted genes. Human imprinting disorders are somewhat rare but comprise a large group of diverse pathologies, primarily involving growth or neurological development. Consistent with the growth phenotypes observed, many of the imprinted genes known to-date are expressed in the human placenta (Table 1) [32], [33].

Table 1
Imprinted genes expressed in the human placenta, with phenotpyes associated with loss of gain of expression, where reported.

Disease pathologies resulting from inappropriate imprinted gene expression may each be due in part, or completely, to an aberrantly functioning placenta. The placenta is fundamental to fetal growth, and Table 1 highlights the imprinted genes expressed in the placenta that have been implicated in fetal growth disorders. As previously stated, IUGR is a defining characteristic of the imprinting disorder SRS. Up to half of all SRS cases may be caused by a reduction in IGF2 expression, as outlined above, but in the remainder the cause is unknown [23]. Whilst IUGR is often idiopathic, it is commonly accompanied by reduced blood flow through the placenta and limited invasion of the decidua and maternal blood vessels [34]. This phenotype is consistent with either the loss of expression of an imprinted gene involved in maximising recruitment of maternal resources (i.e., a paternally expressed gene), or an increase in expression of an imprinted gene acting to limit maternal input (i.e., a maternally expressed gene). A second disease associated with reduced placental perfusion is preeclampsia, whose matrilineal inheritance pattern has highlighted the possibility that imprinted genes might involved in its pathogenesis [35], [36]. In a recent study of 96 cases of BWS, seven resulted from maternally inherited CDKN1C mutations and of these, three pregnancies were complicated by preeclampsia, compared to three of the 89 BWS cases not related to CDKN1C mutations [37]. Interestingly, transgenic mice whose litters carry mutations of the maternal Cdkn1c copy display preeclampsia-like features, including hypertension, proteinuria, and abnormal trophoblast proliferation [38], [39]. These data suggest an important role for CDKN1C in a subset of preeclampsia cases, however, other imprinted susceptibility loci for this complication of pregnancy remain elusive [40].

The imprinted gene PHLDA2 on human Chromosome 11 (Hsa11) is expressed predominately in the placenta, and its expression in the placenta at term correlates negatively with fetal birth weight [41]. Given that PHLDA2 is maternally expressed, this trend is consistent with the parental resource conflict theory, that maternally expressed genes act to limit maternal resource provision. Further evidence that PHLDA2 expression levels in the human placenta might be important in regulating fetal growth comes from two studies comparing placentas from normal and IUGR pregnancies. Both studies found higher levels of PHLDA2 expression in placentas from IUGR pregnancies than placentas from non-IUGR pregnancies [33], [42].

Paternally expressed MEST is thought to play a role in angiogenesis in human trophoblast tissue and decidua, is highly expressed and robustly imprinted in the placenta [43]. MEST is located on Hsa7, and maternal uniparental disomy (mUPD) 7, is implicated in 7–10% of SRS cases. Additionally, one SRS case has been reported with a segmental mUPD for 7q31-qter, specifically implicating the MEST imprinting cluster in this instance, rather than any of the other imprinted genes on Hsa7 [44]. Currently, no direct evidence exists to link human MEST with disease, but mice deficient in Mest are pre- and postnatally growth restricted [45].

GRB10 is a growth factor binding protein, maternally expressed specifically in cytotrophoblast and biallelic elsewhere, located on Hsa7 [46]. The mUPD7 implicated in 7–10% SRS cases would lead to biallelic expression of GRB10 and may be linked to the growth restriction characteristic of SRS for this subset of patients. Currently, however, no evidence exists to directly link GRB10 expression levels with growth in humans [47], [48]. In mouse embryos, Grb10 is widely expressed from the maternally derived chromosome, and ablation of this copy causes embryonic overgrowth, such that neonates are 30% larger than wild-type littermates at birth [49]. This is accompanied by disproportionate overgrowth of the placental labyrinth [50].

Imprinting in the Mouse Placenta

Further clues regarding a role for imprinted genes in the placenta have been derived from studies in transgenic and knockout mice. Ablating the expression of individual imprinted genes leads to a range of pathologies, depending on the gene. Murine paternally expressed Igf2 has been shown to promote placental growth (see below), and loss of Mest or Peg3 causes placental growth restriction. Conversely, deletion of maternally expressed Igf2r, Cdkn1c, or Phlda2 results in placental hyperplasia [32].

The importance of genomic imprinting specifically in the murine placenta can be illustrated by the expression pattern of paternally expressed Igf2. Human and mouse IGF2/Igf2 can be expressed from several different promoters, but in the mouse, the transcripts from one promoter—Igf2P0—are placental-specific [51]. Deletion of the P0 promoter reduces placental size close to that of complete Igf2 KO, i.e., around 40% smaller than normal [51]. Humans also have an IGF2 P0 promoter, but it is not placental-specific, indicating only a partial conservation of imprinting of IGF2P0/Igf2P0 between mice and humans [52].

The main role of the placenta is the nutrition of the fetus. Murine Igf2P0 transcripts are expressed specifically in the labyrinthine trophoblast of the placenta [51], the cellular interface between the maternal blood supply and the fetal capillaries, and the surface across which nutrient exchange with the fetus takes place. Through increasing the surface area, Igf2P0 is thought to enhance passive permeability in the labyrinth, promoting nutrient exchange [51], [53]. In the Igf2P0-null model, fetal Igf2 expression is shown to regulate nutrient supply from the growth-restricted placenta in a paracrine manner [51]. The presence of circulating fetal Igf2 coincident with an imbalance between placental supply and fetal demand results in upregulation of nutrient transfer systems [54]. Placental transcription of glucose transporter Slc2a3 and paternally expressed amino acid transporter Slc38a4 are upregulated, followed by an increase in glucose and amino acid transport from the placenta to the fetus [54]. These data show that imprinted growth regulators may influence nutrient supply through action in the placenta, or by regulating demand from the fetus.

As previously discussed, the expression level of PHLDA2/Phlda2 correlates inversely with fetal growth in both humans and mice [33], [41], [55]. This role as a growth suppressor has recently been directly linked with the exchange of nutrients between mother and fetus in mice [56]. In a transgenic model, a two-fold increase in Phlda2 expression resulted in reduced placental weight, specifically in the junctional zone, and a decrease in glycogen stores and glycogen cell migration, important for fetal glucose supplies late in gestation [56]. This is the reverse of what is seen in the Phlda2 knockout mouse, and unlike the null, impacted on embryonic as well as placental development so that overexpression of Phlda2 led to 13% reduction in fetal weight [55], [56]. These data suggest that the regulation of fetal and placental growth by PHLDA2/Phlda2 might be effected through its potential role in nutrient transfer [56].

The KCNQ1/Kcnq1 Imprinting Cluster

Expression within the KCNQ1/Kcnq1 imprinting cluster on Hsa11/Mmu7 is only partially conserved between humans and mice [25]. Whilst the central six transcripts, covering 400 kb, maintain monoallelic expression in both species, the eight flanking genes are known to be maternally expressed in the mouse and bovine placenta, extending the imprinted domain to 780 kb [57][59]. In contrast, these flanking transcripts are biallelic in the human [25] (Figure 2).

Figure 2
The KCNQ1/Kcnq1 imprinted gene cluster.

The function of several of the genes in the KCNQ1/Kcnq1 cluster has been extensively characterised, and correspond with roles in embryonic and placental growth. ASCL2/Ascl2 is essential for early placental development, whilst CDKN1C/Cdkn1c is a growth suppressor, whose absence causes neonatal lethality in the mouse [60], [61]. Mutations or epimutations affecting CDKN1C result in one type of BWS in the human, commonly involving severe abdominal wall defects [62], [63]. Another group of BWS cases are due to mutations or epimutations immediately upstream of H19. These BWS patients have a high risk of tumours, especially compared to the CDKN1C region (epi)mutation group; see Table 1 [63]. KCNQ1 is imprinted at the majority of expressed sites in the human, except in the heart, the site of the defect in long-QT syndrome that are caused by mutations in KCNQ1 [64], [65]. PHLDA2, whose role has already been discussed, is also encoded at this locus.

A differentially methylated region (DMR) in intron 10 of KCNQ1 acts dually as the imprinting control region (ICR) for the cluster, called KvDMR, and the promoter of an antisense ncRNA KCNQ1OT1, which contributes to the regulation of imprinting at the domain [66], [67] (Figure 2). In the mouse, this ncRNA is imprinted and expressed from the paternally inherited chromosome where its transcription is required for the repression of the paternally inherited protein coding genes in cis [68], [69]. Kcnq1ot1 RNA may be linked to recruitment of the Eed-Ezh2 polycomb protein complex to the paternal chromosome, resulting in the enrichment of H3K27Me3 and H3K9Me2 and a repressed chromatin conformation conducive to allelic silencing [58]. Dnmt1−/− mice are deficient in DNA methytransferase DNMT1, the enzyme responsible for maintenance of DNA methylation. In these mice, histone modifications are able to maintain imprinting of the placental specific genes in the Kcnq1 region, indicating that maintenance methylation is not required for prolonged monoallelic expression of these genes in the placenta. Imprinting of the central six genes is lost in Dnmt1−/− mice [57], [58], [70], indicating that they do require maintenance methylation for monoallelic expression. Despite the absence of a requirement for maintenance methylation for the imprinting of a subset of genes in this cluster, the establishment of the germline DMR (by different enzymes, the de novo DNA methyltransferase, Dnmt3a [71]) remains essential for imprinting across the whole locus [70]. There is evidence that the murine Kcnq1ot1 RNA may form a silencing compartment in the nucleus, to which the repressed alleles are localised [72]. This compartment is larger in the murine placenta than in the fetus, perhaps reflecting the increased size of the repressed region in this tissue [73]. Given that imprinting of the KCNQ1 region in the human embryo and placenta both mirror that of the mouse embryo, if this model is correct it may be that such a transcriptional silencing compartment would be smaller in the human placenta, encompassing only the central seven transcripts.

Differences in the Placenta Between Humans and Mice

The placenta is the organ with the most varied morphology between mammalian species [74]. This is indicative of the different reproductive strategies employed by different species, where young may be precocial or altricial, and litter size and gestational length vary greatly. The lack of conservation of imprinting between humans and mice in the placenta, such as that of IGF2PO and the KCNQ1 region, has been suggested to be due to the marked differences between murine and human placentation and pregnancy [75], [76]. Mice have a labyrinthine interdigitation into the maternal decidua, compared to the villous structure of the exchange surface in the human. Mouse placentas have one or very few central maternal arteries, but in the human, several maternal spiral arteries provide the placenta with nutrients and oxygen. In the mouse, glycogen cells in the placenta become abundant between E13 and E18.5, invade the decidua basalis, and cluster at the base of the central maternal artery. They lyse just before term, possibly to provide energy for the final phase of prenatal growth [77]. Both species manipulate the maternal blood supply to maximise nutrient transfer. In the mouse, it is suggested that the primary cause of maternal artery transformation is the secretion of cytokines—i.e., by glycogen cells, which secrete Igf2 protein and express nuclear Cdkn1c and have been shown to be important for transformation of the central maternal artery [78], [79]. Artery transformation in the mouse is shallow and limited to the proximal decidua [75]. Conversely, human maternal arteries are extensively colonised by endovascular trophoblast cells. These cells relax the elastic artery walls and expand the lumen, allowing increased blood flow to the growing human fetus.

Differences in Imprinted Gene Expression Between Human and Mouse Placentas

In the mouse, 5–15 fetuses may be carried in utero at the same time, depending on the mouse strain, and one pregnancy can occur from two separate matings [80], [81]. This intra-brood competition forms the basis of one of the key features of the parental conflict theory because such a scenario would be predicted to increase parental conflict at the materno-placenta interface [82]. Different levels of conflict in the placenta between mice and humans may account for the divergence in imprinted gene expression profiles, with imprinted expression of certain genes not being required in the human. The transcriptional regulator Ascl2 is imprinted in the mouse placenta, and absolutely required for placentation, whereas in the human this gene is biallelically expressed, indicative of a less stringent requirement for dosage management in humans for this gene [60], [83], [84], or the utilisation of a different mechanism of dosage control in the human. Sheep, like humans, bear singletons and the sheep orthologue of placental specific Ascl2 (SASH2), is biallelically expressed whilst CDKN1C is maternally expressed [85]. To date, most genes that are imprinted in mouse but not in human, including those previously discussed, are imprinted specifically in the placenta of the mouse. Table 2 lists placental-specific imprinted genes identified in the mouse at several loci. With the exception of TFPI2 these genes are not imprinted in the human [25]. This observation lends support to the idea that the placenta could be at the centre of the differences in imprinting between mice and humans. Of the genes listed in Table 2, most are maternally expressed, consistent with an involvement of these genes in limiting placental and/or fetal growth [25]. Perhaps the mouse placenta manages parental conflict through a more limited invasion of the maternal decidua and blood vessels than that of the human placenta, with imprinted genes playing a role in modulating the process.

Table 2
Conservation of imprints in human and mouse http://igc.otago.ac.nz.

Total reproductive capability of mammalian females over a lifetime could also have an impact on parental conflict, and so possibly imprinted gene expression, since deleterious effects of pregnancy on the mother may be additive between pregnancies. It would therefore be illuminating to compare imprinting in monoseasonally oestrous species, such as the giant panda, with imprinting in mammals capable of many fertile oestrous cycles in their lifetimes, such as mice and humans.

Changes in Global Gene Expression in the Placenta during Gestation

Genome-wide expression analyses of early and late murine and human placentas show that early placentation events are more similar between mammalian species than later placental growth [86]. During early gestation and placental developmental stages—i.e., E8.5 to E10.5 in the mouse—the placenta utilises evolutionarily ancient genes, such as those involved in metabolism, the cell cycle, and RNA processing. During mid to late gestation (E10.5 to E15) a transition occurs where expression profiles become enriched for genes that evolved since the divergence of rodents and primates from their common ancestor. In rodents, from E15 to P0 genes specific to the rodent placenta are expressed, and in the human placenta primate-specific genes are all enriched compared to the mouse [86].

This striking selection for high expression of evolutionarily new, species-specific genes, during mid-gestation with specificity increasing as gestation continues, is indicative of the progressive divergence of placental physiology during development. Concomitantly, the conservation of genomic imprinting between humans and mice may be dynamic through pregnancy. Imprinting can be developmentally regulated by epigenetic regulators that are tissue-specific. Germline methylation can therefore be “read” differently in different cell types and at different stages in development, resulting in, for example, the highly tissue-specific imprinting at the GNAS locus on Hsa20/Mmu2 [87]. Differential reading of the germline methylation mark could depend on the presence of tissue-specific transcription factors or epigenetic effectors such as polycomb group proteins. For example, allelic histone modifications in the Kcnq1 region are required to maintain imprinting of placental-specific imprinted genes in the mouse placenta and are able to do so without maintenance of differential methylation at the KvDMR, which is not the case for the genes imprinted in the embryo that still require an intact KvDMR [57], [58]. As placental physiology diverged throughout gestation, differences in developmentally regulated imprinting may also have evolved. It is possible that placental-specific imprinting seen in the mouse (Table 2) may be present in the human placenta, but at a much earlier gestation than has so far been analysed, before differentiation resulted in biallelic expression of these genes. Similarly, in later gestation in humans, genes not imprinted in the mouse may be imprinted in the human placenta.

Imprinting in the Postnatal Human

After birth, resource allocation is distinct from that during pregnancy, and the interaction between offspring and mother is vastly changed. The placenta, and its function to transfer nutrients from the maternal bloodstream and pass them on to the fetus, is no longer present, and the neonate has developed strategies to function ex utero, leading to full independence after weaning. Key organs for imprinted expression postnatally include the brain and endocrine tissues, such as brown adipose tissue, which regulates non-shivering thermogenesis, a pre-weaning postnatal adaptation to independent life [88]. Genes whose imprinted expression was previously vital in the placenta, may cease to be important in some tissues, exemplified by the biallelic expression of IGF2 in human adult liver [89].

It is likely that parental conflict in mammals therefore continues after birth, albeit in an altered fashion (Figure 3) [90]. During the period between weaning and independence of children from their parents, the father has an increased role given his position as “breadwinner” that may be an investment of higher magnitude than that of the mother in older children [91], [92]. Postnatally, some aspects of several imprinting syndromes seem incompatible with the conflict theory in its simplest form. For example, PWS results from a loss of paternally expressed transcripts, yet PWS children are characteristically large. This can be reconciled with the concept of resource allocation by focussing on behaviour. Genes imprinted in the PWS/AS region, which are highly expressed in the brain, may act postnatally to modify behaviour to maximise resources (Figure 3). Emotional and behavioural cues could be utilised by the neonate to manipulate parents in order to provide adequate nutrition. In AS, caused by loss of expression of maternally expressed UBE3A, children prolong suckling and exhibit convivial behaviour that maximises maternal input [93]. In PWS, resulting from the loss of paternally expressed HBII-85 snoRNAs, children suckle badly and wean quickly but are hyperphagic after birth, arguably maximising utilisation of paternal resources and minimising usage of maternal ones [94], [95]. So, conflict exists after birth, but its arena might be considered to have moved from the placenta to the brain [92]. Whether this facet of imprinting displays consistency between humans and mice remains to be seen. Mouse models with targeted deletions of the MBII-85 snoRNA cluster display characteristic PWS features of hypotonia and a failure to thrive, followed by hyperphagia [96], [97]. The mice do not become obese, indicating some species-specific differences in metabolism, however the behavioural parallels between between PWS and the MBII-85-deleted transgenic mouse indicate that some aspects of postnatal conflict may be managed similarly between the two species [96], [97]. Imprinting in the brain is conserved between mice and humans at the GRB10/Grb10 locus, where transcripts are paternally expressed in the central nervous system through similar tissue specific chromatin modifications [46], [98][100]. Grb10 is a growth inhibitor and is maternally expressed in most tissues in mouse [49]. In utero, Grb10 negatively regulates fetal and placental growth, whilst it is involved in glucose homeostasis in adult muscle and adipose tissue [101]. The function of Grb10 in brain and the purpose of its maternal suppression is unknown. The distinct mechanism of GRB10/Grb10 regulation observed in human and mouse brain [46], [100], and opposing allelic repression compared to other tissues, is suggestive of it having a distinct role in this tissue, perhaps in influencing postnatal behaviour in the father's favour [46]. Imprinting in the brain is a developing field, one that will provide new and exciting insights into human behaviour and the evolution of imprinting.

Figure 3
Maternal and paternal resource allocation before and after birth.

Summary

The biological function of reducing the diploid state to functional haploidy has to be questioned in terms of its evolutionary significance. A case needs to be made for the benefit of silencing of one parental allele balanced against the negative impact of a mutation at the remaining allele that would leave the cell with no gene product.

In humans, inappropriate expression of imprinted genes leads in many cases to severe syndromes. This shows that the monoallelic expression of this small subset of genes is indispensible for normal human development. Aberrant prenatal growth occurs frequently in imprinting syndromes. This shows that an important feature of imprinting is the regulation of growth and nutrient transfer between mother and fetus, for which the placenta is key. This regulation should be balanced to serve the interests of both parents equally.

There are several genes that are imprinted in mice but not in humans. This is suggestive of a difference in importance or function of these transcripts between these two species, possibly due to species-specific differences in their respective placental physiology. The lack of conservation in imprinted expression for some genes may also be linked to a reduction in conflict during human pregnancy compared to the mouse, as humans bear singletons rather than large litters, and so have little or no possibility of multiple paternity.

Whilst differences in the reproductive biology of mice and humans are evident, large distinctions in imprinting in organs unrelated to pregnancy have not yet been identified. Following birth, offspring are free from maternal growth constraints, no longer rely on the placenta and must now recruit input from both parents in order to maximise fitness. A resolution of parental conflict postnatally will therefore rely on specific behavioural and emotional cues, engaging organs such as the brain and endocrine axis.

Genomic imprinting in humans is clearly important. Analysis of imprinting disorders and information from closely related mammalian models allows us to define the importance of its conservation and the relevance of any absence of conservation. Through further focussed research into human imprinting, we will elucidate the specialised functions of this remarkable transcriptional mechanism in our species.

Acknowledgments

The authors would like to thank Mike Cowley, Dave Monk, and Adam Prickett for helpful comments and interesting discussions.

Footnotes

The authors have declared that no competing interests exist.

JMF was funded by an MRC PhD Studentship, and currently holds a Wellcome Trust post-doctoral research post. GEM is funded by MRC, Wellcome Trust, Wellbeing of Women, and SPARKS. The funders had no role in the decision to publish or preparation of the article.

References

1. McGrath J, Solter D. Completion of mouse embryogenesis requires both the maternal and paternal genomes. Cell. 1984;37:179–183. [PubMed]
2. Surani MA, Barton SC, Norris ML. Development of reconstituted mouse eggs suggests imprinting of the genome during gametogenesis. Nature. 1984;308:548–550. [PubMed]
3. Cattanach BM, Kirk M. Differential activity of maternally and paternally derived chromosome regions in mice. Nature. 1985;315:496–498. [PubMed]
4. Nicholls RD, Knoll JH, Butler MG, Karam S, Lalande M. Genetic imprinting suggested by maternal heterodisomy in nondeletion Prader-Willi syndrome. Nature. 1989;342:281–285. [PubMed]
5. Barlow DP, Stoger R, Herrmann BG, Saito K, Schweifer N. The mouse insulin-like growth factor type-2 receptor is imprinted and closely linked to the Tme locus. Nature. 1991;349:84–87. [PubMed]
6. Bartolomei MS, Zemel S, Tilghman SM. Parental imprinting of the mouse H19 gene. Nature. 1991;351:153–155. [PubMed]
7. DeChiara TM, Robertson EJ, Efstratiadis A. Parental imprinting of the mouse insulin-like growth factor II gene. Cell. 1991;64:849–859. [PubMed]
8. Ferguson-Smith AC, Sasaki H, Cattanach BM, Surani MA. Parental-origin-specific epigenetic modification of the mouse H19 gene. Nature. 1993;362:751–755. [PubMed]
9. Haig D. The kinship theory of genomic imprinting. Annu Rev Ecol Syst. 2000;31:9–32.
10. Ferguson-Smith AC, Cattanach BM, Barton SC, Beechey CV, Surani MA. Embryological and molecular investigations of parental imprinting on mouse chromosome 7. Nature. 1991;351:667–670. [PubMed]
11. DeChiara TM, Efstratiadis A, Robertson EJ. A growth-deficiency phenotype in heterozygous mice carrying an insulin-like growth factor II gene disrupted by targeting. Nature. 1990;345:78–80. [PubMed]
12. Leighton PA, Ingram RS, Eggenschwiler J, Efstratiadis A, Tilghman SM. Disruption of imprinting caused by deletion of the H19 gene region in mice. Nature. 1995;375:34–39. [PubMed]
13. Lau MM, Stewart CE, Liu Z, Bhatt H, Rotwein P, et al. Loss of the imprinted IGF2/cation-independent mannose 6-phosphate receptor results in fetal overgrowth and perinatal lethality. Genes Dev. 1994;8:2953–2963. [PubMed]
14. Wang ZQ, Fung MR, Barlow DP, Wagner EF. Regulation of embryonic growth and lysosomal targeting by the imprinted Igf2/Mpr gene. Nature. 1994;372:464–467. [PubMed]
15. Ludwig T, Eggenschwiler J, Fisher P, D'Ercole AJ, Davenport ML, et al. Mouse mutants lacking the type 2 IGF receptor (IGF2R) are rescued from perinatal lethality in Igf2 and Igf1r null backgrounds. Dev Biol. 1996;177:517–535. [PubMed]
16. Munier-Lehmann H, Mauxion F, Hoflack B. Function of the two mannose 6-phosphate receptors in lysosomal enzyme transport. Biochem Soc Trans. 1996;24:133–136. [PubMed]
17. Li E, Beard C, Jaenisch R. Role for DNA methylation in genomic imprinting. Nature. 1993;366:362–365. [PubMed]
18. Tremblay KD, Saam JR, Ingram RS, Tilghman SM, Bartolomei MS. A paternal-specific methylation imprint marks the alleles of the mouse H19 gene. Nat Genet. 1995;9:407–413. [PubMed]
19. Thorvaldsen JL, Duran KL, Bartolomei MS. Deletion of the H19 differentially methylated domain results in loss of imprinted expression of H19 and Igf2. Genes Dev. 1998;12:3693–3702. [PMC free article] [PubMed]
20. Frevel MA, Sowerby SJ, Petersen GB, Reeve AE. Methylation sequencing analysis refines the region of H19 epimutation in Wilms tumor. J Biol Chem. 1999;274:29331–29340. [PubMed]
21. Cui H, Niemitz EL, Ravenel JD, Onyango P, Brandenburg SA, et al. Loss of imprinting of insulin-like growth factor-II in Wilms' tumor commonly involves altered methylation but not mutations of CTCF or its binding site. Cancer Res. 2001;61:4947–4950. [PubMed]
22. Takai D, Gonzales FA, Tsai YC, Thayer MJ, Jones PA. Large scale mapping of methylcytosines in CTCF-binding sites in the human H19 promoter and aberrant hypomethylation in human bladder cancer. Hum Mol Genet. 2001;10:2619–2626. [PubMed]
23. Gicquel C, Rossignol S, Cabrol S, Houang M, Steunou V, et al. Epimutation of the telomeric imprinting center region on chromosome 11p15 in Silver-Russell syndrome. Nat Genet. 2005;37:1003–1007. [PubMed]
24. Cooper WN, Luharia A, Evans GA, Raza H, Haire AC, et al. Molecular subtypes and phenotypic expression of Beckwith-Wiedemann syndrome. Eur J Hum Genet. 2005;13:1025–1032. [PubMed]
25. Monk D, Arnaud P, Apostolidou S, Hills FA, Kelsey G, et al. Limited evolutionary conservation of imprinting in the human placenta. Proc Natl Acad Sci U S A. 2006;103:6623–6628. [PMC free article] [PubMed]
26. Yotova IY, Vlatkovic IM, Pauler FM, Warczok KE, Ambros PF, et al. Identification of the human homolog of the imprinted mouse Air non-coding RNA. Genomics. 2008;92:464–473. [PMC free article] [PubMed]
27. Fowden AL, Sferruzzi-Perri AN, Coan PM, Constancia M, Burton GJ. Placental efficiency and adaptation: Endocrine regulation. J Physiol. 2009;587:3459–3472. [PMC free article] [PubMed]
28. Lunghi L, Ferretti ME, Medici S, Biondi C, Vesce F. Control of human trophoblast function. Reprod Biol Endocrinol. 2007;5:6. [PMC free article] [PubMed]
29. Bowen JM, Chamley L, Keelan JA, Mitchell MD. Cytokines of the placenta and extra-placental membranes: roles and regulation during human pregnancy and parturition. Placenta. 2002;23:257–273. [PubMed]
30. Gude NM, Roberts CT, Kalionis B, King RG. Growth and function of the normal human placenta. Thromb Res. 2004;114:397–407. [PubMed]
31. von Rango U, Krusche CA, Kertschanska S, Alfer J, Kaufmann P, et al. Apoptosis of extravillous trophoblast cells limits the trophoblast invasion in uterine but not in tubal pregnancy during first trimester. Placenta. 2003;24:929–940. [PubMed]
32. Coan PM, Burton GJ, Ferguson-Smith AC. Imprinted genes in the placenta–a review. Placenta. 2005;26(Suppl A):S10–S20. [PubMed]
33. Diplas AI, Lambertini L, Lee MJ, Sperling R, Lee YL, et al. Differential expression of imprinted genes in normal and IUGR human placentas. Epigenetics. 2009;4 [PubMed]
34. Pardi G, Marconi AM, Cetin I. Placental-fetal interrelationship in IUGR fetuses–a review. Placenta. 2002;23(Suppl A):S136–S141. [PubMed]
35. Graves JA. Genomic imprinting, development and disease–is pre-eclampsia caused by a maternally imprinted gene? Reprod Fertil Dev. 1998;10:23–29. [PubMed]
36. Oudejans CB, Mulders J, Lachmeijer AM, van DM, Konst AA, et al. The parent-of-origin effect of 10q22 in pre-eclamptic females coincides with two regions clustered for genes with down-regulated expression in androgenetic placentas. Mol Hum Reprod. 2004;10:589–598. [PubMed]
37. Romanelli V, Belinchon A, Campos-Barros A, Heath KE, Garcia-Minaur S, et al. CDKN1C mutations in HELLP/preeclamptic mothers of Beckwith-Wiedemann Syndrome (BWS) patients. Placenta. 2009;30:551–554. [PubMed]
38. Takahashi K, Kobayashi T, Kanayama N. p57(Kip2) regulates the proper development of labyrinthine and spongiotrophoblasts. Mol Hum Reprod. 2000;6:1019–1025. [PubMed]
39. Kanayama N, Takahashi K, Matsuura T, Sugimura M, Kobayashi T, et al. Deficiency in p57Kip2 expression induces preeclampsia-like symptoms in mice. Mol Hum Reprod. 2002;8:1129–1135. [PubMed]
40. Iglesias-Platas I, Monk D, Jebbink J, Buimer M, Boer K, et al. STOX1 is not imprinted and is not likely to be involved in preeclampsia. Nat Genet. 2007;39:279–280. [PubMed]
41. Apostolidou S, bu-Amero S, O'Donoghue K, Frost J, Olafsdottir O, et al. Elevated placental expression of the imprinted PHLDA2 gene is associated with low birth weight. J Mol Med. 2007;85:379–387. [PubMed]
42. McMinn J, Wei M, Schupf N, Cusmai J, Johnson EB, et al. Unbalanced placental expression of imprinted genes in human intrauterine growth restriction. Placenta. 2006;27:540–549. [PubMed]
43. Mayer W, Hemberger M, Frank HG, Grummer R, Winterhager E, et al. Expression of the imprinted genes MEST/Mest in human and murine placenta suggests a role in angiogenesis. Dev Dyn. 2000;217:1–10. [PubMed]
44. Hannula K, Lipsanen-Nyman M, Kontiokari T, Kere J. A narrow segment of maternal uniparental disomy of chromosome 7q31-qter in Silver-Russell syndrome delimits a candidate gene region. Am J Hum Genet. 2001;68:247–253. [PMC free article] [PubMed]
45. Lefebvre L, Viville S, Barton SC, Ishino F, Keverne EB, et al. Abnormal maternal behaviour and growth retardation associated with loss of the imprinted gene Mest. Nat Genet. 1998;20:163–169. [PubMed]
46. Monk D, Arnaud P, Frost J, Hills FA, Stanier P, et al. Reciprocal imprinting of human GRB10 in placental trophoblast and brain: evolutionary conservation of reversed allelic expression. Hum Mol Genet 2009 [PubMed]
47. Monk D, Wakeling EL, Proud V, Hitchins M, bu-Amero SN, et al. Duplication of 7p11.2–p13, including GRB10, in Silver-Russell syndrome. Am J Hum Genet. 2000;66:36–46. [PMC free article] [PubMed]
48. Abu-Amero S, Monk D, Frost J, Preece M, Stanier P, et al. The genetic aetiology of Silver-Russell syndrome. J Med Genet. 2008;45:193–199. [PubMed]
49. Charalambous M, Smith FM, Bennett WR, Crew TE, Mackenzie F, et al. Disruption of the imprinted Grb10 gene leads to disproportionate overgrowth by an Igf2-independent mechanism. Proc Natl Acad Sci U S A. 2003;100:8292–8297. [PMC free article] [PubMed]
50. Charalambous M, Cowley M, Geoghegan F, Smith FM, Radford EJ, et al. Maternally-inherited Grb10 reduces placental size and efficiency. Dev Biol. 2010;337:1–8. [PubMed]
51. Constancia M, Hemberger M, Hughes J, Dean W, Ferguson-Smith A, et al. Placental-specific IGF-II is a major modulator of placental and fetal growth. Nature. 2002;417:945–948. [PubMed]
52. Monk D, Sanches R, Arnaud P, Apostolidou S, Hills FA, et al. Imprinting of IGF2 P0 transcript and novel alternatively spliced INS-IGF2 isoforms show differences between mouse and human. Hum Mol Genet. 2006;15:1259–1269. [PubMed]
53. Sibley CP, Coan PM, Ferguson-Smith AC, Dean W, Hughes J, et al. Placental-specific insulin-like growth factor 2 (Igf2) regulates the diffusional exchange characteristics of the mouse placenta. Proc Natl Acad Sci U S A. 2004;101:8204–8208. [PMC free article] [PubMed]
54. Constancia M, Angiolini E, Sandovici I, Smith P, Smith R, et al. Adaptation of nutrient supply to fetal demand in the mouse involves interaction between the Igf2 gene and placental transporter systems. Proc Natl Acad Sci U S A. 2005;102:19219–19224. [PMC free article] [PubMed]
55. Frank D, Fortino W, Clark L, Musalo R, Wang W, et al. Placental overgrowth in mice lacking the imprinted gene Ipl. Proc Natl Acad Sci U S A. 2002;99:7490–7495. [PMC free article] [PubMed]
56. Tunster SJ, Tycko B, John RM. The imprinted Phlda2 gene regulates extraembryonic energy stores. Mol Cell Biol. 2010;30:295–306. [PMC free article] [PubMed]
57. Lewis A, Mitsuya K, Umlauf D, Smith P, Dean W, et al. Imprinting on distal chromosome 7 in the placenta involves repressive histone methylation independent of DNA methylation. Nat Genet. 2004;36:1291–1295. [PubMed]
58. Umlauf D, Goto Y, Cao R, Cerqueira F, Wagschal A, et al. Imprinting along the Kcnq1 domain on mouse chromosome 7 involves repressive histone methylation and recruitment of Polycomb group complexes. Nat Genet. 2004;36:1296–1300. [PubMed]
59. Arnold DR, Lefebvre R, Smith LC. Characterization of the placenta specific bovine mammalian achaete scute-like homologue 2 (Mash2) gene. Placenta. 2006;27:1124–1131. [PubMed]
60. Guillemot F, Caspary T, Tilghman SM, Copeland NG, Gilbert DJ, et al. Genomic imprinting of Mash2, a mouse gene required for trophoblast development. Nat Genet. 1995;9:235–242. [PubMed]
61. Yan Y, Frisen J, Lee MH, Massague J, Barbacid M. Ablation of the CDK inhibitor p57Kip2 results in increased apoptosis and delayed differentiation during mouse development. Genes Dev. 1997;11:973–983. [PubMed]
62. Hatada I, Ohashi H, Fukushima Y, Kaneko Y, Inoue M, et al. An imprinted gene p57KIP2 is mutated in Beckwith-Wiedemann syndrome. Nat Genet. 1996;14:171–173. [PubMed]
63. Engel JR, Smallwood A, Harper A, Higgins MJ, Oshimura M, et al. Epigenotype-phenotype correlations in Beckwith-Wiedemann syndrome. J Med Genet. 2000;37:921–926. [PMC free article] [PubMed]
64. Wang Q, Curran ME, Splawski I, Burn TC, Millholland JM, et al. Positional cloning of a novel potassium channel gene: KVLQT1 mutations cause cardiac arrhythmias. Nat Genet. 1996;12:17–23. [PubMed]
65. Lee MP, Hu RJ, Johnson LA, Feinberg AP. Human KVLQT1 gene shows tissue-specific imprinting and encompasses Beckwith-Wiedemann syndrome chromosomal rearrangements. Nat Genet. 1997;15:181–185. [PubMed]
66. Mitsuya K, Meguro M, Lee MP, Katoh M, Schulz TC, et al. LIT1, an imprinted antisense RNA in the human KvLQT1 locus identified by screening for differentially expressed transcripts using monochromosomal hybrids. Hum Mol Genet. 1999;8:1209–1217. [PubMed]
67. Fitzpatrick GV, Soloway PD, Higgins MJ. Regional loss of imprinting and growth deficiency in mice with a targeted deletion of KvDMR1. Nat Genet. 2002;32:426–431. [PubMed]
68. Mancini-DiNardo D, Steele SJ, Levorse JM, Ingram RS, Tilghman SM. Elongation of the Kcnq1ot1 transcript is required for genomic imprinting of neighboring genes. Genes Dev. 2006;20:1268–1282. [PMC free article] [PubMed]
69. Shin JY, Fitzpatrick GV, Higgins MJ. Two distinct mechanisms of silencing by the KvDMR1 imprinting control region. Embo J. 2008;27:168–178. [PMC free article] [PubMed]
70. Green K, Lewis A, Dawson C, Dean W, Reinhart B, et al. A developmental window of opportunity for imprinted gene silencing mediated by DNA methylation and the Kcnq1ot1 noncoding RNA. Mamm Genome. 2007;18:32–42. [PubMed]
71. Kaneda M, Okano M, Hata K, Sado T, Tsujimoto N, et al. Essential role for de novo DNA methyltransferase Dnmt3a in paternal and maternal imprinting. Nature. 2004;429:900–903. [PubMed]
72. Terranova R, Yokobayashi S, Stadler MB, Otte AP, van LM, et al. Polycomb group proteins Ezh2 and Rnf2 direct genomic contraction and imprinted repression in early mouse embryos. Dev Cell. 2008;15:668–679. [PubMed]
73. Redrup L, Branco MR, Perdeaux ER, Krueger C, Lewis A, et al. The long noncoding RNA Kcnq1ot1 organises a lineage-specific nuclear domain for epigenetic gene silencing. Development. 2009;136:525–530. [PMC free article] [PubMed]
74. Carter AM. Evolution of the placenta and fetal membranes seen in the light of molecular phylogenetics. Placenta. 2001;22:800–807. [PubMed]
75. Carter AM. Animal models of human placentation–a review. Placenta. 2007;28(Suppl A):S41–S47. [PubMed]
76. Enders AC. Reasons for diversity of placental structure. Placenta. 2009;30(Suppl A):S15–S18. [PubMed]
77. Coan PM, Conroy N, Burton GJ, Ferguson-Smith AC. Origin and characteristics of glycogen cells in the developing murine placenta. Dev Dyn. 2006;235:3280–3294. [PubMed]
78. Georgiades P, Watkins M, Burton GJ, Ferguson-Smith AC. Roles for genomic imprinting and the zygotic genome in placental development. Proc Natl Acad Sci U S A. 2001;98:4522–4527. [PMC free article] [PubMed]
79. Pringle KG, Roberts CT. New light on early post-implantation pregnancy in the mouse: roles for insulin-like growth factor-II (IGF-II)? Placenta. 2007;28:286–297. [PubMed]
80. Baker RJ, Makova KD, Chesser RK. Microsatellites indicate a high frequency of multiple paternity in Apodemus (Rodentia). Mol Ecol. 1999;8:107–111. [PubMed]
81. Dean MD, Ardlie KG, Nachman MW. The frequency of multiple paternity suggests that sperm competition is common in house mice (Mus domesticus). Mol Ecol. 2006;15:4141–4151. [PMC free article] [PubMed]
82. Haig D. Multiple paternity and genomic imprinting. Genetics. 1999;151:1229–1231. [PMC free article] [PubMed]
83. Guillemot F, Nagy A, Auerbach A, Rossant J, Joyner AL. Essential role of Mash-2 in extraembryonic development. Nature. 1994;371:333–336. [PubMed]
84. Miyamoto T, Hasuike S, Jinno Y, Soejima H, Yun K, et al. The human ASCL2 gene escaping genomic imprinting and its expression pattern. J Assist Reprod Genet. 2002;19:240–244. [PMC free article] [PubMed]
85. Thurston A, Taylor J, Gardner J, Sinclair KD, Young LE. Monoallelic expression of nine imprinted genes in the sheep embryo occurs after the blastocyst stage. Reproduction. 2008;135:29–40. [PubMed]
86. Knox K, Baker JC. Genomic evolution of the placenta using co-option and duplication and divergence. Genome Res. 2008;18:695–705. [PMC free article] [PubMed]
87. Liu J, Yu S, Litman D, Chen W, Weinstein LS. Identification of a methylation imprint mark within the mouse Gnas locus. Mol Cell Biol. 2000;20:5808–5817. [PMC free article] [PubMed]
88. Plagge A, Gordon E, Dean W, Boiani R, Cinti S, et al. The imprinted signaling protein XL alpha s is required for postnatal adaptation to feeding. Nat Genet. 2004;36:818–826. [PubMed]
89. Davies SM. Developmental regulation of genomic imprinting of the IGF2 gene in human liver. Cancer Res. 1994;54:2560–2562. [PubMed]
90. Moore T, Haig D. Genomic imprinting in mammalian development: a parental tug-of-war. Trends Genet. 1991;7:45–49. [PubMed]
91. Cole TJ, Power C, Moore GE. Intergenerational obesity involves both the father and the mother. Am J Clin Nutr. 2008;87:1535–1536. [PubMed]
92. Ubeda F. Evolution of genomic imprinting with biparental care: implications for Prader-Willi and Angelman syndromes. PLoS Biol. 2008;6:e208. [PMC free article] [PubMed]
93. Buntinx IM, Hennekam RC, Brouwer OF, Stroink H, Beuten J, et al. Clinical profile of Angelman syndrome at different ages. Am J Med Genet. 1995;56:176–183. [PubMed]
94. Haig D, Wharton R. Prader-Willi syndrome and the evolution of human childhood. Am J Hum Biol. 2003;15:320–329. [PubMed]
95. Sahoo T, del GD, German JR, Shinawi M, Peters SU, et al. Prader-Willi phenotype caused by paternal deficiency for the HBII-85 C/D box small nucleolar RNA cluster. Nat Genet. 2008;40:719–721. [PMC free article] [PubMed]
96. Skryabin BV, Gubar LV, Seeger B, Pfeiffer J, Handel S, et al. Deletion of the MBII-85 snoRNA gene cluster in mice results in postnatal growth retardation. PLoS Genet. 2007;3:e235. [PMC free article] [PubMed]
97. Ding F, Li HH, Zhang S, Solomon NM, Camper SA, et al. SnoRNA Snord116 (Pwcr1/MBII-85) deletion causes growth deficiency and hyperphagia in mice. PLoS ONE. 2008;3:e1709. [PMC free article] [PubMed]
98. Blagitko N, Mergenthaler S, Schulz U, Wollmann HA, Craigen W, et al. Human GRB10 is imprinted and expressed from the paternal and maternal allele in a highly tissue- and isoform-specific fashion. Hum Mol Genet. 2000;9:1587–1595. [PubMed]
99. Hitchins MP, Monk D, Bell GM, Ali Z, Preece MA, et al. Maternal repression of the human GRB10 gene in the developing central nervous system; evaluation of the role for GRB10 in Silver-Russell syndrome. Eur J Hum Genet. 2001;9:82–90. [PubMed]
100. Arnaud P, Monk D, Hitchins M, Gordon E, Dean W, et al. Conserved methylation imprints in the human and mouse GRB10 genes with divergent allelic expression suggests differential reading of the same mark. Hum Mol Genet. 2003;12:1005–1019. [PubMed]
101. Smith FM, Holt LJ, Garfield AS, Charalambous M, Koumanov F, et al. Mice with a disruption of the imprinted Grb10 gene exhibit altered body composition, glucose homeostasis, and insulin signaling during postnatal life. Mol Cell Biol. 2007;27:5871–5886. [PMC free article] [PubMed]
102. da Rocha ST, Charalambous M, Lin SP, Gutteridge I, Ito Y, et al. Gene dosage effects of the imprinted delta-like homologue 1 (dlk1/pref1) in development: implications for the evolution of imprinting. PLoS Genet. 2009;5:e1000392. [PMC free article] [PubMed]
103. Moon YS, Smas CM, Lee K, Villena JA, Kim KH, et al. Mice lacking paternally expressed Pref-1/Dlk1 display growth retardation and accelerated adiposity. Mol Cell Biol. 2002;22:5585–5592. [PMC free article] [PubMed]
104. Reik W, Lewis A. Co-evolution of X-chromosome inactivation and imprinting in mammals. Nat Rev Genet. 2005;6:403–410. [PubMed]

Articles from PLoS Genetics are provided here courtesy of Public Library of Science
PubReader format: click here to try

Formats:

Related citations in PubMed

See reviews...See all...

Cited by other articles in PMC

See all...

Links

  • PubMed
    PubMed
    PubMed citations for these articles