How demography, life history, and kinship shape the evolution of genomic imprinting.

How phenomena like helping, dispersal, or the sex ratio evolve depends critically on demographic and life-history factors. One phenotype that is of particular interest to biologists is genomic imprinting, which results in parent-of-origin-specific gene expression and thus deviates from the predictions of Mendel's rules. The most prominent explanation for the evolution of genomic imprinting, the kinship theory, originally specified that multiple paternity can cause the evolution of imprinting when offspring affect maternal resource provisioning. Most models of the kinship theory do not detail how population subdivision, demography, and life history affect the evolution of imprinting. In this work, we embed the classic kinship theory within an island model of population structure and allow for diverse demographic and life-history features to affect the direction of selection on imprinting. We find that population structure does not change how multiple paternity affects the evolution of imprinting under the classic kinship theory. However, if the degree of multiple paternity is not too large, we find that sex-specific migration and survival and generation overlap are the primary factors determining which allele is silenced. This indicates that imprinting can evolve purely as a result of sex-related asymmetries in the demographic structure or life history of a species.

Stability of XIST repression in relation to genomic imprinting following global genome demethylation in a human cell line

DNA methylation is essential in X chromosome inactivation and genomic imprinting, maintaining repression of XIST in the active X chromosome and monoallelic repression of imprinted genes. Disruption of the DNA methyltransferase genes DNMT1 and DNMT3B in the HCT116 cell line (DKO cells) leads to global DNA hypomethylation and biallelic expression of the imprinted gene IGF2 but does not lead to reactivation of XIST expression, suggesting thatXIST repression is due to a more stable epigenetic mark than imprinting. To test this hypothesis, we induced acute hypomethylation in HCT116 cells by 5-aza-2′-deoxycytidine (5-aza-CdR) treatment (HCT116-5-aza-CdR) and compared that to DKO cells, evaluating DNA methylation by microarray and monitoring the expression of XIST and imprinted genes IGF2, H19, and PEG10. Whereas imprinted genes showed biallelic expression in HCT116-5-aza-CdR and DKO cells, the XIST locus was hypomethylated and weakly expressed only under acute hypomethylation conditions, indicating the importance ofXIST repression in the active X to cell survival. Given that DNMT3A is the only active DNMT in DKO cells, it may be responsible for ensuring the repression of XIST in those cells. Taken together, our data suggest that XIST repression is more tightly controlled than genomic imprinting and, at least in part, is due to DNMT3A.

A model system to study genomic imprinting of human genes

Somatic-cell hybrids have been shown to maintain the correct epigenetic chromatin states to study developmental globin gene expression as well as gene expression on the active and inactive X chromosomes. This suggests the potential use of somatic-cell hybrids containing either a maternal or a paternal human chromosome as a model system to study known imprinted genes and to identify as-yet-unknown imprinted genes. Testing gene expression by using reverse transcription followed by PCR, we show that functional imprints are maintained at four previously characterized 15q11–q13 loci in hybrids containing a single human chromosome 15 and at two chromosome 11p15 loci in hybrids containing a single chromosome 11. In contrast, three γ-aminobutyric acid type A receptor subunit genes in 15q12–q13 are nonimprinted. Furthermore, we have found that differential DNA methylation imprints at the SNRPN promoter and at a CpG island in 11p15 are also maintained in somatic-cell hybrids. Somatic-cell hybrids therefore are a valid and powerful system for studying known imprinted genes as well as for rapidly identifying new imprinted genes.

Roles for genomic imprinting and the zygotic genome in placental development

The placenta contains several types of feto-maternal interfaces where zygote-derived cells interact with maternal cells or maternal blood for the promotion of fetal growth and viability. The genetic factors regulating the interactions between different cell types within feto-maternal interfaces and the relative contributions of the maternal and zygotic genomes are poorly understood. Genomic imprinting, the epigenetic process responsible for parental origin-dependent functional differences between homologous chromosomes, has been proposed to contribute to these events. Previous studies showed that mouse conceptuses with an absence of imprinted differences between the two copies of chromosome 12 (upon paternal inheritance of both copies) die late in gestation and have a variety of defects, including placentomegaly. Here we examined the role of chromosome 12 imprinting in these placentae in more detail. We show that the spatial interactions between different cell types within feto-maternal interfaces are defective and identify abnormal behaviors in both zygote-derived and maternal cells that are attributed to the genome of the zygote but not the mother. These include compromised invasion of the maternal decidualized endometrium and the central maternal artery situated within it by zygote-derived trophoblast, abnormalities in the wall of the central maternal artery, and defects within the zygote-derived cellular layer of the labyrinth, which is in direct contact with maternal blood. These findings demonstrate multiple roles for chromosome 12 imprinting in the placenta that have not previously been associated with imprinting effects. They provide insights into the function of imprinting in placental development and have evolutionary and clinical implications.

Abnormal methylation at the KvDMR1 imprinting control region in clinically normal children conceived by assisted reproductive technologies

Genomic imprinting alterations have been shown to be associated with assisted reproductive technologies (ARTs) in animals. At present, data obtained in humans are inconclusive; however, some epidemiological studies have demonstrated an increased incidence of imprinting disorders in children conceived by ARTs. In the present study, we focused on the effect of ARTs [IVF and intracytoplasmic sperm injection (ICSI)] on the epigenetic reprogramming of the maternally methylated imprinting control region KvDMR1 in clinically normal children. Qualitative and quantitative methylation at KvDMR1 were assessed by the methylation-specific PCR approach and by the methylation-sensitive enzymatic digestion associated with real-time PCR method, respectively. DNA was obtained from peripheral blood of 12/18 and umbilical cord blood and placenta of 6/18 children conceived by IVF or ICSI. The methylation patterns observed in this group were compared with the patterns observed in 30 clinically normal naturally conceived children (negative controls) and in 3 naturally conceived Beckwith-Wiedemann syndrome patients (positive controls). Hypomethylation at KvDMR1 was observed in 3/18 clinically normal children conceived by ARTs (2 conceived by IVF and 1 by ICSI). A discordant methylation pattern was observed in the three corresponding dizygotic twins. Our findings corroborate the hypothesis of vulnerability of maternal imprinting to ARTs. Furthermore, the discordant methylation at KvDMR1 observed between dizygotic twins could be consequent to one of the following possibilities: (i) a differential vulnerability of maternal imprints among different embryos; or (ii) epimutations that occurred during gametogenesis resulting in the production of oocytes without the correct primary imprint at KvDMR1.

CTCF-T, a paralogue of CTCF, directs sequence specific DNA methylation of the imprinting control region of Igf2/H19

SUMMARY Genomic imprinting is an epigenetic mechanism of transcriptional regulation that ensures restriction of expression of a subset of mammalian genes to a single parental allele. The best studied example of imprinted gene regulation is the Igf2/H19 locus, which is also the most commonly altered by loss of imprinting (LOT) in cancer. LOT is associated with numerous hereditary diseases and several childhood, and adult cancers. Differential expression of reciprocal H19 and 1gf2 alleles in somatic cells depends on the methylation status of the imprinting control region (ICR) which regulates binding of CTCF, an ubiquitously expressed 11-zinc finger protein that binds specifically to non-methylated maternal ICR and thereby attenuates expression of Igf2, while it does not bind to methylated paternal ICR, which enables Igf2 expression. Initial ICR methylation occurs during gametogenesis by an as yet unknown mechanism. The accepted hypothesis is that the event of differential maternal and paternal DNA methylation depends on germ-line specific proteins. Our Laboratory identified a novel 11-zinc-finger protein CTCF-T (also known as CTCFL and BORIS) that is uniquely expressed in the male germ-line and is highly homologous within its zinc-finger region with CTCF. The amino-acid sequences flanking the zinc-finger regions of CTCF and CTCF-T have widely diverged, suggesting that though they could bind to the same DNA targets (ICRs) they are likely to have different functions. Interestingly, expression of CTCF-T and CTCF is mutually exclusive; CTCF-T-positive (CTCF-negative) cells occur in the stage of spermatogenesis that coincides with epigenetic reprogramming, including de novo DNA methylation. In our study we demonstrate the role that CTCF-T plays in genomic imprinting. Here we show that CTCF-T binds in vivo to the ICRs of Igf2/H19 and Dlk/Gt12 imprinted genes. In addition, we identified two novel proteins interacting with CTCF-T: a protein arginine methyltransferase PRMT7 and an arginine-rich histone H2A variant that we named trH2A. These interactions were confirmed and show that the two proteins interact with the amino-teiminal region of CTCF-T. Additionally, we show interaction of the amino- terminal region of CTCF-T with histones H1, H2A and H3. These results suggest that CTCF-T is a sequence-specific DNA (ICR) binding protein that associates with histones and recruits PRMT7. Interestingly, PRMT7 has a histone-methyltransferase activity. It has been shown that histone methylation can mark chromatin regions thereby directing DNA-methylation; thus, our hypothesis is that the CTCF-T protein-scaffold directs PRMT7 to methylate histone(s) assembled on ICRs, which marks chromatin for the recruitment of the de novo DNA methyltransferases to methylate DNA. To test this hypothesis, we developed an in vivo DNA-methylation assay using Xenopus laevis' oocytes, where H19 ICR and different expression cDNAs, including CTCF-T, PRMT7 and the de novo DNA methyltransferases (Dnmt3a, Dnmt3b and Dnmt3L) are microinjected into the nucleus. The methylation status of CpGs within the H19 ICR was analysed 48 or 72 hours after injection. Here we demonstrate that CpGs in the ICR are methylated in the presence of both CTCF-T and PRMT7, while control oocytes injected only with ICR did not show any methylation. Additionally, we showed for the first time that Dnmt3L is crucial for the establishment of the imprinting marks on H19 ICR. Moreover, we confirmed that Dnmt3a and Dnmt3b activities are complementary. Our data indicate that all three Dnmt3s are important for efficient de novo DNA methylation. In conclusion, we propose a mechanism for the establishment of de novo imprinting marks during spermatogenesis: the CTCF-T/PRMT7 protein complex directs histone methylation leading to sequence-specific de novo DNA methylation of H19 ICR. RESUME L'empreinte génomique parentale est un mécanisme épigénétique de régulation transcriptionelle qui se traduit par une expression différentielle des deux allèles de certains gènes, en fonction de leur origine parentale. L'exemple le mieux caractérisé de gènes soumis à l'empreinte génomique parentale est le locus Igf2/H19, qui est aussi le plus fréquemment altéré par relaxation d'empreinte (en anglais: loss of imprinting, LOI) dans les cancers. Cette relaxation d'empreinte est aussi associée à de nombreuses maladies héréditaires, ainsi qu'à de nombreux cancers chez l'enfant et l'adulte. Dans les cellules somatiques, les différences d'expression des allèles réciproques H19 et Ig12 est sous le contrôle d'une région ICR (Imprinting Control Region). La méthylation de cette région ICR régule l'ancrage de la protéine à douze doigts de zinc CTCF, qui se lie spécifiquement à l'ICR maternel non-méthylé, atténuant ainsi l'expression de Igf2, alors qu'elle ne s'ancre pas à l'ICR paternel méthyle. Le mécanisme qui accompagne la méthylation initiale de la région ICR durant la gamétogenèse n'a toujours pas été élucidé. L'hypothèse actuelle propose que la différence de méthylation entre l'ADN maternel et paternel résulte de l'expression de protéines propres aux zones germinales. Notre laboratoire a récemment identifié une nouvelle protéine à douze doigts de zinc, CTCF-T (aussi dénommée CTCFL et BORRIS), qui est exprimée uniquement dans les cellules germinales mâles, dont la partie à douze doigts de zinc est fortement homologue à la protéine CTCF. La séquence d'acides aminés de part et d'autre de cette région est quant à elle très divergente, ce qui implique que CTCF-T se lie sans doute au même ADN cible que CTCF, mais possède des fonctions différentes. De plus, l'expression de CTCF-T et de CTCF s'oppose mutuellement; l'expression de la protéine CTCF-T (cellules CTCF-T positives, CTCF negatives) qui a lieu pendant la spermatogenèse coïncide avec la reprogrammation épigénétique, notamment la méthylation de novo de l'ADN. La présente étude démontre le rôle essentiel joué par la protéine CTCF-T dans l'acquisition de l'empreinte génomique parentale. Nous montrons ici que CTCF-T s'associe in vivo avec les régions ICR des loci Igf2/H19 et Dlk/Gt12. Nous avons également identifié deux nouvelles protéines qui interagissent avec CTCF-T : une protéine arginine méthyl transférase PRMT7, et un variant de l'histone H2A, riche en arginine, que nous avons dénommé trH2A. Ces interactions ont été analysées plus en détail, et confinnent que ces deux protéines s'associent avec la région N-terminale de CTCF-T. Aussi, nous présentons une interaction de la région N-terminale de CTCF-T avec les histones H1, H2, et H3. Ces résultats suggèrent que CTCF-T est une protéine qui se lie spécifiquement aux régions ICR, qui s'associe avec différents histones et qui recrute PRMT7. PRMT7 possède une activité méthyl-tansférase envers les histones. Il a été montré que la méthylation des histones marque certains endroits de la chromatine, dirigeant ainsi la méthylation de l'ADN. Notre hypothèse est donc la suivante : la protéine CTCF-T sert de base qui dirige la méthylation des histones par PRMT7 dans les régions ICR, ce qui contribue à marquer la chromatine pour le recrutement de nouvelles méthyl transférases pour méthyler l'ADN. Afin de valider cette hypothèse, nous avons développé un système de méthylation de l'ADN in vivo, dans des oeufs de Xenopus laevis, dans le noyau desquels nous avons mico-injecté la région ICR du locus H19, ainsi que différents vecteurs d'expression pour CTCF-T, PRMT7, et les de novo méthyl transférases (Dnmt3a, Dnmt3b et Dnmt3L). Les CpGs méthyles de la région ICR du locus H19 ont été analysé 48 et 72 heures après l'injection. Cette technique nous a permis de démontrer que les CpGs de la région ICR sont méthyles en présence de CTCF-T et de PRMT7, tandis que les contrôles injectés seulement avec la région ICR ne présentent aucun signe de méthylation. De plus, nous démontrons pour la première fois que la protéine méthyl transférase Dnmt3L est déterminant pour l'établissement de l'empreinte génomique parentale au niveau de la région ICR du locus H19. Aussi, nous confirmons que les activités méthyl transférases de Dnmt3a et Dnmt3b sont complémentaires. Nos données indiquent que les trois protéines Dnmt3 sont impliquées dans la méthylation de l'ADN. En conclusion, nous proposons un mécanisme responsable de la mise en place de nouvelles empreintes génomiques pendant la spermatogenèse : le complexe protéique CTCF-T/PRMT7 dirige la méthylation des histones aboutissant à la méthylation de novo de l'ADN au locus H19.

Placental hydroxymethylation vsmethylation at the imprinting control region 2 on chromosome 11p15.5

In addition to methylated cytosines (5-mCs), hydroxymethylcytosines (5-hmCs) are present in CpG dinucleotide-enriched regions and some transcription regulator binding sites. Unlike methylation, hydroxymethylation does not result in silencing of gene expression, and the most commonly used methods to study methylation, such as techniques based on restriction enzymatic digestion and/or bisulfite modification, are unable to distinguish between them. Genomic imprinting is a process of gene regulation where only one member of an allelic pair is expressed depending on the parental origin. Chromosome 11p15.5 has an imprinting control region (ICR2) that includes a differentially methylated region (KvDMR1) that guarantees parent-specific gene expression. The objective of the present study was to determine the presence of 5-hmC at the KvDMR1 in human placentas. We analyzed 16 third-trimester normal human placentas (chorionic villi). We compared two different methods based on real-time PCR after enzymatic digestion. The first method distinguished methylation from hydroxymethylation, while the other method did not. Unlike other methylation studies, subtle variations of methylation in ICRs could represent a drastic deregulation of the expression of imprinted genes, leading to important phenotypic consequences, and the presence of hydroxymethylation could interfere with the results of many studies. We observed agreement between the results of both methods, indicating the absence of hydroxymethylation at the KvDMR1 in third-trimester placentas. To the best of our knowledge, this is the first study describing the investigation of hydroxymethylation in human placenta using a genomic imprinting model.

Expression and imprinting of insulin-like growth factor II (IGF2) and H19 genes in uterine leiomyomas

Genomic imprinting is defined as a gamete of origin-specific epigenetic modification of DNA leading to differential gene expression in the zygote. Several imprinted genes have been identified and some of them are associated with tumor development. We investigated the expression and the imprinting status of IGF2 and H19 genes in 47 uterine leiomyomas. Using allelic transcription assay, we detected the expression of the IGF2 gene in 10 of a total of 15 informative cases. No loss of imprinting, as determined by the finding of biallelic expression, was detected in any case. The expression of H19 gene was detected in 10 of 20 informative cases and the imprinting pattern was also maintained in all of them. Our data suggest that alterations in IGF2 and H19 genes expression by loss of imprinting do not occur in uterine leiomyomas. (C) 1999 Academic Press.

Loss of imprinting and loss of heterozygosity on 11p15.5 in head and neck squamous cell carcinomas

Background. IGF2 and H19 are reciprocal imprinted genes with paternal and maternal monoallelic expression, respectively. This is interesting, because IGF2 is known as a growth factor, and H19 encodes a RNA with putative tumor suppressor action. Furthermore, IGF2 and H19 are linked genes located on chromosome 11p15.5, a common site of loss of heterozygosity in human cancers.Methods. We performed an allelic-typing assay using a PCR-RFLP-based method for identification of heterozygous Informative cases in head and neck squamous cell carcinomas. Tumoral total RNA was extracted from each of the heterozygotes and further studied by RT-PCR analysis.Results. We detected the expression of the IGF2 gene in 10 of 10 informative cases. Two cases exhibited LOI of the IGF2 gene as evidenced by biallelic expression, and in another case, LOH was coupled with monoallelic expression of this growth factor. LOI for the H19 gene was observed in 1 of 14 informative samples analyzed. In this case, we also detected parallel mono-allelic expression of the IGF2 gene. Down-regulation of the H19 gene was observed in 10 of 14 cases.Conclusion. These findings support the hypothesis that H19 may be a tumor suppressor gene involved In head and neck carcinogenesis. Furthermore, our data showed that genetic and epigenetic chances at 11p15.5 could lead to abnormal expression of imprinted genes in HNSCC. (C) 2001 John Wiley & Sons, Inc.

Genomisches Imprinting Beckwith-Wiedemann-Syndrom assoziierter Gene

In der vorliegenden Arbeit wurde das Imprinting von Genen der Chromosomenregion 11p15.5 des Menschen und des orthologen murinen Abschnitts 7F5 untersucht. Bei der Analyse der humanen Gene H19, IGF2 und KCNQ1OT1 stand deren Regulation durch differentiell methylierte Regionen (DMR) und die Identifizierung von Methylierungsfehlern bei Patienten mit Verdacht auf Beckwith-Wiedemann Syndrom (BWS) im Vordergrund. Hierzu wurden unmethylierte Cytosinnukleotide durch Bisulfitbehandlung in Uracilnukleotide umgewandelt und PCR-amplifizierte DNA-Fragmente sequenziert. Die elterliche Herkunft der Allele wurde mit Hilfe von Einzelnukleotidpolymorphismen (SNP) bestimmt. Während in der H19-Promotorregion in Lymphozyten eine nur tendenziell allelspezifische Methylierung festgestellt werden konnte, wurde im B1-Repeat der H19/IGF2-Region in allen Kontroll- und 20 Patienten-DNAs eine spezifische Methylierung des väterlichen Allels nachgewiesen. Vier BWS-DNAs zeigten hingegen eine nahezu vollständige Hypomethylierung. In der zwe

Conserved characteristics of heterochromatin-forming DNA at the 15q11-q13 imprinting center

Nuclear matrix binding assays (NMBAs) define certain DNA sequences as matrix attachment regions (MARs), which often have cis-acting epigenetic regulatory functions. We used NMBAs to analyze the functionally important 15q11-q13 imprinting center (IC). We find that the IC is composed of an unusually high density of MARs, located in close proximity to the germ line elements that are proposed to direct imprint switching in this region. Moreover, we find that the organization of MARs is the same at the homologous mouse locus, despite extensive divergence of DNA sequence. MARs of this size are not usually associated with genes but rather with heterochromatin-forming areas of the genome. In contrast, the 15q11-q13 region contains multiple transcribed genes and is unusual for being subject to genomic imprinting, causing the maternal chromosome to be more transcriptionally silent, methylated, and late replicating than the paternal chromosome. We suggest that the extensive MAR sequences at the IC are organized as heterochromatin during oogenesis, an organization disrupted during spermatogenesis. Consistent with this model, multicolor fluorescence in situ hybridization to halo nuclei demonstrates a strong matrix association of the maternal IC, whereas the paternal IC is more decondensed, extending into the nuclear halo. This model also provides a mechanism for spreading of the imprinting signal, because heterochromatin at the IC on the maternal chromosome may exert a suppressive position effect in cis. We propose that the germ line elements at the 15q11-q13 IC mediate their effects through the candidate heterochromatin-forming DNA identified in this study.

Gain of imprinting at chromosome 11p15: A pathogenetic mechanism identified in human hepatocarcinomas

Genomic imprinting is a reversible condition that causes parental-specific silencing of maternally or paternally inherited genes. Analysis of DNA and RNA from 52 human hepatocarcinoma samples revealed abnormal imprinting of genes located at chromosome 11p15 in 51% of 37 informative samples. The most frequently detected abnormality was gain of imprinting, which led to loss of expression of genes present on the maternal chromosome. As compared with matched normal liver tissue, hepatocellular carcinomas showed extinction or significant reduction of expression of one of the alleles of the CDKN1C, SLC22A1L, and IGF2 genes. Loss of maternal-specific methylation at the KvDMR1 locus in hepatocarcinoma correlated with abnormal expression of CDKN1C and IGF2, suggesting a function for KvDMR1 as a long-range imprinting center active in adult tissues. These results point to the role of epigenetic mechanisms leading to loss of expression of imprinted genes at chromosome region 11p15 in human tumors.

Dynamic methylation adjustment and counting as part of imprinting mechanisms.

Monoallelic expression in diploid mammalian cells appears to be a widespread phenomenon, with the most studied examples being X-chromosome inactivation in eutherian female cells and genomic imprinting in the mouse and human. Silencing and methylation of certain sites on one of the two alleles in somatic cells is specific with respect to parental source for imprinted genes and random for X-linked genes. We report here evidence indicating that: (i) differential methylation patterns of imprinted genes are not simply copied from the gametes, but rather established gradually after fertilization; (ii) very similar methylation patterns are observed for diploid, tetraploid, parthenogenic, and androgenic preimplantation mouse embryos, as well as parthenogenic and androgenic mouse embryonic stem cells; (iii) haploid parthenogenic embryos do not show methylation adjustment as seen in diploid or tetraploid embryos, but rather retain the maternal pattern. These observations suggest that differential methylation in imprinted genes is achieved by a dynamic process that senses gene dosage and adjusts methylation similar to X-chromosome inactivation.

Imprinted gene expression in in vivo- and in vitro-produced bovine embryos and chorio-allantoic membranes

Cloning by nuclear transfer is often associated with poor results due to abnormal nuclear reprogramming of somatic donor cells and altered gene expression patterns. We investigated the expression patterns of imprinted genes IGF2 and IGF2R in 33- to 36-day bovine embryos and chorio-allantoic membranes derived from in vivo- and in vitro-produced embryos by somatic cell nuclear transfer (SCNT), parthenogenetic activation, and in vitro fertilization (IVF). There was a lower IGF2 expression rate in the SCNT (0.19) and parthenogenetic (0.02) groups when compared to in vivo and IVF embryos (2.01; P < 0.05). In the chorio-allantoic membranes, IGF2 showed a baseline expression pattern (P < 0.05) in parthenotes (0.001) when compared to in vivo, IVF (3.13), and SCNT (0.98) groups. IGF2R was less expressed (P < 0.05) in SCNT chorio-allantoic membranes (0.25) when compared to the in vivo group. The low expression of IGF2 in parthenogenetic embryos and chorio-allantoic membranes confirms its imprinted status in cattle. Alterations in the relative frequency of IGF2 and IGF2R transcripts were observed in SCNT-derived bovine embryos and chorioallantoic membranes, respectively, supporting the hypothesis that abnormalities in the expression of imprinted genes are causes of the low efficiency of SCNT procedures in this species.