The human imprintome: regulatory mechanisms, methods of ascertainment, and roles in disease susceptibility.

Imprinted genes form a special subset of the genome, exhibiting monoallelic expression in a parent-of-origin-dependent fashion. This monoallelic expression is controlled by parental-specific epigenetic marks, which are established in gametogenesis and early embryonic development and are persistent in all somatic cells throughout life. We define this specific set of cis-acting epigenetic regulatory elements as the imprintome, a distinct and specially tasked subset of the epigenome. Imprintome elements contain DNA methylation and histone modifications that regulate monoallelic expression by affecting promoter accessibility, chromatin structure, and chromatin configuration. Understanding their regulation is critical because a significant proportion of human imprinted genes are implicated in complex diseases. Significant species variation in the repertoire of imprinted genes and their epigenetic regulation, however, will not allow model organisms solely to be used for this crucial purpose. Ultimately, only the human will suffice to accurately define the human imprintome.

[1]  R. Weksberg,et al.  Molecular Findings in Beckwith–Wiedemann Syndrome , 2013, American journal of medical genetics. Part C, Seminars in medical genetics.

[2]  T. Haaf Imprinting and the Epigenetic Asymmetry between Parental Genomes , 2011 .

[3]  Andrew P Feinberg,et al.  A nucleolar protein, H19 opposite tumor suppressor (HOTS), is a tumor growth inhibitor encoded by a human imprinted H19 antisense transcript , 2011, Proceedings of the National Academy of Sciences of the United States of America.

[4]  J. Cavaille,et al.  Do repeated arrays of regulatory small‐RNA genes elicit genomic imprinting? , 2011, BioEssays : news and reviews in molecular, cellular and developmental biology.

[5]  E. Kavanagh,et al.  The hallmarks of CDKN1C (p57, KIP2) in cancer. , 2011, Biochimica et biophysica acta.

[6]  A. Klein-Szanto,et al.  Thymine DNA Glycosylase Is Essential for Active DNA Demethylation by Linked Deamination-Base Excision Repair , 2011, Cell.

[7]  Xiaochen Bo,et al.  Genome-wide analysis of the relationships between DNaseI HS, histone modifications and gene expression reveals distinct modes of chromatin domains , 2011, Nucleic acids research.

[8]  Kathryn Roeder,et al.  Multiple Recurrent De Novo CNVs, Including Duplications of the 7q11.23 Williams Syndrome Region, Are Strongly Associated with Autism , 2011, Neuron.

[9]  L. Lefebvre,et al.  Developmental regulation of somatic imprints. , 2011, Differentiation; research in biological diversity.

[10]  A. Ferguson-Smith,et al.  Nonallelic Transcriptional Roles of CTCF and Cohesins at Imprinted Loci , 2011, Molecular and Cellular Biology.

[11]  Mark I. McCarthy,et al.  Identification of an imprinted master trans-regulator at the KLF14 locus related to multiple metabolic phenotypes , 2011, Nature Genetics.

[12]  E. Keverne Epigenetics and brain evolution. , 2011, Epigenomics.

[13]  H. Stefánsson,et al.  Maternally derived microduplications at 15q11-q13: implication of imprinted genes in psychotic illness. , 2011, The American journal of psychiatry.

[14]  D. Dorsett Cohesin: genomic insights into controlling gene transcription and development. , 2011, Current opinion in genetics & development.

[15]  S. Murphy,et al.  Novel retrotransposed imprinted locus identified at human 6p25 , 2011, Nucleic acids research.

[16]  W. Reik,et al.  5-Hydroxymethylcytosine in the mammalian zygote is linked with epigenetic reprogramming. , 2011, Nature communications.

[17]  M. Lacher,et al.  Altered expression of imprinted genes in Wilms tumors. , 2011, Oncology reports.

[18]  D. Pinto,et al.  A novel approach identifies new differentially methylated regions (DMRs) associated with imprinted genes. , 2011, Genome research.

[19]  M. Marra,et al.  Characterization of the Contradictory Chromatin Signatures at the 3′ Exons of Zinc Finger Genes , 2011, PloS one.

[20]  G. Pfeifer,et al.  Reprogramming of the paternal genome upon fertilization involves genome-wide oxidation of 5-methylcytosine , 2011, Proceedings of the National Academy of Sciences.

[21]  A. Guillaumet-Adkins,et al.  Human imprinted retrogenes exhibit non-canonical imprint chromatin signatures and reside in non-imprinted host genes , 2011, Nucleic acids research.

[22]  R. Weksberg,et al.  Disruption of genomic neighbourhood at the imprinted IGF2-H19 locus in Beckwith–Wiedemann syndrome and Silver–Russell syndrome , 2011, Human molecular genetics.

[23]  A. Murrell,et al.  Quantitative analysis of DNA methylation at all human imprinted regions reveals preservation of epigenetic stability in adult somatic tissue , 2011, Epigenetics & Chromatin.

[24]  F. Macciardi,et al.  Role of UBE3A and ATP10A genes in autism susceptibility region 15q11-q13 in an Italian population: A positive replication for UBE3A , 2011, Psychiatry Research.

[25]  S. Mansour,et al.  An atypical case of hypomethylation at multiple imprinted loci , 2011, European Journal of Human Genetics.

[26]  R. Schneider,et al.  Chatting histone modifications in mammals. , 2010, Briefings in functional genomics.

[27]  T. Eggermann,et al.  Genetic and epigenetic findings in Silver-Russell syndrome. , 2010, Pediatric endocrinology reviews : PER.

[28]  B. Hutter,et al.  Imprinted genes show unique patterns of sequence conservation , 2010, BMC Genomics.

[29]  H. Bayley,et al.  Identification of epigenetic DNA modifications with a protein nanopore. , 2010, Chemical communications.

[30]  Jingde Zhu,et al.  Whole-genome DNA methylation profiling using MethylCap-seq. , 2010, Methods.

[31]  Benjamin Tycko,et al.  Allele-specific DNA methylation: beyond imprinting. , 2010, Human molecular genetics.

[32]  Craig Newschaffer,et al.  Parent-Of-Origin Effects in Autism Identified through Genome-Wide Linkage Analysis of 16,000 SNPs , 2010, PloS one.

[33]  A. Ferguson-Smith,et al.  Uniparental disomy and human disease: An overview , 2010, American journal of medical genetics. Part C, Seminars in medical genetics.

[34]  K. Buiting Prader–Willi syndrome and Angelman syndrome , 2010, American journal of medical genetics. Part C, Seminars in medical genetics.

[35]  I. Temple,et al.  Epigenotype–phenotype correlations in Silver–Russell syndrome , 2010, Journal of Medical Genetics.

[36]  C. Kanduri,et al.  Kcnq1ot1 noncoding RNA mediates transcriptional gene silencing by interacting with Dnmt1 , 2010, Development.

[37]  H. Moore,et al.  Telomeric NAP1L4 and OSBPL5 of the KCNQ1 Cluster, and the DECORIN Gene Are Not Imprinted in Human Trophoblast Stem Cells , 2010, PloS one.

[38]  D. Monk Deciphering the cancer imprintome. , 2010, Briefings in functional genomics.

[39]  W. Cooper,et al.  How genome-wide approaches can be used to unravel the remaining secrets of the imprintome. , 2010, Briefings in functional genomics.

[40]  M. Nóbrega,et al.  Genome‐wide maps of transcription regulatory elements , 2010, Wiley interdisciplinary reviews. Systems biology and medicine.

[41]  B. Horsthemke,et al.  Imprinting of RB1 (the new kid on the block). , 2010, Briefings in functional genomics.

[42]  C. Köhler,et al.  Mechanisms and evolution of genomic imprinting in plants , 2010, Heredity.

[43]  A. Green,et al.  The IG-DMR and the MEG3-DMR at Human Chromosome 14q32.2: Hierarchical Interaction and Distinct Functional Properties as Imprinting Control Centers , 2010, PLoS genetics.

[44]  Déborah Bourc'his,et al.  [Evolution of genomic imprinting in mammals: what a zoo!]. , 2010, Medecine sciences : M/S.

[45]  Tyson A. Clark,et al.  Direct detection of DNA methylation during single-molecule, real-time sequencing , 2010, Nature Methods.

[46]  Steven Henikoff,et al.  Histone variants — ancient wrap artists of the epigenome , 2010, Nature Reviews Molecular Cell Biology.

[47]  J. Whittaker,et al.  Epigenetic signatures of Silver–Russell syndrome , 2010, Journal of Medical Genetics.

[48]  A. Hoffman,et al.  Loss of IGF2 imprinting is associated with abrogation of long-range intrachromosomal interactions in human cancer cells. , 2010, Human molecular genetics.

[49]  K. Kernohan,et al.  ATRX partners with cohesin and MeCP2 and contributes to developmental silencing of imprinted genes in the brain. , 2010, Developmental cell.

[50]  C. Boerkoel,et al.  Methylation profiling in individuals with Russell–Silver syndrome , 2010, American journal of medical genetics. Part A.

[51]  S. Mehta,et al.  Methylation analysis of 79 patients with growth restriction reveals novel patterns of methylation change at imprinted loci , 2010, European Journal of Human Genetics.

[52]  P. Laird,et al.  Analysis of the Association between CIMP and BRAFV600E in Colorectal Cancer by DNA Methylation Profiling , 2009, PloS one.

[53]  R. Siebert,et al.  The Human Retinoblastoma Gene Is Imprinted , 2009, PLoS genetics.

[54]  A. Papenfuss,et al.  Eggs, embryos and the evolution of imprinting: insights from the platypus genome. , 2009, Reproduction, fertility, and development.

[55]  M. Shirakawa,et al.  Structural basis for recognition of H3K4 methylation status by the DNA methyltransferase 3A ATRX–DNMT3–DNMT3L domain , 2009, EMBO reports.

[56]  Christel Krueger,et al.  Cohesin Is Required for Higher-Order Chromatin Conformation at the Imprinted IGF2-H19 Locus , 2009, PLoS genetics.

[57]  Laurent Journot,et al.  H19 acts as a trans regulator of the imprinted gene network controlling growth in mice , 2009, Development.

[58]  R. Jirtle Epigenome: the program for human health and disease. , 2009, Epigenomics.

[59]  R. Feil,et al.  Chromatin mechanisms in genomic imprinting , 2009, Mammalian Genome.

[60]  K. Hata,et al.  Histone methylation is mechanistically linked to DNA methylation at imprinting control regions in mammals. , 2009, Human molecular genetics.

[61]  Anne H. O'Donnell,et al.  Mammalian cytosine methylation at a glance , 2009, Journal of Cell Science.

[62]  R. Delorme,et al.  Screening for Genomic Rearrangements and Methylation Abnormalities of the 15q11-q13 Region in Autism Spectrum Disorders , 2009, Biological Psychiatry.

[63]  D. Gudbjartsson,et al.  New common variants affecting susceptibility to basal cell carcinoma , 2009, Nature Genetics.

[64]  A. Beaudet,et al.  Epigenetic profiling at mouse imprinted gene clusters reveals novel epigenetic and genetic features at differentially methylated regions. , 2009, Genome research.

[65]  Ru Huang,et al.  The function of non-coding RNAs in genomic imprinting , 2009, Development.

[66]  I. Temple,et al.  Hypomethylation at multiple maternally methylated imprinted regions including PLAGL1 and GNAS loci in Beckwith–Wiedemann syndrome , 2009, European Journal of Human Genetics.

[67]  Kohta Ikegami,et al.  Interplay between DNA methylation, histone modification and chromatin remodeling in stem cells and during development. , 2009, The International journal of developmental biology.

[68]  E. Wagner,et al.  Identification of the human homolog of the imprinted mouse Air non-coding RNA. , 2008, Genomics.

[69]  B. Crespi,et al.  Genomic imprinting in the development and evolution of psychotic spectrum conditions , 2008, Biological reviews of the Cambridge Philosophical Society.

[70]  N. Kato,et al.  Association study of the 15q11‐q13 maternal expression domain in Japanese autistic patients , 2008, American journal of medical genetics. Part B, Neuropsychiatric genetics : the official publication of the International Society of Psychiatric Genetics.

[71]  Jennette D. Driscoll,et al.  Chromosome 15q11–13 duplication syndrome brain reveals epigenetic alterations in gene expression not predicted from copy number , 2008, Journal of Medical Genetics.

[72]  Thomas W. Mühleisen,et al.  Large recurrent microdeletions associated with schizophrenia , 2008, Nature.

[73]  B. Crespi,et al.  Battle of the sexes may set the brain , 2008, Nature.

[74]  A. Gabory,et al.  The H19 locus acts in vivo as a tumor suppressor , 2008, Proceedings of the National Academy of Sciences.

[75]  G. Schotta,et al.  PR-SET7 and SUV4-20H regulate H4 lysine-20 methylation at imprinting control regions in the mouse , 2008, EMBO Reports.

[76]  B. Horsthemke,et al.  Mechanisms of imprinting of the Prader–Willi/Angelman region , 2008, American journal of medical genetics. Part A.

[77]  A. Hattersley,et al.  Hypomethylation of multiple imprinted loci in individuals with transient neonatal diabetes is associated with mutations in ZFP57 , 2008, Nature Genetics.

[78]  J. Deakin,et al.  The Status of Dosage Compensation in the Multiple X Chromosomes of the Platypus , 2008, PLoS genetics.

[79]  R. Durbin,et al.  A Bayesian deconvolution strategy for immunoprecipitation-based DNA methylome analysis , 2008, Nature Biotechnology.

[80]  A. Ferguson-Smith,et al.  Genomic imprinting at the mammalian Dlk1-Dio3 domain. , 2008, Trends in genetics : TIG.

[81]  Marwan Shinawi,et al.  Prader-Willi phenotype caused by paternal deficiency for the HBII-85 C/D box small nucleolar RNA cluster , 2008, Nature Genetics.

[82]  Sean McWilliam,et al.  Origin, evolution, and biological role of miRNA cluster in DLK-DIO3 genomic region in placental mammals. , 2008, Molecular biology and evolution.

[83]  A. Hartemink,et al.  Computational and experimental identification of novel human imprinted genes. , 2007, Genome research.

[84]  John N. Hutchinson,et al.  Widespread Monoallelic Expression on Human Autosomes , 2007, Science.

[85]  Peter A. Jones,et al.  DNA methylation: The nuts and bolts of repression , 2007, Journal of cellular physiology.

[86]  G. Felsenfeld,et al.  We gather together: insulators and genome organization. , 2007, Current opinion in genetics & development.

[87]  Xiaodong Cheng,et al.  Structure of Dnmt3a bound to Dnmt3L suggests a model for de novo DNA methylation , 2007, Nature.

[88]  C. Allis,et al.  DNMT3L connects unmethylated lysine 4 of histone H3 to de novo methylation of DNA , 2007, Nature.

[89]  Charles Lee,et al.  Identification of the Imprinted KLF14 Transcription Factor Undergoing Human-Specific Accelerated Evolution , 2007, PLoS genetics.

[90]  W. Reik,et al.  A developmental window of opportunity for imprinted gene silencing mediated by DNA methylation and the Kcnq1ot1 noncoding RNA , 2007, Mammalian Genome.

[91]  Dany Severac,et al.  Zac1 regulates an imprinted gene network critically involved in the control of embryonic growth. , 2006, Developmental cell.

[92]  P. Jelinic,et al.  The Testis-Specific Factor CTCFL Cooperates with the Protein Methyltransferase PRMT7 in H19 Imprinting Control Region Methylation , 2006, PLoS biology.

[93]  M. Loda,et al.  Down‐regulation of p21 (CDKN1A/CIP1) is inversely associated with microsatellite instability and CpG island methylator phenotype (CIMP) in colorectal cancer , 2006, The Journal of pathology.

[94]  S. Tilghman,et al.  Elongation of the Kcnq1ot1 transcript is required for genomic imprinting of neighboring genes. , 2006, Genes & development.

[95]  S. Apostolidou,et al.  Limited evolutionary conservation of imprinting in the human placenta. , 2006, Proceedings of the National Academy of Sciences of the United States of America.

[96]  T. Bestor,et al.  Origins of extreme sexual dimorphism in genomic imprinting , 2006, Cytogenetic and Genome Research.

[97]  A. Hoffman,et al.  Cross-species clues of an epigenetic imprinting regulatory code for the IGF2R gene , 2006, Cytogenetic and Genome Research.

[98]  W. Reik,et al.  How imprinting centres work , 2006, Cytogenetic and Genome Research.

[99]  J. Molès,et al.  The Candidate Tumor Suppressor Gene ZAC Is Involved in Keratinocyte Differentiation and Its Expression Is Lost in Basal Cell Carcinomas , 2005, Molecular Cancer Research.

[100]  M. Nakao,et al.  Epigenetic silencing of the imprinted gene ZAC by DNA methylation is an early event in the progression of human ovarian cancer , 2005, International journal of cancer.

[101]  K. Shearwin,et al.  Transcriptional interference--a crash course. , 2005, Trends in genetics : TIG.

[102]  A. Hartemink,et al.  Genome-wide prediction of imprinted murine genes. , 2005, Genome research.

[103]  M. Oshimura,et al.  ZAC, LIT1 (KCNQ1OT1) and p57KIP2 (CDKN1C) are in an imprinted gene network that may play a role in Beckwith–Wiedemann syndrome , 2005, Nucleic acids research.

[104]  W. Reik,et al.  The two-domain hypothesis in Beckwith–Wiedemann syndrome: autonomous imprinting of the telomeric domain of the distal chromosome 7 cluster , 2005 .

[105]  K. Friedrich,et al.  Loss of expression of ZAC/LOT1 in squamous cell carcinomas of head and neck , 2004, Head & neck.

[106]  Lisa M. D'Souza,et al.  Genome sequence of the Brown Norway rat yields insights into mammalian evolution , 2004, Nature.

[107]  R. Weksberg,et al.  Insulator and silencer sequences in the imprinted region of human chromosome 11p15.5. , 2003, Human molecular genetics.

[108]  Hoguen Kim,et al.  Concerted promoter hypermethylation of hMLH1, p16INK4A, and E‐cadherin in gastric carcinomas with microsatellite instability , 2003, The Journal of pathology.

[109]  D. Haig,et al.  What good is genomic imprinting: the function of parent-specific gene expression , 2003, Nature Reviews Genetics.

[110]  Tony Kouzarides,et al.  The Methyl-CpG-binding Protein MeCP2 Links DNA Methylation to Histone Methylation* , 2003, The Journal of Biological Chemistry.

[111]  S. O’Brien,et al.  Placental mammal diversification and the Cretaceous–Tertiary boundary , 2003, Proceedings of the National Academy of Sciences of the United States of America.

[112]  J. J. Breen,et al.  BORIS, a novel male germ-line-specific protein associated with epigenetic reprogramming events, shares the same 11-zinc-finger domain with CTCF, the insulator protein involved in reading imprinting marks in the soma , 2002, Proceedings of the National Academy of Sciences of the United States of America.

[113]  M. F. Williams Primate encephalization and intelligence. , 2002, Medical hypotheses.

[114]  Daiya Takai,et al.  Comprehensive analysis of CpG islands in human chromosomes 21 and 22 , 2002, Proceedings of the National Academy of Sciences of the United States of America.

[115]  D. Barlow,et al.  The non-coding Air RNA is required for silencing autosomal imprinted genes , 2002, Nature.

[116]  A. Coupe,et al.  Relaxation of imprinted expression of ZAC and HYMAI in a patient with transient neonatal diabetes mellitus , 2002, Human Genetics.

[117]  A. Ferguson-Smith,et al.  Comparative sequence analysis of the imprinted Dlk1-Gtl2 locus in three mammalian species reveals highly conserved genomic elements and refines comparison with the Igf2-H19 region. , 2001, Genome research.

[118]  T. Bestor,et al.  Dnmt3L and the Establishment of Maternal Genomic Imprints , 2001, Science.

[119]  S. Murphy,et al.  The neuronatin gene resides in a "micro-imprinted" domain on human chromosome 20q11.2. , 2001, Genomics.

[120]  J. Killian,et al.  Monotreme IGF2 expression and ancestral origin of genomic imprinting. , 2001, The Journal of experimental zoology.

[121]  J. Bockaert,et al.  Characterization of the Methylation-sensitive Promoter of the Imprinted ZAC Gene Supports Its Role in Transient Neonatal Diabetes Mellitus* , 2001, The Journal of Biological Chemistry.

[122]  T. Arzberger,et al.  The expression of the antiproliferative gene ZAC is lost or highly reduced in nonfunctioning pituitary adenomas. , 2000, Cancer research.

[123]  M. Oshimura,et al.  Epigenotype-phenotype correlations in Beckwith-Wiedemann syndrome , 2000, Journal of medical genetics.

[124]  W Miller,et al.  Sequence and comparative analysis of the mouse 1-megabase region orthologous to the human 11p15 imprinted domain. , 2000, Genome research.

[125]  T. Bestor,et al.  The DNA methyltransferases of mammals. , 2000, Human molecular genetics.

[126]  Shirley M. Tilghman,et al.  CTCF mediates methylation-sensitive enhancer-blocking activity at the H19/Igf2 locus , 2000, Nature.

[127]  G. Felsenfeld,et al.  Methylation of a CTCF-dependent boundary controls imprinted expression of the Igf2 gene , 2000, Nature.

[128]  G. Pfeifer,et al.  Maternal-specific footprints at putative CTCF sites in the H19 imprinting control region give evidence for insulator function , 2000, Current Biology.

[129]  M. Srivastava,et al.  H19 and Igf2 monoallelic expression is regulated in two distinct ways by a shared cis acting regulatory region upstream of H19. , 2000, Genes & development.

[130]  J. Byrd,et al.  M6P/IGF2R imprinting evolution in mammals. , 2000, Molecular cell.

[131]  J. Walter,et al.  Embryogenesis: Demethylation of the zygotic paternal genome , 2000, Nature.

[132]  M. Szyf,et al.  Mechanisms of Epigenetic Silencing of the C21 Gene in Y1 Adrenocortical Tumor Cells , 2000, Endocrine research.

[133]  B. Horsthemke,et al.  A previously unrecognised phenotype characterised by obesity, muscular hypotonia, and ability to speak in patients with Angelman syndrome caused by an imprinting defect , 1999, European Journal of Human Genetics.

[134]  S. Tilghman,et al.  Enhancer competition between H19 and Igf2 does not mediate their imprinting. , 1999, Proceedings of the National Academy of Sciences of the United States of America.

[135]  J. Bockaert,et al.  Loss of expression of the candidate tumor suppressor gene ZAC in breast cancer cell lines and primary tumors , 1999, Oncogene.

[136]  J. Strouboulis,et al.  Methylated DNA and MeCP2 recruit histone deacetylase to repress transcription , 1998, Nature Genetics.

[137]  Colin A. Johnson,et al.  Transcriptional repression by the methyl-CpG-binding protein MeCP2 involves a histone deacetylase complex , 1998, Nature.

[138]  M. Bartolomei,et al.  A 5' 2-kilobase-pair region of the imprinted mouse H19 gene exhibits exclusive paternal methylation throughout development , 1997, Molecular and cellular biology.

[139]  M. Loda,et al.  Methylation of the hMLH1 promoter correlates with lack of expression of hMLH1 in sporadic colon tumors and mismatch repair-defective human tumor cell lines. , 1997, Cancer research.

[140]  M. Lalande,et al.  UBE3A/E6-AP mutations cause Angelman syndrome , 1996, Nature Genetics.

[141]  C. Woods,et al.  Somatic overgrowth associated with overexpression of insulin–like growth factor II , 1996, Nature Medicine.

[142]  W. Reik,et al.  Imprinting mutations in the Beckwith-Wiedemann syndrome suggested by altered imprinting pattern in the IGF2-H19 domain. , 1995, Human molecular genetics.

[143]  M. Pazin,et al.  An enhancer deletion affects both H19 and Igf2 expression. , 1995, Genes & development.

[144]  S. Schwartz,et al.  Corrigendum: Inherited microdeletions in the Angelman and Prader–Willi syndromes define an imprinting centre on human chromosome 15 , 1995, Nature Genetics.

[145]  Bernhard Horsthemke,et al.  Inherited microdeletions in the Angelman and Prader–Willi syndromes define an imprinting centre on human chromosome 15 , 1995, Nature Genetics.

[146]  Ziying Liu,et al.  Loss of the imprinted IGF2/cation-independent mannose 6-phosphate receptor results in fetal overgrowth and perinatal lethality. , 1994, Genes & development.

[147]  W. Gerald,et al.  Epigenetic lesions at the H19 locus in Wilms' tumour patients , 1994, Nature Genetics.

[148]  A. Feinberg,et al.  Loss of imprinting of IGF2 is linked to reduced expression and abnormal methylation of H19 in Wilms' tumour , 1994, Nature Genetics.

[149]  DP Barlow Methylation and imprinting: from host defense to gene regulation? , 1993, Science.

[150]  A. Efstratiadis,et al.  Parental imprinting of the mouse insulin-like growth factor II gene , 1991, Cell.

[151]  S. Latt,et al.  Angelman and Prader-Willi syndromes share a common chromosome 15 deletion but differ in parental origin of the deletion. , 1989, American journal of medical genetics.

[152]  A. Bird CpG-rich islands and the function of DNA methylation , 1986, Nature.

[153]  T. Dobzhansky Nothing in Biology Makes Sense Except in the Light of Evolution , 1973 .

[154]  C. Peota Novel approach. , 2011, Minnesota medicine.

[155]  D. Bourc’his,et al.  [Evolution of genomic imprinting in mammals: what a zoo!]. , 2010, Medecine sciences : M/S.

[156]  R. Weksberg,et al.  Beckwith–Wiedemann syndrome , 2010, European Journal of Human Genetics.

[157]  Jahnvi Pflueger,et al.  Distinctive chromatin in human sperm packages genes for embryo development , 2009 .

[158]  L. Goos,et al.  Genomic imprinting and human psychology: cognition, behavior and pathology. , 2008, Advances in experimental medicine and biology.

[159]  A. Hartemink,et al.  imprinted genes Computational and experimental identification of novel human data , 2007 .

[160]  Satoshi Tanaka,et al.  PGC7/Stella protects against DNA demethylation in early embryogenesis , 2007, Nature Cell Biology.

[161]  J. Walter,et al.  Evolution of the Beckwith-Wiedemann syndrome region in vertebrates. , 2005, Genome research.

[162]  N. Niikawa,et al.  Clinical and cytogenetic studies of the Prader-Willi syndrome: Evidence of phenotype-karyotype correlation , 2004, Human Genetics.

[163]  R. Waterland,et al.  Tissue-specific inactivation of murine M6P/IGF2R. , 2003, The American journal of pathology.

[164]  Wendy Dean,et al.  Dynamic reprogramming of DNA methylation in the early mouse embryo. , 2002, Developmental biology.

[165]  Susan M. Drake A Novel Approach. , 1996 .

[166]  T. Lyngbye,et al.  [Beckwith-Wiedemann syndrome]. , 1985, Ugeskrift for laeger.

[167]  Edinburgh Research Explorer Transcript- and tissue-specific imprinting of a tumour suppressor gene , 2022 .