Geneimprint

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• Twentieth Anniversary of the Agouti Mouse Study
• Human Imprintome Genomic Map
• KCNK9 Loss of Imprinting in Triple Negative Breast Cancer
• Fifty Years of Research - Randy L. Jirtle
• I had an Epiphany: Desire to Voluntarily Exercise May Be Epigenetically Determined in the Womb
• William G. Kaelin, Jr. - Recipient of the 2019 Nobel Prize in Physiology or Medicine
• Jirtle Receives EMGS 2019 Alexander Hollaender Award
• Pioneer Scientists: Jack Fowler and Alfred Knudson
• Imprintome Definition Clarified
• Western Diet Blocks Gut Microbiome Programing of the Host Epigenome
• Imprinted Genes Implicated in the Puzzle of Autism
• Environmental Lead Exposure in Early Childhood Alters Imprinted Gene Regulation
• p16 Epimutation Causes Cancer
• Antagonistic Growth Promoting Effects of Imprinted Genes
• Autism and Schizophrenia: The Antithesis of Each Other?
• Environmental Epigenomics in Health and Disease
• Radiation Epigenetics
• These Little Piggies!
• Epigenetic Basis of Suicide Risk?
• Genome-wide Mapping of Human Imprinted Genes
• Negative Bisphenol A Effects on the Epigenome Blocked by Nutritional Supplements
• Imprinted and More Equal
• Genistein methylates the fetal epigenome
• Genome-wide prediction of imprinted murine genes
• Phylogenetic footprint analysis of IGF2 in extant mammals
• Assisted Reproductive Technology: Cautionary Signs
• Imprinting Evolved Over 125 Million Years Ago
• The Price of Silence
• Callipyge Mutation Identified
• Divergent Evolution in M6P/IGF2R Imprinting: Implications for Cloning and Cancer
• IGF2 Imprinting Evolution in Mammals
• Marsupials and Eutherians Reunited
• Imprinting of PEG3
• M6P/IGF2R Imprinting Evolution in Mammals

Genome-wide Mapping of Human Imprinted Genes

29 November 2007: Genomic imprinting is an epigenetic form of gene regulation that results in only the copy inherited from the mother or father to function (Jirtle and Weidman 2007). The phenomenon of imprinting evolved about 150 M years ago in a common ancester to mammals that have live birth - the Therian mammals (Marsupials and Eutherians) (Killian et al. 2000).

Imprinted genes are at high risk for envolvement in diseases since a single genetic mutation or an environmentally-induced epigenetic change can alter their function. Imprinting deregulation results in developmental disorders such as Beckwith-Wiedemann, Angelman and Prader-Willi syndromes. Additionally, the incidence of these disorders is increased in humans conceived by assisted reproductive technology (ART) because of detrimental changes in imprinted gene regulation (Niemitz and Feinberg 2004).

A genome-wide search for imprinted genes in the human genome, with the use of computer-learning algorithms, resulted in the identification of 156 novel candidate imprinted genes (Luedi et al. 2007). Interestingly, humans are predicted to not only contain fewer imprinted genes than mice, but the repertoire of these genes in humans is also markedly different than that in mice (Luedi et al. 2007, Luedi et al. 2005). Consequently, despite the immense popularity of mice as models for human ailments, they may not be a suitable choice for studying diseases resulting principally from the epigenetic deregulation of imprinted genes, or for assessing human risk from environmental factors that alter the epigenome.

Two of the candidate imprinted genes identified were subsequently shown experimentally to be imprinted: KCNK9 is predominantly expressed in the cerebellum of the brain, is a known oncogene, and may be involved in bipolar disorder and epilepsy, while DLGAP2 may play a role in the molecular organization of synapses and in neuronal cell signaling, and is a candidate bladder cancer tumor suppressor. By mapping these candidate imprinted gene onto the disease landscape defined by linkage analyses, we are poised to determine the importance of imprinting deregulation in the etiology of the major complex human diseases and neurological disorders that plague mankind.