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.

[1]  D. J. Driscoll,et al.  Minimal definition of the imprinting center and fixation of chromosome 15q11-q13 epigenotype by imprinting mutations. , 1996, Proceedings of the National Academy of Sciences of the United States of America.

[2]  J. Mann,et al.  Biallelic expression of imprinted genes in the mouse germ line: implications for erasure, establishment, and mechanisms of genomic imprinting. , 1995, Genes & development.

[3]  B. Vissel,et al.  Identification of two distinct subfamilies of alpha satellite DNA that are highly specific for human chromosome 15. , 1990, Genomics.

[4]  U. K. Laemmli,et al.  In vivo topoisomerase II cleavage of the Drosophila histone and satellite III repeats: DNA sequence and structural characteristics. , 1992, The EMBO journal.

[5]  D. J. Driscoll,et al.  Molecular mechanism of angelman syndrome in two large families involves an imprinting mutation. , 1999, American journal of human genetics.

[6]  Howard Cedar,et al.  A role for nuclear NF–κB in B–cell–specific demethylation of the Igκ locus , 1996, Nature Genetics.

[7]  C. Patriotis,et al.  Interphase chromosomes of Friend-S cells are attached to the matrix structures through the centromeric/telomeric regions. , 1994, DNA and cell biology.

[8]  D. Ledbetter,et al.  Tissue-specific and allele-specific replication timing control in the imprinted human Prader-Willi syndrome region. , 1995, Genes & development.

[9]  W. Miller,et al.  Long human-mouse sequence alignments reveal novel regulatory elements: a reason to sequence the mouse genome. , 1997, Genome research.

[10]  P. Cockerill,et al.  Chromosomal loop anchorage of the kappa immunoglobulin gene occurs next to the enhancer in a region containing topoisomerase II sites , 1986, Cell.

[11]  J. Bennetzen,et al.  Matrix attachment regions and structural colinearity in the genomes of two grass species. , 1998, Nucleic acids research.

[12]  U. Francke,et al.  In vivo nuclease hypersensitivity studies reveal multiple sites of parental origin-dependent differential chromatin conformation in the 150 kb SNRPN transcription unit. , 1999, Human molecular genetics.

[13]  S. Leff,et al.  A mouse model for Prader-Willi syndrome imprinting-centre mutations , 1998, Nature Genetics.

[14]  R. Berezney,et al.  A comprehensive study on the isolation and characterization of the HeLa S3 nuclear matrix. , 1991, Journal of cell science.

[15]  D. J. Driscoll,et al.  A novel imprinted gene, encoding a RING zinc-finger protein, and overlapping antisense transcript in the Prader-Willi syndrome critical region. , 1999, Human molecular genetics.

[16]  J. B. Rattner,et al.  Topoisomerase II alpha is associated with the mammalian centromere in a cell cycle- and species-specific manner and is required for proper centromere/kinetochore structure , 1996, The Journal of cell biology.

[17]  D. J. Driscoll,et al.  Gene structure, DNA methylation, and imprinted expression of the human SNRPN gene. , 1996, American journal of human genetics.

[18]  L. Stubbs,et al.  Structure and function correlations at the imprinted mouse Snrpn locus , 1998, Mammalian Genome.

[19]  R. Paro,et al.  Identification of a silencing element in the human 15q11-q13 imprinting center by using transgenic Drosophila. , 1998, Proceedings of the National Academy of Sciences of the United States of America.

[20]  T. Jenuwein,et al.  Dependence of enhancer-mediated transcription of the immunoglobulin mu gene on nuclear matrix attachment regions. , 1994, Science.

[21]  U. K. Laemmli,et al.  Specific inhibition of DNA binding to nuclear scaffolds and histone H1 by distamycin. The role of oligo(dA).oligo(dT) tracts. , 1989, Journal of molecular biology.

[22]  S. H. Wilson,et al.  Enzymes for modifying and labeling DNA and RNA. , 1987, Methods in enzymology.

[23]  M. Nöthen,et al.  Sporadic imprinting defects in Prader-Willi syndrome and Angelman syndrome: implications for imprint-switch models, genetic counseling, and prenatal diagnosis. , 1998, American journal of human genetics.

[24]  K. Taylor,et al.  Intragenic matrix attachment and DNA-protein interactions in the human X-linked Hprt gene. , 1995, Biochimica et biophysica acta.

[25]  U. K. Laemmli,et al.  Cohabitation of scaffold binding regions with upstream/enhancer elements of three developmentally regulated genes of D. melanogaster , 1986, Cell.

[26]  W. Bickmore,et al.  Scaffold attachments within the human genome. , 1997, Journal of cell science.

[27]  R. Nagaraj,et al.  Banded krait minor-satellite (Bkm)-associated Y chromosome-specific repetitive DNA in mouse. , 1994, Nucleic acids research.

[28]  H. Crouse The Controlling Element in Sex Chromosome Behavior in Sciara. , 1960, Genetics.

[29]  D. J. Driscoll,et al.  Imprinting-mutation mechanisms in Prader-Willi syndrome. , 1999, American journal of human genetics.

[30]  J. Bressler,et al.  Genetics of Angelman syndrome. , 1999, American journal of human genetics.

[31]  B. Vogelstein,et al.  Nonrandom distribution of repeated DNA sequences with respect to supercoiled loops and the nuclear matrix. , 1982, Proceedings of the National Academy of Sciences of the United States of America.

[32]  S. Saitoh,et al.  Imprinting in Prader-Willi and Angelman syndromes. , 1998, Trends in genetics : TIG.

[33]  D. Higgs,et al.  Nuclear scaffold attachment sites in the human globin gene complexes. , 1988, The EMBO journal.

[34]  L. Strausbaugh,et al.  High density of an SAR-associated motif differentiates heterochromatin from euchromatin. , 1996, Journal of theoretical biology.

[35]  B. Horsthemke,et al.  Imprinting mutations on human chromosome 15 , 1997, Human mutation.

[36]  T A Gray,et al.  An imprinted, mammalian bicistronic transcript encodes two independent proteins. , 1999, Proceedings of the National Academy of Sciences of the United States of America.

[37]  T. Jenuwein,et al.  Extension of chromatin accessibility by nuclear matrix attachment regions , 1997, Nature.

[38]  A. Poustka,et al.  Imprint switching on human chromosome 15 may involve alternative transcripts of the SNRPN gene , 1996, Nature Genetics.

[39]  T. Grigliatti,et al.  Genomic imprinting and position-effect variegation in Drosophila melanogaster. , 1999, Genetics.

[40]  W. Gehring,et al.  In vivo analysis of scaffold‐associated regions in Drosophila: a synthetic high‐affinity SAR binding protein suppresses position effect variegation , 1998, The EMBO journal.

[41]  N. Seeman,et al.  Sequence-specific Recognition of Double Helical Nucleic Acids by Proteins (base Pairs/hydrogen Bonding/recognition Fidelity/ion Binding) , 2022 .

[42]  S. Krawetz,et al.  Computer-assisted search for sites of nuclear matrix attachment. , 1996, Genomics.

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

[44]  Susan M. Gasser,et al.  A glimpse at chromosomal order , 1987 .

[45]  D. J. Driscoll,et al.  Allele-specific replication timing of imprinted gene regions , 1993, Nature.

[46]  B. Wakimoto,et al.  Heterochromatin and gene expression in Drosophila. , 1995, Annual review of genetics.

[47]  A. Brand,et al.  RAP-1 factor is necessary for DNA loop formation in vitro at the silent mating type locus HML , 1989, Cell.

[48]  U. K. Laemmli,et al.  Organization of the higher-order chromatin loop: specific DNA attachment sites on nuclear scaffold , 1984, Cell.

[49]  D. J. Driscoll,et al.  Imprinting of a RING zinc-finger encoding gene in the mouse chromosome region homologous to the Prader-Willi syndrome genetic region. , 1999, Human molecular genetics.

[50]  B. Horsthemke,et al.  The chromosome 15 imprinting centre (IC) region has undergone multiple duplication events and contains an upstream exon of SNRPN that is deleted in all Angelman syndrome patients with an IC microdeletion. , 1999, Human molecular genetics.