Chromosome instability and immunodeficiency syndrome caused by mutations in a DNA methyltransferase gene

The recessive autosomal disorder known as ICF syndrome (for immunodeficiency, centromere instability and facial anomalies; Mendelian Inheritance in Man number 242860) is characterized by variable reductions in serum immunoglobulin levels which cause most ICF patients to succumb to infectious diseases before adulthood. Mild facial anomalies include hypertelorism, low-set ears, epicanthal folds and macroglossia. The cytogenetic abnormalities in lymphocytes are exuberant: juxtacentromeric heterochromatin is greatly elongated and thread-like in metaphase chromosomes, which is associated with the formation of complex multiradiate chromosomes. The same juxtacentromeric regions are subject to persistent interphase self-associations and are extruded into nuclear blebs or micronuclei. Abnormalities are largely confined to tracts of classical satellites 2 and 3 at juxtacentromeric regions of chromosomes 1, 9 and 16. Classical satellite DNA is normally heavily methylated at cytosine residues, but in ICF syndrome it is almost completely unmethylated in all tissues. ICF syndrome is the only genetic disorder known to involve constitutive abnormalities of genomic methylation patterns. Here we show that five unrelated ICF patients have mutations in both alleles of the gene that encodes DNA methyltransferase 3B (refs 5, 6). Cytosine methylation is essential for the organization and stabilization of a specific type of heterochromatin, and this methylation appears to be carried out by an enzyme specialized for the purpose.

Mutation of a nuclear succinate dehydrogenase gene results in mitochondrial respiratory chain deficiency

We now report a mutation in the nuclear-encoded flavoprotein (Fp) subunit gene of the succinate dehydrogenase (SDH) in two siblings with complex II deficiency presenting as Leigh syndrome. Both patients were homozygous for an Arg554Trp substitution in the Fp subunit. Their parents (first cousins) were heterozygous for the mutation that occurred in a conserved domain of the protein and was absent from 120 controls. The deleterious effect of the Arg to Trp substitution on the catalytic activity of SDH was observed in a SDH- yeast strain transformed with mutant Fp cDNA. The Fp subunit gene is duplicated in the human genome (3q29; 5p15), with only the gene on chromosome 5 expressed in human-hamster somatic cell hybrids. This is the first report of a nuclear gene mutation causing a mitochondrial respiratory chain deficiency in humans.

Chromosome methylation patterns during mammalian preimplantation development

DNA methylation patterns were evaluated during preimplantation mouse development by analyzing the binding of monoclonal antibody to 5-methylcytosine (5-MeC) on metaphase chromosomes. Specific chromosome patterns were observed in each cell stage. A banding pattern predominated in chromosomes at the one-cell stage. Banding was replaced at the two-cell stage by an asymmetrical labeling of the sister chromatids. Then, the proportion of asymmetrical chromosomes decreased by one-half at each cell division until the blastocyst stage, and chromosomes became progressively symmetrical and weakly labeled. Our results indicate that chromosome demethylation is associated with each DNA replication and suggest that a passive mechanism predominates during early development.

Delayed and incomplete reprogramming of chromosome methylation patterns in bovine cloned embryos

Full-term development has now been achieved in several mammalian species by transfer of somatic nuclei into enucleated oocytes [1, 2]. Although a high proportion of such reconstructed embryos can evolve until the blastocyst stage, only a few percent develop into live offspring, which often exhibit developmental abnormalities [3, 4]. Regulatory epigenetic markers such as DNA methylation are imposed on embryonic cells as normal development proceeds, creating differentiated cell states. Cloned embryos require the erasure of their somatic epigenetic markers so as to regain a totipotent state [5]. Here we report on differences in the dynamics of chromosome methylation between cloned and normal bovine embryos before implantation. We show that cloned embryos fail to reproduce distinguishable parental-chromosome methylation patterns after fusion and maintain their somatic pattern during subsequent stages, mainly by a highly reduced efficiency of the passive demethylation process. Surprisingly, chromosomes appear constantly undermethylated on euchromatin in morulae and blastocysts, while centromeric heterochromatin remains more methylated than that of normal embryos. We propose that the abnormal time-dependent methylation events spanning the preimplantation development of clones may significantly interfere with the epigenetic reprogramming, contributing to the high incidence of physiological anomalies occurring later during pregnancy or after clone birth.

A simple method for simultaneous R- or G-banding and fluorescence in situ hybridization of small single-copy genes

A significant improvement in fluorescence in situ hybridization, enabling the detection of single-copy genes as small as 500 bp directly on banded chromosomes, is presented. The induction of chromosome banding, which does not require additional handling or any system of amplification, is obtained simply by using an alkaline (pH 11) p-phenylenediamine anti-fade solution. As the banding produced is related to the timing of 5-bromodeoxyuridine incorporation, either R- or G-banding, constitutive heterochromatin staining, or chromosome asymmetry can be observed simultaneously with the fluorescent hybridized spots. Results of hybridization of small cDNA probes for the human genes for motilin, thymidylate synthetase, and lymphocyte activation-3 are provided as examples of the high-resolution mapping obtainable with this technique.

Hypomethylation of subtelomeric regions in ICF syndrome is associated with abnormally short telomeres and enhanced transcription from telomeric regions

Telomeres and adjacent subtelomeric regions are packaged as heterochromatin in many organisms. The heterochromatic features include DNA methylation, histones H3-Lys9 (Lysine 9) and H4-Lys20 (Lysine 20) methylation and heterochromatin protein1 alpha binding. Subtelomeric DNA is hypomethylated in human sperm and ova, and these regions are subjected to de novo methylation during development. In mice this activity is carried out by DNA methyltransferase 3b (Dnmt3b). Mutations in DNMT3B in humans lead to the autosomal-recessive ICF (immunodeficiency, centromeric region instability, facial anomalies) syndrome. Here we show that, in addition to several satellite and non-satellite repeats, the subtelomeric regions in lymphoblastoid and fibroblast cells of ICF patients are also hypomethylated to similar levels as in sperm. Furthermore, the telomeres are abnormally short in both the telomerase-positive and -negative cells, and many chromosome ends lack detectable telomere fluorescence in situ hybridization signals from either one or both sister-chromatids. In contrast to Dnmt3a/b(-/-) mouse embryonic stem cells, increased telomere sister-chromatid exchange was not observed in ICF cells. Hypomethylation of subtelomeric regions was associated in the ICF cells with advanced telomere replication timing and elevated levels of transcripts emanating from telomeric regions, known as TERRA (telomeric-repeat-containing RNA) or TelRNA. The current findings provide a mechanistic explanation for the abnormal telomeric phenotype observed in ICF syndrome and highlights the link between TERRA/TelRNA and structural telomeric integrity.

Sequence of DNA replication in 277 R- and Q-bands of human chromosomes using a BrdU treatment

Replication times for all important chromosome bands, of both types R and Q (277 structures) are analysed. The R-bands form a group of structures whose DNA replicates during the early S-phase, while the DNA situated in the Q-bands replicates during the late S-phase. There may not exist overlapping between replication times of these two types of structures. The widest R-bands are those which are the earliest to replicate; in general, the most intense Q-bands are those which are the latest to replicate. Especially among these last ones, a certain asynchronism exists between the replication times. Finally the heterochromatin of chromosomes 1, 16 and Y and of the short arms of the acrocentrics could contain two types of DNA which replicate at different times.

Whole-genome methylation scan in ICF syndrome: hypomethylation of non-satellite DNA repeats D4Z4 and NBL2

The ICF (immunodeficiency, centromeric instability and facial abnormalities) syndrome is a rare recessive disease characterized by immunodeficiency, extraordinary instability of certain heterochromatin regions and mutations in the gene encoding DNA methyltransferase 3B. In this syndrome, chromosomes 1 and 16 are demethylated in their centromere-adjacent (juxtacentromeric) heterochromatin, the same regions that are highly unstable in mitogen-treated ICF lymphocytes and B cell lines. We investigated the methylation abnormalities in CpG islands of B cell lines from four ICF patients and their unaffected parents. Genomic DNA digested with a CpG methylation-sensitive restriction enzyme was subjected to two-dimensional gel electrophoresis. Most of the restriction fragments were identical in the digests from the patients and controls, indicating that the methylation abnormality in ICF is restricted to a small portion of the genome. However, ICF DNA digests prominently displayed multicopy fragments absent in controls. We cloned and sequenced several of the affected DNA fragments and found that the non-satellite repeats D4Z4 and NBL2 were strongly hypomethylated in all four patients, as compared with their unaffected parents. The high degree of methylation of D4Z4 that we observed in normal cells may be related to the postulated role of this DNA repeat in position effect variegation in facio- scapulohumeral muscular dystrophy and might also pertain to abnormal gene expression in ICF. In addition, our finding of consistent hypomethylation and overexpression of NBL2 repeats in ICF samples suggests derangement of methylation-regulated expression of this sequence in the ICF syndrome.

Dnmt3b recruitment through E2F6 transcriptional repressor mediates germ-line gene silencing in murine somatic tissues

Methylation of cytosine residues within the CpG dinucleotide in mammalian cells is an important mediator of gene expression, genome stability, X-chromosome inactivation, genomic imprinting, chromatin structure, and embryonic development. The majority of CpG sites in mammalian cells is methylated in a nonrandom fashion, raising the question of how DNA methylation is distributed along the genome. Here, we focused on the functions of DNA methyltransferase-3b (Dnmt3b), of which deregulated activity is linked to several human pathologies. We generated Dnmt3b hypomorphic mutant mice with reduced catalytic activity, which first revealed a deregulation of Hox genes expression, consistent with the observed homeotic transformations of the posterior axis. In addition, analysis of deregulated expression programs in Dnmt3b mutant embryos, using DNA microarrays, highlighted illegitimate activation of several germ-line genes in somatic tissues that appeared to be linked directly to their hypomethylation in mutant embryos. We provide evidence that these genes are direct targets of Dnmt3b. Moreover, the recruitment of Dnmt3b to their proximal promoter is dependant on the binding of the E2F6 transcriptional repressor, which emerges as a common hallmark in the promoters of genes found to be up-regulated as a consequence of impaired Dnmt3b activity. Therefore, our results unraveled a coordinated regulation of genes involved in meiosis, through E2F6-dependant methylation and transcriptional silencing in somatic tissues.

Abnormal methylation pattern in constitutive and facultative (X inactive chromosome) heterochromatin of ICF patients

We have investigated the distribution of DNA methylation in chromosomes and nuclei of normal individuals and ICF (Immunodeficiency, Centromeric instability and Facial abnormalities) syndrome patients, using 5-methylcytosine monoclonal antibody. In this syndrome, DNA digestion with methyl-sensitive enzymes has previously shown a specific hypomethylation of classical satellites located in constitutive heterochromatin. The chromosome methylation pattern confirms this hypomethylation showing in addition a clear undermethylation of facultative heterochromatin (X inactive chromosome). Antibodies give, in normal and ICF chromosomes, a non-uniform labeling of euchromatin, generating a weak R-like banding pattern on chromosomes. This pattern reflects an unequal distribution of DNA methylation over the genome disclosing another aspect of chromosome organization. The breakpoints of chromosome rearrangements and the heterochromatin stretchings observed in ICF patients were analyzed by means of in situ hybridization. These chromosome modifications involve hypomethylated classical DNA satellite sequences. The underlying hypomethylation, associated with an abnormal chromatin organization, may predispose to chromosome instability.

EMR1, an unusual member in the family of hormone receptors with seven transmembrane segments

Proteins with seven transmembrane segments (7TM) define a superfamily of receptors (7TM receptors) sharing the same topology: an extracellular N-terminus, three extramembranous loops on either side of the plasma membrane, and a cytoplasmic C-terminal tail. Upon ligand binding, cytoplasmic portions of the activated receptor interact with heterotrimeric G-coupled proteins to induce various second messengers. A small group, recently recognized on the basis of homologous primary amino acid sequences, comprises receptors to hormones of the secretin/vasoactive intestinal peptide/glucagon family, parathyroid hormone and parathyroid hormone-related peptides, growth hormone-releasing factor, corticotropin-releasing factor, and calcitonin. A cDNA, extracted from a neuroectodermal cDNA library, was predicted to encode a new 886-amino-acid protein with three distinct domains. The C-terminal third contains the seven hydrophobic segments and characteristic residues that allow the protein to be readily aligned with the various hormone receptors in the family. Six egf-like modules, at the N-terminus of the predicted mature protein, are separated from the transmembrane segments by a serine/threonine-rich domain, a feature reminiscent of mucin-like, single-span, integral membrane glycoproteins with adhesive properties. Because of its unique characteristics, this putative egf module-containing, mucin-like hormone receptor has been named EMR1. Southern analysis of a panel of somatic cell hybrids and fluorescence in situ hybridization have assigned the EMR1 gene to human chromosome 19p13.3.

DNMT3B mutations and DNA methylation defect define two types of ICF syndrome

ICF syndrome is a rare autosomal recessive disease characterized by variable immunodeficiency, centromeric instability, and facial abnormalities. Mutations in the catalytic domain of DNMT3B, a gene encoding a de novo DNA methyltransferase, have been recognized in a subset of patients. ICF syndrome is a genetic disease directly related to a genomic methylation defect that mainly affects classical satellites 2 and 3, both components of constitutive heterochromatin. The variable incidence of DNMT3B mutations and the differential methylation defect of alpha satellites allow the identification of two types of patients, both showing an undermethylation of classical satellite DNA. This classification illustrates the specificity of the methylation process and raises questions about the genetic heterogeneity of the ICF syndrome.

Assignment of human desmin gene to band 2q35 by nonradioactive in situ hybridization

A 3-kb DNA fragment, inserted in Bluescribe vector, was used to localize the desmin gene by in situ hybridization on human metaphase chromosomes. The probe was labelled by Bio-11-dUTP and detected by immunofluorescence. Subsequent R-banding indicated that the desmin gene is located in band 2q35.

Specific induction of uncoiling and recombination by azacytidine in classical satellite-containing constitutive heterochromatin

Azacytidine (ACR) is known to induce uncoiling and somatic association involving the constitutive heterochromatin of human chromosomes 1, 9, 15, and 16 and the Y. These regions are composed of alphoid and classical satellite DNA sequences. Using specific probes for chromosomes 1 and 16, we have performed two-color fluorescence in situ hybridization on human lymphocytes cultured in the presence of ACR. We demonstrate that for these two chromosomes (1) uncoiling and association specifically occur in classical satellite-containing regions at the first cell generation, (2) breakages also affect these regions, and (3) somatic recombinations occur between these regions and lead to translocations at the next cell generation. These results suggest that changes in methylation of repetitive DNA sequences are related to chromosomal instability occurring during cell transformation and tumorigenesis.

Segmentation of human chromosomes induced by 5-ACR (5-azacytidine)

The 5-ACR (5-azacytidine) introduced in human lymphocyte cultures induces a lack or a delay of condensation of some chromosome segments corresponding to the G-bands. The resulting R-banding is very similar to that obtained with a 7-h treatment by BrdU, although the segmentation may be much stronger (pulverization) with high doses. However, the 5-ACR does not induce chromatid asymmetry, as BrdU does. This constitutes a new argument for considering that the segmentation and the asymmetry of chromatids depend, at least partly, on two different mechanisms, where proteins are probably involved. Another effect of 5-ACR is to increase chromosome associations by satellites, secondary constrictions, and telomeric regions.

alpha-satellite DNA methylation in normal individuals and in ICF patients: heterogeneous methylation of constitutive heterochromatin in adult and fetal tissues

The methylation profile of ten alpha-satellites was investigated in normal individuals and in ICF (Immunodeficiency, Centromeric instability, Facial abnormalities) patients. Two out of three ICF patients showed modified methylation of these sequences, reproducing a placental profile. CENP-B boxes, the binding sites of centromeric protein B, were always skewed toward nonmethylation. Unexpected results were observed in normal individuals: in somatic adult tissues the methylation pattern of alpha-satellite DNA varied between chromosomes, and in fetal tissues these satellites were homogeneously undermethylated. Detailed methylation analysis of CENP-B boxes revealed that unmethylated alpha-satellite units coexist with thoroughly methylated regions. These observations showed that the two major components of constitutive heterochromatin are differently methylated in normal somatic and fetal tissues, since classical satellites are consistently methylated. The definite changes in the methylation profile of heterochromatin in somatic chromosomes and the asynchronous timing of methylation of classical and alpha-satellites during development may reflect specific roles of highly repeated sequences in genomic organization.

Regulation of DNA methylation activity through Dnmt3L promoter methylation by Dnmt3 enzymes in embryonic development

The genomic DNA is methylated by de novo methyltransferases Dnmt3a and Dnmt3b during early embryonic development. The establishment of appropriate methylation patterns depends on a fine regulation of the methyltransferase activity. The activity of both enzymes increases in the presence of Dnmt3L, a Dnmt3a/3b-like protein. However, it is unclear how the function of Dnmt3L is regulated. We found here that the expression of Dnmt3L is controlled via its promoter methylation during embryonic development. Genetic studies showed that Dnmt3a, Dnmt3b and Dnmt3L are all involved in the methylation of the Dnmt3L promoter. Disruption of both Dnmt3a and Dnmt3b genes in mouse rendered the Dnmt3L promoter devoid of methylation, causing incomplete repression of the Dnmt3L transcription in embryonic stem cells and embryos. Disruption of either Dnmt3a or Dnmt3b led to reduced methylation and increased transcription of Dnmt3L, but severe hypomethylation occurred only when Dnmt3b was deficient. Consistent with the major contribution of Dnmt3b in the Dnmt3L promoter methylation, methylation of Dnmt3L was significantly reduced in mouse models of the human ICF syndrome carrying point mutations in Dnmt3b. Interestingly, Dnmt3L also contributes to the methylation of its own promoter in embryonic development. We thus propose an auto-regulatory mechanism for the control of DNA methylation activity whereby the activity of the Dnmt3L promoter is epigenetically modulated by the methylation machinery including Dnmt3L itself. Insufficient methylation of the DNMT3L promoter during embryonic development due to deficiency in DNMT3B might be implicated in the pathogenesis of the ICF syndrome.

Proto-oncogene amplification and homogeneously staining regions in human breast carcinomas

Cytogenetic studies on fresh human breast cancers revealed that homogeneously staining regions (HSRs), which are assumed to represent DNA amplification, are observed in almost half of the cases. To search for a possible relationship between HSRs and proto-oncogene amplification, 16 proto-oncogenes, including ERBB2, were studied by Southern blot analysis in four tumors with two or three HSRs, and in three tumors without HSRs. Only four proto-oncogenes were found to be amplified in at least one tumor each: HST and INT2 (x3), MYC (x2-3), and FES (x greater than 10). The large sizes of the HSRs, which each corresponded to several percent of the haploid genome, were hardly compatible with the low rate of amplification, except for FES and then only if a large adjacent segment was co-amplified. This incomplete correlation was demonstrated by in situ hybridization, using biotinylated probes, which showed fluorescent spots on only one HSR for FES in one tumor and for INT2 in another one. Our results indicate that most of the large amplifications corresponding to HSRs do not involve the proto-oncogenes usually studied in breast cancer. The large amplification of FES, detected in one tumor, may be coincidental.

Z-DNA immunoreactivity in fixed metaphase chromosomes of primates

Antibodies against Z-DNA bind to fixed metaphase chromosomes of man and Cebus albifrons (Platyrrhini, Primate). By indirect immunofluorescence and indirect immunoperoxidase techniques, a heavy staining is detected in some segments of chromosomes of C. albifrons. These segments correspond to R-band-positive heterochromatin, which has a high G + C-base content. Euchromatin of human and Cebus chromosomes show a weak and heterogeneous staining that consistently reproduces an R- and T-banding pattern in both species. Because chromosome homologies previously were demonstrated between these distantly related species by chromosome banding, our results suggest that Z-DNA has been conserved during the course of primate evolution.

Genes occupy a fixed and symmetrical position on sister chromatids

A high-resolution fluorescence methodology for nonisotopic in situ hybridization was applied to determine the positions occupied by several single-copy genes, DNA sequences, and integrated viral genomes on sister chromatids. The lateral and longitudinal mapping of the probes was performed on prometaphase and metaphase chromosomes. A fixed lateral position, exterior or median in relation to the longitudinal axis of the chromatids, was observed for a given probe, with a symmetrical position of the double fluorescent spots. This position appears to be independent of chromosome condensation stage from prometaphase to metaphase. These observations suggest an opposite helical-handedness conformation of DNA on both chromatids with a mirror symmetry. They support the model of chromosome packaging recently proposed by Boy de la Tour and Laemmli. Moreover, our results indicate that the last stages of chromosome condensation occur by packing down the coils without further coiling.

Localization chromatid breaks in Fanconi's anemia, using three consecutive stains

The location of 339 break points was analyzed in three patients with Fanconi's anemia, using three consecutive stains: ordinary Giemsa, Q-banding, and R-banding. Almost all the breaks seem to take place in the Q bands, using R-banding, and in the R bands, using Q-banding. A very important artifact, varying according to the method used, is thus demonstrated. In fact, the breaks take place in the interbands, between R and Q bands. The breaks were also localized in relation to sister chromatid exchanges (SCEs), seen after BUDR treatment. There is a clear excess of breaks at place of SCE (29%). This may indicate a possible correlation between breaks and SCEs.

Chromosomal phylogeny of Muridae: a study of 10 genera

The karyotypes of 10 different species of the family Muridae (Acomys airensis, Arvicanthis niloticus, Hylomyscus stella, Malacomys longipes, Mastomys huberti, Myomys daltoni, Mus musculus, Rattus norvegicus, Thamnomys gazellae, and Uranomys ruddi) are compared by different banding techniques. From a reconstruction of the presumed ancestral karyotype of the Muridae the sequence of the various rearrangements leading to the present karyotypes is proposed in order to determine their phylogenetic relationships. In particular, the present karyotypes of the mouse and rat differ from the ancestral one by at least 12 and 7 rearrangements, respectively. A clear tendency for accumulation of a specific type of rearrangement in a given branch of the cladogram is observed. In regard to the mouse, a large number of translocations, with break points situated in the proximal part of the long arms, have occurred, which conserved the acrocentric form of the ancestral chromosomes but led to multiple recombinations of the bands.

The prosomal RNA-binding protein p27K is a member of the alpha-type human prosomal gene family

Monoclonal antibodies demonstrated high conservation during evolution of a prosomal protein of M(r) 27,000 and differentiation--specific expression of the epitope. More than 90% of the reacting antigen was found as a p27K protein in the free messenger ribonucleoprotein (mRNP) fraction but another protein of M(r) 38,000, which shared protease fingerprint patterns with the p27K polypeptide, was also labelled in the nuclear and polyribosomal fractions. Sequencing of cDNA recombinant clones encoding the p27/38K protein and comparison with another prosomal protein, p30-33K, demonstrated the existence of a common characteristic sequence pattern containing three highly conserved segments. The genes Hs PROS-27 and Hs PROS-30 were mapped to chromosomes 14 (14q13) and 11 (11p15.1), respectively. The structure of the p27K protein shows multiple potential phosphorylation sites, an NTP-binding fold and an RNA-binding consensus sequence. The Hs PROS-27/beta-galactosidase fusion protein binds a single RNA of about 120 nucleotides from total HeLa cell RNA. Sequence comparisons show that the Hs PROS-27 and Hs PROS-30 genes belong to the gene family that encodes the prosome--MCP (multicatalytic proteinase)--proteasome proteins. Comparison with other members of the family from various species allowed us to show that the tripartite consensus sequence characteristic of the alpha-type sub-family is conserved from archeobacteria to man. The members of this gene family are characterised by very high evolutionary conservation of amino acid sequences of homologous genes and 20%-35% sequence similarity, between different family member within the same species and are clearly distinct from the beta-type family.

Synaptonemal complexes in Gerbillidae: probable role of intercalated heterochromatin in gonosome-autosome translocations

A study of sex chromosomes and synaptonemal complexes in male specimens of Gerbillus chiesmani, G. nigeriae, G. hoogstrali, and Taterillus pygargus is reported. In each of these Gerbillidae species there are two or three translocations of autosomes with X and Y chromosomes. Analysis of mitotic chromosomes consistently shows the presence of constitutive heterochromatin on the der t(X;autosome) at the X-autosome junction and on the der t(Y;autosome). Analysis of the synaptonemal complexes shows the existence of an unusual structure, lightly stained, at the X-autosome junction and at the Y-autosome junction, which is probably heterochromatic in nature, thus corresponding to the mitotic patterns. This heterochromatin separates the autosomal and gonosomal segments, which behave independently and normally. By analogy with findings from humans and other mammals, a general hypothesis is proposed on the role of intercalated heterochromatin between translocated gonosomes and autosomes. This hypothesis explains why the pathological consequences of these translocations may be very different in males and females. The role of intercalated heterochromatin would be to avoid the pathological consequences of gonosome-autosome translocations resulting from inactivation of the sex chromosomes in female somatic cells and male germinal cells.

Abnormal methylation does not prevent X inactivation in ICF patients

DNA undermethylation is a characteristic feature of ICF syndrome and has been implicated in the formation of the juxtacentromeric chromosomal abnormalities of this rare syndrome. We have previously shown that in female ICF patients the inactive X chromosome (Xi) is also undermethylated. This result was unexpected since female ICF patients are not more severely affected than male patients. Here we show that CpG island methylation is abnormal in some ICF patients but in other ICF patients, the difference in methylation pattern between Xi and Xa (active X) is maintained. The consequences of Xi undermethylation on gene expression were investigated by enzyme assays. They showed that significant gene expression did not correlate with CpG island methylation status. The widespread Xi undermethylation does not affect overall Xi replication timing and does not prevent Barr body formation suggesting that a normal methylation pattern is not required for normal chromatin organization of Xi. Molecular investigation of some X-chromosome intron regions showed that the methylation changes in ICF female patients extend to non CpG islands sequences. Our results suggest that the genetic alteration of DNA methylation in ICF syndrome has little consequence on X chromosome gene expression and chromatin organization.