DNA hypomethylation causes an increase in DNase-I sensitivity and an advance in the time of replication of the entire inactive X chromosome

Summary We have examined the effect of 5-azacytidine (5-aza-C) induced hypomethylation of DNA on the time of replication and DNase I sensitivity of the X chromosomes of female Gerbillus gerbillus (rodent) lung fibroblast cells. Using in situ nick translation to visualise the potential state of activity of large regions of metaphase chromosomes we show that 5-aza-C causes a dramatic increase in the DNase-I sensitivity of the entire inactive X chromosome of female G. gerbillus cells and this increase in nuclease sensitivity correlates with a large shift in the time of replication of the inactive X chromosome from late S phase to early S phase. These effects of 5-aza-C on the inactive X chromosome are associated with a 15% decrease in DNA methylation. Our results indicate that DNA methylation concomitantly affects both the time of replication and the chromatin conformation of the inactive X chromosome.     

MODULATION OF OSTEOGENIC DIFFERENTIATION IN HUMAN SKELETAL CELLS IN VITRO BY 5-AZACYTIDINE

Cellular differentiation is controlled by a variety of factors including gene methylation, which represses particular genes as cell fate is determined. The incorporation of 5-azacytidine (5azaC) into DNA in vitro prevents methylation and thus can alter cellular differentiation pathways. Human bone marrow fibroblasts and MG63 cells treated with 5azaC were used as models of osteogenic progenitors and of a more mature osteoblast phenotype, respectively. The capacity for differentiation of these cells following treatment with glucocorticoids was investigated. 5azaC treatment led to significant expression of the osteoblastic marker alkaline phosphatase in MG63 osteosarcoma cells, which was further augmented by glucocorticoids; however, in human marrow fibroblasts alkaline phosphatase activity was only observed in glucocorticoid-treated cultures. MG63 cells represent a phenotype late in the osteogenic lineage in which demethylation is sufficient to induce alkaline phosphatase activity. Marrow fibroblasts are at an earlier stage of differentiation and require stimulation with glucocorticoids. In contrast, the expression of osteocalcin, an osteoblastic marker, was unaffected by 5azaC treatment, suggesting that regulation of expression of the osteocalcin gene does not involve methylation. These models provide novel approaches to the study of the control of differentiation in the marrow fibroblastic system.     

Regulation of mouse satellite DNA replication time.

The satellite DNA sequences located near the centromeric regions of mouse chromosomes replicate very late in S in both fibroblast and lymphocyte cells and are heavily methylated at CpG residues. F9 teratocarcinoma cells, on the other hand, contain satellite sequences which are undermethylated and replicate much earlier in S. DNA methylation probably plays some role in the control of satellite replication time since 5-azacytidine treatment of RAG fibroblasts causes a dramatic temporal shift of replication to mid S. In contrast to similar changes accompanying the inactivation of the X-chromosome, early replication of satellite DNA is not associated with an increase in local chromosomal DNase I sensitivity. Fusion of F9 with mouse lymphocytes caused a dramatic early shift in the timing of the normally late replicating lymphocyte satellite heterochromatin, suggesting that trans-activating factors may be responsible for the regulation of replication timing.     

5-aza-C-induced changes in the time of replication of the X chromosomes of Microtus agrestis are followed by non-random reversion to a late pattern of replication

Treatment with 5-azacytidine (5-aza-C) causes an advance in the time of replication and enhances the DNase-I sensitivity of the inactive X chromosome in Gerbillus gerbillus fibroblasts. We found that these changes were not stably inherited and upon removal of the drug the cells reverted to the original state of one active and one inactive X chromosome. In order to determine whether this reversion was random, we used a cell line of female Microtus agrestis fibroblasts in which the two X chromosomes are morphologically distinguishable. In this work we show that the reversion to a late pattern of replication is not random, and the originally late replicating X chromosome is preferentially reinactivated, suggesting an imprinting-like marking of one or both X chromosomes. The changes in the replication pattern of the X chromosome were associated with changes in total DNA methylation. Double treatment of cells with 5-aza-C did not alter this pattern of euchromatin activation and reinactivation. A dramatic advance in the time of replication of the entire X linked constitutive heterochromatin (XCH) region was however, observed in the doubly treated cells. This change in the replication timing of the XCH occurred in both X chromosomes and was independent of the changes observed in the euchromatic region. These observations suggest the existence of at least two independent regulatory sites which control the timing of replication of two large chromosomal regions.Deceased on 2 Jan. 1987     

Evidence for a relationship between DNA methylation and DNA replication from studies of the 5-azacytidine-reactivated allocyclic X chromosome

We examined the sequence of DNA synthesis of the human active, inactive and reactivated X chromosomes in mouse-human hybrid cells. The two independent reactivants, induced by 5-azacytidine (5-azaC), expressed human hypoxanthinephosphoribosyl transferase (HPRT), and one also expressed human glucose-6-phosphate dehydrogenase (G6PD) and phosphoglycerate kinase (PGK). Restriction enzyme analysis of DNA methylation at the re-expressed loci revealed hypomethylation of CpG clusters, that characterizes the relevant genes on the active X. The transfer of active and inactive X chromosomes from the native environment of the human fibroblast to the foreign environment of the hybrid cell did not affect the specific replication sequence of either human X chromosome. The silent X chromosome when reactivated, remained allocyclic, and the first bands to replicate were the same as prior to reactivation. In one reactivant, however, further progression of replication was significantly altered with respect to the order in which bands were synthesized. This alteration in the replication of the silent X following 5-azaC-induced reactivation suggests that DNA methylation may modulate the replication kinetics of chromosomal DNA.     

A deletion at the mouse Xist gene exposes trans-effects that alter the heterochromatin of the inactive X chromosome and the replication time and DNA stability of both X chromosomes

The inactive X chromosome of female mammals displays several properties of heterochromatin including late replication, histone H4 hypoacetylation, histone H3 hypomethylation at lysine-4, and methylated CpG islands. We show that cre-Lox-mediated excision of 21 kb from both Xist alleles in female mouse fibroblasts led to the appearance of two histone modifications throughout the inactive X chromosome usually associated with euchromatin: histone H4 acetylation and histone H3 lysine-4 methylation. Despite these euchromatic properties, the inactive X chromosome was replicated even later in S phase than in wild-type female cells. Homozygosity for the deletion also caused regions of the active X chromosome that are associated with very high concentrations of LINE-1 elements to be replicated very late in S phase. Extreme late replication is a property of fragile sites and the 21-kb deletions destabilized the DNA of both X chromosomes, leading to deletions and translocations. This was accompanied by the phosphorylation of p53 at serine-15, an event that occurs in response to DNA damage, and the accumulation of gamma-H2AX, a histone involved in DNA repair, on the X chromosome. The Xist locus therefore maintains the DNA stability of both X chromosomes.     

Replication variants of the human inactive X chromosome

Replication variants of the inactive X chromosome were investigated in lymphocytes from six donors by means of terminal BrdU or thymidine incorporation. There were interindividual differences in the incidence of particular variants. In endoreduplicated and tetraploid cells both allocyclic X chromosomes showed the same replication sequence. The Xp22 band of the allocyclic X chromosome seemed to replicate later than the homologous material in some cells. Initiation time of DNA synthesis within the inactive X chromosome was found to be stable; termination time, however, varied greatly relative to the other chromosomes. Early completion of replication within the heterochromatic X chromosome could be demonstrated preferentially for the Xq25–27 terminal sequence, but other variants expressed the phenomenon also. A variable replication rate of the inactive X chromosome is believed to be responsible for its asynchronous, independent replication. The biological significance of the phenomenon is discussed with respect to cell differentiation.     

Replication of X chromosomes in complete moles

Summary DNA replication patterns of X chromosomes in complete hydatidiform moles were studied using cultured fibroblasts from three 46,XX moles resulting from duplication of a haploid sperm, and from a 46,XY mole originating from dispermy. Control cultures included skin fibroblasts from an adult woman and a female fetus as well as PB lymphocytes from an adult woman. Cultures were treated with 5-bromodeoxyuridine for the last 2–4h of the S phase, and the chromosome slides prepared were stained by the Hoechst 33258-Giemsa procedure. Each of the three XX moles studied revealed one early-replicating and one late-replicating X chromosomes, while the XY mole revealed one early-replicating X chromosome. DNA replication patterns of molar X chromosomes were similar to those of adult and fetal fibroblasts, but different from those in adult lymphocytes. These findings indicate that DNA replication kinetics of molar fibroblasts are tissue-specific rather than origin- or developmental-stage specific.     

5-Azacytidine decreases fragmentation of nuclear DNA and pigment formation in first leaf cells of barley seedlings

Realization of programmed cell death in senescence represents an activation/inactivation of the respective gene. Enzymatic methylation of nuclear DNA with the creation of 5methylcytosine is one of the mechanisms, which can regulate gene activity in animal and plant cells. 5Azacytidine (5azaC) acts as an inhibitor of DNA methylation, and induces expression of a range of some genes including genes responsible for senescence. Fragmentation of nuclear DNA is one of the hallmarks of programmed cell death in apoptosis pathway in plant cells. The influence of 5azaC (100 microg/ml) on nuclear DNS amount and its fragmentation in the first leaf cells of barley was studied. It was shown that in the first leaf cells of barley seedlings there is an apoptosis pathway of programmed cell death. It was also observed that nuclear DNA fragmentation under the 5azaC influence is strongly inhibited, and the DNA amount in the first leaf increases. Synthesis and destruction of chlorophyll also play a significant role in programmed cell death in plants. It was shown that under the 5azaC influence, the absorption spectrum of a pigment does not change in leaves and coleoptiles in the light, whereas in the dark condition, these pigments are not created under the 5azaC influence.     

Alterations in the time of X chromosome replication induced by 5-azacytidine in a patient with 48,XXXY/47,XXY

It has recently been shown that 5-azacytidine (5-azaC) can induce altered replication patterns of the late-replicating X chromosome in normal female cells. This has been demonstrated by bromodeoxyuridine labelling of cells late in the S phase. In the present study the same method was applied to the lymphocytes of a Klinefelter patient (48,XXXY/47,XXY). Significant 5-azaC-induced changes in the replication of the entire inactive X chromosome, from late to early, were found in the lymphocytes of this patient. These results indicate that hypomethylating agents can not only alter the replication of individual bands, but also change the gross replication schedule of multiple inactive X chromosomes in the presence of a Y chromosome.     

Patterns of polytene-chromosome replication in Simulium ornatipes (Diptera: Simuliidae)

Double labelling of Simulium ornatipes polytene chromosomes with H³- and C¹⁴-thymidine shows that chromosome synthesis follows three distinct phases viz. a short phase of initiation in puffs and interbands spreading to more condensed regions; a long continuous labelling phase, then a discontinuously labelled end phase as bands complete their replication in temporal sequence. Analysis of H³ labelling patterns indicates that while heterochromatic bands replicate there is no clear correlation between heterochromatic or C-banding regions and band replication time. The major characteristic governing band replication time appears to be band size and density. However, in some bands this relationship is modified, perhaps it is suggested, by DNA organisation influencing the efficiency of replicons. The existence of great variability in homologous band replication times, even within a chromosome pair, indicates that the control of band replication is highly autonomous. It is suggested that polymorphisms at the molecular level determine this variation. Replication time of active nucleolar organisers is very long in contrast to the short replication of condensed inactive organisers. This may reflect differential polytenisation of ribosomal DNA as a result of a developmental polymorphism, or the amplification of ribosomal DNA by active nucleolar organisers.     

Tissue-specific heterogeneity in DNA replication patterns of human X chromosomes

Regional DNA replication kinetics in human X chromosomes have been analysed using BrdU-33258 Hoechst-Giemsa techniques in five cell types from human females: amniotic fluid cells, fetal and adult skin fibroblasts, and fetal and adult peripheral lymphocytes. In all cell types, the late-replicating X chromosome can be distinguished from its active, earlyreplicating homologue, and both the early and late X exhibit temporally and regionally characteristic internal sequences of DNA replication. The replication pattern of the early X in amniotic fluid cells and skin fibroblasts is similar to that of the early X in lymphocytes, although certain discrete regions are later-replicating in these monolayer tissue culture cells than are the corresponding regions in lymphocytes. However, DNA replication kinetics in late X chromosomes from amniotic fluid cells and skin fibroblasts are strikingly different from those observed in lymphocytes with respect both to the initiation and termination of DNA synthesis. The predominant late X pattern observed in 80–95% of lymphocytes, in which replication terminates in the long arm in bands Xq21 and Xq23, was never seen in amniotic fluid cells or skin fibroblasts. Instead, in these cell types, bands Xq25 and Xq27 are the last to complete DNA synthesis, while bands Xq21 and Xq23 are earlier-replicating; this pattern is similar to the alternative replication sequence observed in 5–20% of lymphocyte late X chromosomes. This replication sequence heterogeneity is consistent with the existence of tissue-specific influences on the control of DNA replication in human X chromosomes.     

Kinetic heterogeneity of the replication of genetically inactive X chromosome in human cells

Kinetics of DNA replication in genetically non-active X chromosome was studied in peripheral lymphocytes and skin fibroblasts from four phenotypically normal women and one fetus using BrdU 33258 Hoechst-Giemsa techniques. The localization of the earliest replicated chromosomal segment was shown to be unstable, varying from cell to cell in both lymphocytes and fibroblasts of all persons examined. Several variants of replication sequence in the X chromosome were found in both types of cells. The variants revealed were classified, according to Willard. The statistically significant differences in replication sequence were found between blood lymphocytes and skin fibroblasts in two individuals. The problem of tissue specificity in replication kinetics of the genetically non-active X chromosome is discussed.     

Genetic transformation of somatic cells. VIII. The effect of the DNA methylation inhibitor 5-azacytidine on the stability of thymidine kinase-negative and -positive phenotypes of transformant clone cells

A study was made of the effect of an DNA methylation inhibitor 5-azacytidine (azaC) on the frequency of reversion to a thymidine kinase-positive (TK+) phenotype in 5-bromodeoxy-uridine (BrdU)-resistant subclones obtained from clones of Chinese hamster cells transformed by thymidine kinase gene (tk-gene) of Herpes simplex virus type 1 (HSV1). It is shown that in 8 of 15 BrdU-resistant subclones azaC increases 2-1000-fold the frequency of reversion to TK+ phenotype. Variations in the inducibility of reversions to TK+ phenotype indicate that the DNA methylation associated with TK- phenotype affects but differently tk gene of HSV1. Cultivation of TK+ cells of transformant clones in the presence of azaC may lead to stabilization (or decrease in the rate of the loss) of TK+ phenotype, or may not influence the stability of transformant phenotype. The reaction of TK+ cells of transformant clones depends both on genetically determined rate of the loss of TK+ phenotype, and on the structure of transforming DNA introduced to cells. A conclusion is drawn that the TK- phenotype of transformant clone cells arises due to processes which are not associated with methylation of tk gene of HSV1 in spite of the fact that such a methylation may later stabilize significantly the TK- phenotype.     

The asymmetric methylation of CG palindromic dinucleotides increases sister-chromatid exchanges

Treatment with the base analogue, 5azaC, increases SCEs in CHO but not in mosquito cells. On the other hand, both types of cells show equivalent increases in exchanges when treated with other compounds, such as mitomycin C. Vertebrate DNA is heavily methylated while diptera DNA is heavily demethylated. The sequence of events leading to an increase in SCEs in CHO cells is as follows: first of all, Cs are replaced by 5azaC; in the next cell cycle, CG palindromic dinucleotides exhibit an asymmetric configuration, the Cs in the parental DNA strand being methylated and the Cs in the daughter DNA strand demethylated; after one more cycle, half of the chromosomes show symmetric methylation and the other half symmetric demethylation of both Cs in CG palindromes. The increase of SCEs occurs in the second cell cycle when the hemimethylated DNA enters replication. DNA hemimethylation is believed to be an intermediate stage in the process of demethylation that accompanies gene expression. If so, gene demethylation would be a cause of SCE increase in normal vertebrate cells.     

Satellite 2 demethylation induced by 5-azacytidine is associated with missegregation of chromosomes 1 and 16 in human somatic cells

Satellite sequences are an important part of the pericentromeric regions in mammalian genomes; they play a relevant role in chromosome stability and DNA hypomethylation of these sequences has been reported in ICF syndrome and in some cancers that are closely associated with chromosomal abnormalities. Epigenetic modifications of satellite sequences and their consequences have not been extensively studied in human cells. In the present work, we evaluated satellite 2 methylation patterns in human lymphocytes exposed to 5-azacytidine (5-azaC) and assessed the relationship between these patterns and chromosome missegregation. Human lymphocytes were exposed to 10μM 5-azaC for 24, 48, and 72h. Segregation errors were evaluated in binucleate cells using FISH against pericentromeric regions of chromosomes 1, 9, and 16. DNA methylation patterns were evaluated by immunodetection, and by bisulfite plus urea conversion and sequencing. We have identified that 5-azaC induced missegregation of chromosomes 1 and 16, which have highly methylated satellite 2, after 72h of exposure. Chromosome methylation patterns showed a notable decrease in pericentromeric methylation. Bisulfite conversion and sequencing analysis demonstrated demethylation of satellite 2 associated to 5-azaC exposure, principally after 72h of treatment. This change occurred in a non-specific pattern. Our study demonstrates an association between loss of satellite 2 DNA methylation and chromosome loss in human lymphocytes.     

Alterations of DNA methylation patterns in germ cells and Sertoli cells from developing mouse testis

In situ alterations of DNA methylation were studied between 14 d postcoitum and 4 d postpartum in Sertoli cells and germ cells from mouse testis, using anti-5-methylcytosine antibodies. Compared to cultured fibroblasts, Sertoli cells display strongly methylated juxtacentromeric heterochromatin, but hypomethylated chromatids. Germ cells always possess hypomethylated heterochromatin, whereas their euchromatin passes from a demethylated to a strongly methylated status between days 16 and 17 postcoitum. This hypermethylation occurs in the absence of DNA replication, germ cells being blocked in the G(0)-G(1) phase from day 15 postcoitum to birth. The DNA hypermethylation of germ cells is maintained until birth and could be visualized on both chromatids of metaphase chromosomes at the first postpartum cell division. Subsequently, the DNA hypermethylation is lost semiconservatively, being replaced by a methylation pattern recalling the typical fibroblast pattern. These alterations of DNA methylation follow a strict chronology, are chromosome structure and cell-type dependent, and may underlie profound changes of genome function.