Frequency of reactivation and variability in expression of X-linked enzyme loci.

A mouse-human cell hybrid clone retaining an inactive human X chromosome was treated with 5-azacytidine. Following treatment, expression of the X-linked enzyme markers, hypoxanthine-guanine phosphoribosyltransferase (HPRT), glucose-6-phosphate dehydrogenase (G6PD), phosphoglycerate kinase (PGK), and alpha-galactosidase A (GLA) was examined. Results presented here show that 45 of the 62 clones positive for human HPRT expressed human GLA, while only four of 68 clones negative for human HPRT expressed human GLA. These results strongly suggest that there is coordinate reactivation of GLA and HPRT. Reactivated expression of G6PD was studied in detail. The studies show that 5-azacytidine can induce heritable changes in the inactive human X chromosome resulting in the expression of G6PD activity at a level lower than that from an active human X chromosome.     

DNA demethylation induced by 5-azacytidine does not affect fragile X expression.

Experiments were performed to determine the role of DNA demethylation in fragile X expression. Fragile X positive lymphoblastoid cells were treated with 5-azacytidine and harvested for analysis of fragile X expression both directly following treatment and after a recovery period in the absence of the drug. The effectiveness of 5-azacytidine treatment in inducing DNA demethylation was concurrently monitored by analysis of methylation changes at random autosomal loci in isolated DNA from treated cells. Under conditions where 5-azacytidine was found to inhibit fragile X expression, no DNA demethylation was observed. At the time when demethylation did occur, fragile X expression was not affected. These results strongly indicate that DNA demethylation is not involved in fragile X expression.     

Differential activation of the hprt gene on the inactive X chromosome in primary and transformed Chinese hamster cells.

We have investigated the genetic activation of the hprt (hypoxanthine-guanine phosphoribosyltransferase) gene located on the inactive X chromosome in primary and transformed female diploid Chinese hamster cells after treatment with the DNA methylation inhibitor 5-azacytidine (5azaCR). Mutants deficient in HPRT were first selected by growth in 6-thioguanine from two primary fibroblast cell lines and from transformed lines derived from them. These HPRT- mutants were then treated with 5azaCR and plated in HAT (hypoxanthine-methotrexate-thymidine) medium to select for cells that had reexpressed the hprt gene on the inactive X chromosome. Contrary to previous results with primary human cells, 5azaCR was effective in activating the hprt gene in primary Chinese hamster fibroblasts at a low but reproducible frequency of 2 x 10(-6) to 7 x 10(-6). In comparison, the frequency in independently derived transformed lines varied from 1 x 10(-5) to 5 x 10(-3), consistently higher than in the nontransformed cells. This increase remained significant when the difference in growth rates between the primary and transformed lines was taken into account. Treatment with 5azaCR was also found to induce transformation in the primary cell lines but at a low frequency of 4 x 10(-7) to 8 x 10(-7), inconsistent with a two-step model of transformation followed by gene activation to explain the derepression of hprt in primary cells. Thus, these results indicate that upon transformation, the hprt gene on the inactive Chinese hamster X chromosome is rendered more susceptible to action by 5azaCR, consistent with a generalized DNA demethylation associated with the transformation event or with an increase in the instability of an underlying primary mechanism of X inactivation.     

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.     

Extensive changes in DNA methylation patterns accompany activation of a silent T-DNA ipt gene in Agrobacterium tumefaciens-transformed plant cells.

We crossed a male-sterile, Agrobacterium-transformed Nicotiana tabacum plant that contains a silent, hypermethylated T-DNA ipt oncogene with a normal tobacco plant and found that the methylated state of the ipt gene was stably inherited through meiosis in the offspring. However, when tissues of these plants were placed in cell culture, the ipt gene was spontaneously reactivated in a very small fraction of the cells; if 5-azacytidine was added to the culture medium, ipt gene reactivation occurred at high frequency. We analyzed the pattern of DNA methylation in a region spanning the ipt gene in a line that does not express the ipt gene, in five derivatives of this line that reexpressed the ipt gene either spontaneously or after 5-azacytidine treatment, and in tissues of a sibling of this line that reexpressed ipt spontaneously. We found that the ipt locus was highly methylated in the unexpressed state but that spontaneous or 5-azacytidine-induced reexpression always resulted in extensive demethylation of a region including 5' upstream, coding, and 3' downstream regions of the ipt gene. The role of DNA methylation in gene regulation in this system is discussed.     

DNA methylation changes in human testicular cancer

We previously reported an X/Y imbalance with a relative excess of X- and a relative deficiency of Y-chromosomal DNA in three out of nine testicular tumors of germ cell origin. To study the implications of those changes the methylation status of DNA from seven of the tumors was explored by HpaII/MspI analysis. The 5' regions of the hypoxanthine phosphoribosyltransferase (HPRT) and the phosphoglycerate kinase (PGK) gene loci exhibited main patterns suggestive of active X chromosomes in the tumors. However, a minority of the HPRT loci of one teratocarcinoma with an increased dosage of the X chromosome, as well as one additional teratocarcinoma, revealed patterns analogous to inactive X chromosomes in females. Using probes from several chromosomes it was subsequently found that the teratocarcinoma tumors (3/3) were characterized by generalized hypermethylation. On the contrary, the seminomas showed variable hypomethylation (4/5) or virtually complete demethylation (1/5). The seminoma with the most extensive hypomethylation was disseminated (stage III), whereas the other seminomas were local (stage I). These findings suggest that DNA methylation may play a role in the developmental pathways leading to different histologic types of testicular tumors of germ cell origin. The HPRT results imply that the consequences of extra X chromosomes--a frequent finding in testicular tumors--may be modulated by mechanisms, such as DNA methylation, that control gene activity.     

Variable stability of a selectable provirus after retroviral vector gene transfer into human cells.

Human lymphoblasts deficient in the enzyme hypoxanthine-guanine phosphoribosyltransferase (HPRT) were infected with an amphotropic helper-free retroviral vector expressing human HPRT cDNA. The stability and expression of the HPRT provirus in five cell lines with different proviral integration sites were examined by determining HPRT mutation and reversion frequencies and by blot hybridization studies. Mutation to the HPRT-negative phenotype occurred at frequencies of approximately 4 X 10(-5) to 3 X 10(-6) per generation. Most mutations in each of the five cell lines were associated with partial or complete deletions or rearrangements of the provirus. Several mutants retained a grossly intact HPRT provirus, and in one such mutant HPRT shutdown resulted from a revertible epigenetic mechanism that was not associated with global changes in proviral methylation. Therefore, mutation and shutdown of the HPRT provirus in human lymphoblasts result from mechanisms similar to those reported for several other avian and mammalian replication-competent retroviruses.     

Construction of a defective retrovirus containing the human hypoxanthine phosphoribosyltransferase cDNA and its expression in cultured cells and mouse bone marrow.

Defective ecotropic and amphotropic retroviral vectors containing the cDNA for human hypoxanthine phosphoribosyltransferase (HPRT) were developed for efficient gene transfer and high-level cellular expression of HPRT. Helper cell clones which produced a high viral titer were generated by a simplified method which minimizes cell culture. We used the pZIP-NeoSV(X) vector containing a human hprt cDNA. Viral titers (1 X 10(3) to 5 X 10(4)/ml) of defective SVX HPRT B, a vector containing both the hprt and neo genes, were increased 3- to 10-fold by cocultivation of the ecotropic psi 2 and amphotropic PA-12 helper cells. Higher viral titers (8 X 10(5) to 7.5 X 10(6] were obtained when nonproducer NIH 3T3 cells or psi 2 cells carrying a single copy of SVX HPRT B were either transfected or infected by Moloney leukemia virus. The SVX HPRT B defective virus partially corrected the HPRT deficiency (4 to 56% of normal) of cultured rodent and human Lesch-Nyhan cells. However, instability of HPRT expression was detected in several infected clones. In these unstable variants, both retention and loss of the SVX HPRT B sequences were observed. In the former category, cells which became HPRT- (6-thioguanine resistant [6TGr]) also became G418s, indicative of a cis-acting down regulation of expression. Both hypoxanthine-aminopterin-thymidine resistance (HATr) and G418r could be regained by counterselection in hypoxanthine-aminopterin-thymidine. In vitro mouse bone marrow experiments indicated low-level expression of the neo gene in in vitro CFU assays. Individual CFU were isolated and pooled, and the human hprt gene was shown to be expressed. These studies demonstrated the applicability of vectors like SVX HPRT B for high-titer production of defective retroviruses required for hematopoietic gene transfer and expression.     

Macronuclear DNA demethylation is involved in the encystment process of the ciliate Colpoda inflata.

Ciliate encystment is an eukaryotic cell differentiation process which involves a specific gene expression, to form the resting stage. In this study, we investigate, for first time, the DNA methylation pattern changes during encystment in the ciliate Colpoda inflata, and the 5-azacytidine effect on growing cells and encystment. Results indicate that 5-methylcytosine is present in macronuclear DNA of this ciliate and the 5-azacytidine treatment induces encystment in growth conditions. From restriction enzyme digestion and 5-azacytidine experiments, we conclude that a specific DNA demethylation is probably involved in the encystment gene expression of this ciliate.     

Macronuclear DNA demethylation is involved in the encystment process of the ciliate Colpoda inflata.

Ciliate encystment is an eukaryotic cell differentiation process which involves a specific gene expression, to form the resting stage. In this study, we investigate, for first time, the DNA methylation pattern changes during encystment in the ciliate Colpoda inflata, and the 5-azacytidine effect on growing cells and encystment. Results indicate that 5-methylcytosine is present in macronuclear DNA of this ciliate and the 5-azacytidine treatment induces encystment in growth conditions. From restriction enzyme digestion and 5-azacytidine experiments, we conclude that a specific DNA demethylation is probably involved in the encystment gene expression of this ciliate.     

Direct visualization of the sites of DNA methylation in human,and mosquito chromosomes

Human and mosquito fixed chromosomes were digested with restriction endonucleases that are inhibited by the presence of 5-methylcytosine in their restriction sites (Hha I, Hin PI, Hpa II), and with endonucleases for which cleavage is less dependent on the state of methylation (Taq I, Msp I). Methylation-dependent enzymes extracted low DNA amounts from human chromosomes, while methylation-independent enzymes extracted moderate to high amounts of DNA. After DNA demethylation with 5-azacytidine the isoschizomers Hpa II (methylation-dependent) and Msp I (methylation-independent) extracted 12-fold and 1.4-fold amounts of DNA from human chromosomes, respectively. These findings indicate that human DNA has a high concentration of Hpa II and Msp I restriction sites (CCGG), and that the internal C of this sequence is methylated in most cases, while the external cytosine is methylated less often. All the enzymes tested released moderate amounts of DNA from mosquito chromosomes whether or not the DNA was demethylated with 5-azacytidine. Hpa II induced banding in the centromere chromosome regions. After demethylation with 5-azacytidine this banding disappeared. Mosquito DNA has therefore, moderate to high frequencies of nonmethylated CpG duplets. The only exception is the centromeric DNA, in which the high levels of C methylation present produce cleavage by Hpa II and the appearance of banding. Centromere regions of human chromosomes 1 have a moderately low concentration of Hpa II-Msp I restriction sites.     

5-Azacytidine-induced demethylation of DNA to senescent level does not block proliferation of human fibroblasts.

IMR-90 human diploid fibroblasts (HDF) lose from 30-50% of their genomic 5-methyldeoxycytidine (5mdC) during the cellular aging process. In contrast, immortal SV40-transformed IMR-90 maintain a constant level of 5mdC in culture. Precrisis SV40-transformed HDF (AG3204) represent a stage in between normal cell aging and immortalization because these cells still have a finite proliferative lifespan, but it is longer than that of normal HDF and ends in cell death rather than in G1-arrest. We find that AG3204 cells continue to lose from 12-33% of their 5mdC after a population has become 99% positive for SV40 T-antigen. Both IMR-90 cells and AG3204 cells have similar levels of 5mdC (average of 2.25%) at the end of lifespan. We investigated whether this level of 5mdC is an absolute block to further proliferation by treating IMR-90 and AG3204 cells with 5-azacytidine (5azaC) to reduce their 5mdC levels below the terminal level normally achieved at end of lifespan. We find that both IMR-90 and AG3204 cells undergo extensive proliferation with subterminal levels of 5mdC and that the lifespans of both cell types are shortened by 5azaC treatment. These studies indicate that random genomic DNA demethylation to a specific level of 5mdC is not a direct cause of finite proliferative lifespan. However, the correlation between accelerated DNA demethylation and accelerated aging still suggests that these two phenomena are related. Two ways to explain this relationship are: (1) DNA demethylation during aging is not random, and/or (2) both DNA demethylation and other independent aging processes cooperate to produce finite lifespan. In both cases, accelerated random DNA demethylation could accelerate aging, but not necessarily in direct relationship to the final genomic level of 5mdC achieved during the normal aging process.     

Activation of a nonexpressed hypoxanthine phosphoribosyltransferase allele in mutant H23 HeLa cells by agents that inhibit DNA methylation.

HeLA H23 cells are a mutant female human tumor cell line harboring defective hypoxanthine phosphoribosyltransferase (HPRT; IMP-pyrophosphate phosphoribosyltransferase, EC 2.4.2.8) as a result of a mutation that alters the isoelectric point of the enzyme (G. Milman, E. Lee, G. S. Changas, J. R. McLaughlin, and J. George, Jr., Proc. Natl. Acad. Sci. USA 73:4589-4592, 1976). As shown by Milman et al. and confirmed by us here, rare HAT+ revertants arise spontaneously at 1.9 X 10(-8) frequency and express both mutant and wild-type polypeptides. Thus, the H23 mutant also carries a silent wild-type HPRT allele that is activated in revertants. To test whether the silent allele was activated via hypomethylation of genomic DNA, H23 cells were treated with inhibitors of DNA methylation, and revertants were scored by HAT or azaserine selection. At an optimal dose of 5 microM 5-azacytidine, the reversion frequency was increased about 50-fold when assayed by HAT selection and over 1,000-fold when assayed by azaserine selection. HAT+ and azaserine revertants were heterozygous for HPRT, expressing both wild-type and mutant HPRT polypeptides. Like spontaneous revertants, they contained active HPRT enzyme and were genetically unstable, reverting at about 10(-4) frequency. Similar results were found after treatment with N-methyl-N'-nitro-N-nitrosoguanidine, a DNA-alkylating agent and potent inhibitor of mammalian DNA methylation. By contrast, the DNA-ethylating agent, ethyl methanesulfonate (EMS), did not increase the HAT+ reversion frequency; it did, however, increase the frequency by which H23 revertants heterozygous for HPRT reverted to 6-thioguanine resistance. Of nine EMS revertants, seven lacked HPRT activity and had a substantially reduced expression of the wild-type polypeptide. These observations support the hypothesis that DNA methylation plays an important role in human X-chromosome inactivation and that EMS can inactivate gene expression by promoting enzymatic methylation of genomic DNA as found previously for the prolactin gene in GH3 rat pituitary tumor cells (R. D. Ivarie and J. A. Morris, Proc. Natl. Acad. Sci. USA 79:2967-2970, 1982; R. D. Ivarie, J. A. Morris, and J. A. Martial, Mol. Cell. Biol. 2:179-189, 1982).