Most fragile X syndrome patients have expansion of a (CGG)(n)sequence with >200 repeats (full mutation) in the FMR1 gene responsible for this condition. Hypermethylation of the expanded repeat and of the FMR1 promoter is almost always present and apparently suppresses transcription, resulting in absence of the FMR1 protein. We recently showed that transcriptional reactivation of FMR1 full mutations can be achieved by inducing DNA demethylation with 5-azadeoxycytidine (5-azadC). The level of histone acetylation is another important factor in regulating gene expression; therefore, we treated lymphoblastoid cell lines of non-mosaic full mutation patients with three drugs capable of inducing histone hyperacetylation. We observed a consistent, although modest, reactivation of the FMR1 gene with 4-phenylbutyrate, sodium butyrate and trichostatin A, as shown by RT-PCR. However, we report that combining these drugs with 5-azadC results in a 2- to 5-fold increase in FMR1 mRNA levels obtained with 5-azadC alone, thus showing a marked synergistic effect of histone hyperacetylation and DNA demethylation in the reactivation of FMR1 full mutations.
The analysis of a lymphoblastoid cell line (5106), derived from a rare individual of normal intelligence with an unmethylated full mutation of the FMR1 gene, allowed us to reconstruct the chain of molecular events leading to the FMR1 inactivation and to fragile X syndrome. We found that lack of DNA methylation of the entire promoter region, including the expanded CGG repeat, correlates with methylation of lysine 4 residue on the N-tail of histone H3 (H3-K4), as in normal controls. Normal levels of FMR1 mRNA were detected by real-time fluorescent RT-PCR (0.8-1.4 times compared with a control sample), but mRNA translation was less efficient (-40%), as judged by polysome profiling, resulting in reduced levels of FMRP protein (approximately 30% of a normal control). These results underline once more that CGG repeat amplification per se does not prevent FMR1 transcription and FMRP production in the absence of DNA methylation. Surprisingly, we found by chromatin immunoprecipitation that cell line 5106 has deacetylated histones H3 and H4 as well as methylated lysine 9 on histone H3 (H3-K9), like fragile X cell lines, in both the promoter and exon 1. This indicates that these two epigenetic marks (i.e. histone deacetylation and H3-K9 methylation) can be established in the absence of DNA methylation and do not interfere with active gene transcription, contrary to expectation. Our results also suggest that the molecular pathways regulating DNA and H3-K4 methylation are independent from those regulating histone acetylation and H3-K9 methylation.
In fragile X syndrome, hypermethylation of the expanded CGG repeat and of the upstream promoter leads to transcriptional silencing of the FMR1 gene. Absence of the FMR1 protein results in mental retardation. We previously proved that treatment with 5-azadeoxycytidine (5-azadC) of fragile X cell lines results in reactivation of the FMR1 gene. We now show that this treatment causes passive demethylation of the FMR1 gene promoter. We employed the bisulfite-sequencing technique to detect the methylation status of individual CpG sites in the entire promoter region, upstream of the CGG repeat. Lymphoblastoid cell lines of fragile X males with full mutations of different sizes were tested before and after treatment with 5-azadC at various time points. We observed that individual cells are either completely unmethylated or not, with few relevant exceptions. We also investigated the extent of methylation in the full mutation (CGG repeat) itself by Southern blot analysis after digestion with methylation-sensitive enzymes Fnu4HI and McrBC and found that the CGG repeat remains at least partially methylated in many cells with a demethylated promoter. This may explain the quantitative discrepancy between the large extent of promoter demethylation and the limited levels of FMR1 transcriptional reactivation estimated by quantitative real-time fluorescent RT-PCR analysis.
The fragile X syndrome is caused by a 4200 CGG repeat expansion within the FMR1 gene promoter, with consequent DNA hypermethylation and inactivation of its expression. To further clarify the mechanisms that suppress the activity of the mutant gene and the conditions that may permit its reactivation, we investigated the acetylation and methylation status of three different regions of the FMR1 gene (promoter, exon 1 and exon 16) of three fragile X cell lines, using a chromatin immunoprecipitation (ChIP) assay with antibodies against acetylated-H3/H4 histones and against dimethylated lysine residues K4 and K9 of histone H3 (H3-K4 and H3-K9). We then coupled the ChIP assay with real-time PCR, obtaining absolute quantification of immunoprecipitated chromatin. Basal levels of histone acetylation and H3-K4 methylation were much higher in transcriptionally active wild-type controls than in inactive fragile X cell lines. Treatment of fragile X cell lines with the DNA demethylating drug 5-aza-2-deoxycytidine (5-azadC), known to reactivate the FMR1 gene, induced a decrease of H3-K9 methylation, an increase of H3 and H4 acetylation and an increase of H3-K4 methylation. Treatment with acetyl-L-carnitine (ALC), a compound that reduces the in vitro expression of the FRAXA fragile site without affecting DNA methylation, caused an increase of H3 and H4 acetylation. However, H3-K4 methylation remained extremely low, in accordance with the observation that ALC alone does not reactivate the FMR1 gene. Our experiments indicate that H3-K4 methylation and DNA demethylation are the main epigenetic switches activating the expression of the FMR1 gene, with histone acetylation playing an ancillary role.
X-linked mental retardation (XLMR) is a genetically heterogeneous condition, due to mutations in at least 50 genes, involved in functioning of the central nervous system and located on the X chromosome. Nonspecific XLMR (MRX) is characterized essentially by mental retardation transmitted by X-linked inheritance. More than 80 extended MRX pedigrees have been reported to date, which have been distinguished exclusively by physical position of the corresponding gene on the X chromosome, established by linkage analysis. One such family, MRX21, which was described by us in 1993 and localized to Xp11.4-pter, has now been reanalyzed with additional markers and after one more affected individual had became available. This extra information allowed a significant reduction of the linkage interval and, eventually, identification of the mutant gene. A stop mutation in exon 10 of the IL1RAPL1 gene (in Xp21) was found in the four affected males and in obligate carriers, allowing conclusive counseling of other family members of uncertain carrier status. The W487X mutation results in the production of a truncated IL1RAPL protein, comprised of the extracellular Ig-like domain and transmembrane tract, but lacking the last 210 aminoacids of the cytoplasmic domain. MRX21 is the first extended MRX family with a point mutation in IL1RAPL1 and the second with a stop mutation, which had been previously found only in a small family. Our report confirms the role of the IL1RAPL1 gene in causing nonspecific mental retardation in males and underlines the importance of detailed linkage analysis before candidate gene mutational screening.
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