A fragile X case with an amplification/deletion mosaic pattern

Fragile X syndrome is the most common cause of hereditary mental retardation. The FMR1 gene, which is involved in fragile X syndrome, contains a polymorphic CGG repeat, which expands in affected patients. Expanding triplet repeats have been shown to be a new type of mutation, termed "dynamic mutation", responsible for more than 12 genetic diseases. These mutations occur as multiple steps rather than as a single event. The first step leads to an unstable allele that then becomes increasingly unstable generally achieving further increases in copy or occasionally contraction. In this report, we describe a fragile X boy with both a hypermethylated full mutation and a deletion of 905 bp encompassing the CGG repeat. The upstream breakpoint is 438 bp 5' to the CGG repeat and the downstream breakpoint is 420 bp 3' of the triplet repeats. The deletion includes the ATG starting codon for translation of the FMR1 gene. This was confirmed by using FMRP immunocytochemistry both on blood smears and hair roots. The deleted region is flanked by a ccgg direct repeat next to the breakpoints; this may have had a critical role in the formation of a secondary DNA structure leading to the deletion.     

Fragiles-X Syndrom

Fragile X syndrome is an X-linked neurodevelopmental disorder affecting both males and females. Phenotypical characteristics include intellectual deficits, somatic symptoms and behavioural abnormalities caused by loss of the FMRP protein, which leads to destruction of synapses with metabotropic glutamate receptors. The FMR1 gene harbours a CGG repeat in the 5’-untranslated region. The vast majority of fragile-X syndrome patients have a largely expanded CGG repeat (220 or more triplets, designated “full mutation”) and an inactive gene. Full mutation alleles originate upon proliferation of oogonia in the fetal ovary of females who carry a mitotically unstable premutation (59–200 repeats). Premutation carriers have no symptoms of fragile X syndrome; they may, however, experience premature ovarian insufficiency and/or fragile X-associated tremor/ataxia syndrome. The diagnosis of both syndromes requires genetic testing to measure the number of CGG repeats. Prenatal diagnostics of fragile X syndrome is offered to females carrying a pre- or full mutation.     

甲基化特异性PCR检测FMR1 和XIST基因甲基化实验方法的建立

建立一种快速、灵敏的检测脆性X智障基因（Fragile X mental retardation, FMR1）和X染色体失活基因（X chromosome inactivation,XIST）甲基化的方法,用亚硫酸氢钠和对苯二酚对基因组DNA进行脱氨基修饰。以修饰后的DNA为模板,用两套不同的引物对：1对甲基化特异性引物和1对非甲基化特异性引物扩增FMR1基因（CGG）n重复序列区、FMR1 和XIST 基因的启动子区。PCR产物进一步克隆、测序。以亚硫酸氢钠和对苯二酚脱氨基修饰后的DNA为模板,进行PCR扩增后的产物与预期基因目的基因片段大小相符合,无非特异性扩增产物。测序结果表明,FMR1、XIST基因中的非甲基化的C碱基转变为U碱基,而CpG岛被甲基化的C碱基不改变。成功地建立了检测FMR1、XIST甲基化的方法,为实验室诊断脆性X综合征提供了新的方法。     

Instability of a premutation-sized CGG repeat in FMR1 YAC transgenic mice

Fragile X syndrome results from the massive expansion of a CGG repeat in the 5' untranslated region of the gene FMR1. Data suggest that the hyperexpansion properties of FMR1 CGG repeats may depend on flanking cis-acting elements. We have therefore used homologous recombination in yeast to introduce an in situ CGG expansion corresponding to a premutation-sized allele into a human YAC carrying the FMR1 locus. Several transgenic lines were generated that carried repeats of varying lengths and amounts of flanking sequence. Length-dependent instability in the form of small expansions and contractions was observed in both male and female transmissions over five generations. No parent-of-origin effect or somatic instability was observed. Alterations in tract length were found to occur exclusively in the 3' uninterrupted CGG tract. Large expansion events indicative of a transition from a premutation to a full mutation were not observed. Overall, our results indicate both similarities and differences between the behavior of a premutation-sized repeat in mouse and that in human.     

Analysis of the Fragile X Trinucleotide Repeat in Basques: Association of Premutation and Intermediate Sizes,Anchoring AGGs and Linked Microsatellites with Unstable Alleles

Fragile X Syndrome (FXS) is associated with an unstable CGG repeat sequence in the 5’ untranslated region in the first exon of the FMR1 gene which resides at chromosome position Xq27.3 and is coincident with the fragile site FRAXA. The CGG sequence is polymorphic with respect to size and purity of the repeat. Interpopulation variation in the polymorphism of the FMR1 gene and consequently, in the predisposition to FXS due to the prevalence of certain unstable alleles has been observed. Spanish Basque population is distributed among narrow valleys in northeastern Spain with little migration between them until recently. This characteristic may have had an effect on allelic frequency distributions. We had previously reported preliminary data on the existence of FMR1 allele differences between two Basque valleys (Markina and Arratia). In the present work we extended the study to Uribe, Gernika, Durango, Goierri and Larraun, another five isolated valleys enclosing the whole area within the Spanish Basque region. We analyzed the prevalence of FMR1 premutated and intermediate/grey zone alleles. With the aim to complete the previous investigation about the stability of the Fragile X CGG repeat in Basque valleys, we also analyzed the existence of potentially unstable alleles, not only in relation with size and purity of CGG repeat but also in relation with DXS548 and FRAXAC1 haplotypes implicated in repeat instability. The data show that differences in allele frequencies as well as in the distribution of the mutational pathways previously identified are present among Basques. The data also suggest that compared with the analyzed Basque valleys, Gernika had increased frequency of susceptibility to instability alleles, although the prevalence of premutation and intermediate/grey zone alleles in all the analyzed valleys was lower than that reported in Caucasian populations.Key Words: Fragile X syndrome, FMR1 gene, CGG repeat, FRAXAC1, DXS548, basque country.     

Fragile-X Carrier Screening and the Prevalence of Premutation and Full-Mutation Carriers in Israel

Fragile-X syndrome is caused by an unstable CGG trinucleotide repeat in the FMR1 gene at Xq27. Intermediate alleles (51-200 repeats) can undergo expansion to the full mutation on transmission from mother to offspring. To evaluate the effectiveness of a fragile-X carrier-screening program, we tested 14,334 Israeli women of child-bearing age for fragile-X carrier status between 1992 and 2000. These women were either preconceptional or pregnant and had no family history of mental retardation. All those found to be carriers of premutation or full-mutation alleles were offered genetic counseling and also prenatal diagnosis, if applicable. We identified 207 carriers of an allele with >50 repeats, representing a prevalence of 1:69. There were 127 carriers with >54 repeats, representing a prevalence of 1:113. Three asymptomatic women carried the fully mutated allele. Among the premutation and full-mutation carriers, 177 prenatal diagnoses were performed. Expansion occurred in 30 fetuses, 5 of which had an expansion to the full mutation. On the basis of these results, the expected number of avoided patients born to women identified as carriers, the cost of the test in this study (U.S. $100), and the cost of lifetime care for a mentally retarded person (>$350,000), screening was calculated to be cost-effective. Because of the high prevalence of fragile-X premutation or full-mutation alleles, even in the general population, and because of the cost-effectiveness of the program, we recommend that screening to identify female carriers should be carried out on a wide scale.     

Elevated Fmr1 mRNA levels and reduced protein expression in a mouse model with an unmethylated Fragile X full mutation

The human FMR1 gene contains a CGG repeat in its 5' untranslated region. The repeat length in the normal population is polymorphic (5-55 CGG repeats). Lengths beyond 200 CGGs (full mutation) result in the absence of the FMR1 gene product, FMRP, through abnormal methylation and gene silencing. This causes Fragile X syndrome, the most common inherited form of mental retardation. Elderly carriers of the premutation, defined as a repeat length between 55 and 200 CGGs, can develop a progressive neurodegenerative syndrome: Fragile X-associated tremor/ataxia syndrome (FXTAS). In FXTAS, FMR1 mRNA levels are elevated and it has been hypothesised that FXTAS is caused by a pathogenic RNA gain-of-function mechanism. We have developed a knock in mouse model carrying an expanded CGG repeat (98 repeats), which shows repeat instability and displays biochemical, phenotypic and neuropathological characteristics of FXTAS. Here, we report further repeat instability, up to 230 CGGs. An expansion bias was observed, with the largest expansion being 43 CGG units and the largest contraction 80 CGG repeats. In humans, this length would be considered a full mutation and would be expected to result in gene silencing. Mice carrying long repeats ( approximately 230 CGGs) display elevated mRNA levels and decreased FMRP levels, but absence of abnormal methylation, suggesting that modelling the Fragile X full mutation in mice requires additional repeats or other genetic manipulation.     

The risk of fragile X premutation expansion is lower in carriers detected by general prenatal screening than in carriers from known fragile X families

The Fragile X syndrome is the most common cause of inherited mental retardation. For a female premutation carrier, the risk of having a child with a full mutation is positively correlated with the size of the premutation. The current study was performed to evaluate the risk of premutation expansion in the offspring of average-risk carriers detected by general prenatal screening. Over a 4-year period, 9,660 women underwent DNA screening for FMR1 mutation/premutation at the Tel Aviv Sourasky Medical Center. A premutation was defined as a CGG repeat number >50 in the 5' untranslated region (UTR) of exon 1 in the FMR1 gene. The study included only individuals with no family history of X-linked mental retardation or known FMR1 mutations. A premutation was found in 85 women (1 in 114), 68 of whom consented to have prenatal diagnoses in 74 pregnancies. The abnormal allele was transmitted to the offspring in 44 pregnancies. Of these, no change in allele size was noted in 35 pregnancies (79.6%), and expansion within premutation range was evident in 4 pregnancies (9%). In 5 pregnancies (11.4%), expansion to the full mutation was noted. This occurred only in carriers having more than 90 repeats. We conclude that the likelihood of Fragile X premutation expansion to full mutation is significantly lower in individuals ascertained by general prenatal carrier testing than in those from known Fragile X families.     

Methylation mosaicism of 5'-(CGG)(n)-3' repeats in fragile X, premutation and normal individuals

Fragile X syndrome (FRAXA) is characterized at the molecular level by an expansion of a naturally occurring 5′-(CGG)_n-3′ repeat in the promoter and 5′-untranslated region (5′-UTR) of the fragile X mental retardation (FMR1) gene on human chromosome Xq27.3. When expanded, this region is usually hypermethylated. Inactivation of the FMR1 promoter and absence of the FMR1 protein are the likely cause of the syndrome. By using the bisulfite protocol of the genomic sequencing method, we have determined the methylation patterns in this region on single chromosomes of healthy individuals and of selected premutation carriers and FRAXA patients. In control experiments with unmethylated or M-SssI-premethylated DNAs, this protocol has been ascertained to reliably detect all cytidines or 5-methylcytidines as unmethylated or methylated nucleotides, respectively. Analyses of the DNA from FRAXA patients reveal considerable variability in the lengths of the 5′-(CGG)_n-3′ repeats and in the levels of methylation in the repeat and the 5′-UTR. In one patient (OEl) with high repeat length heterogeneity (n = 15 to >200), shorter repeats (n = 20–80) were methylated or unmethylated, longer repeats (n = 100–150) were often completely methylated, but one repeat with n = 160 proved to be completely unmethylated. This type of methylation mosaicism was observed in several FRAXA patients. In healthy females, methylated 5′-CG-3′ sequences were found in some repeats and 5′-UTRs, as expected for the sequences from one of the X chromosomes. The natural FMR1 promoter is methylation sensitive, as demonstrated by the loss of activity in transfection experiments using the unmethylated or M-SssI-premethylated FMR1 promoter fused to the luciferase gene as an activity indicator.     

Cerebral Protein Synthesis in a Knockin Mouse Model of the Fragile X Premutation

The (CGG)n-repeat in the 5′-untranslated region of the fragile X mental retardation gene (FMR1) gene is polymorphic and may become unstable on transmission to the next generation. In fragile X syndrome, CGG repeat lengths exceed 200, resulting in silencing of FMR1 and absence of its protein product, fragile X mental retardation protein (FMRP). CGG repeat lengths between 55 and 200 occur in fragile X premutation (FXPM) carriers and have a high risk of expansion to a full mutation on maternal transmission. FXPM carriers have an increased risk for developing progressive neurodegenerative syndromes and neuropsychological symptoms. FMR1 mRNA levels are elevated in FXPM, and it is thought that clinical symptoms might be caused by a toxic gain of function due to elevated FMR1 mRNA. Paradoxically, FMRP levels decrease moderately with increasing CGG repeat length in FXPM. Lowered FMRP levels may also contribute to the appearance of clinical problems. We previously reported increases in regional rates of cerebral protein synthesis (rCPS) in the absence of FMRP in an Fmr1 knockout mouse model and in a FXPM knockin (KI) mouse model with 120 to 140 CGG repeats in which FMRP levels are profoundly reduced (80%–90%). To explore whether the concentration of FMRP contributes to the rCPS changes, we measured rCPS in another FXPM KI model with a similar CGG repeat length and a 50% reduction in FMRP. In all 24 brain regions examined, rCPS were unaffected. These results suggest that even with 50% reductions in FMRP, normal protein synthesis rates are maintained.     

Distribution of CGG repeat sizes within the fragile X mental retardation 1 (<Emphasis Type="Italic">FMR1</Emphasis>) homologue in a non-human primate population

Fragile X syndrome, the most common inherited form of mental retardation, arises in individuals with more than 200 CGG repeats in the 5 untranslated region of the fragile X mental retardation 1 (FMR1) gene. Although CGG repeat numbers comparable to those found in the normal human population are found in various non-human primates, neither the within-species size variation nor the propensity for expansion of the CGG repeat has been described for any non-human primate species. The allele distribution has now been determined for FMR1 (homologue) CGG repeats of 265 unrelated founder females of Macaca mulatta monkeys. Among 530 X chromosomes, at least 26 distinct repeat lengths were identified, ranging from 16 to 54 CGG repeats. Of these alleles 79% have between 25 and 33 CGG repeats. Detailed examination of the CGG region revealed a conserved G (CGG)₂ G interruption, although in no case was an AGG trinucleotide detected. Two animals carried borderline premutation alleles with 54 CGG repeats, within the region of marginal instability for humans. Thus, M. mulatta may be useful as an animal model for the study of fragile X syndrome.     

Apparent regression of the CGG repeat in FMR1 to an allele of normal size

The fragile X syndrome is the result of amplification of a CGG trinucleotide repeat in the FMR1 gene and anticipation in this disease is caused by an intergenerational expansion of this repeat. Although regression of a CGG repeat in the premutation range is not uncommon, regression from a full premutation (>200 repeats) or premutation range (50–200 repeats) to a repeat of normal size (<50 repeats) has not yet been documented. We present here a family in which the number of repeats apparently regressed from approximately 110 in the mother to 44 in her daughter. Although the CGG repeat of the daughter is in the normal range, she is a carrier of the fragile X mutation based upon the segregation pattern of Xq27 markers flanking FMR1. It is unclear, however, whether this allele of 44 repeats will be stably transmitted, as the daughter has as yet no progeny. Nevertheless, the size range between normal alleles and premutation alleles overlap, a factor that complicates genetic counseling.     

Instability of the CGG repeat and expression of the FMR1 protein in a male fragile X patient with a lung tumor.

The molecular mechanism of the fragile X syndrome is based on the expansion of an CGG repeat in the 5' UTR of the FMR1 gene in the majority of fragile X patients. This repeat displays instability both between individuals and within an individual. We studied the instability of the CGG repeat and the expression of the FMR1 protein (FMRP) in several different tissues derived from a male fragile X patient. Using Southern blot analysis, only a full mutation is detected in 9 of the 11 tissues tested. The lung tumor contains a methylated premutation of 160 repeats, whereas in the testis, besides the full mutation, a premutation of 60 CGG repeats is detected. Immunohistochemistry of the testis revealed expression of FMR1 in the spermatogonia only, confirming the previous finding that, in the sperm cells of fragile X patients with a full mutation in their blood cells, only a premutation is present. Immunohistochemistry of brain and lung tissue revealed that 1% of the cells are expressing the FMRP. PCR analysis demonstrated the presence of a premutation of 160 repeats in these FMR1-expressing cells. This indicates that the tumor was derived from a lung cell containing a premutation. Remarkably, despite the methylation of the EagI and BssHII sites, FMRP expression is detected in the tumor. Methylation of both restriction sites has thus far resulted in a 100% correlation with the lack of FMR1 expression, but the results found in the tumor suggest that the CpGs in these restriction sites are not essential for regulation of FMR1 expression. This indicates a need for a more accurate study of the exact promoter of FMR1.     

Timing of the absence of <Emphasis Type="Italic">FMR1</Emphasis> expression in full mutation chorionic villi

Fragile X syndrome is caused by the expansion of the CGG repeat in the 5' untranslated region of the FMR1 gene. This expansion leads to methylation of the FMR1 promoter region thereby blocking FMR1 protein (FMRP) expression. Prenatal diagnosis can be performed on chorionic villi samples (CVS) by Southern blot analysis. Alternatively, for males, an immunohistochemical method has been introduced for CVS. In this study, we have used this immunocytochemical method for CVS in full mutation male fetuses at different times of gestational age, varying from 10.0-12.5 weeks, and in two cases of full mutation female fetuses (>13 weeks). FMRP expression studies in CVS from full mutation male fetuses (10.0-12.5 weeks) illustrate the timing of the disappearance of FMRP expression in these CVS. Until approximately 10 weeks of gestation, FMRP is expressed normally in full mutation male CVS, whereas FMRP is completely absent at 12.5 weeks of gestation. FMRP expression in full mutation female CVS (>13 weeks) is completely absent in a number of villi, whereas other villi show normal FMRP expression. Unlabelled villi can only be present in the absence of the expression of the full mutation FMR1 gene on one X-chromosome together with the X-inactivation of the normal X allele. FMRP positive villi can be explained by an active normal X allele. The presence of both positive and negative villi indicates that X-inactivation in human CVS is a random process. No villi are found with a mixture of both FMRP-expressing and non-FMRP-expressing cells. This indicates that X-inactivation occurs very early in development, before the villi start to proliferate, and that X-inactivation in villi is a clonal process. In addition, our results indicate that the timing of both X-inactivation and full mutation FMR1 allele inactivation is different, i.e. X-inactivation occurs earlier in development than inactivation of the full mutation.