Expansion and methylation status at FRAXE can be detected on EcoRI blots used for FRAXA diagnosis: analysis of four FRAXE families with mild mental retardation in males.

The original test for the analysis of the CCG expansion at the FRAXE locus involves Southern blot analysis of HindIII digests. We show that, by using a different probe, the FRAXE mutation can be detected easily on the same EcoRI or EagI+EcoRI blots as are used for detection of FRAXA. Unexpectedly, we found that both the expansion and methylation status can be determined on a single EcoRI digest, because of the presence of a methylation-sensitive EcoRI site very close to the CCG repeat. We thus detected in a series of mentally retarded individuals previously tested for FRAXA expansion a FRAXE proband who led to the identification of a large sibship (7 of 10 children carrying a mutation). We also show that two fragile X families without FRAXA mutation that previously have been described by Oberlé et al. have the FRAXE expansion. In another family also ascertained initially by cytogenetic finding of a fragile X site, we performed the combined cytogenetic and molecular prenatal diagnosis of a mutated male fetus. All nine males (>3 years old) in whom we found a methylated mutation had mild mental retardation. Our results suggest that the threshold of repeat length for abnormal methylation and fragile-site expression may be smaller at FRAXE than at FRAXA.     

A survey of fragile X syndrome in a sample from Spanish Basque country

Fragile X syndrome is the most common inherited form of mental retardation. The syndrome is associated with a CGG repeat expansion in the 5'UTR of the first exon of the FMR1 gene. This gene maps to Xq27.3 and coincides with the cytogenetic fragile site (FRAXA). The present study deals with the prevalence of fragile X syndrome among individuals with mental retardation of unknown cause from institutions and special schools from the Spanish Basque Country. Results of cytogenetic and molecular studies, performed in a group of 134 unrelated individuals (92 males and 42 females) are presented. The cytogenetic marker at Xq27.3 was identified in 12 patients. Other chromosomal abnormalities were found in two cases that this and previous studies confirmed as Angelman and Prader-Willi syndromes. Two males, in whom the cytogenetic marker was identified, were found negative for FRAXA and FRAXE expansion at the molecular level. The present study shows that the frequency of the FRAXA full mutation in individuals of Spanish non-Basque origin is in the range of other Spanish populations. In the sample of Spanish Basque origin we have not found cytogenetic FRAXA site expression, and the CGG repeat size of FMR1 gene is in the normal range. The significance of these results are discussed.     

Polymorphism of trinucleotide repeats at loci FRAXA and FRAXE in the population of Tomsk

Polymorphism of CGG and GCC trinucleotide repeats, whose expansions at the FRAXA and FRAXE loci have been identified as causative mutations in two forms of mental retardation, was studied in Slavic population of Tomsk. At the FRAXA locus a total of 31 allelic variants ranging from 8 to 56 copies of CGG repeat with two modal classes of 28-29 and 18-20 repeat units (with the frequencies of 24.6 and 11.5% respectively) were revealed. Compared to other populations, this locus was characterized by unusually high frequency of intermediate alleles with the sizes of more than 40 CGG repeat units (12.4%). Since intermediate repeats of the FRAXA locus were more prone to instability than normal alleles, it was suggested that Slavic population of Siberia had higher risk of the development of FMR1 dynamic mutations, giving rise to the Martin-Bell syndrome. The FRAXE allele frequency distribution was demonstrated to be normal with 18 allelic variants ranging from 9 to 27 GCC repeat units. In the population of Tomsk this locus had higher than in other populations frequency (26.7%) of short (less than 15 repeat units in size) alleles. In addition, in the Tomsk population both loci were characterized by high level of heterozygosity and low frequencies of modal allele classes. These results can be explained by the high level of outbreeding typical of the population of Siberia.     

Dynamic mutations in human genes: A review of trinucleotide repeat diseases

Dynamic mutations in human genes result from unstable trinucleotide repeats embedded within the transcribed region. The changeable nature of these mutations from generation to generation is in contrast to the static inheritance of other single-gene mutational events, e.g. point mutations, deletions, insertions and inversions, typically associated with Mendelian inheritance patterns. Intergenerational instability of dynamic mutations within families has provided an explanation for the genetic anticipation, leading to increasing severity or earlier age of onset in successive generations, associated with certain inherited disorders. While models for genomic instability presume that trinucleotide repeat expansion results from disruption of the DNA replication process, experimental evidence has not yet been obtained in support of this contention. Nevertheless, examples of unstable trinucleotide repeats continue to increase, although not all are associated with a specific phenotype. Five disorders resulting from small-scale expansions of CAG repeats within the protein-coding region are known: spinobulbar muscular atrophy, Huntington’s disease, spinocerebellar ataxia type 1, dentatorubral-pallidoluysian atrophy (DRPLA) and Machado-Joseph disease. A sixth disorder, Haw River syndrome, is allelic to DRPLA. Five folate-sensitive chromosomal fragile sites characterized to date, viz. FRAXA, FRAXE, FRAXF, FRA11B and FRA16A, all have large-scale CGG repeat expansion. Two disorders, fragile X syndrome and FRAXE mental retardation, result from instability of CGG repeats in the 5’ untranslated region ofFMR1 andF M R2 genes respectively. FRA11B lies close to chromosome 1 1q deletion endpoints in many Jacobsen syndrome patients and may be related to the deletion event producing partial aneuploidy for 1lq. Expansion of FRAXF and FRA16A has not been associated with a phenotype. Myotonic dystrophy results from a large-scale CTG expansion in the 3’ untranslated region of the myotonin protein kinase gene while Friedreich’s ataxia has recently been found to have a large-scale GAA repeat in the first intron ofX25. This article reviews the characteristics of trinucleotide repeat disorders and summarizes current understanding of the molecular pathophysiology.     

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.     

FRAXE expansion is not a common etiological factor among developmentally delayed males.

Expansion of a (CGG)n trinucleotide repeat unit at FRAXE, a newly defined fragile site distal to FRAXA, at Xq28, is reported to be associated with mild mental retardation. Three hundred developmentally delayed male patients referred for fragile X testing but negative for the FMR-1 gene trinucleotide expansion were screened for the FRAXE expansion. This group of patients had a wide range of intellectual or behavioral problems and included 19 patients who had low-level fragile site expression detected cytogenetically at Xq27-q28. None of the patients tested positive for the FRAXE expansion. These results suggest that FRAXE is not a common etiological factor among this group of patients. The data support the hypothesis that FRAXE is either very rare or a benign fragile site that is not associated with any clinical phenotype, similar to the FRAXF and FRA16A sites.     

A study of FRAXE in mentally retarded individuals referred for fragile X syndrome (FRAXA) testing in the United Kingdom.

The folate-sensitive fragile site FRAXE is located in proximal Xq28 of the human X chromosome and lies approximately 600 kb distal to the fragile X syndrome (FRAXA) fragile site at Xq27.3. The cytogenetic expression of FRAXE is thought to be associated with mental handicap, but this is usually mild compared to that of the more common fragile X syndrome that is associated with the expression of the FRAXA fragile site. The exact incidence of FRAXE mental retardation is uncertain. We describe here the results of a U.K. survey designed to assess the frequency of FRAXE in a population of individuals referred for fragile X syndrome testing and found to be negative for expansion events at the FRAXA locus. No FRAXE expansion events were found in 362 cytogenetically negative males studied, and one expansion event was identified in a sample of 534 males for whom cytogenetic analyses were either unrecorded or not performed. Further FRAXE expansion events were detected in two related females known to be cytogenetically positive for a fragile site in Xq27.3-28. To gain insight into the FRAXE phenotype, the clinical details of the identified FRAXE male plus three other FRAXE individuals identified through previous referrals for fragile X syndrome testing are presented. For the population studied, we conclude that FRAXE mental retardation is a relatively rare but significant form of mental retardation for which genetic diagnosis would be appropriate.     

Preliminary evidence of an effect of cerebellar volume on postural sway in FMR1 premutation males

Recent evidence suggests that early changes in postural control may be discernible among females with premutation expansions (55–200 CGG repeats) of the fragile X mental retardation 1 (FMR1) gene at risk of developing fragile X‐associated tremor ataxia syndrome (FXTAS). Cerebellar dysfunction is well described in males and females with FXTAS, yet the interrelationships between cerebellar volume, CGG repeat length, FMR1 messenger RNA (mRNA) levels and changes in postural control remain unknown. This study examined postural sway during standing in a cohort of 22 males with the FMR1 premutation (ages 26–80) and 24 matched controls (ages 26–77). The influence of cerebellar volume, CGG repeat length and FMR1 mRNA levels on postural sway was explored using multiple linear regression. The results provide preliminary evidence that increasing CGG repeat length and decreasing cerebellar volume were associated with greater postural sway among premutation males. The relationship between CGG repeat length and postural sway was mediated by a negative association between CGG repeat size and cerebellar volume. While FMR1 mRNA levels were significantly elevated in the premutation group and correlated with CGG repeat length, FMR1 mRNA levels were not significantly associated with postural sway scores. These findings show for the first time that greater postural sway among males with the FMR1 premutation may reflect CGG repeat‐mediated disruption in vulnerable cerebellar circuits implicated in postural control. However, longitudinal studies in larger samples are required to confirm whether the relationships between cerebellar volume, CGG repeat length and postural sway indicate greater risk for neurological decline.     

Rare fragile sites

Rare folate-sensitive fragile sites are the archetypal trinucleotide repeats. Although the CAG repeat in the androgen receptor, associated with spinobulbar muscular atrophy, was the first to be published in 1991, it was the publication in the same year of the molecular basis of fragile X that focused much attention on trinucleotide repeat expansion as a mutational mechanism. A number of rare fragile sites have had their repeat elements characterised since that time. The so-called "folate-sensitive" fragile sites are likely to be all CCG repeat expansions similar to the fragile X. The folate insensitive fragile sites have more complex longer repeat elements. Only two rare fragile sites (FRAXA and FRAXE) are of unequivocal clinical significance in that they are associated with intellectual disability.     

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.     

ATR protects the genome against CGG.CCG-repeat expansion in Fragile X premutation mice

Fragile X mental retardation syndrome is a repeat expansion disease caused by expansion of a CGG·CCG-repeat tract in the 5′ UTR of the FMR1 gene. In humans, small expansions occur more frequently on paternal transmission while large expansions are exclusively maternal in origin. It has been suggested that expansion is the result of aberrant DNA replication, repair or recombination. To distinguish amongst these possibilities we crossed mice containing 120 CGG·CCG-repeats in the 5′ UTR of the mouse Fmr1 gene to mice with mutations in ATR, a protein important in the cellular response to stalled replication forks and bulky DNA lesions. We show here that ATR heterozygosity results in increased expansion rates of maternally, but not paternally, transmitted alleles. In addition, age-related somatic expansions occurred in mice of both genders that were not seen in ATR wild-type animals. Some ATR-sensitive expansion occurs in postmitotic cells including haploid gametes suggesting that aberrant DNA repair is responsible. Our data suggest that two mechanisms of repeat expansion exist that may explain the small and large expansions seen in humans. In addition, our data provide an explanation for the maternal bias of large expansions in humans and the lower incidence of these expansions in mice.     

Chromatin remodeling in the noncoding repeat expansion diseases

Friedreich ataxia, myotonic dystrophy type 1 and 3 forms of intellectual disability, fragile X syndrome, FRAXE mental retardation, and FRA12A mental retardation are repeat expansion diseases caused by expansion of CTG.CAG, GAA.TTC, or CGG.CCG repeat tracts. These repeats are transcribed but not translated. They are located in different parts of different genes and cause symptoms that range from ataxia and hypertrophic cardiomyopathy to muscle wasting, male infertility, and mental retardation, yet recent reports suggest that, despite these differences, the repeats may share a common property, namely the ability to initiate repeat-mediated epigenetic changes that result in heterochromatin formation.     

A female compound heterozygote (pre- and full mutation) for the CGG FMR1 expansion

Fragile X syndrome is the most common cause of inherited mental retardation. The incidence has been estimated to be 1 in 1250 males and 1 in 2000 females. Molecular studies have shown that 95% of fragile X syndrome cases are caused by the expansion of a CGG triplet in the FMR1 gene with hypermethylation of the adjacent CpG island. In spite of the high incidence of this syndrome, a female with both FMR1 genes in the expanded form has never been reported. We present here a female from the Canary Islands presenting mental retardation and attention problems. Molecular analysis has revealed that both of her FMR1 genes have the CGG expansion, one with a premutation and the other with a full mutation. We have studied the CGG repeat in the FMR1 gene in 64 members of her family and detected 33 normal individuals, 14 carriers with the premutation (1 male and 13 females), and 18 individuals with full mutations (8 males and 10 females). The index case illustrates that the possibility of both parents being carriers of the fragile X syndrome premutation should be considered in consanguineous families or in small communities. Received: 4 April 1996 / Revised: 3 May 1996     

Triplet repeat expansion at the FRAXE locus and X-linked mild mental handicap.

We have recently shown that the expression of the FRAXE fragile site in Xq28 is associated with the expansion of a GCC trinucleotide repeat. In the families studied, FRAXE expression is also associated with mild mental handicap. Here we present data on families that previously had been diagnosed as having the fragile X syndrome but that later were found to be negative for trinucleotide repeat expansion at the FRAXA locus. In these families we demonstrate the presence of a GCC trinucleotide repeat expansion at the FRAXE locus. Studies of the FRAXE locus of normal individuals show that they have 6-25 copies of the repeat, whereas affected individuals have > 200 copies. As in the fragile X syndrome, the amplified CpG residues are methylated in affected males.