Segregation of the fragile X mutation from an affected male to his normal daughter.

We report here a family in which the fragile X mutation segregates from an affected grandfather through his normal daughter to an affected grandson. The grandson shows clinical and cytogenetic expression of fragile X syndrome due to a full mutation (large methylated insertion) in the fragile X gene (FMR-1). The mother shows a premutation (small unmethylated insertion) in her FMR-1 gene as the sole manifestation of the fragile X syndrome. The grandfather expresses the fragile X syndrome at the clinical and cytogenetic level, whereas he is mosaic for a methylated full mutation and an unmethylated premutation. The absence of expression of the fragile X mutation when transmitted through an expressing male might present further evidence for genomic imprinting of the FMR-1 gene. Alternatively, it is possible that the grandfather transmitted his premutation to his daughter due to germline mosaicism with both the premutation and the full mutation present in his sperm.     

Segregation of the fragile X mutation from a male with a full mutation: Unusual somatic instability in the FMR-1 locus

Fragile X syndrome is associated with an unstable CGG-repeat in the FMR-1 gene. There are few reports of affected males transmitting the FMR-1 gene to offspring. We report on a family in which the propositus and his twin sister each had a full mutation with abnormal methylation. Their mother had an FMR-1 allele in the normal range and a large premutation, with normal methylation. The maternal grandmother had two normal FMR-1 alleles. The maternal grandfather had an unusual somatic FMR-1 pattern, with allele size ranging from premutation to full mutation. No allele was detectable by PCR analysis. Multiple Southern blot analyses identified a hybridization pattern that originated at a distinct premutation band and extended into the full mutation range. Methylation studies revealed a mosaic pattern with both unmethylated premutations and methylated full mutations. This individual declined formal evaluation but did not finish high school and has difficulty in reading and writing. The size of the premutation FMR-1 allele passed to his daughter is larger than his most prominent premutation allele. This is most likely due to gonadal mosaicism similar to that in his peripheral lymphocytes. Alternatively, this expansion event may have occurred during his daughter's early embryonic development and this large premutation allele is mitotically unstable. This pattern of FMR-1 alleles in a presumably mildly affected male is highly unusual. These findings are consistent with the absence of transmission of a full fragile X mutation through an expressing male. Studies of tissue specific FMR-1 allele expansion and FMR-1 protein expression on this individual should help to determine the correlation of the molecular findings with the phenotypic effects. © 1996 Wiley-Liss, Inc.     

Tissue differences in fragile X mosaics: Mosaicism in blood cells may differ greatly from skin

The fragile X mutation is diagnosed from the structure of the FMR1 gene in blood cell DNA. An estimated 12 to 41% of affected males are mosaics who carry both a “full mutation” allele from which there is no gene expression and a “premutation” allele which has normal gene expression. We compared the DNA in blood cells and skin fibroblasts from four mosaic fragile X males to see if there was a difference in the relative amounts of premutation and full mutation alleles within the tissues of these individuals. Two of these males showed striking differences in the ratio of premutation to full mutation in different tissues while the other two showed only slight differences. These observations conform with the widely accepted hypothesis that the fragile X CGG repeat is unstable in somatic tissue during early embryogenesis. Accordingly, the mosaicism in brain and skin, which are both ectodermal in origin, may be similar to each other but different from blood which is not ectodermal in origin. Thus, the ratio of full mutation to premutation allele in skin fibroblasts might be a better indicator of psychological impairment than the ratio in blood cells. © 1996 Wiley-Liss, Inc.     

Fragile X syndrome and deletions in FMR1: New case and review of the literature

The fragile X syndrome phenotype of mental retardation is almost always caused by abnormal CGG trinucleotide amplification within the FMR1 gene. Occasionally fragile X syndrome results from point mutations or deletions within or around the FMR1 locus. We have identified a mentally retarded African American male with typical fragile X phenotype and a 300–400 base pair intragenic deletion near the CGG repeat segment, present in his peripheral blood lymphocytes with no apparent mosaicism. His mother, who is not retarded, has a full FMR1 CGG expansion mutation with 700–900 repeats. A review of 23 published cases with FMR1 gene deletions shows full FMR1 mutation in the mother of only 1 other propositus, a male with FMR1 full mutation/premutation/deletion mosaicism of his cultured skin fibroblasts and peripheral blood lymphocytes. The various deletions within FMR1 and their clinical significance are reviewed. Am. J. Med. Genet. 72:430–434, 1997. © 1997 Wiley-Liss, Inc.     

Paternal retraction of a fragile X allele to normal size,showing normal function over two generations

The FMR1 premutation (PM:55-199 CGG) is associated with fragile X-associated tremor/ataxia syndrome (FXTAS) and when maternally transmitted is at risk of expansion to a hypermethylated full mutation (FM: ≥ 200 CGG) that causes fragile X syndrome (FXS). We describe a maternally transmitted PM (77 CGG) that was passed to a son (103 CGG), and to a daughter (220–1822 CGG), who were affected with FXTAS and FXS, respectively. The male with the PM showed low-level mosaicism for normal size of 30 and 37 CGG. This male had two offspring: one female mosaic for PM and FM (56, 157, >200 CGG) and another with only a 37 CGG allele detected in multiple tissues, neither with a clinical phenotype. The female with the 37 CGG allele showed normal levels of FMR1 methylation and mRNA and passed this 37 CGG allele to one of her daughters, who was also unaffected. These findings show that post-zygotic paternal retraction can lead to low-level mosaicism for normal size alleles, with these normal alleles being functional when passed over two generations.     

Direct diagnosis by DNA analysis of the fragile X syndrome of mental retardation

BACKGROUND. The fragile X syndrome, the most common form of inherited mental retardation, is caused by mutations that increase the size of a specific DNA fragment of the X chromosome (in Xq27.3). Affected persons have both a full mutation and abnormal DNA methylation. Persons with a smaller increase in the size of this DNA fragment (a premutation) have little or no risk of retardation but are at high risk of having affected children or grandchildren. The passage from premutation to full-mutation status occurs only with transmission from the mother. We have devised a method of identifying carriers of these mutations by direct DNA analysis. METHOD. We studied 511 persons from 63 families with the fragile X syndrome. Mutations and abnormal methylation were detected by Southern blotting with a probe adjacent to the mutation target. Analysis of EcoRI and EagI digests of DNA distinguished clearly in a single test between the normal genotype, the premutation, and the full mutation. RESULTS. DNA analysis unambiguously established the genetic status at the fragile X locus for all samples tested. This method was much more powerful and reliable than cytogenetic testing or segregation studies with closely linked polymorphic markers. The frequency of mental retardation in persons with premutations was similar to that in the general population, whereas all 103 males and 31 of 59 females with full mutations had mental retardation. About 15 percent of those with full mutations had some cells carrying only the premutation. All the mothers of affected children were carriers of either a premutation or a full mutation. CONCLUSIONS. Direct diagnosis by DNA analysis is now an efficient and reliable primary test for the diagnosis of the fragile X syndrome after birth, as well as for prenatal diagnosis and genetic counseling.     

Strong similarities of the FMR1 mutation in multiple tissues: postmortem studies of a male with a full mutation and a male carrier of a premutation.

Studies of the FMR1 mutation in multiple tissues are important to further our understanding of CGG repeat expansion in development and of the frequency and possible clinical significance of inter-tissue heterogeneity in fragile X syndrome. With some exceptions, most cases reported have shown strong similarity of the mutation size and methylation status between tissues. However, there have been only a few studies of multiple tissues including regions of the brain. We report on two postmortem studies of multiple tissues, one of a male with a full mutation (fully methylated) and one of a male carrier of a premutation. The male with the full mutation (TH) had a typical presentation of fragile X syndrome, including mild mental retardation. He had a methylated full mutation of two predominant sizes in all 12 tissues analyzed, including three regions of the brain. The male carrier of a premutation (GC) was clinically unaffected, and the mutation was the same size in all 14 tissues examined including seven regions of the brain. Therefore, both cases demonstrated lack of inter-tissue heterogeneity, suggesting strong somatic stability after the period of expansion to the observed mutation size(s). Also, both cases showed consistency between clinical phenotype and mutation characteristics in the brain.     

FMR1 premutation carrier frequency in patients undergoing routine population-based carrier screening: Insights into the prevalence of fragile X syndrome,fragile X-associated tremor/ataxia syndrome,and fragile X-associated primary ovarian insufficiency in the United States

PurposeFragile X syndrome is caused by expansion and methylation of a CGG tract in the 5′ untranslated region of the FMR1 gene. The estimated frequency of expanded alleles (≥55 repeats) in the United States is 1:257–1:382, but these estimates were not calculated from unbiased populations. We sought to determine the frequency of fragile X syndrome premutation (55–200 repeats) and full mutation (>200 repeats) alleles in nonselected, unbiased populations undergoing routine carrier screening for other diseases.MethodsA previously validated laboratory-developed test using triplet-primed polymerase chain reaction was used to detect premutation and full mutation alleles in an unselected series of 11,759 consecutive cystic fibrosis carrier screening samples and 2011 samples submitted for screening for genetic diseases prevalent among the Ashkenazi Jewish population.ResultsPremutations were identified in 48 cystic fibrosis screening samples (1:245) and 15 samples (1:134) from the Ashkenazi Jewish population. Adjusted for the ethnic mix of the US population and self-reported ethnicity in our screening population, the estimated female premutation carrier frequency in the United States was 1:178. The calculated frequency of full mutation alleles was 1:3335 overall, and the calculated premutation frequency in males was 1:400. Based on frequency of larger, ≥70 repeat alleles, and reported penetrance, the calculated fragile X-associated tremor and ataxia syndrome, and fragile X-associated primary ovarian insufficiency frequencies is 1:4848 and 1:3560, respectively.ConclusionOur calculated fragile X syndrome carrier rate is higher than previous estimates for the US population and warrants further consideration of population-based carrier screening.     

Development of a novel, accurate, automated, rapid, high-throughput technique suitable for population-based carrier screening for Fragile X syndrome.

PURPOSE: To develop a high-throughput, automated, accurate method suitable for population-based carrier detection of fragile X syndrome. METHODS: We developed a new method called capillary Southern analysis that allows automated high-throughput screening for expanded fragile X mental retardation 1 (FMR1) alleles. Initially samples are analyzed by a multiplex polymerase chain reaction that contains an internal control to establish gender. All females heterozygous for two normal alleles are reported as normal without further analysis. All females homozygous at the FMR1 locus (24% of all analysis) are then analyzed by capillary Southern analysis. Theoretically this method can detect expansion as high as 2000 CGG repeats, although in our series the largest nonmosaic FMR1 present was 950 CGG repeats. After assay development, we performed capillary Southern analysis on 995 female and 557 male samples submitted for fragile X syndrome testing by polymerase chain reaction and Southern blot. RESULTS: The polymerase chain reaction/capillary Southern analysis technique identified 100% of six female premutation carriers, seven full mutation carrier females, one premutation male, and five affected males. There was only one discrepancy between analysis by polymerase chain reaction/Southern blot and analysis by polymerase chain reaction/capillary Southern analysis. A single female sample appeared to be heterozygous for a premutation allele by polymerase chain reaction/capillary Southern analysis but was negative by Southern blot. It is possible this patient is a mosaic for the premutation allele, but because samples were deidentified, we were unable to determine whether this was a true false positive. CONCLUSION: We have developed an automated, high-throughput technique capable of detecting carriers of fragile X syndrome with 100% sensitivity and at least 99.5% specificity. This should allow population-based carrier detection for the most commonly inherited form of mental retardation.     

Fragile X AGG analysis provides new risk predictions for 45–69 repeat alleles

We investigated the effect of AGG interruptions on fragile X repeat instability upon transmission of fragile X intermediate and small premutation alleles with 45–69 CGG repeats. The FMR1 repeat structure was determined for 375 mothers, 48 fathers, and 538 offspring (457 maternal and 81 paternal transmissions) using a novel PCR assay to determine repeat length and AGG interruptions. The number of AGG interruptions and the length of uninterrupted CGG repeats at the 3′ end were correlated with repeat instability on transmission. Maternal alleles with no AGGs conferred the greatest risk for unstable transmissions. All nine full mutation expansions were inherited from maternal alleles with no AGGs. Furthermore, the magnitude of repeat expansion was larger for alleles lacking AGG interruptions. Transmissions from paternal alleles with no AGGs also exhibited greater instability than those with one or more AGGs. Our results demonstrate that characterization of the AGG structure within the FMR1 repeat allows more accurate risk estimates of repeat instability and expansion to full mutations for intermediate and small premutation alleles. © 2013 Wiley Periodicals, Inc.     

Detecting AGG Interruptions in Male and Female FMR1 Premutation Carriers by Single‐Molecule Sequencing

The FMR1 gene contains an unstable CGG repeat in its 5′ untranslated region. Premutation alleles range between 55 and 200 repeat units and confer a risk for developing fragile X‐associated tremor/ataxia syndrome or fragile X‐associated primary ovarian insufficiency. Furthermore, the premutation allele often expands to a full mutation during female germline transmission giving rise to the fragile X syndrome. The risk for a premutation to expand depends mainly on the number of CGG units and the presence of AGG interruptions in the CGG repeat. Unfortunately, the detection of AGG interruptions is hampered by technical difficulties. Here, we demonstrate that single‐molecule sequencing enables the determination of not only the repeat size, but also the complete repeat sequence including AGG interruptions in male and female alleles with repeats ranging from 45 to 100 CGG units. We envision this method will facilitate research and diagnostic analysis of the FMR1 repeat expansion.     

Analysis of CGG variation through 642 meioses in Fragile X families

Fragile X syndrome is the commonest familial form of inherited mental retardation. The molecular defect is an expansion of the CGG trinucleotide repeats in the 5' untranslated region of the FMR1 gene that is inherited in an unstable fashion in fragile X families. In an attempt to provide more information about the CGG tract intergenerational variation, we have evaluated 642 transmissions in 175 Fragile X families. PCR and Southern blot (StB12.3) was used to analyse the CGG number. Among premutated alleles, 90.2% showed expansion, two-thirds to a full mutation while the rest remained in the premutation range, 5.5% of alleles did not vary and finally 4.3% of them reduced in size. Premutated females showed an increased risk of expansion to the full mutation depending on the CGG tract. The estimated risk for 80 triplets is more than seven times that of a woman carrying 59 CGG, the risk being 100% for alleles of >100 repeats. Fifty-nine repeats was the smallest allele that expanded to full mutation. Contractions were detected more frequently in males than in females, being statistically significant. This study contributes to the literature by increasing the data available regarding transmissions in Fragile X families and it allows us to perform more precise genetic counselling for women with the CGG repeat in the premutation range.     

Heritable unstable DNA sequences and hypermethylation associated with fragile X syndrome in Japanese families

Fragile X syndrome, associated with the fragile site at Xq27.3 (FRAXA), is the most common form of familial mental retardation. The fragile X mutation has recently been characterized as a heritable unstable DNA sequence, p(CCG)n/p(CGG)n, in the FRAXA locus. In the present study, a correlation between fragile X-genotypes in the FRAXA locus and hypermethylation of an adjacent CpG island was examined in four Japanese families with fragile X syndrome. We show here that the heritable unstable DNA sequences in the fragile X chromosome usually increase in size when transmitted by female carriers, and that the degree of methylation in the CpG island correlated with the increased sizes of the unstable DNA sequences. When a hypermethylated full mutation was transmitted by a male to his daughters, both the size of the unstable DNA sequence and the degree of the methylation reduced to the premutation range. Our observations suggest that female meiosis has a greater potential for amplifying unstable DNA sequences and that amplified DNA sequences can be transmitted through germ cells, while male germ cells seem not to be able to tolerate highly amplified unstable DNA sequences.     

A fragile X mosaic male with a cryptic full mutation detected in epithelium but not in blood

Individuals with developmental delay who are found to have only fragile X premutations present an interpretive dilemma. The presence of the premutation could be an unrelated coincidence, or it could be a sign of mosaicism involving a full mutation in other tissues. To investigate three cases of this type, buccal epithelium was collected on cytology brushes for Southern blot analysis. In one notable case, the blood specimen of a boy with developmental delay was found to have a premutation of 0.1 extra kb, which was shown by PCR to be an allele of 60 ± 3 repeats. There was no trace of a full mutation. Mosaicism was investigated as an explanation for his developmental delay, although the condition was confounded by prematurity and other factors. The cheek epithelium DNA was found to contain the premutation, plus a methylated full mutation with expansions of 0.9 and 1.5 extra kb. The three populations were nearly equal in frequency but the 1.5 kb expansion was the most prominent. Regardless of whether this patient has clinical signs of fragile X syndrome, he illustrates that there can be gross tissue-specific differences in molecular subpopulations in mosaic individuals. Because brain and epithelium are more closely related embryonically than are brain and blood, cryptic full mutations in affected individuals may be evident in epithelial cells while being absent or difficult to detect in blood. This phenomenon may explain some atypical cases of the fragile X phenotype associated with premutations or near-normal DNA findings. © 1996 Wiley-Liss, Inc.     

46,XY/47,XYY male with the fragile X syndrome: Cytogenetic and molecular studies

We report the first case of a 46,XY/47,XYY mosaic male with fragile X[Fra(X)] expression in both cell lines. Cytogenetic analysis, DNA linkage analysis, and direct detection of the pre- and full mutation for the affected individual and his at-risk female relatives were performed. Southern analysis of PstI-digested DNA with probe pX6 clearly distinguished the normal genotype, the premutation, and the full mutation in various individuals in the patient's family. Fra(X) carriers who had normal cytogenetic results were clearly identified by direct mutation analysis. © 1993 Wiley-Liss, Inc.     

Molecular analysis of 53 fragile X families with the probe StB12.3

Fifty-three pedigrees with the fragile X syndrome have been studied for amplification of the CGG repeat sequence adjacent to the CpG island in the FMR1 gene. Probe StB12.3 allowed direct detection of affected males, carrier females, normal transmitting males, as well as prenatal diagnosis. Comparison of our molecular data with our previous linkage data from 38 families indicates the effectiveness of direct DNA analysis. A total of 325 individuals were studied and no new mutation was found. All daughters of males with a premutation had a premutation. When the mother had a full mutation no children had a premutation. In premutated mothers, the size of the premutation seems to be a determining factor for the transition to the full mutation. All affected males had a full mutation or mosaicism and only 42% of the females with a full mutation were mentally impaired. Analysis of large families over 3 generations illustrated clearly the Sherman paradox. Furthermore, the analysis of these families is in reasonable agreement with the multiallelic model of Morton and Macpherson [Proc Natl Acad Sci USA 89:4215–4217, 1992]. Mosaic cases in the offspring of the mothers with a full mutation suggest a maternal germinal mosaicism. Then an abnormal methylation and a somatic heterogeneity established in very early steps of embryogenesis could explain these Cases. © 1994 Wiley-Liss, Inc.     

A fragile X family with high penetrance in females: risk heterogeneity?

A fragile X family is described which shows two interesting features. In a sibship of seven, the two males and four of the five females are affected with mental retardation. Since the only normal daughter is not a carrier, the penetrance of the fragile X mutation in carrier daughters is 100%. Nevertheless, the penetrance of this syndrome in affected daughters of normal mothers has been estimated at a third. Also, DNA typing analysis of flanking RFLP markers revealed a higher than expected number of crossing-overs. We also include the molecular study of the mutation in the (CGG)n repeat of the FMR-1 gene.