Premutation and intermediate-size FMR1 alleles in 10572 males from the general population: loss of an AGG interruption is a late event in the generation of fragile X syndrome alleles

We previously reported a 1:259 prevalence of female carriers of FMR1 premutation-size alleles (greater than 54 triplet repeats) in the general population. We now have screened 10 572 independent males from the same population for similar alleles using high-throughput Southern blotting. We identified 13 male carriers of an allele with more than 54 repeats. This corresponds to a prevalence of 1:813 males (95% confidence interval 1:527 to 1:1781). Haplotype analysis of four markers flanking the triplet array revealed that the prevalence of the major fragile X mutation-associated haplotype was increased among FMR1 alleles of 40-54 repeats. Although sequencing of highly unstable premutation alleles from fragile X families revealed only pure CGG tracts, this was not the case for alleles of similar size that were identified in males from the general population. Forty-eight out of forty-nine alleles of 40 or more triplets had one or two AGG interruptions. This observation, combined with the observation of the enrichment of major fragile X syndrome haplotypes in all alleles of this size, is evidence that the loss of an AGG interruption in the triplet repeat array is not necessary for expansion of normal alleles of 29-30 triplets to intermediate size. The loss of AGG interruptions thus appears to be a late event that leads to greatly increased instability and may be related to the haplotype background of specific FMR1 alleles.     

Haplotype and interspersion analysis of the FMR1 CGG repeat identifies two different mutational pathways for the origin of the fragile X syndrome

To understand the origins of the fragile X syndrome and factors predisposing alleles to instability and hyperexpansion, we have compared the haplotype (using markers FRAXAC1, FRAXAC2, and DXS548) and AGG interspersion patterns of the FMR1 CGG repeat for 214 normal and 16 premutation chromosomes. Association testing between interspersion pattern and haplotype reveals a highly significant (P < 0.002) non- random distribution, indicating that all three markers are useful in phylogenetic reconstruction of mutational change. Parsimony analysis of the FMR1 CGG repeat substructure predicts that loss of AGG interruptions has occurred independently on many haplotypes associated with the fragile X syndrome, partially explaining the haplotype diversity of this disease. Among haplotypes found in linkage disequilibrium with the fragile X mutation, two different modes of mutation and predisposition to instability have been identified. One pathway has involved the frequent and recurrent loss of AGG interruptions from rare asymmetrical ancestral array structures. Intergenerational transmission studies suggest that these predisposed chromosomes progress relatively rapidly to the disease state. In contrast, the second mutational pathway involves a single haplotype which has maintained two AGG interruptions. Parsimony analysis of CGG repeat substructure within this haplotype suggests that larger alleles have been generated by gradual increments of CGG repeats distal to the most 3' interruption. Pedigree analysis of the intergenerational stability of alleles of this haplotype confirms a gradual progression toward instability thresholds. As a result, a large reservoir of chromosomes carrying large repeats on this haplotype exists. These chromosomes are predisposed to disease. The present data support a model in which there are at least two different mutational pathways predisposing alleles to instability and hyperexpansion associated with the fragile X syndrome.      

A new insight into fragile X syndrome among Basque population

The expansion of a trinucleotide repeat [CGG]n located in the FMR1 X-linked gene is the main cause of fragile X syndrome, the most common form of inherited mental retardation. We have analyzed the factors known, to date, to influence the instability of the repeat in 158 normal X chromosomes from the Spanish Basque population. These factors included length of the repeat, AGG interspersion pattern, length of uninterrupted CGG and DXS548-FRAXAC1 markers associated haplotype. Previous investigations on Basques showed an absence of this disorder among mentally retarded individuals that was likely due to a low prevalence of large CGG alleles and the presence of AGG interruptions on them. The present report suggests that, although the frequency of large alleles is low and they do maintain AGG interruptions, different mutational pathways that might lead to fragile X syndrome could be occurring among Basques. These pathways mainly include alleles with internal sequences 9 + 9 + n and 9 + 12 + 9 that show fragile X associated haplotypes. Besides, the lack of the most proximal AGG interruption, proposed recently as a novel factor involved in CGG repeat instability, was highly identified among alleles with long pure CGG tracts, which showed an internal sequence n + 9. The data suggest that, despite the lower incidence of large alleles, the prevalence of potentially unstable alleles among Basques is similar to that of other Caucasian populations and that these alleles could become fragile X chromosomes.     

Haplotype and AGG-interspersion analysis of FMR1 (CGG)(n) alleles in the Danish population: implications for multiple mutational pathways towards fragile X alleles

The AGG interspersion pattern and flanking microsatellite markers and their association with instability of the FMR1 (CGG)(n) repeat, involved in the fragile X syndrome, were analyzed in DNA from filter-paper blood spots randomly collected from the Danish newborn population. Comparison of DXS548-FRAXAC1 haplotype frequencies in the normal population and among fragile X patients suggested strong linkage disequilibrium between normal alleles and haplotype 7-3 and between fragile X alleles and haplotype 2-1 and 6-4. Comparison of the AGG interspersion pattern in 143 alleles, ranging in size from 34-62 CGG, and their associated haplotypes indicates the existence of at least three mutational pathways from normal alleles toward fragile X alleles in the Danish population. Two subgroups of normal alleles, with internal sequences of (CGG)(10)AGG(CGG)(19) and (CGG)(9)AGG(CGG)(12) AGG(CGG)(9), possibly predisposed for expansion, were identified in the data set. When alleles larger than 34 CGG were investigated, comparing the length of 3' uninterrupted CGG triplets (uCGG), we found that alleles associated with haplotype 2-1 and 6-4 contain significantly longer stretches of uCGG than alleles associated with haplotype 7-3. Thus, the data support that (CGG)(n) instability is correlated to the length of uCGG.     

Fragile X “gray zone” alleles: AGG patterns,expansion risks,and associated haplotypes

The risk for fragile X “gray-zone” alleles to expand appears to depend on the absence of stabilizing AGGs, which interrupt the CGG repeat region. To characterize such alleles better, we analyzed a series of 101 chromosomes with triplet repeat lengths ranging from 35 to 59 for variations in their AGG interspersion patterns. Among these, 11.9% had 3 AGGs, 59.3% had 2, 24.8% had 1, and 4.0% had 0. An inverse relationship between FMR1 repeat length and the number of interrupting AGGs was observed. Within the range of 35–44 repeats, 98.7% of alleles were found to have a pure CGG repeat length (P_CGG) of less than 33. However, among alleles with 45–59 repeats, 50% were found to have 0 or 1 AGG and a P_CGG of more than 33. Thus, gray-zone alleles with 45–59 repeats frequently have a long stretch of pure CGGs and thus are more likely to be unstably inherited than alleles with 35–44 repeats. We found length associations of P_CGG with 2 flanking microsatellites, DXS548 and FRAXAC1: a P_CGG ≤20 was strongly associated with haplotype 20−19, whereas a P_CGG > 20 was more strongly associated with the haplotype 25−21. This result could reflect a founder effect or a generalized instability of CGGs and microsatellites. © 1996 Wiley-Liss, Inc.     

Analysis of FMR1 (CGG)(n) alleles and DXS548-FRAXAC1 haplotypes in three European circumpolar populations: traces of genetic relationship with Asia

Fragile X syndrome, the most common form of inherited mental retardation, is caused by expansion of a (CGG)(n) repeat located in the FMR1 gene. The molecular factors involved in the mutation process from stable (CGG)(n) alleles towards unstable alleles are largely unknown, although family transmission studies and population studies have suggested that loss of AGG interruptions in the (CGG)(n) repeat is essential. We have analysed the AGG interspersion pattern of the FMR1 (CGG)(n) repeat and the haplotype distribution of closely located microsatellite markers DXS548 and FRAXAC1, in three circumarctic populations: Norwegians, Nenets and Saami. The data confirm the conservation, reported in all human populations studied so far, of an AGG interruption for each 9-10 CGG and support the stabilising effect of AGG interruptions. The data also indicate the existence of chromosomes of Asian origin in the Saami and Nenets population, thereby confirming a genetic relationship between Northern Europe and Asia. DXS548-FRAXAC1 haplotype frequencies were compared between 24 Norwegian fragile X males and 119 normal males. Significant linkage disequilibrium were found between the fragile X mutation and haplotype 6-4 and between normal (CGG)(n) alleles and haplotype 7-3.     

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.     

FMR1 CGG Repeat Patterns and Flanking Haplotypes in Three Asian Populations and Their Relationship With Repeat Instability

Hyper-expansion of a CGG repeat in the 5' untranslated region of the FMR1 gene followed by methylation and silencing is the predominant cause of Fragile X syndrome, the most common inherited mental retardation disorder. Most detailed studies of the FMR1 gene have focused on Caucasian populations and patients. We performed a detailed haplotype and linkage disequilibrium analysis of the FMR1 gene in a total of 454 unselected normal X chromosomes from three Asian populations, Chinese, Malay and Indian. Compared to Caucasians and African Americans, the diversity of normal FMR1 CGG repeat lengths, patterns and flanking haplotypes were lower in Asians. Strong linkage disequilibrium was observed between the CGG repeat and flanking FMR1 markers in all three Asian populations, with strong association between specific CGG repeat alleles and flanking marker alleles observed only in the Chinese and Malays. A test for randomness of distribution between FRAXA CGG repeat patterns and flanking FMR1 marker haplotypes also revealed a highly significant non-random distribution between CGG repeat patterns and flanking haplotypes in all three ethnic groups (P < 0.001). Extending previous findings in Caucasians and African Americans we present a novel statistical approach, using data from unselected population samples alone, to show an association between absence of at least one AGG interruption in any position (5', 3', or middle) and increased CGG repeat instability.     

Re-examination of factors associated with expansion of CGG repeats using a single nucleotide polymorphism in FMR1

In at least 98% of fragile X syndrome cases, the disease results from expansion of the CGG repeat in the 5' end of FMR1. The use of microsatellite markers in the FMR1 region has revealed a disparity of risk between haplotypes for CGG repeat expansion. Although instability appears to depend on both the haplotype and the AGG interspersion pattern of the repeat, these factors alone do not completely describe the molecular basis for the linkage disequilibrium between normal and fragile X chromosomes, in part due to instability of the marker loci themselves. In an effort to better understand the mechanism of dynamic mutagenesis, we have searched for and discovered a single nucleotide polymorphism in intron 1 of FMR1 and characterized this marker, called ATL1, in 564 normal and 152 fragile X chromosomes. The G allele of this marker is found in 40% of normal chromosomes, in contrast to 83% of fragile X chromosomes. Not only is the G allele exclusively linked to haplotypes over-represented in fragile X syndrome, but G allele chromosomes also appear to transition to instability at a higher rate on haplotypes negatively associated with risk of expansion. The two alleles of ATL1 also reveal a highly significant linkage disequilibrium between unstable chromosomes and the 5' end of the CGG repeat itself, specifically the position of the first AGG interruption. The data expand the number of haplotypes associated with FMR1 and specifically allow discrimination, by ATL1 alleles, of single haplotypes with differing predispositions to expansion. Such haplotypes should prove useful in further defining the mechanism of dynamic mutagenesis.      

Haplotype and AGG‐interspersion analysis of FMR1 (CGG)n alleles in the Danish population: Implications for multiple mutational pathways towards fragile X alleles

The AGG interspersion pattern and flanking microsatellite markers and their association with instability of the FMR1 (CGG)_n repeat, involved in the fragile X syndrome, were analyzed in DNA from filter‐paper blood spots randomly collected from the Danish newborn population. Comparison of DXS548‐FRAXAC1 haplotype frequencies in the normal population and among fragile X patients suggested strong linkage disequilibrium between normal alleles and haplotype 7–3 and between fragile X alleles and haplotype 2–1 and 6–4. Comparison of the AGG interspersion pattern in 143 alleles, ranging in size from 34–62 CGG, and their associated haplotypes indicates the existence of at least three mutational pathways from normal alleles toward fragile X alleles in the Danish population. Two subgroups of normal alleles, with internal sequences of (CGG)₁₀AGG(CGG)₁₉ and (CGG)₉AGG(CGG)₁₂ AGG(CGG)₉, possibly predisposed for expansion, were identified in the data set. When alleles larger than 34 CGG were investigated, comparing the length of 3' uninterrupted CGG triplets (uCGG), we found that alleles associated with haplotype 2–1 and 6–4 contain significantly longer stretches of uCGG than alleles associated with haplotype 7–3. Thus, the data support that (CGG)_n instability is correlated to the length of uCGG. Am. J. Med. Genet. 93:99–106, 2000. © 2000 Wiley‐Liss, Inc.     

Nucleosomal occupancy and CGG repeat expansion: a comparative analysis of triplet repeat region from mouse and human fragile X mental retardation gene 1

The expansion of CGG repeats in the 5′-untranslated region (5′UTR) of FMR1 gene is the molecular basis of fragile X syndrome in most of the patients. The nature of the flanking sequences in addition to the length and interruption pattern of repeats is predicted to influence CGG repeat instability in the FMR1 gene. We investigated nucleosome occupancy as a contributor to CGG repeat instability in a transgenic mouse model containing unstable (CGG)_26, from human FMR1 cloned downstream of nucleosome-excluding sequence. We observe that the transgene has an open chromatin structure compared to the stable endogenous mouse Fmr1 within the same nucleus. CGG repeats in mouse Fmr1 are flanked by nucleosomes unlike the repeats in the transgene in all the tissues examined. Further in vitro chromatin reconstitution experiments show that DNA fragment without the SV40ori/EPR (nucleosome-excluding sequence) forms more stable chromatin than the one containing it, despite having the same number of CGG repeats. The correlation between nucleosomal organisation of the FMR1 gene and CGG repeat instability was supported by significantly lower frequency of repeat expansion in mice containing an identical transgene without the SV40ori/EPR. Our studies demonstrate that flanking DNA sequences can influence repeat instability through modulation of nucleosome occupancy in the region.     

Fragile X syndrome: the FMR1 CGG repeat distribution among world populations

Fragile X syndrome (FXS) is characterized by moderate to severe intellectual disability, which is accompanied by macroorchidism and distinct facial morphology. FXS is caused by the expansion of the CGG trinucleotide repeat in the 5' untranslated region of the fragile X mental retardation 1 (FMR1) gene. The syndrome has been studied in ethnically diverse populations around the world and has been extensively characterized in several populations. Similar to other trinucleotide expansion disorders, the gene-specific instability of FMR1 is not accompanied by genomic instability. Currently we do not have a comprehensive understanding of the molecular underpinnings of gene-specific instability associated with tandem repeats. Molecular evidence from in vitro experiments and animal models supports several pathways for gene-specific trinucleotide repeat expansion. However, whether the mechanisms reported from other systems contribute to trinucleotide repeat expansion in humans is not clear. To understand how repeat instability in humans could occur, the CGG repeat expansion is explored through molecular analysis and population studies which characterized CGG repeat alleles of FMR1. Finally, the review discusses the relevance of these studies in understanding the mechanism of trinucleotide repeat expansion in FXS.     

Single nucleotide polymorphism and FMR1 CGG repeat instability in two Basque valleys

Fragile X Syndrome (FXS, MIM 309550) is mainly due to the expansion of a CGG trinucleotide repeat sequence, found in the 5' untranslated region of the FMR1 gene. Some studies suggest that stable markers, such as single nucleotide polymorphisms (SNPs) and the study of populations with genetic identity, could provide a distinct advance to investigate the origin of CGG repeat instability. In this study, seven SNPs (WEX28 rs17312728:G>T, WEX70 rs45631657:C>T, WEX1 rs10521868:A>C, ATL1 rs4949:A>G, FMRb rs25707:A>G, WEX17 rs12010481:C>T and WEX10 ss71651741:C>T) have been analyzed in two Basque valleys (Markina and Arratia). We examined the association between these SNPs and the CGG repeat size, the AGG interruption pattern and two microsatellite markers (FRAXAC1 and DXS548). The results suggest that in both valleys WEX28-T, WEX70-C, WEX1-C, ATL1-G, and WEX10-C are preferably associated with cis-acting sequences directly influencing instability. But comparison of the two valleys reveals also important differences with respect to: (1) frequency and structure of "susceptible" alleles and (2) association between "susceptible" alleles and STR and SNP haplotypes. These results may indicate that, in Arratia, SNP status does not identify a pool of susceptible alleles, as it does in Markina. In Arratia valley, the SNP haplotype association reveals also a potential new "protective" factor.     

The effect of FMR1 CGG repeat interruptions on mutation frequency as measured by sperm typing.

Fragile X syndrome results from the unstable expansion of a CGG repeat within the FMR1 gene. Three classes of FMR1 alleles have been identified, normal alleles with 6-60 repeats, premutations with 60-200 repeats, and full mutations with > 230 repeats. Premutations are exquisitely unstable upon transmission. Normal alleles, while generally stable upon transmission, are thought to have different intrinsic mutation frequencies, such that some normal alleles may be predisposed towards expansion while others may be more resistant to such change. One variable that may account for this difference is the occurrence of one or more AGG triplets punctuating the normal CGG repeat. The AGG interruptions lead to alleles that have equivalent overall length but different lengths of perfect repeats. To test the influence of the length of perfect repeats on stability, we examined the CGG repeat of single sorted sperm from two males, each with 39 total repeats, but distinct AGG interruption patterns. Sorted sperm of each donor showed -15% variation in repeat length, consistent with previous studies of sorted sperm at other triplet repeat loci. However, when discounting the majority variation of +/-1 repeat, the male with 29 perfect repeats showed 3% expansion changes while the donor with only 19 perfect repeats had none (< 0.9%). Moreover, > 90% of all variant sperm, including all those observed with expansions, showed expansion or contraction of the 3' end of the repeat array. These data are consistent with the hypothesis that perfect repeat tracts influence the repeat stability and that changes of the FMR1 repeat exhibit polarity.     

Sequence analysis of the fragile X trinucleotide repeat: implications for the origin of the fragile X mutation

This study addresses mechanism of instability of the FMR-1 (CGG)_n-repeat,and investigates features which may distinguish between normalstable and fragile X unstable repeats. To achieve this, we havesequenced 178 alleles to analyze patterns of AGG interruptionswithin the CGG repeat, and have typed the (CA)_n-repeat at DXS548for 204 chromosomes. Overall, our data is consistent with theidea that the length of uninterrupted CGG repeats determinesInstability. We predict that certain sequence configurations[no AGG, and (CGG)_9–11AGG(CGG)     

Molecular screening of fragile X (FRAXA) and FRAXE mental retardation syndromes in the Hellenic population of Greece and Cyprus: incidence, genetic variation, and stability.

This study presents the first large, population-based molecular investigation of the fragile X (FRAXA) and FRAXE mental retardation syndromes in the Hellenic populations of Greece and Cyprus. The aims of this population screening were to determine the prevalence of FRAXA and FRAXE syndromes among idiopathic mentally retarded (IMR) individuals, to estimate the incidence in the general population, and to investigate the molecular mechanism of instability and expansion of the FMR1-repeat. Ten FRAXA patients were identified to have either the full mutation (eight) or premutation (two) from a Hellenic population of 866 unrelated IMR individuals (611 males and 255 females, age range 3-25 years). No FRAXE patients were identified among the 611 IMR males. The incidence of FRAXA in the Hellenic population of Cyprus is estimated at 1 in 4,246 males. The repeat sites from the FMR1 and FMR2 alleles were accurately determined and showed similar distribution and frequencies with other population studies. The analysis of AGG interspersion within the FMR1-repeat in normal males revealed long, pure CGG repeats within the "gray zone" as well as variation within the 3' end showing polarity of instability. This finding supports the hypothesis that the AGG interspersion and the length of the pure repeat are major factors in determining allele stability. Analysis of FRAXAC1, DXS548, and FRAXAC2 identified particular alleles and haplotypes to have a significant association with either gray zone alleles or alleles >15 pure CGG repeats. We hypothesize that this subgroup of alleles and haplotypes are associated with long pure CGGs (>15 CGG) or 35 repeats and, having shared an evolutionary past, would have the tendency to expand.     

Trinucleotide CGG repeat in the FMR1 gene in Chinese mentally retarded patients.

The fragile X syndrome of mental retardation is related to the number of trinucleotide CGG repeats at the 5'-untranslated region of the FMR1 gene located on the X-chromosome. We have studied X-chromosomes from 649 unaffected Chinese subjects and 324 patients with mild mental retardation. All study subjects were unrelated. The CGG repeat number was analysed by electrophoresis of a polymerase chain reaction followed by gel transfer and hybridisation with a 32P-labeled (CCG)5 probe. The DNA samples having detectable CGG expansion were further analysed by Southern blot analysis with probe StB12.3 after restriction digestion by EcoR I and Eag I. For the unaffected Chinese subjects, a different distribution pattern of CGG allele size from Caucasians was observed. It was a bimodal pattern and the CGG repeat number ranged from 19 to 54. The most common CGG repeat allele was 29 compared with 30 in Caucasians. The second mode appeared at 36 repeats. There was mild statistical difference in the repeat patterns between the mentally retarded patients and unaffected subjects, although the essential features were similar. Among the mentally retarded patients, one male had an unmethylated full mutation and one female had a full mutation. The fragile X prevalence was 0.6%, which is lower than two previous studies in Chinese mentally retarded patients utilising cytogenetic analysis. Our results indicate that a large-scale screening program would be worthwhile to determine the prevalence of the fragile X syndrome in the Chinese population.     

Reduced FMRP and increased FMR1 transcription is proportionally associated with CGG repeat number in intermediate-length and premutation carriers.

The 5' untranslated CGG repeat in the fragile X mental retardation-1 (FMR1) gene is expanded in families with fragile X syndrome, with more than 200 CGGs resulting in mental retardation due to the absence of the encoded fragile X mental retardation protein (FMRP). Intermediate and premutation alleles, containing between approximately 40 and 200 repeats, express grossly normal FMRP levels and such carriers are widely believed to be non-penetrant, despite continued reports of subtle cognitive/psychosocial impairment and other phenotypes. Using a highly sensitive quantification assay, we demonstrate significantly diminished FMRP levels in carriers, negatively correlated with repeat number. Despite reduced FMRP, these carrier alleles overexpress FMR1, resulting in a positive correlation between repeat number and FMR1 message level. These biochemical deviations associated with intermediate and premutation FMR1 alleles, found in approximately 4% of the population, suggest that the phenotypic spectrum of fragile X syndrome may need to be revisited.     

Factors involved in the initial mutation of the fragile X CGG repeat as determined by sperm small pool PCR

The fragile X syndrome is one of more than a dozen genetic diseases attributed to the amplification of a trinucleotide repeat. Despite the number of these disease loci, relatively little is known about the mechanism(s) that cause a stable allele to become unstable. Population and family studies of the fragile X CGG repeat have identified a number of factors that may play a role in repeat instability including the number of AGG interruptions, purity of the 3' and 5' end of the repeat and cis-acting factors as related to haplotype background. However, studies that assess whether these factors have an impact on the rate and magnitude of change of the repeat are lacking, mainly due to the lack of an appropriate model system. Therefore, in order to dissect the factors involved in the initial mutations of the CGG repeat, small pool (SP)-PCR was performed on DNA derived from sperm and blood from seven unaffected males whose repeat sizes range from 20 to 33. Using the SP-PCR-derived data, regression analyses suggested that components of the repeat structure such as the number of interruptions and purity of the 3' end of the repeat are important determinants of germline repeat instability. In contrast, elements other than repeat structure, such as haplotype background, seemed to have an impact on somatic repeat instability. The factors identified for either cell type, however, explained only a small portion of the variance, suggesting that other factors may be involved in this process.     

Distribution of (CGG)n and FMR-1 associated microsatellite alleles in a normal Chilean population

We report on the allele distribution in a normal Chilean population at 2 microsatellite loci neighbouring the FRAXA locus and at the CGG repeat in the 5′ end of the FMR-1 gene, which causes the fragile X syndrome. The most common CGG repeat allele was 30 (41.7%), with 29 being second most common (30.2%). This distribution was similar from that seen in Caucasians but different from that observed in Chinese controls, where the most common allele was 29 repeats. Four alleles of FRAXAC1 and 6 of DXS548 were observed in the Chilean sample. A striking linkage disequilibrium of FMR-1 alleles with FRAXAC1 alleles was observed. In 90% of the 30 CGG repeat alleles only 31% of the 29 CGG repeat alleles had the FRAXAC1 154 bp allele. This result is in agreement with the suggestion that slippage between CGG repeat alleles 29 and 30 and between 152 and 154 FRAXAC1 alleles is very rare. This study suggests a founder chromosome effect in the Chilean population. Am. J. Med. Genet. 75:277–282, 1998. © 1998 Wiley-Liss, Inc.