Replication status of the fragile X chromosome,fra(X)(q27), in three heterozygous females

Summary Investigation of lymphocyte cultures from three females heterozygous for fra(X)(q27) shows widely differing proportions of early and late replicating X chromosomes having the fragile site, and suggests that the replication status of the fragile X may be related to the mental capacity of the patient. The study has utilised a sequential staining technique to reduce ascertainment bias, and evidence is presented to suggest that the expression of the fragile site is independent of the differential incorporation of BUdR into the early and late replicating X chromosomes.     

Transmission of fragile (X)(q27) from normal male(s)

Summary A large family with strong evidence for transmission of fragile X chromosome by normal male(s) is reported.     

The X chromosome and fragile X mental retardation

Fragile X syndrome represents the most common inherited cause of mental retardation. It is caused by a stretch of CGG repeats within the fragile X gene, which increases in length as it is transmitted from generation to generation. Once the repeat exceeds a threshold length, no protein is produced, resulting in the fragile X phenotype. Both X chromosome inactivation and inactivation of the FMR1 gene are the result of methylation. X inactivation occurs earlier than inactivation of the FMR1 gene. The instability to a full mutation is dependent on the sex of the transmitting parent and occurs only from mother to child. For most X-chromosomal diseases, female carriers do not express the phenotype. A clear exception is fragile X syndrome. It is clear that more than 50% of the neurons have to express the protein to ensure a normal phenotype in females. This means that a normal phenotype in female carriers of a full mutation is accompanied by a distortion of the normal distribution of X inactivation.     

Expression of the fragile (X) chromosome in an interspecific somatic cell hybrid

Interspecific somatic cell hybrids were constructed between a Chinese hamster lung cell line deficient in hypoxanthine phosphoribosyltransferase and two lymphoblastoid cultures (GM 4025 and GM 3200) from unrelated males affected with the fragile (X) syndrome. Thirteen independent colonies survived selection in hypoxanthine-azaserine, while only one colony survived selection in hypoxanthine-aminopterin-thymidine. One hybrid formed from GM 4025 was found to contain a human X chromosome as the only detectable human chromosome in the majority of cells analyzed. Induction of fragile (X) expression in this hybrid at frequencies up to 20% was achieved by treatments with 5-fluoro-2'-deoxyuridine (5 X 10(-8) M or 1 X 10(-7) M) or methotrexate (5 X 10(-6) or 1 X 10(-5) for 12 h. Use of the somatic cell hybrid system may allow study of the fragile (X) from different patients on a homogeneous xenogeneic background and may provide a better system for characterization of the fragile (X) at the biochemical and molecular level.     

Segregation analysis of autosomal fragile sites in three families with the fragile X chromosome.

Fragile sites on chromosomes 9, at 9p21, 10, at 10q25 and 12, at 12q24, were found in the lymphocytes of some members of three families during the study for detection of a fragile X chromosome. The sites were found to be heritable and folato-sensitive. The genetic implications of these results are discussed.     

Unusual X chromosome inactivation in a mentally retarded girl with an interstitial deletion Xq27: implications for the fragile X syndrome

Summary A de novo interstitial deletion (X)(q27.1q27.3), between the loci DXS 105 and F8, has been found in a mentally retarded female. The deleted X chromosome is preferentially early replicating in fibroblasts, B cells and T cells, suggesting that the missing region plays a role in inactivation of the X chromosome. None of the available DNA probes except DXS 98 maps to the deleted region of about 10000kb. The locus FRAXA is either included in the deletion, or located close to the distal break point.     

Localization of the fragile X chromosome break points in Holstein-Friesian cattle (Bos taurus)

Chromosome fragility is generally believed to affect cattle reproductive performance. Lymphocytes were cultured and the long arm of the X-chromosome was measured in 19 bovines that had been presented as repeat breeders, freemartin cotwins, or as having had anestrus or abortions. The positions of the break points on the X-chromosome were estimated by a measuring compass, starting at the centromere. Relative measurements were calculated from the ratio of break point distance from the centromere to the total Xq length. In our study the break points were found to be mainly in the middle of the long arm (X = 0.52; sigma=0.046). Giemsa banding showed that the break points were located in a large negative G-band observed in region 3 of the long arm. The relationship of these findings to animal reproductive problems is discussed.     

Molecular analysis of a ring chromosome X in a family with fragile X syndrome

The phenotypically normal sister of a patient affected by fragile X syndrome was referred for genetic counselling and was found to carry a mosaic karyotype 46,X,r(X)/45,X. Because the probability of the simultaneous chance occurrence of fragile X syndrome and a ring chromosome X in the same family is very low, we postulated that the breakpoint of the ring chromosome X originated in the cytogenetic break in Xq27.3 responsible for fragile X syndrome. In order to determine the relative positions of the breakpoint on the ring chromosome X and the (CGG)n unstable sequence responsible for the fragile X mutation, we used molecular markers to analyse the telomeric regions of chromosome X in this family. The results showed that the ring chromosome X was the maternal fragile X chromosome and that the telomeric deletion on the long arm encompassed the (CGG)n sequence. This suggests that the cytogenetic break in Xq27.3 is distinct from the unstable (CGG)n sequence, or that the break followed by the end-to-end fusion creating the ring chromosome was not completely conservative. Analysis of DNA markers on the short arm of chromosome X evidenced a deletion of a large part of the pseudoautosomal region, allowing us to position the genes involved in stature and in some syndromes associated with telomeric deletions of Xp on the proximal side of the pseudoautosomal region.     

A heritable fragile 12q24.13 segregating in a family with the fragile X chromosome

Summary A fragile site on chromosome 12, at 12q24.13, was found in the lymphocytes of two members of a family during the study for detection of a fragile X chromosome. The site was found to be heritable and folate-sensitive, and it fulfills all four criteria for a fragile site. It thus can now be confirmed as the heritable fragile site FRA12C.     

Incidence of fragile X in 5,000 consecutive newborn males

Fragile X syndrome (FXS) is the commonest cause of inherited mental retardation in males. Even though this affirmation is repeated in virtually all papers referring to FXS, the precise frequency of this syndrome in the general population is unknown. We present a general population screening analyzing an anonymous series of 5,000 consecutive newborn males from the neonatal screening program of the population of Catalonia in Spain. The aim of the study is to determine the incidence of FXS via a simple and economical methodology based on the nonamplification of the fragment containing the CGG repeats of the FRAXA locus in the samples carrying alleles over 52 repeats. From the initial 5,000 samples, 4,920 were in the normal range, 15 gave rise to bands with more than 52 repeats (11 corresponded to intermediate alleles and four premutated alleles). After further studies, two samples were considered to be carriers of full mutations. According to these results, the incidence of FXS affected newborn males is 1 in 2,466, and 1 in 1,233 males is a carrier of the premutation. We can deduce that 1 in 8,333 is an affected female with clinical manifestations and 1 in 411 will be a premutation carrier woman. Upon reviewing the literature, there seems to be variability in the frequencies found by the different groups. Therefore, given that our study is limited to the Catalan population in Spain, these results should be taken as valid for the Catalan region and should only be extrapolated to other populations with caution.     

Spontaneous and induced chromosome instability in patients with fragile X syndrome

Spontaneous and degranol- and dimatiph-induced chromosomal instability in the lymphocyte culture of patients with fra-X syndrome was investigated. The cultures contained TC 199 and 5% FC serum. It was found that the frequency of spontaneous chromosomal aberrations (CA) was 7.3% in cells from patients with fra(X), 3.9% in patients with MR of unknown origin, and 1.3% in normal individuals. Spontaneous break-points in the patients with fra(X) were localized in 1p, 2q, 3p, 6q, 7q, 16 q more often than in normal individuals. No significant difference was found in SCEs. The cells of patients with fra(X) were not sensitive to the induction of CA by degranol. It was found that chromosomal telomeric changes (CTC) were mutagen-independent, remaining at the spontaneous level: in the patients with fra(X) CTC were 10.5% (9.5% fra-Xq27, and 1% autosomal telomeric changes); in normal individuals CTC were 0.1%.     

The fragile X chromosome (GCC) repeat folds into a DNA tetraplex at neutral pH

UV absorption and CD spectroscopy, along with polyacrylamide gel electrophoresis, were used to study conformational properties of DNA fragments containing the trinucleotide repeat (GCC)_n (n = 4, 8 or 16), whose expansion is correlated with the fragile X chromosome syndrome. We have found that the conformational spectrum of the (GCC)_n strand is wider than has been shown so far. (GCC)_n strands adopt the hairpin described in the literature under a wide range of salt concentrations, but only at alkaline (>7.5) pH values. However, at neutral and slightly acid pH (GCC)₄ and (GCC)₈ strands homodimerize. Our data suggest that the homodimer is a bimolecular tetraplex formed by two parallel-oriented hairpins held together by hemi-protonated intermolecular C·C⁺ pairs. The (GCC)₁₆ strand forms the same tetraplex intramolecularly. We further show that below pH 5 (GCC)_n strands generate intercalated cytosine tetraplexes, whose molecularity depends on DNA strand length. They are tetramolecular with (GCC)₄, bimolecular with (GCC)₈ and monomolecular with (GCC)₁₆. i-Tetraplex formation is a complex and slow process. The neutral tetraplex, on the other hand, arises with fast kinetics under physiological conditions. Thus it is a conformational alternative of the (GCC)_n strand duplex with a complementary (GGC)_n strand.     

Establishment of FXS-A9 panel with a single human X chromosome from fragile X syndrome-associated individual

Fragile X syndrome (FXS) is the most common inheritable form of intellectual disability. FMR1, the gene responsible for FXS, is located on human chromosome Xq27.3 and contains a stretch of CGG trinucleotide repeats in its 5′ untranslated region. FXS is caused by CGG repeats that expand beyond 200, resulting in FMR1 silencing via promoter hypermethylation. The molecular mechanism underlying CGG repeat expansion, a fundamental cause of FXS, remains poorly understood, partly due to a lack of experimental systems. Accumulated evidence indicates that the large chromosomal region flanking a CGG repeat is critical for repeat dynamics. In the present study, we isolated and introduced whole human X chromosomes from healthy, FXS premutation carriers, or FXS patients who carried disease condition-associated CGG repeat lengths, into mouse A9 cells via microcell-mediated chromosome transfer. The CGG repeat length-associated methylation status and human FMR1 expression in these monochromosomal hybrid cells mimicked those in humans. Thus, this set of A9 cells containing CGG repeats from three different origins (FXS-A9 panel) may provide a valuable resource for investigating a series of genetic and epigenetic CGG repeat dynamics during FXS pathogenesis.     

Cytological evidence of defective template in the fragile X chromosome

In cells of fragile X patients, the changed X segment may appear as a poorly staining region or a gap, or as a deletion, involving one or both chromatids. To find out whether the fragile site represents ah incompletely replicated DNA sequence, as has been suggested recently, we analyzed the four chromatids of methotrexate-induced endoreduplicated fragile X chromosomes. Our main observations were: (1) a deleted chromatid was never internal to a poorly staining one; (2) an endoreduplicated X chromosome with a fragile site never included a normal chromatid. These results can be explained by assuming that DNA at the fragile site, when replicated in the presence of methotrexate, may undergo defective replication and give rise to improperly packaged chromatin, appearing as a chromatid with a poorly staining region or a gap in the following metaphase. The same DNA may fail to function as a template in the following S-phase and give rise to a chromatid with a single-stranded segment, appearing as a deleted chromatid in the following metaphase.Dedicated to the memory of Professor Menashe Marcus, teacher, colleague, arid friend     

Evaluation of the fragile X (FRAXA) syndrome with methylation-sensitive PCR

The fragile X (FRAXA) syndrome is the most common form of inherited mental retardation in males. Its peculiar pattern of inheritance results from the parent of origin-specific expansion of a CGG-repeat within the FMR1 gene on the X chromosome. In patients, gene function is abolished by hypermethylation of the promoter and the massively expanded repeat. We have developed a methylation-sensitive polymerase chain reaction (MS-PCR) strategy that combines repeat-length and methylation analysis of the CGG-repeat and the promoters of the FMR1 and XIST genes. The allelic methylation of the latter opposes that of the FMR promoter and serves as an internal control and standard for semiquantitative analyses. This system enables the delineation of 11 distinct patterns encountered in nonaffected, carrier, and affected males and females. We have evaluated our system on well-defined samples with different FMR1 mutations and have used it for the diagnostic evaluation of 253 male and 80 female probands. In the male group, we have identified five full mutations, and three gray-zone and premutation alleles with 54, 55, and 62 repeats, respectively. The female group consists of 33 normal homozygote and 41 heterozygote individuals, two of whom harbor a gray-zone allele with 47 repeats, none with a premutation, and six with a full mutation. Our MS-PCR approach allows the currently most comprehensive diagnostic evaluation of the FRAXA syndrome in a cost- and time-efficient fashion. In addition, it is a valuable tool for the analysis of clonality and skewing phenomena in females.     

Uridine enhances expression of the fragile X chromosome in human lymphocytes

Summary We have studied the effect of uridine on the expression of fragile X (fra[X]) in lymphocyte cultures established in the folate and thymidine deficient medium TC199. The results indicate that uridine enhances the expression of fra(X) and gives a higher mitotic rate. The excess of uridine during DNA synthesis might further promote the previously suggested cycle of misincorporation and removal of deoxyuridine monophosphate when the pool of deoxythymidine triphosphate is continuously depleted.     

A linkage map of sheep chromosome X (OARX) aligned to human chromosome X (HSAX)

We have constructed a genetic linkage map of the sheep X chromosome (OARX) containing 22 new gene loci from across the human X chromosome (HSAX). The female OARX linkage map has a total length of 152.6 cM with average gene spacing of 5.5 cM. Comparison with HSAX confirms one previously reported major breakpoint and inversion, and other minor rearrangements between OARX and HSAX. Comparison of the linkage map with sheep sequence data OAR 1.0 reveals a different arrangement of markers on the q arm, which may more accurately reflect the genuine arrangement of this region.