Fragile (X) expression induced by FUdR is transient and inversely related to levels of thymidylate synthase activity.

Thymidylate synthase (TS) activity was monitored in fluorodeoxyuridine (FUdR)-treated lymphoblasts from individuals carrying the fragile (X) [fra(X)] chromosome. Fra(X) expression and levels of TS activity were measured over a 72-hr period at different cell densities. TS activity was 80%-90% inhibited immediately after exposure to FUdR and remained suppressed for the first 24 hrs. Fra(X) expression was not found until 6-8 hrs after FUdR treatment, and at 24 hrs, reached a maximum expression of approximately 50%. At 48 and 72 hrs, however, increasing levels of TS activity paralleled a dramatic drop in fra(X) expression. High fra(X) expression at 48 and 72 hrs could be maintained by rechallenging cultures with increasing doses of FUdR. At low cell densities, fra(X) expression was maintained at high levels for a much longer period of time. In two lymphoblastoid cell lines from obligate carriers, which either expressed at very low levels or did not express the fra(X) in routine cultures, TS activity was also 90% inhibited but with no corresponding fra(X) expression 12 or 24 hrs after FUdR treatment. We conclude that: FUdR inhibits TS activity immediately and induces fra(X) expression 6-8 hrs later, FUdR-induced fra(X) expression and TS activity are inversely related, the FUdR effect on fra(X) expression and TS activity is time and cell-density dependent, and inhibition of TS activity is a necessary but not sufficient condition for fra(X) expression.     

Cytogenetic investigations in mentally retarded and normal males from 14 families with the fragile site at Xq28

Summary Lymphocyte cultures from 27 mentally retarded males aged 1 year to 77 years, and from 11 normal brothers from a total of 14 families with the fragile X segregating have been examined cytogenetically employing three different culture methods including methods for induction of fra(X) by FUdR (fluorodeoxyuridine) or MTX (methotrexate). All mentally retarded males showed unequivocal fra(X) expression. No statistically significant correlation between fra(X) expression and age could be demonstrated. No enhancement with FUdR was observed. Fibroblast cultures from 10 retarded males expressed fra(X) in a dose-response relationship to increasing concentrations of FUdR. None of the normal males showed fra(X). In vivo folic acid treatment of seven mentally retarded males resulted in marked reduction in fra(X) expression in lymphocyte cultures grown in medium 199. However, reinduction was achieved by FUdR or MTX, except in one case who temporarily received very high doses of folic acid.     

Expression of aphidicolin, FUdR and caffeine‐induced fragile sites in lymphocytes of healthy Turkish individuals

The expression of common fragile sites (c‐fra) and frequency of chromosomal aberrations were studied in peripheral lymphocytes of 50 healthy Turkish individuals (26 males and 24 females from 1 to 87 years of age) after induction with aphidicolin (APC), 5′‐fluorodeoxyuridine (FUdR), and caffeine. A correlation was seen between age and the frequency of chromosomal aberrations in APC and caffeine treated cultures, but there were no significant differences in the frequencies of chromosomal aberrations between males and females in any of the treatments. The mean frequency of aberrations induced by FUdR was significantly higher than that induced by APC and caffeine. A chromosome aberration is defined as a fragile site when present in 1% of the cells analyzed from each culture and in at least 50% of the individuals studied. Using these criteria, 12 c‐fra were observed in the three treatments: 1p21, 1q21, 2p11‐q11, 3p14, 4q31, 6q26, 7q22, 7q32, 8q24, 11q23, 16q23, and Xp22. Sites 3p14, 16q23, and Xp22 were the most frequently observed c‐fra, with only the frequency of Xp22 being significantly increased in females in APC treated cultures. The results of these studies are important as a base against which the effects of other clastogenic and environmental agents, as well as genetic background, can be compared. This revised version was published online in July 2006 with corrections to the Cover Date.     

Folate-sensitive fragile sites on the X-chromosome heterochromatin of the Indian mole rat, Nesokia indica

Folate-sensitive fragile sites have been demonstrated on the X chromosome of the Indian mole rat, Nesokia indica (subfamily Murinae), utilizing peripheral blood lymphocyte cultures. All normal female individuals expressed fragile sites on the constitutive heterochromatic long arm of one of their two X chromosomes (heterozygous expression); in contrast, no fragile sites were found on the single X chromosome of normal males. Preferential transmission of the maternal fragile X to the daughters is therefore suggested. Four sites have been detected so far: fra Xq1, fra Xq2, fra Xq3, and fra Xc (centromeric). It is significant that their location corresponds to the regions where constitutive heterochromatic deletions occur that result in a variety of polymorphic X chromosomes in natural populations of Nesokia. Thus there is a correlation between fragile sites, deletion sites, and karyotypic changes. In individuals that did not reproduce in the laboratory, there were more fragile sites on both X chromosomes of the females (homozygous/double heterozygous expression) and also on the X of the males (hemizygous expression). This difference in fragile site expression from the normal situation could be attributed to one or more new mutations. However, the mechanism by which fragile sites influence reproductive performance is unclear.     

The combined effects of FUdR addition and methionine depletion on the X-chromosome fragile site.

The fragile site on the X chromosome [fra(X)] associated with mental retardation is not normally seen in lymphocytes cultured in media containing folic acid or lacking methionine. The requirement for methionine has been taken to mean that amino acid metabolism or one-carbon transfer via S-adenosyl-methionine is most important in fra(X) expression. The inhibitory effect of folic acid can be overcome, as we have shown, by the addition of 5'-fluorodeoxyuridine (FUdR) to the culture medium, suggesting that depletion of dTMP available for DNA synthesis is most important in expression. We tested the combined effects of FUdR addition and methionine depletion on the fra(X). We found expression of the fra(X), indicating that methionine per se is not necessary for expression. Our work supports the suggestion that expression of the fra(X) is due to specific limitation of the dTMP pool available for DNA synthesis.     

Fragile X expression and X inactivation

Summary The major concept of fragile X pathogenesis postulates that the fragile site at band Xq27.3 [fra(X)] represents the primary defect. The expression of fra(X) is predicted to be an intrinsic property of the mutated chromosome and, hence, should not be suppressed by X inactivation in females or induced by X-linked trans-acting factors. We made fibroblast clones of a fra(X)-positive female. Monoclonality was demonstrated using the DNA methylation assay at DXS255. The mutated X chromosomes and their states of genetic activity in the different clones were also defined by molecular methods. Five clones were selected to induce expression of fra(X) by 10^-7 M FUdR; two carried an active mutated X chromosome, in the other three the mutated X chromosome was inactivated. Fra(X) was found expressed in both types of clones. The percentages of positive cells were as high as 7–10%, regardless of the genetic activity of the mutated X chromosomes. DNA replicating patterns, obtained by BUdR labelling, demonstrated that expression occurred only on the mutated X chromosomes previously identified by molecular methods. The concept that the fragile site represents the primary mutation is now strongly supported by experimental evidence. The expression of fra (X) in females is independent of X inactivation and other trans-acting factors.     

The fragile site (16) (q22)

Summary The rare fragile site at 16q22 was experimentally induced in lymphocyte cultures with various AT-specific, non-intercalating DNA-ligands. The optimum conditions for the induction of fra (16)(q22) were determined. The best expression of fra (16)(q22) was found with the aromatic diamidine berenil which is recommended for further studies on this fragile site. The results indicate that fra (16)(q22) is a region with AT-rich, late replicating DNA. The simultaneous treatment of lymphocytes with berenil and aphidicolin (inhibitor of DNA polymerase ) induces both the rare fra (16) (q22) and the common fra (16) (q23) within the same chromosome. A population study on 350 unselected individuals showed that fra (16)(q22) is the most common of all rare autosomal fragile sites in man. The frequency of individuals heterozygous for fra (16)(q22) is 5.1% no homozygosity for fra (16) (q22) was detected. Statistical analysis indicates that the population is in Hardy-Weinberg equilibrium with respect to the fragile and non-fragile chromosomes 16.     

A comparison of fragile X expression in lymphocyte and lymphoblastoid cultures

This study compares fragile X expression in peripheral blood lymphocyte cultures with expression in lymphoblastoid cell lines established from 23 individuals from families in which the fragile X is segregating. Most patients expressed the fragile X in lymphoblastoid cell lines treated with FUdR under optimal conditions at approximately the same frequency as in peripheral blood cultures from the same individual. No fragile X cells were seen in the lymphoblastoid cell lines from three phenotypically normal males who had transmitted the fragile X gene to offspring or in the lines from three phenotypically normal obligate-carrier females, all of whom were also negative in peripheral blood cultures. Two individuals, however, who expressed at high levels in peripheral blood lymphocytes expressed in lymphoblastoid cells only at low levels or not at all. We describe the considerations needed for the consistent demonstration of the fragile X in lymphoblastoid cell lines.     

Low frequencies of apparently fragile X chromosomes in normal control cultures: a possible explanation

Low frequencies of apparently fragile X [fra(X)] chromosomes have been reported in normal control, short-term, whole blood cultures, and they have been noted in both amniocyte and fetal blood cultures. However, there is currently no universal agreement on the lowest frequency for fra(X)(q27) that is diagnostic for the fragile X syndrome. Here, we present our observations on low levels of apparently fra(X) chromosomes in normal samples. We observed frequencies of 0.5% in short-term whole blood cultures and 0.9% in amniotic fluid cell cultures. In 1982, Steinbach et al. described nonspecific telomeric structural changes (TSC) and suggested that such low frequencies of apparently fra(X) chromosomes in normal material may be occurring by the same mechanism that is responsible for TSC formation. To determine if TSC formation can explain the significant baseline frequencies of fra(X) in normal controls, 10,457 cells were screened from 178 individuals referred for fra(X) analysis. Our findings indicated that TSC are not randomly distributed across chromosomes but tend to occur at specific sites. Based on our observations, we offer the hypothesis that the low frequency of apparent fra(X) in normal individuals may be due to nonrandom TSC distribution.     

Pseudodeficiency of arylsulfatase A: a common genetic polymorphism with possible disease implications

Summary The distribution and frequency of aphidicolin-induced common fragile sites were studied in chromosomes of cultured skin fibroblasts and PHA-stimulated lymphocytes from five normal individuals; 0.2 M aphidicolin was added for the last 26 h of culture. Skin fibroblasts from five fra(X)-positive patients were also studied in the same manner. Fragile sites most frequently found in fibroblasts from normal individuals were 3q26.2, 7q11.23, 16q23, 1p31, 10q11.2, 12q23 and 7q31, whereas those in lymphocytes from the same individuals were 3p14, 16q23, Xp22, 7q32 and 14q24. The distribution of fragile sites in fibroblasts from fra(X)-positive patients was essentially identical with that in normal individuals. The average number of gaps and breaks in 100 metaphases was 36.8 in fibroblasts from normal individuals, 113.8 in those from fra(X)-positive patients, and 279 in lymphocytes from normal individuals. Their rates of chromosome-type breaks and gaps were 7.9%, 29.7% and 54.5%, respectively. Thus, the distribution and frequency of aphidicolin-induced fragile sites were different between skin fibroblasts and lymphocytes, possibly reflecting differences in their DNA replication sequence or gene activity.     

Expression and identification of folate-sensitive fragile sites in British Suffolk sheep (<Emphasis Type="Italic">Ovis aries</Emphasis>)

An investigation to understand the dynamics and biological significance of fragile site expression, and identification of 5-fluorodeoxyuridine (FUdR) induced chromosomal gaps/breaks, were carried out in an experimental flock of 45 Suffolk sheep. The statistical comparison revealed, highly significant variation in the frequency of chromosomal fragile site expression between control and FUdR cultures. Mean (± S.D.) values for cells with gaps and breaks, or aberrant cell count (AC), and the number of aberrations (NoA) per animal were 2.02 ± 0.34, 2.42 ± 0.48, 13.26 ± 0.85 and 21.87 ± 1.88 (P < 0.01) in control and FUdR cultures, respectively. The comparison of age revealed nonsignificant variation between control and FUdR cultures. The G-band analysis of fragile site data revealed gaps in 29 autosomal and two X-chromosomal bands in the control cultures, whereas FUdR treated cultures scored 78 unstable bands in autosomes of which 56 were significantly fragile. X-chromosomes expressed breaks and gaps in six G-negative bands and five of them (Xq13, Xq15, Xq17, Xq24 and Xq26) were significantly fragile. The distribution comparison of autosomal fragile sites between sex groups did not reveal any significant variation. Female X-chromosomes were significantly more fragile than the male X-chromosomes. The distribution comparison for age groups (lambs versus adults) revealed significantly higher number of fragile bands in adults. Comparison of published data on reciprocal translocations in sheep with the fragile-site data obtained in this study indicated that the break sites of both phenomena were correlated. Similarities were also found between fragile sites and breakpoints of evolutionary significance in family Bovidae.     

Three infants having null acute lymphoblastic leukemia with chromosome rearrangements at 11q23: no involvement of a heritable fragile site in this band

Three families are presented in which an infant with null acute lymphoblastic leukemia had a karyotype rearrangement involving a break at 11q23. Peripheral blood was obtained, where possible, from both parents and from the child during periods of remission. The blood was stimulated with phytohemagglutinin and cultured under conditions that enhance expression of heritable folate-sensitive fragile sites. In all individuals studied very low levels of fra(11)(q23.3) were observed. These levels were far below those recorded for expression of the heritable folate-sensitive site fra(11)(q23.3) but are comparable with expression of the common fragile site fra(11)(q23.3) under these conditions.     

Cytogenetic studies in fragile X syndrome]

The main purpose of this work has been to find a method which would enable the diagnosis of FXS at the cytogenetic level. The studies are based on the analysis of chromosomes from 24 cultures on RPMI-1640 base with an addition of 5-fluoro-2'-deoxyuridine (FUdR) as inhibitor of thymidylate synthetase. The results indicate, that the cultures with the addition of FUdR could considerably improve the expression of fragile X chromosome. It is of great importance, particularly un the cases in which the presence of this marker is very low. It was possibly to specify the significant percentage and the exact position of breaks, gaps and fragile sites, mostly present in autosomes. It could mean, that such factors may play a significant role, apart of X chromosome, in the pathogenesis of FXS. The results of work prove, that this kind of method could be used as a screening for cases with fragile X syndrome.     

Fragile X expression is decreased by 5-azacytidine and S-adenosylhomocysteine

A lymphoblastoid cell line derived from a patient with fragile X chromosome exhibited fragility only when 5-fluoro-2'-deoxyuridine (FUdR) was added to the culture medium. Addition of methionine with FUdR greatly increased the frequency of fragile X. Addition of 5-azacytidine (an inhibitor of methylation at the level of DNA) or S-adenosylhomocysteine (an inhibitor of the synthesis of the methyl group donor S-adenosylmethionine) reversed the effect of methionine as well as that of FUdR. It is proposed that DNA methylation is in some way involved in the mechanism of fragile X expression.     

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.     

Cell type-dependent difference in the distribution and frequency of excess thymidine-induced common fragile sites: T lymphocytes and skin fibroblasts

Summary Common fragile sites were induced by excess thymidine in phytohemagglutin-stimulated T lymphocytes from 4 normal individuals, and skin fibroblasts from 4 normal and 5 fra(X) positive individuals. The results indicate that the frequency and distribution of excess thymidine-induced fragile sites are different between these two types of cells. The sites at 1p13 and 2p11.2, induced in both types of cells, have not previously been described, and are thus considered to be excess thymidine-specific fragile sites. These findings extend and support our previous studies on cell type-dependent difference in aphidicolin-induced common fragile sites.     

Enhanced sensitivity of lymphoblastoid cells from individuals carrying the mutation for the fragile X syndrome to the clastogenic effects of FUdR

Individuals known to carry the mutation for the fragile X syndrome can sometimes be identified cytogenetically by the presence of a fragile site on the X chromosome at q27.3. The frequency of cells bearing this fragile site is known to be enhanced by culturing the cells in folic acid deficient medium and/or by introducing folic acid metabolism inhibitors such as FUdR. In this study FUdR induction of chromosomal aberrations other than the fragile X was investigated. Lymphoblastoid cells from an obligate carrier, a mentally retarded male and a control were cultured in folic acid deficient medium in the presence of FUdR and harvested at various times after culture initiation. The frequency of chromosome and chromatid breaks was found to be higher in cells from the individuals carrying the mutation for the fragile X syndrome. The frequency of micronuclei, an indirect index of chromosome breakage, was also more elevated in cells from these individuals than in cells from the control. These findings are of potential importance to carrier detection of this common genetic disorder.     

Fragile X expression in thymidine-prototrophic and auxotrophic human-mouse somatic cell hybrids under low and high thymidylate stress conditions

Expression of the fragile X site fra(X)(q27.3) was studied in thymidine-prototrophic and auxotrophic human-mouse somatic cell hybrids. In these cells, low thymidylate stress, achieved by 5-fluoro-2'-deoxyuridine (FdU) treatment and by limiting the exogenous supply of thymidine (dT), induced fragile X expression. High thymidylate stress, produced by supplying excess amounts of dT, was also effective in inducing fragile X expression, even in a hybrid clone that retained a fragile X chromosome as the only human chromosome; addition of deoxycytidine (dC) completely abolished this effect. In contrast, 5-bromo-2'-deoxyuridine (BrdU) did not induce fragile X expression. Cell-cycle analysis of BrdU-deprived thymidine-auxotrophic hybrid cells indicated that one round of DNA replication under thymidylate stress conditions is sufficient for fragile X expression. Our results suggest that the expression is an intrinsic property of the fragile site itself, which is believed to be composed of replicon clusters with pyrimidine-rich DNA sequence(s).     

Induction of distamycin A-inducible rare fragile sites and increased sister chromatid exchanges at the fragile site

Summary Expression of distamycin A-inducible rare fragile sites by AT-specific DNA-ligands was examined in lymphoblastoid cell lines derived from heterozygous carriers for the fra(8)(q24), fra(16)(pl2), and fra(16)(q22) sites. The sensitivity of fragile site expression to the inducers was different at these fragile sites. The expression of fra(8)(q24) was induced markedly by Hoechst 33258, but not by distamycin A or berenil. An increased expression of fra(16)(p12) was found following treatment with Hoechst 33258 or berenil, but not with distamycin A. At fra(16)(q22), distamycin A markedly induced the fragile site, but Hoechst 33258 and berenil did not. Since their response to the different inducers was similar to that found in cultured lymphocytes, lymphoblastoid cell lines appear to retain their inherent properties. Although BrdUrd alone did nto induce any fragile sites, concomitant treatment with BrdUrd plus the inducer was synergistically effective in inducing all the fragile sites. An increased frequency of sister chromatid exchanges was observed at fra(16)(p12) following simultaneous treatment with BrdUrd and berenil, mainly when the site was expressed as an isochromatid gap. Thus, the induced fra (16)(pl2) site is a hot spot for the formation of sister chromatid exchanges, as found in other reported fragile sites.     

Heritable fragile sites on human chromosomes. XI. Factors affecting expression of fragile sites at 10q25, 16q22, and 17p12.

The fragile sites at 10q25, 16q22, and 17p12 can all be induced in lymphocyte culture by BrdU or BrdC added 6-12 hrs prior to harvest. Without induction, fra(10)(q25) is rarely expressed spontaneously, whereas fra(16)(q22) is frequently expressed spontaneously. Fra(17)(p12) is frequently expressed spontaneously but is probably expressed only after induction in some individuals. Distamycin A, netropsin, and Hoechst 33258 induced high levels of expression of fra(16)(q22) and fra(17)(p12) but did not enhance expression of fra(10)(q25). The mechanisms of induction of fra(16)(q22) by BrdU and distamycin A appear to be different, since the time of induction by BrdU reaches a maximum about 12 hrs prior to harvest whereas induction by distamycin A requires much longer exposure. The fragile sites at 10q25 and 16q22 were both induced in fibroblast culture by BrdU. Fra(17)(p12) is accepted as a fragile site because preliminary studies show that it behaves similarly in lymphocyte culture to fra(16)(q22); however, there is only limited evidence for fragility at 17p12.