Human fragile site FRA16B DNA excludes nucleosomes in the presence of distamycin

Human fragile sites are weak staining gaps in chromosomes generated by specific culture conditions. The short CGG repeating DNA derived from folate-sensitive fragile sites has been shown to exclude single nucleosomes. To test whether this nucleosome exclusion model provides a general molecular mechanism for the formation of fragile sites, a different class of fragile site, the 33-base pair AT-rich repeating DNAs derived from the rare distamycin-inducible site, FRA16B, was examined for its ability to assemble single nucleosomes and nucleosome arrays using in vitro nucleosome reconstitution methods. The FRA16B DNA fragments strongly exclude nucleosome assembly only in the presence of distamycin, and increasing the number of 33-bp repeats increases the effect of distamycin in the destabilization of the nucleosome formation, suggesting a common mechanism for the formation of fragile sites.     

CGG-repeat expansion in the DIP2B gene is associated with the fragile site FRA12A on chromosome 12q13.1

A high level of cytogenetic expression of the rare folate-sensitive fragile site FRA12A is significantly associated with mental retardation. Here, we identify an elongated polymorphic CGG repeat as the molecular basis of FRA12A. This repeat is in the 5' untranslated region of the gene DIP2B, which encodes a protein with a DMAP1-binding domain, which suggests a role in DNA methylation machinery. DIP2B mRNA levels were halved in two subjects with FRA12A with mental retardation in whom the repeat expansion was methylated. In two individuals without mental retardation but with an expanded and methylated repeat, DIP2B expression was reduced to approximately two-thirds of the values observed in controls. Interestingly, a carrier of an unmethylated CGG-repeat expansion showed increased levels of DIP2B mRNA, which suggests that the repeat elongation increases gene expression, as previously described for the fragile X-associated tremor/ataxia syndrome. These data suggest that deficiency of DIP2B, a brain-expressed gene, may mediate the neurocognitive problems associated with FRA12A.     

Population cytogenetics of rare fragile sites in Japan

Summary A population cytogenetic study of three groups of rare fragile sites defined in Human Gene Mapping 8 (HGM8, Berger et al. 1985) has been conducted using peripheral blood lymphocytes of healthy Japanese subjects. We have examined 1,022 blood donors for folate-sensitive and bromodeoxyuridine (BrdU)-requiring, and 845 for distamycin A-inducible fragile sites. Out of 17 rare autosomal fragile sites defined in HGM8, the following six were identified in Japan; folate-sensitive fra(2)(q11), fra(11)(q13) and fra(11)(q23), distamycin A-inducible fra(16)(q22) and fra(17)(p12), and BrdU-requiring fra(10)(q25). The incidences of distamycin A-inducible fra(16)(q22) (1.42%) and fra(17)(p12) (3.08%) were considerably higher than those of the other sites in Japan. Furthermore, a folate-sensitive fra(17)(p12) and a distamycin A-inducible fra(8)(q24.1) have been newly found in the present study. Their incidences were 0.10% (1/1,022) and 0.71% (6/845), respectively. Since the expression of this fra(17)(p12) was induced by fluorodeoxyuridine, supressed by thymidine, but not induced by distamycin A, it can be classified as a folate-sensitive site. The expression of the new distamycin A-inducible fra(8)(q24.1) was also enhanced by treatment with Hoechst 33258, berenil and 4,6-diamidino-2-phenylindole (DAPI). This fragile site fulfils all four classical criteria suggested by Sutherland (1979) and also new criteria for a rare fragile site defined in HGM8 (Berger et al. 1985).     

Molecular basis for expression of common and rare fragile sites

Fragile sites are specific loci that form gaps, constrictions, and breaks on chromosomes exposed to partial replication stress and are rearranged in tumors. Fragile sites are classified as rare or common, depending on their induction and frequency within the population. The molecular basis of rare fragile sites is associated with expanded repeats capable of adopting unusual non-B DNA structures that can perturb DNA replication. The molecular basis of common fragile sites was unknown. Fragile sites from R-bands are enriched in flexible sequences relative to nonfragile regions from the same chromosomal bands. Here we cloned FRA7E, a common fragile site mapped to a G-band, and revealed a significant difference between its flexibility and that of nonfragile regions mapped to G-bands, similar to the pattern found in R-bands. Thus, in the entire genome, flexible sequences might play a role in the mechanism of fragility. The flexible sequences are composed of interrupted runs of AT-dinucleotides, which have the potential to form secondary structures and hence can affect replication. These sequences show similarity to the AT-rich minisatellite repeats that underlie the fragility of the rare fragile sites FRA16B and FRA10B. We further demonstrate that the normal alleles of FRA16B and FRA10B span the same genomic regions as the common fragile sites FRA16C and FRA10E. Our results suggest that a shared molecular basis, conferred by sequences with a potential to form secondary structures that can perturb replication, may underlie the fragility of rare fragile sites harboring AT-rich minisatellite repeats and aphidicolin-induced common fragile sites.     

Population cytogenetics of folate-sensitive fragile sites

Summary The frequencies of folate-sensitive autosomal rare fragile sites (ARFS) were compared in populations of mentally retarded, mentally subnormal, and mentally normal children and of patients referred for diagnostic chromosome study. The frequencies did not differ significantly. Altogether, an autosomal rare fragile site was found in 16 of 1445 individuals (1 in 90). Of six different folate-sensitive ARFS detected, the most common one was FRA9A, with a frequency of 1 in 241 individuals. In addition, FRA17A, classified as a distamycin A-inducible fragile site, was found with a frequency of 1 in 206. It was regarded as a spontaneously expressive fragile site. In 19 families in which transmission of an autosomal rare fragile site was studied, the mother was the carrier in 16 families and the father, in one family. The mean percentage (±SD) of cells expressing ARFS in 55 individuals was 19% (±11.4). The age did not affect the rate of expression. When the rate of expression was calculated separately in a group of mentally retarded (mean=23.4%) and in a group of mentally normal individuals (mean=16.0%), the difference was statistically significant.     

Human chromosome fragility

Fragile sites are heritable specific chromosome loci that exhibit an increased frequency of gaps, poor staining, constrictions or breaks when chromosomes are exposed to partial DNA replication inhibition. They constitute areas of chromatin that fail to compact during mitosis. They are classified as rare or common depending on their frequency within the population and are further subdivided on the basis of their specific induction chemistry into different groups differentiated as folate sensitive or non-folate sensitive rare fragile sites, and as aphidicolin, bromodeoxyuridine (BrdU) or 5-azacytidine inducible common fragile sites. Most of the known inducers of fragility share in common their potentiality to inhibit the elongation of DNA replication, particularly at fragile site loci. Seven folate sensitive (FRA10A, FRA11B, FRA12A, FRA16A, FRAXA, FRAXE and FRAXF) and two non-folate sensitive (FRA10B and FRA16B) fragile sites have been molecularly characterized. All have been found to represent expanded DNA repeat sequences resulting from a dynamic mutation involving the normally occurring polymorphic CCG/CGG trinucleotide repeats at the folate sensitive and AT-rich minisatellite repeats at the non-folate sensitive fragile sites. These expanded repeats were demonstrated, first, to have the potential, under certain conditions, to form stable secondary non-B DNA structures (intra-strand hairpins, slipped strand DNA or tetrahelical structures) and to present highly flexible repeat sequences, both conditions which are expected to affect the replication dynamics, and second, to decrease the efficiency of nucleosome assembly, resulting in decondensation defects seen as fragile sites. Thirteen aphidicolin inducible common fragile sites (FRA2G, FRA3B, FRA4F, FRA6E, FRA6F, FRA7E, FRA7G, FRA7H, FRA7I, FRA8C, FRA9E, FRA16D and FRAXB) have been characterized at a molecular level and found to represent relatively AT-rich DNA areas, but without any expanded repeat motifs. Analysis of structural characteristics of the DNA at some of these sites (FRA2G, FRA3B, FRA6F, FRA7E, FRA7G, FRA7H, FRA7I, FRA16D and FRAXB) showed that they contained more areas of high DNA torsional flexibility with more highly AT-dinucleotide-rich islands than neighbouring non-fragile regions. These islands were shown to have the potential to form secondary non-B DNA structures and to interfere with higher-order chromatin folding. Therefore, a common fragility mechanism, characterized by high flexibility and the potential to form secondary structures and interfere with nucleosome assembly, is shared by all the cloned classes of fragile sites. From the clinical point of view, the folate sensitive rare fragile site FRAXA is the most important fragile site as it is associated with the fragile X syndrome, the most common form of familial mental retardation, affecting about 1/4000 males and 1/6000 females. Mental retardation in this syndrome is considered as resulting from the abolition of the FMR1 gene expression due to hypermethylation of the gene CpG islands adjacent to the expanded methylated trinucleotide repeat. FRAXE is associated with X-linked non-specific mental retardation, and FRA11B with Jacobsen syndrome. There is also some evidence that fragile sites, especially common fragile sites, are consistently involved in the in vivo chromosomal rearrangements related to cancer, whereas the possible implication of common fragile sites in neuropsychiatric and developmental disorders is still poorly documented.     

Replication delay along FRA7H, a common fragile site on human chromosome 7, leads to chromosomal instability

Common fragile sites are specific chromosomal loci that show gaps, breaks, or rearrangements in metaphase chromosomes under conditions that interfere with DNA replication. The mechanism underlying the chromosomal instability at fragile sites was hypothesized to associate with late replication time. Here, we aimed to investigate the replication pattern of the common fragile site FRA7H, encompassing 160 kb on the long arm of human chromosome 7. Using in situ hybridization on interphase nuclei, we revealed that the replication of this region is initiated relatively early, before 30% of S phase is completed. However, a high fraction ( approximately 35%) of S-phase nuclei showed allelic asynchrony, indicating that the replication of FRA7H is accomplished at different times in S phase. This allelic asynchrony is not the result of a specific replication time of each FRA7H allele. Analysis of the replication pattern of adjacent clones along FRA7H by using cell population and two-color fluorescent in situ hybridization analyses showed significant differences in the replication of adjacent clones, under normal growth condition and upon aphidicolin treatment. This pattern significantly differed from that of two nonfragile regions which showed a coordinated replication under both conditions. These results indicate that aphidicolin is enhancing an already existing difference in the replication time along the FRA7H region. Based on our replication analysis of FRA7H and on previous analysis of the common fragile site FRA3B, we suggest that delayed replication is underlying the fragility at aphidicolin-induced common fragile sites.     

Failure of origin activation in response to fork stalling leads to chromosomal instability at fragile sites

Perturbed DNA replication in early stages of cancer development induces chromosomal instability preferentially at fragile sites. However, the molecular basis for this instability is unknown. Here, we show that even under normal growth conditions, replication fork progression along the fragile site, FRA16C, is slow and forks frequently stall at AT-rich sequences, leading to activation of additional origins to enable replication completion. Under mild replication stress, the frequency of stalling at AT-rich sequences is further increased. Strikingly, unlike in the entire genome, in the FRA16C region additional origins are not activated, suggesting that all potential origins are already activated under normal conditions. Thus, the basis for FRA16C fragility is replication fork stalling at AT-rich sequences and inability to activate additional origins under replication stress. Our results provide a mechanism explaining the replication stress sensitivity of fragile sites and thus, the basis for genomic instability during early stages of cancer development.     

Matrix attachment region (MAR) properties and abnormal expansion of AT island minisatellites in FRA16B fragile sites in leukemic CEM cells

AT-rich minisatellites (AT islands) are sites of genomic instability in cancer cells and targets for extremely lethal AT-specific drugs, such as bizelesin. Here we investigated the AT islands in the FRA16B fragile site region for their possible roles in the organization of DNA on the nuclear matrix. The FRA16B AT island nominally spans ~3 kb of mostly >90% A/T DNA. In silico analysis indicates that this domain exhibits characteristics of nuclear matrix attachment regions (MARs): an exceptionally intense computed ‘MAR potential’ and profound duplex destabilization and flexibility. FRA16B repeats specifically bind to isolated nuclear matrices, which indicates their in vitro MAR function. This binding is several-fold greater than that of a known MAR in the c-myc gene. AT islands in fragile sites FRA16B and FRA16D are significantly more abundant in CEM cells that are hypersensitive to bizelesin compared to normal WI-38 cells. FRA16B overabundance in CEM is due to an ~10-fold expansion of FRA16B repeats. The expanded FRA16B minisatellites in CEM cells preferentially localize to the nuclear matrix-associated DNA indicating their in vivo MAR function. The unexpanded repeats in WI-38 cells localize to the loop DNA. The c-myc MAR is also matrix-associated in CEM cells while localizing to loop DNA in WI-38 cells. These results are the first to demonstrate that AT islands in fragile sites can function as MARs both in vitro and in vivo. The ability of FRA16B-mediated MAR sites to rearrange depending on the repeat expansion status could be relevant to both genomic instability of cancer cells and their sensitivity to AT-island targeting drugs.     

A linkage group with FRA16B (the fragile site at 16q22.1)

Summary Polymorphic DNA markers located in bands 16q13, 16q21 and 16q22 were examined for recombination with FRA16B, the fragile site at 16q22.100. A tight linkage cluster D16S10-FRA16B-D16S4-HP was established. There were no recombinants between D16S10 and D16S4, which flank FRA16B. The markers D16S10 and D16S4 are in close proximity on the genetic map and delineate a small chromosomal segment, which contains the distamycin A-inducible fragile site.     

Segregation analysis of rare autosomal fragile sites

Summary Segregation analyses were performed on pedigrees with rare autosomal fragile sites. The results of the analysis of pedigrees with folate sensitive fragile sites, including 2q1, 6p23, 7p11, 8q22, 9q32, 10q23, 11q13, 11q23, 12q13, 16p12, and 20p11, suggested that expression of the gene depended on the carrier parent: it was only 50% penetrant when transmitted by a carrier father, but fully penetrant when transmitted by a carrier mother. Pedigrees with the bromodeoxyuridine (BrdU) fragile site, fra(10)(q25), showed the same trend but the results were not statistically significant. In addition, 38 of the 44 probands with folate sensitive or BrdU-sensitive fragile sites received the gene from their carrier mother and only six received it from their father. In contrast, the analysis of pedigrees with the distamycin A-inducible site, fra(16)(q22), gave the results expected for a simple codominant trait with complete penetrance. Probands with this fragile site received the gene equally from mothers or fathers. The genetic implications of these results are discussed.     

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.     

Sequence rearrangement in the AT-rich minisatellite of the novel rice transposable element Basho.

In the process of characterizing a rice wx deletion mutant, an AT-rich minisatellite sequence that consisted of units of approximately 80 bp was detected about 2.3 kb downstream of the wx gene. This AT-rich minisatellite was a multiple-copy element (1 x 10(3) to 2 x 10(3) copies per haploid genome) and interspersed in the rice genome. By BLAST homology search it was indicated that not only the tandem repeat but also both flanking sequences were conserved among copies. According to the characteristics of the termini (5'-CHH ... CTAG-3') and a target site preference for T, this AT-rich minisatellite accompanying the flanking sequences was classified into a novel transposon, Basho. The results of direct amplification of Basho showed that relatively large variation in size existed in the Basho family. We estimate the variation to be generated by not only alteration of the number of units in the minisatellite but also by duplications of larger blocks including the conserved flanking sequences caused by single-strand mispairing (SSM) at noncontiguous repeats. Because the AT-rich minisatellite contained in Basho possessed several motifs of the matrix attachment region (MAR) in its repeat unit, the functional role as MAR in the rice genome was discussed.     

Segregation of FRAXE in a large family: clinical, psychometric, cytogenetic, and molecular data.

During an ongoing study on X-linked mental retardation, we ascertained a large family in which mild mental retardation was cosegregating with a fragile site at Xq27-28. Clinical, psychometric, cytogenetic, and molecular studies were performed. Apart from mild mental retardation, affected males and females did not show a specific clinical phenotype. Psychometric assessment of four representative affected individuals revealed low academic achievements, with verbal and performance IQs of 61-75 and 70-82, respectively. Cytogenetically the fragile site was always present in affected males and was not always present in affected females. With FISH the fragile site was located within the FRAXE region. The expanded GCC repeat of FRAXE was seen in affected males and females either as a discrete band or as a broad smear. No expansion was seen in unaffected males, whereas three unaffected females did have an enlarged GCC repeat. Maternal transmission of FRAXE may lead to expansion or contraction of the GCC repeat length, whereas in all cases of paternal transmission contraction was seen. In striking contrast to the situation in fragile X syndrome, affected males may have affected daughters. In addition, there appears to be no premutation of the FRAXE GCC repeat, since in the family studied here all males lacking the normal allele were found to be affected.     

A unique AT-rich hypervariable minisatellite 3' to the ApoB gene defines a high information restriction fragment length polymorphism

A DNA restriction fragment length polymorphism has been found immediately 3' to the human apoB gene. Digestion of many different human DNAs at sites flanking the region and Southern blotting analysis reveal that this region can vary in length by approximately 300 base pairs with five alleles readily distinguishable. The length polymorphism is due to a unique AT-rich minisatellite that consists primarily of a 30-base pair tandem repeat with two structurally related subunit sequences, x (ATAATTAAATATTTT) and y (ATAATTAAAATATTT). In general, the sequences repeat in an x-y order. The AT-rich region also contains variant x and y sequences that result from C or G for A substitution. Sequence analysis of one large allele revealed the expected increased number of xy repeats. In addition, similar analysis of three different smaller alleles with the same apparent size on Southern blotting analysis showed that all were of slightly different size due to minor differences in the number of xy repeats. The heterogeneity of this AT-rich minisatellite provides the basis for a highly informative restriction fragment length polymorphism of the apoB gene and should be very useful in association and linkage analysis studies of the contribution of this locus to atherosclerosis susceptibility.     

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

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