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.     

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.     

Chromosome characteristics of X-linked mental retardation. II. Autosomes

The frequencies of chromosome and chromatid breaks and gaps were studied in blood lymphocytes of three groups of individuals: 21 males with X-linked mental retardation characterized by fragile X chromosome; 52 males with non-differentiated X-linked mental retardation having no fra(X) chromosome in their cells; 15 intellectually normal males. The lymphocytes were cultured both in medium 199 and in Eagle's medium supplemented with fluoro-deoxyuridine. The significantly higher frequencies of various autosomal lesions were observed in the individuals with the fragile X chromosome syndrome and in those with mental retardations without fra(X) chromosome, in comparison with normal males. The significant difference in some autosome lesions was also found between both groups of the patients. The distribution of chromosome lesions in autosomes of different groups was significantly higher in chromosomes A and lower in groups B, E, F and G, than expected in accordance with their relative length in the haploid set. In all the groups of individuals studied, the predominant localization of chromosome and chromatid breaks and gaps was observed in fragile sites 1p31, 3p14, 6q26 and 16q23.     

Chromosomal characteristics of X-linked recessive mental retardation. I. The X chromosome

The X-chromosome was studied in blood lymphocytes of 68 males with aspecific mental retardation (MR), their 57 relatives and 15 intellectually normal males. The incidence of a fragile X-chromosome (fra(X)) was found to be 4.7% in an unselected group of 42 patients, 50% among 10 probands in which pedigree data were suggestive of X-linked MR diagnosis, and 75% in the group of 15 patients selected for phenotype characteristic of the fragile X syndrome. The fra(X) was present in 1-43% of metaphases in different individuals, no such marker being observed in cells of 15 normal individuals. No significant difference was found when the incidence of the fra(X) was compared in cells cultured in the medium 199 with low folic acid content and the Eagle's medium supplemented with 5-fluorodeoxyuridine (10.62 +/- 2.94 SEM and 13.53 +/- 2.85 SEM, respectively). The possibility of false-positive diagnosis of the fragile X syndrome was quantitatively appreciated. A half of the patients showing a fra(C) in conventionally stained chromosomes were found to have fragile 6 autosome as the only marker in these cells, and in patients with the evident fragile (X) syndrome the fra(6) constituted about one-third of the fra(X) frequency. Both culture media employed were similar in the fra(6) induction.     

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.     

Chromosomal sensitivity to X-rays in lymphocytes from patients with Turner syndrome

Lymphocytes from patients with Turner syndrome were irradiated with X-rays (200 rad) to determine the chromosomal aberration frequency in first-division metaphases. Five patients with 45,X karyotype; three 45,X/46,Xi(X)q mosaics; one 45,X/47,XXX mosaic and 9 female controls were studied. Patients with a 45,X karyotype exhibited a radioinduced chromosomal aberration frequency similar to controls (38.6 +/- 6.37 and 36.2 +/- 5.11 respectively; p = 0.42). In the mosaics, 45,X cells had a mean frequency of 38.75 +/- 2.16; 46,Xi(X)q cells a mean of 38 +/- 2.16 and the control group a rate of 36.25 +/- 4.32. No differences were observed between 45,X and 46,Xi(X)q cells (p = 0.50), 45,X and normal cells (p = 0.24) or 46,Xi(X)q and normal cells (p = 0.35). Apparently neither the X monosomy nor the Xq isochromosome influences the 'in vitro' X-ray-induced chromosomal damage in Turner syndrome lymphocytes.     

Cytogenetic investigations in a family with ataxia telangiectasia

Summary Cytogenetic findings on a family with ataxia telangiectasia (A-T) in which three of four sibs were affected are described. The affected individuals had approximately twice the level of spontaneous chromosome breakage of a normla control, while the parents and the normal sib had no significant increase. Lymphocytes from all three A-T homozygotes showed specific stable chromosomal rearrangements involving chromosomes 7 and 14. All of these abnormalities involved breakage at the usual four sites associated with A-T (7p14, 7q35, 14q12, and 14q32). Two rearrangements detected in the eldest and most severely affected patient were clones, one of which [t(14;14)(p11;q12)] is not commonly found in A-T cells. No chromosomal rearrangements were encountered in lymphocytes from the control, the parents, or the normal sib. Lymphocytes from the A-T patients also were found to be 7–11 times more sensitive to the induction of chromatid aberrations by X-irradiation than control cells. Lymphocytes from the parents and normal sib showed a moderately increased frequency of X-ray induced aberrations compared with that of the control.     

Fragile site Xq27 and mental retardation. Clinical and cytogenetic manifestation in heterozygotes and hemizygotes of five kindreds

Summary Clinical and cytogenetic data of five kindreds with X-linked mental retardation and a methotrexate-inducible fragile site at the distal long arm of the X chromosome fra(X)(q27) are reported; comprising a total of 26 individuals studied cytogenetically, 10 hemizygotes, five obligate heterozygotes, seven facultative heterozygotes, and four normal males, i.e., fathers and brothers of affected hemizygotes. The heterozygotes in two of these sibships show partial phenotypic and/or mental manifestation. Two of them, who are obligate heterozygotes, expressed fra(X)(q27) in 23% and 16% of their metaphases at the ages of 27 and 53 years. In the obligate and facultative heterozygotes, who are mentally normal, the marker X chromosome could not be detected in lymphocyte cultures. We conclude from these findings that the occurrence of fra(X)(q27) might correlate with the phenotypic expression in heterozygotes rather than with the age of the individual.This investigation was supported in part by the Deutsche Forschungsgemeinschaft     

Chromosomal breakpoints in a cohort of head and neck squamous cell carcinoma patients

Head and neck squamous cell carcinoma (HNSCC) presents complex chromosomal rearrangements, however, the molecular mechanisms behind HNSCC development remain elusive. The identification of the recurrent chromosomal breakpoints could help to understand these mechanisms. Array-CGH was performed in HNSCC patients and the chromosomal breakpoints involved in gene amplification/loss were analyzed. Frequent breakpoints were clustered in chromosomes 12p, 8p, 3q, 14q, 6p, 4q, Xq and 8q. Chromosomes 6, 14, 3, 8 and X exhibited higher susceptibility to have breaks than other chromosomes. We observed that low copy repeat DNA sequences are localized at or flanking breakpoint sites, ranging from 0 to 200 bp. LINES, SINES and Simple Repeats were the most frequent repeat elements identified in these regions. We conclude that in our cohort specific peri-centromeric and telomeric regions were frequently involved in breakpoints, being the presence of low copy repeats elements one of the explanations for the common rearrangement events observed.     

Microphthalmia with linear skin defects syndrome in a mosaic female infant with monosomy for the Xp22 region: molecular analysis of the Xp22 breakpoint and the X-inactivation pattern

This paper describes a female infant with microphthalmia with linear skin defects syndrome (MLS) and monosomy for the Xp22 region. Her clinical features included right microphthalmia and sclerocornea, left corneal opacity, linear red rash and scar-like skin lesion on the nose and cheeks, and absence of the corpus callosum. Cytogenetic studies revealed a 45,X[18]/46,X,r(X)(p22q21) [24]/46,X,del(X)(p22)[58] karyotype. Fluorescence in situ hybridization analysis showed that the ring X chromosome was positive for DXZ1 and XIST and negative for the Xp and Xq telomeric regions, whereas the deleted X chromosome was positive for DXZ1, XIST, and the Xq telomeric region and negative for the Xp telomeric region. Microsatellite analysis for 19 loci at the X-differential region of Xp22 disclosed monosomy for Xp22 involving the critical region for the MLS gene, with the breakpoint between DXS1053 and DXS418. X-inactivation analysis for the methylation status of the PGK gene indicated the presence of inactive normal X chromosomes. The Xp22 deletion of our patient is the largest in MLS patients with molecularly defined Xp22 monosomy. Nevertheless, the result of X-inactivation analysis implies that the normal X chromosomes in the 46,X,del(X)(p22) cell lineage were more or less subject to X-inactivation, because normal X chromosomes in the 45,X and 46,X,r(X)(p22q21) cell lineages are unlikely to undergo X-inactivation. This supports the notion that functional absence of the MLS gene caused by inactivation of the normal X chromosome plays a pivotal role in the development of MLS in patients with Xp22 monosomy. Received: 16 December 1997 / Accepted: 25 February 1998     

Molecular analysis of recombination in a family with Duchenne muscular dystrophy and a large pericentric X chromosome inversion.

It has been demonstrated in animal studies that, in animals heterozygous for pericentric chromosomal inversions, loop formation is greatly reduced during meiosis. This results in absence of recombination within the inverted segment, with recombination seen only outside the inversion. A recent study in yeast has shown that telomeres, rather than centromeres, lead in chromosome movement just prior to meiosis and may be involved in promoting recombination. We studied by cytogenetic analysis and DNA polymorphisms the nature of meiotic recombination in a three-generation family with a large pericentric X chromosome inversion, inv(X)(p21.1q26), in which Duchenne muscular dystrophy (DMD) was cosegregating with the inversion. On DNA analysis there was no evidence of meiotic recombination between the inverted and normal X chromosomes in the inverted segment. Recombination was seen at the telomeric regions, Xp22 and Xq27-28. No deletion or point mutation was found on analysis of the DMD gene. On the basis of the FISH results, we believe that the X inversion is the mutation responsible for DMD in this family. Our results indicate that (1) pericentric X chromosome inversions result in reduction of recombination between the normal and inverted X chromosomes; (2) meiotic X chromosome pairing in these individuals is likely initiated at the telomeres; and (3) in this family DMD is caused by the pericentric inversion.     

Cytogenetic evaluation of 163 azoospermics

A constitutional chromosomal aberration was diagnosed in 38/163 (23.3%) azoospermic patients. Whereas the 47,XXY complement was the commonest (31/38 cases), the following abnormal karyotypes were also found: 46,XX; 46,X,del(Y) (q11); 46,X,r(Y); 46,XY,inv(1) (p3500q21.3)mat; and 46,Y,t(X;3) (q26;q13.2)mat (both the deleted and the annular Y were observed twice). Pooled data from the literature showed that the frequency of chromosomal abnormalities is higher in azoospermic (150.4/1000) than in infertile (55.3/1000) males, which in turn is higher than in newborns (less than 6/1000). The observed different frequency between azoospermic and infertile individuals is given by several types of chromosomal abnormalities, mainly by the complement 47,XXY. The analysis also showed that the male infertility secondary to rob translocations and supernumerary marker chromosomes is usually not related to azoospermia. The contrary occurs in certain rcp and gonosome;autosome translocations and in autosome inversions.     

On the frequency of telomeric chromosomal changes induced by culture conditions suitable for fragile X expression

Summary Under culture conditions suitable for the expression of the fragile site Xq27, nonspecific telomeric structural changes similar to the specific fra(X) formation occurred apparently on every chromosome arm. Significant differences between individuals seem to exist. The total frequency of nonspecific terminal lesions not located on the long arm of the X chromosome was 0.22±0.17 per cell in 37 cultures examined. If telomeric lesions on Xq occur in more than 0.7% of the cells from a single culture in males and more than 1.5% of the cells from single culture in females, then this probably indicates a specific fra(X) expression. Lower percentages may be the result of nonspecific telomeric structural changes in Xq. These are expected to occur in the normal X as well and may, therefore, give rise to false positive diagnoses in the detection of hemi-, hetero-, and perhaps also homozygous fra(X) carriers.     

X-radiation-induced chromosome breakage in retinoblastoma lymphocytes

We have examined the spontaneous and X-radiation-induced chromosomal damage in normal humans and in patients with retinoblastoma using the BudR-Giemsa technique in lymphocytes cultured for 48 h. 9 sporadic unilateral non-hereditary cases, 11 hereditary cases (8 bilateral sporadic and 3 unilateral hereditary cases) and 20 healthy individuals were studied simultaneously. No difference in the spontaneous frequency of chromatid and chromosome aberrations was observed between patients and controls. After treatment with 150 rad the frequency of chromosome exchange aberrations was higher in unilateral hereditary cases than the controls (42.0% +/- 5.3 and 22.3% +/- 2.6 respectively; p = 0.05). In bilateral sporadic retinoblastoma 2 different groups were observed. A hypersensitive group showed a significant increment in radiation-induced chromosomal exchange aberrations over the control group (46.2% +/- 5.4 and 24.2% +/- 2.1 respectively; p = 0.01). The other group had a chromosomal exchange frequency similar to normal individuals (26.5% +/- 2.0 and 24.2% +/- 0.4 respectively; p = 0.10). Sporadic unilateral non-hereditary retinoblastoma had an exchange chromosomal aberration frequency similar to control individuals (26.1% +/- 2.8 and 24.6% +/- 2.7 respectively; p greater than 0.10). These results suggest that: There is no relationship between spontaneous chromosome fragility and retinoblastoma. Sporadic unilateral non-hereditary retinoblastoma has normal chromosome sensitivity to X-irradiation. Some hereditary cases of retinoblastoma are sensitive to X-rays while others behave like normals. A mutation or a submicroscopic deletion at a DNA repair locus which is independent of the retinoblastoma gene may cause this radiosensitivity.     

Expression of folate-sensitive fragile sites in lymphocyte chromosomes

Summary The expression of folate-sensitive fragile sites (FS) was analyzed using MTX as a fragility inducer in seven normal subjects [four unrelated persons and three members of one family (father, mother, and son)]; a woman heterozygous for fra Xq27.3 with a 47,XXX karyotype; and her son, affected by the fra-X syndrome. The mean expression of chromosome lesions (CL) other than Xq27.3 was 70.1% (686CL in 978 metaphases), and the coincidence between CL and FS was 68.9%. We propose six new c-fra sites: bands 4q33 and 11q22 because they were found in two members of the same family; band 13q32 because it had a frequency of expression of 3% of metaphases; and bands 3p13, 8q21, and Xq21 because they were observed in four of the nine individuals studied.     

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.     

Constitutional chromosomal breakage

Summary There were 18 individuals found to have a constitutional chromosome fragility causing an increase in break frequency. For each chromosome the breakpoint is always the same, whether it involves chromosomes from the same person, the same family, or different families. The fragile points are bands 10q24, 12q13, 16q21, 17p12, and Xq27. Autosomal constitutional fragility does not seem to have a phenotypic correspondence. They were found mostly in parents of children with chromosomal abnormalities or in couples with a history of repeated spontaneous abortions which permits one to raise the possibility of an interchromosomal effect. The six constitutional chromosomal fragilities of the X chromosome had in common the association of mental deficiency, delayed speech, and large malformed ears. The break points in constitutional chromosomal fragility were compared to those of spontaneous breaks in vitro, to those induced by X-rays, and to those in Fanconi's anemia. The theoretical consequences of these structural abnormalities are discussed as well as what to do about them when they are found.This study was supported by I.N.S.E.R.M. (C.R.L. No. 7510424).Text of the communication presented at the Symposium on Medical Genetics, Debrecen-Hajduszoboszlo, Hungary, 27–29 april 1976.     

Cytogenetic investigations in three cell types of a Saudi family with ataxia telangiectasia

Summary Chromosomal analyses were performed on lymphocytes, fibroblasts and lymphoblastoid cell lines derived from a Saudi family with ataxia telangiectasia (AT). The three siblings of a consanguineous marriage were all affected. The lymphocytes of the AT homozygotes (probands) showed an increase of 2- to 6-fold and 4- to 8-fold respectively, in the frequency of spontaneous and X-ray-induced chromosomal aberrations compared with controls, while the parents (obligate heterozygotes) of the patients showed no notable difference. The unirradiated lymphocytes from the oldest AT sibling, an 11-year-old boy (AT1), showed specific rearrangements involving chromosomes 7 and 14 [t(7;14)(q35;q12)] and 12 and 14 [t(12;14)(q23;q12)] in two different clones. The most severely affected sibling was a 9-year-old girl (AT2) who presented with a clone showing a novel rearrangement involving chromosomes 14 and 17, namely: del(14) (q31q32) and dup(17)(q21–q24). The lymphocytes from the third sibling, a 2-year-old boy (AT3), showed a t(2;14)(p24;q12). In addition, an inv(14)(q12q32) was observed in all three AT patients, while inv(7)(p14q35) was found only in patients 2 and 3. The lymphocytes from the AT parents and controls showed normal karyotypes. The breakpoints involving chromosomes 2,12 and 17, observed in our studies, have rarely been reported in other series of AT patients. No non-random chromosomal rearrangements were observed either in the skin fibroblasts or in the lymphoblastoid cell lines derived from the AT patients, although all cell lines showed an increase in both spontaneous and radiation-induced chromosomal breaks per cell. The present study constitutes the first report on a cytogenetic analysis of a Saudi family with three AT siblings.     

Frequency of the fragile X syndrome in institutionalized mentally retarded females in Japan

Summary The fragile X [fra(X)] syndrome was screened on 190 Japanese institutionalized females with moderate to severe mental retardation. Two inmates with severe mental retardation (IQ 20) had the fra(X) chromosome in 26% and 15% of the cells examined, indicating that the prevalence of the fra(X) syndrome was about 1% in all female inmates and was about 3.27% in severely mentally retarded females with known causes. However, no female with fra(X) syndrome was found in 35 moderately retarded females. Both had brothers with the fra(X) syndrome and the prevalence was 10% in females with a family history of mental retardation. In addition, the replication study of the fra(X) chromosome in the patients supported the proposal that an excess of the early replicated fra(X) chromosome is related to the mental capacity in heterozygous females. Therefore, the fra(X) syndrome should not be ignored even in severely mentally retarded females with a family history, though the heterozygotes are commonly normal to subnormal in their mental development. in addition, the replication study of the fra(X) chromosome may help to estimate mental development in the carrier children.