Physical mapping of probes proximal to the fragile X locus (FRAX) confirms the order F9-DXS105 (cX55.7)-DXS98 (4D8)-FRAXA

A woman with an abnormal karyotype, (46,X,der(X) (pter----q27::q27----q21), was analyzed using DNA probes in the region Xq27----qter. The results indicate that she is trisomic for the Factor IX locus, disomic for the locus DXS105 (cX55.7) and monosomic for the loci DXS98 (4D8), DXS52 (St14) and Factor VIII. This confirms the absence of the region Xq28 in the abnormal chromosome. Furthermore, the presence of only one copy of 4D8 and two copies of cX55.7 places the DXS98 locus distal to Factor IX and closer to the fragile X locus than DXS105.     

Two sisters with a distal deletion at the Xq26/Xq27 interface: DNA studies indicate that the gene locus for factor IX is present

Summary Two sisters with premature menopause and a small deletion of the long arm of one of their X chromosomes [del (X)(pterq26.3:)] were investigated with polymorphic DNA probes near the breakpoint. The deleted chromosome retained the factor IX (F9) locus and the loci DXS51 (52A) and DXS100 (pX45h), which are proximal to F9. However, the factor VIII (F8) locus was not present, nor were two loci tightly linked to this locus, DXS52 (St14) and DXS15 (DX13) This deletion refines the location of the F9 locus to Xq26 or to the interface Xq26/Xq27, thus placing it more proximally than has been previously reported. The DNA obtained from these patients should be valuable in the mapping of future probes derived from this region of the X chromosome.     

Deletion (X)(q26.1-->q28) in a proband and her mother: molecular characterization and phenotypic-karyotypic deductions.

During a routine prenatal diagnosis we detected a female fetus with an apparent terminal deletion of an X chromosome with a karyotype 46,X,del(X)(q25); the mother, who later underwent premature ovarian failure, had the same Xq deletion. To further delineate this familial X deletion and to determine whether the deletion was truly terminal or, rather, interstitial (retaining a portion of the terminal Xq28), we used a combination of fluorescence in situ hybridization (FISH) and Southern analyses. RFLP analyses and dosage estimation by densitometry were performed with a panel of nine probes (DXS3, DXS17, DXS11, DXS42, DXS86, DXS144E, DXS105, DXS304, and DXS52) that span the region Xq21 to subtelomeric Xq28. We detected a deletion involving the five probes spanning Xq26-Xq28. FISH with a cosmid probe (CLH 128) that defined Xq28 provided further evidence of a deletion in that region. Analysis with the X chromosome-specific cocktail probes spanning Xpter-qter showed hybridization signal all along the abnormal X, excluding the possibility of a cryptic translocation. However, sequential FISH with the X alpha-satellite probe DXZ1 and a probe for total human telomeres showed the presence of telomeres on both the normal and deleted X chromosomes. From the molecular and FISH analyses we interpret the deletion in this family as 46,X,del(X) (pter-->q26::qter). In light of previous phenotypic-karyotypic correlations, it can be deduced that this region contains a locus responsible for ovarian maintenance.     

Three chromosomes' (7;9;22) rearrangement and the origin of the Philadelphia chromosome

Summary A woman with chronic myelocytic leukemia had the Philadelphia chromosome and a complex four-break—three-chromosome rearrangement. The q32q34 portion of chromosome 9 is translocated to band q22 of chromosome 7, and at the end of this segment is attached the deleted q11 qter portion of chromosome 22. A review of 12 cases of the Philadelphia chromosome originating by the rearrangement of three or more chromosomes reveals that chromosomes 9 and 22 are always involved, while the third chromosome is a different one in each case. We discuss the hypothesis that the 22q segment is always specifically attached to band 9q34 wherever this portion of 9q is transposed.Address for offprint requests: Prof. M. Fraccaro, Gruppo Euratom, Via Forlanini, 14, I-27100 Pavia, Italy     

Sex chromosomal dimorphisms narrated by X-chromosome translocation in a spiny frog (<Emphasis Type="Italic">Quasipaa boulengeri</Emphasis>)

Background

In the general model of sex chromosome evolution for diploid dioecious organisms, the Y (or W) chromosome is derived, while the homogametic sex presumably represents the ancestral condition. However, in the frog species Quasipaa boulengeri, heteromorphisms caused by a translocation between chromosomes 1 and 6 are not related to sex, because the same heteromorphic chromosomes are found both in males and females at the cytological level. To confirm whether those heteromorphisms are unrelated to sex, a sex-linked locus was mapped at the chromosomal level and sequenced to identify any haplotype difference between sexes.

Results

Chromosome 1 was assigned to the sex chromosome pair by mapping the sex-linked locus. X-chromosome translocation was demonstrated and confirmed by the karyotypes of the progeny. Translocation heteromorphisms were involved in normal and translocated X chromosomes in the rearranged populations. Based on phylogenetic inference using both male and female sex-linked haplotypes, recombination was suppressed not only between the Y and normal X chromosomes, respectively the Y and translocated X chromosomes, but also between the normal and translocated X chromosomes. Both males and females shared not only the same translocation heteromorphisms but also the X chromosomal dimorphisms in this frog.

Conclusions

The reverse of the typical situation, in which the X is derived and the Y has remained unchanged, is known to be very rare. In the present study, X-chromosome translocation has been known to cause sex chromosomal dimorphisms. The X chromosome has gone processes of genetic differentiation and/or structural changes by chance, which may facilitate sex chromosome differentiation. These sex chromosomal dimorphisms presenting in both sexes may represent the early stages of sex chromosome differentiation and aid in understanding sex chromosome evolution.

     

A linkage study of Emery-Dreifuss muscular dystrophy

Summary We have searched for linkage between polymorphic loci defined by DNA markers on the X chromosome and X-linked Emery-Dreifuss muscular dystrophy (EDMD). There are high recombination rates between EDMD and the Xp loci known to be linked to Becker and Duchenne muscular dystrophy. There is a suggestion of linkage between EDMD and the loci DXS52 and DXS15, defined by probes St 14 and DX13 respectively, located at Xq28. for DXS15=1.14 at =0.15. This is in agreement with the previously reported linkage between a disorder strongly resembling EDMD and colour-blindness (Thomas et al. 1972), suggesting that there is a second locus on the X chromosome concerned with muscle integrity.     

New polymorphisms at the DXS98 locus and confirmation of its location proximal to FRAXA by in situ hybridization.

The locus DXS98, detected with the 1.5-kb anonymous probe p4D-8, was recently shown to be closely linked and proximal to the locus for the fragile X syndrome, with theta = .05 at lod = 3.406, by utilizing a limited number of meioses informative for a two-allele MspI RFLP. Because DXS98 may be the closest available marker to the fragile X locus (FRAXA), we sought to increase its utility for linkage studies by extending its PIC and confirming its localization to Xq27, proximal to FRAXA. We have isolated 15 kb of genomic DNA (lambda 4D8-3) from the DXS98 locus by using p4D-8 to screen a genomic phage library containing partial Sau3A-digested human DNA. Three additional RFLPs for the enzymes BglII and XmnI were found by using the entire lambda 4D8-3 as probe. Combined heterozygosity for the four RFLPs in 25 unrelated females was 48%, as compared with only 28% when the MspI RFLP alone was used. In situ hybridization of unique sequences from lambda 4D8-3 was performed on metaphase chromosomes of lymphocytes and lymphoblasts from patients with the fragile X syndrome. Grains on the X chromosome were significantly clustered at band Xq27. Following fragile site induction, all nine grains in the q27-28 region were proximal to the fragile site. Confirmation of the location of DXS98 proximal to FRAXA and the new RFLPs at this locus make DXS98 more useful for linkage analysis and physical mapping in the region of the fragile X mutation.     

Exclusion mapping of the gene for X-linked neural tube defects in an Icelandic family

Various polymorphic markers with a random distribution along the X chromosome were used in a linkage analysis performed on a family with apparently Xlinked recessive inheritance of neural tube defects (NTD). The lod score values were used to generate an exclusion map of the X chromosome; this showed that the responsible gene was probably not located in the middle part of Xp or in the distal region of Xq. A further refining of these results was achieved by haplotype analysis, which indicated that the gene for X-linked NTD was located either within Xp21.1-pter, distal from the DMD locus, or in the region Xq12–q24 between DXS106 and DXS424. Multipoint linkage analysis revealed that the likelihood for gene location is highest for the region on Xp. The region Xq26–q28, which has syntenic homology with the segment of the murine X chromosome carrying the locus for bent tail (Bn), a mouse model for X-linked NTD, is excluded as the location for the gene underlying X-linked NTD in the present family. Thus, the human homologue of the Bn gene and the present defective gene are not identical, suggesting that more than one gene on the X chromosome plays a role in the development of the neural tube.     

Translocation (X;13)(p11.21;q12.3) in a girl with incontinentia pigmenti and bilateral retinoblastoma

A de novo t(X;13)(p11.21;q12.3) translocation is described in an 19-month-old girl with incontinentia pigmenti (IP) and bilateral retinoblastoma. Based on previously reported two girls and this patient, each with a structural X chromosome abnormality and IP, it was assumed that the locus for IP is at Xp11.21. Q-banding analysis revealed that the translocated chromosomes were of paternal origin. The derivative X chromosome was late-replicating in 9% of cultured peripheral blood lymphocytes and in 1% of skin fibroblasts. The erythrocyte esterase D activity in the patient was normal. Several possibilities were considered for possible causative relationship between the X/13 translocation and the development of retinoblastoma. One possibility involved functional monosomy of 13q14 in a minority of retinoblasts due to the spreading of inactivation of the translocated X chromosome segment.     

Assignment of anonymous DNA probes to specific intervals of human chromosomes 16 and X

Summary Anonymous DNA probes mapping to human chromosome 16 and the distal region of the human X chromosome were isolated from a genomic library constructed using lambda EMBL3 and DNA from a mouse/human hybrid. The hybrid cell contained a der(16)t(X;16)(q26;q24) as the only human chromosome. Fifty clones were isolated using total human DNA as a hybridisation probe. Forty six clones contained single copy DNA in addition to the repetitive DNA. Pre-reassociation with sonicated human DNA was used to map these clones by a combination of Southern blot analysis of a hybrid cell panel containing fragments of chromosomes 16 and X and in situ hybridisation. One clone mapped to 16pter 16p13.11, one clone to 16p13.316p13.11, four clones to 16p13.316p13.13, two clones to 16p13.1316p13.11, one clone to 16p13.11, seven clones to 16p13.1116q12 or 16q13, four clones to 16q12 or 16q13, three clones to 16q1316q22.1, four clones to 16q22.10516q24, and nineteen clones to Xq26Xqter. Two clones mapping to 16p13 detected RFLPs. VK5 (D16S94) detected an MspI RFLP, PIC 0.37. VK20 (D16S96) detected a TaqI RFLP, PIC 0.37 and two MspI RFLPs, PIC 0.30 and 0.50. The adult polycystic kidney disease locus (PKD1) has also been assigned to 16p13. The RFLPs described will be of use for genetic counselling and in the isolation of the PKD1 gene. Similarly, the X clones may be used to isolate RFLPs for genetic counselling and the isolation of genes for the many diseases that map to Xq26qter.     

Molecular studies of a translocated (X;22) DiGeorge patient using somatic cell hybridization.

In order to better characterize the chromosomic rearrangement of an unbalanced 45XX t(X;22) (q28;q11) DiGeorge patient, a somatic hybrid clone segregating the translocated chromosome was constructed and investigated using X and 22 linked markers. Our study demonstrated that this de novo translocation was from paternal origin. The breakpoint was assigned between DXS296 and IDS loci at Xq28 and between D22S9 and BCRL2 at 22q11. This observation and published data allow to locate a "critical region" for DiGeorge syndrome between these two last loci on 22q11. Our hybrid clone may be a useful tool for mapping new probes arising in this region.     

The chromosome breakpoint at 14q32 in an ataxia telangiectasia t(14;14) T cell clone is different from the 14q32 breakpoint in Burkitts and an inv(14) T cell lymphoma

Summary The T cell receptor chain gene locus and the immunoglobulin heavy chain gene locus (IgH) have previously been mapped to the q11 and q32 positions respectively of the human chromosome 14. Both of these sites are also common breakpoints in lymphocytes from ataxia telangiectasia (A-T) patients. Using in situ hybridisation we show that the 14q32 breakpoint in an A-t non-leukaemic T cell clone with t(14;14) translocation, lies outside the IgH locus and proximal to it with respect to the centromere. The 14q11-14qter segment of the homologous chromosome 14 carrying the constant gene region of the chain locus is translocated to this 14q32 position.     

Isodicentric X chromosome in a patient with Turner syndrome — implications for localization of the X-inactivation center

Summary Cytogenetic analyses have previously shown that the region Xq11.2–q21 is retained in all structurally abnormal X chromosomes. From these observations the conclusion has been drawn that this critical region on the proximal long arm of the X chromosome contains the locus controlling X-inactivation. Structurally abnormal X chromosomes without the X-inactivation center would allow nullisomy, disomy, or trisomy for genes on the X chromosome, and this condition is presumed nonviable. We studied a 28-year-old woman with primary amenorrhea and features of Turner syndrome who had an unusual isodicentric chromosome of the short arm of X. This patient provided us with the opportunity to more closely define the location of the X-inactivation center. High resolution chromosome analysis showed a 46,X,idic(X)(pterq13.2::q13.2pter) chromosome pattern in 94% of her cells and a 45,X complement in 6%. Replication studies showed this derivative X chromosome to be late-replicating (inactive) in all cells analyzed. DNA analysis confirmed the breakpoint of the isodicentric chromosome to be proximal to PGK1. Based on these results, the locus for the X-inactivation center can be refined to be within Xq11.2–q13.2.     

Isolation and characterization of a highly polymorphic human locus (DXS455) in proximal Xq28

Human Xq28 is highly gene dense with over 27 loci. Because most of these genes have been mapped by linkage to polymorphic loci, only one of which (DXS52) is informative in most families, a search was conducted for new, highly polymorphic Xq28 markers. From a cosmid library constructed using a somatic cell hybrid containing human Xq27.3----qter as the sole human DNA, a human-insert cosmid (c346) was identified and found to reveal variation on Southern blot analyses with female DNA digested with any of several different restriction endonucleases. Two subclones of c346, p346.8 and p346.T, that respectively identify a multiallelic VNTR locus and a frequent two-allele TaqI polymorphism were isolated. Examination of 21 unrelated females showed heterozygosity of 76 and 57%, respectively. These two markers appeared to be in linkage equilibrium, and a combined analysis revealed heterozygosity in 91% of unrelated females. Families segregating the fragile X syndrome with key Xq28 crossovers position this locus (designated DXS455) between the proximal Xq28 locus DXS296 (VK21) and the more distal locus DXS374 (1A1), which is proximal to DXS52. DXS455 is therefore the most polymorphic locus identified in Xq28 and will be useful in the genetic analysis of this gene dense region, including the diagnosis of nearby genetic disease loci by linkage.     

Linkage analysis of families with fragile-X mental retardation, using a novel RFLP marker (DXS 304).

A new polymorphic DNA marker U6.2, defining the locus DXS304, was recently isolated and mapped to the Xq27 region of the X chromosome. In the previous communication we describe a linkage study encompassing 16 fragile-X families and using U6.2 and five previously described polymorphic markers at Xq26-q28. One recombination event was observed between DXS304 and the fragile-X locus in 36 informative meioses. Combined with information from other reports, our results suggest the following order of the examined loci on Xq: cen-F9-DXS105-DXS98-FRAXA-DXS304-(DXS52-F8 -DXS15). The locus DXS304 is closely linked to FRAXA, giving a peak lod score of 5.86 at a corresponding recombination fraction of .00. On the basis of the present results, it is apparent that U6.2 is a useful probe for carrier and prenatal diagnosis in fragile-X families.     

DNA replication and inactivation patterns in structural abnormality of sex chromosomes

Summary High resolution chromosome analysis and bromodeoxyuridine (BrdUrd) incorporation have been applied to study patterns of chromosomal replication (inactivation) in two cases of unbalanced X-autosome translocations, seven cases of X and Y chromosome rings or fragments, and five cases of dicentric isochromosomes (Xq). Our results indicate the following: (1) In (X-A) translocations, detailed replicational analysis of the translocated autosomal segment is informative. Absence of spreading effect and partial-incomplete spreading effect are the most common observations. (2) Sex chromosome derived fragments and rings can be differentiated based on their replicational features. (3) Dicentric isochromosomes (Xq) can be classified based on intercentromeric distances, replicational asynchrony, and centromere inactivation. (4) A correlation between intercentromeric distance and degree of 45,X mosaicism was observed in dicentric i(Xq) chromosomes.Evidence for spreading effect based on our results and on the review of the literature has been critically analyzed and general rules in evaluating spreading effects (SE) proposed. The cytologic detection of active regions on the late replicating X chromosome and the inactivation capacity of the juxtacentromeric region of Xp is evaluated. It is proposed that centromere suppression and underreplication are related phenomena. Finally, the analysis of informative replicational stages is emphasized and the application of their analysis in basic and clinical cytogenetics demonstrated.     

Localization of the human T-cell receptor gamma locus (TCRG) to 7p14----p15 by in situ hybridization

The human T cell receptor gamma locus (TCRG) has previously been localized on chromosome 7 at band 7p15. In situ hybridization of a TCRG-specific probe allowed us to map the locus at 7p14----p15. These data confirm the previous localization and are in agreement with the molecular characterization of an inversion of chromosome 7, inv(7) (p14q35) which involves the TCRG locus.     

Mapping of the gene for X-chromosomal split-hand/split-foot anomaly to Xq26–q26.1

A large inbred kindred from Pakistan in which an isolated type of split-hand/split-foot anomaly is transmitted as an X-chromosomal trait has previously been described. An X/autosomal translocation and an X-chromosomal rearrangement have been excluded by cytogenetic studies. In order to map the gene responsible for this disorder, linkage analysis has been performed by using 14 highly polymorphic DNA markers distributed over the whole X chromosome. Two-point linkage analysis between the disease locus and X-chromosomal marker loci gives maximal lod scores at = 0.00 with the loci DXS294 (Z _max= 5.13) and HPRT (Z _max= 4.43), respectively, suggesting that the gene for the X-chromosomal split-hand/split-foot anomaly is localized at Xq26–q26.1.     

Exclusion mapping of the X-linked dominant chondrodysplasia punctata/ichthyosis/cataract/short stature (Happle) syndrome: possible involvement of an unstable pre-mutation

Summary Homology with the mouse bare patches mutant suggests that the gene for the X-linked dominant chondrodysplasia punctata / ichthyosis / cataract / short stature syndrome (Happle syndrome) is located in the human Xq28 region. To test this hypothesis, we performed a linkage study in three families comprising a total of 12 informative meioses. Multiple recombinations appear to exclude the Xq28 region as the site of the gene. Surprisingly, multiple crossovers were also found with 26 other markers spread along the rest of the X chromosome. Two-point linkage analysis and analysis of recombination chromosomes seem to exclude the gene from the entire X chromosome. Three different mechanisms are discussed that could explain the apparent exclusion of an X-linked gene from the X chromosome by linkage analysis: (a) different mutations on the X chromosome disturbing X inactivation, (b) metabolic interference, i.e. allele incompatibility of an X-linked gene, and (c) an unstable pre-mutation that can become silent in males. We favour the last explanation, as it would account for the unexpected sex ratio (MF) of 1.21 among surviving siblings, and for the striking clinical variability of the phenotype, including stepwise increases in disease expression in successive generations.     

A regional localisation for an X-linked suppressor gene (XS) for the Lutheran blood group

Summary Suppression of Lutheran blood group expression is usually associated with an autosomal dominant suppressor gene In(Lu) which results in the rare Lu(a-b-) phenotype. X-linked recessive suppression can also occur under the control of the XS locus with normal (XS1) and suppressor (XS2) alleles. The only known kindred with XS2 segregating was examined for polymorphic DNA markers with known regional localisations on the X chromosome. Two point linkage analysis suggested linkage of XS to DXS14 (p58.1) with =0.00, =1.96. DXS14 is situated near the centromere at Xp11. Recombinants with DXS84 (distal to DXS14 on Xp) and recombinants with DXYS1 (pDP34) (on the proximal part of Xq) suggests a localisation for XS near the centromere, between DXS84 and DXYS1 (Xp21.2-Xq21.1). Linkage to a marker on the X chromosome confirms the original assignment of XS to the X chromosome, which was based on pedigree inspection from this family.