Deletions of the steroid sulphatase gene in “classical” X-linked ichthyosis and in X-linked ichthyosis associated with Kallmann syndrome

Summary We have studied 16 men, from 10 unrelated Italian families, affected by steroid suphatase (STS) deficiency, which is the basic defect of X-linked ichthyosis (XLI). The patients' clinical diagnoses were of either isolated ichthyosis or ichthyosis associated with Kallmann syndrome (KS) (hypogonadotropic hypogonadism and anosmia). DNA from patients and their relatives was analysed by Southern blotting followed by hydridization with an STS cDNA probe. None of the patients affected by either XLI or XLI/KS showed any hybridization signal, thus revealing a deletion in the STS gene. We suggest that a gene deletion may be the most common molecular defect involved in XLI and that the syndrome XLI/KS may be due to a deletion of both the STS and the KS loci.     

Deletion pattern of the STS gene in X-linked ichthyosis in a Mexican population

BACKGROUND: X-linked ichthyosis (XLI) is an inherited disorder due to steroid sulfatase deficiency (STS). Most XLI patients (>90%) have complete deletion of the STS gene and flanking sequences. The presence of low copy number repeats (G1.3 and CRI-S232) on either side of the STS gene seems to play a role in the high frequency of these interstitial deletions. In the present study, we analyzed 80 Mexican patients with XLI and complete deletion of the STS gene. MATERIALS AND METHODS: STS activity was measured in the leukocytes using 7-[(3)H]-dehydroepiandrosterone sulfate as a substrate. Amplification of the regions telomeric-DXS89, DXS996, DXS1139, DXS1130, 5' STS, 3' STS, DXS1131, DXS1133, DXS237, DXS1132, DXF22S1, DXS278, DXS1134-centromeric was performed through PCR. RESULTS: No STS activity was detected in the XLI patients (0.00 pmoles/mg protein/h). We observed 3 different patterns of deletion. The first two groups included 25 and 32 patients, respectively, in which homologous sequences were involved. These subjects showed the 5' STS deletion at the sequence DXS1139, corresponding to the probe CRI-S232A2. The group of 32 patients presented the 3' STS rupture site at the sequence DXF22S1 (probe G1.3) and the remaining 25 patients had the 3' STS breakpoint at the sequence DXS278 (probe CRI-S232B2). The third group included 23 patients with the breakpoints at several regions on either side of the STS gene. No implication of the homologous sequences were observed in this group. CONCLUSION: These data indicate that more complex mechanisms, apart from homologous recombination, are occurring in the genesis of the breakpoints of the STS gene of XLI Mexican patients.     

Long-range physical mapping around the human steroid sulfatase locus

The region of the human X chromosome containing the steroid sulfatase locus was analyzed by pulsed-field gel electrophoresis. Restriction site maps were generated for the X chromosome in the blood of a normal male individual and that in the mouse-human hybrid cell line ThyB-X; these maps extend over approximately 4.3 Mb of DNA of the former, and 3.2 Mb of the latter. Physical linkage was defined between the STS locus and sequences detected by the probes GMGX9 (DXS237), GMGXY19 (DYS74), CRI-S232 (DXS278), and dic56 (DXS143), and the order telomere--(STS, DYS74)--DXS237--DXS278--DXS143--centromere was deduced. The pulsed-field maps were used to demonstrate a deletion of 180 kb of DNA from the X chromosome of an individual with X-linked ichthyosis. Also, possible locations for the Kallmann syndrome gene were revealed, and the distance between the steroid sulfatase locus and the pseudoautosomal region was estimated to be at least 4 Mb.     

X-linked ichthyosis,due to steroid sulphatase deficiency,associated with Kallmann syndrome (hypogonadotropic hypogonadism and anosmia): linkage relationships with Xg and cloned DNA sequences from the distal short arm of the X chromosome

Summary We report a large Italian pedigree in which five out of six males are affected by a syndrome, following an X-linked inheritance pattern, characterized by ichthyosis, hypogonadotropic hypogonadism, and anosmia. The concurrence of features of X-linked ichthyosis (XLI) with those of Kallmann syndrome, another disease often inherited as an X-linked trait, prompted us to perform biochemical, cytogenetic, and molecular studies in relation to the short arm of the X chromosome (Xp). Steroid sulphatase (STS) activity was found to be completely deficient in all affected members of the family. Prometaphase chromosome analyses of two obligate heterozygous women and one affected male showed normal karyotypes. Xg blood group antigen analysis and molecular studies employing cloned DNA sequences from the distal segment of the Xp (probes RC8, 782, dic56, and M1A), did not provide evidence for deletions or rearrangements of the X chromosome. The linkage analysis showed no crossovers between the disease, Xg, and DXS 143, the locus defined by probe dic56, thus suggesting the possibility of a linkage between these two markers of the distal segment of Xp and the X-linked ichthyosis, hypogonadism, and anosmia syndrome.     

Molecular analysis of X-linked ichthyosis in Japan

BACKGROUND: X-linked ichthyosis (XLI) is an inherited skin disorder caused by a deficiency of steroid sulfatase (STS). The gene and protein of STS were examined in 19 Japanese patients with XLI. RESULTS: In Western blotting analysis, no cross-reacting peptide was detected in the patients' placenta, although a single band (63 kD) corresponding to STS in a normal subject was observed. Southern blotting was performed using EcoRI digests of cellular DNA from 13 XLI patients and full-length human STS cDNA as a probe. Normal males had bands of 20, 15, 10, 9.0, 6.1, 4.2, 2.6, and 1.5 kb. Twelve of the 19 patients had only 20- and 1.5-kb bands. Only one patient had the same band pattern as that of normal males. The STS gene was analyzed by PCR in 6 of the 19 patients. PCR amplification products were sequenced to analyze the STS gene. Two cases with one-base change in the STS gene and variation in amino acids H444R and E560P were found. Mutant STS cDNA was transfected into COS-1 cells and the STS enzyme activity was assayed. The enzyme activities were less than the minimum detection value of the detection system. CONCLUSIONS: These results suggest that XLI is mainly caused by an extensive deletion of the STS gene and that the PCR method is useful for detection of STS point mutations.     

Multipoint linkage analysis of steroid sulfatase (X-linked ichthyosis) and distal Xp markers

Six families with steroid sulfatase deficiency (STS; X-linked ichthyosis) have been studied with the Xg blood group (XG) and the DNA markers dic56 (DXS143), 782 (DXS85), pD2 (DXS43), and GMGX9. Carrier status of females was determined by assay of STS in hair roots. GMGX9 detects a frequent restriction fragment length polymorphism and also identifies a deletion in the majority of families with STS deficiency, including five of the six reported here. The linkage relationship of this marker to the others was studied in normal three-generation families yielding 32 phase-known meioses informative for two or more markers. No recombinants were observed between STS and GMGX9, giving a maximum lod score of 8.73 at zero recombination. Multipoint linkage analysis taking STS and GMGX9 as a single locus and incorporating two-point marker data and STS-XG data from published studies gave the map (Sequence: see text). This order was 2.4 times more likely than with (STS,GMGX9) and dic56 reversed and is supported by our findings in a male with steroid sulfatase deficiency due to a deletion of Xp22.3 which encompasses the XG locus. He is deleted for GMGX9 but shows normal hybridization to dic56 and 782.     

A multipoint linkage map of the distal short arm of the human X chromosome.

The distal portion of the short arm of the human X chromosome (Xp) exhibits many unique and interesting features. Distal Xp contains the pseudoautosomal region, a number of disease loci, and several cell-surface markers. Several genes in this area have also been observed to escape X-chromosomal inactivation. The characterization of new polymorphic loci in this region has permitted the construction of a refined multipoint linkage map extending 15 cM from the Xp telomere. This interval is known to contain the loci for the diseases X-linked ichthyosis, chondrodysplasia punctata, and Kallmann syndrome, as well as the cell-surface markers Xg and 12E7. This region also contains the junction between the pseudoautosomal region and strictly X-linked sequences. The locus MIC2 has been demonstrated by linkage analysis to be indistinguishable from the pseudoautosomal junction. The steroid sulfatase locus has been mapped to an interval adjacent to the DXS278 locus and 6 cM from the pseudoautosomal junction. The polymorphic locus (STS) DXS278 was shown to be informative in all families studied, and linkage analysis reveals that the locus represents a low-copy repeat with at least one copy distal to the STS gene. The generation of a multipoint linkage map of distal Xp will be useful in the genetic dissection of many of the unique features of this region.     

An Xp22 microdeletion associated with ocular albinism and ichthyosis: approximation of breakpoints and estimation of deletion size by using cloned DNA probes and flow cytometry.

Ocular albinism of the Nettleship-Falls type (OA1) and X-linked ichthyosis (XI) due to steroid sulfatase (STS) deficiency are cosegregating in three cytogenetically normal half-brothers. The mother has patchy fundal hypopigmentation consistent with random X inactivation in an OA1 carrier. Additional phenotypic abnormalities that have been observed in other STS "deletion syndromes" are not present in this family. STS is entirely deleted on Southern blot in the affected males, but the loci MIC2X, DXS31, DXS143, DXS85, DXS43, DXS9, and DXS41 are not deleted. At least part of DXS278 is retained. Flow cytometric analysis of cultured lymphoblasts from one of the XI/OA1 males and his mother detected a deletion of about 3.5 million bp or about 2% of the X chromosome. Southern blot and RFLP analysis in the XI/OA1 family support the order tel-[STS-OA1-DXS278]-DXS9-DXS41-cen. An unrelated patient with the karyotype 46,X,t(X;Y) (p22;q11) retains the DXS143 locus on the derivative X chromosome but loses DXS278, suggesting that DXS278 is the more distal locus and is close to an XI/OA1 deletion boundary. If a contiguous gene deletion is responsible for the observed XI/OA1 phenotype, it localizes OA1 to the Xp22.3 region.     

Tight linkage between myotonic dystrophy and apolipoprotein E genes revealed with allele-specific oligonucleotides

Summary The X chromosomes of individuals with isolated steroid sulphatase deficiency (X-linked ichthyosis) from ten families were studied by flow karyotype analysis. In four of the families, a small but significant reduction in the relative fluorescence of the X chromosome was detected consistent with a deletion ranging from 1.2%–3.4% of the X and amounting to a DNA loss of 1.9–5.2 million base pairs. In the remaining six families, three of which demonstrated a molecular deletion of the DNA sequence GMGX9 (DXS237), the relative fluorescence of the X chromosomes was indistinguishable from normal. The phenotypes of those with X deletions detectable by flow cytometry were similar to those of patients without such deletions.     

Linkage analysis in X-linked ichthyosis (steroid sulfatase deficiency)

Summary Linkage analysis has been carried out in nine unrelated families segregating for X-linked ichthyosis (steroid sulfatase deficiency) using seven polymorphic DNA markers from the distal Xp. Close linkage was found between the disease locus and the loci DXS16, DXS89, and DXS143. In all families except one, Southern hybridization with the human steroid sulfatase cDNA and GMGX9 probes showed a deletion of corresponding loci in affected males. Three patients belonging to the same family had no evident deletion with either of the two above-mentioned probes. None of the other six DNA loci included in the linkage analysis were found to be deleted.     

Definitive localization of X-linked Kallman syndrome (hypogonadotropic hypogonadism and anosmia) to Xp22.3: close linkage to the hypervariable repeat sequence CRI-S232.

Kallmann syndrome is a genetically heterogeneous disease characterized by hypogonadotropic hypogonadism and anosmia. Six families in which the disorder followed an X-linked inheritance were investigated by linkage analysis. Diagnostic criteria were uniformly applied and included tests for hypogonadotropic hypogonadism and anosmia. Close linkage was found by using the hypervariable repeated sequence CRI-S232 (DXS278) previously mapped to Xp22.3. At a maximum lod score of 6.5, the recombination fraction was calculated as .03. Of 30 fully informative meioses, one recombination between the disease locus and the loci recognized by probe CRI-S232 was observed. When an independent approach is used, these results confirm the X-linked Kallmann syndrome assignment previously made by deletion mapping, and allow definitive localization of the syndrome assignment previously made by deletion mapping, and allow definitive localization of the syndrome to the Xp22.3 region. This opens the way to carrier detection and to the identification of a gene responsible for this disorder.     

Partial deletions of a sequence family ("DXS278") and its physical linkage to steroid sulfatase as detected by pulsed-field gel electrophoresis

pCRI-S232 (DXS278) is a 7-kb genomic sequence that hybridizes to multiple polymorphic X-linked restriction fragments on standard Southern analysis. Physical mapping of pCRI-S232 by pulsed-field gel electrophoresis (PFGE) suggests that a sequence in S232 is repeated in multiple X-chromosomal regions in normal individuals. Steroid sulfatase (STS) and DXS237 each hybridize to two of six X-linked SfiI fragments detected by S232. Two independent familial STS deletions, one of which is associated with a phenotype of ichthyosis plus ocular albinism (XI/OA1) and the other with nystagmus plus Rud syndrome, lack some but not all of the normal S232 PFGE fragments. We isolated a DNA fragment, E25B1.8, from a cosmid that contains S232. E25B1.8 detects a subset of the S232 polymorphic fragments on standard Southern blots plus new constant fragments; some, but not all, of the E25B1.8-hybridizing fragments are deleted in the XI/OA1 and Rud syndrome/nystagmus males. The simpler, but highly informative, polymorphism detected by E25B1.8 (DXS452) also eliminates an "intralocus" recombination seen with S232. We conclude that (1) males with STS deletions and complex phenotypes are partially deleted for DXS278, (2) DXS237 and part of DXS278 lie within 800 kb of STS, and (3) a repeat sequence within or around pCRI-S232 is probably located in multiple X-chromosomal locations spanning at least 2-3 Mb.     

Deletion of a DNA sequence in eight of nine families with X-linked ichthyosis (steroid sulphatase deficiency).

Deficiency of steroid sulphatase (STS) is associated with ichthyosis, with failure of the placental production of oestriol in late pregnancy and with difficulties in childbirth. The STS gene has been localised by deletion mapping to the distal tip of the snort arm of the X chromosome, and is of interest in that it appears to escape X-inactivation. We have constructed an X-specific DNA library and screened it for single copy DNA sequences which lie at the distal end of Xp. The sequence GMGX9 was found to map in the interval Xp22.3-pter and to detect a frequent HindIII polymorphism. We have used GMGX9 in linkage studies in families with classical X-linked ichthyosis and this has not only shown tight linkage with STS deficiency but has also revealed that the sequence is deleted in affected males in eight of nine families. GMGX9 is present in all of 26 normal male individuals so far examined. Our findings suggest that a high proportion of the mutations at the STS locus leading to enzyme deficiency are deletions, presumably generated by unequal cross-over events in female meiosis or by illegitimate X-Y interchange in male meiosis.     

Xp22.3 interstitial deletion: A recognizable chromosomal abnormality encompassing VCX3A and STS genes in a patient with X-linked ichthyosis and mental retardation

X-linked ichthyosis is a genetic disorder affecting the skin and caused by a deficit in the steroid sulfatase enzyme (STS), often associated with a recurrent microdeletion at Xp22.31. Most of the STS deleted patients have X-linked ichthyosis as the only clinical feature and it is believed that patients with more complex disorders including mental retardation could be present as a result of contiguous gene deletion. In fact, VCX3A gene, a member of the VCX (variable charge, X chromosome) gene family, was previously proposed as the candidate gene for X-linked non-specific mental retardation in patients with X-linked ichthyosis.     

Steroid sulphatase in man: A non inactivated X-locus with partial gene dosage compensation

Summary Steroid sulphatase (STS) activity was measured with two different steroid substrates in leucocytes from normal human males and females, from females heterozygous for STS deficiency and recessive X-linked ichthyosis, and from individuals with numerical X chromosome aberrations. The results indicate non-inactivation with a partial gene dosage compensation at the STS locus. It is estimated that STS loci on inactive X chromosomes express approximately 45% of the STS activity originating from STS loci on active X chromosomes. It is also demonstrated that 45.XO (Turner syndrome) and 47,XXY (Klinefelter syndrome) individuals have abnormal STS enzyme levels compared with normal women and men, respectively.Supported by the Danish Cancer Society     

Phenotypic variability in X-linked ocular albinism: relationship to linkage genotypes.

One hundred nineteen individuals from 11 families with X-linked ocular albinism (OA1) were studied with respect to both their clinical phenotypes and their linkage genotypes. In a four-generation Australian family, two affected males and an obligatory carrier lacked cutaneous melanin macroglobules (MMGs); ocular features were identical to those of Nettleship-Falls OA1. Four other families had more unusual phenotypic features in addition to OA1. All OA1 families were genotyped at DXS16, DXS85, DXS143, STS, and DXS452 and for a CA-repeat polymorphism at the Kallmann syndrome locus (KAL). Separate two-point linkage analyses were performed for the following: group A, six families with biopsy-proved MMGs in at least one affected male; group B, four families whose biopsy status was not known; and group C, OA-9 only (16 samples), the family without MMGs. At the set of loci closest to OA1, there is no clear evidence in our data set for locus heterogeneity between groups A and C or among the four other families with complex phenotypes. Combined multipoint analysis (LINKMAP) in the 11 families and analysis of individual recombination events confirms that the major locus for OA1 resides within the DXS85-DXS143 interval. We suggest that more detailed clinical evaluations of OA1 individuals and families should be performed for future correlation with specific mutations in candidate OA1 genes.     

A patient with an interstitial deletion in Xp22.3 locates the gene for X-linked recessive chondrodysplasia punctata to within a one megabase interval

A male patient carrying an interstitial deletion in Xp22.3 and affected by Kallmann syndrome, X-linked ichthyosis and mental retardation, but without chondrodysplasia punctata or short stature, was investigated with molecular probes from the distal Xp22.3 region. By means of a novel probe, M115, from the relevant region, the distal deletion breakpoint was shown to be between 3.18 and 3.57 Mb from Xptel. As the patient is not affected by X-linked recessive chondrodysplasia punctata, the gene for this disease can therefore be located to within an interval of less than one megabase proximal to the pseudoautosomal boundary. If the chondrodysplasia punctata gene is associated with a CpG island, this leaves only two islands at 2760 and 3180 kb from the Xp telomere as the most promising candidate sites for this gene.     

Linkage analysis in X-linked ocular albinism.

We studied the linkage of X-linked Nettleship-Falls ocular albinism (OA1) to Xp22.1-Xp22.3 RFLPs at 12 loci in five families, including one in which OA1 cosegregates with a deletion of steroid sulfatase (STS). We found evidence for tight linkage of OA1 to the Xp22.3 loci DXS143, STS, and DXS452. DXS452, a newly described polymorphism detected by the probe E25B1.8, is part of the sequence family "DXS278" (pCRI-S232), but represents a single genetic locus. Every female in this study was heterozygous for the DXS452 RFLP. Thus, this marker will be extremely useful for family studies and genetic counseling. Analysis of individual recombinations suggests that OA1 maps between DXS143 and DXS85. Multipoint linkage analysis was consistent with this localization but was not statistically significant. These data suggest that OA1 lies proximal to the deletion in a previously described family with OA1 and STS deletion, but maps within the Xp22.3-Xp22.2 region.