Construction of a human X-chromosome-enriched phage library which facilitates analysis of specific loci

Invited Review: Polycomb group genes in the regeneration of the healthy and pathological skeletal muscle

The polycomb group (PcG) proteins are epigenetic repressors required during key developmental processes, such as maintenance of cell identity and stem cell differentiation. To exert their repressive function, PcG proteins assemble on chromatin into multiprotein complexes, known as polycomb repressive complex 1 and 2. In this review, we will focus on the role and mode of function of PcG proteins in the development and regeneration of the skeletal muscle, both in normal and pathological conditions and we will discuss the emerging concept of modulation of their expression to enhance the muscle-specific regenerative process for patient benefit.

Advanced molecular cytogenetics in human and mouse

Fluorescence in situ hybridization, spectral karyotyping, multiplex fluorescence in situ hybridization, comparative genomic hybridization, and more recently array comparative genomic hybridization, represent advancements in the field of molecular cytogenetics. The application of these techniques for the analysis of specimens from humans, or mouse models of human diseases, enables one to reliably identify and characterize complex chromosomal rearrangements resulting in alterations of the genome. As each of these techniques has advantages and limitations, a comprehensive analysis of cytogenetic aberrations can be accomplished through the utilization of a combination approach. As such, analyses of specific tumor types have proven invaluable in the identification of new tumor-specific chromosomal aberrations and imbalances (aneuploidy), as well as regions containing tumor-specific gene targets. Application of these techniques has already improved the classification of tumors into distinct categories, with the hope that this will lead to more tailored treatment strategies. These techniques, in particular the application of tumor-specific fluorescence in situ hybridization probes to interphase nuclei, are also powerful tools for the early identification of premalignant lesions.

Characterization of the OFD1/Ofd1 genes on the human and mouse sex chromosomes and exclusion of Ofd1 for the Xpl mouse mutant

Oral-facial-digital type 1 (OFD1) syndrome is an X-linked dominant condition characterized by malformations of the face, oral cavity, and digits. The responsible gene, OFD1, maps to human Xp22 and has an unknown function. We isolated and characterized the mouse Ofd1 gene and showed that it is subject to X-inactivation, in contrast to the human gene. Furthermore, we excluded a role for Ofd1 in the pathogenesis of the spontaneous mouse mutant Xpl, which had been proposed as a mouse model for this condition. Comparative sequence analysis demonstrated that OFD1 is conserved among vertebrates and absent in invertebrates. This analysis allowed the identification of evolutionarily conserved domains in the protein. Finally, we report the identification of 18 apparently nonfunctional OFD1 copies, organized in repeat units on the human Y chromosome. These degenerate OFD1-Y genes probably derived from the ancestral Y homologue of the X-linked gene. The high level of sequence identity among the different units suggests that duplication events have recently occurred during evolution.

In vivo migration of transplanted myoblasts requires matrix metalloproteinase activity

Muscle cell migration and extracellular matrix remodeling are essential aspects of muscle development and regeneration. In this study, using a new technique to assess in vivo myoblast migration, we have confirmed previous results showing that the C(2)C(12) myoblast cell line exhibits a higher migratory capacity than primary myoblasts. To test the hypothesis that matrix metalloproteinases (MMPs) are required for the migration of C(2)C(12) myoblasts, we determined whether a synthetic metalloproteinase inhibitor, BB94 (Batimastat), inhibited this process in vivo. Pretreatment with BB94 for 3 days decreased the C(2)C(12) migration at 2 days after cell injection. Since MMP expression is thus necessary for myoblast migration, we have undertaken the identification and characterization of the MMPs expressed by the C(2)C(12) cell line. An RT-PCR assay was used to determine the pattern of MMP mRNA expression by the C(2)C(12) cell line. The proteolytic activities of the MMPs secreted in the culture medium were also assessed by gelatin zymography. The results showed that MMP2 (gelatinase A, 72-kDa type IV collagenase) and MT1-MMP transcripts were expressed by this cell line; however, only MMP2 was secreted and was able to be activated in the extracellular environment. This cell line failed to express MMP9 (gelatinase B, 92-kDa type IV collagenase), stromelysine 2, or stromelysine 3. Our observation that the membrane type MMP (MT1-MMP) transcript is also expressed by the C(2)C(12) suggests that the MMP2 proform (pro-MMP2), may be activated by the MT1-MMP. This possibility is supported by our observation that the pretreatment of C(2)C(12) with concanavalin A (which is known to induce the expression of MT1-MMP) resulted in the processing of pro-MMP2 to its mature form, in a dose-dependent manner. Overexpression and activation of MMP2 in normal myoblasts showed significant increased migration of mouse myoblasts in vivo. Our finding that MMP2 and MT1-MMP gene are coexpressed by C(2)C(12) myoblasts could account for the high migratory capacity of C(2)C(12). Together these results supported the importance of MMP2 and its activation by MT1-MMP for myoblast migration.

Characterization of Cxorf5 (71-7A), a novel human cDNA mapping to Xp22 and encoding a protein containing coiled-coil alpha-helical domains

The human X chromosome is known to contain several disease genes yet to be cloned. In the course of a project aimed at the construction of a transcription map of the Xp22 region, we fully characterized a novel cDNA, Cxorf5 (HGMW-approved symbol, alias 71-7A), previously mapped to this region but for which no sequence information was available. We isolated and sequenced the full-length transcript, which encodes a predicted protein of unknown function containing a large number of coiled-coild domains, typically presented in a variety of different molecules, from fibrous proteins to transcription factors. We showed that the Cxorf5 cDNA is ubiquitously expressed, undergoes alternative splicing, and escapes X inactivation. Furthermore, we precisely mapped two additional Cxorf5-related loci on the Y chromosome and on chromosome 5. By virtue of its mapping assignment to the Xp22 region, Cxorf5 represents a candidate gene for at least four human diseases, namely spondyloepiphiseal dysplasia late, oral-facial-digital syndrome type 1, craniofrontonasal syndrome, and a nonsyndromic sensorineural deafness.

X linked lymphoproliferative disease in a United Kingdom family

X linked lymphoproliferative disease (XLP; Duncan's disease) is a rare disorder affecting boys and characterised by a defective immune response to Epstein-Barr virus caused by a mutation in a gene located at chromosome Xq25. Three siblings with XLP in a single UK family are reported and the variation in phenotypic expression of the disease in these siblings described. One of the siblings with life threatening fulminant infectious mononucleosis was successfully treated by chemotherapy, followed by bone marrow transplantation using an unaffected brother as the donor. A healthy baby boy recently born into the family was identified as carrying the defective maternal X chromosome using molecular genetic linkage analysis. This family illustrates the extent of present understanding of this often fatal condition.

Analysis of a terminal Xp22.3 deletion in a patient with six monogenic disorders: implications for the mapping of X linked ocular albinism

The molecular characterisation of chromosomal aberrations in Xp22.3 has established the map position of several genes with mutations resulting in diverse phenotypes such as short stature (SS), chondrodysplasia punctata (CDPX), mental retardation (MRX), ichthyosis (XLI), and Kallmann syndrome (KAL). We describe the clinical symptoms of a patient with a complex syndrome compatible with all these conditions plus ocular albinism (OA1). He has a terminal Xp deletion of at least 10 Mb of DNA. Both the mother and sister of the patient are carriers of the deletion and show a number of traits seen in Turner's syndrome. The diagnosis of ocular albinism was confirmed in the patient and his mother, who shows iris translucency, patches and streaks of hypopigmentation in the fundus, and macromelanosomes in epidermal melanocytes. By comparative deletion mapping we can define a deletion interval, which locates the OA1 gene proximal to DXS143 and distal to DXS85, with the breakpoints providing valuable starting points for cloning strategies.

Fluorescence in situ hybridization establishes the order cen-DXS28(C7)-DXS67(B24)-DXS68(L1)-tel in human chromosome Xp21.3

We report here on the order of three DNA markers, C7, B24, and L1, based on the arrangement of their fluorescently labeled hybridization sites in interphase cell nuclei. The three markers map distal to the Duchenne muscular dystrophy (DMD), glycerol kinase deficiency (GKD), and adrenal hypoplasia (AHC) loci on human chromosome Xp21.3. Their order has been a matter of controversy. In interphase chromatin, B24 maps between C7 and L1. We estimate from interphase distance that C7 and L1 are 300-500 kb apart. When the three markers are hybridized to interphase cells of Nijmegen1, a patient with DMD, GKD, and AHC, only C7 appears to be deleted, rather than both C7 and L1, as had been reported elsewhere. C7 is also the only one of the three markers deleted in several other DMD patients studied by others. The deletion results indicate that C7 is the most proximal of the three markers and allow the trio of ordered probes to be oriented on the chromosome: cen-C7(DXS28)-B24(DXS67)-L1(DXS68)-tel.

DXS28 (C7) maps centromeric to DXS68 (L1-4) and DXS67 (B24) by deletion analysis

Complex glycerol kinase deficiency (CGKD) is a contiguous gene syndrome consisting of glycerol kinase deficiency together with Duchenne muscular dystrophy (DMD), congenital adrenal hypoplasia, and/or Aland Island eye disease. Deletion mapping of genomic DNA from patients with CGKD was carried out and allowed definitive ordering of loci DXS28 (C7), DXS68 (L1-4), and DXS67 (B24). Most reports have placed DXS68 centromeric to DXS28 and DXS67 on the basis of the initial mapping of the Iowa patient 3, but others have presented evidence consistent with the placement of DXS28 telomeric to DXS68 and DXS67. Through the use of DNA from CGKD patients with a variety of genomic deletions, this controversy is resolved and the order Xcen...DMD-DXS28-DXS68-DXS67...pter is definitively demonstrated.

A long range restriction map of the distal human X chromosome short arm around the steroid sulfatase locus

The distal short arm of the human X chromosome is of interest because it contains genes which escape X chromosome inactivation and because it is subject to frequent deletions in human patients. The steroid sulfatase gene has been particularly well studied as an example of a gene which escapes X inactivation and which is included in a number of these deletion events. For these reasons a physical map of the region around the STS gene would be of interest. We have constructed a rare cutting enzyme map of this area and have determined the position of several nearby markers with respect to STS. We have also oriented the 5' and 3' ends of the STS gene on this map and have determined the centromeric and telomeric portions of the region. Finally, we have shown that this map can be used to locate deletion breakpoints in STS deficient patients.

A method for generating hybrids containing nonselected fragments of human chromosomes

We have used an irradiation and fusion technique to generate somatic cell hybrids that contain human chromosomal fragments. As a model system, a human-hamster hybrid containing a single human X chromosome was gamma-irradiated and fused with a rodent line. Hybrids were obtained without imposing direct selection for human material. Analysis of 29 clones by in situ hybridization and Southern blotting revealed that human fragments were incorporated into the hybrid cell genomes in most lines. Like chromosome-mediated gene transfer (CMGT)-generated hybrids, these hybrids contained multiple human fragments and retained alphoid centromeric sequences with a high frequency. However, unlike the CMGT, human fragments (apart from alphoid sequences) of less than 10(7) bp showed no evidence for rearrangements. This technique provides a method for constructing hybrids that contain a limited number of small human fragments derived exclusively from any chromosome of choice without the need to impose selection. Such hybrids provide a valuable resource for high-resolution mapping over short distances and for the isolation of disease and other loci mapped genetically.

An extremely polymorphic locus on the short arm of the human X chromosome with homology to the long arm of the Y chromosome

A genomic DNA clone named CRI-S232 reveals an array of highly polymorphic restriction fragments on the X chromosome as well as a set of non-polymorphic fragments on the Y chromosome. Every individual has multiple bands, highly variable in length, in every restriction enzyme digest tested. One set of bands is found in all males, and co-segregates with the Y chromosome in families. These sequences have been regionally localized by deletion mapping to the long arm of the Y chromosome. Segregation analysis in families shows that all of the remaining fragments co-segregate as a single locus on the X chromosome, each haplotype consisting of three or more polymorphic fragments. This locus (designated DXS278) is linked to several markers on Xp, the closest being dic56 (DXS143) at a distance of 2 cM. Although it is outside the pseudoautosomal region, the S232 X chromosome locus shows linkage to pseudoautosomal markers in female meiosis. In determining the X chromosome S232 haplotypes of 138 offspring among 19 families, we observed three non-parental haplotypes. Two were recombinant haplotypes, consistent with a cross-over among the S232-hybridizing fragments in maternal meiosis. The third was a mutant haplotype arising on a paternal X chromosome. The locus identified by CRI-S232 may therefore be a recombination and mutation hotspot.

X/Y translocation in a family with X-linked ichthyosis, chondrodysplasia punctata, and mental retardation: DNA analysis reveals deletion of the steroid sulphatase gene and translocation of its Y pseudogene

We describe a family with two male members showing an X/Y translocation (karyotype: 46,Y,der(X)t(X;Y)(p22;q11]. At physical examination both patients showed ichthyosis, mental retardation and dysmorphic features. Chondrodysplasia punctata and short stature were present in one case. Direct DNA analysis, using a steroid sulphatase cDNA probe, was performed in one patient, his mother and sister, both carriers of the translocation. We found that the translocated region of the Y chromosome includes the steroid sulphatase pseudogene. These results suggest that in our patients the X/Y translocation may be derived from a recombinational event between homologous regions located on the short arm of the X chromosome and the long arm of the Y chromosome. Clinical and molecular studies on the present family add further information for the construction of a tentative physical map of the distal Xp.

A 10-megabase physical map of human Xp21, including the Duchenne muscular dystrophy gene

Using pulsed-field gel electrophoresis and 12 Xp21-derived DNA probes, we have constructed a continuous restriction map spanning more than 4 million base pairs (4 Mbp), including the Duchenne muscular dystrophy gene of more than 2 Mbp. This detailed map is part of a less detailed map spanning 10 Mbp, also spanning the genes for glycerol kinase and congenital adrenal hypoplasia, constructed under electrophoresis conditions which separated DNA fragments in the range 200 to 4000 kbp. DNA from three different tissues was analyzed, and differential methylation was observed.

Deletion proximal to DXS68 locus (L1 probe site) in a boy with Duchenne muscular dystrophy, glycerol kinase deficiency, and adrenal hypoplasia

We report a case of a boy with Duchenne muscular dystrophy (DMD) associated with GK deficiency (GK), congenital adrenal hypoplasia (AHC), and mental retardation. Cytogenetic analysis of prometaphasic chromosomes revealed an interstitial chromosome deletion at Xp21.2 possibly extending to Xp21.1 or Xp21.3. His phenotypically normal mother was heterozygous for this deletion. DNA probe analysis on Southern blots showed that the deletion affected the following probe sites: 754, pERT 84, 21A, XJ2.3, pERT 87, JBir, and J66-H1, whereas L1, C7, and CX5.4 probes gave a normal signal. Pulse field gel electrophoresis after SfiI digestion did not show abnormal fragments with L1. These data are consistent with a deletion of about 4 megabases and indicate that the GK and AHC loci are proximal to L1 and distal to J66-H1.

Microdeletions in patients with X-linked muscular dystrophy: molecular-clinical correlations

The DNA from 68 patients with X-linked (Duchenne and Becker) muscular dystrophy belonging to 49 unrelated families was analyzed for microdeletions using 13 closely linked or gene-specific DNA-markers. Fourteen patients from eight families showed a deletion involving a least one of the markers used, giving a deletion frequency of 16%. The proportion of families with deletions was 36% in the Becker and 8% in the Duchenne form of the disease. With one exception, the extent of the deletion was different in different families. All living, affected males from the same family carried the same deletion. The extent or the localization of the deletion did not correlate with clinical features such as severity of disease or mental retardation.

Familial deletion of Xp21.2 with glycerol kinase deficiency and congenital adrenal hypoplasia

Congenital adrenal hypoplasia (CAH) and glycerol kinase deficiency (GKD) were diagnosed in a male during the neonatal period. On prometaphase chromosomes there was an interstitial deletion involving Xp21.2 and possibly Xp21.3 in the propositus and his mother. Duchenne muscular dystrophy (DMD) was excluded on the basis of normal serum creatine kinase and a muscle biopsy. Molecular hybridization of DNA from the propositus with 11 probes covering Xp21, including the DMD locus, was normal. In situ hybridization with the probe pERT87.15 showed a normal signal at the expected site indicating that the DMD locus was preserved and not translocated. This suggests that the DMD locus is located at the most proximal part of the sub-band Xp21.2 or in Xp21.1, and that the DXS68 (probe L1) is far from it on the distal flanking DNA.

Physical mapping of genes and sequences at the end of the human X chromosome short arm

Human-rodent somatic cell hybrids containing deleted and translocated human X chromosomes have been used to map genes and sequences in and around the pseudoautosomal region. The following order was found: (DXS69, DXS70, DXS143)-(DXS31, STS)-MIC2. This order is consistent with the known inheritance patterns of DXS31, STS and MIC2. Assuming that the translocations and deletions we have studied are not complex rearrangements, we conclude that the pseudoautosomal region consists of less than 5 X 10(6) bp of DNA.

Genetic linkage study between the loci for Duchenne and Becker muscular dystrophy and nine X-chromosomal DNA markers

A set of nine polymorphic loci defined by DNA probes was studied for linkage with the disease locus in ten families with a history of Duchenne muscular dystrophy (DMD), and three families with a history of Becker muscular dystrophy (BMD). The results confirm DMD and BMD linkage to all marker loci and suggest closer linkage of several probes than hitherto detected. This will be of practical interest for risk calculations in affected families.

Long-range restriction map around the Duchenne muscular dystrophy gene

Duchenne muscular dystrophy is an X-linked recessive disease affecting about 1 in 4,000 newborn boys. As in many other inherited diseases, the biochemical basis of the condition is unknown, and as yet there is no effective treatment. Translocations, deletions and other mutations leading to the DMD phenotype are distributed over a chromosomal area of large, but unknown size. Using pulsed-field gradient gel electrophoresis, we have now determined restriction maps of a major fraction of this area, covering two regions of three million basepairs in total, and used it to determine the position of several probes linked to DMD. The maps establish physical distances between structural changes associated with the DMD phenotype and provide evidence for a CpG-rich island proximal to the area containing translocations and deletions associated with the DMD phenotype.

Construction and analysis of an EMBL-3 phage library containing partially digested human chromosome 21-specific DNA inserts (15-20 kb)

In the mouse-human hybrid cell line SCC 16-5, chromosome 21 is the only human chromosome present. Fractions highly enriched for this chromosome were obtained by applying the chromosome velocity sedimentation technique to this cell line. DNA prepared from these chromosomal fractions was partially digested with Mbo I, size fractionated on an NaCl gradient, and cloned in the EMBL-3 phage vector. The phage library thus prepared was highly enriched for human chromosome 21-specific recombinant DNA sequences 15-20 kb long. Of the approximately 21,000 phage clones obtained, at least 99% were recombinant. Following phage plaque filter hybridization and Southern blotting, it was found that half of the recombinants were positive for human repetitive DNA. Almost all phages harbored highly or middle repetitive human or mouse DNA sequences owing to the large size of the recombinant inserts. In this library, the human chromosome 21 is represented approximately four times. All human recombinants studied thus far contained DNA inserts originating from chromosome 21 only. The employed cloning strategy is discussed with regard to utility, purity, quality, and completeness of chromosome-specific recombinant DNA libraries.

Genetic counterselective procedure to isolate interspecific cell hybrids containing single human chromosomes: construction of cell hybrids and recombinant DNA libraries specific for human chromosomes 3 and 4

Counterselection against genes on human chromosome 5 was applied to interspecific human-Chinese hamster cell hybrids which retained this and one additional human chromosome in order to generate cell hybrids retaining single, nonselected human chromosomes. Using this procedure, stable cell hybrids which retain human chromosome 3 exclusively or human chromosome 4 exclusively were isolated. Complete recombinant genomic DNA libraries were prepared from each hybrid using the lambda cloning vector EMBL-4. These libraries represent sources of human DNA fragments derived specifically from chromosomes 3 and 4, respectively. Low-copy or unique human DNA fragments isolated from both libraries were analyzed to confirm their chromosomal origin and to determine the complexity of their hybridization patterns to total human DNA. These single human chromosome libraries represent a means to efficiently saturate chromosomes 3 and 4 with informative, polymorphic genetic markers. DNA fragments from the chromosome 4 library will be particularly useful in identifying additional genetic markers close to the Huntington's disease gene. The same genetic counterselective procedure can be utilized to derive several additional cell hybrids with single human chromosomes.

Detection of deletions spanning the Duchenne muscular dystrophy locus using a tightly linked DNA segment

The Duchenne muscular dystrophy (DMD) locus has been localized to the short arm of the human X chromosome (Xp21) by detection of structural abnormalities and by genetic linkage studies. A library highly enriched for human DNA from Xp21 was constructed using DNA isolated from a male patient who had a visible deletion and three X-linked disorders (DMD, retinitis pigmentosa and chronic granulomatous disease). Seven cloned DNA probes from this library and the probe 754 (refs 5, 8) are used in the present study to screen for deletions in the DNA isolated from 57 unrelated males with DMD. Five of these DMD males are shown to exhibit deletions for one of the cloned DNA segments and at least 38 kb of surrounding DNA. In addition, two subclones from the same region detect four restriction fragment length polymorphisms which exhibit no obligate recombination with DMD in 34 meiotic events. These new DNA segments will complement the existing Xp21 probes for use in carrier detection and prenatal diagnosis of DMD. Elucidation of the end points of the five deletions will help delineate the extent of the DMD locus and ultimately lead to an understanding of the specific sequences involved in DMD.