Topological organization of the MYC/IGK locus in Burkitt's lymphoma cells assessed by nuclear halo preparations.

In Burkitt's lymphoma (BL) cells characteristic chromosomal translocations juxtapose the MYC oncogene to one of the three immunoglobulin (IG) gene loci. This results in deregulation of MYC expression through IG gene enhancer elements. As enhancers and MYC promoters can be as much as several hundred kilobases apart, long-distance effects are to be postulated, which affect chromatin organization. Since transcriptionally active and inactive sequences can be distinguished based on their localization in nuclear halo preparations, we used this technique to assess the topology of wild-type and translocated MYC and IGK genes. Following visualization of these genes by fluorescence in situ hybridization, the signal distribution was determined in nuclear halo structures of human monocytes and the BL-derived cell line LY66. MYC signals derived from the non-translocated chromosome 8 were found equally distributed between the residual nucleus and the surrounding DNA halo. In contrast, the activated MYC and IGK genes on the translocated chromosome in LY66 cells were associated with the residual nucleus in 78 and 88% of cases, respectively. In LY66 cells, attachment to the residual nucleus was restricted to a DNA segment 30 to 50 kb downstream of MYC, while in monocytes it was dispersed over 80 kb around the MYC gene. These findings indicate a specific chromatin organization for the activated MYC locus. Distance measurements between MYC and IGK signals revealed shorter values than expected from their linear distance (325 kb), indicating a back folding of the DNA backbone. Thus, there is strong evidence for a specific topological organization, which is functionally related to the MYC activation status with the specific folding of the DNA strand likely reflecting maintenance of a spatial interaction between IGK enhancer and MYC promoter elements.

A translocation breakpoint cluster disrupts the newly defined 3' end of the SNURF-SNRPN transcription unit on chromosome 15.

Balanced translocations affecting the paternal copy of 15q11--q13 are a rare cause of Prader-Willi syndrome (PWS) or PWS-like features. Here we report on the cytogenetic and molecular characterization of a de novo balanced reciprocal translocation t(X;15)(q28;q12) in a female patient with atypical PWS. The translocation breakpoints in this patient and two previously reported patients map 70-80 kb distal to the SNURF-SNRPN gene and define a breakpoint cluster region. The breakpoints disrupt one of several hitherto unknown 3' exons of this gene. Using RT--PCR we demonstrate that sequences distal to the breakpoint, including the recently identified C/D box small nucleolar RNA (snoRNA) gene cluster HBII-85 as well as IPW and PAR1, are not expressed in the patient. Our data suggest that lack of expression of these sequences contributes to the PWS phenotype.

Gene structure and expression of the mouse dyskeratosis congenita gene, dkc1.

Mutations in the DKC1 gene are responsible for causing X-linked recessive dyskeratosis congenita (DKC) and a more severe allelic variant of the disease, Hoyeraal-Hreidarsson syndrome. Both diseases are characterized by progressive and fatal bone marrow failure. The nucleolar protein dyskerin is the pseudouridine synthase component of the box H+ACA snoRNAs and also interacts with the RNA component (human telomerase, hTR) of the telomerase complex. Dyskerin is therefore thought to function in the processing of pre-rRNA and of the hTR, strengthening the notion that the underlying mechanism of DKC is a premature senescence of cells, especially of the rapidly dividing epithelial and hemopoietic cells. To examine the functions of dyskerin in vivo, it will be necessary to generate mouse models. As a first step, we here provide the genomic structure of the mouse Dkc1 gene and expression analysis of the transcript. Northern hybridizations revealed the tissue-specific expression of an alternative 4.5-kb transcript, in addition to the ubiquitous 2.6-kb transcript. RNA in situ hybridizations on day 10.5-18.5 postconception embryos showed a ubiquitous expression of Dkc1 with a notably higher level of expression confined to the epithelial tissues. In addition, higher level Dkc1 expression was confined to embryonic neural tissues as well as to specific neurons in the cerebellum (Purkinje cells) and the olfactory bulb (mitral cells) of the adult brain. In adult testis, elevated expression was limited to the Leydig cells. The results indicate that some of the pertinent functions of dyskerin may be more tissue-specific than previously thought and are not limited to rapidly dividing cells.

Comparative genome sequence analysis of the Bpa/Str region in mouse and Man.

The progress of human and mouse genome sequencing programs presages the possibility of systematic cross-species comparison of the two genomes as a powerful tool for gene and regulatory element identification. As the opportunities to perform comparative sequence analysis emerge, it is important to develop parameters for such analyses and to examine the outcomes of cross-species comparison. Our analysis used gene prediction and a database search of 430 kb of genomic sequence covering the Bpa/Str region of the mouse X chromosome, and 745 kb of genomic sequence from the homologous human X chromosome region. We identified 11 genes in mouse and 13 genes and two pseudogenes in human. In addition, we compared the mouse and human sequences using pairwise alignment and searches for evolutionary conserved regions (ECRs) exceeding a defined threshold of sequence identity. This approach aided the identification of at least four further putative conserved genes in the region. Comparative sequencing revealed that this region is a mosaic in evolutionary terms, with considerably more rearrangement between the two species than realized previously from comparative mapping studies. Surprisingly, this region showed an extremely high LINE and low SINE content, low G+C content, and yet a relatively high gene density, in contrast to the low gene density usually associated with such regions.

Genomic rearrangement in NEMO impairs NF-kappaB activation and is a cause of incontinentia pigmenti. The International Incontinentia Pigmenti (IP) Consortium.

Familial incontinentia pigmenti (IP; MIM 308310) is a genodermatosis that segregates as an X-linked dominant disorder and is usually lethal prenatally in males. In affected females it causes highly variable abnormalities of the skin, hair, nails, teeth, eyes and central nervous system. The prominent skin signs occur in four classic cutaneous stages: perinatal inflammatory vesicles, verrucous patches, a distinctive pattern of hyperpigmentation and dermal scarring. Cells expressing the mutated X chromosome are eliminated selectively around the time of birth, so females with IP exhibit extremely skewed X-inactivation. The reasons for cell death in females and in utero lethality in males are unknown. The locus for IP has been linked genetically to the factor VIII gene in Xq28 (ref. 3). The gene for NEMO (NF-kappaB essential modulator)/IKKgamma (IkappaB kinase-gamma) has been mapped to a position 200 kilobases proximal to the factor VIII locus. NEMO is required for the activation of the transcription factor NF-kappaB and is therefore central to many immune, inflammatory and apoptotic pathways. Here we show that most cases of IP are due to mutations of this locus and that a new genomic rearrangement accounts for 80% of new mutations. As a consequence, NF-kappaB activation is defective in IP cells.

Comparative sequence analysis of the MECP2-locus in human and mouse reveals new transcribed regions.

Comparative sequence analysis facilitates the identification of evolutionarily conserved regions, that is, gene-regulatory elements, which can not be detected by analyzing one species only. Sequencing of a 152-kb region on human Chromosome (Chr) Xq28 and of the synthenic 123 kb on mouse Chr XC identified the MECP2/Mecp2 locus, which is flanked by the gene coding for Interleukin-1 receptor associated kinase (IRAK/Il1rak) and the red opsin gene (RCP/Rsvp). By comparative sequence analysis, we identified a previously unknown, non-coding 5' exon embedded in a CpG island associated with MECP2/Mecp2. Thus, the MECP2/Mecp2 gene is comprised of four exons instead of three. Furthermore, sequence comparison 3' to the previously reported polyadenylation signal revealed a highly conserved region of 8.5 kb terminating in an alternative polyadenylation signal. Northern blot analysis verified the existence of two main transcripts of 1.9 kb and approximately 10 kb, respectively. Both transcripts exhibit tissue-specific expression patterns and have almost identical short half-lifes. The approximately 10-kb transcript corresponds to a giant 3' UTR contained in the fourth exon of MECP2. The long 3' UTR and the newly identified first intron of MECP2/Mecp2 are highly conserved in human and mouse. Furthermore, the human MECP2 locus is heterogeneous with respect to its DNA composition. We postulate that it represents a boundary between two H3 isochores that has not been observed previously.

The genomic structure of the DMBT1 gene: evidence for a region with susceptibility to genomic instability.

Increasing evidence has accumulated for an involvement of the inactivation of tumour suppressor genes at chromosome 10q in the carcinogenesis of brain tumours, melanomas, and carcinomas of the lung, the prostate, the pancreas, and the endometrium. The gene DMBT1 (Deleted in Malignant Brain Tumours 1) is located at chromosome 10q25.3-q26.1, within one of the putative intervals for tumour suppressor genes. DMBT1 is a member of the scavenger-receptor cysteine-rich (SRCR) superfamily and displays homozygous deletions or lack of expression in glioblastoma multiforme, medulloblastoma, and in gastrointestinal and lung cancers. Based on these properties, DMBT1 has been proposed to be a candidate tumour suppressor gene. We have determined the genomic sequence of DMBT1 to allow analyses of mutations. The gene has at least 54 exons that span a genomic region of about 80 kb. We have identified a putative exon with coding potential for a transmembrane domain. Our data further suggest that alternative splicing gives rise to isoforms of DMBT1 with a differential utilization of SRCR domains and SRCR interspersed domains. The major part of the gene harbours locus specific repeats. These repeats may point to the DMBT1 locus as a region susceptible to chromosomal instability.

Dickkopf genes are co-ordinately expressed in mesodermal lineages.

Dickkopf-1 (dkk-1) is member of a novel family of secreted proteins and functions in head induction during Xenopus embryogenesis, acting as a potent inhibitor of Wnt signalling. Here we report: (1) the isolation of two additional murine members of the dkk family, dkk-2 and dkk-3; and (2) analysis of adult and embryonic gene expression of mouse dkk-1,-2, and -3, Xenopus dkk-1 as well as chicken dkk-3. Comparative developmental analyses of the dkk-1, dkk-2 and dkk-3 in mice indicate that these genes are both temporally and spatially regulated. They define overlapping deep domains in mesenchymal lineages suggesting a co-ordinated mode of action. All dkks show distinct and elevated expression patterns in tissues that mediate epithelial- mesenchyme transformations suggesting that they may participate in heart, tooth, hair and whisker follicle, limb and bone induction. In the limb buds expression of these genes are found in regions of programmed cell death. In a given organ, dkk-1 tends to be the earliest member expressed. Comparison with Xenopus dkk-1 and chicken dkk-3 shows evolutionarily conserved expression patterns. Our observations indicate that dkk genes constitute a new family of secreted proteins that may mediate inductive interactions between epithelial and mesenchymal cells.

Direct visual resolution of gene copy number in the human photopigment gene array.

PURPOSE: To visualize by direct fluorescent in situ hybridization the entire human visual pigment gene array on single X-chromosome fibers and to compare the results with values obtained by other molecular techniques. METHODS: The size of the opsin gene array on the X-chromosome in eight male subjects was investigated by (i) direct visual in situ hybridization (DIRVISH) on elongated DNA fibers: (ii) quantitation of genomic restriction fragments after Southern blot hybridization; (iii) quantitation of restriction fragment length polymorphism after PCR amplification (PCR/RFLP), and (iv) sizing of NotI fragments by pulsed field gel electrophoresis and Southern blot detection. Each male subject's color vision was assessed by Rayleigh matches on a Nagel Type 1 anomaloscope. RESULTS: The number of genes resolved by the DIRVISH protocol, which ranges from 1 to 6, agrees exactly with the gene array sizes obtained in the same male subjects from pulsed field gel electrophoresis, but differs from the estimates derived from the commonly used indirect Southern blot hybridization and PCR/RFLP quantitation methods. In particular, the PCR/RFLP method overestimates the copy number in all but the smallest arrays. CONCLUSIONS: Visualization of the X-chromosome opsin gene array by DIRVISH provides a new, direct method for obtaining exact copy numbers and helps to resolve the controversy about the range and the average visual pigment gene number in the human population in favor of smaller average array sizes.

Genomic organization of a 225-kb region in Xq28 containing the gene for X-linked myotubular myopathy (MTM1) and a related gene (MTMR1).

MTM1 is responsible for X-linked recessive myotubular myopathy, which is a congenital muscle disorder linked to Xq28. MTM1 is highly conserved from yeast to humans. A number of related genes also exist. The MTM1 gene family contains a consensus sequence consisting of the active enzyme site of protein tyrosine phosphatases (PTPs), suggesting that they belong to a new family of PTPs. Database searches revealed homology of myotubularin and all related peptides to the cisplatin resistance-associated alpha protein, which implicates an as yet unknown function. In addition, homology to the Sbf1 protein (SET binding factor 1), involved in the oncogenic transformation of fibroblasts and differentiation of myoblasts, was also evident. We describe 225 kb of genomic sequence containing MTM1 and the related gene, MTMR1, which lies 20 kb distal to MTM1. Although there is only moderate conservation of the exons, the striking similarity in the gene structures indicates that these two genes arose by duplication. Calculations suggest that this event occurred early in evolution long before separation of the human and mouse lineages. So far, mutations have been identified in the coding sequence of only 65% of the patients analyzed, indicating that the remaining mutations may lie in noncoding regions of MTM1 or possibly in MTMR1. Knowledge of the genomic sequence will facilitate mutation analyses of the coding and noncoding sequences of MTM1 and MTMR1.

The human glycine receptor beta subunit gene (GLRB): structure, refined chromosomal localization, and population polymorphism.

The glycine receptor of the human CNS comprises ligand-binding alpha 1 and structural beta subunits encoded by the GLRA1 and GLRB genes, respectively. Screening of a human hippocampal cDNA library resulted in the identification of the novel subunit transcript beta B, differing in the 5'-UTR. Analysis of the genomic organization of GLRB showed that the coding region is distributed over nine exons, highly homologous to the GLRA1 gene. By in situ hybridization, the chromosomal localization of GLRB was refined to band 4q31.3. Based on the identical phenotypes of mouse lines carrying mutant alleles of the alpha 1 and beta subunit genes, GLRB was assumed to be a candidate gene for those cases of hyperekplexia that cannot be associated with mutations of GLRA1. Therefore, flanking intronic sequences were determined, and DNA samples from more than 30 index patients were subjected to SSCP screening of the entire GLRB coding region. A polymorphism in exon 8 was found both in the normal population and in families affected by hyperekplexia, although no coding mutation was detectable.

The human glycine receptor subunit alpha3. Glra3 gene structure, chromosomal localization, and functional characterization of alternative transcripts.

The neuronal glycine receptor is a ligand-gated chloride channel composed of ligand binding alpha and structural beta polypeptides. Homology screening of a human fetal brain cDNA library resulted in the identification of two alternative splice variants of the glycine receptor alpha3 subunit. The amino acid sequence predicted for the alpha3L variant was largely identical to the corresponding rat subunit. In contrast, the novel splice variant alpha3K lacked the coding sequence for 15 amino acids located within the cytoplasmic loop connecting transmembrane spanning region 3 (TM3) and TM4. Using P1 artificial chromosome (PAC) clones, the structure of the GLRA3 gene was elucidated and its locus assigned to human chromosomal bands 4q33-q34 by fluorescence in situ hybridization. Two transcripts of 2.4 and 9 kilobases, corresponding to alpha3L and alpha3K, respectively, were identified and found to be widely distributed throughout the human central nervous system. Structural analysis of the GLRA3 gene revealed that the alpha3K transcript resulted from a complex splice event where excision of the novel exon 8A comprising the alternative sequence of 45 base pairs coincides with the persistence of a large intronic sequence in the 3'-untranslated region. Functional expression in HEK 293 cells of alpha3L and alpha3K subunits resulted in the formation of glycine-gated chloride channels that differed significantly in desensitization behavior, thus defining the cytoplasmic loop as an important determinant of channel inactivation kinetics.

Genomic structure of a novel LIM domain gene (ZNF185) in Xq28 and comparisons with the orthologous murine transcript.

Construction of a transcript map in the DXS52 region in Xq28 had previously led to the isolation of a cDNA with a LIM zinc finger domain in the carboxyl terminus. In parallel, the orthologous murine transcript was isolated from the syntenic region. The human and mouse cDNAs have been designated ZNF185 and Zfp185, respectively. By integrating the cDNA sequence with the cosmid-derived genomic sequence the exon-intron structure of the 3' end of the ZNF185 gene was resolved. Comparative sequence analyses of the human genomic sequence with the full-length murine cDNA facilitated prediction of the 5' end of the gene. The selective expression of three transcripts corresponding to the ZNF185 gene and a related gene was shown by Northern and Southern blots. In situ hybridizations revealed a nonubiquitous and stage-specific expression of Zfp185, especially in differentiating connective tissue. Since LIM proteins regulate cellular proliferation and/or differentiation by diverse mechanisms, and some have directly been associated with disease, conceivably ZNF185 may represent a candidate for a disease-causing gene linked to Xq28. Knowledge of the genomic structure will permit detailed mutation analyses.

Cloning and characterization of an alternatively spliced gene in proximal Xq28 deleted in two patients with intersexual genitalia and myotubular myopathy.

We have identified a novel human gene that is entirely deleted in two boys with abnormal genital development and myotubular myopathy (MTM1). The gene, F18, is located in proximal Xq28, approximately 80 kb centromeric to the recently isolated MTM1 gene. Northern analysis of mRNA showed a ubiquitous pattern and suggested high levels of expression in skeletal muscle, brain, and heart. A transcript of 4.6 kb was detected in a range of tissues, and additional alternate forms of 3.8 and 2.6 kb were present in placenta and pancreas, respectively. The gene extends over 100 kb and is composed of at least seven exons, of which two are noncoding. Sequence analysis of a 4.6-kb cDNA contig revealed two overlapping open reading frames (ORFs) that encode putative proteins of 701 and 424 amino acids, respectively. Two alternative spliced transcripts affecting the large open reading frame were identified that, together with the Northern blot results, suggest that distinct proteins are derived from the gene. No significant homology to other known proteins was detected, but segments of the first ORF encode polyglutamine tracts and proline-rich domains, which are frequently observed in DNA-binding proteins. The F18 gene is a strong candidate for being implicated in the intersexual genitalia present in the two MTM1-deleted patients. The gene also serves as a candidate for other disorders that map to proximal Xq28.

Human histone gene organization: nonregular arrangement within a large cluster.

We have previously located the genes of the five human main type H1 genes and the gene encoding the testicular subtype H1t to the region 21.1 to 22.2 on the short arm of chromosome 6. To investigate the organization of the histone genes in this region, we isolated two YACs from a human YAC library by PCR screening with primers specific for histone H1.1. This screen revealed two YAC clones, YAC Y23 (corresponding to ICRFy901D1223) contains an insert of about 480 kb, whereas the smaller YAC 4A (corresponding to ICRFy900C104) spans about 340 kb and is completely covered by YAC Y23. We have subcloned the YAC inserts in cosmids, determined the linear orientation of the cosmids by cosmid walking, and constructed a restriction map of the entire region by mapping the individual cosmids using partial digests and hybridization with labeled oligonucleotides complementary to the cos site of the vector. Hybridization analysis, subcloning, restriction mapping, and sequencing revealed that most of the previously isolated phage and cosmid clones containing histone genes are part of this YAC including the clones containing the four human main type H1 histone genes H1.1 to H1.4, the H1t gene, and core histone genes. Thirty-five histone genes map within 260 kb of the YAC Y23 insert. All newly identified histone genes were sequenced, and the sequences were deposited with the EMBL nucleotide sequence database. The histone H1.5 gene is not part of this region, and we therefore conclude that the H1.5 gene and the associated core histone genes form a separate subcluster within this chromosomal region.

Transcriptional analysis of the candidate region for incontinentia pigmenti (IP2) in Xq28.

The hereditary form of incontinentia pigmenti (IP2) is a rare disorder characterized by abnormalities of the tissues and organs derived from the ectoderm and neuroectoderm and has been linked to Xq28 distal to the factor VIII gene (F8C). Four YAC clones covering the 1.1-Mb candidate region at the telomere of Xq28 were subjected to direct cDNA selection and Alu long-range PCR. The products of both methods were subsequently used to isolate 154 cosmid clones that were assembled into five cosmid contigs. This first-generation cosmid map covered the region almost entirely and was used as a basis for constructing a transcript map that was in turn integrated with the physical YAC and cosmid maps. To isolate specifically coding sequences, exon trapping and cDNA selection methods were combined. Exon trapping was carried out on YAC Alu-PCR products, YAC Alu long-range PCR products, and on pools of cosmids. The region-specific enriched cDNA library was then screened by using the exon trap products as complex probes. To ensure a more complete analysis, the products from cDNA selection experiments were also used to screen conventional oligo(dT) primed cDNA libraries. Twenty overlapping cDNA contigs were assembled and computer analyses were performed to identify EST hits, open reading frames, protein motifs, and protein sequence homologies. Five of the cDNA contigs corresponded to known sequences such as the factor VIII, c6.1A, and c6.1B. genes, and both distal copies of the factor VIII intron 22 repeat sequence. Expression patterns of the 15 new cDNA contigs were analyzed by Northern blot and RT-PCR studies and these data were integrated with expression data obtained from known EST sequences. Although a more detailed analysis of this 1.1-Mb region with respect to the structure and function of the genes will only ultimately be possible by a global sequencing approach, an analysis of all novel transcripts as candidate genes for incontinentia pigmenti is already in progress.

X-linked myotubular myopathy: refinement of the gene to a 280-kb region with new and highly informative microsatellite markers.

We have recently refined the localization of the myotubular myopathy (MTM1) gene to a 430-kb region between DXS304 and DXS1345 in proximal Xq28. We report two new polymorphic microsatellite markers, DXS8377 and DXS7423, that were physically mapped within the critical interval. A recombination event in a family segregating for MTM1 placed the disease gene telomeric to the trinucleotide polymorphism DXS8377. Together with the recent mapping of two microdeletions associated with MTM1, the recombination refines the critical region to 280 kb. A second recombination event was observed distal to the tetranucleotide repeat DXS7423. This recombination has occurred in the off-spring of a female with a more than 67% probability of being a carrier and very likely restricts the MTM1 gene to a 130-kb region. This physical refinement is significant for positional cloning of the disease gene. The highly polymorphic markers and the precise localization of the MTM1 gene will facilitate genetic diagnosis of the disorder.

The genomic organization of a human creatine transporter (CRTR) gene located in Xq28.

During the course of a large-scale sequencing project in Xq28, a human creatine transporter (CRTR) gene was discovered. The gene is located approximately 36 kb centromeric to ALD. The gene contains 13 exons and spans about 8.5 kb of genomic DNA. Since the creatine transporter has a prominent function in muscular physiology, it is a candidate gene for Barth syndrome and infantile cardiomyopathy mapped to Xq28.

Transcription mapping in a 700-kb region around the DXS52 locus in Xq28: isolation of six novel transcripts and a novel ATPase isoform (hPMCA5).

The chromosomal band Xq28 has been a focus of interest in human genetics because > 20 hereditary diseases have been mapped to this region. However, about two-thirds of the disease genes remain uncloned. The region around the polymorphic DXS52 locus (ST14) within Xq28 lies in the candidate regions for several as-yet-uncloned disease genes. So far, only four melanoma antigen genes (MAGE) and the human biglycan (BGN) gene, have been mapped within the 700-kb stretch around DXS52, suggesting that more genes may reside in this region. By combining exon trapping and direct cDNA selection methods, we sought to identify novel transcripts around the DXS52 locus. In addition to recovering the MAGE and BGN genes, we isolated and mapped six putative novel genes (XAP103-XAP108), the caltractin gene, and a gene encoding a novel Ca(2+)-transporting ATPase isoform (hPMCA5). The newly isolated sequences were considered as representing parts of putative genes if they contained at least one unique exon-trap product and/or at least one expressed sequence tag (EST) from sequence data bases and if, in addition, they showed evidence of expressed RT-OCT and/or Northern blot analysis. Our data facilitated the integration of the transcription map with the physical map around the DXS52 locus. Future analysis of the novel genes as candidates for Barth syndrome (BTHS) and chondrodysplasia punctata (CDPX2) is in progress.