The FSHD-Associated Repeat, D4Z4, Is a Member of a Dispersed Family of Homeobox-Containing Repeats, Subsets of Which Are Clustered on the Short Arms of the Acrocentric Chromosomes

Facioscapulohumeral muscular dystrophy (FSHD) is an autosomal dominant neuromuscular disorder that maps to human chromosome 4q35. FSHD is tightly linked to a polymorphic 3.3-kb tandem repeat locus, D4Z4. D4Z4 is a complex repeat: it contains a novel homeobox sequence and two other repetitive sequence motifs. In most sporadic FSHD cases, a specific DNA rearrangement, deletion of copies of the repeat at D4Z4, is associated with development of the disease. However, no expressed sequences from D4Z4 have been identified. We have previously shown that there are other loci similar to D4Z4 within the genome. In this paper we describe the isolation of two YAC clones that map to chromosome 14 and that contain multiple copies of a D4Z4-like repeat. Isolation of cDNA clones that map to the acrocentric chromosomes and Southern blot analysis of somatic cell hybrids show that there are similar loci on all of the acrocentric chromosomes. D4Z4 is a member of a complex repeat family, and PCR analysis of somatic cell hybrids shows an organization into distinct subfamilies. The implications of this work in relation to the molecular mechanism of FSHD pathogenesis is discussed. We propose the name 3.3-kb repeat for this family of repetitive sequence elements.     

Structure and evolution of the U2 small nuclear RNA multigene family in primates: gene amplification under natural selection?

The organization of U2 genes was compared in apes, Old World monkeys, and the prosimian galago. In humans and all apes (gibbon, orangutan, gorilla, and chimpanzee), the U2 genes were organized as a tandem repeat of a 6-kb element; however, the restriction maps of the 6-kb elements in these divergent species differed slightly, demonstrating that mechanisms must exist for maintaining sequence homogeneity within this tandem array. In Old World monkeys, the U2 genes were organized as a tandem repeat of an 11-kb element; the restriction maps of the 11-kb elements in baboon and two closely related macaques, bonnet and rhesus monkeys, also differed slightly, confirming that efficient sequence homogenization is an intrinsic property of the U2 tandem array. Interestingly, the 11-kb monkey repeat unit differed from the 6-kb hominid repeat unit by a 5-kb block of monkey-specific sequence. Finally, we found that the U2 genes of the prosimian galago were dispersed rather than tandemly repeated, suggesting that the hominid and Old World monkey U2 tandem arrays resulted from independent amplifications of a common ancestral U2 gene. Alternatively, the 5-kb monkey-specific sequence could have been inserted into the 6-kb array or deleted from the 11-kb array soon after divergence of the hominid and Old World monkey lineages.     

Hybridization analysis of D4Z4 repeat arrays linked to FSHD

Facioscapulohumeral muscular dystrophy (FSHD) is an autosomal dominant disease involving shortening of D4Z4, an array of tandem 3.3-kb repeat units on chromosome 4. These arrays are in subtelomeric regions of 4q and 10q and have 1–100 units. FSHD is associated with an array of 1–10 units at 4q35. Unambiguous clinical diagnosis of FSHD depends on determining the array length at 4q35, usually with the array-adjacent p13E-11 probe after pulsed-field or linear gel electrophoresis. Complicating factors for molecular diagnosis of FSHD are the phenotypically neutral 10q D4Z4 arrays, cross-hybridizing sequences elsewhere in the genome, deletions including the genomic p13E-11 sequence and part of D4Z4, translocations between 4q and 10q D4Z4 arrays, and the extremely high G + C content of D4Z4 arrays (73%). In this study, we optimized conditions for molecular diagnosis of FSHD with a 1-kb D4Z4 subfragment probe after hybridization with p13E-11. We demonstrate that these hybridization conditions allow the identification of FSHD alleles with deletions of the genomic p13E-11 sequence and aid in determination of the nonpathogenic D4Z4 arrays at 10q. Furthermore, we show that the D4Z4-like sequences present elsewhere in the genome are not tandemly arranged, like those at 4q35 and 10q26.     

Both hypomethylation and hypermethylation in a 0.2-kb region of a DNA repeat in cancer

NBL2 is a tandem 1.4-kb DNA repeat, whose hypomethylation in hepatocellular carcinomas was shown previously to be an independent predictor of disease progression. Here, we examined methylation of all cytosine residues in a 0.2-kb subregion of NBL2 in ovarian carcinomas, Wilms' tumors, and diverse control tissues by hairpin-bisulfite PCR. This new genomic sequencing method detects 5-methylcytosine on covalently linked complementary strands of a DNA fragment. All DNA clones from normal somatic tissues displayed symmetrical methylation at seven CpG positions and no methylation or only hemimethylation at two others. Unexpectedly, 56% of cancer DNA clones had decreased methylation at some normally methylated CpG sites as well as increased methylation at one or both of the normally unmethylated sites. All 146 DNA clones from 10 cancers could be distinguished from all 91 somatic control clones by assessing methylation changes at three of these CpG sites. The special involvement of DNA methyltransferase 3B in NBL2 methylation was indicated by analysis of cells from immunodeficiency, centromeric region instability, and facial anomalies syndrome patients who have mutations in the gene encoding DNA methyltransferase 3B. Blot hybridization of 33 cancer DNAs digested with CpG methylation-sensitive enzymes confirmed that NBL2 arrays are unusually susceptible to cancer-linked hypermethylation and hypomethylation, consistent with our novel genomic sequencing findings. The combined Southern blot and genomic sequencing data indicate that some of the cancer-linked alterations in CpG methylation are occurring with considerable sequence specificity. NBL2 is an attractive candidate for an epigenetic cancer marker and for elucidating the nature of epigenetic changes in cancer.     

The sequence of the 3.3-kilobase repetitive element fromDipodomys ordii suggests a mechanism for its amplification and interspersion

Summary DNA from the kangaroo rat,Dipodomys ordii, contains a 3.3-kb, highly repeated sequence that is interspersed throughout the genome in small tandem clusters. One 3.3-kb unit has been cloned into pBR322 and the nucleotide sequence determined. The clone used was shown to be representative of the bulk of such sequences found in the genomic DNA. The sequence contains 10 homologous subunits each ca. 260 bp in length. Comparison of these to one another yielded a 258-bp consensus sequence containing a 35-bp terminal inverted repeat. Two unique stretches also occur. One of these contains a region that could serve as a promoter for RNA polymerase III; the other contains a sequence related to the ARS sequences of yeast. It is proposed that an ancestral sequence similar to the consensus sequence was amplified to 10 or more units, and that, subsequently, two other sequences were inserted. The properties of these insertions may have led to the dispersal of the sequence throughout the genome.     

Extensive Direct-Tandem Organization of a Long Repeat DNA Sequence on the Y Chromosome of Chinook Salmon (Oncorhynchus tshawytscha)

A long repetitive DNA sequence (OtY8) has been cloned from male chinook salmon and its genomic organization has been characterized. The repeat has a unit length of 8 kb and is present approximately 300 times per diploid male nucleus. All internal fragments within the 8-kb repeat segregate from father to son, suggesting that the entire repeat unit is located on the Y chromosome. The organization of this sequence into an 8-kb repeat unit is restricted to the Y chromosome, as are several male-specific repeat subtypes identified on the basis of restriction-site variation. The repeat possesses only weak internal sequence similarities, suggesting that OtY8 has not arisen by duplication of a smaller repeat unit, as is the case for other long tandem arrays found in eukaryotes. Based on a laddered pattern arising from partial digestion of genomic DNA with a restriction enzyme which cuts only once per repeat unit, this sequence is not dispersed on the Y chromosome but is organized as a head-to-tail tandem array. Pulse-gel electrophoresis reveals that the direct-tandem repeats are organized into at least six separate clusters containing approximately 12 to 250 copies, comprising some 2.4 Mb of Y-chromosomal DNA in total. Related sequences with nucleotide substitutions and DNA insertions relative to the Y-chromosomal fragment are found elsewhere in the genome but at much lower copy number and, although similar sequences are also found in other salmonid species, the amplification of the repeat into a Y-chromosome-linked tandem array is only observed in chinook salmon. The OtY8 repetitive sequence is genetically tightly associated with the sex-determination locus and provides an opportunity to examine the evolution of the Y chromosome and sex determination process in a lower vertebrate. Received: 4 April 1997 / Accepted: 22 July 1997     

Dynamics of 5S rDNA in the tilapia (Oreochromis niloticus) genome: repeat units,inverted sequences,pseudogenes and chromosome loci

In higher eukaryotes, the 5S ribosomal DNA (5S rDNA) is organized in tandem arrays with repeat units composed of a coding region and a non-transcribed spacer sequence (NTS). These tandem arrays can be found on either one or more chromosome pairs. 5S rDNA copies from the tilapia fish, Oreochromis niloticus, were cloned and the nucleotide sequences of the coding region and of the non-transcribed spacer were determined. Moreover, the genomic organization of the 5S rDNA tandem repeats was investigated by fluorescence IN SITU hybridization (FISH) and Southern blot hybridization. Two 5S rDNA classes, one consisting of 1.4-kb repeats and another one with 0.5-kb repeats were identified and designated 5S rDNA type I and type II, respectively. An inverted 5S rRNA gene and a 5S rRNA putative pseudogene were also identified inside the tandem repeats of 5S rDNA type I. FISH permitted the visualization of the 5S rRNA genes at three chromosome loci, one of them consisting of arrays of the 5S rDNA type I, and the two others corresponding to arrays of the 5S rDNA type II. The two classes of the 5S rDNA, the presence of pseudogenes, and the inverted genes observed in the O. niloticus genome might be a consequence of the intense dynamics of the evolution of these tandem repeat elements.     

Genomic organization of human 5 S rDNA and sequence of one tandem repeat

An organization of human 5 S rDNA repeats is inferred from Southern analyses of restriction digests of genomic DNA fractionated by pulsed-field and conventional gel electrophoreses. A single unit of 2.2 kb is repeated approximately 90 times within a 200-kb fragment (defined by enzymes that do not cleave within individual units, i.e., EcoR1, BglII, HindIII, and PvuII); a comparable number of 5 S sequences are scattered elsewhere in the genome. A lambda clone containing six complete 5 S repeats was obtained from a human placental DNA library. One repeat contains 2231 bp and includes poly(dG-dT).(dC-dA), tracts of polypyrimidine, and an Alu sequence in the spacer region. Also, 5-S-hybridizing clones, containing DNA inserts with an average size of 250 kb, have been obtained as yeast artificial chromosomes. Thus far, four clones have been partially characterized and shown to be 5 S sequences from loci separate from the tandem repeat units.     

Heterogeneous organization of a tandem repeat family in subtelomeric heterochromatin of rye

The presence of tandem repeat multicopy families in subtelomeric regions of all chromosomes is a characteristic feature of the rye karyotype, in contrast to the organization of these regions in chromosomes of extensively studied species, such as human, rice, and Arabidopsis. To study the molecular structure of these regions, we analyzed BAC clones from a library constructed from the genetic material of rye chromosome 1 short arm (1RS). Screening of the library detected numerous clones that contained copies of multicopy tandem families of DNA sequences pSc200, pSc250, and pSc119.2. An examination of the molecular organization of tandem arrays of the pSc200 family, which is the most common in the rye genome, showed that the subtelomeric 1RS region includes several such arrays, each of which contains characteristic blocks of multimers of various periodicity. Such pattern of heterogeneous organization of tandem repeat arrays differs from the view of the tandem arrays as monotonous sequence of identical monomers, which was generally accepted in recent past.     

A tandem array of 5S ribosomal RNA genes in Pythium irregulare

The 5S ribosomal RNA genes of the oomycete Pythium irregulare exist in tandem arrays unlinked to the rDNA repeat unit. A clone with a 9.2-kb insert containing an array of 5S genes was identified in a lambda genomic library and was characterized by restriction mapping and partial sequencing. The array consisted of 9 apparently identical 5S genes and their spacers in tandem, followed by a diverged 5S-like sequence that is likely to be a pseudogene. This gene arrangement, although almost universal in plants and animals, is rare in fungi and protists.     

Cross-hybridizing snake satellite, Drosophila, and mouse DNA sequences may have arisen independently

Previous reports have interpreted hybridization between snake satellite DNA and DNA clones from a variety of distant taxonomic groups as evidence for evolutionary conservation, which implies common ancestry (homology) and/or convergence (analogy) to produce the cross- hybridizing sequences. We have isolated 11 clones from a genomic library of Drosophila melanogaster, using a cloned 2.5-kb snake satellite probe of known nucleotide sequence. We have also analysed published sequence data from snakes, mice, and Drosophila. These data show that (1) all of the cross-hybridization between the snake, fly, and mouse clones can be accounted for by the presence of either of two tandem repeats, [GATA]n and [GACA]n and (2) these tandem repeats are organized differently among the different species. We find no evidence that these sequences are homologous apart from the existence of the simple repeat itself, although their divergence from a common ancestral sequence cannot be ruled out. The sequences contain a variety of homogeneous clusters of tandem repeats of CATA, GA, TA, and CA, as well as GATA and GACA. We suggest that these motifs may have arisen by a self-accelerating process involving slipped-strand mispairing of DNA. Homogeneity of the clusters might simply be the result of a rate of accumulation of tandem repeats that exceeds that of other mutations.      

Repetitive DNA (TGGA)n 5' to the human myelin basic protein gene: a new form of oligonucleotide repetitive sequence showing length polymorphism.

DNA 5' to the human myelin basic protein (MBP) gene, mapped to 18q22----qter, is known to manifest multiallelic DNA length variation with heterozygosity of at least 45%. Isolation of genomic DNA containing the MBP gene first exon and its 5' flanking region reveals that this polymorphism arises from a 994-bp region of the diverged tandem repeat (TGGA)249. This sequence is located from 1082 to 2075 bp upstream of the MBP initiator methionine. The repetitive sequence is 18% diverged from (TGGA)249 and from analysis of higher order subsequence reiterations appears to have undergone extensive recombination. The pattern of higher order repetition suggests that multiple crossover and gene conversion events have occurred within a 1.0-kb region. Molecular clones of this sequence represent essentially the longest allelic form of this region seen in Southern transfer analysis. This repetitive DNA is similar to a sequence 5' to the human myoglobin gene.     

Nucleotide sequence of cDNA clones of the murine myb proto-oncogene.

We have isolated cDNA clones of murine c-myb mRNA which contain approximately 2.8 kb of the 3.9-kb mRNA sequence. Nucleotide sequencing has shown that these clones extend both 5' and 3' to sequences homologous to the v-myb oncogenes of avian myeloblastosis virus and avian leukemia virus E26. The sequence contains an open reading frame of 1944 nucleotides, and could encode a protein which is both highly homologous, and of similar size (71 kd), to the chicken c-myb protein. Examination of the deduced amino acid sequence of the murine c-myb protein revealed the presence of a 3-fold tandem repeat of 52 residues near the N terminus of the protein, and has enabled prediction of some of the likely structural features of the protein. These include a high alpha-helix content, a basic region toward the N terminus of the protein and an overall globular configuration. The arrangement of genomic c-myb sequences, detected using the cDNA clones as probes, was compared with the reported structure of rearranged c-myb in certain tumour cells. This comparison suggested that the rearranged c-myb gene may encode a protein which, like the v-myb protein, lacks the N-terminal region of c-myb.     

A comparative analysis of the Lactuca and Helianthus (Asteraceae) plastid genomes: identification of divergent regions and categorization of shared repeats

We have sequenced two complete chloroplast genomes in the Asteraceae, Helianthus annuus (sunflower), and Lactuca sativa (lettuce), which belong to the distantly related subfamilies, Asteroideae and Cichorioideae, respectively. The Helianthus chloroplast genome is 151?104 bp and the Lactuca genome is 152?772 bp long, which is within the usual size range for chloroplast genomes in flowering plants. When compared to tobacco, both genomes have two inversions: a large 22.8-kb inversion and a smaller 3.3-kb inversion nested within it. Pairwise sequence divergence across all genes, introns, and spacers in Helianthus and Lactuca has resulted in the discovery of new, fast-evolving DNA sequences for use in species-level phylogenetics, such as the trnY-rpoB, trnL-rpl32, and ndhC-trnV spacers. Analysis and categorization of shared repeats resulted in seven classes useful for future repeat studies: double tandem repeats, three or more tandem repeats, direct repeats dispersed in the genome, repeats found in reverse complement orientation, hairpin loops, runs of A's or T's in excess of 12 bp, and gene or tRNA similarity. Results from BLAST searches of our genomic sequence against expressed sequence tag (EST) databases for both genomes produced eight likely RNA edited sites (C → U changes). These detailed analyses in Asteraceae contribute to a broader understanding of plastid evolution across flowering plants.     

Epigenetics of a tandem DNA repeat: chromatin DNaseI sensitivity and opposite methylation changes in cancers

DNA methylation and chromatin DNaseI sensitivity were analyzed in and adjacent to D4Z4 repeat arrays, which consist of 1 to ~100 tandem 3.3-kb units at subtelomeric 4q and 10q. D4Z4 displayed hypomethylation in some cancers and hypermethylation in others relative to normal tissues. Surprisingly, in cancers with extensive D4Z4 methylation there was a barrier to hypermethylation spreading to the beginning of this disease-associated array (facioscapulohumeral muscular dystrophy, FSHD) despite sequence conservation in repeat units throughout the array. We infer a different chromatin structure at the proximal end of the array than at interior repeats, consistent with results from chromatin DNaseI sensitivity assays indicating a boundary element near the beginning of the array. The relative chromatin DNaseI sensitivity in FSHD and control myoblasts and lymphoblasts was as follows: a non-genic D4Z4-adjacent sequence (p13E-11, array-proximal)> untranscribed gene standards > D4Z4 arrays> constitutive heterochromatin (satellite 2; P < 10⁻⁴ for all comparisons). Cancers displaying D4Z4 hypermethylation also exhibited a hypermethylation-resistant subregion within the 3.3-kb D4Z4 repeat units. This subregion contains runs of G that form G-quadruplexes in vitro. Unusual DNA structures might contribute to topological constraints that link short 4q D4Z4 arrays to FSHD and make long ones phenotypically neutral.     

The centromere region of Arabidopsis thaliana chromosome 1 contains telomere-similar sequences.

We describe the structure of an Arabidopsis thaliana genomic clone containing two classes of repetitive DNA elements derived from the centromere region of chromosome 1. One class is comprised of tandem arrays of a highly reiterated repeat containing degenerate telomere sequence motifs. Adjacent to these telomere-similar repeats we found a dispersed repetitive element reiterated approximately five times in the A. thaliana genome. The nucleotide sequence of the dispersed repeat is unusual, being extremely AT-rich and composed of numerous, overlapping repeat motifs.     

Heterogeneity and organization of the ribosomal RNA genes ofCucurbita maxima

Thirty-six clones were recovered fromCucurbita maxima genomic DNA which had been enriched for rDNA and cleaved at the unique repeat unitHind III site. Twenty-nine of these, which contain complete rDNA units, were compared to a standard whose intergenic spacer (IGS) nucleotide sequence has been determined. Twenty-one are identical in length and restriction site pattern. Eight which differ from the standard in length do so because of addition or deletion of varying numbers of IGS subrepetitive units of two different classes, with four of the length variants being different in both of these classes. Seven clones were isolated which contain incomplete repeat units, six of which are composites of rDNA and non-rDNA material. They have been cleaved at the unique rDNAHind III site at one end and at a non-rDNAHind III site at the other. We consider it most likely that these are derived from the termini of repeat unit tandem arrays, although other explanations are possible. Twelve individual plants of two different cultivars were examined for heterogeneity of IGS length distribution. They all appear to be identical in this regard.     

Sequence rearrangements in the plasmid ColV,I-K94

ColV,I-K94 is a conjugative (F-like) plasmid specifying colicins V and I. Numerous rearrangements were observed in ColV,I-K94 plasmids from three culture collections and in derivatives which specified larger inhibition zones and increased titers of colicin V. Several of the rearrangements in ColV,I-K94 derivatives specifying higher titers of colicin V involved a 1.3 ± 0.08-kb inverted repeat sequence which was separated by a 3.3 ± 0.2-kb sequence. This was rearranged in one derivative, pKH46, such that the 3.3-kb sequence became flanked by a 2.5 ± 0.15-kb inverted repeat which was subsequently altered to form a 2.1 ± 0.1-kb inverted repeat. In two other derivatives, the 3.3-kb sequence was deleted together with all of the flanking inverted repeat (in pKH39-2) or part of each repeat (in pKH39-1). A 0.5 ± 0.1-kb sequence adjacent to one of the 1.3-kb repeats was inverted or substituted in both of these plasmids. A novel 12.9 ± 0.7-kb inverted duplication separated by a 7.3 ± 0.4-kb sequence was present in the ColV,I-K94 derivative, pKH41, and insertion of the γδ element was detected in another derivative, pKH46-1, after this nonconjugative plasmid had been mobilized by the F plasmid. The genes for colicin V and for immunity to colicin V were mapped to a 3.6-kb sequence. The copy numbers of both pKH39-2 and pKH46-1::γδ were greater than those of pKH38 from which they were derived.