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 of the gas vesicle plasmid in Halobacterium halobium: inversion isomers, inverted repeats, and insertion sequences.

Halobacterium-halobium NRC-1 harbors a 200-kb plasmid, pNRC100, which contains a cluster of genes for synthesis of buoyant gas-filled vesicles. Physical mapping of pNRC100 by using pulsed-field gel electrophoresis showed the presence of a large (35 to 38-kb) inverted repeat (IR) sequence. Inversion isomers of pNRC100 were demonstrated by Southern hybridization analysis using two restriction enzymes, AflII and SfiI, that cut asymmetrically within the intervening small single-copy region and the large single-copy region, respectively, but not within the large IRs. No inversion isomers were observed for a deletion derivative of pNRC100 lacking one IR, which suggests that both copies are required for inversion to occur. Additionally, the identities and approximate positions of 17 insertion sequences (IS) in pNRC100 were determined by Southern hybridization and limited nucleotide sequence analysis across the IS element-target site junctions: ISH2, a 0.5-kb element, was found in four copies; ISH3, a 1.4-kb heterogeneous family of elements, was present in seven copies; ISH8, a 1.4-kb element, was found in five copies; and ISH50, a 1.0-kb element, was present in a single copy. The large IRs terminated at an ISH2 element at one end and an ISH3 element at the other end. pNRC100 is similar in structure to chloroplast and mitochondrial genomes, which contain large IRs and other large halobacterial and prokaryotic plasmids that are reservoirs of IS elements but lack the large IRs.     

Characterization of the NPHP1 locus: mutational mechanism involved in deletions in familial juvenile nephronophthisis

Familial juvenile nephronophthisis is an autosomal recessive, genetically heterogeneous kidney disorder representing the most frequent inherited cause of chronic renal failure in children. A gene, NPHP1, responsible for approximately 85% of the purely renal form of nephronophthisis, has been mapped to 2q13 and characterized. The major NPHP1 gene defect is a large homozygous deletion found in approximately 80% of the patients. In this study, by large-scale genomic sequencing and pulsed-field gel electrophoresis analysis, we characterized the complex organization of the NPHP1 locus and determined the mutational mechanism that results in the large deletion observed in most patients. We showed that the deletion is 290 kb in size and that NPHP1 is flanked by two large inverted repeats of approximately 330 kb. In addition, a second sequence of 45 kb located adjacent to the proximal 330-kb repeat was shown to be directly repeated 250 kb away within the distal 330-kb repeat deleting the sequence tag site (STS) 804H10R present in the proximal copy. The patients' deletion breakpoints appear to be located within the 45-kb repeat, suggesting an unequal recombination between the two homologous copies of this smaller repeat. Moreover, we demonstrated a nonpathologic rearrangement involving the two 330-kb inverted repeats found in 11 patients and, in the homozygous state, in 2 (1.3%) control individuals. This could be explained by interchromosomal mispairing of the 330-kb inverted repeat, followed by double recombination or by a prior intrachromosomal mispairing of these repeats, leading to an inversion of the NPHP1 region, followed by an interchromosomal unequal crossover event. This complex rearrangement, as well as the common deletion found in most patients, illustrates the high level of rearrangements occurring in the centromeric region of chromosome 2.     

Dynamic plasmid populations in Halobacterium halobium.

Deletion events occurring in the major 150-kilobase-pair (kb) plasmid pHH1 of the archaebacterium Halobacterium halobium were investigated. We found four deletion derivatives of pHH1 in gas-vacuole-negative mutants, two of which (pHH23) [65 kb] and pHH4 [36 kb]) we analyzed. Both plasmids incurred more than one deletion, leading to the fusion of noncontiguous pHH1 sequences. pHH23 and pHH4 overlapped by only 4 kb of DNA sequence. A DNA fragment derived from this region was used to monitor the production of further deletion variants of pHH4. A total of 25 single colonies were characterized, 23 of which contained various smaller pHH4 derivatives. Of the 25 colonies investigated, 2 had lost pHH4 entirely and contained only large (greater than or equal to 100-kb) minor covalently closed circular DNAs. One colony contained the 17-kb deletion derivative pHH6 without any residual pHH4. The sizes of the pHH4 deletion derivatives, produced during the development of a single colony, ranged from 5 to 20 kb. In five colonies, pHH4 was altered by the integration of an additional insertion element. These insertions, as well as copies of the various insertion elements already present in pHH4, presumably serve as hot spots for recombination events which result in deletions. A second enrichment procedure led to the identification of colonies containing either a 16-kb (pHH7) or a 5-kb (pHH8) deletion derivative of pHH4 as the major plasmid. pHH8, the smallest plasmid found, contained the 4 kb of unique DNA sequence shared by pHH23 and pHH4, as well as some flanking pHH4 sequences. This result indicates that the 4-kb region contains the necessary sequences for plasmid maintenance and replication.     

Structure of an unusual sea urchin U1 RNA gene cluster

Genomic clones containing multiple copies of the Lytechinus variegatus U1 gene have been isolated from a gene library in the phage lambda EMBL3. These clones contain both types of U1 RNA gene repeats interspersed in the same 15-kb fragment. In addition, about 1/3 of the repeat units contain a 260-bp insert 460 bp prior to the first nucleotide of the U1 RNA sequence. The inserted sequence is abundant in the sea urchin genome as judged by Southern blots of genomic DNA. There are no repeated sequences flanking the insert. The insert occurs at the same position in the highly conserved 5'-flanking region at which a deletion has previously been reported.     

A 5.9-kb tandem repeat at the euchromatin-heterochromatin boundary of the X chromosome of Drosophila melanogaster

We present an analysis of a chromosomal walk in the region of the euchromatin-heterochromatin transition at the base of the X chromosome of Drosophila melanogaster. This region is difficult to analyse because of the presence of repeated sequences, and we have used cosmids to walk from the last euchromatic gene, suppressor of forked, towards the pericentric heterochromatin. The proximal 30-kb sequence we have isolated consists of repetitive DNA, including four tandem copies of a 5.9-kb sequence. This tandem repeat is itself a mosaic of other, mostly repeated, sequences, including part of a retrotransposon without long terminal repeats, a simple-sequence region of TAA repeats and part of a retrotransposon with long terminal repeats that has not been previously described. Although sequences homologous to these components are found elsewhere in the genome, this arrangement of repeated sequences is only found at the base of the X chromosome. It is conserved in D. melanogaster strains of different geographic origin, but is not conserved in even closely related species.     

Organization of the 1.9-kb repeat unit RCE1 in the centromeric region of rice chromosomes

This paper presents the first report on the structure of a 14-kb centromere sequence in a cereal genome that includes 1.9-kb direct repeats. The cereal centromeric sequence (CCS1) conserved in some Gramineae species contains a 17-bp motif similar to the CENP-B box, which serves as the binding site for the centromere-specific protein CENP-B in human. To isolate centromeric units from rice (Oryza sativa L.), we performed PCR using the CENP-B box-like sequences (CBLS) as primers. A 264-bp clone was amplified by this method, and called RCS1516. It appeared to be a novel member of the CCS1 family, sharing about 60% identity with the CCS1 sequences of other cereals. Then, a 14-kb genomic clone, λRCB11, carrying the RCS1516 sequence was isolated and sequenced. It was found to contain three copies of a 1.9-kb direct repeat, RCE1, separated by 5.1- and 1.7-kb. A 300-bp sequence at the 3′ end of RCE1 is highly conserved in all three copies (>90%) and is almost identical to the RCS1516 sequence including the CBLS motif. The copy number of RCE1 was estimated to range from 10² to 10³ in the haploid genome of rice. Cloned RCE1 units were used for fluorescent in situ hybridization (FISH) analysis, and signals were observed on almost every primary constriction of rice chromosomes. Thus it was concluded that RCE1 is a significant component of the rice centromere. The λRCB11 clone contained at least four A/T-rich regions, which are candidate for matrix attachment regions (MARs), in the sequences between the RCE1 repeats. Other elements that are homologous to the short centromeric repetitive sequences pSau3A9 and pRG5, detected in both sorghum and rice, were also found in the clone. Received: 9 June 1998 / Accepted: 16 September 1998     

Nucleotide sequence of the rat gamma-crystallin gene region and comparison with an orthologous human region

The sequences of a 51-kb region containing the cluster of five rat gamma-crystallin-coding genes (CRYG) and of a 7-kb region surrounding the sixth rat CRYG gene were determined. Approximately 78% of the total sequence represents intergenic DNA. We also sequenced 22 kb of DNA from the human CRYG gene cluster. All CRYG genes are associated with CpG-rich regions. The sequence similarity between the human and rat gene regions drops sharply (to 65%) in intronic and 3'-flanking regions but decreases only gradually in the 5'-flanking region. Highly conserved regions (greater than 80%) are found as far upstream as 1.5 kb. Overall intergenic distances are conserved. The human region contains much more repetitive DNA (24% vs. 10%) but less simple-sequence (sps) DNA (0.7% vs. 4%) than the rat region. Almost all repeats and spsDNA elements are located in the intergenic region. The location of repetitive and spsDNA differs between the orthologous regions and these elements were probably inserted after the evolutionary separation of rat and man. The Alu repeats in man and the B3 repeats in the rat are close copies of their respective consensus sequences and bordered by virtually perfect repeats. In contrast, the B1 and B2 repeats in the rat have diverged considerably from the consensus sequence and the surrounding direct repeats are usually imperfect. Thus the dispersion of the B1 and B2 repeats in the rat probably preceded that of the B3 repeats. Within the rat genomic region the spacing of Z-DNA elements is surprisingly regular, they are located about 12 kb apart. A search for putative matrix-associated regions suggests that the rat CRYG gene cluster is organized into two chromosomal domains.     

Localization and characterization of two novel genes encoding stereospecific dioxygenases catalyzing 2(2,4-dichlorophenoxy)propionate cleavage in Delftia acidovorans MC1

Two novel genes, rdpA and sdpA, encoding the enantiospecific alpha-ketoglutarate dependent dioxygenases catalyzing R,S-dichlorprop cleavage in Delftia acidovorans MC1 were identified. Significant similarities to other known genes were not detected, but their deduced amino acid sequences were similar to those of other alpha-ketoglutarate dioxygenases. RdpA showed 35% identity with TauD of Pseudomonas aeruginosa, and SdpA showed 37% identity with TfdA of Ralstonia eutropha JMP134. The functionally important amino acid sequence motif HX(D/E)X(23-26)(T/S)X(114-183)HX(10-13)R/K, which is highly conserved in group II alpha-ketoglutarate-dependent dioxygenases, was present in both dichlorprop-cleaving enzymes. Transposon mutagenesis of rdpA inactivated R-dichlorprop cleavage, indicating that it was a single-copy gene. Both rdpA and sdpA were located on the plasmid pMC1 that also carries the lower pathway genes. Sequencing of a 25.8-kb fragment showed that the dioxygenase genes were separated by a 13.6-kb region mainly comprising a Tn501-like transposon. Furthermore, two copies of a sequence similar to IS91-like elements were identified. Hybridization studies comparing the wild-type plasmid and that of the mutant unable to cleave dichlorprop showed that rdpA and sdpA were deleted, whereas the lower pathway genes were unaffected, and that deletion may be caused by genetic rearrangements of the IS91-like elements. Two other dichlorprop-degrading bacterial strains, Rhodoferax sp. strain P230 and Sphingobium herbicidovorans MH, were shown to carry rdpA genes of high similarity to rdpA from strain MC1, but sdpA was not detected. This suggested that rdpA gene products are involved in the degradation of R-dichlorprop in these strains.     

The 45-kb unit of major urinary protein gene organization is a gigantic imperfect palindrome.

The multigene family which codes for the mouse major urinary proteins consists of about 35 genes. Most of these are members of two distinct groups, group 1 and group 2. The group 1 and group 2 genes are organized in head-to-head pairs within 12 to 15 remarkably uniform chromosomal units or domains about 45 kilobase pairs (kb) in size. The 45-kb units are located on chromosome 4, and many of them are adjacent to each other. We propose that the 45-kb unit is a unit both of organization and of evolutionary change. In this study the homologies within the unit were observed by examining, in an electron microscope, heteroduplex and foldback structures made from cloned major urinary protein genes. These show that the 45-kb unit is a gigantic imperfect palindrome. Each arm of the palindrome contains two regions of inverted symmetry of 9.5 and 4.5 kb separated by a 3-kb nonsymmetrical region. We argue that the nonsymmetrical regions arose by a series of deletion events in the two arms of the palindrome. The center of the 45-kb unit is an 8-kb sequence without inverted symmetry flanked by the 9.5-kb regions, which contain the 4-kb genes and their immediate 5' and 3' flanking regions. The junction between adjacent 45-kb units is a 2- to 4-kb sequence without inverted symmetry flanked by the 4.5-kb regions. Some of the 45-kb units are arranged as direct tandem repeats. Others appear to be in inverted orientation with respect to a neighboring unit. Cloned major urinary protein genes show few incidences of the repetitive elements B1, B2, R, and MIF. Two elements, a B1 and an R, may be a constant feature of the 45-kb units. If so, in those cases in which the units are in tandem array, both of these elements will occur with a 45-kb periodicity. A comparison of corresponding parts of different 45-kb units shows that they differ because of a number of deletion or insertion events, particularly in the regions 3' to the genes.     

Transferable Streptomyces DNA amplification and coamplification of foreign DNA sequences.

The 8.8-kb amplifiable unit of DNA of Streptomyces achromogenes subsp. rubradiris, AUD-Sar 1, which carries 0.8-kb terminal direct repeats and a spectinomycin resistance determinant, can mediate high-level amplification of an AUD-Sar 1-derived 8.0-kb DNA sequence not only in S. achromogenes but also in the heterologous host Streptomyces lividans. This was seen upon introduction of AUD-Sar 1 into chloramphenicol-sensitive strains of S. lividans via the temperature-sensitive (39 degrees C) plasmid pMT660, which contains the thiostrepton resistance gene tsr. Following the cultivation of transformants at 39 degrees C on media containing spectinomycin, a number of strains which were unable to grow on thiostrepton and which carried the amplified 8.0-kb DNA sequence as arrays of 200 to 300 copies of tandem 8.0-kb repeats were found. Chloramphenicol-resistant strains of S. lividans did not yield amplified sequences under similar conditions. Studies with plasmids carrying inserted antibiotic resistance genes at two sites of AUD-Sar 1 yielded coamplified sequences which contain the inserted DNA. Transformation with a plasmid carrying a 1.0-kb deletion in AUD-Sar 1 followed by growth under similar conditions yielded a 7.0-kb repeated DNA sequence. Southern analysis revealed the absence of vector sequences located on the right side of AUD-Sar 1 in the input plasmids in all examined DNA samples of amplified strains. In contrast, a majority of the samples revealed the presence at unit copy level of AUD-Sar 1 left-adjacent sequences which are part of the input plasmids and in several samples the presence of certain vector sequences located near them. The results suggest input plasmid integration into the S. lividans chromosome prior to the generation of the amplified sequences and the deletion of AUD-Sar 1 adjacent sequences.     

Identification of VCR, a repeated sequence associated with a locus encoding a hemagglutinin in Vibrio cholerae O1.

We have determined the nucleotide sequence of a 6.3-kb BamHI fragment of the chromosome of Vibrio cholerae 569B that includes the sequence of the mannose-fucose-resistant hemagglutinin reported previously (V.L. Franzon, A. Barker, and P. A. Manning, Infect. Immun. 61:3032-3037, 1993). This region contains nine copies of a 124-bp direct repeat, here named VCR, of imperfect dyad symmetry, that are shown by Southern hybridization to occur at least 60 to 100 times in the V. cholerae O1 chromosome. Large-scale chromosomal mapping suggests that the repeats are confined to about 10% of the chromosome. Related sequences are also found in non-O1 V. cholerae but not in other members of the family Vibrionaceae. However, VCR is unrelated to other previously described repetitive sequences.     

Analysis of sequence upstream of the endogenous H19 gene reveals elements both essential and dispensable for imprinting

Imprinting of the linked and oppositely expressed mouse H19 and Igf2 genes requires a 2-kb differentially methylated domain (DMD) that is located 2 kb upstream of H19. This element is postulated to function as a methylation-sensitive insulator. Here we test whether an additional sequence 5' of H19 is required for H19 and Igf2 imprinting. Because repetitive elements have been suggested to be important for genomic imprinting, the requirement of a G-rich repetitive element that is located immediately 3' to the DMD was first tested in two targeted deletions: a 2.9-kb deletion (Delta D MD Delta G) that removes the DMD and G-rich repeat and a 1.3-kb deletion (Delta G) removing only the latter. There are also four 21-bp GC-rich repetitive elements within the DMD that bind the insulator-associated CTCF (CCCTC-binding factor) protein and are implicated in mediating methylation-sensitive insulator activity. As three of the four repeats of the 2-kb DMD were deleted in the initial 1.6-kb Delta DMD allele, we analyzed a 3.8-kb targeted allele (Delta 3.8kb-5'H19), which deletes the entire DMD, to test the function of the fourth repeat. Comparative analysis of the 5' deletion alleles reveals that (i) the G-rich repeat element is dispensable for imprinting, (ii) the Delta DMD and Delta DMD Delta G alleles exhibit slightly more methylation upon paternal transmission, (iii) removal of the 5' CTCF site does not further perturb H19 and Igf2 imprinting, suggesting that one CTCF-binding site is insufficient to generate insulator activity in vivo, (iv) the DMD sequence is required for full activation of H19 and Igf2, and (v) deletion of the DMD disrupts H19 and Igf2 expression in a tissue-specific manner.     

Chromosome walking shows a highly homologous repetitive sequence present in all the centromere regions of fission yeast

By cloning centromere-linked genes followed by partial overlapping hybridization, we constructed a 210-kb map encompassing the centromere in chromosome II and a 60-kp map near the centromere of chromosome I in the fission yeast Schizosaccharomyces pombe which has three chromosomes. Integration of the cloned sequences into the chromosome and subsequent analyses of tetrads and dyads revealed an approximately 50 kb long domain located in the middle of the 210-kb map, tightly linked to the centromere and greatly reduced in meiotic recombination. This domain contained at least two classes of repetitive sequences. One, designated yn1, was specifically present in a particular chromosome and repeated three times in the 210-kb map of chromosome II. The other, designated dg, was located in all the centromere regions of three chromosomes. One (dgI) and two (dgIIa, dgIIb) copies of the dg were found in the maps of chromosomes I and II, respectively. The dgIIa and dgIIb were arranged with a 20-kb interval within the repetitive domain. In the centric region of chromosome II, 3-4 copies of the dg appeared to exist. By determining the nucleotide sequences of dgI and dgIIa, the dg was identified to be 3.8 kb long. The sequence homology was 99% between dgI and dgIIa. These extraordinarily homologous sequences seemed not to be transcribed into RNA nor to be encoding any protein. The larger part of the dg sequence was internally non-repetitious, a 600-bp region existed which consisted of stretches of several short repeating units. The structures in or surrounding the centromeres of S. pombe appear to be much more complex than those of the budding yeast Saccharomyces cerevisiae.     

Polyoma virus defective DNAs. I. Physical maps of a related set of defective molecules (D76, D91, D92).

Three related polyoma virus species, designated D92 (92% the size of full-length polyoma virus DNA), D91 (91%) and D76 (76%) have been analysed and their structures compared with that of polyoma virus A2 DNA. Three independent methods (restriction endonuclease cleavage, depurination fingerprinting and DNA-DNA hybridization) were used in the analysis.The defective DNAs appear to be: (1) entirely composed of viral sequences (no host DNA sequences were detected): (2) made up in part of long continuous sequences of DNA which appear identical to sequences of A2 DNA (D92 contains continuous sequences from 1 to 72 map units on the physical map of A2 DNA; that is, it contains the entire late region and part of the early region of the viral DNA. D91 and D76 contain those same sequences except for a 1% deletion around 18 map units): (3) made up in part of rearranged viral sequences.Several interesting features were noted about the rearranged sequences present in the defective DNAs. Sequences from the region around 67 map units were found linked to other (non-contiguous) regions of the DNA. Sequences from about 72 map units were linked to sequences from about 1 map unit. Multiple copies of sequences from 67 to 72 map units (from around the origin of DNA replication) were found (4 copies in D91 and D92, and 2 copies in D76).     

A unique structure of a mouse gamma-actin processed pseudogene

We have isolated several gamma-actin-related genes from a mouse genomic library. One of these has been shown to be a gamma-actin processed pseudogene (Tokunga, K., Yoda, K. and Sakiyama, S. (1985) Nucleic Acids Res. 13, 3031-3042). Here, we report the structure of another pseudogene (pMA131). pMA131 contained the sequences corresponding to the carboxyl half of a cytoskeletal actin in which random point mutations as well as insertion and deletion events took place. This region was flanked at its 5' end by the sequences related to mouse repetitive sequences, including the MIF-1 family, and was interrupted by the sequence homologous to the R family which is also a mouse repetitive sequence. The coding region was followed by the sequence corresponding to 3' untranslated region of gamma-actin mRNA.