Chromosomal location by in situ hybridization of the human Sau3A family of DNA repeats

Genomic Tackling of Human Satellite DNA: Breaking Barriers through Time

(Peri)centromeric repetitive sequences and, more specifically, satellite DNA (satDNA) sequences, constitute a major human genomic component. SatDNA sequences can vary on a large number of features, including nucleotide composition, complexity, and abundance. Several satDNA families have been identified and characterized in the human genome through time, albeit at different speeds. Human satDNA families present a high degree of sub-variability, leading to the definition of various subfamilies with different organization and clustered localization. Evolution of satDNA analysis has enabled the progressive characterization of satDNA features. Despite recent advances in the sequencing of centromeric arrays, comprehensive genomic studies to assess their variability are still required to provide accurate and proportional representation of satDNA (peri)centromeric/acrocentric short arm sequences. Approaches combining multiple techniques have been successfully applied and seem to be the path to follow for generating integrated knowledge in the promising field of human satDNA biology.

Dark Matter of Primate Genomes: Satellite DNA Repeats and Their Evolutionary Dynamics

A substantial portion of the primate genome is composed of non-coding regions, so-called "dark matter", which includes an abundance of tandemly repeated sequences called satellite DNA. Collectively known as the satellitome, this genomic component offers exciting evolutionary insights into aspects of primate genome biology that raise new questions and challenge existing paradigms. A complete human reference genome was recently reported with telomere-to-telomere human X chromosome assembly that resolved hundreds of dark regions, encompassing a 3.1 Mb centromeric satellite array that had not been identified previously. With the recent exponential increase in the availability of primate genomes, and the development of modern genomic and bioinformatics tools, extensive growth in our knowledge concerning the structure, function, and evolution of satellite elements is expected. The current state of knowledge on this topic is summarized, highlighting various types of primate-specific satellite repeats to compare their proportions across diverse lineages. Inter- and intraspecific variation of satellite repeats in the primate genome are reviewed. The functional significance of these sequences is discussed by describing how the transcriptional activity of satellite repeats can affect gene expression during different cellular processes. Sex-linked satellites are outlined, together with their respective genomic organization. Mechanisms are proposed whereby satellite repeats might have emerged as novel sequences during different evolutionary phases. Finally, the main challenges that hinder the detection of satellite DNA are outlined and an overview of the latest methodologies to address technological limitations is presented.

The wide distribution and horizontal transfers of beta satellite DNA in eukaryotes

Beta satellite DNA (satDNA), also known as Sau3A sequences, are repetitive DNA sequences reported in human and primate genomes. It is previously thought that beta satDNAs originated in old world monkeys and bursted in great apes. In this study, we searched 7821 genome assemblies of 3767 eukaryotic species and found that beta satDNAs are widely distributed across eukaryotes. The four major branches of eukaryotes, animals, fungi, plants and Harosa/SAR, all have multiple clades containing beta satDNAs. These results were also confirmed by searching whole genome sequencing data (SRA) and PCR assay. Beta satDNA sequences were found in all the primate clades, as well as in Dermoptera and Scandentia, indicating that the beta satDNAs in primates might originate in the common ancestor of Primatomorpha or Euarchonta. In contrast, the widely patchy distribution of beta satDNAs across eukaryotes presents a typical scenario of multiple horizontal transfers.

The boundary of macaque rDNA is constituted by low-copy sequences conserved during evolution

In Macaca mulatta, the single rDNA array is flanked by a patchwork of sequences including subregions of human Yp11.2, 4q35.2, and 10p15.3. This composite DNA region is characterized by unique or low-copy sequences, resembling a potentially transcribed region. The analysis of Cercopithecus aethiops, Presbytis cristata, and Hylobates lar suggests that this complex sequence organization could be shared by Old World monkey and lesser ape species. After the lesser apes/great apes divergence, the unique or nonduplicated DNA region underwent amplification and spreading, preferentially marking the p arm of acrocentric chromosomes bearing the rDNA. The molecular analysis of human acrocentric chromosomes revealed some extent of remodeling of the rDNA boundary: near the human NOR, a large 4q35.2 duplication partially resembles that found in MMU; conversely, infrequently represented Yp11.2 sequences totally differed from those of the macaque, and 10p15.3 sequences were lacking. Thus, although evolutionary events modified the sequence organization of the MMU rDNA boundary, its overall sequence feature and the preferential location in vicinity to the NOR have been conserved.

High-resolution organization of mouse centromeric and pericentromeric DNA

We studied the organization of mouse satellite 3 and 4 (MS3 and MS4) in comparison with major (MaSat) and minor (MiSat) DNA sequences, located in the centromeric and pericentromeric regions of mouse telocentric chromosomes by fiber-FISH. The centromeric region consists of a small block of MiSat and MS3 followed by a pericentromeric block of MaSat with MS4. Inside the block of the long-range cluster, MaSat repeats intermingle mostly with MS4, while MiSat intermingle with MS3. The distribution of GC-rich satellite DNA fragments is less strict than that of AT-rich fragments; it is possible to find MS3 fragments in the MaSat array and MS4 fragments in the MiSat array. The methylation pattern does not fully correspond to one of the four families of satellite DNA (satDNA). In each satDNA fragment only part of the DNA is methylated. MS3 and MS4 are heavily methylated being GC-rich. Pericentomeric satellite DNA fragments are more methylated than centromeric ones. Among the four families of satDNA MS4 is the most methylated while MiSat is methylated only to a minimal extent. Estimation of the average fragment length and average distance between fragments shows that the range of the probes used does not cover the whole centromeric region. The existence of unknown sequences in the mouse centromere is likely.

Evolution of beta satellite DNA sequences: evidence for duplication-mediated repeat amplification and spreading

In this article, we report studies on the evolutionary history of beta satellite repeats (BSR) in primates. In the orangutan genome, the bulk of BSR sequences was found organized as very short stretches of approximately 100 to 170 bp, embedded in a 60-kb to 80-kb duplicated DNA segment. The estimated copy number of the duplicon that carries BSR sequences ranges from 70 to 100 per orangutan haploid genome. In both macaque and gibbon, the duplicon mapped to a single chromosomal region at the boundary of the rDNA on the marker chromosome (chromosome 13 and 12, respectively). However, only in the gibbon, the duplicon comprised 100 bp of beta satellite. Thus, the ancestral copy of the duplicon appeared in Old World monkeys ( approximately 25 to approximately 35 MYA), whereas the prototype of beta satellite repeats took place in a gibbon ancestor, after apes/Old World monkeys divergence ( approximately 25 MYA). Subsequently, a burst in spreading of the duplicon that carries the beta satellite was observed in the orangutan, after lesser apes divergence from the great apes-humans lineage ( approximately 18 MYA). The analysis of the orangutan genome also indicated the existence of two variants of the duplication that differ for the length (100 or 170 bp) of beta satellite repeats. The latter organization was probably generated by nonhomologous recombination between two 100-bp repeated regions, and it likely led to the duplication of the single Sau3A site present in the 100-bp variant, which generated the prototype of Sau3A 68-bp beta satellite tandem organization. The two variants of the duplication, although with a different ratios, characterize the hominoid genomes from the orangutan to humans, preferentially involving acrocentric chromosomes. At variance to alpha satellite, which appeared before the divergence of New World and Old World monkeys, the beta satellite evolutionary history began in apes ancestor, where we have first documented a low-copy, nonduplicated BSR sequence. The first step of BSR amplification and spreading occurred, most likely, because the BSR was part of a large duplicon, which underwent a burst dispersal in great apes' ancestor after the lesser apes' branching. Then, after orangutan divergence, BSR acquired the clustered structural organization typical of satellite DNA.

Characterization of restriction enzyme banding polymorphisms in human chromosomes

C and Re-banding chromosome heteromorphisms were analysed in blood cultures from 43 normal individuals. Restriction enzymes used were AluI, DdeI, HaeIII, and MboI. Chromosome pairs exhibiting heteromorphisms were: 1, 3, 4, 6, 9, 10, 12-16, and 18-22. Each individual showed a specific combination of C- and Re-banding heteromorphisms not shared by any other individual in the series. Some polymorphisms could be detected by all the banding methods used. Others could be detected by some of the banding methods, and in some cases by only one of the banding methods used. The efficiency of each banding method to detect chromosomal polymorphisms depended on the type of polymorphism and the chromosomal pair analysed. Our results indicate that Re-banding polymorphisms occur due to changes in base composition of different fractions of heterochromatin or due to the presence or absence of different heterochromatic subsets. C- and Re-banding are complementary methods that expand the identification of chromosomal markers and which can be used to identify the parental origin of individual chromosomes.

Human genome dispersal and evolution of 4q35 duplications and interspersed LSau repeats

We have investigated the evolutionary history of the 4q35 paralogous region, and of a sub-family of interspersed LSau repeats. In HSA, 4q35 duplications were localized at 1q12, 3p12.3, 4q35, 10q26, 20cen, whereas duplicons and interspersed LSau repeats simultaneously labeled the p arm of acrocentric chromosomes. A multi-site localization of 4q35-like sequences was also observed in PTR, GGO, PPY, HLA (Hominoidea) and PAN (Old World monkey), thus indicating that duplications of this region have occurred extensively in the two clades, which diverged at least 25 million years ago. In HSA, PTR and PAN, 4q35-derived duplicons co-localized with rDNA, whereas in GGO and PPY this association was partially lacking. In PAN, the single- and multi-site distribution of rDNA and paralogous sequences, respectively, indicates a different timing of sequence dispersal. The sub-family of interspersed LSau repeats showed a lesser dispersal than 4q35 duplications both in man and great apes. This finding suggests that duplications and repeated sequences have undergone different expansion/contraction events during evolution. The mechanisms underlying the dispersal of paralogous regions may be further derived through studies comparing the detailed structural organization of these genomic regions in man and primates.

CENP-C binds the alpha-satellite DNA in vivo at specific centromere domains

CENP-C is a fundamental component of the centromere, highly conserved among species and necessary for the proper assembly of the kinetochore structure and for the metaphase-anaphase transition. Although CENP-C can bind DNA in vitro,the identification of the DNA sequences associated with it in vivo and the significance of such an interaction have been, until now, elusive. To address this problem we took advantage of a chromatin-immunoprecipitation procedure and applied this technique to human HeLa cells. Through this approach we could establish that: (1) CENP-C binds the alpha-satellite DNA selectively; (2) the CENP-C region between amino acids 410 and 537, previously supposed to contain a DNA-binding domain, is indeed required to perform such a function in vivo;and (3) the profile of the alpha-satellite DNA associated with CENP-C is essentially identical to that recognized by CENP-B. However, further biochemical and ultrastructural characterization of CENP-B/DNA and CENP-C/DNA complexes, relative to their DNA components and specific spatial distribution in interphase nuclei, surprisingly reveals that CENP-C and CENP-B associate with the same types of alpha-satellite arrays but in distinct non-overlapping centromere domains. Our results, besides extending previous observations on the role of CENP-C in the formation of active centromeres, show, for the first time, that CENP-C can associate with the centromeric DNA sequences in vivo and, together with CENP-B, defines a highly structured organization of the alpha-satellite DNA within the human centromere.

Genomic differentiation of 18S ribosomal DNA and beta-satellite DNA in the hominoid and its evolutionary aspects

The chromosome localization of two human multisequence families, rDNA and beta-satellite (beta-sat) DNA, was determined in humans and apes using double color fluorescence in-situ hybridization. Both DNA probes showed a distinct hybridization pattern with species-specific variations in hominoids. The stepwise differentiation of the integration, amplification, multilocalization, and reduction of the DNAs were observed interspecifically through the seven species examined. The stepwise events allowed us to trace back a phylogenetic divergence of the hominoid at the cytogenetic level. The manifestation of the events revealed that variations of the Y chromosome and acrocentric autosomes were synapomorphic characters in the divergence and those of metacentric autosomes were autapomorphic characters. Multilocalization of rDNA in the hominoid could also be interpreted as a result of translocations in terms of hetero-site crossover followed by a centric fission and formation of an acrocentric chromosome. Based on the observed rearrangements of rDNA and beta-sat DNA, we propose the following chromosomal phylogenetic divergence order in hominoids: gibbon-siamang-orangutan-gorilla-human-chimpanzee-bonobo. Our data provide additional evidence that evolution of the hominoid can be effectively studied using cytogenetic approaches.

Frequent hypomethylation in Wilms tumors of pericentromeric DNA in chromosomes 1 and 16

Rearrangements in the pericentromeric heterochromatin of chromosome 1 or 16 are often found in many types of cancers, including Wilms tumors, and have been suggested to contribute to oncogenesis or tumor progression. The oncogenic potential of these rearrangements has been ascribed to the resulting chromosome arm imbalances affecting the dosage of tumor suppressor genes or protooncogenes. Because DNA hypomethylation has been linked to rearrangements in the pericentromeric regions of chromosome 1 and 16 in two types of non-cancer cell populations, we examined methylation of normally highly methylated satellite DNA sequences in these regions in Wilms tumors. Hypomethylation was found to be frequent in juxtacentromeric (satellite 2) sequences and, especially, in centromeric (satellite alpha) sequences of chromosome 1. Hypomethylation of satellite 2 DNA of chromosome 16 showed a high degree of concordance with that of satellite 2 DNA of chromosome 1. We discuss the relationship of this satellite DNA hypomethylation in Wilms tumors to chromosome aberrations, as determined by assays for loss of heterozygosity.

Complex beta-satellite repeat structures and the expansion of the zinc finger gene cluster in 19p12

We investigated the organization, architecture, and evolution of the largest cluster ( approximately 4 Mb) of Krüppel-associated box zinc finger (KRAB-ZNF) genes located in cytogenetic band interval 19p12. A highly integrated physical map ( approximately 700 kb) of overlapping cosmid and BAC clones was developed between genetic STS markers D19S454 and D19S269. Using ZNF91 exon-specific probes to interrogate a detailed EcoRI restriction map of the region, ZNF genes were found to be distributed in a head-to-tail fashion throughout the region with an average density of one ZNF duplicon every 150-180 kb of genomic distance. Sequence analysis of 208,967 bp of this region indicated the presence of two putative ZNF genes: one consisting of a novel member of this gene family (ZNF208) expressed ubiquitously in all tissues examined and the other representing a nonprocessed pseudogene (ZNF209), located 450 kb proximal to ZNF208. Large blocks of ( approximately 25-kb) inverted beta-satellite repeats with a remarkably symmetrical higher order repeat structure were found to bracket the functional ZNF gene. Hybridization analysis using the beta-satellite repeat as a probe indicates that beta-satellite interspersion between ZNF gene cassettes is a general property for 1.5 Mb of the ZNF gene cluster in 19p12. Both molecular clock data as well as a retroposon-mapping molecular fossil approach indicate that this ZNF cluster arose early during primate evolution (approximately 50 million years ago). We propose an evolutionary model in which heteromorphic pericentromeric repeat structures such as the beta satellites have been coopted to accommodate rapid expansion of a large gene family over a short period of evolutionary time. [The sequence data described in this paper have been submitted to GenBank under accession nos. AC003973 and AC004004.]

Concerted evolution of members of the multisequence family chAB4 located on various nonhomologous chromosomes

During the last years it became obvious that a lot of families of long-range repetitive DNA elements are located within the genomes of mammals. The principles underlying the evolution of such families, therefore, may have a greater impact than anticipated on the evolution of the mammalian genome as a whole. One of these families, called chAB4, is represented with about 50 copies within the human and the chimpanzee genomes and with only a few copies in the genomes of gorilla, orang-utan, and gibbon. Members of chAB4 are located on 10 different human chromosomes. FISH of chAB4-specific probes to chromosome preparations of the great apes showed that chAB4 is located, with only one exception, at orthologous places in the human and the chimpanzee genome. About half the copies in the human genome belong to two species-specific subfamilies that evolved after the divergence of the human and the chimpanzee lineages. The analysis of chAB4-specific PCR-products derived from DNA of rodent/human cell hybrids showed that members of the two human-specific subfamilies can be found on 9 of the 10 chAB4-carrying chromosomes. Taken together, these results demonstrate that the members of DNA sequence families can evolve as a unit despite their location at multiple sites on different chromosomes. The concerted evolution of the family members is a result of frequent exchanges of DNA sequences between copies located on different chromosomes. Interchromosomal exchanges apparently take place without greater alterations in chromosome structure.

Contiguous arrays of satellites 1, 3, and beta form a 1.5-Mb domain on chromosome 22p

The centromeric heterochromatin of all the human chromosomes is composed of megabases of tandemly repeated satellite DNA. Some of these sequences have been implicated in centromere formation and/or segregation but the arrangement of most of them on a large scale remains largely uncharacterized because of the difficulties in analyzing repetitive DNA. The alpha satellite is the best studied and is present in large tandem arrays at all centromeres, but satellites 1, 3, and beta have also been detected on a number of chromosomes. Here we have used FISH to extended DNA fibers to analyze these satellites on the short arm of the acrocentric chromosome 22. The satellite sequences were found to form a continuous domain spanning about 1.5 Mb and consisting of a major block of satellite 1 flanked by two blocks of beta satellite and three blocks of satellite 3. These six blocks of satellite DNA appear to form contiguous arrays with little intervening DNA.

Spontaneous apoptosis in mouse F4N-S erythroleukemia cells induces a nonrandom fragmentation of DNA

This study characterizes the fragmented DNA of mouse erythroleukemia (MEL) cells spontaneously entering apoptosis. Fragmented DNA was isolated by introducing a novel procedure that ensured a complete extraction of the characteristic oligonucleosomal ladder. As the results show, less than 10% of DNA of apoptotic cells is fragmented in this form. The main conclusion from experiments to characterize the nature of fragmented DNA is that spontaneous apoptosis induces a nonrandom cleavage of genomic DNA. The Southern analysis performed with total apoptotic DNA revealed that it is strongly enriched in interspersed repetitive sequences. In situ hybridizations with such DNA showed further than in interphase nuclei these sequences flock together and form clusters spread throughout the whole nuclear area whereas in mitotic chromosomes they are located predominantly at their pericentromeric/peritelomeric ends. Partial cloning and sequencing reinforces the notion that the apoptotic DNA is representative for a heterochromatinic portion of the mouse genome. Support for such an unexpected conclusion is coming also from experiments indicating that this DNA is heavily methylated and poorly transcribed.

Identification of amplified DNA sequences in breast cancer and their organization within homogeneously staining regions

A modified comparative genomic hybridization (mCGH) technique was used to identify and map amplified DNA sequences in six homogeneously staining regions (hsr) from three primary breast carcinomas. Five different chromosomal regions and bands were identified as sites of amplification: 8p1, 17q21.1, 17q23 (two cases), 19q13.3, and 20q13.3. The mCGH site located on 17q21.1 was demonstrated to correspond to a 50-100-fold amplification of ERBB2. Further in situ hybridization experiments were used to confirm the mCGH results and to characterize the organization of the amplified sequences within the hsr. In five of six instances, two or more chromosomal regions were found amplified in the same hsr. In the tumor with the less modified karyotype, the two hsr comprised DNA sequences from three different chromosomes and showed different patterns of amplification. In the tumor with the most rearranged karyotype, the hsr-carrying chromosomes were formed by the translocation and amplification of sequences from three or four different chromosomal sites. This illustrates the complexity of the amplification process in breast cancers.

Differential digestion of the centromeric heterochromatic regions of the 5-azacytidine-decondensed human chromosomes 1, 9, 15, and 16 by NdeII and Sau3AI restriction endonucleases

A study on the factors involved in chromosome digestion by restriction endonuclease was carried out on 5-azacytidine treated and untreated human chromosomes 1, 9, 15 and 16 by using NdeII and Sau3AI isoschizomers. After treatment with 5-azacytidine, chromosomes 1, 9, 15, and 16 showed two differentiated areas at the centromeric regions: the centromere, fully condensed, and the pericentromeric heterochromatin, decondensed. Chromosomes not treated with 5-azacytidine after digestion with Sau3AI and NdeII showed all the centromeric regions undigested, except pair number 1, digested at the pericentromeric area. Digestion of the 5-azacytidine decondensed chromosomes with Sau3AI and NdeII showed the centromeres undigested in the four chromosome pairs while the pericentromeric heterochromatin appeared largely digested. Other factors, different to target distribution, are necessary to explain the pattern of restriction endonuclease digestion observed in this communication.

Human ribosomal RNA gene cluster: identification of the proximal end containing a novel tandem repeat sequence

Human ribosomal RNA genes (rDNA) are arranged as tandem repeat clusters on the short arms of five pairs of acrocentric chromosomes. We have demonstrated that a majority of the rDNA clusters are detected as 3-Mb DNA fragments when released from human genomic DNA by EcoRV digestion. This indicated the absence of the EcoRV restriction site within the rDNA clusters. We then screened for rDNA-positive cosmid clones using a chromosome 22-specific cosmid library that was constructed from MboI partial digests of the flow-sorted chromosomes. Three hundred twenty rDNA-positive clones negative for the previously reported distal flanking sequence (pACR1) were chosen and subjected to EcoRV digestion. Seven clones susceptible to EcoRV were further characterized as candidate clones that might have been derived from the junctions of the 3-Mb rDNA cluster. We identified one clone containing part of the rDNA unit sequence and a novel flanking sequence. Detailed analysis of this unique clone revealed that the coding region of the last rRNA gene located at the proximal end of the cluster is interrupted with a novel sequence of approximately 147 bp that is tandemly repeated and is connected with an intervening 68-bp unique sequence. This junction sequence was readily amplified from chromosomes 21 and 15 as well as 22 using the polymerase chain reaction. Fluorescence in situ hybridization further indicated that the approximately 147-bp sequence repeat is commonly distributed among all the acrocentric short arms.

Analysis of GC-rich repetitive nucleotide sequences in great apes

The genomes of four primate species, belonging to the families Pongidae (chimpanzee, gorilla, and orangutan) and Hylobatidae (gibbons), have been analyzed for the presence and organization of two human GC-rich heterochromatic repetitive sequences: beta Satellite (beta Sat) and LongSau (LSau) repeats. By Southern blot hybridization and PCR, both families of repeats were detected in all the analyzed species, thus indicating their origin in an ape ancestor. In the chimpanzee and gorilla, as in man, beta Sat sequences showed a 68-bp Sau3A periodicity and were preferentially organized in large clusters, whereas in the orangutan, they were organized in DNA fragments of 550 bp, which did not seem to be characterized by a tandem organization. On the contrary, in each of the analyzed species, the bulk of LSau sequences showed a longer Sau3A periodicity than that observed in man (450-550 bp). Furthermore, only in the chimpanzee genome some of LSau repeats seemed to be interspersed within blocks of beta Sat sequences. This sequence organization, which also characterizes the human genome, is probably absent in the gorilla. In fact, the analysis of a gorilla genomic library suggested that LSau repeats are not preferentially in linkage with beta Sat sequences. Moreover, LSau sequences were found in a genomic sector characterized by the simultaneous presence of L1 and (CA) repeats, as well as of anonymous sequences and known genes. In spite of the different sequence organization, the nucleotide differences between complete human and gorilla LSau repeats were very few, whereas one gorilla LSau repeat, interrupted by a probably-truncated L1 transposon, showed a higher degree of divergence.(ABSTRACT TRUNCATED AT 250 WORDS)

Functional cloning of centromere protein B (CENP-B) box-enriched alphoid DNA repeats utilizing the sequence-specific DNA binding activity of human CENP-B in vitro

The centromere is a distinctive portion of the chromosome consisting of 'centromere DNA' and 'centromere proteins'. Recently, a direct molecular interaction was discovered between human centromere protein B (CENP-B) and human centromeric alphoid repeats. This enabled us to isolate the CENP-B-targeted centromeric DNA sequences by positively utilizing the biologic activity of CENP-B in vitro. In the previous model experiment, we found that oligonucleotides covering the CENP-B binding sequences were enriched by the DNA immunoprecipitation procedure. Here we apply the same technique to the direct isolation of a functional part of human centromeric DNA from a genomic DNA library. Restriction digestion of two isolated clones showed the typical repeating pattern of an alphoid family that is known to localize at the centromeric region of all human chromosomes. Sequence analysis showed that these two clones frequently contain the authentic CENP-B binding motif, CTTCGTTGGAAACGGGA, or a new one with one base replaced, CTTCGTTGGAAACGGGT. The frequent distribution of these motifs suggests that the isolated sequences are directly involved in the organization of centromeric heterochromatin at the primary constriction in conjunction with CENP-B.

Identification, characterisation and clinical applications of cosmids from the telomeric and centromeric regions of the long arm of chromosome 22

Using human telomeric repeats and centromeric alpha repeats, we have identified adjacent single copy cosmid clones from human chromosome 22 cosmid libraries. These single copy cosmids were mapped to chromosome 22 by fluorescence in situ hybridisation (FISH). Based on these cosmids, we established contigs that included part of the telomeric and subtelomeric regions, and part of the centromeric and pericentromeric regions of the long arm of human chromosome 22. Each of the two cosmid contigs consisted of five consecutive steps and spanned approximately 100-150 kb at both extreme ends of 22q. Moreover, highly informative polymorphic markers were identified in the telomeric region. Our results suggest that the telomere specific repeat (TTAGGG)n encompasses a region that is larger than 40 kb. The cosmid contigs and restriction fragment length polymorphism markers described here are useful tools for physical and genetic mapping of chromosome 22, and constitute the basis of further studies of the structure of the subtelomeric and pericentromeric regions of 22q. We also demonstrate the use of these clones in clinical diagnosis of different chromosome 22 aberrations by FISH.

The DNA rearrangement associated with facioscapulohumeral muscular dystrophy involves a heterochromatin-associated repetitive element: implications for a role of chromatin structure in the pathogenesis of the disease

Facioscapulohumeral muscular dystrophy (FSHD) is an autosomal dominant form of muscular dystrophy. The FSHD locus has been linked to the most distal genetic markers on the long arm of chromosome 4. Recently, a probe was identified that detects an EcoRI fragment length polymorphism which segregates with the disease in most FSHD families. Within the EcoRI fragment lies a tandem array of 3.2 kb repeats. In several familial cases and four independent sporadic FSHD mutations, the variation in size of the EcoRI fragment was due to a decrease in copy number of the 3.2 kb repeats. To gain further insight into the relationship between the tandem array and FSHD, a single 3.2 kb repeat unit was characterized. Fluorescence in situ hybridization (FISH) demonstrates that the 3.2 kb repeat cross-hybridizes to several regions of heterochromatin in the human genome. In addition, DNA sequence analysis of the repeat reveals a region which is highly homologous to a previously identified family of heterochromatic repeats, LSau. FISH on interphase chromosomes demonstrates that the tandem array of 3.2 kb repeats lies within 215 kb of the 4q telomere. Together, these results suggest that the tandem array of 3.2 kb repeats, tightly linked to the FSHD locus, is contained in heterochromatin adjacent to the telomere. In addition, they are consistent with the hypothesis that the gene responsible for FSHD may be subjected to position effect variegation because of its proximity to telomeric heterochromatin.

The organisation of repetitive sequences in the pericentromeric region of human chromosome 10

Three satellite DNA families are present in the pericentromeric region of chromosome 10; the alpha satellite and two 5 bp satellite families defined here as satellites 2 and 3. Pulsed field gel electrophoresis (PFGE) demonstrates that these sequences are organised into five discrete arrays which are linked within a region of approximately 5.3 Megabases (Mb) of DNA. The alpha satellite is largely confined to a 2.2 Mb array which is flanked on its p arm side by two 100-150 kb satellite 3 arrays and on its q arm side by a 900 kb satellite 2 array and a further 320 kb satellite 3 array. This linear order is corroborated by fluorescent in situ hybridisation analyses. In total, these arrays account for 3.6 Mb of DNA in the pericentromeric region of chromosome 10. These data provide both physical information on sequences which may be involved in centromere function and a map across the centromere which has the potential to link yeast artificial chromosome (YAC) contigs currently being developed on both arms of this chromosome.

Organization of the variant domains of alpha satellite DNA on human chromosome 21

The de novo creation of long, homogeneous, satellite DNA domains was postulated previously to occur by saltatory amplification. In this paper, pulsed field gel electrophoresis analysis of the alpha satellite DNA block organization of the human chromosome 21 supports this hypothesis. Double-dimension electrophoresis indicated that the variant copies of the basic alpha satellite repeat of chromosome 21 are organized in a single 3,150 Kb-long domain. It was also established that the other satellite DNAs found in man (beta, II, and III) are organized independently of the alpha satellite DNA block of the same chromosome.

Analysis of human extrachromosomal DNA elements originating from different beta-satellite subfamilies

By screening total human DNA with probes derived from the small polydisperse circular (spc) DNA fraction of cultured human cells, we identified three clones that carry long stretches of beta-satellite DNA. Further experiments have shown that the three sequences belong to at least two different beta-satellite subfamilies, which are characterized by different higher order subunits. Members of one of these subfamilies are located in the cytological satellites of all acrocentric chromosomes, whereas members of another are located on the short arms of the acrocentrics on both sides of the stalk regions and also in the centromeric regions of chromosomes 1 and 9. This is the first time that beta-satellite sequences obtained from the spcDNA of human cells have been assigned to beta-satellite subfamilies that are organized as long arrays of tandemly arranged higher order monomers. This indicates that beta-satellite sequences can be excised from their chromosomal loci via intrastrand-recombination processes.

Mammalian chromosome structure

The DNA sequences that are necessary for the formation of a functional mammalian chromosome are thought to be the origins of replication, the telomeres and the centromere. Telomere structure is now well understood, with the functional element characterized as the motif (TTAGGG)n. The structures of the DNA regions that contain origins of replication and a centromere are known, but the functionally important elements within these regions are still only poorly defined.

Structure of DNA near long tandem arrays of alpha satellite DNA at the centromere of human chromosome 7

The centromeric regions of human chromosomes contain long tracts of tandemly repeated DNA, of which the most extensively characterized is alpha satellite. In a screen for additional centromeric DNA sequences, four phage clones were obtained which contain alpha satellite as well as other sequences not usually found associated with tandemly repeated alpha satellite DNA, including L1 repetitive elements, an Alu element, and a novel AT-rich repeated sequence. The alpha satellite DNA contained within these clones does not demonstrate the higher-order repeat structure typical of tandemly repeated alpha satellite. Two of the clones contain inversions; instead of the usual head-to-tail arrangement of alpha satellite monomers, the direction of the monomers changes partway through each clone. The presence of both inversions was confirmed in human genomic DNA by polymerase chain reaction amplification of the inverted regions. One phage clone contains a junction between alpha satellite DNA and a novel low-copy repeated sequence. The junction between the two types of DNA is abrupt and the junction sequence is characterized by the presence of runs of A's and T's, yielding an overall base composition of 65% AT with local areas > 80% AT. The AT-rich sequence is found in multiple copies on chromosome 7 and homologous sequences are found in (peri)centromeric locations on other human chromosomes, including chromosomes 1, 2, and 16. As such, the AT-rich sequence adjacent to alpha satellite DNA provides a tool for the further study of the DNA from this region of the chromosome. The phage clones examined are located within the same 3.3-Mb SstII restriction fragment on chromosome 7 as the two previously described alpha satellite arrays, D7Z1 and D7Z2. These new clones demonstrate that centromeric repetitive DNA, at least on chromosome 7, may be more heterogeneous in composition and organization than had previously been thought.

Structure of the pericentric long arm region of the human Y chromosome

We have analysed the sequence organization of the DNA in the pericentric region of the long arm of the human Y chromosome. The structures of one cosmid and three yeast artificial chromosome clones were determined. The region consists of a mosaic of the known 5, 48 and 68 base-pair tandemly repeated sequences and at least five novel repeated sequence families. A long range-map of approximately 3.5 x 10(6) base-pairs of genomic DNA was constructed that placed the clones between about 500 x 10(3) and 850 x 10(3) base-pairs from the long arm edge of the centromeric alphoid DNA array.

The organisation of repetitive DNA sequences on human chromosomes with respect to the kinetochore analysed using a combination of oligonucleotide primers and CREST anticentromere serum

The spatial relationship between the families of repetitive DNAs present at the centromeres of human chromosomes and the position of the kinetochore was examined by combining immunocytochemistry with the PRINS oligonucleotide primer extension technique. Heterochromatic domains were decondensed with 5'-azacytidine to facilitate this study. Using this approach our results clearly show that the alphoid DNA sequences are closely associated with the kinetochore of human chromosomes. Simple-sequence satellite DNAs occupy separate, non-overlapping domains within the centromere. These two major families are separated by a third, relatively low-copy repetitive DNA family, SAU-3A. Pulse-field gel electrophoresis was employed to analyse the centromeric domain of human chromosome no. 9 in more detail and the results although preliminary support the conclusions drawn from the immunocytochemistry/PRINS approach.

Beta satellite DNA: characterization and localization of two subfamilies from the distal and proximal short arms of the human acrocentric chromosomes

beta satellite is a repetitive DNA family that consists of approximately 68-bp monomers tandemly repeated in arrays of at least several hundred kilobases. In this report we describe and characterize two subfamilies located exclusively on the human acrocentric chromosomes. The first subfamily is defined by a homogeneous approximately 2.0-kb higher-order repeat unit and is located primarily distal to the ribosomal RNA gene cluster, based both on fluorescence in situ hybridization to metaphase chromosomes and on filter hybridization analysis of translocation chromosomes isolated in somatic cell hybrids. In contrast, the second subfamily is located both distal and proximal to the ribosomal RNA gene cluster on the same acrocentric chromosomes. The DNA sequences of a number of monomers from these two subfamilies are compared to each other and to other beta satellite monomers to assess both inter- and intrasubfamily sequence relationships for these monomers.

A homologous subfamily of satellite III DNA on human chromosomes 14 and 22

We describe a new subfamily of human satellite III DNA that is represented on two different acrocentric chromosomes. This DNA is composed of a tandemly repeated array of diverged 5-base-pair monomer units of the sequence GGAAT or GGAGT. These monomers are organised into a 1.37-kilobase higher-order structure that is itself tandemly reiterated. Using a panel of somatic cell hybrids containing specific human chromosomes, this higher-order structure is demonstrated on chromosomes 14 and 22, but not on the remaining acrocentric chromosomes. In situ hybridisation studies have localised the sequence to the proximal p-arm region of these chromosomes. Analysis by pulsed-field gel electrophoresis (PFGE) reveals that 70-110 copies of the higher-order structure are tandemly organised on a chromosome into a major domain which appears to be flanked on both sides by non-tandemly repeated genomic DNA. In addition, some of the satellite III sequences are interspersed over a number of other PFGE fragments. This study provides fundamental knowledge on the structure and evolution of the acrocentric chromosomes, and should extend our understanding of the complex process of interchromosomal interaction which may be responsible for Robertsonian translocation and meiotic nondisjunction involving these chromosomes.

Potential genetic functions of tandem repeated DNA sequence blocks in the human genome are based on a highly conserved "chromatin folding code"

This review is based on a thorough description of the structure and sequence organization of tandemly organized repetitive DNA sequence families in the human genome; it is aimed at revealing the locus-specific sequence organization of tandemly repetitive sequence structures as a highly conserved DNA sequence code. These repetitive so-called "super-structures" or "higher-order" structures are able to attract specific nuclear proteins. I shall define this code therefore as a "chromatin folding code". Since locus-specific superstructures of tandemly repetitive sequence units are present not only in the chromosome centromere or telomere region but also on the arms of the chromosomes, I assume that their chromatin folding code may contribute to, or even organize, the folding pathway of the chromatin chain in the nucleus. The "chromatin folding code" is based on its specific "chromatin code", which describes the sequence dependence of the helical pathway of the DNA primary sequence (i.e., secondary structure) entrapping the histone octamers in preferential positions. There is no periodicity in the distribution of the nucleosomes along the DNA chain. The folding pathway of the nucleosomal chromatin chain is however still flexible and determined by e.g., the length of the DNA chain between the nucleosomes. The fixation and stabilization of the chromatin chain in the space of the nucleus (i.e., its "functional state") may be mediated by additionally unique DNA protein interactions that are dictated by the "chromatin folding code". The unique DNA-protein interactions around the centromeres of human chromosomes are revealed for example by their "C-banding". I wish to stress that it is not my aim to relate each block of repetitive DNA sequences to a specific "chromatin folding code", but I shall demonstrate that there is an inherent potential for tandem repeated sequence units to develop a locus-specific repetitive higher order structure; this potential may create a specific chromatin folding code whenever a selection force exists at the position of this repetitive DNA structure in the genome.

Human beta satellite DNA: genomic organization and sequence definition of a class of highly repetitive tandem DNA

We describe a class of human repetitive DNA, called beta satellite, that, at a most fundamental level, exists as tandem arrays of diverged approximately equal to 68-base-pair monomer repeat units. The monomer units are organized as distinct subsets, each characterized by a multimeric higher-order repeat unit that is tandemly reiterated and represents a recent unit of amplification. We have cloned, characterized, and determined the sequence of two beta satellite higher-order repeat units: one located on chromosome 9, the other on the acrocentric chromosomes (13, 14, 15, 21, and 22) and perhaps other sites in the genome. Analysis by pulsed-field gel electrophoresis reveals that these tandem arrays are localized in large domains (50-300 kilobase pairs) that are marked by restriction fragment length polymorphisms. In total, beta satellite sequences comprise several million base pairs of DNA in the human genome. Analysis of this DNA family should permit insights into the nature of chromosome-specific and nonspecific modes of satellite DNA evolution and provide useful tools for probing the molecular organization and concerted evolution of the acrocentric chromosomes.

Linkage in human heterochromatin between highly divergent Sau3A repeats and a new family of repeated DNA sequences (HaeIII family)

The hybridization of human DNA with three non-cross-hybridizing monomers (68 bp in length) of the heterochromatic Sau3A family of DNA repeats, indicates the coexistence within a Sau3A-positive genomic block of divergent Sau3A units as well as of unrelated sequences. To gain some insight into the structure of these human heterochromatic DNA regions, three previously cloned Sau3A-positive genomic fragments (with a total length of approximately 1900 base-pairs (bp] were sequenced. The analysis of the sequences showed the presence of clustered Sau3A units with different degrees of divergence and of two DNA regions of approximately 100 bp and 291 bp in length, unrelated to the family of repeats. A consensus sequence derived from the 24 identified Sau3A monomers presents, among highly variable regions, two less variant regions of 8 bp and 10 bp in length, respectively. The Sau3A-unrelated DNA fragment 291 bp in length, used as a probe on genomic DNA digested with a series of restriction enzymes, defines a "new" family of DNA repeats possessing periodicities for HaeIII (HaeIII family). Sau3A and HaeIII repeats display a high degree of linkage in a collection of Sau3A-positive genomic recombinant phages.