A study of sequence homologies in four satellite DNAs of man

Locus-specific differential expression of human satellite sequences in the nuclei of cancer cells and heat-shocked cells

Human satellitess(HSats) are pericentric, tandemly repeating satellite DNA sequences in the human genome. While silent in normal cells, a subset of HSat2 noncoding RNA is expressed and accumulates in the nucleus of cancer cells. We developed a FISH-based approach for identification of the distribution of three subfamilies of HSat2 (A1, A2, B) sequences on individual human chromosomes. Further, using the HSat subfamily annotations in the T2T completed centromere satellite (CenSat) sequence, we isolated, defined and mapped differentially expressed sequence variants of nuclear-restricted HSat2 and HSat3 RNA from cancer cell lines and heat-shocked cells. We identified chromosome-specific and subfamily-specific expression of HSat2 and HSat3 and established a computational pipeline for differential expression analysis of tandemly repeated satellite sequences. Results suggest the differential expression of chromosome-specific HSat2 arrays in the human genome may underlie their accumulation in cancer cells and that specific HSat3 loci are upregulated upon heat shock.

A classical revival: Human satellite DNAs enter the genomics era

The classical human satellite DNAs, also referred to as human satellites 1, 2 and 3 (HSat1, HSat2, HSat3, or collectively HSat1-3), occur on most human chromosomes as large, pericentromeric tandem repeat arrays, which together constitute roughly 3% of the human genome (100 megabases, on average). Even though HSat1-3 were among the first human DNA sequences to be isolated and characterized at the dawn of molecular biology, they have remained almost entirely missing from the human genome reference assembly for 20 years, hindering studies of their sequence, regulation, and potential structural roles in the nucleus. Recently, the Telomere-to-Telomere Consortium produced the first truly complete assembly of a human genome, paving the way for new studies of HSat1-3 with modern genomic tools. This review provides an account of the history and current understanding of HSat1-3, with a view towards future studies of their evolution and roles in health and disease.

Transcription of Satellite DNAs in Mammals

Centromeric and pericentric regions have long been regarded as transcriptionally inert portions of chromosomes. A number of studies in the past 10 years disproved this dogma and provided convincing evidence that centromeric and pericentric sequences are transcriptionally active in several biological contexts.In this chapter, we provide a comprehensive picture of the various contexts (cell growth and differentiation, stress, effect of chromatin organization) in which these sequences are expressed in mouse and human cells and discuss the possible functional implications of centromeric and pericentric sequences activation and/or of the resulting noncoding RNAs. Moreover, we provide an overview of the molecular mechanisms underlying the activation of centromeric and pericentromeric sequences as well as the structural features of encoded RNAs.

DNA methylation of the extraembryonic tissues: an in situ study on human metaphase chromosomes

DNA methylation level and pattern of human metaphase chromosomes from extraembryonic tissues (chorionic villi and placental fibroblasts) were analysed in situ. The DNA methylation global level of these tissues was studied by comparing them with the one observed in fetal fibroblasts and adult lymphocytes. In order to assess the tissue specificity and significance of the observed differences, chromosomal preparations were then treated in parallel. They were first stained with distamycin A/DAPI and pictured, then treated with immunofluorescent staining using monoclonal antibodies raised against 5-methylcytosine. Compared with metaphases from lymphocytes or placental and fetal fibroblasts, distamycin-A/DAPI stained metaphases and constitutive heterochromatic regions with very similar intensities. In contrast, in chorionic villi, the immunofluorescent intensities revealing the presence of 5-methylcytosine was much duller than in the other tissues. In addition, in both chorionic villi and placental fibroblasts, large differences were observed between various chromosome structures within individual metaphases. In particular, the secondary constriction of chromosome 9, the distal segment of chromosome Y and the short arms of acrocentric chromosomes exhibited a much lower staining than the one observed for the secondary constrictions of chromosome 1 and 16 of the same metaphases. Because all these structures are known to be deeply methylated in other somatic tissues, this suggests that in extraembryonic tissues DNA methylation level remained hypomethylated and the pattern is under precise control.

Highly polymorphic repetitive sequences in Rhynchosciara americana genome

Rhynchosciara americana genomic DNA when digested with EcoR1 or BamH1 presents visible fragments suggestive of repetitive sequences after fractionation on EtBr stained agarose gels. The cloning and molecular analysis of some of these fragments showed a highly polymorphic family of repetitive sequences. These were mapped by in situ hybridization to telomeres and some heterochromatic regions on polytene chromosomes.

Chromosome localization and orientation of the simple sequence repeat of human satellite I DNA

The predominant chromosomal locations of human satellite I DNA were detected using fluorescent in situ hybridization (FISH). Synthetic deoxyoligonucleotides designed from consensus sequences of the simple sequence repeats of satellite 1 were used as probes. The most abundant satellite I repeat, the -A-B-A-B-A- form, is located at the pericentromeric regions of chromosomes 3, 4, 13, 14, 15, 21, and 22. The less abundant -B-B-B-form was not detected on chromosome 4, but was present at all the other locations. A variation of FISH that allows strand-specific hybridization of single-stranded probes (CO-FISH) determined that the human satellite I sequences are predominantly arranged in head-to-tail fashion along the DNA strand.

Chromosomal localization of human satellites 2 and 3 by a FISH method using oligonucleotides as probes

Classical satellites I, II and III are composed of a mixture of repeated sequences. However, each of them contains a simple family of repeated sequences as a major component. Satellites 2 and 3 are simple families of repeated sequences that form the bulk of human classical satellites II and III, respectively, and are composed of closely related sequences based on tandem repeats of the pentamer ATTCC. For this reason, extensive cross-hybridizations are probably responsible for the similar in situ hybridization patterns obtained for satellites II and III. We have used a fluorescent in situ hybridization method with highly specific oligonucleotides for satellites 2 and 3, respectively, as probes. Our results show that satellite 2 is mainly located on chromosomes 1, 2, 10 and 16, whereas the major domain of satellite 3 is on chromosome 9. Furthermore, minor sites of satellites 2 and 3 are shown. Two-colour in situ hybridizations have enabled us to define the spatial relationships existing between the major domains of both satellites and centromeric alpha satellite sequences. These experiments indicate that the heterochromatin regions of chromosomes 1, 9 and 16 have different molecular organizations.

Identification of the origin of centromeres in whole-arm translocations using fluorescent in situ hybridization with alpha-satellite DNA probes

We detected 2 patients with whole-arm translocations resulting in a derivative chromosome consisting of 18q and 21q. Because the breakpoints were near the centromere, classical cytogenetic techniques could not determine the centromeric origin of the derivative chromosomes. Using nonradioactive in situ hybridization with a chromosome 18 alpha-satellite DNA probe (D18Z1), the centromeres in the abnormal chromosomes were determined to be from chromosome 18. The abnormality in one patient resulted in monosomy 18p with a karyotype 45,XX, -18, -21, + der(18)t(18;21) (p11;q11)mat complement. The second patient with a 46,XX, -21, + der(18)t(18;21)(p11;q11) de novo karyotype had complete trisomy of 18q. In both cases the appropriate phenotype was observed.

Patterns of digestion of human chromosomes by restriction endonucleases demonstrated by in situ nick translation

A restriction enzyme-nick translation procedure has been developed for localizing sites of restriction endonuclease action on chromosomes. This method involves digestion of fixed chromosome preparations with a restriction enzyme, nick translation with DNA polymerase I in the presence of biotinylated-dUTP, detection of the incorporated biotin label with streptavidinalkaline phosphatase, and finally staining for alkaline phosphatase. Results obtained obtained on human chromosomes using a wide variety of restriction enzymes are described, and compared with results of Giemsa and Feulgen staining after restriction enzyme digestion. Results of nick translation are not in general the opposite of those obtained with Giemsa staining, as might have been expected. Although the nick translation procedure is believed to give a more accurate picture of the distribution of restriction enzyme recognition sites on chromosomes than Giemsa staining, it is clear that the results of the nick translation experiments are affected by accessibility to the enzymes of the chromosomal DNA, as well as by the extractability of the DNA.

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.

Detection of heavy methylation in human repetitive DNA subsets by a monoclonal antibody against 5-methylcytosine

A monoclonal antibody (IgM) against 5-methylcytosine (mC) was isolated and characterized. It showed a high specificity for mC with a cross-reactivity of less than 1% with cytosine and 0.1% with thymidine. An improved immunohybridization method, originally developed with polyclonal antibodies (Sano et al. (1980) Proc. Natl. Acad. Sci. USA 77, 3581), was applied to detect mC in immobilized DNA using the new monoclonal preparation. Human genomic DNA was cleaved with the restriction enzyme EcoRI and successively fractionated by malachite-green affinity chromatography and agarose gel electrophoresis. The fractionated DNA was transferred to nitrocellulose paper and treated with the anti-mC monoclonal antibody. Heavy methylation was observed in EcoRI-ladders of repetitive sequences of 1360, 1750, 2200 and 3400 bp, while 340, 660 and 2700 bp fragments were less methylated. The results show that methylation occurs in limited subsets of satellite II and III repetitive DNAs that contain high amounts of methylatable CpG dinucleotides, or CpG clusters.

Localisation of satellite DNA sequences on human metaphase chromosomes using bromodeoxyuridine-labelled probes

Human highly repeated satellite sequences, cloned into M13, were used as templates to prepare single-stranded DNA probes containing bromodeoxyuridine (BrdUrd) in place of thymine. The probes were hybridised to human metaphase chromosomes and visualised using an indirect immunological detection procedure. The sensitivity and accuracy of the technique were tested using a BrdUrd-labelled probe of known copy number and location: a segment from the 2.5 kb Y chromosome repeat. The procedure proved to be reliable and fast, with a sensitivity similar to that of other in situ hybridisation techniques. The technique was then used to determine the chromosomal locations of a 100 bp repeat from human satellite 3. The satellite 3 probe hybridised to a large number of chromosomes and, surprisingly, the intensity of label at all locations remained unchanged when the slides were washed at a higher stringency. The resolution of the technique was very high and allowed accurate localisation of the satellite sequence. Hybridisation was observed in two regions of the subcentromeric heterochromatin of chromosome 9, in two locations at the centromere and short arm of all the acrocentric autosomes, and at the centromere and long arm of the Y chromosome. In addition the probe hybridised to centromeric heterochromatin in chromosomes 1, 16, 17 and 20. We believe that single-stranded BrdUrd-labelled probes should be very useful for detecting RNA transcripts in cells, and discuss ways by which the procedure could be modified to locate single copy DNA on chromosomes.

Nature of recombination involved in excision and rearrangement of human repetitive DNA

An alphoid-like human repetitive DNA of the Sau3A family is present extrachromosomally and in the chromosomes. In the chromosomes, the DNA is located on chromosome 11 but related sequences are present in chromosome 17. We characterized the nature of the recombination involved in the excision of the extrachromosomal DNA from chromosome 11. The results show that the recombination occurs both between the homologous subunits and between the heterologous subunits with only a 70 to 80% sequence homology among them, suggesting that a DNA structure other than a sequence homology mediates the recombination process. The same type of recombination is responsible for the rearrangement of the related sequences in chromosome 17.

Human chromosome-specific repetitive DNA sequences: novel markers for genetic analysis

Two recombinant DNA clones that are localized to single human chromosomes were isolated from a human repetitive DNA library. Clone pHuR 98, a variant satellite 3 sequence, specifically hybridizes to chromosome position 9qh. Clone pHuR 195, a variant satellite 2 sequence, specifically hybridizes to chromosome position 16qh. These locations were determined by fluorescent in situ hybridization to metaphase chromosomes, and confirmed by DNA hybridizations to human chromosomes sorted by flow cytometry. Pulsed field gel electrophoresis analysis indicated that both sequences exist in the genome as large DNA blocks. In situ hybridization to intact interphase nuclei showed a well-defined, localized organization for both DNA sequences. The ability to tag specific human autosomal chromosomes, both at metaphase and in interphase nuclei, allows novel molecular cytogenetic analyses in numerous basic research and clinical studies.

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

The Sau3A family is a human, clustered, highly repetitive, GC-rich DNA family. In situ hybridization studies with a plasmid carrying a Sau3A monomer as a probe have shown that Sau3A sequences are preferentially concentrated in the heterochromatic regions of human acrocentric chromosomes (D and G groups, both in pericentromeric regions and in cytological satellites) and in pericentromeric heterochromatin of chromosome 1. The same chromosomal locations were observed by using as probes two recombinant phages which carry Sau3A-positive genomic sectors. The two sectors differ for the relative proportions of monomer and multiples of Sau3A repeats, which show different extents of homology to the cloned monomer, and for the presence, in one of the two, of a small amount of an unrelated repeat (alphoid DNA). The similarity of the results obtained with the three probes suggests that heterogeneous Sau3A repeats share the same chromosomal localizations and that the two analyzed genomic sectors may not contain significant amounts of repetitive DNAs other than the Sau3A family. A comparison between the chromosomal locations of Sau3A and EcoRI families of repeats has confirmed that each family is characterized by specific chromosomal locations and that single heterochromatic regions may contain both.

Isolation and characterization of an alpha-satellite repeated sequence from human chromosome 22

We constructed a library in lambda L47.1 with DNA isolated from flow-sorted human chromosome 22. Over 50% of the recombinants contained the same highly repetitive sequence. When this sequence was used to probe Southern blots of EcoRI-digested genomic DNA, a ladder of bands with increments of about 170 bp was observed. This sequence comigrates with satellite III in Ag+/Cs2SO4 gradients and may account for at least part of the 170 bp Hae III ladder seen in isolated satellite III DNA. Partial sequence analysis revealed homology to the 171 bp monomeric repeat unit of alpha-R1-DNA and the X specific alpha-satellite consensus sequence. After low stringency in situ hybridization, silver grains were found over the centromeres of a number of chromosomes. Under high stringency conditions, however, the labeling was concentrated over the centromeric region of chromosome 22. This localization was confirmed using DNA from a panel of human/hamster cell lines which showed that the homologous 2.1 and 2.8 kb EcoR1 restriction fragments were chromosome 22 specific. These clones therefore contain chromosome 22 derived alpha-satellite sequences analogous to other chromosome-specific satellite sequences described previously.

Integration of hepatitis B virus DNA in chromosome-specific satellite sequences

We previously reported the cloning and detailed analysis of the integrated hepatitis B virus sequences in a human hepatoma cell line. We report here the integration of at least one of hepatitis B virus at human satellite DNA sequences. The majority of the cellular sequences identified by this satellite DNA were organized as a multimeric composition of a 0.6-kilobase EcoRI fragment. This clone hybridized in situ almost exclusively to the centromeric heterochromatin of chromosomes 1 and 16 and to a lower extent to chromosome 2 and to the heterochromatic region of the Y chromosome. The immediate flanking host sequence appeared as a hierarchy of repeating units which were almost identical to a previously reported human satellite III DNA sequence.

A long interspersed (LINE) DNA exhibiting polymorphic patterns in human genomes

Several human DNAs digested with Kpn I restriction endonuclease released a 0.6-kilobase (kb) segment that varied in its intensity among human samples. A recombinant DNA clone (N6.4) of these 0.6-kb Kpn I segments was isolated and used to probe the genomic content and restriction cleavage pattern of homologous sequences. The hybridization patterns revealed a previously undescribed, moderately repetitive long interspersed (LINE) sequence family, which we have termed L2Hs (second LINE family in Homo sapiens). This LINE family exhibits both quantitative and qualitative polymorphisms in the human population. The content of L2Hs sequences in human genomes varies over a 5-fold range. Relative to the value for a human placental DNA, sequences homologous to the L2Hs family occur in lower amounts in gorilla DNA (approximately 20%) and even less in DNA from chimpanzees and other primates (less than 1%). Thus, the L2Hs sequences appear to have emerged only recently as a moderately repetitive sequence family in primate evolution. The observed restriction fragment length polymorphism of the L2Hs family members may reflect patterns of sequence rearrangements, amplifications, and/or deletions in human genomes.

Chromosome-specific subfamilies within human alphoid repetitive DNA

Nucleotide sequence data of about 20 X 10(3) base-pairs of the human tandemly repeated alphoid DNA are presented. The DNA sequences were determined from 45 clones containing EcoRI fragments of alphoid DNA isolated from total genomic DNA. Thirty of the clones contained a complete 340 base-pair dimer unit of the repeat. The remaining clones contained alphoid DNA with fragment lengths of 311, 296, 232, 170 and 108 base-pairs. The sequences obtained were compared with an average alphoid DNA sequence determined by Wu & Manuelidis (1980). The divergences ranged from 0.6 to 24.6% nucleotide changes for the first monomer and from 0 to 17.8% for the second monomer of the repeat. On the basis of identical nucleotide changes at corresponding positions, the individual repeat units could be shown to belong to one of several distinct subfamilies. The number of nucleotide changes defining a subfamily generally constitutes the majority of nucleotide changes found in a member of that subfamily. From an evaluation of the proportion of the total amount of alphoid DNA, which is represented by the clones studied, it is estimated that the number of subfamilies of this repeat may be equal to or exceed the number of chromosomes. The expected presence of only one or a few distinct subfamilies on individual chromosomes is supported by the study, also presented, of the nucleotide sequence of 17 cloned fragments of alphoid repetitive DNA from chromosome 7. These chromosome-specific repeats all contain the characteristic pattern of 36 common nucleotide changes that defines one of the subfamilies described. A unique restriction endonuclease (NlaIII) cleavage site present in this subfamily may be useful as a genetic marker of this chromosome. A family member of the interspersed Alu repetitive DNA was also isolated and sequenced. This Alu repeat has been inserted into the human alphoid repetitive DNA, in the same way as the insertion of an Alu repeat into the African green monkey alphoid DNA.

Sequence relationships of three human satellite DNAs

The simple sequence components of three human classical satellite DNAs have been defined, and some segments of each satellite have been sequenced. Each of the classical satellites I, II and III was found to contain, as a major component, a single family of simple repeated sequences. The three simple-sequence families have been called satellites 1, 2 and 3, to indicate the enrichment of each in one of the classical satellites I, II and III, and to differentiate them from these classical satellites, which also contain other repeated components. Satellite 3, the simple sequence component of classical satellite III, when digested with the restriction endonuclease HinfI, forms a ladder based on a repeat of five base-pairs, 5' A-T-T-C-C. The HinfI ladder was shown to be composed of repeated elements with the general sequence 5' (A-T-T-C-C)n-A-TC-T-C-G-G-G-T-T-G. Satellite 2, the simple sequence component of classical satellite II, is digested by HinfI into a large number of very small fragments, of length 10 to 80 base-pairs. These were found to contain the simple repeat 5' A-T-T-C-C, in a highly diverged form. Analysis of satellite 2 sequences suggested that the five base-pair repeat was originally amplified as a higher-order repeat like that of satellite 3. However, the main tandemly repeated segments of satellite 2 in the human genome are much longer, and the simple sequence elements on which they are based are quite degenerate. Satellite 1, the simple sequence component of classical satellite I, is digested by the restriction endonuclease RsaI into a ladder of fragments less than 150 base-pairs in length. These ladder fragments were found to be formed by the loss of RsaI sites from two related A + T-rich sequences, A (17 base-pairs) and B (25 base-pairs), arranged in alternating arrays, -A-B-A-B-A-. Analysis of a large number of cloned fragments from the RsaI ladder of satellite 1 showed that the tandem arrays, -A-B-A-B-A, have a more complex arrangement, with apparent amplification of segments containing particular sequence variants of the repeat units, A and B. No sequence relationship was evident between the repeat elements of satellite 1 and those of satellites 2 and 3.

A cloned sequence, p82H, of the alphoid repeated DNA family found at the centromeres of all human chromosomes

Clone p82H is a human DNA sequence which hybridises in situ exclusively to the centromeric regions of all human chromosomes. It is composed of approximately 14 tandemly repeated variants of a basic 172 bp sequence, and is related to the alphoid family. The organisation of the family of cross-hybridising sequences, detected by the clone p82H, is described both in the human genome and on certain chromosomes, and its relationship to known sequence families is discussed.

Isolation and characterization of an alphoid centromeric repeat family from the human Y chromosome

A collection of human Y-derived cosmid clones was screened with a plasmid insert containing a member of the human X chromosome alphoid repeat family, DXZ1. Two positive cosmids were isolated and the repeats they contained were investigated by Southern blotting, in situ hybridization and sequence analysis. On hybridization to human genomic DNAs, the expected cross-hybridization characteristic of all alphoid sequences was seen and, in addition, a 5500 base EcoRI fragment was found to be characteristic of a Y-specific alphoid repeat. Dosage experiments demonstrated that there are about 100 copies of this 5500 base EcoRI alphoid fragment on the Y chromosome. Studies utilizing DNA from human-mouse hybrids containing only portions of the Y chromosome and in situ hybridizations to chromosome spreads demonstrated the Y centromeric localization of the 5500 base repeat. Cross-hybridization to autosomes 13, 14 and 15 was also seen; however, these chromosomes lacked detectable copies of the 5500 base EcoRI repeat sequence arrangement. Sequence analysis of portions of the Y repeat and portions of the DXZ1 repeat demonstrated about 70% homology to each other and of each to the human consensus alphoid sequence. The 5500 base EcoRI fragment was not seen in gorilla, orangutan or chimpanzee male DNA.

The mechanism and pattern of banding induced by restriction endonucleases in human chromosomes

The mechanism of chromosome banding induced by restriction endonucleases was analyzed by measuring the amount of radioactivity extracted from [14C]thymidine-labeled chromosomes digested first with restriction enzymes and subsequently with proteinase K and DNase I. Restriction enzymes with a high frequency of recognition sites in the DNA produced a large number short DNA fragments, which were extracted from chromosomes during incubation with the enzyme. This loss of DNA resulted in decreased chromosomal staining, which did not occur in regions resistant to restriction enzyme digestion and thus led to banding. Subsequent digestion of chromosomes with proteinase K produced a further loss of DNA, which probably corresponded to long fragments retained in the chromosome by the proteins of fixed chromatin. Restriction enzymes induce chromatin digestion and banding in G1 and metaphase chromosomes, and they induce digestion and the appearance of chromocenters in interphase nuclei. This suggests that the spatial organization and folding of the chromatin fibril plays little or no role in the mechanism of chromosome banding. It was confirmed that the pattern of chromosome banding induced by AluI, MboI, HaeIII, DdeI, RsaI, and HinfI is characteristic for each endonuclease. Moreover, several restriction banding polymorphisms that were not found by conventional C-banding were detected, indicating that there may be a range of variability in the frequency and distribution of restriction sites in homologous chromosome regions.

Organization of a repetitive human 1.8 kb KpnI sequence localized in the heterochromatin of chromosome 15

We have isolated a repetitive 1.8 kb KpnI DNA sequence which is amplified in the homogeneously staining regions of a human melanoma cell line. Under low stringency conditions this sequence (D15Z1) hybridized in situ to the centromeric heterochromatin of chromosomes 1, 9, 15p, 16, and distal Yq as well as to the short arms of the other acrocentric chromosomes. Under conditions of high stringency, labelling was predominantly on the short arm of chromosome 15. D15Z1 was shown to be present at approximately 3,000 copies per haploid genome and organized in long tandem arrays showing restriction site heterogeneity. Sequences homologous to D15Z1 were highly enriched in the less dense shoulder region of a Ag+-Cs2SO4 gradient. Analysis of D15Z1 indicated that this sequence is composed of tandemly arranged imperfect repeats of the consensus 5' AATGG 3' similar to previously identified satellite III sequences. Digestion of D15Z1 with HinfI resulted in a series of restriction fragments making up a subset of the HinfI ladder components of satellites III and IV. These data suggest that D15Z1 represents a chromosome 15 specific domain of human satellites III or IV and that it makes up the major fraction of the heterochromatin of this chromosome. Possible relationships between this sequence and the cytochemical staining properties of human chromosomes with distamycin A/DAPI, D280/170, and antiserum to 5-methylcytosine are discussed.

Organization and chromosomal specificity of autosomal homologs of human Y chromosome repeated DNA

The human Y chromosome contains a group of repeated DNA elements, identified as 3.4-kilobase pair (kb) fragments in Hae III digests of male genomic DNA, which contain both Y-specific and non-Y-specific sequences. We have used these 3.4-kb Hae III Y fragments to explore the organizational properties and chromosomal distribution of the autosomal homologs of the non-Y-specific (NYS) 3.4-kb Hae III Y elements. Three distinct organizations, termed domains, have been identified and shown to have major concentrations on separate chromosomes. We have established that domain K is located on chromosome 15 and domain D on chromosome 16 and suggested that domain R is on chromosome 1. Our findings suggest that each domain is composed of a tandemly arrayed cluster of a regularly repeating unit containing two sets of repeated sequences: one that is homologous to the NYS 3.4-kb Hae III Y sequences and one that does not cross-react with the 3.4-kb Hae III Y repeats. Thus, these autosomal repeated DNA domains, like their Y chromosome counterparts, consist of a complex mixture of repeated DNA elements interspersed among each other in ways that lead to defined periodicities. Although each of the three identified autosomal domains cross-reacts with 3.4-kb Hae III Y fragments purified from genomic DNA, the length periodicities and sequence content of the autosomal domains are chromosome specific. The organizational properties and chromosomal distribution of these NYS 3.4-kb Hae III homologs seem inconsistent with stochastic mechanisms of sequence diffusion between chromosomes.

Distribution of repeated DNA families in the human genome

By means of restriction enzymes analysis and molecular hybridization, the distribution of repeated DNA families has been studied in the different DNA components into which the human genome can be fractionated by density gradient techniques. Three classes of DNA molecules have been analyzed: i) an homogeneous DNA component (satellite-like sequences; Q = 1.696 g/cm3, 3% of total DNA, AT repeated), ii) AT rich (Q = 1.698 g/cm3, 30% of total DNA, AT main-band) and GC rich (Q = 1.708 g/cm3, 6% of total DNA, GC main-band) DNA components. By this approach we have observed that Sau3A digestion of GC main-band gives rise to two bands of 75bp and 150bp, absent or under-represented in both AT rich DNA components. A preliminary characterization of these DNA fragments suggests that they contain one or more families of repeated sequences which fail to hybridize to EcoRI, HindIII and AluI families of repeats. In addition, we have observed that EcoRI sequences (alpha-RI DNA) are under-represented in GC main-band and show the same clustered organization in both AT rich DNA components.

Replication pattern of human repeated DNA sequences

Either aphidicolin- or thymidine-synchronized human HL-60 cells were used to study the replication pattern of a family of human repetitive DNA sequences, the Eco RI 340 bp family (alpha RI-DNA), and of the ladders of fragments generated in total human DNA after digestion with XbaI and HaeIII (alpha satellite sequences). DNAs replicated in early, middle-early, middle-late and late S periods were labelled with BUdR or with [3H]thymidine. The efficiency of the cell synchronization procedure was confirmed by the transition from a high-GC to a high-AT average base composition of the DNA synthesized going from early to late S periods. By hybridizing EcoRI 340 bp repetitive fragments to BUdR-DNAs it was found that this family of sequences is replicated throughout the entire S period. Comparing fluorograph densitometric scans of [3H]DNAs to the scans of ethidium bromide patterns of total HL-60 DNA digested with XbaI and HaeIII, it was observed that DNA synthesized in different S periods is characterized by approximately the same ladder of fragments, while the intensity of each band may vary through the S phase; in particular, the XbaI 2.4 kb fragment becomes undetectable in late S.

Presence of nucleosomes within irregularly cleaved fragments of newly replicated chromatin

In previous reports (Annunziato et al., J. Biol. Chem., 256:11880-11886 [1981]; Annunziato and Seale, Biochemistry 21:5431-5438 [1982]) we have described two classes of newly replicated chromatin which differ in structure, solubility properties, and requirements for maturation. One class is nucleosomal, soluble at low to intermediate ionic strengths, and acquires mature nucleosomal composition and normal repeat length in the absence of concurrent protein synthesis. In contrast, the other class is cleaved irregularly by MNase (appearing as a smear in DNA gels), is insoluble at moderate ionic strengths, requires protein synthesis to gain normal subunit structure, and comprises approximately 60% of total new chromatin DNA after mild nuclease digestion. It is now demonstrated that this heterogeneous component (produced by the action of either MNase or Hae III on chromatin replicated in cycloheximide) yields nucleosomes when redigested with MNase. The presence of nucleosomes within heterogeneous chromatin fragments suggests that nucleosomal and non-nucleosomal regions may be juxtaposed during chromatin replication. These findings are discussed with respect to current models of nucleosome segregation.

Characterization of a cloned DNA sequence that is present at centromeres of all human autosomes and the X chromosome and shows polymorphic variation

We have identified a human DNA recombinant (p308) with a 3.0-kilobase (kb) BamHI insert that hybridizes in situ exclusively to the centromeric region of all human autosomes and the X chromosome. This highly repetitive sequence is significantly enriched on several chromosomes, most prominently on chromosome 6. In all individuals, the majority of genomic repeats are organized as tandem 3.0-kb BamHI repeats, each containing one Taq I site; the others are organized into BamHI and Taq I repeats of variable size that have some chromosome specificity. Using mouse-human hybrids, we have defined the specific organization of this sequence on chromosomes 6, 3, and X. In some individuals, there are differences in the number and nature of the tandem repeats. These polymorphisms segregate in families as if chromosome specific. Although variable from one chromosome to another, 308 contains sequences homologous to DNA present in centric heterochromatin of essentially all human chromosomes and is evolutionarily conserved. Therefore, a significant component of pericentric DNA is similar for all human chromosomes.

Human satellite I sequences include a male specific 2.47 kb tandemly repeated unit containing one Alu family member per repeat

A portion of human satellite I DNA is digested by HinfI into three fragments of 775, 875 and 820bp in length which form a tandemly repeated unit 2.47kb in length, specific to male DNA. One Alu family member per repeat is found within the relatively G+C rich 775bp fragment. The 875 and 820bp fragments are highly A+T rich and consist of long stretches of poly dAdT and related sequences.

U1 small nuclear RNA genes are located on human chromosome 1 and are expressed in mouse-human hybrid cells

The majority, and perhaps all, of the genes for human U1 small nuclear RNA (U1 RNA) were shown to be located on the short arm of human chromosome 1. These genes were mapped by Southern blot analysis of DNA from rodent-human somatic cell hybrids, using the 5' region of a human U1 RNA gene as a human-specific probe. This probe hybridized to DNA fragments present only in digests of total human DNA or to the DNAs of cell lines which contained human chromosome 1. The major families of human U1 RNA genes were identified, but some human genes may have gone undetected. Also, the presence of a few U1 RNA genes on human chromosome 19 could not be ruled out. In spite of the lack of extensive 5'-flanking-region homology between the human and mouse U1 RNA genes, the genes of both species were efficiently transcribed in the hybrid cells, and the U1 RNAs of both species were incorporated into specific ribonucleoprotein particles.

U1 small nuclear RNA genes are located on human chromosome 1 and are expressed in mouse-human hybrid cells

The majority, and perhaps all, of the genes for human U1 small nuclear RNA (U1 RNA) were shown to be located on the short arm of human chromosome 1. These genes were mapped by Southern blot analysis of DNA from rodent-human somatic cell hybrids, using the 5' region of a human U1 RNA gene as a human-specific probe. This probe hybridized to DNA fragments present only in digests of total human DNA or to the DNAs of cell lines which contained human chromosome 1. The major families of human U1 RNA genes were identified, but some human genes may have gone undetected. Also, the presence of a few U1 RNA genes on human chromosome 19 could not be ruled out. In spite of the lack of extensive 5'-flanking-region homology between the human and mouse U1 RNA genes, the genes of both species were efficiently transcribed in the hybrid cells, and the U1 RNAs of both species were incorporated into specific ribonucleoprotein particles.

Two-dimensional gel electrophoretic analysis of the HindIII 1.8-kb repetitive-sequence family in the human genome

The structure and organization of a human repetitive DNA family containing the HindIII 1.8-kb repetitive sequence were studied, using two-dimensional (2D) gel electrophoresis. The HindIII 1.8-kb sequence proved to be part of a repetitive sequence about 5 kb long and interspersed on the genome. The long repetitive sequence family contained several subgroups, as based on polymorphism of the restriction site. Recombinant phages containing the long repetitive sequence were isolated from the human genomic DNA library. Heteroduplex and restriction analysis showed that the structure of the repetitive sequence carried by the phages was close to that expected from 2D gel electrophoretic analysis. The 2D gel electrophoretic analysis was shown to be a reliable and useful approach for surveying and mass analysis of repetitive sequence families.

Comparative structure and evolution of goat and sheep satellite I DNAs

The satellite I DNAs of domestic goat (Capra hircus) and domestic sheep (Ovis aries) have been studied using molecular hybridisation and restriction enzyme analysis. Both satellite DNAs are composed of repeat units of 820 base pairs in length, but their restriction maps, although similar, differ in certain respects. Thus the majority of sheep satellite I repeat units have two EcoRI sites and one AluI site, whereas the majority of goat satellite I repeat units have one EcoRI site and two AluI sites. The sheep satellite I repeat units with the two EcoRI sites are much more homogeneous than the repeats forming the remainder of the satellite, as judged by the difference in the melting temperatures of native and reassociated molecules. DNAs from species of wild sheep and goats were screened for the presence of these repeat units, and they appear to have been amplified during the radiation of the Ovis genus. Goat satellite I is composed of a single sequence type which has changed through base substitution until the sequence now shows considerable heterogeneity. It is proposed that the major sequence types of these two satellite DNAs were amplified by different saltatory replication events at different times in the evolution of the group.

Characterization of a cloned repetitive DNA sequence concentrated on the human X chromosome

A tandemly repeated DNA sequence organized predominantly, if not entirely, in a specific manner on the human X chromosome has been cloned in pBR322 and characterized. The sequence was detected as a 2-kilobase band in ethidium bromide-stained agarose gels of BamHI-digested total human nuclear DNA. Although in situ hybridization of the cloned sequence to human metaphase chromosomes showed a single major site of hybridization at the centromere region of the X chromosome and minor sites of hybridization at several autosomal centromeres, Southern blot analysis of restricted total human DNA indicated that the cloned probe is related to other repeated DNAs, particularly the human alphoid DNAs. Restriction enzyme analysis of the cloned fragment revealed an internal repeat structure based upon multiples of 170 base pairs, confirming this relatedness. All available data, however, suggest that the 2-kilobase spacing of BamHI sites within the repeat may be specific to the X chromosome.

Nucleotide sequences of highly repeated DNAs; compilation and comments

The nucleotide sequence data from highly repeated DNAs of inverte-brates and mammals are summarized and briefly discussed. Very similar conclusions can be drawn from the two data bases. Sequence complexities can vary from 2 bp to at least 359 bp in invertebrates and from 3 bp to at least 2350 bp in mammals. The larger sequences may or may not exhibit a substructure. Significant sequence variation occurs for any given repeated array within a species, but the sources of this heterogeneity have not been systematically partitioned. The types of alterations in a basic repeating unit can involve base changes as well as deletions or additions which can vary from 1 bp to at least 98 bp in length. These changes indicate that sequenceper seis unlikely to be under significant biological constraints and may sensibly be examined by analogy to Kimura's neutral theory for allelic variation. It is not possible with the present evidence to discriminate between the roles ofneutralandselectivemechanisms in the evolution of highly repeated DNA.

Tandemly repeated arrays are constantly subjected to cycles of amplification and deletion by mechanisms for which the available data stem largely from ribosomal genes. It is a matter of conjecture whether the solutions to the mechanistic puzzles involved in amplification or rapid redeployment of satellite sequences throughout a genome will necessarily give any insight into biological functions.

The lack of significant somatic effects when the satellite DNA content of a genome is significantly perturbed indicates that the hunt for specific functions at thecellularlevel is unlikely to prove profitable.

The presence or in some cases theamountof satellite DNA on a chromosome, however, can have significant effects in the germ line. There the data show that localized condensed chromatin, rich in satellite DNA, can have the effect of rendering adjacent euchromatic regionsrec−, or of altering levels of recombination on different chromosomes. No data stemming from natural populations however are yet available to tell us if these effects are of adaptive or evolutionary significance.

Simple repeated sequences in human satellite DNA

In an extensive analysis, using a range of restriction endonucleases, HinfI and TaqI were found to differentiate satellites I, II and III & IV. Satellite I is resistant to digestion by TaqI, but is cleaved by HinfI to yield three major fragments of approximate size 770, 850 and 950bp, associated in a single length of DNA. The 770bp fragment contains recognition sites for a number of other enzymes, whereas the 850 and 950bp fragments are "silent" by restriction enzyme analysis. Satellite II is digested by HinfI into a large number of very small (10-80bp) fragments, many of which also contain TaqI sites. A proportion of the HinfI sites in satellite II have the sequence 5'GA(GC)TC. The HinfI digestion products of satellites III and IV form a complete ladder, stretching from 15bp or less to more than 250bp, with adjacent multimers separated by an increment of 5bp. The ladder fragments do not contain TaqI sites and all HinfI sites have the sequence 5'GA(AT)TC. Three fragments from the HinfI ladder of satellite III have been sequenced, and all consist of a tandemly repeated 5bp sequence, 5'TTCCA, with a non-repeated, G+C rich sequence, 9bp in length, at the 3' end.

Patterns of exchange induced by mitomycin C in C-bands of human chromosomes. I. Relationship to C-band size in chromosomes 1, 9, and 16

Frequencies of exchange were determined in C-bands of chromosomes 1, 9 and 16 in six normal males, and related to relative C-band area. Comparing these different chromosomes, more exchanges occurred on average in 9 than in 1 although their mean C-band sizes were similar. Chromosome 16 exchanges were fewer, both overall and relative to C-band area. Comparing the same chromosome between individuals, there was a positive correlation between relative frequency and band size in both 1-1 and 9-9 exchanges. No clear trend was observed for other exchange events. If homology is required for interchange, it cannot be dependent solely on overall C-band size. Perhaps certain DNA sequences, sensitive to mitomycin C damage, are located in part of each C-band, with less per unit area in chromosome 1 than in 9 and still less in chromosome 16. X- and U-type exchanges between chromosome 9s occurred in near equal frequencies in all individuals. If synapsis of specific, affected sequences is a pre-requisite for interchange, this observation suggests that the affected sequence in chromosome 9 is arranged in both orientations relative to the centromere.

Buoyant density and hybridization analysis of human DNA sequences, including three satellite DNAs

Total human DNA was fractionated from the three types of Cs2SO4 gradient used to prepare satellites I, II and III. Three satellite DNAs were found: satellite I with a mean buoyant density of 1.6888 g/ml comprising about 1.3% of the total, satellite II with a mean buoyant of 1.696 g/ml, comprising about 1% of the total an satellite III with a mean buoyant density of 1.699 g/ml comprising about 2.2% of the total. The buoyant densities of these satellites after purification were 1.686, 1.694 and 1.697 m/gl, respectively. A preparation with the attributes of satellite IV was isolated from the shoulder region of a satellite III preparative gradient. In situ hybridization using complementary RNA showed that the three satellites were located predominantly on chromosomes 9, Y, 15 and 1. Satellite II also showed marked hybridization to chromosome 16. Satellites I and II and III cross-hybridized to each other but satellites I and II did not. On the basis of our hybridization data, we suggest that some of the same sequences which comprise satellite III also comprise satellite I an II.

Interspersed repeated sequences in the African green monkey genome that are homologous to the human Alu family

The dominant family of interspersed repetitive DNA sequences in the human genome has been termed the Alu family. We have found that more than 75% of the lambda phage in a recombinant library representing an African green monkey genome hybridize with a human Alu sequence under stringent conditions. A group of clones selected from the monkey library with probes other than the Alu sequence were analyzed for the presence and distribution of Alu family sequences. The analyses confirm the abundance of Alu sequences and demonstrate that more than one repeat unit is present in some phages. In the clones studied, the Alu units are separated by an average of 8 kilobase pairs of unrelated sequences. The nucleotide sequence of one monkey Alu sequence is reported and shown to resemble the human Alu sequences closely. Hence, the sequence, dispersion pattern, and copy number of the Alu family members are very similar in the African green monkey and human genomes. Among the clones investigated were two that contain segments of the satellite DNA term alpha-component joined to non alpha-component DNA. The experiments indicate that in the monkey genome Alu sequences can occur close to regions of alpha-component DNA.