Chromosome-specific α-satellite DNA from the centromere of chimpanzee chromosome 4

The centromeric regions of human and primate chromosomes are characterized by diverged subsets of tandemly repeated α-satellite DNA. Comparison of the α-satellites on known homologous chromosomes in human and chimpanzee provides insight into the very rapid evolution of satellite DNA sequences and the mechanisms that shape complex genomes. By using oligonucleotide primers specific for a conserved region of human α-satellite DNA, we have amplified a chromosome-specific α-satellite subset from the chimpanzee genome by the polymerase chain reaction. Fluorescence in situ hybridization showed that clones pαPTR4N and pαPTR4H are homologous to sequences at the centromere of the chimpanzee chromosome 4. This α-satellite subset is organized as a series of pentameric (higher-order) repeats, operationally defined by digestion of genomic DNA with HaeIII, MboI, RsaI, SstI, and XbaI. The lengths of four independent centromeric arrays measured by pulsed-field gel electrophoresis varied between 800 and 3,500 kb (mean = 1,850 kb, SD = 1,000 kb). Nucleotide sequence analysis demonstrated that chimpanzee chromosome 4 α-satellite is most closely related to the suprachromosomal subfamily II, which is evolutionarily different from the subfamily I to which the α-satellite on the homologous human chromosome 5 belongs. This implies that the human-chimpanzee sequence divergence has not arisen from a common ancestral α-satellite repeat(s) but instead represents concerted evolution of distinct repeats on homologous chromosomes. Received: 21 February 1997; in revised form: 26 February 1997 / Accepted: 27 February 1997     

Orangutan α-satellite monomers are closely related to the human consensus sequence

Alpha-satellite is a family of tandemly repeated DNA found at the centromeric regions of all human and primate chromosomes. Human α-satellite subsets are largely chromosome-specific and have been further grouped into four suprachromosomal families (SFs), each characterized by a unique set of monomeric types. Although chimpanzee and gorilla α-satellites share sufficient sequence similarity to fit the established SFs, the assumption that the derived human α-satellite consensus and monomeric types represent the sequence of ancestral repeats remains unestablished. By using oligonucleotide primers specific for a conserved region of human α-satellite DNA, we have PCR amplified, cloned, and characterized α-satellite sequences from the orangutan genome. Nucleotide sequence analysis demonstrated that orangutan α-satellite is formed by a single monomeric type that is significantly closer in percentage of sequence identity (mean = 92%, range = 89–96%) to the overall consensus of human α-satellite than to the monomeric types corresponding to the four SFs. Use of cloned sequences as hybridization probes to orangutan genomic DNA digested with a panel of restriction enzymes showed that most orangutan α-satellite subsets are characterized by a monomeric construction. The subset homologous to clone PPY2-5 is organized in distinct higher-order repeat structures consisting of 18 adjacent monomers. By FISH two clones, PPY3-4 and PPY3-5, proved to be specific for the α-satellite on the orangutan homologs of human Chromosomes (Chrs) 10 and 8, respectively. Our data indicate that there was an ancestral monomeric type displaying high sequence similarity to the overall human consensus from which the different great ape and human subsets and SFs may have originated. Received: 24 November 1997 / Accepted: 29 January 1998     

Scaffold attachment regions in centromere-associated DNA

Due to indications that kinetochore proteins are an integral part of the protein scaffold component of the chromosome (Earnshaw et al. 1984), we chose to map the distribution of scaffold attachment regions (SARs) at centromeres. Using the SAR mapping assay of Mirkovitch et al., Southern blots were prepared and probed with ³²P-labeled fragments from the human 1.9 kb centromeric α-satellite repeat unit of chromosome 1 or the 1.7 kb centromeric α-satellite repeat unit of chromosome 16. Our results demonstrated the presence of one SAR site per 1.9 kb repeat unit in chromosome 1, and every 1.7 kb repeat unit in chromosome 16, separated by regions of small DNA loops over the length of the α-satellite regions. We also identified several in vitro vertebrate topoisomerase II and cenP-B consensus sequences throughout the chromosome 1 α-satellite region using computer and base ratio analysis, to address the question as to why some α-satellite regions are SAR related and others are not. To provide in situ indications of SAR localization in the human genome, SAR DNA and non-SAR DNA were prepared following lithium 3,5-di-iodosalicylate extraction. Sequences protected from DNAse I digestion by SAR proteins, as compared with unprotected DNA that was digested by the enzyme, was labeled with biotin-UTP, hybridized to chromosomal DNA in situ, and then detected with fluorescein-avidin-DCS. Both SAR and non-SAR DNA selectively labeled virtually all centromeric regions of the human metaphase karyotype. Chromosomal arms were less strongly bound by SAR DNA, with a pattern that followed the chromosomal axis. In the more condensed chromosomes an R-banding pattern was evident. In general, labeling patterns produced by both SAR and non-SAR fractions were similar, as expected from the indications that SAR DNAs are heterogenous in sequence and do not form a specific class of sequences. We conclude that centromeric regions of several, possibly all, human metaphase chromosomes are also regions where the chromosomal axis contains loops, smaller in size than in the arms and where attachment sites are concentrated. This clustering of SARs may be responsible in part for the tight chromatin packing associated with the primary constriction of the centromeric region. Received: 10 October 1995; in revised form: 10 May 1996 / Accepted: 13 May 1996     

Single base discrimination of CENP-B repeats on mouse and human Chromosomes with PNA-FISH

The satellite repeat structure of the mammalian centromere contains the CENP-B protein binding site. Using the peptide nucleic acid-fluorescence in situ hybridization (PNA-FISH), we show by direct PNA-DNA binding that all detectable CENP-B sites in a mammalian genome might have the same sequence. Two species-specific PNA 17-mers, pMm and pMc, were identified from CENP-B binding sites of Mus musculus and M. caroli, respectively. Fluorescence in situ hybridization confirmed that pMc hybridized to M. caroli centromeres only; however, pMm cross-hybridized to M. musculus and human centromeres. By using a series of CENP-B PNA 17-mers containing 1, 2, 3, 5, and 7 base-pair mismatches to their DNA counterparts, we further demonstrate that PNA-FISH can discriminate between two CENP-B DNA sequences that differ by a single base-pair in mouse and human centromeres, suggesting the degree of conservation of CENP-B sequences throughout the genome. In comparison with DNA oligonucleotides, PNA oligomers demonstrate the higher sequence specificity, improved stability, reproducibility, and lower background. Therefore, PNA oligomers have significant advantages over DNA oligonucleotide probes in analyzing microsatellites in a genome. Received: 16 June 1998 / Accepted: 3 September 1998     

CENP-A associated complex satellite DNA in the kinetochore of the Indian muntjac

The centromere/kinetochore complex is a chromosomal assembly that mediates chromosome motility and mitotic regulation by interacting with microtubules of the mitotic spindle apparatus. Centromere protein A (CENP-A) is a histone H3 homolog that is concentrated in the chromatin of the inner kinetochore plate of human chromosomes. To identify DNA sequences associated with the inner kinetochore plate, we used anticentromere autoantibodies to immunoprecipitate CENP-A associated chromatin selectively from Indian muntjac fibroblasts. DNA was cloned from immunoprecipitated CENP-A- associated chromatin and characterized by DNA sequence and hybridization analyses. A novel centromeric satellite DNA sequence was identified and shown by fluorescence in situ hybridization analysis to be present at all centromeres of the Indian muntjac. This satellite DNA constitutes a 972 bp monomer repeat and shows partial homology with satellite II DNA of the white-tailed deer. Southern blot analysis of muntjac genomic DNA suggests that this satellite DNA is present in repetitive tandem arrays and contains complex internal arrangements. In conjunction with previous work showing the association of CENP-A with human α-satellite DNA, we conclude that the mammalian inner kinetochore plate contains a unique form of chromatin that contains CENP-A in association with complex satellite DNA. Received: 18 May 1999; in revised form: 5 July 1999 / Accepted: 20 July 1999     

Application of cloned satellite DNA sequences to molecular-cytogenetic analysis of constitutive heterochromatin heteromorphisms in man

Summary The cloned alpha-satellite DNA sequences were used to evaluate the specificity and possible variability of repetitive DNA in constitutive heterochromatin of human chromosomes. Five probes with high specificity to individual chromosomes (chromosomes 3, 11, 17, 18, and X) were in situ hybridized to metaphase chromosomes of different individuals. The stable position of alpha-satellite DNA sequences in heterochromatic regions of particular chromosomes was found. Therefore, the chromosome-specific alpha-satellite DNA sequences may be used as molecular markers for heterochromatic regions of certain human chromosomes. The homologous chromosomes of many individuals were characterized by cytologically visible heteromorphisms of hybridization intensity with chromosome-specific alpha-satellite DNA sequences. A special analysis of hybridization between homologues with morphological differences provided the evidence for a high resolution power of the in situ hybridization technique for evaluation of chromosome heteromorphisms. The approaches for detection of heteromorphisms in cases without morphological differences between homologues are discussed. The results obtained indicate that constitutive heterochromatin of human chromosomes has a variable amount of alphasatellite DNA sequences. In situ hybridization of cloned satellite DNA sequences may be used as a new general approach to analysis of chromosome heteromorphisms in man.     

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

We constructed a library in IL47.1 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 -R1-DNA and the X specific -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 -satellite sequences analogous to other chromosome-specific satellite sequences described previously.     

Fluorescence in situ hybridization reveals a break in the α-satellite DNA of chromosome 1 in a family with a balanced whole-arm translocation

We have characterized a whole-arm translocation involving chromosomes 1 and 19 by traditional cytogenetic methods and fluorescence in situ hybridization with chromosome-specific -satellite and whole-chromosome painting probes, and different satellite III DNA probes. We have identified a break in the -satellite DNA region of chromosome 1, with division of this material into two a-satellite DNA blocks. This leaves one translocation chromosome with truncated -satellite DNA from chromosome 1 and the other trranslocation chromosome with all the -satellite DNA from chromosome 19 and truncated -satellite DNA from chromosome 1. We speculate whether the recombination event observed has taken place in tetraplex structures of satellite III DNA interspersed between -satellite DNA.     

Characterization of a swine chromosome-specific centromeric higher-order repeat

The centromeric region of swine chromosomes is comprised of tandemly repeated, divergent DNA monomer units. Here we report that these divergent DNA monomer sequences are organized into higher-order repeats, analogous to the hierarchical organization of α-satellite monomers in human centromeres. In this study, a centromeric cosmid clone was shown to be comprised entirely of a 3.3-kb higher-order repeat, with independent copies of this higher-order repeat more than 99% identical to each other. This higher-order repeat is composed of ten divergent monomer units of approximately 340 bp. The ten monomers are on average 79% identical, and all ten monomers are arranged in the same 5′ to 3′ orientation. In FISH analysis, a cloned 3.3-kb higher-order repeat hybridized to the centromere of Chromosome (Chr) 9 in metaphase spreads and detected two discrete foci in interphase nuclei, demonstrating that this swine higher-order repeat is chromosome-specific. The Chr 9 centromeric array spanned approximately 2.2 Mb as determined by pulsed-field gel electrophoresis. Moreover, the swine Chr 9 centromere is highly polymorphic, because an EcoRI restriction site polymorphism was detected. Thus, the assembly of divergent satellite sequences into chromosome-specific higher-order repeats appears to be a common organizational feature of both the human and swine centromere and suggests that the evolutionary mechanism(s) that create and maintain higher-order repeats is conserved between their genomes. Received: 6 August 1998 / Accepted: 20 January 1999     

Analysis of repetitive DNA in chromosomes by flow cytometry

We developed a flow cytometry method, chromosome flow fluorescence in situ hybridization (FISH), called CFF, to analyze repetitive DNA in chromosomes using FISH with directly labeled peptide nucleic acid (PNA) probes. We used CFF to measure the abundance of interstitial telomeric sequences in Chinese hamster chromosomes and major satellite sequences in mouse chromosomes. Using CFF we also identified parental homologs of human chromosome 18 with different amounts of repetitive DNA.     

Third-strand in situ hybridization (TISH) to non-denatured metaphase spreads and interphase nuclei

A methodology has been developed for binding oligodeoxyribonucleotide ’third strands’ to duplex DNA targets in fixed but not additionally denatured metaphase spreads and interphase nuclei under conditions found to be optimal in solution. Third-strand in situ hybridization (TISH) at pH 6.0 of a psoralen- and biotin-modified 16-nucleotide homopyrimidine third strand to a unique multicopy target sequence in human chromosome 17 α-satellite (D17Z1 locus) is described. UVA-photofixed third strands, rendered fluorescent by fluorescein isothiocyanate-labeled avidin, are reproducibly centromere-specific for chromosome 17, and visible without amplification of the signal in lymphocyte and somatic cell hybrid spreads and interphase nuclei. Two third-strand-specific D17Z1 haplotypes were identified. TISH has potential diagnostic, biochemical, and flow cytometric applicability to native metaphase and interphase chromatin. Received: 1 October 1998; in revised form: 22 December 1998 / Accepted: 12 February 1999     

Localization of BAC clones on mitotic chromosomes of <Emphasis Type="Italic">Musa acuminata</Emphasis> using fluorescence <Emphasis Type="Italic">in situ</Emphasis> hybridization

A bacterial artificial chromosome (BAC) library of banana (Musa acuminata) was used to select BAC clones that carry low amounts of repetitive DNA sequences and could be suitable as probes for fluorescence in situ hybridization (FISH) on mitotic metaphase chromosomes. Out of eighty randomly selected BAC clones, only one clone gave a single-locus signal on chromosomes of M. acuminata cv. Calcutta 4. The clone localized on a chromosome pair that carries a cluster of 5S rRNA genes. The remaining BAC clones gave dispersed FISH signals throughout the genome and/or failed to produce any signal. In order to avoid the excessive hybridization of repetitive DNA sequences, we subcloned nineteen BAC clones and selected their ‘low-copy’ subclones. Out of them, one subclone gave specific signal in secondary constriction on one chromosome pair; three subclones were localized into centromeric and peri-centromeric regions of all chromosomes. Other subclones were either localized throughout the banana genome or their use did not result in visible FISH signals. The nucleotide sequence analysis revealed that subclones, which localized on different regions of all chromosomes, contained short fragments of various repetitive DNA sequences. The chromosome-specific BAC clone identified in this work increases the number of useful cytogenetic markers for Musa.     

Novel Methodology for the Detection of Chromosome 21-Specific α-Satellite DNA Sequences

We present a novel method, based on the hybridization of allele-specific oligonucleotide probes, that allows the specific detection of chromosome 21 α-satellite sequences. Absence of informative polymorphic markers from the centromeric region of chromosome 21 has constituted one of the difficulties in studying the centromere of this chromosome. The α-satellite subfamilies from chromosomes 21 and 13 are almost identical in sequence and thus cannot be distinguished using conventional hybridization techniques. Analysis using nuclear families showed that the centromeric polymorphism, detected using our specific probe and pulsed-field gel restriction analysis, segregates in a Mendelian fashion and exhibits a high degree of polymorphism among unrelated individuals. The alphoid DNA of chromosome 21 is highly polymorphic, useful not only as a definitive anchor for the genetic map, but also for studies of chromosome 21 nondisjunction, including the unequivocal assignment of meiotic origin.     

Hamster chromosomes containing amplified human α-satellite DNA show delayed sister chromatid separation in the absence of de novo kinetochore formation

The centromeres of human chromosomes contain large amounts of the tandemly repeated α-satellite DNA family. Previous studies have shown that integration of α-satellite DNA into ectopic locations in mammalian chromosomes can result in the de novo formation of several features of centromeric function. Here we further examine the possible centromeric properties of α-satellite DNA by introducing it into hamster chromosomes. A large amplified region of ectopic α-satellite DNA was shown to direct binding of anticentromere antibodies (ACAs) and centromere protein B (CENP-B). The chromosome containing these ectopic arrays showed a high frequency of formation of anaphase bridges. Owing to the favourable morphology of these chromosomes, we were able to determine that this bridging was due to delayed sister chromatid disjunction at the location of the ectopic α-satellite, and not due to de novo formation of a fully functional kinetochore. A separate hamster cell line containing large tandemly repeated amplicons including the DHFR gene also displayed similar behaviour during anaphase. These results may support a role for α-satellite DNA in sister chromatid cohesion at centromeres. However, other repetitive DNA in favourable configurations appears to be capable of mimicking this behaviour during anaphase. Received: 31 December 1996; in revised form: 14 February 1997 / Accepted: 24 February 1997     

Comparative mapping of human alphoid satellite DNA repeat sequences in the great apes

Heterochromatic regions of chromosomes contain highly repetitive, tandemly arranged DNA sequences that undergo very rapid variation compared to unique DNA sequences that are predominantly conserved. In this study the chromosomal basis of speciation has been looked at in terms of repeat sequences. We have hybridized twenty-one chromosome-specific human alphoid satellite DNA probes to metaphase spreads of the chimpanzee (Pan troglodytes), gorilla (Gorilla gorilla), and orangutan (Pongo pygmaeus) to investigate the evolutionary relationship of heterochromatic regions among such hominoid species. The majority of the probes did not hybridize to their corresponding equivalent chromosome but presented hybridization signals on non-corresponding chromosomes. Such observations suggest that rapid changes may have occurred in the ancestral alphoid satellite DNA sequence, resulting in divergence among the great ape species. This revised version was published online in July 2006 with corrections to the Cover Date.     

Chromosome specificity of satellite DNAs: short- and long-range organization of a diverged dimeric subset of human alpha satellite from chromosome 3

The human alpha satellite DNA family, like many highly repeated satellite DNAs in eukaryotic genomes, is organized in distinct chromosome-specific subsets. As part of investigations into the molecular and evolutionary basis for the chromosome-specific nature of such subsets, we report the isolation and characterization of alpha satellite sequences specific for human chromosome 3. This subset is characterized by a predominant tandemly arranged 2.9 kb higher-order repeat unit which, in turn, consists of 17 tandem diverged monomer repeat units of 171 bp. Nucleotide sequence analysis reveals that the chromosome 3 higher-order repeat units are comprised, at least in part, of diverged dimeric ( 340 bp) sub-repeats and that this divergence accounts for the chromosome-specific behavior of this subset. Pulsed-field gel electrophoresis demonstrates that the chromosome 3 higher-order repeat units are localized in large domains, at least 1000 kb in length. Familial restriction fragment length polymorphisms associated with the satellite subset can be detected by pulsed field gel electrophoresis and may facilitate molecular analysis of interchromosomal variation.     

The use of peptide nucleic acids for in situ identification of human chromosomes.

The peptide nucleic acids (PNAs) constitute a remarkable new class of synthetic nucleic acid analogues, based on their peptide-like backbone. This structure gives to PNAs the capacity to hybridize with high affinity and specificity to complementary RNA and DNA sequences and a great resistance to nucleases and proteinases. Originally conceived as ligands for the study of double-stranded DNA, the unique physicochemical properties of PNAs have led to the development of a large variety of research and diagnostic assays, including antigene and antisense therapy, genome mapping, and mutation detection. Over the past few years, PNAs have been shown to be powerful tools in cytogenetics for the rapid in situ identification of human chromosomes and the detection of aneuploidies. Recent studies have reported the successful use of chromosome-specific PNA probes on human lymphocytes, amniocytes, and spermatozoa, as well as on isolated oocytes and blastomeres. Multicolor PNA protocols have been described for the identification of several human chromosomes, indicating that PNAs could become a powerful complement to FISH for in situ chromosomal investigation.     

Electrospray ionisation-cleavable tandem nucleic acid mass tag–peptide nucleic acid conjugates: synthesis and applications to quantitative genomic analysis using electrospray ionisation-MS/MS

The synthesis and characterization of isotopomer tandem nucleic acid mass tag–peptide nucleic acid (TNT–PNA) conjugates is described along with their use as electrospray ionisation-cleavable (ESI-Cleavable) hybridization probes for the detection and quantification of target DNA sequences by electrospray ionisation tandem mass spectrometry (ESI-MS/MS). ESI-cleavable peptide TNT isotopomers were introduced into PNA oligonucleotide sequences in a total synthesis approach. These conjugates were evaluated as hybridization probes for the detection and quantification of immobilized synthetic target DNAs using ESI-MS/MS. In these experiments, the PNA portion of the conjugate acts as a hybridization probe, whereas the peptide TNT is released in a collision-based process during the ionization of the probe conjugate in the electrospray ion source. The cleaved TNT acts as a uniquely resolvable marker to identify and quantify a unique target DNA sequence. The method should be applicable to a wide variety of assays requiring highly multiplexed, quantitative DNA/RNA analysis, including gene expression monitoring, genetic profiling and the detection of pathogens.     

Chromosome-specific alpha satellite DNA: nucleotide sequence analysis of the 2.0 kilobasepair repeat from the human X chromosome.

The pericentromeric region of the human X chromosome is characterized by a tandemly repeated family of 2.0 kilobasepair (kb) DNA fragments, initially revealed by cleavage of human DNA with the restriction enzyme BamHI. We report here the complete nucleotide sequence of a cloned member of the repeat family and establish that this X-linked DNA family consists entirely of alpha satellite DNA. Our data indicate that the 2.0 kb repeat consists of twelve alpha satellite monomers arranged in imperfect, direct repeats. Each of the alpha X monomers is approximately 171 basepairs (bp) in length and is 60-75% identical in sequence to previously described primate alpha satellite DNAs. The twelve alpha X monomers are 65-85% identical in sequence to each other and are organized as two adjacent, related blocks of five monomers, plus an additional two monomers also related to monomers within the pentamer blocks. Partial nucleotide sequence of a second, independent copy of the 2.0 kb BamHI fragment established that the 2.0 kb repeat is, in fact, the unit of amplification on the X. Comparison of the sequences of the twelve alpha X monomers allowed derivation of a 171 bp consensus sequence for alpha satellite DNA on the human X chromosome. These sequence data, combined with the results of filter hybridization experiments of total human DNA and X chromosome DNA, using subregions within the 2.0 kb repeat as probes, provide strong support for the hypothesis that individual human chromosomes are characterized by different alpha satellite families, defined both by restriction enzyme periodicity and by chromosome-specific primary sequence.     

Identification of Porto-1, a new repeated sequence that localises close to the centromere of chromosome 2 of Drosophila melanogaster

We have used the polymerase chain reaction (PCR) technique to search the Drosophila melanogaster genome for the presence of sequences with homology to mammalian and yeast centromeric DNA. Using primers based on the human CENP-B box present in α-satellite DNA and part of the Saccharomyces cerevisiae CDEIII centromeric sequence, a number of specific DNA fragments were amplified from total genomic DNA. In situ hybridization to polytene and mitotic chromosomes showed these fragments to localise to centromeric and pericentromeric regions. Direct cloning of the amplified fragments into conventional plasmids proved unsuccessful. However, a recombinant P1 clone containing D. melanogaster genomic DNA that supports PCR amplification by the primers was identified. Molecular characterisation of this clone revealed a DNA fragment that localises primarily to the centromere of chromosome 2. Sequence analysis indicated that this fragment contains at least four different repeats, including Rsp, transposable elements, Bari-1 and a new AT-rich repeated sequence that we have designated Porto-1. Detailed fluorescence in situ hybridization analysis shows that Porto-1 is localised very close to the primary constriction of chromosome 2. Sequence analysis suggests that this repeat was specifically amplified by our primers, although limited homology to the CENP-B box or CDEIII elements was found. In situ hybridization to a number of Drosophila species shows Porto-1 to be present only in D. melanogaster. Received: 13 April 1996; in revised form: 25 June 1996 / Accepted: 6 July 1996