Sequence heterogeneity within the human alphoid repetitive DNA family.

We have cloned and determined the base-sequence and genome organization of two human chromosome-specific alphoid DNA fragments, designated L1.26, mapping principally to chromosomes 13 and 21, and L1.84, mapping to chromosome 18. Their copy number is estimated to be approximately 2,000 per haploid genome. L1.84 has a double-dimer organization, whereas L1.26 has a much less defined higher order tandem organization. Further, we present evidence that the restriction-site spacing within the alphoid DNA family is chromosome specific. From sequence analysis, clones L1.26 and L1.84 are found to consist of 5 and 4 tandemly duplicated 170 bp monomers. Cross-homology between the various monomers is 65-85%. The analysis suggests that the evolution of tandem-arrays does not take place via a defined 340 bp unit, as was inferred by others, but via circularly permutated monomers or multimers of the 170 bp unit.     

Unusual domains of human alphoid satellite DNA with contiguous non-satellite sequences: sequence analysis of a junction region.

The sequence organization of cloned segments of Human DNA carrying unusual domains of alphoid satellite was studied by restriction mapping, electron microscopy and base sequence analysis. In some cases restriction mapping revealed the absence of the typical 340 bp EcoR 1 dimer, although blot hybridizations showed the extensive presence of alphoid satellite. A variant monomeric construction was demonstrated by DNA sequencing. Furthermore, inverted repeats within these domains were detected by electron microscopy. In one case these were shown to be the result of interruptions in the satellite sequence by members of a family of repetitive, conserved elements.     

Sequence heterogeneity of the human alphoid satellite DNA and thermal stability of mismatched alphoid DNA duplexes

1. 340 bp (dimer) and 680 bp (tetramer) fractions of the human alphoid satellite DNA (h alpha RI DNA) were isolated after complete cleavage of total human DNA with EcoR I and cloned in pBR 32.5. 2. Ten clones containing 340 bp inserts and one clone containing 680 bp insert were sequenced in order to investigate the sequence heterogeneity of this satellite DNA and the sequence data were compared with the consensus h alpha RI DNA sequence of Wu and Manuelidis (1980). 3. It was shown that in all clones studied the mutations are nonrandomly distributed along the human alphoid monomers forming distinct conservative and variable regions. 4. This mutation distribution pattern was compared with the nucleotide variations between the consensus sequences of different primate alphoid DNAs and it was found that the interspecies nucleotide divergency of this satellite DNA is quite similar to the intragenomic one. 5. The sequenced h alpha RI DNA clones were used for preparation of DNA-DNA hybrids with a known percentage of base pair mismatching. 6. These hybrids were melted on hydroxyapatite (HAP) and the results obtained were used to determine the relationship between the thermal stability (Tm) and the extent of base pair mismatching for naturally diverged DNA sequences. 7. A value of 0.7 degrees C decrease in Tm per 1% base pair mismatching was found.     

Use of a cloned alphoid repetitive sequence of human DNA in studying the polymorphism of heterochromatin regions of chromosomes

Chromosomal location of the cloned fragment pHS05 of alphoid DNA from the collection of human PstI restricts has been studied in 38 individuals by in situ hybridization. Pericentromeric localization of the DNA fraction studied was found in practically all chromosomes of the set. Significant interchromosomal and poorly expressed interindividual differences were detected in a number of the copies of the sequence class investigated. The majority of the label (approx. 27%) was observed over the pericentromeric region of chromosome 3. No relationship was discovered between hybridization results and the pattern of Q-polymorphism.     

Chromosome-specific alpha satellite DNA: isolation and mapping of a polymorphic alphoid repeat from human chromosome 10

Distinct subsets of the human alpha satellite repetitive DNA family can be found in the centromeric region of each chromosome. Here we described the isolation and mapping of an alpha satellite repeat unit specific for human chromosome 10, using a somatic cell hybrid in which the only human centromere derives from chromosome 10. A hierarchical higher-order repeat unit, consisting of eight tandem approximately 171-bp alphoid monomer units, is defined by six restriction endonucleases. Under high-stringency conditions, a cloned representative of this 8-mer repeat family hybridizes to chromosome 10 only, both by Southern blot analysis of a somatic cell hybrid panel and by in situ hybridization. The probe furthermore detects a polymorphic restriction pattern of the alpha satellite array on chromosome 10. These features will make this probe a valuable genetic marker for studies of the centromeric region of chromosome 10.     

Concerted evolution of alpha satellite DNA: Evidence for species specificity and a general lack of sequence conservation among alphoid sequences of higher primates

We investigated relationships among alpha satellite DNA families in the human, gorilla, chimpanzee, and orangutan genomes by filter hybridization with cloned probes which correspond to chromosome-specific alpha satellite DNAs from at least 12 different human chromosomes. These include representatives of both the dimer-based and pentamer-based subfamilies, the two major subfamilies of human alpha satellite. In addition, we evaluated several high-copy dimer-based probes isolated from gorilla genomic DNA. Under low stringency conditions, all human probes tested hybridized extensively with gorilla and chimpanzee alpha satellite sequences. However, only pentameric and other non-dimeric human alphoid probes hybridized with orangutan alpha satellite sequences; probes belonging to the dimer subfamily did not cross-hybridize detectably with orangutan DNA. Moreover, under high stringency conditions, each of the human probes hybridized extensively only with human genomic DNA; none of the probes cross-hybridized effectively with other primate DNAs. Dimer-based gorilla alpha satellite probes hybridized with human and chimpanzee, but not orangutan, sequences under low stringency hybridization conditions, yet were specific for gorilla DNA under high stringency conditions. These results indicate that the alpha satellite DNA family has evolved in a concerted manner, such that considerable sequence divergence is now evident among the alphoid sequences of closely related primate species.     

Nucleotide sequence of mouse satellite DNA.

The nucleotide sequence of uncloned mouse satellite DNA has been determined by analyzing Sau96I restriction fragments that correspond to the repeat unit of the satellite DNA. An unambiguous sequence of 234 bp has been obtained. The sequence of the first 250 bases from dimeric satellite fragments present in Sau96I limit digests corresponds almost exactly to two tandemly arranged monomer sequences including a complete Sau96I site in the center. This is in agreement with the hypothesis that a low level of divergence which cannot be detected in sequence analyses of uncloned DNA is responsible for the appearance of dimeric fragments. Most of the sequence of the 5% fraction of Sau96 monomers that are susceptible to TaqI has also been determined and has been found to agree completely with the prototype sequence. The monomer sequence is internally repetitious being composed of eight diverged subrepeats. The divergence pattern has interesting implications for theories on the evolution of mouse satellite DNA.     

Nucleotide sequences of highly repetitive DNA from scleractinian corals

The staghorn coral genome contains 5% of a satellite DNA, consisting of 80 to 300 x 10(3) copies of a 118-bp repeat unit per haploid Acropora genome.     

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.     

A subfamily of alphoid repetitive DNA shared by the NOR-bearing human chromosomes 14 and 22

The nucleotide sequence of members of an alpha-repeat subfamily shared by human chromosomes 14 and 22 is presented. This subfamily is organized into a higher-order repeat unit composed of a tandem repetition of an ordered array of four related but distinct 340-bp repeat dimers. An analogous situation has been described for a related but distinct subfamily shared by chromosomes 13 and 21. These two subfamilies were further shown not to be present on the homologous chimpanzee chromosomes and therefore must have arisen by rearrangement of the human genome after separation of the two species. The sequence homology between the 13/21 and the 14/22 subfamilies is about 85%. The 14/22 subfamily represents the only major alphoid DNA species on these two chromosomes and is not present elsewhere in the human genome. Fluorescent in situ hybridizations show that sequences from the 13/21 and 14/22 subfamilies can be used as specific markers for their respective chromosomes.     

Nucleotide sequence of a highly repetitive component of rat DNA.

A highly repetitive component of rat DNA which could not yet be enriched by density gradient centrifugation was isolated with the help of the restriction nuclease Sau3AI. This nuclease converted the bulk of the DNA to small fragments and left a repetitive DNA component as large fragments which were subsequently purified by gel filtration and electrophoresis. This DNA component which was termed rat satellite DNA I is composed of tandemly repeated 370 bp blocks. According to sequence analysis the 370 bp repeats consist of alternating 92 and 93 bp units with homologous but not identical sequences. Methylation of CpG residues was correlated to the rate of cleavage by restriction nucleases. Significant homologies exist between the sequences of rat satellite DNA I and satellite DNAs of several other organisms. The divergence of the sequence of rat satellite DNA I was discussed with respect to evolutionary considerations.     

Nucleotide sequence identity of mitochondrial DNA from different human tissues

Recombinant DNA techniques have been used to search for mitochondrial (mt) nucleotide (nt) sequence differences between human tissues within an individual. mtDNA isolated from brain, heart, liver, kidney, and skeletal muscle of two different individuals was cleaved with SacI and XbaI, and then cloned in bacteriophage M13. Partial nt sequence determination of 121 independently isolated recombinant M13 clones containing either the cytochrome oxidase subunit III gene or the D-loop region of human mtDNA revealed base substitution differences between individuals, and between each individual and the published human mtDNA sequence. A majority of these base substitutions were transitions. No systematic nt sequence differences were identified between tissues within an individual, however. These results suggest that mtDNA sequence alterations do not accompany organogenesis, and that somatic mutations do not accumulate in the mtDNA of different human tissues to a level of greater than one nt substitution per molecule.     

Specific arrangements of human satellite III DNA sequences in human chromosomes

DNA was extracted from various rodent-human somatic cell hybrids that contained single or a few human chromosomes. These DNAs were examined by a combination of restriction endonuclease digestion, gel electrophoresis, and filter hybridisation to radioactive satellite DNA probes following transfer of the denatured restriction fragments from a gel to a nitrocellulose filter. In this way the arrangement of sequences homologous to human satellite III were examined on human chromosomes 1, 7, 11, 15, 22 and X. It was found that the distribution of restriction endonuclease sites within satellite III DNA is different on different chromosomes.     

Cloning of human satellite III DNA: different components are on different chromosomes.

Two fragments cloned from purified human satellite III DNA do not cross-react with each other. One fragment, for which a partial sequence is reported, hybridises to satellite II as well as III and is shown to originate on chromosome 1. The other cloned fragment originates from the Y chromosome. This fragment has undergone considerable changes in size when cloned in lambda gt WES lambda B. Human satellite III is shown to consist of a number of non-cross-reacting sequences which nevertheless are related by the presence of closely spaced Hin F1 sites.     

Analysis of extrachromosomal structures containing human centromeric alphoid satellite DNA sequences in mouse cells

Yeast artificial chromosomes (YACs) spanning the centromeric region of the human Y chromosome were introduced into mouse LA-9 cells by spheroplast fusion in order to determine whether they would form mammalian artificial chromosomes. In about 50% of the cell lines generated, the YAC DNA was associated with circular extrachromosomal structures. These episomes were only present in a proportion of the cells, usually at high copy number, and were lost rapidly in the absence of selection. These observations suggest that, despite the presence of centromeric sequences, the structures were not segregating efficiently and thus were not forming artificial chromosomes. However, extrachromosomal structures containing alphoid DNA appeared cytogenetically smaller than those lacking it, as long as yeast DNA was also absent. This suggests that alphoid DNA can generate the condensed chromatin structure at the centromere. Edited by: H. F. Willard     

Characterization of a human alphoid satellite DNA sequence: Potential use in assessing genetic diversity in Indian populations

Sequence analysis of a human repetitive DNA sequence (pTRF5.6) revealed considerable homology (76%) to the alphoid consensus sequence. Genomic blots of StuI-digested human DNA, hybridized to pTRF5.6, generated a ladder of bands with each band corresponding to oligodeoxyribonucleotide of an approx. 170-bp repeat, indicating a tandemly arrayed organization of this repeat element within the genome. Genomic hybridization analyses of unrelated individuals belonging to various geographical regions of India, using this alphoid satellite probe, revealed polymorphic bands ranging between 2 and 9 kb. Along with an individual-specific band pattern, several isomorphic bands below 2 kb were also evident. There was very little of genetic variability between populations, suggestive of low polymorphism at the inter-population level. Our result suggest that alphoid satellite sequence probe can be used in assessing the genetic diversity of various ethnic groups/populations belonging to different geographical regions.     

Different subfamilies of alphoid repetitive DNA are present on the human and chimpanzee homologous chromosomes 21 and 22.

The alphoid repeat DNA on chimpanzee chromosome 22 was compared with alphoid repeat DNA on its human homologue, chromosome 21. Hybridization of different alphoid probes under various conditions of stringency show that the alphoid repeats of chimpanzee chromosome 22 are not closely related to those of human chromosome 21. Sequence analysis of cloned dimer and tetramer EcoRI fragments from chimpanzee chromosome 22 confirm the low overall level of homology, but reveal the presence of several nucleotide changes which are exclusive to the chromosome 21 subfamily of human alphoid DNA. Southern blot analysis of alphoid repeat DNA on the chimpanzee X chromosome suggests this subfamily has been strongly conserved during and since the separation of chimpanzee and man although the two subfamilies can be distinguished on the basis of Taq I restriction fragments.