Nucleotide sequence heterogeneity of alpha satellite repetitive DNA: a survey of alphoid sequences from different human chromosomes.

The human alpha satellite DNA family is composed of diverse, tandemly reiterated monomer units of approximately 171 basepairs localized to the centromeric region of each chromosome. These sequences are organized in a highly chromosome-specific manner with many, if not all human chromosomes being characterized by individually distinct alphoid subsets. Here, we compare the nucleotide sequences of 153 monomer units, representing alphoid components of at least 12 different human chromosomes. Based on the analysis of sequence variation at each position within the 171 basepair monomer, we have derived a consensus sequence for the monomer unit of human alpha satellite DNA which we suggest may reflect the monomer sequence from which different chromosomal subsets have evolved. Sequence heterogeneity is evident at each position within the consensus monomer unit and there are no positions of strict nucleotide sequence conservation, although some regions are more variable than others. A substantial proportion of the overall sequence variation may be accounted for by nucleotide changes which are characteristic of monomer components of individual chromosomal subsets or groups of subsets which have a common evolutionary history.     

Molecular analysis of a deletion polymorphism in alpha satellite of human chromosome 17: evidence for homologous unequal crossing-over and subsequent fixation.

The human alpha satellite DNA family is organized into chromosome-specific subsets characterized by distinct higher-order repeats based on a approximately 171 basepair monomer unit. On human chromosome 17, the predominant form of alpha satellite is a 16-monomer (16-mer) higher-order repeat present in 500-1000 copies per chromosome 17. In addition, less abundant 15-monomer and 14-monomer repeats are also found constitutively on chromosome 17. Polymorphisms in the form of different higher-order repeat lengths have been described for this subset, the most prominent polymorphism being a 13-monomer (13-mer) higher-order repeat present on approximately 35% of all chromosomes 17. To investigate the nature of this polymorphism, we have cloned, sequenced and compared the relevant regions of the 13-mer to the previously characterized 16-mer repeat. The results show that the repeats are virtually identical, with the principal difference being the exclusion of three monomers from the 13-mer repeat. We propose that the 13-mer is the product of an isolated homologous recombination event between two monomers of the 16-mer repeat. Sequence comparisons reveal the approximate site of recombination and flanking regions of homology. This recombination site corresponds to a position within the alphoid monomer which has been previously implicated in an independent homologous recombination event, suggesting that there may exist a preferred register for recombination in alphoid DNA. We suggest that these events are representative of an ongoing process capable of reorganizing the satellite subset of a given chromosome, thereby contributing to the establishment of chromosome-specific alpha satellite subsets.     

Organization and evolution of alpha satellite DNA from human chromosome 11

The human alpha satellite repetitive DNA family is organized as distinct chromosomal subsets located at the centromeric regions of each human chromosome. Here, we describe a subset of the alpha satellite which is localized to human chromosome 11. The principal unit of repetition of this alpha satellite subset is an 850 bp XbaI fragment composed of five tandem diverged alphoid monomers, each 171 bp in length. The pentamer repeat units are themselves tandemly reiterated, present in 500 copies per chromosome 11. In filter hybridization experiments, the Alpha 11 probes are specific for the centromeric alpha satellite sequences of human chromosome 11. The complete nucleotide sequences of two independent copies of the XbaI pentamer reveal a pentameric configuration shared with the alphoid repeats of chromosomes 17 and X, consistent with the existence of an ancestral pentameric repeat common to the centromeric arrays of at least these three human chromosomes.     

Human centromeric alphoid domains are periodically homogenized so that they vary substantially between homologues. Mechanism and implications for centromere functioning

Sequence analysis of alphoid repeats from human chromosomes 17, 21 and 13 reveals recurrent diagnostic variant nucleotides. Their combinations define haplotypes, with higher order repeats (HORs) containing identical or closely-related haplotypes tandemly arranged into separate domains. The haplotypes found on homologues can be totally different, while HORs remain 99.8% homogeneous both intrachromosomally and between homologues. These results support the hypothesis, never before demonstrated, that unequal crossovers between sister chromatids accumulate to produce homogenization and amplification into tandem alphoid repeats. I propose that the molecular basis of this involves the diagnostic variant nucleotides, which enable pairing between HORs with identical or closely-related haplotypes. Domains are thus periodically renewed to maintain high intrachromosomal and interhomologue homogeneity. The capacity of a domain to form an active centromere is maintained as long as neither retrotransposons nor significant numbers of mutations affect it. In the presented model, a chromosome with an altered centromere can be transiently rescued by forming a neocentromere, until a restored, fully-competent domain is amplified de novo or rehomogenized through the accumulation of unequal crossovers.     

Alphoid DNA polymorphisms for chromosome 21 can be distinguished from those of chromosome 13 using probes homologous to both.

Although alphoid DNA sequences shared among acrocentric chromosomes have been identified, no human chromosome 21-specific sequence has been isolated from the centromeric region. To identify alphoid DNA restriction fragment length polymorphisms (RFLPs) specific for chromosome 21, we hybridized human genomic DNA with alphoid DNA probes [L1.26; aRI(680),21-208] shared by chromosomes 13 and 21. We detected RFLPs with restriction enzymes ECoRI, HaeIII, MboI,StuI, and TaqI. The segregation of these RFLPs was analyzed in the 40 CEPH families. Linkage analysis between these RFLPs and loci previously mapped to either chromosome 13 or 21 revealed RFLPs that appear to be specific to chromosome 21. These polymorphisms may be useful as genetic markers of the centromeric region of chromosome 21. Different alphoid loci within the centromeric region of chromosome 13 were identified.     

Characterisation of a boundary between satellite III and alphoid sequences on human chromosome 10.

Alphoid and satellite III sequences are arranged as large tandem arrays in the centromeric regions of human chromosomes. Several recent studies using in situ hybridisation to investigate the relative positions of these sequences have shown that they occupy adjacent but non-overlapping domains in metaphase chromosomes. We have analysed the DNA sequence at the junction between alphoid and satellite III sequences in a cosmid previously mapped to chromosome 10. The alphoid sequence consists of tandemly arranged dimers which are distinct from the known chromosome 10-specific alphoid family. Polymerase chain reaction experiments confirm the integrity of the sequence data. These results, together with pulsed field gel electrophoresis data place the boundary between alphoid and satellite III sequences in the mapping interval 10 centromere-10q11.2. The sequence data shows that these repetitive sequences are separated by a partial L1 interspersed repeat sequence less than 500bp in length. The arrangement of the junction suggests that a recombination event has brought these sequences into close proximity.     

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.     

Structural analysis of alphoid DNA of primates. I. Heterogeneity of nucleotide sequence of alphoid repeats in human DNA

The nucleotide sequence of two cloned fragments of human alphoid DNA was established. These fragments were earlier characterized in our laboratory as molecular markers of the 3rd (pHS05) and 11th (pHS53) chromosomes. Fragment pHS53 (2546 bp) contains alphoid repeats tandemly arranged and organized into three highly homologous pentamers. The heterogeneity of monomeric sequences within individual pentamers reaches 24-33%. Structural analysis of EcoRI subfragment pHS05 showed that this alphoid tetramer consists of two dimers 340 bp long. These dimers differ up to 16% from each other and from the so-called consensus sequence of the EcoRI-340 bp-restriction fragments family reported earlier by Wu and Manuelidis. The primary structure of four cloned fragments of EcoRI-340 bp-family was established. The data show that human alphoid DNA is highly heterogeneous. This conclusion is opposite to the view suggesting that alphoid DNA is a highly homogeneous class of reiterated sequences of the human genome.     

Report of the First International Workshop on Human Chromosome 2 mapping 1991.

We report the isolation of a clone (pTR9) from a human chromosome 21 lambda phage library, which was found to contain two distinct components: (1) a previously unreported subfamily of human satellite III (pTR9-s3; 1,485 bp) and (2) an alpha satellite sequence (pTR9-alpha; 250 bp) containing 1.5 copies of a 171-bp alphoid unit that shows 88.4% homology to a previously reported alpha satellite consensus sequence. The two components are separated by two direct repeats of 9 bp. Use of the polymerase chain reaction (PCR) to amplify across the junction between pTR9-s3 and pTR9-alpha established that these two sequences are contiguous in total human genomic DNA and in DNA derived from somatic cell hybrids carrying human chromosomes 13, 14, or 21. A related, but considerably more diverged, sequence was also detected on chromosome 15. Southern analysis of somatic cell hybrids at high stringency revealed a common structure of the pTR9-s3 sequence on chromosomes 13, 14, and 21 but not on 15 or 22. This sequence should be useful for the study of the structural organisation of the centromere of these chromosomes and the mechanism of their involvement in Robertsonian translocations.     

Structure, organization, and sequence of alpha satellite DNA from human chromosome 17: evidence for evolution by unequal crossing-over and an ancestral pentamer repeat shared with the human X chromosome.

The centromeric regions of all human chromosomes are characterized by distinct subsets of a diverse tandemly repeated DNA family, alpha satellite. On human chromosome 17, the predominant form of alpha satellite is a 2.7-kilobase-pair higher-order repeat unit consisting of 16 alphoid monomers. We present the complete nucleotide sequence of the 16-monomer repeat, which is present in 500 to 1,000 copies per chromosome 17, as well as that of a less abundant 15-monomer repeat, also from chromosome 17. These repeat units were approximately 98% identical in sequence, differing by the exclusion of precisely 1 monomer from the 15-monomer repeat. Homologous unequal crossing-over is suggested as a probable mechanism by which the different repeat lengths on chromosome 17 were generated, and the putative site of such a recombination event is identified. The monomer organization of the chromosome 17 higher-order repeat unit is based, in part, on tandemly repeated pentamers. A similar pentameric suborganization has been previously demonstrated for alpha satellite of the human X chromosome. Despite the organizational similarities, substantial sequence divergence distinguishes these subsets. Hybridization experiments indicate that the chromosome 17 and X subsets are more similar to each other than to the subsets found on several other human chromosomes. We suggest that the chromosome 17 and X alpha satellite subsets may be related components of a larger alphoid subfamily which have evolved from a common ancestral repeat into the contemporary chromosome-specific subsets.     

Structure of the major block of alphoid satellite DNA on the human Y chromosome

Alphoid DNA is a family of tandemly repeated simple sequences found mainly at the centromeres of the chromosomes of many primates. This paper describes the structure of the alphoid DNA at the centromere of the human Y chromosome. We have used pulsedfield gradient gel electrophoresis, cosmid cloning and DNA sequencing to determine the organization of the alphoid DNA on each of the Y chromosomes present in two somatic cell hybrids. In each case there is a single major block of alphoid DNA. This is approximately 470,000 bases (475 kb) long on one chromosome and approximately 575 kb long on the other. Apart from the size difference, the structures of the two blocks and the surrounding sequences are very similar. However, one restriction enzyme, AvaII, detects two clusters of sites within one block but does not cleave the other. The alphoid DNA within each block is organized into tandemly repeating units, most of which are about 5.7 kb long. A few variant units present on one chromosome are about 6.0 kb long. These variants, like the AvaII site variants, are clustered. The 5.7 kb and 6.0 kb units themselves consist of tandemly repeating 170 base-pair subunits. The 6.0 kb unit has two more of these subunits than the 5.7 kb unit. Our results provide a basis for further structural analysis of the human Y chromosome centromeric region, and suggest that long-range structural polymorphisms of tandemly repeated sequence families may be frequent.     

Isolation and characterization of alphoid DNA sequences specific for the pericentric regions of chromosomes 4, 5, 9, and 19

We have cloned and characterized two distinct types of alphoid DNA elements. Probe pG-Xba 11/340 was obtained by random cloning of human satellite DNA and contains two basic units with overall 88% homology to the 171-bp consensus alphoid sequence. pG-Xba 11/340-like elements are represented about 2,000-4,000 times in the haploid genome and, by in situ hybridization, are found exclusively at the primary constrictions of chromosomes 4 and 9. Probe pG-A16 was cloned from a chromosome 19-specific cosmid library and represents a 2.25-kb higher-order DNA element which is present at roughly 75-150 copies per haploid genome and which hybridizes to the centromeres of chromosomes 5 and 19. Using the pG-A16 probe, further genetic and physical dissection of the central area of chromosome 19 can be envisaged.     

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.     

Genomic organization of alpha satellite DNA on human chromosome 7: evidence for two distinct alphoid domains on a single chromosome.

A complete understanding of chromosomal disjunction during mitosis and meiosis in complex genomes such as the human genome awaits detailed characterization of both the molecular structure and genetic behavior of the centromeric regions of chromosomes. Such analyses in turn require knowledge of the organization and nature of DNA sequences associated with centromeres. The most prominent class of centromeric DNA sequences in the human genome is the alpha satellite family of tandemly repeated DNA, which is organized as distinct chromosomal subsets. Each subset is characterized by a particular multimeric higher-order repeat unit consisting of tandemly reiterated, diverged alpha satellite monomers of approximately 171 base pairs. The higher-order repeat units are themselves tandemly reiterated and represent the most recently amplified or fixed alphoid sequences. We present evidence that there are at least two independent domains of alpha satellite DNA on chromosome 7, each characterized by their own distinct higher-order repeat structure. We determined the complete nucleotide sequences of a 6-monomer higher-order repeat unit, which is present in approximately 500 copies per chromosome 7, as well as those of a less-abundant (approximately 10 copies) 16-monomer higher-order repeat unit. Sequence analysis indicated that these repeats are evolutionarily distinct. Genomic hybridization experiments established that each is maintained in relatively homogeneous tandem arrays with no detectable interspersion. We propose mechanisms by which multiple unrelated higher-order repeat domains may be formed and maintained within a single chromosomal subset.     

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.     

Familial whole-arm translocations (1;19), (9;13), and (12;21): a review of 101 constitutional exchanges

We report here on 3 familial whole-arm translocations (WATs), namely the 8th instance of t(1;19)(p10;q10) and 2 novel exchanges: t(9;13)(p10;q10) and t(12;21)(p10;q10). The exchanges (1;19) and (12;21) were ascertained through a balanced carrier, whereas the t(9;13) was first diagnosed in a boy with a trisomy 9p syndrome and der(9p13p). Results of FISH analyses with the appropriate α-satellite probes were as follows. Family 1, t(1;19): the D1Z5 probe gave a strong signal on both the normal chromosome 1 and the der(1q19p) as well as a weak signal on the der(1p19q). Family 2, t(9;13): the centromere-9 alphoid and D13Z1/D21Z1 probes under standard stringency gave no signal on the der(9p13p) in both the proband and a carrier brother, whereas the der(9q13q) was labelled only with the centromere-9 alphoid repeat in the latter; yet, this probe under low stringency revealed a residual amount of alphoid DNA on the der(9p13p) in the carrier. Family 3, t(12;21): the D12Z3 probe gave a signal on the normal chromosome 12 and the der(12p21q), whereas the D13Z1/D21Z1 repeat labelled the der(12q21p), the normal chromosome 21, and both chromosomes 13. Out of 101 WATs compiled here, 73 are distinct exchanges, including 32 instances between chromosomes with common alphoid repeats. Moreover, 7/9 of recurrent WATs involved chromosomes from the same alphoid family. Thus constitutional WATs appear to recur more frequently than other reciprocal exchanges, often involve chromosomes with common alphoid repeats, and can mostly be accounted for the great homology in alphoid DNA that favours mispairing and illegitimate nonhomologous recombination.     

Two subsets of human alphoid repetitive DNA show distinct preferential localization in the pericentric regions of chromosomes 13, 18, and 21

We have isolated and characterized two human middle repetitive alphoid DNA fragments, L1.26 and L1.84, which localize to two different sets of chromosomes. In situ hybridization revealed both repeats to have major and minor binding sites on the pericentric regions of several chromosomes. Probe L1.26 maps predominantly to chromosomes 13 and 21. Probe L1.84 locates to chromosome 18. Minor hybridization sites for both probes include chromosomes 2, 8, 9, and 20; in addition, L1.26 revealed minor sites on chromosomes 18 and 22. The binding to these sites strongly depends on hybridization conditions. In Southern blot hybridizations to total human DNA, both L1.26 and L1.84 give the same ladder pattern, with a step size of 170 bp, indicating their presence as tandem repeats, but with different band intensities for each probe. The chromosome-specific nature of particular multimers was confirmed by Southern blot analyses of a human-rodent hybrid cell panel. We conclude that L1.26 and L1.84, with their related sequences, constitute subfamilies of alphoid DNA that are specific for subsets of chromosomes and, in some cases, possibly even for single chromosomes.     

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.     

Identification of two distinct subfamilies of alpha satellite DNA that are highly specific for human chromosome 15

We report the isolation of two distinct subfamilies of alpha satellite DNA (pTRA-20 and -25) from human chromosome 15. In situ hybridization experiments indicated that both subfamilies are highly specific for this chromosome. Southern analysis of a somatic hybrid cell line carrying human chromosome 15 revealed a likely higher-order genomic band of 2.5 kb for pTRA-20. Similar analysis for pTRA-25 showed multiple higher-order bands of 3.5, 4.5, and 5 kb at moderately high hybridization stringency, but a predominance of the 4.5-kb species at very high stringency. Direct comparison with human genomic DNA confirmed the authenticity of these higher-order structures and demonstrated polymorphic variations using both probes. The origin of the different alphoid subfamilies on chromosome 15 is discussed. These sequences should be useful for the construction of centromere-based genetic linkage maps for human chromosome 15 and, in conjunction with the other alphoid sequences already reported for chromosomes 13, 14, 21, and 22, should allow a concerted analysis of the evolution and the possible etiological role of these DNAs in aberrations commonly seen in these chromosomes.