Analysis of the monomeric alphoid sequences in the pericentromeric region of human chromosome 7

To further define the structure of the pericentromeric region of human chromosome 7, we have identified and characterized a YAC clone (YAC 311.H5) containing the D7S1480 locus, which maps to the short arm near the centromere of this chromosome, by linkage in CEPH families and radiation hybrid analysis. This YAC contains two new blocks of alphoid DNA (named Z5 and Z6). Both Z5 and Z6 show monomeric structures and a lack of higher-order repeats, and, therefore, belong to suprachromosomal family type 4 (M1). The orientation of the two blocks and the physical distances over the region were defined by pulsed-field gel electrophoresis (PFGE) and fluorescence in situ hybridization on chromatin fibers (FiberFISH). A YAC contig spanning the centromeric region has been developed by STS content.     

Chromosome-specific alpha satellites: two distinct families on human chromosome 18.

Two types of human chromosome 18-specific alpha satellite fragments have been cloned and sequenced. They represent closely related but distinct alphoid families formed by two different types of the higher-order repeated units (1360-bp EcoRI and 1700-bp HindIII fragments) that do not alternate in the genome. The individual repeats within each family are 99% identical and interfamily homology is about 78%. Sequence analysis shows that both repeats belong to alphoid suprachromosomal family 2, but their homology is not higher than that of family members located on different chromosomes. Therefore, the two repeats shared a common origin in the recent past, although they are not the direct offspring of one ancestral sequence. Our data indicate that these two 18-specific domains have appeared as a result of two separate amplification events. Despite the high degree of homology, they are not undergoing intrachromosomal homogenization, although some variation of this process might take place within each domain.     

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     

The phylogeny of human chromosome specific alpha satellites

The chromosomal distribution of sequences homologous to 18 coned alpha satellite fragments was established by in situ hybridization. It appeared that all the cloned sequences were members of small repeated families located on single chromosome pairs. Among the sequences studied specific molecular markers for chromosomes 3, 4, 10,11,17,18 and X were found. Comparison of the hybridization spectra obtained under non-stringent conditions and of restriction site periodicities in different chromosome-specific families allowed the identification of three suprachromosomal families, each located on a characteristic set of chromosomes. The three families together cover all the autosomes and the X chromosome. These data plus those reported previously allow part of the phylogenetic tree of chromosome-specific alpha satellite repeats to be drawn. Each suprachromosomal family has presumably originated from a distinct ancestral sequence and consists of certain types of monomers. Ancestral sequences have evolved into a number of chromosome-specific families by cycles of interchromosomal transfers and subsequent amplification events. The high homogeneity of chromosome-specific families may be a result of intrachromosomal homogenization of amplification units in chromosome-specific alpha satellite domains.     

Evolutionary relationships of multiple alpha satellite subfamilies in the centromeres of human chromosomes 13, 14, and 21

Summary Using Southern and in situ hybridization analyses, we have earlier defined four different subfamilies of alpha satellite DNA (designated pTRA-1, -2, -4, and -7), each of which has a unique higher order structure represented almost identically on human chromosomes 13, 14, and 21. Here we present the complete sequence of single isolates of these four subfamilies, representing approximately 12 kb of sequence information. Sequences of the individual 171-bp monomers that constitute these four subfamilies (and a fifth subfamily, Alpha-R1, that is known to be present on chromosomes 13 and 21) were compared both within and between the different clones. The results indicate that, at the level of their primary sequence, the five alpha subfamilies are characterized by structures that are as unrelated to each other as the different alpha subfamilies from other chromosomes. However, sequence comparisons between monomers of these clones indicate the possibility that pTRA-2, -4, and-1 may have arisen, at least in part, from a common ancestral alphoid sequence. We also provide evidence that exchange of pTRA-1 between nonhomologous centromeres and its homogenization throughout the population, perhaps by unequal exchange mechanisms, could have occurred after the divergence of humans and chimpanzees. The evolution of multiple alphoid subfamilies within a single centromere suggests that unequal exchange mechanisms may be restricted to specific domains. This may in turn contribute to some requirement for subregional pairing of sequences along the length of the centromeres of these chromosomes. Offprint requests to: K.H.A. Choo     

Genomic organization, sequence and polymorphism of the human chromosome 4-specific a-satellite DNA

Two -satellite fragments specific for human chromosome 4 have been cloned and characterized. Under stringent annealing conditions, they hybridized in situ only to the pericentromeric region of chromosome 4, but under nonstringent conditions they hybridized to all chromosomes containing the sequences of -satellite suprachromosomal family 2 (viz., chromosomes 2, 4, 8, 9, 13, 14, 15, 18, 20, 21 and 22). Southern blot analysis reveals the 3.2-kb higher-order repeated unit which exists in two forms: as a single MspI fragment or a combination of the 2.6-kb and 0.6-kb MspI fragments. The two chromosome-4-specific cloned sequences appear to be different parts of this repeated unit. Taken together they constitute about 60% of its length. The primary structure of the higher-order repeated unit is characterized by a dimeric periodicity of the D1-D2 type which is usual to suprachromosomal family 2. At least in one site this regularity is disrupted by monomer deletion leading to the D2-D2 monomeric order. The most likely mechanism of this monomer excision is homologous unequal crossing-over. These sequences may serve as both cytogenetic and restriction-fragment length polymorphism (RFLP) markers for the pericentromeric region of chromosome 4.     

Fusion of a free left Alu monomer and a free right Alu monomer at the origin of the Alu family in the primate genomes.

In the primate genome, a typical Alu element corresponds to a dimeric structure composed of two different but related monomeric sequences arranged in tandem. However, the analysis of primate sequences found in GenBank reveals the presence of free left and free right Alu elements. Here, we report the statistical study of those monomeric elements. We found that only a small fraction of them results from a deletion of a dimeric Alu sequence. The majority derives from the amplification of monomeric progenitor sequences and constitutes two families of monomeric elements: a family of free left Alu monomers that is composed of two subfamilies and a small family of free right Alu monomers. Both families predated the dimeric Alu elements, and a phylogenetic analysis strongly suggests that the first progenitor of the dimeric Alu family arose through the fusion of a free left monomer with a free right monomer.     

Toward a molecular paleontology of primate genomes

Families of related, but nonidentical repetitive DNA sequences, termed the alphoid DNAs, have been identified and characterized in representative species from seven major primate Families. The sequences appear as old as the primate Order itself: they are found in a prosimian (lemur), in a New World monkey, and in all Old World primates examined, including man. The alphoid DNAs are uniquely primate sequences and they may represent the most abundant repetitive DNAs in the primate genome. — A classification scheme for two major families of alphoid DNAs is proposed that is based upon restriction enzyme analysis and Southern blotting with radioactive probes prepared from component DNA (Maio, 1971) and from the human EcoRI dimer sequences (Manuelidis, 1976). The family of alphoid DNAs that hybridizes readily with component is termed the HindIII family of alphoid DNAs. This family shows an almost universal distribution among present-day primates. The family of DNA sequences that hybridizes readily with the human EcoRI dimer probe is termed the EcoRI dimer family of alphoid DNAs. This family may be restricted to the great apes and man. The two probes permitted the discrimination of different, but related alphoid families in present-day primates. Multiple alphoid sequence families are found within the genomes of individual primates and the major primate taxa can be characterized by the representations of the various alphoid DNAs within their genomes. — An Appendix is presented (Brown et al., 1981) indicating that competition hybridization effects may influence the autoradiographic banding patterns, and hence, the interpretations of Southern filter-transfer hybridizations when dealing with related repetitive sequences such as the alphoid DNAs that are present in abundance in eukaryotic genomes.     

Highly repetitive component α and related alphoid DNAs in man and monkeys

The genomes of Old-World, New-World, and prosimian primates contain members of a large class of highly repetitive DNAs that are related to one another and to component DNA of the African green monkey by their sequence homologies and restriction site periodicities. The members, of this class of highly repetitive DNAs are termed the alphoid DNAs, after the prototypical member, component of the African green monkey which was the first such DNA to be identified (Maio, 1971) and sequenced (Rosenberg et al., 1978). The alphoid DNAs appear to be uniquely primate sequences. — From the restriction enzyme cleavage patterns and Southern blot hybridizations under different stringency conditions, the alphoid DNAs comprise multiple sequence families exhibiting varying degrees of homology to component DNA. They also share common elements in their restriction site periodicities (172 · n base-pairs), in the long-range organization of their repeating units, and in their banding behavior in CsCl and Cs₂SO₄ buoyant density gradients, in which they band within the bulk DNA as cryptic repetitive components. — In the three species from the Family Cercopithecidae examined, the alphoid DNAs represent the most abundant, tandemly repetitive sequence components, comprising about 24% of the African green monkey genome and 8 to 10% of the Rhesus monkey and baboon genomes. In restriction digests, the bulk of the alphoid DNAs among the Cercopithecidae appeared quantitatively reduced to a simple series of arithmetic segments based on a 172 base-pair (bp) repeat. In contrast with these simple restriction patterns, complex patterns were observed when human alphoid DNAs were cleaved with restriction enzymes. Detailed analysis revealed that the human genome contains multiple alphoid sequence families which differ from one another both in their repeat sequence organization and in their degree of homology to the African green monkey component DNA. — The finding of alphoid sequences in other Old-World primate families, in a New-World monkey, and in a prosimian primate attests to the antiquity of these sequences in primate evolution and to the sequence conservatism of a large class of mammalian highly repetitive DNA. In addition, the relative conservatism exhibited by these sequences may distinguish the alphoid DNAs from more recently evolved highly repetitive components and satellite DNAs which have a more restricted taxonomical distribution.     

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.     

Structural analysis of alphoid DNA of primates. II. Evolution and possible origin of alphoid DNA of primates

A computer analysis of human and primate alphoid DNA was performed. The number and localization of short inverted complete repeats within alphoid DNA dimers (but not monomers) remain conserved. Thus, in spite of high heterogeneity of the primary structure the conserved secondary structure of alphoid DNA might be functionally important. The analysis of internal periodicity of the monomeric sequences of human and primate alphoid DNA revealed its potential ancient sequence, that is a simple satellite DNA with a reiterated heptanucleotide TGAAAAA, which is suggested to be the ancestor of satellite DNase of rodents. The facts reported propose the ancient origin and possible functional role of alphoid-like DNA as a universal pericentromeric superfamily of DNA.     

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.     

Pentameric ellagitannin oligomers in melastomataceous plants--chemotaxonomic significance

The pantropical plant family Melastomataceae produces characteristic hydrolyzable tannin oligomers. The latter in this family are distinguished from those in other plant families by the fact that the oligomers from dimers to tetramers are composed of two different alternating monomeric units: casuarictin and pterocaryanin C. These oligomers are metabolites that are produced by intermolecular C-O oxidative coupling between the monomers (or their desgalloyl-or des-hexahydroxydiphenoyl derivatives) forming a valoneoyl group as the link between monomers. The chemotaxonomically significant oligomerization pattern of melastomataceous plants provided helpful suggestions for determining the structures of new oligomers (nobotanins Q-T and melastoflorins A-D) isolated from Monochaetum multiflorum, which belongs to this family. Melastoflorins A-D were characterized as pentamers, which are the largest hydrolyzable tannins composed of different monomeric units.     

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.     

Chromosome-specific subsets of human alpha satellite DNA: Analysis of sequence divergence within and between chromosomal subsets and evidence for an ancestral pentameric repeat

Summary The centromeric regions of human chromosomes are characterized by diverged chromosome-specific subsets of a tandemly repeated DNA family, alpha satellite, which is based on a fundamental monomer repeat unit 171 bp in length. We have compared the nucleotide sequences of 44 alphoid monomers derived from cloned representatives of the multimeric higher-order repeat units of human chromosomes 1, 11, 17, and X. The 44 monomers exhibit an average 16% divergence from a consensus alphoid sequence, and can be assigned to five distinct homology groups based on patterns of sequence substitutions and gaps relative to the consensus. Approximately half of the overall sequence divergence can be accounted for by sequence changes specific to a particular homology group; the remaining divergence appears to be independent of the five groups and is randomly distributed, both within and between chromosomal subsets. The data are consistent with the proposal that the contemporary tandem arrays on chromosomes 1, 11, 17, and X derive from a common multimeric repeat, consisting of one monomer each from the five homology groups. The sequence comparisons suggest that this pentameric repeat must have spread to these four chromosomal locations many millions of years ago, since which time evolution of the four, now chromosome-specific, alpha satellite subsets has been essentially independent.     

Structural rearrangements and insertions of dispersed elements in pericentromeric alpha satellites occur preferably at kinkable DNA sites

Centromeric region of human chromosome 21 comprises two long alphoid DNA arrays: the well homogenized and CENP-B box-rich alpha21-I and the alpha21-II, containing a set of less homogenized and CENP-B box-poor subfamilies located closer to the short arm of the chromosome. Continuous alphoid fragment of 100 monomers bordering the non-satellite sequences in human chromosome 21 was mapped to the pericentromeric short arm region by fluorescence in situ hybridization (alpha21-II locus). The alphoid sequence contained several rearrangements including five large deletions within monomers and insertions of three truncated L1 elements. No binding sites for centromeric protein CENP-B were found. We analyzed sequences with alphoid/non-alphoid junctions selectively screened from current databases and revealed various rearrangements disrupting the regular tandem alphoid structure, namely, deletions, duplications, inversions, expansions of short oligonucleotide motifs and insertions of different dispersed elements. The detailed analysis of more than 1100 alphoid monomers from junction regions showed that the vast majority of structural alterations and joinings with non-alphoid DNAs occur in alpha satellite families lacking CENP-B boxes. Most analyzed events were found in sequences located toward the edges of the centromeric alphoid arrays. Different dispersed elements were inserted into alphoid DNA at kinkable dinucleotides (TG, CA or TA) situated between pyrimidine/purine tracks. DNA rearrangements resulting from different processes such as recombination and replication occur at kinkable DNA sites alike insertions but irrespectively of the occurrence of pyrimidine/purine tracks. It seems that kinkable dinucleotides TG, CA and TA are part of recognition signals for many proteins involved in recombination, replication, and insertional events. Alphoid DNA is a good model for studying these processes.     

Molecular structure and evolution of DNA sequences located at the alpha satellite boundary of chromosome 20

We have isolated and characterised one PAC clone (dJ233C1) containing a linkage between alphoid and non-alphoid DNA. The non-alphoid DNA was found to map at the pericentromeric region of chromosome 20, both on p and q sides, and to contain homologies with one contig (ctg176, Sanger Centre), also located in the same chromosome region. At variance with the chromosome specificity shown by the majority of non-alphoid DNA, a subset of alphoid repeats derived from the PAC yielded FISH hybridisation signals located at the centromeric region of several human chromosomes, belonging to three different suprachromosomal families. The evolutionary conservation of this boundary region was investigated by comparative FISH experiments on chromosomes from great apes. The non-alphoid DNA was found to have undergone events of expansion and transposition to different pericentromeric regions of great apes chromosomes. Alphoid sequences revealed a very wide distribution of FISH signals in the great apes. The pattern was substantially discordant with the data available in the literature, which is essentially derived from the central alphoid subset. These results add further support to the emerging opinion that the pericentromeric regions are high plastics, and that the alpha satellite junctions do not share the evolutionary history with the main subsets.     

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.