Analysis of alphoid DNA variation and kinetochore size in human chromosome 21: evidence against pathological significance of alphoid satellite DNA diminutions.

Centromeric alpha satellite DNA sequences are linked to the kinetochore CENP-B proteins and therefore may be involved in the centromeric function. The high heterogeneity of size of the alphoid blocks raises the question of whether small amount of alphoid DNA or "deletion" of this block may have a pathological significance in the human centromere. In the present study, we analysed the correlation between size variations of alphoid DNA and kinetochore sizes in human chromosome 21 by molecular cytogenetic and immunochemical techniques. FISH analyses of alpha satellite DNA sizes in chromosome 21 homologues correlated well with the variation of their physical size as determined by pulsed field gel electrophoresis (PFGE). By contrast, the immunostaining study of the same homologous chromosomes with antikinetochore antibodies suggested that there is no positive correlation between the alpha satellite DNA block and kinetochore sizes. FISH analysis of chromosome 21-specific alphoid DNA and immunostaining of kinetochore extended interphase chromatin fibers indicate that centromeric kinetochore-specific proteins bind to restricted areas of centromeric DNA arrays. Thus, probably, restricted regions of centromeric DNA play an important role in kinetochore formation, centromeric function and abnormal chromosome segregation leading to non-disjunction.     

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.     

Physical map of the centromeric region of human chromosome 7: relationship between two distinct alpha satellite arrays.

A long-range physical map of the centromeric region of human chromosome 7 has been constructed in order to define the region containing sequences with potential involvement in centromere function. The map is centered around alpha satellite DNA, a family of tandemly repeated DNA forming arrays of hundreds to thousands of kilobasepairs at the primary constriction of every human chromosome. Two distinct alpha satellite arrays (the loci D7Z1 and D7Z2) have previously been localized to chromosome 7. Detailed one- and two- locus maps of the chromosome 7 centromere have been constructed. Our data indicate that D7Z1 and D7Z2 arrays are not interspersed with each other but are both present on a common Mlu I restriction fragment estimated to be 3500 kb and 5500 kb on two different chromosome 7's investigated. These long-range maps, combined with previous measurements of the D7Z1 and D7Z2 array lengths, are used to construct a consensus map of the centromere of chromosome 7. The analysis used to construct the map provides, by extension, a framework for analysis of the structure of DNA in the centromeric regions of other human and mammalian chromosomes.     

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.     

Chromosome-specific organization of human alpha satellite DNA

Restriction endonuclease analysis of human genomic DNA has previously revealed several prominent repeated DNA families defined by regularly spaced enzyme recognition sites. One of these families, termed alpha satellite DNA, was originally identified as tandemly repeated 340- or 680-base pair (bp) EcoRI fragments that hybridize to the centromeric regions of human chromosomes. We have investigated the molecular organization of alpha satellite DNA on individual human chromosomes by filter hybridization and in situ hybridization analysis of human DNA and DNA from rodent/human somatic cell hybrids, each containing only a single human chromosome. We used as probes a cloned 340-bp EcoRI alpha satellite fragment and a cloned alpha satellite-containing 2.0-kilobase pair (kbp) BamHI fragment from the pericentromeric region of the human X chromosome. In each somatic cell hybrid DNA, the two probes hybridized to a distinct subset of DNA fragments detected in total human genomic DNA. Thus, alpha satellite DNA on each of the human chromosomes examined--the X and Y chromosomes and autosomes 3, 4, and 21--is organized in a specific and limited number of molecular domains. The data indicate that subsets of alpha satellite DNA on individual chromosomes differ from one another, both with respect to restriction enzyme periodicities and with respect to their degree of sequence relatedness. The results suggest that some, and perhaps many, human chromosomes are characterized by a specific organization of alpha satellite DNA at their centromeres and that, under appropriate experimental conditions, cloned representatives of alpha satellite subfamilies may serve as a new class of chromosome-specific DNA markers.     

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.     

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.     

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.     

A human alpha satellite DNA subset specific for chromosome 12.

We have isolated a DNA clone (pBR12, locus D12Z3) which identifies an alphoid subset specific for chromosome 12. This alphoid subset has an EcoRI periodicity of 680 bp and is characterized by a higher-order repeat of about 1.4 kb (eight basic units of about 170 bp each) as revealed by several restriction enzymes. The sequence analysis confirmed the alphoid nature of pBR12 and the dimeric organization.     

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.     

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.     

Structure of DNA near long tandem arrays of alpha satellite DNA at the centromere of human chromosome 7.

The centromeric regions of human chromosomes contain long tracts of tandemly repeated DNA, of which the most extensively characterized is alpha satellite. In a screen for additional centromeric DNA sequences, four phage clones were obtained which contain alpha satellite as well as other sequences not usually found associated with tandemly repeated alpha satellite DNA, including L1 repetitive elements, an Alu element, and a novel AT-rich repeated sequence. The alpha satellite DNA contained within these clones does not demonstrate the higher-order repeat structure typical of tandemly repeated alpha satellite. Two of the clones contain inversions; instead of the usual head-to-tail arrangement of alpha satellite monomers, the direction of the monomers changes partway through each clone. The presence of both inversions was confirmed in human genomic DNA by polymerase chain reaction amplification of the inverted regions. One phage clone contains a junction between alpha satellite DNA and a novel low-copy repeated sequence. The junction between the two types of DNA is abrupt and the junction sequence is characterized by the presence of runs of A's and T's, yielding an overall base composition of 65% AT with local areas > 80% AT. The AT-rich sequence is found in multiple copies on chromosome 7 and homologous sequences are found in (peri)centromeric locations on other human chromosomes, including chromosomes 1, 2, and 16. As such, the AT-rich sequence adjacent to alpha satellite DNA provides a tool for the further study of the DNA from this region of the chromosome. The phage clones examined are located within the same 3.3-Mb SstII restriction fragment on chromosome 7 as the two previously described alpha satellite arrays, D7Z1 and D7Z2. These new clones demonstrate that centromeric repetitive DNA, at least on chromosome 7, may be more heterogeneous in composition and organization than had previously been thought.     

A human chromosome 9-specific alphoid DNA repeat spatially resolvable from satellite 3 DNA by fluorescent in situ hybridization.

We have isolated a DNA clone (pMR9A) that identifies an alphoid DNA subset specific for chromosome 9. This alphoid subset is characterized by a dimeric organization as revealed by Southern blot analysis after digestion with HaeIII, HinfI, or StuI. Nonradioactive in situ hybridization demonstrated that pMR9A hybridizes only to the centromeric region of chromosome 9 and reveals chromosome 9 aneuploidies in interphase nuclei. In addition, the probe detects quantitative differences in alpha satellite DNA on chromosome 9, but these quantitative differences are not correlated with the size of the heterochromatic region. Double-labeling experiments, using a chromosome 9-specific satellite 3 clone and pMR9A, enabled us spatially to distinguish the alphoid and satellite 3 domains on metaphase chromosomes after treatment of the cultures with 5-azacytidine.     

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.     

Characterization of cloned human alphoid satellite with an unusual monomeric construction: evidence for enrichment in HeLa small polydisperse circular DNA.

A recombinant DNA plasmid library was constructed from HeLa cell extrachromosomal circular DNA and the sequence organization of one family of clones, which contain sequences enriched in HeLa small polydisperse circular (spc) DNA, was studied by restriction mapping and base sequence analysis. Restriction mapping revealed each clone to be composed solely of imperfect tandem repeats of ca. 170 bp. The entire DNA sequence of one clone was determined and found to be alphoid satellite with a variant monomeric construction.     

Sequence, higher order repeat structure, and long-range organization of alpha satellite DNA specific to human chromosome 8.

We have characterized alphoid repeat clones derived from a chromosome 8 library. These clones are specific for human chromosome 8, as demonstrated by use of a somatic cell hybrid mapping panel and by in situ hybridization. Hybridization of the clones to HindIII digests of human genomic DNA reveals a complex pattern of fragments ranging in size from 1.3 to greater than 20 kb. One clone, which corresponds in size to the most prevalent genomic HindIII fragment, appears to represent a major higher order repeat in the chromosome 8 centromere. The DNA sequence of this clone reveals a dimeric organization of alphoid monomers. Restriction analysis of two other clones indicates that they are derivatives of this same repeat unit. The chromosome 8 alphoid clones hybridize to EcoRI fragments of genomic DNA ranging up to 1000 kb in length and reveal a high degree of polymorphism between chromosomes. Distribution of higher order repeat units across the centromere was examined by two-dimensional gel electrophoresis. Repeat units of the same size class tended to cluster together in restricted regions of centromeric DNA.     

Chromosome-specific alpha satellite DNA from the centromere of human chromosome 16

To examine the molecular organization of DNA sequences located in the centromeric region of human chromosome 16 we have isolated and characterized a chromosome 16-specific member of the alpha satellite DNA family. The probe obtained is specific for the centromere of chromosome 16 by somatic cell hybrid analysis and by fluorescence in situ hybridization and allows detection of specific hybridizing domains in interphase nuclei. Nucleotide sequence analysis indicates that this class of chromosome 16 alpha satellite (D16Z2) is organized as a series of diverged 340-bp dimers arranged in a tandem array of 1.7-kb higher-order repeat units. As measured by pulsed-field gel electrophoresis, the total D16Z2 array spans approximately 1,400-2,000 kb of centromeric DNA. These sequences are highly polymorphic, both by conventional agarose-gel electrophoresis and by pulsed-field gel electrophoresis. Investigation of this family of alpha satellite should facilitate the further genomic, cytogenetic, and genetic analysis of chromosome 16.     

Thrombin-induced conformational changes of human alpha 2-macroglobulin: evidence for two functional domains

The interaction of thrombin with alpha 2-macroglobulin (alpha 2M) was characterized by monitoring conformational changes and measuring the increase of free sulfhydryl groups during the reaction. Under experimental conditions where [thrombin] greater than [alpha 2M], the conformational change, measured by increases in the fluorescence of 6-(p-toluidino)-2-naphthalenesulfonate, and thiol group appearance displayed biphasic kinetics. The initial rapid phase results in the formation of a stable complex, the appearance of two sulfhydryl groups, the cleavage of approximately half of the Mr 180 000 subunits, and a conformational change that is not as extensive as that which occurs with trypsin. The slower phase is associated with the appearance of two additional sulfhydryl groups, increased cleavage of the Mr 180 000 subunit, and additional conformational changes. The available evidence suggests that the slow phase results from hydrolysis of the Mr 180 000 subunit(s) due to proteolysis of the alpha 2M-thrombin complex by free thrombin. Experiments with 125I-thrombin document the binding of 1 mol of thrombin/mol of alpha 2M that is not dissociated upon sodium dodecyl sulfate-polyacrylamide gel electrophoresis of the complex. At higher ratios of thrombin to alpha 2M, a second mole of thrombin will reversibly associate with the 1:1 alpha 2M-thrombin complex. Under conditions where [thrombin] less than [alpha 2M], biphasic kinetics were not observed, and the conformational change, sulfhydryl appearance, and hydrolysis of the Mr 180 000 subunit were found to follow second-order kinetics.(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

Concerted evolution of primate alpha satellite DNA. Evidence for an ancestral sequence shared by gorilla and human X chromosome alpha satellite

To understand evolutionary events in the formation of higher-order repeat units in alpha satellite DNA, we have examined gorilla sequences homologous to human X chromosome alpha satellite. In humans, alpha satellite on the X chromosome is organized as a tandemly repeated, 2.0 x 10(3) base-pairs (bp) higher-order repeat unit, operationally defined by the restriction enzyme BamHI. Each higher-order repeat unit is composed of 12 tandem approximately 171 base-pair monomer units that have been classified into five distinct sequence homology groups. BamHI-digested gorilla genomic DNA hybridized with the cloned human 2 x 10(3) bp X alpha satellite repeat reveals three bands of sizes approximately 3.2 x 10(3), 2.7 x 10(3) and 2 x 10(3) bp. Multiple copies of all three repeat lengths have been isolated and mapped to the centromeric region of the gorilla X chromosome by fluorescence in situ hybridization. Long-range restriction mapping using pulsed-field gel electrophoresis shows that the 2.7 x 10(3) and 3.2 x 10(3) bp repeat arrays exist as separate but likely neighboring arrays on the gorilla X, each ranging in size from approximately 200 x 10(3) to 500 x 10(3) bp, considerably smaller than the approximately 2000 x 10(3) to 4000 x 10(3) bp array found on human X chromosomes. Nucleotide sequence analysis has revealed that monomers within all three gorilla repeat units can be classified into the same five sequence homology groups as monomers located within the higher-order repeat unit on the human X chromosome, suggesting that the formation of the five distinct monomer types predates the divergence of the lineages of contemporary humans and gorillas. The order of 12 monomers within the 2 x 10(3) and 2.7 x 10(3) bp repeat units from the gorilla X chromosome is identical with that of the 2 x 10(3) bp repeat unit from the human X chromosome, suggesting an ancestral linear arrangement and supporting hypotheses about events largely restricted to single chromosome types in the formation of alpha satellite higher-order repeat units.