Human gamma X satellite DNA: an X chromosome specific centromeric DNA sequence

The cosmid clone, CX16-2D12, was previously localized to the centromeric region of the human X chromosome and shown to lack human X-specific satellite DNA. A 1.2 kb EcoRI fragment was subcloned from the CX16-2D12 cosmid and was named 2D12/E2. DNA sequencing revealed that this 1,205 bp fragment consisted of approximately five tandemly repeated DNA monomers of 220 bp. DNA sequence homology between the monomers of 2D12/E2 ranged from 72.8% to 78.6%. Interestingly, DNA sequence analysis of the 2D12/E2 clone displayed a change in monomer unit orientation between nucleotide positions 585–586 from a tail-to-head arrangement to a head-to-tail configuration. This may reflect the existence of at least one inversion within this repetitive DNA array in the centromeric region of the human X chromosome. The DNA consensus sequence derived from a compilation of these 220 bp monomers had approximately 62% DNA sequence similarity to the previously determined 8 satellite DNA consensus sequence. Comparison of the 2D12/E2 and 8 consensus sequences revealed a 20 bp DNA sequence that was well conserved in both DNA consensus sequences. Slot-blot analysis revealed that this repetitive DNA sequence comprises approximately 0.015% of the human genome, similar to that found with 8 satellite DNA. These observations suggest that this satellite DNA clone is derived from a subfamily of satellite DNA and is thus designated X satellite DNA. When genomic DNA from six unrelated males and two unrelated females was cut with SstI or HpaI and separated by pulsed-field gel electrophoresis, no restriction fragment length polymorphisms were observed for either X (2D12/E2) or 8 (50E4) probes. Fluorescence in situ hybridization localized the 2D12/E2 clone to the lateral sides of the primary constriction specifically on the human X chromosome.     

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.     

Detection of novel centromeric polymorphisms associated with alpha satellite DNA from human chromosome 11

Summary The pericentromeric region of human chromosomes is composed of diverse classes of repetitive DNAs, which provide a rich source of genetic variability. Here, we describe two novel centromeric polymorphisms associated with a subset of alpha satellite repetitive DNA, D11Z1, which is specific for human chromosome 11. Segregation and inheritance of the polymorphisms are demonstrated and their relative frequencies are determined. These polymorphisms may be useful genetic tools for distinguishing between individual chromosome 11 centromeres. In addition, these polymorphisms may be applied to the development of a centromerebased genetic linkage map of chromosome 11. Molecular models for the generation of these polymorphisms are discussed.     

Localization and polymorphism of a chromosome 12-specific alpha satellite DNA sequence

The isolation and localization of a chromosome 12-specific alpha satellite DNA sequence, p alpha 12H8, is described. This clone contains a complete copy of the 1.4-kb HindIII higher-order repeat present within the alpha satellite array on chromosome 12. The specificity of p alpha 12H8 was demonstrated by in situ hybridization and Southern blot analysis of a somatic cell hybrid mapping panel, both performed under high-stringency conditions. Polymorphic restriction patterns within the alpha satellite array, revealed by the use of the restriction enzymes BglII and EcoRV, were demonstrated to display Mendelian inheritance. These properties make p alpha 12H8 a valuable genetic marker for the centromeric region of chromosome 12.     

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.     

Monosomy for the centromeric and juxtacentromeric region of chromosome 21

Summary A boy with partial monosomy 21 is described. The child has an unbalanced 20/21 translocation with deletion of the centromeric and juxtacentromeric region of chromosome 21. Examination by C-banding technique shows that the translocation is of maternal origin. Investigation of a number of genetic marker systems shows that the HL-A, AcP, and GPT loci are not located in the deleted segment.

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Zusammenfassung Es wird ein Junge mit partieller Monosomie Nr. 21 beschrieben. Das Kind hat eine unbalancierte 20/21-Translokation mit einer Deletion der Zentromer-und Juxtazentromer-Region des Chromosomes Nr. 21. Untersuchung mit der C-Band-Technik zeigt, daß die Translokation mütterlichen Ursprungs ist. Untersuchung einer Reihe genetischer Markersysteme zeigt, daß die HL-A-, AcP- und GPT-Loci nicht in dem deletierten Segment liegen.

     

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.     

A polymorphic alpha satellite sequence specific for human chromosome 13 detected by oligonucleotide primed in situ labelling (PRINS)

The centromeric alpha satellite DNA subfamilies from chromosomes 13 and 21 are almost identical in sequence and cannot be easily distinguished by mean of probes for Southern blot or in situ hybridisation. We have used the oligonucleotide-primed in situ (PRINS) labelling technique with primers defined from the alpha satellite sequence of chromosome 13. One primer was found to label specifically the centromeric region of chromosomes 13 and allowed the detection of a polymorphism between two chromosome 13 homologues in one individual.     

Chromosome-specific alpha satellite DNA from human chromosome 1: hierarchical structure and genomic organization of a polymorphic domain spanning several hundred kilobase pairs of centromeric DNA

The human alpha satellite repetitive DNA family is organized as distinct chromosome-specific subsets localized to the centromeric region of each chromosome. Here, we report he isolation and characterization of cloned repeat units which define a hierarchical subset of alpha satellite on human chromosome 1. This subset is characterized by a 1.9-kb higher-order repeat unit which consists of 11 tandem approximately 171-bp alpha satellite monomer repeat units. The higher-order repeat unit is itself tandemly repeated, present in at least 100 copies at the centromeric region of chromosome 1. Using pulsed-field gel electrophoresis we estimate the total array length of these tandem sequences at the centromere of chromosome 1 to be several hundred kilobase pairs. Under conditions of high stringency, the higher-order repeat probe hybridizes specifically to chromosome 1 and can be used to detect several associated restriction fragment length DNA polymorphisms. As such, this probe may be useful for molecular and genetic analyses of the centromeric region of human chromosome 1.     

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.     

High frequency DNA rearrangements associated with mouse centromeric satellite DNA

A DNA transformed mouse cell line, generated by the microinjection of a pBR322 plasmid containing the herpes thymidine kinase (tk) gene, was observed to exhibit a high frequency of DNA rearrangement at the site of exogenous DNA integration. The instability in this cell line does not appear to be mediated by the tk inserts or the immediately adjacent mouse DNA, but instead may be a consequence of the larger host environment at the chromosomal site of tk insertion. Results obtained from restriction analysis, in situ chromosome hybridizations, and cesium chloride density-gradient fractionations indicate that the tk inserts are organized as a single cluster of direct and inverted repeats embedded within pericentromeric satellite DNA. To determine the molecular identity of the flanking host sequences, one of the mouse-tk junction fragments was cloned, and subsequent restriction and sequence analyses revealed that this DNA fragment consists almost entirely of classical mouse satellite DNA. On the basis of these observations, we suggest that the instability in this cell line may reflect the endogenous instability or fluidity of satellite DNA.     

A novel primary immunodeficiency with specific natural-killer cell deficiency maps to the centromeric region of chromosome 8

We describe four children with a novel primary immunodeficiency consisting of specific natural-killer (NK) cell deficiency and susceptibility to viral diseases. One child developed an Epstein-Barr virus-driven lymphoproliferative disorder; two others developed severe respiratory illnesses of probable viral etiology. The four patients are related and belong to a large inbred kindred of Irish nomadic descent, which suggests autosomal recessive inheritance of this defect. A genomewide scan identified a single 12-Mb region on chromosome 8p11.23-q11.21 that was linked to this immunodeficiency (maximum LOD score 4.51). The mapping of the disease-causing genomic region paves the way for the identification of a novel pathway governing NK cell differentiation in humans.     

Composition and structure of the centromeric region of rice chromosome 8

Understanding the organization of eukaryotic centromeres has both fundamental and applied importance because of their roles in chromosome segregation, karyotypic stability, and artificial chromosome-based cloning and expression vectors. Using clone-by-clone sequencing methodology, we obtained the complete genomic sequence of the centromeric region of rice (Oryza sativa) chromosome 8. Analysis of 1.97 Mb of contiguous nucleotide sequence revealed three large clusters of CentO satellite repeats (68.5 kb of 155-bp repeats) and >220 transposable element (TE)-related sequences; together, these account for approximately 60% of this centromeric region. The 155-bp repeats were tandemly arrayed head to tail within the clusters, which had different orientations and were interrupted by TE-related sequences. The individual 155-bp CentO satellite repeats showed frequent transitions and transversions at eight nucleotide positions. The 40 TE elements with highly conserved sequences were mostly gypsy-type retrotransposons. Furthermore, 48 genes, showing high BLAST homology to known proteins or to rice full-length cDNAs, were predicted within the region; some were close to the CentO clusters. We then performed a genome-wide survey of the sequences and organization of CentO and RIRE7 families. Our study provides the complete sequence of a centromeric region from either plants or animals and likely will provide insight into the evolutionary and functional analysis of plant centromeres.     

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.     

Extensive sequence polymorphisms associated with chromosome 10 alpha satellite DNA and its close linkage to markers from the pericentromeric region

Summary Extensive sequence polymorphisms exist in the chromosome 10 alpha satellite DNA (the D10Z1 locus). Polymorphic morphs revealed by the enzymes PstI, EcoRV, and HincII, can be unambiguously scored and make this centromeric region an excellent genetic marker for the study of multiple endocrine neoplasia, type 2A (MEN2A), as well as for chromosome 10 linkage studies in general. Strong positive lod scores and linkage distance relationships between D10Z1 and DNA markers from the chromosome 10 pericentromeric region, especially FNRB and RBP3, known to be on either side of the centromere, provide independent support for mapping of all these loci.