Distribution of gamma satellite DNA on the human X and Y chromosomes suggests that it is not required for mitotic centromere function

The bulk of the DNA found at human centromeres is composed of tandemly arranged repeats, the most abundant of which is alpha satellite. Other human centromeric repetitive families have been identified, one of the more recent being gamma satellite. To date, gamma satellite DNAs have been reported at the centromeres of human chromosomes 8 and X. Here, we show that gamma-X satellite DNA is not interspersed with the major DZX1 alpha-X block, but rather is organised as a single array of approximately 40-50 kb on the short-arm side of the alpha satellite domain. This repeat array is absent on two mitotically stable Xq isochromosomes. Furthermore, a related repeat DNA has been identified on the human Y chromosome. Fluorescence in situ hybridisation has localised this satellite DNA to the long arm side of the major DYZ3 alpha-Y domain, outside the region previously defined as that required for mitotic centromere function. Together, these data suggest that while blocks of highly related gamma satellite DNAs are present in the pericentromeric regions of both human sex chromosomes, this repeated DNA is not required for mitotic centromere function.     

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.     

A physical map of the chromosome 12 centromere

While current sequencing efforts consider the detection of alpha satellite repeats as logical end points for map construction, detailed maps of most pericentromeric regions are lacking to confirm this hypothesis. Here we identify the different alpha satellite families present at the pericentromeric region of chromosome 12. The order, size and location of these repeats is established using radiation hybrid analysis, pulsed field gel analysis and FISH and the maps are integrated with current sequence information. For the different classes of alpha satellites present at the chromosome 12 centromere the paralogs in the human genome were mapped by FISH. Unique sequences flanking the alpha satellite repeats were identified, some of which are not represented in the current draft sequence. This mapping effort localises the different alpha satellite repeats within the pericentromeric region and anchors them in the current maps. The novel sequences identified may serve as the end point for the ongoing sequencing efforts.     

A primary genetic map of the pericentromeric region of the human X chromosome

We report a genetic linkage map of the pericentromeric region of the human X chromosome, extending from Xp11 to Xq13. Genetic analysis with five polymorphic markers, including centromeric alpha satellite DNA, spanned a distance of approximately 38 cM. Significant lod scores were obtained with linkage analysis in 26 families from the Centre d'Etude du Polymorphisme Humain, establishing estimates of genetic distances between these markers and across the centromere. Physical mapping experiments, using a panel of somatic cell hybrids segregating portions of the X chromosome due to translocations or deletions, are in agreement with the multilocus linkage analysis and indicate the order Xp11 . . . DXS7(L1.28)-TIMP- DXZ1(alpha satellite, cen)- DXS159(cpX73)-PGK1 . . . Xq13. The frequency of recombination in the two approximately 20-cM intervals flanking alpha satellite on either chromosome arm was roughly proportional to the estimated physical distance between markers; no evidence for a reduced crossover frequency was found in the intervals adjacent to the centromere. However, significant interfamilial variations in recombination rates were noted in this region. This primary map should be useful both as a foundation for a higher resolution centromere-based linkage map of the X chromosome and in the localization of genes to the pericentromeric region.     

Robertsonian metacentrics of the house mouse lose telomeric sequences but retain some minor satellite DNA in the pericentromeric area

A combination of cytogenetic and molecular biology techniques were used to study the molecular composition and organisation of the pericentromeric regions of house mouse metacentric chromosomes, the products of Robertsonian (Rb) translocations between telocentrics. Regardless of whether mitotic or meiotic preparations were used, in situ hybridisation failed to reveal pericentromeric telomeric sequences on any of the Rb chromosomes, while all metacentrics retained detectable, although reduced (average 50 kb), amounts of minor satellite DNA in the vicinity of their centromeres. These results were supported by slot blot hybridisation which indicated that mice with 2n=22 Rb chromosomes have 65% of telomeric sequences (which are allocated to the distal telomeres of both Rb and telocentric chromosomes and to the proximal telomeres of telocentrics) and 15% the amount of minor satellite, compared with mice with 2n=40 all-telocentric chromosomes. Pulsed field gel electrophoresis and Southern analysis of DNA from Rb mice showed that the size of the telomeric arrays is similar to that of mice with all-telocentric chromosomes and that the minor satellite sequences were hybridising to larger fragments incorporating major satellite DNA. Since the telomeric sequences are closer to the physical end of the chromosome than the minor satellite sequences, the absence of telomeric sequences and the reduced amount of minor satellite sequences at the pericentromeric region of the Rb metacentrics suggest that the breakpoints for the Rb translocation occur very close to the minor satellite-major satellite border. Moreover, it is likely that the minor satellite is required for centromeric function, 50–67 kb being enough DNA to organise one centromere with a functionally active kinetochore.     

Analysis of the centromeric regions of the human genome assembly

The sequence of the human genome is not yet complete, and major gaps remain at the centromere region of each chromosome, which is comprised of repetitive alpha satellite DNA. In this article, we describe the sequences in the vicinity of the centromere that are included in the current genome assembly, analyze the approximately 7Mb of alpha satellite that have been assembled thus far and anticipate the nature of the sequences that remain to be accounted for.     

Mechanisms and consequences of small supernumerary marker chromosomes: from Barbara McClintock to modern genetic-counseling issues

Supernumerary marker chromosomes (SMCs) are common, but their molecular content and mechanism of origin are often not precisely characterized. We analyzed all centromere regions to identify the junction between the unique chromosome arm and the pericentromeric repeats. A molecular-ruler clone panel for each chromosome arm was developed and used for the design of a custom oligonucleotide array. Of 27 nonsatellited SMCs analyzed by array comparative genomic hybridization (aCGH) and/or fluorescence in situ hybridization (FISH), seven (approximately 26%) were shown to be unique sequence negative. Of the 20 unique-sequence-positive SMCs, the average unique DNA content was approximately 6.5 Mb (range 0.3-22.2 Mb) and 33 known genes (range 0-149). Of the 14 informative nonacrocentric SMCs, five (approximately 36%) contained unique DNA from both the p and q arms, whereas nine (approximately 64%) contained unique DNA from only one arm. The latter cases are consistent with ring-chromosome formation by centromere misdivision, as first described by McClintock in maize. In one case, a r(4) containing approximately 4.4 Mb of unique DNA from 4p was also present in the proband's mother. However, FISH revealed a cryptic deletion in one chromosome 4 and reduced alpha satellite in the del(4) and r(4), indicating that the mother was a balanced ring and deletion carrier. Our data, and recent reports in the literature, suggest that this "McClintock mechanism" of small-ring formation might be the predominant mechanism of origin. Comprehensive analysis of SMCs by aCGH and FISH can distinguish unique-negative from unique-positive cases, determine the precise gene content, and provide information on mechanism of origin, inheritance, and recurrence risk.     

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.     

Two extended arrays of a satellite DNA sequence at the centromere and at the short-arm telomere of Chinese hamster chromosome 5

We have cloned a Chinese hamster chromosome-specific repeated sequence (SatCH5). This satellite is composed of a 33-bp unit organized in two extended tandem arrays. It is localized at the centromere and at the short-arm subtelomere of chromosome 5. Altogether, SatCH5 covers about 1-2 Mb per diploid genome and is not present in other species, including the Syrian hamster and mouse. Since it is known in the Chinese hamster and numerous other vertebrate species that telomeric (TTAGGG)n repeats are localized at the centromeres of several chromosomes, we studied the localization of SatCH5 relative to (TTAGGG)n sequences. Using two-color fluorescence in situ hybridization on stretched chromosomes and on DNA fibers, we have shown that at the centromere of chromosome 5 SatCH5 and the (TTAGGG)n arrays are contiguous. SatCH5 is the first chromosome-specific repetitive sequence located at both the pericentromeric and subtelomeric regions of the same chromosome.     

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.     

Chromosome-specific alpha satellite DNA: nucleotide sequence analysis of the 2.0 kilobasepair repeat from the human X chromosome.

The pericentromeric region of the human X chromosome is characterized by a tandemly repeated family of 2.0 kilobasepair (kb) DNA fragments, initially revealed by cleavage of human DNA with the restriction enzyme BamHI. We report here the complete nucleotide sequence of a cloned member of the repeat family and establish that this X-linked DNA family consists entirely of alpha satellite DNA. Our data indicate that the 2.0 kb repeat consists of twelve alpha satellite monomers arranged in imperfect, direct repeats. Each of the alpha X monomers is approximately 171 basepairs (bp) in length and is 60-75% identical in sequence to previously described primate alpha satellite DNAs. The twelve alpha X monomers are 65-85% identical in sequence to each other and are organized as two adjacent, related blocks of five monomers, plus an additional two monomers also related to monomers within the pentamer blocks. Partial nucleotide sequence of a second, independent copy of the 2.0 kb BamHI fragment established that the 2.0 kb repeat is, in fact, the unit of amplification on the X. Comparison of the sequences of the twelve alpha X monomers allowed derivation of a 171 bp consensus sequence for alpha satellite DNA on the human X chromosome. These sequence data, combined with the results of filter hybridization experiments of total human DNA and X chromosome DNA, using subregions within the 2.0 kb repeat as probes, provide strong support for the hypothesis that individual human chromosomes are characterized by different alpha satellite families, defined both by restriction enzyme periodicity and by chromosome-specific primary sequence.     

High-resolution organization of mouse centromeric and pericentromeric DNA

We studied the organization of mouse satellite 3 and 4 (MS3 and MS4) in comparison with major (MaSat) and minor (MiSat) DNA sequences, located in the centromeric and pericentromeric regions of mouse telocentric chromosomes by fiber-FISH. The centromeric region consists of a small block of MiSat and MS3 followed by a pericentromeric block of MaSat with MS4. Inside the block of the long-range cluster, MaSat repeats intermingle mostly with MS4, while MiSat intermingle with MS3. The distribution of GC-rich satellite DNA fragments is less strict than that of AT-rich fragments; it is possible to find MS3 fragments in the MaSat array and MS4 fragments in the MiSat array. The methylation pattern does not fully correspond to one of the four families of satellite DNA (satDNA). In each satDNA fragment only part of the DNA is methylated. MS3 and MS4 are heavily methylated being GC-rich. Pericentomeric satellite DNA fragments are more methylated than centromeric ones. Among the four families of satDNA MS4 is the most methylated while MiSat is methylated only to a minimal extent. Estimation of the average fragment length and average distance between fragments shows that the range of the probes used does not cover the whole centromeric region. The existence of unknown sequences in the mouse centromere is likely.     

Mouse minor satellite DNA genetically maps to the centromere and is physically linked to the proximal telomere.

As an adjunct to attempts to define functionally important sequences at human centromeres, we have undertaken a long-range physical analysis of these regions in the mouse. Mouse centromeres are usually situated very close to the chromosome ends and are closely associated with minor satellite sequences on the basis of cytological observations. Using pulsed-field gel electrophoresis we find that this satellite DNA is arranged as tandem arrays, predominantly uninterrupted by nonsatellite sequences. These arrays can be released largely intact by digestion with a range of enzymes that generally cleave frequently in non-satellite DNA. The restriction fragments carrying these arrays are polymorphic in size between inbred strains and provide direct markers for mouse centromeres. To illustrate the possible use of these polymorphic markers we have mapped a 1.3-Mb PvuII variant in a set of RI strains to the centromere of Chromosome 7. The minor satellite arrays are very close to the centromeric telomere and physical linkage with terminal repeat sequences can readily be detected, placing many minor satellite arrays on terminal restriction fragments smaller than 1 Mb. The apparent lack of any sizable amount of nonsatellite DNA between the minor satellite and the terminal repeat arrays indicates that many mouse chromosomes are truly telocentric.     

Direct visualization of the genomic distribution and organization of two cervid centromeric satellite DNA families

Several repetitive DNA fragments were generated from PCR amplifications of caribou DNA using primer sequences derived from the white-tailed deer satellite II DNA clone OvDII. Two fragments, designated Rt-0.5 and Rt-0.7, were sequenced and found to have 96% sequence similarity. These caribou clones also had 85% sequence similarity with OvDII. Multiple-colored fluorescence in situ hybridization (FISH) studies with satellite I and satellite II DNA probes to caribou metaphase chromosomes and extended chromatin fibers provided direct visualization of the genomic organization of these two satellite DNA families, with the following findings: (1) Cervid satellite I DNA is confined to the centromeric regions of the acrocentric autosomes, whereas satellite II DNA is found at the centromeric regions of all chromosomes except for the Y. (2) For most acrocentric chromosomes, the satellite I signal appeared to be medially located at the primary constriction, in contrast to that of satellite II, which appeared to be oriented toward the lateral sides as two separate fluorescent dots. (3) The satellite II clone Rt-0.7 appeared to be enriched in the centromeric region of the caribou X chromosome, a pair of biarmed autosomes, and a number of other acrocentric autosomes. (4) Fiber-FISH demonstrated that the satellite I and satellite II arrays were juxtaposed. On highly extended chromatin fibers, the total length of the hybridization signals for the two satellite DNA arrays often reached 300-400 microm. The length of a given satellite II array usually reached 200 microm, corresponding to 2 x 10(3) kb of DNA in a given centromere.     

Formation of novel CENP-A domains on tandem repetitive DNA and across chromosome breakpoints on human chromosome 8q21 neocentromeres

Endogenous human centromeres form on megabase-sized arrays of tandemly repeated alpha satellite DNA. Human neocentromeres form epigenetically at ectopic sites devoid of alpha satellite DNA and permit analysis of centromeric DNA and chromatin organization. In this study, we present molecular cytogenetic and CENP-A chromatin immunoprecipitation (ChIP) on CHIP analyses of two neocentromeres that have formed in chromosome band 8q21 each with a unique DNA and CENP-A chromatin configuration. The first neocentromere was found on a neodicentric chromosome 8 with an inactivated endogenous centromere, where the centromeric activity and CENP-A domain were repositioned to band 8q21 on a large tandemly repeated DNA. This is the first example of a neocentromere forming on repetitive DNA, as all other mapped neocentromeres have formed on single copy DNA. Quantitative fluorescent in situ hybridization (FISH) analysis showed a 60% reduction in the alpha satellite array size at the inactive centromere compared to the active centromere on the normal chromosome 8. This neodicentric chromosome may provide insight into centromere inactivation and the role of tandem DNA in centromere structure. The second neocentromere was found on a neocentric ring chromosome that contained the 8q21 tandemly repeated DNA, although the neocentromere was localized to a different genomic region. Interestingly, this neocentromere is composed of two distinct CENP-A domains in bands 8q21 and 8q24, which are brought into closer proximity on the ring chromosome. This neocentromere suggests that chromosomal rearrangement and DNA breakage may be involved in neocentromere formation. These novel examples provide insight into the formation and structure of human neocentromeres.     

Distribution of XhoI and EcoRI family repetitive DNA sequences into separate domains in the chicken W chromosome

Fluorescence in situ hybridization using as probes three biotinylated or digoxigenin-labeled chicken W chromosome-specific repeating DNA units (0.7 and 1.1 kb XhoI family and 1.2 kb EcoRI family units) suggested that a large fraction of one arm of the W chromosome was occupied by the EcoRI family sequences and that pericentromeric regions were widely occupied by the XhoI family sequences. A minor fraction of the EcoRI family was also present in a narrow region in the proximal half of the other arm. There was a region in the distal half of the latter arm where sequences from neither family hybridized. Evolutionary aspects of the presence of different domains occupied by different repetitive families and the significance of the unhybridized distal region are discussed.by H.C. Macgregor     

The genetic defect in multiple endocrine neoplasia type 2A maps next to the centromere of chromosome 10

Multiple endocrine neoplasia type 2A (MEN2A) is a rare cancer syndrome that is inherited in an apparently autosomal dominant fashion. Previous linkage studies had assigned the MEN2A locus to chromosome 10 in the pericentromeric region. We recently have described several new easily scorable RFLPs for the chromosome 10-specific alpha satellite DNA (the D10Z1) locus that is known, on the basis of previous in situ hybridization experiments, to lie at the centromere. We report here tight linkage between MEN2A and D10Z1, as demonstrated by a maximum lod score of 12.02 at the recombination frequency of zero (1-lod-unit support interval 0-4 cM), indicating that the genetic defect in MEN2A lies in the immediate vicinity of the centromere. By means of a set of ordered polymorphic DNA markers from the pericentromeric region, multipoint as well as pairwise linkage analyses place the MEN2A locus at the middle of a small region (approximately 11 cM) bracketing the centromere with FNRB (at 10p11.2) and RBP3 (at 10q11.2) on either side, providing further support for the centromeric location of the MEN2A locus. Marked sex difference in recombination frequencies exists in this pericentromeric region: significantly (P less than .01) more female than male crossovers were observed across all of the adjacent intervals D10S24-FNRB, FNRB-D10Z1, and D10Z1-RBP3. However, a sex difference was not seen in the 7-cM interval from RBP3 to D10S5, suggesting that large variation in the sex difference in recombination can occur over small chromosomal regions.(ABSTRACT TRUNCATED AT 250 WORDS)     

Absence of satellite III DNA in the centromere and the proximal long-arm region of human chromosome 14: analysis of a 14p- variant.

Cytogenetic methods and molecular probes derived from the centromere and short arm of chromosome 14 were used to investigate the structural properties of a chromosome 14 variant. Results of GTL, CBG, Ag-NOR, and non-banded Giemsa staining of the chromosomes suggested the complete absence of the short arm and possibly a large part of the centromere. Negative in situ hybridisation with an alpha satellite III probe confirmed the absence of the arm; the detection of normal amounts of alpha satellite DNA, however, indicated retention of the centromeric domain. The natural occurrence of a human acrocentric variant lacking a short arm was thus established. Within the detection limits of the methods used, the results demonstrate that satellite III DNA is not essential for normal centromeric activity and allow us to exclude the presence of this satellite DNA within the centromere and proximal long-arm region of human chromosome 14.     

Genetic and physical analyses of the centromeric and pericentromeric regions of human chromosome 5: recombination across 5cen

Human centromeres are poorly understood at both the genetic and the physical level. In this paper, we have been able to distinguish the alphoid centromeric sequences of chromosome 5 from those of chromosome 19. This result was obtained by pulsed-field gel electrophoresis after cutting genomic DNA with restriction endonucleases NcoI (chromosome 5) and BamHI (chromosome 19). We could thus define a highly polymorphic marker, representing length variations of the D5Z1 domain located at the q arm boundary of the chromosome 5 centromere. The centromeric region of chromosome 5 was then analyzed in full detail. We established an approximately 4.6-Mb physical map of the whole region with five rare-cutting enzymes by using nonchimeric YACs, two of which were shown to contain the very ends of 5cen on both sides. The p-arm side of 5cen was shown to contain an alphoid subset (D5Z12) different from those described thus far. Two genes and several putative cDNAs could be precisely located close to the centromere. Several L1 elements were shown to be present within alpha satellites at the boundary between alphoid and nonalphoid sequences on both sides of 5cen. They were used to define STSs that could serve as physical anchor points at the junction of 5cen with the p and q arms. Some STSs were placed on a radiation hybrid map. One was polymorphic and could therefore be used as a second centromeric genetic marker at the p arm boundary of 5cen. We could thus estimate recombination rates within and around the centromeric region of chromosome 5. Recombination is highly reduced within 5cen, with zero recombinants in 58 meioses being detected between the two markers located at the two extremities of the centromere. In its immediate vicinity, 5cen indeed exerts a direct negative effect on meiotic recombination within the proximal chromosomal DNA. This effect is, however, less important than expected and is polarized, as different rates are observed on both arms if one compares the 0 cM/Mb of the p proximal first 5.5 Mb and the 0.64 cM/Mb of the q proximal first 5 Mb to the sex-average 1.02 cM/Mb found throughout the entire chromosome 5. Rates then become close to the average when one goes further within the arms. Finally, most recombinants (21/22), irrespective of the arm, are of female origin, thus showing that recombination around 5cen is essentially occurring in the female lineage.     

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.