Arrays Of Alpha Satellite DNA Research Articles

Human Centromeres Produce Chromosome-Specific and Array-Specific Alpha Satellite Transcripts that Are Complexed with CENP-A and CENP-C

Human centromeres are defined by alpha satellite DNA arrays that are distinct and chromosome specific. Most human chromosomes contain multiple alpha satellite arrays that are competent for centromere assembly. Here, we show that human centromeres are defined by chromosome-specific RNAs linked to underlying organization of distinct alpha satellite arrays. Active and inactive arrays on the same chromosome produce discrete sets of transcripts in cis. Non-coding RNAs produced from active arrays are complexed with CENP-A and CENP-C, while inactive-array transcripts associate with CENP-B and are generally less stable. Loss of CENP-A does not affect transcript abundance or stability. However, depletion of array-specific RNAs reduces CENP-A and CENP-C at the targeted centromere via faulty CENP-A loading, arresting cells before mitosis. This work shows that each human alpha satellite array produces a unique set of non-coding transcripts, and RNAs present at active centromeres are necessary for kinetochore assembly and cell-cycle progression.

Abstract 3471: Replication of megabase-size alpha-satellite DNA arrays in human centromere

Abstract Alphoid centromere array is composed by 171 bp AT rich alphoid monomer that tandemly arranged into high order repeat unit up to 4 MB array. Hallmark of centromeric DNA is CENPB box, a 17 bp motif that is a binding site of CENPB. As the chromosomal site that regulates the precise and accurate chromosome segregation, understanding DNA replication in centromere will reveal insight into faithful chromosome segregation that potentially influence cellular behavior in normal and cancer cell. The present of active replicons within alphoid centromere array are detected by enrichment of nsDNA abundance. This finding is supported by evident of Orc2, Cdt1 and Treslin accumulation on the alphoid centromere array. Chromatin fiber analysis revealed that inter origin distance within alphoid centromere array is irregular. CENPB depletion that is affected centromeric chromatin structure enhances DNA replication activity within alphoid centromeric array, indicates centromeric chromatin landscape alteration affected centromeric DNA replication dynamic. Citation Format: Indri Erliandri. Replication of megabase-size alpha-satellite DNA arrays in human centromere [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2017; 2017 Apr 1-5; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2017;77(13 Suppl):Abstract nr 3471. doi:10.1158/1538-7445.AM2017-3471

Replication of alpha-satellite DNA arrays in endogenous human centromeric regions and in human artificial chromosome.

In human chromosomes, centromeric regions comprise megabase-size arrays of 171 bp alpha-satellite DNA monomers. The large distances spanned by these arrays preclude their replication from external sites and imply that the repetitive monomers contain replication origins. However, replication within these arrays has not previously been profiled and the role of alpha-satellite DNA in initiation of DNA replication has not yet been demonstrated. Here, replication of alpha-satellite DNA in endogenous human centromeric regions and in de novo formed Human Artificial Chromosome (HAC) was analyzed. We showed that alpha-satellite monomers could function as origins of DNA replication and that replication of alphoid arrays organized into centrochromatin occurred earlier than those organized into heterochromatin. The distribution of inter-origin distances within centromeric alphoid arrays was comparable to the distribution of inter-origin distances on randomly selected non-centromeric chromosomal regions. Depletion of CENP-B, a kinetochore protein that binds directly to a 17 bp CENP-B box motif common to alpha-satellite DNA, resulted in enrichment of alpha-satellite sequences for proteins of the ORC complex, suggesting that CENP-B may have a role in regulating the replication of centromeric regions. Mapping of replication initiation sites in the HAC revealed that replication preferentially initiated in transcriptionally active regions.

The Past, Present, and Future of Human Centromere Genomics

The centromere is the chromosomal locus essential for chromosome inheritance and genome stability. Human centromeres are located at repetitive alpha satellite DNA arrays that compose approximately 5% of the genome. Contiguous alpha satellite DNA sequence is absent from the assembled reference genome, limiting current understanding of centromere organization and function. Here, we review the progress in centromere genomics spanning the discovery of the sequence to its molecular characterization and the work done during the Human Genome Project era to elucidate alpha satellite structure and sequence variation. We discuss exciting recent advances in alpha satellite sequence assembly that have provided important insight into the abundance and complex organization of this sequence on human chromosomes. In light of these new findings, we offer perspectives for future studies of human centromere assembly and function.

Abstract 577: DNA replication origin of human alphoid centromere regions .

Abstract The human centromere DNA consist of 171 bp AT-rich-alpha satellite DNA that tandemly arranged into higher order repeat units that is diverged at each centromere, extend from 200kb to 4MB. As the chromosomal site that regulates accurate chromosome segregation, maintaining the correct and coordinated DNA replication prior to cell division is critical. This process should ensure that whole genetic information transferred to daughter cell faithfully. Irregularities on replication process are leading to the mitosis defect and apoptosis. Flanking regions of alpha-satellite DNA arrays are organized in heterochromatin domains that are co-localized with other types of centromeric repeats, i.e. satellite II and gamma-satellite DNA. Previous studies indicate that centromeric DNA replicates in the middle to late S-phase. However little is known what determines activities and positions of replicators on chromatin domains. In this work, we addressed the mechanism of replication on the centromere and other repeat sequences on pericentromeric regions using two different approaches: i) origin mapping using nascent-strand DNA and ii) DNA-protein interaction using chromatin-immunoprecipitation (ChIP) assay. Our results detect active origin of replication within alpha-satellite DNA monomers of centromere, as well as on gamma-satellite repeats. In contrast, satellite II repeats representing centromere-adjacent heterochromatin do not exhibit a significant activity as origin of replication. The accumulation of modified-Histone proteins indicated dynamic activity of DNA arrays. Moreover, DNA replication proteins are formed complex with centromere proteins, presented direct evident on DNA replication activity on centromere. In summary, data indicated position of replicator within alphoid centromere and other large tandem repeat arrays on pericentromeric region with condense chromatin structure, thus suggested role of epigenetic modifications on DNA arrays propagation. Citation Format: Indri Erliandri, Haiqing Fu, Jung-Hyun Kim, Mirit Aladjem, William Earnshaw, Ramaiah Nagaraja, David Schlessinger, Vladimir Larionov. DNA replication origin of human alphoid centromere regions . [abstract]. In: Proceedings of the 104th Annual Meeting of the American Association for Cancer Research; 2013 Apr 6-10; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2013;73(8 Suppl):Abstract nr 577. doi:10.1158/1538-7445.AM2013-577

Functional epialleles at an endogenous human centromere

Human centromeres are defined by megabases of homogenous alpha-satellite DNA arrays that are packaged into specialized chromatin marked by the centromeric histone variant, centromeric protein A (CENP-A). Although most human chromosomes have a single higher-order repeat (HOR) array of alpha satellites, several chromosomes have more than one HOR array. Homo sapiens chromosome 17 (HSA17) has two juxtaposed HOR arrays, D17Z1 and D17Z1-B. Only D17Z1 has been linked to CENP-A chromatin assembly. Here, we use human artificial chromosome assembly assays to show that both D17Z1 and D17Z1-B can support de novo centromere assembly independently. We extend these in vitro studies and demonstrate, using immunostaining and chromatin analyses, that in human cells the centromere can be assembled at D17Z1 or D17Z1-B. Intriguingly, some humans are functional heterozygotes, meaning that CENP-A is located at a different HOR array on the two HSA17 homologs. The site of CENP-A assembly on HSA17 is stable and is transmitted through meiosis, as evidenced by inheritance of CENP-A location through multigenerational families. Differences in histone modifications are not linked clearly with active and inactive D17Z1 and D17Z1-B arrays; however, we detect a correlation between the presence of variant repeat units of D17Z1 and CENP-A assembly at the opposite array, D17Z1-B. Our studies reveal the presence of centromeric epialleles on an endogenous human chromosome and suggest genomic complexities underlying the mechanisms that determine centromere identity in humans.

Genomic size of CENP-A domain is proportional to total alpha satellite array size at human centromeres and expands in cancer cells

Human centromeres contain multi-megabase-sized arrays of alpha satellite DNA, a family of satellite DNA repeats based on a tandemly arranged 171bp monomer. The centromere-specific histone protein CENP-A is assembled on alpha satellite DNA within the primary constriction, but does not extend along its entire length. CENP-A domains have been estimated to extend over 2,500kb of alpha satellite DNA. However, these estimates do not take into account inter-individual variation in alpha satellite array sizes on homologous chromosomes and among different chromosomes. We defined the genomic distance of CENP-A chromatin on human chromosomes X and Y from different individuals. CENP-A chromatin occupied different genomic intervals on different chromosomes, but despite inter-chromosomal and inter-individual array size variation, the ratio of CENP-A to total alpha satellite DNA size remained consistent. Changes in the ratio of alpha satellite array size to CENP-A domain size were observed when CENP-A was overexpressed and when primary cells were transformed by disrupting interactions between the tumor suppressor protein Rb and chromatin. Our data support a model for centromeric domain organization in which the genomic limits of CENP-A chromatin varies on different human chromosomes, and imply that alpha satellite array size may be a more prominent predictor of CENP-A incorporation than chromosome size. In addition, our results also suggest that cancer transformation and amounts of centromeric heterochromatin have notable effects on the amount of alpha satellite that is associated with CENP-A chromatin.

Histone Modifications within the Human X Centromere Region

Human centromeres are multi-megabase regions of highly ordered arrays of alpha satellite DNA that are separated from chromosome arms by unordered alpha satellite monomers and other repetitive elements. Complexities in assembling such large repetitive regions have limited detailed studies of centromeric chromatin organization. However, a genomic map of the human X centromere has provided new opportunities to explore genomic architecture of a complex locus. We used ChIP to examine the distribution of modified histones within centromere regions of multiple X chromosomes. Methylation of H3 at lysine 4 coincided with DXZ1 higher order alpha satellite, the site of CENP-A localization. Heterochromatic histone modifications were distributed across the 400–500 kb pericentromeric regions. The large arrays of alpha satellite and gamma satellite DNA were enriched for both euchromatic and heterochromatic modifications, implying that some pericentromeric repeats have multiple chromatin characteristics. Partial truncation of the X centromere resulted in reduction in the size of the CENP-A/Cenp-A domain and increased heterochromatic modifications in the flanking pericentromere. Although the deletion removed ∼1/3 of centromeric DNA, the ratio of CENP-A to alpha satellite array size was maintained in the same proportion, suggesting that a limited, but defined linear region of the centromeric DNA is necessary for kinetochore assembly. Our results indicate that the human X centromere contains multiple types of chromatin, is organized similarly to smaller eukaryotic centromeres, and responds to structural changes by expanding or contracting domains.

Topoisomerase II cleavage activity within the human D11Z1 and DXZ1 alpha-satellite arrays

Topoisomerase II (Topo II) is a major component of mitotic chromosomes and its unique decatenating activity has been implicated in many aspects of chromosome dynamics including DNA replication, transcription, recombination, chromosome condensation and segregation. Of these, chromosome segregation is the most seriously affected by loss of Topo II, most probably because of residual catenations between sister chromatids. At metaphase, vertebrate chromatids are attached principally through their centromeric regions. Intriguingly, evidence has recently been presented for Topo II cleavage activity within the centromeric alpha-satellite DNA arrays of the human X and Y chromosomes. In this report we extend these observations by mapping distinct sites of Topo II cleavage activity within the alpha-satellite array of human chromosome 11. A single major site of cleavage has been assigned within the centromeric DNA of each of three independently derived, and active, 11 centromeres. Unlike the X and Y centromeres, where cleavage sites mapped close to (within 150 kb of) the short arm edge of the arrays, on chromosome 11, the cleavage sites lie many hundreds of kilobases into each alpha-satellite array. We also demonstrate that catalytically active Topo II is concentrated within the centromere domain through an extended period of G2 and M, with levels declining in G1 and S.

Centromeres: the missing link in the development of human artificial chromosomes

Successful construction of artificial chromosomes is an important step for studies to elucidate the DNA elements necessary for chromosome structure and function. A roadblock to developing a tractable system in multicellular organisms, including humans, is the poorly understood nature of centromeres. Progress has been made in defining the satellite DNA that appears to contribute to the centromere in both humans and Drosophila and large arrays of alpha satellite DNA have been used to construct first-generation human artificial chromosomes. Non-satellite DNA sequences are also capable of forming ‘neo-centromeres’ under some circumstances, however, raising questions about the sequence-dependence of centromere and kinetochore assembly. Taken together with new information on the nature of protein components of the kinetochore, these data support a model in which functional kinetochores are assembled on centromeric chromatin, the competence of which is established epigenetically. The development of human artificial chromosome systems should facilitate investigation of the DNA and chromatin requirements for active centromere assembly.

Formation of de novo centromeres and construction of first-generation human artificial microchromosomes.

We have combined long synthetic arrays of alpha satellite DNA with telomeric DNA and genomic DNA to generate artificial chromosomes in human HT1080 cells. The resulting linear microchromosomes contain exogenous alpha satellite DNA, are mitotically and cytogenetically stable in the absence of selection for up to six months in culture, bind centromere proteins specific for active centromeres, and are estimated to be 6-10 megabases in size, approximately one-fifth to one-tenth the size of endogenous human chromosomes. We conclude that this strategy results in the formation of de novo centromere activity and that the microchromosomes so generated contain all of the sequence elements required for stable mitotic chromosome segregation and maintenance. This first-generation system for the construction of human artificial chromosomes should be suitable for dissecting the sequence requirements of human centromeres, as well as developing constructs useful for therapeutic applications.

Structural analysis of alpha-satellite DNA and centromere proteins using extended chromatin and chromosomes.

Human centromeres are characterized by distinct subsets of alpha-satellite DNA and by a number of centromeric proteins (CENPs) at least one of which, CENP-B, binds specifically to alpha-satellite DNA sequences. When the centromeres of metaphase chromosomes are mechanically stretched to five to 20 times their normal length, CENPs specifically recognized by CREST autoantibodies extend over the entire length of the linear alpha-satellite array. For higher resolution analysis we spread interphase chromatin across a slide resulting in highly extended chromatin fibers. By fluorescence in situ hybridization (FISH) with human alpha-satellite DNA and an oligomer specific for the CENP-B box sequence, the regular spacing of CENP-B binding motifs within arrays of alpha-satellite DNA was visualized directly. FISH with elongated chromatin structures released from interphase nuclei with the drug N-[4-(9-acridinylamino)-3-methoxyphenyl]methanesulfonamide shows that D7Z1 and D7Z2, two distinct alpha-satellite arrays on chromosome 7, are not interspersed with each other but are separated by as little as several hundred kilobases, consistent with previous long-range mapping data. The D7Z2 array, which does not bind detectable amounts of CENPs, can be assigned to the short arm side of the D7Z1 array using artificially stretched chromosomes. In interphase nuclei unreplicated segments give a singlet hybridization signal, whereas fully replicated loci appear as doublets. Although D7Z1 is replicated prior to D7Z2 in the majority of cells, the replication timing of one array relative to the other is variable. The replication of alpha-satellite arrays on homologous chromosomes is highly asynchronous. The newly replicated alpha-satellite lacks the CENP component.

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.

Long-range organization of tandem arrays of alpha satellite DNA at the centromeres of human chromosomes: high-frequency array-length polymorphism and meiotic stability.

The long-range organization of arrays of alpha satellite DNA at the centromeres of human chromosomes was investigated by pulsed-field gel electrophoresis techniques. Both restriction-site and array-length polymorphisms were detected in multiple individuals and their meiotic segregation was observed in three-generation families. Such variation was detected in all of the alpha satellite arrays examined (chromosomes 1, 3, 7, 10, 11, 16, 17, X, and Y) and thus appears to be a general feature of human centromeric DNA. The length of individual centromeric arrays was found to range from an average of approximately 680 kilobases (kb) for the Y chromosome to approximately 3000 kb for chromosome 11. Furthermore, individual arrays appear to be meiotically stable, since no changes in fragment lengths were observed. In total, we analyzed 84 meiotic events involving approximately 191,000 kb of alpha satellite DNA from six autosomal centromeres without any evidence for recombination within an array. High-frequency array length variation and the potential to detect meiotic recombination within them allow direct comparisons of genetic and physical distances in the region of the centromeres of human chromosomes. The generation of primary consensus physical maps of alpha satellite arrays is a first step in the characterization of the centromeric DNA of human chromosomes.