Esperanto for histones: CENP-A, not CenH3, is the centromeric histone H3 variant.

The first centromeric protein identified in any species was CENP-A, a divergent member of the histone H3 family that was recognised by autoantibodies from patients with scleroderma-spectrum disease. It has recently been suggested to rename this protein CenH3. Here, we argue that the original name should be maintained both because it is the basis of a long established nomenclature for centromere proteins and because it avoids confusion due to the presence of canonical histone H3 at centromeres.

Interstitial deletion of proximal 8q including part of the centromere from unbalanced segregation of a paternal deletion/marker karyotype with neocentromere formation at 8p22.

BACKGROUND/AIMS: The 'McClintock mechanism' of chromosome breakage and centromere misdivision, in which a deleted chromosome with its concomitant excised marker or ring chromosome is formed, has been described in approximately one dozen reports. We report a case of a girl with short stature, developmental delay, and dysmorphic features. METHODS: Analysis was performed on the proband and father using cytogenetic chromosome analysis and the Affymetrix 6.0 SNP microarray. Fluorescence in situ hybridization (FISH) using a chromosome 8 alpha-satellite probe and immunofluorescence with antibodies to CENP-C were used to examine the centromere positions in these chromosomes. RESULTS: An abnormal chromosome 8 with a cytogenetically visible deletion was further defined by SNP array as a 10.6-Mb deletion from 8q11.1→q12.1. FISH with a chromosome 8 alpha-satellite probe demonstrated that the deletion removed a significant portion of the pericentromeric alpha-satellite repeat sequences and proximal q arm. The deleted chromosome 8 appeared to have a constriction at 8p22, suggesting the formation of a neocentromere, even though alpha-satellite sequences still appeared at the normal location. Chromosome analysis of the phenotypically normal father revealed the same deleted chromosome 8, as well as an apparently balancing mosaic marker chromosome 8. FISH studies revealed that the majority of the chromosome 8 alpha-satellite DNA resided in the marker chromosome. Immunofluorescence studies with antibodies to CENP-C, a kinetochore protein, proved the presence of a neocentromere at 8p22. The excision of the marker from the deleted chromosome 8 likely necessitated the formation of a new kinetochore at the 8p22 neocentromere to stabilize the chromosome during mitosis. CONCLUSION: This case clearly illustrates the utilization of classic cytogenetics, FISH, and array technologies to better characterize chromosomal abnormalities and provide information on recurrence risks. It also represents a rare case where a neocentromere can form even in the presence of existing alpha-satellite DNA.

Immunolocalization of CENP-A suggests a distinct nucleosome structure at the inner kinetochore plate of active centromeres.

The trilaminar kinetochore directs the segregation of chromosomes in mitosis and meiosis. Despite its importance, the molecular architecture of this structure remains poorly understood [1]. The best known component of the kinetochore plates is CENP-C, a protein that is required for kinetochore assembly [2], but whose molecular role in kinetochore structure and function is unknown. Here we have raised for the first time monospecific antisera to CENP-A [3], a 17 kD centromere-specific histone variant that is 62% identical to the carboxy-terminal domain of histone H3 [4,5] and that resembles the yeast centromeric component CSE4 [6]. We have found by simultaneous immunofluorescence with centromere antigens of known ultrastructural location that CENP-A is concentrated in the region of the inner kinetochore plate at active centromeres. Because CENP-A was previously shown to co-purify with nucleosomes [7], our data suggest a specific nucleosomal substructure for the kinetochore. In human cells, these kinetochore-specific nucleosomes are enriched in alpha-satellite DNA [8]. However, the association of CENP-A with neocentromeres lacking detectable alpha-satellite DNA, and the lack of CENP-A association with alpha-satellite-rich inactive centromeres of dicentric chromosomes together suggest that CENP-A association with kinetochores is unlikely to be determined solely by DNA sequence recognition. We speculate that CENP-A binding could be a consequence of epigenetic tagging of mammalian centromeres.

Epigenetic analysis of kinetochore assembly on variant human centromeres.

Human centromere formation involves the assembly of the mitotic kinetochore onto chromosomal locations that contain the interphase prekinetochore. Immunofluorescent analysis of two functionally converse human centromere variants, neocentromeres and inactive centromeres, has been used to evaluate the functional significance of over 24 CENTROMERE proteins, providing important insight into the epigenetics of centromere formation and kinetochore assembly.

Centromeres, CENP-B and Tigger too.

The highly conserved centromere-associated protein CENP-B is a common feature of mammalian centromeres. Binding sites for CENP-B, so-called 'CENP-B boxes', are present in the otherwise unrelated centromeric satellite DNAs of humans, Mus musculus, Mus caroli, ferrets, giant pandas, tree shrews and gerbils, suggesting a role for CENP-B in centromere function. However, CENP-B and its binding sites are not detected at the centromeres of mammalian Y chromosomes and few, if any, binding sites seem present on African green monkey chromosomes. There is extensive sequence similarity between CENP-B and transposase proteins encoded by the pogo superfamily of transposable elements, which includes the human Tigger elements. Intriguingly, Tigger 2 has an almost perfect match to the CENP-B-binding site within its terminal inverted repeat. Comparison of the amino acid sequence of CENP-B with related proteins raises the possibility that CENP-B might share the ability to cause single-stranded DNA breaks. Such nicks could promote recombination, as has been suggested for the Charcot-Marie-Tooth disease duplication where a recombination hotspot exists close to a mariner-like element. We suggest that by promoting nicks adjacent to CENP-B boxes, CENP-B might facilitate the evolution and maintenance of satellite sequence arrays, rather than have a direct role in centromere function.

A neocentromere derived from a supernumerary marker deleted from the long arm of chromosome 6.

Parental chromosome studies were referred to us after initial finding of a balanced translocation involving chromosomes 4 and 15 in their phenotypically abnormal male child (cytogenetic analysis was done at another laboratory). In addition to the same 4;15 translocation, the father also had an interstitial deletion of the long arm of one chromosome 6 and a marker chromosome. In this article, we report a neocentromere on this marker, which was determined to be composed of chromosome 6 material by FISH. The child's karyotype was re-interpreted to be unbalanced due to the presence of the abnormal chromosome 6, but without the marker. The clinical phenotype associated with the interstitial deletion of chromosome 6 is also reported.

Characterization of a neocentric supernumerary marker chromosome originating from the Xp distal region by FISH, CENP-C staining, and array CGH.

A small supernumerary marker chromosome (SMC) was observed in a girl with severe developmental delay. Her dysmorphism included prominent forehead, hypertelorism, down-slanting palpebral fissures, low-set/large ears, and flat nasal bridge with anteverted nares. This case also presented hypotonia, hypermobility of joints, congenital heart defect, umbilical hernia, failure to thrive, and seizures. The SMC originated from the distal region of Xp as identified by FISH with multiple DNA probes. Staining with antibodies to Centromere Protein C (CENP-C) demonstrated a neocentromere, while FISH with an alpha-satellite DNA probe showed no hybridization to the SMC. A karyotype was described as 47,XX,+neo(X)(pter-->p22.31::p22.31-->pter), indicating a partial tetrasomy of Xp22.31-->pter. This karyotype represents a functional trisomy for Xp22.31-->pter and a functional tetrasomy for the pseudoautosomal region given that there is no X-inactivation center in the marker chromosome. The SMC was further characterized by microarray-based comparative genomic hybridization (array CGH) as a duplicated DNA fragment of approximately 13 megabase pairs containing about 100 genes. We have described here a new neocentromere with discussion of its clinical significance.

Nonrandom localization of recombination events in human alpha satellite repeat unit variants: implications for higher-order structural characteristics within centromeric heterochromatin.

Tandemly repeated DNA families appear to undergo concerted evolution, such that repeat units within a species have a higher degree of sequence similarity than repeat units from even closely related species. While intraspecies homogenization of repeat units can be explained satisfactorily by repeated rounds of genetic exchange processes such as unequal crossing over and/or gene conversion, the parameters controlling these processes remain largely unknown. Alpha satellite DNA is a noncoding tandemly repeated DNA family found at the centromeres of all human and primate chromosomes. We have used sequence analysis to investigate the molecular basis of 13 variant alpha satellite repeat units, allowing comparison of multiple independent recombination events in closely related DNA sequences. The distribution of these events within the 171-bp monomer is nonrandom and clusters in a distinct 20- to 25-bp region, suggesting possible effects of primary sequence and/or chromatin structure. The position of these recombination events may be associated with the location within the higher-order repeat unit of the binding site for the centromere-specific protein CENP-B. These studies have implications for the molecular nature of genetic recombination, mechanisms of concerted evolution, and higher-order structure of centromeric heterochromatin.

Surprising deficiency of CENP-B binding sites in African green monkey alpha-satellite DNA: implications for CENP-B function at centromeres.

Centromeres of mammalian chromosomes are rich in repetitive DNAs that are packaged into specialized nucleoprotein structures called heterochromatin. In humans, the major centromeric repetitive DNA, alpha-satellite DNA, has been extensively sequenced and shown to contain binding sites for CENP-B, an 80-kDa centromeric autoantigen. The present report reveals that African green monkey (AGM) cells, which contain extensive alpha-satellite arrays at centromeres, appear to lack the well-characterized CENP-B binding site (the CENP-B box). We show that AGM cells express a functional CENP-B homolog that binds to the CENP-B box and is recognized by several independent anti-CENP-B antibodies. However, three independent assays fail to reveal CENP-B binding sites in AGM DNA. Methods used include a gel mobility shift competition assay using purified AGM alpha-satellite, a novel kinetic electrophoretic mobility shift assay competition protocol using bulk genomic DNA, and bulk sequencing of 76 AGM alpha-satellite monomers. Immunofluorescence studies reveal the presence of significant levels of CENP-B antigen dispersed diffusely throughout the nuclei of interphase cells. These experiments reveal a paradox. CENP-B is highly conserved among mammals, yet its DNA binding site is conserved in human and mouse genomes but not in the AGM genome. One interpretation of these findings is that the role of CENP-B may be in the maintenance and/or organization of centromeric satellite DNA arrays rather than a more direct involvement in centromere structure.

Genomic analysis of sequence variation in tandemly repeated DNA. Evidence for localized homogeneous sequence domains within arrays of alpha-satellite DNA.

As a model to examine the local distribution of sequence variation within large arrays of tandemly repeated DNA in complex genomes, the long-range organization of alpha-satellite DNA from human chromosome 17 was investigated. Three individual chromosomes, representing different alpha-satellite haplotypes, were segregated into mouse and human somatic cell hybrids and their arrays sized by pulse-field gel electrophoresis. An inventory of the higher-order repeat units found in multiple separate regions of these megabase arrays was obtained using cosmid mapping and two-dimensional gel electrophoresis, a technique that combines the large-scale resolution of pulsed-field gel electrophoresis with the small-scale resolution of conventional gel electrophoresis. These analyses show that alpha-satellite arrays are characterized by the presence of localized homogeneous domains containing only one distinct type of repeat unit. These domains, which consist of sequence variants and/or higher-order repeat length variants, can be up to at least several hundred thousands of bases in length. Both abundant and rare variant repeat units can be localized in these distinct domains, which may correspond to transition states in the evolution of tandem multicopy DNA families. This description of the organization of large arrays of tandem repeats provides insight into mechanisms involved in their homogenization.

Pulsed-field and two-dimensional gel electrophoresis of long arrays of tandemly repeated DNA : analysis of human centromeric alpha satellite.

Complex genomes are characterized by large amounts of tandemly repeated DNA that can comprise up to several percent of the genome in some organisms (1,2). The analysis of the organization of this type of DNA presents certain challenges owing to its repetitive nature, genomic distribution, and large array size. The availability of the large-scale resolution of pulsed-field gel electrophoresis (PFGE) (3,4) has allowed an increased understanding of the genomic organization of long arrays of tandemly repeated DNA, including their overall size and internal polymorphic variation. Such analyses are useful for long-range physical mapping of the large blocks of repetitive DNA characteristic of complex genomes and allow genetic information to be obtained for these loci. Although described here for human centromerit alpha satellite DNA, these techniques are also applicable to other repetitive and multicopy DNA families.

Making CENs of mammalian artificial chromosomes.

Mammalian artificial chromosomes (MACs) hold the promise of providing autonomous vectors for gene therapy in dividing cells. They would not require insertion into the genome and could include sufficient genomic sequences that surround the therapeutic gene to ensure proper tissue-specific and temporal regulation. Several groups have reported successful formation of MACs in human cells using transfection strategies that included alpha satellite DNA, the primary DNA found at normal human centromeres. These results, although extremely encouraging, have limitations such as unpredictable chromosome formation and success thus far in only one transformed human cell line. Examination of other cells where alpha satellite DNA has integrated into ectopic chromosomal locations, as well as naturally occurring dicentric and neocentromere-containing cell lines, suggests that alpha satellite DNA may not be necessary or sufficient for centromere formation. Overall, these results suggest that epigenetic modifications of centromeric DNA are required for efficient centromere formation. Models for this centromere-specific epigenetic modification include a specialized chromatin structure and differential replication timing of centromeric DNA. Thus, further investigation of these centromere-specific epigenetic modifications may suggest strategies for increasing the efficiency of generating human artificial chromosomes for use as gene therapy vectors.

PCR amplification of tandemly repeated DNA: analysis of intra- and interchromosomal sequence variation and homologous unequal crossing-over in human alpha satellite DNA.

Tandemly repeated DNA can comprise several percent of total genomic DNA in complex organisms and, in some instances, may play a role in chromosome structure or function. Alpha satellite DNA is the major family of tandemly repeated DNA found at the centromeres of all human and primate chromosomes. Each centromere is characterized by a large contiguous array of up to several thousand kb which can contain several thousand highly homogeneous repeat units. By using a novel application of the polymerase chain reaction (repPCR), we are able to amplify a representative sampling of multiple repetitive units simultaneously, allowing rapid analysis of chromosomal subsets. Direct sequence analysis of repPCR amplified alpha satellite from chromosomes 17 and X reveals positions of sequence heterogeneity as two bands at a single nucleotide position on a sequencing ladder. The use of TdT in the sequencing reactions greatly reduces the background associated with polymerase pauses and stops, allowing visualization of heterogeneous bases found in as little as 10% of the repeat units. Confirmation of these heterogeneous positions was obtained by comparison to the sequence of multiple individual cloned copies obtained both by PCR and non-PCR based methods. PCR amplification of alpha satellite can also reveal multiple repeat units which differ in size. Analysis of repPCR products from chromosome 17 and X allows rapid determination of the molecular basis of these repeat unit length variants, which appear to be a result of unequal crossing-over. The application of repPCR to the study of tandemly repeated DNA should allow in-depth analysis of intra- and interchromosomal variation and unequal crossing-over, thus providing insight into the biology and genetics of these large families of DNA.

Untangling the role of DNA topoisomerase II in mitotic chromosome structure and function.

DNA topoisomerase II (topo II) is involved in chromosome structure and function, although its exact location and role in mitosis are somewhat controversial. This is due in part to the varied reports of its localization on mitotic chromosomes, which has been described at different times as uniformly distributed, axial on the chromosome arms and predominantly centromeric. These disparate results are probably due to several factors, including use of different preparation and fixation techniques, species differences and changes in distribution during the cell cycle. Recently, several papers have re-investigated the distribution of topo II on chromosomes as a function of cell cycle and species(1-3). The new studies suggest that Topo II has a dynamic pattern of distribution on the chromosomes, in general becoming axial as chromosomes condense during prophase and then concentrating at centromeres during metaphase. These experiments suggest a novel role for topo II in centromere structure and function.

Hamster chromosomes containing amplified human alpha-satellite DNA show delayed sister chromatid separation in the absence of de novo kinetochore formation.

The centromeres of human chromosomes contain large amounts of the tandemly repeated alpha-satellite DNA family. Previous studies have shown that integration of alpha-satellite DNA into ectopic locations in mammalian chromosomes can result in the de novo formation of several features of centromeric function. Here we further examine the possible centromeric properties of alpha-satellite DNA by introducing it into hamster chromosomes. A large amplified region of ectopic alpha-satellite DNA was shown to direct binding of anticentromere antibodies (ACAs) and centromere protein B (CENP-B). The chromosome containing these ectopic arrays showed a high frequency of formation of anaphase bridges. Owing to the favourable morphology of these chromosomes, we were able to determine that this bridging was due to delayed sister chromatid disjunction at the location of the ectopic alpha-satellite, and not due to de novo formation of a fully functional kinetochore. A separate hamster cell line containing large tandemly repeated amplicons including the DHFR gene also displayed similar behaviour during anaphase. These results may support a role for alpha-satellite DNA in sister chromatid cohesion at centromeres. However, other repetitive DNA in favourable configurations appears to be capable of mimicking this behaviour during anaphase.

Interhomologue sequence variation of alpha satellite DNA from human chromosome 17: evidence for concerted evolution along haplotypic lineages.

Alpha satellite DNA is a family of tandemly repeated DNA found at the centromeres of all primate chromosomes. Different human chromosomes 17 in the population are characterized by distinct alpha satellite haplotypes, distinguished by the presence of variant repeat forms that have precise monomeric deletions. Pair-wise comparisons of sequence diversity between variant repeat units from each haplotype show that they are closely related in sequence. Direct sequencing of PCR-amplified alpha satellite reveals heterogeneous positions between the repeat units on a chromosome as two bands at the same position on a sequencing ladder. No variation was detected in the sequence and location of these heterogeneous positions between chromosomes 17 from the same haplotype, but distinct patterns of variation were detected between chromosomes from different haplotypes. Subsequent sequence analysis of individual repeats from each haplotype confirmed the presence of extensive haplotype-specific sequence variation. Phylogenetic inference yielded a tree that suggests these chromosome 17 repeat units evolve principally along haplotypic lineages. These studies allow insight into the relative rates and/or timing of genetic turnover processes that lead to the homogenization of tandem DNA families.

Integration of human alpha-satellite DNA into simian chromosomes: centromere protein binding and disruption of normal chromosome segregation.

Centromeres of mammalian and other complex eukaryotic chromosomes are dominated by one or more classes of satellite DNA. To test the hypothesis that alpha-satellite DNA, the major centromeric satellite of primate chromosomes, is involved in centromere structure and/or function, human alpha-satellite DNA was introduced into African green monkey (AGM) cells. Centromere protein binding was apparent at the sites of integrated human alpha-satellite DNA. In the presence of an AGM centromere on the same chromosome, human alpha-satellite was associated with bridges between the separating sets of chromatids at anaphase and an increased number of lagging chromosomes at metaphase, both features consistent with the integrated alpha-satellite disrupting normal chromosome segregation. These experiments suggest that alpha-satellite DNA provides the primary sequence information for centromere protein binding and for at least some functional aspect(s) of a mammalian centromere, playing a role either in kinetochore formation or in sister chromatid apposition.

Chromosome engineering: prospects for gene therapy.

Recent advances in chromosome engineering and the potential for downstream applications in gene therapy were presented at the Artificial Chromosome Session of Genome Medicine: Gene Therapy for the Millennium in Rome, Italy in September 2001. This session concentrated primarily on the structure and function of human centromeres and the ongoing challenge of equipping human artificial chromosomes (HACs) with centromeres to ensure their mitotic stability. Advances in the 'bottom up' construction of HACs included the transfer into HT1080 cells of circular PACs containing alpha satellite DNA, and the correction of HPRT deficiency in cells using HACs. Advances in the 'top down' construction of HACs using telomere associated chromosome fragmentation in DT40 cells included the formation of HACs that are less than a megabase in size and transfer of HACs through the mouse germline. Significant progress has also been made in the use of human minichromosomes for stable trans-gene expression. While many obstacles remain towards the use of HACs for gene therapy, this session provided an optimistic outlook for future success.

Organization and evolution of an alpha satellite DNA subset shared by human chromosomes 13 and 21.

The structure of the alpha satellite DNA higher-order repeat (HOR) unit from a subset shared by human chromosomes 13 and 21 (D13Z1 and D21Z1) has been examined in detail. By using a panel of hybrids possessing either a chromosome 13 or a chromosome 21, different HOR unit genotypes on chromosomes 13 and 21 have been distinguished. We have also determined the basis for a variant HOR unit structure found on approximately 8% of chromosomes 13 but not at all on chromosomes 21. Genomic restriction maps of the HOR units found on the two chromosome 13 genotypes and on the chromosome 21 genotype are constructed and compared. The nucleotide sequence of a predominant 1.9-kilobasepair HOR unit from the D13Z1/D21Z1 subset has been determined. The DNA sequences of different alpha satellite monomers comprising the HOR are compared, and the data are used to develop a model, based on unequal crossing-over, for the evolution of the current HOR unit found at the centromeres of both these chromosomes.

An unstable dicentric Robertsonian translocation in a markedly discordant twin.

Karyotypes from independent amniocenteses reflected a rare, unstable, functionally dicentric Robertsonian translocation chromosome in most cells in male Twin B who grew more slowly than the chromosomally normal female sib (Twin A). Twin B's balanced de novo Robertsonian translocation dic(13;14)(p11.1;p11.1), present in 81% of cells, underwent recurrent centromeric fission in 6 out of 30 independent colonies that explains a balanced 46,XY,-13,+fis(13)(p11.1),-14,+fis(14)(p11.1) karyotype. Aneuploidy for chromosomes 13q or 14q was present in 5% of cells. Instability of the Robertsonian translocation was evident because nine of the 30 colonies (30%) grown from single amniocytes had metaphase cells with more than one chromosome complement. Although uniparental disomy was excluded and a targeted ultrasound was normal, the couple was advised of the uncertain but real risk of abnormalities in Twin B and the risk to Twin A of terminating Twin B. The pregnancy proceeded and at 31 weeks gestation Twin A was in the 33rd percentile for size and Twin B in the 1st percentile. At 32 weeks, chromosome analysis revealed a balanced 45,XY,dic(13;14)(p11.1;p11.1) karyotype in all of Twin B's newborn cord blood cells with no evidence of fission or aneuploidy. Selection against unbalanced mitotic products of the unstable, functionally dicentric chromosome in early fetal development is proposed to result in Twin B's highly discordant small birth size.