CENP-B: a major human centromere protein located beneath the kinetochore

The centromeres of the Indian muntjac: evidence for the existence of multiple centromeres?

Unlike the centromeres of other species, the "compound' centromeres of the Indian muntjac span over exceptionally extended regions (Brinkley et al., 1984). We extend this concept and show that some of these centromeres are divisible into several chromomeres in which the light staining regions alternate with the dark staining C-band positive segments. Unlike the centromeres of other species where the centromere replicates as one unit, the replication of the sub-units constituting the centromere of the X-chromosome in the muntjac occurs at different times as at least three independent segments. The CREST staining of the centromere regions of even the smallest (Y2) chromosome is interrupted by non-staining segments. Electron microscopy shows similar interruptions in the continuity of the trilamellar kinetochore. Sister chromatid exchanges occur in the region of the centromeres and chromatid breaks within the centromere region occur in the non-fluorescent segments. We interpret these data to suggest that the centromere regions of the Indian muntjac are made up of independent multiple centromeres interrupted by non-centromeric chromatin. Relevance of these parameters in mutagenesis is briefly discussed.

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.

Epigenetic control of mammalian centromere protein binding: does DNA methylation have a role?

Chromosome 1 of the inbred mouse strain DBA/2 has a polymorphism associated with the minor satellite DNA at its centromere. The more terminal block of satellite DNA sequences on this chromosome acts as the centromere as shown by the binding of CREST ACA serum, anti-CENP-B and anti-CENP-E polyclonal sera. Demethylation of the minor satellite DNA sequences accomplished by growing cells in the presence of the drug 5-aza-2′-deoxycytidine results in a redistribution of the CENP-B protein. This protein now binds to an enlarged area on the more terminal block and in addition it now binds to the more internal block of minor satellite DNA sequences on chromosome 1. The binding of the CENP-E protein does not appear to be affected by demethylation of the minor satellite sequences. We present a model to explain these observations. This model may also indicate the mechanism by which the CENP-B protein recognises specific sites within the arrays of minor satellite DNA on mouse chromosomes.

Direct and indirect association of the small GTPase ran with nuclear pore proteins and soluble transport factors: studies in Xenopus laevis egg extracts

Ran is a small GTPase that is required for protein import, mRNA export, and the maintenance of nuclear structures. To gain a better understanding of Ran's role in the nucleus, we have sought to use Xenopus egg extracts for the purification and characterization of proteins from egg extracts bound with a high affinity to a glutathione-S-transferase-Ran fusion protein (GST-Ran). We found that GST-Ran associates specifically with at least 10 extract proteins. We determined the identifies of six Ran-interacting proteins (Rips), and found that they include RanBP2/Nup358, Nup153, Importin beta, hsc70, RCC1, and RanBP1. On the basis of peptide sequence, a seventh Rip (p88) seems to be similar but not identical to Fug1/RanGAP1, the mammalian Ran-GTPase-activating protein. Gel filtration analysis of endogenous extract proteins suggests that Importin beta acts as a primary GTP-Ran effector. Both Ran and Importin beta are coimmunoprecipitated by anti-p340RanBP2 antibodies in the presence of nonhydrolyzable GTP analogues, suggesting that Ran-Importin beta complexes interact with p340RanBP2. Two other Rips, p18 and p88, are coprecipitated with p340RanBP2 in a nucleotide-independent manner. Analysis of the Ran-GTPase pathway in Xenopus extracts allows the examination of interactions between Ran-associated proteins under conditions that resemble in vivo conditions more closely than in assays with purified components, and it thereby allows additional insights into the molecular mechanism of nuclear transport.

Specific interaction between human kinetochore protein CENP-C and a nucleolar transcriptional regulator

CENP-C is a human kinetochore protein that was originally identified as a chromosomal autoantigen in patients with scleroderma spectrum disease. To begin to establish a comprehensive protein map of the human centromere, affinity chromatography was used to identify nuclear proteins that specifically interact with CENP-C. Whereas a number of polypeptides appeared to interact with the full-length CENP-C protein, only a pair of similarly sized proteins of approximately 100 kDa specifically interacted with the isolated carboxyl-terminal third of the CENP-C protein. Neither protein of the doublet bound to control affinity columns. Affinity purification and microsequence analysis of the proteins in the doublet identified them as the two highly related nucleolar transcription factors, UBF1 and UBF2 (also known as the nucleolar autoantigen NOR-90). Immunoblot analysis confirmed that both proteins also interacted with the full-length CENP-C polypeptide with similar affinities. Double indirect immunofluorescence using monospecific antibodies demonstrated that a subset of CENP-C and UBF/NOR-90 is colocalized at nucleoli of interphase HeLa cells, suggesting that the in vitro interaction detected by affinity chromatography may reflect an interaction that occurs in vivo. We discuss the implications of these findings in terms of the properties of interphase centromeres and the role of the nucleolus in scleroderma autoimmunity.

Analysis of extrachromosomal structures containing human centromeric alphoid satellite DNA sequences in mouse cells

Yeast artificial chromosomes (YACs) spanning the centromeric region of the human Y chromosome were introduced into mouse LA-9 cells by spheroplast fusion in order to determine whether they would form mammalian artificial chromosomes. In about 50% of the cell lines generated, the YAC DNA was associated with circular extrachromosomal structures. These episomes were only present in a proportion of the cells, usually at high copy number, and were lost rapidly in the absence of selection. These observations suggest that, despite the presence of centromeric sequences, the structures were not segregating efficiently and thus were not forming artificial chromosomes. However, extrachromosomal structures containing alphoid DNA appeared cytogenetically smaller than those lacking it, as long as yeast DNA was also absent. This suggests that alphoid DNA can generate the condensed chromatin structure at the centromere.

Identification of overlapping DNA-binding and centromere-targeting domains in the human kinetochore protein CENP-C

The kinetochore in eukaryotes serves as the chromosomal site of attachment for microtubules of the mitotic spindle and directs the movements necessary for proper chromosome segregation. In mammalian cells, the kinetochore is a highly differentiated trilaminar structure situated at the surface of the centromeric heterochromatin. CENP-C is a basic, DNA-binding protein that localizes to the inner kinetochore plate, the region that abuts the heterochromatin. Microinjection experiments using antibodies specific for CENP-C have demonstrated that this protein is required for the assembly and/or stability of the kinetochore as well as for a timely transition through mitosis. From these observations, it has been suggested that CENP-C is a structural protein that is involved in the organization or the kinetochore. In this report, we wished to identify and map the functional domains of CENP-C. Analysis of CENP-C truncation mutants expressed in vivo demonstrated that CENP-C possesses an autonomous centromere-targeting domain situated at the central region of the CENP-C polypeptide. Similarly, in vitro assays revealed that a region of CENP-C with the ability to bind DNA is also located at the center of the CENP-C molecule, where it overlaps the centromere-targeting domain.

Localization of anti-CENP antibodies and alphoid sequences in acentric heterochromatin in a breast cancer cell line

Karyotype alterations are a hallmark of cancer cells. Of particular interest to our laboratory are the inactive centromeres and blocks of heterochromatin devoid of the accompanying centromere. When purified or monospecies anticentromere proteins (CENP) antibodies or the whole serum from scleroderma (crest) patients are applied to human chromosomes, the centromere region exhibits the label. When we treated MDA 435 cells with the anti-CENP-A, anti-CENP-B, or the whole serum, the label was apparent on heterochromatin pericentric to the active and inactive centromeres. Moreover, blocks of heterochromatin not associated with any centromere also exhibited the label. Anti-CENP-C, however, is more strictly confined to the centromere in discrete dots and is not detected on any region except the sites of active centromeres. Distribution of alpha sequences also shows a pattern compatible with its distribution in the heterochromatin. Apparently, the use of anti-CENP-A and anti-CENP-B antibodies or alphoid DNA may not detect either the centromere (primary constriction) or the kinetochore; CENP-C may be an exception.

Disruption of CENP antigen function perturbs dynein anchoring to the mitotic kinetochore

Injection of purified autoantibodies against human centromeric proteins into HeLa cells during interphase disrupts the organization of the kinetochore and interferes with chromosomal movements during the subsequent mitosis even though the chromosomes retain the ability to bind microtubules. We have investigated the hypothesis that this phenotype arises from effects on cytoplasmic dynein, the microtubule motor protein. In previous experiments we found that introduction of anticentromere antibodies into cell nuclei during the G1- or S-phases causes a prometaphase-like arrest, while injections during G2-phase cause a metaphase arrest. We show here that, in both cases, the level of detectable cytoplasmic dynein at kinetochores is significantly decreased. In contrast, when injected cells were permitted to enter mitosis in the absence of microtubules (conditions where trilaminar kinetochores could be detected by electron microscopy), the intensity of dynein labeling on the kinetochores was identical to that seen in uninjected control cells exposed to colcemid. Therefore, the loss of dynein label on mitotic kinetochores was correlated both with the injection of anticentromere antibodies and with the presence of intact spindle microtubules. We suggest that the injection of anticentromere antibodies somehow weakens the association of dynein with the kinetochore, so that when microtubules are present, these motor molecules are pulled away from the kinetochores as they generate force. This model offers an explanation for the failure of chromosomes of injected cells to move normally in mitosis even though they have attached microtubules.

The kinesin-like protein CENP-E is kinetochore-associated throughout poleward chromosome segregation during anaphase-A

The kinesin-like protein CENP-E transiently associates with kinetochores following nuclear envelope breakdown in late prophase, remains bound throughout metaphase, but sometime after anaphase onset it releases and by telophase becomes bound to interzonal microtubules of the mitotic spindle. Inhibition of poleward chromosome movement in vitro by CENP-E antibodies and association of CENP-E with minus-end directed microtubule motility in vitro have combined to suggest a key role for CENP-E as an anaphase chromosome motor. For this to be plausible in vivo depends on whether CENP-E remains kinetochore associated during anaphase. Using Indian muntjac cells whose seven chromosomes have large, easily tracked kinetochores, we now show that CENP-E is kinetochore-associated throughout the entirety of anaphase-A (poleward chromosome movement), relocating gradually during spindle elongation (anaphase-B) to the interzonal microtubules. These observations support roles for CENP-E not only in the initial alignment of chromosomes at metaphase and in spindle elongation in anaphase-B, but also in poleward chromosome movement in anaphase-A.

An unusual dicentric Y chromosome with a functional centromere with no detectable alpha-satellite

We describe an unusual marker chromosome Y. This marker is present in 5% of the lymphocytes of a dysgenetic woman showing a mosaic karyotype 45,X/46,XY/47,XY+mar. Q-banding revealed that the marker was morphologically identical to the Y chromosome of the patient but presented the primary constriction in the heterochromatic region. C-banding confirmed that the heterochromatic region was C-positive; furthermore, it showed two spots in the euchromatic region in a position corresponding to that of the centromere in the normal Y. Fluorescence in situ hybridization with the centromere-specific probe pDP 97 and the pancentromeric alpha-satellite probe alpha 27 alpha 30 failed to detect any signal at the primary constriction site. To improve the characterization of the marker chromosome, hybridization was performed using pDP 105, a probe located on the short arm of the Y chromosome, together with chromosome-Y-specific paint-hybridizing to the single sequence spanning the Y short arm. In both cases, positive signals telomeric to the inactive centromere were observed. Possible mechanisms resulting in the formation of the marker chromosome are discussed.

Molecular biology of autoantigens in rheumatic diseases

The advent of molecular biologic techniques has provided new approaches that are of great utility to the study of autoimmune-mediated responses. In the past few years, there has been a remarkable accumulation of knowledge concerning the molecular identity and function of autoantigens, and further consolidation for the use of autoantibodies as diagnostic markers in clinical rheumatology. The understanding of basis methodologies in molecular biology applied to the study of autoantigens, in particular, techniques for cloning and analyzing genes that are important in rheumatic diseases, is valuable for both basic scientists and clinicians interested in diagnostic and prognostic markers of various connective tissue diseases.

Visualizing the spatial relationships between defined DNA sequences and the axial region of extracted metaphase chromosomes

Using fluorescence in situ hybridization to extracted metaphase chromosomes, we present visual evidence that specific human DNA sequences occupy distinctive positions with respect to the axial region of chromosomes and that the DNA is organized into loops emanating from this region. In a stretch of unique DNA on chromosome 11, large loops of DNA can be traced and one specific region associated with the axial region of the chromosome. Within rDNA, nontranscribed spacer sequences are more closely apposed to the chromosome axis than are rRNA genes. Heterochromatic and euchromatic DNAs appear to be organized into loops of similar size. We could not detect loops at centromeres; most alphoid DNA appears to remain close to the axial region.

Centromeres of human chromosomes

The centromere, recognized cytologically as the primary constriction, is essential for chromosomal attachment to the spindle and for proper segregation of mitotic and meiotic chromosomes. Considerable progress has been made in identifying both DNA and protein components of the centromere and kinetochore complex in mammalian chromosomes, including definition of specific motor proteins with demonstrable functions in chromosome movement. Searches for possible environmental influences on chromosome disjunction might logically be based on known components of the segregation apparatus, both intrinsic and extrinsic to the chromosomes themselves. This article reviews available information on both DNA and protein components of the centromere of mammalian, particularly human, chromosomes and summarizes our current understanding of their role(s) in facilitating normal chromosome behavior in mitosis and meiosis.

Nuclear matrix proteins as structural and functional components of the mitotic apparatus

The eukaryotic nucleus is a membrane-enclosed compartment containing the genome and associated organelles supported by a complex matrix of nonhistone proteins. Identified as the nuclear matrix, this component maintains spatial order and provides the structural framework needed for DNA replication, RNA synthesis and processing, nuclear transport, and steroid hormone action. During mitosis, the nucleoskeleton and associated chromatin is efficiently dismantled, packaged, partitioned, and subsequently reassembled into daughter nuclei. The dramatic dissolution of the nucleus is accompanied by the assembly of a mitotic apparatus required to facilitate the complex events associated with nuclear division. Until recently, little was known about the fate or disposition of nuclear matrix proteins during mitosis. The availability of specific molecular probes and imaging techniques, including confocal microscopy and improved immunoelectron microscopy using resinless sections and related procedures, has enabled investigators to identify and map the distribution of nuclear matrix proteins throughout the cell cycle. This chapter will review the structure, function, and distribution of the protein NuMA (nuclear matrix mitotic apparatus) and other nuclear matrix proteins that depart the nucleus during the interphase/mitosis transition to become structural and functional components within specific domains of the mitotic apparatus.

Preference of the recombination sites involved in the formation of extrachromosomal copies of the human alphoid Sau3A repeat family

The human alphoid Sau3A repetitive family DNA is one of the DNA species that are actively amplified to form extrachromosomal circular DNA in several cell lines. The circularization takes place between two of the five approximately 170 bp subunits with an average of 73.1% homology as well as between identical subunits. To investigate the nature of the recombination reaction, we cloned and analyzed the subunits containing recombination junctions. Analysis of a total of 68 junctions revealed that recombination had occurred preferentially at four positions 10-25 (A), 40-50 (B), 85-90 (C) and 135-160 (D) in the 170bp subunit structure. Two regions (B and C) were overlapped with the regions with higher homology between subunits, while other two regions (A and D) cannot be explained solely by the regional homology between the subunits. These regions were located at both junctions of the nucleosomal and the linker region, and overlapped with the binding motifs for alpha protein and CENP-B. Approximately 90% of the recombination occurred between the subunits located next but one (+/- 2 shift), although the frequency of recombination between the adjoining subunits (+/- 1 shift) was approximately 10%.

The centromere: hub of chromosomal activities

Centromeres are the structures that direct eukaryotic chromosome segregation in mitosis and meiosis. There are two major classes of centromeres. Point centromeres, found in the budding yeasts, are compact loci whose constituent proteins are now beginning to yield to biochemical analysis. Regional centromeres, best described in the fission yeast Schizosaccharomyces pombe, encompass many kilobases of DNA and are packaged into heterochromatin. Their associated proteins are as yet poorly understood. In addition to providing the site for microtubule attachment, centromeres also have an important role in checkpoint regulation during mitosis.

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 alpha 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 gamma 8 satellite DNA consensus sequence. Comparison of the 2D12/E2 and gamma 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 gamma 8 satellite DNA. These observations suggest that this satellite DNA clone is derived from a subfamily of gamma satellite DNA and is thus designated gamma 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 gamma X (2D12/E2) or gamma 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.

Presence and abundance of CENP-B box sequences in great ape subsets of primate-specific alpha-satellite DNA

CENP-B, a highly conserved centromere-associated protein, binds to alpha-satellite DNA, the centromeric satellite of primate chromosomes, at a 17-bp sequence, the CENP-B box. By fluorescence in situ hybridization (FISH) with an oligomer specific for the CENP-B box sequence, we have demonstrated the abundance of CENP-B boxes on all chromosomes (except the Y) of humans, chimpanzee, pygmy chimpanzee, gorilla, and orangutan. This sequence motif was not detected in the genomes of other primates, including gibbons, Old and New World monkeys, and prosimians. Our results indicate that the CENP-B box containing subtype of alpha-satellite DNA may have emerged recently in the evolution of the large-bodied hominoids, after divergence of the phylogenetic lines leading to gibbons and apes; the box is thus on the order of 15-25 million years of age. The rapid process of dispersal and fixation of the CENP-B box sequence throughout the human and great ape genomes is thought to be a consequence of concerted evolution of alpha-satellite subsets on both homologous and nonhomologous chromosomes.

Characterization of a novel 350-kilodalton nuclear phosphoprotein that is specifically involved in mitotic-phase progression

A gene assigned to human chromosome 1q32-41 encodes a novel protein of 3,113 amino acids containing an internal tandem repeat of 177 amino acids. The protein, which we have named "mitosin," was identified by direct binding to purified retinoblastoma protein in vitro with a region distantly related to the retinoblastoma protein-binding site of E2F-1. Mitosin is expressed throughout S, G2, and M phases of the cell cycle but is absent in G1. Its localization is dramatically reorganized from a rather homogeneous nuclear distribution in S phase to paired dots at the kinetochore/centromere region, to the spindle apparatus, and then to the midbody during M-phase progression. This spatial reorganization coincides closely with the temporal phosphorylation patterns of mitosin. Overexpression of N-terminally truncated mutants blocks cell cycle progression mainly at G2/M. These results suggest that mitosin may play an important role in mitotic-phase progression.

The C terminus of mitosin is essential for its nuclear localization, centromere/kinetochore targeting, and dimerization

Mitosin is a novel 350-kDa nuclear phosphoprotein that dramatically relocates from the evenly nuclear distribution in S phase to the centromere/kinetochore and mitotic apparatus in M phase. The dynamic relocalization of mitosin is accompanied by the phosphorylation of itself, suggesting that mitosin plays a role in mitotic progression. The molecular basis of nuclear localization and targeting of mitosin to the centromere/kinetochore were characterized using a set of epitope-tagged deletion mutants. The data indicate that the extreme C terminus (amino acids 2,487-3,113) of mitosin has both an independent centromere/kinetochore targeting domain and an unusually spaced bipartite nuclear localization signal. Moreover, the same centromere/kinetochore targeting domain was shown to be essential for the ability of mitosin to bind to itself or other putative mitosin-associated proteins through use of the yeast two-hybrid system. These results suggest that the C terminus of the mitosin is essential for its role in influencing cell cycle progression.

Domains required for CENP-C assembly at the kinetochore

Chromosomes segregate at mitosis along microtubules attached to the kinetochore, an organelle that assembles at the centromere. Despite major advances in defining molecular components of the yeast segregation apparatus, including discrete centromere sequences and proteins of the kinetochore, relatively little is known of corresponding elements in more complex eukaryotes. We show here that human CENP-C, a human autoantigen previously localized to the kinetochore, assembles at centromeres of divergent species, and that the specificity of this targeting is maintained by an inherent destruction mechanism that prevents the accumulation of CENP-C and toxicity of mistargeted CENP-C. The N-terminus of CENP-C is not only required for CENP-C destruction but renders unstable proteins that otherwise possess long half-lives. The conserved targeting of CENP-C is underscored by the discovery of significant homology between regions of CENP-C and Mif2, a protein of Saccharomyces cerevisiae required for the correct segregation of chromosomes. Mutations in the Mif2 homology domain of CENP-C impair the ability of CENP-C to assemble at the kinetochore. Together, these data indicate that essential elements of the chromosome segregation apparatus are conserved in eukaryotes.

Heterochromatin protein 1 is required for correct chromosome segregation in Drosophila embryos

Heterochromatin protein 1 is associated with centromeric heterochromatin in Drosophila, mice, and humans. Loss of function mutations in the gene encoding heterochromatin protein 1 in Drosophila, Suppressor of variegation2-5, decrease the mosaic repression observed for euchromatic genes that have been juxtaposed to centromeric heterochromatin. These heterochromatin protein 1 mutations not only suppress this position-effect variegation, but also cause recessive embryonic lethality. In this study, we analyze the latter phenotype in the hope of gaining insight into heterochromatin function. In our analyses of four alleles of Suppressor of variegation2-5, the lethality was found to be associated with defects in chromosome morphology and segregation. While some of these defects are seen throughout embryonic development, both the frequency and severity of the defects are greatest between cycles 10 and 14 when zygotic transcription of the Suppressor of variegation2-5 gene apparently begins. By this time in development, heterochromatin protein 1 levels are diminished by four-fold in a quarter of the embryos produced by parents that are both heterozygous for a null allele (Suppressor of variegation2-5(05)). In a live analysis of the phenotype, we find prophase to be lengthened by more than two-fold in Suppressor of variegation2-5(05) mutant embryos with subsequent defects in chromosome segregation. The elongated prophase suggests that the segregation phenotype is a consequence of defects in events that occur during prophase, either in chromosome condensation or kinetochore assembly or function. Immunostaining with an antibody against a centromerespecific antigen indicates that the kinetochores of most chromosomes are functional. The immunostaining results are more consistent with defects in chromosome condensation being responsible for the segregation phenotype.

A tightly bound chromosome antigen is detected by monoclonal antibodies in a ring-like structure on human centromeres

Monoclonal antibodies (Mabs) were raised against isolated Chinese hamster protein-depleted chromosomes Chromosome scaffolds) in order to probe for components involved in the higher-order structure of mammalian chromosomes. One of the Mabs detected a ring-like structure in metaphase at the centromere, which is conserved between Chinese hamster and human cells. Additionally, the Mab stained the centrioles in interphase cells in these two species. The antigen was enriched in chromosomal protein preparations by comparison with nuclear protein samples, and has an apparent Mr = 170,000. The centromere antigen remained present in chromosome scaffold preparations, indicating that it was tightly associated with DNA. The antigen was distinct in its centromeric localisation from any of the centromere antigens reported to date. A possible role of the antigen in stabilising the centromere, by holding the sister chromatids together until their separation at the metaphase-anaphase transition is presented.

Mutations derepressing silent centromeric domains in fission yeast disrupt chromosome segregation

The ura4+ gene displays phenotypes consistent with variegated expression when inserted at 11 sites throughout fission yeast centromere 1. An abrupt transition occurs between the zone of centromeric repression and two adjacent expressed sites. Mutations in six genes alleviate repression of the silent-mating type loci and of ura4+ expressed from a site adjacent to the silent locus, mat3-M. Defects at all six loci affect repression of the ura4+ gene adjacent to telomeres and at the three centromeric sites tested. The clr4-S5 and rik1-304 mutations cause the most dramatic derepression at two out of three sites within cen1. All six mutations had only slight or intermediate effects on a third site in the center of cen1 or on telomeric repression. Strains with lesions at the clr4, rik1, and swi6 loci have highly elevated rates of chromosome loss. We propose that the products of these genes are integral in the assembly of a heterochromatin-like structure, with distinct domains, enclosing the entire centromeric region that reduces or excludes access to transcription factors. The formation of this heterochromatic structure may be an absolute requirement for the formation of a fully functional centromere.

Molecular structure and function of autoantigens in systemic sclerosis

Autoantibodies in systemic sclerosis target a limited set of nuclear proteins, principally those of the nucleolus and RNA transcription complexes. These antibodies have proved helpful in diagnosis of this disease, and have been used extensively as probes of nuclear structure and function. Despite these advances, the events that initially trigger autoantibody production in systemic sclerosis are not yet known. While these ANA are not known to disrupt cellular processes by entering living cells, or to cause tissue injury (in contrast to SLE, where autoantibodies may mediate tissue damage), it seems likely that they do not merely represent epiphenomena of the disease. Rather, it is logical to assume that their origin is in some manner tied to etiology of systemic sclerosis, since they segregate by syndrome within the spectrum of this disease (for example, anti-kinetochore antibodies occur in limited cutaneous disease, and anti-topoisomerase I and anti-RNA polymerase antibodies occur in diffuse disease), and since they are distinct from the ANA found in other connective tissue diseases in their selectivity for the nucleolus and RNA polymerases.

Identification and partial characterization of mitotic centromere-associated kinesin, a kinesin-related protein that associates with centromeres during mitosis

Using antipeptide antibodies to conserved regions of the kinesin motor domain, we cloned a kinesin-related protein that associates with the centromere region of mitotic chromosomes. We call the protein MCAK, for mitotic centromere-associated kinesin. MCAK appears concentrated on centromeres at prophase and persists until telophase, after which time the localization disperses. It is found throughout the centromere region and between the kinetochore plates of isolated mitotic CHO chromosomes, in contrast to two other kinetochore-associated microtubule motors: cytoplasmic dynein and CENP-E (Yen et al., 1992), which are closer to the outer surface of the kinetochore plates. Sequence analysis shows MCAK to be a kinesin-related protein with the motor domain located in the center of the protein. It is 60-70% similar to kif2, a kinesin-related protein originally cloned from mouse brain with a centrally located motor domain (Aizawa et al., 1992). MCAK protein is present in interphase and mitotic CHO cells and is transcribed as a single 3.4-kb message.

Isolation of chromosome-associated proteins from Drosophila melanogaster that bind a human centromeric DNA sequence

The molecular mechanism involved in packaging centromeric heterochromatin is still poorly understood. CENP-B, a centromeric protein present in human cells, is though to be involved in this process. This is a DNA-binding protein that localizes to the central domain of the centromere of human and mouse chromosomes due to its association with the 17-bp CENP-B box sequence. We have designed a biochemical approach to search for functional homologues of CENP-B in Drosophila melanogaster. This strategy relies upon the use of DNA fragments containing the CENP-B box to identify proteins that specifically bind this sequence. Three polypeptides were isolated by nuclear protein extraction, followed by sequential ion exchange columns and DNA affinity chromatography. All three proteins are present in the complex formed after gel retardation with the human alphoid satellite DNA that contains the CENP-B box. Footprinting analysis reveals that the complex occupies both strands of the CENP-B box, although it is still unclear which of the polypeptides actually makes contact with the DNA. Localization of fluorescein-labeled proteins after microinjection into early Drosophila embryos shows that they associate with condensed chromosomes. Immunostaining of embryos with a polyclonal serum made against all three polypeptides also shows chromosomal localization throughout mitosis. During metaphase and anaphase the antigens appear to localize preferentially to centromeric heterochromatin. Immunostaining of neuroblasts chromosome spreads confirmed these results, though some staining of chromosomal arms is also observed. The data strongly suggests that the polypeptides we have identified are chromosomal binding proteins that accumulate mainly at the centromeric heterochromatin. Furthermore, DNA binding assays clearly indicate that they have a high specific affinity for the human CENP-B box. This would suggest that at least one of the three proteins isolated might be a functional homologue of the human CENP-B.

Human CENP-A contains a histone H3 related histone fold domain that is required for targeting to the centromere

Centromeres are the differentiated chromosomal domains that specify the mitotic behavior of chromosomes. To examine the molecular basis for the specification of centromeric chromatin, we have cloned a human cDNA that encodes the 17-kD histone-like centromere antigen, CENP-A. Two domains are evident in the 140 aa CENP-A polypeptide: a unique NH2-terminal domain and a 93-amino acid COOH-terminal domain that shares 62% identity with nucleosomal core protein, histone H3. An epitope tagged derivative of CENP-A was faithfully targeted to centromeres when expressed in a variety of animal cells and this targeting activity was shown to reside in the histone-like COOH-terminal domain of CENP-A. These data clearly indicate that the assembly of centromeres is driven, at least in part, by the incorporation of a novel core histone into centromeric chromatin.

Dissociation of minor satellite from the centromere in mouse

The minor satellite DNA of mouse is believed to constitute the centromere. We report that centromeres of some chromosomes in the Cl1D cells of mouse are not associated with this DNA even though the latter is present on these chromosomes. The satellite DNA was detected distally from the centromere and could not be mistaken as a component of the centromere. We also report that the site of the primary constriction may not always coincide with the site of the anti-kinetochore antibody reaction. Whereas the regions containing the major satellite decondense upon treatment with bisbenzimidazole (Hoechst 33258), the sites carrying minor satellite resist decondensing.

Do specific nucleotide bases constitute the centromere?

It is becoming increasingly clear that the underlying base composition of the DNA located in the centromere region is vastly different in different organisms. The chromosomes of related species or even the various chromosomes of the same species differ widely in their so-called centromeric DNA. Yet all centromeres appear physically alike and perform similar functions. The present communication proposes that the physical properties of the centromere are not due to its base composition but due to stereophysical make-up of the DNA segment constituting the centromere. This unique make up might reflect some physical parameter, like curvature, of the DNA present in the centromere constriction. It is further proposed that a proteinaceous factor, centromerase, is responsible for holding the centromeres as one unit until meta-anaphase.

A homologue of the human regulator of mitotic spindle assembly protein (RMSA-1) is present in crane fly and is associated with meiotic chromosomes

In a previous study, we have shown that a newly identified chromosomal protein, RMSA-1 (Regulator of Mitotic Spindle Assembly-1), identified and cloned using a human autoimmune, serum, is essential for mitotic spindle assembly; we proposed that RMSA-1 was a previously unknown physiological substrate for cdc 2 kinase. In the present study, we show that this protein is present in crane fly and is associated with the chromosomes of spermatocytes. A 31 kDa molecule in extracts from crane-fly nuclei, isolated from larvae, pupae and adults, reacts with affinity-purified anti-RMSA-1 autoantibody, shown by immunoblotting. The autoantibody reacts, as shown by immunofluorescence, with crane-fly spermatocyte chromosomes in prophase through anaphase of both meiosis-1 and meiosis-II but does not react with preprophase or telophase nuclei or with spermatid nuclei. In all meiotic stages, the crane-fly sex chromosomes stain more intensely than the autosomes. We conclude that, since RMSA-1 is present in insect and mammalian cells, it is conserved across a variety of animal species. Further, since RMSA-1 binds to chromosomes in meiotic cells, it also may be essential for assembly of the meiotic spindle.

CENP-C is required for maintaining proper kinetochore size and for a timely transition to anaphase

The human autoantigen CENP-C has been demonstrated by immunoelectron microscopy to be a component of the inner kinetochore plate. Here we have used antibodies raised against various portions of CENP-C to probe its function in mitosis. We show that nuclear microinjection of anti-CENP-C antibodies during interphase causes a transient arrest at the following metaphase. Injection of the same antibodies after the initiation of prophase, however, does not disrupt mitosis. Correspondingly, indirect immunofluorescence using affinity-purified human anti-CENP-C antibodies reveals that levels of CENP-C staining are reduced at centromeres in cells that were injected during interphase, but appear unaffected in cells which were injected during mitosis. Thus, we suggest that the injected antibodies cause metaphase arrest by reducing the amount of CENP-C at centromeres. Examination of kinetochores in metaphase-arrested cells by electron microscopy reveals that the number of trilaminar structures is reduced. More surprisingly, the few remaining kinetochores in these cells retain a normal trilaminar morphology but are significantly reduced in diameter. In cells arrested for extended periods, these small kinetochores become disrupted and apparently no longer bind microtubules. These observations are consistent with an involvement of CENP-C in kinetochore assembly, and suggest that CENP-C plays a critical role in both establishing and/or maintaining proper kinetochore size and stabilizing microtubule attachments. These findings also support the idea that proper assembly of kinetochores may be monitored by the cell cycle checkpoint preceding the transition to anaphase.

Correlation of the physical and genetic maps of the centromeric region of the right arm of linkage group III of Neurospora crassa

We have cloned three linked genes serine-1 (ser-1), proline-1 (pro-1) and acetate-2 (ace-2) that lie near the centromere on the right arm of linkage group III (LGIIIR) of Neurospora crassa. The ser-1 gene was cloned by sib selection. A chromosomal walk that spans 205 kilobases (kb) was initiated from ser-1. Complementation analysis with clones isolated during the walk allowed identification of the pro-1 and ace-2 genes. Restriction fragment length polymorphism analysis has confirmed the localization of ser-1, pro-1 and ace-2 to the centromeric region of LGIIIR. Genetically, we measured 1% recombination between ser-1 and pro-1 and 2% recombination between pro-1 and ace-2. Physical distances for these intervals were 114 kb from ser-1 to pro-1 and 36 kb from pro-1 to ace-2. Thus, for the pro-1 to ace-2 interval we calculate a physical/genetic correlation of 18 kb/map unit (mu) whereas, in the immediately adjacent, centromere-proximal interval from ser-1 to pro-1, we calculate 114 kb/mu. This provides evidence for a centromere effect, a decrease in recombination frequency as one approaches the centromere.

A stable dicentric chromosome: both centromeres develop kinetochores and attach to the spindle in monocentric and dicentric configuration

A stable, dicentric human chromosome, which is known from light microscopy to show a 50:50 distribution between monocentric/dicentric appearance, was examined by conventional electron microscopy and after labelling the centromere with anticentromere antibodies from CREST serum. Both centromeres of the chromosome developed kinetochores whether in monocentric or dicentric configuration. The eight monocentrics observed had all developed kinetochores at the centromere outside the constriction; at least six of them also had kinetochores at the centromere in the constriction. The dicentrics from glutaraldehyde fixed cells had spindle microtubules attached to both kinetochore sets irrespective of monocentric/dicentric configuration. The chromosome thus appeared to use both centromeres, either equally or with one serving a chromatid adhesion function while the second was used for transport along the spindle.

Nuclear dot antigens may specify transcriptional domains in the nucleus

A bank of 892 human autoimmune serum samples was screened by indirect immunofluorescence on human tissue culture HT-29 cells. Seven serum samples that stain 4 to 10 bright dots in cell lines of several different mammals, including humans, monkeys, rats, and pigs, were identified. Immunofluorescence experiments indicate that these antigens, called nuclear dot (ND) antigens, are distinct from splicing complexes, kinetochores, and other known nuclear structures. An ND antigen recognized by these sera was cloned by immunoscreening a human lambda gt11 expression library. Analysis of seven cDNA clones for the ND antigen indicates that several mRNAs exist, perhaps derived through alternative splicing mechanisms. One major form of the message has an open reading frame of 1,440 bp capable of encoding a 53,000-M(r) protein. Treatment of cells with detergent, salt, or RNase A fails to remove the ND antigen from the nucleus. However, incubation with DNase I obliterates ND staining, indicating that the ND protein directly or indirectly associates with nuclear DNA. Fusion of the ND protein to a LexA DNA binding domain activates transcription in Saccharomyces cerevisiae. A 75-amino-acid domain that activates transcription in both yeast and primate cells has been identified. We suggest that ND antigens may participate in the activation of transcription of specific regions of the genome.

Nuclear dot antigens may specify transcriptional domains in the nucleus

A bank of 892 human autoimmune serum samples was screened by indirect immunofluorescence on human tissue culture HT-29 cells. Seven serum samples that stain 4 to 10 bright dots in cell lines of several different mammals, including humans, monkeys, rats, and pigs, were identified. Immunofluorescence experiments indicate that these antigens, called nuclear dot (ND) antigens, are distinct from splicing complexes, kinetochores, and other known nuclear structures. An ND antigen recognized by these sera was cloned by immunoscreening a human lambda gt11 expression library. Analysis of seven cDNA clones for the ND antigen indicates that several mRNAs exist, perhaps derived through alternative splicing mechanisms. One major form of the message has an open reading frame of 1,440 bp capable of encoding a 53,000-M(r) protein. Treatment of cells with detergent, salt, or RNase A fails to remove the ND antigen from the nucleus. However, incubation with DNase I obliterates ND staining, indicating that the ND protein directly or indirectly associates with nuclear DNA. Fusion of the ND protein to a LexA DNA binding domain activates transcription in Saccharomyces cerevisiae. A 75-amino-acid domain that activates transcription in both yeast and primate cells has been identified. We suggest that ND antigens may participate in the activation of transcription of specific regions of the genome.

Novel structural organisation of a Mus musculus DBA/2 chromosome shows a fixed position for the centromere

Chromosome 1 of the inbred mouse strain DBA/2 shows an unusual polymorphism associated with its centromeric satellite DNA sequences. The minor satellite array has undergone amplification and is present as two blocks separated by major satellite sequences. Both minor satellite blocks appear to carry the sequence motif necessary for CENP-B protein binding. Despite this apparent similarity the functional centromere, as defined by the location of CREST antigens, appears to form only within the more terminal block. The two blocks also vary in that sister chromatid association only occurs with this more terminal block.

Centromeric DNA cloned from functional kinetochore fragments in mitotic cells with unreplicated genomes

Treatment of cells arrested in the cell cycle at the G1/S-phase boundary with 5 mM caffeine induces premature mitosis, resulting in chromosomal fragmentation and detachment of centromere-kinetochore fragments, which are subsequently attached to the mitotic spindle and segregated in anaphase. Taking advantage of this in vivo separation of the centromere, we have developed a procedure for isolation of a centromere-enriched fraction of mitotic chromatin. Using this method, we have isolated and cloned DNA from the centromere-enriched material of Chinese hamster cells. One of the clones thus obtained was characterized in detail. It contains 6 kb of centromere-associated sequence that exhibits no recognizable homology with other mammalian centromeric sequences and is devoid of any extensive repetitive structure. This sequence is present in a single copy on chromosome 1 and is species-specific. Distinctive features of the clone include the presence of several A+T-rich regions and clusters of multiple topoisomerase II consensus cleavage sites and other sequence motifs characteristic of nuclear matrix-associated regions. We hypothesize that these features might be related to the more compact packaging of centromeric chromatin in interphase nuclei and mitotic chromosomes.

Development of a sequence-tagged site for the centromere of chromosome 10: its use in cytogenetic and physical mapping

We sequenced the alphoid centromere probe p alpha 10RP8 (D10Z1), aligned it to three published consensus sequences, and developed a sequence-tagged site (STS), sJRH-2, based upon oligonucleotide primers having two 3' mismatches with these consensus sequences. Polymerase chain reaction (PCR) amplification using genomic DNA from a somatic cell hybrid panel representing all human chromosomes demonstrated amplification from only those cell lines containing chromosome 10. Fluorescence in situ hybridization of the amplified product demonstrated intense and specific hybridization of the PCR product to 10p11.1-q11.1. A human genomic yeast artificial chromosome (YAC) library was screened using the sJRH-2 PCR assay, and five clones were identified. Sequence analysis of one chimeric clone (consisting of DNA segments derived from chromosomes 5p and 10cen) confirmed specificity of the STS for the centromere of chromosome 10. sJRH-2 provides a convenient cytogenetic marker for chromosome 10, which will also be useful for physical mapping of the pericentromeric region of chromosome 10, a region that harbors the gene(s) for three forms of multiple endocrine neoplasia (types 2A, 2B, and familial medullary thyroid carcinoma). The GenBank accession number for the p alpha 10RP8 sequence is X63622.

Molecular cloning of a human homologue of Drosophila heterochromatin protein HP1 using anti-centromere autoantibodies with anti-chromo specificity

We have identified a novel autoantibody specificity in scleroderma that we term anti-chromo. These antibodies recognize several chromosomal antigens with apparent molecular mass of between 23 and 25 kDa, as determined by immunoblots. Anti-chromo autoantibodies occur in 10–15% of sera from patients with anti-centromere antibodies (ACA). We used anti-chromo antibodies to screen a human expression library and obtained cDNA clones encoding a 25 kDa chromosomal autoantigen. DNA sequence analysis reveals this protein to be a human homologue of HP1, a heterochromatin protein of Drosophila melanogaster. We designate our cloned protein HP1Hs alpha. Epitope mapping experiments using both human and Drosophila HP1 reveal that anti-chromo antibodies target a region at the amino terminus of the protein. This region contains a conserved motif, the chromo domain (or HP1/Pc box), first recognized by comparison of Drosophila HP1 with the Polycomb gene product. Both proteins are thought to play a role in creating chromatin structures in which gene expression is suppressed. Anti-chromo thus defines a novel type of autoantibody that recognizes a conserved structural motif found on a number of chromosomal proteins.

Structure of the colcemid-treated PtK1 kinetochore outer plate as determined by high voltage electron microscopic tomography

High voltage electron microscopic tomography was used to determine the organization of the kinetochore plate and its attachment to the underlying chromosome. Six reconstructions were computed from thick sections of Colcemid-treated PtK1 cells and analyzed by a number of computer graphics methods including extensive thin slicing, three-dimensional masking, and volume rendering. When viewed en-face the kinetochore plate appeared to be constructed from a scaffold of numerous 10-20-nm thick fibers or rods. Although the fibers exhibited regions of parallel alignment and hints of a lattice, they were highly variable in length, orientation and spacing. When viewed in stereo, groups of these fibers were often seen oriented in different directions at different depths to give an overall matted appearance to the structure. When viewed "on edge," the plate was 35-40 nm thick, and in thin slices many regions were tripartite with electron-opaque domains, separated by a more translucent middle layer, forming the inner and outer plate boundaries. These domains were joined at irregular intervals. In some slices, each domain appeared as a linear array of 10-20-nm dots or rods embedded in a less electron-opaque matrix, and adjacent dots within or between domains often appeared fused to form larger blocks. The plate was connected to the underlying chromosome by less densely arrayed 10-20-nm thick fibers that contacted the chromosome-facing (i.e., inner) surface of the plate in numerous patches. These patches tended to be arrayed in parallel rows perpendicular to the long axis of the chromosome. In contrast to connecting fibers, corona fibers were more uniformly distributed over the cytoplasmic-facing (i.e., outer) surface of the plate. When large portions of the reconstructions were viewed, either en-face or in successive slices parallel to the long axis of the chromosome, the edges of the plate appeared splayed into multiple "fingers" that partly encircled the primary constriction. Together these observations reveal that regions of the kinetochore outer plate contain separate structural domains, which we hypothesize to serve separate functional roles. Our three-dimensional images of the kinetochore are largely consistent with the hypothesis that the outer plate is composed of multiple identical subunits (Zinkowski, R. P., J. Meyne, and B. R. Brinkley. 1991. J. Cell Biol. 113:1091-1110).

CENP-F is a .ca 400 kDa kinetochore protein that exhibits a cell-cycle dependent localization

We have identified a novel .ca 400 kDa cell-cycle dependent kinetochore associated protein in human cells, designated CENP-F, using human autoimmune serum. Immunofluorescence staining using the native serum, affinity purified antibodies, or antibodies raised against a cloned portion of CENP-F first reveals CENP-F homogeneously distributed throughout the nucleus of HeLa cells in the G2 stage of the cell cycle. Progression into prophase is accompanied by the localization of CENP-F to all the kinetochore regions of the karyotype. Kinetochore association is maintained throughout metaphase, but at the onset of anaphase CENP-F is no longer detected in association with the kinetochore but is found at the spindle mid-zone. By telophase, it is concentrated into a narrow band on either side of the midbody. Studies of the interaction of CENP-F with the kinetochore indicate that this protein associates with the kinetochore independent of tubulin and dissociation is dependent on events connected with the onset of anaphase. Nuclease digestion studies and immunoelectron-microscopy indicate that CENP-F is localized to the kinetochore plates and specifically to the outer surface of the outer kinetochore plate. The distribution of CENP-F closely parallels that of another high molecular weight kinetochore associated protein, CENP-E. Comparative studies indicate that there are antibodies in the CENP-F reactive autoimmune serum that recognize determinants present in the central helical rod domain of CENP-E. Immune depletion experiments confirm that CENP-F exhibits the distribution pattern in cells that was seen with the native autoimmune serum.

A human centromere protein, CENP-B, has a DNA binding domain containing four potential alpha helices at the NH2 terminus, which is separable from dimerizing activity

The alphoid DNA-CENP-B (centromere protein B) complex is the first sequence-specific DNA/protein complex detected in the centromeric region of human chromosomes. In the reaction, CENP-B recognizes a 17-bp sequence (CENP-B box) and assembles two alphoid DNA molecules into a complex, which is designated complex A (Muro, Y., H. Masumoto, K. Yoda, N. Nozaki, M. Ohashi, and T. Okazaki. 1992. J. Cell Biol. 116:585-596). Since CENP-B gene is conserved in mammalian species and CENP-B boxes are found also in mouse centromere satellite DNA (minor satellite), this sequence-specific DNA-protein interaction may be important for some kind of common centromere function. In this study we have characterized the structure of CENP-B and CENP-B-alphoid DNA complex. We have shown by chemical cross-linking that CENP-B formed a dimer, and have estimated by molecular weight determination the composition of complex A to be a CENP-B dimer and two molecules of alphoid DNA. The DNA binding domain has been delimited within the NH2-terminal 125-amino acid region containing four potential alpha-helices using truncated CENP-B made in Escherichia coli cells. We have shown that CENP-B had sites highly sensitive to proteases and that the DNA binding domain was separable from the dimerizing activity by the proteolytic cleavage at 20 kD from the COOH terminus of the molecule. Thus, CENP-B may organize a higher order structure in the centromere by juxtaposing two CENP-B boxes in the alphoid DNA repeat through both the DNA-protein and protein-protein interactions.

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.

Formation of primary constriction and heterochromatin in mouse does not require minor satellite DNA

Whereas the major satellite fraction in mouse extends its domain from the centromere to the distal end of the pericentric heterochromatin, the minor satellite DNA is present specifically in the centromere or primary constriction. We hybridized the biotinylated minor satellite sequence to L929 cells of mouse origin. The sequence hybridized to all chromosomes. Whereas hybridization was detected on all active centromeres, the inactive centromeres in certain dicentrics did not show any signal. This satellite, however, was detected in all inactive centromeres in a heptacentric chromosome. The intensity of fluorescence on the inactive centromeres of the heptacentric was similar to that present on the active centromeres. Several heterochromatin blocks, which were not associated with any centromere, were also found to lack hybridization with the minor satellite. The inactive centromeres, whether carrying the minor satellite DNA fraction or not, generally do not react with the antikinetochore antibodies present in the scleroderma serum. These studies are interpreted to show that (1) the primary constriction in mouse can be formed without the participation of minor satellite, (2) heterochromatin in mouse may constitute without this fraction, (3) the major and minor satellite may not be interspersed but are joined at some defined boundary, and (4) the binding of CENP-B does not depend upon the quantity of minor satellite or the number of CENP boxes present in the inactive centromeres.

Migration of centromere proteins in rabbit spermatids

Human autoantibodies were used to localize centromere proteins by immunoelectron microscopy, immunofluorescence, and confocal microscopy in isolated cells and in cryosections of rabbit testis. A computer-assisted three-dimensional reconstruction of the positions and sizes of fluorescent spots allowed us to follow their movements during the different phases of spermiogenesis. In very young spermatids, the centromeres were distributed within a space separated from both the external nuclear limits and the nuclear core. They moved towards the nuclear center in cap phase spermatids, where they clustered into a few large centromeric masses. In preelongating spermatids, the immunolabeled proteins were dispersed within an equatorial area, where they formed one large mass. In late spermatids, the mass moved towards the posterior part of the nucleus, and, in the spermatozoon, the two basal knobs located at the base of the nuclei were the only strongly immunolabeled structures, while no labeling of the main part of the nucleus was observed. Since the number of centromeres remained close to the number of chromosomes until the cap phase of spermatid differentiation, we hypothesize that the labeling of young spermatids corresponds to centrometric proteins associated with their specific DNA counterparts, while the centromere proteins, possibly detached from their DNA loci, were released from nuclei of old spermatids in the same way as are histones and transition proteins.