Neo-centromere formation on a 2.6 Mb mini-chromosome in DT40 cells

We describe a mammalian artificial mini-chromosome lacking human alphoid DNA and mouse minor and major satellite DNA repeats. This mini-chromosome, initially recovered in a mouse embryonic stem (ES) cell line (CGR8), is 2.6 Mb in size and consists of sequences derived from the human Y chromosome and mouse chromosomes 12 and 15. It is not stable in the CGR8 cells but replicates and segregates with high fidelity after transfer into chicken DT40 cells. Combined analysis by immunocytochemistry/fluorescence in situ hybridisation (FISH) on metaphase spreads detected an active neo-centromere on the mini-chromosome in these cells. Further analysis by immunocytochemistry/FISH on stretched chromatin allowed the localisation of the CENP-C protein to the DNA sequence derived from interval 5 of the human Y chromosome.     

The accuracy of segregation of human mini-chromosomes varies in different vertebrate cell lines, correlates with the extent of centromere formation and provides evidence for a trans-acting centromere maintenance activity

We show that the accuracy of mitotic segregation of three engineered, mapped human mini-chromosomes differs between human, mouse and chicken cell lines. We have studied the cause of these differences by analysing the extent of centromere formation on one mini-chromosome immunocytochemically. In human and chicken cell lines the mini-chromosomes segregate accurately and form centromeres but in one mouse cell line centromere formation is undetectable and mitotic segregation is inaccurate. These results indicate that the centromere is maintained by an activity that functions in trans and varies either in amount or specificity between different cells. Structurally defined mini-chromosomes may allow this activity to be studied.     

Replication of yeast DNA and novel chromosome formation in mouse cells.

To determine whether yeast DNA can replicate or segregate in mammalian cells, we have transferred genomic DNA from the yeast Saccharomyces cerevisiae into mouse cells. Most of the lines contained stably integrated yeast DNA. However, in two of the lines, the yeast DNA was maintained as numerous small extrachromosomal elements which were still present after 26 cell divisions in selection but which were lost rapidly out of selection. This indicates that, although yeast DNA can replicate in mouse cells, the yeast centromere does not function to give segregation. In one cell line we observed a large novel chromosome consisting almost entirely of yeast DNA. This chromosome segregates well and contains mouse centromeric minor satellite DNA and variable amounts of major satellite DNA which probably comprise the functional centromere. The yeast DNA in the novel chromosome has a compacted chromatin structure which may be responsible for the efficient formation of anaphase bridges. Furthermore, yeast DNA integrated into mouse chromosomes forms constrictions at the point of integration. These features have previously been presumed to be hallmarks of centromeric function in transfection assays aimed at identifying putative centromeric DNA. Hence our results suggest caution be exercised in the interpretation of such assays.     

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.     

Restriction enzyme banding of mouse metaphase chromosomes

Fixed metaphase chromosomes from mouse strain RIII embryos or A9 cells were treated with a restriction endonuclease, followed by Giemsa staining. Aha I, Hinf I, or Mbo I treatment produced a C-band pattern, and Eco RII or Hae III produced a G-band plus C-band pattern. Ava II and Bst NI each produced a G-band pattern, but on most chromosomes only a small segment of each C-band, adjacent to the centromere, was stained. These tiny residual C-bands may contain a minor satellite located adjacent to the major satellite clusters.     

Lack of detectable kinetochores on some chromosomes in mouse x human hybrids.

When treated with an anti-kinetochore antibody present in the sera of scleroderma (var. CREST) patients, most chromosomes exhibit kinetochore dots at the position of the centromere. In this paper we report that some chromosomes in the mouse x human somatic cell hybrid fail to show these dots. In the early passages in a hybrid, HYG-1, the frequency of such chromosomes was higher (0.85%) than in later passages (0.45%) studied after five months of continuous culturing. In parallel, the mean number of human chromosomes in the hybrid also dropped. The somewhat hypodiploid parental cell lines, when similarly treated, showed only a rare chromosome without kinetochore dots. Immunoblots of the proteins showed that the sera used for kinetochore detection recognized all major centromere proteins (CENPs). Electron microscopy of some offlying metaphase chromosomes in another hybrid, HR61, exhibited a lack of trilamellar kinetochores. This study suggests that akinetochoric chromosomes might provide a novel mechanism responsible for chromosome loss and genesis of aneuploidy. In early passages, some cells in the hybrid showed detached kinetochores. These autonomous kinetochores could be seen in clusters and involved some mouse chromosomes also. Potential significance of these autonomous kinetochores in generating compound centromeres is discussed.     

An unpaired mouse centromere passes consistently through male meiosis and does not significantly compromise spermatogenesis

ST1 is an artificial mini-chromosome approximately 4.5 Mb in size containing mouse minor and major satellite DNA, human alphoid DNA and sequences derived from interval 5 of the human Y chromosome. Here we have measured the mitotic and meiotic transmission of ST1 and have used the mini-chromosome to define the ability of mice to monitor the presence of unpaired centromeres during meiosis. ST1 is mitotically stable, remaining intact and autonomous in mice for many generations. Female mice efficiently transmit ST1 to their offspring at a frequency approaching 50%. Male mice also reliably transmit the mini-chromosome, though to only 20% of their offspring. Presence of ST1 in males is not associated with any compromise in the output of the seminiferous epithelium nor with histological or immunocytochemical evidence of increased apoptosis, outcomes predicted for a synapsis checkpoint. These data indicate that the presence of an unpaired centromere is not sufficient to arrest male meiosis, implying that univalents are normally eliminated by a mechanism other than a tension-sensitive spindle checkpoint.P.J. Mee and M.M. Shen contributed equally to this article     

Isolation and characterization of a mouse subtelomeric sequence

A mouse subtelomeric sequence, ST1, was generated from genomic DNA of the mouse HR9 (129/Sv origin) cell line by the polymerase chain reaction (PCR) using a single telomeric primer. ST1 was cloned and characterized: it is composed of 670 bp of novel DNA sequence flanked on each end by inverted telomeric hexanucleotide repeats (TTAGGG)_n. PCR amplification from BALB/c mouse DNA using this single primer gave the same major product. Southern analysis and PCR using internal ST1 primers confirmed that the ST1 sequence is present in mouse genomic DNA. In situ hybridization to metaphase chromosomes of SJL origin mapped ST1 to many, if not every, mouse telomere. PCR experiments using different combinations of the telomeric, minor satellite, and ST1 primers indicated that some ST1 copies are adjacent to minor satellite sequences, that telomeric and ST1 sequences are not generally interspersed with minor satellite sequences,and that ST1 and the minor satellite have a consistent and specific orientation relative to each other and to the telomere.by H.F. Willard     

Sequence of centromere separation: characterization of multicentric chromosomes in a rat cell line

The B₁ cell line of rat cerebral endothelium origin exhibits several dicentric and multicentric chromosomes. These chromosomes, unlike multicentrics in mouse (Vig and Zinkowski 1986) do not show premature centromere separation. All centromeres deposit kinetochore proteins and appear to be functional. Even the centromeres which fail to migrate to the poles during anaphase and make side arm bridges bind to spindle microtubules. Some multicentric chromosomes show kinetochores spaced apart with intervening stretches of euchromatin while others are located adjacent to each other thus exhibiting tandem repeats and forming a compound kinetochore (Brinkeley et al. 1984). Also, unlike mouse multicentric chromosomes in which different pericentric regions and the centromeres replicate at different times, the rat chromosomes appear to replicate all pericentric and centric regions in a given multicentric simultaneously. The present studies indicate that centromeres in rat and mouse replicate during the last part of the S-phase and in continuation with the pericentric heterochromatin.     

Selective digestion of mouse metaphase chromosomes

Metaphase chromosomes prepared from colcemid-treated mouse L929 cells by non-ionic detergent lysis exhibit distinct heterochromatic centromere regions and associated kinetochores when viewed by whole mount electron microscopy. Deoxyribonuclease I treatment of these chromosomes results in the preferential digestion of the chromosomal arms leaving the centromeric heterochromatin and kinetochores apparently intact. Enrichment in centromere material after DNase I digestion was quantitated by examining the increase in 10,000xg pellets of the 1.691 g/cc satellite DNA relative to main band DNA. This satellite species has been localized at the centromeres of mouse chromosomes by in situ hybridization. From our analysis it was determined that DNase I digestion results in a five to six-fold increase in centromeric material. In contrast to the effect of DNase I, micrococcal nuclease was found to be less selective in its action. Digestion with this enzyme solubilized both chromosome arms and centromeres leaving only a small amount of chromatin and intact kinetochores.     

Isolation of a variant family of mouse minor satellite DNA that hybridizes preferentially to chromosome 4

Two cosmids (HRS-1 and HRS-2) containing mouse minor satellite DNA sequences have been isolated from a mouse genomic library. In situ hybridization under moderate stringency conditions to metaphase chromosomes from RCS-5, a tumor cell line derived from the SJL strain, mapped both HRS-1 and HRS-2 to the centromeric region of chromosome 4. Sequence data indicate that these cloned minor satellite DNA sequences have a basic higher order repeat of 180 bp, composed of three diverged 60-bp monomers. Digestion of mouse genomic DNA with several restriction enzymes produces a ladder of minor satellite fragments based on a 120-bp repeat. The restriction enzyme NlaIII (CATG) digests all the minor satellite DNA into three prominent bands of 120, 240, and 360 bp and a weak band of 180 bp. Thus, the majority of minor satellite sequences in the genome are arranged in repeats based on a 120-bp dimer, while the family of minor satellite sequences described here represents a rare variant of these sequences. Our results raise the possibility that there may be other variant families of minor satellites analogous to those of alphoid DNA present in humans.     

High-resolution organization of mouse centromeric and pericentromeric DNA

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

Differential stability of a human mini-chromosome in mouse cell lines

A 4 Mb human mini-chromosome, ΔΔ2, was transferred from Chinese hamster ovary (CHO) cells into a mouse L cell line. The mini-chromosome could be transferred intact into the L cells, with 112/119 clones maintaining a mini-chromosome of the same size as the original. Ten clones were grown for 30 days in continuous culture. The mini-chromosomes were maintained stably with or without selection at a copy number of 1–2 per cell and none experienced any size alterations, as determined by pulsed-field gel electrophoresis. Thus ΔΔ2 is structurally and mitotically stable in L cells. This contrasts with results in embryonic stem cells, in which ΔΔ2 is highly unstable. These findings indicate that established somatic cell lines, such as L cells and CHO cells, have less stringent controls over centromeric function than do normal embryonic cells. Received: 4 December 1997; in revised form: 25 February 1998 / Accepted: 14 April 1998     

High-resolution organization of mouse telomeric and pericentromeric DNA

We studied the organization of telomeric, major and minor satellite DNA sequences located in the pericentromeric regions of mouse telocentric and Robertsonian metacentric chromosomes by high-resolution fluorescence in situ hybridization. Molecular data have already proved that in telocentrics, from the physical chromosome end, telomeric sequences are followed by minor and then by major satellite DNA. We showed that the three families of repetitive DNA are organized as uninterrupted long-range cluster repeats and that there is no intermingling between telomeric and minor satellite DNA or between the major and the minor tandem repeats or with non-satellite DNA. The pericentromeric region of metacentric chromosomes consists of a small block of minor satellite DNA sandwiched between two blocks of major satellite DNA.     

Sequence organization and cytological localization of the minor satellite of mouse.

A complete 120 bp genomic consensus sequence for the mouse minor satellite has been determined from enriched L929 centromeric sequences. The extensive sequence homology existing between the major and minor satellite suggests an evolutionary relationship. Some sequences flanking the minor satellite has also been identified and they provide insight into centromeric DNA organization. Isotopic in situ hybridization analysis of the minor satellite to mouse L929 and Mus musculus metaphase spreads showed that this repetitive DNA class is localized specifically to centromeres of all chromosomes of the karyotype. With the use of high resolution non-isotopic fluorescence in situ hybridization the minor satellite is further localized to the outer surface of the centromere in a discrete region at or immediately adjacent to the kinetochore. Our cytological data suggests that the minor satellite might play a role in the organization of the kinetochore region rather than, as previously suggested, sites for general anchoring of the genome to the nuclear matrix.     

DNA repeat arrays in chicken and human genomes and the adaptive evolution of avian genome size

Background

Birds have smaller average genome sizes than other tetrapod classes, and it has been proposed that a relatively low frequency of repeating DNA is one factor in reduction of avian genome sizes.

Results

DNA repeat arrays in the sequenced portion of the chicken (Gallus gallus) autosomes were quantified and compared with those in human autosomes. In the chicken 10.3% of the genome was occupied by DNA repeats, in contrast to 44.9% in human. In the chicken, the percentage of a chromosome occupied by repeats was positively correlated with chromosome length, but even the largest chicken chromosomes had repeat densities much lower than those in human, indicating that avoidance of repeats in the chicken is not confined to minichromosomes. When 294 simple sequence repeat types shared between chicken and human genomes were compared, mean repeat array length and maximum repeat array length were significantly lower in the chicken than in human.

Conclusions

The fact that the chicken simple sequence repeat arrays were consistently smaller than arrays of the same type in human is evidence that the reduction in repeat array length in the chicken has involved numerous independent evolutionary events. This implies that reduction of DNA repeats in birds is the result of adaptive evolution. Reduction of DNA repeats on minichromosomes may be an adaptation to permit chiasma formation and alignment of small chromosomes. However, the fact that repeat array lengths are consistently reduced on the largest chicken chromosomes supports the hypothesis that other selective factors are at work, presumably related to the reduction of cell size and consequent advantages for the energetic demands of flight.     

CENP-B is a highly conserved mammalian centromere protein with homology to the helix-loop-helix family of proteins

CENP-B is a centromere associated protein originally identified in human cells as an 80 kDa autoantigen recognized by sera from patients with anti-centromere antibodies (ACA). Recent evidence indicates that CENP-B interacts with centromeric heterochromatin in human chromosomes and may bind to a specific subset of human alphoid satellite DNA. CENP-B has not been unambiguously identified in non-primates and could, in principal, be a primate-specific alphoid DNA binding protein. In this work, a human genomic DNA segment containing the CENP-B gene was isolated and subjected to DNA sequence analysis. In vitro expression identified the site for translation initiation of CENP-B, demonstrating that it is encoded by an intronless open reading frame (ORF) in human DNA. A homologous mouse gene was also isolated and characterized. It was found to possess a high degree of homology with the human gene, containing an intronless ORF coding for a 599 residue polypeptide with 96% sequence similarity to human CENP-B. 5 and 3 flanking and untranslated sequences were conserved at a level of 94.6% and 82.7%, respectively, suggesting that the regulatory properties of CENP-B may be conserved as well. CENP-B mRNA was detected in mouse cells and tissues and an immunoreactive nuclear protein identical in size to human CENP-B was detected in mouse 3T3 cells using human ACA. Analysis of the sequence of CENP-B revealed a segment of significant similarity to a DNA binding motif identified for the helix-loop-helix (HLH) family of DNA binding proteins. These data demonstrate that CENP-B is a highly conserved mammalian protein that may be a member of the HLH protein family and suggest that it plays a role in a conserved aspect of centromere structure or function.     

Sequence of centromere separation: Separation in a quasi-stable mouse-human somatic cell hybrid

A quasi-stable mouse-human hybrid cell line, HR61, containing between one and ten human chromosomes was analyzed for the sequence of centromere separation. The purpose was to determine which genome of the two initiates centromere separation first. The data clearly indicate that the separation of centromeres of the human genome is not only initiated but is completed before any centromeres from the mouse chromosomes start splitting into daughter units. The information on whether uniparental chromosome loss results from a lack of deposition of kinetochore proteins was equivocal. The human genome also completes its DNA replication before the mouse genome does. Our studies, therefore, show that the timing of centromere separation is tightly linked to the completion of replication of DNA. At least in this cell line the segregant genome is not the one which exhibits delayed DNA replication.