Mouse satellite DNA, centromere structure, and sister chromatid pairing

Epigenetics and Heart Development

Epigenetic control of gene expression during cardiac development and disease has been a topic of intense research in recent years. Advances in experimental methods to study DNA accessibility, transcription factor occupancy, and chromatin conformation capture technologies have helped identify regions of chromatin structure that play a role in regulating access of transcription factors to the promoter elements of genes, thereby modulating expression. These chromatin structures facilitate enhancer contacts across large genomic distances and function to insulate genes from cis-regulatory elements that lie outside the boundaries for the gene of interest. Changes in transcription factor occupancy due to changes in chromatin accessibility have been implicated in congenital heart disease. However, the factors controlling this process and their role in changing gene expression during development or disease remain unclear. In this review, we focus on recent advances in the understanding of epigenetic factors controlling cardiac morphogenesis and their role in diseases.

High-throughput analysis of satellite DNA in the grasshopper Pyrgomorpha conica reveals abundance of homologous and heterologous higher-order repeats

Satellite DNA (satDNA) constitutes an important fraction of repetitive DNA in eukaryotic genomes, but it is barely known in most species. The high-throughput analysis of satDNA in the grasshopper Pyrgomorpha conica revealed 87 satDNA variants grouped into 76 different families, representing 9.4% of the genome. Fluorescent in situ hybridization (FISH) analysis of the 38 most abundant satDNA families revealed four different patterns of chromosome distribution. Homology search between the 76 satDNA families showed the existence of 15 superfamilies, each including two or more families, with the most abundant superfamily representing more than 80% of all satDNA found in this species. This also revealed the presence of two types of higher-order repeats (HORs), one showing internal homologous subrepeats, as conventional HORs, and an additional type showing non-homologous internal subrepeats, the latter arising by the combination of a given satDNA family with a non-annotated sequence, or with telomeric DNA. Interestingly, the heterologous subrepeats included in these HORs showed higher divergence within the HOR than outside it, suggesting that heterologous HORs show poor homogenization, in high contrast with conventional (homologous) HORs. Finally, heterologous HORs can show high differences in divergence between their constituent subrepeats, suggesting the possibility of regional homogenization.

A link between repetitive sequences and gene replication time

Genes display a wide range of replication times in S phase. In general, late replication is associated with transcriptionally repressive states and early replication with transcriptional competence. Rare examples of early-replicating repressive states have also been identified that are consistent with molecular evidence that repressive states are not all uniform in nature. Here we show that the replication times of over 4000 Drosophila genes correlate with the abundance of repetitive sequences in approximately 200-kb regions flanking the genes. In particular, Satellite-Related sequences (SRs) and the simple sequence repeats (SSRs) (CA)n and (ACTG)n were increasingly abundant in the regions flanking progressively later replicating genes, while (CATA)n repeats were more abundant around earlier replicating genes. These four sequences comprise less than 0.5% of the 'euchromatic genome' in Drosophila, yet they account for 5% of the variation of gene replication timing. Although the effect is not strong, it is broad: 99% of the genome is within the region of correlation of at least one of the above repeats. The role of SSRs and non-centromeric SRs in the genome is not known. We propose that SSRs and SRs foster transcriptionally repressive states throughout the genome in order to minimize spurious transcription.

At the interface between signaling and executing anaphase--Cdc14 and the FEAR network

Anaphase is the stage of the cell cycle when the duplicated genome is separated to opposite poles of the cell. The irreversible nature of this event confers a unique burden on the cell and it is therefore not surprising that the regulation of this cell cycle stage is complex. In budding yeast, a signaling network known as the Cdc fourteen early anaphase release (FEAR) network and its effector, the protein phosphatase Cdc14, play a key role in the coordination of the multiple events that occur during anaphase, such as partitioning of the DNA, regulation of spindle stability, activation of microtubule forces, and initiation of mitotic exit. These functions of the FEAR network contribute to genomic stability by coordinating the completion of anaphase and the execution of mitotic exit.

A PIT-1 homeodomain mutant blocks the intranuclear recruitment of the CCAAT/enhancer binding protein alpha required for prolactin gene transcription

The pituitary-specific homeodomain protein Pit-1 cooperates with other transcription factors, including CCAAT/enhancer binding protein alpha (C/EBPalpha), in the regulation of pituitary lactotrope gene transcription. Here, we correlate cooperative activation of prolactin (PRL) gene transcription by Pit-1 and C/EBPalpha with changes in the subnuclear localization of these factors in living pituitary cells. Transiently expressed C/EBPalpha induced PRL gene transcription in pituitary GHFT1-5 cells, whereas the coexpression of Pit-1 and C/EBPalpha in HeLa cells demonstrated their cooperativity at the PRL promoter. Individually expressed Pit-1 or C/EBPalpha, fused to color variants of fluorescent proteins, occupied different subnuclear compartments in living pituitary cells. When coexpressed, Pit-1 recruited C/EBPalpha from regions of transcriptionally quiescent centromeric heterochromatin to the nuclear regions occupied by Pit-1. The homeodomain region of Pit-1 was necessary for the recruitment of C/EBPalpha. A point mutation in the Pit-1 homeodomain associated with the syndrome of combined pituitary hormone deficiency in humans also failed to recruit C/EBPalpha. This Pit-1 mutant functioned as a dominant inhibitor of PRL gene transcription and, instead of recruiting C/EBPalpha, was itself recruited by C/EBPalpha to centromeric heterochromatin. Together our results suggest that the intranuclear positioning of these factors determines whether they activate or silence PRL promoter activity.

Centromeres become unstuck without heterochromatin

In most if not all eukaryotes, sister-chromatid cohesion, which is mediated by the chromosomal complex Cohesin, is destroyed by proteolysis at the transition from metaphase to anaphase. In metazoans, Cohesin is removed from chromosomes in two steps, and the centromere and its associated pericentric heterochromatin constitute the last point of linkage between sister chromatids at metaphase. Mechanistic insight is now emerging on the way in which cells distinguish cohesion at the centromere from cohesion along chromosome arms. We discuss recent advances in our understanding of the role of centromeric heterochromatin in sister-chromatid cohesion and propose a causal relationship between this specialized type of chromatin and the removal by proteolysis of Cohesins that are associated with it.

New insights into host factor requirements for prokaryotic beta-recombinase-mediated reactions in mammalian cells

The prokaryotic beta-recombinase catalyzes site-specific recombination between two directly oriented minimal six sites in mammalian cells, both on episomic and chromatin-integrated substrates. Using a specific recombination activated gene expression system, we report the site-specific recombination activity of an enhanced green fluorescent protein (EGFP) fused version of beta-recombinase (beta-EGFP). This allows expression of active beta-recombinase detectable in vivo and in fixed cells by fluorescence microscopy. In addition, cellular viability is compatible with a substantial level of expression of the beta-EGFP protein. Using fluorescence-activated cell sorting, we have been able to enrich cell populations expressing this fusion protein. Application of this strategy has allowed us to study in more depth the host factor requirements for this system. Previous work showed that eukaryotic HMG1 protein was necessary and sufficient to help beta-recombinase activity in vitro. The influence of ectopic expression of HMG1 protein in the recombination process has been analyzed, indicating that HMG1 overexpression does not lead to a significant increase on the efficiency of beta-recombinase-mediated recombination both on episomal substrates and chromatin-associated targets. In addition, beta-recombinase-mediated recombination has been demonstrated in HMG1 deficient cells at the same levels as in wild type cells. These data demonstrate the existence of cellular factors different from HMG-1 that can act as helpers for beta-recombinase activity in the eukaryotic environment.

Splitting the chromosome: cutting the ties that bind sister chromatids

In eukaryotic cells, sister DNA molecules remain physically connected from their production at S phase until their separation during anaphase. This cohesion is essential for the separation of sister chromatids to opposite poles of the cell at mitosis. It also permits chromosome segregation to take place long after duplication has been completed. Recent work has identified a multisubunit complex called cohesin that is essential for connecting sisters. Proteolytic cleavage of one of cohesin's subunits may trigger sister separation at the onset of anaphase.

Pattern of chromosomal localization of the Hoppel transposable element family in the Drosophila melanogaster subgroup

We have isolated a Hoppel-like transposon from heterochromatin of the second chromosome of Drosophila melanogaster and used a conserved DNA sequence between the different elements of this family to determine their distribution in both mitotic and polytene chromosomes. The hybridization pattern of polytene chromosomes extends throughout the entire chromocentre, as well as a substantial portion of the fourth chromosome. Analysis of different wild-type strains of D. melanogaster shows variation in euchromatic insertion sites, although most insertions are found near the chromocentre. The positions and the number of heterochromatic clusters of Hoppel on mitotic chromosomes are conserved among the several strains analysed. Accurate mapping of this element was achieved by in situ hybridization on D. melanogaster mitotic chromosomes that had previously been banded with Hoechst 33258. To evaluate the evolutionary stability of this pattern, different species were analysed by in situ hybridization and Southern blotting. We conclude that Hoppel has a conserved distribution in mitotic heterochromatin within the D. melanogaster subgroup, established around 5 million years ago. The overall conservation of heterochormatic organization supports the notion that heterochormatin does perform important structural and functional roles.

A direct link between sister chromatid cohesion and chromosome condensation revealed through the analysis of MCD1 in S. cerevisiae

The S. cerevisiae MCD1 (mitotic chromosome determinant) gene was identified in genetic screens for genes important for chromosome structure. MCD1 is essential for viability and homologs are found from yeast to humans. Analysis of the mcd1 mutant and cell cycle-dependent expression pattern of Mcd1p suggest that this protein functions in chromosome morphogenesis from S phase through mitosis. The mcd1 mutant is defective in sister chromatid cohesion and chromosome condensation. The physical association between Mcd1p and Smc1p, one of the SMC family of chromosomal proteins, further suggests that Mcd1p functions directly on chromosomes. These data implicate Mcd1p as a nexus between cohesion and condensation. We present a model for mitotic chromosome structure that incorporates this previously unsuspected link.

A cereal centromeric sequence

We report the identification of a family of sequences located by in situ hybridisation to the centromeres of all the Triticeae chromosomes studied, including the supernumerary and midget chromosomes, the centromeres of all maize chromosomes and the heterochromatic regions of rice chromosomes. This family of sequences (CCS1), together with the cereal genome alignments, will allow the evolution of the cereal centromeres and their sites to be studied. The family of sequences also shows homology to the CENP-B box. The centromeres of the cereal species and the proteins that interact with them can now be characterised.

Islands of complex DNA are widespread in Drosophila centric heterochromatin

Heterochromatin is a ubiquitous yet poorly understood component of multicellular eukaryotic genomes. Major gaps exist in our knowledge of the nature and overall organization of DNA sequences present in heterochromatin. We have investigated the molecular structure of the 1 Mb of centric heterochromatin in the Drosophila minichromosome Dp1187. A genetic screen of irradiated minichromosomes yielded rearranged derivatives of Dp1187 whose structures were determined by pulsed-field Southern analysis and PCR. Three Dp1187 deletion derivatives and an inversion had one breakpoint in the euchromatin and one in the heterochromatin, providing direct molecular access to previously inaccessible parts of the heterochromatin. End-probed pulsed-field restriction mapping revealed the presence of at least three "islands" of complex DNA, Tahiti, Moorea, and Bora Bora, constituting approximately one half of the Dp1187 heterochromatin. Pulsed-field Southern analysis demonstrated that Drosophila heterochromatin in general is composed of alternating blocks of complex DNA and simple satellite DNA. Cloning and sequencing of a small part of one island, Tahiti, demonstrated the presence of a retroposon. The implications of these findings to heterochromatin structure and function are discussed.

Localization of centromere function in a Drosophila minichromosome

The DNA elements responsible for centromere activity in a metazoan have been localized using the Drosophila minichromosome Dp1187. Deleted minichromosomes were generated by irradiation mutagenesis, and their molecular structures were determined by pulsed-field Southern blot analysis. Analyses of the transmission behavior of Dp1187 derivatives localized sequences necessary for chromosome inheritance within the centric heterochromatin. The essential core of the centromere is contained within a 220 kb region that includes significant amounts of complex DNA. Completely normal inheritance also requires approximately 200 kb on either side of the essential core. This flanking DNA predominantly contains highly repeated sequences, and the amount required for normal transmission differs among division types and between the sexes. We propose that the essential core is the site of kinetochore formation and that flanking DNA provides two functions: sister chromatid cohesion and indirect assistance in kinetochore formation or function.

Transposable elements map in a conserved pattern of distribution extending from beta-heterochromatin to centromeres in Drosophila melanogaster

In situ hybridisation to mitotic chromosomes shows that sequences homologous to different Drosophila melanogaster transposable elements are widely distributed not only in beta but also in alpha-heterochromatin. Clusters of these sequences are detected in most proximal positions. They colocalise with known satellite sequences in several regions, but are also located in places where no known sequence has been mapped so far. The pattern of hybridisation is dinstinctive and specific for each element, and presents constant features in six different D. melanogaster strains studied. The entirely heterochromatic Y chromosome contains large amounts of these sequences. Additionally, some of these sequences appear to be present in substantial quantities in the smallest minichromosome of Drosophila, Dp(1;f)1187.

Characterization of a new family of tobacco highly repetitive DNA, GRS, specific for the Nicotiana tomentosiformis genomic component

Members of a new family of highly repetitive DNA sequences called GRS were isolated from Nicotiana tabacum L. genomic DNA and characterized. Cloned, sequenced monomeric units (180-182 bp) of GRS exhibit properties characteristic of molecules that possess a stable curvature. The GRS family represents about 0.15% of total genomic DNA (10(4) copies per haploid genome) and could be derived from either Nicotiana tomentosiformis or Nicotiana otophora, two possible ancestors of the T genome of the amphidiploid N. tabacum. Sequence homology between the HRS60 (Koukalová et al. 1989) and the GRS family has been estimated to be 57%. In situ hybridization was used to localize GRS on mitotic chromosomes. Hybridization signals were obtained on five pairs of chromosomes at intercalary sites of the longer chromosome arms. The majority of GRS sequences appeared to be organized in tandem arrays and a minority were found to be dispersed through the genome in short clusters, interspersed with other types of DNA repeats, including 25S rDNA sequences. Several loci containing both GRS and HRS60 were also found. Such hybrid loci may indicate intergenomic transfer of the DNA in the amphidiploid N. tabacum. GRS sequences, like HRS60 (Fajkus et al. 1992), were found to specify the location of nucleosomes. The position of the nucleosome core has been mapped with respect to a conserved Mbol site in the GRS sequence and an oligo A/T tract is a major centre of the DNA curvature.

Interactions between the nod+ kinesin-like gene and extracentromeric sequences are required for transmission of a Drosophila minichromosome

In this study, we demonstrate a role for extracentromeric sequences in chromosome inheritance. Genetic analyses indicate that transmission of the Drosophila minichromosome Dp1187 is sensitive to the dosage of nod+, a kinesin-like gene required for the meiotic transmission of achiasmate chromosomes. Minichromosome deletions displayed increased loss rates in females heterozygous for a loss-of-function allele of nod (nod/+). We have analyzed the structures of nod-sensitive deletions and conclude that multiple regions of Dp1187 interact genetically with nod+ to promote normal chromosome transmission. Most nod+ interactions are observed with regions that are not essential for centromere function. We propose that normal chromosome transmission requires forces generated outside the kinetochore, perhaps to maintain tension on kinetochore microtubules and stabilize the attachment of achiasmate chromosomes to the metaphase spindle.

DNA curvature of the tobacco GRS repetitive sequence family and its relation to nucleosome positioning

Recently, a highly repetitive DNA sequence family (GRS) from tobacco was described in our laboratory. These sequences were found to be localized predominantly in the pericentromeric heterochromatin of tobacco chromosomes. To test the hypothesis that these sequences play an important role in the formation of heterochromatin, we investigated the DNA curvature of the GRS sequences and its possible impact to the chromatin structure at these loci. Application of the nearest-neighbour wedge model of intrinsic DNA curvature for the GRS1 family member predicted two loci of curvature: a major bend at the 5' end of the sequence and a minor bend of opposite direction at the centre of the GRS1. The presence of the major and the minor loci of DNA curvature was studied experimentally using permutation analysis and site-directed mutagenesis. The experimental results were consistent with the computer predictions. We gave evidence that the described DNA curvature is also present in the entire GRS family. Genomic statistical sequencing showed the conservation of the major bend sequence determinants in the members of the GRS family. To investigate the chromatin structure at the GRS sequences, we determined the nucleosome positioning in vivo at these sequences using thermal cycle primer extension. A relation between the curvature pattern and the histone octamer position was observed: the major bend is excluded from the nucleosome surface to the linker region, while the minor bend is distributed along the core DNA. The suggestion is made that the sequences in the minor locus of curvature define the rotational setting of the nucleosome, and a possible role of the major bend as a factor, which defines the translational setting, is discussed.

Characterization of a family of tandemly repetitive DNA sequences from the fern sawfly, Strongylogaster osmundae (Hymenoptera: Tenthredinidae)

A family of repetitive DNA sequences in the genome of the sawfly, Strongylogaster osmundae (Hymenoptera: Tenthredinidae) was characterized. The family consists of a tandemly arranged array whose basic repeat unit is 1.0 kb. According to the compositions and arrangements of bases, the basic repeat unit can be divided into three distinct domains. Three domains share nucleotide sequence homology of 88, 74 and 89%, respectively, between members in this family. Second domain which had lower homology with the other two domains was found characteristically rich with polypurine/polypyrimidine sequences.

A rosy future for heterochromatin

The demonstration by Zhang and Spradling (1) of efficient P element transposition into heterochromatic regions will aid ongoing studies of heterochromatin structure and function. P element insertions will provide entry points for further molecular analysis of heterochromatin and will allow the isolation of small and large heterochromatic deficiencies. The generation of heterochromatic P insertions also will aid the study of heterochromatic genes. Of the heterochromatic insertions isolated by Zhang and Spradling, five were homozygous lethal, and one of these defined a lethal locus not previously uncovered by heterochromatic deficiencies. P elements have previously been used to mutagenize and clone specific heterochromatic genes (14, 19, 26). New methods, like those described here (1, 32), should allow the efficient identification and molecular isolation of other single-copy heterochromatic genes. Furthermore, since position-effect suppression allowed the recovery of heterochromatic P insertions, it may also allow the recovery of insertions in euchromatic regions previously refractory to P mutagenesis. Studies of position-effect variegation show that genes normally found in heterochromatin require a heterochromatic context for normal expression and that heterochromatin is inhibitory to euchromatic gene expression (16). The physical basis of these related phenomena--chromatin assembly, nuclear positioning, and/or heterochromatin elimination--can be resolved only with a more thorough understanding of heterochromatin structure and functions. Analyzing heterochromatin also will help define the chromosomal components responsible for inheritance processes such as chromosome pairing, sister chromatid adhesion, and centromere function. These efforts will be facilitated by the effective use of P elements combined with other current molecular-genetic approaches.

Chromosome condensation and sister chromatid pairing in budding yeast

We have developed a fluorescent in situ hybridization (FISH) method to examine the structure of both natural chromosomes and small artificial chromosomes during the mitotic cycle of budding yeast. Our results suggest that the pairing of sister chromatids: (a) occurs near the centromere and at multiple places along the chromosome arm as has been observed in other eukaryotic cells; (b) is maintained in the absence of catenation between sister DNA molecules; and (c) is independent of large blocks of repetitive DNA commonly associated with heterochromatin. Condensation of a unique region of chromosome XVI and the highly repetitive ribosomal DNA (rDNA) cluster from chromosome XII were also examined in budding yeast. Interphase chromosomes were condensed 80-fold relative to B form DNA, similar to what has been observed in other eukaryotes, suggesting that the structure of interphase chromosomes may be conserved among eukaryotes. While additional condensation of budding yeast chromosomes were observed during mitosis, the level of condensation was less than that observed for human mitotic chromosomes. At most stages of the cell cycle, both unique and repetitive sequences were either condensed or decondensed. However, in cells arrested in late mitosis (M) by a cdc15 mutation, the unique DNA appeared decondensed while the repetitive rDNA region appeared condensed, suggesting that the condensation state of separate regions of the genome may be regulated differently. The ability to monitor the pairing and condensation of sister chromatids in budding yeast should facilitate the molecular analysis of these processes as well as provide two new landmarks for evaluating the function of important cell cycle regulators like p34 kinases and cyclins. Finally our FISH method provides a new tool to analyze centromeres, telomeres, and gene expression in budding yeast.

Scanning electron microscopy of the centromeric region of L-cell chromosomes after treatment with Hoechst 33258 combined with 5-bromodeoxyuridine

When mouse L-cells were treated with a combination of 5-bromodeoxyuridine (BrdUrd) and Hoechst 33258, the metaphase chromosomes revealed under-condensation of the chromatin fibers in the sister centromeres. The application of the osmium-thiocarbohydrazide technique to the air-dried chromosome preparations made it possible to elucidate the ultrastructure of the under-condensed centromeric region at the level of the 30 nm chromatin fiber. Scanning electron microscopy revealed that the under-condensed region consisted of a coiled fiber with a diameter of about 400 nm, and a gyre diameter of approximately 600 nm. The coiled fiber was composed of the 30 nm chromatin fiber loops. These findings indicate that a continuous coiled structure, which is the final higher order structure of the condensed chromatin fiber, exists throughout the entire length of the mouse L-cell metaphase chromosome.

The DNA fragments produced by AluI and BstNI digestion of fixed mouse chromosomes

AluI and BstNI restriction endonucleases were used to study cytological and biochemical effects on centromere DNA in fixed mouse chromosomes. These enzymes were employed, as it is known that AluI is incapable of attacking major satellite DNA, contrary to BstNI that is known to cut this DNA fraction into monomers of 234 bp. After digestion in situ, electrophoretic analysis was carried out to characterize the DNA purified (1) from the material remaining on the chromosomes and (2) from the material solubilized from chromosomes. The DNA was then transferred to a nylon filter and 32P-labelled major satellite DNA was used as a probe for hybridization experiments. Other preparations were simply stained with Giemsa after digestion in situ with AluI and BstNI. Our results show that although restriction endonuclease cleavage primarily depends on DNA base sequence, this factor is not always sufficient to explain nuclease-induced cytological effects. In fact, the structural organization of peculiar regions such as the centromeres of mouse chromosomes might affect cleavage efficiency when restriction enzyme digestion is performed in situ.

Somatic instability of a Drosophila chromosome

A mitotically unstable chromosome, detectable because of mosaic expression of marker genes, was generated by X-ray mutagenesis in Drosophila. Nondisjunction of this chromosome is evident in mitotic chromosome preparations, and premature sister chromatid separation is frequent. The mosaic phenotype is modified by genetic elements that are thought to alter chromatin structure. We hypothesize that the mitotic defects result from a breakpoint deep in the pericentric heterochromatin, within or very near to the DNA sequences essential for centromere function. This unique chromosome may provide a tool for the genetic and molecular dissection of a higher eukaryotic centromere.

The evolution of meiosis

Meiosis is too complex to have arisen at once full blown and a stepwise scheme is proposed for its evolution, where each step is believed to have provided an immediate selective advantage: (1) The first step in this tentative sequence is the development of a haploidization process by means of a rapid series of mitotic non-disjunctions, turned on under conditions where haploidy is favored. The non-disjunctions may have resulted from a conditional mutation which caused sister centromere cohesiveness in the past mitotic metaphase. (2) Next probably came the formation of rudimentary synaptonemal complex type structures, first at Holliday-type configurations and later extending from these along chromosome pairs. These structures between homologues, though costly to produce and maintain, may have directly served the disjunctive function by setting the stage for the production of haploidy in one division, under conditions where it was advantageous. (3) Then secondarily acquired functions of the synaptonemal complex or structures associated with it may have promoted greatly increased crossover frequency, in part at least by increasing the frequency of the isomerization-type reaction. The resulting recombination of linked genes could have been advantageous under some conditions. (4) Finally, it is proposed that the capability was acquired for enhanced association of sister chromatids during the period between pachytene and anaphase I to give rise to chiasma-mediated disjunction, so that the relatively costly synaptonemal complex maintenance until anaphase I could be abandoned without losing disjunctive capability. It is implied that the modern synaptonemal complex is a structure which embodies a number of separately encoded proteins and that secondary structures and functions are associated with close homologue pairing. This scheme is based upon observable cytological and molecular characteristics of modern organisms.

Cytological and molecular characterization of centromeres in Mus domesticus and Mus spretus

We have applied EM in situ hybridization (EMISH) and pulsed field gel electrophoresis (PFGE) to samples from diploid primary cell cultures and an established cell line to examine in detail the relative organization of the major and minor satellite DNAs and telomere sequences in the genomes of Mus domesticus and Mus spretus. EMISH localizes the Mus domesticus minor satellite to a single site at the centromere-proximal end of each chromosome. Double label hybridizations with both minor satellite and telomere probes show that they are in close proximity and possibly are linked. In fact, PFGE of M. domesticus DNA digested with Sal I and Sfi I reveals the presence of fragments which hybridize to both probes and is consistent with the physical linkage of these two sequences. The M. domesticus minor satellite is the more abundant satellite in Mus spretus. Its distribution in M. spretus is characterized by diffuse labeling with no obvious concentration near chromosome ends. In addition to this repeat the M. spretus genome contains a small amount of DNA that hybridizes to a M. domesticus major satellite probe. Unlike the M. domesticus minor satellite, it is not telomere proximal but is confined to a domain at the border of the centromere and the long arm. Thus, although both species possess all three sequences, except for the telomeres, their distribution relative to one another is not conserved. Based on the results presented, we propose preliminary molecular maps of the centromere regions of Mus domesticus and Mus spretus.

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

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

Scanning electron microscopy of mammalian chromosomes from prophase to telophase

Changes in the morphology of human and murine chromosomes during the different stages of mitosis have been examined by scanning electron microscopy. Two important findings have emerged from this study. The first is that prophase chromosomes do not become split into pairs of chromatids until late prophase or early metaphase. This entails two distinct processes of condensation, the earlier one starting as condensations of chromosomes into chromomeres which then fuse to form a cylindrical body. After this cylindrical body has split in two longitudinally, further condensation occurs by mechanisms that probably include coiling of the chromatids as well as other processes. The second finding is that the centromeric heterochromatin does not split in two at the same time as the rest of the chromosome, but remains undivided until anaphase. It is proposed that the function of centromeric heterochromatin is to hold the chromatids together until anaphase, when they are separated by the concerted action of topoisomerase II acting on numerous similar sites provided by the repetitive nature of the satellite DNA in the heterochromatin. A lower limit to the size of blocks of centromeric heterochromatin is placed by the need for adequate mechanical strength to hold the chromatids together, and a higher limit by the necessity for rapid splitting of the heterochromatin at anaphase. Beyond these limits malsegregation will occur, leading to aneuploidy. Because the centromere remains undivided until anaphase, it cannot undergo the later stage of condensation found in the chromosome arms after separation into chromatids, and therefore the centromere remains as a constriction.

DNA sequence mapping using electron microscopy

DNA sequences can be mapped on chromosomes at high resolution in the electron microscope after hybridization with a nonisotopically labeled probe followed by detection with a two-step antibody reaction employing a colloidal gold tag. Hybridization probes can be modified with biotin-dUTP, digoxigenin-dUTP, dinitrophenyl-dUTP, or N-acetoxy-2-acetylaminofluorene (AAF). The availability of different sizes of colloidal gold particles permits the simultaneous detection of several sequences. In addition, low signals can be amplified either with an antibody sandwich scheme or by silver intensification. This technology is applicable both to TEM and SEM preparations of chromosomes, and we have used it to map a number of highly and moderately repeated sequences on whole mount metaphase chromosomes.

Evolution of a centromeric satellite DNA and phylogeny of lacertid lizards

1. The composition and phyletic distribution of a highly repetitive satellite DNA, isolated from Podarcis sicula, was studied. 2. This DNA was rich in adenine and thymine and displayed frequent adenine stretches. It was always located on the centromeric heterochromatin even in quite taxonomically distant species. 3. Southern blot hybridization of the Taq I satellite on various species of lacertid families showed a close affinity among Podarcis, Algyroides and Lacerta dugesii. 4. All the other taxa investigated did not seem to possess this repeated sequence.

Centromeres of mammalian chromosomes

The centromere is the major cis-acting genetic locus involved in chromosome segregation in mitosis and meiosis. The mammalian centromere is characterized by large amounts of tandemly repeated satellite DNA and by a number of specific centromere proteins, at least one of which has been shown to interact directly with centromeric satellite DNA sequences. Although direct functional assays of chromosome segregation are still lacking, the data are most consistent with a structural and possibly functional role for satellite DNA in the mammalian centromere.

Centromere separation. Early replication of repetitive DNA associated with inactive centromeres

Four types of stable dicentric and one octacentric chromosomes from mouse brain tumor cells and L-929 cells were analyzed for the timing of replication of repetitive deoxyribonucleic acid (DNA) located in the centric and pericentric regions associated with active versus inactive centromeres. The repetitive DNA present in the heterochromatin blocks of inactive centromeres replicates much earlier than similar DNA associated with the active centromeres. The former appears to replicate during early to mid S when several euchromatic segments are still replicating. There seems to be little or no overlap in the timing of replication of the repetitive DNA present in the vicinity of prematurely separating centromeres (which are accessory and nonfunctional) and those that separate at meta-anaphase junction (which are the functional centromeres). In the absence of any information about the mechanism(s) controlling initiation and completion of DNA synthesis in the two types of heterochromatic blocks, the differential timing of replication of the DNA with similar base composition remains an enigma.

A binding protein (p82 protein) recognizes specifically the curved heterochromatic DNA in Artemia franciscana

DNA bending has been suggested to play a role in the regulation of gene expression, initiation of DNA replication, site specific recombination and DNA packaging. In Artemia franciscana (Phillopoda anostraca) cells we have revealed that an AluI DNA family of repeats, 113-bp in length, is the major component of the constitutive heterochromatin found in the species. By analysis of cloned oligomeric (monomer to hexamer) heterochromatic fragments and electrophoretic experiments we verified that the repetitive DNA shows a stable curvature that confers a solenoidal geometry to the double helix. Using the cloned monomeric fragment, as molecular probe, we describe the detection in an A. franciscana cell extract of a protein of 82 kDa (p82) that preferentially binds to heterochromatic DNA. This protein, purified of the other DNA binding proteins present in the crude cell extract, shows a greater affinity with the tandem copies of the AluI DNA fragment than with the monomer sequence. The binding of p82 protein to heterochromatic DNA is also drastically reduced in the presence of the antibiotic distamycin A, suggesting a role of the DNA curvature in the formation of the nucleoproteic complex.

The chromosomal distribution of the major and minor satellite is not conserved in the genus Mus

The cytological distribution of the major and minor satellite first identified in Mus musculus was studied in the karyotypes of three related subspecies and two other species of the genus Mus. Both the major and minor satellite showed species dependent hybridization patterns. The major satellite is confined to the centromere region in M. musculus and related subspecies. However, in M spretus and M. caroli, the chromosomal arm regions contain this sequence class. In contrast the minor satellite is found at the kinetochore region in M. musculus and related subspecies but is distributed throughout the entire centromeric domain in M. spretus and appears to be excluded from the chromosomes of M. caroli. There is an apparent correlation between the chromosomal location of these satellites and their phylogenetic relationship. Determination of the biological roles of the major and minor satellites from M. musculus must take into account their differential chromosomal distribution in other Mus species.

Kinetochore formation in experimentally undercondensed chromosomes

Treatment of human and mouse cell cultures with the cytidine analogue 5-azadeoxycytidine and the AT-specific DNA ligand Hoechst 33258 dramatically inhibited condensation of the pericentromeric heterochromatin in several chromosomes. When stained with antikinetochore autoimmune sera, these experimentally undercondensed chromosomes showed kinetochores with preserved antigenicity. The undercondensed and normally condensed chromosomes share the major antigenic determinants of the kinetochore.

Satellite DNAs contain sequences that induced curvature

The repeating units of mouse, rat, and alpha-monkey satellites have been cloned. All three show properties that are characteristic of curved DNA: (i) their migration in polyacrylamide gels is slower than predicted from their sequences, and (ii) they appear as curved molecules when visualized by electron microscopy. All three satellite repeats contain runs of d(A.T)n greater than or equal to 3 residues that are likely to be responsible for their curvature. From analysis of 20 different satellite DNA sequences, we conclude that, in satellite DNA, adenine residues show a high tendency to cluster in groups of three or more.

Preservation of a complex satellite DNA in two species of echinoderms

The cloning and sequencing of a tandemly arrayed repetitive DNA sequence from the sea cucumber Holothuria tubulosa has been recently described (Sainz, J., Azorín, F. and Cornudella, L. 1989. Gene 80, 57-64). We have now searched the genomes of several echinoderm species for the presence of homologous repetitive elements. A close but not identical repeated sequence has been identified in a related holothuroid, H. polii. The monomeric repeat unit is 391 bp long and has a base composition of 66.8% A and T residues, lined up in tracts of 4 nt or larger. The monomeric sequence lacks any internal subrepeat organization although it displays a substantial degree of internal redundancy in the form of inverted and direct repeats. The repeated element accounts for 0.34% of the genome which corresponds to a repetition frequency of about 0.5 x 10(5) copies per haploid complement. The intra- and interspecific homologies among monomers of the satellite DNA as derived from sequence analyses are very high, averaging 97%. The results suggest that the homogeneity of the highly reiterated DNA sequence may be attributed to evolutionary conservative trends.

Centromere structure and function in neoplasia

The mammalian centromere plays an essential role in maintenance of diploidy in the cell. It is therefore imperative that we understand the structure and function of the mammalian centromere in order to plan strategy to control the incidence of aneuploidy and resultant malformations of the nonneoplastic as well as neoplastic tissues. Even though considerable information is available about the structure and some functional aspects of centromeres of lower eukaryotes such as yeast, the structure of the mammalian centromere is still a matter of conjecture limited to an understanding of the base composition of the alphoid sequences putatively located in the centromeric DNA of higher apes. We do, however, have a better understanding of the structure and role of the kinetochore. In all eukaryotes analyzed so far, the centromeres in a given genome separate in a sequential manner dependent upon the time of replication of pericentric and centromeric DNA. Some chromosomes, generally found in neoplastic cells, that carry more than one centromere show premature separation of the accessory centromeres. These centromeres and the associated pericentric regions replicate their DNA in an earlier part of the S phase than those that show kinetochore activity; both, however, carry DNA of the same composition. The active centromeres in these chromosomes show kinetochore protein binding as detected by antikinetochore antibody; the inactive centromeres are usually devoid of these proteins. The double minutes in neoplastic cells also lack kinetochore proteins, perhaps due to a lack of any centromere. Some dicentric and multicentric chromosomes in cancer cells and transformed cell lines do not display premature centromere separation. In these chromosomes, all centromeric sites show kinetochore proteins and all centromeric regions replicate their DNA simultaneously. These chromosomes also exhibited meiotic-like behavior of some centromeres and show postanaphase separation of some centromeres, resulting in bridges. These bridges, upon breakage and rejoining of sister chromatids, generate new multicentric chromosomes. The resulting chromosomes also exhibit formation of compound kinetochores. Some of these phenomena are novel descriptions of the centromere behavior in cancer cells. This review also discusses the role of aberrant centromere separation in human biology, providing correlates between errors of centromere separation and neoplasia.

High-mobility group protein HMG-I localizes to G/Q- and C-bands of human and mouse chromosomes

Mammalian metaphase chromosomes can be identified by their characteristic banding pattern when stained with Giemsa dye after brief proteolytic digestion. The resulting G-bands are known to contain regions of DNA enriched in A/T residues and to be the principal location for the L1 (or Kpn 1) family of long interspersed repetitive sequences in human chromosomes. Here we report that antibodies raised against a highly purified and biochemically well characterized nonhistone "High-Mobility Group" protein, HMG-I, specifically localize this protein to the G-bands in mammalian metaphase chromosomes. In some preparations in which chromosomes are highly condensed, HMG-I appears to be located at the centromere and/or telomere regions of mammalian chromosomes as well. To our knowledge, this is the first well-characterized mammalian protein that localizes primarily to G-band regions of chromosomes.

Sequence-directed curvature of repetitive AluI DNA in constitutive heterochromatin of Artemia franciscana

An Alu I family of repeated DNA sequence 113 bp in length was found to be the major component of the heterochromatin in Artemia franciscana. On the basis of the analysis of cloned oligomeric (monomer to examer) heterchromatic fragments we predicted that the sequence could produce a stable curvature in chromosomal DNA. This prediction was confirmed by polyacrylamide gel electrophoresis analysis and by electron microscope observations. The anomalous mobility of these fragments is reversed when the DNA samples are electrophoresed in the presence of distamycin A. Moreover treatment of living Artemia with this drug produces visible decondensation of heterochromatic masses in the interphase nuclei.

Alternate centromere inactivation in a pseudodicentric (15;20)(pter;pter) associated with a progressive neurological disorder

A 13 year old male with a severe progressive neurological disorder was found to have a pseudodicentric chromosome resulting from a telomeric fusion 15p;20p. In lymphocytes, the centromeric constriction of the abnormal chromosome was always that of the chromosome 20, while in fibroblasts both centromeres were alternately constricted. Cd staining was positive only at the active centromere, but a weak anticentromere immunofluorescence was present at the inactive one. We suggest that centromere inactivation results from a modified conformation of the functional DNA sequences preventing normal binding to centromere specific proteins. We also postulate that the patient's disorder, reminiscent of a spongy glioneuronal dystrophy as seen in Alper's and Creutzfeldt-Jakob diseases, may be secondary to the presence of the pathogenic isoform of the prion protein encoded by a gene mapped to 20p12----pter.

Kinetochore development in two dicentric chromosomes in man. A light and electron microscopic study

Two dicentric human chromosomes were investigated with light and electron microscopic techniques. One chromosome, with a translocation tdic(5;13)(p12;p12), behaved as a dicentric in about half the cells: it had two primary constrictions; C- and Cd-banding showed two centromeres; and the CREST antikinetochore antibody reacted with the two centromeres with equal affinity. Electron microscopic analysis of sectioned metaphases showed that the dicentric could develop kinetochores at both centromeres simultaneously. The other dicentric chromosome, tdic(21;21)(q22;q22), occasionally showed two primary constrictions, but both C- and Cd-banding distinguished between an active and an inactive centromere, and the CREST antibody reacted only weakly with the inactive centromere. Electron microscopy showed kinetochore development at only one centromere.

The metaphase scaffold is helically folded: sister chromatids have predominantly opposite helical handedness

We have studied the three-dimensional folding of the scaffolding in histone H1-depleted chromosomes by immunofluorescence with an antibody specific for topoisomerase II. Two different types of decondensed chromosomes are observed. The majority of the chromosomes are expanded, and the central fluorescence signal is surrounded by a large halo of chromatin. A much smaller number of chromosomes are more compact in length; they contain a smaller halo of chromatin and their scaffolds are not extended but folded into a genuine, quite regular helical coil. This conclusion is based on a three-dimensional structural analysis by optical sectioning. The number of helical coils is related to chromosome length. Surprisingly, sister chromatids have predominantly opposite helical handedness; that is, they are related by mirror symmetry.

Analysis of the replication mode of double minutes using the PCC technique combined with BrdUrd labeling

A cultured line of neuroblastoma cells (NB) was found to contain double minute chromosomes (DMs) DMs have been reported to be acentric and, therefore, to be segregated randomly into daughter cells without separating their sister elements. When NB cells were fused with Chinese hamster metaphase cells, prematurely condensed chromosomes (PCCs) were induced. DMs seen together with G2 PCCs appeared to be closely paired, dot-like structures resembling DMs observable in metaphase cells. In contrast, DMs in G1 cells showed a tendency to become single as the stage progressed so that the majority of DMs in late G1 cells were actually no longer double. DMs in S-phase cells, however, again appeared double. These results clearly indicate why DMs are invariably double and never assume a quadruple configuration in metaphase cells in spite of their non-disjunctional segregation at anaphase. Such a characteristic mode of DM replication was further confirmed by a 5-bromo-2'-deoxyuridine (BrdUrd) labeling experiment: when NB cells were exposed to BrdUrd for two successive rounds of DNA replication prior to PCC induction, half of the resulting single G1 minutes as well as G1 PCCs stained dark and the other half stained light after staining for sister chromatid differentiation.

Sequence of centromere separation: differential replication of pericentric heterochromatin in multicentric chromosomes

The dicentric and multicentric chromosomes in L cells and a brain tumor cell line of mouse display only one site of kinetochore formation associated with the 'active' centromere. The accessory or 'inactive' centromeres show premature separation. These cell lines were treated with 10(-6) M 5-bromodeoxyuridine (BrdUrd) followed by anti-BrdUrd antibody to study the pattern of replication of pericentric heterochromatin flanking the active vs inactive centromeres. Regardless of its quantity, heterochromatin around the inactive centromere replicates earlier than that associated with the active centromere. There appears to be a relationship between the timing of separation of a centromere and the timing of replication of pericentric heterochromatin. The premature replication of heterochromatin associated with an inactive centromere may be responsible for its premature separation and, hence, inactivity.

Curvature of mouse satellite DNA and condensation of heterochromatin

Cloned, sequenced mouse satellite DNA exhibits properties characteristic of molecules that possess a stable curvature. Circularly permuted fragments containing the region predicted to bend were used to map the curvature relative to DNA sequence. The altered mobility of these fragments in polyacrylamide gels is reversed when gels are run in the presence of distamycin A, a drug that binds preferentially to AT-rich DNA. Treatment of living mouse cells with this drug dramatically reduces the condensation of centromeric heterochromatin, the exclusive location of satellite sequences. In situ hybridization of satellite probes to extended chromosomes at the electron microscope level shows that satellite does not comprise a single block but is distributed throughout the centromere region. Based on these experiments, we hypothesize that the structure of mouse satellite DNA is an important feature of centromeric heterochromatin condensation.