A glimpse at chromosomal order

Cis-acting sequences regulating expression of the human alpha-globin cluster lie within constitutively open chromatin

Current models suggest that tissue-specific genes are arranged in discrete, independently controlled segments of chromatin referred to as regulatory domains. Transition from a closed to open chromatin structure may be an important step in the regulation of gene expression. To determine whether the human alpha-globin cluster, like the beta-globin cluster, lies within a discrete, erythroid-specific domain, we have examined the long-range genomic organization and chromatin structure around this region. The alpha genes lie adjacent to at least four widely expressed genes. The major alpha-globin regulatory element lies 40 kb away from the cluster within an intron of one of these genes. Therefore, unlike the beta cluster, cis-acting sequences controlling alpha gene expression are dispersed within a region of chromatin that is open in both erythroid and nonerythroid cells. This implies a difference in the hierarchical control of alpha- and beta-globin expression.

Nuclear distribution of histone deacetylase: a marker enzyme for the internal nuclear matrix

Nuclear matrins are proteins that localize to the internal nuclear matrix. In a previous study, we reported that histone deacetylase is a component of the internal matrix, suggesting that histone deacetylase is a nuclear matrin. Here, we demonstrate that the majority of the histone deacetylase activity is associated with the internal nuclear matrices of chicken and trout liver. Thus, the association of the histone deacetylase with the internal nuclear matrix is neither tissue- nor species-specific. Using histone deacetylase as a marker enzyme for the partitioning of the internal nuclear matrix during nuclear fractionations, we show that in contrast to the internal nuclear matrices of trout liver, trout hepatocellular carcinoma and chicken liver, the stability of the chicken erythrocyte internal nuclear matrix is temperature-dependent. Our results support a model that has the histone deacetylase mediating transient interactions between the internal nuclear matrix and chromatin regions undergoing dynamic acetylation, for example transcriptionally active chromatin regions.

Scaffold-associated regions: cis-acting determinants of chromatin structural loops and functional domains

It has been proposed that scaffold-associated regions are DNA elements that form the bases of chromatin loops in eukaryotic cells. Recent evidence supports a role for these elements as cis-acting 'handlers' of both structural and functional chromatin domains.

Restriction site variation, gene duplication, and the activity of sn-glycerol-3-phosphate dehydrogenase in Drosophila melanogaster

Restriction site variation in a 25-kb region including the sn-glycerol-3-phosphate dehydrogenase (Gpdh) locus has been assessed in 29 single female D. melanogaster lines from the Cardwell (Australia, QLD) population. The Gpdh locus was duplicated in about one-third of the lines, although the duplication was incomplete and lacked exons 1 and 2. There was no restriction site variation in the duplicated region. Three insertions were found in the gene region but only one affected GPDH activity. The lines with the duplication had higher levels of GPDH activity and protein amount than did nonduplicated lines. This effect was also observed in lines extracted from two other Australian populations. The duplication is shown to have a similar structure in each population investigated and is also present in populations from China and Africa. It is suggested that the effect of the duplication on GPDH activity, which might be due to structural factors affecting transcription at the Gpdh locus, could account for the worldwide distribution of the duplication.

DNA loops: structural and functional properties of scaffold-attached regions

The long DNA molecules of eukaryotic genomes appear to be organized into large loops formed by the binding of dispersed DNA sequences to non-histone proteins. This partitioning of DNA into topologically constrained units constitutes one of the highest orders of DNA packing in chromosomes. DNA loops are likely to define functional units as well as topological domains, contributing to the regulation of gene expression and DNA replication. This review presents recent work on the properties of the DNA sequences and proteins thought to be involved in loop formation, and on their possible significance for replication and transcription.

Chromatin as an essential part of the transcriptional mechanism

The increasingly detailed biochemical definition of the protein complexes that regulate gene transcription has led to the re-emergence of questions about the role of histones. Much recent evidence suggests that transcriptional activation requires that transcription factors successfully compete with histones for binding to promoters, and that there may be more than one mechanism by which this is achieved.

Biological significance of unwinding capability of nuclear matrix-associating DNAs

Matrix attachment regions (MARs) are thought to separate chromatin into topologically constrained loop domains. A MAR located 5' of the human beta-interferon gene becomes stably base-unpaired under superhelical strain, as do the MARs flanking the immunoglobulin heavy chain gene enhancer; in both cases a nucleation site exists for DNA unwinding. Concatemerized oligonucleotides containing the unwinding nucleation site exhibited a strong affinity for the nuclear scaffold and augmented SV40 promoter activity in stable transformants. Mutated concatemerized oligonucleotides resisted unwinding, showed weak affinity for the nuclear scaffold, and did not enhance promoter activity. These results suggest that the DNA feature capable of relieving superhelical strain is important for MAR functions.

Chromosome structure and eukaryotic gene organization

The DNA in the eukaryotic nucleus is highly compacted but well organized into distinct regional units. Chromosomal bands are characterized by their structure and distinctive replication time. They are subdivided into chromatin loops which serve as functional domains that have discrete boundary elements and can be regulated during development.

Synergistic effect of histone H1 and nucleolin on chromatin condensation in mitosis: role of a phosphorylated heteromer

Repeated motifs, rich in basic residues, are characteristic of both the N-terminal domain of the nucleolus-specific protein, nucleolin, and the second half of the C-terminal domain of histone H1. These repeats are also the target for phosphorylation by the mitosis-specific p34cdc2 kinase. We have previously shown that synthetic peptides [(KTPKKAKKP)2 for histone H1 and (ATPAKKAA)2 for nucleolin] corresponding to these two repeated motifs are able to act in synergy to induce DNA hypercondensation (Erard et al., 1990). In order to determine the molecular basis of this synergistic interaction, we have studied the condensation of the homopolymer poly(dA).poly(dT) in the presence of the two synthetic peptides. Circular dichroism has been used to monitor the psi (+)-type condensation and has revealed that phosphorylation enhances the synergistic effect of the two peptides. Analysis of different combinations of the two peptides suggests that there is a direct interaction between them which is stabilized by phosphorylation. Furthermore, there is a striking correlation between the degree of homopolymer condensation and the stability of the heteromeric complex. Phosphorylation takes place on the threonine residues on the repeat motifs within a region which is likely to adopt a beta-turn structure. Circular dichroism and infrared spectroscopy provide evidence that phosphorylation stabilizes the beta-turn structure of both peptides, and computer modeling shows that this may be due to steric hindrance imposed by the phosphate group. We suggest that phosphorylated nucleolin and histone H1 interact through their homologous domain structured in beta-spirals in order to condense certain forms of DNA during mitosis.

Dynamic chromatin: the regulatory domain organization of eukaryotic gene loci

It is hypothesized that nuclear DNA is organized in topologically constrained loop domains defining basic units of higher order chromatin structure. Our studies are performed in order to investigate the functional relevance of this structural subdivision of eukaryotic chromatin for the control of gene expression. We used the chicken lysozyme gene locus as a model to examine the relation between chromatin structure and gene function. Several structural features of the lysozyme locus are known: the extension of the region of general DNAasel sensitivity of the active gene, the location of DNA-sequences with high affinity for the nuclear matrix in vitro, and the position of DNAasel hypersensitive chromatin sites (DHSs). The pattern of DHSs changes depending on the transcriptional status of the gene. Functional studies demonstrated that DHSs mark the position of cis-acting regulatory elements. Additionally, we discovered a novel cis-activity of the border regions of the DNAasel sensitive domain (A-elements). By eliminating the position effect on gene expression usually observed when genes are randomly integrated into the genome after transfection, A-elements possibly serve as punctuation marks for a regulatory chromatin domain. Experiments using transgenic mice confirmed that the complete structurally defined lysozyme gene domain behaves as an independent regulatory unit, expressing the gene in a tissue specific and position independent manner. These expression features were lost in transgenic mice carrying a construct, in which the A-elements as well as an upstream enhancer region were deleted, indicating the lack of a locus activation function on this construct. Experiments are designed in order to uncover possible hierarchical relationships between the different cis-acting regulatory elements for stepwise gene activation during cell differentiation. We are aiming at the definition of the basic structural and functional requirements for position independent and high level gene expression. The result of these experiments will have important consequences for random gene transfer with predictable and reproducible expression of transgenes.

The nuclear matrix: a heuristic model for investigating genomic organization and function in the cell nucleus

Despite significant advances in deciphering the molecular events underlying genomic function, our understanding of these integrated processes inside the functioning cell nucleus has, until recently, met with only very limited success. A major conundrum has been the "layers of complexity" characteristic of all cell structure and function. To understand how the cell nucleus functions, we must also understand how the cell nucleus is put together and functions as a whole. The value of this neo-holistic approach is demonstrated by the enormous progress made in recent years in identifying a wide variety of nuclear functions associated with the nuclear matrix. In this article we summarize basic properties of in situ nuclear structure, isolated nuclear matrix systems, nuclear matrix-associated functions, and DNA replication in particular. Emphasis is placed on identifying current problems and directions of research in this field and illustrating the intrinsic heuristic value of this global approach to genomic organization and function.

DNA and RNA within the nucleus: how much sequence-specific spatial organization?

Spatial organization of various nuclear components is often proposed as a means by which nuclei more efficiently carry out their various tasks. Such functional compartmentalization may involve a sequence-specific packaging and placement of DNA and RNA. Here we review recent insights, allowed primarily by advances in fluorescent in situ hybridization methodology, into the organization of nucleic acids within individual nuclei.

Coming to grips with a complex matter. A multidisciplinary approach to the synaptonemal complex

Research into the synaptonemal complex (SC) is currently finding renewed interest. This is because the primarily cytological knowledge of the SC has been increasingly supplemented by immunochemical characterization and genetical studies over recent years. Moreover, yeast, offering one of the most handy and rewarding experimental systems, has joined the group of organisms in which the SC can be studied cytologically. In this essay I shall present aspects concerning the SC and its role in meiotic pairing that have emerged over the past few years, parts of which were discussed at a recent meeting in Obertraun, Austria.

Functional and structural units in the chromomere

Electron microscopic observations demonstrate the existence of several DNA packing levels in the chromomere. A linear DNA molecule forms a big (chromomere) loop anchored to the chromosomal scaffold. The loop forms a set of smaller loops in the rosette pattern. Packing of the DNA by the histone octamer particles results in nucleosomes and nucleomeres. To establish the possible correspondence between the structural units of a chromomere and the genetical units (genes, exons, introns) in it, we compared the lengths of the units. Statistical analysis of the 315 sequenced genes indicate that the average gene size corresponds to the average length of a rosette loop. It means that a chromomere contains one or more genes. Assuming that exon-intron boundaries cannot bind nucleosomes we constructed DNA-packing models of the 88 genes. They demonstrate that the first (in 77.8 per cent of the genes) and the last (in 52.7 per cent) exons of the genes are too short to bind nucleosomes. Many genes contain long (nucleosome binding) pieces of DNA. Long packed pieces are introns in vertebrates; they are exons in invertebrates and plants. The average size gene contains two nucleomeres.

The nucleotide sequence of a CpG island demonstrates the presence of the first exon of the gene encoding the human lysosomal membrane protein lamp2 and assigns the gene to Xq24

An EagI-EcoRI clone of human genomic DNA, p2-7, mapped to Xq24 has been sequenced. This analysis has confirmed the presence of a CpG island and has identified the first exon of the human LAMP2 gene, encoding a glycoprotein of the lysosomal membrane. Since the p2-7 clone corresponds to single-copy DNA, we can assign the human LAMP2 gene to Xq24.

Scaffold-attached regions from the human interferon beta domain can be used to enhance the stable expression of genes under the control of various promoters

We have transfected DNA corresponding to the complete chromatin domain of human interferon beta (huIFN-beta) gene into mouse L cells. In this construct, which is flanked by scaffold-attached regions (SARs), the gene's transcription was enhanced 20-30-fold with respect to DNAs containing only the immediate regulatory elements. To elucidate the role of SAR elements in the transcriptional enhancement, their position was varied relative to several artificial promoter-gene combinations. It was found that SARs enhance general promoter functions in an orientation- and partially distance-independent manner; their effect is restricted to the integrated state of transfected templates. During the phase of transient expression, SAR elements were generally found to have an antagonizing effect.

Mapping of the duplicated rabbit immunoglobulin kappa light chain locus

The rabbit has two isotypic forms of the immunoglobulin kappa light chain, K1 and K2, which probably arose by duplication. In the normal rabbit, only traces of K2 light chains are produced. However, K2 levels are elevated in allotype-suppressed rabbits and in the Basilea strain which does not produce K1 because of a K1 mRNA splice site mutation. Previous cloning and sequencing showed that each isotype has its own set of J kappa genes but it was not known whether the two isotypes utilize shared or separate sets of V kappa genes. In addition, although genetic linkage of allotypes associated with the K1 and K2 genes has been demonstrated, physical linkage had not been previously demonstrated by overlapping cosmid or phage clones. We used pulsed field and transverse alternating field electrophoresis to obtain megabase maps and to estimate the size of the duplication of the rabbit kappa light chain locus. We found that the two C kappa genes are about 1 megabase apart. One explanation for the poor expression of K2, could be great physical distance from V kappa genes. However, we found that there are V kappa, J kappa and C kappa 2 genes within a approximately 105-kb fragment. Thus, physical distance of V kappa from C kappa 2 may not be the basis for poor K2 expression.

Analysis of genes and chromosomes by nonisotopic in situ hybridization

Nonisotopic in situ hybridization is a powerful tool to analyze the organization of complex genomes. Current approaches utilizing this technique for the analysis of linear and spatial genome organizations are presented. Clinical applications of these approaches, which open new avenues for diagnosis of disease-related chromosomal changes, are also discussed.

Chromosome assembly in vitro: topoisomerase II is required for condensation

The role of topoisomerase II (topo II) in chromosome condensation was studied in a mitotic extract derived from Xenopus eggs by specific immunodepletion. HeLa nuclei, which have a high complement of endogenous topo II, are converted to mitotic chromosomes in the topo II-depleted extract equally well as in the control. Chicken erythrocyte nuclei, however, which have a very low content of topo II, do not convert to condensed chromosomes in the depleted extract, although their condensation is normal upon addition of purified topo II. Dosage experiments support the possible notion of a structural involvement of topo II in chromosome condensation. In the topo II-depleted extract the erythrocyte nuclei progress to precondensation chromosomes, which lack the nuclear membrane-lamina complex and consist of a cluster of swollen chromatids.

A matrix/scaffold attachment region binding protein: identification, purification, and mode of binding

Matrix/scaffold attachment regions (MARs/SARs) partition chromatin into functional loop domains. Here we have identified a chicken protein that selectively binds to MARs from the chicken lysozyme locus and to MARs from Drosophila, mouse, and human genes. This protein, named ARBP (for attachment region binding protein), was purified to homogeneity and shown to bind to MARs in a cooperative fashion. ARBP is an abundant nuclear protein and a component of the internal nuclear network. Deletion mutants indicate that multiple AT-rich sequences, if contained in a minimal approximately 350 bp MAR fragment, can lead to efficient binding of ARBP. Furthermore, dimerization mutants show that, to bind ARBP efficiently, MAR sequences can act synergistically over large distances, apparently with the intervening DNA looping out. The binding characteristics of ARBP to MARs reproduce those of unfractionated matrix preparations, suggesting that ARBP is an important nuclear element for the generation of functional chromatin loops.

Mosaicism of tyrosinase-locus transcription and chromatin structure in dark vs. light melanocyte clones of homozygous chinchilla-mottled mice

The chinchilla-mottled (cm) mutation at the mouse tyrosinase-encoding locus leads to a transversely striped pattern of dark- and light-grey coat colors in homozygotes. The same basic pattern occurs in various other genotypes and has previously been found to represent the clonal developmental history of melanocytes. In a homozygote such as cm/cm, cis-acting mechanisms would be expected to account for the color differences. To search for these mechanisms, the genomic structure of the mutation was examined and compared with the wild-type, and its function was compared in cultured melanocyte clones of the respective colors. Evidence from restriction mapping indicated that the coding region of the mutant gene resembles that of the fully and uniformly pigmented wild-type. However, the upstream sequences are rearranged in the mutation. The rearrangement begins 5 kb 5' of the transcription initiation site and is estimated to encompass at least 30 kb of distal upstream sequence. At least two stable functional states of the cm gene were detectable: Light-cell clones have low levels of tyrosinase-specific transcription, reduced DNAase I sensitivity of tyrosinase chromatin, and no detectable hypersensitive sites near the gene; dark-cell clones have higher (but subnormal) levels of transcription, greater sensitivity of chromatin to DNAase I, and a hypersensitive site in the promoter region. The changed relation between the structural gene and its upstream region may separate it from cis-acting control elements, resulting in reduced and variable ability to achieve the appropriate chromatin configuration near the time of melanocyte determination; differences in expression among clonal initiator cells are then mitotically perpetuated.

A very large spontaneous deletion at aprt locus in CHO cells: sequence similarities with small aprt deletions

Spontaneous deletion mutants can be isolated from CHO cell lines heterozygous at the adenine phosphoribosyltransferase locus at frequencies up to 10(-4), i.e., about 100-fold higher than spontaneous point mutations. Indirect evidence has suggested that most deletions were in the megabase range. We have fully characterized one such mutant, Del 155, and shown that it resulted from an illegitimate recombination that took place between overlapping tetranucleotides. Comparisons with sequences of other deletions at various loci revealed a number of similarities, most striking of which was a CHI-like motif found within 6 bp of the upstream breakpoint of Del 155 and breakpoints of 8/21 previously described short deletions at the CHO aprt locus. Homology also existed between the downstream breakpoint of Del 155 and breakpoints of retinoblastoma gene deletions (3/6 cases) and also a 20-bp stretch of an Alu sequence in which breakpoints at the low-density lipoprotein receptor locus have been shown to cluster. The magnitude of the deletion event in Del 155 was assessed by pulsed field (PF) gel analysis and found to be at least 2100 kb long. PF analysis also indicated that the downstream breakpoint was near a region of structural differences between the two chromosomes carrying apart. These structural differences were probably not implicated in the mechanism of the high frequency event, since no indication of breakpoint clustering among a large collection of mutants was found either by conventional or PF electrophoretic analyses.

Paranemic structures of DNA and their role in DNA unwinding

A DNA structure is defined as paranemic if the participating strands can be separated without mutual rotation of the opposite strands. The experimental methods employed to detect paranemic, unwound, DNA regions is described, including probing by single-strand specific nucleases (SNN), conformation-specific chemical probes, topoisomer analysis, NMR, and other physical methods. The available evidence for the following paranemic structures is surveyed: single-stranded DNA, slippage structures, cruciforms, alternating B-Z regions, triplexes (H-DNA), paranemic duplexes and RNA, protein-stabilized paranemic DNA. The problem of DNA unwinding during gene copying processes is analyzed; the possibility that extended paranemic DNA regions are transiently formed during replication, transcription, and recombination is considered, and the evidence supporting the participation of paranemic DNA forms in genes committed to or undergoing copying processes is summarized.

A view of interphase chromosomes

Metaphase chromosomes are dynamically modified in interphase. This review focuses on how these structures can be modified, and explores the functional mechanisms and significance of these changes. Current analyses of genes often focus on relatively short stretches of DNA and consider chromatin conformations that incorporate only a few kilobases of DNA. In interphase nuclei, however, orderly transcription and replication can involve highly folded chromosomal domains containing hundreds of kilobases of DNA. Specific "junk" DNA sequences within selected chromosome domains may participate in more complex levels of chromosome folding, and may index different genetic compartments for orderly transcription and replication. Three-dimensional chromosome positions within the nucleus may also contribute to phenotypic expression. Entire chromosomes are maintained as discrete, reasonably compact entities in the nucleus, and heterochromatic coiled domains of several thousand kilobases can acquire unique three-dimensional positions in differentiated cell types. Some aspects of neoplasia may relate to alterations in chromosome structure at several higher levels of organization.

Assembly of the cell nucleus

Purified DNA can be assembled into structures that closely resemble cell nuclei. The cell-free systems that allow this can be exploited to study assembly pathways for several components of the nucleus. They also offer great opportunities for the experimental analysis of nuclear function.

Transvection and long-distance gene regulation

Numerous genes contain regulatory elements located many tens of kilobases away from the promoter they control. Specific mechanisms must be required to ensure that such distant elements can find and interact with their proper targets but not with extraneous genes. This review explores the connections between transvection phenomena, the activation of domains of homeotic gene expression, position effect variegation and silencers. These various examples of long-distance effects suggest that, in all cases, related forms of chromatin packaging may be involved.

Transcriptional enhancers can act in trans

Enhancers have been defined operationally as cis-regulatory sequences that can stimulate transcription of RNA polymerase-II-transcribed genes over large distances and even when located downstream of the gene. Recently, it has become evident that enhancers can also stimulate transcription in trans if they are brought into close proximity to the promoter/gene. These reports provide clues to the mechanism of remote enhancer action. In addition, the findings, together with genetic studies in Drosophila, strongly suggest that enhancer action in trans could underlie phenomena such as 'transvection', where one chromosome affects gene expression in the paired homolog.

DNaseI hypersensitive sites at the 3' end of the human apolipoprotein B gene

The chromatin structure of the 3' end of the human apolipoprotein B gene has been examined. Two DNaseI hypersensitive sites were present in nuclei from liver-derived HepG2 cells and intestine-derived CaCo-2 cells, in which the apo-B gene is transcriptionally active, but were absent from HeLa cells, where the gene is not expressed, and from free DNA. The region in a segment enriched in recognition sites for topoisomerase II and known to participate in anchoring the 3' end of the gene to the nuclear matrix. The second DNaseI hypersensitive site resided in the 3' untranslated portion of the gene. Furthermore, nucleosomes were present along a 1.4-kilobase (HindIII-BamHI) segment of DNA containing the two 3' DNaseI hypersensitive sites, and a static array of nucleosomes was present along the A/T-rich hypervariable region.

The crosslinking of nuclear protein to DNA using ionizing radiation

DNA-protein complexes were generated in intact Chinese hamster ovary (CHO) cells by the use of ionizing radiation. The DNA-protein crosslinks, as measured by a filter-binding assay, occurred immediately following the irradiation, were produced in a dose-dependent manner and were reversible. The reversibility of the crosslinks in the intact cells was dependent upon general protein synthesis. Three proteins that were attached to DNA in unirradiated cells were analyzed according to the presence of DNA attached to the proteins before, during and after exposure to ionizing radiation. All three proteins contained more DNA reversibly attached to the proteins after exposure to 5 Gy ionizing radiation as compared to unirradiated cells. One of the proteins was increasingly attached to DNA using 2.5-50 Gy X-ray. These data suggest that the increased DNA-protein crosslinking observed with ionizing radiation may involve the increase in particular protein(s) crosslinked to DNA as well as an increase in the amount of DNA attached to specific proteins.

A transcriptional terminator between enhancer and promoter does not affect remote transcriptional control

Enhancers stimulate transcription of RNA polymerase II-transcribed genes in an orientation-independent manner and over long distances. This stimulation is known to be associated with an increased polymerase density over the linked gene. However, many aspects of the exact mechanism of remote gene control remain to be elucidated. Based on some reports on RNA polymerase I transcription, we wanted to test whether RNA polymerase II enters at the enhancer and from there proceeds towards the promoter while synthesizing unstable transcripts ("scanning/readthrough transcription" model). For this, we have inserted a complete terminator region from the mouse beta-globinmaj gene between the SV40 enhancer and the rabbit beta-globin promoter. In contrast to what the model predicts, insertion of the terminator had no affect on remote enhancer action. Furthermore, we have determined the RNA polymerase density over the spacer DNA between enhancer and promoter, and over the reporter gene, by means of the so-called run-on transcription assay. We find very low transcription of the spacer, but high transcription of the globin reporter gene. Thus, our data are not consistent with a scanning/readthrough transcription mechanism where RNA polymerase II would move from the enhancer to the promoter while transcribing the intervening spacer DNA. These and other findings are compatible with a model where enhancer and promoter are brought into close proximity, perhaps with concomitant looping out of the intervening DNA.

Disassembly of chromatin into approximately equal to 50 kb units by detergent

Nuclei isolated from higher eukaryotic cell lines were directly analyzed by field inversion gel electrophoresis. Brief incubation of nuclei with ionic detergents yielded a single band between 50-100 kb. The apparent fragment size decreased to approximately equal to 50 kb after proteinase digestion. The latter treatment alone induced less regular, less than or equal to 50 kb fragmentation. DNA extracted from detergent and proteinase-treated nuclei also appeared in a band of about 40 kb. Embedding into agarose plugs did not protect nuclei, as opposed to cells, from detergent-induced fragmentation. The phenomenon is strikingly analogous to the double-strand DNA cleavage reactions mediated by topoisomerase II. Our data are compatible with any of the following interpretations: 1.) regularly spaced protein bridges, probably involving topoisomerase II, maintain or control continuity of chromosomal DNA in certain states of higher eukaryotic cells. 2.) The DNA might become accessible to a putative endonuclease at regularly spaced sites upon detergent treatment of isolated nuclei.

On the topology of normal chromatids and on their translocations in myelogenous leukemia

After some comments on the topology of chromatids, restructuring of the interphase nucleus is conjectured to depend upon the nuclear vesicle apparatus. These vesicles change the intrinsic shape of chromatids to fit the different topology of the interphase nuclear spheroid. Reciprocal translocations between selected chromatids result whenever the nucleus of malignant cells organizes de novo certain exceptional or emergency differentiation paths. However, the almost unavoidable chimeric genes resulting from these translocations may be less ominous than hitherto suspected. This seems to be the case for chronic myelogenous leukemia, where the bcr-abl chimeric gene lessens the aggressiveness of the primary clone when functioning in the context of myelomonocitic differentiation. Finally, our model estimates the statistical incidences of the bcr-abl chimera. These estimates are found to agree with clinical data better than evaluations from the random mutation theory.

Dependence of position-effect variegation in Drosophila on dose of a gene encoding an unusual zinc-finger protein

Position-effect variegation is the inactivation in some cells of a gene translocated next to heterochromatin, the region of the chromosome that is permanently condensed. The number of copies of the Drosophila gene Suvar(3)7 is a dose-limiting factor in this phenomenon, and seems from its sequence that it encodes a protein with five widely spaced zinc-fingers. This novel arrangement of zinc-fingers could help in packaging the chromatin fibre into heterochromatin, and also reflect a novel method of controlling the expression from DNA domains.

DNA methylation and late replication probably aid cell memory, and type I DNA reeling could aid chromosome folding and enhancer function

DNA methylation in mammals is reviewed, and it is concluded that one role of methylation is to aid cell memory, which is defined as the ability of mitotically derived progeny cells to remember and re-establish their proper cellular identity. Methylation of X-linked CpG-rich islands probably stabilizes X-chromosome inactivation, but other mechanisms appear to be involved. Late replication is discussed as a key ancestral mechanism for X inactivation, and it is emphasized that early and late replication domains may each be self perpetuating. Therefore, early-late replication timing becomes another strong candidate mechanism for cell memory. A chromosome-loop folding enigma is discussed, and it is concluded that special mechanisms are needed to explain the formation and maintenance of specific looped domains. DNA reeling, such as done by type I restriction-modification enzymes, is proposed to provide this special mechanism for folding. DNA reeling mechanisms can help to explain the cis-spreading of X-chromosome inactivation as well as long-range action by enhancers.