The distribution of CpG islands in mammalian chromosomes.

Using fluorescent in situ suppression hybridization to metaphase chromosomes, we have directly shown that CpG islands are predominantly found in the early replicating (R band) regions of the genome. Conversely, late replicating (G band) DNA is sparsely populated with islands. The very highest concentration of CpG islands is in a subset of R bands, most of which are known as T bands. We suggest that there is an interdependence between the differences in island density and the behaviour of chromosomal domains. Our findings indicate which regions of the genome will yield the highest density of coding sequence information. An awareness of local island density may influence the choice of method for identifying exons in genomic DNA.

Differences in the localization and morphology of chromosomes in the human nucleus.

Using fluorescence in situ hybridization we show striking differences in nuclear position, chromosome morphology, and interactions with nuclear substructure for human chromosomes 18 and 19. Human chromosome 19 is shown to adopt a more internal position in the nucleus than chromosome 18 and to be more extensively associated with the nuclear matrix. The more peripheral localization of chromosome 18 is established early in the cell cycle and is maintained thereafter. We show that the preferential localization of chromosomes 18 and 19 in the nucleus is reflected in the orientation of translocation chromosomes in the nucleus. Lastly, we show that the inhibition of transcription can have gross, but reversible, effects on chromosome architecture. Our data demonstrate that the distribution of genomic sequences between chromosomes has implications for nuclear structure and we discuss our findings in relation to a model of the human nucleus that is functionally compartmentalized.

Modulation of DNA binding specificity by alternative splicing of the Wilms tumor wt1 gene transcript.

The technique of whole-genome polymerase chain reaction was used to study the DNA binding properties of the product of the wt1 gene. The zinc finger region of this gene is alternatively spliced such that the major transcript encodes a protein with three extra amino acids between the third and fourth fingers. The minor form of the protein binds specifically to DNA. It is now shown that the major form of wt1 messenger RNA encodes a protein that binds to DNA with a specificity that differs from that of the minor form. Therefore, alternative splicing within the DNA binding domain of a transcription factor can generate proteins with distinct DNA binding specificities and probably different physiological targets.

Re-modelling of nuclear architecture in quiescent and senescent human fibroblasts.

Spatial organisation of the genome within the nucleus can play a role in maintaining the expressed or silent state of some genes [1]. There are distinct addresses for specific chromosomes, which have different functional characteristics, within the nuclei of dividing populations of human cells [2]. Here, we demonstrate that this level of nuclear architecture is altered in cells that have become either quiescent or senescent. Upon cell cycle exit, a gene-poor human chromosome moves from a location at the nuclear periphery to a more internal site in the nucleus, and changes its associations with nuclear substructures. The chromosome moves back toward the edge of the nucleus at a distinctive time after re-entry into the cell cycle. There is a 2-4 hour period at the beginning of G1 when the spatial organisation of these human chromosomes is established. Lastly, these experiments provide evidence that temporal control of DNA replication can be independent of spatial chromosome organisation. We conclude that the sub-nuclear organisation of chromosomes in quiescent or senescent mammalian somatic cells is fundamentally different from that in proliferating cells and that the spatial organisation of the genome is plastic.

Putting the genome on the map.

The first complete genomic sequence of a eukaryote (Saccharomyces cerevisiae) has already been accomplished. It is estimated that the sequence of the human genome will be known early in the next millennium. Yet it is already apparent that, despite their immense length, these linear primary sequence maps will be inadequate descriptions of the eukaryotic genome, be it of a budding yeast or a human. To reflect our growing awareness of the importance of spatial context in chromosome function and in gene expression we argue that a more complete map of the genome should seek to embody the richness of information that we expect of the maps we use to navigate our way around the outside world.

Mammalian chromosome banding--an expression of genome organization.

Banding of metaphase chromosomes is an invaluable aid to analysing the complex genomes of vertebrates, but the biochemical basis for this phenomenon is poorly understood. Advances in molecular biology are beginning to point to features of genome organization that may play roles in chromosome banding.

The Nuclear Protein Database (NPD): sub-nuclear localisation and functional annotation of the nuclear proteome.

The Nuclear Protein Database (NPD) is a curated database that contains information on more than 1300 vertebrate proteins that are thought, or are known, to localise to the cell nucleus. Each entry is annotated with information on predicted protein size and isoelectric point, as well as any repeats, motifs or domains within the protein sequence. In addition, information on the sub-nuclear localisation of each protein is provided and the biological and molecular functions are described using Gene Ontology (GO) terms. The database is searchable by keyword, protein name, sub-nuclear compartment and protein domain/motif. Links to other databases are provided (e.g. Entrez, SWISS-PROT, OMIM, PubMed, PubMed Central). Thus, NPD provides a gateway through which the nuclear proteome may be explored. The database can be accessed at http://npd.hgu.mrc.ac.uk and is updated monthly.

Interspecific backcross mice show sex-specific differences in allelic inheritance.

Transmission distortion is identified as a difference in transmission frequency of two alleles from the normal 1:1 Mendelian segregation in diploid organisms. Transmission distortion can extend over part or all of a chromosome. The recent development of interspecific mouse backcrosses has provided a powerful method for multilocus mapping of entire chromosomes in a single cross, and consequently for identifying distortions in allelic inheritance. We used an interspecific backcross of [(C57BL/6J x Mus spretus)F1 x C57BL/6J] mice to map molecular loci to mouse chromosome 2 and had previously found that the distal region of the chromosome showed distortions in allelic inheritance. We now report the mapping of five loci (Actc-1, D2Hgu1, His-1, Hox-4.1 and Neb) to chromosome 2, which, in addition to the Abl, Ada, B2m, Bmp-2a, Hc, Emv-15, Fshb, Hck-1, Pax-1, Pck-1, Spna-2 and Vim loci previously mapped in our interspecific backcross, serve as markers to measure allelic inheritance along approximately 75% of mouse chromosome 2. Statistical analyses are used to identify and delimit chromosomal regions showing transmission distortion and to determine whether there are sex-specific differences in allelic inheritance. These studies provide evidence for sex-specific differences in allelic inheritance for chromosome 2 and suggest biological explanations for this form of transmission distortion.

The expression of the Wilms' tumour gene, WT1, in the developing mammalian embryo.

In the developing mouse, the Wilms' tumour gene, WT1, is first expressed in the intermediate mesenchyme lateral to the coelomic cavity (13 somite, early 9 dpc embryo). A few hours later, it is present around all the cavity and in the urogenital ridge (the earliest mesonephric tubules) and the differentiating heart mesothelium. By 11 dpc, expression is in the uninduced metanephric mesenchyme and in the presumptive motor neurons of the spinal cord. By 12.5 dpc, WT1 expression has increased in the induced mesenchyme of the kidney and a day later is particularly marked in the nephrogenic condensations. At 13.5 dpc, WT1 is briefly expressed in some differentiating body-wall musculature, while two days later, there is a small domain of expression in the roof of the fourth ventricle of the brain. By day 20, however, expression has become restricted to the kidney glomeruli. RNA-PCR analysis on 12.5 dpc embryos and on adult tissues shows that WT1 is weakly expressed in both eye and tongue. The expression pattern in human embryos (28-70 days) is very similar to that in the equivalent mouse stages (10-15 dpc). The results indicate that WT1 is mainly present in mesodermally derived tissues, although exceptions are ectodermally derived spinal cord and brain. The data indicate that WT1 plays a role in mediating some cases of the mesenchyme-to-epithelial transition, but its expression elsewhere argues that it has other tissue-specific roles in development.

PRC2-independent chromatin compaction and transcriptional repression in cancer.

The silencing of large chromosomal regions by epigenetic mechanisms has been reported to occur frequently in cancer. Epigenetic marks, such as histone methylation and acetylation, are altered at these loci. However, the mechanisms of formation of such aberrant gene clusters remain largely unknown. Here, we show that, in cancer cells, the epigenetic remodeling of chromatin into hypoacetylated domains covered with histone H3K27 trimethylation is paralleled by changes in higher-order chromatin structures. Using fluorescence in situ hybridization, we demonstrate that regional epigenetic silencing corresponds to the establishment of compact chromatin domains. We show that gene repression is tightly correlated to the state of chromatin compaction and not to the levels of H3K27me3-its removal through the knockdown of EZH2 does not induce significant gene expression nor chromatin decompaction. Moreover, transcription can occur with intact high-H3K27me3 levels; treatment with histone deacetylase inhibitors can relieve chromatin compaction and gene repression, without altering H3K27me3 levels. Our findings imply that compaction and subsequent repression of large chromatin domains are not direct consequences of PRC2 deregulation in cancer cells. By challenging the role of EZH2 in aberrant gene silencing in cancer, these findings have therapeutical implications, notably for the choice of epigenetic drugs for tumors with multiple regional epigenetic alterations.

Dual Y-chromosome painting and immunofluorescence staining of archival human liver transplant biopsies.

Combining fluorescence in situ hybridization (FISH) and indirect immunofluorescence staining of protein markers provides a highly specific method for identifying chromosomes in phenotypically defined cells and tissues. We developed a technique enabling dual chromosome painting and immunofluorescence staining of archival formalin-fixed, paraffin-embedded material, and used this to phenotype chimeric cells in female-to-male human liver transplants.

Histone acetylation and the maintenance of chromatin compaction by Polycomb repressive complexes.

Mechanisms controlling higher-order chromatin structure or chromatin compaction and linking this to gene regulation are poorly understood. Previously, we had shown that the PRC1 Polycomb repressive complex is required to maintain a compact chromatin state at Polycomb target loci in embryonic stem cells (ESCs) of the mouse and that this activity, together with the ability to repress target gene expression, is surprisingly independent of the histone ubiquitination activity of the Ring1B component of PRC1. Here we investigate and discuss the role of another histone modification--histone acetylation--in Polycomb function. We show that inhibition of histone deacetylases leads to some decompaction of Hox loci and suggest that histone deacetylation has a role in the pathway of PRC1-mediated chromatin compaction. We discuss whether PRC1 and histone hypoacetylation function together to establish a chromatin template at which stable nucleosomes act to antagonize transcriptional elongation.

Human diseases with underlying defects in chromatin structure and modification.

Chromatin structure is important for regulating gene expression and for the proper condensation and segregation of chromosomes during cell division. Several human genetic diseases have been found to be due to mutations in genes producing proteins known or suspected to be involved in maintaining or modifying chromatin structure. Here we describe these 'chromatin diseases' and review what is known about the associated chromatin proteins in light of recent advances in the understanding of chromatin components, modification and function.

Evolution of homologous sequences on the human X and Y chromosomes, outside of the meiotic pairing segment.

A sequence isolated from the long arm of the human Y chromosome detects a highly homologous locus on the X. This homology extends over at least 50 kb of DNA and is postulated to be the result of a transposition event between the X and Y chromosomes during recent human evolution, since homologous sequences are shown to be present on the X chromosome alone in the chimpanzee and gorilla.

Aniridia, Wilms' tumor and human chromosome 11.

Aniridia-a developmental abnormality of the eye in which the iris is apparently absent-has been shown to be genetically associated with Wilms' tumor (an embryonic nephroblastoma) in the WAGR syndrome. Genetic and cytogenetic evidence points to band p13 of human chromosome 11 as the localization of the genes responsible for these defects. Deleted chromosomes 11 from WAGR patients and clinically associated translocations involving 11p13 have been used to map and order genes and anonymous DNA markers around the WAGR locus refining the localization of the aniridia and Wilms' tumor genes to within about 1 million base pairs of DNA.

Factors affecting the timing and imprinting of replication on a mammalian chromosome.

Fluorescence in situ hybridisation has been used to follow replication of the short arm of human chromosome 11 using chromosome anomalies to distinguish the maternally-and paternally-derived homologues. The temporal difference in replication timing within and between chromosomes has been estimated by combining S phase detection with dual colour fluorescence in situ hybridisation. Proximal regions of 11p, including the WT1 gene, tend to replicate earlier on the maternally-derived chromosome than on the paternally-derived homologue. More distal parts of 11p (including the IGF2 gene) have the opposite imprint. The average difference in replication timing between homologous loci in the population of cells is small compared to the differences between loci along a single chromosome. The imprint is not strictly adhered to since many nuclei have hybridisation patterns opposite to the trend within the population. The nature of the imprinting signal has been investigated. Absolute replication time, but not the imprint, was affected by azacytidine, an inhibitor of DNA methylation. The replication imprint was modified by treatments that inhibit histone deacetylation. We suggest that replication imprinting reflects differences in chromatin structure between homologues.

Unusual chromosome architecture and behaviour at an HSR.

Amplification of sequences within mammalian chromosomes is often accompanied by the formation of homogeneously staining regions (HSRs). The arrangement of DNA sequences within such amplicons has been investigated, but little is known about the chromosome structure or behaviour of these unusual regions. We have analysed the metaphase chromosome structure of the dihydrofolate reductase (DHFR) amplicon of CHOC400 cells. The chromatin in this region contains hyperacetylated nucleosomes yet, at the same time, appears to be densely packed like heterochromatin. The region does not bind heterochromatin proteins. We show that the dense packing of the region is restricted to DNA located close to the chromosome core/scaffold. In contrast, levels of the chromosome scaffold protein topoisomerase II at HSRs are the same as those found at other euchromatic locations. Metaphase chromosome condensation of the HSR is shown to be sensitive to topoisomerase II inhibitors, and sister chromatids often appear to remain attached within the HSRs at metaphase. We suggest that these features underlie anaphase bridging and the aberrant interphase structure of the HSR. The DHFR amplicon is widely used as a model system to study mammalian DNA replication. We conclude that the higher-order chromosome structure of this amplicon is unusual and suggest that caution needs to be exercised in extrapolating data from HSRs to normal chromosomal loci.