Nuclear dreams: The malignant alteration of nuclear architecture

Cancer is diagnosed by examining the architectural alterations to cells and tissues. Changes in nuclear structure are among the most universal of these and include increases in nuclear size, deformities in nuclear shape, and changes in the internal organization of the nucleus. These may all reflect changes in the nuclear matrix, a non-chromatin nuclear scaffolding determining nuclear form, higher order chromatin folding, and the spatial organization of nucleic acid metabolism. Malignancy-induced changes in this structure may have profound effects on chromatin folding, on the fidelity of genome replication, and on gene expression. Elucidating the mechanisms and the biological consequences of nuclear changes will require the identification of the major structural molecules of the internal nuclear matrix and an understanding of their assembly into structural elements. If biochemical correlates to malignant alterations in nuclear structure can be identified then nuclear matrix proteins and, perhaps nuclear matrix-associated structural RNAs, may be an attractive set of diagnostic markers and therapeutic targets. J. Cell. Biochem. 70:172–180, 1998. © 1998 Wiley-Liss, Inc.     

Structural–Functional Domains of the Eukaryotic Genome

It is well known that DNA folding in the eukaryotic cell nucleus is tightly coupled with the operation of epigenetic mechanisms defining the repertoires of the genes expressed in different types of cells. To understand these mechanisms, it is important to know how DNA is packaged in chromatin. About 30 years ago a hypothesis was formulated, according to which epigenetic mechanisms operate not at the level of individual genes, but rather groups of genes localized in structurally and functionally isolated genomic segments that were called structural and functional domains. The question of what exactly these domains constitute has been re-examined multiple times as our knowledge of principles of chromatin folding has changed. In this review, we discuss structural and functional genomic domains in light of the current model of interphase chromosome organization based on the results of analysis of spatial proximity between remote genomic elements.     

Chromatin organization during spermiogenesis in Octopus vulgaris. I: Morphological structures

In the process of the chromatin remodeling that occurs during spermiogenesis in some animal species, it is possible to distinguish between two separate aspects: the chromatin condensation pattern itself (granular, fibrillar, or lamellar), and the architecture of this pattern, that is to say, its arrangement within the nucleus. In the cephalopod Octopus vulgaris these two aspects are clearly differentiated. The condensation pattern develops from 25 nm fibers to fibers with a tubular aspect and with a progressively increasing diameter (40-60 nm and then to 80 nm), to end finally in the form of very thin fibers (3-5 nm) product of the coalescence and dissolution of the major fibers. The main directive force that governs this process lies in the global change that occurs in the proteins that interact with all (or the major part) of the genomic DNA. The condensation pattern by itself in this species does not present a fixed order: most of the fibers appear without any predominant spatial direction in the spermiogenic nuclei. However, as the nuclei elongate, the chromatin fibers arrange in parallel following the elongation axis. This parallel disposition of the chromatin fibers appears to be mediated by two specific areas, each of which we call a "polar nuclear matrix" (PNM). These matrices differentiate in the basal and apical nuclear poles adjacent to the centriolar implantation fosse and the acrosome, respectively. The areas that constitute the PNM have the following characteristics: (a) they are the only areas where DNA is found anchored to the nuclear membrane; (b) they are the zones from which the chromatin condensation pattern (fibers/tubules) begins; and (c) they are most probably the points through which the mechanical forces originating from nuclear elongation are transmitted to chromatin, causing the chromatin fibers/tubules to adopt an almost perfectly parallel disposition. Finally, we discuss the importance of the architecture of the chromatin condensation pattern, as it is one of the determining factors of the spatial organization of the mature sperm genome and chromosome positioning.     

Subnuclear organelles: new insights into form and function

The cell nucleus is a complex and highly dynamic environment with many functionally specialized regions of substructure that form and maintain themselves in the absence of membranes. Relatively little is known about the basic physical properties of the nuclear interior or how domains within the nucleus are structurally and functionally organized and interrelated. Here, we summarize recent data that shed light on the structural and functional properties of three prominent subnuclear organelles--nucleoli, Cajal bodies (CBs) and speckles. We discuss how these findings impact our understanding of the guiding principles of nuclear organization and various types of human disease.     

Comparative 3D Genome Structure Analysis of the Fission and the Budding Yeast

We studied the 3D structural organization of the fission yeast genome, which emerges from the tethering of heterochromatic regions in otherwise randomly configured chromosomes represented as flexible polymer chains in an nuclear environment. This model is sufficient to explain in a statistical manner many experimentally determined distinctive features of the fission yeast genome, including chromatin interaction patterns from Hi-C experiments and the co-locations of functionally related and co-expressed genes, such as genes expressed by Pol-III. Our findings demonstrate that some previously described structure-function correlations can be explained as a consequence of random chromatin collisions driven by a few geometric constraints (mainly due to centromere-SPB and telomere-NE tethering) combined with the specific gene locations in the chromosome sequence. We also performed a comparative analysis between the fission and budding yeast genome structures, for which we previously detected a similar organizing principle. However, due to the different chromosome sizes and numbers, substantial differences are observed in the 3D structural genome organization between the two species, most notably in the nuclear locations of orthologous genes, and the extent of nuclear territories for genes and chromosomes. However, despite those differences, remarkably, functional similarities are maintained, which is evident when comparing spatial clustering of functionally related genes in both yeasts. Functionally related genes show a similar spatial clustering behavior in both yeasts, even though their nuclear locations are largely different between the yeast species.     

Inter-Chromosomal Contact Networks Provide Insights into Mammalian Chromatin Organization

The recent advent of conformation capture techniques has provided unprecedented insights into the spatial organization of chromatin. We present a large-scale investigation of the inter-chromosomal segment and gene contact networks in embryonic stem cells of two mammalian organisms: humans and mice. Both interaction networks are characterized by a high degree of clustering of genome regions and the existence of hubs. Both genomes exhibit similar structural characteristics such as increased flexibility of certain Y chromosome regions and co-localization of centromere-proximal regions. Spatial proximity is correlated with the functional similarity of genes in both species. We also found a significant association between spatial proximity and the co-expression of genes in the human genome. The structural properties of chromatin are also species specific, including the presence of two highly interactive regions in mouse chromatin and an increased contact density on short, gene-rich human chromosomes, thereby indicating their central nuclear position. Trans-interacting segments are enriched in active marks in human and had no distinct feature profile in mouse. Thus, in contrast to interactions within individual chromosomes, the inter-chromosomal interactions in human and mouse embryonic stem cells do not appear to be conserved.