Dynamics of telomeres and promyelocytic leukemia nuclear bodies in a telomerase-negative human cell line.

Telomerase-negative tumor cells maintain their telomeres via an alternative lengthening of telomeres (ALT) mechanism. This process involves the association of telomeres with promyelocytic leukemia nuclear bodies (PML-NBs). Here, the mobility of both telomeres and PML-NBs as well as their interactions were studied in human U2OS osteosarcoma cells, in which the ALT pathway is active. A U2OS cell line was constructed that had lac operator repeats stably integrated adjacent to the telomeres of chromosomes 6q, 11p, and 12q. By fluorescence microscopy of autofluorescent LacI repressor bound to the lacO arrays the telomere mobility during interphase was traced and correlated with the telomere repeat length. A confined diffusion model was derived that describes telomere dynamics in the nucleus on the time scale from seconds to hours. Two telomere groups were identified that differed with respect to the nuclear space accessible to them. Furthermore, translocations of PML-NBs relative to telomeres and their complexes with telomeres were evaluated. Based on these studies, a model is proposed in which the shortening of telomeres results in an increased mobility that could facilitate the formation of complexes between telomeres and PML-NBs.

Uncoupling the replication machinery: replication fork progression in the absence of processive DNA synthesis.

The precise coordination of the different steps of DNA replication is critical for the maintenance of genome stability. We have probed the mechanisms coupling various components of the replication machinery and their response to polymerase stalling by inhibition of the DNA polymerases in living mammalian cells with aphidicolin. We observed little change in the behaviour of proteins involved in the initiation of DNA replication. In contrast, we detected a marked accumulation of the single stranded DNA binding factor RPA34 at sites of DNA replication. Finally, we demonstrate that proteins involved in the elongation step of DNA synthesis dissociate from replication foci in the presence of aphidicolin. Taken together, these data indicate that inhibition of processive DNA polymerases uncouples the initiation of DNA replication from subsequent elongation steps. We, therefore, propose that the replication machinery is made up of distinct functional sub-modules that allow a flexible and dynamic response to challenges during DNA replication.

Histone acetylation increases chromatin accessibility.

In eukaryotes, the interaction of DNA with proteins and supramolecular complexes involved in gene expression is controlled by the dynamic organization of chromatin inasmuch as it defines the DNA accessibility. Here, the nuclear distribution of microinjected fluorescein-labeled dextrans of 42 kDa to 2.5 MDa molecular mass was used to characterize the chromatin accessibility in dependence on histone acetylation. Measurements of the fluorescein-dextran sizes were combined with an image correlation spectroscopy analysis, and three different interphase chromatin condensation states with apparent pore sizes of 16-20 nm, 36-56 nm and 60-100 nm were identified. A reversible change of the chromatin conformation to a uniform 60-100 nm pore size distribution was observed upon increased histone acetylation. This result identifies histone acetylation as a central factor in the dynamic regulation of chromatin accessibility during interphase. In mitotic chromosomes, the chromatin exclusion limit was 10-20 nm and independent of the histone acetylation state.

Mobility of multi-subunit complexes in the nucleus: accessibility and dynamics of chromatin subcompartments.

The cell nucleus contains a number of mobile subnuclear organelles involved in RNA processing, transcriptional regulation and antiviral defence like Cajal and promyelocytic leukaemia (PML) bodies. It remains an open question how these bodies translocate to specific nuclear regions within the nucleus to exert their biological function. The mobility and localisation of macromolecules in the nucleus are closely related to the dynamic organisation and accessibility of chromatin. This relation has been studied with biologically inert fluorescent particles like dextrans, polystyrene nanospheres and inactive protein crystals formed by the Mx1-YFP fusion protein or other ectopically expressed proteins like vimentin. As reviewed here, properties of the chromatin environment can be identified from these experiments that determine the mobility of Cajal and PML bodies and other supramolecular complexes.

Characterization of nuclear compartments identified by ectopic markers in mammalian cells with distinctly different karyotype.

The functional organization of chromatin in cell nuclei is a fundamental question in modern cell biology. Individual chromosomes occupy distinct chromosome territories in interphase nuclei. Nuclear bodies localize outside the territories and colocalize with ectopically expressed proteins in a nuclear subcompartment, the interchromosomal domain compartment. In order to investigate the structure of this compartment in mammalian cells with distinctly different karyotypes, we analyzed human HeLa cells (3n+ = 71 chromosomes) and cells of two closely related muntjac species, the Chinese muntjac (2n = 46 chromosomes) and the Indian muntjac (2n = 6/7 chromosomes). The distribution of ectopically expressed intermediate filament proteins (vimentin and cytokeratins) engineered to contain a nuclear localization sequence (NLS) and a nuclear particle forming protein (murine Mx1) fused to a yellow fluorescent protein (YFP) was compared. The proteins were predominantly localized in regions with poor DAPI staining independent of the cells' karyotype. In contrast to NLS-vimentin, the NLS-modified cytokeratins were also found close to the nuclear periphery. In Indian muntjac cells, NLS-vimentin colocalized with Mx1-YFP as well as the NLS-cytokeratins. Since the distribution of the ectopically expressed protein markers is similar in cells with distinctly different chromosome numbers, the property of the delineated, limited compartment might indeed depend on chromatin organization.

Characterization of a nuclear compartment shared by nuclear bodies applying ectopic protein expression and correlative light and electron microscopy.

To investigate the accessibility of interphase nuclei for nuclear body-sized particles, we analyzed in cultured cells from human origin by correlative fluorescence and electron microscopy (EM) the bundle-formation of Xenopus-vimentin targeted to the nucleus via a nuclear localization signal (NLS). Moreover, we investigated the spatial relationship of speckles, Cajal bodies, and crystalline particles formed by Mx1 fused to yellow fluorescent protein (YFP), with respect to these bundle arrays. At 37 degrees C, the nucleus-targeted, temperature-sensitive Xenopus vimentin was deposited in focal accumulations. Upon shift to 28 degrees C, polymerization was induced and filament arrays became visible. Within 2 h after temperature shift, arrays were found to be composed of filaments loosely embedded in the nucleoplasm. The filaments were restricted to limited areas of the nucleus between focal accumulations. Upon incubation at 28 degrees C for several hours, NLS vimentin filaments formed bundles looping throughout the nuclei. Speckles and Cajal bodies frequently localized in direct neighborhood to vimentin bundles. Similarly, small crystalline particles formed by YFP-tagged Mx1 also located next to vimentin bundles. Taking into account that nuclear targeted vimentin locates in the interchromosomal domain (ICD), we conclude that nuclear body-sized particles share a common nuclear space which is controlled by higher order chromatin organization.

Nuclear body movement is determined by chromatin accessibility and dynamics.

Promyelocytic leukemia (PML) and Cajal bodies are mobile subnuclear organelles, which are involved in activities like RNA processing, transcriptional regulation, and antiviral defense. A key parameter in understanding their biological functions is their mobility. The diffusion properties of PML and Cajal bodies were compared with a biochemically inactive body formed by aggregates of murine Mx1 by using single-particle tracking methods. The artificial Mx1-yellow fluorescent protein body showed a very similar mobility compared with PML and Cajal bodies. The data are described quantitatively by a mechanism of nuclear body movement consisting of two components: diffusion of the body within a chromatin corral and its translocation resulting from chromatin diffusion. This finding suggests that the body mobility reflects the dynamics and accessibility of the chromatin environment, which might target bodies to specific nuclear subcompartments where they exert their biological function.

Diffusion-limited compartmentalization of mammalian cell nuclei assessed by microinjected macromolecules.

In order to investigate the accessibility of the nucleoplasm for macromolecules with different physical properties, we microinjected FITC-conjugated dextrans of different sizes as well as anionic FITC-dextrans and FITC-poly-L-lysine into mammalian cell nuclei. Small dextrans displayed a homogeneous nuclear distribution. With increasing molecular mass (42 to 2500 kDa), FITC-dextrans were progressively excluded from chromatin regions, accumulating in and thereby outlining an apparently extended interchromatin space. Anionic FITC-dextrans (500 kDa) showed complete exclusion from labeled chromatin regions, while the positively charged FITC-poly-L-lysine was to some extent present within the chromatin regions. Moreover, the FITC-poly-L-lysine preferentially localized at the nuclear periphery. We also found a size-dependent exclusion of FITC-dextrans from nucleoli regions, while the FITC-poly-L-lysine accumulated in the nucleoli. Thus, the distinct and restricted nuclear accessibility for macromolecules is dependent on molecule size and electrical charge.