Tethering RNA to chromatin for fluorescence microscopy based analysis of nuclear organization.

Nuclear RNAs emerge as important factors to orchestrate the dynamic organization of the nucleus into functional subcompartments. By tethering RNAs to distinct genomic loci, RNA-dependent chromatin changes can be dissected by fluorescence microscopic analysis. Here we describe how this approach is implemented in mammalian cells. It involves two high-affinity protein-nucleic acid interactions that can be established with a number of different protein domains and DNA and RNA sequences. A prototypic system is described here in detail: It consists of the binding of MS2 bacteriophage coat protein to its RNA recognition sequence and the interaction between the bacterial LacI repressor protein to its target lacO operator DNA sequence. Via these interactions RNAs tagged with the MS2 recognition sequences can be recruited to a locus with integrated lacO repeats. By inducing RNA-chromatin binding a number of RNA-dependent activities can be dissected: (i) The RNA-induced compaction or decondensation of chromatin, (ii) identification of RNA-interacting chromatin modifiers that set epigenetic signals such as posttranslational histone modifications, and (iii) nuclear relocation of a genomic locus targeted by the tethered RNA. Thus, a variety of RNA-dependent activities can be evaluated with the MS2-LacI system, which are crucial for understanding how RNA shapes nuclear organization.

The shelterin protein POT-1 anchors Caenorhabditis elegans telomeres through SUN-1 at the nuclear periphery.

Telomeres are specialized protein-DNA structures that protect chromosome ends. In budding yeast, telomeres form clusters at the nuclear periphery. By imaging telomeres in embryos of the metazoan Caenorhabditis elegans, we found that telomeres clustered only in strains that had activated an alternative telomere maintenance pathway (ALT). Moreover, as in yeast, the unclustered telomeres in wild-type embryos were located near the nuclear envelope (NE). This bias for perinuclear localization increased during embryogenesis and persisted in differentiated cells. Telomere position in early embryos required the NE protein SUN-1, the single-strand binding protein POT-1, and the small ubiquitin-like modifier (SUMO) ligase GEI-17. However, in postmitotic larval cells, none of these factors individually were required for telomere anchoring, which suggests that additional mechanisms anchor in late development. Importantly, targeted POT-1 was sufficient to anchor chromatin to the NE in a SUN-1-dependent manner, arguing that its effect at telomeres is direct. This high-resolution description of telomere position within C. elegans extends our understanding of telomere organization in eukaryotes.

Samp1 is a component of TAN lines and is required for nuclear movement.

The position of the nucleus is regulated in different developmental stages and cellular events. During polarization, the nucleus moves away from the future leading edge and this movement is required for proper cell migration. Nuclear movement requires the LINC complex components nesprin-2G and SUN2, which form transmembrane actin-associated nuclear (TAN) lines at the nuclear envelope. Here we show that the nuclear envelope protein Samp1 (NET5) is involved in nuclear movement during fibroblast polarization and migration. Moreover, we demonstrate that Samp1 is a component of TAN lines that contain nesprin-2G and SUN2. Finally, Samp1 associates with SUN2 and lamin A/C, and the presence of Samp1 at the nuclear envelope requires lamin A/C. These results support a role for Samp1 in the association between the LINC complex and lamins during nuclear movement.

Three-dimensional organization of promyelocytic leukemia nuclear bodies.

Promyelocytic leukemia nuclear bodies (PML-NBs) are mobile subnuclear organelles formed by PML and Sp100 protein. They have been reported to have a role in transcription, DNA replication and repair, telomere lengthening, cell cycle control and tumor suppression. We have conducted high-resolution 4Pi fluorescence laser-scanning microscopy studies complemented with correlative electron microscopy and investigations of the accessibility of the PML-NB subcompartment. During interphase PML-NBs adopt a spherical organization characterized by the assembly of PML and Sp100 proteins into patches within a 50- to 100-nm-thick shell. This spherical shell of PML and Sp100 imposes little constraint to the exchange of components between the PML-NB interior and the nucleoplasm. Post-translational SUMO modifications, telomere repeats and heterochromatin protein 1 were found to localize in characteristic patterns with respect to PML and Sp100. From our findings, we derived a model that explains how the three-dimensional organization of PML-NBs serves to concentrate different biological activities while allowing for an efficient exchange of components.

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.

High-precision structural analysis of subnuclear complexes in fixed and live cells via spatially modulated illumination (SMI) microscopy.

Spatially modulated illumination (SMI) microscopy is a method of wide field fluorescence microscopy featuring interferometric illumination, which delivers structural information about nanoscale architecture in fluorescently labelled cells. The first prototype of the SMI microscope proved its applicability to a wide range of biological questions. For the SMI live cell imaging this system was enhanced in terms of the development of a completely new upright configuration. This so called Vertico-SMI transfers the advantages of SMI nanoscaling to vital biological systems, and is shown to work consistently at different temperatures using both oil- and water-immersion objective lenses. Furthermore, we increased the speed of data acquisition to minimize errors in the detection signal resulting from cellular or object movement. By performing accurate characterization, the present Vertico-SMI now offers a fully-fledged microscope enabling a complete three-dimensional (3D) SMI data stack to be acquired in less than 2 seconds. We have performed live cell measurements of a tet-operator repeat insert in U2OS cells, which provided the first in vivo signatures of subnuclear complexes. Furthermore, we have successfully implemented an optional optical configuration allowing the generation of high-resolution localization microscopy images of a nuclear pore complex distribution.