Three-dimensional reconstruction of nucleolar components by electron microscope tomography.

The nucleus is a complex volume constituted of numerous subcompartments in which specific functions take place due to a specific spatial organization of their molecular components. To understand how these molecules are spatially organized within these machineries, it is necessary to investigate their three-dimensional organization at high resolution. To reach this goal, electron tomography appears to be a method of choice; it can generate tomograms with a resolution of a few nanometers by using multiple projections of a tilted section several hundred to several thousand nanometers in thickness imaged by transmission electron microscopy (TEM).Specific identification of molecules of interest contained within such thick sections requires their specific immunocytochemical labelling using electron-dense markers. We recently demonstrated that electron tomography of proteins immunostained with nanogold particles before embedding, and subsequently amplified with silver, was very fruitful due to the inherently high spatial resolution of the medium-voltage scanning and transmission electron microscope (STEM). Here we describe this approach, which is very efficient for tracing the 3D organization of proteins within complex machineries by using antibodies raised against one of the proteins, or against GFP to analyse GFP-tagged proteins.

Three-dimensional organization of pKi-67: a comparative fluorescence and electron tomography study using FluoroNanogold.

The monoclonal antibody (MAb) Ki-67 is routinely used in clinical studies to estimate the growth fraction of tumors. However, the role of pKi-67, the protein detected by the Ki-67 MAb, remains elusive, although some biochemical data strongly suggest that it might organize chromatin. To better understand the functional organization of pKi-67, we studied its three-dimensional distribution in interphase cells by confocal microscopy and electron tomography. FluoroNanogold, a single probe combining a dense marker with a fluorescent dye, was used to investigate pKi-67 organization at the optical and ultrastructural levels. Observation by confocal microscopy followed by 3D reconstruction showed that pKi-67 forms a shell around the nucleoli. Double labeling experiments revealed that pKi-67 co-localizes with perinucleolar heterochromatin. Electron microscopy studies confirmed this close association and demonstrated that pKi-67 is located neither in the fibrillar nor in the granular components of the nucleolus. Finally, spatial analyses by electron tomography showed that pKi-67 forms cords 250-300 nm in diameter, which are themselves composed of 30-50-nm-thick fibers. These detailed comparative in situ analyses strongly suggest the involvement of pKi-67 in the higher-order organization of perinucleolar chromatin.

Three-dimensional organization of active rRNA genes within the nucleolus.

In this work, we have localized transcribing rRNA genes at the ultrastructural level and described their three-dimensional organization within the nucleolus by electron tomography. Isolated nucleoli, which exhibit a reduced transcriptional rate, were used to determine the sites of initial BrUTP incorporation (i.e. rRNA synthesis by the transcriptional machinery). Using pulse-chase experiments with BrUTP and an elongation inhibitor, cordycepin, it was possible to precisely localize the initial sites of BrUTP incorporation. Our data show that BrUTP incorporation initially takes place in the fibrillar centers and that elongating rRNAs rapidly enter the surrounding dense fibrillar component. Furthermore, we investigated the spatial arrangement of RNA polymerase I molecules within the whole volume of the fibrillar centers. Electron tomography was performed on thick sections of cells that had been labeled with anti-RNA polymerase I antibodies prior to embedding. Detailed tomographic analyses revealed that RNA polymerase I molecules are mainly localized within discrete clusters. In each of them, RNA polymerase I molecules were grouped as several coils, 60 nm in diameter. Overall, these findings have allowed us to propose a model for the three-dimensional organization of transcribing rDNA genes within the nucleolus.