Site-Specific Cryo-focused Ion Beam Sample Preparation Guided by 3D Correlative Microscopy

The development of cryo-focused ion beam (cryo-FIB) for the thinning of frozen-hydrated biological specimens enabled cryo-electron tomography (cryo-ET) analysis in unperturbed cells and tissues. However, the volume represented within a typical FIB lamella constitutes a small fraction of the biological specimen. Retaining low-abundance and dynamic subcellular structures or macromolecular assemblies within such limited volumes requires precise targeting of the FIB milling process. In this study, we present the development of a cryo-stage allowing for spinning-disk confocal light microscopy at cryogenic temperatures and describe the incorporation of the new hardware into existing workflows for cellular sample preparation by cryo-FIB. Introduction of fiducial markers and subsequent computation of three-dimensional coordinate transformations provide correlation between light microscopy and scanning electron microscopy/FIB. The correlative approach is employed to guide the FIB milling process of vitrified cellular samples and to capture specific structures, namely fluorescently labeled lipid droplets, in lamellas that are 300 nm thick. The correlation procedure is then applied to localize the fluorescently labeled structures in the transmission electron microscopy image of the lamella. This approach can be employed to navigate the acquisition of cryo-ET data within FIB-lamellas at specific locations, unambiguously identified by fluorescence microscopy.     

The import pathway of human and Thermoplasma 20S proteasomes into HeLa cell nuclei is different from that of classical NLS-bearing proteins

Wild-type proteasomes of human erythrocytes and the archaeon Thermoplasma acidophilum compete with each other for transport into nuclei of digitonin-permeabilized HeLa cells in the presence of an energy-regenerating system and rabbit reticulocyte lysate. 'NLS'-mutated Thermoplasma proteasomes were also able to compete with human proteasomes in the same assay, although with lower efficiency. Furthermore, in contrast to the other archaeal and bacterial cell lysates tested, the Thermoplasma cytosol efficiently supported nuclear import of human and Thermoplasma proteasomes. However, the same lysate could barely direct the nuclear transport of BSA-NLSsv40 peptide conjugates or the classical NLS-bearing protein, nucleoplasmin. Finally, additional importin alpha/beta significantly decreased the import efficiency of both human and Thermoplasma proteasomes. Taken together, these results suggest that nuclear import of proteasomes may use a novel pathway that is different from that of classical NLS-bearing proteins.     

Microvascular anastomosis in an optical cavity: is it possible?

Microsurgery is one of the highly interesting surgical procedures that can be performed using different applications and in different specialties, including plastic surgery. The endoscope is a popular instrument used in many fields, including plastic surgery. Although the operating microscope is still a must for microsurgical performance, microsurgery could be performed, depending on the experiences and facilities, by using other visual-assisting equipment. From this point of view, the authors tried to find less costly and more widespread equipment suitable for performing microsurgery that can, furthermore, be applied in special situations and indications, such as operating in an optical cavity. The authors investigated this issue with the endoscope. In this experimental project, the authors performed vascular microsurgical anastomoses of the rats' femoral vessels to create an optical cavity in a prefabricated skin retraction model in the groin area of 10 Sprague-Dawley male rats. The microsurgical anastomoses of the femoral vessels and nerves were performed easily in a reasonable time, without recorded difficulties, and with maximum physical and visual comfort for the surgeon. The authors spent a mean time of 28.1, 27.3, and 19.2 minutes for the arterial, venous, and neural anastomoses, respectively. In this group of animals, 90 percent vascular patency and 100 percent accurate neural anastomoses were recorded. The advantage the authors noted was that this new technique of operating in the field of microsurgery, with its feasibility and difficulties, would be a point of research and application for the young generations of microsurgeons.     

Mapping molecular landscapes inside cells

Cryoelectron tomography opens a window into the inner space of cells. It combines the potential of three-dimensional imaging with a close-to-life preservation of biological samples. Tomograms with molecular resolution are essentially images of the cellular proteome and, in conjunction with advanced pattern recognition techniques, they can be used to map the molecular landscape inside organelles and cells.     

Proteasome-cytochrome c interactions: a model system for investigation of proteasome host-guest interactions

Owing to its high thermal stability and structural simplicity, the archaebacterium Thermoplasma Acidophilum 20S proteasome was selected for mechanistic studies in this work. This oligomeric enzyme complex consists of a barrel-shaped 20S core (approximately 700kDa) comprised of four stacked seven-membered rings with a alpha(7)beta(7)beta(7)alpha(7) subunit structure situated around a 7-fold symmetry axis. The hollow interior of the proteasome has three large interconnected chambers with narrow (13 A diameter) entrances from solution located at either end of the barrel. The 14 beta-subunit proteolytic sites are located on the inner surface of the central chamber. Herein, we demonstrate that unfolded horse heart ferricytochrome c (Cyt c) is a novel chromophoric probe for investigation of the mechanism of proteasome action. Under conditions of temperature and denaturant which unfold Cyt c but do not alter the thermophilic proteasome, Cyt c is extensively cleaved by the proteasome. Ten peptides were isolated and sequenced from the proteasome digest. Analysis of the cleavage products established that unfolded Cyt c and its covalently attached heme prosthetic group are translocated to the central chamber where proteolysis occurs. In the presence of site-specific inhibitors of the proteasome, we demonstrate that unfolded cytochrome c can be sequestered inside the proteasome complex. Upon cooling, a quasistable host-guest complex is formed. Analysis of the complex via UV/visible spectroscopy and mass spectrometry gave evidence that the sequestered Cyt c is essentially intact within the inhibited proteasome. High-performance liquid chromatography data show that (1) complexes with an apparent stoichiometry of approximately one Cyt c per proteasome can be formed and (2) when inhibition is removed from the complex, a rapid turnover of the sequestered Cyt c occurs.     

FhuA-mediated phage genome transfer into liposomes: a cryo-electron tomography study

BACKGROUND: The transfer of phage genomes into host cells is a well established but only dimly understood process. Following the irreversible phage binding to a receptor in the bacterial outer membrane, the DNA is ejected from the viral capsid and transferred across the bacterial cell envelope. In Escherichia coli, the mere interaction of the phage T5 with its outer membrane receptor, the ferrichrome transporter FhuA, is sufficient to trigger the release of the DNA from the phage capsid. Although the structure of FhuA has been determined at atomic resolution, the understanding of the respective roles of phage and bacterial proteins in DNA channeling and the mechanisms by which the transfer of the DNA is mediated remains fragmentary. RESULTS: We report on the use of cryo-electron tomography to analyze, at a molecular level, the interactions of T5 phages bound to FhuA-containing proteoliposomes. The resolution of the three-dimensional reconstructions allowed us to visualize the phage-proteoliposome interaction before and after release of the genome into the vesicles. After binding to its receptor, the straight fiber of the phage T5 (the "tip" of the viral tail made of pb2 proteins) traverses the lipid bilayer, allowing the transfer of its double-stranded DNA (121,000 bp) into the proteoliposome. Concomitantly, the tip of the tail undergoes a major conformational change; it shrinks in length (from 50 to 23 nm), while its diameter increases (from 2 to 4 nm). CONCLUSIONS: Taking into account the crystal structure of FhuA, we conclude that FhuA is only used as a docking site for the phage. The tip of the phage tail acts like an "injection needle," creating a passageway at the periphery of FhuA, through which the DNA crosses the membrane. A possible mechanistic scenario for the transfer of the viral genome into bacteria is discussed.     

A giant protease with a twist: the TPP II complex from Drosophila studied by electron microscopy

Tripeptidyl peptidase II (TPP II) is an exopeptidase of the subtilisin type of serine proteases that is thought to act downstream of the proteasome in the ubiquitin-proteasome pathway. Recently, a key role in a pathway parallel to the ubiquitin-proteasome pathway has been ascribed to TPP II, which forms a giant protease complex in mammalian cells. Here, we report the 900-fold purification of TPP II from Drosophila eggs and demonstrate via cryo-electron microscopy that TPP II from Drosophila melanogaster also forms a giant protease complex. The presented three-dimensional reconstruction of the 57 x 27 nm TPP II complex at 3.3 nm resolution reveals that the 150 kDa subunits form a superstructure composed of two segmented and twisted strands. Each strand is 12.5 nm in width and composed of 11 segments that enclose a central channel.     

ATP hydrolysis by the proteasome regulatory complex PAN serves multiple functions in protein degradation

To clarify the role of ATP in proteolysis, we studied archaeal 20S proteasomes and the PAN (proteasome-activating nucleotidase) regulatory complex, a homolog of the eukaryotic 19S ATPases. PAN's ATPase activity was stimulated similarly by globular (GFPssrA) and unfolded (casein) substrates, and by the ssrA recognition peptide. Denaturation of GFPssrA did not accelerate its degradation or eliminate the requirement for PAN and ATP. During degradation of one molecule of globular or unfolded substrates, 300-400 ATP molecules were hydrolyzed. An N-terminal deletion in the 20S alpha subunits caused opening of the substrate-entry channel and rapid degradation of unfolded proteins without PAN; however, degradation of globular GFPssrA still required PAN's ATPase activity, even after PAN-catalyzed unfolding. Thus, substrate binding activates ATP hydrolysis, which promotes three processes: substrate unfolding, gate opening in the 20S, and protein translocation.