During the ribosomal translocation, the binding of elongation factor G (EF-G) to the pretranslocational ribosome leads to a ratchet-like rotation of the 30S subunit relative to the 50S subunit in the direction of the mRNA movement. By means of cryo-electron microscopy we observe that this rotation is accompanied by a 20 A movement of the L1 stalk of the 50S subunit, implying that this region is involved in the translocation of deacylated tRNAs from the P to the E site. These ribosomal motions can occur only when the P-site tRNA is deacylated. Prior to peptidyl-transfer to the A-site tRNA or peptide removal, the presence of the charged P-site tRNA locks the ribosome and prohibits both of these motions.
Characterization and Comprehensive Proteome Profiling of Exosomes Secreted by Hepatocytes
Synopsis Exosomes constitute a discrete population of nanometer-sized (30-150 nm) vesicles formed in endocytic compartments and released to the extracellular environment by different cell types. In this work we demonstrated by electron microscopic, western blotting and proteomic analyses that primary hepatocytes secrete exosome-like vesicles containing proteins involved in metabolizing lipoproteins, endogenous compounds as well as xenobiotics. These new findings contribute to improve our knowledge about biology's hepatocyte and may have important diagnostic, prognosis and therapeutic implications in liver diseases Exosomes represent a discrete population of vesicles that are secreted from various cell types to the extracellular media. Their protein and lipid composition are a consequence of sorting events at the level of the multivesicular body, a central organelle which integrates endocytic and secretory pathways. Characterization of exosomes from different biological samples has shown the presence of common as well as cell-type specific proteins. Remarkably, the protein content of the exosomes is modified upon pathological or stress conditions. Hepatocytes play a central role in the body response to stress metabolizing potentially harmful endogenous substances as well as xenobiotics. In the present study we described and characterized for first time exosome secretion in non-tumoral hepatocytes, and using a systematic proteomic approach, we establish the first extensive proteome of a hepatocyte-derived exosome population which should be useful in furthering our understanding of the hepatic function and in the identification of components that may serve as biomarkers for hepatic alterations. Our analysis identifies a significant number of proteins previously described among exosomes derived from others cell types as well as proteins involved in metabolizing lipoproteins, endogenous compounds and xenobiotics, not previously described in exosomes. Furthermore, we demonstrated that exosomal membrane proteins can constitute an interesting tool to express non-exosomal proteins into exosomes with therapeutic purposes.
Dynamic reorganization of the functionally active ribosome explored by normal mode analysis and cryo-electron microscopy
Combining structural data for the ribosome from x-ray crystallography and cryo-electron microscopy with dynamic models based on elastic network normal mode analysis, an atomically detailed picture of functionally important structural rearrangements that occur during translocation is elucidated. The dynamic model provides a near-atomic description of the ratchet-like rearrangement of the 70S ribosome seen in cryo-electron microscopy, and permits the identification of bridging interactions that either facilitate the conformational switching or maintain structural integrity of the 50S͞30S interface. Motions of the tRNAs residing in the A and P sites also suggest the early stages of tRNA translocation as a result of this ratchet-like movement. Displacement of the L1 stalk, alternately closing and opening the intersubunit space near the E site, is observed in the dynamic model, in line with growing experimental evidence for the role of this structural component in facilitating the exiting of tRNA. Finally, a hinge-like transition in the 30S ribosomal subunit, similar to that observed in crystal structures of this complex, is also manifest as a dynamic mode of the ribosome. The coincidence of these dynamic transitions with the individual normal modes of the ribosome and the good correspondence between these motions and those observed in experiment suggest an underlying principle of nature to exploit the shape of molecular assemblies such as the ribosome to provide robustness to functionally important motions.dynamical transitions ͉ ratchet-like reorganization ͉ translocation ͉ molecular machines T he ribosome synthesizes proteins by translating the genetic information residing on the mRNA into a specific sequence of amino acids. Binding of elongation factor G and subsequent GTP hydrolysis promotes the translocation process (1). This process is accompanied by large conformational rearrangements of the ribosome (2, 3). In particular, a ratchet-like relative rotation of the two ribosomal subunits has been observed, and proposed as a key mechanical step in the translocation of the mRNA⅐tRNAs complex (4). Other motions, such as a large displacement of the L1 stalk region (5-7, 37), rearrangement of the L7͞L12 stalk (2), and domain movement in the 30S subunit (8), have also been observed and implicated as functionally relevant for protein synthesis (9).Cryo-electron microscopy (cryo-EM) and x-ray crystallography have provided glimpses of functionally important conformational changes occurring during protein synthesis in the ribosome (2-4, 9-11). However, these static structural models provide key information mostly about the endpoint states of such large-scale conformational transitions and do not directly probe the conformational transitions. Theoretical techniques (modeling and simulation) can be used to augment this information, to lend an understanding of the dynamics at a close-to-atomic level. Recent atomic-resolution structures of the ribosome (12-14) make simulation methods based on atomic or near-atomic theories po...
Although three-dimensional electron microscopy (3D-EM) permits structural characterization of macromolecular assemblies in distinct functional states, the inability to classify projections from structurally heterogeneous samples has severely limited its application. We present a maximum likelihood-based classification method that does not depend on prior knowledge about the structural variability, and demonstrate its effectiveness for two macromolecular assemblies with different types of conformational variability: the Escherichia coli ribosome and Simian virus 40 (SV40) large T-antigen.
Aminoacyl-tRNAs (aa-tRNAs) are delivered to the ribosome as part of the ternary complex of aa-tRNA, elongation factor Tu (EF-Tu) and GTP. Here, we present a cryo-electron microscopy (cryo-EM) study, at a resolution of approximately 9 A, showing that during the incorporation of the aa-tRNA into the 70S ribosome of Escherichia coli, the flexibility of aa-tRNA allows the initial codon recognition and its accommodation into the ribosomal A site. In addition, a conformational change observed in the GTPase-associated center (GAC) of the ribosomal 50S subunit may provide the mechanism by which the ribosome promotes a relative movement of the aa-tRNA with respect to EF-Tu. This relative rearrangement seems to facilitate codon recognition by the incoming aa-tRNA, and to provide the codon-anticodon recognition-dependent signal for the GTPase activity of EF-Tu. From these new findings we propose a mechanism that can explain the sequence of events during the decoding of mRNA on the ribosome.
Cryo-EM density maps showing the 70S ribosome of E. coli in two different functional states related by a ratchet-like motion were analyzed using real-space refinement. Comparison of the two resulting atomic models shows that the ribosome changes from a compact structure to a looser one, coupled with the rearrangement of many of the proteins. Furthermore, in contrast to the unchanged inter-subunit bridges formed wholly by RNA, the bridges involving proteins undergo large conformational changes following the ratchet-like motion, suggesting an important role of ribosomal proteins in facilitating the dynamics of translation.
The homotetrameric tumor suppressor p53 consists of folded core and tetramerization domains, linked and flanked by intrinsically disordered segments that impede structure analysis by x-ray crystallography and NMR. Here, we solved the quaternary structure of human p53 in solution by a combination of small-angle x-ray scattering, which defined its shape, and NMR, which identified the core domain interfaces and showed that the folded domains had the same structure in the intact protein as in fragments. We combined the solution data with electron microscopy on immobilized samples that provided medium resolution 3D maps. Ab initio and rigid body modeling of scattering data revealed an elongated cross-shaped structure with a pair of loosely coupled core domain dimers at the ends, which are accessible for binding to DNA and partner proteins. The core domains in that open conformation closed around a specific DNA response element to form a compact complex whose structure was independently determined by electron microscopy. The structure of the DNA complex is consistent with that of the complex of four separate core domains and response element fragments solved by x-ray crystallography and contacts identified by NMR. Electron microscopy on the conformationally mobile, unbound p53 selected a minor compact conformation, which resembled the closed conformation, from the ensemble of predominantly open conformations. A multipronged structural approach could be generally useful for the structural characterization of the rapidly growing number of multidomain proteins with intrinsically disordered regions.DNA binding ͉ intrinsically unfolded ͉ modular ͉ natively disordered ͉ protein T he tumor suppressor p53 is a tetrameric, multidomain transcription factor that plays a central role in the cell cycle and maintaining genomic integrity (1, 2). It binds to specific DNA response elements, is integrated in various signaling networks by a multitude of protein-protein interactions, and is controlled by extensive posttranslational modifications (1, 3, 4). p53 protein is a homotetramer of 4 ϫ 393 residues. Each chain consists of two folded domains [the core, and the tetramerization domain (323-360)] that are linked by an intrinsically disordered sequence. The transactivation domain (1-67) (5), proline-rich region (67-94), nuclear localization signal (NLS)-containing region (303-323) (6), and C-terminal negative regulatory domain (360-393) are also intrinsically disordered (7-9) (see refs. 10 and 11 for reviews). The DNAbinding core domain (residues 94-294) binds to sequencespecific response elements associated with p53 target gene promoters (12)(13)(14). The structures of the core domain complexes with DNA have been solved by crystallography (15)(16)(17), and in solution in the absence of DNA by NMR (18). The structure of the tetramerization domain has been solved by both NMR and x-ray crystallography (19-21).Structural studies on full-length p53 have been impeded both by its intrinsic instability and the presence of disordered regions (...
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