[Intersubunit Mobility of the Ribosome].

Ribosomes are ribonucleoprotein nanoparticles synthesizing all proteins in living cells. The function of the ribosome is to translate the genetic information encoded in a nucleotide sequence of mRNA into the amino acid sequence of a protein. Each translation step (occurring after the codon-dependent binding of the aminoacyl-tRNA with the ribosome and mRNA) includes (i) the transpeptidation reaction and (ii) the translocation that unidirectionally drives the mRNA chain and mRNA-bound tRNA molecules through the ribosomal intersubunit space; the latter process is driven by the free energy of the chemical reaction of transpeptidation. Thus, the translating ribosome can be considered a conveying protein-synthesizing molecular machine. In this review we analyze the role of ribosomal intersubunit mobility in the process of translocation.

Formation of New Polysomes on Free mRNAs in a Cell-Free Translation Systems Is Accompanied by Partial Disassembly of Previously Formed Polysomes.

A method for detection of the fluorescence-labeled mRNA in translating ribosomal complexes has been developed. It is demonstrated that in the working cell-free translation system with preformed polysomes, formation of new polysomes on free mRNA takes place. For the first time, it is shown that the process is accompanied by partial disassembly of the previously formed polysomes. This result is interpreted as an indication of the direct relationship between processes of translation termination of polysomal ribosomes and translation initiation of free mRNAs.

Topology of mRNA chain in isolated eukaryotic double-row polyribosomes.

In the process of protein synthesis, the translating ribosomes of eukaryotic cells form polyribosomes that are found to be multiplex functional complexes possessing elements of ordered spatial organization. As revealed by a number of electron microscopy studies, the predominant visible configurations of the eukaryotic polyribosomes are circles (circular polyribosomes) and two-stranded formations (so-called double-row polyribosomes). The "long" (i.e. heavy loaded) polyribosomes are usually represented by double-row structures, which can be interpreted as either topologically circular ("collapsed rings"), or topologically linear (zigzags or helices). In the present work we have analyzed the mRNA path within the eukaryotic polyribosomes, isolated from a wheat germ cell-free translation system, by integrating two approaches: the visualization of mRNA ends in polyribosomes by marking them with gold nanoparticles (3'-end) and initiating 40S subunits (5'-end), as well as by the cryoelectron tomography. Examination of the location of the mRNA markers in polyribosomes and mutual orientation of ribosomes in them has shown that the double-row polyribosomes of the same sample can have both circular and linear arrangements of their mRNA.

Internal initiation of polyuridylic acid translation in bacterial cell-free system.

The task of the present work was to answer the question: is the free 5'-end needed for effective translation of a model polyribonucleotide template - polyuridylic acid - in a bacterial (E. coli) cell-free system? For this purpose, the template activities of the original polyuridylic acid with its free 5'-end and the polyuridylic acid with blocked 5'-end were compared in the bacterial cell-free translation system. To block the 5'-end, the cytidylic oligodeoxyribonucleotide with fluorescein residue at its 5'-end and uridylic oligoribonucleotide sequence at its 3'-end, schematically described as FAM(dC)10(rU)50, was covalently attached (ligated) to the 5'-end of the template polyuridylic acid. It was shown that the efficiency of polyphenylalanine synthesis on the 5'-blocked template and on the polyuridylic acid with free 5'-end was virtually the same. It was concluded that bacterial ribosomes are capable of effectively initiating translation at the polyuridylic sequence independently of the 5'-end of template polyribonucleotide, i.e. via an internal initiation mechanism, in the absence of a Shine-Dalgarno sequence and AUG start codon.

Leader sequences of eukaryotic mRNA can be simultaneously bound to initiating 80S ribosome and 40S ribosomal subunit.

Binding of mRNA leader sequences to ribosomes was studied in conditions of a cell-free translation system based on wheat germ extract. Leader sequence of TMV mRNA (the so-called omega-RNA sequence) was able to bind simultaneously 80S ribosome and 40S ribosomal subunit. It was found that nucleotide substitutions in omega-RNA resulting in destabilization of RNA structure have no effect on the complex formation with both 80S ribosome and 40S ribosomal subunit. Leader sequence of globin mRNA is also able to form a similar joint complex. It is supposed that the ability of mRNA leader sequences to bind simultaneously 80S ribosome and 40S subunit is independent of leader nature and may reflect previously unknown eukaryotic mechanisms of translation initiation.

Chemical and enzymatic probing of spatial structure of the omega leader of tobacco mosaic virus RNA.

The 5'-untranslated sequence of tobacco mosaic virus RNA - the so-called omega leader - exhibits features of a translational enhancer of homologous and heterologous mRNAs. The absence of guanylic residues, the presence of multiple trinucleotide CAA repeats in its central region, and the low predictable probability of the formation of an extensive secondary structure of the Watson-Crick type were reported as the peculiarities of the primary structure of the omega leader. In this work we performed chemical and enzymatic probing of the secondary structure of the omega leader. The isolated RNA comprising omega leader sequence was subjected to partial modifications with dimethyl sulfate and diethyl pyrocarbonate and partial hydrolyses with RNase A and RNase V1. The sites and the intensities of the modifications or the cleavages were detected and measured by the primer extension inhibition technique. The data obtained have demonstrated that RNase A, which attacks internucleotide bonds at the 3' side of pyrimidine nucleotides, and diethyl pyrocarbonate, which modifies N7 of adenines not involved in stacking interactions, weakly affected the core region of omega leader sequence enriched with CAA-repeats, this directly indicating the existence of a stable spatial structure. The significant stability of the core region structure to RNase A and diethyl pyrocarbonate was accompanied by its complete resistance against RNase V1, which cleaves a polyribonucleotide chain involved in Watson-Crick double helices and generally all A-form RNA helices, thus being an evidence in favor of a non-Watson-Crick structure. The latter was confirmed by the full susceptibility of all adenines and cytosines of the omega polynucleotide chain to dimethyl sulfate, which exclusively modifies N1 of adenines and N3 of cytosines not involved in Watson-Crick interactions. Thus, our data have confirmed that (1) the regular (CAA)(n) sequence characteristic of the core region of the omega leader does form stable secondary structure, and (2) the structure formed is not the canonical double helix of the Watson-Crick type.

[Folding of the firefly luciferase polypeptide chain with immobilized C-terminus].

Refolding of Photinus pyralis firefly luciferase from a denatured state is a slow process; its rate and productivity depend on molecular chaperones of the Hsp70 family. In contrast, cotranslational folding of the enzyme is fast and productive in the absence of chaperones [Svetlov et al., 2006. Protein Sci. 15, 242-247]. During cotranslational folding, the C-termini of polypeptides are bound to massive particles - ribosomes. The question arises whether the immobilization of the polypeptide C-terminus on a massive particle promotes the folding. To test this experimentally, the luciferase with oligohistidine tag at its C-terminus was prepared. This allowed us to immobilize the protein C-terminal segment on chelating Sepharose beads. Here we show that both immobilized and free chains of urea-denatured enzyme refold with the same rate. At the same time, the immobilization of luciferase results in higher refolding yield due to prevention of inter-molecular aggregation. Chaperones of the Hsp70 family promote refolding of both immobilized and free luciferase polypeptides. The results presented here suggest that the high rate of cotranslational folding is not caused by the immobilization of polypeptide C-termini by itself, but is rather due to a favorable start conformation of the growing polypeptide in the peptidyl-transferase center of the ribosome and/or the strongly vectorial character of the folding from N- to C-terminus during polypeptide synthesis.

[RNA world and its evolution].

The early idea of A. N. Belozersky on the precedence of RNA in the origin of life on Earth is developed. Basing on the present knowledge of functional omnipotence of RNA, the author considers three novel mechanisms that could play a critical role in the origin and evolution of the ancient RNA world: (1) the reaction of spontaneous transesterification of polyribonucleotides in aqueous media, discovered by A.B. Chetverin, which could result in elongation of primary short oligoribonucleotides and generation of sequence variants for subsequent selection; (2) compartmentation of functional RNA ensembles in the form of mixed molecular colonies on moist solid surfaces, in the absence of membranes and any other coats; (3) systematic exponential enrichment of RNA population in functionally "the best" molecules by means of alternately dissolving the colonies upon flooding and forming new ones upon drying a pool ("primordial natural SELEX").

Effective non-viral leader for cap-independent translation in a eukaryotic cell-free system.

The 61 nt 5'-untranslated region (5'-UTR) of mRNA encoding for a light-emitting protein of hydroid polyp Obelia longissima, obelin, is shown to provide a high level of cap-independent translation of heterologous mRNAs in cell-free translation systems based on wheat germ extracts. The inhibition of translation typically observed when excess mRNA is present or produced in a eukaryotic system (the so-called self-inhibition phenomenon) is found abated with mRNA constructs carrying the obelin mRNA leader. The role of the sequestration of a limiting initiation factor, probably eIF4F, in the self-inhibition phenomenon and the possible independence of the obelin mRNA leader from eIF4F are discussed. We propose the obelin mRNA leader be used for effective cap-independent translation in eukaryotic cell-free systems, including combined transcription-translation systems with uncontrolled phage polymerase-catalyzed accumulation of mRNA.

[RNA polymerase as a molecular machine]. / RNK-polimeraza kak molekuliarnaia mashina.

Structure and function of DNA-dependent RNA polymerase is considered in terms of a conveying molecular machine. The use of mechanical energy and mechanical devices, such as "power-stroke motor", is supposed unlikely in the conveying function of RNA polymerase, as well as other molecular machines. Brownian motion and thermal mobility of macromolecules and their parts are postulated as the only motive impulse at the molecular level. Binding of substrates and subsequent chemical reaction as the energy input may provide successive selection and fixation of alternative conformational states of the enzyme complex thus providing the directionality of the conveyance ("Brownian ratchet mechanism"). The following sequence of events "substrate binding--fixation of a certain conformational state--chemical reaction--fixation of an alternative conformational state--translocation (dissociation and downstream reassociation) of product-template duplex" is proposed as the principal scheme of the forward movement of RNA polymerase along DNA template.

Ribosome-associated protein that inhibits translation at the aminoacyl-tRNA binding stage.

We have recently isolated and characterized a novel protein associated with Escherichia coli ribosomes and named protein Y (pY). Here we show that the ribosomes from bacterial cells growing at a normal physiological temperature contain no pY, whereas a temperature downshift results in the appearance of the protein in ribosomes. The protein also appears in the ribosomes of those cells that reached the stationary phase of growth at a physiological temperature. Our experiments with cell-free translation systems demonstrate that the protein inhibits translation at the elongation stage by blocking the binding of aminoacyl-tRNA to the ribosomal A site. The function of the protein in adaptation of cells to environmental stress is discussed.

Cell-free production of biologically active polypeptides: application to the synthesis of antibacterial peptide cecropin.

An approach to preparative production of polypeptides, including uneasily testable, degradable, and toxic ones, is proposed on the basis of in vitro expression systems of last generation, such as continuous-exchange cell-free and continuous-flow cell-free transcription-translation systems. The approach implies that a polypeptide of interest is synthesized as a fusion protein with the polypeptide linked to green fluorescent protein (GFP) through a cleavable spacer. The GFP moiety provides direct visualization and quantitative monitoring of the polypeptide synthesis, as well as solubility and stability of the product. The synthesis of functionally active antibacterial polypeptide cecropin P1 (31 amino acid residues) has been demonstrated.

Continuous-exchange cell-free protein-synthesizing system: synthesis of HIV-1 antigen Nef.

HIV-1 antigen Nef, Green Fluorescent Protein (GFP), and the fusion protein GFP-Nef ("Green Fluorescent Nef") were synthesized in bacterial cell-free system with continuous supply of substrates and continuous removal of low-molecular-weight products through a dialysis membrane during incubation, the so-called continuous-exchange cell-free (CECF) system. The identity of synthesized proteins was confirmed by electrophoretic mobility, Western blotting, and GFP fluorescence. The system produced several nanomoles (hundreds of microg) of each protein per ml of the reaction mixture. Construction of GFP-fused proteins is considered as a general strategy for visualization and monitoring of cell-free production of the proteins that have no easily testable functions.

Co-translational folding of an eukaryotic multidomain protein in a prokaryotic translation system.

Continuous monitoring of the enzymatic activity of newly synthesized firefly luciferase in Escherichia coli cell-free translation system was performed to record folding kinetics of this multidomain eukaryotic protein in the prokaryotic cytosol. Whereas in vitro refolding of denatured luciferase in prokaryotic cytosol occurred with a low yield of active enzyme and took about an hour, the enzyme acquired its native structure immediately upon release from the ribosome, as seen from the immediate halt of active luciferase accumulation upon blocking of translation with inhibitors. The nascent luciferase was also capable of acquiring the active conformation prior to release from the ribosome, when its C terminus was extended with a polypeptide segment. Specific enzymatic activity of the firefly luciferase was found to be equally high irrespective of whether this protein was synthesized in eukaryotic or prokaryotic translation systems. The data presented demonstrate the fundamental ability of prokaryotic cytosol to support effective co-translational protein folding in general and co-translational folding of multidomain proteins in particular.

Cell-free synthesis and affinity isolation of proteins on a nanomole scale.

The performance of conventional cell-free gene expression systems based on the Escherichia coli S30 extract can be significantly improved by using expression vectors that encode viral structural elements known to enhance translation in vivo and to protect mRNA from ribonuclease action. The expression vectors reported here are designed to produce a functionally active protein carrying the Strep-tag oligopeptide at its C-terminus. They can be used in translation, transcription-translation or replication-translation reactions. Depending on its type, the reaction yields up to 40 micrograms per mL, or about 1 nmol of a standard protein. The presence of Strep-tag allows the synthesized protein to be easily isolated on a streptavidin-agarose column under mild conditions and the entire procedure to be completed within one working day. The results show that standard low-cost, cell-free systems can serve for rapid preparation of purified proteins in amounts that can satisfy a number of needs of a research laboratory.