Hibernation as a Stage of Ribosome Functioning.

In response to stress, eubacteria reduce the level of protein synthesis and either disassemble ribosomes into the 30S and 50S subunits or turn them into translationally inactive 70S and 100S complexes. This helps the cell to solve two principal tasks: (i) to reduce the cost of protein biosynthesis under unfavorable conditions, and (ii) to preserve functional ribosomes for rapid recovery of protein synthesis until favorable conditions are restored. All known genes for ribosome silencing factors and hibernation proteins are located in the operons associated with the response to starvation as one of the stress factors, which helps the cells to coordinate the slowdown of protein synthesis with the overall stress response. It is possible that hibernation systems work as regulators that coordinate the intensity of protein synthesis with the energy state of bacterial cell. Taking into account the limited amount of nutrients in natural conditions and constant pressure of other stress factors, bacterial ribosome should remain most of time in a complex with the silencing/hibernation proteins. Therefore, hibernation is an additional stage between the ribosome recycling and translation initiation, at which the ribosome is maintained in a "preserved" state in the form of separate subunits, non-translating 70S particles, or 100S dimers. The evolution of the ribosome hibernation has occurred within a very long period of time; ribosome hibernation is a conserved mechanism that is essential for maintaining the energy- and resource-consuming process of protein biosynthesis in organisms living in changing environment under stress conditions.

In vitro Reconstitution of the S. aureus 30S Ribosomal Subunit and RbfA Factor Complex for Structural Studies.

Ribosome-binding factor A (RbfA) from Staphylococcus aureus is a cold adaptation protein that is required for the growth of pathogenic cells at low temperatures (10-15°C). RbfA is involved in the processing of 16S rRNA, as well as in the assembly and stabilization of the small 30S ribosomal subunit. Structural studies of the 30S-RbfA complex will help to better understand their interaction, the mechanism of such complexes, and the fundamental process such as 30S subunit assembly that determines and controls the overall level of protein biosynthesis. This article describes protocols for preparation of RbfA and the small 30S ribosomal subunits and reconstitution and optimization of the 30S-RbfA complex to obtain samples suitable for cryo-electron microscopy studies.

[Elongation Factor P: New Mechanisms of Function and an Evolutionary Diversity of Translation Regulation].

The protein synthesis in cells occurs in ribosomes, with the involvement of protein translational factors. One of these translational factors is the elongation factor P (EF-P). EF-P is a three-domain protein that binds between the P and E sites of the ribosome, near the P-tRNA, the peptidyl transferase center, and E-site codon of the mRNA. The majority of studies showed that the EF-P helps the ribosome to synthesize stalling amino acid motifs, such as polyprolines. In the first part of this review, we inspect the general evolutionary variety of the EF-P in different organisms, the problems of the regulation provided by the EF-P, and its role in the sustainability of the protein balance in the cell in different physiological states. Although the functions of the EF-P have been well studied, there are still some problems that remain to be solved. The data from recent studies contradict the previous theories. Consequently, in the second part, we discuss the recent data that suggest the involvement of the EF-P in each translocation event, not only in those related to poly-proline synthesis. This activity contradicts some aspects of the known pathway of the removal of the E-tRNA during the translocation event. In addition, in the third part of this review, we tried to partly shift the interest from the antistalling activity of domain I of the EF-P to the action of domain III, the functions of which has not been closely studied. We expand on the idea about the involvement of domain III of the EF-P in preventing the frameshift and debate the EF-P's evolutionary history.

Antimicrobial peptide protegrin-3 adopt an antiparallel dimer in the presence of DPC micelles: a high-resolution NMR study.

A tendency to dimerize in the presence of lipids was found for the protegrin. The dimer formation by the protegrin-1 (PG-1) is the first step for further oligomeric membrane pore formation. Generally there are two distinct model of PG-1 dimerization in either a parallel or antiparallel ß-sheet. But despite the wealth of data available today, protegrin dimer structure and pore formation is still not completely understood. In order to investigate a more detailed dimerization process of PG-1 and if it will be the same for another type of protegrins, in this work we used a high-resolution NMR spectroscopy for structure determination of protegrin-3 (RGGGL-CYCRR-RFCVC-VGR) in the presence of perdeuterated DPC micelles and demonstrate that PG-3 forms an antiparallel NCCN dimer with a possible association of these dimers. This structural study complements previously published solution, solid state and computational studies of PG-1 in various environments and validate the potential of mean force simulations of PG-1 dimers and association of dimers to form octameric or decameric ß-barrels.

High-resolution NMR structure of the antimicrobial peptide protegrin-2 in the presence of DPC micelles.

PG-1 adopts a dimeric structure in dodecylphosphocholine (DPC) micelles, and a channel is formed by the association of several dimers but the molecular mechanisms of the membrane damage by non-α-helical peptides are still unknown. The formation of the PG-1 dimer is important for pore formation in the lipid bilayer, since the dimer can be regarded as the primary unit for assembly into the ordered aggregates. It was supposed that only 12 residues (RGGRL-CYCRR-RFCVC-V) are needed to endow protegrin molecules with strong antibacterial activity and that at least four additional residues are needed to add potent antifungal properties. Thus, the 16-residue protegrin (PG-2) represents the minimal structure needed for broad-spectrum antimicrobial activity encompassing bacteria and fungi. As the peptide conformation and peptide-to-membrane binding properties are very sensitive to single amino acid substitutions, the solution structure of PG-2 in solution and in a membrane mimicking environment are crucial. In order to find evidence if the oligomerization state of PG-1 in a lipid environment will be the same or not for another protegrins, we investigate in the present work the PG-2 NMR solution structure in the presence of perdeuterated DPC micelles. The NMR study reported in the present work indicates that PG-2 form a well-defined structure (PDB: 2MUH) composed of a two-stranded antiparallel ß-sheet when it binds to DPC micelles.

[Structure of amyloid-beta peptides in a complex with model membranes].

Structures of amyloid-beta peptides Aß1-40, Aß10-35, Aß13-23 and Aß16-22 in a complex with model membranes in solution were obtained on the analysis of NMR experimental data. It has been established that the process of peptide-micelle complex formation occurs through the amino acid residues L17, F19, F20 and G29-M35.