[Molecular changes in inbred mice with individual vulnerability vs resilience to stress-induced depressive-like state].

The C57BL/6 mice were subjected to a chronic combined stress which resulted in the induction of a depressive-like state. The occurrence of a depressive-like state was defined by a decrease in sensitivity to the reward determined by the diminished preference of sweetened solutions over regular drinking water. Such decrease is generally considered as a sign of an unhedonic-like state: one of the key features of clinical depression. Applied here, the paradigm in mice allows unhedonia induction in a subpopulation of stressed animals (54% in the current study); remaining mice are regarded as resilient to stress-induced hedonic deficit. The resilient subgroup is taken, therefore, as a "functional control" for those effects of stress that are not accompanied by development of the stress-induced depressive-like state in mice. The analysis of the mRNA extracted from the hippocampi of stress-subjected and home-cage control mice enabled the assessment of gene expression level of over 13 000 genes. This study showed that unhedonic mice are characterized by an up-regulation of 278 and down-regulation of 174 genes related mostly to the CNS development and functions, inter-cellular interactions and signalling, neurological disorders, apoptosis and behavioural regulation. Resilient animals demonstrated up-regulation of 924 and down-regulation of only 29 genes that control formation of cell assemblies, molecular transport, CNS functioning, neurological disorders and various biochemical reactions. Thus, gene expression profiles in the hippocampus of susceptible vs resilient to stress-induced unhedonia inbred subgroups of animals are strictly distinct in both quantity and quality.

[A new method to measure the functional activity of class-1 translation termination factor eRF1]. / Novyi metod opredeleniia funktsional'noi aktivnosti factora terminatsii transliatsii pervogo klassa eRF1.

Termination of protein synthesis (hydrolysis of the last peptidyl-tRNA on the ribosome) takes place when the ribosomal A site is occupied simultaneously by one of the three stop codons and by a class-1 translation termination factor. The existing procedures to measure the functional activity of this factor both in vitro and in vivo have serious drawbacks, the main of which are artificial conditions for in vitro assays, far from those in the cell, and indirect evaluation of activity in in vivo systems. A simple reliable and sensitive system to measure the functional activity of class-1 translation termination factors could considerably expedite the study of the terminal steps of protein synthesis, at present remaining poorly known, especially in eukaryotes. We suggest a novel system to test the functional activity in vitro using native functionally active mRNA, rather than tri-, tetra-, or oligonucleotides as before. This mRNA is specially designed to contain one of the three terminating (stop) codons within the coding nucleotide sequence. Plasmids have been generated that carry the genes of suppressor tRNAs each of which is specific toward one of the three stop codons. They were shown to support normal synthesis of a reporter protein, luciferase, by reading through the stop codon within the coding mRNA sequence. We have demonstrated that human class-1 translation termination factor eRF1 is able to compete with suppressor tRNA for a stop codon and to completely prevent its suppressive effect at a sufficient concentration. Forms of eRF1 with point mutations in functionally essential regions have lower competitive ability, demonstrating the sensitivity of the method to the eRF1 structure. The enzymatic reaction catalyzed by the full-size reporter protein is accompanied by emission of light quanta. Therefore, competition between suppressor tRNA and eRF1 can be measured using a luminometer, and this allows precise kinetic measurements in a continuous automatic mode.

[Suppression of nonsense mutations in the Dystrophin gene by a suppressor tRNA gene]. / Ispol'zovanie gena supressornoi tRNK dlia ispravleniia nonsens-mutatsii v gene distrofina.

Nonsense mutations in the dystrophin gene are the cause of Duchenne muscular dystrophy (DMD) in 10-15% of patients. In such an event, one approach to gene therapy for DMD is the use of suppressor tRNAs to overcome the premature termination of translation of the mutant mRNA. We have carried out cotransfection of the HeLa cell culture with constructs containing a suptRNA gene (pcDNA3suptRNA) and a marker LacZ gene (pNTLacZhis) using their polymer VSST-525 complexes. It was found that the number of cells producing beta-galactosidase depends inversely on the dose of the suptRNA gene. A single in vivo injection of the construct providing for expression of the suptRNAochre gene into mdx mouse muscle resulted in the production of dystrophin in 2.5% of fibers. This suggests that suppressor tRNAs are applicable in gene therapy for hereditary diseases caused by nonsense mutations.

Dimer formation by tRNAs.

Available data on formation of dimers and other oligomers by "mature" tRNAs and the transcripts of their genes show that the dimers may be formed in vitro during the purification of individual tRNAs as well as on heating and subsequent cooling of tRNA preparations. The functional activity of dimers varies for different tRNAs. Structural analysis of tRNAs that are able or unable to form dimers suggests the importance of the hairpin melting temperature for dimer formation. Pathways of dimer formation and specific structural features of tRNA dimers are discussed.

Transfer RNA(Phe) isoacceptors possess non-identical set of identity elements at high and low Mg2+ concentration.

Primary structures of phage T5- and Escherichia coli-encoded tRNA(Phe) are distinct at four out of 11 positions known as identity elements for E. coli phenylalanyl-tRNA synthetase (FRS). In order to reveal structural requirements for FRS recognition, aminoacylation of wild-type phage T5 tRNA(Phe) gene transcript and mutants containing substitutions of the identity elements at positions 20, 34, 35 and 36 was compared with E. coli tRNA(Phe) gene transcript. The wild-type phage T5 transcript can be aminoacylated with the same catalytic efficiency as the E. coli counterpart. However, the maximal aminoacylation rate for T5 and E. coli transcripts was reached at different Mg2+ concentrations: 4 and 15 mM, respectively. Aminoacylation assays with tRNA(Phe) mutants revealed that (i) phage transcripts with the substituted anticodon bases at positions 35 and 36 were efficient substrates for aminoacylation at 15 mM Mg2+ but not at optimal 4 mM Mg2+; (ii) any change of G34 in phage transcripts dramatically decreased the aminoacylation efficiency at both 4 and 15 mM Mg2+ whereas G34A mutation in the E. coli transcript exhibits virtually no influence on aminoacylation rate at 15 mM Mg2+; (iii) substitution of A20 with U in the phage transcript caused no significant change in the aminoacylation rate at both Mg2+ concentrations; (iv) phage transcripts with double substitutions A20U+A35C and A20U+A36C were very poor substrates for FRS. Collectively, the results indicate the non-identical mode of tRNA(Phe) recognition by E. coli FRS at low and high Mg2+ concentrations. Probably, along with identity elements, the local tRNA conformation is essential for recognition by FRS.