[Expanding the Genetic Code: Unnatural Base Pairs in Biological Systems].

The genetic code is considered to use five nucleic bases (adenine, guanine, cytosine, thymine and uracil), which form two pairs for encoding information in DNA and two pairs for encoding information in RNA. Nevertheless, in recent years several artificial base pairs have been developed in attempts to expand the genetic code. Employment of these additional base pairs increases the information capacity and variety of DNA sequences, and provides a platform for the site-specific, enzymatic incorporation of extra functional components into DNA and RNA. As a result, of the development of such expanded systems, many artificial base pairs have been synthesized and tested under various conditions. Following many stages of enhancement, unnatural base pairs have been modified to eliminate their weak points, qualifying them for specific research needs. Moreover, the first attempts to create a semi-synthetic organism containing DNA with unnatural base pairs seem to have been successful. This further extends the possible applications of these kinds of pairs. Herein, we describe the most significant qualities of unnatural base pairs and their actual applications.

[Local Protein Synthesis in Dendrites and its Regulation Normally and During Plastic Changes].

Specifics and key regulation mechanisms of compartmentalised protein synthesis in dendrites are reviewed. The up-to-date literature data of the subject are analysed. The results of many molecular, cytological and physiological experiments are presented. Also there is some information about a number of neurological diseases connected with dendritic translation regulation malfunction.

Receptor-binding domain of ephrin-A1: production in bacterial expression system and activity.

Eph receptor tyrosine kinases and their ligands, the ephrins, perform an important regulatory function in tissue organization, as well as participate in malignant transformation of cells. Ephrin-A1, a ligand of A class Eph receptors, is a modulator of tumor growth and progression, and the mechanism of its action needs detailed investigation. Here we report on the development of a system for bacterial expression of an ephrin-A1 receptor-binding domain (eA1), a procedure for its purification, and its renaturation with final yield of 50 mg/liter of culture. Functional activity of eA1 was confirmed by immunoblotting, laser scanning confocal microscopy, and flow cytometry. It is shown that monomeric non-glycosylated receptor-binding domain of ephrin-A1 is able to activate cellular EphA2 receptors, stimulating their phosphorylation. Ligand eA1 can be used to study the features of ephrin-A1 interactions with different A class Eph receptors. The created expression cassette is suitable for the development of ligands with increased activity and selectivity and experimental systems for the delivery of cytotoxins into tumor cells that overexpress EphA2 or other class A Eph receptors.

[Isolation and functional characterization of lipase from the thermophilic alkali-tolerant bacterium Thermosyntropha lipolytica].

As a result of sequencing the genome of the termophilic alkali-tolerant lipolytic bacterium Thermosyntropha lipolytica, the gene encoding a lipase secreted into the medium was identified. The recombinant enzyme was expressed in Escherichia coli. It was isolated, purified, and functionally characterized. The lipase exhibited hydrolytic activity toward para-nitrophenyl esters of various chain lengths, as well as triglycerides, including vegetable oils. The optimal reaction conditions were achieved at temperatures from 70 to 80 degrees C and pH 8.0. Enzyme saved more than 80% of its activity in the presence of 10% methanol. This new thermostable lipase may be a promising biocatalyst for organic synthesis; it may find application in the food and detergent industry and biodiesel production.

[Interface of the interaction of the middle domain of human translation termination factor eRF1 with eukaryotic ribosomes].

Termination of translation in eukaryotes is governed by two polypeptide chain release factors. The middle (M) domain of the class 1 translation termination factor eRF1 contains the strictly conserved GGQ motif and involved in hydrolysis of the peptidyl-tRNA ester bond within the peptidyl transferase center of the large ribosome subunit. Heteronuclear NMR spectroscopy was used to map the interaction interface of the M-domain of human termination factor eRF1 with eukaryotic ribosomes. The protein was found to interact specifically with the large 60S ribosomal subunit: no interaction was detected between the M-domain of eRF1 and the 40S ribosomal subunit. The protein residues at the interaction interface are mainly situated on the long alpha-helix, alpha1 of the M-domain. Some residues adjacent to alpha1, in strand beta5, and in two short helices alpha2 and alpha3 are also involved in the protein-ribosome contact. The interaction of the functionally inactive mutant G183A with the 60S ribosomal subunit is substantially weaker than that found for the wild-type protein. Moreover, the interaction interfaces are not identical in these two cases. The results highlight the functional importance of the long alphal helix and also indicate that conformational flexibility of the GGQ loop is essential for forming tight protein-ribosome contacts.

[How translation termination factor eRF1 Euplotes does not recognise UGA stop codon].

In universal-code eukaryotes, a single class-1 translation termination factor eRF1 decodes all three stop codons, UAA, UAG, and UGA. In some ciliates with variant genetic codes one or two stop codons are used to encode amino acid(s) and are not recognized by eRF1. In Stylonychia, UAG and UAA codons are reassigned as glutamine codons, and in Euplotes, UGA is reassigned as cysteine codon. In omnipotent eRF1s, stop codon recognition is associated with the N-terminal domain of eRF1. Because variant-code ciliates most likely evolved from universal code ancestor(s), structural features should exist in ciliate eRF1s that restrict their stop codon recognition. To find out amino acid residues which confer UAR-only specificity to Euplotes aediculatus eRF1, eRFI chimeras were constructed by swapping eRF1 E. aediculatus N-terminal domain sequences with the matching ones from the human protein. In these chimeras the MC-domain was from human eRF1. Functional analysis of these chimeric eRFI highlighted the crucial role of the two regions (positions 38-50 and 123-145) in the N-terminal domain of E. aediculatus eRF1 that restrict E. aediculatus eRF1 specificity toward UAR codons. Possibly, restriction of eRF1 specificity to UAR codons might have been an early event occurring in independent instances in ciliate evolutionary history, possibly facilitating the reassignment of UGA to sense codons.

[Influence of individual domains of the translation termination factor eRF1 on induction of the GTPase activity of the translation termination factor eRF3].

Translation termination in eukaryotes is governed by two proteins, belonging to the class-1 (eRF1) and class-2 (eRF3) polypeptide release factors. eRF3 catalyzes hydrolysis of GTP to GDP and inorganic phosphate in the ribosome in the absence of mRNA, tRNA, aminoacyl-tRNA and peptidyl-tRNA but needs the presence of eRF1. It's known that eRF1 and eRF3 interact with each other in vitro and in vivo via their C-terminal regions. eRF1 consists of three domains - N, M, and C. In this study we examined the influence of individual domains of the human eRF1 on induction of the human eRF3 GTPase activity in the ribosome in vitro. It was shown that none of the N-, M-, C- and NM-domains induces eRF3 GTPase activity in presence of the ribosomes. MC-domain does induce GTPase activity of eRF3 but four times less efficient than full-length eRF1, therefore, MC-domain (and very likely M-domain) binds to the ribosome in the presence of eRF3. Based on these data and taking into account the data available in literature, a conclusion was drawn that the N domain of eRF1 is not essential for eRF1-dependent induction of the eRF3 GTPase activity. A working hypothesis is formulated, postulating that GTPase activity eRF3 during the translation termination is associated with the intermolecular interactions of GTP/GDP, GTPase center of the large ribosomal subunit (60S), MC-domain of eRF1, C-terminal region and GTP-binding domains of eRF3, but without participation of the N-terminal region of eRF3.

[Thermal denaturation of eukaryotic class 1 translation termination factor eRF1. Relationship between stability of the eRF1 molecule and alteration of functional activity of its mutants].

Thermal denaturation of eukaryotic class-1 translation termination factor eRF1 and its mutants was examined using differential scanning microcalorimetry (DSK). Changes of free energy caused by mutants in the N domain of human eRF1 were calculated. Melting of eRF1 molecule composed of three individual domains is cooperative. Some amino acid substitutions did not affect protein thermostability and in some other cases even slightly stabilize the protein globule. These imply that these amino acid residues are not involved in maintenance of the 3D structure of human eRF1. Thus, in Glu55Asp, Tyr125Phe, Asn61Ser, Glu55Arg, Glu55A1a, Asn61Ser + Ser64Asp, Cys127Ala and Ser64Asp mutants selective inactivation of release activity is not caused by a destabilization of protein 3D structure and, most likely, is associated with local stereochemical changes introduced by substitutions of amino acid side chains in the functionally essential sites of N-domain molecule. Some residues (Asn129, Phe131) as shown by calorimetric measurements are essential for preservation of stable protein structure, but at the same time they affect selective stop codon recognition probably via their neighboring amino acids. Recognition of UAG and UAA stop codons in vitro is more sensitive to preservation of protein stability than the UGA recognition.