[The Influence of A/G Composition of 3' Stop Codon Contexts on Translation Termination Efficiency in Eukaryotes].

Translation termination is a finishing step of protein biosynthesis. The significant role in this process belongs not only to protein factors of translation termination but also to the nearest nucleotide environment of stop codons. There are numerous descriptions of stop codons readthrough, which is due to specific nucleotide sequences behind them. However, represented data are segmental and don't explain the mechanism of the nucleotide context influence on translation termination. It is well known that stop codon UAA usage is preferential for A/T-rich genes, and UAG, UGA-for G/C-rich genes, which is related to an expression level of these genes. We investigated the connection between a frequency of nucleotides occurrence in 3' area of stop codons in the human genome and their influence on translation termination efficiency. We found that 3' context motif, which is cognate to the sequence of a stop codon, stimulates translation termination. At the same time, the nucleotide composition of 3' sequence that differs from stop codon, decreases translation termination efficiency.

[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.

[Epilepsy in adults: a costs-of-illness study].

An aim of the study was to assess clinical-economic effectiveness of therapy in the stages of examination of an epileptic patient by a local neurologist and then by an epileptologist after therapy optimization. Three hundreds and ten patients with different forms of epilepsy and types of epileptic seizures were treated. Costs-of-illness and medical services were assessed using common parameters on the basis of current prices in the health-care system. Special attention was drawn to expenses related to purchasing of antiepileptic drugs (traditional and new ones). The expenses for treatment were compared to treatment effectiveness. It is concluded that mean costs of treatment of epilepsy, including new brands of antiepileptic drugs with high prices, have substantial medical-social benefits that compensate expenses for their purchasing at the expense of other direct and indirect costs.

The intramolecular impact to the sequence specificity of B-->A transition: low energy conformational variations in AA/TT and GG/CC steps.

It is well known, that local B--> A transformation in DNA is involved in several biological processes. In vitro B<--> A transition is sequence-specific. The physical basis of this specificity is not known yet. Here we analyze the effect of intramolecular interactions on the structural behavior of the GG/CC and AA/TT steps. These steps exemplify sequence specific bias to the B- or A-form structure. Optimization of potential energy of the molecular systems composed of an octanucleotide, neutralized by Na(+) and solvated with TIP3P water molecules in rectangular box with periodic boundary conditions gives the statistically representative sets of low energy structures for GG/CC and AA/TT steps in the middle of the diverse flanking sequences. Permissible 3D variations of GG/CC and AA/TT, and correlation of the relative motion of base pairs in these steps were analyzed. AA/TT step permits high variability for low energy conformers in the B-form DNA and small variability for low energy conformers in the A-form DNA. In contrast GG/CC step permits high variability for low energy conformers in the A-form DNA and small variability for low energy conformers in the B-form DNA. The relative motion of base pairs in GG/CC step is high correlated, while in AA/TT step this correlation is notably less. Atom-atom interactions inside-the-step always favors the B-form and their component - stacking interactions (atom-atom interactions between nucleic bases) is crucial for the duplex stabilization. Formation of the A-form for both steps is a result of interactions with the flanking sequences and water-cation environment in the box. The average energy difference between conformations presenting B-form and A-form for the GG/CC step is high, while for the AA/TT step it is rather low. Thus, intramolecular interactions in GG/CC and AA/TT steps affect the possible conformational diversity ("conformational entropy") of the A- and B- type structures of DNA step. This determines the known bias of the A-form DNA depending on the enrichment of sequences with GG/CC. If structural tuning during the process of protein-DNA complex formation lead to the local B--> A transformation of DNA, it is largely directed by high conformational diversity of GG/CC step in the A-form. In such a case the presence in the target site of both kinds of examined steps ensures the reversible character of ligand binding.

The Intramolecular Impact to the Sequence Specificity of B→A Transition: Low Energy Conformational Variations in AA/TT and GG/CC Steps.

Abstract It is well known, that local B→A transformation in DNA is involved in several biological processes. In vitro B↔A transition is sequence-specific. The physical basis of this specificity is not known yet. Here we analyze the effect of intramolecular interactions on the structural behavior of the GG/CC and AA/TT steps. These steps exemplify sequence specific bias to the B- or A-form structure. Optimization of potential energy of the molecular systems composed of an octanucle-otide, neutralized by Na(+) and solvated with TIP3P water molecules in rectangular box with periodic boundary conditions gives the statistically representative sets of low energy structures for GG/CC and AA/TT steps in the middle of the diverse flanking sequences. Permissible 3D variations of GG/CC and AA/TT, and correlation of the relative motion of base pairs in these steps were analyzed. AA/TT step permits high variability for low energy conformers in the B-form DNA and small variability for low energy conformers in the A-form DNA. In contrast GG/CC step permits high variability for low energy conformers in the A-form DNA and small variability for low energy conformers in the B-form DNA. The relative motion of base pairs in GG/CC step is high correlated, while in AA/TT step this correlation is notably less. Atom-atom interactions inside-the-step always favors the B-form and their component - stacking interactions (atomatom interactions between nucleic bases) is crucial for the duplex stabilization. Formation of the A-form for both steps is a result of interactions with the flanking sequences and water-cation environment in the box. The average energy difference between conformations presenting B-form and A-form for the GG/CC step is high, while for the AA/TT step it is rather low. Thus, intramolecular interactions in GG/CC and AA/TT steps affect the possible conformational diversity ("conformational entropy") of the A- and B- type structures of DNA step. This determines the known bias of the A-form DNA depending on the enrichment of sequences with GG/CC. If structural tuning during the process of protein-DNA complex formation lead to the local B→A transformation of DNA, it is largely directed by high conformational diversity of GG/CC step in the A-form. In such a case the presence in the target site of both kinds of examined steps ensures the reversible character of ligand binding.

[Short fragments of a protein globule with predominant conformation].

It has been found that 1500 tetrapeptides out of 160000 possible combinations occurring in proteins exhibit preference for particular conformational states. Most conformationally stable tetrapeptides obtained in the analysis of a sampling containing 706 proteins are in the alpha-helical form. The features of the amino acid composition of conformationally stable oligopeptides have been studied.

[Nucleosomal repeat and the location of exons and introns in genes of collagens types I and VII].

Regions with a quasiperiodical location of exon--intron sites have been found in the loci of genes of I and VII type collagens (with a total length of exons more than 15% of the entire size of the locus). The periods observed are similar to periods typical for the nucleosomal level of the organization of chromatin. It was shown that the sites consisting of successively arranged exons and introns form groups involving two to five such regions of the same length. The groups encoding the fibrillar regions of the gene product contain more than 50% of exons. The regions are on the average 165 nt long, which is close to the minimal nucleosomal repeat length observed in some regions of the eukaryotic genome. In the nonfibrillar region of the gene of VII type collagen, groups of several exon-intron pairs with an average length of 227 nt were identified. The change in the length of exon-introns sites on going from the nonfibrillar to the fibrillar moiety occurs in a jump, which is clearly seen on a periodogram of the locus.

[Statistical analysis of DNA sequences nearby splicing sites].

Recognition of coding regions within eukaryotic genomes is one of oldest but yet not solved problems of bioinformatics. New high-accuracy methods of splicing sites recognition are needed to solve this problem. A question of current interest is to identify specific features of nucleotide sequences nearby splicing sites and recognize sites in sequence context. We performed a statistical analysis of human genes fragment database and revealed some characteristics of nucleotide sequences in splicing sites neighborhood. Frequencies of all nucleotides and dinucleotides in splicing sites environment were computed and nucleotides and dinucleotides with extremely high\low occurrences were identified. Statistical information obtained in this work can be used in further development of the methods of splicing sites annotation and exon-intron structure recognition.

[Left-handed helix of polyproline II type in linker regions of DNA-binding proteins].

Using the databases of proteins and linkers, a search has been undertaken with the aim to find linker segments adopting the polyproline II conformation in DNA-protein complexes. Seventy three linker-DNA complexes were found. It was shown that the mean length of polyproline II segment comprises six residues, praline being not dominant. The symmetry of praline disposition in these regions prevents the formation of the cooperative water net involving amide groups. An example of specific distribution of proline in some proteins of the motility apparatus is presented.

[An analysis of the secondary structure of spider spidroins I and II belonging to different species]. / Analiz vtorichnykh struktur spidroinov pervogo i vtorogo tipov iz paukov, prinadlezhashchikh razlichnym vidam.

We have analyzed the secondary structure of spidroin proteins of I and II types, related to spiders of different species. We used standard methods of secondary structure prediction NNPREDICT and JPRED and also analyzed the occurrences of oligopeptides with a preferred secondary structure with the help of the OLIGON program. We have demonstrated that local segments of the polypeptide chain can adopt alpha- and beta-conformations as well as the left-handed helix of polyproline II type. Periodical patterns found in the amino acid distribution indicate that there is a possibility of development of a macroscopic order accompanied by local conformational transitions.

[Left-handed helix conformation of poly-L-proline II type in globular proteins. Statistics of incidence and a role of sequence]. / Levospiral'naia konformatsiia tipa poli-L-prolin II v globuliarnykh belkakh. Statistika vstrechaemosti i rol' posledovatel'nosti.

Regions of left-handed polyproline II type conformation in globular proteins were studied throughout the PDB bank. The length and sequence of corresponding fragments were analyzed. It was found that a lot of tetrapeptides (from combinatorial possible ones) show the tendency to be included in the left-handed helices. Much more tetrapeptides do not occur in this structure type.

[How do point amino acid substitutions affect the protein structure?]. / Kak tochechnye aminokislotnye zameny vliiaiut na strukturu belkov?

In order to estimate the influence of point mutations on the protein structure, 552 pairs of structurally aligned proteins with pairwise sequence identities greater than 60% were analyzed. We selected all isolated point mismatches from these alignments. The statistics of local conformational changes corresponding to these mismatches was studied. This study revealed two surprising aspects: (a) only an extremely minor fraction (< 3%) of all observed mutations leads to significant changes in local conformations; (b) observed substitutions, which affect local conformation are more frequently those of similar (high scoring) amino acid pairs rather than the substitutions thought of as "hazardous" (low scoring), although the overall average score of the changing substitutions is still lower than the corresponding average score for the substitutions that leave the structure unchanged.