DNA methylation of genes of the main components of the telomerase complex in Danio rerio.

The methylation status of the genes of telomerase reverse transcriptase (tert) and telomerase RNA (terc) was determined in brain tissues of Danio rerio of different age. It is found that, regardless of the age of fish, the regulatory region of the tert gene was completely methylated, whereas the coding region remained unmethylated in all cases. The level of methylation of the region located downstream of the coding region of the terc gene changes with age. This region was analyzed in the samples of other tissues, and its methylation status was also nonuniform. The alteration of the methylation status in the 3'-untranslated region of the terc gene suggests the possibility of transcription of the antisense strand in this region.

Oligonucleotide inhibitors of telomerase: prospects for anticancer therapy and diagnostics.

The activity of telomerase allows eukaryotic cells to have unlimited division potential. On its functioning, telomerase synthesizes short DNA repeats at the 3'-end of DNA within chromosomes that ensures genome stability during cell division. Telomerase is active in the majority of cancer cell types and is virtually absent in somatic cells with rare exceptions. This difference allows us to consider inhibition of telomerase activity as a possible approach to antitumor therapy. Telomerase is a nucleoprotein composed of two main components: the reverse transcriptase (hTERT), which is a catalytic subunit, and telomerase RNA (hTR), which encodes a template for synthesis of repeats. The biogenesis and features of telomerase seem very promising for its inhibition due to complementary interactions. In this review, we analyze putative pathways of oligonucleotide influence on telomerase and consider the known native and modified oligonucleotide inhibitors of telomerase, as well as possible mechanisms of their action. We also discuss the application of telomerase-targeted oligonucleotide conjugates for in vivo imaging of tumor cells.

Assays for detection of telomerase activity.

Progressive loss of the telomeric ends of chromosomes caused by the semi-conservative mechanism of DNA replication is an important timing mechanism which controls the number of cells doubling. Telomerase is an enzyme which elongates one chain of the telomeric DNA and compensates for its shortening during replication. Therefore, telomerase activity serves as a proliferation marker. Telomerase activity is not detected in most somatic cells, with the exception of embryonic tissues, stem cells, and reproductive organs. In most tumor cells (80-90%), telomerase is activated and plays the role of the main instrument that supports the telomere length, which can be used for the diagnostics of neoplastic transformation. This is the primary reason why assays regarding the development of telomerase activity have attracted the attention of researchers. Telomerase activity testing may be useful in the search for telomerase inhibitors, which have the potential to be anti-cancer drugs. Moreover, telomerase activation may play a positive role in tissue regeneration; e.g., after partial removal of the liver or cardiac infarction. All telomerase activity detection assays can be divided into two large groups: those based on direct detection of telomerase products, and those based on different systems of amplification of the signals from DNA that yield from telomerase. The methods discussed in this review are suitable for testing telomerase activity in different samples: in protozoa and mammalian cells, mixed cellular populations, and tissues.

[Trans-translation: facts and hypothesis].

Trans-translation is a unique process which switches the synthesis of a polypeptide chain encoded by a nonstop messenger RNA to the mRNA-like domain of tmRNA. It is used in bacterial cells for rescuing the ribosomes arrested during translation of nonstop mRNA and directing this mRNA and the product polypeptide for degradation. tmRNA activity is essential for bacterial survival under adverse conditions, quality-control of translation and regulation of certain physiological pathways. This review will focus on recent advances in trans-translation investigation: the details of tmRNA-SmpB interaction and the structure of the early ribosomal complexes will be characterized; the causes for the empty A site appearance in the translating ribosomes, possible mechanisms of the stalled ribosomes recognition and resume codon determination will be discussed, the proteins degraded nonstop mRNA and tagged peptide will be viewed.

Deamination of 5-methylcytosine residues in Mammalian cells.

DNA demethylation in mammalia occurs after fertilization and during embryogenesis and accompanies cell aging and cancer transformation. With the help of the primer extension reaction, MALDI MS and DNA cleavage by thymine DNA glycosylase deamination of 5-methylcytosine residues has been shown to take place when the model methylated DNA duplexes are treated with nuclear extracts from the cell lines CHO, HeLa, and Skov3. The hypothesis that deamination of 5-methylcytosine is the first stage of demethylation in mammalia has been postulated.

[Telomerase: structure and properties of the enzyme, characteristics of the yeast telomerase].

Telomerase is a ribonucleoprotein that extends the telomeric ends of the chromosomes to counterbalance the natural shortening due to incomplete DNA replication in eukaryotic cells. The core enzyme consists of catalytic reverse transcriptase subunit TERT (Telomerase Reverse Transcriptase) and RNA subunit TER (Telomerase RNA), a short specific region of which serves as a template for synthesis of the telomeric repeats. In this review we focus on the telomerase from yeast Saccharomyces cerevisiae. Despite the intensive research of telomerase in different organisms, the enzyme mechanism remains unclear. The observed peculiarities of the yeast telomerase is of great interest too. Unlike ciliate and human telomerases, yeast enzyme can add only one telomeric repeat to a DNA oligonucleotide (primer) imitating the single-stranded telomeric end of the chromosome and remains stably bound to it after elongation. This review is an attempt to summarise results of numerous studies of the structure and functions of the core enzyme components, their interactions between each other and with a primer, telomerase activity on different substrates in vitro. Also the peculiarities of the telomerase functioning in a cell and accessory proteins of the telomerase complex are discussed.

Complex of transfer-messenger RNA and elongation factor Tu. Unexpected modes of interaction.

Transfer-messenger RNA (tmRNA) is a stable RNA in bacteria of 360 +/- 40 nucleotides that can be charged with alanine and can function as both tRNA and mRNA. Ribosomes that are stalled either in a coding region of mRNA or at the 3' end of an mRNA fragment lacking a stop codon are rescued by replacing their mRNA for tmRNA. Here we demonstrate that the interaction of tmRNA with the elongation factor Tu shows unexpected features. Deacylated tmRNA can form a complex with either EF-Tu.GDP or EF-Tu.GTP, the association constants are about one order of magnitude smaller than that of an Ala-tRNA.EF-Tu.GTP complex. tmRNA as well as Ala-tmRNA can be efficiently cross-linked with EF-Tu.GDP using a zero-length cross-link. The efficiency of cross-linking in the case of deacylated tmRNA does not depend on an intact CCA-3' end and is about the same, regardless whether protein mixtures such as the post-ribosomal supernatant (S100 enzymes) or purified EF-Tu are present. Two cross-linking sites with EF-Tu.GDP have been identified that are located outside the tRNA part of tmRNA, indicating an unusual interaction of tmRNA with EF-Tu.GDP.

Structure of 5S rRNA within the Escherichia coli ribosome: iodine-induced cleavage patterns of phosphorothioate derivatives.

The protection patterns of 5S rRNA in solution, within the ribosomal 50S subunit, 70S ribosomes, and functional complexes, were assessed with the phosphorothioate method. About 20% of the analyzed positions (G9-G107) showed strong assembly defects: A phosphorothioate at one of these positions significantly impaired the incorporation of 5S rRNA into 50S particles. The reverse has also been observed: A phosphorothioate is preferred over a phosphate residue in the assembly process at a few positions. The results further demonstrate that 5S rRNA undergoes conformational changes during the assembly in the central protuberance of the 50S subunit and upon association with the small ribosomal subunit forming a 70S ribosome. In striking contrast, when the 70S ribosomes are once formed, the contact pattern of the 5S rRNA is the same in various functional states such as initiation-like complexes and pre- and posttranslocational states.

Effect of point mutations at position 89 of the E. coli 5S rRNA on the assembly and activity of the large ribosomal subunit.

Nucleotide residue U89 in the D loop of Escherichia coli 5S rRNA is adjacent to two domains of 23S rRNA in the large ribosomal subunit [Dokudovskaya et al., RNA 2 (1996) 146-152]. 50S ribosomal subunits were reconstituted containing U89(C, G or A) mutants of 5S rRNAs and the activities of the corresponding 70S ribosomes were studied. The U89C mutant behaves similarly to the wild-type 5S rRNA. Replacement of the pyrimidine base at position U89 by more bulky purine bases impairs the incorporation of 5S rRNA into 50S subunits, whereas the particles formed showed full activities in poly(U)-dependent poly(Phe) synthesis in the presence of either U89G or U89A 5S rRNA mutants. The activity of the reconstituted particles depends on the incorporation of 5S rRNA in agreement with early observations.

[Phosphate sites of RNA-ligands interacting with ribosome at different stages of translation. Thiophosphate method of analysis]. / Fosfatnye uchastki RNK-ligandov, vzaimodeistvuiushchie s ribosomoi na razlichnykh stadiiakh transliatsii. Izuchenie s pomoshch'iu tiofosfatnogo metoda.

A novel footprinting method was recently developed which identifies phosphate groups of RNA involved in strong RNA-RNA and RNA-protein interactions. The method is based on iodine-dependent RNA cleavage at phosphothioate groups as long as these groups are not protected from iodine. Our recent studies of mRNA and tRNA regions protected in active ribosomes are summarized; initiation state of ribosomes as well as two elongation states in pre- and post-translocational states were analyzed. Only one phosphate group of mRNA, which was two positions upstream of the decoding codons, was weakly protected in longation complexes, whereas this group and the phosphate groups in the Shine-Dalgarno sequence were protected in the initiation complex. No protection was observed downstream of the decoding codons. On the contrary, numerous phosphate residues of tRNA were protected by the ribosome. The tRNA protection patterns significantly varied between two tRNAs simultaneously bound to the ribosome. The protection pattern of an individual tRNA was not significantly affected by translocation. The data indicate that both tRNA molecules are tightly bound to the ribosome, whereas mRNA is fixed predominantly by two tRNAs via codon-anticodon interaction. A possible translocation mechanism is suggested.

5S rRNA sugar-phosphate backbone protection in complexes with specific ribosomal proteins.

5S ribosomal RNA forms stable specific complexes with ribosomal proteins L18, L25 and L5. In this work, interaction of phosphate residues of E. coli 5S rRNA within 5S rRNA-protein complexes has been studied. For this purpose 5S rRNA with statistically distributed phosphorothioate residues has been used for complex formation and the accessibility of phosphorothioates to iodine cleavage in the complex and in the free state has been studied. In free 5S rRNA, the phosphate residue at A73 was partially protected, probably due to being involved in the organization of the spatial structure of 5S rRNA. This protection is stronger in the complex with three proteins when the 5S rRNA structure is stabilized. In the 5S rRNA-L18 complex only two phosphate groups, G7 and A34, were protected. L25 in a complex with 5S rRNA protects large numbers of phosphorothioate groups concentrating in two clusters, indicating the possibility of two binding sites for this protein on 5S rRNA. The protection pattern differs from that for individual proteins because of the possible rearrangement of the structure.

Interaction of mRNA with the Escherichia coli ribosome: accessibility of phosphorothioate-containing mRNA bound to ribosomes for iodine cleavage.

The contacts of phosphate groups in mRNAs with ribosomes were studied. Two mRNAs were used: one mRNA contained in the middle two defined codons to construct the pre- and the post-translocational states, the other was a sequence around the initiation site of the natural cro-mRNA. Phosphorothioate nucleotides were randomly incorporated at a few A, G, U or C positions during in vitro transcription. Iodine can cleave the thioated positions if they are not shielded by ribosomal components. Only a few minor differences in iodine cleavage of ribosome bound and non-bound mRNA were observed: the nucleotide two positions upstream of the decoding codons (i.e. those codons involved in codon-anticodon interactions) showed a reduced accessibility for iodine and the nucleotide immediately following the decoding codons an enhanced accessibility in both elongating states. In initiating ribosomes where the mRNA contained a strong Shine-Dalgarno sequence, at least five phosphates were additionally slightly protected covering the Shine-Dalgarno sequence and nucleotides downstream including the initiator AUG in the P site (Al, G3, G-2, G-5 and A-7). The low contact levels of the phosphates in the mRNA with the elongating ribosome strikingly contrast with the pronounced contact patterns previously described for tRNAs. The data obtained in this study, as well as results of previous studies, suggest that mRNA regions downstream and upstream of decoding codons form only weak contacts with ribosomal components and that the mRNA thus is mainly fixed by codon-anticodon interaction on the elongating ribosome.

Transglycosylation activity of cellobiohydrolase I from Trichoderma longibrachiatum on synthetic and natural substrates.

Using 4-methylumbelliferyl (MUF) beta-D-cellobioside as a substrate, the ability of cellobiohydrolase I from Trichoderma longibrachiatum to catalyze transglycosylation has been demonstrated. At substrate concentrations greater than 2 mM, the formation of MUF-tetrasaccharide was detected using HPLC. In the course of enzymatic reaction, a concentration of the transglycosylation product passed through a maximum, since at later stages of the reaction the product was further hydrolyzed. At MUF-beta-D-cellobioside concentrations of 2-10 mM, the maximum weight content of MUF-tetrasaccharide amounted to 1-4% of the total content of saccharides. In the reaction system, containing 2.5 mM MUF-beta-D-cellobioside and 10 mM MUF-beta-D-glucoside, MUF-trisaccharide was formed as the main transglycosylation product. In hydrolysis of natural substrates (cellulose and cellotriose) in the presence of MUF-beta-D-glucoside a formation of MUF-trisaccharide was also observed.

[Functionally important lysine residues in inorganic pyrophosphatase from E. coli. I. Interaction of inorganic pyrophosphatase with pyridoxal-5'-phosphate]. / Funktsional'no vazhnyi ostatok lizina v neorganicheskoi pirofosfataze iz E. coli. I. Vzaimodeistvie neorganicheskoi pirofosfatazy s piridoksal'-5'-fosfatom.

Interaction of inorganic pyrophosphatase from E. coli with pyridoxal-5'-phosphate includes binding of the reagent at the active site through the phosphate group and then a reversible modification of one lysine residue in each of the enzyme's subunit. In the equilibrium state the protein's molecules contain both inactive modified and native subunits. A stable secondary amine is formed upon the sodium borohydride reduction of the modified protein.