Cells Resistant to Toxic Concentrations of Manganese Have Increased Ability to Repair DNA.

Manganese (Mn) is crucially important for vital activity of cells and has many biological functions. Nevertheless, high doses of Mn taken up by an organism over a long period may cause neurodegenerative diseases such as manganism and Parkinsonism. The molecular mechanisms of this Mn toxicity are still poorly studied. It is now believed that Mn-induced pathophysiological neural processes are multifaceted and affect several metabolic pathways. In particular, Mn ions might affect the processes of DNA replication and repair. To test this possibility, we obtained an SKOV-3 cell line resistant to the toxic action of Mn ions. We found that these cells are characterized by the activation of poly(ADP-ribose)polymerase, which leads to increased ability to repair DNA. Thus, the model used here supports the suggestion that at least one cause of Mn cytotoxicity might be disorders of the processes involved in DNA replication and repair.

[The manganese-induced infidelity of the DNA synthesis as a possible cause of manganism].

The impact of the 8 most common bivalent metal cations (Mg2+, Mn2+, Co2+, Cd2+, Zn2+, Ni2+, Ca2+, Cu2+) on the operation of the whole complex of DNA polymerases in mice brain cell extracts was tested. A decrease in the fidelity of the DNA synthesis was observed in the presence of several metals; among them, Mn2+ caused the most significant effect. It was also demonstrated that this effect was mainly due to the DNA polymerase iota (Pol iota) activity. It is well known that occupational or environmental exposure to excessive Mn could lead to development of neurodegenerative diseases (e.g., manganism). However, the molecular mechanism underlying these pathologies is still unknown. Our results suggest that the neurotoxic effect of Mn2+ may be associated with local activation of highly error-prone Pol iota that increases incorrect DNA synthesis at elevated concentrations of this metal.

Inhibition of Mn(2+)-induced error-prone DNA synthesis with Cd(2+) and Zn(2+).

Bivalent metal cations are key components in the reaction of DNA synthesis. They are necessary for all DNA polymerases, being involved as cofactors in catalytic mechanisms of nucleotide polymerization. It is also known that in the presence of Mn2+ the accuracy of DNA synthesis is considerably decreased. The findings of this work show that Cd2+ and Zn2+ selectively inhibit the Mn2+-induced error-prone DNA polymerase activity in extracts of cells from human and mouse tissues. Moreover, these cations in low concentrations also can efficiently inhibit the activity of homogeneous preparations of DNA polymerase iota (Pol ι), which is mainly responsible for the Mn2+-induced error-prone DNA polymerase activity in cell extracts. Using a primary culture of granular cells from postnatal rat cerebellum, we show that low concentrations of Cd2+ significantly increase cell survival in the presence of toxic Mn2+ doses. Thus, we have shown that in some cases low concentrations of Cd2+ can display a positive influence on cells, whereas it is widely acknowledged that this metal is not a necessary microelement and is toxic for organisms.

[Effect of Mn(II) on the error-prone DNA polymerase iota activity in extracts from human normal and tumor cells].

The DNA polymerase iota (Pol iota), which has some peculiar features and is characterized by an extremely error-prone DNA synthesis, belongs to the group of enzymes preferentially activated by Mn2+ instead of Mg2+. In this work, the effect of Mn2+ on DNA synthesis in cell extracts from a) normal human and murine tissues, b) human tumor (uveal melanoma), and c) cultured human tumor cell lines SKOV-3 and HL-60 was tested. Each group displayed characteristic features of Mn-dependent DNA synthesis. The changes in the Mn-dependent DNA synthesis caused by malignant transformation of normal tissues are described. It was also shown that the error-prone DNA synthesis catalyzed by Pol iota in extracts of all cell types was efficiently suppressed by an RNA aptamer (IKL5) against Pol iota obtained in our work earlier. The obtained results suggest that IKL5 might be used to suppress the enhanced activity of Pol iota in tumor cells.

Aptamers: problems, solutions and prospects.

Aptamers are short single-stranded oligonucleotides that are capable of binding various molecules with high affinity and specificity. When the technology of aptamer selection was developed almost a quarter of a century ago, a suggestion was immediately put forward that it might be a revolutionary start into solving many problems associated with diagnostics and the therapy of diseases. However, multiple attempts to use aptamers in practice, although sometimes successful, have been generally much less efficient than had been expected initially. This review is mostly devoted not to the successful use of aptamers but to the problems impeding the widespread application of aptamers in diagnostics and therapy, as well as to approaches that could considerably expand the range of aptamer application.

DNA polymerase ι of mammals as a participant in translesion synthesis of DNA.

This review describes the properties of some specialized DNA polymerases participating in translesion synthesis of DNA. Special attention is given to these properties in vivo. DNA polymerase iota (Polι) of mammals has very unusual features and is extremely error-prone. Based on available data, a hypothesis is proposed explaining how mammalian cells can explore the unusual features of DNA Polι to bypass DNA damages and to simultaneously prevent its mutagenic potential.

Effect of human cell malignancy on activity of DNA polymerase iota.

An increased level of mutagenesis, partially caused by imbalanced activities of error prone DNA polymerases, is a key symptom of cell malignancy. To clarify the possible role of incorrect DNA polymerase iota (Pol iota) function in increased frequency of mutations in mammalian cells, the activity of this enzyme in extracts of cells of different mouse organs and human eye (melanoma) and eyelid (basal-cell skin carcinoma) tumor cells was studied. Both Mg2+, considered as the main activator of the enzyme reaction of in vivo DNA replication, and Mn2+, that activates homogeneous Pol iota preparations in experiments in vitro more efficiently compared to all other bivalent cations, were used as cofactors of the DNA polymerase reaction in these experiments. In the presence of Mg2+, the enzyme was active only in cell extracts of mouse testicles and brain, whereas in the presence of Mn2+ the activity of Pol iota was found in all studied normal mouse organs. It was found that in cell extracts of both types of malignant tumors (basal-cell carcinoma and melanoma) Pol iota activity was observed in the presence of either Mn2+ or Mg2+. Manganese ions activated Pol iota in both cases, though to a different extent. In the presence of Mn2+ the Pol iota activity in the basal-cell carcinoma exceeded 2.5-fold that in control cells (benign tumors from the same eyelid region). In extracts of melanoma cells in the presence of either cation, the level of the enzyme activity was approximately equal to that in extracts of cells of surrounding tumor-free tissues as well as in eyes removed after traumas. The distinctive feature of tissue malignancy (in basal-cell carcinoma and in melanoma) was the change in DNA synthesis revealed as Mn2+-activated continuation of DNA synthesis after incorrect incorporation of dG opposite dT in the template by Pol iota. Among cell extracts of different normal mouse organs, only those of testicles exhibited a similar feature. This similarity can be explained by cell division blocking that occurs in all normal cells except in testicles and in malignant cells.

[Activity of error-prone DNA polymerase iota in different periods of house mouse Mus musculus ontogeny].

Analysis of incorrect activity of error-prone DNA polymerase iota in M. musculus ontogeny demonstrated considerable changes in its activity, which peaks in most organs during prenatal development and decreases in the adult body. We propose that the capacity of error-prone DNA polymerases to synthesize on damaged DNA regions is critical for the realization of rapidly changing genetic program in mammalian embryogenesis, which relieves the replication block and prevents cell death.

Evolution of DNA polymerase iota structure and function in eukaryotes.

Analysis of DNA polymerase iota (Pol iota) enzymic activity in different classes of eukaryotes has shown that error-prone activity of this enzyme can be found only in mammals, and that it is completely absent from organisms that are at lower stages of development. It was supposed that the emergence of the error-prone Pol iota activity in mammals is caused by structural alteration of the active center. Possible functions of error-prone Pol iota in higher eukaryotes are discussed.

[Association between high activity of DNA polymerase iota and the development of human uveal melanoma].

Enzymatic activity of DNA polymerase iota (Pol t) was analyzed in human uveal melanoma cell extracts, using an earlier elaborated approach. The Pol t activity was observed in seven out of eight malignant tumors, while it was absent in the normal uveal tract cells of the same patients. These findings serve as an additional confirmation of the Pol t oncogenic potential.

A false note of DNA polymerase iota in the choir of genome caretakers in mammals.

DNA polymerase iota (Pol iota) of mammals is a member of the Y family of DNA polymerases. Among many other genome caretakers, these enzymes are responsible for maintaining genome stability. The members of the Y-family DNA polymerases take part in translesion DNA synthesis, bypassing some DNA lesions, and are characterized by low fidelity of DNA synthesis. A unique ability of Pol iota to predominantly incorporate G opposite T allowed us to identify the product of this enzyme among those synthesized by other DNA polymerases. This product can be called a "false note" of Pol iota. We measured the enzyme activity of Pol iota in crude extracts of cells from different organs of five inbred strains of mice (N3H/Sn, 101/H, C57BL/6, BALB/c, 129/J) that differed in a number of parameters. The "false note" of Pol iota was clearly sounding only in the extracts of testis and brain cells from four analyzed strains: N3H/Sn, 101/H, C57BL/6, BALB/c. In mice of 129/J strain that had a nonsense mutation in the second exon of the pol iota gene, the Pol iota activity was reliably detectable only in the extracts of brain. The data show that the active enzyme can be formed in some cell types even if they carry a nonsense mutation in the pol iota gene. This supports tissue-specific regulation of pol iota gene expression through alternative splicing. A semiquantitative determination of pol iota activity in mice strains different in their radiosensitivity suggests a reciprocal correlation between the enzyme activity of pol iota in testis and the resistance of mice to radiation.

Enhanced activity of DNA polymerase iota in mouse brain cells is associated with aggressiveness.

Recent studies performed with crude extracts of mouse tissues showed that the activity of DNA-polymerase iota (Pol iota) can be detected only in brain and testis extracts. To assess whether the activity of Pol iota is associated with animal behavior, we determined Pol iota activity in brain extracts of mice of two lines sharply differing in aggressiveness (RSB and RLB). We found that Pol iota activity in the mice with aggressive behavior was three times higher than in the less aggressive mice. The possible relationship between the activity of Pol iota and animal behavior is discussed.

DNA polymerase iota-like activity in crude cell extracts of different mouse organs.

The recently discovered DNA polymerase iota differs greatly from the numerous eukaryotic and prokaryotic DNA polymerases known previously in its ability to catalyze error-prone DNA synthesis. Using homogeneous preparations of the enzyme, it was shown previously that DNA polymerase iota incorporated preferentially dGMP opposite the thymidine of the template in the growing DNA chain. To elucidate the role of this enzyme in the mammals, its activity was assayed in crude cell extracts of different mouse organs. It is shown that the extracts of the brain and testis cells exhibit the highest activity of DNA polymerase iota, which is not in agreement with the results of other authors. The data suggest that the tissue specific expression of DNA polymerase iota is regulated to a significant degree at the posttranscriptional and posttranslational levels.

L-Homoserine: a novel excreted metabolic marker of hepatitis B abnormally produced in liver from methionine.

The hepatitis B infection leads to various profound pathological processes in liver metabolism. Some biochemical alterations detectable by blood analysis are currently used for a preliminary evaluation of the infection. Based on existing data we present here evidence that non-protein amino acid L-homoserine is a pathological, hepatitis B-induced metabolite that is formed and excreted into urine from methionine via splitting S-adenosylmethionine. The urine L-homoserine is proposed as a new marker in the pre-diagnosis examinations that is easier for the clinical analysis than currently used blood test, and is applicable to large-scale epidemiological surveys of the probability of hepatitis B.

SSCP screening of individual aptamers.

Aptamers are specific binding nucleic acids that emerge from in vitro selection. During the systematic evolution of ligands by exponential enrichment (SELEX) procedure, analysis of the sequences of the numerous selected individual molecules becomes an important step in the final stage of aptamer selection. The sequencing of cloned aptamers from the selected pool generally reveals groups of identical sequences and rarely occurring individual aptamers. This study demonstrates an approach similar to the single strand conformation polymorphism (SSCP) method used for mutation testing in genes. Human angiotensin I-specific aptamers have been used to show the efficiency of the SSCP method to classify selected individual sequences into identity groups, which minimizes sequencing efforts. Additionally this approach allows the rapid isolation and identification of aptamers from a mixture.

[Determination of homoserine kinase activity by chromatographic separation and measurement of reaction products]. / Opredelenie aktivnosti gomoserinkinazy putem khromatograficheskogo razdeleniia i izmereniia produktov reaktsii.

A highly specific procedure for quantitative assay of the homoserine kinase activity in an optimized enzymatic reaction using 14C-labelled homoserine or [gamma 33P]-ATP as substrates, and paper or thin-layer chromatography for separation of the formed o-phosphohomoserine, is described. The procedure is simple, sensitive and allows the assay for the activity of both purified and non-purified homoserine kinases.

[Cloning and structural characteristics of human hair keratin genes rich in sulfur]. / Klonirovanie i strukturnaia kharakteristika genov bogatykh seroi keratinov volos cheloveka.

Two human genomic genes for the hair high-sulphur keratins were for the first time cloned in a 15 kb fragment. The primary structures of the coding regions of the genes and their 5'- and 3'-flanks were determined. In the 5'-flanking region, TATA boxes, initiating codons and a 18 nucleotide sequence, previously described in sheep keratin genes and designated as "the matrix-specific" sequence was revealed. Basing on the nucleotide sequences, the encoded amino acid sequences of the high-sulphur keratins were determined for the first time. The suggested functional role of the structural elements (regions) revealed in the proteins primary structure and problems concerning their evolution tendencies are discussed.

[Design of a gene coding encoding a polypeptide, mixing the enzyme activity of Escherichia coli homoserine kinase and threonine synthetase]. / Konstruirovanie gena, kodiruiushchego polipeptid, sovmeshchaiushchii fermentativnye aktivnosti gomoserinkinazy i treoninsintetaty Escherichia coli.

The functioning of Escherichia coli threonine operon isolated genes thrB and thrC was studied by using the genetic complementation and enzymatic activity determination techniques. A new gene thrBC was obtained by the genes merging. The genes thrB and thrC were shown to function in Escherichia coli cells independent of the operon and the polipeptide encoded by the thrBC gene combined the functions to express the products of both genes in bacterial cell. At the same time the enzyme coded for by the merged genes demonstrates the level of activity compared with the ones of the isolated genes.