[Functional Hypermethylation of ALDH1L1, PLCL2, and PPP2R3A in Colon Cancer].

DNA hypermethylation and mutations are key mechanisms for the downregulation of tumor suppressor genes. NotI-microarrays allowed us to detect hypermethylation and/or deletions in 180 NotI sites associated with 188 genes of human chromosome 3, in 24 paired (tumor/normal) colon samples. The most frequent aberrations (in more than 20% of tumor samples) were detected in the promoter regions of 20 genes. Expression and promoter methylation of these genes were analyzed using the data for paired colon samples from The Cancer Genome Atlas project. Three genes - ALDH1L1, PLCL2, and PPP2R3A - revealed a more than two-fold average decrease in expression and a negative correlation between mRNA level and promoter hypermethylation. The expression of these three genes was then evaluated in 30 paired colon samples by quantitative PCR. Frequent (in more than 60% of cases) and significant (5-9-fold on average) mRNA level decrease was found for each of the genes in the tumor samples. The results indicate a suppressor role of the ALDH1L1, PLCL2, and PPP2R3A genes in colon cancer, as well as functional significance of hypermethylation in the downregulation of these genes.

Stable G-Quadruplex Structures of Oncogene Promoters Induce Potassium-Dependent Stops of Thermostable DNA Polymerase.

Amplification of GC-rich regions of genomic DNA is hindered either by high stability of DNA double helix or as a result of alternative structure formation by a guanine-rich DNA strand. Such potential G-quadruplex (G4) sequences are fairly common in promoters of the human genome. The efficiency of PCR amplification of promoter sequences for several human oncogenes (MYC, NRAS, TERT, KRAS, KIT) was studied. We demonstrate that the efficiency of DNA polymerase is reduced in the presence of potassium ions. The primer-extension technique localized DNA polymerase stops at the 3'-ends of potential quadruplex sequences. The structural and thermodynamic properties of short G-rich oligonucleotides corresponding to the stops of DNA polymerase were analyzed. These oligonucleotides formed stable parallel G4 in the presence of potassium ions. Correlation between the stability of G4 structure and efficiency of DNA polymerase stops was revealed. The results provide a method for detecting new G4 structures in extended genomic sequences and also clarify the mechanism of inhibition of DNA polymerase in G-rich regions of DNA.

[Differential expression of an ensemble of the key genes involved in cell-cycle regulation in lung cancer].

Targeted cancer therapy directed at individual targets is often accompanied by the rapid development of drug resistance. The development of a new generation of antitumor drugs involves the search for many targets simultaneously to block or, conversely, restore their activity. In this regard, simultaneous analysis of gene expression in a complex network of interactions, primarily cell cycle control elements, is relevant for the search of specific molecular markers for the differential diagnosis of adenocarcinoma (ADC) and squamous cell lung cancer (SCC), as well as new targets for therapy. In this paper we performed an extended quantitative analysis of the expression of two suppressor genes, CTDSPL and its target RB1, as well as 84 genes of the main participants of the p16^(INK4A)-Cdk/cyclin D1-Rb and p53/p21^(Waf1) signaling pathways in the histological types of non-small-cell lung cancer (NSCLC), i.e., ADC and SCC, using the special panel of the Human Cell Cycle Regulation Panel. The expression profile of some genes shows the specificity to the histological type of NSCLC and the presence of metastases. The genes with a significantly increased expression that affect the activity of Rb (cyclins, cyclin-dependent kinases, their activators, inhibitors, etc.) can serve as potential targets for combined therapy of both ADC and SCC.

[Interaction of two tumor suppressors: Phosphatase CTDSPL and Rb protein].

Earlier we established that CTDSPL gene encoding small carboxy-terminal domain serine phosphatase can be considered a classical tumor suppressor gene. Besides, transfection of tumor cell line MCF-7 with CTDSPL led to the content decrease of inactive phosphorylated form of another tumor suppressor, retinoblastoma protein (Rb), and subsequently to cell cycle arrest at the G1/S boundary. This result implied that small phosphatase CTDSPL is able to specifically dephosphorylate and activate Rb protein. In order to add some fuel to this hypothesis, in the present work we studied the interaction of two tumor suppressors CTDSPL and Rb in vitro. GST pool-down assay revealed that CTDSPL is able to precipitate Rb protein from MCF-7 cell extracts, while surface plasmon resonance technique showed that interaction of the two proteins is direct. Results of this study reassert that phosphatase CTDSPL and Rb could be involved in the common mechanism of cell cycle regulation.

[G-quadruplex ligands: mechanisms of anticancer action and target binding].

Since the discovery of potential therapeutic value of quadruplex secondary nucleic acids structures, many compounds that stabilize these targets were found. Such progress became possible due to understanding of the structural features of G-quadruplexes. Quadruplex ligands selectively suppress the growth of tumor cells by indirect inhibition of the telomerase activity and/or attenuation of oncogenes' overexpression. Therapeutic effect demonstrated in vivo supports the prospect of such compounds for the development of the targeted anticancer drugs. This review reveals the significance of G-quadruplexes as therapeutic targets and focuses on biochemical properties of the low molecular weight quadruplex ligands.

[Characteristic of the two-step RNA dimerization in avian sarcoma and leukosis viruses].

Dimerization of two copies of genomic RNA is a necessary step of retroviral replication. In the case of human immunodeficiency virus type 1 (HIV-1) the process is explored in many details. It is proved that conserved stem-loop structure is an essential element in RNA dimerization. Similar model of two-step dimerization mechanism can be considered for avian sarcoma and leukosis virus group (ASLV) in spite of the absence of homology between dimer initiation site (DIS) of ASLV and that of HIV-1. In this paper, short RNA fragments of two viruses: avian sarcoma virus CT-10 and avian leukosis virus HPRS-103 have been chosen in order to investigate the structural requirements of dimerization process and compare them to that of HIV-1. The rate of spontaneous transition from loose to tight dimer was studied as a function of stem length and temperature. Although both types of dimers were observed for both avian retroviruses chosen, fragments of CT-10 requires much higher RNA concentration to form loose dimer. In spite of identical sequence of the loops (5'-A-CUGCAG-3') avian sarcoma virus CT-10 RNA fragments dimerization was greatly impaired. The differences can be explained by deletion of adenine 271 in avian sarcoma virus CT-10 in the stem and by resulting shortening of the self-complementary loop.

A pseudoknot-compatible universal site is located in the large ribosomal RNA in the peptidyltransferase center.

The RNA secondary structure is not confined to a system of the hairpins and can contain pseudoknots as well as topologically equivalent slipped-loop structure (SLS) conformations. A specific primary structure that directs folding to the pseudoknot or SLS is called SL-palindrome (SLP). Using a computer program for searching the SLP in the genomic sequences, 419 primary structures of large ribosomal RNAs from different kingdoms (prokaryota, eukaryota, archaebacteria) as well as plastids and mitochondria were analyzed. A universal site was found in the peptidyltransferase center (PTC) capable of folding to a pseudoknot of 48 nucleotides in length. Phylogenetic conservation of its helices (concurrent replacements with no violation of base pairing, covariation) has been demonstrated. We suggest the reversible folding-unfolding of the pseudoknot for certain stages of the ribosome functioning.

[Why termination tRNAs have not been found? Because they are hidden in the large ribosomal RNA]. / Pochemu ne naideny terminatornye tRNK? Potomy chto oni spriatany v bol'shoi ribosomnoi RNK.

It is well known that protein synthesis in ribosomes on mRNA requires two kinds of tRNAs: initiation and elongation. The former initiates the process (formylmethionine tRNA in prokaryotes and special methionine tRNA in eukaryotes). The latter participates in the synthesis proper, recognizing the sense codons. The synthesis is assisted by special proteins: initiation, elongation, and termination factors. The termination factors are necessary to recognize stop codons (UAG, UGA, and UAA) and to release the complete protein chain from the elongation tRNA preceding a stop codon. No termination tRNA capable of recognizing stop codons by its anticodon is known. The termination factors are thought to do this. We discovered in the large ribosomal RNA two regions that, like tRNAs, contain the anticodon hairpin, but with triplets complementary to stop codons. By analogy, we called them termination tRNAs (Ter-tRNA1 and Ter-tRNA2), though they transport no amino acids, and suggested them to directly recognize stop codons. The termination factors only condition such a recognition, making it specific and reliable (of course, they fulfill the hydrolysis of the ester bond between the polypeptide and tRNA). A strong argument in favor of our hypothesis came from vertebrate mitochondria. They acquired two new stop codons, AGA and AGG (in the standard code, they are two out of six arginine codons). We revealed that the corresponding anticodons appear in Ter-tRNA1.

[The role of structural elements in dimerization of RNA fragments in avian retroviruses]. / Rol' strukturnykh élementov v dimerizatsii fragmentov RNK retrovirusov ptits.

The slipped loop structure, earlier identified as an unusual DNA structure, was found to be a possible element of the RNA folding. In order to experimentally test this suggestion, model oligoribonucleotides capable of forming the SLS were synthesized. Treatment of the oligoribonucleotides with nuclease S1 and RNases specific for single- and double-stranded RNA demonstrated the steric possibility of SLS formation. To determine the possible functional role of SLS-RNA, various naturally occurring RNAs were screened in silico. Among the most interesting findings were dimerization initiation sites of avian retroviral genomic RNAs. Analysis of RNA from 31 viruses showed that formation of the intermolecular SLS during RNA dimerization is theoretically possible, competing with the formation of an alternative hairpin structure. Identification of the secondary structure of selected RNA dimers employing nuclease digestion techniques as well as covariance analysis of the retroviral RNA dimerization initiation site sequences were used to show that the alternative conformation (loop-loop interaction of two hairpins) is the most preferred. Alternative structures and conformational transitions in RNA dimerization mechanisms in avian retroviruses are discussed.