T. V. Shevchuk

Effect of Hypermethylation of CCWGG Sequences in DNA of Mesembryanthemum crystallinum Plants on Their Adaptation to Salt Stress

Under salt stress conditions, the level of CpNpG-methylation (N is any nucleoside) of the nuclear genome of the facultative halophyte Mesembryanthemum crystallinum in the CCWGG sequences (W = A or T) increases two-fold and is coupled with hypermethylation of satellite DNA on switching-over of C3-photosynthesis to the crassulacean acid metabolism (CAM) pathway of carbon dioxide assimilation. The methylation pattern of the CCWGG sequences is not changed in both the 5′-promoter region of the gene of phosphoenolpyruvate carboxylase, the key enzyme of C4-photosynthesis and CAM, and in the nuclear ribosomal DNA. Thus, a specific CpNpG-hypermethylation of satellite DNA has been found under conditions of expression of a new metabolic program. The functional role of the CpNpG-hypermethylation of satellite DNA is probably associated with formation of a specialized chromatin structure simultaneously regulating expression of a large number of genes in the cells of M. crystallinum plants on their adaptation to salt stress and switching-over to CAM metabolism.

DNA methyltransferases and structural-functional specificity of eukaryotic DNA modification

Properties of the main families of mammalian, plant, and fungal DNA methyltransferases are considered. Structural-functional specificity of eukaryotic genome sequences methylated by DNA methyltransferases is characterized. The total methylation of cytosine in DNA sequences is described, as well as its relation with RNA interference. Mechanisms of regulation of expression and modulation of DNA methyltransferase activity in the eukaryotic cell are discussed.

Structural and functional features of the 5-methylcytosine distribution in the eukaryotic genome

DNA methylation is an integral part of the mechanism of a remodeling and modification of the chromatin structure. The global complex net of chromatin modification and remodeling reactions is still to be determined, and studies of the mechanisms controlling the epigenetic processes of histone modification and DNA methylation are in their infancy. Cytosine methylation occurs predominantly in CpG sequences of the eukaryotic genome, and it also takes place at symmetric CpHpG and nonsymmetric CpHpH sites (where H is A, T, or C). The modification efficiency of the three types of DNA methylation sites depends on their genomic localization. Different regions of the eukaryotic genome are remarkable for their methylation features: CpG-islands, CpG-island shores, differentially methylated regions of imprinted genes, and regions of nonalternative site-specific modification. The three canonical sites (CpG, CpHpG, and CpHpH) differ in DNA methylation efficiency depending on their nucleotide context. An epigenetic code of DNA methylation can be assumed with context differences playing a specific functional role. The review summarizes the main up-to-date data on the structural and functional features of site-specific cytosine methylation in eukaryotic genomes. Pathogenesis-related alterations in the methylation pattern of the eukaryotic genome are considered.

Expression of exogenous DNA methyltransferases: Application in molecular and cell biology

DNA methyltransferases might be used as powerful tools for studies in molecular and cell biology due to their ability to recognize and modify nitrogen bases in specific sequences of the genome. Methylation of the eukaryotic genome using exogenous DNA methyltransferases appears to be a promising approach for studies on chromatin structure. Currently, the development of new methods for targeted methylation of specific genetic loci using DNA methyltransferases fused with DNA-binding proteins is especially interesting. In the present review, expression of exogenous DNA methyltransferase for purposes of in vivo analysis of the functional chromatin structure along with investigation of the functional role of DNA methylation in cell processes are discussed, as well as future prospects for application of DNA methyltransferases in epigenetic therapy and in plant selection.

Hypermethylation of 5′-Region of the Human Calcitonin Gene in Leukemias: Structural Features and Diagnostic Significance

Methylation of the 5′-region of the calcitonin gene was investigated in bone marrow and peripheral blood cells of 27 healthy volunteers and 25 leukemic patients. In all patients suffering from various forms of myeloid and lymphoid leukemia, hypermethylation of CpG sequences was observed in this region of the calcitonin gene. Cytosine hypermethylation in the CpG sequence did not involve cytosines of adjacent CpNpG sequences (where N is any nucleoside). The 5′-region of the calcitonin gene lacked CpNpG methylation both in healthy controls and in leukemic patients; this apparently represents specific “non-alternative” type of CpG methylation in the extended DNA sequence. Methylation of the calcitonin gene was monitored in 18 leukemic patients during malignant progression and medical treatment. Hypermethylation of the calcitonin gene was not observed on long-term clinical hematological remission. In ten patients characterized by unstable (or incomplete) remission hypermethylation of the calcitonin gene persisted through the whole period of observation. In relapses, hypermethylation of the calcitonin gene appeared again and in six patients, this “molecular relapse” being registered 1-8 months before onset of clinical and laboratory signs of disease progression. The leukemia-specific hypermethylation of CpG sequences of the 5′-region of the calcitonin gene is a promising prognostic and diagnostic marker of leukemias and might be useful for monitoring of this disease.

The absence of the CpNpG methylation at the 5′-terminal region of the human calcitonin gene in norm and leukemias

The inner cytosine methylation was analyzed in the CCWGG sequences of the 5′-terminal region of the human calcitonin gene from peripheral blood and bone marrow cells in various forms of leukemia. Since these sequences remain nonmethylated both in the norm and in various leukemia forms, the CpG dinucleotide hypermethylation of the 5′-end of the human calcitonin gene, characteristic for the development of leukemias, does not spread to adjacent CpNpG sequences.

35S promoter methylation in kanamycin-resistant kalanchoe (Kalanchoe pinnata L.) plants expressing the antimicrobial peptide cecropin P1 transgene

Transgenic kalanchoe plants (Kalanchoe pinnata L.) expressing the antimicrobial peptide cecropin P1 gene (cecP1) under the control of the 35S cauliflower mosaic virus 35S RNA promoter and the selective neomycin phosphotransferase II (nptII) gene under the control of the nopaline synthase gene promoter were studied. The 35S promoter methylation and the cecropin P1 biosynthesis levels were compared in plants growing on media with and without kanamycin. The low level of active 35S promoter methylation further decreases upon cultivation on kanamycin-containing medium, while cecropin P1 synthesis increases.

Novel expression system for enhanced synthesis of antimicrobial peptide cecropin P1 in plants

A gene of antimicrobial peptide cecropin P1 (CP1) was inserted into the vector plasmid pPCV91 under the control of promoter 35S RNA of cauliflower mosaic virus (CaMV 35S) containing four enhancer sequences CaMV 35S and nontranslated leader sequence Ω RNA of tobacco mosaic virus. The recombinant vector obtained was used for agrobacterial transformation of tobacco plants (Nicotiana tabacum L., variety Samsun) with the polymerase chain reaction (PCR)-based method. The presence of gene CP1 in the genome of plants was proven by western-blot analysis and testing the antibiotic activity of plant extracts. In different plant lines, the level of cecropin P1 synthesis amounted 0.02–0.2% of total soluble plant leaf protein. The transgenic plants, unlike the control ones, displayed enhanced tolerance to phytopathogenic microorganisms and oxidative stress. It was established that the ability of the transgenic plants to express cecropin P1 is transmitted to progeny.

The Effect of the Gene Encoding EcoRII DNA Methyltransferase on the Phenotype of Transgenic Tumor Cell Lines of Nicotiana tabacumand the Methylation Level of CpNpG Sequences in Their Genome

Several tumor cell lines were obtained by transforming Nicotiana tabacumplants with the recombinant Ti plasmid comprising the gene encoding EcoRII DNA methyltransferase (M·EcoRII) and subjected to analysis. The transformed lines differed in their morphology, growth dependence on hormones, and nopaline-synthesizing capacity. Southern blot-hybridization showed that the M·EcoRII gene was present in the cells of all transformed lines. However, genome analysis using polymerase chain reaction with the oligonucleotide primers recognizing 5-ends of the M·EcoRII gene did not exhibit the full-length copies of the gene. Lower methylation of CpNpG sequences characteristic of all transformed cells could result from the disturbance of one of several plant DNA methyltransferase genes following its homologous recombination with the M·EcoRII gene.