[Packaging of Subchromosomal-Size DNA Molecules in Chromatin Bodies in the Ciliate Macronucleus].

A fundamental difference between somatic nuclei (macronuclei) of ciliates and cell nuclei of higher eukaryotes is that the macronuclear genome is a huge number (up to tens or hundreds of thousands) of gene-sized (0.5-25 kb) or subchromosomal (up to 2000 kb) minichromosomes. Electron microscopy shows that macronuclear chromatin usually looks like chromatin bodies or fibrils 200-300 nm thick in the interphase. However, the question of how many DNA molecules are contained in an individual chromatin body remains open. The organization of chromatin in macronuclei was studied in the ciliates Didinium nasutum and three Paramecium sp, which differ in pulsed-field gel electrophoresis (PFGE) karyotype, and compared with the model of topologically associated domains (TADs) of higher eukaryotic nuclei. PFGE showed that the sizes of macronuclear DNAs ranged from 50 to 1700 kb, while the majority of the molecules were less than 500 kb in length. A comparative quantitative analysis of the PFGE and electron microscopic data showed that each chromatin body contained one minichromosome in P. multimicronucleatum in the logarithmic growth phase, while bodies in the D. nasutum macronucleus contained two or more DNA molecules each. Chromatin bodies aggregated during starvation, when activity of the macronuclei decreased, leading to an increase of chromatin body size or the formation of 200- to 300-nm fibrils of several chromatin bodies. A model was proposed to explain the formation of such structures. In terms of topological characteristics, macronuclear chromatin bodies with subchromosomal DNA molecules were found to correspond to higher eukaryotic TADs.

[Virus-Like Particles as an Instrument of Vaccine Production].

The paper discusses the techniques which are currently implemented for vaccine production based on virus-like particles (VLPs). The factors which determine the characteristics of VLP monomers assembly are provided in detail. Analysis of the literature demonstrates that the development of the techniques of VLP production and immobilization of target antigens on their surface have led to the development of universal platforms which make it possible for virtually any known antigen to be exposed on the particle surface in a highly concentrated form. As a result, the focus of attention has shifted from the approaches to VLP production to the development of a precise interface between the organism's immune system and the peptides inducing a strong immune response to pathogens or the organism's own pathological cells. Immunome-specified methods for vaccine design and the prospects of immunoprophylaxis are discussed. Certain examples of vaccines against viral diseases and cancers are considered.

Virus-Like Particles as an Instrument of Vaccine Production.

The paper discusses the techniques which are currently implemented for vaccine production based on virus-like particles (VLPs). The factors which determine the characteristics of VLP monomers assembly are provided in detail. Analysis of the literature demonstrates that the development of the techniques of VLP production and immobilization of target antigens on their surface have led to the development of universal platforms which make it possible for virtually any known antigen to be exposed on the particle surface in a highly concentrated form. As a result, the focus of attention has shifted from the approaches to VLP production to the development of a precise interface between the organism's immune system and the peptides inducing a strong immune response to pathogens or the organism's own pathological cells. Immunome-specified methods for vaccine design and the prospects of immunoprophylaxis are discussed. Certain examples of vaccines against viral diseases and cancers are considered.

Evidence for horizontal transfer of the LTR retrotransposon mdg3, which lacks an env gene.

Horizontal (interspecific) transfer is regarded as a possible strategy for the propagation of transposable elements through evolutionary time. To date, however, conclusive evidence that transposable elements are capable of horizontal transfer from one species to another has been limited to class II or DNA-type elements. We tested the possibility of such transfer for several Drosophila melanogaster LTR retrotransposons of the gypsy group in an experiment in which D. melanogaster and D. virilis somatic cell lines were used as donor and recipient cells, respectively. This approach was chosen in light of the high levels of LTR retrotransposon amplification and expression observed in cultured D. melanogaster cells. In the course of the experiment, parallel analysis for mdg1, mdg3, 17.6, 297, 412 and B104/roo retrotransposons was performed to detect their presence in the genome of recipient cells. Only the mdg3 retrotransposon, which lacks an env gene, was found to be transmitted into recipient cells. This model, based on the use of cultured cells, is a promising system for further investigating the mechanisms of LTR retrotransposon transfer.

Phosphorylation of the protein encoded by the first open reading frame of the MDG4 transposable element (gypsy) by homologous and heterologous casein kinases type 2.

Homogeneous casein kinase type 2 (CK2) was obtained from oocytes of Rana temporaria and cells of Drosophila melanogaster by chromatography on heparin-Sepharose, phosphocellulose, and Mono Q columns using a Pharmacia FPLC system. The procedure was first successfully used for the purification of CK2 from the Drosophila melanogaster cell culture. It has been shown that the protein encoded by the first open reading frame (ORF) of the gypsy transposable element (MDG4) is an effective protein substrate both for homologous and heterologous CK2 from the oocytes of Rana temporaria in vitro. Both enzymes catalyze the incorporation of two moles of phosphate per mole of protein. The Km and Vmax values for the reaction catalyzed by CK2 from the Drosophila cell culture were 32.5 +/- 2.1 nM and 70.97 +/- 1.89 nmol/min per microg, respectively, and for CK2 from oocytes, these values were 37.6 +/- 2.8 nM and 66.02 +/- 2.15 nmol/min per microg, respectively.

The endogenous Drosophila melanogaster retrovirus gypsy can propagate in Drosophila hydei cells.

The endogenous Drosophila melanogaster retrovirus gypsy (mdg4) forms virus-like particles (VLPs) which are found as extracellular particles in the medium used to culture D. melanogaster cells. The D. hydei somatic cell line DH14, which does not harbour gypsy sequences, was exposed to D. melanogaster VLPs. Subsequent PCR and Southern analysis revealed that gypsy elements had penetrated into the D. hydei cells, suggesting interspecific transmission of the retrovirus. A D. hydei cell line containing gypsy sequences was established and grown in a mixed culture together with the G418-resistant D. hydei cell line DH33, and gypsy was shown to be transmitted from cell to cell. The proportion of cells carrying gypsy increased with time. The rate of gypsy invasion of the lines DH14 and DH33 was 10(-3) and 10(-2) per cell per generation, respectively. The results demonstrate the possibility of interspecific horizontal transfer of gypsy in the form of its VLPs.

Presence of the gypsy (MDG4) retrotransposon in extracellular virus-like particles.

As a first step to investigate the functional activity of gypsy virus-like particles (VLPs) we explored the possibility of preservation of its VLP in extracellular form. The preparations containing extracellular gypsy VLP from Drosophila melanogaster and D. virilis were obtained. Full-length polyA+ RNA and polyA+ RNA-DNA complexes of gypsy were observed in both preparations. The polypeptides with some specificity to gypsy nucleic acids were identified in the obtained VLP preparations. These data accompanied by morphological characteristics of samples testify the presence of intact gypsy VLP in cultured media both from D. melanogaster and D. virilis cultivated cells.