[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.

The first complete Mag family retrotransposons discovered in Drosophila.

A retrotransposon of the Mag family was found in the Drosophila simulans genome for the first time. We also identified novel transposable elements representing the Mag family in seven Drosophila species. The high similarity between the 3' and 5' long terminal repeats in the found copies of transposable elements indicates that their retrotransposition has occurred relatively recently. Thus, the Mag family of retrotransposons is quite common for the genus Drosophila.

Isolation of eukaryotic DNA fragments containing structural genes and the adjacent sequences.

In Drosophila melanogaster structural genes are located close to moderately reiterated sequences. One of the clones obtained contains the DNA related to intercalary heterochromatin of D. melanogaster. These are individual differences in the distribution of genetic material in polytenic chromosomes of different stocks of D. melanogaster. The techniques that allow isolation of DNA fragments containing structural genes at the beginning, in the middle, or the end of the coding strand have been elaborated.

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.

The Drosophila mobile element jockey belongs to LINEs and contains coding sequences homologous to some retroviral proteins.

A detailed investigation of the Drosophila melanogaster mobile dispersed repetitive element jockey was performed. This is similar in its structural organization and coding potential to the long interspersed elements (LINEs) of various organisms. A complete copy of jockey (approx. 5 kb) is terminated with an oligodeoxynucleotide (dA) sequence preceded by two long open reading frames (ORFs) overlapping with a frameshift-1. Judging by the sequence homologies, ORF1 codes for a nucleic-acid-binding protein, and ORF2 for a reverse transcriptase which is most similar in its sequence to putative reverse transcriptase of other LINEs. As demonstrated by sequencing two deleted jockey copies, they contain only a small part of ORF2; however, other regions, including the terminal sequences, are highly conservative. The existence of a large number of jockey copies with a deletion in the second frame may indicate that they can use reverse transcriptase in trans.

Identification of spliced RNA species of Drosophila melanogaster gypsy retrotransposon. New evidence for retroviral nature of the gypsy element.

We have identified a novel RNA species of Drosophila melanogaster gypsy retrotransposon that is ca. 2 kb in length and corresponds to the third open reading frame (ORF3) of the gypsy element. This RNA is generated by splicing of the primary gypsy transcript, as is the case for retroviral env gene expression. Therefore, the striking resemblance between gypsy and retroviruses has now been extended by this study to the expression strategies of these retroelements. The primary structure of spliced RNA was determined, and its analysis shows that both gypsy subfamilies (6K and 7K) apparently are able to encode functionally active ORF3 translation products.

A comparative study of the location of mobile dispersed genes in salivary gland and midgut polytene chromosomes of Drosophila melanogaster.

The location of DNA fragments representing mobile dispersed genes (MDG) in salivary gland and midgut polytene chromosomes was compared by means of in situ hybridization. In the Drosophila stock under study the average number of hybridization sites in the polytene chromosomes of one nucleus was 20 for MDG-1 and 10 for MDG-3. The total numbers of hybridization sites and their relative positions proved to be same in the polytene chromosomes of the two tissues. These results support the idea of a stable location of the mobile dispersed genes in the course of ontogenesis.

Properties of promoter regions of mdg1 Drosophila retrotransposon indicate that it belongs to a specific class of promoters.

A sequence 30 bp downstream from the start site of the Drosophila melanogaster retrotransposon mdg1 is shown to be responsible for correct and precise initiation of mdg1 RNA synthesis in combination with the RNA start-site sequence TCAGTT. A sequence-specific DNA binding protein is demonstrated to interact with the +30 sequence, and the efficient binding of this factor is necessary for in vivo transcriptional activity of the plasmid constructs containing mdg1 promoter fragments. The nucleotides -8/+34 of mdg1 represent a minimal promoter which is able to provide correct initiation of transcription by RNA polymerase II at basal levels. A comparison with properties of some other retrotransposable elements and several developmentally regulated cellular genes allows us to conclude that together they form a specific class of RNA polymerase II promoter. This promoter class characteristically lacks upstream sequences necessary for transcription initiation, such as TATA boxes, but requires a specific downstream promoter element within 40 bp downstream of the RNA start site. The level of transcription can, however, be modulated by upstream regulatory elements. The identified sequence-specific downstream initiation factor may be responsible for transcription initiation on promoters of some genes which belong to this class.

Control of transcription of Drosophila retrotransposons.

Studies of transcriptional control sequences responsible for regulated and basal-level RNA synthesis from promoters of Drosophila melanogaster retrotransposons reveal novel aspects of gene regulation and lead to identification of trans-acting factors that can be involved in RNA polymerase II transcription not only of retrotransposons, but of many other cellular genes. Comparisons between promoters of retrotransposons and some other Drosophila genes demonstrate that there is a greater variety in basal promoter structure than previously thought and that many promoters may contain essential sequences downstream from the RNA start site.

Selection and some properties of recombinant clones of lambda bacteriophage containing genes of Drosophila melanogaster.

The lambdagt clones containing fragments of the Drosophila melanogaster genome were prepared and characterized by hybridization of their DNA with (I) lambdagt-cRNA; (2) lambdaC-cRNA; (3) Dm-cRNA; (4) the mRNA of D.melanogaster culture cells and (5) the stable cytoplasmic poly (A) RNA from the same source. The technique for a simple selection of hybrid clones is described. The hybridization with mRNA allows one to select the clones containing structural genes of D.melanogaster. It was found that in all cases when the clone contains the structural gene it also contains the reiterated base sequences of the D.melanogaster genome. Several clones containing D. melanogaster DNA fragments with a size of (2-4)x1O6 daltons hybridizing with a relatively large portion of mRNA were selected for further analysis.

jockey, a mobile Drosophila element similar to mammalian LINEs, is transcribed from the internal promoter by RNA polymerase II.

The mobile element jockey is similar in structural organization and coding potential to the LINEs of various organisms. As demonstrated here, two polyadenylated jockey transcripts detected at different stages of Drosophila ontogenesis and in cell cultures have the same length as genomic copies of jockey and correspond to the strand containing ORFs. alpha-amanitin experiments indicate that jockey is transcribed by RNA polymerase II. Analysis of both expression of CAT constructions and initiation of transcription in jockey genomic and transfected copies has shown that jockey transcription is controlled by an internal promoter. Inward location of the promoter allows it to be preserved in the course of replication via reverse transcription and accounts for the distribution of jockey and probably other LINEs throughout the genome. This is the first case of an internal promoter described for RNA polymerase II. The comparison of sequences at the beginning of LINE elements in Drosophila allows one to detect possible core sequences.

Mobile dispersed genetic element MDG1 of Drosophila melanogaster: nucleotide sequence of long terminal repeats.

Long terminal repeats (LTRs) of two members of mdg1 family were sequenced. In the both cases, they are represented by perfect direct repeats 442 and 444 bp in length. Sixteen nucleotides in the LTRs of two different mdg1 elements are different. Each LTR contains slightly mismatched 16-nucleotide inverted repeats located at the ends of the LTR. Six base pairs closest to the termini of LTR form perfect inverted repeats. On the gene-distal sides of LTRs, short 4-nucleotide direct repeats are located, probably representing the duplication of a target DNA sequence arising from insertion of mdg. They are different in the two cases analyzed. Just as the other analyzed eukaryotic transposable elements, mdg1 starts with TGT and ends with ACA. Within the both strands of LTR, the sequences similar to Hogness box (a putative signal for RNA initiation, or a selector) and AATAAA blocks (putative polyadenylation signals) are present. The LTR of mdg1 contains many short direct and inverted repetitive sequences. These include a 10-nucleotide sequence forming a perfect direct repeat with the first ten nucleotides of the LTR. A region of LTR about 70 bp long is represented by simple repetitive sequences (TAT).

Retrotransposon Gypsy and genetic instability in Drosophila (review).

The laboratory mutator strain (MS) has properties which can be characterized as genetic instability. It exhibits the high level of gypsy autonomous transposition in somatic and germ cells. This paper summarizes all the data concerning this system and gypsy itself that has been obtained in our works during the last years.

Leader region of mdg1 Drosophila retrotransposon RNA contains 3'-end processing sites.

Transient expression of the mdg1 deletion mutants revealed sites of 3'-end processing in the leader region of the transcribed RNA. The efficiency of the processing is regulated in different types of cells. The sequences within the mdg1 body and the 3'-LTR are involved in its regulation. We have also shown, that one of the small open reading frames in the mdg1 leader region in principle might be translated.