[Insertion of Multiple Artificial Introns of Universal Design into cDNA during Minigene Construction Assures Correct Transgene Splicing].

The presence of introns is often required for efficient transgene expression. The use of full-length genes for transgenesis is associated with technical difficulties due to the large size of the genetic construct. To solve this problem, we recently suggested a universal design of small artificial introns that ensures efficient splicing. However, the insertion of more than one intron into cDNA might result in the aberrant splicing of the minigene with exon skipping. Here, we showed that the insertion of two artificial introns of universal design into cDNA resulted in a splicing pattern that corresponds to the excision of each intron with an exon between them remaining in the transcript. No transcript formation with exon skipping was detected. Therefore, the developed design of small artificial introns assures splicing solely between the donor and the acceptor splice sites of each single intron and results in the generation of a correct transcript from minigene pre-mRNA. These findings enable the construction of minigenes for transgenesis with more than one artificial intron, with no additional cis-elements required to prevent aberrant splicing.

[Optimal Artificial Mini-Introns for Transgenic Expression in the Cells of Mice and Hamsters].

Introns can frequently enhance transgene expression, and sometimes they are absolutely substantial. Based on an analysis of murine genes, in which mRNA does not have alternative splicing, a universal design of the efficiently spliced artificial introns of small sizes has been proposed. These introns are shown to be efficiently spliced in CHO cells from hamster ovaries. The proposed strategy can be used to include introns in cDNA, which would elevate the production of recombinant proteins in cell culture, as well as in transgenic animals.

[Induction of transcription through the scs insulator leads to abnormal development of Drosophila melanogaster].

A regulatory element named scs is one of the first insulators discovered in Drosophila, which was found on the boundary of the hsp70 domain. The 993-bp scs insulator contains two promoters at the ends and two polyadenylation signals located in the same orientation in the central part of the insulator. In the Drosophila transgenic lines, induction of a strong transcription through the scs insulator only in the direction that coincides with the direction of the two polyadenylation sites activity results in multiple phenotypic defects of the Drosophila development and embryonic lethality. A similar effect was not observed upon testing of other known Drosophila insulators.

The use of artificial transcription terminators for creating transgenic plants with high-level expression of reporter gene.

In this study, we investigated the possibility of increasing the level of transgene expression using DNA element that can terminate transcription.