[«He always talked about something else ¼ Alexey Matveyevich Olovnikov and his unusual science.]

In this article, we celebrate the life and scientific contributions of the exceptional theoretical gerontologist Alexey Matveyevich Olovnikov (1936-2022), who is renowned for his visionary hypothesis regarding the role of telomeres in aging. He postulated that the ends of linear chromosomes cannot be completely replicated, which explains the limited potential of somatic cell divisions. He also predicted the presence of a specialized DNA polymerase that lengthens telomeres in germ, cancer, and stem cells. These and other aspects of telomere biology have been confirmed and are now the foundations of modern gerontology. Alexey proposed several hypotheses on aging, biorhythms, morphogenesis and evolution, all of which are striking and extraordinary, much like their author.

Interaction of Telomeric Retroelement HeT-A Transcripts and Their Protein Product Gag in Early Embryogenesis of Drosophila.

The telomere is a nucleoprotein complex at the ends of linear chromosomes that protects them from fusion and degradation. The telomere consists of telomeric DNA, a protective protein complex and telomeric RNA. Biogenesis of telomeric transcripts in development is still far from being understood. Drosophila telomeres are elongated by a transposition of specialized telomeric retrotransposons that encode proteins. Using transgenic constructs encoding tagged telomeric protein, we found that transcripts of Drosophila telomeric element HeT-A bind Gag-HeT-A protein encoded by these transcripts. Maternal HeT-A transcripts and Gag-HeT-A form ribonucleoprotein granules around centrosomes, centers of microtubule organization, during blastoderm formation, upon disruption of telomere silencing during oogenesis. The specific localization of HeT-A RNA is dependent on microtubules since disruption of microtubules caused delocalization of HeT-A transcripts. This transgenic system is a valuable model for the study of telomeric RNA biogenesis.

piRNA clusters as a main source of small RNAs in the animal germline.

PIWI subfamily Argonaute proteins and small RNAs bound to them (PIWI interacting RNA, piRNA) control mobilization of transposable elements (TE) in the animal germline. piRNAs are generated by distinct genomic regions termed piRNA clusters. piRNA clusters are often extensive loci enriched in damaged fragments of TEs. New TE integration into piRNA clusters causes production of TE-specific piRNAs and repression of cognate sequences. piRNAs are thought to be generated from long single-stranded precursors encoded by piRNA clusters. Special chromatin structures might be essential to distinguish these genomic loci as a source for piRNAs. In this review, we present recent findings on the structural organization of piRNA clusters and piRNA biogenesis in Drosophila and other organisms, which are important for understanding a key epigenetic mechanism that provides defense against TE expansion.

[A key role of the internal region of the 5'-untranslated region in the human L1 retrotransposon transcription activity].

The long 5-untranslated region (5'-UTR) of the human retrotransposon L1 harbors a unique internal promoter which ensures new copies of this mobile element to be much less dependent on an integration site at the level of transcription. The mechanism of this promoter's action still remains unclear, but due to some early studies the opinion has been -formed that the most important part for its function ("minimal promoter") is the first 100-150 nts of the 5'-UTR. In this paper we show that activity of the "minimal promoter" is rather poor in comparison with the entire 5'-UTR. The absolutely crucial part which is indispensable for the effective transcription is the internal region of the 5'-UTR (+390...+662) containing multiple binding sites for various transcription factors. This region may be considered as a transcriptional enhancer. Deletion of this segment leads to a dramatic lost of transcription level irrespectively of cell type, while deletion of the first 100 nt decreases the transcription efficiency no more than 1.5 to 2-fold. Thus, the organization of the L1 regulatory region may be much more similar to that of well-studied invertebrate LINE elements than it was thought before. Also we suggest a possible existence of an alternative sense promoter within the internal part of the L1 5'-UTR driving the synthesis of a 5'-truncated mRNA of the retrotransposon.