[The Peptide Drug ACTH(4-7)PGP (Semax) Suppresses mRNA Transcripts Encoding Proinflammatory Mediators Induced by Reversible Ischemia of the Rat Brain].

Due to its nootropic, neuroprotective, and immunomodulatory effects, the peptide Semax is utilized in the treatment of ischemic stroke. Our earlier RNA-Seq analysis of the transcriptome in an ischemic model of transient occlusion of the middle cerebral artery showed an increase in the mRNA levels of many proinflammatory genes, and the suppression of their induction by Semax. However, for many relevant genes, including Il1a, Il1b, Il6 and Tnfa, the levels of their expression were too low for detailed quantitative evaluation. Here we utilize qRT-PCR to analyze the effects of the Semax peptide on the expression of weakly expressed mRNAs encoding several proinflammatory mediators, and show that exposure to Semax leads to a statistically significant decrease in the Il1a, Il1b, Il6, Ccl3, and Cxcl2 mRNAs, which compensates for the increase in the transcription of these genes induced by ischemia-reperfusion. We conclude that the observed protective effect of Semax in the model of stroke may be due to its anti-inflammatory effects. We also discuss the limitations of the RNA-Seq when applied to quantifying less abundant transcripts as compared to the real-time RT-PCR method.

Neuroprotective Effects of Peptides in the Brain: Transcriptome Approach.

The importance of studying the action mechanisms of drugs based on natural regulatory peptides is commonly recognized. Particular attention is paid to the peptide drugs that contribute to the restoration of brain functions after acute cerebrovascular accidents (stroke), which for many years continues to be one of the main problems and threats to human health. However, molecular genetic changes in the brain in response to ischemia, as well as the mechanisms of protective effects of peptides, have not been sufficiently studied. This limits the use of neuroprotective peptides and makes it difficult to develop new, more efficient drugs with targeted action on brain functions. Transcriptome analysis is a promising approach for studying the mechanisms of the damaging effects of cerebral ischemia and neuroprotective action of peptide drugs. Beside investigating the role of mRNAs in protein synthesis, the development of new neuroprotection strategies requires studying the involvement of regulatory RNAs in ischemia. Of greatest interest are microRNAs (miRNAs) and circular RNAs (circRNAs), which are expressed predominantly in the brain. CircRNAs can interact with miRNAs and diminish their activity, thereby inhibiting miRNA-mediated repression of mRNAs. It has become apparent that analysis of the circRNA/miRNA/mRNA system is essential for deciphering the mechanisms of brain damage and repair. Here, we present the results of studies on the ischemia-induced changes in the activity of genes and peptide-mediated alterations in the transcriptome profiles in experimental ischemia and formulate the basic principles of peptide regulation in the ischemia-induced damage.

PECULIARITIES OF THE STRUCTURE AND EXPRESSION OF HUMAN SPHINGOMYELIN SYNTHASE 1 GENE (SGMS1).

The article is a review of the results of the study of the structural and functional organization of the human sphingomyelin synthase 1 gene (SGMS1) in Human Molecular Genetics Department of Institute of Molecular Genetics RAS. SGMS1 gene encodes an essential enzyme which is involved in the synthesis of sphingomyelin and diacylglycerol from phosphatidylcholine and ceramide, wich determines its participation in the regulation of intracellular vesicular transport, cholesterol metabolism, cell proliferation, apoptosis and other significant processes. Our research has shown that the SGMS1 gene is located on the chromosome 10, has a size of 320 kb and contains more than 20 exons. A detailed study of the SGMS1 gene's structure allowed us to identify the variety of its transcripts. mRNA isoforms with different fragments of 5R untranslated region (5R UTR) and encoding the full length protein, as well as transcripts resulting from alternative combinations of exons and containing the coding region of the gene and 3R UTR have been discovered. We have found new transcripts among the products of SGMS1 gene ­ circular RNAs, which mostly contained sequences of multi-exon 5R UTR of the gene. They are conservative and predominantly expressed in the brain. Circular RNAs of SGMS1 gene had a large number of binding sites for a microRNA that may determine the functional significance of these molecules. The review describes the latest information about the structural and functional organization of the human gene SGMS1 as well as the features of its expression.

[Alternative promoters localised in SGMS1 gene introns take part in regulation of its expression in human tissues].

Sphingomyelin synthase 1 (SMS1) is an enzyme of vital importance which is responsible for the synthesis of sphingomyelin and diacylglycerol from phosphatidylcholine and ceramide in eukaryotic cells. Previously we have investigated in detail the structure of SGMS1 human gene and identified a lot of its transcripts. We revealed the isoforms of mRNA differing in the 5'-UTR and coding the full-length protein, and also the transcripts arising from alternative combination of the exons localized in the coding region of the gene and 3'-UTR. From the results of computer analysis it follows that the synthesis of transcripts differing in the 5'-UTR is enabled by the different promoters of SGMS1 gene. It has been found in the present work by the method of real-time PCR that the content of five alternative transcripts of this gene, differing in the 5'-UTR, is substantially dissimilar among human tissues. In all the investigated tissues those transcripts are presented most prominently whose synthesis takes place under the control of the distal promoter including exon 1. In lesser extent are presented the transcripts including 5'-end exons whose synthesis is enabled by the promoters localized in introns of this gene. The differential level of content of SGMS1 gene transcripts, differing in the 5'-UTR, indicates that the use of the alternative promoters is tissue-specific and apparently strictly regulated. The structural organization of 5'-UTR variants of SGMS1 transcripts, directed by alternative promoters, is substantially different; this can provide regulation of the gene functioning on post-transcriptional level.