Veronika G. Dmitrieva

Expression of sphingomyelin synthase 1 gene in rat brain focal ischemia

Metabolites of the sphingomyelin cycle are reported to play an important role in neuronal death after ischemia. To elucidate the involvement of the key enzyme of this cycle, sphingomyelin synthase (SMS), in the mechanism underlying cerebral ischemia, we, for the first time, investigated changes in the mRNA expression of the SMS1 gene in rats after focal cerebral ischemia. According to our histological analysis, the damaged area is localized only in the ipsilateral cortex. In the ischemic cortex, the level of SMS1 transcripts was decreased at 3 and 24 h after occlusion, and at 72 h it had returned to the control level. A reduced level of SMS1 mRNA expression in the subcortex of rats with occlusion and sham-operated animals also was appeared during the first 24 h after surgery. This could be attributed to the effect of surgical stress. Seventy-two hours after occlusion, SMS1 mRNA expression in subcortex of ischemic rats was still at a decreased level; this may be considered to be a somewhat distant extended effect. Our results show the early response of the SMS1 gene that can be induced by both ischemia and stress. The results also suggest that inhibition of SMS1 mRNA expression may contribute to ceramide accumulation in a damaged cortex.

Effects of ischemia on the expression of neurotrophins and their receptors in rat brain structures outside the lesion site, including on the opposite hemisphere

Neurotrophins stimulate the regeneration of neural tissue after lesions. It is also known that the sources of neurogenesis and cerebral function recovery are predominantly located in subcortical brain structures. The effects of ischemia on the expression of genes that encode neurotrophins (Bdnf, Ngf, Nt-3) and their receptors (TrkB, TrkA, TrkC, p75) in brain structures outside the lesion site were studied 3, 24, and 72 h after irreversible unilateral occlusion of the middle cerebral artery in rats. Changes in the mRNA expression of these genes were assessed by relative quantification using real-time RT-PCR. Sham surgery was found to stimulate the expression of genes that encode neurotrophins (Bdnf, Ngf) and their receptor (p75). It has been shown that ischemia influenced the expression of neurotrophins (Bdnf, Ngf, Nt-3) and their receptors (TrkB, TrkA, TrkC, p75) in brain structures outside the lesion focus, including the contralateral hemisphere. The downregulation of Bdnf and TrkB transcripts and Ngf and TrkA upregulation in the contralateral cortex on the first day of ischemia obviously reflected stress response. On day 3, Nt-3 transcription increased in all investigated structures outside the lesion focus. In the contralateral hemisphere, relative levels of TrkA and TrkC mRNA expression increased, while p75 expression decreased. Presumably, the observed changes in gene transcription serve to facilitate neuroplasticity and neural tissue regeneration.

Tripeptide Pro-Gly-Pro affects rat-brain transcriptome during focal ischemia

Tripeptide Pro-Gly-Pro (PGP) belongs to the group of biologically active regulatory peptides that are resistant to peptidases. This makes it possible to use it as a C-terminal fragment of peptide agents Semax and Selank. In recent years, the independent effects of PGP were revealed. The question was raised of whether PGP contributes to the action of pharmaceutical agents that contain this peptide as a fragment. Genome-wide analysis was performed to examine the PGP impacts on the transcriptome of rat cerebral cortex in experimental ischemia. We compared the gene expression levels in animals exposed to ischemia and PGP and in rats of the ischemia control group in 3 and 24 h after the permanent occlusion of the left middle cerebral artery. The altered expression of 29 genes was detected in 3 h, while the altered expression of 57 genes was detected in 24 h. The proteins encoded by these genes fulfill various functions, such as cytokines, transport proteins, transcription factors, transmembrane receptors, etc. Biological processes associated with the genes with altered expression under experimental conditions were determined. It was shown that PGP affects a number of processes involved in the functioning of various body systems. The expression of genes associated with the immune response process changed most significantly a day after the occlusion of the middle cerebral artery. The predominant effect of the suppression of the expression of the immune system genes was observed.

Semax, an analog of ACTH(4−7), regulates expression of immune response genes during ischemic brain injury in rats

Brain stroke continues to claim the lives of million people every year. To build the effective strategies for stroke treatment it is necessary to understand the neuroprotective mechanisms that are able to prevent the ischemic injury. Consisting of the ACTH(4−7) fragment and the tripeptide Pro-Gly-Pro (PGP), the synthetic peptide Semax effectively protects brain against ischemic stroke. However, the molecular mechanisms underlying its neuroprotection and participation of PGP in them are still needed to be clarified. To reveal biological processes and signaling pathways, which are affected by Semax and PGP, we performed the transcriptome analysis of cerebral cortex of rats with focal cerebral ischemia treated by these peptides. The genome-wide biochip data analysis detected the differentially expressed genes (DEGs) and bioinformatic web-tool Ingenuity iReport found DEGs associations with several biological processes and signaling pathways. The immune response is the process most markedly affected by the peptide: Semax enhances antigen presentation signaling pathway, intensifies the effect of ischemia on the interferon signaling pathways and affects the processes for synthesizing immunoglobulins. Semax significantly increased expression of the gene encoding the immunoglobulin heavy chain, highly affects on cytokine, stress response and ribosomal protein-encoding genes after occlusion. PGP treatment of rats with ischemia attenuates the immune activity and suppresses neurotransmission in the CNS. We suppose that neuroprotective mechanism of Semax is realized via the neuroimmune crosstalk, and the new properties of PGP were found under ischemia. Our results provided the basis for further proteomic investigations in the field of searching Semax neuroprotection mechanism.

Cplx2 gene expression following semax or PGP administration under conditions of two experimental models of rat-brain ischemia

Complexin 2 is a cytosolic protein participating in synaptic-vesicle exocytosis. The RT-PCR technique was used in a real-time study of the dynamics of variation of expression of the Cplx2 gene that encodes this protein. The study was performed in the rat brain. Measurements under the conditions of incomplete global ischemia were performed during 1 day; measurements under the conditions of focal ischemia were carried out 3, 24, and 72 h after irreversible occlusion of the medial cerebral artery. The most significant decrease in Cplx2 transcripts under the conditions of incomplete global ischemia was observed in the hippocampus and the frontal cortex of rats 12 and 24 h after irreversible occlusion of the common carotid arteries, respectively. Under conditions of focal ischemia, a decrease in the content of Cplx2 transcripts was observed only in focal lesions of the frontoparietal cortex 24 h after occlusion. The effect of Semax neuroprotector peptide and its C-terminal fragment Pro-Gly-Pro on Cplx2 expression was examined under the model ischemia conditions. In the case of incomplete global ischemia, application of Semax compensated for the maximum decrease in Cplx2 expression in the frontal cortex and hippocampus in rats caused by lesions. However, the peptide had no effect when used in rats with focal ischemia. The effect of PGP on Cplx2 expression under conditions of experimental ischemia was more complicated and did not always coincide with the effect of Semax. The obtained results provide insight into the specific features of Cplx2 expression under the conditions of experimental brain ischemia and help to better understand the mechanisms of activity of peptide preparations.