11 research outputs found

    Влияние дексаметазона на экспрессию и содержание гликозилированных компонентов в ткани головного мозга мышей

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    Introduction. Glucocorticoids are actively used in the treatment of various diseases, however their long-term use leads to numerous negative side-effects, the molecular mechanisms of which remain poorly understood.Aim. Study of the short-term (1–10 days) effects of various doses of dexamethasone (Dex) (0,1–10 mg/kg) on the expression of the glucocorticoid receptor (GR, Nr3c1), core proteins of main proteoglycans and heparan sulfate metabolism-involved genes, as well as the content of carbohydrate macromolecules of glycosaminoglycans in the brain tissue of experimental animals.Materials and methods. In the study, C57Bl/6 mice were used. The expression of GR, proteoglycan core proteins and heparan sulfate metabolism-involved genes was determined by real-time polymerase chain reaction with reverse transcription. The content and localization of GR protein molecule were studied by Western blot and immunohistochemical analysis, and the glycosaminoglycan content was determined by dot-blot analysis and Alcian Blue staining.Results. It was shown that a single Dex administration leads to fast (1–3 days) short-term activation of GR expression (+1.5 times, p <0.05), proteoglycan’s genes (syndecan-3, Sdc3; perlecan, Hspg2; phosphacan, Ptprz1; neurocan, Ncan; +2–3-fold; p <0.05) and heparan sulfate-metabolism-involved genes (Ndst1, Glce, Hs2st1, Hs6st1, Sulf1 / 2; +1.5–2-fold; p <0.05) in the mouse brain, with a return to control values by 7–10 days after Dex administration. At the same time, the effect of Dex on carbohydrate macromolecules of glycosaminoglycans was more delayed and stable, increasing the content of low-sulfated glycosaminoglycans in the brain tissue in a dose-dependent manner starting from day 1 after Dex administration. Highly-sulfated glycosaminoglycans showed more delayed response to Dex administration, and an increase in their content was observed only at higher doses (2.5 and 10 mg/kg) and only on 7–10 days after its administration, apparently, mainly due to an increase in heparan sulfate content.Conclusion. In general, the effect of a single injection of Dex on the transcriptional activity of GR, proteoglycan core proteins and heparan sulfate metabolism-involved genes were short-termed, and the genes expression quickly returned to the normal levels. However, even a single use of Dex significantly increased the content of total as well as highly sulfated glycosaminoglycans in the mouse brain tissue, which can lead to the changes in the composition and structure of the brain tissue, as well as its functional characteristics.Введение. Глюкокортикоиды активно используются при лечении различных заболеваний, однако их длительное применение приводит ко множеству побочных эффектов, молекулярные механизмы развития которых остаются недостаточно изученными.Цель исследования – изучение краткосрочного (1–10 сут) влияния различных доз дексаметазона (Dex) (0,1–10 мг/кг) на экспрессию глюкокортикоидного рецептора (GR, Nr3c1), коровых белков основных протеогликанов и ферментов биосинтеза углеводных цепей гепарансульфата, а также содержание углеводных макромолекул гликозаминогликанов в ткани головного мозга экспериментальных животных.Материалы и методы. В исследовании использовали мышей линии C57Bl/6. Экспрессию GR, коровых белков протеогликанов и генов, кодирующих ферменты биосинтеза гепарансульфата, определяли с помощью полимеразной цепной реакции с обратной транскрипцией в реальном времени. Содержание и локализация белковой молекулы GR были изучены методами Вестерн-блоттинга и иммуногистохимического анализа, а содержание гликозаминогликанов – с помощью дот-блот анализа и окраски альциановым синим.Результаты. Было показано, что однократное введение Dex приводило к быстрой (на 1–3-и сутки) кратковременной активации экспрессии GR (+1,5 раза; p <0,05) некоторых генов коровых белков протеогликанов (синдекан-3, Sdc3; перлекан, Hspg2; фосфакан, Ptprz1; нейрокан, Ncan; +2–3 раза; p <0,05) и генов ферментов биосинтеза гепарансульфатов (Ndst1, Glce, Hs2st1, Hs6st1, Sulf1 / 2; +1,5–2 раза; p <0,05) в мозге мышей с возвращением к контрольным показателям к 7–10-м суткам после введения Dex. При этом влияние данного препарата на углеводные макромолекулы гликозаминогликанов имело более отсроченный и стабильный характер, дозозависимо увеличивая содержание общих гликозаминогликанов в ткани мозга, начиная с 1-х суток после введения Dex. Высокосульфатированные гликозаминогликаны демонстрировали более медленный ответ на введение препарата, повышение их содержания наблюдалось только при более высоких дозах (2,5 и 10 мг/кг) и только на 7–10-е сутки после его введения в основном за счет повышения содержания гепарансульфата.Заключение. Влияние однократного применения Dex на транскрипционную активность GR, протеогликанов и ферментов биосинтеза гепарансульфата носит кратковременный характер, и экспрессия генов быстро возвращается к нормальному уровню. Однако даже однократное применение Dex значительно повышает содержание общих и высокосульфатированных гликозаминогликанов в ткани головного мозга мышей, что может привести к изменению состава и структуры ткани головного мозга, а также его функциональных характеристик

    Multiple Irradiation Affects Cellular and Extracellular Components of the Mouse Brain Tissue and Adhesion and Proliferation of Glioblastoma Cells in Experimental System In Vivo

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    Intensive adjuvant radiotherapy (RT) is a standard treatment for glioblastoma multiforme (GBM) patients; however, its effect on the normal brain tissue remains unclear. Here, we investigated the short-term effects of multiple irradiation on the cellular and extracellular glycosylated components of normal brain tissue and their functional significance. Triple irradiation (7 Gy*3 days) of C57Bl/6 mouse brain inhibited the viability, proliferation and biosynthetic activity of normal glial cells, resulting in a fast brain-zone-dependent deregulation of the expression of proteoglycans (PGs) (decorin, biglycan, versican, brevican and CD44). Complex time-point-specific (24–72 h) changes in decorin and brevican protein and chondroitin sulfate (CS) and heparan sulfate (HS) content suggested deterioration of the PGs glycosylation in irradiated brain tissue, while the transcriptional activity of HS-biosynthetic system remained unchanged. The primary glial cultures and organotypic slices from triple-irradiated brain tissue were more susceptible to GBM U87 cells’ adhesion and proliferation in co-culture systems in vitro and ex vivo. In summary, multiple irradiation affects glycosylated components of normal brain extracellular matrix (ECM) through inhibition of the functional activity of normal glial cells. The changed content and pattern of PGs and GAGs in irradiated brain tissues are accompanied by the increased adhesion and proliferation of GBM cells, suggesting a novel molecular mechanism of negative side-effects of anti-GBM radiotherapy

    Simulations of efficient Raman amplification into the multipetawatt regime

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    Contemporary high-power laser systems make use of solid-state laser technology to reach petawatt pulse powers. The breakdown threshold for optical components in these systems, however, demands metre-scale beams. Raman amplification of laser beams promises a breakthrough by the use of much smaller amplifying media, that is, millimetre-diameter plasmas, but so far only 60 GW peak powers have been obtained in the laboratory, far short of the desired multipetawatt regime. Here we show, through the first large-scale multidimensional particle-in-cell simulations of this process, that multipetawatt peak powers can be reached, but only in a narrow parameter window dictated by the growth of plasma instabilities. Raman amplification promises reduced cost and complexity of intense lasers, enabling much greater access to higher-intensity regimes for scientific and industrial applications. Furthermore, we show that this process scales to short wavelengths, enabling compression of X-ray free-electron laser pulses to attosecond duration

    Recent improvements in confinement and beta in the MST reversed-field pinch

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    In the general area of confinement improvement and concept advancement, recent results in the Madison Symmetric Torus (MST) reversed-field pinch (RFP) include good confinement of both thermal and large-orbit ions and near doubling of total beta to 26% with deuterium pellet injection. Current profile control enables MST to reduce stochastic transport and achieve tokamak-like confinement. In standard RFP operation, substantial MHD tearing mode activity results in stochastic transport and an energy confinement time of about I ms in MST. Application of inductive current profile control reduces MHD activity and accompanying stochasticity, improving confinement by about a factor of ten. Previous work concentrated on electron confinement in improved-confinement RFP operation. Recent work confirms that ions are also well confined, and that high beta and improved confinement can be achieved simultaneously

    Turbulence and coherent structures in non-neutral plasmas

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