Матлашов Михаил Егорович

Аспирант (Лаборатория молекулярных технологий)

Эл. почта: matlashowww@mail.ru

Избранные публикации

  1. Pereverzev A.P., Matlashov M.E., Staroverov D.B., Lukyanov K.A., Gurskaya N.G. (2015). Differences of Nonsense-Mediated mRNA Degradation Activity in Mammalian Cell Lines Revealed by a Fluorescence Reporter. Bioorg. Khim. 41 (5), 587–91 [+]

    Activity of nonsense-mediated mRNA degradation (NMD) was studied in several mammalian cell cultures using recently developed genetically encoded fluorescence sensor [Pereverzev et al., Sci. Rep., 2015, vol. 5, p. 7729]. This NMD reporter enables measurement of NMD activity in single live cells using ratio of green and red fluorescent proteins signals. The following cell lines were analyzed: mouse colon carcinoma CT26, mouse Lewis lung carcinoma LLC, human T-cell leukemia Jurkat, and spontaneously immortalized human keratinocytes HaCaT. These cell lines demonstrated very different NMD activities. In CT26, NMD activity was low, whereas in LLC it was high (8.5-fold higher than in CT26). Jurkat and HaCaT cells possessed strong heterogeneity and consisted of two cell subpopulations with high and low NMD activities. In addition, we detected high NMD activity in primary culture of mouse embryonic hippocampal neurons.

  2. Ermakova Y.G., Bilan D.S., Matlashov M.E., Mishina N.M., Markvicheva K.N., Subach O.M., Subach F.V., Bogeski I., Hoth M., Enikolopov G., Belousov V.V. (2014). Red fluorescent genetically encoded indicator for intracellular hydrogen peroxide. Nat Commun 5, 5222 [+]

    Reactive oxygen species (ROS) are conserved regulators of numerous cellular functions, and overproduction of ROS is a hallmark of various pathological processes. Genetically encoded fluorescent probes are unique tools to study ROS production in living systems of different scale and complexity. However, the currently available recombinant redox sensors have green emission, which overlaps with the spectra of many other probes. Expanding the spectral range of recombinant in vivo ROS probes would enable multiparametric in vivo ROS detection. Here we present the first genetically encoded red fluorescent sensor for hydrogen peroxide detection, HyPerRed. The performance of this sensor is similar to its green analogues. We demonstrate the utility of the sensor by tracing low concentrations of H2O2 produced in the cytoplasm of cultured cells upon growth factor stimulation. Moreover, using HyPerRed we detect local and transient H2O2 production in the mitochondrial matrix upon inhibition of the endoplasmic reticulum Ca(2+) uptake.

  3. Mishina N.M., Markvicheva K.N., Bilan D.S., Matlashov M.E., Shirmanova M.V., Liebl D., Schultz C., Lukyanov S., Belousov V.V. (2013). Visualization of intracellular hydrogen peroxide with HyPer, a genetically encoded fluorescent probe. Meth. Enzymol. 526, 45–59 [+]

    The fluorescent sensor HyPer allows monitoring of intracellular H2O2 levels with a high degree of sensitivity and specificity. Here, we provide a detailed protocol of ratiometric imaging of H2O2 produced by cells during phagocytosis, including instructions for experiments on different commercial confocal systems, namely, Leica SP2, Leica SP5, and Carl Zeiss LSM, as well as wide-field Leica 6000 microscope. The general experimental scheme is easily adaptable for imaging H2O2 production by various cell types under a variety of conditions.