Богданова Екатерина Андреевна

Кандидат биологических наук

Научный сотрудник (Лаборатория методов иммуносеквенирования)

Тел.: +7 (495) 988-40-83

Эл. почта: katya@ibch.ru

Избранные публикации

  1. Mishina N.M., Mishin A.S., Belyaev Y., Bogdanova E.A., Lukyanov S., Schultz C., Belousov V.V. (2015). Live-Cell STED Microscopy with Genetically Encoded Biosensor. Nano Lett. 15 (5), 2928–2932 [+]

    Of the various super-resolution techniques, stimulated emission depletion (STED) microscopy achieves the best temporal resolution at high spatial resolution, enabling live-cell imaging beyond the diffraction limit. However, STED and most other super-resolution imaging methods utilize a particular type of information extractable from the raw data, namely the positions of fluorophores. To expand on the use of super-resolution techniques, we report here the live-cell STED microscopy of a dynamic biosensor. Using the fluorescent H2O2 sensor HyPer2 for subdiffraction imaging, we were able not only to image filaments with superior resolution by localizing emission but also to trace H2O2 produced within living cell by monitoring brightness of the probe. STED microscopy of HyPer2 demonstrates potential utility of FP-based biosensors for super-resolution experiments in situ and in vivo.

  2. Shagina I., Bogdanova E., Mamedov I., Lebedev Y., Lukyanov S., Shagin D. (2010). Normalization of genomic DNA using duplex-specific nuclease. BioTechniques 48 (6), 351–355 [+]

    An application of duplex-specific nuclease (DSN) normalization technology to whole-genome shotgun sequencing of genomes with a large proportion of repetitive DNA is described. The method uses a thermostable DSN from the Kamchatka crab that specifically hydrolyzes dsDNA. In model experiments on human genomic DNA, we demonstrated that DSN normalization of double-stranded DNA formed during C0t analysis is effective against abundant repetitive sequences with high sequence identity, while retaining highly divergent repeats and coding regions at baseline levels. Thus, DSN normalization applied to C0t analysis can be used to eliminate evolutionarily young repetitive elements from genomic DNA before sequencing, and should prove invaluable in studies of large eukaryotic genomes, such as those of higher plants.

  3. Bogdanov A.M., Bogdanova E.A., Chudakov D.M., Gorodnicheva T.V., Lukyanov S., Lukyanov K.A. (2009). Cell culture medium affects GFP photostability: a solution. Nat. Methods 6 (12), 859–60 ID:298
  4. Markvicheva K.N., Bogdanova E.A., Staroverov D.B., Lukyanov S., Belousov V.V. (2008). Imaging of intracellular hydrogen peroxide production with HyPer upon stimulation of HeLa cells with epidermal growth factor. Methods Mol. Biol. 476, 79–86 [+]

    Reactive oxygen species (ROS) regulate both normal cell functions by activating a number of enzymatic cascades and pathological processes in many diseases by inducing oxidative stress. For many years since the discovery of ROS in biological systems, there were no adequate methods of detection and quantification of these molecules inside the living cells. We developed the first genetically encoded fluorescent indicator for the intracellular detection of hydrogen peroxide, HyPer, that can be used for imaging of H2O2 production by cells under various physiological and pathological conditions. Unlike most known ROS indicators, HyPer allows the generation of a real-time image series that give precise information about the time course and intensity of H2O2 changes in any compartment of interest. In this chapter, we describe the method of confocal imaging of hydrogen peroxide production in HeLa cells upon stimulation with epidermal growth factor. The technique described may be accepted with minimal variations for the use in other cell lines upon various conditions leading to H2O2, production.

  5. Shcherbo D., Merzlyak E.M., Chepurnykh T.V., Fradkov A.F., Ermakova G.V., Solovieva E.A., Lukyanov K.A., Bogdanova E.A., Zaraisky A.G., Lukyanov S., Chudakov D.M. (2007). Bright far-red fluorescent protein for whole-body imaging. Nat. Methods 4 (9), 741–6 [+]

    Разработан новый флуоресцентный белок Katushka, обладающий флуоресценцией в дальне-красной области спектра, которая является предпочтительной для анализа сигнала внутри тканей животных. Katushka в десять раз ярче, чем созданные ранее дальне-красные флуоресцентные белки и характеризуется высокой скоростью созревания, высокой рН-стабильностью и фотостабильностью. Это делает новый белок идеальным инструментом для прижизненного мечения клеток внутри целых организмов. Создан мономерный вариант белка Katushka, названный mKate, для исследования внутриклеточной локализации белков.

  6. Shagin D.A., Rebrikov D.V., Kozhemyako V.B., Altshuler I.M., Shcheglov A.S., Zhulidov P.A., Bogdanova E.A., Staroverov D.B., Rasskazov V.A., Lukyanov S. (2002). A novel method for SNP detection using a new duplex-specific nuclease from crab hepatopancreas. Genome Res. 12 (12), 1935–42 [+]

    Охарактеризован новый фермент — дуплекс-специфическая нуклеаза (ДСН) из гепатопанкреаса камчатского краба. ДСН обладает высокой специфичностью к двухцепочечной ДНК при отсутствии гидролитической активности по отношению к одноцепочечной ДНК и РНК и стабильность в широком диапазоне температур. Благодаря уникальной комбинации свойств ДСН является идеальным инструментом для удаления двухцепочечной ДНК из сложных смесей нуклеиновых кислот.