Email this article Biocrystallization of bacterial nucleoid under stress
- Authors: Sinitsyn D.O.1, Loiko N.G.1,2, Gularyan S.K.1, Stepanov A.S.1, Tereshkina K.B.1,3, Chulichkov A.L.1, Nikolaev A.A.2, El-Registan G.I.2, Popov V.O.2, Sokolova O.S.4, Shaitan K.V.1,4, Popov A.N.5, Krupyanskii Y.F.1
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Affiliations:
- Semenov Institute of Chemical Physics
- Federal Research Center “Fundamentals of Biotechnology,”
- Dmitry Mendeleev University of Chemical Technology of Russia
- Moscow State University
- European Synchrotron Radiation Facility
- Issue: Vol 11, No 5 (2017)
- Pages: 833-838
- Section: Chemical Physics of Biological Processes
- URL: https://journals.rcsi.science/1990-7931/article/view/199650
- DOI: https://doi.org/10.1134/S1990793117050128
- ID: 199650
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Abstract
Structural, biochemical, and genetic changes caused by stress factors are known to be largely similar for cells of all modern organisms, which inherited the basic strategies of adaptation to different types of stress from their ancient ancestors. In the present work, the adaptation process is considered for the simplest example of the bacterial E. coli nucleoid. Experimental studies performed recently on prokaryotic bacterial cells, the simplest living organisms, have demonstrated that, under unfavorable environmental conditions (for example, starvation), bacterial cells can use biocrystallization, a special mechanism of protection of the genetic apparatus (nucleoid), generally untypical of living organisms. This mechanism helps to protect the nucleoid from damage and resume the activity of the bacterial cells later, upon improvement of the external conditions. The results of studying the structure of the nucleoid of E. coli bacteria (BL21-Gold strain (DE3)) subjected to starvation stress by using synchrotron radiation at the ESRF beamline ID23-1 are reported.
About the authors
D. O. Sinitsyn
Semenov Institute of Chemical Physics
Email: yufk@chph.ras.ru
Russian Federation, Moscow, 119991
N. G. Loiko
Semenov Institute of Chemical Physics; Federal Research Center “Fundamentals of Biotechnology,”
Email: yufk@chph.ras.ru
Russian Federation, Moscow, 119991; Moscow, 119071
S. K. Gularyan
Semenov Institute of Chemical Physics
Email: yufk@chph.ras.ru
Russian Federation, Moscow, 119991
A. S. Stepanov
Semenov Institute of Chemical Physics
Email: yufk@chph.ras.ru
Russian Federation, Moscow, 119991
K. B. Tereshkina
Semenov Institute of Chemical Physics; Dmitry Mendeleev University of Chemical Technology of Russia
Email: yufk@chph.ras.ru
Russian Federation, Moscow, 119991; Moscow, 125047
A. L. Chulichkov
Semenov Institute of Chemical Physics
Email: yufk@chph.ras.ru
Russian Federation, Moscow, 119991
A. A. Nikolaev
Federal Research Center “Fundamentals of Biotechnology,”
Email: yufk@chph.ras.ru
Russian Federation, Moscow, 119071
G. I. El-Registan
Federal Research Center “Fundamentals of Biotechnology,”
Email: yufk@chph.ras.ru
Russian Federation, Moscow, 119071
V. O. Popov
Federal Research Center “Fundamentals of Biotechnology,”
Email: yufk@chph.ras.ru
Russian Federation, Moscow, 119071
O. S. Sokolova
Moscow State University
Email: yufk@chph.ras.ru
Russian Federation, Moscow, 119991
K. V. Shaitan
Semenov Institute of Chemical Physics; Moscow State University
Email: yufk@chph.ras.ru
Russian Federation, Moscow, 119991; Moscow, 119991
A. N. Popov
European Synchrotron Radiation Facility
Email: yufk@chph.ras.ru
France, Grenoble, 38000
Yu. F. Krupyanskii
Semenov Institute of Chemical Physics
Author for correspondence.
Email: yufk@chph.ras.ru
Russian Federation, Moscow, 119991
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