Elucidation of cellular mechanisms of autophagy involvement in plant adaptation to microgravity conditions
Heading:
1Yemets, AI, 1Plokhovska, SH, 1Shadrina, RYu., 1Kravets, OA, 1Blume, Ya.B 1Institute of Food Biotechnology and Genomics of the National Academy of Sciences of Ukraine, Kyiv, Ukraine |
Space Sci. & Technol. 2023, 29 ;(2):22-31 |
https://doi.org/10.15407/knit2023.02.022 |
Publication Language: English |
Abstract: It was shown that clinostating conditions induce autophagy without increasing of programmed cell death (PCD) index in the epidermal cells of the root apex of A. thaliana seedlings. After the phase of activation of autophagy, its regulatory weakening occurs, which probably indicates adaptive changes to the conditions of clinostating. The induction of autophagy correlates with an increase in the expression levels of atg8 genes, some of which (atg8e and atg8i) may be involved in the implementation of autophagy under the microgravity condition. The transcriptional activity of cytoskeleton genes involved in the implementation of stress-induced autophagy, in particular α- and β-tubulin genes, was analyzed. Joint coexpression of α- and β-tubulin genes and atg8 under microgravity conditions was revealed. These results illustrate the role of the cytoskeleton in the development of microgravity-induced autophagy and make it possible to identify genes specific to this type of stress.
The induction of autophagy and PСD was studied under the action of gamma- irradiation as a concomitant microgravity factor of space flights, as well as under the combined action of acute irradiation and clinostating. Gamma-irradiation in doses equivalent to those in the spacecraft cabin (1 - 6 Gy) induced dose-dependent changes in the topology and cytogenetic state of the root apical meristem, as well as slightly inhibited of the early plant development. In the meristem, heterogeneity increased, PCD indexes, mainly proliferative death and autophagy, increased. With the combined action of gamma irradiation (2 Gy) and clinostating, the density of autophagosomes in the epidermal cell root apices of 6-day-old seedlings increased (24 hours after irradiation), and after 4 days it decreased, compared to the non-irradiated control.
Treatment of seeds of A. thaliana with a NO donor had a stimulating effect on plant development, increased the content of endogenous NO in root tissues and the resistance of plants to clinostating. Under clinostating conditions, compared to the control, the optimum concentration of NO decreased, possibly due to the contribution of NO to the generation of ROS. The negative effect of NO scavenger on seedling growth was enhanced by clinostating, including increased accumulation of autophagosomes in epidermal cells. These data indicate that endogenous NO content is an important component of intracellular signaling mechanisms involved in the response of plant cells to simulated microgravity, including autophagy induction mechanisms. The obtained data deepen the understanding of the molecular mechanisms of the development of stress-induced autophagy, in particular the involvement of different isotopes of ATG8 proteins and their interaction with α- and β-tubulins, as well as other molecular components involved in the induction of autophagy, and will be the basis for the development of approaches to increase stress resistance and adaptation of plants to the conditions of long space flights.
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Keywords: adaptation, Arabidopsis thaliana, atg8 genes, autophagy, clinostating, gamma-irradiation, gene expression of α- and β-tubulins, nitric oxide |
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