Gender-related sensitivity of development and growth to real microgravity in<i>Xenopus laevis</i>

Horn, Ernst-Peter; Gabriel, M.

doi:10.1002/jez.1831

Cited by 3 publications

(2 citation statements)

References 55 publications

(82 reference statements)

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“…Responses to altered gravity, from gene expression to morphological aberrations, depend on site (as we have demonstrated earlier) and developmental stage, with different sensitive ''ontogenetic windows'' for each structure [158,159], and sometimes on gender [160]. As a general rule, cells are more sensitive to altered gravity if they are in a nonsteady state-actively cycling, changing their differentiation status, participating in some developmental process, or naturally labile (such as immune cells).…”

Section: Discussionmentioning

confidence: 97%

Behavior of Stem-Like Cells, Precursors for Tissue Regeneration in Urodela, Under Conditions of Microgravity

Grigoryan

Radugina

2019

Stem Cells and Development

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We summarize data from our experiments on stem-like cell-dependent regeneration in amphibians in microgravity. Considering its deleterious effect on many tissues, we asked whether microgravity is compatible with reparative processes, specifically activation and proliferation of source cells. Experiments were conducted using tailed amphibians, which combine profound regenerative capabilities with high robustness, allowing an in vivo study of lens, retina, limb, and tail regeneration in challenging settings of spaceflight. Microgravity promoted stem-like cell proliferation to a varying extent (up to 2-fold), and it seemed to speed up source cell dedifferentiation, as well as sequential differentiation in retina, lens, and limb, leading to formation of bigger and more developed regenerates than in 1g controls. It also promoted proliferation and hypertrophy of Müller glial cells, eliciting a response similar to reactive gliosis. A significant increase in stem-like cell proliferation was mostly beneficial for regeneration and only in rare cases caused moderate tissue growth abnormalities. It is important that microgravity yielded a lasting effect even if applied before operations. We hypothesize on the potential mechanisms of gravity-dependent changes in stem-like cell behavior, including fibroblast growth factor 2 signaling pathway and heat shock proteins, which were affected in our experimental settings. Taken together, our data indicate that microgravity does not disturb the natural regenerative potential of newt stem-like cells, and, depending on the system, even stimulates their dedifferentiation, proliferation, and differentiation. We discuss these data along with publications on mammalian stem cell behavior in vitro and invertebrate regeneration in vivo in microgravity. In vivo data are very scarce and require further research using contemporary methods of cell behavior analysis to elucidate mechanisms of stem cell response to altered gravity. They are relevant for both practical applications, such as managing human reparative responses in spaceflight, and fundamental understanding of stem cell biology.

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Section: Discussionmentioning

confidence: 97%

Behavior of Stem-Like Cells, Precursors for Tissue Regeneration in Urodela, Under Conditions of Microgravity

Grigoryan

Radugina

2019

Stem Cells and Development

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“…The list of environmental factors that have been shown to induce this plasticity is long and growing. Physical factors include temperature (Hayes et al, ; Laurila et al, ; Darrow et al, ), habitat shape (Calich and Wassersug, ), photoperiod (Wright et al, ), water depth (Denver et al, ; Kulkarni et al, ), and gravity (Horn and Gabriel, ). Chemical factors include pH (Cummins, ), salinity (Squires et al, ; Bernabo et al, ), oxygen level (Smith, ), and various pollutants (Diana et al, ; Griffis‐Kyle and Ritchie, ; Sharma and Patiño, ; Zaya et al, ), and pharmaceuticals (Conners et al, ).…”

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confidence: 99%

Caging, but not air deprivation, slows tadpole growth and development in the amphibian Xenopus laevis

Rose

2014

J. Exp. Zool.

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Xenopus laevis tadpoles raised in submerged cages in normoxic water develop more slowly than tadpoles raised with access to air. This study distinguishes between the effects of being caged and being deprived access to air on development and growth. Tadpoles were raised in high and low density control tanks and in cages in the same tank that were either completely submerged or with the top exposed to air. Experiments were repeated with the cages in different positions relative to the air stones and with and without the water flow from air stones supplemented with a pump. Whereas caging tadpoles has a large effect on their development and growth, additionally depriving them of air has a small effect and this effect can be removed by optimizing water flow through the cage. The effect of caging, though significant in this study, is small compared to the variation in growth and developmental rates that is commonly encountered within and among controls in lab studies. Caging effects can also be diminished by optimizing rearing conditions and/or having exceptionally vigorous tadpoles. The effects of air deprivation and caging thus pose less of a problem for experimenting on air-deprived (AD) and air-restored Xenopus tadpoles than their inherent variability in growth and developmental rates and their susceptibility to growth and developmental arrest. Further, the effect of air deprivation in this air-breathing amphibian does not pose a conflict with evolutionary hypotheses for lung loss involving lengthening of the larval period and delay in the onset of air breathing.

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Challenges to the central nervous system during human spaceflight missions to Mars

Clément

Boyle

George

et al. 2020

Journal of Neurophysiology

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Space travel presents a number of environmental challenges to the central nervous system, including changes in gravitational acceleration that alter the terrestrial synergies between perception and action, galactic cosmic radiation that can damage sensitive neurons and structures, and multiple factors (isolation, confinement, altered atmosphere, and mission parameters, including distance from Earth) that can affect cognition and behavior. Travelers to Mars will be exposed to these environmental challenges for up to 3 years, and space-faring nations continue to direct vigorous research investments to help elucidate and mitigate the consequences of these long-duration exposures. This article reviews the findings of more than 50 years of space-related neuroscience research on humans and animals exposed to spaceflight or analogs of spaceflight environments, and projects the implications and the forward work necessary to ensure successful Mars missions. It also reviews fundamental neurophysiology responses that will help us understand and maintain human health and performance on Earth.

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Gender-related sensitivity of development and growth to real microgravity inXenopus laevis

Cited by 3 publications

References 55 publications

Behavior of Stem-Like Cells, Precursors for Tissue Regeneration in Urodela, Under Conditions of Microgravity

Behavior of Stem-Like Cells, Precursors for Tissue Regeneration in Urodela, Under Conditions of Microgravity

Caging, but not air deprivation, slows tadpole growth and development in the amphibian Xenopus laevis

Challenges to the central nervous system during human spaceflight missions to Mars

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