Your search keyword '"M. S. Lemak"' showing total 2 results

1. Adaptive Changes in the Vestibular System of Land Snail to a 30-Day Spaceflight and Readaptation on Return to Earth

Author

Pavel M. Balaban, Aleksey Malyshev, Peter M. Kolosov, T. A. Korshunova, Nikolay Aseyev, Richard Boyle, L. A. Uroshlev, M. S. Lemak, Yekaterina Popova, M. V. Roshchin, Victor N. Ierusalimsky, E. A. Chesnokova, Svetlana Volkova, Ivan A. Novikov, Igor S. Zakharov, Alia Kh. Vinarskaya, Artem S. Kasianov, and Alena B. Zuzina

Subjects

0301 basic medicine, gravitaxis, neuroplasticity, Gravitaxis, Snail, Biology, Spaceflight, lcsh:RC321-571, law.invention, gravity sensing, 03 medical and health sciences, Cellular and Molecular Neuroscience, 0302 clinical medicine, law, biology.animal, lcsh:Neurosciences. Biological psychiatry. Neuropsychiatry, Original Research, Vestibular system, Weightlessness, vestibular system, Land snail, mollusks, Anatomy, Helix lucorum, biology.organism_classification, Statocyst, 030104 developmental biology, statocyst, Neuroscience, 030217 neurology & neurosurgery

Abstract

The vestibular system receives a permanent influence from gravity and reflexively controls equilibrium. If we assume gravity has remained constant during the species' evolution, will its sensory system adapt to abrupt loss of that force? We address this question in the land snail Helix lucorum exposed to 30 days of near weightlessness aboard the Bion-M1 satellite, and studied geotactic behavior of postflight snails, differential gene expressions in statocyst transcriptome, and electrophysiological responses of mechanoreceptors to applied tilts. Each approach revealed plastic changes in the snail's vestibular system assumed in response to spaceflight. Absence of light during the mission also affected statocyst physiology, as revealed by comparison to dark-conditioned control groups. Readaptation to normal tilt responses occurred at ~20 h following return to Earth. Despite the permanence of gravity, the snail responded in a compensatory manner to its loss and readapted once gravity was restored.

Published

2017

2. Functional Changes in the Snail Statocyst System Elicited by Microgravity

Author

Richard Boyle, M. V. Roshchin, Pavel M. Balaban, Yekaterina Popova, Aleksey Malyshev, Victor N. Ierusalimsky, Tania A. Korshunova, Igor S. Zakharov, Nikolay Aseyev, M. S. Lemak, and Natasha I. Bravarenko

Subjects

Central Nervous System, Nervous system, Anatomy and Physiology, Science, Snails, Biophysics, Snail, Biology, Model Organisms, biology.animal, medicine, Animals, FMRFamide, Neurons, Evolutionary Biology, Multidisciplinary, Behavior, Animal, Weightlessness, Systems Biology, Helix (gastropod), Animal Structures, Anatomy, Space Flight, biology.organism_classification, Helix lucorum, Electrophysiological Phenomena, Statocyst, Cell biology, medicine.anatomical_structure, Gene Expression Regulation, Negative gravitaxis, Medicine, Research Article, Neuroscience

Abstract

BackgroundThe mollusk statocyst is a mechanosensing organ detecting the animal's orientation with respect to gravity. This system has clear similarities to its vertebrate counterparts: a weight-lending mass, an epithelial layer containing small supporting cells and the large sensory hair cells, and an output eliciting compensatory body reflexes to perturbations.Methodology/principal findingsIn terrestrial gastropod snail we studied the impact of 16- (Foton M-2) and 12-day (Foton M-3) exposure to microgravity in unmanned orbital missions on: (i) the whole animal behavior (Helix lucorum L.), (ii) the statoreceptor responses to tilt in an isolated neural preparation (Helix lucorum L.), and (iii) the differential expression of the Helix pedal peptide (HPep) and the tetrapeptide FMRFamide genes in neural structures (Helix aspersa L.). Experiments were performed 13-42 hours after return to Earth. Latency of body re-orientation to sudden 90° head-down pitch was significantly reduced in postflight snails indicating an enhanced negative gravitaxis response. Statoreceptor responses to tilt in postflight snails were independent of motion direction, in contrast to a directional preference observed in control animals. Positive relation between tilt velocity and firing rate was observed in both control and postflight snails, but the response magnitude was significantly larger in postflight snails indicating an enhanced sensitivity to acceleration. A significant increase in mRNA expression of the gene encoding HPep, a peptide linked to ciliary beating, in statoreceptors was observed in postflight snails; no differential expression of the gene encoding FMRFamide, a possible neurotransmission modulator, was observed.Conclusions/significanceUpregulation of statocyst function in snails following microgravity exposure parallels that observed in vertebrates suggesting fundamental principles underlie gravi-sensing and the organism's ability to adapt to gravity changes. This simple animal model offers the possibility to describe general subcellular mechanisms of nervous system's response to conditions on Earth and in space.

Published

2011