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Mechanical factors contributing to the Venus flytrap’s rate-dependent response to stimuli

Saikia, Eashan; Läubli, Nino F; Vogler, Hannes; Rüggeberg, Markus; Herrmann, Hans J; Burgert, Ingo; Burri, Jan T; Nelson, Bradley J; Grossniklaus, Ueli; Wittel, Falk K (2021). Mechanical factors contributing to the Venus flytrap’s rate-dependent response to stimuli. Biomechanics and Modeling in Mechanobiology, 20(6):2287-2297.

Abstract

The sensory hairs of the Venus flytrap (Dionaea muscipula Ellis) detect mechanical stimuli imparted by their prey and fire bursts of electrical signals called action potentials (APs). APs are elicited when the hairs are sufficiently stimulated and two consecutive APs can trigger closure of the trap. Earlier experiments have identified thresholds for the relevant stimulus parameters, namely the angular displacement [Formula: see text] and angular velocity [Formula: see text]. However, these experiments could not trace the deformation of the trigger hair's sensory cells, which are known to transduce the mechanical stimulus. To understand the kinematics at the cellular level, we investigate the role of two relevant mechanical phenomena: viscoelasticity and intercellular fluid transport using a multi-scale numerical model of the sensory hair. We hypothesize that the combined influence of these two phenomena and [Formula: see text] contribute to the flytrap's rate-dependent response to stimuli. In this study, we firstly perform sustained deflection tests on the hair to estimate the viscoelastic material properties of the tissue. Thereafter, through simulations of hair deflection tests at different loading rates, we were able to establish a multi-scale kinematic link between [Formula: see text] and the cell wall stretch [Formula: see text]. Furthermore, we find that the rate at which [Formula: see text] evolves during a stimulus is also proportional to [Formula: see text]. This suggests that mechanosensitive ion channels, expected to be stretch-activated and localized in the plasma membrane of the sensory cells, could be additionally sensitive to the rate at which stretch is applied.

Keywords: Dionaea muscipula; Ion channels; Mechanotransduction; Multi-scale modelling; Sensory hair; Venus flytrap.

Additional indexing

Item Type:Journal Article, refereed, original work
Communities & Collections:07 Faculty of Science > Department of Plant and Microbial Biology
07 Faculty of Science > Zurich-Basel Plant Science Center
Dewey Decimal Classification:580 Plants (Botany)
Scopus Subject Areas:Life Sciences > Biotechnology
Physical Sciences > Modeling and Simulation
Physical Sciences > Mechanical Engineering
Uncontrolled Keywords:Mechanical Engineering, Modelling and Simulation, Biotechnology
Language:English
Date:1 December 2021
Deposited On:11 Oct 2021 07:07
Last Modified:26 Dec 2024 02:35
Publisher:Springer
ISSN:1617-7940
OA Status:Hybrid
Free access at:PubMed ID. An embargo period may apply.
Publisher DOI:https://doi.org/10.1007/s10237-021-01507-8
PubMed ID:34431032
Project Information:
  • Funder: schweizerischer nationalfonds zur förderung der wissenschaftlichen forschung
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  • Funder: schweizerischer nationalfonds zur förderung der wissenschaftlichen forschung
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  • Funder: ETH Zurich
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