Snatching Sundews-Analysis of Tentacle Movement in Two Species of in Terms of Response Rate, Response Time, and Speed of Movement

Overview

Journal Plants (Basel)

Date 2022 Dec 11

PMID 36501252

Authors

Caroline Ivesic

Wolfram Adlassnig

Marianne Koller-Peroutka

Linda Kress

Ingeborg Lang

Affiliations

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Abstract

, Droseraceae, catch prey with sticky tentacles. Both Australian and widespread show three types of anatomically different tentacles: short, peripheral, and snap-tentacles. The latter two are capable of fast movement. This motion was analysed after mechanical, chemical, and electrical stimulation with respect to response rate, response time, and angular velocity of bending. Compared to , responds more frequently and faster; the tentacles bend with higher angular velocity. Snap-tentacles have a lower response rate, shorter response time, and faster angular velocity. The response rates for chemical and electrical stimuli are similar, and higher than the rates for mechanical stimulus. The response time is not dependent on stimulus type. The higher motility in indicates increased dependence on mechanical prey capture, and a reduced role of adhesive mucilage. The same tentacle types are present in both species and show similar motility patterns. The lower response rate of snap-tentacles might be a safety measure against accidental triggering, since the motion of snap-tentacles is irreversible and tissue destructive. Furthermore, tentacles seem to discern stimuli and respond specifically. The established model of stereotypical tentacle movement may not fully explain these observations.

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