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Maximal force characteristics of the Ca(2+)-powered actuator of Vorticella convallaria.

ABSTRACT: The millisecond stalk contraction of the sessile ciliate Vorticella convallaria is powered by energy from Ca(2+) binding to generate contractile forces of ?10 nN. Its contractile organelle, the spasmoneme, generates higher contractile force under increased stall resistances. By applying viscous drag force to contracting V. convallaria in a microfluidic channel, we observed that the mechanical force and work of the spasmoneme depended on the stalk length, i.e., the maximum tension (150-350 nN) and work linearly depended on the stalk length (?2.5 nN and ?30 fJ per 1 ?m of the stalk). This stalk-length dependency suggests that motor units of the spasmoneme may be organized in such a way that the mechanical force and work of each unit cumulate in series along the spasmoneme.

SUBMITTER: Ryu S 

PROVIDER: S-EPMC3433611 | biostudies-literature | 2012 Sep

REPOSITORIES: biostudies-literature

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Maximal force characteristics of the Ca(2+)-powered actuator of Vorticella convallaria.

Ryu Sangjin S   Lang Matthew J MJ   Matsudaira Paul P  

Biophysical journal 20120901 5

The millisecond stalk contraction of the sessile ciliate Vorticella convallaria is powered by energy from Ca(2+) binding to generate contractile forces of ∼10 nN. Its contractile organelle, the spasmoneme, generates higher contractile force under increased stall resistances. By applying viscous drag force to contracting V. convallaria in a microfluidic channel, we observed that the mechanical force and work of the spasmoneme depended on the stalk length, i.e., the maximum tension (150-350 nN) an  ...[more]

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