Morphological determinants of bite force capacity in insects: a biomechanical analysis of polymorphic leaf-cutter ants

Morphological determinants of bite force capacity in insects: a biomechanical analysis of polymorphic leaf-cutter ants

The extraordinary success of social insects is partially based on division of labour, i.e. individuals exclusively or preferentially perform specific tasks. Task preference may correlate with morphological adaptations so implying task specialization, but the extent of such specialization can be diff...

Full description

Saved in:
Bibliographic Details
Published in:Journal of the Royal Society interface 2021-09, Vol.18 (182), p.20210424-20210424
Main Authors: Püffel, Frederik, Pouget, Anaya, Liu, Xinyue, Zuber, Marcus, van de Kamp, Thomas, Roces, Flavio, Labonte, David
Format: Article
Language:eng
Subjects:
Adaptation, Physiological
Animals
Ants
Bite Force
Humans
Life Sciences–Physics interface
Mandible
Plant Leaves
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The extraordinary success of social insects is partially based on division of labour, i.e. individuals exclusively or preferentially perform specific tasks. Task preference may correlate with morphological adaptations so implying task specialization, but the extent of such specialization can be difficult to determine. Here, we demonstrate how the physical foundation of some tasks can be leveraged to quantitatively link morphology and performance. We study the allometry of bite force capacity in leaf-cutter ants, polymorphic insects in which the mechanical processing of plant material is a key aspect of the behavioural portfolio. Through a morphometric analysis of tomographic scans, we show that the bite force capacity of the heaviest colony workers is twice as large as predicted by isometry. This disproportionate 'boost' is predominantly achieved through increased investment in muscle volume; geometrical parameters such as mechanical advantage, fibre length or pennation angle are likely constrained by the need to maintain a constant mandibular opening range. We analyse this preference for an increase in size-specific muscle volume and the adaptations in internal and external head anatomy required to accommodate it with simple geometric and physical models, so providing a quantitative understanding of the functional anatomy of the musculoskeletal bite apparatus in insects.
ISSN:1742-5662
1742-5689
1742-5662