Prey finding behavior and mechanosensilla of larval Toxorhynchites brevipalpis Theobald (Diptera : Culicidae)

Abstract

Behavioral experiments demonstrated that starved 3rd-instar Toxorhynchites brevipalpis (Diptera : Culicidae) will attack a glass probe in response to vibrations alone. Frequencies in the range of 80–200 Hz elicited 85% of the attacks. The observation that most attacks occurred while the larva was drifting forward towards the probe, substantiates that the predatory behavior of these organisms is basically opportunistic. The main setae on the thorax and abdomen arise from setal support plates and are of 4 general morphological types: dendritic, smooth, spinulate spiniform, and unbranched aciculate setae. The numbers and lengths of the setae on 3rd- and 4th-instar larvae are given. Each seta is innervated by a bipolar neuron with a tubular body in the dendrite, a characteristic of mechanosensilla. By virtue of their abundance and location, it seems probable that one or more types of these setae sense the water vibrations capable of eliciting an attack response. The tubular bodies of the 4 types of setae are somewhat unusual in that they lack electron-dense material, except near sites of attachment of the microtubules to the dendritic membrane, yet possess a large number of complexly arranged microtubules. Among the setal types, variations were observed in the prominence of microtubular attachment sites, proportion of tubules associated with the sites, and orientation of microtubules. In spinulate spiniform setae, the arrangement of microtubules varies within the same tubular body; peripherally most of the microtubules are in one direction with little convergence and have only one distinct attachment site, whereas medially they converge considerably resulting in 2 groups, each associated with its own well-defined site. The attachment sites, which presumably through linkage with the dendritic membrane provide a means of initiating depolarization, are associated with the distal ends of almost all of the microtubules. This suggests that in these tubular bodies depolarization may be initiated through mechanical force acting along the length of the microtubules, that is, stretching and/or compression.