Host selection by larvae of a marine insect <span class="italic">Halocladius variabilis</span>: nutritional dependency or escape from predation?

Norah E. Brown; Sean C. Mitchell; David J. Garbary

doi:10.1017/S0025315412001634

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Garbary, David J. Miller, Anthony G. and Scrosati, Ricardo A. 2014. Ascophyllum nodosum and its symbionts: XI. The epiphyte Vertebrata lanosa performs better photosynthetically when attached to Ascophyllum than when alone. ALGAE, Vol. 29, Issue. 4, p. 321.

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Volume 93, Issue 5
August 2013 , pp. 1373-1379

Host selection by larvae of a marine insect Halocladius variabilis: nutritional dependency or escape from predation?

Norah E. Brown ^(a1), Sean C. Mitchell ^(a1) and David J. Garbary ^(a1)

- https://doi.org/10.1017/S0025315412001634
- Published online: 05 December 2012

Abstract

Larvae of the Holarctic marine chironomid, Halocladius variabilis (Staeger), have strong fidelity to the tuft-forming brown alga, Elachista fucicola (Velley) Areschoug, an abundant epiphyte on intertidal fucoids of the North Atlantic. We show that larvae are sufficiently motile to select an algal host in a Petri dish within 3–4 cm, and that larvae show differential behaviour with respect to host selection in the presence or absence of a predator. In the absence of predators 53% of larvae found an algal host within 1 hour; however, after 24 hours, there was no significant difference in host selection. When an isopod predator (Idotea sp.) was present, more larvae found a host within 1 hour (81%) and Elachista was chosen over three of the four other hosts. Furthermore, when larvae were present in Elachista, predator (Carcinus maenus) success was significantly reduced relative to two other algal hosts. The adaptive significance of Elachista as a refuge from predation was confirmed by experiments demonstrating that larval growth with other algal hosts was greater than with Elachista. These experiments suggest that microhabitat selection by larvae of H. variabilis reveals important tradeoffs for growth and predator avoidance.

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COPYRIGHT: © Marine Biological Association of the United Kingdom 2012

Corresponding author

Correspondence should be addressed to: D.J. Garbary, Department of Biology, St Francis Xavier University, Antigonish, Nova Scotia, B2G 2W5, Canada email: dgarbary@gmail.com

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