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First published online January 5, 2005
Journal of Experimental Biology 208, 383-390 (2005)
Published by The Company of Biologists 2005
doi: 10.1242/jeb.01394

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Redox signaling in colonial hydroids: many pathways for peroxide

Neil W. Blackstone^*, Matthew J. Bivins, Kimberly S. Cherry, Robert E. Fletcher and Gabrielle C. Geddes

Department of Biological Sciences, Northern Illinois University, DeKalb, IL 60115 USA

^* Author for correspndence (e-mail: neilb{at}niu.edu)

Accepted 15 November 2004

Studies of mitochondrial redox signaling predict that the colonial hydroids Eirene viridula and Podocoryna carnea should respond to manipulations of reactive oxygen species (ROS). Both species encrust surfaces with feeding polyps connected by networks of stolons; P. carnea is more `sheet-like' with closely spaced polyps and short stolons, while E. viridula is more `runner-like' with widely spaced polyps and long stolons. Treatment with the chemical antioxidant vitamin C diminishes ROS in mitochondrion-rich epitheliomuscular cells (EMCs) and produces phenotypic effects (sheet-like growth) similar to uncouplers of oxidative phosphorylation. In peripheral stolon tips, treatment with vitamin C triggers a dramatic increase of ROS that is followed by tissue death and stolon regression. The enzymatic anti-oxidant catalase is probably not taken up by the colony but, rather, converts hydrogen peroxide in the medium to water and oxygen. Exogenous catalase does not affect ROS in mitochondrion-rich EMCs, but does increase the amounts of ROS emitted from peripheral stolons, resulting in rapid, runner-like growth. Treatment with exogenous hydrogen peroxide increases ROS levels in stolon tips and results in somewhat faster colony growth. Finally, untreated colonies of E. viridula exhibit higher levels of ROS in stolon tips than untreated colonies of P. carnea. ROS may participate in a number of putative signaling pathways: (1) high levels of ROS may trigger cell and tissue death in peripheral stolon tips; (2) more moderate levels of ROS in stolon tips may trigger outward growth, inhibit branching and, possibly, mediate the redox signaling of mitochondrion-rich EMCs; and (3) ROS may have an extra-colony function, perhaps in suppressing the growth of bacteria.

Key words: anti-oxidant, clonal, cnidarian, colony development, Eirene, evolutionary morphology, hydroid, Podocoryna, Podocoryne, reactive oxygen species, redox signalling

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This article has been cited by other articles:

				K. S. C. Vogt, G. C. Geddes, L. S. Bross, and N. W. Blackstone Physiological characterization of stolon regression in a colonial hydroid J. Exp. Biol., March 1, 2008; 211(5): 731 - 740. [Abstract] [Full Text] [PDF]