Symbiosis-induced adaptation to oxidative stress
Symbiosis-induced adaptation to oxidative stress
Cnidarians in symbiosis with photosynthetic protists must withstand daily hyperoxic/anoxic transitions within their host cells. Comparative studies between symbiotic (Anemonia viridis) and non-symbiotic (Actinia schmidti) sea anemones show striking differences in their response to oxidative stress. First, the basal expression of SOD is very different. Symbiotic animal cells have a higher isoform diversity (number and classes) and a higher activity than the non-symbiotic cells. Second, the symbiotic animal cells of A. viridis also maintain unaltered basal values for cellular damage when exposed to experimental hyperoxia (100% O(2)) or to experimental thermal stress (elevated temperature +7 degrees C above ambient). Under such conditions, A. schmidti modifies its SOD activity significantly. Electrophoretic patterns diversify, global activities diminish and cell damage biomarkers increase. These data suggest symbiotic cells adapt to stress while non-symbiotic cells remain acutely sensitive. In addition to being toxic, high O(2) partial pressure (P(O(2))) may also constitute a preconditioning step for symbiotic animal cells, leading to an adaptation to the hyperoxic condition and, thus, to oxidative stress. Furthermore, in aposymbiotic animal cells of A. viridis, repression of some animal SOD isoforms is observed. Meanwhile, in cultured symbionts, new activity bands are induced, suggesting that the host might protect its zooxanthellae in hospite. Similar results have been observed in other symbiotic organisms, such as the sea anemone Aiptasia pulchella and the scleractinian coral Stylophora pistillata. Molecular or physical interactions between the two symbiotic partners may explain such variations in SOD activity and might confer oxidative stress tolerance to the animal host.
277-285
Richier, Sophie
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Furla, Paola
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Plantivaux, Amandine
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Merle, Pierre-Laurent
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Allemand, Denis
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January 2005
Richier, Sophie
0fc0b375-6918-4c06-9d6f-229f6c4046ca
Furla, Paola
d3e7b181-371a-4a7a-8749-594e704d10d7
Plantivaux, Amandine
861ed1a3-bcee-4c1a-8871-862aa0958280
Merle, Pierre-Laurent
57d40c27-ef81-4395-9085-541acd320f3a
Allemand, Denis
a9a9145a-9129-4827-83ae-f204d180d945
Richier, Sophie, Furla, Paola, Plantivaux, Amandine, Merle, Pierre-Laurent and Allemand, Denis
(2005)
Symbiosis-induced adaptation to oxidative stress.
Journal of Experimental Biology, 208 (2), .
(doi:10.1242/?jeb.01368).
(PMID:15634847)
Abstract
Cnidarians in symbiosis with photosynthetic protists must withstand daily hyperoxic/anoxic transitions within their host cells. Comparative studies between symbiotic (Anemonia viridis) and non-symbiotic (Actinia schmidti) sea anemones show striking differences in their response to oxidative stress. First, the basal expression of SOD is very different. Symbiotic animal cells have a higher isoform diversity (number and classes) and a higher activity than the non-symbiotic cells. Second, the symbiotic animal cells of A. viridis also maintain unaltered basal values for cellular damage when exposed to experimental hyperoxia (100% O(2)) or to experimental thermal stress (elevated temperature +7 degrees C above ambient). Under such conditions, A. schmidti modifies its SOD activity significantly. Electrophoretic patterns diversify, global activities diminish and cell damage biomarkers increase. These data suggest symbiotic cells adapt to stress while non-symbiotic cells remain acutely sensitive. In addition to being toxic, high O(2) partial pressure (P(O(2))) may also constitute a preconditioning step for symbiotic animal cells, leading to an adaptation to the hyperoxic condition and, thus, to oxidative stress. Furthermore, in aposymbiotic animal cells of A. viridis, repression of some animal SOD isoforms is observed. Meanwhile, in cultured symbionts, new activity bands are induced, suggesting that the host might protect its zooxanthellae in hospite. Similar results have been observed in other symbiotic organisms, such as the sea anemone Aiptasia pulchella and the scleractinian coral Stylophora pistillata. Molecular or physical interactions between the two symbiotic partners may explain such variations in SOD activity and might confer oxidative stress tolerance to the animal host.
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Published date: January 2005
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Environmental
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Local EPrints ID: 341907
URI: http://eprints.soton.ac.uk/id/eprint/341907
ISSN: 0022-0949
PURE UUID: d26e746c-7854-426d-a866-7c62ffa68b97
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Date deposited: 15 Aug 2012 13:00
Last modified: 14 Mar 2024 11:45
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Author:
Sophie Richier
Author:
Paola Furla
Author:
Amandine Plantivaux
Author:
Pierre-Laurent Merle
Author:
Denis Allemand
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