| Title | Leaf functional and micro- morphological photoprotective attributes in two ecotypes of Colobanthus quitensis from the Andes and maritime Antarctic |
| Author | Bascuñán-Godoy, L.; García-Plazaola, J.I.; Bravo, L.A.; Corcuera, L.J. |
| Author Affil | Bascuñán-Godoy, L., Universidad de Concepción, Departamento de Botánica, Concepcion, Chile. Other: Universidad de País Vasco, Spain |
| Source | Polar Biology, 33(7), p.885-896, . Publisher: Springer-Verlag, Berlin, Federal Republic of Germany. ISSN: 0722- 4060 |
| Publication Date | July 2010 |
| Notes | In English. Based on Publisher- supplied data Ant. Acc. No: 88693. GeoRef Acc. No: 300464 |
| Index Terms | ecology; plant ecology; temperature; vegetation; Andes; Antarctica; Chile; biochemistry; cold adaptation; low temperature; Plantae; plasticity; South America |
| Abstract | Colobanthus quitensis (Kunth) Bartl. (Cariophyllaceae) is distributed from Mexico to the Maritime Antarctic. It grows forming inconspicuous populations in humid and cold sites along high elevations in the Andes Mountains. Mediterranean Andes is characterized by a wider oscillation of diurnal and seasonal temperature, while the Maritime Antarctic is characterized by permanent low temperatures. Both places may experience high irradiance during sunny days (reaching up to 2,000 µmol photons m-2 s-1); however, the frequency of sunny days in the Maritime Antarctica is significantly lower (less than 20% of the whole growing season). We study whether acclimation to each environment relies on different photoprotective mechanisms. The Andean ecotype that has a longer growing season and a higher light integral reduces light absorption by the development of smaller chloroplasts with lower stacking granum area and down-regulation of Lhcb2. It also enhances the dissipation of the excess of absorbed energy by higher level of de- epoxidation of xanthophylls pool. On the other hand, the Antarctic ecotype which has developed under a shorter growing season, with lower total irradiance and continuous low temperatures, maximizes photochemical process even at low temperatures and it has a lower light-harvesting/core complex ratio and higher level of photoprotection supplied by an unusually high beta -carotene and xanthophylls cycle pool. It resembles a well full light acclimated plant, probably due to higher excitation pressure imposed by lower temperature even at moderate irradiance. It is suggested that the biochemical plasticity of this species, highlighted by the development of these different strategies, is essential to cope successfully with these particular environments. |
| URL | http://hdl.handle.net/10.1007/s00300-010-0765-4 |
| Publication Type | journal article |
| Record ID | 64005121 |