Differential thermal adaptation of clonal strains of a protist morphospecies originating from different climatic zones.

Eco-physiological variation and local adaptation are key issues in microbial ecology. Here, we investigated the thermal adaptation of 19 strains of the same Spumella morphospecies (Chrysophyceae, Heterokonta). In order to test for local adaptation and the existence of specific ecotypes we analysed growth rates of these strains, which originated from different climate regions. We applied temperature-adaptation as an eco-physiological marker and analysed growth rates of the different Spumella strains at temperatures between 0 degrees C and 35 degrees C. The temperatures allowing for maximal growth of strains from temperate and warm climatic zones ranged between 19.9 degrees C and 33.4 degrees C. Phylogenetically, most of these 'warm'-adapted strains fall into two different previously defined 18S rDNA Spumella clusters, one of them consisting of mostly soil organisms and the other one being a freshwater cluster. As a rule, the 'warm'-adapted strains of the soil cluster grew slower than the 'warm'-adapted isolates within the freshwater cluster. This difference most probably reflect different strategies, i.e. the formation of cysts at the expense of lower growth rates in soil organisms. In contrast, as expected, all isolates from Antarctica were cold-adapted and grew already around melting point of freshwater. Surprisingly, optimum temperature for these strains was between 11.8 degrees C and 17.7 degrees C and maximum temperature tolerated was between 14.6 degrees C and 23.5 degrees C. Our data indicate that despite the relatively high optimal temperature of most Antarctic strains, they may have a relative advantage below 5-10 degrees C only. Based on the thermal adaptation of the flagellate strains the Antarctic strains were clearly separated from the other investigated strains. This may indicate a limited dispersal of flagellates to and from Antarctica. Even if the latter assumption needs support from more data, we argue that the high levels of eco-physiological and molecular microdiversity indicate that the current species concepts do not sufficiently reflect protist eco-physiological differentiation.

Evidence for geographic isolation and signs of endemism within a protistan morphospecies.

The possible existence of endemism among microorganisms resulting from and preserved by geographic isolation is one of the most controversial topics in microbial ecology. We isolated 31 strains of "Spumella-like" flagellates from remote sampling sites from all continents, including Antarctica. These and another 23 isolates from a former study were characterized morphologically and by small-subunit rRNA gene sequence analysis and tested for the maximum temperature tolerance. Only a minority of the Spumella morpho- and phylotypes from the geographically isolated Antarctic continent follow the worldwide trend of a linear correlation between ambient (air) temperature during strain isolation and heat tolerance of the isolates. A high percentage of the Antarctic isolates, but none of the isolates from locations on all other continents, were obligate psychrophilic, although some of the latter were isolated at low ambient temperatures. The drastic deviation of Antarctic representatives of Spumella from the global trend of temperature adaptation of this morphospecies provides strong evidence for geographic transport restriction of a microorganism; i.e., Antarctic protistan communities are less influenced by transport of protists to and from the Antarctic continent than by local adaptation, a subtle form of endemism.