Respiration-induced weathering patterns of two endolithically growing lichens.

The two endolithic lichen species Hymenelia prevostii and Hymenelia coerulea were investigated with regard to their thallus morphology and their effects on the surrounding substrate. The physiological processes responsible for the observed alterations of the rock were identified. Whereas the thallus surface of H. coerulea was level, H. prevostii formed small depressions that were deepest in the thallus center. In a cross-section, both species revealed an algal zone consisting of algal cavities parallel to the substrate surface and a fungal zone below. However, H. prevostii revealed significantly larger cavities with more than twice the cell number and a denser pattern of cavities than H. coerulea, resulting in a biomass per surface area being more than twice as large. Below H. prevostii the layer of macroscopically visibly altered rock material was about twice as deep and within this layer, the depletion of calcium and manganese was considerably higher. In simultaneous measurements of the oxygen uptake/oxygen release and pH shift, the isolated algal strains of both lichens revealed respiration-induced acidification of the medium in the dark. At higher light intensities, H. coerulea and to a lesser extent also H. prevostii alkalized the medium which may lessen the acidification effect somewhat under natural conditions. In a long-term growth experiment, the isolated algal strains of both lichens revealed acidification of the medium to a similar extent. Neither acidic lichen substances nor oxalic acid was identified. The significant differences between the weathering patterns of both species are based on the same respiration-induced acidification mechanism, with H. prevostii having a greater effect due to its higher biomass per area.

DEWFALL AS A WATER SOURCE FREQUENTLY ACTIVATES THE ENDOLITHIC CYANOBACTERIAL COMMUNITIES IN THE GRANITES OF TAYLOR VALLEY, ANTARCTICA(1).

Endolithic photosynthetic microorganisms like cyanobacteria and algae are well known from savannas and deserts of the world, the high Arctic, and also Antarctic habitats like the Dry Valleys in the Ross Dependency. These endolithic microbial communities are thought to be at the limits of life with reported ages in the order of thousands of years. Here we report on an extensive chasmoendolithic cyanobacterial community inside granite rocks of Mt. Falconer in the lower Taylor Valley, Dry Valleys. On average, the cyanobacterial community was 4.49 ± 0.95 mm below the rock surface, where it formed a blue-green layer. The community was composed mainly of the cyanobacterium Chroococcidiopsis sp., with occasional Cyanothece cf. aeruginosa (Nägeli) Komárek and Nostoc sp. Mean biomass was 168 ± 44 g carbon · m(-2) , and the mean chl a content was 24.3 ± 34.2 mg · m(-2) . In situ chl fluorescence measurements-a relative measure of photosynthetic activity-showed that they were active over long periods each day and also showed activity the next day in the absence of any moisture. Radiocarbon dating gave a relatively young age (175-280 years) for the community. Calculations from microclimate data demonstrated that formation of dew or rime was possible and could frequently activate the cyanobacteria and may explain the younger age of microbial communities at Mt. Falconer compared to older and less active endolithic microorganisms reported earlier from Linnaeus Terrace, a higher altitude region that experiences colder, drier conditions.