Below is from the SOL613 image from Spirit Sept. 26, 2005. A true color image would be from the averaging of 3 with 4
and 4 with 5 if I remember right. I could only use what was provided and then try to adjust it. Filters 2, 5 & 6 were used.
keith phillips
Thiomargarita namibiensis, a giant bacterium discovered off the coast of Namibia, has a repertoire of survivaltechniques that would be the envy of any extremophile. left Light-photomicrograph of three cells of Thiomargarita.
The prokaryote, measuring up to 0.75 mm wide, is 100 times larger than
its nearest competitor in the bacterial size contest. An international
team of biologists were stunned to discover the organism while studying
the sediments in the coastal waters of Namibia. The "Sulfur Pearl
of
Namibia" has adapted to an environment low in oxygen and high in
hydrogen sulfide that would be toxic to most life forms.
'When I told them, my colleagues at first didn't believe me because the bacteria were so big. But I've been working with exotic bacteria for a while now and I knew immediately that these were sulfur bacteria,' said Heide Schulz, of the Max Planck Institute for Marine Microbiology. Microscopic analysis revealed that much of the volume of the cell is taken up by a vacuole. The bacteria uses the vacuole to store the nitrates that it uses to oxidize sulfide. The researchers noted that nitrate concentrations within the cell could be up to 10.000 times higher than in the surrounding sea water This combination of the oxidation of sulfide with the reduction of nitrate provides the bacteria with an energy source which is not accessible for most bacteria in the absence of oxygen. The massive vacuole allows Thiomargarita to "hold its breath" until the appropriate nutrients become available.
Dr. Schulz was part of a team of scientists who were looking for two other kinds of sulfur bacteria, Beggiatoa and Thioploca, which they had found off the Pacific coast of South America. Both areas feature the hydrographic similar features, particularly an upsurgence of deep ocean water rich with the nutrients on which phytoplankton and other marine organisms depend. But the scientists found only minor levels of Beggiatoa and Thioploca, but quite a lot of Thiomargarita.
The genetically similar Thioploca and Thiomargarita, have evolved separate adaptations to the same ecological challenge of surviving in the high sulfide environment. While nitrate is found in sea water, it does not penetrate the oxygen-poor, sulfide-rich sediment where these bacteria are found. Thioploca cells form filaments that cling to each other and secrete a sheath of mucous film. This sheath provides a vertical tunnel through the sediment up to the overlying water, allowing the Thioploca filaments to 'commute' between their food source and the nitrate they need to metabolize it. Thiomargarita, in contrast, do not commute. Rather, they form strands of single, unattached cells evenly separated by a mucous sheath, and wait for nutrients to pass by.
The discovery of these organisms should stimulate research into the origins of life on planet Earth. The biosphere depends on the constant recycling of key elements including carbon, nitrogen, and sulfur. Microorganisms are major contributors to this recycling as they facilitate reduction and oxidation. This turn facilitates the transfer of elements to the oceans, sediments, and atmosphere, and to other organisms.
The appetite of these bacteria for sulfide and nitrate also suggest another role for them. It might be possible to utilize the bacteria to remediate coastal waters polluted by excess nitrates from agricultural runoff.
The research appears in the April 16, 1999 issue of Science."