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Abstract
Recent research has shown that the distribution of biogenic nitrogen and sulfur compounds (in particular, N 2 O, DMS and dissolved DMSO) observed in five perennially ice-covered lakes of the McMurdo Dry Valleys, Antarctica, appear to lack obvious biogeochemical explanations. This study examined the hypothesis that the distribution of these compounds resulted from thermodynamic constraints on microbially mediated processes. The thermodynamic favorableness of a number of ecologically important redox reactions in these lakes was assessed using a simplified Nernst equation and mathematically modified E h measurements. Our qualitative analysis revealed that the relative dominance of denitrification and nitrification as formation and loss processes for N 2 O was a complex pattern that was related to the redox conditions present. The results indicate that nitrification was initially the sole pathway for the formation of N 2 O with denitrification being thermodynamically unfavorable. As the redox conditions became less oxic, both denitrification and nitrification were possible. Once complete anoxia occurred, the importance of nitrification decreased considerably and the loss of N 2 O via denitrification became increasingly important. With respect to DMSO, the results indicated that DMSO was thermodynamically unfavorable as an electron acceptor for the respiration of organic material by bacteria in well-oxygenated environments, giving a partial explanation for the relatively elevated levels of DMSO found in many aquatic environments. Overall, the results of this study showed that subtle variations in the redox conditions present provided a plausible explanation for the unusual distributions of biogenic sulfur and nitrogen compounds observed in the lakes of the McMurdo Dry Valleys.
We thank John Lisle, Barbara Vaughn, Valerie Sloane, and Scott Konley for their assistance in the field. We also thank Berry Lyons (Byrd Polar Research Center, Ohio State University), Mike Madigan (Southern Illinois University), and an anonymous reviewer for constructive criticisms of an early version of this manuscript. Logistical support provided through Raytheon Polar Services, Petroleum Helicopters Inc., the U.S. Air Force and New York Air National Guard is gratefully acknowledged. This research has been made possible through funding from the National Science Foundation to JCP (OPP-9815998; OPP-0096250; OPP-0237335; OPP-0085400) and to CMF (Post-doctoral Research Fellowship in Microbial Biology DBI-0074372).
Notes
*Data taken from CitationMilazzo and Carol (1978).
**Data derived from CitationAmend and Shock (2001).
*Data taken from CitationMilazzo and Carol (1978).
**Data taken from CitationWood (1981).
***Data derived from CitationAmend and Shock (2001).