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Appl. Environ. Microbiol., Jun 1995, 2314-2321, Vol 61, No. 6
TL Peeples and RM Kelly
The bioenergetic response of the extremely thermoacidophilic archaeon
Metallosphaera sedula to thermal and nutritional stresses was examined.
Continuous cultures (pH 2.0, 70(deg)C, and dilution rate of 0.05 h(sup-1))
in which the levels of Casamino Acids and ferrous iron in growth media were
reduced by a step change of 25 to 50% resulted in higher levels of several
proteins, including a 62-kDa protein immunologically related to the
molecular chaperone designated thermophilic factor 55 in Sulfolobus
shibatae (J. D. Trent, J. Osipiuk, and T. Pinkau, J. Bacteriol.
172:1478-1484, 1990), on sodium dodecyl sulfate-polyacrylamide gels. The
62-kDa protein was also noted at elevated levels in cells that had been
shifted from 70 to either 80 or 85(deg)C. The proton motive force
((Delta)p), transmembrane pH ((Delta)pH), and membrane potential
((Delta)(psi)) were determined for samples obtained from continuous
cultures (pH 2.0, 70(deg)C, and dilution rate of 0.05 h(sup-1)) and
incubated under nutritionally and/or thermally stressed and unstressed
conditions. At 70(deg)C under optimal growth conditions, M. sedula was
typically found to have a (Delta)p of approximately -190 to -200 mV, the
result of an intracellular pH of 5.4 (extracellular pH, 2.0) and a
(Delta)(psi) of +40 to +50 mV (positive inside). After cells had been
shifted to either 80 or 85(deg)C, (Delta)(psi) decreased to nearly 0 mV and
internal pH approached 4.0 within 4 h of the shift; respiratory activity,
as evidenced by iron speciation in parallel temperature-shifted cultures on
iron pyrite, had ceased by this point. If cultures shifted from 70 to
80(deg)C were shifted back to 70(deg)C after 4 h, cells were able to regain
pyrite oxidation capacity and internal pH increased to nearly normal levels
after 13 h. However, (Delta)(psi) remained close to 0 mV, possibly the
result of enhanced ionic exchange with media upon thermal damage to cell
membranes. Further, when M. sedula was subjected to an intermediate
temperature shift from 73 to 79(deg)C, an increase in pyrite dissolution
(ferric iron levels doubled) over that of the unshifted control at 73(deg)C
was noted. The improvement in leaching was attributed to the synergistic
effect of chemical and biological factors. As such, periodic exposure to
higher temperatures, followed by a suitable recovery period, may provide a
basis for improving bioleaching rates of acidophilic chemolithotrophs.
Copyright © 1995, American Society for Microbiology
Bioenergetic Response of the Extreme Thermoacidophile Metallosphaera sedula to Thermal and Nutritional Stresses
Department of Chemical Engineering, The Johns Hopkins University, Baltimore, Maryland 21218, and Department of Chemical Engineering, North Carolina State University, Raleigh, North Carolina 27695-7905
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