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Appl. Environ. Microbiol., Jun 1997, 2391-2396, Vol 63, No. 6
CJ Han, SH Park and RM Kelly
The response of an extremely thermoacidophilic archaeon, Metallosphaera
sedula (growth temperature range, 50 to 79(deg)C; optimum temperature,
74(deg)C; optimum pH, 2.0), to thermal stress was investigated by using a
10-liter continuous cultivation system. M. sedula, growing at 74(deg)C, pH
2.0, and a dilution rate of 0.04 hr(sup-1), was subjected to both abrupt
and gradual temperature shifts in continuous culture to determine the
responses of cell density levels and protein synthesis patterns. An abrupt
temperature shift from 74 to 79(deg)C resulted in little, if any, changes
in cell density and a small increase in total protein per cell. When the
culture temperature was shifted further to 80.5(deg)C, cell density dropped
to below 5 x 10(sup6) cells/ml from 10(sup8) cells/ml, leading to washout
of the culture. Operation at this temperature and slightly higher
temperatures, however, could be achieved by exposing the culture to thermal
stress more gradually (0.5(deg)C increments). As a result, stable operation
could be maintained at temperatures of up to 81(deg)C, and the washout
temperature could be increased to 82.5(deg)C. Continuous culture operation
at 81(deg)C for 100 h (stressed phase) led to an approximately sevenfold
lower steady-state cell density than that observed for operation at or
below 79(deg)C. However, sodium dodecyl sulfate-polyacrylamide gel
electrophoresis analysis (both one and two dimensional) revealed
significantly higher levels (sixfold increase) of a 66-kDa stress response
protein (MseHSP60), immunologically related to Thermophilic Factor 55 from
Sulfolobus shibatae (J. D. Trent, J. Osipiuk, and T. Pinkau, J. Bacteriol.
172:1478-1484, 1990). If the acclimated culture was returned to a lower
temperature (i.e., 74(deg)C), the amount of MseHSP60 returned to levels
observed prior to thermal acclimation. Furthermore, when the previously
acclimated culture (at 81(deg)C) was shifted back from 74 to 81(deg)C,
without going through gradual acclimation steps, the result was the
immediate onset of washout, suggesting no residual thermotolerance. This
study shows that gradual thermal acclimation of M. sedula could only extend
the temperature range of stable growth for this organism by 2(deg)C above
its maximal growth temperature, albeit at reduced cell densities. Also,
this investigation illustrates the utility of continuous culture for
characterizing heat shock response and assessing maximum growth
temperatures for extremely thermophilic microorganisms.
Copyright © 1997, American Society for Microbiology
Acquired Thermotolerance and Stressed-Phase Growth of the Extremely Thermoacidophilic Archaeon Metallosphaera sedula in Continuous Culture
Department of Chemical Engineering, North Carolina State University, Raleigh, North Carolina 27695-7905
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