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Appl. Environ. Microbiol., Aug 1996, 2970-2977, Vol 62, No. 8
M Diaz-Ravina and E Baath
The development of metal tolerance in soil bacterial communities exposed to
different heavy metals was examined under laboratory conditions. An
agricultural soil amended with different Zn concentrations was studied most
intensively, and measurements were made over a 28-month incubation period
by means of the thymidine incorporation technique. Tolerance levels were
not affected by metal concentrations lower than 2 mmol of Zn kg (dry
weight) of soil(sup-1), but above this value, the level of Zn tolerance
increased exponentially with the logarithm of the soil Zn concentration. An
increased metal tolerance was detected after only 2 days of Zn exposure.
Thereafter, stable tolerance values were observed at different sampling
times for bacterial communities exposed to up to 8 mmol of Zn kg (dry
weight)(sup-1), indicating no changes in tolerance with time. The tolerance
of bacterial communities exposed to 32 mmol of Zn kg (dry weight)(sup-1)
increased rapidly within the second week of incubation, but then the values
remained unchanged until the end of the experiment. Bacterial communities
from soil contaminated with 16 mmol of Zn kg (dry weight)(sup-1) showed an
increase of the same magnitude, but the increase started later, after 4
months of incubation, and took place for a much longer period (more than 1
year). Cd, Cu, and Ni addition also resulted in metal-tolerant communities,
and the level of tolerance increased with prolonged incubations of the
soils. The bacterial community at the end of the incubation period also
exhibited a lower pH optimum and an increased tolerance to low osmotic
potential. The results suggest that the increase in metal tolerance of the
community after adding metals can be attributed to an immediate effect due
to the death of sensitive species and a later effect due to different
competitive abilities and adaptation of surviving bacteria.
Copyright © 1996, American Society for Microbiology
Development of Metal Tolerance in Soil Bacterial Communities Exposed to Experimentally Increased Metal Levels
Department of Microbial Ecology, Lund University, S-223 62 Lund, Sweden, and Instituto de Investigaciones Agrobiologicas de Galicia (Consejo Superior de Investigaciones Cientificas), 15080 Santiago de Compostela, Spain
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