TY - JOUR
T1 - Incorporating dormancy in dynamic microbial community models
AU - Stolpovksy, K.
AU - Martinez-Lavanchy, P.
AU - Heipieper, H.J.
AU - Van Cappellen, P.
AU - Thullner, M.
PY - 2011
Y1 - 2011
N2 - Biogeochemical activity in natural and engineered systems depends on the abundances, functional capabilities
and physiological states of the indigenous microorganisms. Typically, only a fraction of the
microbial population is active at any given time. As environmental conditions change, previously active
microorganisms may switch to an inactive or dormant state, while dormant ones may become active.
Here, we present an extended modeling concept for the growth and decay of microorganisms that explicitly
accounts for their ability to switch between active and dormant states. The equations describing the
switching between physiological states are implemented into a biogeochemical reaction simulator. The
model was used to reproduce published data from two laboratory experiments in which microorganisms
were subjected to intermittent substrate supply or reactivated after a prolonged period of starvation.
Parameter values obtained from the simulation of these experiments were used for subsequent sensitivity
analyses and for the simulation of hypothetical scenarios. Results for hypothetical microbial
communities consisting of two competing species exposed to periodic feeding imply that, under certain
conditions, an effective dormancy-reactivation strategy may have a competitive advantage over a
fast growth strategy. That is, organisms that can switch rapidly in response to fluctuations in external
conditions may outcompete fast-growing organisms. Furthermore, certain combinations of growth and
dormancy strategies may lead to the long-term coexistence of the two competing species. Overall, the
simulated population dynamics show that dormancy is an important feature of microbial communities,
which can lead to complex responses to environmental fluctuations.
AB - Biogeochemical activity in natural and engineered systems depends on the abundances, functional capabilities
and physiological states of the indigenous microorganisms. Typically, only a fraction of the
microbial population is active at any given time. As environmental conditions change, previously active
microorganisms may switch to an inactive or dormant state, while dormant ones may become active.
Here, we present an extended modeling concept for the growth and decay of microorganisms that explicitly
accounts for their ability to switch between active and dormant states. The equations describing the
switching between physiological states are implemented into a biogeochemical reaction simulator. The
model was used to reproduce published data from two laboratory experiments in which microorganisms
were subjected to intermittent substrate supply or reactivated after a prolonged period of starvation.
Parameter values obtained from the simulation of these experiments were used for subsequent sensitivity
analyses and for the simulation of hypothetical scenarios. Results for hypothetical microbial
communities consisting of two competing species exposed to periodic feeding imply that, under certain
conditions, an effective dormancy-reactivation strategy may have a competitive advantage over a
fast growth strategy. That is, organisms that can switch rapidly in response to fluctuations in external
conditions may outcompete fast-growing organisms. Furthermore, certain combinations of growth and
dormancy strategies may lead to the long-term coexistence of the two competing species. Overall, the
simulated population dynamics show that dormancy is an important feature of microbial communities,
which can lead to complex responses to environmental fluctuations.
U2 - 10.1016/j.ecolmodel.2011.07.006
DO - 10.1016/j.ecolmodel.2011.07.006
M3 - Article
SN - 0304-3800
VL - 222
SP - 3092
EP - 3102
JO - Ecological Modelling
JF - Ecological Modelling
IS - 17
ER -