Browsing by Subject "Hot spot"
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Publication Microbial community structure and function is shaped by microhabitat characteristics in soil(2016) Ditterich, Franziska; Kandeler, EllenSoil microorganisms play a key role in degradation processes in soil, such as organic matter decomposition and degradation of xenobiotics. Microbial growth and activity and therefore degradation processes are influenced by different ecological factors, such as substrate availability, pH and temperature. During soil development different microhabitats are formed which differ in their physiochemical properties. There is some evidence that mineral composition is a driver for specific microbial colonization. Thereby, the heterogeneity of soils with differences in mineral composition and substrate availability can lead to a spatial distribution of soil microorganisms. At the soil-litter interface, a biogeochemical hot spot in soil, the abundance and activity of soil microorganisms increases due to high substrate availability, and degradation processes such as pesticide degradation are enhanced. This thesis aimed to clarify the influence of habitat properties on the structure and function of the microbial community in soil. In particular, focus was on mineral-microbe interactions that result from the mineral composition and substrate availability in an artificial soils system. Furthermore this thesis was designed to increase our understanding of the bacterial and fungal roles in pesticide degradation at the soil-litter interface using 4-chloro-2-methylphenoxyacetic acid (MCPA) as a model xenobiotic. These two aspects of the thesis were examined in three studies. The first study focused on the succession of microbial communities and enzyme activities in an artificial soils system with varying mineral composition and substrate availability over a period of 18 months. In the second study a microcosm experiment was used to study the bacterial pathway of MCPA degradation at the soil-litter interface. Over a period of 27 days the succession of bacterial degraders was followed. The third study focused on the degradation of MCPA in soil by nonspecific fungal enzymes, through the addition of fungal laccases as well as litter during 42 days of incubation. Both studies indicated the involvement of fungi in MCPA degradation and the importance of the ecological behavior of different degraders as a function of substrate availability. Results of the first study indicated that the microbial community was affected by mineral properties under high substrate availability and by the availability of beneficial nutrients at the end of incubation when substrate had become limited. The measured enzyme activities provided clear evidence that microbial community structure was driven by nutrient limitation during incubation. In the presence of easily available organic substrates at the beginning of the experiment, the soil microbial community was dominated by copiotrophic bacteria (e.g. Betaproteobacteria), whereas under substrate limitation at the end of incubation, more recalcitrant compounds became important to oligotrophic bacteria (e.g. Acidobacteria), which then became dominant. The results of the second study indicated that the contribution of the potential degraders to degradation of MCPA differed, and this was also seen in the succession of specific bacterial MCPA degraders. Added litter stimulated MCPA degradation due to the availability of litter-derived carbon and induced a two-phase response of fungi. This was seen in the development of pioneer and late stage fungal communities. Both fungal communities were probably involved in MCPA degradation. Therefore, the third study focused on the fungal pathway. These results indicated that the fungal laccases used had no direct influence on degradation and were as efficient as litter in providing additional nutrient sources, increasing MCPA degradation by bacteria and fungi. The observed differences between litter and enzyme addition underscored the observation that the enzyme effect was short-lived and that substrate quality is an important factor in degradation processes. In conclusion, this thesis demonstrated that soil microbial communities and therefore degradation processes are driven by mineral composition as well as substrate availability and quality. In addition, this thesis extends our understanding of degradation processes such as the degradation of xenobiotics, with MCPA as model compound, in soil. The combined insights from all three studies suggest that the use of a simple system such as the artificial soil system can increase our understanding of complex mechanisms such as degradation of pesticides.Publication Microbial regulation of pesticide degradation coupled to carbon turnover in the detritusphere(2015) Pagel, Holger; Streck, ThiloMany soil functions, such as nutrient cycling or pesticide degradation, are controlled by microorganisms. Dynamics of microbial populations and biogeochemical cycling in soil are largely determined by the availability of carbon (C). The detritusphere is a microbial “hot spot” of C turnover. It is characterized by a concentration gradient of C from litter (high) into the adjacent soil (lower). Therefore, this microhabitat is very well suited to investigate the influence of C availability on microbial turnover. My thesis aimed at the improved understanding of biochemical interactions involved in the degradation of the herbicide 4-chloro-2-methylphenoxyacetic acid (MCPA) coupled to C turnover. In the detritusphere gradients of organic matter turnover from litter into the adjacent soil could be identified. Increased C availability, due to the transport of dissolved organic substances from litter into soil, resulted in the boost of microbial biomass and activity as well as in the acceleration of MCPA degradation. Fungi and bacterial MCPA-degraders benefited most from litter-C input. Accelerated MCPA degradation was accompanied by increased incorporation of MCPA-C into soil organic matter. The experimental results show that the transport of dissolved organic substances from litter regulates C availability, microbial activity and finally MCPA degradation in the detritusphere. In general, litter-derived organic compounds provide energy and resources for microorganisms. The following possible regulation mechanisms were identified: i) Litter might directly supply the co-substrate alpha-ketoglutarate (or surrogates) required for enzymatic oxidation of MCPA by bacterial MCPA degraders. Alternatively it might provide additional energy and resources for production and regeneration of the needed co-substrate. ii) Additional litter-C might alleviate substrate limitation of enzyme production by bacteria and bacterial consortia resulting in an increased activity of specific enzymes attacking MCPA. iii) Litter-derived organic substances might stimulate MCPA degradation via fungal co-metabolism by unspecific extracellular enzymes, either directly by inducing enzyme production, or by supplying primary substrates that provide the energy consumed by co-metabolic MCPA transformation. A new biogeochemical model abstracts these regulation mechanisms in such a way that C availability controls physiological activity, growth, death and maintenance of microbial pools. Based on a global sensitivity analysis, 41% (n=33) of all considered parameters and input values were classified as “very important” and “important”. These mainly include biokinetic parameters and initial values. The calibration of the model allowed to validate the implemented regulation mechanisms of accelerated MCPA degradation. The Pareto-analysis showed that the model structure was adequate and the identified parameter values were reasonable to reproduce the observed dynamics of C and MCPA. The model satisfactorily matched observed abundances of gene-markers of total bacteria and specific MCPA degraders. However, it underestimated the steep increase of fungal ITS fragments, most probably because this gene-marker is only inadequately suited as a measure of fungal biomass. The model simulations indicate that soil fungi primarily benefit from low-quality C, whereas bacterial MCPA-degraders preferentially use high-quality C. According to the simulations, MCPA was predominantly transformed via co-metabolism to high-quality C. Subsequently, this C was primarily assimilated by bacterial MCPA-degraders. The highest turnover of litter-derived C occurred by substrate uptake for microbial growth. Input and microbial turnover of litter-C stimulated MCPA degradation mainly in a soil layer at 0-3 mm distance to litter. As a consequence of this, a concentration gradient of MCPA formed, which triggered the diffusive upward transport of MCPA from deeper soil layers into the detritusphere. The results of the three studies suggest: The detritusphere is a biogeochemical hot spot where microbial dynamics control matter cycling. The integrated use of experiments and mathematical modelling gives detailed insight into matter cycling and dynamics of microorganisms in soil. Microbial communities need to be explicitly considered to understand the regulation of soil functions.