Geobacter sulfurreducens likely utilized approximately 0.45 moles acetate per mole of cellobiose consumed. Approximately 0.3
moles acetate was modeled as the electron donor producing 0.6 moles CO2 with a minor fraction of the acetate incorporated into biomass. While 4.9 mM fumarate was provided to the tri-culture, 2.23 moles of fumarate were transformed per mole of cellobiose consumed. The 2.23 moles of fumarate were reduced to 1.63 moles of succinate with 0.02 moles of malate also detected. Incomplete NU7026 cell line recovery of the fumarate-malate-succinate couple may be due to some carbon potentially diverted to biomass. G. sulfurreducens was electron acceptor limited as verified by its complete removal of fumarate, and being electron acceptor limited likely facilitated electron equivalents being available for sulfate reduction. However, that limitation was forced by an apparent inhibition of PF-4708671 manufacturer the C. cellulolyticum whenever succinate approached 10 mM in experiments with elevated fumarate levels
(data not shown). The model of the three species community culture accounts for 236 mg per liter biomass corresponding to 5.25 × 108 cells per ml. Based upon PCR amplification ratios and cell counts, nearly 80% of the community was comprised of C. cellulolyticum with minor contributions by G. sulfurreducens and D. vulgaris (Figure 5 and Additional File 1). Biomass was ascribed a molecular weight of 104 g/M based on the C4H7O1.5N + minerals formula with the oxidation of said mole requiring 17 electron equivalents of ~ -0.3 mV as described by Harris and Adams 1979 [48]. Accordingly, mass balance determinations accounted for 93% of the
carbon and 112% of the electrons available to the tri-culture. Conclusions These results demonstrate that C. cellulolyticum, D. vulgaris, and G. sulfurreducens can be grown in coculture in a continuous culture system in which D. vulgaris and G. sulfurreducens are dependent upon the see more metabolic byproducts of C. cellulolyticum for nutrients. Moreover, the overall cell densities achieved and maintained under Verteporfin solubility dmso these conditions were appropriate for observing changes in the cell densities resulting from growth or decline from perturbations of nutrients or by stress conditions. Effective methods have been developed to monitor population dynamics and metabolic fluxes of the coculture. This represents a step towards developing a tractable model ecosystem comprised of members representing the functional groups of a trophic network. Future studies will aim to add additional complexities with the goal of better representing subsurface communities and conditions, as well as responses after perturbing the systems with various stresses (i.e. high salt concentrations, nitrate load, and varying pH conditions) in order to determine how the individual members and the community respond in terms of growth rate and metabolic activity.
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