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1. Building microbial kinetic models for environmental application: A theoretical perspective

   https://doi.org/10.1016/j.apgeochem.2023.105782  

   Jin, Qusheng (November 2023, Applied Geochemistry)

   Kinetic modeling of microbial reactions is a common tool for addressing the central environmental questions of our time, from contaminant remediation to the global carbon cycle. This review presents an overview of trait-based frameworks for modeling the kinetics of microbial reactions, with an emphasis on environmental application. I first highlight two key model assumptions: the simplification of microbial communities as ensembles of microbial functional groups and the description of microbial metabolism at a coarse-grained level with three metabolic reactions – catabolic reaction, biomass synthesis, and maintenance. Next, I aim to establish a connection between microbial rate laws and the mechanisms of metabolic reactions. For metabolic reactions limited by single substrates, the widely used rate law is the Monod equation. However, in cases where substrates are solids or nonaqueous phase liquids (NAPLs), the Contois equation and the Best equation may offer better alternatives. In microbial metabolisms limited by multiple nutrients simultaneously, two competing rate laws exist: the multiplicative rate law and Liebig’s law of the minimum. Then I present two strategies for extending the modeling framework developed for laboratory cultures to natural environments. One strategy follows the multiplicative rate law and incorporates dimensionless functions to account for pH, temperature, salinity, cell density, and other environmental conditions. The other strategy focuses on the physiology of natural microbes, explicitly considering dormancy, biomass decay, and physiological acclimation. After that, I highlight recent improvements enabled by the application of molecular biology tools, ranging from functional gene-based models to metabolic models. Finally, I discuss the inherent limitations of trait-based modeling frameworks and their implications for model development and evaluation, including the gap between functional groups represented in silico and microbial communities found in natural environments, as well as the requirement of internal consistency in microbial parameter sets. 

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2. Selection for toxin production in spatially structured environments increases with growth rate

   https://doi.org/10.1093/ismejo/wraf061  

   Bisesi, Ave T; Chacón, Jeremy M; Smanski, Michael J; Kinkel, Linda; Harcombe, William R (April 2025, The ISME Journal)

   Abstract Microbes adopt a diversity of strategies to successfully compete with coexisting strains for space and resources. One common strategy is the production of toxic compounds to inhibit competitors, but the strength and direction of selection for this strategy varies depending on the environment. Existing theoretical and experimental evidence suggests growth in spatially structured environments makes toxin production more beneficial because competitive interactions are localized. Because higher growth rates reduce the length-scale of interactions in structured environments, theory predicts that toxin production should be especially beneficial under these conditions. We tested this hypothesis by developing a genome-scale metabolic modeling approach and complementing it with comparative genomics to investigate the impact of growth rate on selection for costly toxin production. Our modeling approach expands the current abilities of the dynamic flux balance analysis platform COMETS to incorporate signaling and toxin production. Using this capability, we find that our modeling framework predicts that the strength of selection for toxin production increases as growth rate increases. This finding is supported by comparative genomics analyses that include diverse microbial species. Our work emphasizes that toxin production is more likely to be maintained in rapidly growing, spatially structured communities, thus improving our ability to manage microbial communities and informing natural product discovery. 

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3. Simulated annealing fitting: a global optimization method for quantitatively analyzing growth kinetics of colloidal Ag nanoparticles

   https://doi.org/10.1039/D1NH00152C  

   Wu, Siyu; An, Qinwei; Sun, Yugang (June 2021, Nanoscale Horizons)

   null (Ed.)

   The involvement of heterogeneous solid/liquid reactions in growing colloidal nanoparticles makes it challenging to quantitatively understand the fundamental steps that determine nanoparticles' growth kinetics. A global optimization protocol relying on simulated annealing fitting and the LSW growth model is developed to analyze the evolution data of colloidal silver nanoparticles synthesized from a microwave-assisted polyol reduction reaction. Fitting all data points of the entire growth process determines with high fidelity the diffusion coefficient of precursor species and the heterogeneous reduction reaction rate parameters on growing silver nanoparticles, which represent the principal functions to determine the growth kinetics of colloidal nanoparticles. The availability of quantitative results is critical to understanding the fundamentals of heterogeneous solid/liquid reactions, such as identifying reactive species and reaction activation energy barriers. 

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4. Quantifying microbial energy supplies with the Water-Organic-Rock-Microbe (WORM) Portal (Oral Presentation)

   Boyer, Grayson; Weeks, Katelyn; Robare, Jordyn; Shock, Everett L (July 2025, Goldschmidt 2025 Conference)

   Microbes need energy to grow, reproduce, repair damage, maintain their metabolisms, and interact with their environment. Phototrophic microbes can harness the power of sunlight while chemotrophs derive energy from chemical compounds. Thermodynamic calculations can tell us whether a chemotrophic metabolic reaction will yield energy in an aqueous environment depending on fluid composition, temperature, and pressure. If the calculation reveals that energy is not available for a reaction, the reaction can be ruled out as a viable metabolic strategy in that system. Similarly, energy supplies can be quantified for energy-yielding reactions to generate hypotheses about how chemotrophic microbes harness energy in a system. Because of its usefulness for interpreting chemotroph metabolic strategies, several recent studies have quantified microbial energy supplies in natural systems and growth experiments using free and open-source software tools developed for the Water-Organic-Rock-Microbe (WORM) Portal online computing environment [1, 2, 3, 4]. The WORM Portal is an NSF-funded geochemical modeling platform for researchers, students, and the public that can be accessed for free through an internet browser. The WORM Portal comes pre-packaged with computational Jupyter notebook tools and educational demos covering a variety of topics in geobiology and geochemistry. In this presentation, we will demonstrate how the WORM Portal can be used to quantify microbial energy supplies, chemical affinities, and power (energy over time) in water samples and growth media under ambient conditions and elevated temperatures and pressures, and how you can apply the WORM Portal to quantify energy supplies in your own systems of interest. [1] Alain et al. (2022). Sulfur disproportionation is exergonic in the vicinity of marine hydrothermal vents. Environmental Microbiology, 24(5), 2210-2219. [2] Howells et al. (2025). Energetic and genomic potential for hydrogenotrophic, formatotrophic, and acetoclastic methanogenesis in surface-expressed serpentinized fluids of the Samail Ophiolite. Frontiers in Microbiology, 15, 1523912. [3] Parsons et al. "Hydrothermal Seepage of Altered Crustal Formation Water Seaward of the Middle America Trench, Offshore Costa Rica." Geochemistry, Geophysics, Geosystems 25.1 (2024): e2023GC011246. [4] Rhim et al. (2024). Mode of carbon and energy metabolism shifts lipid composition in the thermoacidophile Acidianus. Applied and Environmental Microbiology, 90(2), e01369-23. 

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5. Technical note: A modified formulation of dynamic energy budget theory for faster computation of biological growth

   https://doi.org/10.5194/bg-22-1809-2025  

   Tang, Jinyun; Riley, William J (January 2025, Biogeosciences)

   Middelburg, Jack (Ed.)

   Abstract. The mass conservation equation in the presence of boundary fluxes and chemical reactions from non-equilibrium thermodynamics is used to derive a modified dynamic energy budget (mDEB) model. Compared to the standard dynamic energy budget (sDEB) model (Kooijman, 2009), this modified formulation does not place the dilution effect in the mobilization kinetics of reserve biomass, and it maintains the partition principle for reserve mobilization dynamics for both linear and non-linear kinetics. Overall, the mDEB model shares most features with the sDEB model. However, for biological growth that requires multiple nutrients, the mDEB model is computationally much more efficient by not requiring numerical iterations for obtaining the specific growth rate. In an example of modeling the growth of Thalassiosira weissflogii in a nitrogen-limiting chemostat, the mDEB model was found to have almost the same accuracy as the sDEB model while requiring almost half of the computing time of the sDEB model. Since the sDEB model has been successfully applied in numerous studies, we believe that the mDEB model can help improve the modeling of biological growth and the associated ecosystem processes in various contexts. 

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