Microbial adaptation to fluctuating nutrient and oxygen conditions requires coordinated regulation of metabolic networks to maintain redox homeostasis within physicochemical and energetic constraints. While oxygen-dependent responses in Propionibacterium freudenreichii (PFR) have been characterized at the transcriptomic level, the role of carbon source in defining system-level metabolic states remains unclear. Here, we investigated carbon source-dependent metabolic reprogramming and cofactor biosynthesis in PFR strain DSM 20271T using label-free quantitative proteomics integrated with physiological and metabolite analyses. Distinct carbon sources defined discrete metabolic states shaped by redox balance and flux distribution. Lactate supported a comparatively balanced physiological state characterized by enhanced respiratory metabolism, amino acid biosynthesis, and riboflavin metabolism, enabling high specific vitamin B12 yields (~100 g g-1 wet biomass). In contrast, hexose metabolism (glucose and fructose) imposed a redox-constrained state marked by upregulation of transport systems, glycolysis, and the pentose phosphate pathway, resulting in increased biomass but reduced biosynthetic efficiency. A defining feature of the hexose-driven state was activation of aspartate metabolism. Proteomic and metabolite data, together with functional assays, support a model in which aspartate is converted to fumarate and subsequently reduced to succinate, providing an alternative electron sink that facilitates NADH reoxidation under redox-constrained conditions. Together, these findings establish that carbon source shapes physiological state through flux distribution, redox homeostasis, and resource allocation, with cofactor biosynthesis emerging as a system-level property rather than a simple consequence of biosynthetic enzyme abundance.
Savijoki, K., Chamlagain, B., Edelmann, M., Hiippala, K., Deptula, P., Kariluoto, S. A., Nyman, T. A., Piironen, V., Varmanen, P.
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