Abstract
ABSTRACTPolyhydroxyalkanoates (PHAs) are polyesters produced by numerous microorganisms for energy and carbon storage. Simultaneous synthesis and degradation of PHA drives a dynamic cycle linked to the central carbon metabolism, which modulates numerous and diverse bacterial processes, such as stress endurance, pathogenesis, and persistence. Here, we analyze the role of the PHA cycle in conferring robustness to the model bacterium P. putida KT2440. To assess the effect of this cycle in the cell, we began by constructing a PHA depolymerase (PhaZ) mutant strain that had its PHA cycle blocked. We then restored the flux through the cycle in the context of an engineered library of P. putida strains harboring differential levels of PhaZ. High-throughput phenotyping analyses of this collection of strains revealed significant changes in response to PHA cycle performance impacting cell number and size, PHA accumulation, and production of extracellular (R)-hydroxyalkanoic acids. To understand the metabolic changes at the system level due to PHA turnover, we contextualized these physiological data using the genome-scale metabolic model iJN1411. Model-based predictions suggest successive metabolic steady states during the growth curve and an important carbon flux rerouting driven by the activity of the PHA cycle. Overall, we demonstrate that modulating the activity of the PHA cycle gives us control over the carbon metabolism of P. putida, which in turn will give us the ability to tailor cellular mechanisms driving stress tolerance, e.g., defenses against oxidative stress, and any potential biotechnological applications.
Highlights
Polyhydroxyalkanoates (PHAs) are polyesters produced by numerous microorganisms for energy and carbon storage
Pseudomonas putida is a paradigm of the “cosmopolitan bacterium” that is well-known for its robust metabolism and stress resilience [13,14,15]
To study the effect of a defective PHA cycle on the physiology of P. putida, we started by constructing a host strain that was missing the PhaZ depolymerase-encoding gene and was unable to hydrolyze PHA
Summary
Polyhydroxyalkanoates (PHAs) are polyesters produced by numerous microorganisms for energy and carbon storage. Most of these relevant traits of pseudomonads are powered by their primary and accessory metabolisms and are in their core genome, which comprises around 1,000 genes [3,4,5,6,7] Boosted by these exceptional metabolic features, Pseudomonas spp. have emerged as a notable bacterial group, sparking growing interest in fields as diverse as plant and human diseases [8, 9], agriculture, biodegradation, and industrial biotechnology [5, 10, 11]. Despite said interest and the intense scrutiny of Pseudomonas’ metabolism in recent years [4, 12], the molecular basis underpinning dynamic control of their physiology under disturbance conditions remains largely unknown Among this diverse group, Pseudomonas putida is a paradigm of the “cosmopolitan bacterium” that is well-known for its robust metabolism and stress resilience [13,14,15]. KT2440 is a paradigmatic model for production of bioproducts such as bacterial polyesters or polyhydroxyalkanoates (PHAs) [10, 19, 20]
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