Steinn Guđmundsson scite author profile

Photosynthesis has recently gained considerable attention for its potential role in the development of renewable energy sources. Optimizing photosynthetic organisms for biomass or biofuel production will therefore require a systems understanding of photosynthetic processes. We reconstructed a high-quality genome-scale metabolic network for Synechocystis sp. PCC6803 that describes key photosynthetic processes in mechanistic detail. We performed an exhaustive in silico analysis of the reconstructed photosynthetic process under different light and inorganic carbon (Ci) conditions as well as under genetic perturbations. Our key results include the following. (i) We identified two main states of the photosynthetic apparatus: a Ci-limited state and a light-limited state. (ii) We discovered nine alternative electron flow pathways that assist the photosynthetic linear electron flow in optimizing the photosynthesis performance. (iii) A high degree of cooperativity between alternative pathways was found to be critical for optimal autotrophic metabolism. Although pathways with high photosynthetic yield exist for optimizing growth under suboptimal light conditions, pathways with low photosynthetic yield guarantee optimal growth under excessive light or Ci limitation. (iv) Photorespiration was found to be essential for the optimal photosynthetic process, clarifying its role in high-light acclimation. Finally, (v) an extremely high photosynthetic robustness drives the optimal autotrophic metabolism at the expense of metabolic versatility and robustness. The results and modeling approach presented here may promote a better understanding of the photosynthetic process. They can also guide bioengineering projects toward optimal biofuel production in photosynthetic organisms.constraint-based modeling | photobioenergetic | metabolic engineering | biosustainability | metabolic robustness T he recent emphasis on biosustainability has brought attention to photosynthetic microorganisms. Microphototrophs, including cyanobacteria, represent efficient biological systems for producing biomass from inorganic carbon (Ci) and high-value products such as carotenoids, and they are also viewed as a potential source of biofuel (1, 2). On the other hand, photosynthesis is an inherently inefficient process, and photoautotrophic growth is limited by environmental perturbations (3). The success of future light-driven bioengineering approaches requires a systems understanding of the photosynthetic processes, including their bioenergetics and robustness.Optimal photosynthetic performance requires fine-tuning the light/energy conversion by the photosystems and metabolic reactions, with the ATP/NADPH ratio being a particularly important parameter (4, 5). Carbon dioxide (CO 2 ) fixation through the Calvin cycle is the main ATP and NADPH sink in the autotrophic metabolism, requiring an ATP/NADPH ratio of 1.5. Because the photosynthetic linear electron flow (LEF) pathway generates an ATP/NADPH ratio of 1.28, additional ATP is needed (4, 5). Phototrophs have...

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Computationally efficient flux variability analysis

Guđmundsson

2010

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BackgroundFlux variability analysis is often used to determine robustness of metabolic models in various simulation conditions. However, its use has been somehow limited by the long computation time compared to other constraint-based modeling methods.ResultsWe present an open source implementation of flux variability analysis called fastFVA. This efficient implementation makes large-scale flux variability analysis feasible and tractable allowing more complex biological questions regarding network flexibility and robustness to be addressed.ConclusionsNetworks involving thousands of biochemical reactions can be analyzed within seconds, greatly expanding the utility of flux variability analysis in systems biology.

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High‐quality genome‐scale metabolic modelling of Pseudomonas putida highlights its broad metabolic capabilities

Nogales

Mueller

Guđmundsson

et al. 2019

Environmental Microbiology

149

138

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Genome-scale reconstructions of metabolism are computational species-specific knowledge bases able to compute systemic metabolic properties. We present a comprehensive and validated reconstruction of the biotechnologically relevant bacterium Pseudomonas putida KT2440 that greatly expands computable predictions of its metabolic states. The reconstruction represents a significant reactome expansion over available reconstructed bacterial metabolic networks. Specifically, iJN1462 (i) incorporates several hundred additional genes and associated reactions resulting in new predictive capabilities, including new nutrients supporting growth; (ii) was validated by in vivo growth screens that included previously untested carbon (48) and nitrogen (41) sources; (iii) yielded gene essentiality predictions showing large accuracy when compared with a knockout library and Bar-seq data; and (iv) allowed mapping of its network to 82 P. putida sequenced strains revealing functional core that reflect the large metabolic versatility of this species, including aromatic compounds derived from lignin. Thus, this study provides a thoroughly updated metabolic reconstruction and new computable phenotypes for P. putida, which can be leveraged as a first step toward understanding the pan metabolic capabilities of Pseudomonas.

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Reliability of quantitative EEG features

Guđmundsson

Rúnarsson

Sigurðsson

et al. 2007

Clinical Neurophysiology

179

106

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Support vector machines and dynamic time warping for time series

Guđmundsson

Rúnarsson

Sigurðsson

2008

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