Systems-level physiology of the human red blood cell is computed from metabolic and macromolecular mechanisms

Yurkovich, James T.; Yang, Laurence T.; Kim, Jaehyung

doi:10.1101/797258

Cited by 6 publications

(6 citation statements)

References 56 publications

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“…We consider C. reinhardtii PC-model to be a superior version of the basic M-model, as it can be used for simple analyses such as FBA with better accuracy and more utilities. Our PC-model formulation is similar to Yurkovich et al (2019) , adding protein concentrations and enzyme concentrations as variables into the model, which constrains respective reaction fluxes. The total proteome budget has defaulted to 150 mg per gram of dry cell weight (gDW).…”

Section: Resultsmentioning

confidence: 99%

Novel Context-Specific Genome-Scale Modelling Explores the Potential of Chlamydomonas reinhardtii for Synthetic Biology Applications

Yao

Dahal

Yang

2022

Preprint

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Gene expression data of cell cultures is commonly measured in biological and medical studies to understand cellular decision-making in various conditions. Metabolism, affected but not solely determined by the expression, is much more difficult to measure experimentally. Thus, finding a reliable method to predict cell metabolism for given expression data will greatly benefit model-aided metabolic engineering. We have developed such a pipeline that can explore cellular fluxomics from expression data, using only a high-quality genome-scale metabolic model. This is done through two main steps: first, construct a protein-constrained metabolic model by integrating protein and enzyme information into the metabolic model. Secondly, overlay the expression data onto the modified model using a new two-step non-convex and convex optimization formulation, resulting in context-specific models with optionally calibrated rate constants. The resulting model computes proteomes and intracellular flux states that are consistent with the measured transcriptomes. Therefore, it provides detailed cellular insights that are difficult to glean individually from the omic data or metabolic models alone. As a case study, we apply the pipeline to interpret triacylglycerol (TAG) overproduction by Chlamydomonas reinhardtii, using time-course RNA-Seq data. The pipeline allows us to compute C. reinhardtii metabolism under nitrogen deprivation and metabolic shifts after an acetate boost. We also suggest a list of possible bottlenecking proteins that need to be overexpressed to increase the TAG accumulation rate, as well as discussing other TAG-overproduction strategies.

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Section: Resultsmentioning

confidence: 99%

Novel Context-Specific Genome-Scale Modelling Explores the Potential of Chlamydomonas reinhardtii for Synthetic Biology Applications

Yao

Dahal

Yang

2022

Preprint

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“…A modeling approach called metabolism and macromolecular mechanisms (MM) was developed recently for human RBCs. [ 61 ] Unlike ME‐models, the reactions related to transcription and translation are not present in RBC‐MM. In RBC‐MM, proteomic data were used to constrain enzyme abundances, which constrained the reaction fluxes.…”

Section: Measuring and Predicting Proteome Allocation Using Me‐modelsmentioning

confidence: 99%

“…This model simulates metabolism, hemoglobin binding, and the formation and detoxification of ROS. [ 61 ]…”

Section: Measuring and Predicting Proteome Allocation Using Me‐modelsmentioning

confidence: 99%

Synthesizing Systems Biology Knowledge from Omics Using Genome‐Scale Models

Dahal

Yurkovich

et al. 2020

Proteomics

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Omic technologies have enabled the complete readout of the molecular state of a cell at different biological scales. In principle, the combination of multiple omic data types can provide an integrated view of the entire biological system. This integration requires appropriate models in a systems biology approach. Here, genome‐scale models (GEMs) are focused upon as one computational systems biology approach for interpreting and integrating multi‐omic data. GEMs convert the reactions (related to metabolism, transcription, and translation) that occur in an organism to a mathematical formulation that can be modeled using optimization principles. A variety of genome‐scale modeling methods used to interpret multiple omic data types, including genomics, transcriptomics, proteomics, metabolomics, and meta‐omics are reviewed. The ability to interpret omics in the context of biological systems has yielded important findings for human health, environmental biotechnology, bioenergy, and metabolic engineering. The authors find that concurrent with advancements in omic technologies, genome‐scale modeling methods are also expanding to enable better interpretation of omic data. Therefore, continued synthesis of valuable knowledge, through the integration of omic data with GEMs, are expected.

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“…Lately, detailed experimental and computational studies revamped the interest in the erythrocyte 28–35 . Systems biology and omics studies have now elucidated the complexity of the erythrocyte metabolome and proteome, not just by directly measuring thousands of small‐molecule analytes but also by identifying hundreds of enzymes that are harbored within the mature erythrocyte and can theoretically catalyse at least as many reactions 31,36–41 . Thus, there is now a large amount of available data on erythrocyte metabolism to distill out higher‐level insights and translate them into function.…”

Section: Introductionmentioning

confidence: 99%

Erythrocyte metabolism

Chatzinikolaou,

Margaritelis,

Paschalis

et al. 2024

Acta Physiologica

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Our aim is to present an updated overview of the erythrocyte metabolism highlighting its richness and complexity. We have manually collected and connected the available biochemical pathways and integrated them into a functional metabolic map. The focus of this map is on the main biochemical pathways consisting of glycolysis, the pentose phosphate pathway, redox metabolism, oxygen metabolism, purine/nucleoside metabolism, and membrane transport. Other recently emerging pathways are also curated, like the methionine salvage pathway, the glyoxalase system, carnitine metabolism, and the lands cycle, as well as remnants of the carboxylic acid metabolism. An additional goal of this review is to present the dynamics of erythrocyte metabolism, providing key numbers used to perform basic quantitative analyses. By synthesizing experimental and computational data, we conclude that glycolysis, pentose phosphate pathway, and redox metabolism are the foundations of erythrocyte metabolism. Additionally, the erythrocyte can sense oxygen levels and oxidative stress adjusting its mechanics, metabolism, and function. In conclusion, fine‐tuning of erythrocyte metabolism controls one of the most important biological processes, that is, oxygen loading, transport, and delivery.

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Systems-level physiology of the human red blood cell is computed from metabolic and macromolecular mechanisms

Cited by 6 publications

References 56 publications

Novel Context-Specific Genome-Scale Modelling Explores the Potential of Chlamydomonas reinhardtii for Synthetic Biology Applications

Novel Context-Specific Genome-Scale Modelling Explores the Potential of Chlamydomonas reinhardtii for Synthetic Biology Applications

Synthesizing Systems Biology Knowledge from Omics Using Genome‐Scale Models

Erythrocyte metabolism

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