Metabolomics and modelling approaches for systems metabolic engineering
Metabolic engineering involves the manipulation of microbes to produce desirable compounds through genetic engineering or synthetic biology approaches. Metabolomics involves the quantitation of intracellular and extracellular metabolites, where mass spectrometry and nuclear magnetic resonance based...
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sg-ntu-dr.10356-1648582023-02-28T17:14:14Z Metabolomics and modelling approaches for systems metabolic engineering Khanijou, Jasmeet Kaur Kulyk, Hanna Bergès, Cécilia Khoo, Leng Wei Ng, Pnelope Yeo, Hock Chuan Helmy, Mohamed Bellvert, Floriant Chew, Wee Selvarajoo, Kumar School of Biological Sciences Singapore Institute of Food and Biotechnology Innovation (SIFBI), A*STAR Bioinformatics Institute (BII), A*STAR National University of Singapore Science::Biological sciences Quantitative Metabolomics Dynamic Metabolomics Metabolic engineering involves the manipulation of microbes to produce desirable compounds through genetic engineering or synthetic biology approaches. Metabolomics involves the quantitation of intracellular and extracellular metabolites, where mass spectrometry and nuclear magnetic resonance based analytical instrumentation are often used. Here, the experimental designs, sample preparations, metabolite quenching and extraction are essential to the quantitative metabolomics workflow. The resultant metabolomics data can then be used with computational modelling approaches, such as kinetic and constraint-based modelling, to better understand underlying mechanisms and bottlenecks in the synthesis of desired compounds, thereby accelerating research through systems metabolic engineering. Constraint-based models, such as genome scale models, have been used successfully to enhance the yield of desired compounds from engineered microbes, however, unlike kinetic or dynamic models, constraint-based models do not incorporate regulatory effects. Nevertheless, the lack of time-series metabolomic data generation has hindered the usefulness of dynamic models till today. In this review, we show that improvements in automation, dynamic real-time analysis and high throughput workflows can drive the generation of more quality data for dynamic models through time-series metabolomics data generation. Spatial metabolomics also has the potential to be used as a complementary approach to conventional metabolomics, as it provides information on the localization of metabolites. However, more effort must be undertaken to identify metabolites from spatial metabolomics data derived through imaging mass spectrometry, where machine learning approaches could prove useful. On the other hand, single-cell metabolomics has also seen rapid growth, where understanding cell-cell heterogeneity can provide more insights into efficient metabolic engineering of microbes. Moving forward, with potential improvements in automation, dynamic real-time analysis, high throughput workflows, and spatial metabolomics, more data can be produced and studied using machine learning algorithms, in conjunction with dynamic models, to generate qualitative and quantitative predictions to advance metabolic engineering efforts. National Research Foundation (NRF) Published version This work was supported by the Intra-create Thematic Grant “Cities” (grant number: NRF2019-THE001-0007). 2023-02-20T07:57:42Z 2023-02-20T07:57:42Z 2022 Journal Article Khanijou, J. K., Kulyk, H., Bergès, C., Khoo, L. W., Ng, P., Yeo, H. C., Helmy, M., Bellvert, F., Chew, W. & Selvarajoo, K. (2022). Metabolomics and modelling approaches for systems metabolic engineering. Metabolic Engineering Communications, 15, e00209-. https://dx.doi.org/10.1016/j.mec.2022.e00209 2214-0301 https://hdl.handle.net/10356/164858 10.1016/j.mec.2022.e00209 36281261 2-s2.0-85140139739 15 e00209 en NRF2019-THE001-0007 Metabolic Engineering Communications © 2022 The Authors. Published by Elsevier B.V. on behalf of International Metabolic Engineering Society. This is an open access article under the CC BY-NC-ND license (http://creativecommons.org/licenses/by-nc-nd/4.0/). application/pdf |
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Science::Biological sciences Quantitative Metabolomics Dynamic Metabolomics Khanijou, Jasmeet Kaur Kulyk, Hanna Bergès, Cécilia Khoo, Leng Wei Ng, Pnelope Yeo, Hock Chuan Helmy, Mohamed Bellvert, Floriant Chew, Wee Selvarajoo, Kumar Metabolomics and modelling approaches for systems metabolic engineering |
| description |
Metabolic engineering involves the manipulation of microbes to produce desirable compounds through genetic engineering or synthetic biology approaches. Metabolomics involves the quantitation of intracellular and extracellular metabolites, where mass spectrometry and nuclear magnetic resonance based analytical instrumentation are often used. Here, the experimental designs, sample preparations, metabolite quenching and extraction are essential to the quantitative metabolomics workflow. The resultant metabolomics data can then be used with computational modelling approaches, such as kinetic and constraint-based modelling, to better understand underlying mechanisms and bottlenecks in the synthesis of desired compounds, thereby accelerating research through systems metabolic engineering. Constraint-based models, such as genome scale models, have been used successfully to enhance the yield of desired compounds from engineered microbes, however, unlike kinetic or dynamic models, constraint-based models do not incorporate regulatory effects. Nevertheless, the lack of time-series metabolomic data generation has hindered the usefulness of dynamic models till today. In this review, we show that improvements in automation, dynamic real-time analysis and high throughput workflows can drive the generation of more quality data for dynamic models through time-series metabolomics data generation. Spatial metabolomics also has the potential to be used as a complementary approach to conventional metabolomics, as it provides information on the localization of metabolites. However, more effort must be undertaken to identify metabolites from spatial metabolomics data derived through imaging mass spectrometry, where machine learning approaches could prove useful. On the other hand, single-cell metabolomics has also seen rapid growth, where understanding cell-cell heterogeneity can provide more insights into efficient metabolic engineering of microbes. Moving forward, with potential improvements in automation, dynamic real-time analysis, high throughput workflows, and spatial metabolomics, more data can be produced and studied using machine learning algorithms, in conjunction with dynamic models, to generate qualitative and quantitative predictions to advance metabolic engineering efforts. |
| author2 |
School of Biological Sciences |
| author_facet |
School of Biological Sciences Khanijou, Jasmeet Kaur Kulyk, Hanna Bergès, Cécilia Khoo, Leng Wei Ng, Pnelope Yeo, Hock Chuan Helmy, Mohamed Bellvert, Floriant Chew, Wee Selvarajoo, Kumar |
| format |
Article |
| author |
Khanijou, Jasmeet Kaur Kulyk, Hanna Bergès, Cécilia Khoo, Leng Wei Ng, Pnelope Yeo, Hock Chuan Helmy, Mohamed Bellvert, Floriant Chew, Wee Selvarajoo, Kumar |
| author_sort |
Khanijou, Jasmeet Kaur |
| title |
Metabolomics and modelling approaches for systems metabolic engineering |
| title_short |
Metabolomics and modelling approaches for systems metabolic engineering |
| title_full |
Metabolomics and modelling approaches for systems metabolic engineering |
| title_fullStr |
Metabolomics and modelling approaches for systems metabolic engineering |
| title_full_unstemmed |
Metabolomics and modelling approaches for systems metabolic engineering |
| title_sort |
metabolomics and modelling approaches for systems metabolic engineering |
| publishDate |
2023 |
| url |
https://hdl.handle.net/10356/164858 |
| _version_ |
1759855217621336064 |