Combining gene network, metabolic and leaf-level models shows means to future-proof soybean photosynthesis under rising CO2

Kannan, Kavya; Wang, Yu; Lang, Meagan; Challa, Ghana S.; Long, Stephen P.; Marshall‐Colón, Amy

doi:10.1093/insilicoplants/diz008

Cited by 21 publications

(13 citation statements)

References 60 publications

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“…A third area in plant multiscale modeling are models that were developed to explore strategies for engineering plants to achieve specific objectives. For example, a gene regulatory network model, a protein translation model, a mechanistic photosynthesis model, and a leaf-level physiological model were coupled to explore the impacts of genetic modifications to soybean photosynthesis in ambient and elevated CO 2 [33]. The integrated model was used to identify gene regulatory controls of the allocation of resources from Rubisco to RuBP regeneration, which has been shown to improve photosynthesis under elevated CO 2 .…”

Section: Multiscale Models For Plant Engineeringmentioning

confidence: 99%

“…The yggdrasil framework [50] is an Open source Python package that can couple models written in a variety of programming languages including C/C++, Python, R, Matlab, and Fortran. Kannan et al used the yggdrasil framework to one-way couple a gene regulatory network model (R), a protein translation model (Python), and a leaf photosynthesis model (Matlab) [33]. yggdrasil is also capable of two-way coupling between models with different timescales, throughout a simulation.…”

Section: The Future Of Multiscale Plant Modelingmentioning

confidence: 99%

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Multiscale plant modeling: from genome to phenome and beyond

Matthews

Marshall‐Colón

2021

Emerging Topics in Life Sciences

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Plants are complex organisms that adapt to changes in their environment using an array of regulatory mechanisms that span across multiple levels of biological organization. Due to this complexity, it is difficult to predict emergent properties using conventional approaches that focus on single levels of biology such as the genome, transcriptome, or metabolome. Mathematical models of biological systems have emerged as useful tools for exploring pathways and identifying gaps in our current knowledge of biological processes. Identification of emergent properties, however, requires their vertical integration across biological scales through multiscale modeling. Multiscale models that capture and predict these emergent properties will allow us to predict how plants will respond to a changing climate and explore strategies for plant engineering. In this review, we (1) summarize the recent developments in plant multiscale modeling; (2) examine multiscale models of microbial systems that offer insight to potential future directions for the modeling of plant systems; (3) discuss computational tools and resources for developing multiscale models; and (4) examine future directions of the field.

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Section: Multiscale Models For Plant Engineeringmentioning

confidence: 99%

Section: The Future Of Multiscale Plant Modelingmentioning

confidence: 99%

Multiscale plant modeling: from genome to phenome and beyond

Matthews

Marshall‐Colón

2021

Emerging Topics in Life Sciences

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“…For example, simulating dynamic light conditions is necessary to retrieve canopy scale data that would reflect environmental variability [ 4 ]. In fact, whereas most of the past experiments and models considered photosynthesis at the steady state [ 10 , 11 , 17 , 43 , 48 , 53 ], the importance of considering some photosynthetic processes in their transient states has been recognized [ 9 , 14 , 31 , 46 , 47 ]. Plants are exposed to fluctuating irradiance due to the movements of clouds, the effect of wind and the gaps within the canopy [ 35 , 39 ].…”

Section: Introductionmentioning

confidence: 99%

A low-cost automated growth chamber system for continuous measurements of gas exchange at canopy scale in dynamic conditions

et al. 2021

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Background Obtaining instantaneous gas exchanges data is fundamental to gain information on photosynthesis. Leaf level data are reliable, but their scaling up to canopy scale is difficult as they are acquired in standard and/or controlled conditions, while natural environments are extremely dynamic. Responses to dynamic environmental conditions need to be considered, as measurements at steady state and their related models may overestimate total carbon (C) plant uptake. Results In this paper, we describe an automatic, low-cost measuring system composed of 12 open chambers (60 × 60 × 150 cm; around 400 euros per chamber) able to measure instantaneous CO2 and H2O gas exchanges, as well as environmental parameters, at canopy level. We tested the system’s performance by simulating different CO2 uptake and respiration levels using a tube filled with soda lime or pure CO2, respectively, and quantified its response time and measurement accuracy. We have been also able to evaluate the delayed response due to the dimension of the chambers, proposing a method to correct the data by taking into account the response time ($${t}_{0}$$ t 0 ) and the residence time (τ). Finally, we tested the system by growing a commercial soybean variety in fluctuating and non-fluctuating light, showing the system to be fast enough to capture fast dynamic conditions. At the end of the experiment, we compared cumulative fluxes with total plant dry biomass. Conclusions The system slightly over-estimated (+ 7.6%) the total C uptake, even though not significantly, confirming its ability in measuring the overall CO2 fluxes at canopy scale. Furthermore, the system resulted to be accurate and stable, allowing to estimate the response time and to determine steady state fluxes from unsteady state measured values. Thanks to the flexibility in the software and to the dimensions of the chambers, even if only tested in dynamic light conditions, the system is thought to be used for several applications and with different plant canopies by mimicking different environmental conditions.

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“…The model was also used to predict phenotypic responses due to altered circadian timing in clock-mutant plants [30]. More advanced multiscale models have been used to explore the impacts of genetic modifications to soybean photosynthesis in ambient and elevated carbon dioxide [31] and to explore potential gene engineering strategies for producing trees with improved bioenergy traits while mitigating negative impacts on tree growth [32].…”

Section: Introductionmentioning

confidence: 99%

Integrative Modelling of Gene Expression and Digital Phenotypes to Describe Senescence in Wheat

Rodriguez

2021

Genes

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Senescence is the final stage of leaf development and is critical for plants’ fitness as nutrient relocation from leaves to reproductive organs takes place. Although senescence is key in nutrient relocation and yield determination in cereal grain production, there is limited understanding of the genetic and molecular mechanisms that control it in major staple crops such as wheat. Senescence is a highly orchestrated continuum of interacting pathways throughout the lifecycle of a plant. Levels of gene expression, morphogenesis, and phenotypic development all play key roles. Yet, most studies focus on a short window immediately after anthesis. This approach clearly leaves out key components controlling the activation, development, and modulation of the senescence pathway before anthesis, as well as during the later developmental stages, during which grain development continues. Here, a computational multiscale modelling approach integrates multi-omics developmental data to attempt to simulate senescence at the molecular and plant level. To recreate the senescence process in wheat, core principles were borrowed from Arabidopsis Thaliana, a more widely researched plant model. The resulted model describes temporal gene regulatory networks and their effect on plant morphology leading to senescence. Digital phenotypes generated from images using a phenomics platform were used to capture the dynamics of plant development. This work provides the basis for the application of computational modelling to advance understanding of the complex biological trait senescence. This supports the development of a predictive framework enabling its prediction in changing or extreme environmental conditions, with a view to targeted selection for optimal lifecycle duration for improving resilience to climate change.

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Combining gene network, metabolic and leaf-level models shows means to future-proof soybean photosynthesis under rising CO2

Cited by 21 publications

References 60 publications

Multiscale plant modeling: from genome to phenome and beyond

Multiscale plant modeling: from genome to phenome and beyond

A low-cost automated growth chamber system for continuous measurements of gas exchange at canopy scale in dynamic conditions

Integrative Modelling of Gene Expression and Digital Phenotypes to Describe Senescence in Wheat

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