Synthetic Botany

Boehm, Christian R.; Pollak, Bernardo; Purswani, Nuri; Patron, Nicola J.; Haseloff, Jim

doi:10.1101/cshperspect.a023887

Cited by 26 publications

(30 citation statements)

References 186 publications

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“…At present, almost all engineering of plant gene expression uses natural regulatory parts, leaving engineered genes open to unwanted crosstalk from endogenous control systems in the host. Fortunately, the fastgrowing field of synthetic regulatory circuits in plants (Boehm et al, 2017;Kassaw et al, 2018) can provide orthogonal systems to modulate gene expression; these may be very useful in reengineering genes that drive carbon loss. Finally, we acknowledge that smart breeding approaches that integrate multiple processes and focus on phenotypic outputs like growth rate and yield provide an alternative to directed engineering of metabolic subprocesses, and that directed approaches might fail if the various subprocesses interact in a nonlinear and hence difficult-to-predict manner on emergent agronomic traits.…”

Section: Closing Pointsmentioning

confidence: 99%

Engineering Strategies to Boost Crop Productivity by Cutting Respiratory Carbon Loss

et al. 2019

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Roughly half the carbon that crop plants fix by photosynthesis is subsequently lost by respiration. Nonessential respiratory activity leading to unnecessary CO 2 release is unlikely to have been minimized by natural selection or crop breeding, and cutting this large loss could complement and reinforce the currently dominant yield-enhancement strategy of increasing carbon fixation. Until now, however, respiratory carbon losses have generally been overlooked by metabolic engineers and synthetic biologists because specific target genes have been elusive. We argue that recent advances are at last pinpointing individual enzyme and transporter genes that can be engineered to (1) slow unnecessary protein turnover, (2) replace, relocate, or reschedule metabolic activities, (3) suppress futile cycles, and (4) make ion transport more efficient, all of which can reduce respiratory costs. We identify a set of engineering strategies to reduce respiratory carbon loss that are now feasible and model how implementing these strategies singly or in tandem could lead to substantial gains in crop productivity.

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Section: Closing Pointsmentioning

confidence: 99%

Engineering Strategies to Boost Crop Productivity by Cutting Respiratory Carbon Loss

et al. 2019

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“…The main eukaryotic chassis are Saccharomyces cerevisiae and mammalian cells (Adams, 2016). In the case of photosynthetic eukaryotes, synthetic biology tools have been developed for Arabidopsis (Arabidopsis thaliana) and Marchantia polymorpha (Boehm et al, 2017); however, unicellular chassis have only emerged recently. Many eukaryotic algal genomes have been sequenced (data from the National Center for Biotechnology Information Genome, https:// www.ncbi.nlm.nih.gov/): 64 green algae, nine red algae, nine diatoms, five dinoflagellates, and three brown algae.…”

Section: Synthetic Biology In Eukaryotic Algaementioning

confidence: 99%

The Synthetic Biology Toolkit for Photosynthetic Microorganisms

et al. 2019

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“…Understanding these extant topologies, and revealing the principles underlying the drive to complexity may also pave the way for the prediction of future organ designs through morphospace analyses [ 9 ]. Such approaches combined with synthetic biology [ 97 , 98 ] can provide a discrete framework for the rational re-engineering of complex multicellular systems [ 99 ]. In this way, organisms with novel functions may be generated following known structure–function principles, through morphogenetic engineering [ 100 ].…”

Section: Further Potential For Developmental Connectomicsmentioning

confidence: 99%

Network-based approaches to quantify multicellular development

Jackson¹,

Duran-Nebreda²,

Bassel³

2017

J. R. Soc. Interface.

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Multicellularity and cellular cooperation confer novel functions on organs following a structure–function relationship. How regulated cell migration, division and differentiation events generate cellular arrangements has been investigated, providing insight into the regulation of genetically encoded patterning processes. Much less is known about the higher-order properties of cellular organization within organs, and how their functional coordination through global spatial relations shape and constrain organ function. Key questions to be addressed include: why are cells organized in the way they are? What is the significance of the patterns of cellular organization selected for by evolution? What other configurations are possible? These may be addressed through a combination of global cellular interaction mapping and network science to uncover the relationship between organ structure and function. Using this approach, global cellular organization can be discretized and analysed, providing a quantitative framework to explore developmental processes. Each of the local and global properties of integrated multicellular systems can be analysed and compared across different tissues and models in discrete terms. Advances in high-resolution microscopy and image analysis continue to make cellular interaction mapping possible in an increasing variety of biological systems and tissues, broadening the further potential application of this approach. Understanding the higher-order properties of complex cellular assemblies provides the opportunity to explore the evolution and constraints of cell organization, establishing structure–function relationships that can guide future organ design.

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Synthetic Botany

Cited by 26 publications

References 186 publications

Engineering Strategies to Boost Crop Productivity by Cutting Respiratory Carbon Loss

Engineering Strategies to Boost Crop Productivity by Cutting Respiratory Carbon Loss

The Synthetic Biology Toolkit for Photosynthetic Microorganisms

Network-based approaches to quantify multicellular development

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