Increase carbon uptake and mitigate climate change by enhancing natural systems through engineered biology.

Engineering Biology for Climate & Sustainability

Biosequestration of Greenhouse Gases Goal:

Increase carbon uptake and mitigate climate change by enhancing natural systems through engineered biology.

Current State-of-the-Art

In addition to the active removal of greenhouse gases from the atmosphere, engineering biology can be used to bolster the uptake and storage of carbon in natural ecosystems. Agricultural ecosystems, wetlands and deserts all represent promising terrestrial ecosystems for carbon storage. Plant engineering, such as increasing carbon capture phenotypes through overexpression or engineering rhizosphere communities, could increase soil carbon capacity by modifying crops to store more carbon in their roots. Wetlands already represent major global carbon sinks¹ and a source of increasing greenhouse gas (GHG) emissions.² Pollutant-degrading microbes could be deployed to help wetland plants fight pollution-related wetland degradation and support carbon sequestration. Engineering approaches that can rapidly restore wetlands, increase carbon storage, and reduce methane production (or increased methane utilization) could have a large beneficial climate effect.

Climate change is also contributing significantly to changes in terrestrial ecosystems conditions, particularly in the amount of heat they experience and the amount of water available. Arid ecosystems represent a promising target for soil carbon accumulation given that they account for ~40% of land area, are typically already very low carbon soils, and the limited water already stabilizes soil carbon pools.³ Engineering microbial communities that colonized these arid soils (biocrusts) provides a very promising approach to store soil carbon. Some large-scale projects in China have already demonstrated the feasibility of artificial inoculation of sands with biocrust cyanobacteria (hundreds of hectares⁴) for stabilizing soils, building soil carbon, and initiating ecosystem restoration. Given that large, and unfortunately growing, scale of arid ecosystems these approaches could have a massive impact and could potentially turn wastelands back into arable lands to help support Earth’s growing population. Finally, microbial ice nucleation could be leveraged to help maintain snowpack, create more reflective surfaces in alpine and polar environments, and preserve permafrost and prevent carbon release.⁵

Engineering biology could also enhance coastal and ocean carbon sequestration. Ocean and coastal environments account for significant amounts of CO₂ removal and storage, but are highly susceptible to damage caused by climate change. The processes of carbon cycling and storage in marine environments are less researched, but extremely productive.⁶^, ⁷ Phytoplanktons and macroalgae, such as kelp, could be engineered to improve carbon capture in the ocean and mitigate ocean acidification. Similarly, planctomycetota (bacteria that carry out anammox, anaerobic ammonium oxidation, reactions), halophiles, and viruses could also play very important roles in marine carbon sequestration, and potentially be incorporated into microbiomes or otherwise be stably deployed into oceans to increase carbon capture.

Breakthrough Capabilities & Milestones

Enhance soil carbon storage capacity via engineered biology.

Understand the role of soil microbiome in modifying (specifically, increasing) soil carbon capacity.

Bottleneck/Challenge: The high complexity and multitude of soil microbes make it difficult to identify soil microbial community function using currently available -omics techniques.

Potential Solution: Develop high-throughput proteomics techniques to better understand biological functions in soil matrix.

Potential Solution: Improve soil metabolomics reference databases and metabolomics techniques to better understand biogeochemical cycling in soil.

Potential Solution: Integrate multiple -omics datasets into a single database.

Bottleneck/Challenge: Paucity of models for how soil microbiota regulate soil carbon capacity across different spatial (microscopic, mesoscopic, and macroscopic) and temporal scales.

Potential Solution: Develop tools to enable the measurement of biochemical reactions (microscale) in the field (macroscale).

Potential Solution: Consolidate datasets from lab- and field-based studies to create an integrated soil microbiome database.

Potential Solution: Develop computational models (informed by lab and field studies) to bridge the knowledge gaps between different spatial and temporal scales.

Bottleneck/Challenge: Limited understanding of how microbes deposit carbon as minerals and sediments in soil.

Potential Solution: Develop metabolite labeling and tracing tools that can be used to track carbon movement in soil microbiome first in laboratory conditions and later in situ.⁸

Bottleneck/Challenge: Current poor understanding of the chemical and ecological factors that govern the residence time of specific molecules in soils (e.g., betaine).

Potential Solution: Highly controlled ecosystem studies coupled to high resolution mass spectrometry to determine the factors that affect the turnover of specific molecules in soils.

Engineer model plants to increase root biomass contributing to below-ground carbon storage.

Bottleneck/Challenge: Avoiding undesired phenotypes associated with engineering metabolic flux.⁹^, ¹⁰

Potential Solution: Genetic determinants for some carbon-storing compounds are well characterized (see Harman-Ware et al., 2021¹¹); apply this understanding to systems/organismal engineering to enable control of compound synthesis, transport, and storage.

Engineer the root systems of crop and non-model plants to store more carbon.

Bottleneck/Challenge: The synthesis of carbon-storing compounds can vary by cultivar in response to environmental conditions.

Potential Solution: Undertake large field trials using genomic, transcriptomic, proteomic, and metabolomic analyses to understand the contributions of genetics and the environment to the synthesis of key carbon-storing compounds, such as suberin, in non-model and crop plants.¹²

Potential Solution: Understand and engineer synthesis and transport mechanisms for carbon-storing compounds, such as suberin, that are synthesized above and below ground for consistent root accumulation across environmental conditions and relevant plant cultivars.

Potential Solution: Engineer suberin to increase carrying capacity and retain carbon for longer time periods.

Engineer plant roots to secrete metabolites that recruit microbes capable of converting labile plant exudates into stable soil carbon.

Bottleneck/Challenge: Relationships between plants and microbes vary under differing environmental conditions, potentially to the plant’s benefit (see von Rein et al., 2016¹³; Wipf et al., 2021¹⁴); preferencing the recruitment of target microbes under stressful environmental conditions may disrupt interactions that support plant health.

Potential Solution: Engineer microbiomes that are responsive to changing conditions.

Bottleneck/Challenge: Plant metabolites may need to be converted to alternative forms or compounds by microbiome community members in order to recruit microbes that increase carbon capacity, which would be challenging to track and elucidate.

Potential Solution: Enhance capabilities for tracing metabolite transfer from plants through the microbiome, working toward greater resolution (e.g., Family or Genus) of involved community members.

Potential Solution: Harness microbial communities and knowledge of specific molecules with longer residence times under specific environmental and ecological conditions.

Potential Solution: Maximize microbial conversion of exudate to biomass (and subsequently, microbial necromass) by designing microbial communities that use all exudate components.

Enable stable, long-term carbon storage in soil microbiomes, such as by introducing fungi to enhance weathering.

Bottleneck/Challenge: Unstable soil aggregates (i.e., due to tilling) release captured carbon back into the atmosphere.

Potential Solution: Engineer soil microbes to produce biofilms to promote the formation of soil aggregates.

Potential Solution: Engineer biomaterials to stabilize soil micro-aggregates.

Bottleneck/Challenge: Fungal hyphal networks (e.g,. arbuscular mycorrhizal fungi) have been shown to enhance mineral weathering in soil, but the most well-studied of such fungi – mycorrhizal fungi –need host plants to survive.

Potential Solution: Engineer arbuscular mycorrhizal fungi to survive independent of a host plant.

Potential Solution: Develop means to seed soil with fungi capable of mineral weathering (e.g., saprotrophic fungi) and surviving without host plants.

Identify and characterize exometabolites beneficial to increasing carbon storage capacity in plants or soil.

Bottleneck/Challenge: The exometabolome is challenging to characterize because of extensive cross-feeding/uptake by other community members.

Potential Solution: Develop improved tools to quantify the exchange of metabolites within complex microbiomes.¹⁵

Enable microbial communities in permafrost to retain and/or capture greenhouse gases.

Develop methods for in situ modification of soil microbial communities to increase carbon storage in evolving at-risk soils.

Restore disturbed natural biocrusts and increase carbon sequestration in arid lands.

Assess the carbon removal potential of deploying artificial biocrust in a variety of arid environments.

Bottleneck/Challenge: More understanding is needed on the durability of sequestered carbon and how biocrust interacts with other parts of the carbon cycle.

Potential Solution: Identify biochemical factors that increase carbon sequestration in biocrusts.

Potential Solution: Measure carbon sequestration capacity in artificial biocrust over temporal and spatial scales, and under different environmental conditions (e.g., temperature, precipitation, and nutrient levels).

Demonstrate engineered biocrust communities to sequester carbon in arid environments.

Bottleneck/Challenge: It is difficult to isolate fast-growing and suitable cyanobacteria for inoculating biocrust.

Potential Solution: Identify, cultivate, and engineer filamentous cyanobacteria from a variety of dryland regions for desired growth rate and robustness under requisite environmental conditions (e.g., high summer heat).

Potential Solution: Develop and engineer consortia of cyanobacteria (different species) to more successfully inoculate artificial or native biocrusts.

Bottleneck/Challenge: Processes for inoculating engineered cyanobacteria into natural biocrusts are underdeveloped.

Engineer and deploy artificial biocrust to restore and increase climate-resilience of native biocrust and desert ecosystems.

Enhance albedo via engineered microbes.

Identify and engineer microbes with increased ice nucleation capabilities.

Bottleneck/Challenge: Mechanisms of microbial ice nucleation are not well understood.

Potential Solution: Use advanced -omics techniques to identify links between microbes/microbial communities and their ability to nucleate ice.

Bottleneck/Challenge: A lack of genetic editing tools to engineer ice nucleating biological systems.

Potential Solution: Develop genetic tools (e.g., transformation methods, genetic parts) for engineering cryophilic microbial chassis.

Potential Solution: Identify or design ice nucleating proteins with high efficiency and robustness of ice nucleation.

Demonstrate biological ice formation in simulated environments.

Deploy engineered microbes to nucleate ice and help preserve snowpack in the environment.

Enhance ocean and coastal carbon capacity via engineered biology.

Engineer anaerobic and halophilic microbes and planctomycetota to supplement coastal wetland soils for increased carbon storage.

Engineer phytoplankton to be more robust to declining marine conditions, including increased water temperatures, acidification, eutrophication, and hypoxia.

Engineer macroalgae (including seaweed and kelp) for carbon capture and reduction of ocean acidification.

Bottleneck/Challenge: Limited gene editing tools for engineering macroalgae (e.g., Saccharina and Gracilaria).

Potential Solution: Develop and improve direct bacterial transformation (such as in ways similar to agrobacterium transformation of plants).¹⁶

Potential Solution: Gain better control of gametophyte hybridization and development of CRISPR-Cas systems.¹⁷

Bottleneck/Challenge: Macroalgae grown in offshore environments compete for nutrients with carbon-fixing phytoplankton.

Potential Solution: Deploy carbon-capturing microbes that produce nutrients necessary for macroalgae growth in coastal algal farms.

Systematically engineer marine biological carbon pumps to increase the amount of recalcitrant dissolved organic carbon in the ocean.

Bottleneck/Challenge: Paucity of information about (but ever-increasing volume of) refractory organic compounds and chemical structures.

Potential Solution: Develop further understanding of and engineer microbes that enhance processes involved in the biological carbon pump that leads to long-term sequestration of carbon from the surface ocean to the deep ocean interiors.

Potential Solution: Identify how conversion of short-lived organic pools to recalcitrant carbon impacts microbial-driven nutrient cycles.

Potential Solution: Develop further understanding of how bacteria, viruses, plankton, and other microbes interact to facilitate long-term carbon sequestration.

Footnotes

Nahlik, A. M., & Fennessy, M. S. (2016). Carbon storage in US wetlands. Nature Communications, 7(1), 13835. https://doi.org/10.1038/ncomms13835
Zhang, Z., Zimmermann, N. E., Stenke, A., Li, X., Hodson, E. L., Zhu, G., Huang, C., & Poulter, B. (2017). Emerging role of wetland methane emissions in driving 21st century climate change. Proceedings of the National Academy of Sciences, 114(36), 9647–9652. https://doi.org/10.1073/pnas.1618765114
Rodríguez-Caballero, E., Castro, A. J., Chamizo, S., Quintas-Soriano, C., Garcia-Llorente, M., Cantón, Y., & Weber, B. (2018). Ecosystem services provided by biocrusts: From ecosystem functions to social values. Journal of Arid Environments, 159, 45–53. https://doi.org/10.1016/j.jaridenv.2017.09.005
Zhou, X., Zhao, Y., Belnap, J., Zhang, B., Bu, C., & Zhang, Y. (2020). Practices of biological soil crust rehabilitation in China: Experiences and challenges. Restoration Ecology, 28(S2), S45–S55. https://doi.org/10.1111/rec.13148
Brouillette, M. (2021). How microbes in permafrost could trigger a massive carbon bomb. Nature, 591(7850), 360–362. https://doi.org/10.1038/d41586-021-00659-y
National Academies of Sciences, Engineering, and Medicine. (2019). Negative Emissions Technologies and Reliable Sequestration: A Research Agenda. https://doi.org/10.17226/25259
Zhang, Y., Zhang, J., Liang, Y., Li, H., Li, G., Chen, X., Zhao, P., Jiang, Z., Zou, D., Liu, X., & Liu, J. (2017b). Carbon sequestration processes and mechanisms in coastal mariculture environments in China. Science China Earth Sciences, 60(12), 2097–2107. https://doi.org/10.1007/s11430-017-9148-7
Watts-Williams, S. J. (2022). Track and trace: How soil labelling techniques have revealed the secrets of resource transport in the arbuscular mycorrhizal symbiosis. Mycorrhiza, 32(3), 257–267. https://doi.org/10.1007/s00572-022-01080-7
Mahmood, K., Zeisler-Diehl, V. V., Schreiber, L., Bi, Y.-M., Rothstein, S. J., & Ranathunge, K. (2019). Overexpression of ANAC046 Promotes Suberin Biosynthesis in Roots of Arabidopsis thaliana. International Journal of Molecular Sciences, 20(24), 6117. https://doi.org/10.3390/ijms20246117
Baxter, I., Hosmani, P. S., Rus, A., Lahner, B., Borevitz, J. O., Muthukumar, B., Mickelbart, M. V., Schreiber, L., Franke, R. B., & Salt, D. E. (2009). Root Suberin Forms an Extracellular Barrier That Affects Water Relations and Mineral Nutrition in Arabidopsis. PLOS Genetics, 5(5), e1000492. https://doi.org/10.1371/journal.pgen.1000492
Harman-Ware, A. E., Sparks, S., Addison, B., & Kalluri, U. C. (2021). Importance of suberin biopolymer in plant function, contributions to soil organic carbon and in the production of bio-derived energy and materials. Biotechnology for Biofuels, 14(1), 75. https://doi.org/10.1186/s13068-021-01892-3
Harman-Ware, A. E., Sparks, S., Addison, B., & Kalluri, U. C. (2021). Importance of suberin biopolymer in plant function, contributions to soil organic carbon and in the production of bio-derived energy and materials. Biotechnology for Biofuels, 14(1), 75. https://doi.org/10.1186/s13068-021-01892-3
von Rein, I., Gessler, A., Premke, K., Keitel, C., Ulrich, A., & Kayler, Z. E. (2016). Forest understory plant and soil microbial response to an experimentally induced drought and heat-pulse event: The importance of maintaining the continuum. Global Change Biology, 22(8), 2861–2874. https://doi.org/10.1111/gcb.13270
Wipf, H. M.-L., Bùi, T.-N., & Coleman-Derr, D. (2021). Distinguishing Between the Impacts of Heat and Drought Stress on the Root Microbiome of Sorghum bicolor. Phytobiomes Journal, 5(2), 166–176. https://doi.org/10.1094/PBIOMES-07-20-0052-R
Douglas, A. E. (2020). The microbial exometabolome: Ecological resource and architect of microbial communities. Philosophical Transactions of the Royal Society B: Biological Sciences, 375(1798), 20190250. https://doi.org/10.1098/rstb.2019.0250
Oertel, W., Wichard, T., & Weissgerber, A. (2015). Transformation of Ulva mutabilis (Chlorophyta) by vector plasmids integrating into the genome. Journal of Phycology, 51(5), 963–979. https://doi.org/10.1111/jpy.12336
Wang, X., Yao, J., Zhang, J., & Duan, D. (2020a). Status of genetic studies and breeding of Saccharina japonica in China. Journal of Oceanology and Limnology, 38(4), 1064–1079. https://doi.org/10.1007/s00343-020-0070-1

Last updated: September 19, 2022 Back