Increase ecosystem resilience to climate change.

Engineering Biology for Climate & Sustainability

Conservation of Ecosystems and Biodiversity Goal:

Increase ecosystem resilience to climate change.

Current State-of-the-Art

Extreme climate events and disasters, such as wildfires, droughts, heat waves, hurricanes, and floods, have devastating effects on ecosystems and are poised to become even more frequent and intense as the planet continues to warm. Combined with ecology, geosciences, and other research disciplines, engineering biology provides options to help study and mitigate impacts from extreme weather events and to assist in ecosystem restoration.

One of the most ecologically devastating impacts from global warming has been an increase in intensity and frequencies of wildfires.¹ While wildfires are a natural part of forest ecosystem cycles, extreme wildfires diminish the ability for forests to recover post-fire. Forest fires affect the full landscape of an ecosystem, including everything from trees, grasses, and shrubs, to lichen and mosses, soils, and waterways. To aid the recovery of forests after catastrophic fires, trees and forest soils could be seeded with engineered fungi, microbes, and microbial communities to improve water-retention, combat soil erosion, and improve bio-recycling of detritus and undergrowth.

Ocean warming and ocean acidification have been detrimental to marine and coastal ecosystems. Heat waves damage coral reefs and kelp forests and heighten the likelihood of toxic algal blooms.²^, ³ Engineering biology approaches, such as genetically engineering keystone marine and freshwater species to increase resistance to environmental stressors, could help protect parts of the marine ecosystem from the effects of climate change. For example, to mitigate or reverse coral bleaching, researchers are helping corals tolerate higher heat and lower pH levels by engineering symbiotic microbes that can colonize coral to facilitate reactive oxygen species scavenging.⁴ For coastal ecosystems, halotolerant plants, such as mangroves, could be developed to better adapt to rising sea levels.⁵

Climate change is also altering the length and median temperature of seasons, with changing temperatures impacting population dynamics across ecosystems. These changes in population dynamics can lead to ecosystem collapses and catastrophes. In particular, research suggests warming summers and winters drive an increase in disease transmission of pathogens that target humans, including Zika, malaria, yellow fever, and dengue,⁶^, ⁷ animals (such as avian malaria; see Liao et al., 2017⁸; U.S. National Park Service, 2017⁹), and plants (such as bark and pine beetles; see Bentz et al., 2010¹⁰; Sambaraju et al, 2012¹¹; Ungerer et al., 1999¹²). Engineering biology could play a key role in mitigating risks from increased pathogen transmission and the spread of invasive species. For example, using gene drives, invasive insect species could be managed through engineered population control, such as altered mating success rate and fecundity based on desired traits (e.g., host genetic markers). Additionally, endangered species could be engineered for increased resistance against biotic and abiotic stresses, such as engineering the microbiome of honey bees and other pollinators to help protect them against pathogens and pesticides.

Breakthrough Capabilities & Milestones

Enhance forest restoration and recovery from fires and other environmental stressors.

Discover genes for conferring heat-stress and drought tolerance in microbes, fungi, plants, and insects.

Engineer symbiotic fungi (e.g., arbuscular mycorrhizal fungi) to enhance beneficial symbiotic traits (i.e., nutrient exchange, water retention, stress resistance) for seedling establishment in reforesting operations.

Engineer and field-test heat and burn-resistant microbes in high-threat areas.

Deploy engineered organisms with robust regenerative capabilities to restore soils.

Engineer plants and microbiomes to help plants adapt to new climate aspects as species migrate or are planted outside of their native range.

Engineer native plants and trees robust to invasive pathogens and pests.

Increase marine ecosystem resilience to adverse climatic factors through engineered biology and biomaterials.

Bioprospect and analyze marine species to determine potential marine model organisms, particularly those robust to changing climates, such as planctomycetota.

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

Engineer micro- and macroalgae to capture, degrade and remove pollutants, including pesticides, herbicides, and petroleum.

Engineer kelp and plankton to have higher tolerance to heat, acid, and salinity stress.

Bottleneck/Challenge: Many marine species are not yet considered model organisms or have the toolkits necessary for efficient engineering.

Potential Solution: Develop genetic tools for engineering foundational marine species (e.g., kelp, plankton).

Bottleneck/Challenge: Effects of acute climate events (such as marine heat waves) on foundational marine species (e.g., kelp, plankton) are not well understood.

Potential Solution: Identify genetic markers for heat resistance, acidification, and salinity fluctuations in kelp, plankton, and other key species.

Engineer living biomaterials and biocoatings to protect aquatic organisms against pollutants and ocean acidification.

Improve salt tolerance in coast-adjacent soils and plant species.

Engineer adaptive living biomaterials that respond to fluctuations in marine salinity, acidity, and trace particles/solutes.*

*Liu, A. P., Appel, E. A., Ashby, P. D., Baker, B. M., Franco, E., Gu, L., Haynes, K., Joshi, N. S., Kloxin, A. M., Kouwer, P. H. J., Mittal, J., Morsut, L., Noireaux, V., Parekh, S., Schulman, R., Tang, S. K. Y., Valentine, M. T., Vega, S. L., Weber, W., … Chaudhuri, O. (2022). The living interface between synthetic biology and biomaterial design. Nature Materials, 21(4), 390–397. https://doi.org/10.1038/s41563-022-01231-3

Mitigate climate change-induced emergence of pathogens and invasive species.

Develop vaccines to protect endangered wildlife against newly-emergent pathogens.

Expand capabilities for monitoring/detecting environmental DNA (eDNA) and protein, and metabolite profiling to monitor the spread of pathogens and invasive species.

Bottleneck/Challenge: Identity of the most significant, system-disrupting pathogens (e.g., microbial parasites) and invasive species.

Potential Solution: Use strain-agnostic sample and detection platforms (e.g., nucleic acid or protein nanopore sequencers, activity-based chemical probes) to monitor sensitive environments.

Bottleneck/Challenge: Performing eDNA tests requires extensive sample processing.

Potential Solution: Develop simplified, field-deployable sample-preparation kits and protocols for testing local water streams and middens

Develop biosensors to enable detection of genetic and molecular hallmarks of known and emerging zoonoses.

Develop gene drives to control invasive species (e.g., mosquito, bark beetle, cane toad).

Engineer the microbiome of pollinator insects (e.g., honey bees) to protect them against specific pathogens and pesticides.

Footnotes

United Nations Environment Programme. (2022). Spreading like Wildfire: The Rising Threat of Extraordinary Landscape Fires. UNEP – UN Environment Programme. http://www.unep.org/resources/report/spreading-wildfire-rising-threat-extraordinary-landscape-fires
Smale, D. A., Wernberg, T., Oliver, E. C. J., Thomsen, M., Harvey, B. P., Straub, S. C., Burrows, M. T., Alexander, L. V., Benthuysen, J. A., Donat, M. G., Feng, M., Hobday, A. J., Holbrook, N. J., Perkins-Kirkpatrick, S. E., Scannell, H. A., Sen Gupta, A., Payne, B. L., & Moore, P. J. (2019). Marine heatwaves threaten global biodiversity and the provision of ecosystem services. Nature Climate Change, 9(4), 306–312. https://doi.org/10.1038/s41558-019-0412-1
EPA. (2013). Climate Change and Harmful Algal Blooms [Overviews and Factsheets]. https://www.epa.gov/nutrientpollution/climate-change-and-harmful-algal-blooms
Quigley, K. M., Alvarez Roa, C., Beltran, V. H., Leggat, B., & Willis, B. L. (2021). Experimental evolution of the coral algal endosymbiont, Cladocopium goreaui: Lessons learnt across a decade of stress experiments to enhance coral heat tolerance. Restoration Ecology, 29(3), e13342. https://doi.org/10.1111/rec.13342
Menéndez, P., Losada, I. J., Torres-Ortega, S., Narayan, S., & Beck, M. W. (2020). The Global Flood Protection Benefits of Mangroves. Scientific Reports, 10(1), 4404. https://doi.org/10.1038/s41598-020-61136-6
Anwar, A., Anwar, S., Ayub, M., Nawaz, F., Hyder, S., Khan, N., & Malik, I. (2019). Climate Change and Infectious Diseases: Evidence from Highly Vulnerable Countries. Iranian Journal of Public Health, 48(12), 2187–2195. https://www.ncbi.nlm.nih.gov/pmc/articles/PMC6974868/
McDermott, A. (2022). Climate change hastens disease spread across the globe. Proceedings of the National Academy of Sciences, 119(7), e2200481119. https://doi.org/10.1073/pnas.2200481119
Liao, W., Atkinson, C. T., LaPointe, D. A., & Samuel, M. D. (2017). Mitigating Future Avian Malaria Threats to Hawaiian Forest Birds from Climate Change. PLOS ONE, 12(1), e0168880. https://doi.org/10.1371/journal.pone.0168880
U.S. National Park Service. (2017). Tracking the Spread of Avian Malaria within Haleakalā National Park (U.S. National Park Service). Retrieved July 7, 2022, from https://www.nps.gov/articles/000/tracking-the-spread-of-avian-malaria.htm
Bentz, B. J., Régnière, J., Fettig, C. J., Hansen, E. M., Hayes, J. L., Hicke, J. A., Kelsey, R. G., Negrón, J. F., & Seybold, S. J. (2010). Climate Change and Bark Beetles of the Western United States and Canada: Direct and Indirect Effects. BioScience, 60(8), 602–613. https://doi.org/10.1525/bio.2010.60.8.6
Sambaraju, K. R., Carroll, A. L., Zhu, J., Stahl, K., Moore, R. D., & Aukema, B. H. (2012). Climate change could alter the distribution of mountain pine beetle outbreaks in western Canada. Ecography, 35(3), 211–223. https://doi.org/10.1111/j.1600-0587.2011.06847.x
Ungerer, M. J., Ayres, M. P., & Lombardero, M. J. (1999). Climate and the northern distribution limits of Dendroctonus frontalis Zimmerman (Coleoptera: Scolytidae). Journal of Biogeography 26:1133-1145. http://www.fs.usda.gov/treesearch/pubs/1327