A new cyanobacteria strain, ‘Chonkus,' could play a role in carbon capture, thanks to its carbon-dense granules and unique adaptations.
A novel strain of cyanobacteria, informally called “Chonkus,” has been identified in hydrothermal waters off Italy's Vulcano Island, sparking interest for its potential in carbon capture. Discovered during a marine study aimed at collecting water samples from the shallow volcanic vents of Vulcano, this large cyanobacteria, formally designated as strain UTEX 3222, displays unique characteristics that may contribute to carbon sequestration efforts.
The hydrothermal environment around Vulcano provides a high carbon dioxide (CO₂) concentration, which is thought to enhance the growth of Chonkus. Observations reveal that the cells of this cyanobacteria develop carbon-dense granules, which accelerate its sinking rate in marine environments. Scientists believe these adaptations allow Chonkus to absorb carbon directly from its environment, promoting its growth and leading it to settle in ocean depths, where it stores the captured carbon.
Potential Benefits for Industrial Applications
Chonkus's ability to form large colonies and store carbon internally is not just valuable in its natural surroundings; it holds promise for industrial applications. By storing carbon more efficiently than other strains, Chonkus could reduce energy expenses for industries involved in carbon capture by up to 30 percent. Professor George Church, a prominent Health Sciences and Technology researcher affiliated with Harvard University and the Massachusetts Institute of Technology, noted that the discovery taps into natural evolutionary processes, potentially assisting humanity in addressing the climate crisis through environmentally efficient means.
Balancing Innovation and Environmental Caution
While Chonkus exhibits a range of desirable traits for carbon capture, researchers advise cautious application. Large-scale microbial releases may disrupt existing ecosystems and carbon retention may not be permanent if these organisms die. Nevertheless, given its resilience to high temperatures and rapid growth rate it holds potential for various bio-manufacturing uses, particularly in settings like bioreactors.
Although there are still challenges to address, this discovery signals a promising step toward more sustainable carbon capture solutions through naturally occurring microbial adaptations.