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In a landmark study, researchers at Yale University and NOVA School of Science and Technology, NOVA University Lisbon (NOVA-FCT), have unveiled how subterranean bacteria thrive in oxygen-deprived environments by harnessing a specialized family of proteins. These proteins enable the bacteria to offload excess electrons onto tiny hair-like structures known as nanowires, creating an intricate, natu by Clarence Oxford
Los Angeles CA (SPX) Mar 21, 2024
In a landmark study, researchers at Yale University and NOVA School of Science and Technology, NOVA University Lisbon (NOVA-FCT), have unveiled how subterranean bacteria thrive in oxygen-deprived environments by harnessing a specialized family of proteins. These proteins enable the bacteria to offload excess electrons onto tiny hair-like structures known as nanowires, creating an intricate, natural electrical network beneath the Earth's surface. This discovery marks a significant advancement in our understanding of microbial life and its biochemical mechanisms.
Nikhil Malvankar, an associate professor at Yale's Molecular Biophysics and Biochemistry Department and Microbial Sciences Institute, alongside Carlos Salgueiro, Full Professor at NOVA-FCT, co-led this groundbreaking research. They found that a widespread family of proteins, cytochromes, are pivotal in charging the nanowires, allowing bacteria to engage in a unique form of electron transfer critical for their survival. This process is akin to the microbial version of "breathing" and underscores the sophistication of life forms adapting to extreme environments.
This bioelectrical grid is essential for sustaining a diverse microbial ecosystem, facilitating interactions among various microorganisms. The discovery also illuminates the previously unknown role of soil bacteria in Earth's electrical conductivity, contributing to the planet's electromagnetic properties. It further highlights the intricate connections between life forms and the geophysical processes of Earth.
Understanding this microbial electrical grid is not just an academic pursuit; it has practical implications for environmental sustainability and technology innovation. For instance, these mechanisms play a crucial role in the natural cycling of greenhouse gases, with certain microbes absorbing methane, a potent greenhouse gas, from the ocean. This absorption is a critical natural process mitigating the impact of global warming. Conversely, microbial activity is also responsible for a significant portion of methane emissions to the atmosphere, underscoring the dual role microbes play in Earth's climate system.
The researchers emphasize the potential applications of their findings in developing new energy sources, biomaterials, and strategies for environmental protection. By leveraging the principles of microbial electron transfer, scientists can pioneer technologies for renewable energy generation and create materials with novel properties. Additionally, this knowledge offers pathways to reduce greenhouse gas emissions by understanding and potentially manipulating microbial processes.
This study not only advances our knowledge of the unseen microbial world but also opens new avenues for leveraging biological processes for environmental and technological benefits.
Research Report:Widespread extracellular electron transfer pathways for charging microbial cytochrome OmcS nanowires via periplasmic cytochromes PpcABCDE
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