‘Follow the Water’: Microbial Water Acquisition in Desert Soils

Cowan, Don A; Cary, S. Craig; DiRuggiero, Jocelyne; Eckardt, Frank; Ferrari, Belinda; Hopkins, David W.; Lebre, Pedro H.; Maggs-Kölling, Gillian; Pointing, Stephen B.; Ramond, Jean-Baptiste; Tribbia, Dana; Warren-Rhodes, Kimberley

doi:10.3390/microorganisms11071670

Cited by 3 publications

(1 citation statement)

References 131 publications

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“…In the real world, nutrients could be limited in the environment, such as in the glacial environments, where bacteria face nutrient limitations due to the low organic matter content and slow nutrient release from ice melt [56]. Bacteria in desert soils are limited to rainfall and high evaporation rates; water becomes the main limitation for these bacteria [57].…”

Section: Antibiofouling and Bactericide Propertiesmentioning

confidence: 99%

The Effect of Micro/Nano Roughness on Antifouling and Bactericidal Surfaces

I. Garcia-Gonzalez,

R. Crick

2023

Superhydrophobic Coating - Recent Advances in Theory and Applications

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The importance of microorganisms, especially bacteria, has often been underestimated, yet they have vital roles in staying in the environment and affecting human health and industries. These microorganisms have complex systems and change quickly over time, becoming more resistant. The spread of harmful microorganisms has negative effects on industries and human health. Even microorganisms that seem harmless can be a big problem because they are becoming more resistant to normal cleaning and antibiotics. They resist ways like creating strong biofilms, which make these microorganisms even tougher and help infections spread. Although there are other options like using heat or chemicals, the problem of bacterial resistance is still a big worry for health and industries. Trying out new ideas that do not use chemicals or antibiotics, like using superhydrophobic surfaces, could be a big solution. These surfaces use both special chemicals and changes in how they feel to water to stop bacteria from sticking and growing. By looking for new ways, we can get better at dealing with these microorganisms and find better ways to live with them.

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Section: Antibiofouling and Bactericide Propertiesmentioning

confidence: 99%

The Effect of Micro/Nano Roughness on Antifouling and Bactericidal Surfaces

I. Garcia-Gonzalez,

R. Crick

2023

Superhydrophobic Coating - Recent Advances in Theory and Applications

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Metagenomic approaches and opportunities in arid soil research

Ejaz,

Badr,

Hassan

et al. 2024

Science of The Total Environment

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Clearing the air: unraveling past and guiding future research in atmospheric chemosynthesis

Ray,

Tribbia,

Cowan

et al. 2023

Microbiol Mol Biol Rev

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SUMMARY Atmospheric chemosynthesis is a recently proposed form of chemoautotrophic microbial primary production. The proposed process relies on the oxidation of trace concentrations of hydrogen (≤530 ppbv), carbon monoxide (≤90 ppbv), and methane (≤1,870 ppbv) gases using high-affinity enzymes. Atmospheric hydrogen and carbon monoxide oxidation have been primarily linked to microbial growth in desert surface soils scarce in liquid water and organic nutrients, and low in photosynthetic communities. It is well established that the oxidation of trace hydrogen and carbon monoxide gases widely supports the persistence of microbial communities in a diminished metabolic state, with the former potentially providing a reliable source of metabolic water. Microbial atmospheric methane oxidation also occurs in oligotrophic desert soils and is widespread throughout copiotrophic environments, with established links to microbial growth. Despite these findings, the direct link between trace gas oxidation and carbon fixation remains disputable. Here, we review the supporting evidence, outlining major gaps in our understanding of this phenomenon, and propose approaches to validate atmospheric chemosynthesis as a primary production process. We also explore the implications of this minimalistic survival strategy in terms of nutrient cycling, climate change, aerobiology, and astrobiology.

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‘Follow the Water’: Microbial Water Acquisition in Desert Soils

Cited by 3 publications

References 131 publications

The Effect of Micro/Nano Roughness on Antifouling and Bactericidal Surfaces

The Effect of Micro/Nano Roughness on Antifouling and Bactericidal Surfaces

Metagenomic approaches and opportunities in arid soil research

Clearing the air: unraveling past and guiding future research in atmospheric chemosynthesis

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