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Soil Microbes Consume Atmospheric Hydrogen
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Soil Microbes Consume Atmospheric Hydrogen

bioxone October 9, 2020October 8, 2020

SHRESTHA DUTTA, AMITY UNIVERSITY KOLKATA

Soil microbes use up atomic hydrogen (H2) from the Earth’s atmosphere and serve as the primary sink in the global biogeochemical H2 cycle as indicated in the field and lab-based examinations. Hydrogen oxidation in soil follows biphasic kinetics with both high-affinity (Km < 100 nM) and low-affinity (Km > 1000 nM) enzyme action. It is to be noted that significant rates of atmospheric hydrogen (H2) utilization have been seen in temperate soils because of the action of high-affinity enzymes, for example, group 1h [NiFe]-hydrogenase. Microbes with low-affinity have been known for quite a long time and are believed to breed on high concentrations of H2 produced in microniches, for example, N2-fixing root nodules. While soil microorganisms harbor an extent of hydrogenases that catalyze H2 oxidation under oxic conditions, it is imagined that the group 1h [NiFe]-hydrogenases are fundamentally responsible for (sub-) atmospheric H2 oxidation, as observed with a few recently isolated Actinobacteria that utilize atmospheric H2 to conserve energy during endurance. Actinobacteria are ample in soils based on culture-free examinations and are believed to be chiefly responsible for atmospheric H2 oxidation. 

Researchers designed extensive primers to target the large subunit gene (hhyL) of group 1h [NiFe]-hydrogenases for long-read sequencing to uncover its taxonomic distribution across the soils. This methodology uncovered a diverse group of microorganisms having hhyL gene. In Acidobacterial, group 1h [NiFe]-hydrogenase qualities were abundant and expressed in temperate soils. To support H2 utilization by acid bacteria, researchers examined two model mesophilic soil acid bacteria, which indicate group 1h [NiFe]-hydrogenases and utilize atmospheric H2 during carbon starvation. It is for the first time through mesophilic acid bacteria, which are ample in temperate soils, have been showing to oxidize H2 at low atmospheric concentration. As this physiology permits microbes to endure times of carbon starvation, it could clarify the achievement of soil acid bacteria. Researchers show that the capacity to oxidize atmospheric levels of H2, with a long-read sequencing approach of group 1h [NiFe]-hydrogenase gene, is more extensively distributed amidst the soil microbes. This helps the microbes to persist in carbon starvation.

Also read: Phototherapy to Protect Cancer cells

Source:-Acidobacteria are active and abundant members of diverse atmospheric H2-oxidizing communities detected in temperate soils:-  Andrew T. Giguere, Stephanie A. Eichorst, Dimitri V. Meier, Craig W. Herbold, Andreas Richter, Chris Greening & Dagmar Woebken  https://www.nature.com/articles/s41396-020-00750-8

  • Why Do We Age? The Biology Of Ageing Explained
  • The Corrosion Prediction from the Corrosion Product Performance
  • Nitrogen Resilience in Waterlogged Soybean plants
  • Cell Senescence in Type II Diabetes: Therapeutic Potential
  • Transgene-Free Canker-Resistant Citrus sinensis with Cas12/RNP

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Tagged atomic H2 biogeochemical cycle biphasic kinetics enzyme action high-affinity enzymes hydrogenase genes long-read sequencing microniches microorganism are microorganism bacteria soil microbe and soil structure temperate soil temperatures

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Research Student Vacancy Available at MACS ARI Pune

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-Shristi Sharma, Team bioXone MACS ARI Vacancy MSc – Botany Research Students Vacancy. MSc Botany Research Student vacancy for eligible candidates. Research position vacant at MACS ARI, Pune. MACS ARI, Pune is hiring bsc candidates for project vacancies, interested and eligible candidates can check out all of the details on the research student post given […]

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Should you trust ePCR over conventional PCR?

bioxone October 25, 2020October 25, 2020

Parnad Basu, Amity University Kolkata PCR (Polymerase Chain Reaction) is a technique used to amplify small segments of any DNA. In conventional PCR, DNA libraries suffer from template mispairing. This ultimately leads to the obvious loss of unique sequences. To be more efficient, ePCR (emulsion Polymerase Chain Reaction) can be used as it has a […]

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bioxone July 4, 2021July 3, 2021

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One of the largest icebergs of all time breaks-up

bioxone February 20, 2021February 21, 2021

Sampriti Roy, University of Calcutta Several large cracks were seen in the iceberg A-68A (that was once colossal) towards the end of January, as revealed by satellite images. The iceberg has since broken into multiple pieces. (“Antarctic icebergs are named after the Antarctic quadrant in which they were originally sighted followed by a sequential number […]

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