Stabilization of the catalytically active structure of a molybdenum-dependent formate dehydrogenase depends on a highly conserved lysine residue

INIS

• residues 100%
• stabilization 100%
• dehydrogenases 100%
• molybdenum 100%
• lysine 100%
• formates 100%
• escherichia coli 36%
• carbon dioxide 27%
• amino acids 18%
• values 9%
• simulation 9%
• levels 9%
• enzymes 9%
• engineering 9%
• design 9%
• energy storage 9%
• kinetics 9%
• affinity 9%
• electrons 9%
• melting points 9%
• reduction 9%
• oxidation 9%
• molecular dynamics method 9%
• mobility 9%
• catalysis 9%

Keyphrases

• Molybdenum 100%
• Lysine Residue 100%
• Formate Dehydrogenase 100%
• Active Structure 100%
• Escherichia Coli 50%
• Lysine 25%
• Formate 25%
• Occupancy 12%
• Molecular Dynamics Simulation 12%
• CO2 Utilization 12%
• Amino Acids 12%
• Spectroscopic Analysis 12%
• Melting Temperature 12%
• Km Value 12%
• Innovative Energy 12%
• Catalytic Activity 12%
• CO2 Reduction Reaction (CO2RR) 12%
• Electron Transfer 12%
• Biocatalyst 12%
• Interconversion 12%
• Formate Oxidation 12%
• Energy Storage Utilization 12%
• Support Engineering 12%
• Molybdenum Cofactor 12%
• Amino Acid Exchange 12%
• Enzyme Kinetic Analysis 12%

Chemistry

• Molybdenum 100%
• Lysine Residue 100%
• Lysine 100%
• Formate Dehydrogenase 100%
• Formate 37%
• Amino Acid 25%
• Cofactor 25%
• Melting Point 12%
• Biocatalyst 12%
• Spectroscopic Analysis 12%
• Km 12%
• Kinetic Method 12%
• Carbon Dioxide Reduction 12%
• Carbon Dioxide Utilization 12%
• Molecular Dynamics 12%
• Catalyst Activity 12%
• Carbon Dioxide 12%
• Arginine 12%
• Energy Storage 12%