EC Number | Application | Comment | Organism |
---|---|---|---|
1.1.1.1 | biofuel production | proteome analysis as well as enzyme assays performed in cell-free extracts demonstrates that glycerol is degraded via glyceraldehyde-3-phosphate, which is further metabolized through the lower part of glycolysis leading to formation of mainly ethanol and hydrogen. Fermentation of glycerol to ethanol and hydrogen by this bacterium represents a remarkable option to add value to the biodiesel industries by utilization of surplus glycerol | Anaerobium acetethylicum |
1.1.1.6 | biofuel production | proteome analysis as well as enzyme assays performed in cell-free extracts demonstrates that glycerol is degraded via glyceraldehyde-3-phosphate, which is further metabolized through the lower part of glycolysis leading to formation of mainly ethanol and hydrogen. Fermentation of glycerol to ethanol and hydrogen by this bacterium represents a remarkable option to add value to the biodiesel industries by utilization of surplus glycerol | Anaerobium acetethylicum |
1.2.1.10 | biofuel production | proteome analysis as well as enzyme assays performed in cell-free extracts demonstrates that glycerol is degraded via glyceraldehyde-3-phosphate, which is further metabolized through the lower part of glycolysis leading to formation of mainly ethanol and hydrogen. Fermentation of glycerol to ethanol and hydrogen by this bacterium represents a remarkable option to add value to the biodiesel industries by utilization of surplus glycerol | Anaerobium acetethylicum |
1.2.1.12 | biofuel production | proteome analysis as well as enzyme assays performed in cell-free extracts demonstrates that glycerol is degraded via glyceraldehyde-3-phosphate, which is further metabolized through the lower part of glycolysis leading to formation of mainly ethanol and hydrogen. Fermentation of glycerol to ethanol and hydrogen by this bacterium represents a remarkable option to add value to the biodiesel industries by utilization of surplus glycerol | Anaerobium acetethylicum |
1.2.7.1 | biofuel production | proteome analysis as well as enzyme assays performed in cell-free extracts demonstrates that glycerol is degraded via glyceraldehyde-3-phosphate, which is further metabolized through the lower part of glycolysis leading to formation of mainly ethanol and hydrogen. Fermentation of glycerol to ethanol and hydrogen by this bacterium represents a remarkable option to add value to the biodiesel industries by utilization of surplus glycerol | Anaerobium acetethylicum |
2.3.1.8 | biofuel production | proteome analysis as well as enzyme assays performed in cell-free extracts demonstrates that glycerol is degraded via glyceraldehyde-3-phosphate, which is further metabolized through the lower part of glycolysis leading to formation of mainly ethanol and hydrogen. Fermentation of glycerol to ethanol and hydrogen by this bacterium represents a remarkable option to add value to the biodiesel industries by utilization of surplus glycerol | Anaerobium acetethylicum |
2.7.1.29 | biofuel production | proteome analysis as well as enzyme assays performed in cell-free extracts demonstrates that glycerol is degraded via glyceraldehyde-3-phosphate, which is further metabolized through the lower part of glycolysis leading to formation of mainly ethanol and hydrogen. Fermentation of glycerol to ethanol and hydrogen by this bacterium represents a remarkable option to add value to the biodiesel industries by utilization of surplus glycerol | Anaerobium acetethylicum |
2.7.1.40 | biofuel production | proteome analysis as well as enzyme assays performed in cell-free extracts demonstrates that glycerol is degraded via glyceraldehyde-3-phosphate, which is further metabolized through the lower part of glycolysis leading to formation of mainly ethanol and hydrogen. Fermentation of glycerol to ethanol and hydrogen by this bacterium represents a remarkable option to add value to the biodiesel industries by utilization of surplus glycerol | Anaerobium acetethylicum |
2.7.2.3 | biofuel production | proteome analysis as well as enzyme assays performed in cell-free extracts demonstrates that glycerol is degraded via glyceraldehyde-3-phosphate, which is further metabolized through the lower part of glycolysis leading to formation of mainly ethanol and hydrogen. Fermentation of glycerol to ethanol and hydrogen by this bacterium represents a remarkable option to add value to the biodiesel industries by utilization of surplus glycerol | Anaerobium acetethylicum |
4.2.1.11 | biofuel production | proteome analysis as well as enzyme assays performed in cell-free extracts demonstrates that glycerol is degraded via glyceraldehyde-3-phosphate, which is further metabolized through the lower part of glycolysis leading to formation of mainly ethanol and hydrogen. Fermentation of glycerol to ethanol and hydrogen by this bacterium represents a remarkable option to add value to the biodiesel industries by utilization of surplus glycerol | Anaerobium acetethylicum |
5.3.1.1 | biofuel production | proteome analysis as well as enzyme assays performed in cell-free extracts demonstrates that glycerol is degraded via glyceraldehyde-3-phosphate, which is further metabolized through the lower part of glycolysis leading to formation of mainly ethanol and hydrogen. Fermentation of glycerol to ethanol and hydrogen by this bacterium represents a remarkable option to add value to the biodiesel industries by utilization of surplus glycerol | Anaerobium acetethylicum |
5.4.2.11 | biofuel production | proteome analysis as well as enzyme assays performed in cell-free extracts demonstrates that glycerol is degraded via glyceraldehyde-3-phosphate, which is further metabolized through the lower part of glycolysis leading to formation of mainly ethanol and hydrogen. Fermentation of glycerol to ethanol and hydrogen by this bacterium represents a remarkable option to add value to the biodiesel industries by utilization of surplus glycerol | Anaerobium acetethylicum |
EC Number | Molecular Weight [Da] | Molecular Weight Maximum [Da] | Comment | Organism |
---|---|---|---|---|
1.1.1.6 | 40072 | - |
calculated from sequence | Anaerobium acetethylicum |
EC Number | Organism | UniProt | Comment | Textmining |
---|---|---|---|---|
1.1.1.1 | Anaerobium acetethylicum | A0A1D3TV27 | - |
- |
1.1.1.6 | Anaerobium acetethylicum | A0A1D3TV18 | - |
- |
1.2.1.10 | Anaerobium acetethylicum | A0A1D3TRQ6 | - |
- |
1.2.1.12 | Anaerobium acetethylicum | - |
- |
- |
1.2.7.1 | Anaerobium acetethylicum | - |
- |
- |
2.3.1.8 | Anaerobium acetethylicum | - |
- |
- |
2.7.1.29 | Anaerobium acetethylicum | A0A1D3TV19 | - |
- |
2.7.1.40 | Anaerobium acetethylicum | A0A1D3TRL9 | - |
- |
2.7.2.3 | Anaerobium acetethylicum | A0A1D3TPD1 | - |
- |
4.2.1.11 | Anaerobium acetethylicum | A0A1D3TPM8 | - |
- |
5.3.1.1 | Anaerobium acetethylicum | A0A1D3TX75 | - |
- |
5.4.2.11 | Anaerobium acetethylicum | A0A1D3TPC3 | - |
- |
5.4.2.11 | Anaerobium acetethylicum | A0A1D3TXG7 | - |
- |
EC Number | Substrates | Comment Substrates | Organism | Products | Comment (Products) | Rev. | Reac. |
---|---|---|---|---|---|---|---|
1.1.1.1 | acetaldehyde + NADH + H+ | activity of the enzyme is confirmed by proteome analysis and enzyme assays with cell extract glycerol-grown cells | Anaerobium acetethylicum | ethanol + NAD+ | - |
? | |
1.1.1.6 | glycerol + NAD+ | activity of the enzyme is confirmed by proteome analysis and enzyme assays with cell extract glycerol-grown cells | Anaerobium acetethylicum | glycerone + NADH + H+ | - |
? | |
1.2.1.10 | acetyl-CoA + NADH + H+ | activity of the enzyme is confirmed by proteome analysis and enzyme assays with cell extract glycerol-grown cells | Anaerobium acetethylicum | acetaldehyde + CoA + NAD+ | - |
? | |
1.2.1.12 | D-glyceraldehyde 3-phosphate + phosphate + NAD+ | activity of the enzyme is confirmed by proteome analysis and enzyme assays with cell extract glycerol-grown cells | Anaerobium acetethylicum | 3-phospho-D-glyceroyl phosphate + NADH + H+ | - |
? | |
1.2.7.1 | pyruvate + CoA + 2 oxidized ferredoxin | activity of the enzyme is confirmed by proteome analysis and enzyme assays with cell extract glycerol-grown cells | Anaerobium acetethylicum | acetyl-CoA + CO2 + 2 reduced ferredoxin + 2 H+ | - |
? | |
2.3.1.8 | additional information | enzymes is confirmed by total proteome analysis of glycerol-grown cells | Anaerobium acetethylicum | ? | - |
? | |
2.7.1.29 | additional information | enzyme is confirmed by total proteome analysis of glycerol-grown cells | Anaerobium acetethylicum | ? | - |
? | |
2.7.1.40 | additional information | enzyme is confirmed by total proteome analysis of glycerol-grown cells | Anaerobium acetethylicum | ? | - |
? | |
2.7.2.3 | additional information | enzymes is confirmed by total proteome analysis of glycerol-grown cells | Anaerobium acetethylicum | ? | - |
? | |
4.2.1.11 | additional information | enzymes is confirmed by total proteome analysis of glycerol-grown cells | Anaerobium acetethylicum | ? | - |
? | |
5.3.1.1 | additional information | enzyme is confirmed by total proteome analysis of glycerol-grown cells | Anaerobium acetethylicum | ? | - |
? | |
5.4.2.11 | additional information | enzymes is confirmed by total proteome analysis of glycerol-grown cells | Anaerobium acetethylicum | ? | - |
? |
EC Number | Synonyms | Comment | Organism |
---|---|---|---|
1.1.1.6 | GldA | - |
Anaerobium acetethylicum |
EC Number | pH Optimum Minimum | pH Optimum Maximum | Comment | Organism |
---|---|---|---|---|
1.1.1.6 | 7.5 | - |
assay at | Anaerobium acetethylicum |
EC Number | General Information | Comment | Organism |
---|---|---|---|
1.1.1.1 | metabolism | anaerobic fermentative metabolism of glycerol. Proteome analysis as well as enzyme assays performed in cell-free extracts demonstrate that glycerol is degraded via glyceraldehyde-3-phosphate, which is further metabolized through the lower part of glycolysis leading to formation of mainly ethanol and hydrogen | Anaerobium acetethylicum |
1.1.1.6 | metabolism | anaerobic fermentative metabolism of glycerol: proteome analysis as well as enzyme assays performed in cell-free extracts demonstrate that glycerol is degraded via glyceraldehyde-3-phosphate, which is further metabolized through the lower part of glycolysis leading to formation of mainly ethanol and hydrogen | Anaerobium acetethylicum |
1.2.1.10 | metabolism | anaerobic fermentative metabolism of glycerol. Proteome analysis as well as enzyme assays performed in cell-free extracts demonstrate that glycerol is degraded via glyceraldehyde-3-phosphate, which is further metabolized through the lower part of glycolysis leading to formation of mainly ethanol and hydrogen | Anaerobium acetethylicum |
1.2.1.12 | metabolism | anaerobic fermentative metabolism of glycerol. Proteome analysis as well as enzyme assays performed in cell-free extracts demonstrate that glycerol is degraded via glyceraldehyde-3-phosphate, which is further metabolized through the lower part of glycolysis leading to formation of mainly ethanol and hydrogen | Anaerobium acetethylicum |
1.2.7.1 | metabolism | anaerobic fermentative metabolism of glycerol. Proteome analysis as well as enzyme assays performed in cell-free extracts demonstrate that glycerol is degraded via glyceraldehyde-3-phosphate, which is further metabolized through the lower part of glycolysis leading to formation of mainly ethanol and hydrogen | Anaerobium acetethylicum |
2.3.1.8 | metabolism | anaerobic fermentative metabolism of glycerol. Proteome analysis as well as enzyme assays performed in cell-free extracts demonstrate that glycerol is degraded via glyceraldehyde-3-phosphate, which is further metabolized through the lower part of glycolysis leading to formation of mainly ethanol and hydrogen | Anaerobium acetethylicum |
2.7.1.29 | metabolism | anaerobic fermentative metabolism of glycerol. Proteome analysis as well as enzyme assays performed in cell-free extracts demonstrate that glycerol is degraded via glyceraldehyde-3-phosphate, which is further metabolized through the lower part of glycolysis leading to formation of mainly ethanol and hydrogen | Anaerobium acetethylicum |
2.7.1.40 | metabolism | anaerobic fermentative metabolism of glycerol. Proteome analysis as well as enzyme assays performed in cell-free extracts demonstrate that glycerol is degraded via glyceraldehyde-3-phosphate, which is further metabolized through the lower part of glycolysis leading to formation of mainly ethanol and hydrogen | Anaerobium acetethylicum |
2.7.2.3 | metabolism | anaerobic fermentative metabolism of glycerol. Proteome analysis as well as enzyme assays performed in cell-free extracts demonstrate that glycerol is degraded via glyceraldehyde-3-phosphate, which is further metabolized through the lower part of glycolysis leading to formation of mainly ethanol and hydrogen | Anaerobium acetethylicum |
4.2.1.11 | metabolism | anaerobic fermentative metabolism of glycerol. Proteome analysis as well as enzyme assays performed in cell-free extracts demonstrate that glycerol is degraded via glyceraldehyde-3-phosphate, which is further metabolized through the lower part of glycolysis leading to formation of mainly ethanol and hydrogen | Anaerobium acetethylicum |
5.3.1.1 | metabolism | anaerobic fermentative metabolism of glycerol. Proteome analysis as well as enzyme assays performed in cell-free extracts demonstrate that glycerol is degraded via glyceraldehyde-3-phosphate, which is further metabolized through the lower part of glycolysis leading to formation of mainly ethanol and hydrogen | Anaerobium acetethylicum |
5.4.2.11 | metabolism | anaerobic fermentative metabolism of glycerol. Proteome analysis as well as enzyme assays performed in cell-free extracts demonstrate that glycerol is degraded via glyceraldehyde-3-phosphate, which is further metabolized through the lower part of glycolysis leading to formation of mainly ethanol and hydrogen | Anaerobium acetethylicum |