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Literature summary extracted from
- New insights into the function and global distribution of polyethylene terephthalate (PET)-degrading bacteria and enzymes in marine and terrestrial metagenomes (2018), Appl. Environ. Microbiol., 84, e02773-17 .
Cloned(Commentary)
| EC Number | Cloned (Comment) | Organism |
|---|---|---|
| 3.1.1.101 | heterologous expression in Escherichia coli | uncultured bacterium |
Inhibitors
| EC Number | Inhibitors | Comment | Organism | Structure |
|---|---|---|---|---|
| 3.1.1.101 | acetonitrile | 30% | uncultured bacterium |  |
| 3.1.1.101 | phenylmethylsulfonyl fluoride | 10 mM | uncultured bacterium | |
| 3.1.1.101 | SDS | 5% | uncultured bacterium | |
Metals/Ions
| EC Number | Metals/Ions | Comment | Organism | Structure |
|---|---|---|---|---|
| 3.1.1.101 | rubidium | 1 mM/L increases the activity by 50% | uncultured bacterium | |
Organism
| EC Number | Organism | UniProt | Comment | Textmining |
|---|---|---|---|---|
| 3.1.1.74 | Saccharomonospora viridis | W0TJ64 | - |
- |
| 3.1.1.74 | Thermobifida alba | E9LVH7 | - |
- |
| 3.1.1.74 | Thermobifida cellulosilytica | E9LVH9 | - |
- |
| 3.1.1.74 | Thermobifida fusca | E5BBQ3 | - |
- |
| 3.1.1.74 | Thermobifida fusca | E9LVI0 | - |
- |
| 3.1.1.101 | Ideonella sakaiensis | A0A0K8P6T7 | - |
- |
| 3.1.1.101 | Saccharomonospora viridis | W0TJ64 | - |
- |
| 3.1.1.101 | Thermobifida alba | E9LVH7 | - |
- |
| 3.1.1.101 | Thermobifida cellulosilytica | E9LVH9 | - |
- |
| 3.1.1.101 | Thermobifida fusca | E5BBQ3 | - |
- |
| 3.1.1.101 | Thermobifida fusca | E9LVI0 | - |
- |
| 3.1.1.101 | Thermobifida halotolerans | H6WX58 | - |
- |
| 3.1.1.101 | Thermomonospora curvata | D1A9G5 | - |
- |
| 3.1.1.101 | Thermomonospora curvata DSM 43183 | D1A9G5 | - |
- |
| 3.1.1.101 | uncultured bacterium | C3RYL0 | - |
- |
| 3.1.1.101 | uncultured bacterium | G9BY57 | - |
- |
Synonyms
| EC Number | Synonyms | Comment | Organism |
|---|---|---|---|
| 3.1.1.74 | cut-2.KW3 | - |
Thermobifida fusca |
| 3.1.1.74 | Cut1 | - |
Thermobifida alba |
| 3.1.1.74 | Cut1 | - |
Thermobifida fusca |
| 3.1.1.74 | Cut190 | - |
Saccharomonospora viridis |
| 3.1.1.74 | Cut2 | - |
Thermobifida cellulosilytica |
| 3.1.1.74 | cutinase 1 | - |
Thermobifida fusca |
| 3.1.1.74 | PET hydrolase | - |
Saccharomonospora viridis |
| 3.1.1.101 | cut-2.KW3 | - |
Thermobifida fusca |
| 3.1.1.101 | Cut1 | - |
Thermobifida alba |
| 3.1.1.101 | Cut1 | - |
Thermobifida fusca |
| 3.1.1.101 | Cut190 | - |
Saccharomonospora viridis |
| 3.1.1.101 | Cut2 | - |
Thermobifida cellulosilytica |
| 3.1.1.101 | cutinase 1 | - |
Thermobifida fusca |
| 3.1.1.101 | ISF6_4831 | - |
Ideonella sakaiensis |
| 3.1.1.101 | PET hydrolase | - |
Saccharomonospora viridis |
| 3.1.1.101 | PET2 | - |
uncultured bacterium |
| 3.1.1.101 | Tcur_1278 | - |
Thermomonospora curvata |
Temperature Optimum [°C]
| EC Number | Temperature Optimum [°C] | Temperature Optimum Maximum [°C] | Comment | Organism |
|---|---|---|---|---|
| 3.1.1.101 | 70 | - |
- |
uncultured bacterium |
Temperature Stability [°C]
| EC Number | Temperature Stability Minimum [°C] | Temperature Stability Maximum [°C] | Comment | Organism |
|---|---|---|---|---|
| 3.1.1.101 | 90 | - |
the enzyme (PET2) retains 80% of its relative activity at 90°C after incubation for more than 5 h | uncultured bacterium |
pH Optimum
| EC Number | pH Optimum Minimum | pH Optimum Maximum | Comment | Organism |
|---|---|---|---|---|
| 3.1.1.101 | 8 | 9 | - |
uncultured bacterium |
General Information
| EC Number | General Information | Comment | Organism |
|---|---|---|---|
| 3.1.1.74 | additional information | a search algorithm that allows the in silico identification of PET hydrolase gene candidates from genomes and metagenomes is developed. 504 novel possible enzyme candidates in the UniProtKB and nonredundant RefSeq databases and the metagenomic database available in the NCBI database are identified | Thermobifida alba |
| 3.1.1.74 | additional information | a search algorithm that allows the in silico identification of PET hydrolase gene candidates from genomes and metagenomes is developed. 504 novel possible enzyme candidates in the UniProtKB and nonredundant RefSeq databases and the metagenomic database available in the NCBI database are identified | Thermobifida cellulosilytica |
| 3.1.1.74 | additional information | a search algorithm that allows the in silico identification of PET hydrolase gene candidates from genomes and metagenomes is developed. 504 novel possible enzyme candidates in the UniProtKB and nonredundant RefSeq databases and the metagenomic database available in the NCBI database are identified | Thermobifida fusca |
| 3.1.1.74 | additional information | a search algorithm that allows the in silico identification of PET hydrolase gene candidates from genomes and metagenomes is developed. 504 novel possible enzyme candidates in the UniProtKB and nonredundant RefSeq databases and the metagenomic database available in the NCBI database are identified | Saccharomonospora viridis |
| 3.1.1.101 | additional information | a search algorithm that allows the in silico identification of PET hydrolase gene candidates from genomes and metagenomes is developed. 504 novel possible enzyme candidates in the UniProtKB and nonredundant RefSeq databases and the metagenomic database available in the NCBI database are identified | Thermobifida alba |
| 3.1.1.101 | additional information | a search algorithm that allows the in silico identification of PET hydrolase gene candidates from genomes and metagenomes is developed. 504 novel possible enzyme candidates in the UniProtKB and nonredundant RefSeq databases and the metagenomic database available in the NCBI database are identified | Thermobifida cellulosilytica |
| 3.1.1.101 | additional information | a search algorithm that allows the in silico identification of PET hydrolase gene candidates from genomes and metagenomes is developed. 504 novel possible enzyme candidates in the UniProtKB and nonredundant RefSeq databases and the metagenomic database available in the NCBI database are identified | Thermobifida fusca |
| 3.1.1.101 | additional information | a search algorithm that allows the in silico identification of PET hydrolase gene candidates from genomes and metagenomes is developed. 504 novel possible enzyme candidates in the UniProtKB and nonredundant RefSeq databases and the metagenomic database available in the NCBI database are identified | uncultured bacterium |
| 3.1.1.101 | additional information | a search algorithm that allows the in silico identification of PET hydrolase gene candidates from genomes and metagenomes is developed. 504 novel possible enzyme candidates in the UniProtKB and nonredundant RefSeq databases and the metagenomic database available in the NCBI database are identified | Ideonella sakaiensis |
| 3.1.1.101 | additional information | a search algorithm that allows the in silico identification of PET hydrolase gene candidates from genomes and metagenomes is developed. 504 novel possible enzyme candidates in the UniProtKB and nonredundant RefSeq databases and the metagenomic database available in the NCBI database are identified | Thermomonospora curvata |
| 3.1.1.101 | additional information | a search algorithm that allows the in silico identification of PET hydrolase gene candidates from genomes and metagenomes is developed. 504 novel possible enzyme candidates in the UniProtKB and nonredundant RefSeq databases and the metagenomic database available in the NCBI database are identified | Saccharomonospora viridis |
| 3.1.1.101 | additional information | a search algorithm that allows the in silico identification of PET hydrolase gene candidates from genomes and metagenomes is developed. 504 novel possible enzyme candidates in the UniProtKB and nonredundant RefSeq databases and the metagenomic database available in the NCBI database are identified | Thermobifida halotolerans |
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