Basic Information
Gene Structure
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Domain
| Database | EntryID | E-Value | Start | end | InterPro ID | Description |
|---|
Regulation&Interaction
Annotation
Orthologous Group
| Orthologous ID | Species Number | All hits in PereRegDB | Hits of this species | Orthologous Detail |
|---|
Expression Profile
| DataSet | Number of Samples expressed(TPM>1) | Mean | Min | Max | Standard deviation(SD) | Coeffcient variation(CV) |
|---|
Pathway
| GO Term | Description | GO Category |
|---|---|---|
| GO:0003674 | molecular_function | MF |
| GO:0003824 | catalytic activity | MF |
| GO:0006082 | organic acid metabolic process | BP |
| GO:0006520 | amino acid metabolic process | BP |
| GO:0006807 | nitrogen compound metabolic process | BP |
| GO:0008150 | biological_process | BP |
| GO:0008152 | metabolic process | BP |
| GO:0008652 | amino acid biosynthetic process | BP |
| GO:0009058 | biosynthetic process | BP |
| GO:0009692 | ethylene metabolic process | BP |
| GO:0009693 | ethylene biosynthetic process | BP |
| GO:0009987 | cellular process | BP |
| GO:0010817 | regulation of hormone levels | BP |
| GO:0016053 | organic acid biosynthetic process | BP |
| GO:0016829 | lyase activity | MF |
| GO:0016846 | carbon-sulfur lyase activity | MF |
| GO:0016847 | 1-aminocyclopropane-1-carboxylate synthase activity | MF |
| GO:0018871 | 1-aminocyclopropane-1-carboxylate metabolic process | BP |
| GO:0019752 | carboxylic acid metabolic process | BP |
| GO:0032787 | monocarboxylic acid metabolic process | BP |
| GO:0042218 | 1-aminocyclopropane-1-carboxylate biosynthetic process | BP |
| GO:0042445 | hormone metabolic process | BP |
| GO:0042446 | hormone biosynthetic process | BP |
| GO:0043436 | oxoacid metabolic process | BP |
| GO:0043449 | cellular alkene metabolic process | BP |
| GO:0043450 | alkene biosynthetic process | BP |
| GO:0044237 | cellular metabolic process | BP |
| GO:0044238 | primary metabolic process | BP |
| GO:0044249 | cellular biosynthetic process | BP |
| GO:0044281 | small molecule metabolic process | BP |
| GO:0044283 | small molecule biosynthetic process | BP |
| GO:0046394 | carboxylic acid biosynthetic process | BP |
| GO:0065007 | biological regulation | BP |
| GO:0065008 | regulation of biological quality | BP |
| GO:0071704 | organic substance metabolic process | BP |
| GO:0072330 | monocarboxylic acid biosynthetic process | BP |
| GO:1900673 | olefin metabolic process | BP |
| GO:1900674 | olefin biosynthetic process | BP |
| GO:1901564 | organonitrogen compound metabolic process | BP |
| GO:1901566 | organonitrogen compound biosynthetic process | BP |
| GO:1901576 | organic substance biosynthetic process | BP |
| GO:1901605 | alpha-amino acid metabolic process | BP |
| GO:1901607 | alpha-amino acid biosynthetic process | BP |
| KEGG Term | Name | Description |
|---|---|---|
| map01110 | Biosynthesis of secondary metabolites | - |
| map01110 | Biosynthesis of secondary metabolites | - |
| map01100 | Metabolic pathways | - |
| map01100 | Metabolic pathways | - |
| map00270 | Cysteine and methionine metabolism | Cysteine and methionine are sulfur-containing amino acids. Cysteine is synthesized from serine through different pathways in different organism groups. In bacteria and plants, cysteine is converted from serine (via acetylserine) by transfer of hydrogen sulfide [MD:M00021]. In animals, methionine-derived homocysteine is used as sulfur source and its condensation product with serine (cystathionine) is converted to cysteine [MD:M00338]. Cysteine is metabolized to pyruvate in multiple routes. Methionine is an essential amino acid, which animals cannot synthesize. In bacteria and plants, methionine is synthesized from aspartate [MD:M00017]. S-Adenosylmethionine (SAM), synthesized from methionine and ATP, is a methyl group donor in many important transfer reactions including DNA methylation for regulation of gene expression. SAM may also be used to regenerate methionine in the methionine salvage pathway [MD:M00034]. |
| map00270 | Cysteine and methionine metabolism | Cysteine and methionine are sulfur-containing amino acids. Cysteine is synthesized from serine through different pathways in different organism groups. In bacteria and plants, cysteine is converted from serine (via acetylserine) by transfer of hydrogen sulfide [MD:M00021]. In animals, methionine-derived homocysteine is used as sulfur source and its condensation product with serine (cystathionine) is converted to cysteine [MD:M00338]. Cysteine is metabolized to pyruvate in multiple routes. Methionine is an essential amino acid, which animals cannot synthesize. In bacteria and plants, methionine is synthesized from aspartate [MD:M00017]. S-Adenosylmethionine (SAM), synthesized from methionine and ATP, is a methyl group donor in many important transfer reactions including DNA methylation for regulation of gene expression. SAM may also be used to regenerate methionine in the methionine salvage pathway [MD:M00034]. |