|
disaccharide binding
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GO_0048030 |
[Binding to a disaccharide. Disaccharides are sugars composed of two monosaccharide units.] |
|
cellotetraose binding
|
GO_0044586 |
[Binding to a cellotetraose, an oligosaccharide consisting of four glucose residues resulting from hydrolysis of cellulose.] |
|
cellopentaose binding
|
GO_0044587 |
[Binding to a cellopentaose, an oligosaccharide consisting of four glucose residues resulting from hydrolysis of cellulose.] |
|
laminaribiose binding
|
GO_0044588 |
[Binding to laminaribiose, a disaccharide.] |
|
pectin binding
|
GO_0044589 |
[Binding to pectin.] |
|
galacturonan binding
|
GO_0048028 |
[Binding to a simple or complex galacturonan. Galacturonan is any glycan composed solely of galacturonic acid residues, a specific type of glycuronan, and a constituent of some pectins.] |
|
fatty-acyl-CoA catabolic process
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GO_0036115 |
[The chemical reactions and pathways resulting in the breakdown of a fatty-acyl-CoA, any derivative of coenzyme A in which the sulfhydryl group is in thiolester linkage with a fatty-acyl group.] |
|
butyryl-CoA catabolic process to butyrate
|
GO_0044581 |
[The chemical reactions a resulting in the resulting in the breakdown of butyryl-CoA to form butyrate.] |
|
butyrate biosynthetic process
|
GO_0046358 |
[The chemical reactions and pathways resulting in the formation of butyrate, the anion of butyric acid.] |
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cyanide catabolic process
|
GO_0019500 |
[The chemical reactions and pathways resulting in the breakdown of cyanide, NC-, the anion of hydrocyanic acid. Cyanide is a potent inhibitor of respiration.] |
|
cyanide metabolic process
|
GO_0019499 |
[The chemical reactions and pathways involving cyanide, NC-, the anion of hydrocyanic acid. Cyanide is a potent inhibitor of respiration, reacting with the ferric form of cytochrome aa3 and thus blocking the electron transport chain.] |
|
arsonoacetate catabolic process
|
GO_0019501 |
[The chemical reactions and pathways resulting in the breakdown of arsonoacetate, a synthetic, organic compound containing a single arsenic atom.] |
|
arsonoacetate metabolic process
|
GO_0018872 |
[The chemical reactions and pathways involving arsonoacetate, a synthetic, organic compound containing a single arsenic atom. Arsonoacetate and other arsenic containing compounds are used in agricultural applications as animal feed additives, cotton defoliants and post-emergence grass herbicides.] |
|
L-proline betaine metabolic process
|
GO_0019502 |
[The chemical reactions and pathways involving stachydrine, N-methylproline methylbetaine, the betaine derivative of L-proline found in alfalfa, chrysanthemum, and citrus plants.] |
|
alkaloid metabolic process
|
GO_0009820 |
[The chemical reactions and pathways involving alkaloids, nitrogen containing natural products which are not otherwise classified as peptides, nonprotein amino acids, amines, cyanogenic glycosides, glucosinolates, cofactors, phytohormones or primary metabolites (such as purine or pyrimidine bases).] |
|
amino-acid betaine metabolic process
|
GO_0006577 |
[The chemical reactions and pathways involving any betaine, the N-trimethyl derivative of an amino acid.] |
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non-proteinogenic amino acid metabolic process
|
GO_0170041 |
[The chemical reactions and pathways involving non-proteingenic amino acids.] |
|
L-amino acid metabolic process
|
GO_0170033 |
[The chemical reactions and pathways involving an L-amino acid.] |
|
L-proline betaine biosynthetic process
|
GO_0019503 |
[The chemical reactions and pathways resulting in the formation of stachydrine, N-methylproline methylbetaine, the betaine derivative of L-proline.] |
|
L-amino acid biosynthetic process
|
GO_0170034 |
[The chemical reactions and pathways resulting in the formation of L-amino acids, the L-enantiomers of amino acids.] |
