CATH Classification
Level | CATH Code | Description |
---|---|---|
2 | Mainly Beta | |
2.40 | Beta Barrel | |
2.40.30 | Elongation Factor Tu (Ef-tu); domain 3 | |
2.40.30.30 | Riboflavin kinase-like |
Domain Context
CATH Clusters
Superfamily | Riboflavin kinase-like |
Functional Family | Riboflavin biosynthesis protein |
Enzyme Information
2.7.1.26 |
Riboflavin kinase.
based on mapping to UniProt Q59263
ATP + riboflavin = ADP + FMN.
-!- The cofactors FMN and FAD participate in numerous processes in all organisms, including mitochondrial electron transport, photosynthesis, fatty-acid oxidation, and metabolism of vitamin B(6), vitamin B12 and folates. -!- While monofunctional riboflavin kinase is found in eukaryotes, some bacteria have a bifunctional enzyme that exhibits both this activity and that of EC 2.7.7.2. -!- In Bacillus subtilis, ATP can be replaced by other phosphate donors but with decreasing enzyme activity in the order ATP > dATP > CTP > UTP.
|
2.7.7.2 |
FAD synthetase.
based on mapping to UniProt Q59263
ATP + FMN = diphosphate + FAD.
-!- Highly specific for ATP as phosphate donor. -!- The cofactors FMN and FAD participate in numerous processes in all organisms, including mitochondrial electron transport, photosynthesis, fatty-acid oxidation, and metabolism of vitamin B6, vitamin B12 and folates. -!- While monofunctional FAD synthetase is found in eukaryotes and in some prokaryotes, most prokaryotes have a bifunctional enzyme that exhibits both this activity and that of EC 2.7.1.26.
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UniProtKB Entries (1)
Q59263 |
RIBF_CORAM
Corynebacterium ammoniagenes
Bifunctional riboflavin kinase/FMN adenylyltransferase
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PDB Structure
PDB | 5A88 |
External Links | |
Method | X-RAY DIFFRACTION |
Organism | |
Primary Citation |
Structural Insights Into the Synthesis of Fmn in Prokaryotic Organisms.
Acta Crystallogr.,Sect.D
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