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Original: In molecular biology, the prokaryotic riboflavin biosynthesis protein is a bifunctional enzyme found in bacteria.

Riboflavin is converted into catalytically active cofactors (FAD and FMN) by the actions of riboflavin kinase EC 2.7.1.26, which converts it into FMN, and FAD synthetase EC 2.7.7.2, which adenylates FMN to FAD. Eukaryotes usually have two separate enzymes, while most prokaryotes have a single bifunctional protein that can carry out both catalyses, although exceptions occur in both cases. While eukaryotic monofunctional riboflavin kinase is orthologous to the bifunctional prokaryotic enzyme, the monofunctional FAD synthetase differs from its prokaryotic counterpart, and is instead related to the PAPS-reductase family. The bacterial FAD synthetase that is part of the bifunctional enzyme has remote similarity to nucleotidyl transferases and, hence, it may be involved in the adenylylation reaction of FAD synthetases.

Edited:

The prokaryotic riboflavin biosynthesis protein is a bifunctional enzyme found in bacteria that catalyzes the phosphorylation of riboflavin into flavin mononucleotide (FMN) and the adenylylation of FMN into flavin adenine dinucleotide (FAD).

Structure
Prokaryotic riboflavin biosynthesis proteins are also known as the prokaryotic type-I FAD synthetases, which consist of a C-terminal riboflavin kinase (RFK) and an N-terminal FMN-adenylyltransferase (FMNAT).

Mechanism
Riboflavin is converted into catalytically active cofactors FAD and FMN by the actions of riboflavin kinase EC 2.7.1.26, which converts it into FMN, and FMN adenylyltransferase EC 2.7.7.2, which adenylates FMN to FAD. The RFK module phosphorylates the riboflavin substrate and converts it into FMN, which is then released from the module. This reaction is dependent on an ATP molecule stabilized by an Mg2+ ion, which causes only a single phosphate group to leave the ATP and bond to riboflavin. The released FMN then joins to the N-terminal FMNAT module and is adenylated, with the adenylyl group of ATP attaching to the phosphate group on FMN and the diphosphate group leaving.

ATP + riboflavin ⇌ ADP + FMN

ATP + FMN ⇌ diphosphate + FAD

Phylogenetic domain comparison
Eukaryotes usually have two separate enzymes, while most prokaryotes have a single bifunctional protein that can carry out both catalyses, although exceptions occur in both cases. While eukaryotic monofunctional RFK is orthologous to the bifunctional prokaryotic RFK module, the monofunctional FMNAT differs from its prokaryotic counterpart, and is instead related to the PAPS-reductase family. The bacterial FMNAT module of the bifunctional enzyme has remote similarity to eukaryotic nucleotidyltransferases and, hence, it may be involved in the adenylylation reaction of FAD synthases.