Flavoproteins are
proteins that contain a
nucleic acid derivative of
riboflavin. These proteins are involved in a wide array of biological processes, including removal of
radicals contributing to oxidative stress,
photosynthesis, and
DNA repair. The flavoproteins are some of the most-studied families of enzymes.
Flavoproteins have either FMN (
flavin mononucleotide) or FAD (
flavin adenine dinucleotide) as a prosthetic group or as a
cofactor. The flavin is generally tightly bound (as in
adrenodoxin reductase, wherein the FAD is buried deeply).[1] About 5-10% of flavoproteins have a covalently linked FAD.[2] Based on the available structural data, FAD-binding sites can be divided into more than 200 different types.[3]
90 flavoproteins are encoded in the human genome; about 84% require FAD and around 16% require FMN, whereas 5 proteins require both.[4] Flavoproteins are mainly located in the
mitochondria.[4] Of all flavoproteins, 90% perform redox reactions and the other 10% are
transferases,
lyases,
isomerases,
ligases.[5]
Discovery
Flavoproteins were first mentioned in 1879, when they isolated as a bright-yellow
pigment from cow's milk. They were initially termed lactochrome. By the early 1930s, this same pigment had been isolated from a range of sources, and recognised as a component of the
vitamin B complex. Its structure was determined and reported in 1935 and given the name
riboflavin, derived from the ribityl side chain and yellow colour of the conjugated ring system.[6]
The first evidence for the requirement of flavin as an
enzymecofactor came in 1935.
Hugo Theorell and coworkers showed that a bright-yellow-coloured
yeastprotein, identified previously as essential for
cellular respiration, could be separated into
apoprotein and a bright-yellow pigment. Neither apoprotein nor pigment alone could catalyse the
oxidation of
NADH, but mixing of the two restored the enzyme activity. However, replacing the isolated pigment with riboflavin did not restore enzyme activity, despite being indistinguishable under
spectroscopy. This led to the discovery that the protein studied required not riboflavin but
flavin mononucleotide to be catalytically active.[6][7]
The flavoprotein family contains a diverse range of enzymes, including:
Adrenodoxin reductase that is involved in steroid hormone synthesis in vertebrate species, and has a ubiquitous distribution in metazoa and prokaryotes[1]
^Garma, Leonardo D.; Medina, Milagros; Juffer, André H. (2016-11-01). "Structure-based classification of FAD binding sites: A comparative study of structural alignment tools". Proteins: Structure, Function, and Bioinformatics. 84 (11): 1728–1747.
doi:
10.1002/prot.25158.
ISSN1097-0134.
PMID27580869.
S2CID26066208.
^Theorell, H. (1935). "Preparation in pure state of the effect group of yellow enzymes". Biochemische Zeitschrift. 275: 344–46.
^Warburg, O.; Christian, W. (1938). "Isolation of the prosthetic group of the amino acid oxydase". Biochemische Zeitschrift. 298: 150–68.
^Christie, S. M. H.; Kenner, G. W.; Todd, A. R. (1954). "Nucleotides. Part XXV. A synthesis of flavin?adenine dinucleotide". Journal of the Chemical Society: 46–52.
doi:
10.1039/JR9540000046.
^Daniel, R.A.; Errington, J. (1993). "Cloning, DNA Sequence, Functional Analysis and Transcriptional Regulation of the Genes Encoding Dipicolinic Acid Synthetase Required for Sporulation in Bacillus subtilis". Journal of Molecular Biology. 232 (2): 468–83.
doi:
10.1006/jmbi.1993.1403.
PMID8345520.
^Clausen, Monika; Lamb, Christopher J.; Megnet, Roland; Doerner, Peter W. (1994). "PAD1 encodes phenylacrylic acid decarboxylase which confers resistance to cinnamic acid in Saccharomyces cerevisiae". Gene. 142 (1): 107–12.
doi:
10.1016/0378-1119(94)90363-8.
PMID8181743.
The menu "science" of the program
STRAP provides A comprehensive collection of all flavo-proteins with known 3D-structure. It compares the protein structures to elucidate phylogenetic relationships.