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Wikipedia

Flavin adenine dinucleotide

May 06, 2023

"FAD" redirects here. For other uses, see FAD (disambiguation).

In biochemistry, flavin adenine dinucleotide (FAD) is a redox-active coenzyme associated with various proteins, which is involved with several enzymatic reactions in metabolism. A flavoprotein is a protein that contains a flavin group, which may be in the form of FAD or flavin mononucleotide (FMN). Many flavoproteins are known: components of the succinate dehydrogenase complex, α-ketoglutarate dehydrogenase, and a component of the pyruvate dehydrogenase complex.

Flavin adenine dinucleotide
Identifiers
  • 146-14-5 Y
3D model (JSmol)
3DMet
  • B04792
1208946
ChEBI
  • CHEBI:16238 Y
ChEMBL
  • ChEMBL1232653 N
DrugBank
  • DB03147 Y
ECHA InfoCard 100.005.149
EC Number
  • 205-663-1
108834
  • 5184
KEGG
  • C00016 N
MeSH Flavin-Adenine+Dinucleotide
  • 643975
UNII
  • ZC44YTI8KK Y
  • DTXSID4048307
  • InChI=1S/C27H33N9O15P2/c1-10-3-12-13(4-11(10)2)35(24-18(32-12)25(42)34-27(43)33-24)5-14(37)19(39)15(38)6-48-52(44,45)51-53(46,47)49-7-16-20(40)21(41)26(50-16)36-9-31-17-22(28)29-8-30-23(17)36/h3-4,8-9,14-16,19-21,26,37-41H,5-7H2,1-2H3,(H,44,45)(H,46,47)(H2,28,29,30)(H,34,42,43)/t14-,15+,16+,19-,20+,21+,26+/m0/s1 Y[PubChem]
    Key: VWWQXMAJTJZDQX-UYBVJOGSSA-N Y[PubChem]
  • quinone form: c12cc(C)c(C)cc1N=C3C(=O)NC(=O)N=C3N2C[C@H](O)[C@H](O)[C@H](O)COP(=O)(O)OP(=O)(O)OC[C@@H]4[C@@H](O)[C@@H](O)[C@@H](O4)n5cnc6c5ncnc6N
  • semiquinone form: c12cc(C)c(C)cc1N[C]3C(=O)NC(=O)N=C3N2C[C@H](O)[C@H](O)[C@H](O)COP(=O)([O-])OP(=O)([O-])OC[C@@H]4[C@@H](O)[C@@H](O)[C@@H](O4)n5cnc6c5ncnc6N
  • hydroquinone form: c12cc(C)c(C)cc1NC=3C(=O)NC(=O)NC=3N2C[C@H](O)[C@H](O)[C@H](O)COP(=O)([O-])OP(=O)([O-])OC[C@@H]4[C@@H](O)[C@@H](O)[C@@H](O4)n5cnc6c5ncnc6N
  • flavin-N(5)-oxide form: c12cc(C)c(C)cc1[N+]([O-])=C3C(=O)NC(=O)N=C3N2C[C@H](O)[C@H](O)[C@H](O)COP(=O)(O)OP(=O)(O)OC[C@@H]4[C@@H](O)[C@@H](O)[C@@H](O4)n5cnc6c5ncnc6N
Properties
C27H33N9O15P2
Molar mass 785.557 g·mol−1
Appearance White, vitreous crystals
log P -1.336
Acidity (pKa) 1.128
Basicity (pKb) 12.8689
Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa).
N verify (what is YN ?)

FAD can exist in four redox states, which are the flavin-N(5)-oxide, quinone, semiquinone, and hydroquinone.[1] FAD is converted between these states by accepting or donating electrons. FAD, in its fully oxidized form, or quinone form, accepts two electrons and two protons to become FADH2 (hydroquinone form). The semiquinone (FADH·) can be formed by either reduction of FAD or oxidation of FADH2 by accepting or donating one electron and one proton, respectively. Some proteins, however, generate and maintain a superoxidized form of the flavin cofactor, the flavin-N(5)-oxide.[2][3]

History

Flavoproteins were first discovered in 1879 by separating components of cow's milk. They were initially called lactochrome due to their milky origin and yellow pigment.[4] It took 50 years for the scientific community to make any substantial progress in identifying the molecules responsible for the yellow pigment. The 1930s launched the field of coenzyme research with the publication of many flavin and nicotinamide derivative structures and their obligate roles in redox catalysis. German scientists Otto Warburg and Walter Christian discovered a yeast derived yellow protein required for cellular respiration in 1932. Their colleague Hugo Theorell separated this yellow enzyme into apoenzyme and yellow pigment, and showed that neither the enzyme nor the pigment was capable of oxidizing NADH on their own, but mixing them together would restore activity. Theorell confirmed the pigment to be riboflavin's phosphate ester, flavin mononucleotide (FMN) in 1937, which was the first direct evidence for enzyme cofactors.[5] Warburg and Christian then found FAD to be a cofactor of D-amino acid oxidase through similar experiments in 1938.[6] Warburg's work with linking nicotinamide to hydride transfers and the discovery of flavins paved the way for many scientists in the 40s and 50s to discover copious amounts of redox biochemistry and link them together in pathways such as the citric acid cycle and ATP synthesis.

Properties

Flavin adenine dinucleotide consists of two portions: the adenine nucleotide (adenosine monophosphate) and the flavin mononucleotide (FMN) bridged together through their phosphate groups. Adenine is bound to a cyclic ribose at the 1' carbon, while phosphate is bound to the ribose at the 5' carbon to form the adenine nucledotide. Riboflavin is formed by a carbon-nitrogen (C-N) bond between the isoalloxazine and the ribitol. The phosphate group is then bound to the terminal ribose carbon, forming a FMN. Because the bond between the isoalloxazine and the ribitol is not considered to be a glycosidic bond, the flavin mononucleotide is not truly a nucleotide.[7] This makes the dinucleotide name misleading; however, the flavin mononucleotide group is still very close to a nucleotide in its structure and chemical properties.

 
Reaction of FAD to form FADH2
 
Approximate absorption spectrum for FAD

FAD can be reduced to FADH2 through the addition of 2 H+ and 2 e. FADH2 can also be oxidized by the loss of 1 H+ and 1 e to form FADH. The FAD form can be recreated through the further loss of 1 H+ and 1 e. FAD formation can also occur through the reduction and dehydration of flavin-N(5)-oxide.[8] Based on the oxidation state, flavins take specific colors when in aqueous solution. flavin-N(5)-oxide (superoxidized) is yellow-orange, FAD (fully oxidized) is yellow, FADH (half reduced) is either blue or red based on the pH, and the fully reduced form is colorless.[9][10] Changing the form can have a large impact on other chemical properties. For example, FAD, the fully oxidized form is subject to nucleophilic attack, the fully reduced form, FADH2 has high polarizability, while the half reduced form is unstable in aqueous solution.[11] FAD is an aromatic ring system, whereas FADH2 is not.[12] This means that FADH2 is significantly higher in energy, without the stabilization through resonance that the aromatic structure provides. FADH2 is an energy-carrying molecule, because, once oxidized it regains aromaticity and releases the energy represented by this stabilization.

The spectroscopic properties of FAD and its variants allows for reaction monitoring by use of UV-VIS absorption and fluorescence spectroscopies. Each form of FAD has distinct absorbance spectra, making for easy observation of changes in oxidation state.[11] A major local absorbance maximum for FAD is observed at 450 nm, with an extinction coefficient of 11,300 M−1 cm−1.[13] Flavins in general have fluorescent activity when unbound (proteins bound to flavin nucleic acid derivatives are called flavoproteins). This property can be utilized when examining protein binding, observing loss of fluorescent activity when put into the bound state.[11] Oxidized flavins have high absorbances of about 450 nm, and fluoresce at about 515-520 nm.[9]

Chemical states

In biological systems, FAD acts as an acceptor of H+ and e in its fully oxidized form, an acceptor or donor in the FADH form, and a donor in the reduced FADH2 form. The diagram below summarizes the potential changes that it can undergo.

 

Along with what is seen above, other reactive forms of FAD can be formed and consumed. These reactions involve the transfer of electrons and the making/breaking of chemical bonds. Through reaction mechanisms, FAD is able to contribute to chemical activities within biological systems. The following pictures depict general forms of some of the actions that FAD can be involved in.

Mechanisms 1 and 2 represent hydride gain, in which the molecule gains what amounts to be one hydride ion. Mechanisms 3 and 4 radical formation and hydride loss. Radical species contain unpaired electron atoms and are very chemically active. Hydride loss is the inverse process of the hydride gain seen before. The final two mechanisms show nucleophilic addition and a reaction using a carbon radical.

 
Mechanism 1. Hydride transfer occurs by addition of H+ and 2 e
 
Mechanism 2. Hydride transfer by abstraction of hydride from NADH
 
Mechanism 3. Radical formation by electron abstraction
 
Mechanism 4. The loss of hydride to electron deficient R group
 
Mechanism 5. Use of nucleophilic addition to break R1-R2 bond
 
Mechanism 6. Carbon radical reacts with O2 and acid to form H2O2

Biosynthesis

FAD plays a major role as an enzyme cofactor along with flavin mononucleotide, another molecule originating from riboflavin.[8] Bacteria, fungi and plants can produce riboflavin, but other eukaryotes, such as humans, have lost the ability to make it.[9] Therefore, humans must obtain riboflavin, also known as vitamin B2, from dietary sources.[14] Riboflavin is generally ingested in the small intestine and then transported to cells via carrier proteins.[9] Riboflavin kinase (EC 2.7.1.26) adds a phosphate group to riboflavin to produce flavin mononucleotide, and then FAD synthetase attaches an adenine nucleotide; both steps require ATP.[9] Bacteria generally have one bi-functional enzyme, but archaea and eukaryotes usually employ two distinct enzymes.[9] Current research indicates that distinct isoforms exist in the cytosol and mitochondria.[9] It seems that FAD is synthesized in both locations and potentially transported where needed.[11]

 

Function

Flavoproteins utilize the unique and versatile structure of flavin moieties to catalyze difficult redox reactions. Since flavins have multiple redox states they can participate in processes that involve the transfer of either one or two electrons, hydrogen atoms, or hydronium ions. The N5 and C4a of the fully oxidized flavin ring are also susceptible to nucleophilic attack.[15] This wide variety of ionization and modification of the flavin moiety can be attributed to the isoalloxazine ring system and the ability of flavoproteins to drastically perturb the kinetic parameters of flavins upon binding, including flavin adenine dinucleotide (FAD).

The number of flavin-dependent protein encoded genes in the genome (the flavoproteome) is species dependent and can range from 0.1% - 3.5%, with humans having 90 flavoprotein encoded genes.[16] FAD is the more complex and abundant form of flavin and is reported to bind to 75% of the total flavoproteome[16] and 84% of human encoded flavoproteins.[17] Cellular concentrations of free or non-covalently bound flavins in a variety of cultured mammalian cell lines were reported for FAD (2.2-17.0 amol/cell) and FMN (0.46-3.4 amol/cell).[18]

FAD has a more positive reduction potential than NAD+ and is a very strong oxidizing agent. The cell utilizes this in many energetically difficult oxidation reactions such as dehydrogenation of a C-C bond to an alkene. FAD-dependent proteins function in a large variety of metabolic pathways including electron transport, DNA repair, nucleotide biosynthesis, beta-oxidation of fatty acids, amino acid catabolism, as well as synthesis of other cofactors such as CoA, CoQ and heme groups. One well-known reaction is part of the citric acid cycle (also known as the TCA or Krebs cycle); succinate dehydrogenase (complex II in the electron transport chain) requires covalently bound FAD to catalyze the oxidation of succinate to fumarate by coupling it with the reduction of ubiquinone to ubiquinol.[11] The high-energy electrons from this oxidation are stored momentarily by reducing FAD to FADH2. FADH2 then reverts to FAD, sending its two high-energy electrons through the electron transport chain; the energy in FADH2 is enough to produce 1.5 equivalents of ATP[19] by oxidative phosphorylation. Some redox flavoproteins non-covalently bind to FAD like Acetyl-CoA-dehydrogenases which are involved in beta-oxidation of fatty acids and catabolism of amino acids like leucine (isovaleryl-CoA dehydrogenase), isoleucine, (short/branched-chain acyl-CoA dehydrogenase), valine (isobutyryl-CoA dehydrogenase), and lysine (glutaryl-CoA dehydrogenase).[20] Additional examples of FAD-dependent enzymes that regulate metabolism are glycerol-3-phosphate dehydrogenase (triglyceride synthesis) and xanthine oxidase involved in purine nucleotide catabolism.[21] Noncatalytic functions that FAD can play in flavoproteins include as structural roles, or involved in blue-sensitive light photoreceptors that regulate biological clocks and development, generation of light in bioluminescent bacteria.[20]

Flavoproteins

Flavoproteins have either an FMN or FAD molecule as a prosthetic group, this prosthetic group can be tightly bound or covalently linked. Only about 5-10% of flavoproteins have a covalently linked FAD, but these enzymes have stronger redox power.[11] In some instances, FAD can provide structural support for active sites or provide stabilization of intermediates during catalysis.[20] Based on the available structural data, the known FAD-binding sites can be divided into more than 200 types.[22]

90 flavoproteins are encoded in the human genome; about 84% require FAD, and around 16% require FMN, whereas 5 proteins require both to be present.[17] Flavoproteins are mainly located in the mitochondria because of their redox power.[17] Of all flavoproteins, 90% perform redox reactions and the other 10% are transferases, lyases, isomerases, ligases.[16]

Oxidation of carbon-heteroatom bonds

Carbon-nitrogen

Monoamine oxidase (MAO) is an extensively studied flavoenzyme due to its biological importance with the catabolism of norepinephrine, serotonin and dopamine. MAO oxidizes primary, secondary and tertiary amines, which nonenzymatically hydrolyze from the imine to aldehyde or ketone. Even though this class of enzyme has been extensively studied, its mechanism of action is still being debated. Two mechanisms have been proposed: a radical mechanism and a nucleophilic mechanism. The radical mechanism is less generally accepted because no spectral or electron paramagnetic resonance evidence exists for the presence of a radical intermediate. The nucleophilic mechanism is more favored because it is supported by site-directed mutagenesis studies which mutated two tyrosine residues that were expected to increase the nucleophilicity of the substrates.[23]

 

Carbon-oxygen

Glucose oxidase (GOX) catalyzes the oxidation of β-D-glucose to D-glucono-δ-lactone with the simultaneous reduction of enzyme-bound flavin. GOX exists as a homodimer, with each subunit binding one FAD molecule. Crystal structures show that FAD binds in a deep pocket of the enzyme near the dimer interface. Studies showed that upon replacement of FAD with 8-hydroxy-5-carba-5-deaza FAD, the stereochemistry of the reaction was determined by reacting with the re face of the flavin. During turnover, the neutral and anionic semiquinones are observed which indicates a radical mechanism.[23]

 

Carbon-sulfur

Prenylcysteine lyase (PCLase) catalyzes the cleavage of prenylcysteine (a protein modification) to form an isoprenoid aldehyde and the freed cysteine residue on the protein target. The FAD is non-covalently bound to PCLase. Not many mechanistic studies have been done looking at the reactions of the flavin, but the proposed mechanism is shown below. A hydride transfer from the C1 of the prenyl moiety to FAD is proposed, resulting in the reduction of the flavin to FADH2. COformED IS a carbocation that is stabilized by the neighboring sulfur atom. FADH2 then reacts with molecular oxygen to restore the oxidized enzyme.[23]

 

Carbon-carbon

UDP-N-acetylenolpyruvylglucosamine Reductase (MurB) is an enzyme that catalyzes the NADPH-dependent reduction of enolpyruvyl-UDP-N-acetylglucosamine (substrate) to the corresponding D-lactyl compound UDP-N-acetylmuramic acid (product). MurB is a monomer and contains one FAD molecule. Before the substrate can be converted to product, NADPH must first reduce FAD. Once NADP+ dissociates, the substrate can bind and the reduced flavin can reduce the product.[23]

 

Thiol/disulfide chemistry

Glutathione reductase (GR) catalyzes the reduction of glutathione disulfide (GSSG) to glutathione (GSH). GR requires FAD and NADPH to facilitate this reaction; first a hydride must be transferred from NADPH to FAD. The reduced flavin can then act as a nucleophile to attack the disulfide, this forms the C4a-cysteine adduct. Elimination of this adduct results in a flavin-thiolate charge-transfer complex.[23]

 

Electron transfer reactions

Cytochrome P450 type enzymes that catalyze monooxygenase (hydroxylation) reactions are dependent on the transfer of two electrons from FAD to the P450. Two types of P450 systems are found in eukaryotes. The P450 systems that are located in the endoplasmic reticulum are dependent on a cytochrome P-450 reductase (CPR) that contains both an FAD and an FMN. The two electrons on reduced FAD (FADH2) are transferred one at a time to FMN and then a single electron is passed from FMN to the heme of the P450.[24]

The P450 systems that are located in the mitochondria are dependent on two electron transfer proteins: An FAD containing adrenodoxin reductase (AR) and a small iron-sulfur group containing protein named adrenodoxin. FAD is embedded in the FAD-binding domain of AR.[25][26] The FAD of AR is reduced to FADH2 by transfer of two electrons from NADPH that binds in the NADP-binding domain of AR. The structure of this enzyme is highly conserved to maintain precisely the alignment of electron donor NADPH and acceptor FAD for efficient electron transfer.[26] The two electrons in reduced FAD are transferred one a time to adrenodoxin which in turn donates the single electron to the heme group of the mitochondrial P450.[27]

The structures of the reductase of the microsomal versus reductase of the mitochondrial P450 systems are completely different and show no homology.[24]

Redox

p-Hydroxybenzoate hydroxylase (PHBH) catalyzes the oxygenation of p-hydroxybenzoate (pOHB) to 3,4-dihyroxybenzoate (3,4-diOHB); FAD, NADPH and molecular oxygen are all required for this reaction. NADPH first transfers a hydride equivalent to FAD, creating FADH, and then NADP+ dissociates from the enzyme. Reduced PHBH then reacts with molecular oxygen to form the flavin-C(4a)-hydroperoxide. The flavin hydroperoxide quickly hydroxylates pOHB, and then eliminates water to regenerate oxidized flavin.[23] An alternative flavin-mediated oxygenation mechanism involves the use of a flavin-N(5)-oxide rather than a flavin-C(4a)-(hydro)peroxide.[2][3]

 

Nonredox

Chorismate synthase (CS) catalyzes the last step in the shikimate pathway—the formation of chorismate. Two classes of CS are known, both of which require FMN, but are divided on their need for NADPH as a reducing agent. The proposed mechanism for CS involves radical species. The radical flavin species has not been detected spectroscopically without using a substrate analogue, which suggests that it is short-lived. However, when using a fluorinated substrate, a neutral flavin semiquinone was detected.[23]

 

Complex flavoenzymes

Glutamate synthase catalyzes the conversion of 2-oxoglutarate into L-glutamate with L-glutamine serving as the nitrogen source for the reaction. All glutamate syntheses are iron-sulfur flavoproteins containing an iron-sulfur cluster and FMN. The three classes of glutamate syntheses are categorized based on their sequences and biochemical properties. Even though there are three classes of this enzyme, it is believed that they all operate through the same mechanism, only differing by what first reduces the FMN. The enzyme produces two glutamate molecules: one by the hydrolysis of glutamine (forming glutamate and ammonia), and the second by the ammonia produced from the first reaction attacking 2-oxoglutarate, which is reduced by FMN to glutamate.[23]

Clinical significance

Flavoprotein-related diseases

Due to the importance of flavoproteins, it is unsurprising that approximately 60% of human flavoproteins cause human disease when mutated.[17] In some cases, this is due to a decreased affinity for FAD or FMN and so excess riboflavin intake may lessen disease symptoms, such as for multiple acyl-CoA dehydrogenase deficiency.[9] In addition, riboflavin deficiency itself (and the resulting lack of FAD and FMN) can cause health issues.[9] For example, in ALS patients, there are decreased levels of FAD synthesis.[9] Both of these paths can result in a variety of symptoms, including developmental or gastrointestinal abnormalities, faulty fat break-down, anemia, neurological problems, cancer or heart disease, migraine, worsened vision and skin lesions.[9] The pharmaceutical industry therefore produces riboflavin to supplement diet in certain cases. In 2008, the global need for riboflavin was 6,000 tons per year, with production capacity of 10,000 tons.[4] This $150 to 500 million market is not only for medical applications, but is also used as a supplement to animal food in the agricultural industry and as a food colorant.[4]

Drug design

New design of anti-bacterial medications is of continuing importance in scientific research as bacterial antibiotic resistance to common antibiotics increases. A specific metabolic protein that uses FAD (Complex II) is vital for bacterial virulence, and so targeting FAD synthesis or creating FAD analogs could be a useful area of investigation.[28] Already, scientists have determined the two structures FAD usually assumes once bound: either an extended or a butterfly conformation, in which the molecule essentially folds in half, resulting in the stacking of the adenine and isoalloxazine rings.[14] FAD imitators that are able to bind in a similar manner but do not permit protein function could be useful mechanisms of inhibiting bacterial infection.[14] Alternatively, drugs blocking FAD synthesis could achieve the same goal; this is especially intriguing because human and bacterial FAD synthesis relies on very different enzymes, meaning that a drug made to target bacterial FAD synthase would be unlikely to interfere with the human FAD synthase enzymes.[29]

Optogenetics

Optogenetics allows control of biological events in a non-invasive manner.[30] The field has advanced in recent years with a number of new tools, including those to trigger light sensitivity, such as the Blue-Light-Utilizing FAD domains (BLUF). BLUFs encode a 100 to 140 amino acid sequence that was derived from photoreceptors in plants and bacteria.[30] Similar to other photoreceptors, the light causes structural changes in the BLUF domain that results in disruption of downstream interactions.[30] Current research investigates proteins with the appended BLUF domain and how different external factors can impact the proteins.[30]

Treatment monitoring

There are a number of molecules in the body that have native fluorescence including tryptophan, collagen, FAD, NADH and porphyrins.[31] Scientists have taken advantage of this by using them to monitor disease progression or treatment effectiveness or aid in diagnosis. For instance, native fluorescence of a FAD and NADH is varied in normal tissue and oral submucous fibrosis, which is an early sign of invasive oral cancer.[31] Doctors therefore have been employing fluorescence to assist in diagnosis and monitor treatment as opposed to the standard biopsy.[31]

Additional images

See also

References

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  26. ^ a b Hanukoglu I (2017). "Conservation of the Enzyme-Coenzyme Interfaces in FAD and NADP Binding Adrenodoxin Reductase-A Ubiquitous Enzyme". Journal of Molecular Evolution. 85 (5): 205–218. Bibcode:2017JMolE..85..205H. doi:10.1007/s00239-017-9821-9. PMID 29177972. S2CID 7120148.
  27. ^ Hanukoglu I, Jefcoate CR (Apr 1980). "Mitochondrial cytochrome P-450scc. Mechanism of electron transport by adrenodoxin" (PDF). The Journal of Biological Chemistry. 255 (7): 3057–61. doi:10.1016/S0021-9258(19)85851-9. PMID 6766943.
  28. ^ McNeil MB, Fineran PC (May 2013). "Prokaryotic assembly factors for the attachment of flavin to complex II". Biochimica et Biophysica Acta (BBA) - Bioenergetics. 1827 (5): 637–47. doi:10.1016/j.bbabio.2012.09.003. PMID 22985599.
  29. ^ Serrano A, Ferreira P, Martínez-Júlvez M, Medina M (2013). "The prokaryotic FAD synthetase family: a potential drug target". Current Pharmaceutical Design. 19 (14): 2637–48. doi:10.2174/1381612811319140013. PMID 23116401.
  30. ^ a b c d Christie JM, Gawthorne J, Young G, Fraser NJ, Roe AJ (May 2012). "LOV to BLUF: flavoprotein contributions to the optogenetic toolkit". Molecular Plant. 5 (3): 533–44. doi:10.1093/mp/sss020. PMID 22431563.
  31. ^ a b c Sivabalan S, Vedeswari CP, Jayachandran S, Koteeswaran D, Pravda C, Aruna PR, Ganesan S (2010). "In vivo native fluorescence spectroscopy and nicotinamide adinine dinucleotide/flavin adenine dinucleotide reduction and oxidation states of oral submucous fibrosis for chemopreventive drug monitoring". Journal of Biomedical Optics. 15 (1): 017010–017010–11. Bibcode:2010JBO....15a7010S. doi:10.1117/1.3324771. PMID 20210484. S2CID 40028193.

External links

  • FAD bound to proteins in the PDB
  • FAD entry in the NIH Chemical Database

May 06, 2023
flavin, adenine, dinucleotide, redirects, here, other, uses, disambiguation, biochemistry, flavin, adenine, dinucleotide, redox, active, coenzyme, associated, with, various, proteins, which, involved, with, several, enzymatic, reactions, metabolism, flavoprote. FAD redirects here For other uses see FAD disambiguation In biochemistry flavin adenine dinucleotide FAD is a redox active coenzyme associated with various proteins which is involved with several enzymatic reactions in metabolism A flavoprotein is a protein that contains a flavin group which may be in the form of FAD or flavin mononucleotide FMN Many flavoproteins are known components of the succinate dehydrogenase complex a ketoglutarate dehydrogenase and a component of the pyruvate dehydrogenase complex Flavin adenine dinucleotide IdentifiersCAS Number 146 14 5 Y3D model JSmol quinone form Interactive imagesemiquinone form Interactive imagehydroquinone form Interactive imageflavin N 5 oxide form Interactive image3DMet B04792Beilstein Reference 1208946ChEBI CHEBI 16238 YChEMBL ChEMBL1232653 NDrugBank DB03147 YECHA InfoCard 100 005 149EC Number 205 663 1Gmelin Reference 108834IUPHAR BPS 5184KEGG C00016 NMeSH Flavin Adenine DinucleotidePubChem CID 643975UNII ZC44YTI8KK YCompTox Dashboard EPA DTXSID4048307InChI InChI 1S C27H33N9O15P2 c1 10 3 12 13 4 11 10 2 35 24 18 32 12 25 42 34 27 43 33 24 5 14 37 19 39 15 38 6 48 52 44 45 51 53 46 47 49 7 16 20 40 21 41 26 50 16 36 9 31 17 22 28 29 8 30 23 17 36 h3 4 8 9 14 16 19 21 26 37 41H 5 7H2 1 2H3 H 44 45 H 46 47 H2 28 29 30 H 34 42 43 t14 15 16 19 20 21 26 m0 s1 Y PubChem Key VWWQXMAJTJZDQX UYBVJOGSSA N Y PubChem SMILES quinone form c12cc C c C cc1N C3C O NC O N C3N2C C H O C H O C H O COP O O OP O O OC C H 4 C H O C H O C H O4 n5cnc6c5ncnc6Nsemiquinone form c12cc C c C cc1N C 3C O NC O N C3N2C C H O C H O C H O COP O O OP O O OC C H 4 C H O C H O C H O4 n5cnc6c5ncnc6Nhydroquinone form c12cc C c C cc1NC 3C O NC O NC 3N2C C H O C H O C H O COP O O OP O O OC C H 4 C H O C H O C H O4 n5cnc6c5ncnc6Nflavin N 5 oxide form c12cc C c C cc1 N O C3C O NC O N C3N2C C H O C H O C H O COP O O OP O O OC C H 4 C H O C H O C H O4 n5cnc6c5ncnc6NPropertiesChemical formula C 27H 33N 9O 15P 2Molar mass 785 557 g mol 1Appearance White vitreous crystalslog P 1 336Acidity pKa 1 128Basicity pKb 12 8689Except where otherwise noted data are given for materials in their standard state at 25 C 77 F 100 kPa N verify what is Y N Infobox references FAD can exist in four redox states which are the flavin N 5 oxide quinone semiquinone and hydroquinone 1 FAD is converted between these states by accepting or donating electrons FAD in its fully oxidized form or quinone form accepts two electrons and two protons to become FADH2 hydroquinone form The semiquinone FADH can be formed by either reduction of FAD or oxidation of FADH2 by accepting or donating one electron and one proton respectively Some proteins however generate and maintain a superoxidized form of the flavin cofactor the flavin N 5 oxide 2 3 Contents 1 History 2 Properties 3 Chemical states 4 Biosynthesis 5 Function 6 Flavoproteins 6 1 Oxidation of carbon heteroatom bonds 6 1 1 Carbon nitrogen 6 1 2 Carbon oxygen 6 1 3 Carbon sulfur 6 2 Carbon carbon 6 3 Thiol disulfide chemistry 6 4 Electron transfer reactions 6 5 Redox 6 6 Nonredox 6 7 Complex flavoenzymes 7 Clinical significance 7 1 Flavoprotein related diseases 7 2 Drug design 7 3 Optogenetics 7 4 Treatment monitoring 8 Additional images 9 See also 10 References 11 External linksHistory EditFlavoproteins were first discovered in 1879 by separating components of cow s milk They were initially called lactochrome due to their milky origin and yellow pigment 4 It took 50 years for the scientific community to make any substantial progress in identifying the molecules responsible for the yellow pigment The 1930s launched the field of coenzyme research with the publication of many flavin and nicotinamide derivative structures and their obligate roles in redox catalysis German scientists Otto Warburg and Walter Christian discovered a yeast derived yellow protein required for cellular respiration in 1932 Their colleague Hugo Theorell separated this yellow enzyme into apoenzyme and yellow pigment and showed that neither the enzyme nor the pigment was capable of oxidizing NADH on their own but mixing them together would restore activity Theorell confirmed the pigment to be riboflavin s phosphate ester flavin mononucleotide FMN in 1937 which was the first direct evidence for enzyme cofactors 5 Warburg and Christian then found FAD to be a cofactor of D amino acid oxidase through similar experiments in 1938 6 Warburg s work with linking nicotinamide to hydride transfers and the discovery of flavins paved the way for many scientists in the 40s and 50s to discover copious amounts of redox biochemistry and link them together in pathways such as the citric acid cycle and ATP synthesis Properties EditFlavin adenine dinucleotide consists of two portions the adenine nucleotide adenosine monophosphate and the flavin mononucleotide FMN bridged together through their phosphate groups Adenine is bound to a cyclic ribose at the 1 carbon while phosphate is bound to the ribose at the 5 carbon to form the adenine nucledotide Riboflavin is formed by a carbon nitrogen C N bond between the isoalloxazine and the ribitol The phosphate group is then bound to the terminal ribose carbon forming a FMN Because the bond between the isoalloxazine and the ribitol is not considered to be a glycosidic bond the flavin mononucleotide is not truly a nucleotide 7 This makes the dinucleotide name misleading however the flavin mononucleotide group is still very close to a nucleotide in its structure and chemical properties Reaction of FAD to form FADH2 Approximate absorption spectrum for FAD FAD can be reduced to FADH2 through the addition of 2 H and 2 e FADH2 can also be oxidized by the loss of 1 H and 1 e to form FADH The FAD form can be recreated through the further loss of 1 H and 1 e FAD formation can also occur through the reduction and dehydration of flavin N 5 oxide 8 Based on the oxidation state flavins take specific colors when in aqueous solution flavin N 5 oxide superoxidized is yellow orange FAD fully oxidized is yellow FADH half reduced is either blue or red based on the pH and the fully reduced form is colorless 9 10 Changing the form can have a large impact on other chemical properties For example FAD the fully oxidized form is subject to nucleophilic attack the fully reduced form FADH2 has high polarizability while the half reduced form is unstable in aqueous solution 11 FAD is an aromatic ring system whereas FADH2 is not 12 This means that FADH2 is significantly higher in energy without the stabilization through resonance that the aromatic structure provides FADH2 is an energy carrying molecule because once oxidized it regains aromaticity and releases the energy represented by this stabilization The spectroscopic properties of FAD and its variants allows for reaction monitoring by use of UV VIS absorption and fluorescence spectroscopies Each form of FAD has distinct absorbance spectra making for easy observation of changes in oxidation state 11 A major local absorbance maximum for FAD is observed at 450 nm with an extinction coefficient of 11 300 M 1 cm 1 13 Flavins in general have fluorescent activity when unbound proteins bound to flavin nucleic acid derivatives are called flavoproteins This property can be utilized when examining protein binding observing loss of fluorescent activity when put into the bound state 11 Oxidized flavins have high absorbances of about 450 nm and fluoresce at about 515 520 nm 9 Chemical states EditIn biological systems FAD acts as an acceptor of H and e in its fully oxidized form an acceptor or donor in the FADH form and a donor in the reduced FADH2 form The diagram below summarizes the potential changes that it can undergo Along with what is seen above other reactive forms of FAD can be formed and consumed These reactions involve the transfer of electrons and the making breaking of chemical bonds Through reaction mechanisms FAD is able to contribute to chemical activities within biological systems The following pictures depict general forms of some of the actions that FAD can be involved in Mechanisms 1 and 2 represent hydride gain in which the molecule gains what amounts to be one hydride ion Mechanisms 3 and 4 radical formation and hydride loss Radical species contain unpaired electron atoms and are very chemically active Hydride loss is the inverse process of the hydride gain seen before The final two mechanisms show nucleophilic addition and a reaction using a carbon radical Mechanism 1 Hydride transfer occurs by addition of H and 2 e Mechanism 2 Hydride transfer by abstraction of hydride from NADH Mechanism 3 Radical formation by electron abstraction Mechanism 4 The loss of hydride to electron deficient R group Mechanism 5 Use of nucleophilic addition to break R1 R2 bond Mechanism 6 Carbon radical reacts with O2 and acid to form H2O2Biosynthesis EditFAD plays a major role as an enzyme cofactor along with flavin mononucleotide another molecule originating from riboflavin 8 Bacteria fungi and plants can produce riboflavin but other eukaryotes such as humans have lost the ability to make it 9 Therefore humans must obtain riboflavin also known as vitamin B2 from dietary sources 14 Riboflavin is generally ingested in the small intestine and then transported to cells via carrier proteins 9 Riboflavin kinase EC 2 7 1 26 adds a phosphate group to riboflavin to produce flavin mononucleotide and then FAD synthetase attaches an adenine nucleotide both steps require ATP 9 Bacteria generally have one bi functional enzyme but archaea and eukaryotes usually employ two distinct enzymes 9 Current research indicates that distinct isoforms exist in the cytosol and mitochondria 9 It seems that FAD is synthesized in both locations and potentially transported where needed 11 Function EditFlavoproteins utilize the unique and versatile structure of flavin moieties to catalyze difficult redox reactions Since flavins have multiple redox states they can participate in processes that involve the transfer of either one or two electrons hydrogen atoms or hydronium ions The N5 and C4a of the fully oxidized flavin ring are also susceptible to nucleophilic attack 15 This wide variety of ionization and modification of the flavin moiety can be attributed to the isoalloxazine ring system and the ability of flavoproteins to drastically perturb the kinetic parameters of flavins upon binding including flavin adenine dinucleotide FAD The number of flavin dependent protein encoded genes in the genome the flavoproteome is species dependent and can range from 0 1 3 5 with humans having 90 flavoprotein encoded genes 16 FAD is the more complex and abundant form of flavin and is reported to bind to 75 of the total flavoproteome 16 and 84 of human encoded flavoproteins 17 Cellular concentrations of free or non covalently bound flavins in a variety of cultured mammalian cell lines were reported for FAD 2 2 17 0 amol cell and FMN 0 46 3 4 amol cell 18 FAD has a more positive reduction potential than NAD and is a very strong oxidizing agent The cell utilizes this in many energetically difficult oxidation reactions such as dehydrogenation of a C C bond to an alkene FAD dependent proteins function in a large variety of metabolic pathways including electron transport DNA repair nucleotide biosynthesis beta oxidation of fatty acids amino acid catabolism as well as synthesis of other cofactors such as CoA CoQ and heme groups One well known reaction is part of the citric acid cycle also known as the TCA or Krebs cycle succinate dehydrogenase complex II in the electron transport chain requires covalently bound FAD to catalyze the oxidation of succinate to fumarate by coupling it with the reduction of ubiquinone to ubiquinol 11 The high energy electrons from this oxidation are stored momentarily by reducing FAD to FADH2 FADH2 then reverts to FAD sending its two high energy electrons through the electron transport chain the energy in FADH2 is enough to produce 1 5 equivalents of ATP 19 by oxidative phosphorylation Some redox flavoproteins non covalently bind to FAD like Acetyl CoA dehydrogenases which are involved in beta oxidation of fatty acids and catabolism of amino acids like leucine isovaleryl CoA dehydrogenase isoleucine short branched chain acyl CoA dehydrogenase valine isobutyryl CoA dehydrogenase and lysine glutaryl CoA dehydrogenase 20 Additional examples of FAD dependent enzymes that regulate metabolism are glycerol 3 phosphate dehydrogenase triglyceride synthesis and xanthine oxidase involved in purine nucleotide catabolism 21 Noncatalytic functions that FAD can play in flavoproteins include as structural roles or involved in blue sensitive light photoreceptors that regulate biological clocks and development generation of light in bioluminescent bacteria 20 Flavoproteins EditFlavoproteins have either an FMN or FAD molecule as a prosthetic group this prosthetic group can be tightly bound or covalently linked Only about 5 10 of flavoproteins have a covalently linked FAD but these enzymes have stronger redox power 11 In some instances FAD can provide structural support for active sites or provide stabilization of intermediates during catalysis 20 Based on the available structural data the known FAD binding sites can be divided into more than 200 types 22 90 flavoproteins are encoded in the human genome about 84 require FAD and around 16 require FMN whereas 5 proteins require both to be present 17 Flavoproteins are mainly located in the mitochondria because of their redox power 17 Of all flavoproteins 90 perform redox reactions and the other 10 are transferases lyases isomerases ligases 16 Oxidation of carbon heteroatom bonds Edit Carbon nitrogen Edit Monoamine oxidase MAO is an extensively studied flavoenzyme due to its biological importance with the catabolism of norepinephrine serotonin and dopamine MAO oxidizes primary secondary and tertiary amines which nonenzymatically hydrolyze from the imine to aldehyde or ketone Even though this class of enzyme has been extensively studied its mechanism of action is still being debated Two mechanisms have been proposed a radical mechanism and a nucleophilic mechanism The radical mechanism is less generally accepted because no spectral or electron paramagnetic resonance evidence exists for the presence of a radical intermediate The nucleophilic mechanism is more favored because it is supported by site directed mutagenesis studies which mutated two tyrosine residues that were expected to increase the nucleophilicity of the substrates 23 Carbon oxygen Edit Glucose oxidase GOX catalyzes the oxidation of b D glucose to D glucono d lactone with the simultaneous reduction of enzyme bound flavin GOX exists as a homodimer with each subunit binding one FAD molecule Crystal structures show that FAD binds in a deep pocket of the enzyme near the dimer interface Studies showed that upon replacement of FAD with 8 hydroxy 5 carba 5 deaza FAD the stereochemistry of the reaction was determined by reacting with the re face of the flavin During turnover the neutral and anionic semiquinones are observed which indicates a radical mechanism 23 Carbon sulfur Edit Prenylcysteine lyase PCLase catalyzes the cleavage of prenylcysteine a protein modification to form an isoprenoid aldehyde and the freed cysteine residue on the protein target The FAD is non covalently bound to PCLase Not many mechanistic studies have been done looking at the reactions of the flavin but the proposed mechanism is shown below A hydride transfer from the C1 of the prenyl moiety to FAD is proposed resulting in the reduction of the flavin to FADH2 COformED IS a carbocation that is stabilized by the neighboring sulfur atom FADH2 then reacts with molecular oxygen to restore the oxidized enzyme 23 Carbon carbon Edit UDP N acetylenolpyruvylglucosamine Reductase MurB is an enzyme that catalyzes the NADPH dependent reduction of enolpyruvyl UDP N acetylglucosamine substrate to the corresponding D lactyl compound UDP N acetylmuramic acid product MurB is a monomer and contains one FAD molecule Before the substrate can be converted to product NADPH must first reduce FAD Once NADP dissociates the substrate can bind and the reduced flavin can reduce the product 23 Thiol disulfide chemistry Edit Glutathione reductase GR catalyzes the reduction of glutathione disulfide GSSG to glutathione GSH GR requires FAD and NADPH to facilitate this reaction first a hydride must be transferred from NADPH to FAD The reduced flavin can then act as a nucleophile to attack the disulfide this forms the C4a cysteine adduct Elimination of this adduct results in a flavin thiolate charge transfer complex 23 Electron transfer reactions Edit Cytochrome P450 type enzymes that catalyze monooxygenase hydroxylation reactions are dependent on the transfer of two electrons from FAD to the P450 Two types of P450 systems are found in eukaryotes The P450 systems that are located in the endoplasmic reticulum are dependent on a cytochrome P 450 reductase CPR that contains both an FAD and an FMN The two electrons on reduced FAD FADH2 are transferred one at a time to FMN and then a single electron is passed from FMN to the heme of the P450 24 The P450 systems that are located in the mitochondria are dependent on two electron transfer proteins An FAD containing adrenodoxin reductase AR and a small iron sulfur group containing protein named adrenodoxin FAD is embedded in the FAD binding domain of AR 25 26 The FAD of AR is reduced to FADH2 by transfer of two electrons from NADPH that binds in the NADP binding domain of AR The structure of this enzyme is highly conserved to maintain precisely the alignment of electron donor NADPH and acceptor FAD for efficient electron transfer 26 The two electrons in reduced FAD are transferred one a time to adrenodoxin which in turn donates the single electron to the heme group of the mitochondrial P450 27 The structures of the reductase of the microsomal versus reductase of the mitochondrial P450 systems are completely different and show no homology 24 Redox Edit p Hydroxybenzoate hydroxylase PHBH catalyzes the oxygenation of p hydroxybenzoate pOHB to 3 4 dihyroxybenzoate 3 4 diOHB FAD NADPH and molecular oxygen are all required for this reaction NADPH first transfers a hydride equivalent to FAD creating FADH and then NADP dissociates from the enzyme Reduced PHBH then reacts with molecular oxygen to form the flavin C 4a hydroperoxide The flavin hydroperoxide quickly hydroxylates pOHB and then eliminates water to regenerate oxidized flavin 23 An alternative flavin mediated oxygenation mechanism involves the use of a flavin N 5 oxide rather than a flavin C 4a hydro peroxide 2 3 Nonredox Edit Chorismate synthase CS catalyzes the last step in the shikimate pathway the formation of chorismate Two classes of CS are known both of which require FMN but are divided on their need for NADPH as a reducing agent The proposed mechanism for CS involves radical species The radical flavin species has not been detected spectroscopically without using a substrate analogue which suggests that it is short lived However when using a fluorinated substrate a neutral flavin semiquinone was detected 23 Complex flavoenzymes Edit Glutamate synthase catalyzes the conversion of 2 oxoglutarate into L glutamate with L glutamine serving as the nitrogen source for the reaction All glutamate syntheses are iron sulfur flavoproteins containing an iron sulfur cluster and FMN The three classes of glutamate syntheses are categorized based on their sequences and biochemical properties Even though there are three classes of this enzyme it is believed that they all operate through the same mechanism only differing by what first reduces the FMN The enzyme produces two glutamate molecules one by the hydrolysis of glutamine forming glutamate and ammonia and the second by the ammonia produced from the first reaction attacking 2 oxoglutarate which is reduced by FMN to glutamate 23 Clinical significance EditFlavoprotein related diseases Edit Due to the importance of flavoproteins it is unsurprising that approximately 60 of human flavoproteins cause human disease when mutated 17 In some cases this is due to a decreased affinity for FAD or FMN and so excess riboflavin intake may lessen disease symptoms such as for multiple acyl CoA dehydrogenase deficiency 9 In addition riboflavin deficiency itself and the resulting lack of FAD and FMN can cause health issues 9 For example in ALS patients there are decreased levels of FAD synthesis 9 Both of these paths can result in a variety of symptoms including developmental or gastrointestinal abnormalities faulty fat break down anemia neurological problems cancer or heart disease migraine worsened vision and skin lesions 9 The pharmaceutical industry therefore produces riboflavin to supplement diet in certain cases In 2008 the global need for riboflavin was 6 000 tons per year with production capacity of 10 000 tons 4 This 150 to 500 million market is not only for medical applications but is also used as a supplement to animal food in the agricultural industry and as a food colorant 4 Drug design Edit New design of anti bacterial medications is of continuing importance in scientific research as bacterial antibiotic resistance to common antibiotics increases A specific metabolic protein that uses FAD Complex II is vital for bacterial virulence and so targeting FAD synthesis or creating FAD analogs could be a useful area of investigation 28 Already scientists have determined the two structures FAD usually assumes once bound either an extended or a butterfly conformation in which the molecule essentially folds in half resulting in the stacking of the adenine and isoalloxazine rings 14 FAD imitators that are able to bind in a similar manner but do not permit protein function could be useful mechanisms of inhibiting bacterial infection 14 Alternatively drugs blocking FAD synthesis could achieve the same goal this is especially intriguing because human and bacterial FAD synthesis relies on very different enzymes meaning that a drug made to target bacterial FAD synthase would be unlikely to interfere with the human FAD synthase enzymes 29 Optogenetics Edit Optogenetics allows control of biological events in a non invasive manner 30 The field has advanced in recent years with a number of new tools including those to trigger light sensitivity such as the Blue Light Utilizing FAD domains BLUF BLUFs encode a 100 to 140 amino acid sequence that was derived from photoreceptors in plants and bacteria 30 Similar to other photoreceptors the light causes structural changes in the BLUF domain that results in disruption of downstream interactions 30 Current research investigates proteins with the appended BLUF domain and how different external factors can impact the proteins 30 Treatment monitoring Edit There are a number of molecules in the body that have native fluorescence including tryptophan collagen FAD NADH and porphyrins 31 Scientists have taken advantage of this by using them to monitor disease progression or treatment effectiveness or aid in diagnosis For instance native fluorescence of a FAD and NADH is varied in normal tissue and oral submucous fibrosis which is an early sign of invasive oral cancer 31 Doctors therefore have been employing fluorescence to assist in diagnosis and monitor treatment as opposed to the standard biopsy 31 Additional images Edit Riboflavin FADH2See also EditFMN FMO flavin containing monooxygenase NADReferences Edit Teufel Robin Agarwal Vinayak Moore Bradley S 2016 04 01 Unusual flavoenzyme catalysis in marine bacteria Current Opinion in Chemical Biology 31 31 39 doi 10 1016 j cbpa 2016 01 001 ISSN 1879 0402 PMC 4870101 PMID 26803009 a b Teufel R Miyanaga A Michaudel Q Stull F Louie G Noel JP Baran PS Palfey B Moore BS 28 November 2013 Flavin mediated dual oxidation controls an enzymatic Favorskii type rearrangement Nature 503 7477 552 6 Bibcode 2013Natur 503 552T doi 10 1038 nature12643 PMC 3844076 PMID 24162851 a b Teufel Robin Stull Frederick Meehan Michael J Michaudel Quentin Dorrestein Pieter C Palfey Bruce Moore Bradley S 2015 07 01 Biochemical Establishment and Characterization of EncM s Flavin N5 oxide Cofactor Journal of the American Chemical Society 137 25 8078 8085 doi 10 1021 jacs 5b03983 ISSN 1520 5126 PMC 4720136 PMID 26067765 a b c Abbas CA Sibirny AA Jun 2011 Genetic control of biosynthesis and transport of riboflavin and flavin nucleotides and construction of robust biotechnological producers Microbiology and Molecular Biology Reviews 75 2 321 60 doi 10 1128 mmbr 00030 10 PMC 3122625 PMID 21646432 Hayashi H 2013 B Vitamins and Folate Chemistry Analysis Function and Effects Cambridge UK The Royal Society of Chemistry p 7 ISBN 978 1 84973 369 4 Warburg O Christian W 1938 Isolation of the prosthetic group of the amino acid oxidase Biochemische Zeitschrift 298 150 168 Metzler DE Metzler CM Sauke DJ 2003 Biochemistry 2nd ed San Diego Harcourt Academic Press ISBN 978 0 12 492541 0 a b Devlin TM 2011 Textbook of Biochemistry with Clinical Correlations 7th ed Hoboken NJ John Wiley amp Sons ISBN 978 0 470 28173 4 a b c d e f g h i j k Barile M Giancaspero TA Brizio C Panebianco C Indiveri C Galluccio M Vergani L Eberini I Gianazza E 2013 Biosynthesis of flavin cofactors in man implications in health and disease Current Pharmaceutical Design 19 14 2649 75 doi 10 2174 1381612811319140014 PMID 23116402 Teufel Robin Miyanaga Akimasa Michaudel Quentin Stull Frederick Louie Gordon Noel Joseph P Baran Phil S Palfey Bruce Moore Bradley S 2013 11 28 Flavin mediated dual oxidation controls an enzymatic Favorskii type rearrangement Nature 503 7477 552 556 Bibcode 2013Natur 503 552T doi 10 1038 nature12643 ISSN 1476 4687 PMC 3844076 PMID 24162851 a b c d e f Kim HJ Winge DR May 2013 Emerging concepts in the flavinylation of succinate dehydrogenase Biochimica et Biophysica Acta BBA Bioenergetics 1827 5 627 36 doi 10 1016 j bbabio 2013 01 012 PMC 3626088 PMID 23380393 Liu S 2012 Bioprocess Engineering Kinetics Sustainability and Reactor Design Newnes ISBN 978 0 444 63783 3 Lewis JA Escalante Semerena JC Aug 2006 The FAD dependent tricarballylate dehydrogenase TcuA enzyme of Salmonella enterica converts tricarballylate into cis aconitate Journal of Bacteriology 188 15 5479 86 doi 10 1128 jb 00514 06 PMC 1540016 PMID 16855237 a b c Kuppuraj G Kruise D Yura K Nov 2014 Conformational behavior of flavin adenine dinucleotide conserved stereochemistry in bound and free states The Journal of Physical Chemistry B 118 47 13486 97 doi 10 1021 jp507629n PMID 25389798 Monteira M 2013 B Vitamins and Folate Chemistry Analysis Function and Effects Cambridge UK The Royal Society of Chemistry p 94 ISBN 978 1 84973 369 4 a b c Macheroux P Kappes B Ealick SE Aug 2011 Flavogenomics a genomic and structural view of flavin dependent proteins The FEBS Journal 278 15 2625 34 doi 10 1111 j 1742 4658 2011 08202 x PMID 21635694 S2CID 22220250 a b c d Lienhart WD Gudipati V Macheroux P Jul 2013 The human flavoproteome Archives of Biochemistry and Biophysics 535 2 150 62 doi 10 1016 j abb 2013 02 015 PMC 3684772 PMID 23500531 Huhner J Ingles Prieto A Neususs C Lammerhofer M Janovjak H Feb 2015 Quantification of riboflavin flavin mononucleotide and flavin adenine dinucleotide in mammalian model cells by CE with LED induced fluorescence detection Electrophoresis 36 4 518 25 doi 10 1002 elps 201400451 PMID 25488801 S2CID 27285540 Stryer L Berg JM Tymoczko JL 2007 Biochemistry 6th ed New York Freeman ISBN 978 0 7167 8724 2 a b c Mansoorabadi SO Thibodeaux CJ Liu HW Aug 2007 The diverse roles of flavin coenzymes nature s most versatile thespians The Journal of Organic Chemistry 72 17 6329 42 doi 10 1021 jo0703092 PMC 2519020 PMID 17580897 King MW 18 May 2020 Vitamins Minerals Supplements The Medical Biochemistry Page Garma Leonardo D Medina Milagros Juffer Andre 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 ISSN 1097 0134 PMID 27580869 S2CID 26066208 a b c d e f g h Fagan RL Palfey BA 2010 Flavin Dependent Enzymes Comprehensive Natural Products II Chemistry and Biology 7 37 113 a b Hanukoglu I 1996 Electron transfer proteins of cytochrome P450 systems PDF Adv Mol Cell Biol Advances in Molecular and Cell Biology 14 29 55 doi 10 1016 S1569 2558 08 60339 2 ISBN 9780762301133 Ziegler GA Vonrhein C Hanukoglu I Schulz GE Jun 1999 The structure of adrenodoxin reductase of mitochondrial P450 systems electron transfer for steroid biosynthesis Journal of Molecular Biology 289 4 981 90 doi 10 1006 jmbi 1999 2807 PMID 10369776 a b Hanukoglu I 2017 Conservation of the Enzyme Coenzyme Interfaces in FAD and NADP Binding Adrenodoxin Reductase A Ubiquitous Enzyme Journal of Molecular Evolution 85 5 205 218 Bibcode 2017JMolE 85 205H doi 10 1007 s00239 017 9821 9 PMID 29177972 S2CID 7120148 Hanukoglu I Jefcoate CR Apr 1980 Mitochondrial cytochrome P 450scc Mechanism of electron transport by adrenodoxin PDF The Journal of Biological Chemistry 255 7 3057 61 doi 10 1016 S0021 9258 19 85851 9 PMID 6766943 McNeil MB Fineran PC May 2013 Prokaryotic assembly factors for the attachment of flavin to complex II Biochimica et Biophysica Acta BBA Bioenergetics 1827 5 637 47 doi 10 1016 j bbabio 2012 09 003 PMID 22985599 Serrano A Ferreira P Martinez Julvez M Medina M 2013 The prokaryotic FAD synthetase family a potential drug target Current Pharmaceutical Design 19 14 2637 48 doi 10 2174 1381612811319140013 PMID 23116401 a b c d Christie JM Gawthorne J Young G Fraser NJ Roe AJ May 2012 LOV to BLUF flavoprotein contributions to the optogenetic toolkit Molecular Plant 5 3 533 44 doi 10 1093 mp sss020 PMID 22431563 a b c Sivabalan S Vedeswari CP Jayachandran S Koteeswaran D Pravda C Aruna PR Ganesan S 2010 In vivo native fluorescence spectroscopy and nicotinamide adinine dinucleotide flavin adenine dinucleotide reduction and oxidation states of oral submucous fibrosis for chemopreventive drug monitoring Journal of Biomedical Optics 15 1 017010 017010 11 Bibcode 2010JBO 15a7010S doi 10 1117 1 3324771 PMID 20210484 S2CID 40028193 External links EditFAD bound to proteins in the PDB FAD entry in the NIH Chemical Database Retrieved from https en wikipedia org w index php title Flavin adenine dinucleotide amp oldid 1123584285, wikipedia, wiki, book, books, library,

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