Biotin Synthase | |||||||||
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Identifiers | |||||||||
EC no. | 2.8.1.6 | ||||||||
CAS no. | 80146-93-6 | ||||||||
Databases | |||||||||
IntEnz | IntEnz view | ||||||||
BRENDA | BRENDA entry | ||||||||
ExPASy | NiceZyme view | ||||||||
KEGG | KEGG entry | ||||||||
MetaCyc | metabolic pathway | ||||||||
PRIAM | profile | ||||||||
PDB structures | RCSB PDB PDBe PDBsum | ||||||||
Gene Ontology | AmiGO / QuickGO | ||||||||
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Biotin synthase (BioB) (EC 2.8.1.6) is an enzyme that catalyzes the conversion of dethiobiotin (DTB) to biotin; this is the final step in the biotin biosynthetic pathway. Biotin, also known as vitamin B7, is a cofactor used in carboxylation, decarboxylation, and transcarboxylation reactions in many organisms including humans. [1] Biotin synthase is an S-Adenosylmethionine (SAM) dependent enzyme that employs a radical mechanism to thiolate dethiobiotin, thus converting it to biotin.
This radical SAM enzyme belongs to the family of transferases, specifically the sulfurtransferases, which transfer sulfur-containing groups. The systematic name of this enzyme class is dethiobiotin:sulfur sulfurtransferase. This enzyme participates in biotin metabolism. It employs one cofactor, iron-sulfur.
In 2004, the crystal structure of biotin synthase in complex with SAM and dethiobiotin was determined to 3.4 angstrom resolution. [2] The PDB accession code for this structure is 1R30. The protein is a homodimer, meaning it is composed of two identical amino acid chains that fold together to form biotin synthase. Each monomer in the structure shown in figure contains a TIM barrel with an [4Fe-4S]2+cluster, SAM, and an [2Fe-2S]2+cluster.
The [4Fe-4S]2+cluster is used as a catalytic cofactor, directly coordinating to SAM. Orbital overlap between SAM and a unique Fe atom on the [4Fe-4S]2+cluster has been observed. [3] The predicted role of the [4Fe-4S]2+cofactor is to transfer an electron onto SAM through an inner sphere mechanism, forcing it into an unstable high energy state that ultimately leads to the formation of the 5’deoxyadenosyl radical. [4]
The [2Fe-2S]2+cluster is thought to provide a source of sulfur from which to thiolate DTB. Isotopic labelling [5] and spectroscopic studies [6] show destruction of the [2Fe-2S]2+cluster accompanies BioB turnover, indicating that it is likely sulfur from [2Fe-2S]2+that is being incorporated into DTB to form biotin.
The reaction catalyzed by biotin synthase can be summarized as follows:
dethiobiotin + sulfur + 2 S-adenosyl-L-methionine biotin + 2 L-methionine + 2 5'-deoxyadenosine
The proposed mechanism for biotin synthase begins with an inner sphere electron transfer from the sulfur on SAM, reducing the [4Fe-4S]2+cluster. This results in a spontaneous C-S bond cleavage, generating a 5’-deoxyadenosyl radical (5’-dA). [7] This carbon radical abstracts a hydrogen from dethiobiotin, forming a dethiobiotinyl C9 carbon radical, which is immediately quenched by bonding to a sulfur atom on the [2Fe-2S]2+. This reduces one of the iron atoms from FeIII to FeII. At this point, the 5’-deoxyadenosyl and methionine formed earlier are exchanged for a second equivalent of SAM. Reductive cleavage generates another 5’-deoxyadenosyl radical, which abstracts a hydrogen from C6 of dethiobiotin. This radical attacks the sulfur attached to C9 and forms the thiophane ring of biotin, leaving behind an unstable diferrous cluster that likely dissociates. [8] [9]
The use of an inorganic sulfur source is quite unusual for biosynthetic reactions involving sulfur. However, dethiobiotin contains nonpolar, unactivated carbon atoms at the locations of desired C-S bond formation. The formation of the 5’-dA radical allows for hydrogen abstraction of the unactivated carbons on DTB, leaving behind activated carbon radicals ready to be functionalized. By nature, radical chemistry allows for chain reactions because radicals are easily quenched through C-H bond formation, resulting in another radical on the atom the hydrogen came from. We can consider the possibility of a free sulfide, alkane thiol, or alkane persulfide being used as the sulfur donor for DTB. At physiological pH, these would all be protonated, and the carbon radical would likely be quenched by hydrogen atom transfer rather than by C-S bond formation. [10]
Biotin synthase is not found in humans. Since biotin is an important cofactor for many enzymes, humans must consume biotin through their diet from microbial and plant sources. [11] However, the human gut microbiome has been shown to contain Escherichia coli that do contain biotin synthase, [12] providing another source of biotin for catalytic use. The amount of E. coli that produce biotin is significantly higher in adults than in babies, indicating that the gut microbiome and developmental stage should be taken into account when assessing a person's nutritional needs. [13]
Oxidative phosphorylation or electron transport-linked phosphorylation or terminal oxidation is the metabolic pathway in which cells use enzymes to oxidize nutrients, thereby releasing chemical energy in order to produce adenosine triphosphate (ATP). In eukaryotes, this takes place inside mitochondria. Almost all aerobic organisms carry out oxidative phosphorylation. This pathway is so pervasive because it releases more energy than alternative fermentation processes such as anaerobic glycolysis.
Iron–sulfur clusters are molecular ensembles of iron and sulfide. They are most often discussed in the context of the biological role for iron–sulfur proteins, which are pervasive. Many Fe–S clusters are known in the area of organometallic chemistry and as precursors to synthetic analogues of the biological clusters. It is believed that the last universal common ancestor had many iron-sulfur clusters.
Succinate dehydrogenase (SDH) or succinate-coenzyme Q reductase (SQR) or respiratory complex II is an enzyme complex, found in many bacterial cells and in the inner mitochondrial membrane of eukaryotes. It is the only enzyme that participates in both the citric acid cycle and the electron transport chain. Histochemical analysis showing high succinate dehydrogenase in muscle demonstrates high mitochondrial content and high oxidative potential.
Ferredoxins are iron–sulfur proteins that mediate electron transfer in a range of metabolic reactions. The term "ferredoxin" was coined by D.C. Wharton of the DuPont Co. and applied to the "iron protein" first purified in 1962 by Mortenson, Valentine, and Carnahan from the anaerobic bacterium Clostridium pasteurianum.
Iron–sulfur proteins are proteins characterized by the presence of iron–sulfur clusters containing sulfide-linked di-, tri-, and tetrairon centers in variable oxidation states. Iron–sulfur clusters are found in a variety of metalloproteins, such as the ferredoxins, as well as NADH dehydrogenase, hydrogenases, coenzyme Q – cytochrome c reductase, succinate – coenzyme Q reductase and nitrogenase. Iron–sulfur clusters are best known for their role in the oxidation-reduction reactions of electron transport in mitochondria and chloroplasts. Both Complex I and Complex II of oxidative phosphorylation have multiple Fe–S clusters. They have many other functions including catalysis as illustrated by aconitase, generation of radicals as illustrated by SAM-dependent enzymes, and as sulfur donors in the biosynthesis of lipoic acid and biotin. Additionally, some Fe–S proteins regulate gene expression. Fe–S proteins are vulnerable to attack by biogenic nitric oxide, forming dinitrosyl iron complexes. In most Fe–S proteins, the terminal ligands on Fe are thiolate, but exceptions exist.
Methionine synthase also known as MS, MeSe, MTR is responsible for the regeneration of methionine from homocysteine. In humans it is encoded by the MTR gene (5-methyltetrahydrofolate-homocysteine methyltransferase). Methionine synthase forms part of the S-adenosylmethionine (SAMe) biosynthesis and regeneration cycle, and is the enzyme responsible for linking the cycle to one-carbon metabolism via the folate cycle. There are two primary forms of this enzyme, the Vitamin B12 (cobalamin)-dependent (MetH) and independent (MetE) forms, although minimal core methionine synthases that do not fit cleanly into either category have also been described in some anaerobic bacteria. The two dominant forms of the enzymes appear to be evolutionary independent and rely on considerably different chemical mechanisms. Mammals and other higher eukaryotes express only the cobalamin-dependent form. In contrast, the distribution of the two forms in Archaeplastida (plants and algae) is more complex. Plants exclusively possess the cobalamin-independent form, while algae have either one of the two, depending on species. Many different microorganisms express both the cobalamin-dependent and cobalamin-independent forms.
Lysine 2,3-aminomutase is a radical SAM enzyme that facilitates the conversion of the amino acid lysine to beta-lysine. It accomplishes this interconversion using three cofactors and a 5'-deoxyadenosyl radical formed in a S-Adenosyl methionine (SAM) activated radical reaction pathway.[1] The generalized reaction is shown below:
Formate dehydrogenases are a set of enzymes that catalyse the oxidation of formate to carbon dioxide, donating the electrons to a second substrate, such as NAD+ in formate:NAD+ oxidoreductase (EC 1.17.1.9) or to a cytochrome in formate:ferricytochrome-b1 oxidoreductase (EC 1.2.2.1). This family of enzymes has attracted attention as inspiration or guidance on methods for the carbon dioxide fixation, relevant to global warming.
In enzymology, carbon monoxide dehydrogenase (CODH) (EC 1.2.7.4) is an enzyme that catalyzes the chemical reaction
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The fnr gene of Escherichia coli encodes a transcriptional activator (FNR) which is required for the expression of a number of genes involved in anaerobic respiratory pathways. The FNR protein of E. coli is an oxygen – responsive transcriptional regulator required for the switch from aerobic to anaerobic metabolism.
"Type III mutants, originally frdB, were designated fnr because they were defective in fumarate and nitrate reduction and impaired in their ability to produce gas." - Lambden and Guest, 1976 Journal of General Microbiology97, 145-160
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Squire Booker is an American biochemist at Penn State University. Booker directs an interdisciplinary chemistry research program related to fields of biochemistry, enzymology, protein chemistry, natural product biosynthesis, and mechanisms of radical dependent enzymes. He is an associate editor for the American Chemical Society Biochemistry Journal, is a Hughes Medical Institute Investigator, and an Eberly Distinguished Chair in Science at Penn State University.
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