Four steps of molybdenum cofactor (Moco) biosynthetic pathway occurring in bacteria and humans: (i) radical-mediated cyclization guanosine 5'-triphosphate (GTP) to (8S)‑3,8‐cyclo‑7,8‑dihydroguanosine-5́‑triphosphate (3,8‑cH2GTP), (ii) formation of cyclic pyranopterin monophosphate (cPMP) from the 3,8‑cH2GTP, (iii) conversion of cPMP into molybdopterin (MPT), (iv) insertion of molybdate into MPT to form Moco (human enzymes in parentheses).
Molybdopterins are a class of cofactors found in most molybdenum-containing and all tungsten-containing enzymes. Synonyms for molybdopterin are: MPT and pyranopterin-dithiolate. The nomenclature for this biomolecule can be confusing: Molybdopterin itself contains no molybdenum; rather, this is the name of the ligand (apterin) that will bind the active metal. After molybdopterin is eventually complexed with molybdenum, the complete ligand is usually called molybdenum cofactor.
The only molybdenum-containing enzymes that do not feature molybdopterins are the nitrogenases (enzymes that fix nitrogen). These contain an iron-sulfur center of a very different type, which also contains molybdenum.[5]
Unlike many other cofactors, molybdenum cofactor (Moco) cannot be taken up as a nutrient. The cofactor thus requires de novo biosynthesis. Molybdenum cofactor biosynthesis occurs in four steps: (i) the radical-mediated cyclization of nucleotide, guanosine triphosphate (GTP), to (8S)‑3',8‐cyclo‑7,8‑dihydroguanosine 5'‑triphosphate (3',8‑cH2GTP), (ii) the formation of cyclic pyranopterin monophosphate (cPMP) from the 3',8‑cH2GTP, (iii) the conversion of cPMP into molybdopterin (MPT), (iv) the insertion of molybdate into MPT to form Moco.[6][7]
Two enzyme-mediated reactions convert guanosine triphosphate to the cyclic phosphate of pyranopterin. One of these enzymes is a radical SAM, a family of enzymes often associated with C—X bond-forming reactions (X = S, N).[8][7][6] This intermediate pyranopterin is then converted to the molybdopterin via the action of three further enzymes. In this conversion, the enedithiolate is formed, although the substituents on sulfur remain unknown. Sulfur is conveyed from cysteinyl persulfide in a manner reminiscent of the biosynthesis of iron-sulfur proteins. The monophosphate is adenylated (coupled to ADP) in a step that activates the cofactor toward binding Mo or W. These metals are imported as their oxyanions, molybdate, and tungstate.
In some enzymes, such as xanthine oxidase, the metal is bound to one molybdopterin, whereas, in other enzymes, e.g., DMSO reductase, the metal is bound to two molybdopterin cofactors.[9]
Models for the active sites of enzymes molybdopterin-containing enzymes are based on a class of ligands known as dithiolenes.[10]
Some bacterial oxidoreductases use tungsten in a similar manner as molybdenum by using it in a tungsten-pterin complex, with molybdopterin. Thus, molybdopterin may complex with either molybdenum or tungsten. Tungsten-using enzymes typically reduce free carboxylic acids to aldehydes.[11]
The first tungsten-requiring enzyme to be discovered also requires selenium (though the precise form is unknown). In this case, the tungsten-selenium pair has been speculated to function analogously to the molybdenum-sulfur pairing of some molybdenum cofactor-requiring enzymes.[12] Although a tungsten-containing xanthine dehydrogenase from bacteria has been found to contain tungsten-molybdopterin and also non-protein-bound selenium (thus removing the possibility of selenium in selenocysteineorselenomethionine form), a tungsten-selenium molybdopterin complex has not been definitively described.[13]
