Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts:   Target Concepts:
Query: EC:1.12.7.2 (hydrogenase)
 3,522 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Enzymological studies on the multienzyme acetyl-CoA decarbonylase synthase (ACDS) complex from Methanosarcina barkeri have been conducted in order to identify and characterize physiologically relevant substrates and reactions in acetyl-CoA synthesis and decomposition in methanogens. Whereas previous investigations employed carbon monoxide as substrate and reducing agent for acetyl-CoA synthesis, we discovered that bicarbonate (or CO2) acts as a highly efficient carbonyl group precursor substrate in the presence of either hydrogen or Ti3+.EDTA as reducing agent. In reactions with Ti3+.EDTA, synthesis of acetyl-CoA was strongly dependent on ferredoxin, and in reactions with H2, dependence on ferredoxin was absolute. Two major hydrogenases were resolved from the enzyme complex preparation by HPLC gel filtration. One of these hydrogenases was shown to be active in reconstitution of acetyl-CoA synthesis in CO2-containing reactions with H2 as reducing agent. The hydrogenase active in reconstitution was capable of reducing ferredoxin, but was unreactive toward the 8-hydroxy-5-deazaflavin derivative coenzyme F420. In contrast, the hydrogenase that did not reconstitute acetyl-CoA synthesis was reactive with F420 but was unable to reduce ferredoxin. Further experiments were performed in which the value of the equilibrium constant (Keq) was determined for the reaction: H2 + CO2 + CH3-H4SPt + CoASH <--> acetyl-CoA + H4SPt + H2O, where CH3-H4SPt and H4SPt stand for N5-methyl-tetrahydrosarcinapterin and tetrahydrosarcinapterin, respectively. Keq for this reaction was found to be 2.09 x 10(6) M-1ATMH2-1 at 37 degrees C. Calculations of thermodynamic values for additional, related reactions were made and are discussed.(ABSTRACT TRUNCATED AT 250 WORDS)
 ...
PMID:Substrate and accessory protein requirements and thermodynamics of acetyl-CoA synthesis and cleavage in Methanosarcina barkeri. 771 64

Nickel is an essential nutrient for selected microorganisms where it participates in a variety of cellular processes. Many microbes are capable of sensing cellular nickel ion concentrations and taking up this nutrient via nickel-specific permeases or ATP-binding cassette-type transport systems. The metal ion is specifically incorporated into nickel-dependent enzymes, often via complex assembly processes requiring accessory proteins and additional non-protein components, in some cases accompanied by nucleotide triphosphate hydrolysis. To date, nine nickel-containing enzymes are known: urease, NiFe-hydrogenase, carbon monoxide dehydrogenase, acetyl-CoA decarbonylase/synthase, methyl coenzyme M reductase, certain superoxide dismutases, some glyoxylases, aci-reductone dioxygenase, and methylenediurease. Seven of these enzymes have been structurally characterized, revealing distinct metallocenter environments in each case.
 ...
PMID:Nickel uptake and utilization by microorganisms. 1282 70

This review describes the functions, structures, and mechanisms of nine nickel-containing enzymes: glyoxalase I, acireductone dioxygenase, urease, superoxide dismutase, [NiFe]-hydrogenase, carbon monoxide dehydrogenase, acetyl-coenzyme A synthase/decarbonylase, methyl-coenzyme M reductase, and lactate racemase. These enzymes catalyze their various chemistries by using metallocenters of diverse structures, including mononuclear nickel, dinuclear nickel, nickel-iron heterodinuclear sites, more complex nickel-containing clusters, and nickel-tetrapyrroles. Selected other enzymes are active with nickel, but the physiological relevance of this metal specificity is unclear. Additional nickel-containing proteins of undefined function have been identified.
...
PMID:Nickel-dependent metalloenzymes. 2403 22

Nickel enzymes, present in archaea, bacteria, plants, and primitive eukaryotes are divided into redox and nonredox enzymes and play key functions in diverse metabolic processes, such as energy metabolism and virulence. They catalyze various reactions by using active sites of diverse complexities, such as mononuclear nickel in Ni-superoxide dismutase, glyoxylase I and acireductone dioxygenase, dinuclear nickel in urease, heteronuclear metalloclusters in [NiFe]-carbon monoxide dehydrogenase, acetyl-CoA decarbonylase/synthase and [NiFe]-hydrogenase, and even more complex cofactors in methyl-CoM reductase and lactate racemase. The presence of metalloenzymes in a cell necessitates a tight regulation of metal homeostasis, in order to maintain the appropriate intracellular concentration of nickel while avoiding its toxicity. As well, the biosynthesis and insertion of nickel active sites often require specific and elaborated maturation pathways, allowing the correct metal to be delivered and incorporated into the target enzyme. In this review, the phylogenetic distribution of nickel enzymes will be briefly described. Their tridimensional structures as well as the complexity of their active sites will be discussed. In view of the latest findings on these enzymes, a special focus will be put on the biosynthesis of their active sites and nickel activation of apo-enzymes.
 ...
PMID:Structure, function, and biosynthesis of nickel-dependent enzymes. 3202 53