Monooxygenase

About: Monooxygenase is a research topic. Over the lifetime, 2692 publications have been published within this topic receiving 100245 citations.

Growth of Rhodococcus sp. strain BCP1 on gaseous n-alkanes: new metabolic insights and transcriptional analysis of two soluble di-iron monooxygenase genes.

Abstract: Rhodococcus sp. strain BCP1 was initially isolated for its ability to grow on gaseous n-alkanes, which act as inducers for the co-metabolic degradation of low-chlorinated compounds. Here, both molecular and metabolic features of BCP1 cells grown on gaseous and short-chain n-alkanes (up to n-heptane) were examined in detail. We show that propane metabolism generated terminal and sub-terminal oxidation products such as 1- and 2-propanol, whereas 1-butanol was the only terminal oxidation product detected from butane metabolism. Two gene clusters, prmABCD and smoABCD – coding for soluble di-iron monooxgenases (SDIMOs) involved in gaseous n-alkanes oxidation – were detected in the BCP1 genome. By means of reverse transcriptase-quantitative PCR (RT-qPCR) analysis, a set of substrates inducing the expression of the sdimo genes in BCP1 were assessed as well as their transcriptional repression in the presence of sugars, organic acids or during the cell growth on rich medium (Luria Bertani broth). The transcriptional start sites of both the sdimo gene clusters were identified by means of primer extension experiments. Finally, proteomic studies revealed changes in the protein pattern induced by growth on gaseous- (n-butane) and/or liquid (n-hexane) short-chain n-alkanes as compared to growth on succinate. Among the differently expressed protein spots, two chaperonins and an isocytrate lyase were identified along with oxidoreductases involved in oxidation reactions downstream of the initial monooxygenase reaction step.

Hydrocarbon hydroxylation by cytochrome P450 enzymes.

Abstract: In chemical terms, the regio- and stereoselective hydroxylation of hydrocarbon C-H bonds is a very difficult transformation. Nevertheless, these reactions are deftly catalyzed by a variety of metalloenzymes, among which the most diverse are the many members of the cytochrome P450 family. Cytochrome P450 enzymes are found in most classes of organisms, including bacteria, fungi, plants, insects, and mammals. Thousands of such proteins are now known (http://drnelson.utmem.edu/cytochromeP450.html), including 57 in the human genome (1), 20 in Mycobacterium tuberculosis (2), 272 in Arabidopsis (3), and the amazing number of 457 in rice (4). The nomenclature for these enzymes is based on their sequence similarity when appropriately aligned, a somewhat arbitrary similarity cutoff (approximately >40% identity) being used to define members of a family and a higher cutoff (approximately >55% identity) members of a subfamily (5). Thus CYP3A4 corresponds to the fourth enzyme in family 3, subfamily A. This nomenclature allows the naming of enzymes without regard to their origin or specific properties. The mammalian, plant, and fungal proteins are commonly membrane bound and are relatively difficult to manipulate, but the bacterial proteins are usually soluble, monomeric proteins. For that reason, much of the early research on mechanisms of cytochrome P450 enzymes was carried out with bacterial enzymes, particularly with the prototypical enzyme CYP101 (P450cam) from Pseudomonas putida (6, 7). From a chemist's point of view, there is a particular interest in the thermophilic enzymes, which currently include CYP119 (8-10), P450st (11), CYP174A1 (12), and CYP231A2 (13). The thermal stability of these enzymes makes them attractive starting points for the development of industrially useful catalysts. In this context, particular attention has also focused on CYP102 (P450BM3), a self-sufficient enzyme from Bacillus megaterium in which the flavoprotein protein required for transfer of electrons from NADPH is fused to the hemoprotein (14). The resulting simplicity and high catalytic rate have led to extensive efforts to engineer this protein for practical catalytic purposes (15-19). Although these proteins have properties that make them particularly attractive for engineering purposes, the large reservoir of P450 enzymes that collectively catalyze an astounding diversity of reactions suggests that P450 catalysis will develop into a highly useful technology. The cytochrome P450 enzymes are defined by the presence in the proteins of a heme (iron protoporphyrin IX) prosthetic group coordinated on the proximal side by a thiolate ion (20, 21). This feature gives rise to the spectroscopic signature that defines these enzymes, as the thiolate-ligated ferrous-CO complex is characterized by a Soret absorption maximum at ∼450 nm (21). A thiolate-coordinated heme group is present in all P450 enzymes, although not all proteins with such coordination are members of this superfamily. One obvious exception, for example, is chloroperoxidase, which has a thiolate-coordinated heme group but normally catalyzes a very different reaction than the P450 enzymes (21-23). Although there are unusual P450 enzymes, such as the thromboxane and prostacyclin synthases (24), or CYP152 from Sphingomonas paucimobilis or Bacillus subtilis (25, 26), that normally utilize peroxides as substrates, the defining reaction for P450 enzymes is the reductive activation of molecular oxygen. In this reaction, one of the oxygen atoms of molecular oxygen is inserted into the substrate and the other oxygen atom is reduced to a molecule of water. With one exception to date (27, 28), the electrons required for this reduction of molecular oxygen derive from reduced pyridine nucleotides (NADH or NADPH). The overall equation for the reaction thus adheres to the formula: RH + NAD(P)H + O2 + H+ -> ROH + NAD(P)+ + H2O, where RH stands for a substrate with a hydroxylatable site. P450 enzymes therefore belong to the monooxygenase class of enzymes that only insert one of the oxygen atoms of molecular oxygen into their substrates. However, under appropriate circumstances or with specific substrates, other P450-catalyzed reactions can be observed, including desaturation, carbon-carbon bond scission, and carbon-carbon bond formation (29, 30). This review specifically focuses on P450-catalyzed hydrocarbon hydroxylation, the reaction that is most characteristic of P450 enzymes and that has been most extensively investigated. However, the principles that apply in these reactions also apply to other hydroxylation reactions, including those that occur on carbons adjacent to nitrogen, sulfur, or oxygen.

Cytochrome P-4502E1: its physiological and pathological role

Abstract: The role of the microsomal ethanol-oxidizing system (MEOS) in hepatic ethanol metabolism is reviewed, with focus on its constitutive, ethanol-inducible cytochrome P-4502E1 (2E1). The MEOS was purified and reconstituted using 2E1, phospholipids, and cytochrome P-450 reductase and shown to oxidize ethanol to acetaldehyde, mainly as a monooxygenase and secondarily via hydroxyl radicals, with transcriptional and posttranscriptional regulation. Polymorphism of 2E1 was recognized, and enzymology (including cofactors, role of lipids, inducers, and inhibitors) as well as cellular and tissue distribution were chartered. Physiological functions involve lipid metabolism and ketone utilization in starvation, obesity, and diabetes. The most significant role of 2E1 is its adaptive response to high blood ethanol levels with a corresponding acceleration of ethanol metabolism. The associated free radical production, however, contributes to liver injury in the alcoholic. Most importantly, 2E1 has a unique capacity to activate many xenobiotics (85 of which are listed) to hepatotoxic or carcinogenic products. Induction of 2E1 also results in enhanced production of acetaldehyde, a highly reactive and toxic metabolite. The proliferation of the endoplasmic reticulum associated with 2E1 induction is also accompanied by enhanced activity of other cytochrome P-450s, resulting in accelerated metabolism of, and tolerance to, other drugs, as well as increased degradation of retinol and its hepatic depletion. Some substrates and metabolites, however, are innocuous and may eventually be used as markers of heavy drinking. Recently discovered effective 2E1 inhibitors also have great therapeutic potential.