Catalytic cycle resting state

Figure 18.11 Plausible catalytic cycle for the ORR by simple Fe porphyrins adsorbed on the electrode surface and side Reactions (18.15)-(18.18). At pH < 3, the resting state of the catalyst is assumed to be ferric-aqua.

The classical peroxidative catalytic cycle involves the formation of a so-called compound I intermediate product of the binding of the hydrogen peroxide to the heme group of the enzyme and the subsequent release of a water molecule. The cycle operates through a second intermediate, compound II, to the resting state enzyme by two individual one-electron withdrawals from the reducing substrates [70],... 

Extensive studies have established that the catalytic cycle for the reduction of hydroperoxides by horseradish peroxidase is the one depicted in Figure 6 (38). The resting enzyme interacts with the peroxide to form an enzyme-substrate complex that decomposes to alcohol and an iron-oxo complex that is two oxidizing equivalents above the resting state of the enzyme. For catalytic turnover to occur the iron-oxo complex must be reduced. The two electrons are furnished by reducing substrates either by electron transfer from substrate to enzyme or by oxygen transfer from enzyme to substrate. Substrate oxidation by the iron-oxo complex supports continuous hydroperoxide reduction. When either reducing substrate or hydroperoxide is exhausted, the catalytic cycle stops. 

The first step in the catalytic cycle is the reaction between H2O2 and the Fe(ni) resting state of the enzyme to generate compound I, a high-oxidation-state intermediate comprising an Fe(IV) oxoferryl center and a porphyrin-based cation radical... 

The resting state of the catalyst, in the schemes chosen so far, has been a species at the beginning of the catalytic cycle. We will discuss one example, E, in which this is not the case. 

At high PPh3 concentrations, where the catalyst resting state is (PPh3)3Rh(CO)H, phosphine dissociation must occur to form the coordinatively unsaturated intermediates 3c and 3t. This dissociation is suppressed by increased PPh3 concentration, which serves to reduce the concentration of active Rh species in the catalytic cycle. 

Crabtree and coworkers proposed a catalytic cycle for the reaction outUned in Equation 6.10. The mechanism is based on labeling and kinetic studies, and is outlined in Scheme 6.4 [25]. Adduct 36 was observed in nuclear magnetic resonance (NMR) spectra and appears to be a catalyst resting state. It should be noted that there is no change in the oxidation state of Ir, and that the key step is thought... 

Fig. 5. Catalytic cycle of cytochrome P450. The substrate HR binds to the resting enzyme A to form intermediate B, which is reduced by one electron to form C and then reacts with dioxygen. The resulting ferric-peroxo intermediate D is reduced by one equivalent to form the transient oxyferrous intermediate E, which proceeds quickly to intermediate F with release of a molecule of water. F is designated Fe(V)=0 to indicate that it is oxidized by two equivalents greater than A and not to imply anything about the true oxidation state of the iron. Intermediate F then transfers an oxygen atom to the substrate to regenerate the resting enzyme. The peroxide shunt refers to the reaction of B with hydrogen peroxide to produce the intermediate F, which can then proceed to product formation.

Alternatively, the rhodium dimer 30 may be cleaved by an amine nucleophile to give 34. Since amine-rhodium complexes are known to be stable, this interaction may sequester the catalyst from the productive catalytic cycle. Amine-rhodium complexes are also known to undergo a-oxidation to give hydridorhodium imine complexes 35, which may also be a source of catalyst poisoning. However, in the presence of protic and halide additives, the amine-rhodium complex 34 could react to give the dihalorhodate complex 36. This could occur by associative nucleophilic displacement of the amine by a halide anion. Dihalorhodate 36 could then reform the dimeric complex 30 by reaction with another rhodium monomer, or go on to react directly with another substrate molecule with loss of one of the halide ligands. It is important to note that the dihalorhodate 36 may become a new resting state for the catalyst under these conditions, in addition to or in place of the dimeric complex. 

As described above (Section 3.3.1.1), in situ HP IR measurements under catalytic conditions identified the anion [MeIr(CO)2l3] as the catalyst resting state in the Cativa process. The rate controlling step in the catalytic cycle was proposed to be carbonylation of [MeIr(CO)2l3] (Eq. (7)). 

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