Carbonic turnover number

Controlled potential electrolysis of the substrates, at —1.4V vs. SCE, at a carbon felt electrode on which only 3.6x10" mol Bjj were immobilized (approx. 1 X 10 ° mol cm" ) resulted in the production of 76pmol of valeronitrile 16, corresponding to a turnover number of 2100 This example shows that the combination of inner sphere redox mediators and high surface electrodes is promising. 

Different enzymes exhibit different specific activities and turnover numbers. The specific activity is a measure of enzyme purity and is defined as the number of enzyme units per milligram of protein. During the purification of an enzyme, the specific activity increases, and it reaches its maximum when the enzyme is in the pure state. The turnover number of an enzyme is the maximal number of moles of substrate hydrolyzed per mole of enzyme per unit time [63], For example, carbonic anhydrase, found in red blood cells, is a very active enzyme with a turnover number of 36 X 106/min per enzyme molecule. It catalyzes a very important reaction of reversible hydration of dissolved carbon dioxide in blood to form carbonic acid [57, p. 220],... 

Asymmetric ECH with [Rh(L)2(Cl)2]+ complexes containing chiral polypyridyl ligands has been attempted, in homogeneous media (L = (7)-(12)) and at carbon electrodes coated with polymer films prepared by electropolymerization of [Rh(13)2(Cl)2]+ -61 62 The latter catalytic system gave the best results in terms of turnover number (up to 4,750) and enantiomeric excess, (ee) when applied to the hydrogenation of acetophenone (ee 18%) and 2-butanone (ee 10%).62 Polymeric materials derived from the complexes [RhI(bpy)(COD)]+ 36 and [Pd(bpy)2]2+33have also been applied to the ECH reaction. 

Several approaches have been undertaken to construct redox active polymermodified electrodes containing such rhodium complexes as mediators. Beley [70] and Cosnier [71] used the electropolymerization of pyrrole-linked rhodium complexes for their fixation at the electrode surface. An effective system for the formation of 1,4-NADH from NAD+ applied a poly-Rh(terpy-py)2 + (terpy = terpyridine py = pyrrole) modified reticulated vitreous carbon electrode [70]. In the presence of liver alcohol dehydrogenase as production enzyme, cyclohexanone was transformed to cyclohexanol with a turnover number of 113 in 31 h. However, the current efficiency was rather small. The films which are obtained by electropolymerization of the pyrrole-linked rhodium complexes do not swell. Therefore, the reaction between the substrate, for example NAD+, and the reduced redox catalyst mostly takes place at the film/solution interface. To obtain a water-swellable film, which allows the easy penetration of the substrate into the film and thus renders the reaction layer larger, we used a different approach. Water-soluble copolymers of substituted vinylbipyridine rhodium complexes with N-vinylpyrrolidone, like 11 and 12, were synthesized chemically and then fixed to the surface of a graphite electrode by /-irradiation. The polymer films obtained swell very well in aqueous... 

Washing for over 100 h in a solvent such as toluene before the reaction resulted in no significant loss of the catalytic activity, and recovery and reusability studies at high turnover number also indicated the catalyst stability. Same catalysts, H5[PV2Mo10O40] supported on fiber and fabric carbon materials, catalyzed 02-based oxidations of acetaldehyde and 1-propanethiols [113], This aerobic heterogeneous oxidation proceeded under mild reaction conditions. 

The product is exclusively carbon monoxide, and good turnover numbers are found in preparative-scale electrolysis. Analysis of the reaction orders in CO2 and AH suggests the mechanism depicted in Scheme 4.6. After generation of the iron(O) complex, the first step in the catalytic reaction is the formation of an adduct with one molecule of CO2. Only one form of the resulting complex is shown in the scheme. Other forms may result from the attack of CO2 on the porphyrin, since all the electronic density is not necessarily concentrated on the iron atom [an iron(I) anion radical and an iron(II) di-anion mesomeric forms may mix to some extent with the form shown in the scheme, in which all the electronic density is located on iron]. Addition of a weak Bronsted acid stabilizes the iron(II) carbene-like structure of the adduct, which then produces the carbon monoxide complex after elimination of a water molecule. The formation of carbon monoxide, which is the only electrolysis product, also appears in the cyclic voltammogram. The anodic peak 2a, corresponding to the reoxidation of iron(II) into iron(III) is indeed shifted toward a more negative value, 2a, as it is when CO is added to the solution. 

Perhaps the only distinct advantage of enzymic catalysts is their (occasionally) very high turnover rate in situ. Thus, the molar activity (formerly called the turnover number) of some enzymes approaches 36,000,000/min/molecule (7). This latter number pertains to carbonic anhydrase C, the enzyme that converts C02 to HC03 . However, chemists do not need enzymes to convert COz to HCO3-, as long as we are not considering in vivo reactions. Since many enzymes have molar activities as low as 1150/min/molecule, we need not consider molar activities of 100 to 500 (for nonenzymic catalysts) as a severe handicap. It is evident that enzymes and nonenzymic chiral catalysts, rather than being competitors, complement one another. 

Carbonic anhydrase is a metalloprotein with a co-ordinate bonded zinc atom immobilized at three histidine residues (His 94, His 96 and Hisl 19) close to the active site of the enzyme. The catalytic activity of the different isoenzymes varies but cytosolic CA II is notable for its very high turnover number (Kcat) of approximately 1.5 million reactions per second. 

FIGURE 6. (a) The pH dependence of the Michaelis constant (Am) for the alkaline-phosphatase-catalyzed decomposition of AMPPD in 0.05 M carbonate buffer at 37 °C (b) the same pH dependence for the turnover number (fccat). Reprinted with permission from Reference 50. Copyright (1996) American Chemical Society... 

Carbonic anhydrase of erythrocytes (Mr 30,000) has one of the highest turnover numbers we know of. It catalyzes the reversible hydration of C02 ... 

Carbon monoxide oxidase 893 Carbonic acid, pkCa value of 99 Carbonic anhydrase 443,676 - 678,710 active site structure 679 mechanism 678 turnover number of 458,678 Carbonium ion. See Carbocation 1,1 -Carbonyl-diimidazole 105s Carbonyl group... 

It is likely that more silicon-carbon bonds are produced by the hydrosilylation of olefins than by any other method except the direct process. This deceptively simple addition of an Si-H bond to a C-C multiple bond can be promoted by a variety of means, but transition metal catalysis is by far the most significant. Two relatively old catalysts, H2PtCl6 ( Speier s catalyst ) and Pt2(Me2ViSiOSiMe2Vi)3 ( Karstedt s catalyst ), remain the most effective, and the remarkable rates and turnover numbers observed in these systems are among the most impressive in all of organometallic chemistry. The bulk of the literature on hydrosilylation falls outside the scope of this review, and readers are directed to the comprehensive work on hydrosilylation edited by Marciniec.93... 

It was once thought that the rate of equilibrium of the catalytic acid and basic groups on an enzyme with the solvent limited the rates of acid- and base-catalyzed reactions to turnover numbers of 103 s 1 or less. This is because the rate constants for the transfer of a proton from the imidazolium ion to water and from water to imidazole are about 2 X 103 s 1. However, protons are transferred between imidazole or imidazolium ion and buffer species in solution with rate constants that are many times higher than this. For example, the rate constants with ATP, which has a pKa similar to imidazole s, are about I0 J s 1 M-1, and the ATP concentration is about 2 mM in the cell. Similarly, several other metabolites that are present at millimolar concentrations have acidic and basic groups that allow catalytic groups on an enzyme to equilibrate with the solvent at 107 to 108 s-1 or faster. Enzyme turnover numbers are usually considerably lower than this, in the range of 10 to 103 s-1, although carbonic anhydrase and catalase have turnover numbers of 106 and 4 X 107 s 1, respectively. 

The catalytic activity of an enzyme is measured by its turnover number, which is defined as the number of substrate molecules acted on by one molecule of enzyme per second. As indicated in Table 24.2, enzymes vary greatly in their turnover number. Most enzymes have values in the 1-20,000 range, but carbonic anhydrase, which catalyzes the reaction of C02 with water to yield bicarbonate ion, acts on 600,000 substrate molecules per second. 

Carbonic anhydrase II, present in human red blood cells (RBCs), catalyzes the reversible hydration of C02. It is one of the most efficient enzymes and only diffusion-limited in its turnover numbers. The catalytic Zn11 is ligated by three histidine residues and OH this ZnOH+ structure renders the zinc center an efficient nucleophile which is able to attack the C02 molecule and capture it in an adjacent hydrophobic pocket. The catalytic mechanism is shown in Figure 9.5. 

A simple calculation reveals that the picture cannot be quite as simple. Carbonic anhydrase has an exceptionally high overall rate of reaction, its turnover number kcat is -5 x 105 s-1 consequently, the rate constants of individual steps must be greater than this number. The acid dissociation of a Zn11 aqua species seems to be inconsistent with this requirement. The dissociation constant fQ can be written as the ratio of forward k and backward kh rate constants [Eq. (9.20)]. 

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