Amidase

APA may be either obtained directly from special Penicillium strains or by hydrolysis of penicillin Q with the aid of amidase enzymes. A major problem in the synthesis of different amides from 6-APA is the acid- and base-sensitivity of its -lactam ring which is usually very unstable outside of the pH range from 3 to 6. One synthesis of ampidllin applies the condensation of 6-APA with a mixed anhydride of N-protected phenylglydne. Catalytic hydrogenation removes the N-protecting group. Yields are low (2 30%) (without scheme). 

Recent patents and pubHcations describe process improvements. Conversions can be followed by on-line hplc (93). The enzyme amidase can be used to reduce residual monomers (94—96). A hydrogenation process for reduction of acrylamide in emulsions containing more that 5% residual monomer has been patented (95). Biodegradable oils have been developed (97). 

In a similar way, several cephalosporins have been hydrolyzed to 7-aminodeacetoxycephalosporanic acid (72), and nocardicin C to 6-aminonocardicinic acid (73). Penicillin G amidase from Pscherichia coli has been used in an efficient resolution of a racemic cis intermediate required for a preparation of the synthon required for synthesis of the antibiotic Loracarbef (74). The racemic intermediate (21) underwent selective acylation to yield the cis derivative (22) in 44% yield the product displayed a 97% enantiomeric excess (ee). 

D-pbenyl alanine DT-phenylalanine amide amidase Ochrobactrum anthropic Rhodococms erythropolis ... 

Hydrolysis of Nitriles. The chemical hydrolysis of nitriles to acids takes place only under strong acidic or basic conditions and may be accompanied by formation of unwanted and sometimes toxic by-products. Enzymatic hydrolysis of nitriles by nitrile hydratases, nittilases, and amidases is often advantageous since amides or acids can be produced under very mild conditions and in a stereo- or regioselective manner (114,115). 

There are two distinct classes of enzymes that hydrolyze nitriles. Nittilases (EC 3.5.5. /) hydrolyze nittiles directiy to corresponding acids and ammonia without forming the amide. In fact, amides are not substrates for these enzymes. Nittiles also may be first hydrated by nittile hydratases to yield amides which are then converted to carboxyUc acid with amidases. This is a two-enzyme process, in which enantioselectivity is generally exhibited by the amidase, rather than the hydratase. 

Hydrolysis of esters and amides by enzymes that form acyl enzyme intermediates is similar in mechanism but different in rate-limiting steps. Whereas formation of the acyl enzyme intermediate is a rate-limiting step for amide hydrolysis, it is the deacylation step that determines the rate of ester hydrolysis. This difference allows elimination of the undesirable amidase activity that is responsible for secondary hydrolysis without affecting the rate of synthesis. Addition of an appropriate cosolvent such as acetonitrile, DMF, or dioxane can selectively eliminate undesirable amidase activity (128). 

Chirazymes. These are commercially available enzymes e.g. lipases, esterases, that can be used for the preparation of a variety of optically active carboxylic acids, alcohols and amines. They can cause regio and stereospecific hydrolysis and do not require cofactors. Some can be used also for esterification or transesterification in neat organic solvents. The proteases, amidases and oxidases are obtained from bacteria or fungi, whereas esterases are from pig liver and thermophilic bacteria. For preparative work the enzymes are covalently bound to a carrier and do not therefore contaminate the reaction products. Chirazymes are available form Roche Molecular Biochemicals and are used without further purification. 

This amide, readily formed from an amine and the anhydride or enzymatically using penicillin amidase, is readily cleaved by penicillin acylase (pH 8.1, A -methylpyrrolidone, 65-95% yield). This deprotection procedure works on peptides, phosphorylated peptides, and oligonucleotides, as well as on nonpeptide substrates. The deprotection of racemic phenylacetamides with penicillin acylase can result in enantiomer enrichment of the cleaved amine and the remaining amide. An immobilized form of penicillin G acylase has been developed. ... 

Prilocaine local anesthetic. S(-r)-isomer slowly hydrolyzed by amidase... 

To accelerate the polymerization process, some water-soluble salts of heavy metals (Fe, Co, Ni, Pb) are added to the reaction system (0.01-1% with respect to the monomer mass). These additions facilitate the reaction heat removal and allow the reaction to be carried out at lower temperatures. To reduce the coagulate formation and deposits of polymers on the reactor walls, the additions of water-soluble salts (borates, phosphates, and silicates of alkali metals) are introduced into the reaction mixture. The residual monomer content in the emulsion can be decreased by hydrogenizing the double bond in the presence of catalysts (Raney Ni, and salts of Ru, Co, Fe, Pd, Pt, Ir, Ro, and Co on alumina). The same purpose can be achieved by adding amidase to the emulsion. 

Several classes of enzymes have been used to separate stereoisomers of a-H-and a-disubstituted amino acids, eg amidases, nitrilases, hydantoinases, acylases and esterases. 

As illustrated in Figure A8.3 nitrilases catalyse conversions of nitriles directly into the corresponding carboxylic adds (route A), while other nitrile converting enzymes, die nitrile hydratases, catalyse the conversion of nitriles into amides (route B) which, by the action of amidases usually present in the whole cell preparations, are readily transformed into carboxylic adds (route C). 

L-Amino adds could be produced from D,L-aminonitriles with 50% conversion using Pseudomonas putida and Brembacterium sp respectively, the remainder being the corresponding D-amino add amide. However, this does not prove the presence of a stereoselective nitrilase. It is more likely that the nitrile hydratase converts the D,L-nitrile into the D,L-amino add amide, where upon a L-spedfic amidase converts the amide further into 50% L-amino add and 50% D-amino add amide. In this respect the method has no real advantage over the process of using a stereospecific L-aminopeptidase (vide supra). 

Hydantoinases belong to the E.C.3.5.2 group of cyclic amidases, which catalyze the hydrolysis of hydantoins [4,54]. As synthetic hydantoins are readily accessible by a variety of chemical syntheses, including Strecker reactions, enantioselective hydantoinase-catalyzed hydrolysis offers an attractive and general route to chiral amino acid derivatives. Moreover, hydantoins are easily racemized chemically or enzymatically by appropriate racemases, so that dynamic kinetic resolution with potential 100% conversion and complete enantioselectivity is theoretically possible. Indeed, a number of such cases using WT hydantoinases have been reported [54]. However, if asymmetric induction is poor or ifinversion ofenantioselectivity is desired, directed evolution can come to the rescue. Such a case has been reported, specifically in the production of i-methionine in a whole-cell system ( . coli) (Figure 2.13) [55]. 

Carnell et al. discovered that whole cells of Cunninghamella echinulata NRRL1384 were able to deracemize racemic N-(l-hydroxy-l-phenylethyl)benzamide (24) to produce the (R) enantiomer (Figure 5.17) [30]. The deracemization involves fast, highly (S)-selective oxidation, followed by slower, partially (R)-selective reduction of the ketone (25). Optimization by removing competing extracellular amidase/prote-ase activity resulted in 82% yield and 92% ee. 

Enantioselective transformations of several cyclopropane or oxirane-containing nitriles were studied using nitrile-transforming enzymes [78]. Microbial Rhodococcus sp. whole cells containing a nitrile hydratase/amidase system hydrolyzed a number... 

Both cis- and trans-chrysanthemic nitriles and amides were resolved into highly enantiopure amides and acids by Rhodococcus sp. whole cells [85]. The overall enantioselectivity of reactions of nitriles originated from the combined effects of a higher (lJ )-selective amidase and a (IJ )-selective nitrile hydratase (Figure 6.29). Chrysanthemic acids are related to constituents of pyrethrum flowers and insecticides. 

The biocatalytic differentiation of enantiotopic nitrile groups in prochiral or meso substrates has been studied by several research groups. For instance, the nitrilase-catalyzed desymmetrization of 3-hydroxyglutaronitrile [92,93] followed by an esterification provided ethyl-(Jl)-4-cyano-3-hydroxybutyrate, a useful intermediate in the synthesis of cholesterol-lowering dmg statins (Figure 6.32) [94,95]. The hydrolysis of prochiral a,a-disubstituted malononitriles by a Rhodococcus strain expressing nitrile hydratase/amidase activity resulted in the formation of (R)-a,a-disubstituted malo-namic acids (Figure 6.33) [96]. 

Penicillin G acylase (PGA, EC 3.5.1.11, penicillin G amidase) catalyzes the hydrolysis of the phenylacetyl side chain of penicillin to give 6-aminopenicillanic acid. PGA accepts only phenylacetyl and structurally similar groups (phenoxyacetyl, 4-pyridylacetyl) in the acyl moiety of the substrates, whereas a wide range of structures are tolerated in the amine part [100]. A representative selection of amide substrates, which have been hydrolyzed in a highly selective fashion, is depicted in Figure 6.36. 

Racemic a-amino amides and a-hydroxy amides have been hydrolyzed enantio-selectively by amidases. Both L-selective and o-selective amidases are known. For example, a purified L-selective amidase from Ochrobactrum anthropi combines a very broad substrate specificity with a high enantioselectivity on a-hydrogen and a,a-disubstituted a-amino acid amides, a-hydroxyacid amides, and a-N-hydroxya-mino acid amides [102]. A racemase (a-amino-e-caprolactam racemase, EC 5.1.1.15) converts the o-aminopeptidase-catalyzed hydrolysis of a-amino acid amides into a DKR (Figure 6.38) [103]. 

The hydrolysis with a (R)-specific amidase from Klebsiella oxytoca resolved 2-hydroxy- and 2-amino-3,3,3-trifluoro-2-methylpropionamide, giving the (R)-acid and the remaining (S)-amide (Figure 6.39) [104,105]. 

P-Lactamases (EC 3.5.2.6) produced by bacteria cleave the P-lactam ring and are responsible for their resistance to P-lactam antibiotics. Lactamases are useful catalysts for the enantioselective hydrolysis of P-lactams and other cyclic amides. P-lactams shown in Figure 6.40 were resolved by whole-cell systems containing an amidase [106]. 

Figure 6.39 Resolution of 2-hydroxy- and 2-amino-3,3,3-trifluoro-2-methylpropionamide by an amidase.

The anomalous behaviour observed in attempted 1-deprotection of certain 4-heteroarylmethyl-l-(4-methoxyphenyl)-2-azetidinones by the action of CAN has been investigated further <961771 > and evidence obtained to support the mechanism proposed, which involves the intermediate 47 when the 4-substituent is the tetrazolylmethyl group as in 46 <96T10169>. Use of the novel enzyme, o-phthalyl amidase, as a deprotection agent for P-lactams has been developed <96MI875>. 

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