Acyl acylation step

Because the position of electrophilic attack on an aromatic nng is controlled by the direct ing effects of substituents already present the preparation of disubstituted aromatic com pounds requires that careful thought be given to the order of introduction of the two groups Compare the independent preparations of m bromoacetophenone and p bromoace tophenone from benzene Both syntheses require a Friedel-Crafts acylation step and a bromination step but the major product is determined by the order m which the two steps are carried out When the meta directing acetyl group is introduced first the final product IS m bromoacetophenone... 

Scheme 68 shows the conversion of the phenoxymethylpenicillin-derived disulfide (see Scheme 10) to penem derivative (91) (78JA8214). Of particular interest in this sequence is the reductive acylation step to afford (89) and the Wittig ring closure to give (90). The rate of the latter reaction was found to be greatly infiuenced by the steric and electronic character of both the thiol ester and the carboxyl blocking group. 

As a demonstration of the complete synthesis of a pharmaceutical in an ionic liquid, Pravadoline was selected, as the synthesis combines a Friedel-Crafts reaction and a nucleophilic displacement reaction (Scheme 5.1-24) [53]. The allcylation of 2-methylindole with l-(N-morpholino)-2-chloroethane occurs readily in [BMIM][PF6] and [BMMIM][PF6] (BMMIM = l-butyl-2,3-dimethylimida2olium), in 95-99 % yields, with potassium hydroxide as the base. The Friedel-Crafts acylation step in [BMIM][PF6] at 150 °C occurs in 95 % yield and requires no catalyst. 

In the foregoing micellar reactions, it is likely that the reaction proceeds through the acylation of the hydroxyl group of the ligands, and the results indicate that the acylation step is greatly enhanced by complexation with Zn2 + ions under micellar... 

The ratios of these slopes for L- and D-esters are shown in Table 12. The kL/kD values of the acylation step in the CTAB micelle are very close to those in Table 9, as they should be. It is interesting to note that the second deacylation step also occurs enantioselectively. Presumably it is due to the deacylation ocurring by the attack of a zinc ion-coordinated hydroxide ion which, in principle, should be enantioselective as in the hydroxyl group of the ligand. Alternatively, the enantioselectivity is also expected when the free hydroxide ion attack the coordinated carbonyl groups of the acyl-intermediate with the zinc ion. At any rate, the rates of both steps of acylation and deacylation for the L-esters are larger than those for the D-esters in the CTAB micelle. However, in the Triton X-100 micelle, the deacylation step for the D-esters become faster than for the L-esters. 

The first step, which is called the acylation reaction, involves a formation of an acyl-enzyme where the RC(0 )X group is covalently bound to the specially active serine residue and the XH group is expelled from the active site. The second step, which is called the deacylation step, involves an attack of an HY group on the acyl-enzyme. Here we concentrate on the acylation step which is the reverse of the second step when X and Y are identical. 

In some cases the hydrogenolysis of the N-benzyl bond may be followed by an intramolecular N-acylation step (Scheme 4.69).310... 

Weik and Rademann have described the use of phosphoranes as polymer-bound acylation equivalents [65]. The authors chose a norstatine isostere as a synthetic target and employed classical polymer-bound triphenylphosphine in their studies (Scheme 7.54). Initial alkylation of the polymer-supported reagent was achieved with bromoacetonitrile under microwave irradiation. Simple treatment with triethyl-amine transformed the polymer-bound phosphonium salt into the corresponding stable phosphorane, which could be efficiently coupled with various protected amino acids. In this acylation step, the exclusion of water was crucial. 

Cram and co-workers have been successful in modifying certain of their cavitands such that reactions with a bound substrate are promoted. Such systems provide a first step towards the synthesis of rudimentary enzymes (Cram, Katz, Dicker, 1984). One example of this type, involving a binding step followed by a fast acylation step, is illustrated by Figure 5.1. This sequence resembles part of the mechanism used by chymo-trypsin to cleave a peptide bond. Thus, the enzymic process entails several stages but, like the model system, begins with a binding step followed by a crucial transacylation step. 

Now, GC-IRMS can be used to measure the nitrogen isotopic composition of individual compounds [657]. Measurement of nitrogen isotope ratios was described by Merritt and Hayes [639], who modified a GC-C-IRMS system by including a reduction reactor (Cu wire) between the combustion furnace and the IRMS, for reduction of nitrogen oxides and removal of oxygen. Preston and Slater [658] have described a less complex approach which provides useful data at lower precision. Similar approaches have been described by Brand et al. [657] and Metges et al. [659]. More recently Macko et al. [660] have described a procedure, which permits GC-IRMS determination of 15N/14N ratios in nanomole quantities of amino acid enantiomers with precision of 0.3-0.4%o. A key step was optimization of the acylation step with minimal nitrogen isotope fractionation [660]. 

Fig. 3.3. Major steps in the hydrolase-catalyzed hydrolysis of peptide bonds, taking chymo-trypsin, a serine hydrolase, as the example. Asp102, His57, and Ser195 represent the catalytic triad the NH groups of Ser195 and Gly193 form the oxyanion hole . Steps a-c acylation Steps d-f deacylation. A possible mechanism for peptide bond synthesis by peptidases is represented by the reverse sequence Steps f-a.

Serine peptidases can hydrolyze both esters and amides, but there are marked differences in the kinetics of hydrolysis of the two types of substrates as monitored in vitro. Thus, the hydrolysis of 4-nitrophenyl acetate by a-chy-motrypsin occurs in two distinct phases [7] [22-24]. When large amounts of enzyme are used, there is an initial rapid burst in the production of 4-nitro-phenol, followed by its formation at a much slower steady-state rate (Fig. 3.7). It was shown that the initial burst of 4-nitrophenol corresponds to the formation of the acyl-enzyme complex (acylation step). The slower steady-state production of 4-nitrophenol corresponds to the hydrolysis of the acetyl-enzyme complex, regenerating the free enzyme. This second step, called deacylation, is much slower than the first, so that it determines the overall rate of ester hydrolysis. The rate of the deacylation step in ester hydrolysis is pH-dependent and can be slowed to such an extent that, at low pH, the acyl-enzyme complex can be isolated. 

This process has many benefits in the context of green chemistry it involves two enzymatic steps, in a one-pot procedure, in water as solvent at ambient temperature. It has one shortcoming, however-penicillin acylase generally works well only with amines containing an aromatic moiety and poor enantioselectivities are often observed with simple aliphatic amines. Hence, for the easy-on/easy-off resolution of aliphatic amines a hybrid form was developed in which a hpase [Candida antarctica hpase B (CALB)] was used for the acylation step and peniciUin acylase for the deacylahon step [22]. The structure of the acyl donor was also optimized to combine a high enanhoselectivity in the first step with facile deacylation in the second step. It was found that pyridyl-3-acetic acid esters gave optimum results (see Scheme 6.8). 

The natural substrates of lipases are triglycerides and, in an aqueous environment, lipases catalyze their hydrolysis into fatty acids and glycerol. In anhydrous media, lipases can be active in the reverse reaction [19]. In fact, in the acylation step, acids, lactones, (cyclic) carbonates [20, 21], cyclic amides [22, 23], (cyclic) thioesters [24, 25], and cyclic phosphates [26] have been found to act as suitable acyl donors. In the deacylation step, apart from water, lipases also accept alcohols [27], amines [28, 29], and thiols [30] as nucleophiles although the specificity of lipases is lower for amines and thiols than for water and alcohols [31]. 

Although many publications have covered the enantioselectivity of lipases in the deacylation step, their enantioselectivity in the acylation step (i.e., towards the acyl donor) has received much less attention. Generally, the selectivity of lipases towards racemic esters or acids is low to moderate [75-77]. Directed evolution and site-directed mutagenesis lead to a significant increase in the selectivity of the wild-type enzymes [78-80]. However, the enantiomeric ratios attained are still well below those typically obtained in kinetic resolutions of secondary alcohols. 

A transhydrocyanation reaction catalyzed by / / I INI. on Celite was investigated by Hanefeld and co-workers [41]. To shift the unfavorable equilibrium, the reaction was coupled with an irreversible acylation step. Problems occurred due to hydrolysis of the acyl donor by the water needed for enzyme activity and subsequent deactivation of the / Ihl I N1. by the acid formed. In situ derivatization in the cyanohydrin synthesis catalyzed by PaHNL on Celite was investigated, and a one-pot chemoenzymatic synthesis of protected cyanohydrins was developed using ethyl cyanoformate as both HCN donor and protecting reagent [70]. 

The control experiments reported in Table 5.5 show that (a) thiolysis of pNPOAc in the absence of metal ions is only 5 x faster than the very slow background reaction (fi/2 3 days) and (b) remarkable accelerations are brought about by the metal salts alone, which is ascribed to the formation of reactive metal bound methoxide species in equilibrium with the tiny amount of free methoxide in the buffered solution [Eq. (la)]. Whereas these large accelerations are interesting per se, here it suffices to emphasize that mixtures of 10 and m + are much more effective than either thiol or metal ion alone. The reactivity order Ca Sr > Ba found in the acylation step closely parallels that found in deacylation. 

Step 2 Nucleophilic addition reaction, release of leaving group (alkylation or acylation step) ... 

Figure 17.19 Rates of hydrolysis of two families of esters by a hydrolase, chymotrypsin. The esters of N-acetyl-L-phenylalanine exhibit very similar rates because the process in each case is limited by the same enzyme deacylation reaction (Zerner et al., 1964). The esters of N-benzoyl glycine exhibit rates varying by more than a factor of 3 because their hydrolyses are mostly limited by the initial enzyme acylation step (Epand and Wilson, 1963).

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