Tetrahedral mechanism esters

The most important species m the mechanism for ester hydrolysis is the tetrahe dral intermediate Evidence m support of the existence of the tetrahedral intermediate... 

This is like the A1 mechanism except that the protonated substrate SH +, instead of reacting alone, reacts with something else in the rate-determining step, a nucleophile or a base, written as Nu in equation (41). A typical example of this very common mechanism is ester hydrolysis, say of the methyl esters in equation (42), where SH+ reacts with two water molecules in the slow step,29 giving the neutral tetrahedral intermediate [5] directly. Reasonably enough, the rate equations obtainable are very similar to those for the A1 mechanism, with the addition of an extra aNu term, see equation (43) ... 

Before discussmg the mechanism of cleavage of carboxylic acid esters and amides by hydrolases, some chemical principles are worth recalling. The chemical hydrolysis of carboxylic acid derivatives can be catalyzed by acid or base, and, in both cases, the mechanisms involve addition-elimination via a tetrahedral intermediate. A general scheme of ester and amide hydrolysis is presented in Fig. 3. / the chemical mechanisms of ester hydrolysis will be... 

Although the mechanism of ester formation has been the subject of some controversy, this process is related to polyborate formation in that both cases likely involve nucleophilic attack of an HO oxygen on B(OH)3 followed by elimination of water from a tetrahedral intermediate, Eq. (4). 

Fig. 3. Mechanism of ester hydrolysis involves a high energy tetrahedral intermediate. Phos-...

The most important species in the mechanism for ester hydrolysis is the tetrahedral intermediate. Evidence in support of the existence of the tetrahedral intermediate was developed by Professor Myron Bender on the basis of isotopic labeling experiments he carried out at the University of Chicago. Bender prepared ethyl benzoate, labeled with the mass-18 isotope of oxygen at the carbonyl oxygen, then subjected it to acid-catalyzed hydrolysis in ordinary (unlabeled) water. He found that ethyl benzoate, recovered from the reaction before hydrolysis was complete, had lost a portion of its isotopic label. This observation is consistent only with the reversible formation of a tetrahedral intermediate under the reaction conditions ... 

It seems probable that the mechanism of ester aminolysis is similar to that of the reaction between amines and aryl halides, a reaction which also exhibits general base catalysis (see section III.C). The reaction would then involve the formation of a tetrahedral intermediate (2) by addition of amine across the carbonyl double bond in an equilibrium step, which can then decompose via two independent pathways, one catalysed by base (A ) and the other not (/ 3). Whether... 

Tertiary benzoyloxymethylsulfonamides (17) undergo hydrolysis via pH-independent and acid- and base-catalysed processes. Reactions are also buffer catalysed for buffer species with pXa values > 10.5. For the pH-independent pathway, hydrolysis takes place via formation of an Al-sulfonyliminium ion (Scheme 2). The mechanism of the acid-catalysed process involves pre-equilibrium protonation of the substrate followed by iminium ion formation. The base-catalysed pathway involves the normal Bac2 mechanism of ester hydrolysis. The buffer-catalysed reaction gives rise to a curved Brpnsted plot, with values of 1.6 and 0.25 for nucleophiles with pXa values <12.5 and >13, respectively. This is indicative of nucleophilic catalysis associated with a change in rate-limiting step from formation of the tetrahedral intermediate for buffer species with pXa > 13 to decomposition of the tetrahedral intermediate for buffer species with pXa < 12.5. ... 

Protonation of the carbonyl oxygen as emphasized earlier makes the carbonyl group more susceptible to nucleophilic attack A water molecule adds to the carbonyl group of the protonated ester m step 2 Loss of a proton from the resulting oxonium ion gives the neutral form of the tetrahedral intermediate m step 3 and completes the first stage of the mechanism... 

Section 2010 Ester hydrolysis can be catalyzed by acids and its mechanism (Figure 20 4) is the reverse of the mechanism for Fischer esterification The reaction proceeds via a tetrahedral intermediate... 

Hydrolysis. Esters are cleaved (hydroly2ed) into an acid and an alcohol through the action of water. This hydrolysis is cataly2ed by acids or bases. The mechanistic aspects of ester hydrolysis have received considerable attention and have been reviewed (16). For most esters only two reaction pathways are important. Both mechanisms involve a tetrahedral intermediate and addition-elimination reactions i7i7... 

The nucleophilic catalysis mechanism only operates when the alkoxy group being hydrolyzed is not much more basic than the nucleophilic catalyst. This relationship can be imderstood by considering the tetrahedral intermediate generated by attack of the potential catalyst on the ester ... 

FIGURE 20.4 The mechanism of acid-catalyzed ester hydrolysis. Steps 1 through 3 show the formation of the tetrahedral intermediate. Dissociation of the tetrahedral intermediate is shown in steps 4 through 6. 

Tire mechanism of the Claisen condensation is similar to that of the aldol condensation and involves the nucleophilic addition of an ester enolate ion to the carbonyl group of a second ester molecule. The only difference between the aldol condensation of an aldeiwde or ketone and the Claisen condensation of an ester involves the fate of the initially formed tetrahedral intermediate. The tetrahedral intermediate in the aldol reaction is protonated to give an alcohol product—exactly the behavior previously seen for aldehydes and ketones (Section 19.4). The tetrahedral intermediate in the Claisen reaction, however, expels an alkoxide leaving group to yield an acyl substitution product—exactly the behavior previously seen for esters (Section 21.6). The mechanism of the Claisen condensation reaction is shown in Figure 23.5. 

The mechanism for the lipase-catalyzed reaction of an acid derivative with a nucleophile (alcohol, amine, or thiol) is known as a serine hydrolase mechanism (Scheme 7.2). The active site of the enzyme is constituted by a catalytic triad (serine, aspartic, and histidine residues). The serine residue accepts the acyl group of the ester, leading to an acyl-enzyme activated intermediate. This acyl-enzyme intermediate reacts with the nucleophile, an amine or ammonia in this case, to yield the final amide product and leading to the free biocatalyst, which can enter again into the catalytic cycle. A histidine residue, activated by an aspartate side chain, is responsible for the proton transference necessary for the catalysis. Another important factor is that the oxyanion hole, formed by different residues, is able to stabilize the negatively charged oxygen present in both the transition state and the tetrahedral intermediate. 

The intermediates 74 and 76 can now lose OR to give the acid (not shown in the equations given), or they can lose OH to regenerate the carboxylic ester. If 74 goes back to ester, the ester will still be labeled, but if 76 reverts to ester, the 0 will be lost. A test of the two possible mechanisms is to stop the reaction before completion and to analyze the recovered ester for 0. This is just what was done by Bender, who found that in alkaline hydrolysis of methyl, ethyl, and isopropyl benzoates, the esters had lost 0. A similar experiment carried out for acid-Catalyzed hydrolysis of ethyl benzoate showed that here too the ester lost However, alkaline hydrolysis of substimted benzyl benzoates showed no loss. This result does not necessarily mean that no tetrahedral intermediate is involved in this case. If 74 and 76 do not revert to ester, but go entirely to acid, no loss will be found even with a tetrahedral intermediate. In the case of benzyl benzoates this may very well be happening, because formation of the acid relieves steric strain. Another possibility is that 74 loses OR before it can become protonated to 75. Even the experiments that do show loss do not prove the existence of the tetrahedral intermediate, since it is possible that is lost by some independent process not leading to ester hydrolysis. To deal with this possibility. Bender and Heck measured the rate of loss in the hydrolysis of ethyl trifluorothioloacetate- 0 ... 

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