Reactivity carboxylic

After acyl halides acid anhydrides are the most reactive carboxylic acid derivatives Three of them acetic anhydride phthahc anhydride and maleic anhydride are mdus trial chemicals and are encountered far more often than others Phthahc anhydride and maleic anhydride have their anhydride function incorporated into a nng and are referred to as cyclic anhydrides... 

It is generally beheved that selectivity of hydrolytic enzymes strongly depends on the proximity of the chiral center to the reacting carbonyl group, and only a few examples of successful resolutions exist for compounds that have the chiral center removed by more than three bonds. A noticeable exception to this rule is the enantioselective hydrolysis by Pseudomonasfluorescens Hpase (PEL) of racemic dithioacetal (5) that has a prochiral center four bonds away from the reactive carboxylate (24). The monoester (6) is obtained in 89% yield and 98% ee. 

Amides are the least reactive carboxylic acid derivative, and the only nucleophilic acyl substitution reaction they undergo is hydrolysis. Amides are fairly stable in water, but the amide bond is cleaved on heating in the presence of strong acids or bases. Nominally, this cleavage produces an amine and a car boxylic acid. 

Another occasionally used method for the preparation of acyclic A-(l-alkoxyalkyl)amides (or carbamates) proceeds via addition of reactive carboxylic acid derivatives to aldimines. In a one-pot procedure, treatment of the imine with the acid chloride (or ethyl chloroformate) and subsequent (m)ethanolysisofthe intermediary a-chloroamide leads to the oc-alkoxyamide56-58. 

Other examples of esterification with trialkyloxonium salts have been reported.7,8 The present procedure offers the advantages that the reactive carboxylate ion is generated in sitv and that a low-boiling, nonaqueous solvent is employed, whereby the experimental procedure is considerably simplified. A related method has been reported which utilizes a hindered amine wdth dimethyl sulfate [Sulfuric acid, dimethyl csterj as the alkylating agent.9 The present procedure is carried out under somewhat milder conditions and avoids the use of highly toxic reagents. 

A similar mechanism was postulated for the Ca " -dependent inactivation of Ca -ATPase by ATP-imidazolidate [380] that results in intramolecular crosslinking with the formation of a new protein band of 125 kDa. In both cases the reactive carboxyl group was suggested to be the phosphate acceptor Asp351. 

Riehm, J.P., and Scheraga, H.A. (1965) Structural studies of ribonuclease. XVII. A reactive carboxyl group in ribonuclease. Biochemistry 4, 772. 

The absorption and emission maxima of trimethinecyanine 9a (551 nm and 565 nm), squaraine 9b (631 nm and 641 nm), and cyanine 9c (784 nm and 805 nm) hardly change after complexation with a-CD and [S-CD in water, but the fluorescence quantum yields increase noticeably [28]. CD complexes of these water-soluble dyes containing reactive carboxylic functionalities have potential use as fluorescent labels. 

A variety of hydrophobic and hydrophilic squaraine rotaxane probes and labels such as 21a-21e c Rp and 22a-22e c Rp, containing reactive carboxylic functionalities and hydrophilic sulfo groups, are disclosed in a recent patent application [60]. It was shown that not only aniline-based squaraines 21a-21e but also heterocyclic squaraines 22a-22e can form stable pseudorotaxane complexes. The indo-lenine-based squaraine 22a forms rotaxane 22a C Rp. Importantly, also the sulfonated squaraine 22b could be successfully encapsulated in a Leigh-type, phenylene-based, tetralactam macrocycle to yield the water-soluble rotaxane 22b C Rp. Quatemized, indolenme-based squaraines do not form pseudorotaxanes probably because of sterical hindrance caused by /V-alkyl and 3,3 -dimethyl groups. On the other hand, quatemized benzothiazole (22c) and benzoselenazole (22d) squaraines could be embedded in a Leigh-type macrocycle to yield rotaxanes 22c C Rp and 22d C Rp, respectively. The hydrophilic, mono-reactive rotaxane 22e-NHS C Rp based on asymmetric squaraine, synthesized by a cross-reaction of squaric acid with the two different indolenines, was also obtained. 

Acid chlorides are the most reactive carboxylic acid derivatives, and easily converted to acid anhydrides, esters and amides via nucleophilic acyl substitutions (see Section 5.5.5). Acid chlorides are sufficiently reactive with H2O, and quite readily hydrolysed to carboxylic acid (see Section 5.6.1). 

Acid anhydrides are the second most reactive of the carboxylic acid derivatives. They are fairly readily converted to the other less reactive carboxylic acid derivatives, e.g. esters, carboxylic acids and amides. Acid anhydrides undergo many reactions similar to those of acid chlorides, and they can often be used interchangeably. 

Amides are the least reactive carboxylic acid derivatives, and are easily obtained from any of the other carboxylic acid derivatives. Carboxylic acids react with ammonia and 1° and 2° amines to give 1°, 2° and 3° amides. 

The hydrolysis of the more reactive carboxylic esters is catalyzed by a wide range of oxyanions. The mechanism proposed for the neutral hydrolysis of esters on p. 158 involves two molecules of water, one as a nucleophile and one as a general base. In principle an oxyanion or other nucleophile can replace either of these molecules, and both general base and nucleophilic catalysis of ester hydrolysis are well-known. The detailed mechanism of nucleophilic catalysis depends, to some extent, on the type of anion concerned, but the differences occur at a relatively late stage in the reaction, and the similarities are sufficient to allow generalizations about oxyanion reactions as a class. Some of the differences are not normally kinetically significant, and are best mentioned briefly at this point. 

This equation is not intended to imply a mechanism for peptide synthesis. The equilibrium position for this reaction in an aqueous solution favors the free amino acids rather than the peptide. Therefore, both biological and laboratory syntheses of peptides usually do not involve a simple splitting out of water. Since the dipeptide of Eq. 2-11 still contains reactive carboxyl and amino groups, other amino acid units can be joined by additional peptide linkages to form polypeptides. These range from short-chain oligomers to polymers of from 50 to several thousand amino acid units, the proteins.75-77... 

Using the data of Wilson and Cannan (18), Cleaves (81) was able to show that the rate of formation of pyrrolidone carboxylic acid from glutamic acid in aqueous solution depends directly on the concentration of the ionic species of glutamic acid in solution. Thus, the reactive species are (I), (II), and (IV), while (III) is relatively unreactive. Protonation of the amino group and dissociation of the y-carboxyl group thus makes these groups less reactive carboxylate ion resonance apparently hinders nucleophilic attack by the amino nitrogen. 

Another carboxylic acid activation in a neutral environment together with all mechanistic details is shown in Figure 6.13 carboxylic acids and carbonyldiimidazole (A) react to form the reactive carboxylic acid imidazolide B. 

Because the acidic hydrogen is the usual cause of undesired reactivity, carboxylic acids are commonly protected as esters. Most often, simple methyl esters are used. The ester can be prepared via the acyl chloride or by Fischer esterification (see Section 19.4). The ester group can be converted back to the carboxylic acid by hydrolysis under acidic or basic (saponification) conditions (see Section 19.5). 

Acid chlorides (RCOCI), which have the best leaving group (CO, are the most reactive carboxylic acid derivatives, and amides (RCONH2), which have the worst leaving group rNH2), are the least reactive. 

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