Carbonate diesters, hydrolysis

The reaction of cycloheptaamylose with diaryl carbonates and with diaryl methylphosphonates provides a system in which a carboxylic acid derivative can be directly compared with a structurally analogous organo-phosphorus compound (Brass and Bender, 1972). The alkaline hydrolysis of these materials proceeds in twro steps, each of which is associated with the appearance of one mole of phenol (Scheme Y). The relative rates of the two steps, however, are reversed. Whereas the alkaline hydrolysis of carbonate diesters proceeds with the release of two moles of phenol in a first-order process (kh > fca), the hydrolysis of methylphosphonate diesters proceeds with the release of only one mole of phenol to produce a relatively stable aryl methylphosphonate intermediate (fca > kb), In contrast, kinetically identical pathways are observed for the reaction of cycloheptaamylose with these different substrates—in both cases, two moles of phenol are released in a first-order process.3 Maximal catalytic rate constants for the appearance of phenol are presented in Table XI. Unlike the reaction of cycloheptaamylose with m- and with p-nitrophenyl methylphosphonate discussed earlier, the reaction of cycloheptaamylose with diaryl methylphosphonates... 

An approach to the synthesis of a prostaglandin intermediate began with 2-furanacetonitrile (71JOC3191). Friedel-Crafts acylation with pimelic half-ester acid chloride and Wolff-Kishner reduction of the product with concomitant hydrolysis of the nitrile group to acid yielded the diester (78) on diazomethane treatment. Ring opening of the furan by a standard procedure yielded a diketo diester (79) which on refluxing in aqueous methanolic potassium carbonate underwent hydrolysis and cyclization to the diacid (80 Scheme 19). 

Notes. (1) The mother-liquors from the washings and recrystallisations are saved for the recovery of 4-nitrophthalic acid. The combined mother-liquors are concentrated to small bulk and the organic acids extracted into ether. Upon esterification of the residue after evaporation of the ether by the Fischer-Speier method (Section 5.12.3, p. 695), the 3-nitro acid forms the acid ester and may be removed by shaking the product with sodium carbonate solution, while the 4-nitrophthalic acid yields the neutral diester. Hydrolysis of the neutral ester gives the pure 4-nitrophthalic acid, m.p. 165 °C. (2) The acid may also be recrystallised from glacial acetic acid. 

Fig. 2. Synthesis of uma2enil (18). The isonitrosoacetanihde is synthesized from 4-f1iioroani1ine. Cyclization using sulfuric acid is followed by oxidization using peracetic acid to the isatoic anhydride. Reaction of sarcosine in DMF and acetic acid leads to the benzodiazepine-2,5-dione. Deprotonation, phosphorylation, and subsequent reaction with diethyl malonate leads to the diester. After selective hydrolysis and decarboxylation the resulting monoester is nitrosated and catalyticaHy hydrogenated to the aminoester. Introduction of the final carbon atom is accompHshed by reaction of triethyl orthoformate to...

Oxo esters are accessible via the diastereoselective 1,4-addition of chiral lithium enamine 11 as Michael donor. The terr-butyl ester of L-valine reacts with a / -oxo ester to form a chiral enamine which on deprotonation with lithium diisopropylamide results in the highly chelated enolate 11. Subsequent 1,4-addition to 2-(arylmethylene) or 2-alkylidene-l,3-propanedioates at — 78 °C, followed by removal of the auxiliary by hydrolysis and decarboxylation of the Michael adducts, affords optically active -substituted <5-oxo esters232 (for a related synthesis of 1,5-diesters, see Section 1.5.2.4.2.2.1.). In the same manner, <5-oxo esters with contiguous quaternary and tertiary carbon centers with virtually complete induced (> 99%) and excellent simple diastereoselectivities (d.r. 93 7 to 99.5 0.5) may be obtained 233 234. 

Carbonic acid esters (alkoxycarbonyl derivatives) are diesters of general formula R-O-CO-O-R. A single mechanism operates in the HO -catalyzed (and presumably also in the enzyme-catalyzed) hydrolysis of carbonic acid esters, namely a rate-determining addition of the base to the carbonyl C-atom to form an intermediate whose breakdown yields the drug (ROH), C02, and an alcohol (R OH) (Fig. 8.7,a) [153],... 

One process that capitalizes on butadiene, synthesis gas, and methanol as raw materials is BASF s two-step hydrocarbonylation route to adipic acid(3-7). The butadiene in the C4 cut from an olefin plant steam cracker is transformed by a two-stage carbonylation with carbon monoxide and methanol into adipic acid dimethyl ester. Hydrolysis converts the diester into adipic acid. BASF is now engineering a 130 million pound per year commercial plant based on this technology(8,9). Technology drawbacks include a requirement for severe pressure (>4500 psig) in the first cobalt catalyzed carbonylation step and dimethyl adipate separation from branched diester isomers formed in the second carbonylation step. 

Fig. 2). The staphylococcal enzyme may appear to be more akin in its mode of action to the spleen enzyme because they both hydrolyze DNA and RNA to 3 -nucleotides, whereas the venom enzyme releases 5 -nucleotides. However, their mode of action and specificity are quite different, and the structural requirements of the staphylococcal enzyme substrates are perhaps more nearly similar to those of the venom enzyme. The principal difference is that the staphylococcal enzyme cleaves the diester bond between the phosphate and the 5 -carbon of the sugar, whereas the venom enzyme cleaves on the other side of the phosphate, that is, between the phosphate and the nonspecific hydroxylic component of the diester bond. In contrast to both spleen and venom diesterases, the primary product released by staphylococcal nuclease hydrolysis is a derivative bearing a hydroxyl group (on the 5 position) rather than a phosphoryl group. Therefore, the 3 -phosphoryl product formed from polynucleotide hydrolysis is a secondary consequence of such cleavage. 

The reaction mechanism of carbonic anhydrase (CA) is still a matter of controversy. Pocker and Guilbert232 have reported that the hydrolysis of diesters by CA, specifically the hydrolysis of methyl 4-nitrophenylcarbonate, is similar to that which occurs in CO 2 hydrolysis the rate varies as though dependent on the ionization of a group in the enzyme with a pK near 7. Only the basic form is active. - ... 

Although the acetoacetic ester synthesis and the malonic ester synthesis are used to prepare ketones and carboxylic acids, the same alkylation, without the hydrolysis and decarboxylation steps, can be employed to prepare substituted /3-ketoesters and /3-diesters. In fact, any compound with two anion stabilizing groups on the same carbon can be deprotonated and then alkylated by the same general procedure. Several examples are shown in the following equations. The first example shows the alkylation of a /3-ketoester. Close examination shows the similarity of the starting material to ethyl acetoacetate. Although sodium hydride is used as a base in this example, sodium ethoxide could also be employed. 

Azo-ene reactions. The ene reaction provides a powerful method for C-C bond formation with concomitant activation of an allylic C-H bond. A variety of functionalized carbon skeletons can be constructed due to the range of enophiles which can be used. For example, carbonyl compounds give homoallylic alcohols and imino derivatives of aldehydes afford homoallylic amines. The azo-ene reaction offers a method for effecting allylic amination by treatment of an alkene with an azo-diester to afford a diacyl hydrazine which upon N-N cleavage furnishes a carbamate. Subsequent hydrolysis of the carbamate provides an allylic amine. Use of chiral diazenedicarboxylates provides a method for effecting stereoselective electrophilic amination. 

One veiy useful transfomiation of these adducts is given in equation (7S). Hydrolysis of the diester to the diacid, followed by bis-decaiboxylation either by a double Cuitius rearrangement or oxidatively with ceric artunonium nitrate,yields an unsaturated lactone. This overall sequence is equivalent to effecting a Diels-Alder reaction wiA carbon dioxide, which is unreactive as a dienophile. 

In a study by Berti et al., acid-catalyzed hydrolysis of styrene oxide was reported to occur with 67% inversion and 33% retention at the benzyl carbon.45 In a later study, it was reported that the styrene glycol product formed in the acid-catalyzed hydrolysis of chiral styrene oxide is completely racemic, which would indicate an A-l mechanism.46 As these two results indicate quite different mechanisms for this reaction, the glycol product from acid-catalyzed hydrolysis of chiral styrene oxide was converted to its bis-( + )-a-(methoxy-a-trifluoromethyl)phenylacetate diester derivative, and the composition of the diastereomeric diester mixture was determined by H NMR.47 This study agreed with those of Berti et al. and showed that acid-catalyzed hydrolysis of styrene oxide occurs with 67% inversion and 33% retention at the benzyl carbon. Acid-catalyzed methanolysis of styrene oxide is reported to occur with 89% inversion at the benzyl carbon.48 The fact that the diol product from acid-catalyzed hydrolysis of chiral styrene oxide is not completely racemic demonstrates that the lifetime of the carbocation is not sufficiently long for it to become symmetrically solvated. 

P-O bond fission is the usual mode of attack by nucleophiles on phosphodiesters, although there are exceptions. The labile diester methyl-2,4-dinitrophenyl phosphate shows significant amounts of attack at aromatic carbon (nucleophilic aromatic substitution, with loss of methyl phosphate) in competition with attack at phosphorus, most notably with hydroxide and with primary amines.46 Due to the small size of the methyl group it is sterically susceptible to nucleophilic attack in phosphate esters the hydrolysis of the dimethyl phosphate anion occurs almost exclusively by C-O bond fission.4 With larger or less labile leaving groups, even... 

The total synthesis of (-)-l-O-methylsweroside aglucone (486, R = Me) has been described by Ikeda and Hutchinson. We briefly mentioned (Vol. 4, p. 504) an earlier synthesis of the racemate of 486 (R = Me) by Hutchinson et al., and the key intermediate, 488, is the same, but now it has been prepared in optically active form. The starting material was (-)-489, made either by enzymatic in vitro oxidation of ( )-cyclohexene-4,5-bismethanol, or enantio-tropic hydrolysis of the corresponding diesters with pig-liver esterase. Two one-carbon homologations and a Pummerer reaction then converted this material... 

The open-chain tautomers 24b and 25 of precursor incipient imidazolidine and perhydropyrimidine derivatives, which bear a six carbon transferable fragment, on acid-catalyzed reactions with tryptamine formed the diester 85. A similar reaction of 24a leads to quantitative formation of 86 and the reaction of 25 with tryptamine is appreciably faster than that of 24b. Sodium cyanoborohydride/acetic acid reduction of 85 was accompanied by intramolecular aminolysis to form piperidone 87. Its Bischler-Napieralski cyclization followed by borohydride reduction gave cis- and trara-isomers of indoloquinolizine ester 88, which on hydrolysis to acid and subsequent methylene lactam rearrangement gave methylene lactam 89. Its DIBAL reduction gave 18- or-deplancheine 84a (88T6187). 

The degradation of the Senecio alkaloids continues to be effected by saponification or hydrogenolysis. The use of alkali in the hydrolysis does not alter the necine moiety but it may cause a change in the geometrical configuration about an a,j8-oarbon-carbon double bond in the necic acid. Hydrogenolysis provides important information as to the location of the esterified hydroxyl on the necine, and subsequent conversions permit a decision as to which end of a dicarboxylic necic acid (in the cyclic diesters) is attached to the allylic or primary hydroxyl of the necine. 

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