Nucleophilic substitution phenolic oxygen alkylation

For carbon-carbon bond-formation purposes, S 2 nucleophilic substitutions are frequently used. Simple S 2 nucleophilic substitution reactions are generally slower in aqueous conditions than in aprotic organic solvents. This has been attributed to the solvation of nucleophiles in water. As previously mentioned in Section 5.2, Breslow and co-workers have found that cosolvents such as ethanol increase the solubility of hydrophobic molecules in water and provide interesting results for nucleophilic substitutions (Scheme 6.1). In alkylations of phenoxide ions by benzylic chlorides, S/y2 substitutions can occur both at the phenoxide oxygen and at the ortho and para positions of the ring. In fact, carbon alkylation occurs in water but not in nonpolar organic solvents and it is observed only when the phenoxide has at least one methyl substituent ortho, meta, or para). The effects of phenol substituents and of cosolvents on the rates of the competing alkylation processes... 

O-Alkylation. The most thoroughly investigated alkylation using 1 is with oxygen nucleophiles. Only a limited number of successful O-alkylations exist and are currently limited to sodium acetate, a potassium carboxylate (15), and substituted phenols. The conditions used in all cases employ polar aprotic solvents (e.g., DMF, DMSO) and elevated temperatures, and use either 2 directly (eq 8) or sodium iodide or potassium iodide for in situ conversion of 1 to 2 (eq 9). 

Amino acid residues, except hydrocarbon chains, may provide nucleophilic sites (electron-rich centers) or electrophilic sites (electron-deficient centers) for chemical modifications. Electron-rich centers include sulfur nucleophiles (thiol of Cys and thioether of Thr), nitrogen nucleophiles (e-amino of Lys, imidazole of His and Guanidyl of Arg), oxygen nucleophiles (phenolic of Tyr, carboxyl of Asp and Glu and hydroxyl of Ser and Thr), and carbon nucleophile (a-position of indole ring of Trp), with an increasing nucleophilicity in that order. They provide nucleophilic sites for alkylation (nncleophilic substitution), acylation, addition and oxidation at pH near or above their pK values. Electron-deficient centers include ammonium cation of Lys, guanidiiun cation of Arg and imidazolium cation of His. They provide electrophilic sites for metalation and reduction at pH near or below their pK values. 

Certain compounds (electrophilic) can react with phenols (nucleophilic). The nucleophilic activity can be either in the iaromatic ring or the oxygen in the hydroxyl group. Examples of electrophilic aromatic substitution include nitration, halogenation, Friedel-Crafts reactions (alkylation and acylation), and sulfonation. The halogenation example shown below is a polysubstitution reaction involving bromine. The polysubstitution usually occurs when polar solvents are used. 

Phenols can be viewed as stable forms of enol tautomers, and phenolate anions display ambident nucleophilicity at oxygen as weU as C2/C6 and C4 (ortholpara positions). Consequently, phenolate anions are susceptible to C—C bond formation upon reaction with appropriate organic electrophiles (e.g., alkyl halides and sulfonates). When bond formation occurs at a substituted arene carbon, a quatonaty centCT is generated, which may lead to isolation of stable cyclohexadienone products and complete a net alkylative dearomatization (Scheme 15.1) [2]. 

The Tsuji-Trost reaction is the palladinum-catalyzed substitution of allylic leaving groups by carbon nucleophiles. The nucleophile can be carbon-, nitrogen-, or oxygen- based compounds such as alcohols, enolates, phenols, and enamines, and the leaving group can be a halide or an acetate. This emerged as a powerful procedure for the formation of C—C, C—O and C—N bonds. The reaction, also known as Trost allylation or allylic alkylation, was named after Jiro Tsuij, who first reported the method in 1965 [42], and Barry Trost, who introduced an asymmetric version in 1973 [43]. 

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