Amino acids imines and

Peptide synthesis via a three or tour component condensation (amino acid, imine and bocyanide)... 

Q An amino acid reacts with the enzyme-bound PLP inline by nucleophilic addition of its -NH2 group to the C=N bond of the imine, giving a PLP-amino acid imine and releasing the enzyme amino group. 

The mechanism of the first part of transamination is shown in Figure 29.14. The process begins with reaction between the a-amino acid and pyridoxal phosphate, which is covalently bonded to the aminotransferase by an iminc linkage between the side-chain -NTI2 group of a lysine residue and the PLP aldehyde group. Deprotonation/reprotonation of the PLP-amino acid imine in steps 2 and 3 effects tautomerization of the imine C=N bond, and hydrolysis of the tautomerized imine in step 4 gives an -keto acid plus pyridoxamine... 

Step 1 of Figure 29.14 Transimination The first step in transamination is trans-imination—the reaction of the PLP—enzyme imine with an a-amino acid to give a PLP—amino acid imine plus expelled enzyme as the leaving group. The reaction occurs by nucleophilic addition of the amino acid -NH2 group to the C=N bond of the PLP imine, much as an amine adds to the C=0 bond of a ketone or aldehyde in a nucleophilic addition reaction (Section 19.8). The pro-tonated diamine intermediate undergoes a proton transfer and expels the lysine amino group in the enzyme to complete the step. 

Figure 29.15 Mechanism of steps 2-4 of amino acid transamination, the conversion of a PLP-amino acid imine to PMP and an a-keto acid.

Clerici and Porta reported that phenyl, acetyl and methyl radicals add to the Ca atom of the iminium ion, PhN+Me=CHMe, formed in situ by the titanium-catalyzed condensation of /V-methylanilinc with acetaldehyde to give PhNMeCHMePh, PhNMeCHMeAc, and PhNMeCHMe2 in 80% overall yield.83 Recently, Miyabe and co-workers studied the addition of various alkyl radicals to imine derivatives. Alkyl radicals generated from alkyl iodide and triethylborane were added to imine derivatives such as oxime ethers, hydrazones, and nitrones in an aqueous medium.84 The reaction also proceeds on solid support.85 A-sulfonylimines are also effective under such reaction conditions.86 Indium is also effective as the mediator (Eq. 11.49).87 A tandem radical addition-cyclization reaction of oxime ether and hydrazone was also developed (Eq. 11.50).88 Li and co-workers reported the synthesis of a-amino acid derivatives and amines via the addition of simple alkyl halides to imines and enamides mediated by zinc in water (Eq. 11.51).89 The zinc-mediated radical reaction of the hydrazone bearing a chiral camphorsultam provided the corresponding alkylated products with good diastereoselectivities that can be converted into enantiomerically pure a-amino acids (Eq. 11.52).90... 

Biosorption is a rather complex process affected by several factors that include different binding mechanisms (Figure 10.4). Most of the functional groups responsible for metal binding are found in cell walls and include carboxyl, hydroxyl, sulfate, sulfhydryl, phosphate, amino, amide, imine, and imidazol moieties.4 90 The cell wall of plant biomass has proteins, lipids, carbohydrate polymers (cellulose, xylane, mannan, etc.), and inorganic ions of Ca(II), Mg(II), and so on. The carboxylic and phosphate groups in the cell wall are the main acidic functional groups that affect directly the adsorption capacity of the biomass.101... 

Possible racemisation of imines, derivatives of amino acids and R(—)-myrtenal, has been examined by Dufrasne et al.1 After 72 h, no significant effect on chiral purity was observed. For imines being derivatives of chiral primary amines and the a-substituted 8-keto-aldehydes, no evidence of epimerisation has been indicated by the NMR measurements.3 For a series of imines, being derivatives of amino acids or amino acid esters and (R)-BINOL reagents, Chin et al.5 have tested the possibility of epimerization under experiment conditions. It was shown that R S ratio has changed only slightly, and after 24 h, the difference was lower than 10%. 

Catalytic asymmetric cyanide addition to imines constitutes an important C—C bondforming reaction, as the product amino nitriles may be converted to non-proteogenic a-amino acids. Kobayashi and co-workers have developed two different versions of the Zr-catalyzed amino nitrile synthesis [73]. The first variant is summarized in Scheme 6.22. The bimetallic complex 65, formed from two molecules of 6-Br-binol and one molecule of 2-Br-binol in the presence of two molecules of Zr(OtBu)4 and N-methylimidazole, was proposed as the active catalytic species. This hypothesis was based on various NMR studies more rigorous kinetic data are not as yet available. Nonetheless, as depicted in Scheme 6.22, reaction of o-hydroxyl imine 66 with 5 mol% 65 and 1—1.5 equiv. Bu3SnCN (CH2C12, —45 °C) leads to the formation of amino nitrile 67 with 91 % ee and in 92 % isolated yield. As is also shown in Scheme 6.22, electron-withdrawing (— 68) and electron-rich (—> 69), as well as more sterically hindered aryl substituents (— 70) readily undergo asymmetric cyanide addition. 

Coordinated a-amino amides can be formed by the nucleophilic addition of amines to coordinated a-amino esters (see Chapter 7.4). This reaction forms the basis of attempts to use suitable metal coordination to promote peptide synthesis. Again, studies have been carried out using coordination of several metals and an interesting early example is amide formation on an amino acid imine complex of magnesium (equation 75).355 However, cobalt(III) complexes, because of their high kinetic stability, have received most serious investigation. These studies have been closely associated with those previously described for the hydrolysis of esters, amides and peptides. Whereas hydrolysis is observed when reactions are carried out in water, reactions in dimethyl-formamide or dimethyl sulfoxide result in peptide bond formation. These comparative results are illustrated in Scheme 91.356-358 The key intermediate (126) has also been reacted with dipeptide... 

Chiral addition of allyl metals to imines is one of the useful approaches toward the synthesis of homoallylic amines. These amines can be readily converted to a variety of biologically important molecules such as a-, / -, and y-amino acids. Itsuno and co-workers utilized the allylborane 174 derived from diisopropyl tartrate and cr-pinene for the enantioselective allylboration of imines. The corresponding iV-aluminoimines 173 are readily available from the nitriles via partial reduction using diisobutylaluminium hydride (DIBAL-H) <1999JOM103>. Recently, iV-benzyl-imines 176 have also been utilized for the asymmetric allylboration with allylpinacol boronate 177 in the presence of chiral phosphines as the chiral auxiliaries to obtain homoallylic A -benzylamines 178 in high yield and selectivity (Scheme 29) <2006JA7687>. 

Amines quaternary ammonium derivatives, amino acid peptides and imines... 

Amino Acid Oxidase and Chemical In Situ Reduction of the Initially Formed Imino Compound A simple and interesting procedure for the deracemization of a-amino acids was introduced by Soda [48], who combined the oxidation of the D-enantiomer of D,L-proline to dehydro-prohne with a chemical reduction of the imine 21 in on -pot, thereby restoring the racemic mixture. If the reaction in the first step is completely enantioselective, the e.e. of the amino acid after one cycle is 50%. Repeating the reaction in successive cycles raises the e.e. close to 100% (Scheme 13.19). 

From a.-Amino Acid Amides and Amidines a-Amino acid amides, which fall into the amine-imine class according to the general model (beginning of Section II,B), are converted to 3-alkyl-4-hydroxy-l,2,5-thiadiazoles by reaction with sulfur mono-chloride, thionyl chloride, or thionyl aniline. A large number of -amino acid amides were employed in the synthesis (see Table I)... 

Strecker reactions are among the most efficient methods of synthesis of a-amino nitriles, useful intermediates in the synthesis of amino acids [73] and nitrogen-containing heterocycles such as thiadiazoles, imidazoles, etc. [74]. Although classical Strecker reactions have some limitations, use of trimethylsilyl cyanide (TMSCN) as a source of cyano anion provides promising and safer routes to these compounds [73b,75]. TMSCN is, however, readily hydrolyzed in the presence of water, and it is necessary to perform the reactions under strictly anhydrous conditions. BusSnCN [76], on the other hand, is stable in water and a potential source of cyano anion, and it has been found that Strecker-type reactions of aldehydes, amines, and BuaSnCN proceed smoothly in the presence of a catalytic amoimt of Sc(OTf)3 in water [77]. No surfactant was needed in this reaction. The reaction was assumed to proceed via imine formation and successive cyanation (it was confirmed that imine formation was much faster than cyanohydrin ether formation under these reaction conditions) again the dehydration process (imine formation) proceeded smoothly in water. 

Trimethylsilyl difluoroenol ethers and their imine analogs react with a variety of different electrophiles [29] (Schemes 2.196 and 2.197). They have, for example, been used for the synthesis of fluorinated amino acids [30] and anti-malarials [31]. 

Scheme 10.17 Insoluble supports for chiral PTC and their use in the alkylation of amino acids imines.

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