Aldehydes amino group

The 4-hydroxy-1-alkene (homoallylic alcohol) 81 is oxidized to the hetni-acetal 82 of the aldehyde by the participation of the OH group when there is a substituent at C3. In the absence of the substituent, a ketone is obtained. The hemiacetal is converted into butyrolactone 83[117], When Pd nitro complex is used as a catalyst in /-BuOH under oxygen, acetals are obtained from homoallylic alcohols even in the absence of a substituent at C-3[l 18], /-Allylamine is oxidized to the acetal 84 of the aldehyde selectively by participation of the amino group[l 19],... 

The final step can involve introduction of the amino group or of the carbonyl group. o-Nitrobenzyl aldehydes and ketones are useful intermediates which undergo cyclization and aromatization upon reduction. The carbonyl group can also be introduced by oxidation of alcohols or alkenes or by ozonolysis. There are also examples of preparing indoles from o-aminophcnyl-acetonitriles by partial reduction of the cyano group. 

Amino-5-nitrothiazole, on treatment with arenesulfonyl halides and dimethylformamide at 140 C, gives (5-nitro-2-thiazolyl)amidme (274) (Scheme 168) (507, 508). The condensation products of the reaction of 2-aminothiazole derivatives with various aldehydes are grouped in Tables... 

The amino group is readily dia2oti2ed in aqueous solution, and this reaction forms a basis for the assay of sulfas. Aldehydes also react to form anils, and the yellow product formed with 4-(dimethylamino)hen2a1dehyde can be used for detection in thiu-layer and paper chromatography. Chromatographic retention values have been deterrnined in a number of thiu layer systems, and have been used as an expression of the lipophilic character of sulfonamides (23). These values have corresponded well with Hansch lipophilic parameters determined in an isobutyl alcohol—water system. 

Pyridoxal Derivatives. Various aldehydes of pyridoxal (Table 3) react with hemoglobin at sites that can be somewhat controlled by the state of oxygenation (36,59). It is thereby possible to achieve derivatives having a wide range of functional properties. The reaction, shown for PLP in Figure 3, involves first the formation of a Schiff s base between the amino groups of hemoglobin and the aldehyde(s) of the pyridoxal compound, followed by reduction of the Schiff s base with sodium borohydride, to yield a covalendy-linked pyridoxyl derivative in the form of a secondary amine. 

FIGURE 17.11 Imine formation between the aldehyde function of 11-c/s-retinal and an amino group of a protein (opsin) is involved in the chemistry of vision. The numbering scheme in retinal is specifically developed for carotenes and related compounds. 

The alkaloids cotamine (259), hydrastinine (261), and berberinal (260), each possessing a grouping formed by interaction of an aldehyde with a secondary amino group in their molecule, are unusual. The Grignard reaction of free base 166 does not occur as readily as that of the corresponding salt 167. Both reactions lead to the alkylated product 168. For example, only 50% of hydrastinine reacts and 50% is regenerated, whereas hydrastinine hydrochloride reacts almost quantitatively (261). The salt undoubtedly contains a C=N double bond. In the case of the free base, the presence of a C=N double bond was not proven, and the reaction probably occurs by direct cleavage of the C—OH bond. 

The observations that heteroaromatic amino compounds are not easily diazotized, are quite readily hydrolyzed,and often do not form Schiff bases with aldehydes have all been incorrectly interpreted as indications that these compounds exist principally in the imino form, whereas these observations can reasonably be attributed to the fact that the amino groups in compounds of the type of 4-aminopyridine are electron deficient as a result of the contribution of structures of type 36. ... 

Aminobutenones of Z-configuration having at least one hydrogen atom attached to the amino group (80MI1) condense with aldehydes (EtOH, piperidine acetate, 25°C, 12 h) in 2 1 ratio to form 1,4-dihydropyiidine derivatives 290 (50NKZ1061). 

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. 

Penicilloic acid 5, the substrate for the projected lactamization reaction, could be derived from the suitably protected intermediate 6. Retrosynthetic disassembly of 6, in the manner illustrated, provides D-penicillamine hydrochloride (7) and tert-butyl phthalimido-malonaldehydate (8) as potential building blocks. In the synthetic direction, it is conceivable that the thiol and amino groupings in 7 could be induced to converge upon the electrophilic aldehyde carbonyl in 8 to give thiazolidine 6 after loss of a molecule of water. 

The synthesis of the E-ring intermediate 20 commences with the methyl ester of enantiomerically pure L-serine hydrochloride (22) (see Scheme 9). The primary amino group of 22 can be alkylated in a straightforward manner by treatment with acetaldehyde, followed by reduction of the intermediate imine with sodium borohydride (see 22 —> 51). The primary hydroxyl and secondary amino groups in 51 are affixed to adjacent carbon atoms. By virtue of this close spatial relationship, it seemed reasonable to expect that the simultaneous protection of these two functions in the form of an oxazolidi-none ring could be achieved. Indeed, treatment of 51 with l,l -car-bonyldiimidazole in refluxing acetonitrile, followed by partial reduction of the methoxycarbonyl function with one equivalent of Dibal-H provides oxazolidinone aldehyde 52. 

Surprisingly, acetylation in hot pyridine yields the pyridinium salt 10. The amino group has amidine character and is resistant to diazotization, and condenses only with reactive aldehydes such as formaldehyde and trichloroacetaldehyde.41... 

The addition of titanated allyl carbamates to jV-protectcd (S )-amino aldehydes allows rapid access to intermediates for various dipeptide isosteres98-10°, offering a versatile brick-box system (Table 5). If an acidic amino group is present, two equivalents of reagent are required. 

Miscellaneous Identified Inhibitors. 3-Acetyl-6-methoxy-benzaldehyde is present in the leaves of the desert shrub Encelia farinosa. It is apparently leached from the leaves and washed into the soil by rain. Concentrations of approximately 0.5 mg. per gram of dried leaf material have been measured. In sand culture studies, growth of tomato seedlings was inhibited by 50 p.p.m. while 115 p.p.m. reduced growth by 50% (53). A concentration of 250 p.p.m. killed the test plants within one day. The structure was confirmed by synthesis, and the synthetic material was shown to be as active as the natural product (54). Derivatives were also prepared in which a cyano, nitro, or amino group was substituted for the aldehyde moiety. The amino derivative was reported to be the most highly toxic. 

B) The aldehyde groups interact with dyes containing amino groups ... 

Pyridoxal phosphate mainly serves as coenzyme in the amino acid metabolism and is covalently bound to its enzyme via a Schiff base. In the enzymatic reaction, the amino group of the substrate and the aldehyde group of PLP form a Schiff base, too. The subsequent reactions can take place at the a-, (3-, or y-carbon of the respective substrate. Common types of reactions are decarboxylations (formation of biogenic amines), transaminations (transfer of the amino nitrogen of one amino acid to the keto analog of another amino acid), and eliminations. 

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