Quinine, structure

Quaternary carbon. 84 Quaternary structure (protein). 1038 Quinine, structure of, 533, 950 Quinoline, aromaticity of, 533... 

Quinoline forms part of quinine (structure at the head of this chapter) and isoquinoline forms the central skeleton of the isoquinoline alkaloids, which we will discuss at some length in Chapter 51. In this chapter we need not say much about quinoline because it behaves rather as you would expect—its chemistry is a mixture of that of benzene and pyridine. Electrophilic substitution favours the benzene ring and nucleophilic substitution favours the pyridine ring. So nitration of quinoline gives two products—the 5-nitroquinolines and the 8-nitroquinolines—in about equal quantities (though you will realize that the reaction really occurs on protonated quinoline. 

Iht4-aminoquinolines (Fig. 9-3) are the closest of the anli-lulinals that are based on the quinine structure. This group a siKtiluted at the same position 4 as quinine and has an j))iniiieuiccarbon equivalent lo quinine s C-9 pasiiion. Jusi... 

The quinine structure (Fig. 7-6) has two components the quinoline portion, which is bonded to the 8 position of the quinuclidine ring via a methanol bridge at its 4 position. The stereochemistry of quinine, (-) 8S 9R, differs from quinidine, (+) 8R 9S the chiral... 

German apothecary Friedrich Koch (1786-1865) (a) Swiss chemist Amd Jules Pictet (1857-1937) (b) 3D-model of quinine structure (c). 

Obviously, iminoxyl and acyl(alkyl)aminoxyl radicals cannot be formed by the direct interaction of NO with the double bonds of the quinines, but these radicals are produced as a result of thermal conversions of primary oxyaminoxyl radicals most likely because of the strong angular strain arising from their bicyclic structure. Oxyaminoxyl radicals can decompose, giving alkoxyl radicals, which subsequently break down, leading to the destruction of the quinine structure with the formation of acyl radicals containing nitroso groups ... 

The antimalarial properties attributed to preparations from Dichroa febrifuga by the Chinese were confirmed about 1944 and two alkaloids, febrifugine (999) and isofebrifugine (1000), were isolated eventually. After difficult structural elucidations, syntheses of ( )-febrifugine followed it proved to be half as active as the natural material, itself far better than quinine, but the therapeutic index was disappointingly low (67HC(24-l)490). 

It has long been known that quaternary ammonium salts can exert a curare-like action, and in recent years much attention has been given to the synthesis and pharmacological testing of such products work on this subject up to 1936 has been reviewed by Ing, and more recently a theoretical discussion of the relationship between structure and action in drugs of this type has been provided by Holmes, Jenden and Taylor.Chase, Lehmann and Yonkmann have compared the action of quaternary salts of quinine with that of -erythroidine hydrochloride and of dihydro- -erythroidine hydrobromide. Quinine ethochloride shows marked curariform action of short duration. ... 

These results indicate that quinine and quinidine differ in structure from cinchonine and cinehonidine in containing a methoxyl group in position 6 in a quinoline nucleus. The identity of the other oxidation products, meroquinenine, cincboloiponic and loiponic acids, in all foiu" cases indicates that the second half of the molecule has the same structure in all four alkaloids. Further, this second half must be joined to the quinoline nucleus at position 4 by a group capable of conversion into carboxyl. 

The directions of rotation at C and C have been arrived at from the following considerations. The deoxy-bases (II p. 443 Q = quinoline residue) obtained from cinchonine and cinchonidine are structurally identical, i but optically different, and since they must be optically identical at C and C, and C is no longer asymmetric, the difference between them (see table, p. 446) must be due to difference in direction of rotation at C , which must therefore be dextrorotatory in cinchonine and laevorotatory in cinchonidine, and this must also be true of quinidine and quinine respectively and of the corresponding dihydro-bases. The keto-bases, cinchoninone and quininone, might be expected to exist each in two pairs, since carbon atom 8 is, according to the formula (p. 442), asymmetric, but it is better represented by the tautomeric grouping —... 

Bohman and Allenmark resolved a series of sulphoxide derivatives of unsaturated malonic acids of the general structure 228. The classical method of resolution via formation of diastereoisomeric salts with cinchonine and quinine has also been used by Kapovits and coworkers " to resolve sulphoxides 229, 230, 231 and 232 which are precursors of chiral sulphuranes. Miko/ajczyk and his coworkers achieved optical resolution of sulphoxide 233 by utilizing the phosphonic acid moiety for salt formation with quinine. The racemic sulphinylacetic acid 234, which has a second centre of chirality on the a-carbon atom, was resolved into pure diastereoisomers by Holmberg. Racemic 2-hydroxy- and 4-hydroxyphenyl alkyl sulphoxides were separated via the diastereoisomeric 2- or 4-(tetra-0-acetyl-D-glucopyranosyloxy)phenyl alkyl sulphoxides 235. The optically active sulphoxides were recovered from the isolated diastereoisomers 235 by deacetylation with base and cleavage of the acetal. Racemic 1,3-dithian-l-oxide 236... 

FIG. 22 Chemical structures of (a) dextromethorphan hydrobromide, (b) papaverine hydrochloride, (c) quinine hydrochloride, and (d) berberine chloride. 

At the time, little was known about the internal structure of compounds or about how one compound was transformed into another. Chemists concentrated instead on the proportions of various chemicals in a substance. Hofmann realized that the proportions of ingredients in the antimalaria drug quinine— 20 equivalents of carbon, 11 equivalents of hydrogen, 1 equivalent of nitrogen, and 2 equivalents of oxygen —were almost identical to those in aniline. The difference was only two equivalents of water. Hofmann speculated that he might be able to turn aniline into quinine. With European colonization headed toward the tropics, the drug was desperately needed. 

Reaction centers of bacteria contain polypeptides, bacteriochlorophylls, bacteriopheo-phytins, two quinines, and nonheme iron atom. In some bacterial species, both the quinones are ubiquinones, whereas in some others one of the quinones is menaquinone [37,39]. Depending on the bacterial species chloroplasts contain plastoquinone and phyl-loquinone. Structures of ubiquinone, menaquinone, and phylloquinone are provided in Figures 7.12 through 7.14, respectively. 

Most of the attempted asymmetric reductions have used sodium borohydride in conjunction with quaternary ammonium catalysts. Recently, the solution structures of ion pairs formed by quaternary ammonium ions derived from quinine with borohydride ion have been characterized by nuclear magnetic resonance methods in CDC13.1741... 

C. Hofstetter, P. S. Wilkinson, T. C. Pochapsky, NMR Structure Determination of Ion Pairs Derived from Quinine A Model for Templating in Asymmetric Phase-Transfer Reductions by BH4" with Implications for Rational Design of Phase-Transfer Catalysts , J. Org. Chem 1999, 64, 8794-8800. 

More than half of the reported secondary metabolites from macroalgae are isoprenoids. Terpenes, steroids, carotenoids, prenylated quinines, and hydroqui-nones make up the isoprenoid class, which is understood to derive from either the classical mevalonate pathway, or the mevalonate-independent pathway (Stratmann et al. 1992). Melavonic acid (MVA) (Fig. 1.2) is the first committed metabolite of the terpene pathway. Dimethylallyl (dl meth al lal) pyrophosphate (DMAPP) (Fig. 1.3) and its isomer isopentenyl pyrophosphate (IPP, Fig. 1.3) are intermediates of the MVA pathway and exist in nearly all life forms (Humphrey and Beale 2006). Geranyl (ja ran al) (C10) and famesyl (C15) units are generated by head-to-tail (Fig. 1.3) condensation of two (for C10) or three (for C15) 5-carbon DMA-like isoprene units, identifiable in final products by the characteristic fish-tail repeating units, as traced over the structure of a sesquiterpene in Fig. 1.3 (Humphrey and Beale 2006). Additional IPP condensation with famesyl pyrophosphate (FPP)... 

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