Strychnine, structure

In the post-World War II years, synthesis attained a different level of sophistication partly as a result of the confluence of five stimuli (1) the formulation of detailed electronic mechanisms for the fundamental organic reactions, (2) the introduction of conformational analysis of organic structures and transition states based on stereochemical principles, (3) the development of spectroscopic and other physical methods for structural analysis, (4) the use of chromatographic methods of analysis and separation, and (5) the discovery and application of new selective chemical reagents. As a result, the period 1945 to 1960 encompassed the synthesis of such complex molecules as vitamin A (O. Isler, 1949), cortisone (R. Woodward, R. Robinson, 1951), strychnine (R. Woodward, 1954), cedrol (G. Stork, 1955), morphine (M. Gates, 1956), reserpine (R. Woodward, 1956), penicillin V (J. Sheehan, 1957), colchicine (A. Eschenmoser, 1959), and chlorophyll (R. Woodward, 1960) (page 5). ... 

It is not certain that the rest of the molecule in these two alkaloids is identical in structure with that in strychnine and brucine. 

While this work was in progress Spath and Bretschneider showed that strychnine, on oxidation with permanganate in alkaline solution, furnished W-oxalylanthranilic acid (VII), brucine yielding oxalyl-4 5-dimethoxy-anthranilic acid, the latter observation providing confirmation of the evidence previously adduced that the two methoxy-groups in brucine are in the oj Ao-position relative to each other as indicated by Lions, Perkin and Robinson. The results so far considered indicate the presence in brucine and strychnine of the complex (VIII), which can be extended to (IX) if account is taken of the readiness with which carbazole can be obtained from strychnine and brucine and certain of their derivatives by decomposition with alkali at temperatures ranging from 200° to 400°, Knowledge of the structure of the rest of the molecule is mainly due to the results of the exhaustive study by Leuchs and his pupils of the oxidation... 

Three new papers bearing on the structure of strychnine have become available too late for inclusion in this summary of recent work. Woodward, Brehm and Nelson have compared the ultra-violet absorption spectra of strychnine and Leuchs s strychnone (p.. 559) and used the results for a discussion of the relationship of the two alkaloids. Prelog and Kathriner have investigated the oxidation of strychnine, i/t-strychnine and brucine by permanganate in weakly acid solution and Bailey and Robinson from a study of the brucones have confirmed the conclusion of Woodward et al. that Leuchs s strychnone is a true indole derivative. Mention must also be made of a paper by Clemo and King on new reduction products of strychnine, of which a preliminary account has been published with a summary of the ensuing discussion. 

Comparatively few alterations have been made since 1989 in the structures accepted for well-known alkaloids. A slight but important change has been adopted in the formula of strychnine and contributions to the chemistry of that alkaloid and its associates are still being made, though the formula seems now so well established that Woodward has recently suggested and discussed a scheme for the biogenesis of strychnine on which Robinson has commented favourably. Robinson has also proposed a scheme for the biogenesis of emetine. This involves a modification in the formula of that alkaloid, which is supported by Dewar s interpretation of the results of recent chemical work on emetine by Karrer et al., by Spath and by Pailer. ... 

Strychnine, the most celebrated member of the Strychnos alkaloids, possesses a complex polycyclic structure which is assembled from only twenty-four skeletal atoms. In addition to its obvious architectural complexity, strychnine s structure contains a contiguous array of six unsymmetrically substituted tetrahedral (asymmetric) carbon atoms of which five are included within one saturated six-membered ring. The intimidating structure of the strychnine molecule elicited the following remark by Sir Robert Robinson in 1952 For its molecular size it is the most complex substance known. 5... 

The structural homology between intermediate 4 and isostrych-nine I (3) is obvious intermediates 3 and 4 are simply allylic isomers and the synthetic problem is now reduced to isomerizing the latter substance into the former. Treatment of 4 with hydrogen bromide in acetic acid at 120°C results in the formation of a mixture of isomeric allylic bromides which is subsequently transformed into isostrychnine I (3) with boiling aqueous sulfuric acid. Following precedent established in 194810 and through the processes outlined in Scheme 8a, isostrychnine I (3) is converted smoothly to strychnine (1) upon treatment with potassium hydroxide in ethanol. Woodward s landmark total synthesis of strychnine (1) is now complete. 

Glycine receptor function is modulated by alcohols and anesthetics [4]. Amino acid residue al(S267) is critical for alcohol potentiation, as mutation to small residues (Gly, Ala) enhance, and mutation to large residues (His, Cys, Tyr) diminish the ethanol effect. Glycine recqrtor modulation by Zn2+ involves structural determinants located within the large N-terminal domain. Additional glycinergic modulators include neuroactive steroids and the anthelmintic, ivermectin, which activates glycine receptors by a novel, strychnine-insensitive mechanism. 

Stress Proteins Structural Bioinformatics Structural Genomics Strychnine STX... 

Figure 11.10 Glycine receptor pharmacology and structure, (a) Amino acids that act as agonists at glycine receptors, and strychnine a competitive antagonist, (b) Subunit composition of foetal and adult glycine receptors in the spinal cord. The receptors are shown with a pentameric assembly but the a. and subunits are distinct from those that form GABAa receptors. Picrotoxin is also an effective glycine antagonist and in recombinant systems is selective for homomeric receptors...

The dopaminergic potential of the Dendrobium species is, to date, open for exploration. An interesting feature of the Dendrobium species is their ability to elaborate sesquiterpene alkaloids, the chemical structure of which resembles the one of strychnine. One such alkaloid is dendrobine, which is widespread in the genus. Kudo et al. noted that dendrobine, isolated from Dendrobium nobile, exhibits a strychnine-like presynaptic inhibition in frog spinal cord (64). 

Using either of the methods just described in successive steps allows the identification of progressively larger fragments of the chemical structure of the molecule being studied or elucidated. In the case of strychnine, 1, shown... 

An n,l-ADEQUATE spectrum of strychnine (1) recorded using a /CH delay optimized for 8 Hz and a 1JCC delay optimized for 50 Hz is shown in Figure 11.77 The spectrum was recorded with the F1 frequency range set for 350 ppm with the transmitter located at 175 ppm just downfield of the CIO carbonyl resonance. To illustrate the interpretation of an n, 1-ADEQUATE spectrum, correlations for the C14 methine resonance will be considered. Obviously, based on the structure of strychnine (1), there are three carbon-carbon correlations possible from C14 to the C13 methine, the C15 methylene, and C21 quaternary vinyl carbons. 

Scheme 4.2 Strychnine is readily accessed via isostrychnine or the Wieland-Gumlich aldehyde using chemistry discovered during structural elucidation/degradation studies...

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