Synthesis of the ring-A precursor

Starting point for the synthesis of the ring-A precursor was methoxydimethyl-indol H-1 synthesized by condensation of the Schiff base from m-anisidine and acetoin. Reaction with the Grignard reagent of propargyl iodide gave racemic propargyl indolenine rac-H-2; ring closure to the aminoketone rac-H-3 was brought about by BF₃ and HgO in MeOH through intermediate rac-H-2a (electrophilic addition) with the two methyl groups forced into a cis-relationship by kinetic as well as thermodynamic reasons.^{[1]: 521-522}

Resolution of the racemic aminoketone into the two enantiomers. Reaction of rac-H-3 with (−)-ethyl isocyanate permitted isolation by crystallization of one of the two diastereomeric urea derivatives formed (the other does not crystallize). Treatment of racemic ketone rac-H-3 (or of mother liquors from the previous crystallization) with (+)-ethyl isocyanate gave the enantiomer of the first urea derivative. Pyrolytic decomposition of each of these urea derivatives led to enantiopure aminoketones, the desired (+)-H-3, and (−)-H-3.^{[1]: 524-525} The "unnatural" (−)-enantiomer (−)-H-3 was used to determine the absolute configuration; in various later steps, (−)-H-3 and enantio-intermediates derived from it were used as model compounds in exploratory experiments.^[38]: 173 Woodward wrote regarding the unnatural enantiomer "our experience has been such that this is just about the only kind of model study which we regard as wholly reliable".^[1]: 529

Determination of the absolute configuration of ring-A precursor (+)-H-3. For this determination, the levo-rotatory ("unnatural") enantiomer of aminoketone (−)-H-3 was used in order to save precious material: Acylation of the amino group of (−)-H-3 with chloroacetyl chloride, followed by treatment of the product H-3a with potassium t-butoxide in t-butanol, afforded tetracyclic keto-lactame H-3b. Its keto carbonyl was converted to a methylene group by desulfurization of the dithioketal of H-3b with Raney nickel to give lactam H-3c. Destruction of the aromatic ring by ozonolysis, involving the loss of a carboxyl function by spontaneous decarboxylation, led to bicyclic lactam-carboxylic acid H-3d. This material was identified with a product H-3h derived from (+)-camphor, possessing the same constitution and the absolute configuration as shown in formula H-3d.^{[1]: 525-526}

The material for this identification of H-3d was synthesized from (+)-camphor as follows: cis-isoketopinic acid H-3e, obtained from (+)-camphor by an established route described in the literature,^[70] was converted via the corresponding chloride, azide, and isocyanate to methyl-urethane H-3f. When treated with potassium t-butoxide in t-butanol and subsequently with KOH, H-3f was converted to H-3h, clearly by way of the intermediate H-3g. The identity of the two samples of H-3d and H-3h obtained by the two routes described, established the absolute configuration of (+)-H-3, the enantiomer of the ring-A precursor.^{[1]: 525-526}

Synthesis of the ring-D precursor from (-)-camphor

(−)-Camphor was nitrosated in the α-position of the carbonyl group to give oxime H-4, Beckmann cleavage afforded via the corresponding nitrile the amide H-5. Hofmann degradation via an intermediary amine and its ring closure led to lactam H-6. Conversion of its N-nitroso derivative H-7 gave diazo compound H-8. Thermal decomposition of H-8 induced methyl migration to give cyclopentene H-9. Reduction to H-10 (LiAlH₄), oxidation (chromic acid) to aldehyde H-11, Wittig reaction (carbomethoxymethylenetriphenylphosphorane) to H-12 and hydrolysis of the ester group finally gave trans-carboxylic acid H-13.^{[1]: 527-528 [note 14]}

Coupling of ring-A and ring-D precursors to "pentacyclenone"

N-acylation of tricyclic aminoketone (+)-H-3 with the chloride H-14 of carboxylic acid H-13 gave amide H-15, which on treatment with potassium t-butoxide in t-butanol stereoselectively produced pentacyclic keto-lactam H-16 via an intramolecular Michael reaction which directs the indicated hydrogen atoms in trans relationship to each other. In anticipation of the Birch reduction of the aromatic ring, protective groups for the two carbonyl functions of H-16 were required, one for the ketone carbonyl group as ketal H-17, and the other for the lactam carbonyl as the highly sensitive enol ether H-20. The latter protection was achieved by treatment of H-17 with Meerwein salt (triethyloxonium tetrafluoroborate) to give iminium salt H-18, followed by conversion to orthoamide H-19 (NaOMe/MeOH), and finally expelling one molecule of methanol by heating in toluene. Birch reduction of H-20 (lithium in liquid ammonia, t-butanol, THF) provided tetraene H-21. Treatment with acid under carefully controlled conditions led first to an intermediate dione with the double bond in β,γ position which moved to the conjugated position in dione H-22, dubbed pentacyclenone.^{[1]: 528-531 [14]: 5}

From "pentacyclenone" to "corrnorsterone"

The ethylene ketal protecting group in pentacyclenone H-22 was converted to the ketone group of H-23 by acid-catalyzed hydrolysis.^[1]: 531 The dioxime primarily formed by reaction of diketone H-23 with hydroxylammonium chloride was regioselectively hydrolyzed (nitrous acid/acetic acid) to the desired mono-oxime H-24. This is the oxime of the sterically more hindered ketone group, the nitrogen atom of which is destined to become the nitrogen of the target molecule's ring D. Crucial for this purpose is the configuration at the monoxime double bond, the hydroxyl group occupying the sterically less hindered position.^[1]: 532 The C,C double bonds of both the cyclopentene and the cyclohexenone ring in H-24 were then cleaved by ozonolysis (ozone at 80 °C in MeOH, periodic acid), and the carboxylic group formed esterified with CH₂N₂) to diketone H-25. An intramolecular aldol condensation of the 1,5-dicarbonyl unit in MeOH using pyrrolidine acetate as the base, followed by tosylation of the oxime's hydroxyl group, afforded the cyclohexenone derivative H-26. A second ozonolysis in wet methyl acetate, followed by treatment with periodic acid and CH₂N₂ gave H-27. Beckmann rearrangement (MeOH, sodium polystyrene sulfonate, 2 hrs, 170 °C) produced regioselectively^[1]: 532 lactam H-27a (not isolated) which reacted further in an amine-carbonyl condensation → aldol condensation cascade to the tetracycle H-28,^{[1]: 533-534} called α-corrnorsterone, implicating it as a "cornerstone"^[1]: 534 in the synthesis of the desired A-D-component.^{[1]: 531-537}

This compound required strongly alkaline conditions in order to open its lactam ring, but it was discovered that a minor isomer, also isolated from the reaction mixture, β-corrnorsterone H-29, undergoes this lactam ring opening under alkaline condition with great ease.^[1]: 536 Structurally, the two isomers differ only in the orientation of the propionic acid side chain at ring A: the β-isomer has the more stable trans-orientation of this chain relative to the neighboring acetic acid chain formed after opening of the lactam ring. Equilibration of α-corrnorsterone H-28 by heating in strong base, followed by acidification and treatment with diazomethane, led to the isolation of pure β-corrnorsterone H-29 in 90 % yield.^[1]: 537 The correct absolute configuration of the six contiguous asymmetric centers in β-corrnorsterone was confirmed by an x-ray crystal structure analysis of bromo-β-corrnorsterone^{[71][1]: 529} with the "unnatural" configuration.^{[1]: 538 [14]: 8 [4]: 0:49:20-0:50:42}

Synthesis of the A-D-component carrying the propionic acid function at ring D as methoxycarbonyl group (model A-D-component)

Treatment of β-corrnorsterone H-29 with methanolic HCl cleaved the lactam ring and produced an enol ether derivative named hesperimine^{[note 15]} H-30u. Ozonolysis to aldehyde H-32u, reduction of the aldehyde group with NaBH₄ in MeOH to the primary alcohol H-33u and, finally, conversion of the hydroxy group via the corresponding mesylate gave bromide H-34u. This constitutes the model A-D-component, the one with an undifferentiated propionic acid function at ring D (i.e., bearing a methyl ester group like all other side chains).^{[1]: 539-540}

Synthesis of the A-D-component carrying the propionic acid function at ring D as nitrile group

Conversion of β-corrnorsterone H-29 to the proper A-D-component H-34^{[1]: 538-539} containing the carboxyl function of the ring D propionic acid side chain as a nitrile group, differentiated from all the other methoxycarbonyl groups, involved the following steps: treatment of H-29 with a methanolic solution of thiophenol and HCl afforded phenyl-thioenolether derivative H-30, which upon ozonolysis at low temperature gave the corresponding thioester-aldehyde H-31 and, when followed by treatment with liquid ammonia, the amide H-32. Reduction of the aldehyde group with NaBH₄ to H-33, mesylation of the primary hydroxy group with methanesulfonic anhydride under conditions that also convert the primary amide group into the desired nitrile group and, finally, replacement of the methansulfonyloxy group by bromide produced A-D-component H-34 with the propionic acid function at ring D as nitrile, differentiated from all other such side chains.^{[1]: 539-540 [4]: 1:01:56-1:19:47}

The construction of the corrin chromophore with its three vinylogous amidine units constitutes  – besides the direct single bond connection between the rings A and D  – the central challenge to any attempt to synthesize vitamin B₁₂. The very first approach to a total synthesis of vitamin B₁₂ launched by Cornforth^{[45]: 261-268} was discontinued when confronted with the task of coupling synthesized ring precursors.^{[18]: 1493,1496} Coupling the Harvard A-D-components with the ETH B-C-component required extensive exploratory work, this in spite of the knowledge gained in the ETH model syntheses of less complex (i.e., less peripherally substituted) corrins. What might be called an epic engagement for formally making just two C,C bonds lasted from early 1967^[18]: 1557 until June 1970.^[2]

Both at ETH and Harvard, extensive model studies on the coupling of simplified enaminoid analogues of the A-D-component with the (ring C) imino- and thio-iminoester derivative of the full-fledged B-C-component had consistently shown that a coupling of the Harvard and the ETH components could hardly be achieved by the method that had been so successful in the synthesis of the simpler corrins, namely, by an intermolecular enamino-imino(or thio-imino)ester condensation^{[7][8][18]: 1561 [62]: 41-58 [1]: 544 [4]: 1:25:02-1:26:26} The outcome of these model studies determined the final structure type of a Harvard A-D-component: a structure capable of acting as a component of a C/D-coupling by sulfide contraction via alkylative coupling,^{[8]: 384-386 [47]} i.e., the bromide H-34u.^{[7]: 18-22 [62]: 47,51-52} This method had already been implemented by the ETH group in the synthesis of the B-C-component.^{[33]: 16-19 [37]: 1927-1941 [18]: 1537-1540}

An extensive search for optimal conditions, first for a C/D-coupling of a A-D-component with the ETH B-C-component E-19, then for conditions of the subsequent intramolecular A/B-corrin-ring closure was pursued in both laboratories, using the f-undifferentiated model A-D-component^{[note 7]} H-34u^[1]: 540 as a model.^{[2]: 287-300 [18]: 1561-1564} As the result of work by Yoshito Kishi at Harvard,^{[2]: 290 [18]: 1562 [14]: 11-12} and Peter Schneider at ETH,^{[48]: 12,22-29 [18]: 1563-1564} optimal conditions for the C/D-coupling were eventually found at Harvard, while the first and most reliable method for the corrin-ring closure between rings A and B was developed at ETH.^[18]: 1562 The procedures of C/D-coupling and A/B-corrin-ring closure developed in this model series were later applied to the corresponding steps in the f-differentiated series as parts of the cobyric acid synthesis.

Synthesis of dicyano-cobalt(III)-5,15-bisnor-a,b,c,d,e,f,g-heptamethyl-cobyrinate from the ring-D undifferentiated model A-D-component

D/C coupling.^{[7]: 22-23 [2]: 287-292 [48]: 12,22-28 [18]: 1561-1562}

The key problem in this step was the lability of the primary coupling product, thioether HE-35u, isomerizing to other thioethers at first not amenable to sulfide contraction in a reproducible procedure with acceptable yields.^{[2]: 287-290 [4]: 1:26:59-1:32:00} Induced by potassium t-butoxide in THF/t-butanol under rigorously controlled conditions with strict exclusion of air and moisture, the model A-D-component H-34u smoothly reacted with the B-C-component E-19^{[48]: 53-58} to give the sulfur-bridged coupling product HE-35u, named "thioether type I", in essentially quantitative yield.^{[2]: 287-288} However, this product could be isolated only under very carefully controlled conditions, since it equilibrates with extreme ease (e.g., chromatography, or traces of trifluoroacetic acid in methylenechloride solution) to the more stable isomeric thioether HE-36u (thioether type II) which contains, in contrast to thioether type I, the π-system of a conjugatively stabilized vinylogous amidine.^[2]: 289 Depending on conditions, still another isomer HE-37u (thiother type III) was observed.^[2]: 290 Starting with such mixtures of coupling products, at ETH a variety of conditions (e.g. methyl-mercury complex, BF₃, triphenylphosphine^{[48]: 58-65 [2]: 291}) were found to induce (via HE-38u) the contraction step to HE-39u in moderate yields.^{[18]: 1562 [2]: 287-292} With the choice of the solvent found to be crucial,^{[4]: 1:34:52-1:35:12} the optimal procedure at Harvard was heating thiother type II HE-36u in sulfolane in the presence of 5.3 equivalents trifluoroacetic acid and 4.5 equivalents of tris-(β-cyanoethyl)-phosphine at 60 °C for 20 hours, producing HE-39u in up to 85% yield.^{[2]: 292 [48]: 65-72} Later it was discovered that nitromethane could also be used as solvent.^{[4]: 1:34:52-1:35:13 [48]: 28}

A/B-ring closure.^{[2]: 293-300 [48]: 12,29-39 [18]: 1562-1564}

The problem of corrin-ring closure between rings A and B was solved in two different ways, one developed at ETH, the other pursued at Harvard.^[32]: 19 Both methods correspond to procedures developed before in the synthesis of metal complexes^[72] as well as free ligands^[73] of simpler corrins.^{[7]: 25-28 [8]: 387-389 [18]: 1563} In the explorations of ring-closure procedures for the much more highly substituted A/B-seco-corrinoid intermediate HE-39u, the ETH group focused on the intramolecular version of the oxidative sulfide contraction method, eventually leading to the dicyano-cobalt(III)-complex HE48u.^{[48]: 29-39 [2]: 297-299} This first totally synthetic corrinoid intermediate was identified with a corresponding sample derived from vitamin B₁₂.^[18]: 1563

At Harvard, it was shown that the closure to the corrin macrocycle could also be realized by the method of thioiminoester/enamine condensation.^{[2]: 299-300} All reactions described here had to be executed on a very small scale, with "... the utmost rigor in the exclusion of oxygen from the reaction mixtures"^[2]: 296, and most of them also under strict exclusion of moisture and light, demanding very high standards of experimental expertise.^[2]: 304

The major obstacle in achieving an A/B-corrin-ring closure was the exposure of the highly unstable ring B exocyclic methylidene double bond, which tends to isomerize into a more stable, unreactive endocyclic position with great ease.^{[48]: 86,97-98 [2]: 293-294 [3]: 161 [18]: 1562}

The problem was solved at ETH^{[18]: 1562-1563 [48]: 29-39,126-135} by finding that treatment of the thiolactone-thiolactam intermediate HE-40u (obtained from HE-39u by reacting with P₂S₅^{[48]: 73-83}) with dimethylamine in dry MeOH (room temperature, exclusion of air and light) smoothly opens the thiolactone ring at ring B, forming by elimination of H₂S the exocyclic methylidene double bond as well as a dimethylamino-amide group in the acetic acid side chain.^{[48]: 32-34,96-99} These conditions are mild enough to prevent double bond tautomerization to the thermodynamically more stable isomeric position in the ring. Immediate conversion with a Zn-perchlorate-hexa(dimethylformamide) complex in methanol to zinc complex HE-41u, followed by oxidative coupling (0,05 mM solution of I₂/KI in MeOH, 3 h) afforded HE-42u.^{[48]: 100-105} Sulfide contraction (triphenylphosphine, trifluoroacetic acid, 85 °C, exclusion of air and light) followed by re-complexation with Zn(ClO₄)₂ (KCl, MeOH, diisopropylamine) led to the chloro-zinc complex HE-43u.^{[48]: 105-116} The free corrinium salt formed when HE-43u was treated with trifluoroacetic acid in acetonitrile was re-complexed with anhydrous CoCl₂ in THF to the dicyano-cobalt(III)-complex HE-44u.^{[48]: 117-125 [2]: 295} Conversion of the dimethylamino-amide group in the acetic acid side chain of ring B into the corresponding methylester group (O-methylation by trimethyloxonium tetrafluoroborate, followed by decomposition of the iminium salt with aqueous NaHCO₃) afforded totally synthetic 5,15-bisnor-heptamethyl cobyrinate HE-48u.^{[48]: 11,117-125} A crystalline sample of HE-48u was identified via UV/VIS, IR, and ORD spectra with a corresponding crystalline sample derived from vitamin B₁₂^{[48]: 42,135-141 [55]: 14,64-71,78-90 [2]: 287,301-303 [3]: 146-150 [74]}

Later at Harvard,^{[2]: 299-300} the A/B-corrin-ring closure was also achieved by converting the thiolactone-thiolactame intermediate HE-40u to thiolactone-thioiminoester HE-45u by S-methylation of the thiolactam sulfur (MeHgOi-Pr, then trimethyloxonium tetrafluoroborate). The product HE-45u was subjected to treatment with dimethylamine (as in the ETH variant), forming the highly labile methylidene derivative HE-46u, which then was converted with anhydrous CoCl₂ in THF to dicyano-cobalt(III) complex HE-47u, the substrate ready to undergo the (A⇒B)-ring closure by a thioiminoester/enamine condensation. A careful search at Harvard for reaction conditions led to a procedure (KO-t-Bu, 120 °C, two weeks) that gave corrin Co complex HE-44u, identical with and in overall yields comparable with HE-44u obtained by the ETH variant of the sulfide contraction procedure.^[2]: 300 Since in corrin model syntheses such a C,C-condensation required induction by a strong base, its application in a substrate containing seven methylester groups was not without problems;^[18]: 1562 in a, milder reactions conditions were applied.^[3]: 162

Synthesis of dicyano-cobalt(III)-5,15-bisnor-a,b,d,e,g-pentamethyl-cobyrinate-c-N,N-dimethylamide-f-nitrile (the common corrinoid intermediate) from the ring-D-differentiated A-D-component

The A-D-component H-34^{[note 8]} with its propionic acid function at ring D differentiated from all the other carboxyl functions as nitrile group had become available at Harvard in spring 1971.^[51]: 23 As a result of the comprehensive exploratory work that had been done with the model A-D-component at Harvard and ETH,^{[2]: 288-292 [48]: 22-28 [18]: 1561-1562} joining the proper A-D-component H-34 with the B-C-component E-19 by three operations H-34 + E-19 →→ HE-36 → HE-39.^{[3]: 158-159 [4]: 1:19:48-1:36:15}

Closing the corrin ring was achieved in the sequence HE-39 (P₂S₅, xylene, γ-picoline)→ HE-40^{[4]: 1:36:45-1:37:49} → HE-41^{[4]: 1:37:51-1:42:33} → HE-42^{[4]: 1:42:35-1:44:34} → HE-43 (overall yield "about 60 %"^{[4]: 1:44:35-1:46:32}), and finally to cobalt complex HE-44.^{[4]: 1:46:34-1:52:51 [3]: 160-166} Reactions in this sequence were based on the procedures developed in the undifferentiated model series.^{[2]: 293-300 [48]: 29-39 [18]: 1562-1564} Two methods were available for the A/B-ring closure: oxidative sulfide contraction within a zinc complex, followed by exchange of zinc by cobalt (ETH^{[3]: 162-165}), or the Harvard alkylative variant of a sulfide contraction,^{[3]: 160-162} thio-iminoester/enamine condensation of the cobalt complex (improved reaction conditions: diazabicyclononanone in DMF, 60 °C, several hours^[3]: 162). Woodward preferred the former one:^[3]: 165 "...the oxidative method is somewhat superior, in that it is relatively easier to reproduce, .... ".^{[4]: 1:52:37-1:53:06}

The corrin complex dicyano-cobalt(III)-5,15-bisnor-pentamethyl-cobyrinate-c-N,N-dimethylamide-f-nitrile HE-44 took up the role of the common corrinoid intermediate in the two approaches to cobyric acid synthesis: HE-44 ≡ E-37. Due to the high configurational lability of C-H chirogenic centers C-3, C-8 and C-13^{[4]: 1:21:49-1:23:42,1:35:43-1:36:14,1:51:51-1:52:30} at the ligand periphery in basic or acidic milieu, separation by HPLC was indispensable for isolation, purification and characterization of pure diastereomers of this and the following corrinoid intermediates.^{[3]: 165-166 [9]: 88-89 [4]: 1:53:07-2:01:24}

Starting material for the synthesis of a ring-C precursor was (+)-camphorquinone H-35^{[note 16]} which was converted to the acetoxy-trimethylcyclohexene-carboxylic acid H-36 by BF₃ in acetic anhydride, a reaction pioneered by Manasse & Samuel in 1902,^[75], already successfully applied in a previous synthesis of the ring-C precursor by Pelter and Cornforth.^{[note 6]} Conversion of H-36 to amide H-37 was followed by its ozonolysis to peroxide H-38 which was reduced to the keto-succinimide H-46 by zinc and MeOH. Treatment with methanolic HCl gave lactam H-40, followed by thermal elimination of methanol to the ring-C precursor H-41^{[1]: 540-542 [48]: 49-50 [14]: 4-5,15} This was found to be identical with the ring-C precursor E-13 prepared by a different route^{[note 5]} at ETH.^{[61]: 32 [44]: 30,33-34,81}

Syntheses of the ring-B precursor

Two syntheses of ring-B precursor (+)-E-5 were realized; the one starting from 2-butanone was used further.^[6]: 188 Two pathways for the conversion of the ring-B precursor into the ring-C precursor (+)-E-5 → (−)-E-13 ≡ H-41 were developed, one at ETH,^{[44]: 15-39 [1]: 544}, and one at Harvard.^{[6]: 193 [note 17]} These conversions turned out to be inadequate for producing large amounts of ring-C-precursor.^{[46]: 38 [18]: 1561} However, the pathway developed at ETH served the purpose of determining the absolute configuration of the ring-B precursor.^{[6]: 193 [61]: 32} Bulk amounts of ring-C precursor to be used for the production of the B-C-component at ETH^{[44]: 40 [6]: 193 [33]: 631} were prepared at Harvard from (+)-camphor by a route originally developed by Pelter and Cornforth.^{[note 6]}

Ring-B precursor from 2-butanone and glyoxylic acid. Aldol condensation between 2-butanone and glyoxylic acid by treatment with concentrated phosphoric acid) gave stereoselectively (trans)-3-methyl-4-oxo-2-pentenoic acid E-1.^{[39]: 11-20,45-45} Diels-Alder reaction of E-1 with butadiene in benzene in the presence of SnCl₄ afforded the racemate of the chiral Diels-Alder adduct E-2 which was resolved into the enantiomers by sequential salt formation with both (−)- and (+)-1-phenylethylamine.^{[43]: 22,59-62} The chirogenic centers of the (+)-enantiomer (+)-E-2 possessed the absolute configuration of ring B in vitamin B₁₂.^{[60]: 35 [6]: 191} Oxidation of this (+)-enantiomer with chromic acid in acetone in the presence of sulfuric acid afforded the dilactone (+)-E-3 of the intermediary tricarboxylic acid E-3a.^{[43]: 35,72-73} Thermodynamic control of dilactone formation leads to the cis-configuration of the ring junction.^{[43]: 32-34} Elongation of the acetic acid side chain of (+)-E-3 by the Arndt-Eistert reaction (via the corresponding acid chloride and diazoketone) gave dilactone (+)-E-4.^{[61]: 15-16,65-67} Treatment of (+)-E-4 with NH₃ in MeOH at room temperature formed a dual mixture of isomeric lactam-lactones in a ratio of 2:1, with ring-B precursor (+)-E-5 predominating (isolated in 55% yield).^{[46]: 12-17,57-63 [6]: 186-188 [12][1]: 542-543} The isomeric lactam-lactone could be isomerized to (+)-E-5 by treatment in methanolic HCl.^{[61]: 24-26,81-84}

Alternative synthesis of racemic ring-B precursor from Hagemann's ester: implementation of the amidacetal-Claisen rearrangement. Five steps were needed to transform Hagemann's ester rac-E-6 into the racemate of the lactam-lactone rac-E-5 form of the ring-B precursor.^{[60]: 14-31 [6]: 188-190} The product of the C-methylation step rac-E-6 → rac-E-7 (NaH, CH₃I) was purified via its crystalline oxime. The cis-hydroxy-ester (configuration secured by lactone formation^[60]: 64) resulting from the reduction step rac-E-7 → rac-E-8 (NaBH₄) had to be separated from the trans isomer. The thermal rearrangement rac-E-8 → rac-E-9 constitutes the implementation of the amidacetal-Claisen rearrangement in organic synthesis,^{[76][60]: 36-49} a precedent to Johnson's orthoester-Claisen and Ireland's ester-enolate rearrangement.^[77] Ozonolysis (O₃/MeOH, HCOOH/H₂O₂) of the N,N-dimethylamide ester rac-E-9 afforded dilactone acid rac-E-10, from which two reactions led to lactam-lactone methylester rac-E-7, the racemate of ring-B precursor (+)-E-7.^{[60]: 57-67}

Determination of absolute configuration of (+)-ring-B precursor via its conversion into the (+)-ring-C precursor

The conversion of ring-B precursor into the ring-C precursor was based on a reductive decarbonylation of thiolactone E-12 with chloro-tris-(triphenylphosphino)-rhodium(I).^{[44]: 14-32 [6]: 191-193 [12]} Treatment of a methanolic solution of ring-B precursor (+)-E-5 with diazomethane in the presence of catalytic amounts of sodium methoxide, followed by thermal elimination of methanol, gave methylidene lactam E-11, which was converted to the thiolactone E-12 with liquid H₂S containing a catalytic amount of trifluoracetic acid.^{[44]: 15-16,56-58} Heating E-12 in toluene with the Rh(I)-complex afforded ring-C precursor (−)-E-13 besides the corresponding cyclopropane derivative E-14. Ring-C precursors prepared via this route and from (+)-camphor at Harvard ^{[1]: 540-542} were found to be identical: (−)-E-13 ≡ H-41.^{[44]: 33-34}

Ozonolysis of ring-C precursor (−)-E-13 gave succinimide derivative (−)-E-15.^{[44]: 33-35,88-89} This succinimide was found to be identical^{[6]: 193 [1]: 543-544} in constitution and optical rotation (i.e., configuration) with the corresponding succinimide derived from ring C of Vitamin B₁₂, isolated after ozonolysis of crystalline heptamethyl-cobyrinate (cobester^{[note 9]}) prepared from Vitamin B₁₂.^{[56]: 9-18,67-70}

The approach pursued at Harvard for conversion of ring-B precursor into ring-C precursor was based on a photochemical degradation of the acetic acid side chain carboxyl group, starting from (+)-E-7 prepared at ETH.^{[note 17]}

Coupling of ring-B and ring-C precursors to the B-C-component. Implementation of the sulfide contraction C,C-condensation method

The iminoester/enamine C,C-condensation method for constructing the vinylogous amidine system, developed in the model studies on corrin synthesis,^[28][35] failed completely in attempts to create the targeted C,C-bond between ring-B precursor (+)-E-5 with ring-C precursor (−)-E-13 to give the B-C-component E-18.^{[6]: 193-194 [8]: 379 [1]: 544} The problem was solved by "intramolecularization" of the bond formation process between the electrophilic (thio)iminoester carbon and the nucleophilic methylidene carbon of the enamine system through first oxidatively connecting these two centers by a sulfur bridge, and then achieving the C,C-bond formation by a now intramolecular thio-iminoester/enamine condensation with concomitant transfer of the sulfur to a thiophile.^{[6]: 194-197 [8]: 380-386 [18]: 1537-1538}

Conversion of lactam (+)-E-5 into the corresponding thiolactam E-16 (P₂S₅),^{[46]: 20-23,74-75} oxidation of E-16 with benzoyl peroxide in the presence of ring-C precursor (−)-E-13 (prepared at Harvard by the Cornforth route^{[note 6]}), followed by heating the reaction product E-17 in triethylphosphite (as both solvent and thiophile) afforded B-C-component E-18 as a (not separated) mixture of two epimers (regarding the configuration of the propionic side chain at ring B) in up to 80 % yield.^{[46]: 38-43,96-102 [33]: 16-19 [8]: 381-383 [48]: 20-21,50-52}

The bracketed formulas in the reaction scheme illustrate the type of mechanism operating in the process: E-16a = primary coupling of E-12 and E-10 to E-13; E-17a = extrusion of the sulfur atom (captured by thiophile) to E-14, where it is left open whether this latter process occurs at the stage of the episulfide. This reaction concept developed at this stage, dubbed sulfide contraction,^{[6]: 199 [47][18]: 1534-1541 [37]: 1927-1941} turned out to make possible the construction of all three meso-carbon bridges of the vitamin's corrin ligand in both approaches of the synthesis.^{[12][11][2]: 288-292,297-300 [3]: 158-164}

The conversion of bicyclic lactone-lactam E-18 into the corresponding thiolactone-thiolactam E-20 was brought about by heating with P₂S₅/4-methylpyridine in xylene at 130 °C; milder condition produced thiolactam-lactone E-19, used for coupling with the Harvard A-D-components.^{[51]: 73-83}

Synthesis of ring-D precursor for the A/D approach

The starting material for the ring-D precursor,^{[61]: 40-61 [63]: 17-22 [12]} the (−)-enantiomer of the dilactone-carboxylic acid (−)-E-3, was prepared from the (−)-enantiomer of the Diels-Alder adduct (−)-E-2^{[note 18]} by oxydation with chromic acid/sulfuric acid in acetone.^{[43]: 35,72-73} Treatment of (−)-E-3 with NH₃ in MeOH gave a lactone-lactam-acid which was esterified with diazomethane to the ester E-21,^{[61]: 104-110} the lactone ring of which was opened with KCN in MeOH to give E-22.^{[61]: 114-116} Conventional conditions of an Arndt-Eistert reaction (SOCl₂: acid chloride, then CH₂N₂ in THF: diazoketone, treated with Ag₂O in MeOH) led to an  – unforeseen, yet useful  – ring closure of the originally formed chain-elongated ester through participation of the cyano group as a neighboring electrophile, affording the bicyclic enamino-ester derivative E-23.^{[61]: 116-120} Hydrolysis with aqueous HCl, accompanied by decarboxylation, and re-esterification with diazomethane gave keto-lactam-ester E-24.^{[61]: 123-126 [63]: 40-41} Ketalization ((CH₂OH)₂, CH(OCH₃)₃, TsOH) of E-24 and conversion of this lactam-ester to thiolactam E-25 (P₂S₅) was followed by reductive removal of the sulfur with Raney nickel, acetylation of the amino group, and hydrolysis of the ketal (AcOH) to afford E-26.^{[63]: 42-59} This was converted by deacetylation of the amino group with HCl, and then by treatment with NH₂OH/HCl, MeOH/NaOAc into oxime E-27. Beckmann fragmentation (HCl, SOCl₂ in CHCl₃, N-polystyryl-piperidine) of this oxime E-27 produced imino-nitrile E-28,^{[63]: 60-67} which, when treated with bromine (in MeOH, phosphate buffer pH 7.5, -10 °C) gave ring-D precursor E-29.^{[51]: 84-88}

Conversion of the ring-B precursor into the ring-A precursor for the A/D approach

The ring-A precursor (−)-E-31 required in the A/D approach is a close derivative of ring-B precursor (+)-E-5. Its preparation from (+)-E-5 required opening of the lactone group (KCN in MeOH), followed by re-esterification with diazomethane to E-30, then conversion of the lactam group into a thiolactam group with P₂S₅ to yield (−)-E-31.^{[51]: 63-72 [12]}

Coupling of the B-C-component with ring-D and ring-A precursors

The most efficient way of attaching the two rings D and A to the B-C-component E-18 was to convert E-18 directly into its thiolactam-thiolactone derivative E-20 and then to proceed by first coupling ring-D precursor E-29 to ring C, and then ring-A precursor E-31 to ring B, both by the sulfide contraction method.^{[51]: 26-31 [9]: 80-83 [12]} The search for the reaction conditions for these attachments was greatly facilitated by exploratory work done on the two sulfide contraction steps in the A/B approach model study.^{[51]: 27 [48]: 22-39 [2]: 285-300}

Attachment of ring-D precursor E-29 to the ring-C thiolactam in E-20 by sulfide contraction via alkylative coupling (t-BuOK in t-BuOH/THF, tris-(β-cyano-ethyl)-phosphin/CF₃COOH in sulfolane) afforded the B/C/D-sesqui-corrinoid E-32.^{[51]: 89-97} To attach ring-A precursor E-31, the ring B of E-32 was induced to expose its exocyclic methylidene double bond by treatment with dimethylamine in MeOH (using the method^{[note 19]} developed by Schneider^{[48]: 32-34}) forming E-33^{[51]: 108-115} which was subjected to the following cascade of operations:^{[51]: 130-150} iodination (N-iodosuccinimide, CH₂Cl₂, 0°), coupling with the thiolactam sulfur of the ring-A precursor E-31 [(CH₃)₃Si]₂N-Na in benzene/t-BuOH), complexation (Cd(ClO₄)₂ in MeOH), treatment with triphenylphosphine/CF₃COOH in boiling benzene (sulfide contraction) and, finally, re-complexation with Cd(ClO₄)₂/N,N-diisopropylethylamine in benzene/MeOH). These six operations, all carried out without isolation of intermediates, gave A/D-seco-corrin complex E-34 as mixture of peripheral epimers (separable via HPLC^{[51]: 143-147}) in 42-46 % overall yield.^[51]: 139

A/D-corrin-ring closure by the photochemical A/D-seco-corrin→corrin cycloisomerization to dicyano-cobalt(III)-5,15-bisnor-a,b,d,e,g-pentamethyl-cobyrinate-c-N,N-dimethylamide-f-nitrile (the common corrinoid intermediate)

The conditions and prerequisites for the final (A⇒D)-corrin-ring closure were taken over from extensive corrin model studies.^{[36][78][9]: 71-74,83-84 [18]: 1565-1566 [37]: 1942-1962} Problems specific to the cobyric acid synthesis that had to be tackled were:^[9]: 84-88 the possible formation of two diastereomeric A/D-trans-junctions in the ring closure,^{[51]: 37-38} exposure of the methylidene double bond at ring A of the A/D-seco-corrin E-34 in a labile Cd complex,^{[51]: 35-36 [18]: 1566} and epimerizability of the peripheral stereogenic centers C-3, C-8 and C-13 before and after ring closure.^{[51]: 39 [3]: 148-150}

In the application of this novel process in the A/D approach of the cobyric acid synthesis,^{[9]: 86-95 [51]: 39-53 [12]: 1419} the reaction proceeded most efficiently and with highest coil stereoselectivity in favor of the natural A/D-trans junction in an A/D-seco-corrin cadmium complex.^{[51]: 42-45 [3]: 166} Treatment of Cd-complex E-34 as mixture of peripheral epimers with 1,8-Diazabicyclo(5.4.0)undec-7-ene in sulfolane at 60 °C under strict protection against light to eliminate the cyano group at ring A, directly followed by re-treatment with Cd(ClO₄)₂, led to labile^[51]: 172 A/D-seco-corrin complex E-35 as a mixture of peripheral epimers. This was directly subjected to the key step, the photochemical ring closure reaction under rigorous exclusion of air:^[51]: 40 visible light, under Argon, MeOH, AcOH, 60 °C. Product of the A/D-ring closure was the free corrin ligand E-36, as the originally formed Cd-corrinate  – in contrast to the Cd-seco-corrinate E-35  – decomplexes in the reaction medium.^{[51]: 173 [12]: 1419} Corrin E-36 was immediately complexed (CoCl₂,^{[18]: 1499-1500,1563-64} KCN, air, H₂O, CH₂Cl₂) and finally isolated (thick-layer chromatography) as mixture of peripheral epimers in 45-50 % yield over four operations:^{[51]: 169-179} the common corrinoid intermediate dicyano-cobalt(III)-complex E-37 ≡ HE-44.^{[note 20]}

HPLC analysis of this mixture E-37 showed the presence of six epimers with natural ligand helicity (Σ 95%, CD spectra), among them 26% of natural diastereomer 3α,8α,13α, and an equal amount of its C-13 neo-epimer 3α,8α,13β.^{[51]: 46,179-186 [12]: 1414} Two HPLC fractions (Σ 5%) contained diastereomers with unnatural ligand helicity, as shown by inverse CD spectra.^{[51]: 42-43} Product mixtures from several such cycloisomerizations were combined for preparative HPLC separation and full characterization of the 14 isolated diastereomers of E-37^{[51]: 207-251} (of 16 theoretically possible, regarding helicity and the epimeric centers C-3, C-8, C-13^[51]: 39).

In an analytical run, the mixture of cadmium-seco-complex epimers E-35 was separated by HPLC (in the dark) into the natural chloro-cadmium-3α,8α,13α-A/D-seco-corrinate diastereomer (ααα)-E-35 and four other epimer fractions^{[51]: 281-293} Upon irradiation^{[51]: 53 [12]} and following cobaltation, (ααα)-E-35 produced E-37 in yields of 70-80% as an essentially dual mixture of mainly the 3α,8α,13α epimer, besides some 3α,8α,13β epimer. Less than 1% of fractions with unnatural coil were formed (HPLC, UV/VIS, CD).^{[51]: 293-300}

Mechanistically, the photochemical A/D-seco-corrin corrin cycloisomerization involves an antarafacial sigmatropic shift of the α-hydrogen of the CH₂ position C-19 at ring D to the CH₂ position of the methylidene group at ring A within a triplet excited state, creating a transient 15-center-16-electron π-system (see E-35a in fig. 27) that antarafacially collapses between positions C-1 and C-19 to the corrin system.^{[36][37]: 1946,1967-1993 [79]} The coil selectivity of the ring closure in favor of the corrin ligand's natural helicity is interpreted as relating to the difference in steric hindrance between the g-methoxycarbonyl acetic acid chain at ring D and the methylidene region of ring A in the two possible helical coil configurations of the A/D-seco-corrin complex (fig. 28).^{[51]: 38 [37]: 1960-1962}

This introduction of methyl groups could draw on exploratory studies on model corrins^{[7]: 13-14 [8]: 375-377 [80][18]: 1528,1530-1532} as well as on exploratory experiments carried out at ETH on cobester^{[note 9]} and its (c→C-8)-lactone derivative.^{[55]: 27-43} Chloromethyl benzyl ether alkylated the meso position C-10 of cobester, but not that of the corresponding lactone, the difference in behavior reflecting the difference in steric hindrance exerted on the meso position C-10 by its neighboring substituents.^{[55]: 37-39} This finding was decisive for the choice of the substrate to be used for introducing methyl groups at meso positions C-5 and C-10 of E-37/HE-44.^{[9]: 96-99 [55]: 19 [3]: 167 [18]: 1567-1568} In this final phase of the synthesis, HPLC again turned out to be absolutely indispensable for separation, isolation, characterization and, above all, identification of pure isomers of dicyano-cobalt(III)-complexes of totally as well as partially synthetic origin.^{[9]: 96-102 [3]: 165 [55]: 61-63 [5]: 0:21:13-0:25:28 [18]: 1566-1567}

The first step was to convert the c-N,N-dimethylcarboxamide group of E-37/HE-44 into the (c→C-8)-lactone derivative E-38/HE-45 by treatment with iodine/AcOH effecting iodination at C-8, followed by intramolecular O-alkylation of the carboxamide group to an iminium salt that hydrolyzes to the lactone.^{[63]: 23,90-108 [3]: 166-167 [4]: 2:02:18-2:09:02} This lactonization leads to cis-fused rings.^{[55]: 19 [5]: 0:09:34-0:10:43} Reaction of (c→C-8)-lactone E-38/HE-45 with chloromethyl benzyl ether in acetonitrile in the presence of LiCl gave, besides mono-adduct, the bis-benzyloxy adduct E-39/HE-46. When treated with thiophenol, this produced the bis-phenylthio-derivative E-40/HE-47. Treatment with Raney nickel in MeOH not only set free the two methyl groups at the meso positions, but also reductively opened the lactone ring to the free c-carboxyl group at ring B, producing the correct α-configuration at C-8. Esterification of c-carboxyl with diazomethane afforded hexamethylester-f-nitrile E-41/HE-48.^{[55]: 19-21,39-43,146-205 [3]: 167-169} For steric reasons, only the predominant^{[55]: 19 [63]: 24 [4]: 2:08:20-2:09:02} C-3 α-epimer (with the C-3 side chain below the plane of the corrin ring) reacted to a 5,15-disubstituted product E-38/H-45, the reaction thus amounting to a chemical separation of the C-3 epimers.^{[55]: 40 [5]: 0:12:51-0:14:33,0:15:56-0:16:24}

In improved procedures developed at Harvard later in 1972,^{[18]: 1569 footnote 62} the reagent chloromethyl benzyl ether was replaced by formaldehyde/sulfolane/HCl in acetonitrile for the alkylation step, and Raney nickel in the reduction step was replaced by zinc/acetic acid to give E-41/HE-48.^{[5]: 0:00:32-0:21:12}

Concentrated H₂SO₄ at room temperature converted the nitrile function of pure (3α,8α,13α)-E-41/HE-48 into the primary f-amide group of E-42/HE-49, besides partial epimerization at C-13;^{[9]: 100-103 [55]: 21,134-136 [3]: 150-151,169-170} an alternative procedure for the selective f-nitrile→f-amide conversion (BF₃ in CH₃COOH) later developed at Harvard proceeded without epimerization at C-13.^{[18]: 1569 footnote 62 [5]: 0:46:40-0:49:45 [55]: 21} A crystalline sample of the 3α,8α,13α-epimer of dicyano-cobalt (III)-a,b,c,d,e,g-hexamethyl-cobyrinate-f-amide E-42/HE-49, isolated by HPLC, was the first totally synthetic intermediate to be chromatographically and spectroscopically identified with a relay sample made from vitamin B₁₂.^{[55]: 136-141 [3]: 170}

In the remaining steps of the synthesis, only epimerization at C-13 played an important role,^{[55]: 19-21} with 13α being the configuration of the natural corrinoids, and 13β known as neo-epimers of vitamin B₁₂ and its derivatives;^{[3]: 169-170 [81]} these are readily separable by HPLC.^{[5]: 0:19:30-0:20:21 [55]: 135,208-209}

In the course of 1972, comprehensive identifications (HPLC, UV/VIS, IR, NMR, CD, mass spectra) of crystalline samples of totally synthetic intermediates with the corresponding compounds derived from vitamin B₁₂ were carried out in both laboratories: individually compared and identified were the 3α,8α,13α and 3α,8α,13β neo-epimer of f-amide E-42/HE-49, as well as the corresponding pair of C-13-epimeric nitriles E-41/HE-48.^{[55]: 206-221 [57]: 46-47 [5]: 0:27:28-0:46:32} All these dicyano-cobalt(III)-complexes are soluble in organic solvents^[56]: 11 in which the separation power of HPLC by far exceeds that of analytical methods operating in water,^{[55]: 44-45} the solvent in which cobyric acid was to be identified, and where it exists as two easily equilibrating aquo-cyano complexes, epimeric regarding the position of the two non-identical axial Co ligands.^{[63]: 196-197 [57]: 49-60}

These thorough identifications of the totally synthetic with partially synthetic materials mark the accomplishment of the two syntheses. They also reciprocally provided structure proof for a specific constitutional isomer isolated from a mixture of isomeric mono-amides formed in the partial ammonolysis of the B₁₂-derived cobester,^{[note 9]} tentatively assigned to be the 3α,8α,13α-f-amide E-42/HE-49 (see fig. 30).^{[56]: 9-18,67-70 [55]: 226-239 [59]}

The final task of reaching cobyric acid from f-amide E-42/HE-49 required the critical step of hydrolyzing the singular amide function into a free carboxyl function without touching any of the six methoxycarbonyl groups around the molecule's periphery. Since exploratory attempts by the conventional method of amide hydrolysis via nitrosation led to detrimental side reactions at the chromophore, a novel way of "hydrolyzing" the f-amide group without touching the six methylester groups was conceived and explored at ETH: treatment of f-amide E-42/HE-49 (B₁₂-derived relay material) with the unusual reagent α-chloro-propyl-(N-cyclohexyl)-nitrone^[82] and AgBF₄ in CH₂Cl₂, then with HCl in H₂O/dioxane, and finally with dimethylamine in isopropanol afforded the f-acid E-43/HE-50 in 57% yield.^{[63]: 24-25,159-172 [3]: 170-172 [5]: 0:53:17-0:58:30} Sustained experimentations at Harvard eventually showed the nitrosation method to be successful (N₂O₄, CCl₄, NaOAc) and to produce the f-carboxyl group even more effectively.^{[3]: 172-173 [5]: 0:58:19-0:59:15}

It was also at Harvard that conditions for the last step were explored, conversion of all remaining ester groups into primary amide groups by ammonolysis. Liquid ammonia in ethylene glycol, in the presence of NH₄Cl and the absence of oxygen, converted f-carboxy-hexamethylester E-43/HE-50 into f-carboxy-hexa-amide E-44/HE-51 (= cobyric acid).^{[3]: 173-175 [55]: 24} This was crystallized and shown both as the α-cyano-β-aquo and the α-aquo-β-cyano form to be chromatographically and spectroscopically identical with the corresponding forms of natural cobyric acid.^{[5]: 0:59:53-1:09:58 [3]: 175-176 [63]: 26-27,196-221} At Harvard, the transformation E-43/HE-50 → E-44/HE-51 was eventually carried out starting with f-amide that had been obtained by total synthesis via the A/B approach.^{[57]: 47-61} The ETH group contented itself with a corresponding f-amide → cobyric acid conversion and subsequent cobyric acid identification where the actual starting material f-amide was derived from vitamin B₁₂.^{[55]: 22 [63]: 15 [12]: footnote 45 [18]: 1570-1571}