Stereoselective access to tubuphenylalanine and tubuvaline: improved Mn-mediated radical additions and assembly of a tubulysin tetrapeptide analog.

Synthesis of tubuphenylalanine and tubuvaline (Tuv), α-substituted γ-amino acid building blocks for tubulysin family of antimitotic compounds, has been improved using a radical addition reaction in the presence of unprotected hydroxyl functionality. The key carbon-carbon bond construction entails stereoselective Mn-mediated photolytic additions of alkyl iodides to the C=N bond of chiral N-acylhydrazones, and generates the chiral amines in high yield with complete stereocontrol. Reductive N-N bond cleavage and alcohol oxidation converted these amino alcohols into the corresponding γ-amino acids. The route to Tuv proceeded via peptide coupling with serine methyl ester, followed by a high-yielding sequence to convert the serine amide to a thiazole. Finally, peptide bond construction established the tubulysin framework in the form of a C-terminal alcohol analog. Attempted oxidation to the C-terminal carboxylate was unsuccessful; control experiments with dipeptide 18 showed a cyclization interfered with the desired oxidation process.

1. Introduction

The tubulysins are a group of unusual peptides distinguished by two novel γ-amino acid residues, tubuphenylalanine and tubuvaline, both of which are α,γ-disubstituted γ-amino acids. Initially isolated from culture broths of the myxobacteria Archangium gephyra and Angiococcus disciformis, these are extraordinary antimitotic agents, with potency superior to vinblastine and dolastatin-10 (growth inhibition of human cervical carcinoma DSM ACC 158, tubulysin D: IC50 20 pg/mL).[1,2] After further isolation efforts, the series now includes tubulysins A–I, U, and V, as well as pretubulysin (Scheme 1).[3,4,5]

Scheme 1

Retrosynthetic analysis of tubulysis, highlighting the γ-amino acids.

The extraordinary potency of tubulysins and their interesting impacts on tubulin biochemistry[6] have inspired numerous efforts to probe their therapeutic potential through synthesis and medicinal chemistry. We disclosed our initial studies directed toward synthesis of the tubulysins in 2004,[7] and the first total syntheses were achieved by Ellman (tubulysin D, 2006)[8] and Zanda (tubulysins U and V, 2007).[9] Despite numerous synthetic efforts (which have been reviewed[10,11,12] and continue to emerge[13,14,15]), accessing both of the γ-amino acid subunits tubuvaline (Tuv, Scheme 1) and tubuphenylalanine (Tup) with excellent stereocontrol has proven to be a difficult challenge. Prior tubulysin syntheses have been hampered by limited stereoselectivity in alkene or ketone reductions to generate the requisite configuration at the α carbon of the γ-amino acids. In general, most approaches to γ-amino acids are limited by reliance upon homologation of the naturally abundant α-amino acids. These factors emphasize the need for new and versatile methodology for γ-amino acid synthesis,[16,17] and serving this need became the cornerstone of our synthetic strategy.

Our plan for a more versatile C–C bond construction approach to synthesis of γ-amino acids would obviate the limitations of naturally occurring α-amino acid precursors, facilitating preparation of γ-amino acids bearing unusual functionality or substitution patterns. Taking guidance from the tubulysins, we required that the ideal method would be applicable to strategic construction of either the Cβ-Cγ or Cγ–Cδ bonds of γ-amino acids (as shown for Tup and Tuv, Scheme 1) and independent of substituents at the α-position. Stereoselective intermolecular additions of alkyl radicals to the C=N bonds are well-suited to this need; these reactions have been reviewed,[18-26] and new ones continue to develop.[27,28,29] We introduced a photolysis method[30,31] for this reaction type which employs Mn2(CO)10 to generate alkyl radicals, leading to efficient additions of primary and secondary alkyl iodides to chiral N-acylhydrazones.[32-35] The availability of efficient primary radical addition has opened many new synthetic applications; with earlier methods, primary alkyl radicals were prone to premature reduction or other side reactions (e.g., addition of ethyl radical under triethylborane or diethylzinc initiation).[20-26] The functional group tolerance and non-basic conditions of this method show excellent potential for synthesis of multifunctional amines;[36-41] the tubulysin γ-amino acids would test this potential. Indeed, our initial studies on tubulysins achieved preparation of Tuv precursor A and Tup itself (B) via these Mn-mediated radical addition reactions.[7] Here we disclose improved preparations of A and B that demonstrate the functional group compatibility of a free hydroxyl during the Mn-mediated coupling, as well as tolerance of imino compounds that are prone to E1cb elimination. We further disclose a high-yielding sequence leading from A to tubuvaline, and the assembly of a C-terminal alcohol analog of the tubulysin tetrapeptide.

2. Results and Discussion

Preparation of γ-Amino Acids

Improvements to our previously reported γ-amino acid syntheses began with an effort to address a low yield (56%) in the Mn-mediated coupling of phenylacetaldehyde hydrazone 4 (Scheme 2) with iodide 5a, bearing a silyl-protected alcohol, en route to tubuphenylalanine.[7] To this end, we examined alternate iodide partners to find that iodide 5b,[42] bearing a free hydroxyl group, functioned more efficiently in the Mn-mediated radical addition. The reaction entailed photolysis (300 nm) of 4 and 5b with Mn2(CO)10 in the presence of InCl3 as a Lewis acid, and furnished 1,4-hydrazino alcohol 6b in 79% yield, a significant improvement over the previously reported coupling. The identical stereochemical outcomes in 6a and 6b were correlated via O-silylation of 6b in 98% yield, which established that the free hydroxyl group was not detrimental to stereoselectivity. Then, N–N bond cleavage afforded Tup precursor 7 with the C-terminus in the alcohol oxidation state.

Scheme 2

Mn-mediated radical additions in γ-amino acid synthesis.

Preparation of the γ-amino acid progenitor of tubuvaline followed the previously published route[7] from known alcohol 8[43] (Scheme 2). Jin’s one-step Lemieux-Johnson oxidation[44] shortened this sequence by one step, but did not improve the overall yield. In the key step, the Mn-mediated coupling method was carried out with slow addition (10 h) of a solution of Mn2(CO)10 in CH2Cl2 during the photolysis (254 nm, pyrex glassware). It should be noted that typical Mn-mediated radical addition reactions do not require 254 nm light nor slow addition for successful reaction, but in this case at least, it led to a small improvement in yield. Thus isopropyl iodide added to the C=N bond of hydrazone 9, affording 10 in 84% isolated yield as a single diastereomer (versus 77% reported previously[7]). Treatment of the hydrazone 9 with fluoride ion (TBAF) resulted in loss of the benzyloxy substituent, but this E1cb process did not occur during the radical addition reaction, underscoring its non-basic character. In another improvement upon our previously reported route, modified conditions for N–N bond cleavage[45] furnished trifluoroacetamide 11 in 97% yield.

Elaboration of the Tubuvaline Thiazole

The thiazole portion of tubuvaline was envisioned to arise from serine via cyclization and oxidation. Desilylation and oxidation of 11 provided the γ-amino acid A (Scheme 3), to which serine methyl ester was attached in a peptide bond construction mediated by diethyl cyanophosphate (DECP). Silylation then afforded 12 in quantitative yield over the two steps. Alternatively, the serine could be installed with the silyl group already present, albeit with diminished coupling yield (83%). Next, conversion of the peptide bond to a thioamide was achieved with freshly prepared Belleau’s reagent[46] added to a refluxing solution of 12 in THF; this afforded the thioamide 13 in dependably high yield. Desilylation of the serine hydroxyl group, then successive cyclization with diethylaminosulfur trifluoride (DAST)[47] and mild oxidation from thiazoline to thiazole with BrCCl3 under Williams’ conditions[48] completed the preparation of tubuvaline derivative 14 in excellent overall yield.

Scheme 3

Installation of the Tuv thiazole.

Assembly of the Peptide Backbone

Next, assembly of the peptide was initiated via saponification of tubuvaline methyl ester 14 with LiOH in aqueous MeOH (Scheme 4). This proceeded selectively in 98% yield, preserving the N-trifluoroacetyl protection in 15. Meanwhile, Ba(OH)2 caused hydrolysis of the N-trifluoroacetamide of tubuphenylalaninol derivative 7, releasing free amine 16. The Tuv and Tup components then engaged in peptide coupling in the presence of DECP and Hunig’s base, leading to dipeptide 17 in quantitative yield. Another hydrolytic deprotection with Ba(OH)2 exposed the primary amine at the N-terminus, where the final two amino acids, N-methylpipecolic acid (Mep) and isoleucine (Ile) would next be attached.

Scheme 4

Assembly of di- and tetrapeptides.

We explored several alternatives for coupling the Mep and Ile units to the N-terminus of 18. One attractive approach was to introduce Ile as an azide, followed by hydrogenation of the azide with concomitant removal of the O-benzyl group in the Tuv fragment, with in situ coupling to an active ester form of Mep.[8] This showed some promise, as the first coupling occurred smoothly (Equation 1). Unfortunately the azide reduction and coupling of 23 to Mep gave complex mixtures, due in part to incomplete removal of the O-benzyl group.

Coupling of 18 to a previously constructed Mep-Ile dipeptide[9] emerged as a more reliable approach. The known dipeptide Mep-IleOH was prepared as its trifluoroacetate salt (19, Scheme 4) via acylation of isoleucine tert-butyl ester with MepOH[49] and removal of the tert-butyl group with trifluoroacetic acid. An ethyl acetate solution of this salt was exposed to isobutyl chloroformate in the presence of N-methylpyrrolidine to form the mixed anhydride, and the Tuv-Tup dipeptide 18 was introduced. In several trials using this procedure, the tetrapeptide 20 was reliably obtained with yields ranging from 42–48%. Desilylation under typical conditions afforded primary alcohol 21 in quantitative yield.

To convert 21 to tubulysin V, all that remained was oxidation of the C-terminus to a carboxylic acid and debenzylation of the C5′ hydroxyl group. Toward this end, a number of oxidations were attempted, but useful oxidation products were not observed (neither aldehyde nor carboxylic acid). From examination of product mixtures in oxidations with PhI(OAc)2 and TEMPO, mass spectra and 1H NMR data suggested that the aldehyde was formed, then trapped intramolecularly by the γ-amido group. Although similar oxidations of related compounds have been reported,[50,51] our attempts to purify a component of this material or make use of it for further transformations were unsuccessful. Toward a better understanding of the outcome, the simpler Tuv-Tup dipeptide 18 was used for a control experiment. After N-acylation with Boc2O and desilylation, oxidation under the PhI(OAc)2/TEMPO conditions gave cyclized hemiaminal 22 in 52% overall yield (Scheme 4). Although we were forced to consider an alternate path to access the tubulysins, this study placed the foundation for a modified route which is currently in progress.

3. Conclusion

In conclusion, a C-terminal alcohol analog in the tubulysin family has been assembled via a route which constructs both of the γ-amino acids with complete stereoselectivity (>98:2). The γ-amino acid synthesis expands the access to building blocks for bioorganic chemistry, including unusual peptide natural products[52-58] and conformationally constrained peptide mimics.[59,60] The key enabling methodology is a highly stereoselective Mn-mediated coupling of alkyl iodides with chiral N-acylhydrazones. Advances in this Mn-mediated radical addition chemistry attributed to this synthetic effort are (a) primary alkyl addition in the presence of unprotected hydroxyl functionality to access tubuphenylalanine in high yield, (b) avoidance of E1cb-type elimination of β-alkoxy functionality in a tubuvaline precursor by employing non-basic isopropyl radical addition to the C=N bond, and (c) an alternative procedure involving slow addition of Mn2(CO)10 to improve the yield of 10. Taken together with our previous Mn-mediated coupling studies,[30,31,36-41] these advances broaden the scope and functional group compatibility of Mn-mediated radical additions to hydrazones, cementing the viability of this reaction for complex target-directed synthesis.

4. Experimental Section

Procedures and product characterization data for the Mn-mediated coupling steps are provided here; for complete experimental details, see Supporting Information.

Mn-Mediated Radical Addition: Hydrazino alcohol 6b

A solution of hydrazone 4 (360 mg, 1.22 mmol) in CH2Cl2 (30 mL) was added to InCl3 (541 mg, 2.45 mmol, dried under vacuum for ca. 12 h) in a pyrex Schlenk tube. The mixture was stirred for 2 h at room temperature. Then iodide 5b (degassed by bubbling argon for 15 min, 856 mg, 4.28 mmol) was added followed by addition of Mn2(CO)10 (524 mg, 1.35 mmol) as a solid. The reaction mixture was degassed by bubbling argon for 15 min, then irradiated for 15 h using a Rayonet photochemical reactor (300 nm, pyrex glassware); the ambient temperature inside the irradiation chamber reached ca 35 °C. The reaction mixture was diluted with diethyl ether, then triethylamine (2.0 mL, 16 mmol) was added. After stirring 1 h, concentration and flash chromatography (petroleum ether/ethyl acetate, 3:1 → 1:2) afforded hydrazino alcohol 6b (357 mg, 79% yield, dr >98:2) as a colorless oil; [α]D24 −26.6; IR νmax (NaCl, film) 3441, 2925, 1754, 1745, 1730, 1494, 1452, 1401, 1239, 1093, 1030 cm−1; 1H NMR (CDCl3, 400 MHz) δ 7.42–7.16 (m, 8H), 7.08–7.03 (m, 2H), 3.96–3.90 (m, 2H), 3.69–3.58 (m, 1H), 3.56–3.48 (m, 3H), 3.03 (dd, J = 13.4, 3.4 Hz, 1H), 2.80 (m, apparent d, J = 6.8 Hz, 2H), 2.45 (dd, J = 13.3, 10.1 Hz, 1H), 1.99–1.88 (m apparent octet, 1H), 1.58 (ddd, J = 14.3, 7.2, 5.5 Hz, 1H), 1.43 (ddd, J = 14.2, 6.5, 6.5 Hz, 1H), 0.93 (d, J = 6.8 Hz, 3H); 13C NMR (100 MHz, CDCl3) δ 158.5, 139.0, 135.6, 129.1, 129.1, 128.8, 128.5, 127.0, 126.4, 68.0, 65.7, 58.8, 58.5, 40.2, 37.3, 36.7, 32.5, 17.6; MS (ESI) m/e (rel. intensity) 391 ([M+Na]+, 100), 369 ([M + H]+, 57); Anal. Calcd for C22H28N2O3: C, 71.71; H, 7.66; N, 7.60. Found: C, 71.06; H, 7.47; N, 7.48.

Mn-Mediated Radical Addition with Slow Addition: Hydrazine 10

To a solution of hydrazone 9 (300 mg, 0.62 mmol) in CH2Cl2 (31 mL) was added InCl3 (275 mg, 1.24 mmol dried under vacuum for ca. 12 h), followed by isopropyl iodide (0.25 mL, 2.49 mmol, filtered through basic alumina). The mixture was stirred for 15 min at room temperature. Using a syringe pump, a solution of Mn2(CO)10 in CH2Cl2 (10 mL) was added over 10 h at a rate of 1 mL/h while the mixture was irradiated using a Rayonet photochemical reactor (254 nm, pyrex glassware). After the addition was complete, irradiation was continued for another 5 h; the ambient temperature inside the irradiation chamber reached ca 35 °C. Concentration and flash chromatography (hexanes → 3:1 hexanes/EtOAc) afforded hydrazine 10 as a colorless oil (276 mg, 84% yield, dr >98:2). Analytical data for this material were consistent with the prior report.[7]