The configurations of stereocenters of chiral alcohols are commonly assigned by making a pair of diastereomeric Mosher esters and analyzing their 1H NMR spectra by the subtraction protocol of the “advanced Mosher method”.1 In contrast, making Mosher esters of achiral alcohols is pointless. Or is it?
Consider the pairs of methylene protons on either side of the carbinol carbon in the three classes of secondary alcohols 1a—3a shown in Figure 1. Chiral alcohol 1a—bearing different substituents on either side of the carbinol— is the usual candidate for the advanced Mosher rule. The (R)- and (S)-Mosher esters 1e are made and the resonances in their 1H NMR spectra are assigned. Subtraction of the corresponding chemical shifts according to the rule provides the configuration. Achiral alcohol 2a—having the same substituents on either side of the carbinol—has no stereocenter and its methylene resonances are equivalent by symmetry.2 The equivalence is broken in the Mosher ester 2e, and the resonances can now be assigned by a “backwards” application of the Mosher rule.3 The second Mosher ester derivative of 2a is the enantiomer of 2e, so it provides no new information (its methylene resonances simply reverse places).
Figure 1.
Uses of the Mosher rule for three classes of alcohols
There is no pressing need to assign proton resonances of Mosher ester derivatives of achiral compounds. But the analysis applies directly to chiral compounds that have elements of near-symmetry. Consider alcohol 3a, bearing different but very similar substituents on either side of the carbinol. Because the compound almost has a plane of symmetry, the pairs of methylene protons will be (accidentally) chemical shift equivalent in the alcohol 3a but different in the Mosher ester 3e. Now, in a “shortcut” of the usual advanced Mosher rule, subtraction of the pair of resonances from each other (rather than from the corresponding resonances in the diastereomeric Mosher ester) provides the absolute configuration of the alcohol. The diastereomeric Mosher ester can be made and the advanced Mosher rule can be applied as usual, but like the enantiomer of 2e, the diastereomer of 3e will provide no new information.
We selected the natural product petrocortyne A 4 as a suitable test of the “shortcut” Mosher method (Figure 2). This is a typical representative of a group of related natural products whose members exhibit diverse biological activities.4 In particular, the dialkynyl carbinol stereocenter at C14 of petrocortyne A has a near-plane of symmetry that extends for seven carbon atoms on either side before being broken. As a consequence of this local symmetry, the formally different protons H11 and H17 are accidentally equivalent, but this equivalence should be broken by making a Mosher ester.
Figure 2.
Proposed structures for petrocortyne A
Petrocortyne A 4 has been isolated by two different groups from similar sponges collected in similar locations.5 The optical rotations of both samples had the same sign though different magnitudes. And both groups applied the advanced Mosher method to assign configurations to their samples. The Shin group5a assigned the 3R,14R configuration to petrocortyne A 4, while the Jung group5b deduced the enantiomer 3S,14S. It seems likely that one of these assignments is incorrect. And because of the difficulty of assigning the C14 stereocenter, we also considered the possibility that both were incorrect.
To rigorously assign the configuration of petrocortyne A, we decided to make all four possible stereoisomers of 4 in individual, pure form by fluorous mixture synthesis,6 and then to convert these isomers to Mosher esters for comparison with each other and with the data for the natural samples. The preparation of the starting quasiracemate7 7a,b and the mixture and post-mixture phases of the synthesis are summarized in Scheme 1.
Scheme 1.
Fluorous mixture and post mixture stages of the synthesis of four isomers of petrocortyne A
Straightforward preparations of the fragments (5, 9, and 14) are briefly summarized in the Supporting Information. Ketone 5 (C1—C10) was divided in half and reduced with the (R)- and (S)- CBS reagents.8 The resulting alcohols 6 were directly tagged with a fluorous diisopropylsilyl triflate9,10 bearing the C4F9 group (TIPSRf4OTf = Si(iPr)2(CH2)3C4F9) or the standard triisopropylsilyl triflate (TIPSOTf) to give quasienantiomers R-7a and S-7b in 61 and 64% overall yield, respectively, for the two steps. The quasienantiomers were mixed and the resulting quasiracemate was deprotected with DDQ to provide an alcohol, which was immediately converted to the iodide 8a,b (42% overall yield).
Quasiracemate 8a,b was divided in half and used to alkylate the propargyl anions derived from R-9 and S-9 (C12-C22) to give R-10a,b (14R mixture) and S-10a,b (14S mixture) in 34 and 33% yields, respectively, after careful purification. Fluorous tagging of these products with silyl triflates bearing C4F9 and C3F7 groups encoded the configurations at C14 in products 11a,b/a (99%) and 11a,b/c (85%). These two-compound mixtures were in turn mixed and the resulting four-compound mixture 11a,b/a,c was treated with MeI to remove the MTM group, giving an alcohol 12a,b/a,c (90%). Subsequent Dess-Martin oxidation provided an aldehyde 13a,b/a,c (74%), which was coupled with the ylide derived from phosphonium salt 14 (C22-C46) to provide Z-alkene 15a,b/a,c in 44% yield.
This final mixture was demixed by fluorous HPLC,10 and the four individual quasiisomers (15a/a, 15a/c, 15b/a, 15b/c) were detagged and purified by flash chromatography to give the four petrocortyne A stereoisomers 4. These four samples exhibited substantially identical 1H (600 MHz) and 13C (125 MHz) spectra. All four spectra in turn matched the spectra reported for both natural samples of petrocortyne A,5 thereby confirming the two-dimensional structure of 4. Like the spectra, the optical rotations (Scheme 1) did not differentiate the two possible diastereomers of petrocortyne A. But they did of course differentiate the enantiomers. The (3S) pair of petrocortyne diastereomers is dextrorotatory, supporting the assignment of Jung5b rather than Shin.5a
Next, we converted the pair of diastereomers with the (3S) configuration to both the bis-(R)- and bis-(S)- Mosher esters, and recorded a set of 1D and 2D 1H NMR spectra for assignment and analysis. The structures of the Mosher esters and their spectra are shown in the Supporting Information. Our expectation that all the 1D spectra might be substantially identical in the region of the C14 stereocenter proved to be wrong; there were small yet clear differences. Thanks to these differences, we could clearly show that both natural samples have the syn relative configuration between C3 and C14 by comparing Mosher spectra from natural and synthetic samples.
We next analyzed the Mosher spectra by applying the standard advanced method and the short-cut method. The shortcut method does not apply to C3 (no local symmetry), but its configuration is correctly assigned by the standard Mosher rule (see Supporting Information). The subtraction data for key protons needed to validate the two methods for assigning C14 are shown in Table 1.11 In the standard analysis, data from both bis-(R) and bis-(S) Mosher esters are used, and the usual subtraction (δS — δR) validates that the Mosher method does correctly assign the C14 configuration of both diastereomers.
Table 1.
Chemical shifts of H11 and H17 in Mosher esters and application of the advanced (†S — †R) and shortcut (†H11 — †H17) Mosher methods.
| Config. | H# | δ S-MTPA | δ R-MTPA | δS — δRa) | δH11—δH17b) |
|---|---|---|---|---|---|
| 3S,14R | 11 | 2.214 | 2.190 | +0.024c) | -0.040c) |
| 3S,14R | 17 | 2.204 | 2.233 | -0.029c) | |
| 3S,14S | 11 | 2.185 | 2.219 | -0.034d) | +0.015d) |
| 3S,14S | 17 | 2.220 | 2.204 | +0.026d) |
The standard advanced Mosher method
The shortcut Mosher method with the R-MTPA ester
Indicates 14R
Indicates 14S
In the shortcut analysis, data of symmetry-related pairs from a single Mosher ester are subtracted from each other (δH11 — δH17). Accordingly, having two Mosher esters generates two sets of data. If the 1D spectra of the Mosher esters are identical (as in truly symmetric systems), then the subtraction results will give the same magnitude with opposite signs. The Mosher ester spectra of the petrocortyne derivatives are not identical, so the magnitudes of the subtractions are slightly different. But the signs of the subtractions are the opposite, so both analyses correctly indicate the known configurations of the compounds. This validates the applicability of the shortcut Mosher method.
With the optical rotations and Mosher spectra of all isomers of petrocortyne A 4 in hand, we can confirm that the (3S,14S) configuration assignment of Jung is correct and that the (3R,14R) assignment of Shin must be reversed;12 his sample of petrocortyne also must have the (3S,14S) configuration since his data (optical rotation, Mosher spectra) match ours for that isomer.
This assignment of the (3S,14S)-configuration to petrocortyne A is rigorous and is based solely on comparison of data derived from natural and synthetic samples and Mosher derivatives; it does not depend on applying Mosher rules. At the same time, we have validated that both the standard and shortcut Mosher methods are applicable to assigning the configuration of the challenging C14 stereocenter in petrocortyne and related molecules. So previous assignments in related compounds can now be confirmed or revised and future assignments can be made without recourse to a complete stereoisomer library.
The “shortcut” method should be generally applicable to assigning stereocenters in molecules or molecular fragments with local symmetry, and the method should be generalizable beyond Mosher esters to the family of related chiral ∝-trifluoromethyl ∝-aryl esters1c,d and beyond. The method conserves precious natural product samples because only one derivative is made. If the pairs(s) of protons that are related by local symmetry can be unambiguously assigned,13 then a reliable assignment of configuration will follow from the shortcut method.
Supplementary Material
Acknowledgements
We thank the National Institutes of Health, National Institute of General Medical Sciences, for funding. We thank Dr. J. H. Jung, Pusan National University, for copies of spectra of natural petrocortyne A.
Footnotes
Supporting Information Available: Contains summary schemes for synthesis of fragments 5, 9, and 14, and copies of NMR spectra of the petrocortyne isomers and derived Mosher esters. This material is available free of charge via the Internet at http://pubs.acs.org.
References and Notes
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