Ripostatin A

 

Ripostatin A

Org. Letters 2012, 14, 4690

W. Tang & E. V. Prusov*

The retrosynthesis of Ripostatin A begins with a deprotection of the protected methyl acetal which quite sensitive.  This was achieved by a mild neutral aqueous hydrolysis.  The terminal acid functionality was derived from oxidation of the primary alcohol by Dess-Martin periodinane oxidation followed by Pinnick Oxidation (sodium perchlorate).  The alcohol was originally in its TBS-protected form in 8.  Predictably, the central alkene group in 8 was formed by a ring-closing-metathesis reaction using Grubb’s second generation catalyst. The double allyl groups required for the RCM reaction were neatly installed by a double Stille reaction between allyl stannane 5 and double-vinyl-iodide compound 6.  Conceptually, this is really interesting as it reduces the need to install the two carbon-carbon-double-bond groups separately.  The ester group of compound 6 is the next disconnection giving rise to acid 5 and alcohol 4.  The ketal group of 4 comes from the open ketone 3, which is prepared by an Patterson Aldol reaction between methyl ketone 2 and aldehyde 1.  The syntheses of both 1 and 2 have been described by the authors in their previous publication Angew. Chem. Int. Ed. 2012, 51, 3401–3404.

 

(-)-KAITOCEPHALIN

 

 

(-)-KAITOCEPHALIN

Organic Letters, 2012, 14, 1644-1647

K. Takahashi, D. Yamaguchi, J. Ishihara, S. Hatakeyama*

The retrosythesis of (-)-Kaitocephalin begins with unmasking all the acid groups by oxidizing phenyl and carbon-carbon double bonds while the amino and alcohol groups are also simultaneously generated by deprotecting the oxazolidone ring of 14.  This is very rarely seen in total syntheses as people generally shy away from such strong oxidations towards the end of the synthesis.  So, keeping a benzene ring and carbon-carbon double bonds are “masked acids” is a useful disconnection.  Compound 14 predictably comes from acid chloride 13 and deprotected form of amine 12.  Compound 12 is formed by a stereoselective intramolecular C-H amination in 11 mediated by a Rh catalyst.   This is a neat way of establishing a crucial stereocenter.  Compound 11 comes from protected alcohol 10.  Compound 10 is generated by an intramolecular addition of a carbamate on cyclic sulfamate 9, which comes from another stereoselective intramolecular C-H amination of sulfonamide 8.  This step is very similar to the preparation of 12 from 11 – sulfonyl versus and carbonyl and also a different ligand is used in the Rh catalyst.  Compound 8 comes from protected alcohol 7, which in turn is prepared by a Overman rearrangement reaction of alcohol 6.  This step establishes the quaternary spiro stereocenter.  Compound 6 is formed by a Suzuki reaction between alkyl boronate ester and vinyl iodide 5.  This comes from protection-deprotection of alcohol 4 whose precursor is ketone 3.  Ketone 3 comes from the iodination of 2, which is derived from alcohol 1, by an enzyme-mediated stereoselective oxidation.