Conagenin

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Conagenin
Category Enzyme inhibitors
Catalog number BBF-01047
CAS 134381-30-9
Molecular Weight 249.26
Molecular Formula C10H19NO6

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Description

It is produced by the strain of Sreptomyces roseosporus M1696-AF3. It is a low molecular immune modulator.

Specification

Synonyms (S)-2-((2R,3S,4R)-2,4-dihydroxy-3-methylpentanamido)-3-hydroxy-2-methylpropanoic acid; N-(3,5-Dideoxy-3-methyl-D-xylonoyl)-2-methyl-L-serine; Conagenine
IUPAC Name (2S)-2-[[(2R,3S,4R)-2,4-dihydroxy-3-methylpentanoyl]amino]-3-hydroxy-2-methylpropanoic acid
Canonical SMILES CC(C(C)O)C(C(=O)NC(C)(CO)C(=O)O)O
InChI InChI=1S/C10H19NO6/c1-5(6(2)13)7(14)8(15)11-10(3,4-12)9(16)17/h5-7,12-14H,4H2,1-3H3,(H,11,15)(H,16,17)/t5-,6+,7+,10-/m0/s1
InChI Key GLESHRYLRAOJPS-DHCFDGJBSA-N

Properties

Appearance Colorless Crystal
Boiling Point 594.1 °C at 760 mmHg
Melting Point 159-161 °C
Density 1.326 g/cm3

Reference Reading

1. Total synthesis of (+)-conagenin
Xiao-Zhen Jiao, Li-Ping Wang, Qiong Xiao, Ping Xie, Xiao-Tian Liang J Asian Nat Prod Res. 2009;11(3):274-80. doi: 10.1080/10286020902828369.
A new approach for the synthesis of the (+)-conagenin has been achieved based on Evans asymmetry syn-aldol reaction and the self-regeneration of stereocenters strategy.
2. Synthesis of (+)-conagenin
Yohei Matsukawa, Minoru Isobe, Hiyoshizo Kotsuki, Yoshiyasu Ichikawa J Org Chem. 2005 Jun 24;70(13):5339-41. doi: 10.1021/jo050407s.
An efficient total synthesis of (+)-conagenin was achieved. The right fragment of conagenin, alpha-methylserine containing a quaternary stereocenter attached to nitrogen, was synthesized using allyl cyanate-to-isocyanate rearrangement. The left fragment, 2,4-dihydroxy-3-methylpentanoic acid, has three contiguous stereogenic centers, which was efficiently constructed by enantioselective monoreduction of 2-alkyl-1,3-diketones reported by Cossy, and chelation-controlled stereoselective reduction of beta-hydroxy ketone. These two fragments were coupled through intramolecular amide bond formation with high efficiency.
3. Synthesis of α-amino acids based on chiral tricycloiminolactone derived from natural (+)-camphor
Yong-Chun Luo, Huan-Huan Zhang, Yao Wang, Peng-Fei Xu Acc Chem Res. 2010 Oct 19;43(10):1317-30. doi: 10.1021/ar100050p.
Amino acids are one of the most important classes of the building blocks of life: they are the structural subunits of proteins, peptides, and many secondary metabolites. In addition to the 20 α-amino acids that constitute the backbone of proteins, hundreds of other natural α-amino acids have been discovered either in free form or as components in natural products. The difference between these molecules is the substituents at the chiral carbon situated between the amino and carboxyl moieties; this carbon (and any atom along a chain attached to it) is thus an important synthetic target. Because tailor-made α-amino acids are increasingly popular in biochemistry and organic synthesis, further refinement in synthetic methods to generate both natural (L-configuration) and unnatural (D-configuration) amino acids is a very active area of current research. In this Account, we examine the tricycloiminolactones, which are versatile glycine equivalents derived from natural camphor. We have developed the tricycloiminolactones in our laboratory and used them in the synthesis of several kinds of enantiopure α-amino acids. As nucleophiles, enolated tricycloiminolactones were shown to successfully participate in alkylations, Aldol reactions, Michael additions, and Mannich reactions. These reactions all gave excellent stereoselectivities and high yields. Simple conversion of the products offered α-alkyl-α-amino acids, α,α-dialkyl-α-amino acids, β-hydroxy-α-amino acids, α,γ-diamino acids, and α,β-diamino acids. One particular advantage is that the same electrophile can react with two chiral templates in the same way, thus affording access to both enantiomeric amino acids. In other words, some natural (L-configuration) α-amino acids and their unnatural (D-configuration) counterparts can be prepared very conveniently. The relation between substrate structures and product stereoconformations derived from our investigations serves as a convenient guide in the synthesis of useful chiral amino acids. In addition, highly stereoselective 1,3-diploar cycloadditions between alkenes and chiral nitrones derived from tricycloiminolactones provide a potential method for the synthesis of γ-hydroxy-α-amino acids. We also discuss applications of our methods in the synthesis of complex natural products, including conagenin, polyoxamic acid, lactacystin, and sphingofungin F. The preparation of some clinically important drug molecules, such as thiaphenicol, florfenicol, and chloramphenicol, was greatly simplified with our methods. The tricycloiminolactones offer a number of advantages in the synthesis of both natural and unnatural α-amino acids and provide many useful building blocks in the synthetic pursuit of complex molecules.

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