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1 towards the enhanced production of Taxol and baccatin III.
2 old greater than the microtubule affinity of baccatin III.
3 2'-deoxy-PTX, N-debenzoyl-2'-deoxy-PTX, and baccatin III.
4 he fact that it is essentially a substituted baccatin III.
5 ion step to protect three hydroxyl groups of baccatin III (1), followed by hydride ester cleavage and
7 f 500 nL of taxol (20 mM) and its precursor, baccatin III (30 mM), is separated using such a column w
8 clitaxel was prepared from 7-(triethylsilyl)-baccatin III (8) and enantioenriched N-benzoyl-2-azetidi
9 measured for two forms of solid 10-deacetyl baccatin III: a dimethyl sulfoxide (DMSO) solvate and an
12 55 degrees C; the k' values for 10-deacetyl baccatin III and 10-deacetyl taxol go through a maximum
13 While there was no interference from the baccatin III and 10-deacetylbaccatin III, cephalomannine
15 4-O-acetylation of 4-deacetylbaccatin III to baccatin III and 13-acetyl-4-deacetylbacatin III to 13-a
16 .4 +/- 0.5 microM and 4.9 +/- 0.3 microM for baccatin III and beta-phenylalanoyl-CoA, respectively.
17 he enantiopure side chain precursor to 7-TES-baccatin III and subsequent silyl ether deprotection aff
18 One interpretation of these data is that baccatin III and Taxol differ in their abilities to nucl
20 ly functionalized diterpenoid core skeleton (baccatin III) and the subsequent assembly of a phenyliso
21 (1)H-NMR and MS verification of the product baccatin III derived from 10-deacetylbaccatin III and ac
22 cient synthesis of 13-epi-7-O-(triethylsilyl)baccatin III from 13-deoxybaccatin III is described.
23 The preparation of 13-oxo-7-O-(triethylsilyl)baccatin III from 13-epi-7-O-(triethylsilyl)baccatin III
24 n III, 2-p-azido baccatin III was similar to baccatin III, having no Taxol-like activity, further ind
25 native source for Taxol and its intermediate Baccatin III, however the very low yields remain a hinde
28 ibrium constants for the growth reaction for baccatin III-induced GTP-tubulin and GDP-tubulin assembl
33 es at C4, suggesting that the C7 hydroxyl of baccatin III must remain deacylated for enzyme function.
35 for further media optimization for Taxol and Baccatin III production in five different liquid media u
37 ated using the X-ray geometry of 10-deacetyl baccatin III supports the contention that the B, C, and
38 e novo 17-gene biosynthesis and isolation of baccatin III, the industrial precursor to Taxol, in Nico
40 mical coupling of 10-deacetylbaccatin III or baccatin III to C-13 paclitaxel side chain has been summ
41 )baccatin III from 13-epi-7-O-(triethylsilyl)baccatin III using tetrapropylammonium perruthenate and
42 ere semisynthesized from the natural product baccatin III via silyl protecting group manipulation, re
43 ontrast to 2-m-azido baccatin III, 2-p-azido baccatin III was similar to baccatin III, having no Taxo
46 at catalyzes the selective 13-O-acylation of baccatin III with beta-phenylalanoyl CoA as the acyl don
47 Oxidation of 13-deoxy-7-O-(triethylsilyl)baccatin III with tert-butyl peroxide, followed by reduc