Nucleoside analogues bearing a fluorine in the C2'-position have been synthesized by S2-like cyclizations of acyclic thioaminal precursors. This strategy provides access to two scaffolds, d-1',2'-cis-thiofuranosides and d-1',2'-trans-furanosides, which are difficult to generate using the standard approach for nucleoside synthesis. The addition of silylated nucleobases onto model C2-fluorinated dithioacetal substrates resulted in 1,2-syn diastereoselectivity, which is consistent with the C2-F and S-alkyl moiety being in close proximity. A new series of analogues bearing a C3' all-carbon quaternary center along with a C2'-F atom have also been synthesized using this approach and are being investigated as potential antimetabolites.
A novel thiol-functionalized PCL (PCL-HDT) was synthesized following a convenient two-step procedure. Taking advantage of the pendant thiol group, degradable elastomeric materials have been prepared from PCL-HDT by redox or thiol-ene reaction. Elastomers were characterized by HRMAS NMR spectroscopy to confirm the formation of disulfide or thioether cross-links. The thermal and mechanical properties of elastomers have been assessed by DSC, DMA and tensile tests. Disulfide containing elastomers (EM SS ) and thioether containing elastomers (EM TE ) exhibited improved mechanical properties with ultimate strains up to 220%. The stability of the mechanical properties at temperatures close to body temperature was confirmed by DMA with G 0 z 200 MPa and G 00 z 15 MPa. Finally, the reversibility of the disulfide formation and breaking has been evaluated, and confirmed the potential of these degradable elastomers as biomaterials.
The design of a novel nucleoside scaffold that exhibits an all-carbon quaternary center is reported. This allows for both α- and β-anomers of a given 2'-deoxy-2',2'-difluoro nucleoside analog (NA) to have potential biological activity. Using an intramolecular atom-transfer reaction, an all-carbon quaternary center was obtained without the use of heavy metals and/or harsh conditions. The chemistry developed is efficient, easily scalable and leads to novel libraries of molecules.
We report on the design and synthesis of molecules having E- and P-selectins blocking activity both in vitro and in vivo. The GlcNAc component of the selectin ligand sialyl Lewis(X) was replaced by an acyclic tether that links two saccharide units. The minimization of intramolecular dipole-dipole interactions and the gauche effect would be at the origin of the conformational bias imposed by this acyclic tether. The stereoselective synthesis of these molecules, their biochemical and biological evaluations using surface plasmon resonance spectroscopy (SPR), and in vivo assays are described. Because the structure of our analogues differs from the most potent E-selectin antagonists reported, our acyclic analogues offer new opportunities for chemical diversity.
A series of 5‐substituted thieno[3,2‐e][1,4]diazepin‐2‐ones was synthesized in four steps from methyl 3‐aminothiophene‐2‐carboxylate. After the coupling of 3‐aminothiophene with α‐amino acids, the key final step that involves an uncatalysed Pictet–Spengler reaction allowed the cyclization of the seven‐membered diazepinone ring. The reaction was first optimized and then exemplified in three different series (phenylalanine, alanine and proline) that led to 24 target diazepinones, which includes 19 optically pure diastereomers.
p21Cip1 (p21) is a universal cyclin-dependent
kinase
(CDK) inhibitor that halts cell proliferation and tumor growth by
multiple mechanisms. The expression of p21 is often downregulated
in cancer cells as a result of the loss of function of transcriptional
activators, such as p53, or the increased degradation rate of the
protein. To identify small molecules that block the ubiquitin-mediated
degradation of p21 as a future avenue for cancer drug discovery, we
have screened a compound library using a cell-based reporter assay
of p21 degradation. This led to the identification of a benzodiazepine
series of molecules that induce the accumulation of p21 in cells.
Using a chemical proteomic strategy, we identified the ubiquitin-conjugating
enzyme UBCH10 as a cellular target of this benzodiazepine series.
We show that an optimized benzodiazepine analogue inhibits UBCH10
ubiquitin-conjugating activity and substrate proteolysis by the anaphase-promoting
complex.
Reported herein are the first diastereoselective and Lewis acid-mediated radical reactions of N-heterocyclic carbene (NHC) boranes. We applied these reactions to the synthesis of four propionate diastereoisomers combining an aldol reaction, followed by a stereoselective radical-based reduction in which the NHC borane serves as the hydrogen donor, thus obviating the use of tin-based reagents. The 2,3-syn isomer is obtained by combining an NHC-borane and a Lewis acid (MgBr·OEt), while using a reverse polarity strategy provides the 2,3-anti isomer.
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