Anna Mühlman scite author profile

A study on the use of derivatized carbohydrates as C2-symmetric HIV-1 protease inhibitors has been undertaken. L-Mannaric acid (6) was bis-O-benzylated at C-2 and C-5 and subsequently coupled with amino acids and amines to give C2-symmetric products based on C-terminal duplication. Potent HIV protease inhibitors, 28 Ki = 0.4 nM and 43 Ki = 0.2 nM, have been discovered, and two synthetic methodologies have been developed, one whereby these inhibitors can be prepared in just three chemical steps from commercially available materials. A remarkable increase in potency going from IC50 = 5000 nM (23) to IC50 = 15 nM (28) was observed upon exchanging -COOMe for -CONHMe in the inhibitor, resulting in the net addition of one hydrogen bond interaction between each of the two -NH- groups and the HIV protease backbone (Gly 48/148). The X-ray crystal structures of 43 and of 48 have been determined (Figures 5 and 6), revealing the binding mode of these inhibitors which will aid further design.

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Optimization of P1–P3 groups in symmetric and asymmetric HIV‐1 protease inhibitors

Andersson

Fridborg

Löwgren

et al. 2003

European Journal of Biochemistry

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HIV-1 protease is an important target for treatment of AIDS, and efficient drugs have been developed. However, the resistance and negative side effects of the current drugs has necessitated the development of new compounds with different binding patterns. In this study, nine C-terminally duplicated HIV-1 protease inhibitors were cocrystallised with the enzyme, the crystal structures analysed at 1.8-2.3 Å resolution, and the inhibitory activity of the compounds characterized in order to evaluate the effects of the individual modifications. These compounds comprise two central hydroxy groups that mimic the geminal hydroxy groups of a cleavage-reaction intermediate. One of the hydroxy groups is located between the d-oxygen atoms of the two catalytic aspartic acid residues, and the other in the gauche position relative to the first. The asymmetric binding of the two central inhibitory hydroxyls induced a small deviation from exact C2 symmetry in the whole enzyme-inhibitor complex. The study shows that the protease molecule could accommodate its structure to different sizes of the P2/P2¢ groups. The structural alterations were, however, relatively conservative and limited. The binding capacity of the S3/S3¢ sites was exploited by elongation of the compounds with groups in the P3/P3¢ positions or by extension of the P1/P1¢ groups. Furthermore, water molecules were shown to be important binding links between the protease and the inhibitors. This study produced a number of inhibitors with K i values in the 100 picomolar range.

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Impact of the Central Hydroxyl Groups on the Activity of Symmetrical HIV-1 Protease Inhibitors Derived From l-Mannaric Acid

et al. 2000

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Anna Mühlman

Design and Synthesis of New PotentC₂-Symmetric HIV-1 Protease Inhibitors. Use ofl-Mannaric Acid as a Peptidomimetic Scaffold

Optimization of P1–P3 groups in symmetric and asymmetric HIV‐1 protease inhibitors

Impact of the Central Hydroxyl Groups on the Activity of Symmetrical HIV-1 Protease Inhibitors Derived From l-Mannaric Acid

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Anna Mühlman

Design and Synthesis of New PotentC2-Symmetric HIV-1 Protease Inhibitors. Use ofl-Mannaric Acid as a Peptidomimetic Scaffold

Optimization of P1–P3 groups in symmetric and asymmetric HIV‐1 protease inhibitors

Impact of the Central Hydroxyl Groups on the Activity of Symmetrical HIV-1 Protease Inhibitors Derived From l-Mannaric Acid

Contact Info

Product

Resources

About

Design and Synthesis of New PotentC₂-Symmetric HIV-1 Protease Inhibitors. Use ofl-Mannaric Acid as a Peptidomimetic Scaffold