X-ray crystallographic structure of a complex between a synthetic protease of human immunodeficiency virus 1 and a substrate-based hydroxyethylamine inhibitor.

Swain, Amy L.; Miller, Maria; Green, Jeremy; Rich, Daniel H.; Schneider, Jens; Kent, Stephen B. H.; Wlodawer, Alexander

doi:10.1073/pnas.87.22.8805

Cited by 281 publications

(163 citation statements)

References 24 publications

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“…Of course, in the orthorhombic space group to which these crystals belong, molecules 1 and 2 are distinct crystallographically and make different lattice contacts. As judged by the definition above, these two molecules are similar to those previously observed in the same space group for MVT-101 , JG-365 (Swain et al, 1990), and U85548e (Jaskolski et al, 1991). Although this result might indicate strict correlation between crystal packing forces and orientation of the flaps, recent results from this and other laboratories have indicated that this is not the case, because in some other isomorphous structures the opposite arrangement of the two molecules was also observed (J.K.M.…”

Section: I F O Isupporting

confidence: 83%

“…The distance between OPl(203) and OP2(204) is 2.6 A and the torsion around (H0)C-C(0H) is 50" (Kinemage 1). The two asymmetric centers (C * 203,204) at the scissile bond both have the R configuration, unlike some previously reported inhibitors with one OH substituent at the scissile bond, such as hydroxyethylamine (Swain et al, 1990) and hydroxyethylene (Jaskolski et al, 1991), which have the S diastereomers preferentially bound by the enzyme. However, the R configuration reported here is equivalent to S in the inhibitors mentioned above, with the difference being the result of the nomenclature only.…”

Section: I F O Imentioning

confidence: 73%

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Crystal structure of a complex of HIV‐1 protease with a dihydroxyethylene‐containing inhibitor: Comparisons with molecular modeling

Thanki¹,

Rao²,

Foundling³

et al. 1992

Protein Science

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The structure of a crystal complex of recombinant human immunodeficiency virus type 1 (HIV-1) protease with a peptide-mimetic inhibitor containing a dihydroxyethylene isostere insert replacing the scissile bond has been de- The bound inhibitor diastereomer has the R configurations at both of the hydroxyl chiral carbon atoms. One of the diol hydroxyl groups is positioned such that it forms hydrogen bonds with both the active site aspartates, whereas the other interacts with only one of them. Comparison of this X-ray structure with a model-built structure of the inhibitor, published earlier, reveals similar positioning of the backbone atoms and of the side-chain atoms in the P2-P2' region, where the interaction with the protein is strongest. However, the X-ray structure and the model differ considerably in the location of the P3 and P3' end groups, and also in the positioning of the second of the two central hydroxyl groups. Reconstruction of the central portion of the model revealed the source of the hydroxyl discrepancy, which, when corrected, provided a PI-PI' geometry very close to that seen in the X-ray structure.

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Section: I F O Isupporting

confidence: 83%

Section: I F O Imentioning

confidence: 73%

Crystal structure of a complex of HIV‐1 protease with a dihydroxyethylene‐containing inhibitor: Comparisons with molecular modeling

Thanki¹,

Rao²,

Foundling³

et al. 1992

Protein Science

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show abstract

“…The synthetic enzyme has been prepared in crystalline form and was used to solve the three-dimensional structure of both the native molecule and the enzyme complexed with several dif- ferent substrate-derived inhibitors Swain et al, 1990;Jaskolski et al, 1991). The chemical synthesis approach brings the entire world of organic chemistry into the realm of proteins.…”

mentioning

confidence: 99%

“…The range of chemical alterations that can be made to a native protein is limited only by the imagination and by any peculiarities of the particular chemical methodology being employed. In addition to the synthetic accessibility of the HIV-1 protease, knowledge of its three-dimensional structure Wlodawer et al, 1989;Erickson et al, 1990;Swain et al, 1990;Bone et al, 1991;Jaskolski et al, 1991) is invaluable in designing experiments to probe the interrelationship of enzyme structure with catalytic function.…”

mentioning

confidence: 99%

“…However, in the numerous protease-inhibitor complexes that have been solved, the geometry of this turn varies and is not necessarily identical in both subunits. For example, in the complex with JG-365, the geometries are type I' and 11' (Swain et al, 1990); with U85548e, type I' and I1 (Jaskolski et al, 1991); and with MVT-101, type I' and IV (Milier et al, 1989). In all cases, the residues of these turns possess high thermal factors, indicating high mobility (Jaskolski et al, 1991).…”

mentioning

confidence: 99%

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Structural engineering of the HIV‐1 protease molecule with a β‐turn mimic of fixed geometry

1993

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An important goal in the de novo design of enzymes is the control of molecular geometry. To this end, an analog of the protease from human immunodeficiency virus 1 (HIV-1 protease) was prepared by total chemical synthesis, containing a constrained, nonpeptidic type 11' 0-turn mimic of predetermined three-dimensional structure.The mimic &turn replaced residues GlyI6,l7 in each subunit of the homodimeric molecule. These residues constitute the central amino acids of two symmetry-related type I' 0-turns in the native, unliganded enzyme. The 0-turn mimic-containing enzyme analog was fully active, possessed the same substrate specificity as the GlyI67l7-containing enzyme, and showed enhanced resistance to thermal inactivation. These results indicate that the precise geometry of the @turn at residues 15-18 in each subunit is not critical for activity, and that replacement of the native sequence with a rigid 0-turn mimic can lead to enhanced protein stability. Finally, the successful incorporation of a fixed element of secondary structure illustrates the potential of a "molecular kit set" approach to protein design and synthesis.

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Building molecular charge distributions from fragments: Application to HIV-1 protease inhibitors

Young¹,

Topol²,

Rashin³

et al. 1997

J. Comput. Chem.

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X-ray crystallographic structure of a complex between a synthetic protease of human immunodeficiency virus 1 and a substrate-based hydroxyethylamine inhibitor.

Cited by 281 publications

References 24 publications

Crystal structure of a complex of HIV‐1 protease with a dihydroxyethylene‐containing inhibitor: Comparisons with molecular modeling

Crystal structure of a complex of HIV‐1 protease with a dihydroxyethylene‐containing inhibitor: Comparisons with molecular modeling

Structural engineering of the HIV‐1 protease molecule with a β‐turn mimic of fixed geometry

Building molecular charge distributions from fragments: Application to HIV-1 protease inhibitors

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