Conserved Folding in Retroviral Proteases: Crystal Structure of Synthetic HIV-1 Protease

Wlodawer, Alexander; Miller, Maria; Jaskólski, M.; Sathyanarayana, Bangalore K.; Baldwin, Eric T.; Weber, Irene T.; Selk, Linda; Clawson, Leigh; Schneider, Jens; Kent, Stephen B. H.

doi:10.1126/science.2548279

Cited by 1,140 publications

(759 citation statements)

References 28 publications

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“…5A; Kinemage 2). Although the apoenzyme of HIV-1 PR is strictly symmetric under conditions of the investigation of its crystals reported previously (Lapatto et al, 1989;Navia et al, 1989;Wlodawer et al, 1989), most of the inhibitors studied so far are asymmetric, and thus the two molecules in the protein dimer of the resulting complex are nonequivalent. It was reported that this asymmetry is present even in the complexes of protease with quasisymmetric inhibitors Bone et al, 1991).…”

Section: I F O Imentioning

confidence: 92%

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 Imentioning

confidence: 92%

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

Self Cite

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“…The crystal structures of the human immunodeficiency virus 1 (HIVl) (Navia et al, 1989;Wlodawer et al, 1989) and Rous sarcoma virus (RSV) PRs confirmed the homodimeric nature of these viral enzymes and also defined the regions of interaction between the monomers. The extensive hydrophobic interface present in these PR dimers is dominated by a n antiparallel P-sheet formed by the interdigitation of the N-terminal (residues 1-4 in HIVl and 1-5 in RSV) and the C-terminal (residues 96-99 in HIVl and 119-124 in RSV) 0-strands of each monomer ( Fig.…”

Section: Introductionmentioning

confidence: 88%

Synthetic “interface” peptides alter dimeric assembly of the HIV 1 and 2 proteases

1992

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Retroviral proteases are obligate homodimers and play an essential role in the viral life cycle. Dissociation of dimers or prevention of their assembly may inactivate these enzymes and prevent viral maturation. A salient structural feature of these enzymes is an extended interface composed of interdigitating N-and C-terminal residues of both monomers, which form a four-stranded 6-sheet. Peptides mimicking one 6-strand (residues 95-99), or two &strands (residues 1-5 plus 95-99 or 95-99 plus 95-99) from the human immunodeficiency virus 1 (HIVl) interface were shown to inhibit the HIVl and 2 proteases (PRs) with ICso's in the low micromolar range. These interface peptides show cognate enzyme preference and do not inhibit pepsin, renin, or the Rous sarcoma virus PR, indicating a degree of specificity for the HIV PRs. A tethered HIVl P R dimer was not inhibited to the same extent as the wild-type enzymes by any of the interface peptides, suggesting that these peptides can only interact effectively with the interface of the two-subunit HIV PR. Measurements of relative dissociation constants by limit dilution of the enzyme show that the one-strand peptide causes a shift in the observed Kd for the HIVl PR. Both one-and two-strand peptides alter the monomer/dimer equilibrium of both HIVl and HIV2 PRs. This was shown by the reduced cross-linking of the HIV2 PR by disuccinimidyl suberate in the presence of the interface peptides. Refolding of the HIVl and H1V2 PRs with the interface peptides shows that only the two-strand peptides prevent the assembly of active PR dimers. Although both one-and two-strand peptides seem to affect dimer dissociation, only the two-strand peptides appear to block assembly. The latter may prove to be more effective backbones for the design of inhibitors directed toward retroviral PR dimerization in vivo.Keywords: aspartyl protease; cross-linking; dimer interface; dissociation; enzyme inhibition; HIVl protease; HIV2 protease; peptide; refolding; tethered dimer Dimerization is required to create a symmetric active site for aspartyl proteases (PRs) encoded by retroviruses. The crystal structures of the human immunodeficiency virus 1 (HIVl) (Navia et al., 1989;Wlodawer et al., 1989) and Rous sarcoma virus (RSV) PRs confirmed the homodimeric nature of these viral enzymes and also defined the regions of interaction between the monomers. The extensive hydrophobic interface present in these PR dimers is dominated by a n antiparallel P-sheet formed by the interdigitation of the N-terminal (residues 1-4 in HIVl and 1-5 in RSV) and the C-terminal (residues 96-99 in HIVl and 119-124 in RSV) 0-strands of each monomer ( Fig. 1 and kinemages). These interactions appear to be a major stabilizing force in the enzyme,

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“…The functional structure of HN-1 protease is a homodimer in which each monomer contributes one of the two catalytic aspartic acids in the active site (Lapatto et al, 1989;Navia et al, 1989;Wlodawer et al, 1989). The catalytic apparatus of HIV-1 protease is nearly identical to that of the pepsin-like proteases of the eu- karyotes, except for one major structural difference.…”

mentioning

confidence: 99%

Active‐site mobility in human immunodeficiency virus, type 1, protease as demonstrated by crystal structure of A28S mutant

Lin¹,

Hartsuck²,

Foundling³

et al. 1998

Protein Science

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The mutation Ala28 to serine in human immunodeficiency virus, type 1, (HIV-I) protease introduces putative hydrogen bonds to each active-site carboxyl group. These hydrogen bonds are ubiquitous in pepsin-like eukaryotic aspartic proteases. In order to understand the significance of this difference between HN-l protease and homologous, eukaryotic aspartic proteases, we solved the three-dimensional structure of A28S mutant HIV-1 protease in complex with a peptidic inhibitor U-8936OE. The structure has been determined to 2.0 8, resolution with an R factor of 0.194. Comparison of the mutant enzyme structure with that of the wild-type HIV-I protease bound to the same inhibitor (Hong L, Trehame A, Hartsuck JA, Foundling S, Tang J, 1996, Biochemistry 35:10627-10633) revealed double occupancy for the Ser28 hydroxyl group, which forms a hydrogen bond either to one of the oxygen atoms of the active-site carboxyl or to the carbonyl oxygen of Asp". We also observed marked changes in orientation of the Asp2' catalytic carboxyl groups, presumably caused by the new hydrogen bonds. These observations suggest that catalytic aspartyl groups of HIV-1 protease have significant conformational flexibility unseen in eukaryotic aspartic proteases. This difference may provide an explanation for some unique catalytic properties of HIV-I protease.

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Conserved Folding in Retroviral Proteases: Crystal Structure of Synthetic HIV-1 Protease

Cited by 1,140 publications

References 28 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

Synthetic “interface” peptides alter dimeric assembly of the HIV 1 and 2 proteases

Active‐site mobility in human immunodeficiency virus, type 1, protease as demonstrated by crystal structure of A28S mutant

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