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PDBsum entry 1epr
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Hydrolase/hydrolase inhibitor
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PDB id
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1epr
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Contents |
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* Residue conservation analysis
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Enzyme class:
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E.C.3.4.23.22
- endothiapepsin.
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Reaction:
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Hydrolysis of proteins with broad specificity similar to that of pepsin A, preferring hydrophobic residues at P1 and P1', but does not cleave 14-Ala-|-Leu-15 in the B chain of insulin or Z-Glu-Tyr. Clots milk.
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DOI no:
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Protein Sci
3:2129-2143
(1994)
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PubMed id:
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A structural comparison of 21 inhibitor complexes of the aspartic proteinase from Endothia parasitica.
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D.Bailey,
J.B.Cooper.
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ABSTRACT
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The aspartic proteinases are an important family of enzymes associated with
several pathological conditions such as hypertension (renin), gastric ulcers
(pepsin), neoplastic disease (cathepsins D and E), and AIDS (HIV proteinase).
Studies of inhibitor binding are therefore of great importance for design of
novel inhibitors for potential therapeutic applications. Numerous X-ray analyses
have shown that transition-state isostere inhibitors of aspartic proteinases
bind in similar extended conformations in the active-site cleft of the target
enzyme. Upon comparison of 21 endothiapepsin inhibitor complexes, the hydrogen
bond lengths were found to be shortest where the isostere (P1-P'1) interacts
with the enzyme's catalytic aspartate pair. Hydrogen bonds with good geometry
also occur at P'2, and more so at P3, where a conserved water molecule is
involved in the interactions. Weaker interactions also occur at P2, where the
side-chain conformations of the inhibitors appear to be more variable than at
the more tightly held positions. At P2 and, to a lesser extent, P3, the
side-chain conformations depend intriguingly on interactions with spatially
adjacent side chains, namely P'1 and P1, respectively. The tight binding at
P1-P'1, P3, and P'2 is also reflected in the larger number of van der Waals
contacts and the large decreases in solvent-accessible area at these positions,
as well as their low temperature factors. Our analysis substantiates earlier
proposals for the locations of protons in the transition-state complex.
Aspartate 32 is probably ionized in the complexes, its charge being stabilized
by 1, or sometimes 2, hydrogen bonds from the transition-state analogues at P1.
The detailed comparison also indicates that the P1 and P2 residues of substrate
in the ES complex may be strained by the extensive binding interactions at P3,
P'1, and P'2 in a manner that would facilitate hydrolysis of the scissile
peptide bond.
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Selected figure(s)
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Figure 3.
Fig. 3. hydrogen bondinteractions with inhibitorsare shown (top) with agraph showing te donor-acceptor dis-
tances for the 21 nhibitor complexes (+ indicates an 0. . .H-N interaction, @ indicates an 0. . .H-N nteraction with an
at theproton greater than 160'. and X indicates n 0. . .H-0 interaction). Some of theiteractions with the aspartate carbox-
yls willbe van er Waals contactsratherthan hydrogen bonds (see text for discussion of proton locations).
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Figure 5.
Fig. 5. A: distribution of x, angles observed for each position of the inhibitors. The distribution of x2 angles.
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The above figures are
reprinted
by permission from the Protein Society:
Protein Sci
(1994,
3,
2129-2143)
copyright 1994.
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Figures were
selected
by an automated process.
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Literature references that cite this PDB file's key reference
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PubMed id
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Reference
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J.Pícha,
M.Buděšínský,
P.Fiedler,
M.Sanda,
and
J.Jiráček
(2010).
Synthesis of α-carboxyphosphinopeptides derived from norleucine.
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Amino Acids,
39,
1265-1280.
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L.Coates,
H.F.Tuan,
S.Tomanicek,
A.Kovalevsky,
M.Mustyakimov,
P.Erskine,
and
J.Cooper
(2008).
The catalytic mechanism of an aspartic proteinase explored with neutron and X-ray diffraction.
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J Am Chem Soc,
130,
7235-7237.
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PDB codes:
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L.Coates,
P.T.Erskine,
S.Mall,
R.Gill,
S.P.Wood,
D.A.Myles,
and
J.B.Cooper
(2006).
X-ray, neutron and NMR studies of the catalytic mechanism of aspartic proteinases.
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Eur Biophys J,
35,
559-566.
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L.Leherte
(2006).
Similarity measures based on Gaussian-type promolecular electron density models: alignment of small rigid molecules.
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J Comput Chem,
27,
1800-1816.
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L.Leherte,
N.Meurice,
and
D.P.Vercauteren
(2005).
Influence of conformation on the representation of small flexible molecules at low resolution: alignment of endothiapepsin ligands.
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J Comput Aided Mol Des,
19,
525-549.
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A.Nayeem,
S.Krystek,
and
T.Stouch
(2003).
An assessment of protein-ligand binding site polarizability.
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Biopolymers,
70,
201-211.
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P.T.Erskine,
L.Coates,
S.Mall,
R.S.Gill,
S.P.Wood,
D.A.Myles,
and
J.B.Cooper
(2003).
Atomic resolution analysis of the catalytic site of an aspartic proteinase and an unexpected mode of binding by short peptides.
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Protein Sci,
12,
1741-1749.
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PDB codes:
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C.Schoen,
U.Reichard,
M.Monod,
H.D.Kratzin,
and
R.Rüchel
(2002).
Molecular cloning of an extracellular aspartic proteinase from Rhizopus microsporus and evidence for its expression during infection.
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Med Mycol,
40,
61-71.
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N.S.Andreeva,
and
L.D.Rumsh
(2001).
Analysis of crystal structures of aspartic proteinases: on the role of amino acid residues adjacent to the catalytic site of pepsin-like enzymes.
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Protein Sci,
10,
2439-2450.
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S.W.Cho,
N.Kim,
M.U.Choi,
and
W.Shin
(2001).
Structure of aspergillopepsin I from Aspergillus phoenicis: variations of the S1'-S2 subsite in aspartic proteinases.
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Acta Crystallogr D Biol Crystallogr,
57,
948-956.
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PDB code:
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C.M.Stultz,
and
M.Karplus
(2000).
Dynamic ligand design and combinatorial optimization: designing inhibitors to endothiapepsin.
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Proteins,
40,
258-289.
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J.B.Cooper,
and
D.A.Myles
(2000).
A preliminary neutron Laue diffraction study of the aspartic proteinase endothiapepsin.
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Acta Crystallogr D Biol Crystallogr,
56,
246-248.
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J.Symersky,
M.Monod,
and
S.I.Foundling
(1997).
High-resolution structure of the extracellular aspartic proteinase from Candida tropicalis yeast.
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Biochemistry,
36,
12700-12710.
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PDB code:
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C.Abad-Zapatero,
R.Goldman,
S.W.Muchmore,
C.Hutchins,
K.Stewart,
J.Navaza,
C.D.Payne,
and
T.L.Ray
(1996).
Structure of a secreted aspartic protease from C. albicans complexed with a potent inhibitor: implications for the design of antifungal agents.
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Protein Sci,
5,
640-652.
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PDB code:
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S.M.Cutfield,
E.J.Dodson,
B.F.Anderson,
P.C.Moody,
C.J.Marshall,
P.A.Sullivan,
and
J.F.Cutfield
(1995).
The crystal structure of a major secreted aspartic proteinase from Candida albicans in complexes with two inhibitors.
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Structure,
3,
1261-1271.
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PDB code:
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The most recent references are shown first.
Citation data come partly from CiteXplore and partly
from an automated harvesting procedure. Note that this is likely to be
only a partial list as not all journals are covered by
either method. However, we are continually building up the citation data
so more and more references will be included with time.
Where a reference describes a PDB structure, the PDB
codes are
shown on the right.
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