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PDBsum entry 1hb0
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Contents |
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* Residue conservation analysis
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Enzyme class:
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E.C.3.4.21.36
- pancreatic elastase.
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Reaction:
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Hydrolysis of proteins, including elastin. Preferential cleavage: Ala-|-Xaa.
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DOI no:
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Nat Struct Biol
8:689-694
(2001)
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PubMed id:
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X-ray snapshots of serine protease catalysis reveal a tetrahedral intermediate.
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R.C.Wilmouth,
K.Edman,
R.Neutze,
P.A.Wright,
I.J.Clifton,
T.R.Schneider,
C.J.Schofield,
J.Hajdu.
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ABSTRACT
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Studies on the catalytic mechanism and inhibition of serine proteases are widely
used as paradigms for teaching enzyme catalysis. Ground-breaking work on the
structures of chymotrypsin and subtilisin led to the idea of a conserved
catalytic triad formed by the active site Ser, His and Asp residues. An oxyanion
hole, consisting of the peptide amide of the active site serine and a
neighbouring glycine, was identified, and hydrogen bonding in the oxyanion hole
was suggested to stabilize the two proposed tetrahedral intermediates on the
catalytic pathway. Here we show electron density changes consistent with the
formation of a tetrahedral intermediate during the hydrolysis of an acyl-enzyme
complex formed between a natural heptapeptide and elastase. No electron density
for an enzyme-product complex was observed. The structures also suggest a
mechanism for the synchronization of hydrolysis and peptide release triggered by
the conversion of the sp2 hybridized carbonyl carbon to an sp3 carbon in the
tetrahedral intermediate. This affects the location of the peptide in the active
site cleft, triggering the collapse of a hydrogen bonding network between the
peptide and the beta-sheet of the active site.
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Selected figure(s)
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Figure 3.
Figure 3. Isotropic temperature factors in the acyl -enzyme
complex and in the tetrahedral intermediate (b) formed between
porcine pancreatic elastase and human  -casomorphin-7.
a, B-factors for the structure in Fig. 1a, where the PPE
-BCM7 acyl -enzyme complex is stabilized at pH 5. Three
N-terminal residues are disordered. b, B-factors for the
structure of the tetrahedral intermediate in Fig. 1c. This
structure was obtained in a freeze-quenched crystal following a
1 min long pH jump to pH 9. For data collection and refinement
statistics, see Table 1.
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Figure 4.
Figure 4. Structural changes within the peptide binding pocket
during catalysis. a, The active site cleft showing the
location of the peptide substrate (pink) in the acyl -enzyme
complex at pH 5. The enzyme is shown as a gray space filling
model with Ser 195 (green), His 57 (purple) and Asp 102 (brown)
highlighted. b, Model of the protein -peptide complex at pH 5
(pink) overlaid with the model of the tetrahedral intermediate
(blue) (see Methods) . A circle highlights the active site Ser
residue under the bound peptide. Both Wat 318 and hydrogen bonds
between enzyme and peptide are red in the acyl -enzyme complex
and blue in the tetrahedral intermediate. During product
release, the loop formed by residues 217 -219 (immediately below
the binding pocket) moves so as to partially fill a space
previously occupied by the peptide. Arg 217 takes up a position
similar to that found in the native unliganded structure (1QNJ)5.
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The above figures are
reprinted
by permission from Macmillan Publishers Ltd:
Nat Struct Biol
(2001,
8,
689-694)
copyright 2001.
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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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M.Amitay,
and
A.Shurki
(2011).
Hydrolysis of organophosphate compounds by mutant butyrylcholinesterase: a story of two histidines.
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Proteins,
79,
352-364.
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G.Bujacz,
B.Wrzesniewska,
and
A.Bujacz
(2010).
Cryoprotection properties of salts of organic acids: a case study for a tetragonal crystal of HEW lysozyme.
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Acta Crystallogr D Biol Crystallogr,
66,
789-796.
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P.O.Syrén,
and
K.Hult
(2010).
Substrate conformations set the rate of enzymatic acrylation by lipases.
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Chembiochem,
11,
802-810.
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S.Westenhoff,
E.Nazarenko,
E.Malmerberg,
J.Davidsson,
G.Katona,
and
R.Neutze
(2010).
Time-resolved structural studies of protein reaction dynamics: a smorgasbord of X-ray approaches.
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Acta Crystallogr A,
66,
207-219.
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M.Amitay,
and
A.Shurki
(2009).
The structure of G117H mutant of butyrylcholinesterase: nerve agents scavenger.
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Proteins,
77,
370-377.
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N.Otte,
M.Bocola,
and
W.Thiel
(2009).
Force-field parameters for the simulation of tetrahedral intermediates of serine hydrolases.
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J Comput Chem,
30,
154-162.
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S.G.Burston
(2009).
Anything a ClpA can do, two ClpAs can do better.
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Structure,
17,
483-484.
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A.Korostelev,
H.Asahara,
L.Lancaster,
M.Laurberg,
A.Hirschi,
J.Zhu,
S.Trakhanov,
W.G.Scott,
and
H.F.Noller
(2008).
Crystal structure of a translation termination complex formed with release factor RF2.
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Proc Natl Acad Sci U S A,
105,
19684-19689.
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PDB codes:
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C.Petibois,
and
M.Cestelli Guidi
(2008).
Bioimaging of cells and tissues using accelerator-based sources.
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Anal Bioanal Chem,
391,
1599-1608.
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P.A.Sigala,
D.A.Kraut,
J.M.Caaveiro,
B.Pybus,
E.A.Ruben,
D.Ringe,
G.A.Petsko,
and
D.Herschlag
(2008).
Testing geometrical discrimination within an enzyme active site: constrained hydrogen bonding in the ketosteroid isomerase oxyanion hole.
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J Am Chem Soc,
130,
13696-13708.
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PDB codes:
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R.Conners,
A.V.Konarev,
J.Forsyth,
A.Lovegrove,
J.Marsh,
T.Joseph-Horne,
P.Shewry,
and
R.L.Brady
(2007).
An unusual helix-turn-helix protease inhibitory motif in a novel trypsin inhibitor from seeds of Veronica (Veronica hederifolia L.).
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J Biol Chem,
282,
27760-27768.
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PDB codes:
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B.Liu,
C.J.Schofield,
and
R.C.Wilmouth
(2006).
Structural analyses on intermediates in serine protease catalysis.
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J Biol Chem,
281,
24024-24035.
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PDB codes:
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E.S.Radisky,
J.M.Lee,
C.J.Lu,
and
D.E.Koshland
(2006).
Insights into the serine protease mechanism from atomic resolution structures of trypsin reaction intermediates.
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Proc Natl Acad Sci U S A,
103,
6835-6840.
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PDB codes:
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J.A.Gutierrez,
Y.X.Pan,
L.Koroniak,
J.Hiratake,
M.S.Kilberg,
and
N.G.Richards
(2006).
An inhibitor of human asparagine synthetase suppresses proliferation of an L-asparaginase-resistant leukemia cell line.
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Chem Biol,
13,
1339-1347.
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X.Ding,
B.F.Rasmussen,
G.A.Petsko,
and
D.Ringe
(2006).
Direct crystallographic observation of an acyl-enzyme intermediate in the elastase-catalyzed hydrolysis of a peptidyl ester substrate: Exploiting the "glass transition" in protein dynamics.
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Bioorg Chem,
34,
410-423.
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A.Schmidt,
and
V.S.Lamzin
(2005).
Extraction of functional motion in trypsin crystal structures.
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Acta Crystallogr D Biol Crystallogr,
61,
1132-1139.
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PDB codes:
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D.Vivares,
P.Arnoux,
and
D.Pignol
(2005).
A papain-like enzyme at work: native and acyl-enzyme intermediate structures in phytochelatin synthesis.
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Proc Natl Acad Sci U S A,
102,
18848-18853.
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PDB codes:
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K.Aertgeerts,
S.Ye,
M.G.Tennant,
M.L.Kraus,
J.Rogers,
B.C.Sang,
R.J.Skene,
D.R.Webb,
and
G.S.Prasad
(2004).
Crystal structure of human dipeptidyl peptidase IV in complex with a decapeptide reveals details on substrate specificity and tetrahedral intermediate formation.
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Protein Sci,
13,
412-421.
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PDB codes:
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A.Schmidt,
C.Jelsch,
P.Ostergaard,
W.Rypniewski,
and
V.S.Lamzin
(2003).
Trypsin revisited: crystallography AT (SUB) atomic resolution and quantum chemistry revealing details of catalysis.
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J Biol Chem,
278,
43357-43362.
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PDB codes:
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I.Ahel,
D.Korencic,
M.Ibba,
and
D.Söll
(2003).
Trans-editing of mischarged tRNAs.
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Proc Natl Acad Sci U S A,
100,
15422-15427.
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J.Blanco,
R.A.Moore,
and
R.E.Viola
(2003).
Capture of an intermediate in the catalytic cycle of L-aspartate-beta-semialdehyde dehydrogenase.
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Proc Natl Acad Sci U S A,
100,
12613-12617.
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PDB codes:
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C.M.Wilmot,
and
A.R.Pearson
(2002).
Cryocrystallography of metalloprotein reaction intermediates.
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Curr Opin Chem Biol,
6,
202-207.
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G.Katona,
R.C.Wilmouth,
P.A.Wright,
G.I.Berglund,
J.Hajdu,
R.Neutze,
and
C.J.Schofield
(2002).
X-ray structure of a serine protease acyl-enzyme complex at 0.95-A resolution.
|
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J Biol Chem,
277,
21962-21970.
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PDB code:
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H.R.Stennicke,
C.A.Ryan,
and
G.S.Salvesen
(2002).
Reprieval from execution: the molecular basis of caspase inhibition.
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Trends Biochem Sci,
27,
94.
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J.Antony,
N.Gresh,
L.Olsen,
L.Hemmingsen,
C.J.Schofield,
and
R.Bauer
(2002).
Binding of D- and L-captopril inhibitors to metallo-beta-lactamase studied by polarizable molecular mechanics and quantum mechanics.
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J Comput Chem,
23,
1281-1296.
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K.A.Scheibner,
J.De Angelis,
S.K.Burley,
and
P.A.Cole
(2002).
Investigation of the roles of catalytic residues in serotonin N-acetyltransferase.
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J Biol Chem,
277,
18118-18126.
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PDB code:
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M.Topf,
P.Várnai,
C.J.Schofield,
and
W.G.Richards
(2002).
Molecular dynamics simulations of the acyl-enzyme and the tetrahedral intermediate in the deacylation step of serine proteases.
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Proteins,
47,
357-369.
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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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Links
