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Contents |
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(+ 1 more)
289 a.a.
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(+ 11 more)
304 a.a.
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PDB id:
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Hydrolase
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Title:
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P4 protein from bacteriophage phi12 apo state
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Structure:
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Ntpase p4. Chain: a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, x. Synonym: p4 packaging atpase. Engineered: yes
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Source:
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Bacteriophage phi-12. Bacteriophage phi12. Organism_taxid: 161736. Expressed in: escherichia coli. Expression_system_taxid: 562.
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Biol. unit:
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Hexamer (from PDB file)
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Resolution:
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2.50Å
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R-factor:
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0.251
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R-free:
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0.224
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Authors:
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E.J.Mancini,D.E.Kainov,J.M.Grimes,R.Tuma,D.H.Bamford,D.I.Stuart
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Key ref:
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E.J.Mancini
et al.
(2004).
Atomic snapshots of an RNA packaging motor reveal conformational changes linking ATP hydrolysis to RNA translocation.
Cell,
118,
743-755.
PubMed id:
DOI:
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Date:
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22-Jul-04
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Release date:
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04-Nov-04
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PROCHECK
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Headers
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References
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DOI no:
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Cell
118:743-755
(2004)
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PubMed id:
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Atomic snapshots of an RNA packaging motor reveal conformational changes linking ATP hydrolysis to RNA translocation.
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E.J.Mancini,
D.E.Kainov,
J.M.Grimes,
R.Tuma,
D.H.Bamford,
D.I.Stuart.
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ABSTRACT
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Many viruses package their genome into preformed capsids using packaging motors
powered by the hydrolysis of ATP. The hexameric ATPase P4 of dsRNA bacteriophage
phi12, located at the vertices of the icosahedral capsid, is such a packaging
motor. We have captured crystallographic structures of P4 for all the key points
along the catalytic pathway, including apo, substrate analog bound, and product
bound. Substrate and product binding have been observed as both binary complexes
and ternary complexes with divalent cations. These structures reveal large
movements of the putative RNA binding loop, which are coupled with nucleotide
binding and hydrolysis, indicating how ATP hydrolysis drives RNA translocation
through cooperative conformational changes. Two distinct conformations of bound
nucleotide triphosphate suggest how hydrolysis is activated by RNA binding. This
provides a model for chemomechanical coupling for a prototype of the large
family of hexameric helicases and oligonucleotide translocating enzymes.
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Selected figure(s)
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Figure 2.
Figure 2. Structure of the P4 Hexamer(A) The P4 hexamer is
shown in terms of its secondary structural elements and solvent
accessible surface in top, side, and bottom views. The secondary
structural elements are colored according to the bar where
different colors distinguish subdomains or segments of the P4
monomer: N-terminal safety pin motif (blue), all β domain (dark
purple), conserved RecA-like ATP binding domain (red), and
antiparallel β strands and C-terminal helix (green). Six
molecules of AMPcPP, drawn as ball-and-stick representations,
are located in clefts between monomers. The solvent-accessible
surface of P4 (without nucleotides) is colored according to the
electrostatic potential (defined in the key). The top view shows
the solvent-exposed face of the P4 hexamer, while the bottom
view shows the C-terminal face that packs against the procapsid.
Representations and calculations were performed with GRASP
(Nicholls et al., 1991).(B) Cartoon showing the position of the
P4 hexamer (red) on the empty φ12 procapsid (green) while
packaging ssRNA (cyan).
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Figure 3.
Figure 3. The Nucleotide Binding SiteResidues involved in
nucleotide binding and catalysis and elements of secondary
structure in the cleft between two P4 monomers (cyan and
purple). Nucleotides and selected residues of the active site
are drawn in a ball-and-stick representation. Residues are
labeled in black only in the first panel. The nucleotides are
color coded according to their conformation: AMPcPP inactive
“I” (orange), AMPcPP active “A” (red), product “P”
(blue), and ADP-Mg^2+ (yellow). The electron density for the
bound nucleotides and ions, calculated from the final Fourier
difference (2F[o] − F[c]), is shown in a beige surface
representation (1.0 σ). Mg^2+ ions are shown as pink balls,
while the anomalous Fourier difference map for the Mn^2+ ions is
shown as magenta chicken wire. The phosphates are anchored by
residues of the P loop (colored in red). The views are chosen to
be equivalent for each nucleotide binding site. The associated
cartoon representation shows the coordination of nucleotides to
selected residues of the catalytic sites and divalent cations.
Distances (in Å) are shown as dotted lines.
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The above figures are
reprinted
by permission from Cell Press:
Cell
(2004,
118,
743-755)
copyright 2004.
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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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A.Y.Lyubimov,
M.Strycharska,
and
J.M.Berger
(2011).
The nuts and bolts of ring-translocase structure and mechanism.
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Curr Opin Struct Biol,
21,
240-248.
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E.Chapman,
A.N.Fry,
and
M.Kang
(2011).
The complexities of p97 function in health and disease.
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Mol Biosyst,
7,
700-710.
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E.Crozat,
A.Meglio,
J.F.Allemand,
C.E.Chivers,
M.Howarth,
C.Vénien-Bryan,
I.Grainge,
and
D.J.Sherratt
(2010).
Separating speed and ability to displace roadblocks during DNA translocation by FtsK.
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EMBO J,
29,
1423-1433.
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Y.R.Chemla
(2010).
Revealing the base pair stepping dynamics of nucleic acid motor proteins with optical traps.
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Phys Chem Chem Phys,
12,
3080-3095.
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A.Y.Mulkidjanian,
M.Y.Galperin,
and
E.V.Koonin
(2009).
Co-evolution of primordial membranes and membrane proteins.
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Trends Biochem Sci,
34,
206-215.
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J.R.Moffitt,
Y.R.Chemla,
K.Aathavan,
S.Grimes,
P.J.Jardine,
D.L.Anderson,
and
C.Bustamante
(2009).
Intersubunit coordination in a homomeric ring ATPase.
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Nature,
457,
446-450.
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K.Aathavan,
A.T.Politzer,
A.Kaplan,
J.R.Moffitt,
Y.R.Chemla,
S.Grimes,
P.J.Jardine,
D.L.Anderson,
and
C.Bustamante
(2009).
Substrate interactions and promiscuity in a viral DNA packaging motor.
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Nature,
461,
669-673.
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N.D.Thomsen,
and
J.M.Berger
(2009).
Running in reverse: the structural basis for translocation polarity in hexameric helicases.
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Cell,
139,
523-534.
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PDB code:
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S.R.Barkow,
I.Levchenko,
T.A.Baker,
and
R.T.Sauer
(2009).
Polypeptide translocation by the AAA+ ClpXP protease machine.
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Chem Biol,
16,
605-612.
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T.J.Lee,
C.Schwartz,
and
P.Guo
(2009).
Construction of bacteriophage phi29 DNA packaging motor and its applications in nanotechnology and therapy.
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Ann Biomed Eng,
37,
2064-2081.
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X.Chen,
and
B.L.Stitt
(2009).
ADP but not P(i) dissociation contributes to rate limitation for Escherichia coli Rho.
|
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J Biol Chem,
284,
33773-33780.
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A.B.Deutman,
C.Monnereau,
J.A.Elemans,
G.Ercolani,
R.J.Nolte,
and
A.E.Rowan
(2008).
Mechanism of threading a polymer through a macrocyclic ring.
|
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Science,
322,
1668-1671.
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A.M.De Palma,
W.Heggermont,
K.Lanke,
B.Coutard,
M.Bergmann,
A.M.Monforte,
B.Canard,
E.De Clercq,
A.Chimirri,
G.Pürstinger,
J.Rohayem,
F.van Kuppeveld,
and
J.Neyts
(2008).
The thiazolobenzimidazole TBZE-029 inhibits enterovirus replication by targeting a short region immediately downstream from motif C in the nonstructural protein 2C.
|
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J Virol,
82,
4720-4730.
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B.Suchanova,
and
R.Tuma
(2008).
Folding and assembly of large macromolecular complexes monitored by hydrogen-deuterium exchange and mass spectrometry.
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Microb Cell Fact,
7,
12.
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D.E.Kainov,
E.J.Mancini,
J.Telenius,
J.Lísal,
J.M.Grimes,
D.H.Bamford,
D.I.Stuart,
and
R.Tuma
(2008).
Structural basis of mechanochemical coupling in a hexameric molecular motor.
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J Biol Chem,
283,
3607-3617.
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PDB codes:
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E.Eryilmaz,
J.Benach,
M.Su,
J.Seetharaman,
K.Dutta,
H.Wei,
P.Gottlieb,
J.F.Hunt,
and
R.Ghose
(2008).
Structure and dynamics of the P7 protein from the bacteriophage phi 12.
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J Mol Biol,
382,
402-422.
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PDB code:
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E.J.Enemark,
and
L.Joshua-Tor
(2008).
On helicases and other motor proteins.
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Curr Opin Struct Biol,
18,
243-257.
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M.Oram,
C.Sabanayagam,
and
L.W.Black
(2008).
Modulation of the packaging reaction of bacteriophage t4 terminase by DNA structure.
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J Mol Biol,
381,
61-72.
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N.D.Thomsen,
and
J.M.Berger
(2008).
Structural frameworks for considering microbial protein- and nucleic acid-dependent motor ATPases.
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Mol Microbiol,
69,
1071-1090.
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R.S.Williams,
G.J.Williams,
and
J.A.Tainer
(2008).
A charged performance by gp17 in viral packaging.
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Cell,
135,
1169-1171.
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S.Sun,
K.Kondabagil,
B.Draper,
T.I.Alam,
V.D.Bowman,
Z.Zhang,
S.Hegde,
A.Fokine,
M.G.Rossmann,
and
V.B.Rao
(2008).
The structure of the phage T4 DNA packaging motor suggests a mechanism dependent on electrostatic forces.
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Cell,
135,
1251-1262.
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PDB codes:
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V.B.Rao,
and
M.Feiss
(2008).
The bacteriophage DNA packaging motor.
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Annu Rev Genet,
42,
647-681.
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V.L.Morton,
P.G.Stockley,
N.J.Stonehouse,
and
A.E.Ashcroft
(2008).
Insights into virus capsid assembly from non-covalent mass spectrometry.
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Mass Spectrom Rev,
27,
575-595.
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C.M.Sanders,
O.V.Kovalevskiy,
D.Sizov,
A.A.Lebedev,
M.N.Isupov,
and
A.A.Antson
(2007).
Papillomavirus E1 helicase assembly maintains an asymmetric state in the absence of DNA and nucleotide cofactors.
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Nucleic Acids Res,
35,
6451-6457.
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PDB code:
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H.T.Jäälinoja,
J.T.Huiskonen,
and
S.J.Butcher
(2007).
Electron cryomicroscopy comparison of the architectures of the enveloped bacteriophages phi6 and phi8.
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Structure,
15,
157-167.
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J.T.Huiskonen,
and
S.J.Butcher
(2007).
Membrane-containing viruses with icosahedrally symmetric capsids.
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Curr Opin Struct Biol,
17,
229-236.
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M.R.Singleton,
M.S.Dillingham,
and
D.B.Wigley
(2007).
Structure and mechanism of helicases and nucleic acid translocases.
|
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Annu Rev Biochem,
76,
23-50.
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P.Guo,
and
T.J.Lee
(2007).
Viral nanomotors for packaging of dsDNA and dsRNA.
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Mol Microbiol,
64,
886-903.
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S.R.White,
and
B.Lauring
(2007).
AAA+ ATPases: achieving diversity of function with conserved machinery.
|
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Traffic,
8,
1657-1667.
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S.R.White,
K.J.Evans,
J.Lary,
J.L.Cole,
and
B.Lauring
(2007).
Recognition of C-terminal amino acids in tubulin by pore loops in Spastin is important for microtubule severing.
|
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J Cell Biol,
176,
995.
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S.Sun,
K.Kondabagil,
P.M.Gentz,
M.G.Rossmann,
and
V.B.Rao
(2007).
The structure of the ATPase that powers DNA packaging into bacteriophage T4 procapsids.
|
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Mol Cell,
25,
943-949.
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PDB codes:
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Y.Astier,
D.E.Kainov,
H.Bayley,
R.Tuma,
and
S.Howorka
(2007).
Stochastic detection of motor protein-RNA complexes by single-channel current recording.
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Chemphyschem,
8,
2189-2194.
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B.Bukau,
J.Weissman,
and
A.Horwich
(2006).
Molecular chaperones and protein quality control.
|
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Cell,
125,
443-451.
|
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D.Keramisanou,
N.Biris,
I.Gelis,
G.Sianidis,
S.Karamanou,
A.Economou,
and
C.G.Kalodimos
(2006).
Disorder-order folding transitions underlie catalysis in the helicase motor of SecA.
|
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Nat Struct Mol Biol,
13,
594-602.
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E.Skordalakes,
and
J.M.Berger
(2006).
Structural insights into RNA-dependent ring closure and ATPase activation by the Rho termination factor.
|
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Cell,
127,
553-564.
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PDB code:
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J.L.Adelman,
Y.J.Jeong,
J.C.Liao,
G.Patel,
D.E.Kim,
G.Oster,
and
S.S.Patel
(2006).
Mechanochemistry of transcription termination factor Rho.
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Mol Cell,
22,
611-621.
|
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J.L.Ross,
K.Wallace,
H.Shuman,
Y.E.Goldman,
and
E.L.Holzbaur
(2006).
Processive bidirectional motion of dynein-dynactin complexes in vitro.
|
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Nat Cell Biol,
8,
562-570.
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J.T.Huiskonen,
F.de Haas,
D.Bubeck,
D.H.Bamford,
S.D.Fuller,
and
S.J.Butcher
(2006).
Structure of the bacteriophage phi6 nucleocapsid suggests a mechanism for sequential RNA packaging.
|
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Structure,
14,
1039-1048.
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N.K.Maluf,
and
M.Feiss
(2006).
Virus DNA translocation: progress towards a first ascent of mount pretty difficult.
|
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Mol Microbiol,
61,
1-4.
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P.M.Matias,
S.Gorynia,
P.Donner,
and
M.A.Carrondo
(2006).
Crystal structure of the human AAA+ protein RuvBL1.
|
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J Biol Chem,
281,
38918-38929.
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PDB code:
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R.G.Baumann,
J.Mullaney,
and
L.W.Black
(2006).
Portal fusion protein constraints on function in DNA packaging of bacteriophage T4.
|
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Mol Microbiol,
61,
16-32.
|
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|
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R.G.Coumans,
J.A.Elemans,
R.J.Nolte,
and
A.E.Rowan
(2006).
Processive enzyme mimic: Kinetics and thermodynamics of the threading and sliding process.
|
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Proc Natl Acad Sci U S A,
103,
19647-19651.
|
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T.H.Massey,
C.P.Mercogliano,
J.Yates,
D.J.Sherratt,
and
J.Löwe
(2006).
Double-stranded DNA translocation: structure and mechanism of hexameric FtsK.
|
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Mol Cell,
23,
457-469.
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PDB codes:
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X.Jiang,
H.Jayaram,
M.Kumar,
S.J.Ludtke,
M.K.Estes,
and
B.V.Prasad
(2006).
Cryoelectron microscopy structures of rotavirus NSP2-NSP5 and NSP2-RNA complexes: implications for genome replication.
|
| |
J Virol,
80,
10829-10835.
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A.Scott,
H.Y.Chung,
M.Gonciarz-Swiatek,
G.C.Hill,
F.G.Whitby,
J.Gaspar,
J.M.Holton,
R.Viswanathan,
S.Ghaffarian,
C.P.Hill,
and
W.I.Sundquist
(2005).
Structural and mechanistic studies of VPS4 proteins.
|
| |
EMBO J,
24,
3658-3669.
|
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PDB code:
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C.Meier,
E.J.Mancini,
D.H.Bamford,
M.A.Walsh,
D.I.Stuart,
and
J.M.Grimes
(2005).
Overcoming the false-minima problem in direct methods: structure determination of the packaging enzyme P4 from bacteriophage phi13.
|
| |
Acta Crystallogr D Biol Crystallogr,
61,
1238-1244.
|
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|
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|
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J.Hinnerwisch,
W.A.Fenton,
K.J.Furtak,
G.W.Farr,
and
A.L.Horwich
(2005).
Loops in the central channel of ClpA chaperone mediate protein binding, unfolding, and translocation.
|
| |
Cell,
121,
1029-1041.
|
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|
|
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J.Lísal,
and
R.Tuma
(2005).
Cooperative mechanism of RNA packaging motor.
|
| |
J Biol Chem,
280,
23157-23164.
|
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J.Lísal,
T.T.Lam,
D.E.Kainov,
M.R.Emmett,
A.G.Marshall,
and
R.Tuma
(2005).
Functional visualization of viral molecular motor by hydrogen-deuterium exchange reveals transient states.
|
| |
Nat Struct Mol Biol,
12,
460-466.
|
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J.Qiao,
X.Qiao,
and
L.Mindich
(2005).
In vivo studies of genomic packaging in the dsRNA bacteriophage Phi8.
|
| |
BMC Microbiol,
5,
10.
|
|
|
|
|
|
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M.Cianci,
S.Antonyuk,
N.Bliss,
M.W.Bailey,
S.G.Buffey,
K.C.Cheung,
J.A.Clarke,
G.E.Derbyshire,
M.J.Ellis,
M.J.Enderby,
A.F.Grant,
M.P.Holbourn,
D.Laundy,
C.Nave,
R.Ryder,
P.Stephenson,
J.R.Helliwell,
and
S.S.Hasnain
(2005).
A high-throughput structural biology/proteomics beamline at the SRS on a new multipole wiggler.
|
| |
J Synchrotron Radiat,
12,
455-466.
|
|
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|
|
|
|
V.Guallar,
and
K.W.Borrelli
(2005).
A binding mechanism in protein-nucleotide interactions: implication for U1A RNA binding.
|
| |
Proc Natl Acad Sci U S A,
102,
3954-3959.
|
|
|
|
|
|
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X.Agirrezabala,
J.Martín-Benito,
J.R.Castón,
R.Miranda,
J.M.Valpuesta,
and
J.L.Carrascosa
(2005).
Maturation of phage T7 involves structural modification of both shell and inner core components.
|
| |
EMBO J,
24,
3820-3829.
|
|
|
|
|
|
|
Y.R.Chemla,
K.Aathavan,
J.Michaelis,
S.Grimes,
P.J.Jardine,
D.L.Anderson,
and
C.Bustamante
(2005).
Mechanism of force generation of a viral DNA packaging motor.
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Cell,
122,
683-692.
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|
|
|
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A.L.Horwich
(2004).
Chaperoned protein disaggregation--the ClpB ring uses its central channel.
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Cell,
119,
579-581.
|
|
|
|
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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
code is
shown on the right.
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Links
