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PDBsum entry 1nr0
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Structural protein
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PDB id
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1nr0
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Contents |
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* Residue conservation analysis
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DOI no:
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J Biol Chem
279:31697-31707
(2004)
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PubMed id:
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Identification of functional residues on Caenorhabditis elegans actin-interacting protein 1 (UNC-78) for disassembly of actin depolymerizing factor/cofilin-bound actin filaments.
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K.Mohri,
S.Vorobiev,
A.A.Fedorov,
S.C.Almo,
S.Ono.
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ABSTRACT
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Actin-interacting protein 1 (AIP1) is a WD40 repeat protein that enhances actin
filament disassembly in the presence of actin-depolymerizing factor
(ADF)/cofilin. AIP1 also caps the barbed end of ADF/cofilin-bound actin
filament. However, the mechanism by which AIP1 interacts with ADF/cofilin and
actin is not clearly understood. We determined the crystal structure of
Caenorhabditis elegans AIP1 (UNC-78), which revealed 14 WD40 modules arranged in
two seven-bladed beta-propeller domains. The structure allowed for the mapping
of conserved surface residues, and mutagenesis studies identified five residues
that affected the ADF/cofilin-dependent actin filament disassembly activity.
Mutations of these residues, which reside in blades 3 and 4 in the N-terminal
propeller domain, had significant effects on the disassembly activity but did
not alter the barbed end capping activity. These data support a model in which
this conserved surface of AIP1 plays a direct role in enhancing
fragmentation/depolymerization of ADF/cofilin-bound actin filaments but not in
barbed end capping.
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Selected figure(s)
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Figure 1.
FIG. 1. Structure of UNC-78. A, ribbon diagram of UNC-78
showing two covalently linked seven-bladed  -propellers. The
nomenclature used to describe the blades and strands is shown.
Middle, view down the axis of the N-terminal -propeller domain; left,
side view of UNC-78 showing the concave and convex surfaces.
This orientation is obtained by a 90° rotation about the
vertical axis relative to the middle image. The arrow identifies
the approximate location of the pseudo-2-fold axis (i.e.  167°)
that relates the two individual domains Right, view down the
axis of the C-terminal -propeller domain. This
orientation is obtained by successive rotations of 60 and
20° about the horizontal and vertical axes relative to the
middle image. B and C, the hydrogen bonds that are important for
the domain/domain interface in UNC-78. B, five selected main
chain-main chain hydrogen bonds are marked: Lys9 N-Thr50 O (a),
Ile^327 N-Gly599 O (b), Ala^326 O-Ala^344 N (c), Leu13 N-His323
O (d), and Arg15 N-Cys36 O (e). C, side chain-side chain
hydrogen bonds between conserved residue His323 of the first
domain and Ser341 and Asp343 of the second domain are shown. The
side chain of conserved residue Trp351 stabilizes this
interaction. D, superposition of the C. elegans (red) and S.
cerevisiae (blue) AIP1 (PDB code 1PI6 [PDB]
). The two molecules were superimposed on the basis of the
N-terminal -propeller domains,
which highlights the 9° greaterclosure
between domains in the yeast protein. E, stereo view of the
2F[o] - F[c] electron density map of the WD40 repeat "structural
tetrad" formed between Trp563 in strand C, Thr553 in strand B,
His535 in the DA loop between two successive repeats, and the
conservative Asp557 in the turn between strands B and C.
Electron density contours at 1.5  .
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Figure 3.
FIG. 3. Conserved surface residues of AIP1. Conserved
surface residues of AIP1 that were selected for mutagenesis are
shown in red. Green residues are conserved but corresponding to
the consensus sequence of WD40 repeats. Blue residues are
charged and highly conserved but buried inside the molecule. The
structures on the left are views from the top of propellers, and
those on the right are from the bottom of propeller 1. The
structures are shown in space-filling models (top) and ribbon
diagrams (bottom).
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The above figures are
reprinted
by permission from the ASBMB:
J Biol Chem
(2004,
279,
31697-31707)
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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C.Xu,
and
J.Min
(2011).
Structure and function of WD40 domain proteins.
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Protein Cell,
2,
202-214.
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PDB codes:
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C.H.Choi,
H.Patel,
and
D.L.Barber
(2010).
Expression of actin-interacting protein 1 suppresses impaired chemotaxis of Dictyostelium cells lacking the Na+-H+ exchanger NHE1.
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Mol Biol Cell,
21,
3162-3170.
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H.G.Kim,
J.W.Ahn,
I.Kurth,
R.Ullmann,
H.T.Kim,
A.Kulharya,
K.S.Ha,
Y.Itokawa,
I.Meliciani,
W.Wenzel,
D.Lee,
G.Rosenberger,
M.Ozata,
D.P.Bick,
R.J.Sherins,
T.Nagase,
M.Tekin,
S.H.Kim,
C.H.Kim,
H.H.Ropers,
J.F.Gusella,
V.Kalscheuer,
C.Y.Choi,
and
L.C.Layman
(2010).
WDR11, a WD protein that interacts with transcription factor EMX1, is mutated in idiopathic hypogonadotropic hypogonadism and Kallmann syndrome.
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Am J Hum Genet,
87,
465-479.
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S.Ono
(2010).
Dynamic regulation of sarcomeric actin filaments in striated muscle.
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Cytoskeleton (Hoboken),
67,
677-692.
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Z.L.Chi,
F.Yasumoto,
Y.Sergeev,
M.Minami,
M.Obazawa,
I.Kimura,
Y.Takada,
and
T.Iwata
(2010).
Mutant WDR36 directly affects axon growth of retinal ganglion cells leading to progressive retinal degeneration in mice.
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Hum Mol Genet,
19,
3806-3815.
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C.K.Lau,
J.L.Bachorik,
and
G.Dreyfuss
(2009).
Gemin5-snRNA interaction reveals an RNA binding function for WD repeat domains.
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Nat Struct Mol Biol,
16,
486-491.
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K.Ono,
and
S.Ono
(2009).
Actin-ADF/cofilin rod formation in Caenorhabditis elegans muscle requires a putative F-actin binding site of ADF/cofilin at the C-terminus.
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Cell Motil Cytoskeleton,
66,
398-408.
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S.S.Bradrick,
and
M.Gromeier
(2009).
Identification of gemin5 as a novel 7-methylguanosine cap-binding protein.
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PLoS One,
4,
e7030.
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T.K.Footz,
J.L.Johnson,
S.Dubois,
N.Boivin,
V.Raymond,
and
M.A.Walter
(2009).
Glaucoma-associated WDR36 variants encode functional defects in a yeast model system.
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Hum Mol Genet,
18,
1276-1287.
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S.L.Hooper,
K.H.Hobbs,
and
J.B.Thuma
(2008).
Invertebrate muscles: thin and thick filament structure; molecular basis of contraction and its regulation, catch and asynchronous muscle.
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Prog Neurobiol,
86,
72.
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D.A.Hattendorf,
A.Andreeva,
A.Gangar,
P.J.Brennwald,
and
W.I.Weis
(2007).
Structure of the yeast polarity protein Sro7 reveals a SNARE regulatory mechanism.
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Nature,
446,
567-571.
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PDB code:
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D.Fasshauer,
and
R.Jahn
(2007).
Budding insights on cell polarity.
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Nat Struct Mol Biol,
14,
360-362.
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J.Li,
W.M.Brieher,
M.L.Scimone,
S.J.Kang,
H.Zhu,
H.Yin,
U.H.von Andrian,
T.Mitchison,
and
J.Yuan
(2007).
Caspase-11 regulates cell migration by promoting Aip1-Cofilin-mediated actin depolymerization.
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Nat Cell Biol,
9,
276-286.
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M.G.Clark,
and
D.C.Amberg
(2007).
Biochemical and genetic analyses provide insight into the structural and mechanistic properties of actin filament disassembly by the Aip1p cofilin complex in Saccharomyces cerevisiae.
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Genetics,
176,
1527-1539.
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N.Ren,
J.Charlton,
and
P.N.Adler
(2007).
The flare gene, which encodes the AIP1 protein of Drosophila, functions to regulate F-actin disassembly in pupal epidermal cells.
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Genetics,
176,
2223-2234.
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P.Y.Cho,
T.I.Kim,
S.Li,
S.J.Hong,
M.H.Choi,
S.T.Hong,
and
Y.E.Chung
(2007).
Metacercarial proteins interacting with WD40-repeat protein of Clonorchis sinensis.
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Korean J Parasitol,
45,
229-232.
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W.Hirschner,
H.M.Pogoda,
C.Kramer,
U.Thiess,
B.Hamprecht,
K.H.Wiesmüller,
M.Lautner,
and
S.Verleysdonk
(2007).
Biosynthesis of Wdr16, a marker protein for kinocilia-bearing cells, starts at the time of kinocilia formation in rat, and wdr16 gene knockdown causes hydrocephalus in zebrafish.
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J Neurochem,
101,
274-288.
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J.B.Moseley,
and
B.L.Goode
(2006).
The yeast actin cytoskeleton: from cellular function to biochemical mechanism.
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Microbiol Mol Biol Rev,
70,
605-645.
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K.Mohri,
K.Ono,
R.Yu,
S.Yamashiro,
and
S.Ono
(2006).
Enhancement of actin-depolymerizing factor/cofilin-dependent actin disassembly by actin-interacting protein 1 is required for organized actin filament assembly in the Caenorhabditis elegans body wall muscle.
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Mol Biol Cell,
17,
2190-2199.
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K.Okada,
H.Ravi,
E.M.Smith,
and
B.L.Goode
(2006).
Aip1 and cofilin promote rapid turnover of yeast actin patches and cables: a coordinated mechanism for severing and capping filaments.
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Mol Biol Cell,
17,
2855-2868.
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K.Ono,
R.Yu,
K.Mohri,
and
S.Ono
(2006).
Caenorhabditis elegans kettin, a large immunoglobulin-like repeat protein, binds to filamentous actin and provides mechanical stability to the contractile apparatuses in body wall muscle.
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Mol Biol Cell,
17,
2722-2734.
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M.G.Clark,
J.Teply,
B.K.Haarer,
S.C.Viggiano,
D.Sept,
and
D.C.Amberg
(2006).
A genetic dissection of Aip1p's interactions leads to a model for Aip1p-cofilin cooperative activities.
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Mol Biol Cell,
17,
1971-1984.
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R.Yu,
and
S.Ono
(2006).
Dual roles of tropomyosin as an F-actin stabilizer and a regulator of muscle contraction in Caenorhabditis elegans body wall muscle.
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Cell Motil Cytoskeleton,
63,
659-672.
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I.I.Serysheva,
S.L.Hamilton,
W.Chiu,
and
S.J.Ludtke
(2005).
Structure of Ca2+ release channel at 14 A resolution.
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J Mol Biol,
345,
427-431.
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S.Nicholson-Dykstra,
H.N.Higgs,
and
E.S.Harris
(2005).
Actin dynamics: growth from dendritic branches.
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Curr Biol,
15,
R346-R357.
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S.Ono,
K.Mohri,
and
K.Ono
(2005).
Molecular and biochemical characterization of kettin in Caenorhabditis elegans.
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J Muscle Res Cell Motil,
26,
449-454.
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S.Yamashiro,
K.Mohri,
and
S.Ono
(2005).
The two Caenorhabditis elegans actin-depolymerizing factor/cofilin proteins differently enhance actin filament severing and depolymerization.
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Biochemistry,
44,
14238-14247.
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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
