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PDBsum entry 1v8k
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Structural protein
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PDB id
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1v8k
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Contents |
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* Residue conservation analysis
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DOI no:
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Cell
116:591-602
(2004)
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PubMed id:
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A common mechanism for microtubule destabilizers-M type kinesins stabilize curling of the protofilament using the class-specific neck and loops.
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T.Ogawa,
R.Nitta,
Y.Okada,
N.Hirokawa.
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ABSTRACT
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Unlike other kinesins, middle motor domain-type kinesins depolymerize the
microtubule from its ends. To elucidate its mechanism, we solved the X-ray
crystallographic structure of KIF2C, a murine member of this family. Three major
class-specific features were identified. The class-specific N-terminal neck
adopts a long and rigid helical structure extending out vertically into the
interprotofilament groove. This structure explains its dual roles in targeting
to the end of the microtubule and in destabilization of the lateral interaction
of the protofilament. The loop L2 forms a unique finger-like structure, long and
rigid enough to reach the next tubulin subunit to stabilize the peeling of the
protofilament. The open conformation of the switch I loop could be reversed by
the shift of the microtubule binding L8 loop, suggesting its role as the sensor
to trigger ATP hydrolysis. Mutational analysis supports these structural
implications.
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Selected figure(s)
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Figure 3.
Figure 3. The Open Conformation of the Nucleotide Binding
Pocket of KIF2C in the AMP-PNP Form(A) Comparison of the
structures of KIF2C in the ADP form (red) and in the AMP-PNP
form (blue). The interaction between the neck (green) and the
KVD-finger (pink) is also shown. Note the disulfide bond
(yellow) between the neck and the KVD-finger.(B) Comparison of
the configuration of the switch I and switch II regions of KIF1A
(purple) and KIF2C (blue). Although both structures are of the
AMP-PXP (X = C or N) form, the switch I loop is distant from the
γ-phosphate due to the rotation of α3. To move the switch I
loop closer to the γ-phosphate, α3 must be rotated as shown by
the yellow arrows. This rotation may be triggered by the
preceding L8 loop. This open conformation of the switch I loop
is similar to the structure of the salt bridge mutant (R598A) of
Kar3. The structures of the wild-type (purple) and R598A mutant
(blue) of Kar3 are shown for comparison (C). The mutation
resulted in the rotation of α3 and the switch I loop moved away
from the nucleotide binding pocket (yellow arrow).
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Figure 6.
Figure 6. Structural Model of the Mechanism of MT
Depolymerization by KIF-M(A) ADP bound KIF-M (light blue) binds
to the side wall of the MT.(B) The neck helix (green) interferes
with the M loop in the interprotofilament groove, and KIF-M
cannot bind tightly to the side wall of the MT. The nucleotide
binding pocket is trapped in the open state. Thus, ATP bound
KIF-M diffuses along the MT protofilament.(C) When KIF-M reaches
the end of the MT, the curved conformation of the protofilament
allows full contact with KIF-M. The L8 loop (blue) closes the
nucleotide binding pocket and ATP hydrolysis takes place. The
neck helix destabilizes the lateral interaction of the
protofilament, and the KVD-finger (red) stabilizes the curved
conformation of the interdimer groove.(D) Tubulin dimer or
oligomer is spontaneously released from the curved end of the
protofilament.Hydrolysis of ATP on the tubulin dimer (or
oligomer) releases KIF-M and the next cycle starts.
Alternatively, only the tubulin dimer is released and KIF-M
remains on the protofilament, sliding back to release the next
tubulin dimer processively (C′ and D′). The same mechanism
can also explain depolymerization from the minus end of MT (E).
Dimerization of KIF-M is not required for this mechanism, but
will further increase the depolymerization activity (F).
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The above figures are
reprinted
by permission from Cell Press:
Cell
(2004,
116,
591-602)
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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N.Naber,
A.Larson,
S.Rice,
R.Cooke,
and
E.Pate
(2011).
Multiple conformations of the nucleotide site of Kinesin family motors in the triphosphate state.
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J Mol Biol,
408,
628-642.
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W.Marande,
and
L.Kohl
(2011).
Flagellar kinesins in protists.
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Future Microbiol,
6,
231-246.
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Y.Oguchi,
S.Uchimura,
T.Ohki,
S.V.Mikhailenko,
and
S.Ishiwata
(2011).
The bidirectional depolymerizer MCAK generates force by disassembling both microtubule ends.
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Nat Cell Biol,
13,
846-852.
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B.Wickstead,
J.T.Carrington,
E.Gluenz,
and
K.Gull
(2010).
The expanded Kinesin-13 repertoire of trypanosomes contains only one mitotic Kinesin indicating multiple extra-nuclear roles.
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PLoS One,
5,
e15020.
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C.L.Parke,
E.J.Wojcik,
S.Kim,
and
D.K.Worthylake
(2010).
ATP hydrolysis in Eg5 kinesin involves a catalytic two-water mechanism.
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J Biol Chem,
285,
5859-5867.
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PDB code:
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C.Peters,
K.Brejc,
L.Belmont,
A.J.Bodey,
Y.Lee,
M.Yu,
J.Guo,
R.Sakowicz,
J.Hartman,
and
C.A.Moores
(2010).
Insight into the molecular mechanism of the multitasking kinesin-8 motor.
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EMBO J,
29,
3437-3447.
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PDB code:
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G.V.Schimizzi,
J.D.Currie,
and
S.L.Rogers
(2010).
Expression levels of a kinesin-13 microtubule depolymerase modulates the effectiveness of anti-microtubule agents.
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PLoS One,
5,
e11381.
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J.C.Gatlin,
and
K.Bloom
(2010).
Microtubule motors in eukaryotic spindle assembly and maintenance.
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Semin Cell Dev Biol,
21,
248-254.
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J.R.Cooper,
M.Wagenbach,
C.L.Asbury,
and
L.Wordeman
(2010).
Catalysis of the microtubule on-rate is the major parameter regulating the depolymerase activity of MCAK.
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Nat Struct Mol Biol,
17,
77-82.
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L.Wordeman
(2010).
How kinesin motor proteins drive mitotic spindle function: Lessons from molecular assays.
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Semin Cell Dev Biol,
21,
260-268.
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M.Nishiyama,
Y.Shimoda,
M.Hasumi,
Y.Kimura,
and
M.Terazima
(2010).
Microtubule depolymerization at high pressure.
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Ann N Y Acad Sci,
1189,
86-90.
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M.Sanhaji,
C.T.Friel,
N.N.Kreis,
A.Krämer,
C.Martin,
J.Howard,
K.Strebhardt,
and
J.Yuan
(2010).
Functional and spatial regulation of mitotic centromere-associated kinesin by cyclin-dependent kinase 1.
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Mol Cell Biol,
30,
2594-2607.
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P.Xie
(2010).
Mechanism of processive movement of monomeric and dimeric kinesin molecules.
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Int J Biol Sci,
6,
665-674.
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R.Hou,
and
Z.Wang
(2010).
A coordinated molecular 'fishing' mechanism in heterodimeric kinesin.
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Phys Biol,
7,
036003.
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S.C.Ems-McClung,
and
C.E.Walczak
(2010).
Kinesin-13s in mitosis: Key players in the spatial and temporal organization of spindle microtubules.
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Semin Cell Dev Biol,
21,
276-282.
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A.M.Mulder,
A.Glavis-Bloom,
C.A.Moores,
M.Wagenbach,
B.Carragher,
L.Wordeman,
and
R.A.Milligan
(2009).
A new model for binding of kinesin 13 to curved microtubule protofilaments.
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J Cell Biol,
185,
51-57.
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A.Marx,
A.Hoenger,
and
E.Mandelkow
(2009).
Structures of kinesin motor proteins.
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Cell Motil Cytoskeleton,
66,
958-966.
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A.Mielgo,
V.A.Torres,
K.Clair,
S.Barbero,
and
D.G.Stupack
(2009).
Paclitaxel promotes a caspase 8-mediated apoptosis through death effector domain association with microtubules.
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Oncogene,
28,
3551-3562.
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A.Mielgo,
V.A.Torres,
M.C.Schmid,
R.Graf,
S.G.Zeitlin,
P.Lee,
D.J.Shields,
S.Barbero,
C.Jamora,
and
D.G.Stupack
(2009).
The death effector domains of caspase-8 induce terminal differentiation.
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PLoS One,
4,
e7879.
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J.C.Cochran,
C.V.Sindelar,
N.K.Mulko,
K.A.Collins,
S.E.Kong,
R.S.Hawley,
and
F.J.Kull
(2009).
ATPase cycle of the nonmotile kinesin NOD allows microtubule end tracking and drives chromosome movement.
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Cell,
136,
110-122.
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PDB codes:
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J.R.Cooper,
and
L.Wordeman
(2009).
The diffusive interaction of microtubule binding proteins.
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Curr Opin Cell Biol,
21,
68-73.
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M.Nishiyama,
Y.Kimura,
Y.Nishiyama,
and
M.Terazima
(2009).
Pressure-induced changes in the structure and function of the kinesin-microtubule complex.
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Biophys J,
96,
1142-1150.
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N.Hirokawa,
R.Nitta,
and
Y.Okada
(2009).
The mechanisms of kinesin motor motility: lessons from the monomeric motor KIF1A.
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Nat Rev Mol Cell Biol,
10,
877-884.
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V.Mennella,
D.Y.Tan,
D.W.Buster,
A.B.Asenjo,
U.Rath,
A.Ma,
H.J.Sosa,
and
D.J.Sharp
(2009).
Motor domain phosphorylation and regulation of the Drosophila kinesin 13, KLP10A.
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J Cell Biol,
186,
481-490.
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C.A.Moores,
and
R.A.Milligan
(2008).
Visualisation of a kinesin-13 motor on microtubule end mimics.
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J Mol Biol,
377,
647-654.
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D.Tan,
W.J.Rice,
and
H.Sosa
(2008).
Structure of the kinesin13-microtubule ring complex.
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Structure,
16,
1732-1739.
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PDB code:
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M.Kikkawa
(2008).
The role of microtubules in processive kinesin movement.
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Trends Cell Biol,
18,
128-135.
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M.Wagenbach,
S.Domnitz,
L.Wordeman,
and
J.Cooper
(2008).
A kinesin-13 mutant catalytically depolymerizes microtubules in ADP.
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J Cell Biol,
183,
617-623.
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P.G.Dastidar,
and
A.Lohia
(2008).
Bipolar spindle frequency and genome content are inversely regulated by the activity of two N-type kinesins in Entamoeba histolytica.
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Cell Microbiol,
10,
1559-1571.
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R.Nitta,
Y.Okada,
and
N.Hirokawa
(2008).
Structural model for strain-dependent microtubule activation of Mg-ADP release from kinesin.
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Nat Struct Mol Biol,
15,
1067-1075.
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PDB codes:
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C.Blaineau,
M.Tessier,
P.Dubessay,
L.Tasse,
L.Crobu,
M.Pagès,
and
P.Bastien
(2007).
A novel microtubule-depolymerizing kinesin involved in length control of a eukaryotic flagellum.
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Curr Biol,
17,
778-782.
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C.V.Sindelar,
and
K.H.Downing
(2007).
The beginning of kinesin's force-generating cycle visualized at 9-A resolution.
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J Cell Biol,
177,
377-385.
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PDB code:
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L.A.Amos,
and
K.Hirose
(2007).
A cool look at the structural changes in kinesin motor domains.
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J Cell Sci,
120,
3919-3927.
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S.C.Ems-McClung,
K.M.Hertzer,
X.Zhang,
M.W.Miller,
and
C.E.Walczak
(2007).
The interplay of the N- and C-terminal domains of MCAK control microtubule depolymerization activity and spindle assembly.
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Mol Biol Cell,
18,
282-294.
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T.N.Davis,
and
L.Wordeman
(2007).
Rings, bracelets, sleeves, and chevrons: new structures of kinetochore proteins.
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Trends Cell Biol,
17,
377-382.
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G.Niewiadomska,
M.Baksalerska-Pazera,
and
G.Riedel
(2006).
Cytoskeletal transport in the aging brain: focus on the cholinergic system.
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Rev Neurosci,
17,
581-618.
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K.M.Hertzer,
S.C.Ems-McClung,
S.L.Kline-Smith,
T.G.Lipkin,
S.P.Gilbert,
and
C.E.Walczak
(2006).
Full-length dimeric MCAK is a more efficient microtubule depolymerase than minimal domain monomeric MCAK.
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Mol Biol Cell,
17,
700-710.
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M.Kikkawa,
and
N.Hirokawa
(2006).
High-resolution cryo-EM maps show the nucleotide binding pocket of KIF1A in open and closed conformations.
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EMBO J,
25,
4187-4194.
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PDB codes:
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M.L.Gupta,
P.Carvalho,
D.M.Roof,
and
D.Pellman
(2006).
Plus end-specific depolymerase activity of Kip3, a kinesin-8 protein, explains its role in positioning the yeast mitotic spindle.
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Nat Cell Biol,
8,
913-923.
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P.Dubessay,
C.Blaineau,
P.Bastien,
L.Tasse,
J.Van Dijk,
L.Crobu,
and
M.Pagès
(2006).
Cell cycle-dependent expression regulation by the proteasome pathway and characterization of the nuclear targeting signal of a Leishmania major Kin-13 kinesin.
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Mol Microbiol,
59,
1162-1174.
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S.Uchimura,
Y.Oguchi,
M.Katsuki,
T.Usui,
H.Osada,
J.Nikawa,
S.Ishiwata,
and
E.Muto
(2006).
Identification of a strong binding site for kinesin on the microtubule using mutant analysis of tubulin.
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EMBO J,
25,
5932-5941.
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A.T.Moore,
K.E.Rankin,
G.von Dassow,
L.Peris,
M.Wagenbach,
Y.Ovechkina,
A.Andrieux,
D.Job,
and
L.Wordeman
(2005).
MCAK associates with the tips of polymerizing microtubules.
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J Cell Biol,
169,
391-397.
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B.Gigant,
C.Wang,
R.B.Ravelli,
F.Roussi,
M.O.Steinmetz,
P.A.Curmi,
A.Sobel,
and
M.Knossow
(2005).
Structural basis for the regulation of tubulin by vinblastine.
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Nature,
435,
519-522.
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PDB code:
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I.Schuchardt,
D.Assmann,
E.Thines,
C.Schuberth,
and
G.Steinberg
(2005).
Myosin-V, Kinesin-1, and Kinesin-3 cooperate in hyphal growth of the fungus Ustilago maydis.
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Mol Biol Cell,
16,
5191-5201.
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L.R.Sproul,
D.J.Anderson,
A.T.Mackey,
W.S.Saunders,
and
S.P.Gilbert
(2005).
Cik1 targets the minus-end kinesin depolymerase kar3 to microtubule plus ends.
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Curr Biol,
15,
1420-1427.
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M.I.Molodtsov,
E.A.Ermakova,
E.E.Shnol,
E.L.Grishchuk,
J.R.McIntosh,
and
F.I.Ataullakhanov
(2005).
A molecular-mechanical model of the microtubule.
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Biophys J,
88,
3167-3179.
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N.Hirokawa,
and
R.Takemura
(2005).
Molecular motors and mechanisms of directional transport in neurons.
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Nat Rev Neurosci,
6,
201-214.
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A.Moore,
and
L.Wordeman
(2004).
The mechanism, function and regulation of depolymerizing kinesins during mitosis.
|
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Trends Cell Biol,
14,
537-546.
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K.Shipley,
M.Hekmat-Nejad,
J.Turner,
C.Moores,
R.Anderson,
R.Milligan,
R.Sakowicz,
and
R.Fletterick
(2004).
Structure of a kinesin microtubule depolymerization machine.
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EMBO J,
23,
1422-1432.
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PDB code:
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N.Hirokawa,
and
R.Takemura
(2004).
Molecular motors in neuronal development, intracellular transport and diseases.
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Curr Opin Neurobiol,
14,
564-573.
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N.J.Ganem,
and
D.A.Compton
(2004).
The KinI kinesin Kif2a is required for bipolar spindle assembly through a functional relationship with MCAK.
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J Cell Biol,
166,
473-478.
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S.C.Ems-McClung,
and
C.E.Walczak
(2004).
Catastrophic kinesins: piecing together their mechanism by 3D reconstruction.
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Cell,
116,
485-486.
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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
