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Contents |
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* Residue conservation analysis
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Enzyme class 2:
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Chain A:
E.C.2.7.11.22
- cyclin-dependent kinase.
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Reaction:
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1.
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L-seryl-[protein] + ATP = O-phospho-L-seryl-[protein] + ADP + H+
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2.
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L-threonyl-[protein] + ATP = O-phospho-L-threonyl-[protein] + ADP + H+
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L-seryl-[protein]
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+
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ATP
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=
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O-phospho-L-seryl-[protein]
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+
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ADP
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+
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H(+)
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L-threonyl-[protein]
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+
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ATP
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=
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O-phospho-L-threonyl-[protein]
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+
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ADP
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+
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H(+)
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Enzyme class 3:
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Chain B:
E.C.?
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Note, where more than one E.C. class is given (as above), each may
correspond to a different protein domain or, in the case of polyprotein
precursors, to a different mature protein.
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Molecule diagrams generated from .mol files obtained from the
KEGG ftp site
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DOI no:
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Cell
84:863-874
(1996)
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PubMed id:
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Crystal structure and mutational analysis of the human CDK2 kinase complex with cell cycle-regulatory protein CksHs1.
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Y.Bourne,
M.H.Watson,
M.J.Hickey,
W.Holmes,
W.Rocque,
S.I.Reed,
J.A.Tainer.
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ABSTRACT
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The 2.6 Angstrom crystal structure for human cyclin-dependent kinase 2(CDK2) in
complex with CksHs1, a human homolog of essential yeast cell cycle-regulatory
proteins suc1 and Cks1, reveals that CksHs1 binds via all four beta strands to
the kinase C-terminal lobe. This interface is biologically critical, based upon
mutational analysis, but far from the CDK2 N-terminal lobe, cyclin, and
regulatory phosphorylation sites. CDK2 binds the Cks single domain conformation
and interacts with conserved hydrophobic residues plus His-60 and Glu-63 in
their closed beta-hinge motif conformation. The beta hinge opening to form the
Cks beta-interchanged dimer sterically precludes CDK2 binding, providing a
possible mechanism regulating CDK2-Cks interactions. One face of the complex
exposes the sequence-conserved phosphate-binding region on Cks and the
ATP-binding site on CDK2, suggesting that CKs may target CDK2 to other
phosphoproteins during the cell cycle.
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Selected figure(s)
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Figure 1.
Figure 1. Quality of the Structure and Overall View of the
CDK2–CksHs1 Complex(A) Stereo view of the 2.6 Å
resolution omit Fo–Fc electron density map, contoured at 2σ,
showing the predominant cluster of hydrophobic residues forming
the binding interface. The coordinates of this region (5% of the
total number of atoms) were omitted and the protein coordinates
were refined by simulated annealing before the phase
calculation. Residues are labeled in white for CDK2 and in
yellow for CksHs1.(B) Ribbon diagram of CksHs1 (yellow) bound to
CDK2, with the N-lobe in purple and the C-lobe in blue and
green. The ATP molecule is displayed at the interface of the two
CDK2 lobes (white bonds with red oxygen and blue nitrogen atoms
as spheres) and is taken from the free CDK2 coordinates ([11]).
The functional structural elements are color coded for CDK2: the
β1–β2 loop, red; the disordered loop to the PSTAIRE sequence
in helix α1, asterisks; the T loop, white. Side chains forming
the phosphorylation sites in the β1–β2 loop (Thr-14 and
Tyr-15) and in the T loop (Thr-160) (orange bonds with red
oxygen atoms as balls), as well as the CksHs1 side chains
forming the conserved phosphate anion–binding site (β1
Lys-11, β2 Arg-20, β3 Trp-54, and β4 Arg-71) (white bonds
with blue nitrogen atoms as balls), are displayed. The CDK2
secondary elements involved in the binding interface are
highlighted (green), and CksHs1 loops β1–β2 and β3–β4
are labeled L1 and L3, respectively.(C) CksHs1 molecular
surface, colored with the residues buried to a 1.6 Å probe
radius in pale yellow, the nonburied residues in white, and the
phosphate anion–binding site in blue. A ribbon diagram of the
CDK2 molecule is shown with the color code and orientation as in
(B). A CksHs1 Cα trace (orange) is shown through the surface
and reveals that the buried residues cluster in the interior
concave face of the CksHs1 β sheet and in the β1–β2 and
β3–β4 loops, which envelop the CDK2 helix α5 and loop L14
(green).(D) CDK2 molecular surface, with buried residues in
helix α5 (green) and loop L14 (cyan); nonburied residues are
shown in white. CksHs1 residues involved in the binding
interface are shown (orange bonds with red oxygen, blue
nitrogen, and yellow sulfur atoms as balls) with a Cα trace
(yellow). CksHs1 residues in all four β strands participate in
the binding interface.
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Figure 5.
Figure 5. The CDK2–Cyclin A–CksHs1 Ternary Complex(A)
Ribbon diagram of a CDK2–cyclin A–CksHs1 complex model based
on the coordinates of our CDK2–CksHs1 complex and those of a
CDK2–cyclin A complex ([30]) in which the two CDK2 molecules
were superimposed based on the Cα atoms of the C-lobe. Besides
two distinct binding sites for cyclin A and CksHs1 at the
molecular surface of CDK2, this model reveals a large
bowl-shaped groove centered around the phosphorylation site at
Thr-160 (middle) in the activated conformation of the CDK2 T
loop and bordered by cyclin A and CksHs1 molecules. The presence
of positively charged residues (Lys-24, Lys-30, and Lys-34 in
CksHs1 and Lys-226 and Lys-417 in cyclin A) located on each side
of the groove is displayed (purple bonds and blue for nitrogen
atoms as balls). The molecules and the functionally important
elements in CDK2 are color coded as in Figure 1B, with cyclin A
in green. ATP is taken from the CDK2–cyclin A complex
coordinates previously described ( [30]).(B) Molecular surface
of the CDK2–cyclin A–CksHs1 complex oriented  vert,
similar 90° away from that in (A), with the same color code.
The CksHs1 phosphate anion–binding site (blue) is exposed into
the solvent and located on the same side of the CDK2 catalytic
site with the ATP molecule bound between the two lobes, thus
forming a continuous surface for recognition of a Cdk substrate
or other phosphoproteins. The two CksHs1 α helices (orange) are
also solvent accessible. The T loop (white), containing the
phosphorylation site at position Thr-160 (middle), protrudes at
the interface of CksHs1 and cyclin A. Figure 1 and Figure 2 and
2B, 3C, and 4 were generated with the Application Visualization
System (AVS) (Advanced Visual Systems, Waltham, Massachusetts),
and Figure 1A and Figure 2C were generated with TURBO-FRODO (
[52]). The solvent-accessible surfaces were calculated with MS (
[9]), and the ribbon diagrams were generated using RIBBONS (
[8]) implemented in AVS.
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The above figures are
reprinted
by permission from Cell Press:
Cell
(1996,
84,
863-874)
copyright 1996.
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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.Krishnan,
S.A.Nair,
and
M.R.Pillai
(2010).
Loss of cks1 homeostasis deregulates cell division cycle.
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J Cell Mol Med,
14,
154-164.
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B.Di Fiore,
and
J.Pines
(2010).
How cyclin A destruction escapes the spindle assembly checkpoint.
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J Cell Biol,
190,
501-509.
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D.G.Srinivasan,
B.Fenton,
S.Jaubert-Possamai,
and
M.Jaouannet
(2010).
Analysis of meiosis and cell cycle genes of the facultatively asexual pea aphid, Acyrthosiphon pisum (Hemiptera: Aphididae).
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Insect Mol Biol,
19,
229-239.
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R.Holic,
A.Kukalev,
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E.J.Andress,
I.Lau,
C.W.Yu,
M.J.Edelmann,
B.M.Kessler,
and
V.P.Yu
(2010).
Cks1 activates transcription by binding to the ubiquitylated proteasome.
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Mol Cell Biol,
30,
3894-3901.
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S.S.Taylor,
and
A.P.Kornev
(2010).
Yet another "active" pseudokinase, Erb3.
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Proc Natl Acad Sci U S A,
107,
8047-8048.
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S.V.Del Rincón,
J.Rogers,
M.Widschwendter,
D.Sun,
H.B.Sieburg,
and
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Development and validation of a method for profiling post-translational modification activities using protein microarrays.
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PLoS One,
5,
e11332.
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B.T.Tobe,
A.A.Kitazono,
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and
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(2009).
Morphogenesis signaling components influence cell cycle regulation by cyclin dependent kinase.
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Cell Div,
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J.J.Perry,
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A.J.Olson,
and
J.A.Tainer
(2009).
p38alpha MAP kinase C-terminal domain binding pocket characterized by crystallographic and computational analyses.
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J Mol Biol,
391,
1.
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PDB code:
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H.Daub,
J.V.Olsen,
M.Bairlein,
F.Gnad,
F.S.Oppermann,
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Z.Greff,
G.Kéri,
O.Stemmann,
and
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Kinase-selective enrichment enables quantitative phosphoproteomics of the kinome across the cell cycle.
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Mol Cell,
31,
438-448.
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H.S.Martinsson-Ahlzén,
V.Liberal,
B.Grünenfelder,
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and
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(2008).
Cyclin-dependent kinase-associated proteins Cks1 and Cks2 are essential during early embryogenesis and for cell cycle progression in somatic cells.
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Mol Cell Biol,
28,
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J.Nilmeier,
and
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Multiscale Monte Carlo Sampling of Protein Sidechains: Application to Binding Pocket Flexibility.
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4,
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R.Wolthuis,
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J.Ogink,
R.Medema,
and
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(2008).
Cdc20 and Cks direct the spindle checkpoint-independent destruction of cyclin A.
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Mol Cell,
30,
290-302.
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G.Lippens,
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and
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Molecular mechanisms of the phospho-dependent prolyl cis/trans isomerase Pin1.
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FEBS J,
274,
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and
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PIER: protein interface recognition for structural proteomics.
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Proteins,
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400-417.
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J.A.Ubersax,
and
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8,
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J.Gu,
and
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Identifying allosteric fluctuation transitions between different protein conformational states as applied to Cyclin Dependent Kinase 2.
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BMC Bioinformatics,
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S.Xu,
M.Abbasian,
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B.E.Cathers,
W.Xie,
F.Mercurio,
M.Pagano,
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and
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(2007).
Substrate recognition and ubiquitination of SCFSkp2/Cks1 ubiquitin-protein isopeptide ligase.
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J Biol Chem,
282,
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T.Cardozo,
and
M.Pagano
(2007).
Wrenches in the works: drug discovery targeting the SCF ubiquitin ligase and APC/C complexes.
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BMC Biochem,
8,
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M.Shirayama,
M.C.Soto,
T.Ishidate,
S.Kim,
K.Nakamura,
Y.Bei,
S.van den Heuvel,
and
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(2006).
The Conserved Kinases CDK-1, GSK-3, KIN-19, and MBK-2 Promote OMA-1 Destruction to Regulate the Oocyte-to-Embryo Transition in C. elegans.
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Curr Biol,
16,
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M.Pagano,
and
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Skp2 contains a novel cyclin A binding domain that directly protects cyclin A from inhibition by p27Kip1.
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J Biol Chem,
281,
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Structural basis of the Cks1-dependent recognition of p27(Kip1) by the SCF(Skp2) ubiquitin ligase.
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Mol Cell,
20,
9.
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PDB codes:
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M.A.Seeliger,
M.Spichty,
S.E.Kelly,
M.Bycroft,
S.M.Freund,
M.Karplus,
and
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Role of conformational heterogeneity in domain swapping and adapter function of the Cks proteins.
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J Biol Chem,
280,
30448-30459.
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N.J.Pearson,
C.F.Cullen,
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and
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(2005).
A pre-anaphase role for a Cks/Suc1 in acentrosomal spindle formation of Drosophila female meiosis.
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EMBO Rep,
6,
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The structure of cyclin E1/CDK2: implications for CDK2 activation and CDK2-independent roles.
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EMBO J,
24,
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PDB code:
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V.P.Yu,
C.Baskerville,
B.Grünenfelder,
and
S.I.Reed
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A kinase-independent function of Cks1 and Cdk1 in regulation of transcription.
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Mol Cell,
17,
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N.Kannan,
and
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(2004).
Evolutionary constraints associated with functional specificity of the CMGC protein kinases MAPK, CDK, GSK, SRPK, DYRK, and CK2alpha.
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Protein Sci,
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T.Soyano,
R.Nishihama,
and
Y.Machida
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Mitotic cyclins stimulate the activity of c-Myb-like factors for transactivation of G2/M phase-specific genes in tobacco.
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J Biol Chem,
279,
32979-32988.
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S.Kitajima,
Y.Kudo,
I.Ogawa,
T.Bashir,
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M.Miyauchi,
M.Pagano,
and
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(2004).
Role of Cks1 overexpression in oral squamous cell carcinomas: cooperation with Skp2 in promoting p27 degradation.
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Am J Pathol,
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T.Cardozo,
and
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(2004).
The SCF ubiquitin ligase: insights into a molecular machine.
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and
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(2003).
PEA-15 binding to ERK1/2 MAPKs is required for its modulation of integrin activation.
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J Biol Chem,
278,
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M.A.Seeliger,
S.E.Breward,
A.Friedler,
O.Schon,
and
L.S.Itzhaki
(2003).
Cooperative organization in a macromolecular complex.
|
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Nat Struct Biol,
10,
718-724.
|
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M.C.Morris,
P.Kaiser,
S.Rudyak,
C.Baskerville,
M.H.Watson,
and
S.I.Reed
(2003).
Cks1-dependent proteasome recruitment and activation of CDC20 transcription in budding yeast.
|
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Nature,
423,
1009-1013.
|
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P.Aloy,
and
R.B.Russell
(2003).
Understanding and Predicting Protein Assemblies With 3D Structures.
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Comp Funct Genomics,
4,
410-415.
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R.Dajani,
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V.Thompson,
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and
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(2003).
Structural basis for recruitment of glycogen synthase kinase 3beta to the axin-APC scaffold complex.
|
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EMBO J,
22,
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PDB code:
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T.Hattori,
K.Kitagawa,
C.Uchida,
T.Oda,
and
M.Kitagawa
(2003).
Cks1 is degraded via the ubiquitin-proteasome pathway in a cell cycle-dependent manner.
|
| |
Genes Cells,
8,
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|
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W.Dewitte,
and
J.A.Murray
(2003).
The plant cell cycle.
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| |
Annu Rev Plant Biol,
54,
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L.Chen,
and
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(2003).
A negatively charged amino acid in Skp2 is required for Skp2-Cks1 interaction and ubiquitination of p27Kip1.
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J Biol Chem,
278,
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A.A.Kitazono,
and
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An essential function of yeast cyclin-dependent kinase Cdc28 maintains chromosome stability.
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J Biol Chem,
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Three different binding sites of Cks1 are required for p27-ubiquitin ligation.
|
| |
J Biol Chem,
277,
42233-42240.
|
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D.Tedesco,
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and
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The pRb-related protein p130 is regulated by phosphorylation-dependent proteolysis via the protein-ubiquitin ligase SCF(Skp2).
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| |
Genes Dev,
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E.A.Oakenfull,
C.Riou-Khamlichi,
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| |
Philos Trans R Soc Lond B Biol Sci,
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|
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M.C.Morris,
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P.Aloy,
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The third dimension for protein interactions and complexes.
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Trends Biochem Sci,
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|
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C.Ellenrieder,
B.Bartosch,
G.Y.Lee,
M.Murphy,
C.Sweeney,
M.Hergersberg,
M.Carrington,
R.Jaussi,
and
T.Hunt
(2001).
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|
| |
DNA Cell Biol,
20,
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|
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C.Spruck,
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A.P.Smith,
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T.W.Krek,
and
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Where a reference describes a PDB structure, the PDB
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