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PDBsum entry 2a23
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Recombination
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PDB id
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2a23
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DOI no:
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J Biol Chem
280:28701-28710
(2005)
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PubMed id:
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A PHD finger motif in the C terminus of RAG2 modulates recombination activity.
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S.K.Elkin,
D.Ivanov,
M.Ewalt,
C.G.Ferguson,
S.G.Hyberts,
Z.Y.Sun,
G.D.Prestwich,
J.Yuan,
G.Wagner,
M.A.Oettinger,
O.P.Gozani.
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ABSTRACT
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The RAG1 and RAG2 proteins catalyze V(D)J recombination and are essential for
generation of the diverse repertoire of antigen receptor genes and effective
immune responses. RAG2 is composed of a "core" domain that is required
for the recombination reaction and a C-terminal nonessential or
"non-core" region. Recent evidence has emerged arguing that the
non-core region plays a critical regulatory role in the recombination reaction,
and mutations in this region have been identified in patients with
immunodeficiencies. Here we present the first structural data for the RAG2
protein, using NMR spectroscopy to demonstrate that the C terminus of RAG2
contains a noncanonical PHD finger. All of the non-core mutations of RAG2 that
are implicated in the development of immunodeficiencies are located within the
PHD finger, at either zinc-coordinating residues or residues adjacent to an
alpha-helix on the surface of the domain that participates in binding to the
signaling molecules, phosphoinositides. Functional analysis of disease and
phosphoinositide-binding mutations reveals novel intramolecular interactions
within the non-core region and suggests that the PHD finger adopts two distinct
states. We propose a model in which the equilibrium between these states
modulates recombination activity. Together, these data identify the PHD finger
as a novel and functionally important domain of RAG2.
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Selected figure(s)
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Figure 2.
FIG. 2. The RAG2 C terminus contains a noncanonical PHD
finger. A, alignment of the RAG2 zinc finger to representative
zinc fingers from similar structural classes. The RAG2 sequence
(aa 414-487) was aligned to the indicated PHD, RING, and FYVE
finger sequences. Red circles represent zinc-binding residues
Cys-419, His-452, and His-481 of RAG2 that deviate from the PHD
finger consensus. Zn1, first zinc; Zn2, second zinc; L1 and L2,
extended segments of sequence between pairs of zinc-coordinating
residues. B, the RAG2 zinc finger is structurally most similar
to the PHD finger. Ribbon schematics compare the C-terminal zinc
finger of RAG2 to the indicated PHD, RING, and FIVE fingers. The
ligands of the two zinc ions appear as interleaved pairs in the
primary sequence of these proteins as shown in A. Two extended
polypeptide segments (L1 and L2, see A) separate equivalent
pairs of zinc-coordinating residues. The L1 segment contains the
first strand of the conserved  -sheet, whereas the
conformation of L2 varies significantly between different
proteins. The four domains are oriented in the same way using
conserved -sheet and zinc ions as
structural reference. The L2  -helix of RAG2 is
denoted in blue. Yellow, zinc-coordinating cysteine residues;
blue, zinc-coordinating histidine residues; red spheres, zinc
atoms.
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Figure 4.
FIG. 4. Model of RAG2-PtdInsP interactions. A, structural
overlay of the RAG2 PHD finger (green) on the EEA1 FYVE
finger-IP(1,3)[2] complex (FYVE domain, magenta; inositol
1,3-P[2], yellow). (Protein Data Bank code 1HYI [PDB]
(46).) The conserved -sheet and zinc ions
were used to overlay the two structures. Arginine side chains
important for FYVE-PtdInsP binding are shown in magenta. Basic
residues of RAG2 in the L2 segment (Arg-464 and His-468) are
shown in blue. B, ribbon schematic of the RAG2 PHD finger
structure with the indicated basic residues (blue) and
disease-linked residues (red). C, schematic comparison of RAG2
and ING2 C termini. PHD fingers are shown in green. The blue
boxes denote regions of positively charged residues important
for PtdInsP binding by ING2. The analogous regions of RAG2 (L2
and CT) are also highlighted in blue, with the one inside the
PHD finger (L2) corresponding to the blue -helix region in B.
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The above figures are
reprinted
by permission from the ASBMB:
J Biol Chem
(2005,
280,
28701-28710)
copyright 2005.
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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.H.Aguissa-Touré,
R.P.Wong,
and
G.Li
(2011).
The ING family tumor suppressors: from structure to function.
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Cell Mol Life Sci,
68,
45-54.
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D.G.Schatz,
and
Y.Ji
(2011).
Recombination centres and the orchestration of V(D)J recombination.
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Nat Rev Immunol,
11,
251-263.
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C.Couëdel,
C.Roman,
A.Jones,
P.Vezzoni,
A.Villa,
and
P.Cortes
(2010).
Analysis of mutations from SCID and Omenn syndrome patients reveals the central role of the Rag2 PHD domain in regulating V(D)J recombination.
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J Clin Invest,
120,
1337-1344.
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K.L.Yap,
and
M.M.Zhou
(2010).
Keeping it in the family: diverse histone recognition by conserved structural folds.
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Crit Rev Biochem Mol Biol,
45,
488-505.
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M.D.Best,
H.Zhang,
and
G.D.Prestwich
(2010).
Inositol polyphosphates, diphosphoinositol polyphosphates and phosphatidylinositol polyphosphate lipids: structure, synthesis, and development of probes for studying biological activity.
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Nat Prod Rep,
27,
1403-1430.
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S.Desiderio
(2010).
Temporal and spatial regulatory functions of the V(D)J recombinase.
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Semin Immunol,
22,
362-369.
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Y.Bultsma,
W.J.Keune,
and
N.Divecha
(2010).
PIP4Kbeta interacts with and modulates nuclear localization of the high-activity PtdIns5P-4-kinase isoform PIP4Kalpha.
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Biochem J,
430,
223-235.
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A.G.Matthews,
and
M.A.Oettinger
(2009).
RAG: a recombinase diversified.
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Nat Immunol,
10,
817-821.
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J.M.Jones,
and
C.Simkus
(2009).
The roles of the RAG1 and RAG2 "non-core" regions in V(D)J recombination and lymphocyte development.
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Arch Immunol Ther Exp (Warsz),
57,
105-116.
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N.Shimazaki,
A.G.Tsai,
and
M.R.Lieber
(2009).
H3K4me3 stimulates the V(D)J RAG complex for both nicking and hairpinning in trans in addition to tethering in cis: implications for translocations.
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Mol Cell,
34,
535-544.
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D.R.Wilson,
D.D.Norton,
and
S.D.Fugmann
(2008).
The PHD domain of the sea urchin RAG2 homolog, SpRAG2L, recognizes dimethylated lysine 4 in histone H3 tails.
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Dev Comp Immunol,
32,
1221-1230.
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H.Du,
H.Ishii,
M.J.Pazin,
and
R.Sen
(2008).
Activation of 12/23-RSS-dependent RAG cleavage by hSWI/SNF complex in the absence of transcription.
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Mol Cell,
31,
641-649.
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L.A.Baker,
C.D.Allis,
and
G.G.Wang
(2008).
PHD fingers in human diseases: disorders arising from misinterpreting epigenetic marks.
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Mutat Res,
647,
3.
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A.Argentaro,
J.C.Yang,
L.Chapman,
M.S.Kowalczyk,
R.J.Gibbons,
D.R.Higgs,
D.Neuhaus,
and
D.Rhodes
(2007).
Structural consequences of disease-causing mutations in the ATRX-DNMT3-DNMT3L (ADD) domain of the chromatin-associated protein ATRX.
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Proc Natl Acad Sci U S A,
104,
11939-11944.
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PDB codes:
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A.G.Matthews,
A.J.Kuo,
S.Ramón-Maiques,
S.Han,
K.S.Champagne,
D.Ivanov,
M.Gallardo,
D.Carney,
P.Cheung,
D.N.Ciccone,
K.L.Walter,
P.J.Utz,
Y.Shi,
T.G.Kutateladze,
W.Yang,
O.Gozani,
and
M.A.Oettinger
(2007).
RAG2 PHD finger couples histone H3 lysine 4 trimethylation with V(D)J recombination.
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Nature,
450,
1106-1110.
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PDB code:
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E.M.Oltz,
and
O.Osipovich
(2007).
Targeting V(D)J recombinase: putting a PHD to work.
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Immunity,
27,
539-541.
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I.Abarrategui,
and
M.S.Krangel
(2007).
Noncoding transcription controls downstream promoters to regulate T-cell receptor alpha recombination.
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EMBO J,
26,
4380-4390.
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M.S.Krangel
(2007).
T cell development: better living through chromatin.
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Nat Immunol,
8,
687-694.
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R.L.Pinsonneault,
P.M.Vacek,
J.P.O'Neill,
and
B.A.Finette
(2007).
Induction of V(D)J-mediated recombination of an extrachromosomal substrate following exposure to DNA-damaging agents.
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Environ Mol Mutagen,
48,
440-450.
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S.Ramón-Maiques,
A.J.Kuo,
D.Carney,
A.G.Matthews,
M.A.Oettinger,
O.Gozani,
and
W.Yang
(2007).
The plant homeodomain finger of RAG2 recognizes histone H3 methylated at both lysine-4 and arginine-2.
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Proc Natl Acad Sci U S A,
104,
18993-18998.
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PDB codes:
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Y.Liu,
R.Subrahmanyam,
T.Chakraborty,
R.Sen,
and
S.Desiderio
(2007).
A plant homeodomain in RAG-2 that binds Hypermethylated lysine 4 of histone H3 is necessary for efficient antigen-receptor-gene rearrangement.
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Immunity,
27,
561-571.
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D.Jung,
C.Giallourakis,
R.Mostoslavsky,
and
F.W.Alt
(2006).
Mechanism and control of V(D)J recombination at the immunoglobulin heavy chain locus.
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Annu Rev Immunol,
24,
541-570.
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J.P.de Villartay
(2006).
Passera ou ne passera pas--accessibility is key.
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Nat Immunol,
7,
1019-1021.
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M.Chatterji,
C.L.Tsai,
and
D.G.Schatz
(2006).
Mobilization of RAG-generated signal ends by transposition and insertion in vivo.
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Mol Cell Biol,
26,
1558-1568.
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K.L.West,
N.C.Singha,
P.De Ioannes,
L.Lacomis,
H.Erdjument-Bromage,
P.Tempst,
and
P.Cortes
(2005).
A direct interaction between the RAG2 C terminus and the core histones is required for efficient V(D)J recombination.
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Immunity,
23,
203-212.
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X.Shi,
and
O.Gozani
(2005).
The fellowships of the INGs.
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J Cell Biochem,
96,
1127-1136.
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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
