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Molecular and Cellular Biology, May 1999, p. 3788-3797, Vol. 19, No. 5
0270-7306/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
Detection of RAG Protein-V(D)J Recombination Signal
Interactions Near the Site of DNA Cleavage by UV
Cross-Linking
Quinn M.
Eastman,1
Isabelle J.
Villey,2,3 and
David G.
Schatz2,3,*
Department of Molecular Biophysics and
Biochemistry,1 Howard Hughes Medical
Institute,2 and Section of
Immunobiology,3 Yale University School of
Medicine, New Haven, Connecticut 06520-8011
Received 18 September 1998/Returned for modification 2 November
1998/Accepted 27 January 1999
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ABSTRACT |
V(D)J recombination is initiated by double-strand cleavage at
recombination signal sequences (RSSs). DNA cleavage is mediated by the
RAG1 and RAG2 proteins. Recent experiments describing RAG protein-RSS
complexes, while defining the interaction of RAG1 with the nonamer,
have not assigned contacts immediately adjacent to the site of DNA
cleavage to either RAG polypeptide. Here we use UV cross-linking to
define sequence- and site-specific interactions between RAG1 protein
and both the heptamer element of the RSS and the coding flank DNA.
Hence, RAG1-DNA contacts span the site of cleavage. We also detect
cross-linking of RAG2 protein to some of the same nucleotides that
cross-link to RAG1, indicating that, in the binding complex, both RAG
proteins are in close proximity to the site of cleavage. These results
suggest how the heptamer element, the recognition surface essential for
DNA cleavage, is recognized by the RAG proteins and have implications
for the stoichiometry and active site organization of the RAG1-RAG2-RSS complex.
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INTRODUCTION |
The variable portions of antigen
receptor genes are assembled from component gene segments during
lymphocyte development by a process known as V(D)J recombination. The
gene segments that undergo rearrangement are flanked by recombination
signal sequences (RSSs), consisting of conserved heptamer
(CACAGTG) and nonamer (ACAAAAACC) elements
separated by a spacer of either 12 or 23 bp. Recombination brings two
protein-coding regions together in an imprecise junction and joins the
two RSSs with the heptamer elements fused head-to-head. Recombination
occurs predominantly between gene segments flanked by RSSs with spacers
of unequal lengths. This "12/23 rule" helps to restrict the
reaction to developmentally useful combinations (19).
The products of the recombination activating genes, RAG1 and
RAG2, are necessary for the initiation of V(D)J
recombination (28, 41) and together catalyze the creation of
a double-strand break at the border of an RSS (23, 50). They
first introduce a nick 5' to the first C nucleotide of the heptamer
element. This exposes a 3' hydroxyl which then attacks the opposite
strand of the DNA, creating a 5'-phosphorylated blunt end on the signal side and a closed hairpin on the side that will form protein-coding sequence (see Fig. 1A).
The sequence requirements for hairpin formation are more stringent than
those for initial nicking. In cells and in crude extracts, hairpin
formation requires the formation of a synaptic complex involving the
two RSSs, while nicking can occur at an isolated signal (10, 11,
13, 44, 45). The RAG proteins intrinsically prefer to cleave a
12/23 pair of signals (52); however, the ubiquitous
DNA-bending proteins HMG-1 and HMG-2 strengthen this preference by
boosting cleavage at the RSS with a 23-bp spacer and by aiding in the
formation of a synaptic complex (39, 49). In addition, in a
single-signal context, some mutations of the heptamer element
substantially inhibit hairpin formation without preventing initial
nicking (7, 31).
Mutants of RAG1 have been identified as sensitive to the sequence of
the coding flank DNA immediately adjacent to the heptamer (33,
36). The same coding flank sequences that prevent recombination with the mutant RAG1 (referred to as "bad flanks") inhibit hairpin formation and not nicking when catalyzed by unmutated RAG1 and RAG2 in
vitro. This preference, observed under conditions where the 12/23 rule
is not being obeyed (in the presence of Mn2+), disappears
when unpaired DNA is introduced into the coding flank or under
conditions of coupled cleavage (7, 31, 52). This suggests
that to catalyze hairpin formation, RAG1 and RAG2 must unwind the DNA
at the heptamer-coding flank border and that synaptic complex formation
promotes DNA unwinding.
The two-step reaction mechanism and stereochemistry of V(D)J signal
cleavage have prompted comparisons with retroviral integration and
transposition by elements such as Tn10 and Mu
(51), and it was recently discovered that the
Tn10 transposition mechanism includes the creation of
hairpins at DNA termini (16). Transposases and retroviral
integrases share not only a mechanism of phosphoryl transfer but also a
common active-site architecture. In these systems, the active site is
defined by three acidic amino acid residues that coordinate the
divalent metal ions necessary for catalysis (3, 5, 38). For
the RAG proteins, these amino acid residues have not been identified,
leaving the issue of active-site architecture unresolved.
Individual roles for each of the RAG proteins in the catalysis of DNA
cleavage have not been established. Neither protein has any obvious
enzymatic activity on its own, but some progress has been made in
identifying contacts between RAG1 protein and RSS DNA. Experiments
using surface plasmon resonance and also an in vivo one-hybrid system
provided evidence that RAG1 by itself has the ability to recognize and
bind the RSS (8, 43). These studies suggested that the
nonamer element is the more important DNA sequence feature required for
binding and is recognized by the region of the RAG1 protein that has
sequence similarity to the DNA-binding domain of Hin recombinase
(hereafter called the nonamer-binding domain [NBD]). Later work that
examined the formation of a stable complex containing RAG1, RAG2, and
RSS DNA showed that RAG2 protein and both of the heptamer and nonamer
elements were necessary for efficient and stable binding (2,
15).
The location of RAG2 in the RAG-RSS complex has been difficult to
identify. Specific contacts between RAG1 and RSS DNA, as identified by
dimethyl sulfate interference analysis, are found in the nonamer
element and extend into the nonamer-proximal portion of the heptamer.
One study has shown that the DNase I footprinting pattern obtained by
using RAG1 alone is essentially the same as the pattern obtained with
RAG1 and RAG2 (29). Another recent study found that when
RAG1 and RAG2 were both bound to RSS DNA, the patterns of protection
and binding interference extended further into the spacer and the
nonamer-proximal portion of the heptamer than when only RAG1 was bound
(46). Thus, it is possible that RAG2 makes weak contacts
with the spacer and heptamer elements or that it does not contact the
DNA at all, altering the DNA-binding tendencies of RAG1 indirectly.
In a single-RSS context, contacts between coding flank DNA and RAG
proteins are required to stabilize a RAG-DNA complex (15). However, strong contacts between RAG1 or RAG2 and the nonamer-distal portion of the heptamer or coding flank DNA have not been identified. The presence of RAG2 in the RAG protein-RSS complex has been shown to
encourage distortion of the DNA backbone at the heptamer-coding flank
border (46). With the location of RAG2 unknown and RAG1's location most firmly established at the nonamer element, it was unclear
which of the RAG proteins contact the DNA near the site of DNA
cleavage. To address this question, we have introduced the photolabile
nucleotides 5-iododeoxyuridine (IdU) and 5-iododeoxycytosine (IdC) into
RSS oligonucleotide substrates at specific positions near the
heptamer-coding flank border (54). We reasoned that if the
interactions between the RAG proteins and the DNA surrounding the site
of cleavage are weak or transient, it still might be possible to
capture the protein molecules interacting closely with the RSS DNA by
UV cross-linking. We have detected sequence-specific interactions
between RAG1 protein and both the nonamer-distal portion of the
heptamer element and coding flank DNA. In addition, two of the
iodinated nucleotide positions that cross-link to RAG1 protein also
cross-link to RAG2 protein. Detection of both RAG1 and RAG2 proteins
near the heptamer-coding flank border suggests that both proteins
participate in direct recognition of the heptamer DNA and in
construction of the enzymatic active site.
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MATERIALS AND METHODS |
Proteins.
The F2A1 cell line was generated by transfecting
the B-cell lymphoma line M12 with heat shock-regulated RAG1 and RAG2
expression vectors as described previously (10, 18). The
proteins expressed were murine RAG1 (amino acids 264 to 1008) and
murine RAG2 (amino acids 1 to 387) with C-terminal extensions
consisting of nine histidines and three copies of the c-myc epitope tag
(24, 34, 35). A 30-liter portion of cultured cells was heat
shocked for 6 min at 45°C, allowed to recover for 6 h,
harvested, and frozen at 
70°C. All subsequent steps were carried
out on ice or at 4°C. Cell pellets were extracted with 100 ml of
extraction buffer (325 mM NaCl; 3 mM MgCl2; 25 mM Tris-Cl,
pH 7.5; 0.2 mM EDTA; 0.2 mM EGTA; 20% glycerol; 0.1% Nonidet P-40
[NP-40], 5 mM dithiothreitol [DTT], 0.5 mM phenylmethylsulfonyl
fluoride [PMSF]). After centrifugation at 30,000 × g
for 30 min the supernatant was removed and diluted with 150 ml of
buffer Q (20 mM Tris-Cl, pH 7.5; 20% glycerol, 5 mM DTT) plus 0.5 mM
PMSF. This diluted extract was recentrifuged at 20,000 × g for 30 min and then loaded onto a 50-ml Q Sepharose Fast Flow
column (Pharmacia) at 5 ml/min. The column was washed with 250 ml of
buffer Q plus 140 mM NaCl and then eluted with 180 ml of buffer Q plus
350 mM NaCl. Proteins were precipitated by the addition of 72 g of
(NH4)2SO4, recovered by
centrifugation, resuspended in 25 ml of dialysis buffer, and dialyzed
against 1 liter of buffer N7.5 (300 mM NaCl; 20 mM Na-HEPES, pH 7.5; 20 mM imidazole-Cl, pH 7.5; 20% glycerol; 0.1% NP-40; 7 mM
-mercaptoethanol) overnight. Proteins were loaded onto a 6-ml
Ni2+-nitrilotriacetic acid (NTA) Superflow column (Qiagen)
at 0.6 ml/min. The column was washed with 50 ml of buffer N7.5 and then with 25 ml of N6.2 (200 mM NaCl; 40 mM imidazole-Cl, pH 6.2; 20% glycerol; 7 mM -mercaptoethanol). RAG proteins were eluted with a
100-ml gradient of imidazole (40 to 600 mM) in buffer N6.2. Fractions
containing RAG proteins (determined by silver staining after sodium
dodecyl sulfate-polyacrylamide gel electrophoresis [SDS-PAGE]) were
pooled and dialyzed against buffer H (100 mM NaCl; 20 mM HEPES, pH 7.5;
3 mM MgCl2; 20% glycerol; 1 mM EDTA; 5 mM DTT) overnight.
RAG proteins were further purified by loading them onto a 1-ml HiTrap
heparin-Sepharose column (Pharmacia) at 0.6 ml/min, washing them with
buffer H, and then eluting them in buffer H with a 10-ml gradient of
NaCl (100 mM to 1.5 M), omitting MgCl2. The most active
fractions (as determined by their ability to cleave the fr12x23
substrate [10]) were pooled, adjusted to 50%
glycerol, and stored at 20°C. The preparation (30 µg each of RAG1
and RAG2 proteins per ml) is approximately 60% pure as determined by
silver staining of SDS-PAGE gels.
Murine HMG2 protein (amino acids 1 to 185) lacking the C-terminal
acidic domain and with an amino-terminal extension
(MASHHHHHHSRTRRASVGPS) containing a polyhistidine region and
protein kinase A phosphorylation site (55) was obtained by
overexpression in Escherichia coli. Bacteria were lysed and
sonicated briefly in buffer N7.5. After a thermal denaturation step at
72°C for 10 min, the bulk of the bacterial proteins was removed by
centrifugation for 30 min at 30,000 × g and 0.45-µm
(pore size) filtration. Further purification over a
Ni2+-NTA column and elution with an imidazole gradient
produced essentially pure protein, which was stored at 20°C in 50% glycerol.
Substrates.
The oligonucleotides used were synthesized by
the Keck Foundation Biotechnology Resource Laboratory at Yale
University on an Applied Biosystems 3948 synthesizer, with
5-iododeoxy-uridyl or -cytidyl phosphoramidites obtained from Glen
Research. Unmodified oligonucleotides were purified by urea-PAGE.
Sequences of the oligonucleotides used to make the unmutated C-1b and
H2b substrates were as follows (z represents 5-iododeoxyuridine):
QME27, 5'-TAAGACGTCGACGCGT-3' (16 bases); QME28,
5'-zAAGACGTCGACGCGT-3' (16 bases); QME29,
5'-GGATCCGGTTTTTGTTCAGGGCTGTATCACTGTG-3' (34 bases); QME211,
5'-GGATCCGGTTTTTGTTCAGGGCTGTATCACTGzG-3' (34 bases); and
WTTOP, 5'-ACGCGTCGACGTCTTACACAGTGATACAGCCCTGAACAAAAACCGGATCC-3' (50 bases).
All cross-linking substrates were prepared by 5'-end labeling 50 pmol
of one oligonucleotide (in the C-1b and H2b substrates,
QME28 and
QME27, respectively) with an excess of [
-
32P]ATP and
polynucleotide kinase. The labeled oligonucleotide was
then annealed to
a twofold excess of partner oligonucleotides
(for C-1b and H2b, WTTOP
and either QME29 or QME211 was used)
and then ligated overnight at room
temperature. Substrates were
purified on native 10% polyacrylamide
gels. Monitoring the efficiency
of ligation on denaturing
polyacrylamide gels revealed that >80%
of the
32P-labeled
DNA migrated at 50 nucleotides for C-1b and H2b
substrates.
For C-1b and H2b substrates, mutation of the heptamer element replaced
5'-CACAGTG (top strand) with 5'-GAGCAGT. Mutation
of
the nonamer element replaced 5'-ACAAAAACC (top strand)
with 5'-AGTCTCTGA.
Mutation of both the heptamer and the
nonamer replaced 5'-CACAGTG
(top strand) with
5'-GAGCAGT and 5'-ACAAAAACC (top strand) with
5'-ACAAGGACC. 23-RSS substrates had identical coding flanks
and
had the following sequence for a spacer:
5'-ATACAGCCCTGATGTCTGGCTGT-3'.
For point mutants of the H2b and C-1b substrates, the sequence
5'-TTACACAGTG was changed to either 5'-TTAtACAGTG
or 5'-ggACACAGTG
(bad flank) (lowercase letters
indicate altered residues). For
C-1t substrates, the equivalent
top-strand sequence was always
5'-TT
CCACAGTG
(underlined position was iodinated). The bottom-strand
sequence
was either complementary (5'-CACTGTGGAA) or not
(5'-CACTGTGccA).
Substrates with iodomodifications at other positions were constructed
analogously. For C-3t and C-2t substrates, the
32P label
was placed 5' to the iodinated nucleotide: top strand,
5'-pTTACACAGTG-3' or 5'-TpTACACAGTG-3', respectively. For H1t
and H3t
substrates, the
32P label was placed between the second and
third positions of the
heptamer: top strand, 5'-CApCAGTG. A mutant
control for H3t was
obtained by replacing CA
CAGTG
with GC
CCAGT (iodinated unmutated
base-pair underlined). For H5b substrates, the
32P label
was placed between the fifth and sixth positions of the
heptamer:
bottom strand, 3'-GTGTpCAC-5'. The mutant control for
H5b replaced
5'-CACA
GTG with 5'-GCGA
GAC.
For H6t substrates, the
32P label was placed between
the fifth and sixth positions of the
heptamer: top strand,
5'-CACAGpTG-3'. The mutant control for H6t
replaced (top strand)
5'-CACAG
TG with
5'-ACGCA
TT.
Cross-linking and cleavage reactions.
A standard
cross-linking reaction mixture (75 mM Na-acetate; 2 mM Mg-diacetate; 20 mM Na-HEPES, pH 7.5; 10 µM ZnSO4; 2 mM DTT; 8% glycerol,
0.1 mg of bovine serum albumin per ml) contained 180 ng of each RAG
protein and 2 × 106 cpm (1 pmol) of
32P-labeled DNA in 100 µl. Cross-linking reactions were
set up at room temperature in polystyrene 96-well dishes. After the RAG proteins were added, reaction mixtures were incubated at 37°C for 10 min. Competitor DNA (5 µg of sheared salmon sperm DNA in most
reactions), if used, was added after 5 min, and mixtures were incubated
for 5 min more at 37°C. Cross-linking, shielded by the bottom of the
polystyrene dish, took place for 12 min on a FotoPrep I 3-3500 UV
illuminator with 312-nm bulbs. After the cross-linking, mixtures were
transferred to Eppendorf tubes, heated to 68°C for 10 min, cooled,
and adjusted to 10 mM MgCl2 and 1 mM CaCl2. The
mixtures were digested by a mixture of 2 µg of DNase I and 0.2 µg
of micrococcal nuclease for 1 h at 37°C. Mixtures were
trichloroacetic acid (TCA) precipitated and subjected to SDS-PAGE with
sample buffer containing -mercaptoethanol. Separating gels were
7.5% (29:1) acrylamide-bisacrylamide, and the stacking gel contained
1% SDS. Gels were stained with Coomassie blue to identify protein
markers before being dried for autoradiography. Cleavage reactions were
performed in the same buffer as the standard cross-linking reaction.
Immunoprecipitations.
Cross-linking reaction mixtures to be
immunoprecipitated were cross-linked as described above but were not
heated to 68°C after UV irradiation. After digestion with nucleases,
two cross-linking reaction mixtures containing twice the normal amount
of RAG protein were pooled, adjusted to 0.1% SDS, and heated at 68°C
for 10 min. Then, 500 µl of ice-cold immunoprecipitation (IP) wash
buffer (1 M NaCl; 50 mM Tris, pH 7.5; 1% NP-40) was added, and the
mixtures were precleared for 30 min at 4°C with 20 µl of protein
G-agarose beads (Gibco-BRL). Next, 20 µg of anti-R1P7, anti-RAG2, or
anti-R1P1 (a control, because the RAG1 protein used here does not have
the R1P1 epitope) antibodies and an additional 20 µl of protein
G-agarose beads were added. Mixtures were rotated overnight at 4°C
and then centrifuged and washed five times with IP wash buffer.
Precipitated proteins were eluted with 1% SDS at 55°C, TCA
precipitated, and analyzed by SDS-PAGE as described above. The
antibodies used here have been described elsewhere (1, 18,
25). The epitopes recognized included R1P7, RAG1 (amino acids 590 to 758); RAG2 (amino acids 70 to 516); and R1P1 (control), RAG1 (amino
acids 56 to 123). The samples (see Fig. 8A) were transferred to a
polyvinylidene difluoride membrane, probed with 9E10 (anti-myc tag)
antibody, and developed by using alkaline phosphatase-conjugated
secondary antibody and 5-bromo-4-chloro-3-indolylphosphate-nitroblue
tetrazolium (Jackson Immunoresearch).
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RESULTS |
An assay for detecting cross-linking of RAG proteins to iodinated
nucleotides in heptamer and coding-flank DNA.
We constructed 50-bp
RSS substrates from three oligonucleotides, with a 32P
label placed so that it is separated from the location of the iodinated
nucleotide by only one or two phosphodiester bonds (Fig. 1B). The substrates are based upon a
recombination signal with an optimized 12-bp spacer and 16 bp of coding
flank DNA (30, 43). Incubation of RAG1 and RAG2 proteins
with the iodomodified DNA followed by UV irradiation creates a novel
covalent bond between the iodinated nucleotide and a polypeptide in
close proximity to it (Fig. 1C). IdU and IdC are thought to cross-link
preferentially to amino acids with aromatic and sulfur-containing side
chains (26). It is important to recognize that failure to
observe cross-linking to a particular nucleotide does not necessarily
indicate the lack of protein contact altogether; instead, it may mean
only that an appropriate amino acid is not close enough to the
iodinated nucleotide. Subsequent nuclease treatment degrades
un-cross-linked DNA and removes all but a few nucleotides from the
modified protein (Fig. 1C). SDS-PAGE analysis and autoradiography allow
visualization of the transfer of the 32P label to a
polypeptide which, after cross-linking, will not differ substantially
from its pre-cross-linking molecular weight (Fig. 1C). In this study we
used a partially purified preparation of truncated RAG1 and RAG2
proteins, expressed in a mammalian cell line and modified with
polyhistidine tags at the C terminus to facilitate their purification.
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FIG. 1.
Experimental setup for detecting RAG protein-DNA
interactions near the site of cleavage. (A) RSS cleavage by RAG
proteins. The gray triangle represents
CACAGTGN12/23ACAAAAACC. RAG1 and RAG2 catalyze first a
nucleophilic attack by H2O on the top strand 5' to the
heptamer element, followed by use of the 3' OH to attack the DNA
phosphate (P) on the other strand. Coding flank refers to the DNA next
to the RSS before cleavage. Signal end and coding end refer to the DNA
species created by a double-strand break. (B) The coding flank
(C) and heptamer (H) base pairs are numbered
according to their distance from the site of DNA cleavage. IdU
positions are named according to the element (C or H), the base pair,
and the strand (top [t] or bottom [b]). In C-1b and H2b substrates
the labeled phosphate is at the position indicated. (C) Schematic of
cross-linking assay. The gray oval represents generic RAG protein
binding to the DNA, represented as the interlocking "helix." The
lightning bolt arrow (UV irradiation) site-specifically cross-links RAG
protein to the DNA through the iodo group. Surrounding DNA is removed
by nucleases and TCA precipitation.
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We initially used substrates with IdU introduced into the bottom
strand, at the second position of the heptamer (H2b) and
the first
position of the coding flank (C-1b) immediately adjacent
to the
heptamer (Fig.
1B). Note that these two positions are on
either side of
the site of nucleophilic attack during hairpin
formation; the
32P-labeled phosphate is the object of that attack. The
major cross-linked
protein migrates in an SDS-acrylamide gel (shown in
Fig.
2) exactly
as expected for the
truncated RAG1 protein. No signal is observed
with a noniodinated
substrate (Fig.
2, lane 1), without UV irradiation
(lanes 3 and 10), or
with reactions lacking RAG protein (lanes
2 and 9). In agreement with
previous results that showed that
stable binding of RAG proteins to RSS
DNA requires a divalent
cation, the amount of cross-linked protein
drops considerably
when the 2 mM Mg
2+ present in a standard
binding reaction mixture is replaced with
0.5 mM EDTA (lanes 7 and 14).
The cross-linking signal is also
less when 2 mM Mg
2+ is
replaced by 2 mM Ca
2+ (lanes 6 and 13). Although the
overall efficiency of the cross-linking
reaction is low (<5% of the
cpm in the binding reaction mixture
is transferred to
nuclease-resistant material), binding seems
to be stable, as little
drop in the signal is seen when the preformed
RAG-DNA complex is
challenged before UV irradiation with a 100-fold
excess of unlabeled
nonspecific DNA (lanes 5 and 12). The immunoprecipitation
experiments
described below confirm that the
32P-labeled bands detected
are RAG1 and RAG2.
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FIG. 2.
RAG1 can be cross-linked to RSS DNA by using IdU and UV
light. All three substrates used have consensus heptamer and nonamer
sequences. See Fig. 1 for a graphic representation of the IdU and
32P positions. Components were added as indicated above the
lanes. The divalent cations used were 2 mM MgCl2 (Mg), 2 mM
CaCl2 (Ca), or 0.5 mM EDTA (). Competitor (comp.) DNA was
5 µg of sheared salmon sperm DNA added after 5 min at 37°C. Binding
reaction mixtures were incubated, cross-linked, treated with nuclease,
and analyzed by SDS-PAGE as described in Materials and Methods.
Positions of the protein markers are indicated on the left edge of the
gel (sizes in kilodaltons). The black and white triangles indicate the
expected positions of the truncated RAG1 and RAG2 proteins,
respectively. The broad band at or above 200 kDa may be a highly
cross-linked protein that does not completely enter the gel and has not
been investigated further.
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Sequence specificity of cross-linking.
To determine whether
the protein-DNA interactions detected depended upon specific DNA
sequences, we used cross-linking substrates that had severe mutations
of either the heptamer element, the nonamer element, or both. In the
absence of competitor DNA, mutations of the heptamer or nonamer
elements do not eliminate cross-linking to the RAG1-sized protein.
(Fig. 3, lanes 3 to 5). However,
challenge with sheared salmon sperm DNA after incubating of the protein and labeled cross-linking substrate at 37°C for 5 min reveals that
the interactions of RAG protein with the mutated substrates are labile
(lanes 8 to 10), while challenge does not disrupt cross-linking to the
wild-type substrate (lane 7). Stable interactions were sequence
specific in the presence of Mg2+, requiring both the
heptamer and the nonamer elements, when IdU was placed at either the
H2b position (Fig. 3A) or the C-1b position (Fig. 3C). In addition to
the cross-linking efficiency being generally poorer when
Mg2+ is replaced by Ca2+ (Fig. 3B and D),
mutating the heptamer element does not reduce the (already low)
cross-linking signal detected in Ca2+ when the IdU is at
the H2b position (Fig. 3B, lane 8). In this respect, our results
resemble the observations made previously (29) of
nonspecific DNA binding in the presence of Ca2+, although
the interactions captured are still nonamer dependent.
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FIG. 3.
Cross-linking of RAG1 to heptamer-coding flank DNA
requires both heptamer and nonamer sequences. The 12-RSS substrates
used are indicated above the lanes: HN (consensus heptamer and nonamer
elements), xN (mutant heptamer), Hx (mutant nonamer), and xx (mutant
heptamer and nonamer). The position of the IdU residue and the divalent
cation used are indicated to the right of each panel. Competitor DNA (5 µg of sheared salmon sperm DNA) was added to the reaction mixtures
for lanes 6 to 10. Reaction mixtures in lanes 1 and 6 contained a
control substrate lacking IdU. The black and white triangles indicate
the expected positions of the RAG1 and RAG2 proteins, respectively.
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The specificity of DNA binding was examined further by using two other
kinds of unlabeled competitor DNA: nonspecific single-stranded
DNA and
a consensus 12-RSS substrate. Competitor DNA was added
to the
32P-labeled substrate DNA either before the RAG proteins (0 min)
or 5 min after the RAG proteins were added (Fig.
4). RAG proteins
could bind a 12-RSS
substrate in the presence of an excess of
genomic DNA (lanes 3 and 9).
However, the cross-linking signal
is reduced compared to when the
competitor DNA is added after
5 min. We had previously determined that
genomic DNA added after
5 min did not reduce the cross-linking signal
(Fig.
2). With this
comparison in mind, single-stranded
oligonucleotides also did
not diminish the cross-linking signal when
added at
t = 0 or 5
min (lanes 1, 4, 7, and 10). As
expected from the results described
by others, an intact 12-RSS
substrate could effectively compete
for DNA binding when present at
t = 0 minutes (lanes 2 and 8),
but it competes less
effectively when added after complex formation
(lanes 5 and 11)
(
15,
20). We conclude that nonspecific single-stranded
DNA
used as competitor by others (
15,
29) does not interfere
with cross-linking and that the RAG-DNA binding specificity, as
measured indirectly here by the differing ability of 12-RSS and
genomic
DNA to compete for RAG proteins, is comparable to that
observed by
others (
2,
15). Sheared genomic DNA added after
5 min was
used in subsequent binding reactions because under these
conditions the
strongest cross-linking that still required both
heptamer and nonamer
sequences was observed.
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FIG. 4.
Cross-linking to RAG1 can be blocked with specific
competitor DNA. Binding reactions contained 2 mM Mg2+ and
the indicated cross-linking substrate. Competitor DNA was added either
before RAG protein (0') or 5 min after RAG protein (5') was added. The
competitor DNAs used were 1 µM top-strand oligonucleotide used to
make the substrate "xx" in Fig. 3 (ss-M), 1 µM unlabeled 50-bp
double-stranded HN substrate (ds-WT), or 5 µg of sheared salmon sperm
DNA, equivalent to ~1.5 µM 50-bp DNA (ds-N). The black and white
triangles indicate the expected positions of the RAG1 and RAG2
proteins, respectively.
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Both 12-RSS and 23-RSS DNA cross-link like RAG proteins.
To
determine whether RAG proteins would cross-link to DNA near the
heptamer-coding flank border at 23-RSSs as well, we devised substrates
that were 32P labeled and iodomodified at the C-1b and H2b
positions as for the 12-RSS substrates described above (Fig.
5A). We observed weaker cross-linking to
the RAG1-sized protein with the 23-RSS substrates compared to the
12-RSS substrates (data not shown), but the signal is still highly
dependent upon heptamer and nonamer sequences (compare lanes 1 and 2 and lanes 3 and 4). HMG1 and HMG2 proteins, DNA-bending proteins that
have an affinity for distorted and unpaired DNA sequences
(4), have been reported to increase binding of the RAG
proteins to a 23-RSS substrate. We observed that HMG2 did not uniformly
enhance the interactions leading to cross-linking but instead resulted
in decreased cross-linking to the heptamer H2b position and increased
cross-linking to the coding-flank position C-1b (lanes 5 and 7).
Interestingly, in reactions with substrates iodinated at the C-1b
position, we observed a band, less prominent than the RAG1-sized band,
that migrated at the expected size of RAG2 (white triangle, lanes 3 and
7). The identity of this band is addressed below.
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FIG. 5.
Cross-linking reactions with 23-RSS substrates and
12-RSS substrates substituted at other heptamer-coding flank positions.
All cross-linking reaction mixtures contain 2 mM Mg2+ and
have sheared salmon sperm DNA added after 5 min. The black and white
triangles indicate the expected positions of the RAG1 and RAG2
proteins, respectively. (A) 23-RSS substrates with IdU at the C-1b or
H2b positions. "mut" indicates that both the heptamer and nonamer
are mutated. In lanes 5 to 8, 50 ng of HMG2 protein was added before
the RAG protein. (B and C) Cross-linking reactions with 12-RSS
substrates with IdU or IdC at the indicated positions. Each mutant
("mut") changes each base pair of the entire heptamer, except the
modified nucleotide (see Materials and Methods), and leaves the nonamer
intact. There are no mutants for C-3t, C-2t, and H1t because prior
experimentation established that there was minimal cross-linking to
those positions. Lanes 1 and 2 in each case are positive (C-1b) and
negative (C-1b mut, "xx" from Fig. 3) control cross-linking
reactions, respectively.
|
|
Evaluating other heptamer and coding-flank positions for RAG
cross-linking.
We scanned through the heptamer and coding flank to
find other pyrimidines that cross-link to RAG proteins. We used 12-RSS substrates with IdU or IdC incorporated at the C-3t, C-2t, H1t, H3t,
H5b, and H6t positions (Fig. 5B and C; "t" and "b" indicate the
top and bottom strands, respectively, as defined in Fig. 1B). With
these substrates, the 32P label is placed so that a maximum
of two phosphodiester bonds separates the labeled phosphate from the
iodomodified base (see Materials and Methods). Cross-linking was
detected when IdC was incorporated into the H3t position (Fig. 5B, lane
6), with the signal being somewhat weaker than the reference C-1b
signal but still greatly reduced when the heptamer element is mutated
(lane 7). Besides the specific signal at the H3t position, only very low-level cross-linking, which did not change when the RSS was mutated,
was observed with the other substrates tested (Fig. 5B and C).
As noted above, failure to observe cross-linking at a particular DNA
position is difficult to interpret. It might reflect
the absence of a
close protein-DNA interaction at that position,
a close interaction
involving amino acid residues inappropriate
for cross-linking, or a
perturbation of the binding interaction
as a result of iodination of
the RSS. To investigate the last
possibility, RAG cleavage reactions
were performed by using iodinated
RSS substrates, and reaction products
were visualized on denaturing
polyacrylamide gels (Fig.
6). An iodine introduced at the C-1b
and
H5b positions (lanes 4 and 6) and H2b positions (data not
shown)
allowed hairpin formation (nicking could not be evaluated
with these
substrates because of the position of the
32P label; see
bottom of Fig.
6). Iodination at positions H6t, C-2t,
and C-3t
permitted nicking but not hairpin formation (lanes 2,
3, and 7), while
modification of the H1t position blocked all
nicking and hairpin
formation (lane 5). Because the iodo group
lies in the major groove,
these results suggest that to recognize
the heptamer-coding flank
region and to perform cleavage, the
RAG proteins make close contacts
with major groove recognition
elements. These findings also suggest
that our failure to observe
specific cross-linking at a number of
positions is due, at least
in part, to interference with the RAG-RSS
interaction by the iodine
substitution.
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FIG. 6.
Single RSS cleavage reactions with iodinated substrates.
Cleavage was carried out in 2 mM Mg2+, and products were
visualized by denaturing PAGE. Lane 1 is an uncleaved control, while
lane 8 is a positive control (noniodinated wild-type RSS). Substrates
have IdU or IdC introduced at the positions indicated above each lane
and are labeled with 32P as indicated in the diagrams at
the bottom of the figure. The C-1b and H5b substrates are labeled on
the bottom strand, permitting only hairpin cleavage products (and not
the nicked top strand) to be visualized on the gel. Hairpin formation
with the H5b substrate generates a labeled 34-nucleotide signal end
product, whereas for the other substrates, a labeled 32-nucleotide
hairpin coding end product is generated.
|
|
Effects of heptamer mutations and suboptimal coding-flank sequence
on cross-linking efficiency.
Cross-linking of RAG proteins to RSS
DNA was more efficient in the presence of Mg2+, which
supports catalysis, than in the presence of Ca2+, which
does not. To examine further the link between catalysis and
cross-linking, we made 12-RSS cross-linking substrates with a C-to-T
mutation of the first position of the heptamer, a mutation which
prevents hairpin formation but not nicking (10, 11, 31).
With the iodo group at either the H2b or the C-1b position, this
mutation reduced the amount of cross-linking (Fig.
7A, lanes 2, 3, 5, and 6). Therefore, the
presence of the canonical C-G base pair at the first position of the
heptamer is important for close interactions on both sides of the site
of cleavage, as well as for hairpin formation.
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FIG. 7.
Cross-linking to and cleavage of point mutant 12-RSS
substrates. (A) Cross-linking reactions. IdU (C-1b and H2b)- or IdC
(C-1t)-substituted substrates containing a consensus nonamer were used,
as indicated above the lanes. Substrates contained either a consensus
(w) or a mutant (m) heptamer (top strand, 5'-tACAGTG). The
three nucleotides of the coding flank closest to the heptamer are shown
above each lane (top-strand sequence as defined in Fig. 1A). 5'-TTA is
a good flank, whereas 5'-ggA and 5'-TTc are bad flanks. The underlined
nucleotides in lane 9 have no Watson-Crick base pairs on the bottom
strand (the corresponding bottom-strand nucleotides are CC). The
reaction in lane 1 contained a control substrate lacking IdU. The black
and white triangles indicate the expected positions of the RAG1 and
RAG2 proteins, respectively. (B) Single RSS cleavage reactions in 2 mM
Mg2+ with noniodinated substrates. The structure of the
substrate and the position of the 32P label are indicated
at the top of the panel. Products were analyzed on a denaturing
polyacrylamide gel. Nicking and hairpin formation result in 16- and
32-nucleotide products, respectively. Lane 1 is uncleaved substrate,
and the sequences of the other substrates are indicated as in panel A. Lane 7 is an end-labeled 10-bp ladder (Gibco-BRL).
|
|
Hairpin formation in a single-RSS context is also sensitive to
coding-flank sequence. "Bad" flanks support only nicking, while
"good" flanks allow both nicking and hairpin formation (
31,
36). The cross-linking substrates used in the experiments
described
above contained a good flank (5'-TTA-3' immediately adjacent
to
the heptamer on the top strand [Fig.
1B]). Changing two residues
to create the bad flank sequence 5'-GGA-3' had different effects
on
cross-linking, depending on the site of the iodo group: at
the C-1b
position cross-linking was increased (Fig.
7A, lanes
2 and 4), while at
the H2b position cross-linking was reduced
(lanes 5 and 7). Therefore,
a bad flank does not eliminate the
interactions necessary for
cross-linking. Instead, the results
suggest that a bad flank
selectively perturbs the DNA structure
near the coding flank-heptamer
border, impairing interactions
between RAG1 and the second base pair of
the
heptamer.
We also examined cross-linking to the first position of the coding
flank on the top strand (C-1t). Because an iodo group could
be
introduced only on a pyrimidine, which at this position invariably
generates a bad flank, these experiments were performed only in
the
context of a bad flank. Interestingly, no cross-linking at
this
position was observed unless a noncomplementary sequence
was introduced
into the bottom strand, leading to unpairing of
2 bp of the coding
flank (Fig.
7A, lanes 8 and 9; note that the
bottom strand also has a
bad-flank sequence). Unpairing has been
found by others (
7,
31) to restore hairpin formation on a
bad-flank sequence, and
analysis of cleavage reactions with the
two bad-flank substrates
confirms this (Fig.
7B, compare lanes
5 and 6). Therefore,
cross-linking to the C-1t position correlates
well with hairpin
formation ability, perhaps because an unpaired
structure at the
heptamer-coding flank border allows the C-1t
nucleotide to rotate into
a new position that makes closer contacts
with
RAG1.
Finally, experiments were performed to confirm that the mutated
single-RSS substrates used here yielded the expected cleavage
products.
For this purpose,
32P was introduced at the 5' end of the
top strand, and reaction
products were visualized by denaturing PAGE
(Fig.
7B; note that
the substrates used in Fig.
7B are not iodinated).
As predicted,
mutation of the first position of the heptamer (lane 3),
or bad-flank
sequences (lanes 4 and 5), reduced hairpin formation but
not nicking,
and introduction of unpairing in the coding flank
substantially
increased hairpin formation with a bad-flank sequence
(lane 6).
These results were obtained in a Mg
2+-containing
buffer identical to that used in the cross-linking
experiments, and
similar results were obtained in Mn
2+ (data not
shown).
Immunoprecipitation analysis of 32P-labeled RAG
proteins.
The major cross-linked protein in most reactions
appeared to be RAG1, although in reactions with substrates with IdU at
the C-1b position, a labeled species was visible at the expected
position of RAG2 (Fig. 5A, lanes 3 and 7; Fig. 5B, lane 1; Fig. 5C,
lane 1). To ascertain the identities of the cross-linked proteins, we
used anti-RAG1 and anti-RAG2 antibodies to immunoprecipitate the
proteins after cross-linking and nuclease digestion. These antibodies
are specific for either RAG1 or RAG2 proteins and detect a single band
in immunoblots of the RAG protein preparations used here (data not
shown). To reduce coimmunoprecipitation of RAG1 with RAG2, which occurs
in mock binding reactions (Fig. 8A,
lane 3), we disrupted noncovalent
interactions by adding 0.1% SDS and heating the binding reaction
mixtures to 68°C before partially renaturing the proteins (enough to
be recognized by the antibodies) in the presence of 1% NP-40. Under
these conditions we observed efficient direct immunoprecipitation of
RAG1 and RAG2 but not coimmunoprecipitation (lanes 6 and 7).
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FIG. 8.
Verification of the identities of
32P-labeled proteins with anti-RAG antibodies. (A) Mock
binding reaction mixtures (no 32P-labeled DNA) were diluted
with IP wash buffer, precleared, and immunoprecipitated overnight at
4°C. Immunoprecipitations were performed with antibodies to RAG1
(anti-R1) or RAG2 (anti-R2) or with a control antibody (see Materials
and Methods). Lane 1 contains 10 ng of each RAG protein. Reaction
mixtures in lanes 6 to 8 were adjusted to 0.1% SDS and incubated at
68°C for 10 minutes before dilution with cold IP wash buffer. Sizes
of the protein markers are indicated in kilodaltons. It is unclear why
RAG2 is not coprecipitated more efficiently in lane 2 (compare lanes 2 and 3). We note that the RAG1 antibody used recognizes epitopes within
the region of RAG1 that interact with RAG2 (25) and is a
different antibody than that used previously for coimmunoprecipitation
studies of RAG1 and RAG2 (18). (B) Immunoprecipitations of
cross-linking reactions, with wild-type 12-RSS substrates with IdU at
the indicated positions, after nuclease treatment. The antibodies used for
immunoprecipitation are indicated above each lane. (C)
Immunoprecipitations of cross-linking reaction mixtures with anti-RAG2
antibodies. Lanes 1 to 4 use the same 23-RSS substrates and mutants as
described in Fig. 5A, and lanes 5 to 6 use the 12-RSS C3t substrate and
mutant used in Fig. 5B. Note that the immunoprecipitated samples shown
here are enriched for RAG2 protein over the nonenriched samples in Fig.
5B. Because the efficiency of cross-linking to RAG1 is much higher than
that to RAG2, small amounts of background RAG1 are visible in some
lanes.
|
|
By using this direct immunoprecipitation assay and 12-RSS substrates,
the
32P-labeled band which migrates at ~100 kDa, the
expected size of
the truncated RAG1 protein, was brought down with
anti-RAG1 antibodies
(Fig.
8B, lanes 1 and 4) and at a background level
with anti-RAG2
antibodies (compare lanes 2 and 5 to lane 3). This
confirms that
the upper cross-linked band is RAG1 protein. The 55-kDa
RAG2-sized
band precipitated with anti-RAG2 antibodies (lane 2, white
triangle)
and not RAG1 antibodies or control antibodies (lanes 1 and 3)
in cross-linking reactions with C-1b modified substrate. This
precipitated product was not visible with the H2b modified substrate
(lane
5).
We then performed anti-RAG2 immunoprecipitations with 23-RSS
substrates, their corresponding mutants, and with 12-RSS substrates
with IdC at the H3t position (Fig.
8C). This confirmed RAG2
cross-linking
to the C-1b but not to the H2b positions (lanes 1 and 3).
The
labeled RAG2 product was also visible when IdC was incorporated
at
the H3t position (lane 5), but only when the heptamer was intact
(lane
6). There was a significant amount of
32P-labeled RAG1
protein that precipitated with anti-RAG2 antibodies
in these
experiments despite our denaturation-renaturation protocol
(Fig.
8B,
lane 2, and Fig.
8C, lanes 1 and 3; see legend to Fig.
8).
In summary, the
32P-labeled protein bands observed in
cross-linking reactions with iodosubstituted RSSs have been identified
by specific immunoprecipitation as the RAG1 and RAG2 proteins.
RAG1
cross-links to the C-1b, H2b, and H3t positions, while RAG2
cross-links
weakly to the C-1b and H3t
positions.
| |
DISCUSSION |
Cross-linking of RAG proteins to RSS DNA near the site of
cleavage.
Here we show, by UV-induced cross-linking, interactions
between the RAG1 protein and both coding-flank and nearby heptamer element DNA. We also show that the RAG2 protein cross-links to a subset
of the same positions. Several facts suggest that these interactions
are significant for RAG-mediated RSS cleavage. First, they are sequence
specific, requiring both heptamer and nonamer elements (Fig. 3).
Second, they are stable to challenge by nonspecific competitor DNA
(Fig. 4). Third, cross-linking appears to be site specific, occurring
efficiently only when the iodonucleotide is placed at the C-1b, H2b,
and H3t positions or at the C-1t position with an unpaired coding flank
(although the absence of cross-linking at the other positions examined
must be interpreted cautiously). Fourth, efficient binding and
cross-linking depend upon the presence of a divalent cation (Fig. 2).
Recent studies have suggested a direct role for divalent cations in
guiding the DNA binding activities of RAG1 and RAG2 at the
heptamer-coding flank border (37). Cross-linking can
be detected in the presence of Ca2+, which does not
support nicking or hairpin formation, suggesting that the observed
interactions are not exclusively associated with catalysis.
Ca2+ supports DNA binding, and Ca2+-containing
RAG-DNA complexes can undergo cleavage when Mg2+ or
Mn2+ is added (14, 15). Immunoprecipitation
analysis revealed that both full-length and nicked top-strand DNAs are
found associated with cross-linked bottom-strand DNA (data not shown).
Thus, nicking is not required for cross-linking; neither is catalysis
in general. However, conditions that favor catalysis, such as an
unmutated heptamer, an unpaired coding flank, and the presence of
Mg2+, promote interactions that result in cross-linking.
Importantly, these results establish for the first time that both RAG1
and RAG2 proteins specifically interact with the DNA near the site of
cleavage and reveal four nucleotides that the RAG proteins contact closely.
How is the heptamer element recognized?
The three-dimensional
placement of the IdU and IdC groups that cross-link to the RAG proteins
suggests that RAG1 and RAG2 make contacts with the nonamer-distal
portion of the heptamer DNA in the major groove, with individual sites
of interaction marking a broad arc around the double helix (modeled in
Fig. 9A). Our observation that some
iodination positions, especially those near the site of cleavage,
inhibit cleavage also points to major groove recognition. The
palindromic sequence of the heptamer element (CAC//GTG) had raised the
possibility that the heptamer might be recognized symmetrically, with a
twofold axis through the fourth base pair. This possibility is unlikely
given our failure to detect cross-linking at the H5b and H6t positions
at intensities similar to those observed at the H3t and H2b positions.
Asymmetric recognition of the two halves of the heptamer is also
consistent with the higher conservation and greater functional
importance of the first three nucleotides of the heptamer (13, 30,
31). How does the nonamer-proximal half of the heptamer
contribute to recognition and cleavage of a RSS? The last 4 bp of the
heptamer element have been shown to contribute to RAG1 binding, as
shown by methylation interference and cleavage competition assays
(29, 31, 46). In addition, the purine-pyrimidine alteration
of the consensus heptamer might help to stabilize altered DNA
structures that have been observed at CACA stretches (48).
Indeed, a large number of biophysical and biochemical experiments have
established that (CA)n sequences such as the
heptamer element are more bendable and less thermally stable than other
DNA sequences (6, 9, 12) and that they are capable of
adopting a variety of conformations (40, 47, 48). This
malleability may be an important part of heptamer recognition by RAG
proteins (2, 46) because of the considerable distortion of
the DNA backbone necessary for hairpin formation.
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FIG. 9.
Map of cross-linking positions on heptamer-coding flank
DNA. (A) Three-dimensional model developed by using MOLMOL
(16a). Colors: green, pyrimidine base that when iodomodified
cross-links to RAG1; purple, pyrimidine base that when iodomodified
cross-links to RAG1 and RAG2; light blue, position that cross-links
only when the base is an unpaired iodomodified pyrimidine; red, iodine;
orange, target phosphate for nicking; yellow, target phosphate for
hairpin formation; medium blue, other DNA, represented for simplicity
as standard B-form DNA. (B) Linear model of heptamer-coding flank
sequence, with a color scheme as in panel A. Purine bases necessary for
hairpin formation (31) are underlined.
|
|
Unpairing of heptamer-coding flank DNA contributes to the efficiency of
hairpin formation (
7,
31), and our results show
that such
unpairing leads to a new cross-linking interaction between
RAG1 and
coding-flank DNA, immediately adjacent to the site of
cleavage
(position C-1t; Fig.
7A). In a fully paired DNA substrate,
additional
protein-DNA contacts would likely be necessary to drive
the
energetically unfavorable process of unpairing of coding-flank
residues. We speculate that the interaction at C-1t may represent
such
an
interaction.
Stoichiometry and interactions in higher-order RAG-DNA
complexes.
The stronger and more widespread cross-linking to RAG1
protein, compared to RAG2 protein, indicates that RAG1 is the major player in recognizing the heptamer element. The detection of RAG1-DNA interactions at the nonamer-distal portion of the heptamer raises questions about the stoichiometry of the RAG protein-DNA complex. The
distance between the position 1 of the coding flank and position 6 of
the nonamer, modeled on undistorted B-form DNA, is more than 70 Å.
Does the same RAG1 protein molecule bind both the heptamer and nonamer
elements at the same time? While this is a possibility, it is tempting
to think that heptamer and nonamer elements on the same RSS are bridged
by a dimer of RAG1 molecules. Both the zinc-binding domain of RAG1
adjacent to the NBD (32) and the NBD itself (37)
have been identified as capable of dimerization. Furthermore, a
recently identified mutation of RAG1 that impairs NBD dimerization also
reduces the efficiency of DNA cleavage at a single signal, implying
that a multimer of RAG1 is the part of the actively cleaving
protein-DNA complex (53). A number of laboratories have
detected heterogeneous RAG-DNA complexes that differ in their
electrophoretic mobilities (2, 37, 46, 53). The
stoichiometries of these different RAG-DNA complexes have not been
directly determined. The recent identification of one of these
complexes as a two-signal synaptic complex (14) may enable
the definition of protein-DNA contacts that are specific for a 12/23
pair of signals. One might expect, from comparisons with Mu transposase
(17, 27), that in a two-signal RAG-DNA complex, the pattern
of protein contacts would extend farther over the heptamer and coding
flank than in a one-signal complex.
Contributions made by RAG2 protein: organization of the active
site?
Cross-linking to RAG2 is always accompanied by cross-linking
to RAG1. This suggests that RAG1 and RAG2 interact closely near heptamer-element DNA. Cross-linking to RAG2 can be detected at two
positions which in undistorted B-form DNA are separated by 14 Å (Fig.
9A), raising the possibility that RAG1 and RAG2 form an extended
interface in the vicinity of the heptamer. Alternatively, more than one
RAG2 molecule may contact each RAG1 molecule, as has been suggested on
the basis of immunoprecipitation data (18, 42). The
more-restricted and less-efficient cross-linking to RAG2 that we
observe may indicate a weak or limited set of DNA contacts and/or
contacts via amino acids that are unsuitable for cross-linking. We note
that we have not been able to detect efficient cross-linking to the
C-1b or H2b positions with high concentrations of bacterially produced,
catalytically active RAG1 protein in the absence of RAG2, despite the
fact that this RAG1 protein exhibits specific RSS binding
(32a). One reason for this might be that without the
influence of RAG2, the part of RAG1 protein that makes contacts with
the heptamer-coding flank border is disordered. We speculate that RAG2
alters the structure of this portion of RAG1 and that the bulk of RAG2
is located away from RSS DNA. The somewhat more extended pattern of
binding interference and protection in the spacer region when RAG2 is
present is consistent with this idea (46).
It is provocative that the strongest cross-linking of RAG2 occurs at
the nucleotide position nearest to the target phosphate
for hairpin
formation, suggesting that both RAG1 and RAG2 play
a role in forming
the catalytic active site. Further investigations
of the organization
of the active site require identification
of amino acid residues, such
as aspartates or glutamates, that
would coordinate divalent cations and
whose mutation would disrupt
catalysis but not formation of a
RAG1-RAG2-RSS DNA complex. At
this point the possibility that either
RAG1 or RAG2 contributes
catalytic amino acid residues remains open. It
is also formally
possible that separate active sites, analogous to the
sites contained
in the proteins TnsA and TnsB in the Tn
7
system (
22,
38),
mediate nicking and hairpin formation.
Sequencing of peptide fragments
of RAG1 and RAG2 cross-linked to RSS
DNA or other mapping techniques
(
21) might give hints
leading to the identification of amino
acid residues involved in
catalysis.
| |
ACKNOWLEDGMENTS |
We thank Chia-Lun Tsai for assistance with RAG protein
purification, Karla Rodgers for bacterial RAG1 protein and instruction on NAMOT and MOLMOL, the Schatz lab for patience with dimmed lights, Tad Koch for initial advice on cross-linking, and Eugenia Spanopoulou and Sankar Ghosh for helpful comments on the manuscript. We thank the
W. M. Keck Foundation Biotechnology Resource Laboratory at Yale
University for rapid oligonucleotide synthesis and the National Cell
Culture Center (Minneapolis, Minn.) for large-scale F2A1 culture.
Q.M.E. was supported by a predoctoral fellowship from the National
Science Foundation. I.J.V. was supported by an INSERM postdoctoral fellowship. This work was supported by Public Health Service grant AI-32524 from the National Institutes of Health. D.G.S. is an associate
investigator of the Howard Hughes Medical Institute.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Section of
Immunobiology, Yale University School of Medicine, 310 Cedar St., P.O.
Box 208011, New Haven, CT 06520-8011. Phone: (203) 737-2255. Fax: (203)
737-1764. E-mail: david.schatz{at}yale.edu.
| |
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Molecular and Cellular Biology, May 1999, p. 3788-3797, Vol. 19, No. 5
0270-7306/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
