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J. Biol. Chem., Vol. 275, Issue 50, 39671-39677, December 15, 2000
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From the Department of Cancer Immunology and AIDS, Dana-Farber
Cancer Institute and the Department of Pathology, Harvard Medical
School, Boston, Massachusetts 02115
Received for publication, March 28, 2000, and in revised form, September 22, 2000
Retroviral integration is mediated by viral
preintegration complexes (PICs), and human immunodeficiency virus type
1 (HIV-1) PICs treated with high salt lose their in vitro
integration activity. Barrier-to-autointegration factor (BAF) is a host
protein that efficiently restores PIC activity, but the mechanism(s) by
which BAF participates in HIV-1 integration remains largely unknown. Here we developed a gel shift assay to study BAF DNA binding, and
analyzed 14 mutant proteins containing substitutions of conserved residues for binding and PIC reconstitution activities. Although wild-type BAF efficiently bound double-stranded DNA, binding to single-stranded DNA, RNA, or an RNA/DNA hybrid was not detected, suggesting that BAF associates with retroviral cDNA relatively late
during reverse transcription. Although some of the BAF mutant proteins
efficiently bound DNA, others were defective for binding. Mutants that
bound DNA efficiently reconstituted HIV-1 integration, even though in
one case binding was just 0.2% of wild-type BAF. Although misfolded
mutants did not reconstitute integration, a structurally intact DNA
binding-defective mutant displayed partial activity at high BAF
concentration. We therefore conclude that both BAF protein structure
and its DNA binding activity play roles in reconstituting HIV-1
integration in vitro.
Integration of a cDNA copy of the retroviral RNA genome into a
host cell chromosome is essential for efficient gene expression and
viral replication. The key viral players in integration are the
integrase protein, which enters cells as a virion component, and the
DNA attachment site, which is comprised of sequences at the ends of the
linear cDNA made by reverse transcription. In vivo,
integration is mediated by large nucleoprotein complexes, termed
preintegration complexes
(PICs),1 that are derived
from the cores of infecting virions. PICs isolated from infected cells
can integrate their endogenous cDNA into an added target DNA
in vitro (for a review, see Ref. 1).
In addition to the viral integrase, recent studies implicate
host-encoded proteins as important cofactors in retroviral cDNA integration. Moloney murine leukemia virus (MMLV) and human
immunodeficiency virus type 1 (HIV-1) PICs treated with elevated
concentrations of salt and subsequently purified by size exclusion
chromatography and nonionic density gradient centrifugation lost their
normal intermolecular integration activity (2, 3). Adding back protein
extracts of uninfected host cells to such salt-depleted PICs restored
normal integration activity, showing that host proteins play essential
roles in retroviral PIC function in vitro (2-5). Two
different proteins, HMG I(Y) (4, 5) and the barrier-to-autointegration factor (BAF) (6), were identified by purifying host cell extracts and
assaying for reconstitution of salt-disrupted PIC integration activity
in vitro. Both HMG I(Y) and BAF display reconstitution activity following their expression and purification from
Escherichia coli (3-7). For both MMLV and HIV-1,
recombinant BAF was about 500-fold more active than recombinant HMG
I(Y) at reconstituting the integration activity of salt-washed PICs (3,
5, 7). BAF was not detected in MMLV virions (2, 6), leading to models
wherein it associates with retroviruses during the processes of reverse
transcription and PIC formation in infected cells (3, 6).
BAF interacts with various components of the inner nuclear membrane,
including lamina-associated polypeptide 2 (9) and emerin (10),
suggesting that one of its normal physiological roles is aiding
reorganization of postmitotic nuclei (9, 10). BAF is an 89-residue
nonspecific DNA binding protein that exists as a dimer in solution (6,
8). Although DNA binding is proposed to be important for BAF function
in retroviral cDNA integration (6), this has not been
experimentally investigated. Here, we established a gel mobility shift
assay to study the DNA binding activity of recombinant human BAF. We
then engineered recombinant mutant proteins containing substitutions of
conserved amino acid residues. Purified mutant proteins were assayed
for DNA binding activity by gel mobility shift and reconstitution of
integration activity to salt-washed HIV-1 PICs. Each mutant that bound
DNA by gel shift efficiently reconstituted HIV-1 integration activity. Because only structurally intact DNA binding-defective mutants displayed PIC reconstitution activity at high BAF concentration, we
conclude that the native structure of the BAF protein in addition to
its DNA binding function plays a role in reconstituting HIV-1 integration activity in vitro.
Polyacrylamide Gel Mobility Shift Assay--
A double-stranded
30-base pair (bp) oligonucleotide substrate was prepared for gel
mobility shift as follows. The 5'-end of 5'-GAATCCTAACTGGGCGGAGTTATGCTGGTG-3' was labeled with 32P
using T4 polynucleotide kinase (Amersham Pharmacia Biotech) as
described previously (11). Following heat inactivation of the kinase,
the complementary single strand was annealed as described (11).
Unincorporated nucleotide was removed by passage over a P6 spin column
(Bio-Rad) as described previously (12). For binding assays employing
either single-stranded RNA or an RNA/DNA heteroduplex, a synthetic 30 base RNA (5'-CAGGGACAAGCCCGCGGUGACGAUCUCUAA-3') was end-labeled,
divided into two fractions, and either purified by spin column or first
annealed to its cDNA strand prior to spin column chromatography.
DNA binding reactions (50 µl) contained 2% glycerol, 0.01% Triton
X-100, 0.5× TBE (44.5 mM Tris base, 44.5 mM
borate, 1 mM EDTA, pH 8.3), 0.001% bromphenol blue, and 5 nM nucleic acid substrate. BAF was added last, and DNA
binding proceeded for 15 min on ice. Binding reactions were separated
on native 5% polyacrylamide gels containing 0.5× TBE. Gels were
pre-electrophoresed in 0.5× TBE for 1 h prior to loading, and
electrophoresis continued for approximately 2 h until the
bromphenol blue dye approached the bottom of the gel. Dried gels were
exposed for autoradiography, and protein·DNA complex formation
was quantified using either densitometry (IS-1000 Digital Imaging
System) or phosphorimaging (PhosphorImager, Molecular Dynamics). DNA
binding activity was calculated as the percentage of wild-type
protein·DNA complex formation at 50 nM protein.
Activities of defective mutants were similarly calculated, with the
addition that the percentage of wild-type complex formation was divided by the -fold increase in protein concentration over 50 nM.
Site-directed Mutagenesis--
Mutagenesis was performed using
the Stratagene QuikChange mutagenesis kit as specified by the
manufacturer. The template for mutagenesis was pET15bhBAF (8), a
generous gift of Dr. Robert Craigie. This plasmid encodes a 20-residue
peptide with a hexahistidine tag (His-Tag) fused to the amino terminus
of BAF. The His-tag, which facilitates purification by metal-chelating
affinity chromatography (6, 8, 11, 13), was removed from BAF prior to
the majority of the in vitro DNA binding and integration
assays (see below). The presence of mutations, as well as the absence
of off-site changes, were confirmed in mutant plasmids by dideoxy sequencing.
Protein Expression and Purification--
Wild-type and mutant
BAF proteins were expressed in Escherichia coli and purified
essentially as described previously (8). In brief, protein expression
vectors were transformed into BL21(DE3) pLysS (Novagen), and cells were
grown in 500 ml of Terrific broth containing 100 µg/ml ampicillin at
37 °C until the optical density at 600 nm was approximately 0.8. Protein expression was induced by adding
isopropyl-1-thio-
BAF was purified using fast protein liquid chromatography (Amersham
Pharmacia Biotech). A 2-ml column of chelating Sepharose Fast Flow
(Amersham Pharmacia Biotech) was precharged with nickel and
equilibrated with buffer A essentially as described previously (11).
The cell extract was loaded, and the column was washed with
approximately 50 ml of buffer A and then with a similar volume of
buffer A containing 20 mM imidazole. The column was
developed using a linear gradient of 20 to 600 mM imidazole
in buffer A. BAF-containing fractions identified by denaturing
polyacrylamide gel electrophoresis were pooled, and EDTA was added to
the final concentration of 10 mM. Pooled fractions were
dialyzed against buffer B (50 mM potassium phosphate, pH
6.5, 200 mM NaCl, 10 mM EDTA, 5 mM
The His-tag was removed by cleavage with thrombin. Thrombin was added
to the final concentration of 20 National Institutes of Health
units per mg of BAF, and cleavage proceeded for 40 min at room
temperature. Thrombin was removed from solution by adsorption to a
benzamidine-Sepharose 6B column (Amersham Pharmacia Biotech) as
described previously (11). The column eluate was dialyzed against
buffer C (20 mM Tris-HCl, pH 7.0, 10% glycerol, 150 mM NaCl, 5 mM DTT, 0.1 mM EDTA),
and the concentration of thrombin-cleaved BAF in the clarified
dialysate was calculated using an extinction coefficient of 1.24 ml·mg HIV-1 Infection, Isolation of PICs, Salt Stripping, and
Integration Assays--
SupT1 and MOLTIIIB cells were grown in RPMI
medium supplemented with 10% fetal calf serum. SupT1 cells were
infected by coculture with chronically infected MOLTIIIB cells as
described previously (3, 15). PICs were isolated, incubated with 1.2 M KCl for salt stripping, purified by spin column
chromatography, and then by Nycodenz gradient centrifugation as
described (3, 15). Integration and PIC reconstitution assays using 100 or 500 ng of purified BAF protein were performed, separated on agarose
gels, and analyzed by Southern blotting also as described previously (3, 15). Southern blots were processed for autoradiography, and
integration activity was quantified by densitometry or by phosphorimaging. Integration activity was calculated as the percentage of the 9.7-kilobase (kb) HIV-1 cDNA substrate that was converted into the 15.1-kb integration product. Mutant BAF reconstitution activity was calculated as the percentage of wild-type BAF activity. Mutants were analyzed in at least two independent experiments.
Gel Filtration Chromatography--
The multimeric state of
recombinant BAF was analyzed by fast protein liquid chromatography
using a Superdex 200 HR 10/30 column (Amersham Pharmacia Biotech). The
column was calibrated by analyzing the elution profiles of molecular
mass standards (Bio-Rad) in buffer D (20 mM Tris-HCl, pH
7.5, 1 mM EDTA, 50 mM KCl, 6% sucrose, 1 mM DTT). The retention times of BAF (0.3-0.4 mg) were
analyzed under the same conditions. The dimeric and higher order
multimeric species of wild-type BAF were collected separately and
concentrated by ultrafiltration using a Centricon 3 concentrator
(Amicon). Concentrated samples were dialyzed against buffer C prior to
gel mobility shift assays and gel filtration chromatography.
Circular Dichroism (CD)--
The CD spectra of BAF proteins (0.3 mg/ml) in buffer E (50 mM potassium phosphate, pH 7.5, 50 mM KCl, 0.1 mM EDTA, 1 mM DTT, 5%
glycerol) were recorded on an AVIV 62DS spectropolarimeter. Measurements in the far-UV region (260-190 nm) were made using a
0.1-cm path length cell.
DNA Binding Activity by Gel Mobility Shift--
BAF is a
nonspecific host cell DNA binding protein (6) that efficiently restores
intermolecular integration activity to salt-stripped MMLV (6) and HIV-1
(3) PICs in vitro. A polyacrylamide gel mobility shift assay
was established to investigate the nucleic acid binding properties of
recombinant human BAF purified following its expression in E. coli. A 30-bp oligonucleotide of random sequence was chosen as the
substrate for DNA binding. Preliminary experiments revealed that the
presence of low concentrations of glycerol and nonionic detergent in
the binding buffer, and electrophoresis at room temperature as opposed
to 4 °C, yielded two protein·DNA complexes with distinct
electrophoretic mobilities (Fig.
1A and data not shown).
Although a protein concentration of 10 nM BAF monomer was
sufficient for complex formation (Fig. 1A, lane
2), 50-100 nM BAF retarded the mobility of virtually
all of the DNA substrate, yielding some aggregated material in the well
of the gel (Fig. 1A, lane 5, and 1B,
lane 3). We previously determined that BAF concentrations in
the range of 5 to 50 nM efficiently reconstituted the
integration activity of salt-depleted HIV-1 PICs in vitro
(3). Thus, we conclude that the protein·DNA complexes observed by gel
mobility shift are relevant to BAF's cofactor role in HIV-1
integration. Increasing the concentration of BAF in the DNA binding
reaction yielded a series of novel species, most of which displayed
slower electrophoretic mobilities than the two complexes that were
observed at lower concentrations (Fig. 1A, compare
lanes 6 and 7 to lanes 2-4). Because
we previously determined that BAF concentrations greater than
approximately 250 nM inhibited functional reconstitution of
salt-stripped PICs (Ref. 3 and data not shown), we speculate that the
protein·DNA aggregates and novel complexes observed by gel mobility
shift at high BAF concentrations are not relevant to HIV-1
integration.
To investigate whether the observed protein·DNA complexes were due to
the DNA binding activity of human BAF and not potentially contaminating
E. coli proteins, DNA binding reactions were repeated using
purified BAF protein still containing the His-tag. Because the His-tag
was removed as a 17-residue thrombin cleavage product, we reasoned that
the larger size of the His-tag protein might yield protein·DNA
complexes displaying slower electrophoretic mobilities than those
formed with the proteolyzed protein. Although the presence of the
His-tag yielded a minor novel species (Fig. 1B, lane
4), it is clear that it retarded the mobility of the two
protein·DNA complexes that formed using thrombin-cleaved BAF (Fig.
1B, compare lanes 4 and 5 to
lanes 2 and 3). We therefore conclude that the
protein·DNA complexes observed by gel mobility shift are due to the
DNA binding activity of human BAF protein. The stoichiometries of BAF
to DNA in the different nucleoprotein complexes were not investigated.
Only uninfected cell extracts, and not extracts of purified virions,
restore intermolecular integration activity to salt-washed MMLV PICs
(2). Western blotting also failed to detect BAF in MMLV virions (6),
leading to the hypothesis that BAF is recruited to nascent cDNA
during reverse transcription and PIC formation in the cytoplasm of
infected cells (6). Reverse transcription is a multistep process, and
various nucleic acid species, including single-stranded DNA and RNA/DNA
hybrids, are generated from single-stranded RNA templates en route to
the linear double-stranded cDNA product (16). To investigate
whether BAF may have binding affinity for either the RNA template or
these DNA synthesis intermediates, single-stranded RNA, single-stranded
DNA, and an RNA/DNA hybrid were analyzed in the gel mobility shift
assay. BAF did not show detectable levels of binding to any of these
nucleic acid substrates (data not shown). The absence of detectable
binding to single-stranded RNA is consistent with the absence of BAF in
virions (2, 6), and the lack of binding to the RNA/DNA hybrid and
single-stranded DNA implies that BAF associates with nascent cDNA
relatively late in the reverse transcription process.
Mutagenesis Strategy and Mutant BAF DNA Binding Activity--
At
the outset of this project, we had knowledge of the primary sequences
of mouse, human, and Caenorhabditis elegans
BAF.2 Due to the absence of
structural data for BAF at this point, amino acid residues were chosen
for mutagenesis on the basis of absolute conservation across these
three species. Forty-seven amino acids of the 89-residue protein
(52.8% identity) are invariant in an expanded alignment that includes
rat and zebrafish, and 10 of the 11 residues we chose for mutagenesis
are identical across these five species (Fig.
2). Six of the 47 invariant residues, Lys-6, His-7, Lys-18, Lys-41, Lys-54, and Lys-64, are positively charged and therefore could potentially interact nonspecifically with
DNA through the phosphodiester backbone. Four of these charged residues, Lys-6, Lys-18, Lys-41, and Lys-54, were included in our
mutant set (Fig. 2). Hydrophobic residues Ile-26, Leu-50, and Trp-62
were chosen for their potential roles in BAF·BAF protein interactions, and Pro-14, Tyr-43, and Cys-80 were targeted because these were the only invariant representatives of these residues in the
sequence alignment (Fig. 2). The double mutant C80A/R82A, inadvertently
generated during mutagenesis, was examined alongside the other single
amino acid BAF mutant proteins.
Fourteen different mutant proteins were purified following expression
in E. coli (Table I).
Preliminary DNA binding experiments analyzed mutants at 50 nM protein, because this concentration of wild-type BAF
shifted the majority of the double-stranded DNA substrate (Fig.
1A, lane 4, and 1B, lane
3). Five of the mutant proteins, P14A, W62A, K41A, K53A, and K54A,
supported 20-100% of the wild-type level of DNA binding activity
(Fig. 3A and Table I).
Although the binding of P14A to DNA was indistinguishable from the
activity of wild-type BAF (Fig. 3A, compare lane
3 to lane 2), W62A bound DNA about one-half as
efficiently as did wild-type in repeated experiments (Fig.
3A, lane 7, and Table I). K41A, K53A, and K54A
each bound DNA about one-third as efficiently as did wild-type BAF
(Fig. 3A and Table I). Thus, two of the invariant lysine
residues that we targeted, Lys-41 and Lys-54 (Fig. 2), are not
essential for BAF DNA binding activity under these conditions. Similar
to the results reported here, K53E was previously reported to display
reduced DNA binding activity (8). In contrast, K54E did not support
detectable levels of DNA binding (8). It is possible that substituting
Glu for Lys-54 had a negative impact on the overall structure of the
BAF dimer as compared with the less disruptive Ala residue tested
here.
Four of the BAF mutants, Y43A, L50A, C80A, C80A/R82A, displayed 5-20%
of the wild-type level of DNA binding activity (Fig. 3B and
Table I). In repeated experiments, C80A/R82A supported the formation of
only the more slowly migrating of the two protein·DNA complexes
observed using wild-type BAF (Fig. 3B). K18A also supported formation of just the more slowly migrating nucleoprotein complex, but
in this case DNA binding activity was only about 0.2% the level of
wild-type BAF (Fig. 3B and Table I). This is the first report that invariant residue Lys-18 plays a role in the binding of BAF
protein to DNA.
Four of the mutant proteins, K6A, I26K, I26A, and L50K, failed to
support detectable levels of DNA binding, even when assayed at the
elevated protein concentration of 1.25 µM (Table I). One of these mutants, K6A, carries Ala in place of an invariant Lys residue
(Fig. 2), and K6E was previously reported defective for DNA binding
(8).
Gel Filtration Analysis of BAF Proteins--
The results of the
previous experiments revealed that, although some of the recombinant
BAF mutant proteins bound DNA similarly to wild-type, others were
significantly reduced or completely defective for DNA binding activity
(Table I). The observed DNA binding defects could be due to either
protein structure changes caused by the mutations, removal of side
chains critical for binding without perturbing the overall structure of
the globular protein, or a combination of both of these reasons. To
address this, wild-type BAF and mutants defective for DNA binding were
analyzed by gel filtration chromatography and CD spectroscopy (see
below). Mutants suffering structural changes would be expected to
display gel filtration profiles and/or CD spectra altered from those of
the wild-type protein.
Wild-type BAF eluted as two distinct populations from the gel
filtration column, the smaller of which displayed a retention time
slightly faster than that of a 17-kDa molecular mass standard (Fig.
4). Because thrombin-cleaved BAF has a
predicted mass of 10.3 kDa, it appears that this species is dimeric
BAF. Consistent with this interpretation, recombinant human BAF
analyzed by sedimentation equilibrium and gel filtration was previously
reported as dimeric (8). The larger BAF species eluted from the column
between 158- and 44-kDa mass standards (Fig. 4). Assuming that this
species is a higher order multimer of dimeric BAF, it appeared by this analysis to be either hexameric or octameric. The precise number of BAF
protomers in this higher order multimer was not investigated further.
Mutant BAF proteins that displayed greatly reduced DNA binding
activity, as well as those completely devoid of DNA binding, were
analyzed next. Although two of the mutants that displayed reduced
binding, Y43A and C80A/R82A, yielded primarily dimeric protein (Fig. 4
and Table I), two of the DNA binding-defective proteins, I26A and I26K,
yielded mostly the higher order multimer (Fig. 4 and Table I). Based on
the gel filtration profiles of these four mutant proteins, we next
tested whether DNA binding required pre-existing BAF dimers in
solution. Column fractions containing dimers and higher order multimers
of wild-type BAF were collected separately, concentrated by
ultrafiltration, and re-analyzed by gel filtration and gel mobility
shift. Wild-type dimers and higher order multimers retained their
starting multimeric state during this second round of column
chromatography, showing that the different multimeric forms were
relatively stable (data not shown). Dimers and higher order multimers
displayed similar levels of DNA binding activity, each forming both of
the previously noted wild-type protein·DNA complexes in native
polyacrylamide gels (data not shown). Thus, each of the multimeric
forms probably contributes to the DNA binding activity of the wild-type
protein, and the lack of I26A and I26K dimers does not per
se explain the DNA binding-defective phenotype of these mutant
proteins. The results of CD spectroscopy suggest that these mutants
were defective due to alterations in protein structure (see below).
The gel filtration profile of L50K differed significantly from the
wild-type pattern (Fig. 4), suggesting that this mutation altered the
ability of BAF to properly multimerize in solution. In contrast, L50A,
C80A, and K18A, each of which supported reduced DNA binding activity,
as well as the DNA binding-defective mutant K6A, yielded the wild-type
gel filtration pattern of dimers and higher order multimers (Table I).
Because L50A contained the wild-type ratio of BAF multimers, we
conclude that the L50K multimerization defect is due to the presence of
a disruptive Lys residue, as opposed to the absence of the Leu normally
at this position. This interpretation is consistent with the location
of Leu-50 at the dimer interface in the solution structure of the BAF
dimer (8). Unlike the Lys substitution, substituting Ala for Leu-50
apparently did not grossly affect BAF·BAF protein interactions.
Tyr-43 and Lys-53 are also located at the dimer interface (8),
suggesting that the 3- to 10-fold reductions in DNA binding activity
observed with Y43A, L50A, and K53A (Fig. 3 and Table I) could be due to small changes in dimer stability that were undetectable by gel filtration chromatography. The reduced DNA binding activity of K53E was
likewise suggested to be due to an alteration in dimer stability
(8).
CD Spectra of Wild-type and BAF Mutant Proteins--
Three of the
DNA binding-defective mutants, I26A, I26K, and L50K, stood out because
each of these lacked dimeric BAF as detected by gel filtration
chromatography (Fig. 4 and Table I). Thus, CD spectroscopy was used to
further analyze the structure of these mutant proteins, as well as the
other DNA binding-defective mutant, K6A. Wild-type BAF yielded a CD
spectrum typical of
L50K also displayed a CD spectrum with less intense far-UV minima at
208 and 222 nm than did wild-type BAF, although this mutant appeared
more similar to wild-type than did either I26A or I26K (Fig. 5 and data
not shown). L50K apparently suffers both multimerization (Fig. 4) and
protein structure defects (Fig. 5), although it is unclear from these
data whether the inability to properly multimerize precluded proper
folding, or vice versa.
In contrast to the other DNA binding-defective mutants, the CD spectrum
of K6A was very similar to that of wild-type BAF (Fig. 5). K6A appeared
wild-type both by gel filtration (Table I) and CD spectroscopy (Fig.
5), yet was completely defective for DNA binding as detected by gel
mobility shift (Table I). We therefore suggest that Lys-6 is critical
for BAF DNA binding activity, because it directly interacts with DNA.
This conclusion is consistent with a model of BAF DNA binding based on
previous structural and mutagenic data (8). Here, we additionally
measured biophysical properties of purified BAF mutant proteins,
experiments whose results were required to conclude that a particular
DNA binding mutant was defective solely due to its inability to bind DNA.
Restoration of Integration Activity to Salt-stripped HIV-1
PICs--
PICs treated with 1.2 M KCl and subsequently
purified by size exclusion and Nycodenz gradient centrifugation lose
their ability to integrate HIV-1 cDNA in vitro, and
recombinant human BAF efficiently restores in vitro
integration activity to salt-washed HIV-1 PICs (3). The results of gel
mobility shift experiments revealed a variety of DNA binding
phenotypes, which ranged from undetectable levels of DNA binding to the
wild-type level of activity (Fig. 3 and Table I). Each of the purified
mutant proteins was next tested alongside wild-type BAF for PIC
reconstitution activity.
As expected, treating HIV-1 PICs with 1.2 M KCl prior to
purification abolished in vitro integration activity (Fig.
6, A and B, compare
lanes 2 to lanes 1). Also as previously reported
(3), 100 ng of purified protein, corresponding to approximately 40 nM of wild-type BAF, restored about one-half of the level
of integration activity that was present prior to salt-stripping (Fig.
6, A and B, compare lanes 3 to
lanes 1).
Each of the BAF mutants was initially assayed for PIC reconstitution
activity at 40 nM protein. Although each of the mutants that bound DNA by gel mobility shift supported efficient PIC
reconstitution activity under this condition, none of the DNA
binding-defective mutants were active (Fig. 6, A and
B, and Table I). Thus, the DNA binding activity of human BAF
protein is important for its ability to efficiently restore integration
activity to salt-stripped HIV-1 PICs in vitro. Because
mutants C80A/R82A and K18A displayed efficient reconstitution activity
(Table I), we conclude that the ability to form just the larger of the
two nucleoprotein complexes by gel shift is sufficient for BAF function
in the PIC reconstitution assay (Fig. 3B).
Many of the BAF mutants were quantitatively more active in the PIC
reconstitution assay as compared with the gel mobility shift assay
(Table I). This was most evident for K18A: This mutant displayed only
0.2% of the wild-type protein's gel shift activity, yet in repeated
experiments it reconstituted about the same level of HIV-1 integration
activity as did wild-type BAF (Fig. 6A, compare lanes
4 to lane 3, Table I). Thus, efficient DNA binding
activity as measured by gel mobility shift is not required for
efficient reconstitution of salt-stripped HIV-1 PIC integration
activity under these assay conditions.
We next analyzed the BAF mutants that were completely defective for DNA
binding activity using 500 ng of purified protein, which corresponded
to approximately 200 nM BAF, in the PIC reconstitution assay. As previously eluted to, this level of wild-type BAF was somewhat inhibitory for restoring integration activity (Fig.
6C, lane 2); repeated experiments revealed that
200 nM BAF restored about 50% of the level of PIC activity
that was accomplished using 40 nM protein. K18A BAF, which
functioned similarly to wild-type at 40 nM protein, also
acted similar to the wild-type at 200 nM BAF (Fig.
6C, compare lane 6 to lane 2).
Surprisingly, K6A restored about the same level of integration activity
as wild-type BAF using this assay condition (Fig. 6C,
compare lane 4 to lanes 2 and 6).
Unlike K6A, the other DNA binding-defective mutants, I26A, I26K, and
L50K, did not support detectable levels of PIC reconstitution activity
under this condition (Table I and data not shown). Because K6A
displayed a gel filtration profile and CD spectrum similar to wild-type
(Fig. 5 and Table I), and these other defective mutants displayed
altered gel filtration profiles (Fig. 4 and Table I) and CD spectra
(Fig. 5), our results indicate that the native structure of human BAF
protein in addition to its DNA binding function plays a role in
restoring integration activity to salt-depleted HIV-1 PICs in
vitro.
We did not anticipate that mutants K18A and K6A, which displayed gel
shift activities of 0.2% and <0.01% of wild-type BAF, respectively,
would function in the PIC reconstitution assay. It therefore seems
likely that BAF interacts with a component(s) of salt-stripped HIV-1
PICs in addition to the cDNA itself, and this interaction
quantitatively increases reconstitution activity as compared with the
free DNA binding activity that was measured by gel mobility shift.
Although an elevated concentration of K6A was required to detect PIC
reconstitution activity (Fig. 6, B and C), K18A
restored HIV-1 integration activity as efficiently as wild-type BAF
(Fig. 6A and Table I). Thus, the extremely weak DNA binding
activity of K18A appears to make it a significantly better cofactor
than K6A for functional reconstitution of HIV-1 integration. We noticed
that the presence of the amino-terminal His-tag increased the DNA
binding activity of K18A approximately 50-fold over that observed using
the thrombin-cleaved protein (Fig. 7,
compare lanes 2 and 3 to lane 6). This
stimulation is not novel to the BAF protein, as the His-tag was
previously observed to significantly enhance weak DNA binding
activities of certain deletion mutants of recombinant HIV-1 integrase
(18) and the catalytic activities of recombinant HIV-1 RNase H (19). We
suggest that this artificial stimulation of DNA binding activity
correlates with the efficiency of K18A function in the reconstitution
assay and speculate that an analogous stimulation in binding activity may occur when K18A BAF interacts with certain components of
salt-stripped HIV-1 PICs. Consistent with this interpretation, K6A BAF,
which was 5- to 10-fold less active than K18A in the PIC reconstitution assay (Fig. 6 and Table I), remained inactive for DNA binding when
assayed as a His-tag protein (data not shown). We note that the His-tag
did not stimulate either K6A or K18A reconstitution activity at either
40 nM (data not shown) or 200 nM (Fig.
6C) BAF.
How might K6A function in HIV-1 integration in the absence of
detectable DNA binding activity? As eluted to, one possibility is that
protein components present in salt-stripped PICs enhance the binding of
K6A BAF to HIV-1 DNA. Alternatively, K6A might function in the PIC
reconstitution assay without directly binding to DNA. In this scenario,
endogenous BAF's DNA binding activity was required for PIC formation
in vivo, but once formed other protein components in
addition to BAF contribute to the native integration-competent
structure of the PIC. Salt stripping, which inactivates PIC function,
presumably removes BAF protein. We speculate that some aspect of native
PIC structure remains after salt treatment, and K6A BAF, although
unable to bind DNA by itself, partially filled a void left behind by
the endogenous BAF protein and in doing so partially reconstituted PIC
function. Although speculative, this model is consistent with the
observation that viral integrase, which catalyzes the chemical steps of
integration, remains PIC-associated following salt stripping (2-7).
Experiments are currently underway to further define BAF's role in
HIV-1 integration.
We thank R. Craigie for pET15b-hBAF plasmid
DNA and sharing results prior to publication, V. N. Pandey for the
synthetic 30 base RNA oligonucleotide, and H. Chen for a
critical review of the manuscript.
*
This work was supported by National Institutes of Health
Grant AI39394, by funds from the G. Harold and Lelia Y. Mathers
Foundation, and by a gift from the Friends 10.The costs of publication of this
article were defrayed in part by the
payment of page charges. The article
must therefore be hereby marked
"advertisement" in accordance with 18 U.S.C. Section
1734 solely to indicate this fact.
Published, JBC Papers in Press, September 25, 2000, DOI 10.1074/jbc.M002626200
2
R. Craigie, personal communication.
The abbreviations used are:
PIC, preintegration
complex;
MMLV, Moloney murine leukemia virus;
HIV-1, human
immunodeficiency virus type 1;
BAF, barrier-to-autointegration factor;
bp, base pair(s);
His-tag, hexahistidine tag;
kb, kilobase(s);
CD, circular dichroism;
WT, wild-type;
DTT, dithiothreitol.
Both the Structure and DNA Binding Function of the
Barrier-to-Autointegration Factor Contribute to Reconstitution of
HIV Type 1 Integration in Vitro*
ABSTRACT
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS AND DISCUSSION
REFERENCES
INTRODUCTION
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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS AND DISCUSSION
REFERENCES
MATERIALS AND METHODS
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS AND DISCUSSION
REFERENCES
-D-galactopyranoside to the final concentration of 0.4 mM, and cells were harvested 2.5 h post-induction. The cells were resuspended in 30 ml of ice-cold 25 mM HEPES, pH 7.6, 0.1 mM EDTA, frozen in liquid
N2, and thawed on ice overnight. The remaining steps were
performed on ice or at 4 °C. Thawed cells were resuspended in 30 ml
of lysis buffer (20 mM HEPES, pH 7.6, 150 mM
KCl, 2 mM EDTA, 0.01% lysozyme, 0.1% Triton X-100),
incubated for 1 h, and sonicated as described previously (11). The
supernatant was discarded after centrifugation at 40,000 × g, and the insoluble pellet containing BAF was extracted
under denaturing conditions using buffer A (6 M
guanidine-HCl, 150 mM KCl, 20 mM HEPES, pH 7.6, 2 mM -mercaptoethanol, 0.1 mM EDTA, 5 mM imidazole).
-mercaptoethanol), the dialysate was cleared by centrifugation at
19,000 × g for 10 min, and the concentration of BAF in
the supernatant was determined by spectrophotometry using a calculated extinction coefficient (14) of 1.05 ml·mg
1
cm1.
1 cm1. BAF was frozen in liquid
N2 and stored at 
80 °C. Thrombin cleavage yields the
sequence Gly-Ser-His-Met at the amino terminus, where Met is the
predicted terminus of endogenous human BAF (8).
RESULTS AND DISCUSSION
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS AND DISCUSSION
REFERENCES
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Fig. 1.
BAF DNA binding activity by polyacrylamide
gel mobility shift. A, BAF was omitted from the DNA
binding reaction in lane 1; lane 2 contained 10 nM BAF; lane 3, 20 nM; lane
4, 50 nM; lane 5, 100 nM;
lane 6, 250 nM; lane 7, 1.25 µM. The arrows to the left of the gel indicate
the gel well, and the migration positions of the BAF·DNA complexes
(compl) and free DNA substrate (sub).
B, BAF was omitted from the binding reaction in lane
1; the reaction in lane 2 contained 10 nM
BAF; lane 3, 50 nM BAF; lane 4, 10 nM His-tag BAF; lane 5, 50 nM
His-tag BAF. The migration position of the His-tag protein·DNA
complexes are marked HTcompl; other labeling is the same as
in A.
View larger version (11K):
[in a new window]
Fig. 2.
Amino acid sequence alignment and
identification of targeted residues. The primary amino acid
sequences of human (h), mouse (m), rat
(r), zebrafish (zb), and C. elegans
(ce) BAF are shown. The human, mouse, zebrafish, and
C. elegans sequences were from Ref. 8, and the rat sequence
was from Ref. 9. Dashes indicate the positions of amino acid
identity. Residues chosen for mutagenesis are noted above the human
sequence, and the locations of the five 
-helices and
310-helical turn in the BAF solution structure (8) are
noted below the C. elegans sequence. That study revealed
that most of the residues important for dimerization reside in helix 3, and helices 4 and 5 comprise a helix-turn-helix motif important for DNA
binding.
Summary of BAF mutant proteins
View larger version (65K):
[in a new window]
Fig. 3.
DNA binding activity of mutant BAF
proteins. A, BAF was omitted from the reaction in
lane 1. Lanes 2-7 contained 50 nM
wild-type (WT), P14A, K41A, K53A, K54A, and W62A BAF,
respectively. Other labeling is as in Fig. 1. B, Each panel
contains three lanes of the indicated mutant tested at the protein
concentrations 0.05, 0.25, and 1.25 µM; the
triangles above the gels depict this increase in protein
concentration across the lanes. K18A BAF was analyzed on a separate
polyacrylamide gel. Other labeling is as in Fig. 1.
View larger version (18K):
[in a new window]
Fig. 4.
Gel filtration chromatography of wild-type
and mutant BAF proteins. The elution profiles of BAF mutants I26A,
L50K, Y43A, and C80A/R82A are shown relative to the wild-type
chromatogram. Absorbance at 280 nm (A280) was
plotted against relative retention time (Rt).
Wild-type eluted at two predominant positions, which, based on
migration distance relative to molecular mass standards, were
consistent with either hexameric or octameric (indicated by
A) and dimeric (B) BAF. Vertical lines
indicate the retention times of 158-, 44-, and 17-kDa molecular mass
standards.
-helical proteins (Fig.
5), displaying minima at or near far-UV
wavelengths of 208 and 222 nm (17). I26A and I26K each displayed less
minima in these regions, indicating that these proteins contain less overall helical content than does wild-type BAF (Fig. 5 and data not
shown). Changes at Ile-26 apparently perturb BAF protein structure, suggesting that I26A and I26K are defective for DNA binding because of
these alterations. This interpretation is consistent with the location
of Ile-26 in the hydrophobic core of the BAF monomer (8). Presumably,
replacing this conserved residue with either Ala or Lys changed
the hydrophobicity of the core, which altered the native structure of
BAF (Fig. 5). Trp-62 and Cys-80 also form part of the BAF hydrophobic
core (8). Replacing either of these invariant residues with Ala did not
appear to have the same negative impact on BAF protein structure as did
the I26A substitution (Table I).
View larger version (18K):
[in a new window]
Fig. 5.
CD spectroscopy of wild-type and mutant BAF
proteins. The mean residue ellipticity ( 
mre) of the
indicated protein is plotted against wavelength. mre is
in units of 103
deg·cm2·dmol1.
View larger version (48K):
[in a new window]
Fig. 6.
Reconstitution of integration activity to
salt-washed HIV-1 PICs. A, PICs isolated from infected
cells were either treated with 1.2 M KCl (lane
2) or mock treated (lane 1) prior to spin column
chromatography, Nycodenz gradient centrifugation, and in
vitro integration assays. Although wild-type (WT) BAF
was added to the PIC reconstitution assay in lane 3, the
reactions in lanes 4-10 contained the indicated mutant
proteins. B, lane 1 contained gradient-purified
mock treated PICs; lane 2, PICs were treated with high salt
prior to purification; lane 3, wild-type BAF in the
reconstitution assay; lane 4, K6A BAF. The cDNA
substrate band is more intense in lanes 2-4 because 3-fold
more material was loaded in these lanes. C, lane
1 contained salt-stripped PICs; lanes 2-7 contained
the indicated thrombin-cleaved or His-tag (HT) protein at
200 nM BAF. cDNA, 9.7-kb HIV-1 integration substrate;
IP, 15.1-kb integration product.
View larger version (55K):
[in a new window]
Fig. 7.
The His-tag greatly enhances the DNA binding
activity of K18A BAF. Lane 1 contained 50 nM His-tag K18A BAF (HTK18A); lane 2,
250 nM HTK18A; lane 3, 1.25 µM
HTK18A; lane 4, 50 nM His-tag wild-type BAF
(HTWT); lane 5, 50 nM wild-type BAF;
lane 6, 1.25 µM K18A BAF. Note that although
the nucleoprotein complex containing K18A BAF in lane 6 comigrated with the more slowly migrating wild-type complex in
lane 5, the His-tag K18A complex in lanes 2 and
3 comigrated with just the larger of the two complexes
formed using the His-tag wild-type protein (lane 4). Other
labeling is the same as in Fig. 1.
ACKNOWLEDGEMENTS
FOOTNOTES
To whom correspondence should be addressed: Dept. of Cancer
Immunology and AIDS, Dana-Farber Cancer Institute, 44 Binney St., Boston, MA 02115. Tel.: 617-632-4361; Fax: 617-632-3113; E-mail: alan_engelman@dfci.harvard.edu.
ABBREVIATIONS
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INTRODUCTION
MATERIALS AND METHODS
RESULTS AND DISCUSSION
REFERENCES
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Copyright © 2000 by The American Society for Biochemistry and Molecular Biology, Inc.
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