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Molecular and Cellular Biology, July 1999, p. 4866-4873, Vol. 19, No. 7
0270-7306/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
Fanconi Anemia Proteins FANCA, FANCC, and
FANCG/XRCC9 Interact in a Functional Nuclear Complex
Irene
Garcia-Higuera,
Yanan
Kuang,
Dieter
Näf,
Jennifer
Wasik, and
Alan D.
D'Andrea*
Department of Pediatric Oncology, Dana-Farber
Cancer Institute, and Department of Pediatrics, Children's
Hospital, Harvard Medical School, Boston, Massachusetts
Received 22 February 1999/Returned for modification 12 April
1999/Accepted 21 April 1999
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ABSTRACT |
Fanconi anemia (FA) is an autosomal recessive cancer susceptibility
syndrome with at least eight complementation groups (A to H). Three FA
genes, corresponding to complementation groups A, C, and G, have been
cloned, but their cellular function remains unknown. We have previously
demonstrated that the FANCA and FANCC proteins interact and form a
nuclear complex in normal cells, suggesting that the proteins cooperate
in a nuclear function. In this report, we demonstrate that the recently
cloned FANCG/XRCC9 protein is required for binding of the FANCA and
FANCC proteins. Moreover, the FANCG protein is a component of a nuclear
protein complex containing FANCA and FANCC. The amino-terminal region of the FANCA protein is required for FANCG binding, FANCC binding, nuclear localization, and functional activity of the complex. Our
results demonstrate that the three cloned FA proteins cooperate in a
large multisubunit complex. Disruption of this complex results in
the specific cellular and clinical phenotype common to most FA
complementation groups.
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INTRODUCTION |
Fanconi anemia (FA) is an autosomal
recessive disease characterized by developmental abnormalities,
chromosomal instability, cancer susceptibility, and progressive bone
marrow failure (1, 6, 23). Somatic cell fusion studies have
defined at least eight genetic complementation groups (FA-A through
FA-H) (13, 14, 37). The genes corresponding to groups A, C,
and G have been cloned (7, 9, 26, 38), and mutations in
these genes account for greater than 80% of FA patients (3,
13). FANCA, FANCC, and FANCG have no sequence similarity to each
other or to other proteins in the GenBank database, and their
biochemical functions remain unknown.
We have recently determined that the FANCA and FANCC proteins interact
and form a cytoplasmic and nuclear complex in normal cells (21,
29). FANCA and FANCC fail to bind in vitro (18), suggesting that their interaction requires additional adapter proteins or posttranslational modifications. The FANCA/FANCC protein complex is not detected in cell lines derived from FA patients in
groups A, B, C, E, F, G, and H, suggesting that the products of other
FA genes are required for its assembly (44). Consistent with
this model of regulated assembly, phosphorylation of the FANCA protein
correlates with FANCC binding (44). While other proteins
have been shown to bind to FANCC (17, 20), the physiological relevance of these binding interactions remains unknown.
The relationship between the newly cloned FANCG/XRCC9 protein and the
FANCA/FANCC complex remains unknown. The human XRCC9 cDNA was
originally expression cloned by its ability to partially complement the
mitomycin C (MMC) sensitivity of the Chinese hamster ovary (CHO) mutant
UV40 cell line (25). The cDNA was independently cloned by
its ability to complement the MMC sensitivity of an FA-G
patient cell line (7). Mutations were found in the human FANCG/XRCC9 gene in cell lines derived from FA-G patients
(7). Little is known about the function or expression
patterns of the FANCG/XRCC9 protein.
Based on the cellular abnormalities observed in FA, the FA proteins may
regulate any one of several biochemical mechanisms. FA cells are
hypersensitive to cross-linking agents, such as diepoxybutane and MMC,
suggesting a defect in DNA repair. FA cells also exhibit abnormal cell
cycle progression (15, 20) and reduced cell survival
(5, 28, 33, 34, 41). FA cells are hypersensitive to reactive
oxygen radicals as well (12), suggesting a defect in the
removal or repair of oxygen-mediated cellular damage.
The selective sensitivity of FA cells to DNA cross-linking agents
suggests a specific defect in interstrand DNA cross-link repair. Little
is known about the mechanism of DNA cross-link repair in mammalian
cells. Studies with Saccharomyces cerevisiae (11,
27) have demonstrated that cross-link repair requires the
generation and repair of double-strand breaks (DSBs). In mammalian cells, DSB repair is performed by at least two primary, nonoverlapping mechanisms, homologous recombination (HR) and nonhomologous end joining
(NHEJ) (reviewed in reference 4). HR is executed by a family of RAD51 proteins (2, 24). Nonhomologous
recombination is performed by a discrete set of proteins, including the
Ku, DNA-PK, XRCC4, and DNA ligase IV proteins (reviewed in reference 40). Interestingly, recent studies have demonstrated
that FA cells are defective in the fidelity of rejoining of specific
DSBs (8, 36), suggesting that the FA proteins interact with
the HR or NHEJ pathway.
In the current study, we demonstrated that the FANCG protein is
required for the interaction of the FANCA and FANCC proteins. Furthermore, we demonstrated that the FANCG protein is a component of a
large nuclear protein complex containing FANCA, FANCG, and FANCC.
Increasing evidence suggests that this protein complex plays a direct
or indirect role in interstrand DNA cross-link repair and in the
maintenance of normal chromosome stability.
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MATERIALS AND METHODS |
Cell culture.
Epstein-Barr virus-transformed lymphoblasts
were maintained in RPMI medium supplemented with 15% heat-inactivated
fetal calf serum and grown in a humidified 5%
CO2-containing atmosphere at 37°C. FA-G lymphoblast lines
EUFA316 and EUFA143 were provided by Hans Joenje (7, 13).
Simian virus (SV40)-transformed GM6914 FA-A fibroblasts, expressing
various mutant forms of the FANCA polypeptide, have previously been
described (29). GM0637 cells are SV40-transformed
fibroblasts from a normal adult control.
Retroviral infection of FA cell lines.
The indicated pMMP
constructs were transfected by lipofection into 293 producer cells
(human embryonic kidney cells) expressing the vesicular stomatitis
virus G envelope protein (30). Retroviral supernatants were
collected on day 5 following lipofection and contained 4.6 × 106 infectious units/ml, as estimated by Southern blot
analysis of infected NIH 3T3 cells (data not shown).
FA lymphoblasts were infected with the various pMMP supernatants by a
4-h incubation in the presence of 8 µg of Polybrene per ml
(32). Infected cells were washed free of viral supernatant and resuspended in growth medium. After 48 h, cells were
transferred to medium containing puromycin (1 µg/ml). Dead cells were
removed over a Ficoll cushion after 5 days, and surviving cells were
grown under continuous selection in puromycin.
MMC sensitivity assays.
MMC sensitivity assays for
lymphoblasts were performed as previously described (43).
Immunoprecipitation and immunoblotting.
Whole-cell extracts
were prepared in lysis buffer (50 mM Tris HCl [pH 7.4], 150 mM NaCl,
1% [vol/vol] Triton X-100) supplemented with protease inhibitors (1 µg each of leupeptin and pepstatin per ml, 2 µg of aprotinin per
ml, and 1 mM phenylmethylsulfonyl fluoride) and phosphatase inhibitors
(1 mM sodium orthovanadate and 10 mM sodium fluoride).
Immunoprecipitation was performed essentially as previously described
(21), except that the protein A Sepharose-bound immune
complexes were washed with lysis buffer. Immunoblotting was done as
previously reported by using anti-FANCA, anti-FANCC, or anti-FANCG
antiserum or with anti-
-tubulin antibody (Boehringer Mannheim
Biochemicals, Indianapolis, Ind.) or anti-human topoisomerase II
antibody (Calbiochem-Novabiochem Corporation, La Jolla, Calif.).
Cell fractionation.
Cell fractions were obtained by
hypotonic swelling followed by Dounce homogenization as previously
described (21). Prior to immunoprecipitation, both nuclear
and cytoplasmic fractions were adjusted to 150 mM NaCl and 1% Triton
X-100.
In vitro translation.
For in vitro translation of FANCA,
FANCC, and FANCG, the TNT T7 Coupled Reticulocyte System (Promega,
Madison, Wis.) was used in accordance with the manufacturer's
instructions. Proteins were independently synthesized in the presence
of [35S]methionine, subsequently mixed (where indicated),
incubated at 30°C for 30 min, and diluted in lysis buffer prior to immunoprecipitation.
Generation of human FANCG cDNA constructs.
Total
RNA (2 µg) prepared from MG63 cells was used for random-primed
reverse transcription (RT) in a 50-µl reaction mixture. Four
microliters of the RT reaction mixture was subjected to PCR using
primers FANCG (5' primer) (5'GCCGCggatccATGTCCCGCCAGACCACCTCTG3') and FANCG (3' primer)
(5'GCCGCgaattcCTACAGGTCACAAGACTTTGGC3'). The resulting PCR
product of 1,866 bp, encoding the full-length FANCG polypeptide, was
subcloned into the NcoI and BglII sites of
retroviral vector pMMP. The pMMP vector (32) was modified by
ligation with a puromycin resistance cDNA cassette.
Generation of anti-FANCG sera.
The affinity-purified
antiantisera specific for FANCA and FANCC have been previously
described (43) (21). Rabbit polyclonal antisera
against FANCG were generated by using glutathione
S-transferase (GST)-FANCG fusion proteins as antigen
sources. Initially, we used RT-PCR and the full-length FANCG open
reading frame cDNA as the template in order to amplify a cDNA fragment
corresponding to the carboxyl-terminal region of the FANCG protein. A
3' fragment was amplified by using primers
5'GCCGCagatctAGGCTCTATCAGCAACTGGGG3' and FANCG (3' primer).
The resulting PCR product of 987 bp, encoding the carboxyl-terminal 329 amino acids of the FANCG polypeptide, was digested with
BglII/EcoRI and subcloned into the
BamHI/EcoRI sites of plasmid pGEX2T (Pharmacia).
A GST-FANCG (C-terminal) fusion protein of the expected size (66 kDa)
was expressed in Escherichia coli BL21, purified over
glutathione-Sepharose, and used to immunize New Zealand White rabbits.
FANCG-specific immune antisera were affinity purified over AminoLink
Plus columns (Pierce) loaded with the GST-FANCG (C-terminal) fusion protein.
Immunofluorescence microscopy.
Immunofluorescence microscopy
of human fibroblasts was performed as previously described
(29).
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RESULTS |
Expression of FANCG restores the binding of FANCA and FANCC.
Initially, we isolated the FANCG cDNA by RT-PCR and tested its function
in FA lymphoblast lines (Fig. 1).
Consistent with previous studies (7), retroviral infection
with pMMP-FANCG specifically corrected the MMC sensitivity of FA-G
cells (Fig. 1A) but failed to correct the MMC sensitivity of FA-A cells
(Fig. 1B).
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FIG. 1.
Characterization of the MMC sensitivities of FA-A and
FA-G lymphoblast lines. The full-length FANCG cDNA (7, 25)
was isolated by RT-PCR of RNA from a human MG63 tumor cell line and
subcloned into the murine retroviral vector pMMP(puro) (19).
The indicated retroviral supernatants were generated and used to infect
FA lymphoblast lines, and puromycin-resistant cells were selected. The
cells analyzed included EUFA316 (FA-G) cells, HSC72 (FA-A) cells, and
normal (PD7) cells. Consistent with previous studies (7),
pMMP-FANCG infection also resulted in functional complementation
(correction of MMC sensitivity) of another FA-G cell line, EUFA143
(data not shown). WT, wild type.
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We have previously shown that the FANCA and FANCC proteins bind in
normal lymphoblasts but fail to bind in FA-G lymphoblasts
(
44). We next examined the effect of FANCG expression on the
interaction of the FANCA and FANCC proteins in two FA-G cell lines
(Fig.
2). For uncorrected FA-G cell lines
(lanes 1 and 3), comparatively
low levels of the FANCA and FANCC
proteins were observed (whole-cell
extract immunoblots) and FANCA did
not coimmunoprecipitate with
FANCC. Interestingly, for FA-G cell lines
corrected with pMMP-FANCG
(lanes 2 and 4), expression of FANCC, and
particularly of FANCA,
was increased and FANCA/FANCC binding was
restored.
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FIG. 2.
Expression of FANCG in FA-G lymphoblasts restores the
FANCA/FANCC interaction. Whole-cell extracts (WCE) were generated from
lymphoblast lines, including EUFA316, EUFA316-FANCG, EUFA143,
EUFA143-FANCG, and PD7 (normal adult control). These protein extracts
(100 µg) were probed directly by immunoblotting with either
anti-FANCA or anti-FANCC serum. The FANCA protein is indicated by an
arrow, and additional bands in the anti-FANCA immunoblot are
nonspecific. Alternatively, the same amount of protein from each
extract (2 mg) was used for immunoprecipitation with affinity-purified
anti-FANCC serum as indicated. Immune complexes were resolved by sodium
dodecyl sulfate-polyacrylamide gel electrophoresis, transferred to
nitrocellulose, and immunoblotted with anti-FANCA or anti-FANCC serum.
WT, wild type; IP, immunoprecipitation. The values to the right of the
gel are molecular sizes in kilodaltons.
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FANCG is a component of the FANCA/FANCC protein complex.
The
FANCG protein may restore FANCA/FANCC binding either through a direct
physical interaction with the protein complex or through an indirect
interaction. To test for a direct physical interaction, we examined the
FANCA/FANCC protein complex for the presence of FANCG protein (Fig.
3). For this purpose, we generated an
affinity-purified anti-FANCG serum specific for the carboxyl-terminal region of FANCG. For FA-G lymphoblasts complemented with FANCG and for
normal lymphoblasts, immunoprecipitation with an anti-FANCA serum
resulted in coimmunoprecipitation of the FANCA (163 kDa), FANCG (65 kDa), and FANCC (60 kDa) proteins (Fig. 3A, lanes 6, 10, 18, and 22).
Likewise, immunoprecipitation with an anti-FANCG serum (lanes 7, 11, 19, and 23) or an anti-FANCC serum (lanes 8, 12, 20, and 24) resulted
in the coimmunoprecipitation of the three proteins.
Immunoprecipitation of the complex was less efficient through
FANCC, perhaps indicating that the C-terminal epitope of the FANCC
protein is concealed in the multimeric complex and less accessible to
the antibody.
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FIG. 3.
FANCG is a component of the cytoplasmic and nuclear
FANCA/FANCC protein complex. (A) The indicated lymphoblast lines,
including EUFA316 (FA-G cells), EUFA316 corrected with the FANCG cDNA
(FA-G + FANCG), or PD7 (normal adult control) were lysed and
fractionated into cytoplasmic and nuclear fractions. Proteins from each
fraction were immunoprecipitated with control nonimmune (P), anti-FANCA
(A), anti-FANCG (G), or anti-FANCC (C) serum. Proteins were resolved by
sodium dodecyl sulfate-polyacrylamide gel electrophoresis, transferred
to nitrocellulose, and immunoblotted with anti-FANCA (upper panel),
anti-FANCG (middle panel) or anti-FANCC (lower panel) serum. To
demonstrate that the absence of the FANCA/FANCC interaction in FA-G
cells is not simply due to the low expression level of FANCA and FANCC
in these cells, three times more cytoplasmic extract (6 mg in 1 ml) was
used for EUFA316 (lanes 1 to 4) than for the other two cell lines
(lanes 5 to 12). (B) To ensure effective fractionation, samples from
the indicated lymphoblast lines described in panel A were analyzed for
topoisomerase levels (upper panel) and -tubulin levels (lower
panel). WT, wild type; IgG, immunoglobulin G; IP,
immunoprecipitating.
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The multisubunit complex of the FANCA, FANCG, and FANCC proteins was
observed in cellular fractions derived from the cytoplasm
and the
nucleus of the respective cell lines (compare lanes 1
to 12 to lanes 13 to 24). Efficient cellular fractionation was
confirmed by analyzing the
marker proteins topoisomerase II and
-tubulin (Fig.
3B). Consistent
with the results in Fig.
2, FANCA
failed to coimmunoprecipitate with
FANCC or FANCG in the mutant
FA-G cell line (Fig.
3A, lane 2).
Interestingly, FANCA was only
weakly detectable in the nuclear fraction
of these cells compared
with their corrected counterpart (compare lanes
14 and 18), suggesting
that correction with FANCG not only restores
FANCA/FANCC binding
but also enhances nuclear accumulation of the
complex. Whether
this observation reflects a real deficiency in the
nuclear translocation
process or is a direct consequence of the low
expression level
of FANCA and FANCC in mutant FA-G cells remains to be
determined.
Taken together, these results demonstrate that the FANCG
protein
is bound in a protein complex with FANCA and FANCC; absence of
the FANCG protein results in absence of FANCA/FANCC binding and
appears
to decrease FANCA/FANCC nuclear
accumulation.
The interaction of FANCA, FANCG, and FANCC was also analyzed by using
in vitro-translated proteins (Fig.
4). In
vitro-translated
FANCA and FANCG proteins coimmunoprecipitated with
either anti-FANCA
serum (lane 2) or anti-FANCG serum (lane 3). In
contrast, in vitro-translated
FANCC protein did not coimmunoprecipitate
with the FANCA or FANCG
protein (lanes 6 and 11), suggesting that the
binding of FANCC
to the FANCA/FANCG complex is weaker or is regulated
by other
adapter proteins or posttranslational modifications which are
not present in the cell-free in vitro translation mixture. Accordingly,
the coimmunoprecipitation of FANCA and FANCG from whole-cell extracts
was more efficient than the coimmunoprecipitation of FANCA and
FANCC or
FANCG and FANCC (Fig.
3).
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FIG. 4.
Binding of FANCA and FANCG in vitro. In
vitro-translated, [35S]methionine-labeled FANCA (A),
FANCG (G), and FANCC (C) were prepared in separate reactions and mixed
as indicated (Input Protein). Immunoprecipitation was done with either
preimmune (P), anti-FANCA (A), anti-FANCG (G), or anti-FANCC (C) serum.
Total reticulocyte lysate (without immunoprecipitation) containing
labeled FANCA, FANCG, and FANCC was loaded in lanes 13, 14, and 15, respectively. IP, immunoprecipitating.
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The amino-terminal region of FANCA is required for FANCG binding,
FANCC binding, and functional activity of the complex.
We next
determined the region of the FANCA protein required for interaction
with FANCG (Fig. 5). By using a mutant
series of FANCA polypeptides (Fig. 5A), we have recently determined
that the amino-terminal region of FANCA is required for nuclear
localization, FANCC binding, and functional activity (29).
In the current study, we examined FA-A fibroblasts (GM6914 cells)
expressing these mutant FANCA polypeptides (Fig. 5B).
Immunoprecipitation of either wild-type FANCA or mutant forms of FANCA
containing the intact amino-terminal nuclear localization signal (NLS)
sequence resulted in coimmunoprecipitation of FANCG (Fig. 5B, lanes 1, 3, 7, and 8). In contrast, mutant forms of the FANCA protein which lack
the N-terminal NLS region of FANCA failed to bind to FANCG (Fig. 5B,
lanes 4 to 6), failed to translocate to the cell nucleus and failed to
complement MMC sensitivity (Table 1).
Taken together, these data demonstrate that the amino-terminal NLS
region of the FANCA protein is required for FANCG binding, FANCC
binding, nuclear localization, and functional activity. Interestingly,
nuclear localization is necessary but not sufficient for functional
activity. For instance, the SV40 FANCA protein accumulates in the
nucleus but fails to bind FANCG and FANCC and fails to function (Table 1). Whether the amino-terminal NLS region of FANCA directly binds to
FANCG or requires additional adapter proteins or posttranslational modifications (indirect binding) remains to be determined.
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FIG. 5.
The amino-terminal NLS region of FANCA is required for
FANCG binding and functional activity. (A) Schematic representation of
wild-type (WT) FANCA and mutant proteins. The wild-type FANCA protein
is 1,455 amino acids long and contains a bipartite NLS and a partial
leucine zipper (LZ) motif. The FANCA- NLS mutant protein is missing
the amino-terminal 35 amino acids. The FANCA-NLS-mut2 protein has all
of the basic amino acids of the NLS mutated. The SV40T-FANCA protein
contains the 13-amino-acid NLS of the SV40 T antigen in place of the
NLS of FANCA. The FANCA(H1110P) and FANCA(R1117G) mutations are based
on FANCA mutational screens (22). cDNAs encoding these
mutant FANCA proteins were generated and expressed in the FA-A
fibroblast line GM6914 as previously described (29). (B)
Cell lysates were prepared from GM6914 FA-A fibroblasts expressing the
indicated FANCA mutant proteins. The FANCA proteins were
immunoprecipitated with an anti-FANCA serum (anti-carboxy-terminal
antibody), and the immune complexes were analyzed by anti-FANCA and
anti-FANCG immunoblotting. As a negative control, GM6914 cells
expressing nlsLacZ (no FANCA protein) were analyzed (lane 2). For the
FANCA-Xho mutant protein, immunoprecipitation was done with the
anti-FANCA (anti-amino-terminal) antibody as previously described
(29). IP, immunoprecipitation.
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Analysis of the FANCA/FANCG/FANCC complex in other FA
complementation groups.
The interaction of the FANCA, FANCG, and
FANCC proteins was next examined in various lymphoblast lines derived
from normal controls or FA patients (Fig.
6). The FANCA/FANCG/FANCC complex was
detected in normal lymphoblasts, in FANCA-corrected FA-A cells, and in
FA-D cells (see the anti-FANCC immunoblot, lanes 2, 6, and 16).
FANCA/FANCG binding without a FANCC interaction was observed in cells
derived from multiple FA complementation groups, including groups A, B,
C, E, F, and H (see the anti-FANCG immunoblot, lanes 8, 10, 12, 14, 16, 18, 20, and 24). These results further suggest that the interaction
between the FANCA and FANCG proteins is a constitutive (and perhaps
direct) interaction which is not regulated by FANCC or by the products
of other FA genes. In contrast, the binding of FANCC appears to require
FANCA/FANCG binding and the products of other FA genes, as previously
described (44).
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FIG. 6.
Analysis of the FANCA/FANCG/FANCC protein complex in
cell lines from multiple FA complementation groups. (A) Whole-cell
extracts were prepared from the indicated lymphoblast lines, and
proteins were immunoprecipitated with either preimmune (P) or
anti-FANCA (A) serum. Immune complexes were immunoblotted with
antiserum to FANCA, FANCG, or FANCC, as indicated. The cell lines
analyzed included normal control PD7 cells (lanes 1 and 2) and HSC72
(lanes 3 and 4), HSC72-FA-A (lanes 5 and 6), BD32 (lanes 7 and 8),
HSC230 (lanes 9 and 10), PD4 (lanes 11 and 12), HSC536 (lanes 13 and
14), PD20L (lanes 15 and 16), EUFA130 (lanes 17 and 18), EUFA121 (lanes
19 and 20), EUFA316 (lanes 21 and 22), and EUFA173 (lanes 23 and 24)
cells. The BD32 (FA-A) cell line expressed a mutant FANCA polypeptide
[FANCA(H1110P)]. The HSC536 (FA-C) cell line expressed a mutant FANCC
polypeptide [FANCC(L554P)]. All of the cell lines examined expressed
comparatively equal levels of FANCC protein as judged by whole-cell
lysate immunoblotting (data not shown), except PD4 cells, which
expressed no FANCC protein. IP, immunoprecipitating; IgG,
immunoglobulin G. WT, wild type.
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One FA-A cell line (BD-32) (lanes 7 and 8) expressed a mutant,
nonfunctional form of the FANCA protein with a histidine residue
replaced with a proline at amino acid 1110 [FANCA(H1110P)]
(
19).
This mutant form of the FANCA protein still
coimmunoprecipitated
with FANCG (lane 8), although FANCC was not
observed in the complex.
These results suggest that FANCG binding is
necessary but not
sufficient for FANCA activity; FANCC binding is also
required
for functional activity of the complex. Interestingly, FANCA
and
FANCG levels appeared to be decreased in cells derived from FA
groups A, B, E, F, and H (lanes 8, 10, 18, 20, and 24), suggesting
that
other FA genes may regulate FANCA and FANCG protein expression
or
stability.
The FANCA, FANCG, and FANCC proteins stabilize the FA protein
complex.
In an attempt to establish the effects of individual
protein components (FANCA, FANCG, and FANCC) on the stability and
expression level of the FA protein complex, we analyzed isogenic pairs
of mutant and corrected FA cell lines by whole-cell lysate immunoblots (Fig. 7). For FA-A cells, correction with
FANCA resulted in an increase in the expression level of the FANCC and
FANCG proteins (lanes 2 and 3). For FA-G cells, correction with FANCG
resulted in an increase in the expression level of the FANCA and FANCC proteins (lanes 4 and 5). For FA-C cells, correction with FANCC resulted in an increase in the expression level of the FANCA and FANCG
proteins (lanes 6 and 7). Taken together, these results further suggest
that the three FA proteins FANCA, FANCG, and FANCC bind in a complex
and that the stability of the complex is enhanced by each component.
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FIG. 7.
The FANCA, FANCG, and FANCC proteins stabilize the FA
protein complex. Whole-cell extracts from the indicated lymphoblast
lines were prepared, and the same amount of protein from each was
resolved by sodium dodecyl sulfate-polyacrylamide gel electrophoresis,
transferred to nitrocellulose, and immunoblotted with affinity-purified
antiserum against the FANCA, FANCC, or FANCG protein, as indicated. WT,
wild type.
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Nuclear localization of the FANCA and FANCG proteins.
To
further confirm the cellular localization of the FANCA and FANCG
proteins, we performed immunofluorescence on an SV40-transformed normal
human fibroblast line (Fig. 8). The FANCA
and FANCG proteins were expressed primarily in the nuclei of
retrovirus-infected cells, consistent with previous studies
(29) and consistent with the functional interaction of the
proteins. Some cytoplasmic expression of the FANCA and FANCG proteins
was also observed.
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FIG. 8.
Nuclear localization of the FANCA and FANCG
polypeptides. The human fibroblast line GM0637, derived from a normal
(wild-type) control, was infected with either pMMP-FANCA (wild type)
(A) or pMMP-FANCG (wild type) (B) as indicated. Pools of infected cells
were stained with anti-FANCA or anti-FANCG serum or stained with the
DNA-specific dye 4',6-diamidino-2-phenylindole (DAPI) and analyzed by
immunofluorescence assay as previously described (29).
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DISCUSSION |
Our results demonstrate that the three cloned FA genes encode
proteins which interact in a multisubunit complex. The complex was
detected in both the cytoplasm and the nucleus, consistent with
previous studies which localized FANCC to both cellular compartments (10, 21, 43, 45). Accumulation of the nuclear complex is
required for the function of the complex (29). Mutation of any of the three FA genes leads to disruption of the protein complex, resulting in the conserved FA cellular and clinical phenotype.
The structural features of the various protein-protein contacts within
the multisubunit complex are not fully understood. Based on an analysis
of truncated and point mutant forms of the FANCA protein, the
amino-terminal NLS of FANCA is required for FANCG binding and FANCC
binding (29) (Fig. 9). Based
on the FANCA-Xho mutant protein, the amino terminus of FANCA is also sufficient for the binding interaction with FANCG. The carboxy-terminal leucine zipper region of FANCA is deleted in the FANCA-Xho mutant protein and is therefore not required for FANCG binding. Sequences at
the carboxy terminus of FANCA, perhaps including the leucine zipper,
are required for FANCC binding. For example, in the patient-derived point mutant proteins FANCA(H1110P) and FANCA(R1117G) (19), the mutations near the leucine zipper region of FANCA disrupt FANCC
binding, nuclear localization, and function. Additional posttranslational modifications of FANCA or other adapter proteins may
also be required to enable the interaction of FANCC with the complex
(44).
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FIG. 9.
Schematic model of molecular interactions of the FANCA,
FANCG, and FANCC proteins. Based on available data, at least two
regions of the FANCA polypeptide are required for the FANCA-FANCG-FANCC
interaction. First, the amino-terminal region of the FANCA protein,
which includes the bipartite NLS region, is required for interaction
with the FANCG protein. Second, a region near the carboxy terminus of
FANCA is required for the FANCC interaction. Patient-derived point
mutations in this region disrupt the FANCC interaction. The FANCC
interaction is a weak or regulated interaction, requiring FANCA/FANCG
binding and the products of other FA genes (44). The region
of FANCG required for FANCA binding is not known. The region of FANCC
required for FANCA binding may be the carboxy terminus of FANCC. This
region is highly conserved among human, murine, and bovine FANCC
proteins. Also, an FA-C patient-derived point mutation
[FANCC(L554P)] ablates FANCA binding (21).
|
|
The detailed stoichiometry of the FANCA-FANCG-FANCC
interaction is not clear. It is apparent that anti-FANCA
antibodies are as efficient as anti-FANCG antibodies in
immunoprecipitating FANCA and FANCG. FANCA/FANCG binding is even
observed for in vitro-translated proteins, suggesting that the
interaction is direct. In contrast, the anti-FANCC antibody is less
efficient in immunoprecipitating FANCA and FANCG. These results suggest
that there is a large pool of cellular FANCC uncomplexed with FANCA and
FANCG. Whether the uncomplexed FANCC protein has a discrete cellular or
biochemical function, compared to the complexed form, remains unknown.
There are several possible explanations for the substoichiometric
interaction of FANCC with the FANCA/FANCG complex. First, binding of
the FANCC protein may be regulated. Consistent with this hypothesis,
FANCC binding correlates with the phosphorylation of the FANCA protein
(44). The phosphorylation sites of FANCA and the relevant
cellular kinase(s) remain unknown. Second, our current
immunoprecipitation strategy may be efficient at preserving the
FANCA/FANCG interaction but inefficient at preserving the FANCC
interaction. Third, the epitope of the FANCC protein recognized by our
anti-FANCC antibody may be poorly accessible when FANCC is complexed
with FANCA/FANCG.
Analysis of other multisubunit complexes, such as the nucleotide
excision repair complex (42) and the RNA polymerase II holoenzyme (16), also reveals some subunits with strong,
constitutive interactions and other subunits with weak or regulated
interactions. For instance, the ERCC2, ERCC3, and p62 proteins interact
within the RNA polymerase transcription factor complex TFIIH but these interactions are dependent on the salt concentration (35).
Our results demonstrate that expression of FANCG not only restores the
binding of FANCA and FANCC (Fig. 2) but also increases the expression
of FANCA and FANCC (Fig. 2 and 7). Likewise, FANCC correction of an
FA-C cell line increases the expression of FANCA and FANCG (Fig. 7),
although FANCA/FANCG binding is observed even in the absence of FANCC.
Increased protein expression may result from increased synthesis or
decreased turnover. We hypothesize that it probably results from the
increased stability conferred by protein-protein interactions in the
complex. To support this model, we have performed pulse-chase experiments to determine the half-life of newly synthesized FANCA protein (9a). In uncorrected FA-G lymphoblasts, the FANCA
protein was unstable. Following correction of these cells by FANCG
protein expression, the FANCA protein half-life was prolonged,
suggesting that FANCG binding directly protects FANCA from degradation.
Consistent with these results, the stabilization of binding members has
been observed for other multisubunit complexes, such as the AP-1
complex and the excision repair complex (31, 39).
Cells from other FA complementation groups, including groups B, E, F,
and H, have decreased levels of the FANCA, FANCC, and FANCG proteins.
The protein products of the FANCB, FANCE,
FANCF, and FANCH genes may therefore regulate the
stability of the FA protein complex, perhaps through direct
association with the complex. Based on sucrose gradient sedimentation
(20a), the nuclear protein complex is large (>400 kDa),
suggesting the presence of additional adapter proteins. Purification of
the FA complex may therefore allow the identification of other FA gene products.
Finally, the biochemical function of the nuclear FA protein complex
remains unknown. Since FA cells have an underlying defect in the
fidelity of rejoining of specific DSBs (9, 36), the complex
may represent a novel DSB repair pathway or may modulate a known DSB
repair pathway, such as the HR pathway or the NHEJ pathway.
Identification of additional proteins in the FA nuclear complex may
elucidate its biochemical function.
| |
ACKNOWLEDGMENTS |
We thank C. Mathew for the BD32 (FA-A) cell line and H. Joenje
for EUFA143 and EUFA316 cells.
This research was supported by NIH grants R01-HL5725 and PO1-CA39542.
I.G.H. is supported by a fellowship from the Cancer Research Institute.
A.D.D. is a Scholar of the Leukemia Society of America.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Pediatric Oncology, Dana-Farber Cancer Institute, Harvard Medical
School, Boston, MA 02115. Phone: (617) 632-2112. Fax: (617) 632-2085. E-mail: a_dandrea{at}farber.harvard.edu.
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Abstract
Introduction
