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Blood, Vol. 95 No. 5 (March 1), 2000:
pp. 1788-1796
NEOPLASIA
FGFR1 is fused to the centrosome-associated protein
CEP110 in the 8p12 stem cell myeloproliferative disorder with
t(8;9)(p12;q33)
Géraldine Guasch,
Gary J. Mack,
Cornel Popovici,
Nicole Dastugue,
Daniel Birnbaum,
Jérome B. Rattner, and
Marie-Josèphe Pébusque
From the Laboratoire d'Oncologie Moléculaire, Inserm U119,
Institut de Cancérologie et d'Immunologie de Marseille,
Marseille, France; the University of Calgary, Alberta, Canada; the
Laboratoire des Hémopathies, Hôpital de Purpan, Toulouse,
France; and the Laboratoire de Biologie des Tumeurs, Institut
Paoli-Calmettes, Marseille, France
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Abstract |
The hallmark of the 8p12 stem cell myeloproliferative disorder (MPD)
is the disruption of the FGFR1 gene, which encodes a tyrosine
kinase receptor for members of the fibroblast growth factor family.
FGFR1 can be fused to at least 3 partner genes at chromosomal
regions 6q27, 9q33, or 13q12. We report here the cloning of the
t(8;9)(p12;q33) and the detection of a novel fusion betweenFGFR1 and the CEP110 gene, which codes for a
novel centrosome-associated protein with a unique cell-cycle
distribution. CEP110 is widely expressed at various levels in
different tissues and is predicted to encode a 994-amino acid
coiled-coil protein with 4 consensus leucine zippers
[L-X(6)-L-X(6)-L-X(6)-L]. Both reciprocal fusion transcripts are
expressed in the patient's cells. The CEP110-FGFR1 fusion protein
encodes an aberrant tyrosine kinase of circa 150-kd, which retains most
of CEP110 with the leucine zipper motifs and the catalytic domain of
FGFR1. Transient expression studies show that the CEP110-FGFR1 protein
has a constitutive kinase activity and is located within the cell cytoplasm.
(Blood. 2000;95:1788-1796)
© 2000 by The American Society of Hematology.
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Introduction |
Two distinct clinical syndromes have been associated
with recurrent translocations of the 8p12 chromosomal region: stem-cell myeloproliferative disorder (MPD) and acute myeloid leukemia (AML). The
MPD is characterized by B- or T-cell lymphoblastic leukemia/lymphoma, myeloid hyperplasia, and peripheral blood eosinophilia, and it generally progresses to AML (1for review and references
therein). The second group of diseases consists of acute myelomonocytic
or monocytic leukemia, predominantly associated with
erythrophagocytosis [t(8;14)(p11;q11.1);2
t(8;16)(p11;p13);3-9 t(8;19)(p11;q13);7
t(8;22)(p11;q13)].10 The t(8;16) and t(8;22) translocations fuse the MOZ gene with the genes encoding the
transcriptional coactivators CBP11 and p300,12
respectively. In MPD, the 8p12 breakpoint, associated with at least 3 different partners 6q27, 9q33, and 13q12disrupts the FGFR1
gene,13 which encodes 1 of the 4 tyrosine kinase receptors
for the fibroblast growth factors.14 Two breakpoints
associated with FGFR1 have already been characterized. FGFR1 is fused to the FOP gene in
t(6;8)(q27;p11)15 and to the FIM/RAMP/ZNF198 gene
in t(8;13)(p11;q12).16-20 In both cases, the chimeric
proteins with putative oncogenic properties contain potential oligomerization domains encoded by the 6q27 (FOP) and 13q12
(FIM) genes fused to the tyrosine kinase domain of FGFR1.
FIM-FGFR1 is constitutively activated16 and predominantly
cytoplasmic,20,21 and it has a constitutive
dimerization capability mediated by the FIM N-terminus
sequences.21
We report here the characterization of the third chromosomal
rearrangement event occurring in 8p12 MPD in 1 patient. The
FGFR1 gene is fused to the CEP110 (centrosome protein
110) gene, which encodes a novel protein identified with human
autoimmune sera and is associated with the centrosome. One of the 2 fusion products generated by the translocation t(8;9), CEP110-FGFR1
encodes an aberrant tyrosine kinase that is constitutively activated
and localized in the cell cytoplasm.
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Materials and methods |
Patient
A 37-year-old man was examined for fatigue, weight loss, and
gingival bleeding. He had hepatomegaly and splenomegaly. The hemogram
showed hemoglobin 11 g/L, platelets 63 giga/L, leukocytes 97.8 giga/L with 21% neutrophils, 33% eosinophils, 1%
basophils, 13% lymphocytes, 16% monocytes, and 16% immature
granulocytes (3% myeloblasts, 7% promyelocytes, 4% myelocytes, 1%
metamyelocytes, and 1% eosinophil myelocytes). The leukocyte alkaline
phosphatase score was 0. Bone marrow was hypercellular and was
characterized by hyperplasia of the granulocytic lineage (86%
granulocytes, including 59% eosinophils). Both the peripheral blood
and the bone marrow counts were consistent with a diagnosis of
eosinophilic chronic leukemia. According to the ISCN
nomenclature,22 the karyotype at diagnosis was
46,XY, t(8;9)(p12;q33)[8]/48, idem, +der(9)t(8;9);+21[12].
After 1 month of hydroxyurea (500 mg/d), the myeloproliferative
syndrome accelerated to a monocytic blast crisis. The patient did not
respond to several courses of chemotherapy induction and died 10 months
later. Peripheral blood cells from the patient were obtained after
informed consent was given.
Human cell lines and peripheral blood cells
The following cell lines were purchased from the American Type
Culture Collection: JY (B-lymphoblastic ALL), U937 (histiocytic lymphoma), KG1 (myeloblastic/promyelocytic AML), Daudi (Burkitt's lymphoma), HSB-2, MO, and MOLT-4 (T-ALL), HEL (erythroleukemia AML),
HL60 (promyelocytic AML) cultured in the presence or absence of phorbol
esters, MIA PaCa-2 (pancreatic carcinoma), IMR-90 (lung fibroblast),
A549 (lung carcinoma), HeLa (epithelioid carcinoma). The IE8 (pre-B/B
stage ALL) and SU-DHL-1 (Ki-1 lymphoma cells) cell lines were gifts
from T. LeBien (University of Minnesota Medical School, MN) and R. Rimokh (Hôpital E. Herriot, Lyon, France), respectively.
Peripheral blood cells isolated from blood samples obtained from
healthy donors (Centre Régional de Transfusion Sanguine, Marseille, France) were fractionated (B and T lymphocytes,
granulocytes, and monocytes) as previously described.23
CD34+ cells were purified from mobilized blood cells as
described24 (kindly provided by C. Chabannon, Institut
Paoli-Calmettes, Marseille, France).
Cloning and sequencing of the t(8;9) fusion cDNA
To isolate 1 of the t(8;9) fusion transcripts, 5' RACE-PCR was
performed using the Marathon cDNA amplification kit (Clontech, Palo
Alto, CA). Specifically, the first-strand cDNA was synthesized from 2 µg total RNA from the patient by using primer F5R (Table 1). Second-strand cDNA synthesis and cDNA
adaptor ligation were performed according to the manufacturer's
instructions. The fragment containing the fusion cDNA was amplified by
2 sequentially nested PCRs using F4R (Table 1) and adaptor-specific AP1
primers and then by F3R (Table 1) and adaptor-specific AP2 primers.
Polymerase chain reaction (PCR) conditions were as follows: an initial
denaturation step at 95°C for 5 minutes, followed by 30 cycles
(denaturation, 94°C for 30 seconds; annealing, 60°C for 30 seconds; elongation, 68°C for 4 minutes), and a final extension at
68°C for 10 minutes in a DNA Thermal Cycler 480 (Perkin Elmer
Cetus, Montigny-Le-Bretonneux, France). The PCR product was ethanol
precipitated and cloned in the pUC18 plasmid by using Sure Clone
Ligation Kit (Pharmacia, Uppsala, Sweden). Individual clones were
manually sequenced with forward- and reverse-sequencing primers for
pUC18 using T7Sequencing Kit (Pharmacia), and products were analyzed on
5% polyacrylamide/urea sequencing gels.
CEP110 cDNA cloning and analysis
Two independent approaches were used in the cloning of the
CEP110 wild-type gene. (1) Autoimmune serum JK was identified
from a serum bank of 25,000 autoimmune sera collected for testing at the Advanced Diagnostic Laboratory (University of Calgary,
Canada). This serum was used at a dilution of 1:1000 to
immunoscreen a HeLa 5' stretch  gt11 cDNA expression library
(Clontech), as previously described.25 From this screen, 4 reactive cDNA clones were identified. DNA sequencing of these clones
revealed a single novel cDNA clone, designated 21.
Additional cDNA clones that overlapped and extended clone 21 were
obtained by rescreening the HeLa cDNA library using specific 5'
and 3' probes by DNA hybridization as described.25
Each probe was labeled with [32P]dCTP (random primer
labeling kit; Stratagene, La Jolla, CA) and was purified from free
nucleotides using microspin G-50 columns (Pharmacia). All cDNA clones
were cloned into the pBluescript vector (Stratagene), and the DNA
sequence was determined using exonuclease III-generated deletions as
described26 and the dye terminator cycle-sequencing
ready-reaction kit (Applied Biosystems, Foster City, CA) according to
the manufacturer's recommendations. Reactions were analyzed at the
University of Calgary DNA sequencing facility. Rescreening of the HeLa
cDNA library was continued until the entire coding region of the
centrosome protein was identified. The nucleotide and predicted amino
acid sequence of CEP110 is available in GenBank under the accession
number AF083322. All nucleic acid and protein sequence searches and
analyses were conducted on the local network server using the BLAST
search program.27
(2) Several rounds of RACE-PCR obtained the full-length
cDNA for CEP110 from the t(8;9) patient's RNA. A first round
of 5' RACE-PCR was performed with primers derived from the
aa52c11.r1 cDNA clone sequence (accession no. AA491 104). The
single-strand cDNA was obtained from 2 µg total placental mRNA using
the specific primer RACE1 (Table 1). Second-strand cDNA and adaptor
ligation were conducted according to the manufacturer's protocol.
Nested PCR was performed using primer pairs RACE2-AP1 and RACE3-AP2
(Table 1). The PCR conditions were the same as described above.
Amplified fragments were size-fractionated by agarose gel
electrophoresis and cloned in the pUC18 vector. Individual clones were
sequenced at Génome Express (Grenoble, France) using an automated
sequencer (Applied Biosystems 373; Applied Biosystems). Sequence
comparisons with GenBank and dbEST entries were made using BLASTN and
TBLASTN.27 These resulted in the retrieval of several cDNA
clone sequences. Specific primers RACE4, RACE5, and RACE6 (Table 1)
were derived from 1 of the cDNA clones (clone 71) and were used for a
second round of 5' RACE-PCR. A third round of 5' RACE-PCR
was performed using RACE4 primer and nested PCR with RACE7 and RACE8
reverse primers derived from the 5' untranslated region of CEP110
(see "Results") and the AP1 and AP2 adaptor primers,
respectively. PCR product cloning and sequencing were performed as
described above.
Northern blot analyses
The multiple-tissue Northern blots (Clontech; human, no. 7759-1, 7760-1, and 7767-1; mouse, no. 7762-1) were hybridized according to the
manufacturer's instructions. Human probes used were a 0.6-kb fragment
obtained from the third round 5' RACE PCR using RACE8 reverse
primer corresponding to the human CEP110-5' untranslated region; a 2.5-kb cDNA fragment obtained from the second round of
5' RACE-PCR with RACE6 primer corresponding to the insert of cDNA
clone 71; and a 1.2-kb insert fragment from cDNA clone mu38gO2 (accession no. AA209914) corresponding to the 3' part of murine Cep110. All probes were labeled with [32P]dCTP in
random priming reactions.
Wild-type and fusion gene expression analysis by RT-PCR
Reverse-transcription reactions (RT) were performed using 2 µg
total RNA, random hexanucleotides, and SuperScript II reverse transcriptase (Gibco-BRL, Burlington, Ontario, Canada)
according to standard procedures. The equivalent of 500 ng
reverse-transcribed RNA from either t(8;9) patient's leukemic cells or
various cell lines was used for PCR detection of wild-type and fusion
gene expression. The primer pairs (Table 1) were as follows: FGFR1 (FA-F9.2, PCR product, 259 bp); CEP110 (CEPF-CEPR, PCR product, 130 bp); FGFR1-CEP110 (FA-CEPR, PCR product, 177 bp); and CEP110-FGFR1 (CEPF-F9.2, PCR product, 212 bp). All PCR amplifications were as
follows: initial step of denaturation (95°C for 5 minutes); 30 cycles (denaturation, 95°C for 30 seconds, annealing, 58°C for
30 seconds, extension 72°C for 1 minute); final extension step
(72°C for 10 minutes). The amplified fragments were gel-purified, cloned in the pUC18 plasmid, and sequenced as described above. Human
 2 microglobulin primer pair (2MF-2MR; see Table 1; PCR product, 268 bp) was used as control to estimate reaction efficiencies.
PCR amplification of t(8;9) breakpoints on derivative chromosome 8
Using FA-CEPR primer pair (Table 1), the fusion junction
FGFR1-CEP110 (der(8) chromosome fragment of 272 bp) was
amplified from the patient's genomic DNA. PCR products were cloned
and sequenced as described above.
Autokinase activity and tyrosine phosphorylation analysis of the
CEP110-FGFR1 fusion protein
106 NIH3T3 or Cos-1 cells were transiently transfected
using 10 µg reconstructed full-length CEP110-FGFR1
cDNA inserted into the pcDNA3 expression vector (Invitrogen) or 10 µg
empty vector and 30 µL FuGENE 6 transfection reagent (Roche
Diagnostics, Meylan, France) following the manufacturer's
recommendations. Twenty-four hours after transfection and 2 hours after
serum starvation, cells were cultured in the presence or absence of 10 ng/ml FGF1 plus 10 µg/mL heparin. The FGFR1-expressing cell line NFlg
2628 was used as a positive control. Cell lysates and
immunoprecipitation using an antibody directed against an FGFR1
C-terminal peptide (anti-C-FGFR1) (C15; Santa Cruz Biotech, Santa Cruz,
CA) were performed as described.29 Half of each
immunoprecipitate was challenged for autokinase activity in the
presence of  [32P]ATP and 5 mmol/L
MnCl229 and was analyzed by electrophoresis and
autoradiography. Phosphorylation on tyrosine and level of expression
were analyzed by immunoblotting with an anti-phosphotyrosine antibody
(4G10; UBI, Lake Placid, NY) and an anti-C-FGFR1 antibody, respectively.30,31
Recombinant protein production and antibody generation
For antibody Ab72, a 510-bp Ecl136 II/Pvu II
digestion fragment of CEP110 (corresponding to amino acids
805-972) was cloned into the Sma I site of the
glutathione-S-transferase (GST) expression vector pGEX
3 × (Pharmacia). Antibody 5'2 was generated against amino
acids 5-103 of CEP110. Large-scale protein inductions (500 mL) were
carried out, and the GST-CEP110 fusion proteins were injected into New
Zealand White rabbits for the production of polyclonal antibody as
previously described.25
Affinity purification
Purified GST-CEP110 fusion protein and control GST bacterial lysates
were dialyzed against 100 mmol/L MOPS (3-[N-Morpholino] propanesulfonic acid) (pH 7) overnight at 4°C. Each protein sample was then covalently coupled to 1 mL Affigel 10 beads (Bio Rad Laboratories, Hercules, CA) according to the manufacturer's
instructions in a total volume of 5 mL overnight at 4°C. The
protein-bead slurry was then packed into a 10-mL econo-column (Bio Rad
Laboratories). Antibacterial and anti-GST antibodies were depleted from
4 mL rabbit serum (Ab72 and Ab5'2) by repeated passage over the
protein-bead column. This precleared serum was then repeatedly passed
over the GST-CEP110 fusion protein column for 2 to 4 hours at room temperature. The column was washed with 25-bed volumes of tris-buffered saline. Antibody was eluted by passing 15 mL elution buffer (5% acetic
acid. 0.15 mol/L NaCl2) over the column and collecting 1-mL
fractions into 150 µL 1 mol/L tris-HCl (pH 9). The absorbency of each
fraction was then read at OD 280, and all protein-containing fractions
were pooled and dialyzed against Dulbecco's phosphate-buffered saline
(DPBS) overnight at 4°C. The dialyzed antibody was then concentrated in a Centricon 30 (Amicon, Oakville, Ontario, Canada) according to the manufacturer's instructions.
Indirect immunofluorescence
HeLa cells grown on coverslips were extracted in 0.5% Triton X-100
in DPBS for 2 minutes and fixed in 100% methanol at  20°C for 10 minutes. The coverslips were then blocked with 1:200 dilution of
normal goat serum (NGS) in DPBS at room temperature for 30 minutes and
then incubated with a 1:50 dilution of affinity-purified anti-CEP110
antibody (Ab72) in NGS-DPBS for 30 minutes at 37°C. After a wash in
DPBS, the coverslips were incubated with a 1:10 000 dilution of
antipericentrin antibody in NGS-DPBS and further incubated for 30 minutes at 37°C. The coverslips were then washed and incubated with
a mixture of Cy3-conjugated antirabbit 1:400 and fluorescein
isothiocyanate (FITC)-conjugated antimouse 1:400 secondary antibody
(Jackson Laboratories, Oak Grove PA) in NGS-DPBS for 30 minutes at
37°C. After incubation the coverslips were washed in DPBS,
counterstained with DAPI (4',6'-diamidino-2-phenylindole), and mounted in 90% glycerol containing paraphenylenediamine. Cells were observed using a Leica (Heidelberg, Germany) DMRB
microscope using a 100× objective. Images were recorded with an
RTE/CCD detector (Princeton Instruments, Trenton, NJ) using IPLab
Spectrum software (Signal Analytics, Vienna, VA).
Cos-1 cells were grown as monolayers on coverslips the day before
transfection (2 × 105 cells/60-mm plates) using 2 µg plasmid DNA and 3 µL FuGENE transfection reagent. Twenty-four
hours after transfection, cells were washed once in PBS and fixed in
3.7% paraformaldehyde in PBS for 15 minutes at room temperature. After
extensive PBS washes, cells were permeabilized and blocked in 5% fetal
calf serum PBS and 0.1% Triton X 100 for 15 minutes. Cells were
incubated with either the purified anti-CEP110 antibodies (Ab72 or
Ab5'2) or the human immune serum, each used at 1:20 dilution for
1 hour at room temperature, rinsed several times in PBS, and incubated
for at least 1 hour with either the Alexa-conjugated antirabbit 1:500
(Molecular Probes, Eugene, OR) or FITC-conjugated
F(ab')2 fragment goat antihuman IgG, FC
(Immunotech, Marseille, France) secondary antibodies,
respectively. Coverslips were then washed several times in PBS and
incubated for 1 hour in PBS containing 25 µg/mL 7-AAD
(7-aminoactinomycin D; Molecular Probes) used to visualize DNA. After
several washes with PBS, coverslips were mounted in
Mowiol. Cellular localization of proteins was analyzed by
confocal laser system microscopy using a TCS NT Leica apparatus.
Green fluorescent protein transfection constructs and transient
transfection
Various portions of the protein-encoding CEP110 cDNA were
cloned in-frame into pEGFP-N1 (Clontech), a red-shifted green
fluorescent protein (GFP) eukaryotic expression vector (see Figure 7).
A 2957-bp fragment of the coding region of CEP110 was amplified
by PCR using the primers SPINF and SPINR (Table 1) and was cloned into
the Ecl136 II site of pEGFP-N1 to create the construct
CEP110-GFP. Fragment A was amplified by PCR using the primers SPINF and
21REV3 (Table 1) and was cloned to the Ecl136 II site of
pEGFP-N1 to create expression construct A. Fragment B was amplified by
PCR using the primers SPINF and 21R4 (Table 1) and was
cloned to the Ecl136 II site of pEGFP-N1 to create construct B. Fragment C was generated by Dra I/Eco RV digestion of
the full-length CEP110 cDNA and was cloned to the Eco47
III site of pEGFP-N1 to create construct C. Fragment D was generated by
digesting the full-length CEP110 cDNA with EcoR V and
cloning the C-terminal fragment to the Eco47 III site of
pEGFP-N1 to create construct D. Fragment E was generated by digesting
full-length CEP110 cDNA with Eco RV and Ecl136
II and was cloned to the Eco47 III site of pEGFP-N1 to create
construct E. Fragment F was amplified by PCR using the primers 21F4 and
SPINR (Table 1) and was cloned to the Ecl136 II site of
pEGFP-N1 to create construct F. Fragment G was amplified by PCR using
the primers 21F4 and 21REV3 (Table 1) and was cloned to the
Ecl136 II site of pEGFP-N1 to create expression construct G.
HeLa cell coverslips at 30% to 40% confluence were washed briefly in
serum-free medium (Opti-MEM; Gibco-BRL) and were incubated with 2 µg
DNA-lipofectin reagent (Gibco-BRL) in Opti-MEM for 3 hours. The
transfection medium was then replaced with complete medium (DMEM, 10%
fetal calf serum). Twenty-four hours later transfected cells were
extracted for 1 minute in 0.5% Triton-X-100 in DPBS and fixed in 4%
paraformaldehyde (Sigma, Oakville, Ontario, Canada) in DPBS for 10 minutes. The coverslips were then processed for indirect
immunofluorescence with antipericentrin antibody 1:10 000 as described above.
| |
Results |
FGFR1 chromosomal translocation
In a previous work we showed that the t(8;9) breakpoint interrupts
the FGFR1 locus.13 To determine the fusion partner
of FGFR1 in a t(8;9) MPD, RNA was isolated from the patient's
leukemic cells and subjected to RACE using nested primers within
FGFR1 exon 14. Two of the retrieved clones were sequenced and
had novel sequences upstream of FGFR1 exon 9. To clone more of
the 5' region of the FGFR1 partner gene, 2 rounds of
5' RACE-PCR were performed, resulting in a 2.8-kb cDNA contig.
Database searches with the novel sequence showed 100% identity with
several expressed sequence tags (ESTs) and with the CEP110
mRNA. Of the retrieved ESTs, EST AA491104, which surrounded the t(8;9)
breakpoint, is derived from the cDNA clone aa52c11. This cDNA clone was
entirely sequenced and had 100% identity with the
3' region of CEP110 (GenBank accession no. AF083322), a
novel gene that was identified by screening a cDNA expression library
with a human autoimmune serum containing autoantibodies to the
centrosome. During the cloning of this autoantigen, a set of cDNA
clones that showed no significant similarity with any protein of the
GenBank database was assembled and spanned 3893 bp. An open-reading
frame (ORF) of 2982 bp in this cDNA initiates at nucleotide position
473 and is preceded by several in-frame stop codons. A termination
codon for this ORF is found at nucleotide position 3455. Two potential
poly(A)+ initiation signals (AATAAA) are found at position 3866-3871 and 3887-3892. During the independent cloning of CEP110 as a novel
antigen and as the FGFR1 partner in the t(8;9) multiple CEP110
cDNA variants, were identified with different 5' noncoding and
coding regions. Of them, cDNA clones were identified that
contained a 141-bp in-frame deletion between nucleotide positions 2755 to 2896 in the ORF. These results indicated that the CEP110
cDNA is alternatively spliced.
A search of GeneMap 98 from NCBI
(http://www.ncbi.nlm.nih.gov/genemap98/map/loc.cgi?) resulted in the
identification of a sequence-tagged site from the Whitehead
Institute (Cambridge, MA), WI-11 957, specific to
CEP110 and EST AA499 904. As described in the GeneBridge 4 radiation hybrid database, WI-11 957 maps to 9q33, the region of the
chromosome 9 breakpoint involved in the t(8;9).
Features of the deduced amino acid sequence of CEP110
The predicted ORF of CEP110 cDNA codes for 994 amino acids.
From the deduced amino acid sequence, the molecular weight of CEP110
was calculated as 116 813 d. A GenBank database search with the amino
acid sequence revealed no significant similarity with known proteins.
However, regions of weak similarity could be observed with a number of
coiled-coil proteins, including CENP-E, myosin heavy chain, and kinesin
light chain. Analyzing the amino acid sequence with the program
COILS32 showed that CEP110 is predicted to have extensive
stretches of coiled-coil structure throughout much of its sequence,
except between amino acids 65-80, 295-320, and 810-850, and last 114 amino acids of the C-terminus (data not shown).
A protein MOTIF search
(http://www.motif.genome.ad.jp/motif-bin/nph-motif2) revealed the
possibility of 1 amidation site, 2 N-myristoylation sites, and 1 N-glycosylation site. Furthermore, there are 2 potential cyclic
adenosine monophosphate-phosphorylation sites, 19 casein kinase II
phosphorylation sites, and 20 protein kinase C phosphorylation sites.
In addition, there are 4 predicted leucine zippers
(L-X(6)-L-X(6)-L-X(6)-L) at amino acid positions 28-49, 97-118, 496-517, and 689-710 (Figure 1). There are
no consensus sequences for microtubule or nucleotide binding. Overall,
CEP110 is an acidic protein with a predicted pI of 5.43.
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| Fig 1.
Schematic representation of FGFR1, CEP110, and both
CEP110-FGFR1 and FGFR1-CEP110 chimeric proteins.
FGFR1 domains are indicated as follows: IgI, IgII, IgIII, the 3 immunoglobulin-like domains; TM, the transmembrane domain; TK1 and TK2,
the tyrosine kinase 1 and 2 subdomains interrupted by a kinase insert
(KI). CEP110 regions are indicated as follows: diamonds, leucine zipper
motifs; waved lines, predicted coiled-coil region. Double arrows
indicate the t(8;9) breakpoint. Nucleotide and amino acids sequences
are indicated for CEP110-FGFR1 and both wild-type products.
|
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Characterization of the fusion junctions in the t(8;9)
We next examined the nucleotide sequence spanning the t(8;9)
breakpoint on both parental and derivative chromosomes. RT-PCR assays
localized the breakpoint at positions 1259 and 2424 from the start
codon in the FGFR1 (accession no. M34 185) and CEP110 mRNA, respectively. The translocation leads to the formation of the two
reciprocal transcripts. CEP110-FGFR1, transcribed from chromosome derivative 9, encodes a large protein containing all 4 leucine zipper motifs of CEP110 at its N-terminus, and the catalytic domain of FGFR1 at its C-terminus (Figure 1). The junction sequence is
described above the representation of the fusion protein in Figure 1.
FGFR1-CEP110, transcribed from chromosome derivative 8, encodes
a protein containing the FGFR1 N-terminal region with its
ligand-binding and transmembrane domains and the CEP110 C-terminal region (Figure 1).
To determine the precise position of the t(8;9) breakpoints, genomic
DNA from the patient's leukemic cells was PCR-amplified (FA-CEPR
primers; Table 1), sequenced, and compared with the sequence of normal
human genomic DNA. In FGFR1, the breakpoint is localized in
exon 8, corresponding to position 1259 from ATG, 12 bp upstream of the
exon8/intron 8 boundary. In CEP110, the breakpoint occurs at
position 1658 of an intron of 1744 bp. The breakpoint intron of
CEP110 contains AluJb and MIR elements (Mask Repeat
Sequence, http://ftp.genome.washington.edu/).
Gene expression
Hybridization of a CEP110 probe to human multiple-tissue
Northern blots identified 3 main transcripts of approximately 7.5, 4.5, and 1.5 kb with different rates of expression. A high-level expression
of the 7.5- and 1.5-kb transcripts was seen in testis (Figure
2A) and trachea (Figure 2B), respectively.
The 7.5-kb transcript was weakly expressed in the majority of tissues,
including ovary (Figure 2A), trachea, adrenal gland, and bone marrow
(Figure 2B). In addition, CEP110 transcripts were barely expressed in thymus and peripheral blood cells (Figure 2A) and heart, brain, and
liver (data not shown). To further analyze Cep110 expression, we hybridized a murine Cep110 probe to a murine Northern blot. Six main transcripts were revealed in mouse liver that varied in size
from 1.5 kb to 9 kb (Figure 2C).
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| Fig 2.
CEP110 expression.
(A,B) Indicated human poly(A)+ RNA from Clontech Northern blots was
hybridized with CEP110 probes either derived from the cDNA
insert of CEP110 clone 71 (A) or the 5' untranslated
probe (B). (C) Mouse poly(A)+ Northern blot (Clontech) hybridized with
a CEP110 probe from cDNA clone mu38gO2. The marker sizes (in
kb) are indicated on the left.
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The expression of CEP110 and FGFR1 wild-type genes was
assessed by RT-PCR assays from either the t(8;9) patient or various normal and malignant hematopoietic cells (Figure
3). Both types of gene were expressed in
all tested cells (Figure 3). In contrast, the 2 reciprocal fusion
transcripts were only found in the t(8;9) leukemic cells (Figure
4). Sequence analysis confirmed that these unique products contained fusions of FGFR1 and CEP110
sequences, as expected.
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| Fig 3.
Expression of FGFR1 and CEP110 genes.
RT-PCR products were obtained from a variety of tissues and normal and
tumoral hematopoietic cells (listed in "Materials and Methods")
using specific primer pairs of each gene (FGFR1, FA-F9.2; CEP110,
CEPF-CEPR; see Table 1). Each panel is a photograph of the ethidium
bromide-stained agarose gel in which PCR products were electrophoresed.
2 Microglobulin (2 mol/L) amplification was used to estimate the
efficiency of RT-PCR reactions. Labels of the source of the material
and PCR product sizes are indicated at the top of rows and on the left,
respectively.
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| Fig 4.
Expression of the fusion transcripts.
RT-PCR was performed using RNA from the t(8;9) patient's malignant
cells and specific primers located near the translocation breakpoint
(FA-CEPR and CEPF-F9; see Table 1). Chromosomal positions and
transcript sizes are indicated at the top and on the right,
respectively.
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Constitutive kinase activity and tyrosine phosphorylation of
CEP110-FGFR1
NIH3T3 or Cos-1 cells were transiently transfected with
CEP110-FGFR1 cDNA. Anti-C-FGFR1 immunoprecipitates were
immunoblotted with anti-C-FGFR1 antibody to verify the proper
expression of the fusion construct (data not shown) and with
anti-phosphotyrosine antibody to measure the tyrosine phosphorylation
level of the kinase. A portion of the NIH3T3 immunoprecipitate was
also assayed for autophosphorylation activity in the presence of
[32P]ATP. The fusion protein was detectable as a
band of approximately 150 kd (Figure 5,
right panel, 2 last rows). The fusion protein had autophosphorylation
activity and was constitutively tyrosine-phosphorylated regardless of
FGF1 stimulation (Figure 5, left and right panels, respectively). In
contrast, tyrosine phosphorylation of FGFR1 in NFlg26 cells was
stimulated by the addition of FGF1 and heparin (Figure 5, left and
right panels). These results indicated that CEP110-FGFR1 is a
constitutively activated tyrosine kinase and suggested that this
activation may be mediated by dimerization of the CEP110 portion of the
fusion protein, which contains the leucine zippers.
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| Fig 5.
Autokinase assay and phosphorylation on tyrosine of the
CEP110-FGFR1 fusion protein.
NIH3T3 cells transiently transfected by either CEP110-FGFR1 cDNA
(CEP110-FGFR1) or the empty vector (pcDNA3) and FGFR1 overexpressing
cells (NFlg26) were cultured in the presence (+) or absence ()
of FGF1 plus heparin. Immunoprecipitates using anti-C-FGFR1 antibody
were analyzed for autokinase activity (left panel) (autoradiography of
4 hours for all samples) and phosphorylation on tyrosine after Western
blot with anti-phosphotyrosine antibody 4G10 (right panel). The
position of molecular mass standards (in kd) is indicated.
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Immunolocalization of CEP110 during the cell cycle
To further characterize CEP110, we determined its localization in
the cell. Affinity-purified Ab72 antibody was used in indirect immunofluorescence studies in conjunction with a mouse antibody raised
against the human centrosome protein pericentrin. Preimmune rabbit sera
showed no specific reactivity in these studies (data not shown).
As shown in Figures 6A to 6C, G1 cells
revealed CEP110 staining as single, small foci colocalizing with
pericentrin reactivity at the centrosome. In all the cells examined,
the area of CEP110 reactivity at the centrosome was smaller than that
of pericentrin reactivity and was often seen at the center or periphery
of pericentrin staining (data not shown), suggesting the association of
CEP110 with the centrosome. Before and during centrosome separation, CEP110 was observed in association with only 1 of the 2 centrosome duplexes (Figure 6F, arrowhead). However, before prophase, CEP110 reactivity was observed at both centrosome duplexes (Figures 6G to 6I).
At early prophase, as pericentrin reactivity at the centrosome increased, CEP110 reactivity at both centrosomes appeared to decrease and was barely detectable in most cases. Further, from metaphase to
anaphase, only weak reactivity to CEP110 could be detected at the
spindle poles (Figures 6J to 6L and data not shown). By the end of
telophase and the beginning of G1 of the next cell cycle, CEP110 was
once again observed as a small focus at the centrosome of each daughter
cell (Figures 6N, 6O). CEP110 reactivity was not observed at the
intercellular bridge or midbody, where other centrosome components can
be found.
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| Fig 6.
Immunolocalization of CEP110 during the cell cycle.
HeLa cells were double-stained for CEP110 (C, F, I, L, O) and
pericentrin (B, E, H, K, N) and counterstained for DNA with DAPI (A, D,
G, J, M). In early interphase, CEP110 is seen as a small focus at the
centrosome (C). In later interphase cells, when duplicated centrosomes
begin to separate CEP110 reactivity, is only found at 1 centrosome (F,
arrowhead). In late interphase-early prophase cells CEP110 reactivity
can be found on both centrosomes (I). Pericentrin reactivity is
prominent at the spindle poles during metaphase (K), but CEP110
reactivity is barely detectable (L). At telophase, CEP110 reactivity is
detected as small foci at the centrosome in the daughter cells (O,
arrowheads). Bar = 10 µm.
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Fusion of CEP110 to GFP
The localization of CEP110 to the centrosome is likely mediated
through protein-protein interactions. However, several protein-protein interaction motifs are found throughout CEP110, among them 4 leucine zippers, and several coiled-coil regions. Thus, to define which region(s) of CEP110 are necessary for its interaction with the centrosome, a series of CEP110 deletion constructs fused to
GFP were created and transfected in HeLa cells. After 24 hours,
the transfected cells were fixed and immunostained with antibody to pericentrin to identify the centrosome. Figure
7 summarizes the structure of each
CEP110-GFP deletion construct and its ability to localize to the
centrosome. These results demonstrated that the region necessary for
targeting CEP110 to the centrosome was confined to a 170-amino acid
fragment of the C-terminus.
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| Fig 7.
Schematic diagram of GFP-tagged CEP110 constructs.
Various regions of CEP110 were tagged with GFP at their C-terminus,
transfected, and examined for their ability to target the centrosome.
Colocalization of GFP with pericentrin staining was scored as
yes, whereas no colocalization was scored as no. The
amino acid positions of CEP110 in each construct are shown. Shaded
ovals indicate the GFP portion of the fusion protein.
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CEP110-FGFR1 is found in the cytoplasm
The localizations of fusion CEP10-FGFR1 and endogenous CEP110
proteins were compared by indirect immunofluorescence in transiently transfected Cos-1 cells. In control cells transfected with the empty
vector (pcDNA3) and revealed by the purified antibody directed against
the CEP110 N-terminus (Ab5'2), the endogenous CEP110 was found in
the same localization, ie, concentrated in the centrosome (Figure
8A). Similar patterns were found using the
C-terminus CEP110 antibody (Ab72) (data not shown) and the human serum
(Figure 8C). In contrast, the fusion protein CEP110-FGFR1 was detected mainly in the cytoplasm (Figures 8B, 8D). The fusion protein was not
detected by the CEP110 C-terminus antibody (Ab72), which recognizes an
epitope not present in the chimeric protein (data not shown). Altogether, the CEP110-FGFR1 fusion protein resulting from the t(8;9)
was translocated to a subcellular compartment different from both
CEP110 and FGFR1 wild-type proteins, which are centrosome and plasma
membrane-bound, respectively.
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| Fig 8.
Immunolocalization of endogenous CEP110 and CEP110-FGFR1
fusion protein.
Cos-1 cells transfected with the expression vector pcDNA3, either empty
(A, C) or containing CEP110-FGFR1 fusion cDNA (B, D),
were subjected to double- immunofluorescence staining with anti-CEP110
antibodies (Ab5'2 and human immune serum), revealed by
Alexa-conjugated antirabbit (for Ab5'2) or FITC-conjugated
antihuman (for human serum) secondary antibodies and 7-AAD to visualize
endogenous CEP110 (arrowheads) and CEP110-FGFR1 (both in green) and the
DNA (in red), respectively. Magnification, × 1000.
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Discussion |
In a previous work,13 we identified FGFR1 as the
gene involved in the specific stem cell myeloproliferative disorder
associated with the 8p12 region. We report here the molecular
characterization of the third event associated with MPD, ie, the
t(8;9)(p12;q33). In this case, the FGFR1 gene was fused
in-frame to CEP110, a novel gene coding for a centrosome
protein that behaved as an autoantigen in a human autoimmune disease.
The t(8;9) breakpoint in the FGFR1 gene is localized in exon 8, 12 bp upstream of the exon 8/intron 8 junction. It is distinct from the breakpoints in the
t(6;8)15 and
t(8;13)16-20 that are located slightly
more 3' within FGFR1 intron 8, but it preserves the
same FGFR1 sequence in the chimeric protein. Such fairly
precise rearrangements, clustered either in an intron or with
a small deletion of the 3' end of the upstream exon, have
already been observed, for example, in the RET oncogene in
thyroid carcinoma.33
Analysis of the deduced amino-acid sequence of CEP110 reveals extensive
regions of coiled-coil structure. In this respect, CEP110 is similar to
other centrosome proteins that function as antigens, among them
pericentrin,34 ninein,35 and
CEP250/CNAP1.25 In addition to the coiled-coil structure, 4 leucine zippers are found in CEP110. Leucine zipper motifs are
well-characterized motifs involved in protein-protein
interaction36,37 and are found in other centrosome proteins
including ninein35 and CEP250 (Mack and Rattner,
unpublished observations).
In the MPD linked to 8p12, the key oncogene is
FGFR1.13 In the t(8;9) patient's leukemic cells, 2 reciprocal fusion genes were identified as a result of the
translocation. CEP110-FGFR1 transcript encodes an aberrant
tyrosine kinase of approximately 150 kd, which contains the 808 first
amino acid residues from CEP110 (81.3% of the entire protein),
including the leucine zippers, joined to the FGFR1 intracellular region
minus the major part of its juxtamembrane domain. CEP110-FGFR1 is
constitutively phosphorylated in transfected cells. This is the case
for the 2 other fusion proteins involved in the 8p12 MPD,
FIM-FGFR1,16 and FOP-FGFR1 (Guasch et al, January 1999, unpublished data). These activated aberrant tyrosine
kinases are likely to promote leukemogenesis through constitutive
activation of the FGFR1 kinase mediated by the N-terminus
homodimerization motifs of the FGFR1 partners, which contain either
zinc fingers for FIM/ZNF198,16-20 leucine-rich region for
FOP,15 or leucine zippers for CEP110. In a recent work, 21 we showed that FIM-FGFR1 has constitutive
dimerization capability mediated by the FIM N-terminus sequences.
The fusion of 2 proteins resulting from a chromosomal translocation
event often creates an aberrantly located protein.38 We
show here that CEP110 is a centrosome component. Based on the indirect
immunofluorescence pattern, we suggest that CEP110 is a component of
the mature centrosome and has a function in centriole maturation. In
human cells, the centrosome is a distinct cytoplasmic protein complex
that is the primary microtubule-organizing center of the cell (see
Brinkley39). To identify the domains of CEP110 that specify
its centrosome localization, various regions of the protein were fused
to GFP and transfected to HeLa cells. The centrosome-binding domain of
CEP110 was found to lie within a 170-amino acid region near the
C-terminus (amino acids 617-787). This region includes the fourth
leucine zipper motif and is primarily of coiled-coil structure. The
presence of a single leucine zipper in the centrosome-binding domain of
CEP110 is similar to that found for the centrosome-targeting domain of
CEP250 (Mack and Rattner, June 1998, unpublished data). Because the region targeting CEP110 to the centrosome is retained in
CEP110-FGFR1, there is the possibility that the constitutively activated fusion protein is located within this organelle, therein inducing disruption of centrosome structure, function, or both. Indeed,
transient overexpression of centrosome-associated kinases PLK1 and
STK15/BTAK/aurora2 in NIH3T3 cells results in centrosome amplification,
aneuploidy, and transformation.40-43 We demonstrate here
that CEP110-FGFR1 has an aberrant cellular localization compared to its
normal counterparts. Although endogenous FGFR1 is at the membrane and
CEP110 has a unique centrosome localization, CEP110-FGFR1 predominantly
localizes in the cytoplasm and is not confined to either the membrane
or the centrosome (however, we cannot completely eliminate the
possibility that a proportion of CEP110-FGFR1 may go to the centrosome
and exert a potential effect there but is undetected under the
conditions used in this study). FIM-FGFR1, another fusion protein
involved in the 8p12 MPD, also localizes within the
cytoplasm.21 Thus, in this particular syndrome, fusion proteins may affect the growth of hematopoietic stem cell through continuous kinase stimuluspresumably triggered by its dimerization mediated by the protein-protein interaction motifs of the FGFR1 protein partnerand inappropriate recruitment in the cytoplasm of
signaling substrates. The oncogenic activation of protein tyrosine kinases through structural alterations produced by chromosomal rearrangements has been frequently associated with human hematologic malignancies.16,44-47 Another mechanism of activation
involves gene dysregulation, in particular alterations of other FGFR
family members in multiple myeloma48 or in
osteosarcoma.49 The oncogenic kinases are constitutively
activated and variably affect the signaling pathways.
The 3 FGFR1 partners are different, unrelated proteins with different
cellular localizations, ie, nuclear and nucleolar for FIM,21 cytoplasmic for FOP (Guasch et al, January 1999, unpublished data), and centrosome for CEP110 (as
described in the current work). Accumulating data (clustered
breakpoints in FGFR1, presence of dimerization motifs in each
partner, cytoplasmic localization of the fusion protein) suggest that a
common mechanism may sustain the oncogenic activity of the rearranged
FGFR1 kinase. Further work will aim at the identification of this
mechanism and the target cell in which it is abnormally triggered.
| |
Acknowledgments |
We thank Drs Mawas and Maraninchi for encouragement and comments. We
also thank J. Adélaide and B. Zhang for occasional help in
cloning and sequencing the fusion genes, T. Alario for CD34+ cell
purification, and V. Ollendorff for helpful advice.
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Footnotes |
Submitted February 26, 1999; accepted November 8, 1999.
G.G., G.J.M., and C.P. contributed equally to this work.
Supported by Inserm, Institut Paoli-Calmettes, and by grants from the
Ligue Nationale contre le Cancer, Comité du Var de la Ligue
Nationale contre le Cancer, and FEGEFLUC. G.G. is a recipient of a
fellowship from MESR; C.P. is supported by the Société Française d'Hématologie; G.J.M. is supported by
the Alberta Heritage Foundation for Medical Research; J.B.R. is
supported by the National Cancer Institute of Canada, with funds
from the Canadian Cancer Society.
Reprints: Marie-Josèphe Pébusque,
Laboratoire d'Oncologie Moléculaire, Inserm U119, Institut de
Cancérologie et d'Immunologie de Marseille, 27 Boulevard
Leï Roure, 13009 Marseille, France; e-mail:
pebusque{at}marseille.inserm.fr.
The publication costs of this
article were defrayed in part by
page charge payment. Therefore,
and solely to indicate this fact,
this article is hereby marked
"advertisement"
in accordance with 18 U.S.C.
section 1734.
| |
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Abstract
Introduction