PRAM-1 Is a Novel Adaptor Protein Regulated by Retinoic Acid (RA) and Promyelocytic Leukemia (PML)-RA Receptor alpha  in Acute Promyelocytic Leukemia Cells*

Christel Moog-Lutzabc, Erik J. Petersonbdefg, Pierre G. Lutzab, Steve Eliasond, Florence Cavé-Rianta, Andrew Singerd, Yolande Di Gioiaa, Sally Dmowskidf, Joanne Kamensh, Yvon E. Cayreaijk, and Gary Koretzkydfj

From the a Unité INSERM 417, Hôpital Saint-Antoine, 184 Rue du Faubourg Saint-Antoine, 75012 Paris, France, the Departments of d Pathology and e Medicine and the f Abramson Family Cancer Research Institute, University of Pennsylvania, Philadelphia, Pennsylvania 19104, the h BASF Bioresearch Corporation, Worcester, Massachusetts 01605, and the i Department of Microbiology/Immunology, Kimmel Cancer Institute, Thomas Jefferson University, Philadelphia, Pennsylvania 19107-5541

Received for publication, December 26, 2000, and in revised form, March 21, 2001

    ABSTRACT
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INTRODUCTION
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The t(15;17) translocation, found in 95% of acute promyelocytic leukemia, encodes a promyelocytic leukemia (PML)-retinoic acid receptor alpha  (RARalpha ) fusion protein. Complete remission of acute promyelocytic leukemia can be obtained by treating patients with all-trans retinoic acid, and PML-RARalpha plays a major role in mediating retinoic acid effects in leukemia cells. A main model proposed for acute promyelocytic leukemia is that PML-RARalpha exerts its oncogenic effects by repressing the expression of retinoic acid-inducible genes critical to myeloid differentiation. By applying subtraction cloning to acute promyelocytic leukemia cells, we identified a retinoic acid-induced gene, PRAM-1 (PML-RARalpha target gene encoding an Adaptor Molecule-1), which encodes a novel adaptor protein sharing structural homologies with the SLAP-130/fyb adaptor. PRAM-1 is expressed and regulated during normal human myelopoiesis. In U937 myeloid precursor cells, PRAM-1 expression is inhibited by expression of PML-RARalpha in the absence of ligand and de novo superinduced by retinoic acid. PRAM-1 associates with other adaptors, SLP-76 and SKAP-55HOM, in myeloid cell lines and with protein tyrosine kinase lyn. By providing the first evidence that PML-RARalpha dysregulates expression of an adaptor protein, our data open new insights into signaling events that are disrupted during transformation by PML-RARalpha and induced by retinoic acid during de novo differentiation of acute promyelocytic leukemia cells.

    INTRODUCTION
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
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DISCUSSION
REFERENCES

In human acute promyelocytic leukemia (APL),1 a specific translocation, t(15;17) (1), creates a promyelocytic leukemia (PML)-retinoic acid receptor alpha  (RARalpha ) fusion between the amino-terminal region of the PML locus (2-5) and the carboxyl terminus of the RARalpha (6, 7). The causal role of the PML-RARalpha fusion protein in APL has been demonstrated in transgenic mice (8), although its effects do not appear to confer a fully malignant phenotype in murine promyelocytes (9). Leukemic transformation is likely to initiate in a subpopulation of hematopoietic stem/progenitor cells (10). In these cells, PML-RARalpha confers resistance to growth factor starvation (10), presumably exerting its oncogenic effect through repression of the genetic program normally leading to full myeloid differentiation. Because external signals such as cytokines regulate limited expansion and maturation of hematopoietic progenitor cells in the bone marrow, PML-RARalpha may initiate leukemia transformation in these cells by disrupting differentiation signaling pathways. However, though cytosolic signalings in APL cell differentiation are getting increasing attention (11), genes whose expression is repressed by PML-RARalpha remain poorly identified (9). Complete remission of APL can be obtained by treating patients with all-trans retinoic acid (ATRA) (12-15), which induces full differentiation of leukemic cells (15). This suggests that pharmacological levels of ligand can reverse the oncogenic effects of PML-RARalpha . It is likely that PML-RARalpha mediates the sensitivity of APL blasts to ATRA-induced differentiation. Indeed, ligand binding to the fusion protein induces the release of transcriptional repression (16), and PML-RARalpha may have an ATRA-dependent activator function (17). However, little is known about specific signaling through which ATRA induces differentiation.

Antigens binding to T and B cell receptors initiate intracellular signaling events leading to clonal expansion of reactive cells. Unlike growth factor receptors, T cell receptor and B cell receptor lack intrinsic tyrosine kinase activities. Instead, antigen receptor engagement results in activation of cytoplasmic protein tyrosine kinases (PTK). Among the substrates of the antigen receptor PTKs are members of a class of proteins that mediate protein-protein interactions, known as adaptors (18, 19). With multiple binding sites and the potential to create combinations of multiprotein complexes, adaptors are well suited to integrate signals from surface receptors. Little is known about adaptor proteins in myeloid cells (18).

Like APL patient blasts, NB4 leukemic cells carry the t(15;17) and undergo ATRA-induced granulocytic differentiation (20). By applying a subtraction cloning approach to these cells, we identified a novel ATRA-inducible gene designated PRAM-1 (PML-RARalpha target gene encoding an Adaptor Molecule-1). The predicted PRAM-1 protein contains proline-rich and SH3-like domains and shares structural homologies with the adaptor SLAP-130/fyb (21, 22). Ectopic expression of PML-RARalpha in U937 myeloid precursor cells inhibits PRAM-1 expression, which is superinduced upon treatment with ATRA. Furthermore, PRAM-1 is expressed and regulated early during in vitro differentiation of primary human hematopoietic stem/progenitor cells. Finally, PRAM-1 interacts with known partner molecules of SLAP-130/fyb, such as SLP-76 and SKAP-HOM, as well as with the PTK lyn. These observations point to PRAM-1 as an adaptor protein with potentially important roles in leukemogenesis and myeloid differentiation.

    EXPERIMENTAL PROCEDURES
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Cell Lines, Culture, and Differentiation-- NB4 (20), NB4.306 (23), and U937-PR9 and U937-MT cell lines (17) were cultured in RPMI 1640 medium with 10% fetal bovine serum (Life Technologies, Inc.) and 2 mM L-glutamine (Life Technologies, Inc.). COS-7 cells were grown in 9-cm Petri dishes in Dulbecco's modified Eagle's medium containing 5% fetal bovine serum. Cell viability was estimated using standard trypan blue dye exclusion. Cells were grown at 37 °C in a humidified atmosphere of 5% CO2.

Exponentially growing NB4, NB4.306, and U937-derived cells (<= 1 × 106 cells/ml) were seeded at 2 × 105 cells/ml 16 h prior to ATRA treatment. U937-PR9 and U937-MT cells were used for induction of PML-RARalpha expression or as control, respectively. Cells were cultured either with or without varying concentrations of ZnSO4 (Sigma) and ATRA (Sigma). Differentiation was assessed by (i) the percentage of cells with nitro blue tetrazolium (Sigma) deposits, as described (24), and (ii) cell morphology under light microscopy on cytospin slides stained with May-Grünwald-Giemsa (Sigma).

Human Cell Preparation and Liquid Culture-- Cord blood cells were obtained with informed consent from healthy donors at the end of full term deliveries at the Saint-Vincent de Paul Hospital (Paris, France). Sample preparation (achieving a purity of 95 ± 2% CD34+) and CD34+ cell culture were conducted as described (25). Primary APL cells expressing the PML-RARalpha gene were obtained from patients diagnosed at Saint-Louis Hospital (Paris, France) and kindly provided by C. Chomienne. Cells were purified and cultivated with 10-7 M ATRA as described (14). 5 days after treatment, cells were tested for differentiation (>= 80% nitro blue tetrazolium-positive). Mononuclear cells and granulocytes were isolated from peripheral blood using a Ficoll Paque (Amersham Pharmacia Biotech) density gradient. Monocytes were further purified from lymphocytes using an indirect labeling system followed by a magnetic separation on a macs column (Myltenyi Biotec). Cell purity assessed by May-Grünwald-Giemsa was >= 95%.

PRAM-1 cDNA Cloning-- A cDNA fragment isolated from an ATRA-treated NB4 cDNA library2 contained 1063 bp corresponding to the 3' end of PRAM-1 cDNA. This fragment was used to search expressed sequence tag data bases (GenBankTM/EMBL and Incyte Genomics Lifeseq®) and, in combination with RACE-PCR reactions using HL-60 RACE-ready cDNA (CLONTECH), allowed us to generate 1800 bp of continuous open reading frame sequence. A 494-bp 5' cDNA sequence was amplified by RACE-PCR from ATRA-treated NB4 RNA (with 5 × 10-7 M for 48 h) using the Marathon cDNA amplification kit (CLON- TECH) with a 5'-CCTTGGAAACGGAGTGGCCCCCAGC-3' primer. Sequence homologies were identified using the FastA and BLAST programs by searching GenBankTM, EMBL, and the Incyte Genomics Lifeseq® data base. Sequence information from many different Incyte Genomics data base clones was used to confirm and extend the results of RACE-PCR experiments. For example, clone 3418957H1 is 100% identical to the 5' terminal end of the final PRAM-1 RACE product clone. Using the Marathon cDNA and the Advantage-GC polymerase (CLONTECH), a contiguous cDNA was generated by reverse transcription-PCR amplification of PRAM-1 from ATRA-treated NB4 RNA using 5'-GGCCCCAGCTCGGGTCCCACTCATC-3' and 5'-TGGCTGTCCTGGCCCCACGCCTACC-3' primers. PCR products were subcloned into pT-Adv (CLONTECH) and sequenced. All PCR-generated cDNAs were confirmed by multiple, independent derivations from RNA templates.

Sequencing and Computer Analysis-- Plasmid DNA was purified through Nucleobond columns (Macherey-Nagel), and double-stranded DNA templates were sequenced using pBluescript and internal primers. Sequence analysis and alignments were obtained using the GCG programs (Wisconsin Package, version 10.0-UNIX, Genetic Computer Group, Inc.). Sequence homologies were identified using the FastA and BLAST programs by searching data banks as above and, in the case of translated sequences, by searching Swiss-Prot, PIR/NBRF, and SPTREMBL data banks.

Plasmid Constructs-- The PRAM-1 coding sequence was subcloned into a pCB6+-derived expression vector (26) under the control of the zinc-inducible sheep metallothionein promoter from the pMT010 vector (27), resulting in the pMT-PRAM-1 vector. The PRAM-1 coding sequence was also inserted into the pAT4 vector (28), to direct the expression of PRAM-1 tagged with the F domain of the human estrogen receptor at its amino terminus. SLP-76 and SKAP-HOM cDNAs were inserted into the pEF-BOS expression vector (29, 30), at a site located 3' to the sequences encoding the Flag epitope.

Northern Blots-- Total RNA extraction and hybridization were as described (25). Human RNA Master Blot and human immune system multiple tissue Northern blot II were from CLONTECH. The PRAM-1 probe corresponded to the 3' end (1063 bp) of the PRAM-1 cDNA. The glyceraldehyde-3-phosphate dehydrogenase (GAPDH) probe was a 574-bp PCR product obtained using 5'-ATCACCATCTTCCAGGA-3' sense and 5'-CCTGCTTCACCACCTTCTTG-3' antisense primers. Radioactivity was detected and quantified using a Storm 860 phosphorimaging system (Amersham Pharmacia Biotech).

Semi-quantitative Reverse Transcription-PCR-- Total RNA from CD34+ cells induced to differentiate toward the myeloid lineage was extracted at different times using an Rneasy mini kit (Qiagen). Reverse transcription was performed using the AdvantageTM system (CLONTECH). Expression of the PRAM-1 and control beta -actin mRNA in differentiating cells was analyzed by semi-quantitative PCR using a GeneAmp PCR System 9600 (PerkinElmer Life Sciences) with the following primers corresponding to distinct exon sequences: sense (5'-CCTCAGTTCAGCAAGCCGCCAGGAG-3') and antisense (5'-CCAGGGGGAGTGGTTGGTTTTCCAG-3') for PRAM-1; sense (5'-CCTCGCCTTTGCCGATCC-3') and antisense (5'-GGATCTTCATGAGGTAGTCAGTC-3') for beta -actin. PCR cycles were conducted with (i) denaturation for 45 s at 94 °C, (ii) annealing for 45 s at 60 °C, and (iii) extension for 1 min at 72 °C, followed by an extension final step at 72 °C for 7 min. The number of PCR cycles was determined for PRAM-1 (35 cycles) and beta -actin (25 cycles) to ensure quantification of the PCR products in a linear range of amplification. The beta -actin PCR reaction was performed using cDNA prepared at each day of the kinetic to determine the dilutions needed to provide equal amounts of reverse transcription products for all samples. Aliquots of each PCR reaction were electrophoresed, transferred onto nylon filters (Hybond-N, Amersham Pharmacia Biotech), and hybridized with the PRAM-1 (5'-CGGCACAGCATCTCCTCATTG-3') and beta -actin (5'-ACCCCGTGCTGCTGACCGAGG-3') 32P-labeled probes as described (25). Radioactivity was quantified using a Storm 860 phosphorimaging system (Amersham Pharmacia Biotech).

Antibodies-- An amino-terminal peptide (ESHQDFRSIKAKFQA) was synthesized according to the deduced amino acid sequence of the PRAM-1 protein and coupled to keyhole limpet hemocyanin through a cysteine residue added to the carboxyl-terminal amino acid of the peptide (Eurogentec). Rabbit sera (1PNP) were collected before (pre-immune) and 3 months after the initial injection and three booster immunizations (Eurogentec). A polyclonal sheep antiserum (Elmira Biologicals) was raised against the carboxyl-terminal 134 amino acids of human PRAM-1 fused with glutathione S-transferase (generated by cloning the corresponding PRAM-1 coding sequence into the pGEX vector (Amersham Pharmacia Biotech)). The monoclonal antibody directed against the F domain of the human estrogen receptor was as described (28). Anti-Tyr(P) monoclonal antibody 4G10 was purchased from Upstate Biotechnologies, Inc., anti-Flag monoclonal antibody M2 was purchased from International Biotechnologies, Inc., and anti-lyn was purchased from Santa Cruz Biotechnology, Inc. Anti-SLP-76 sheep antiserum 0083 and anti-SKAP-HOM rabbit antiserum were as described (29, 30).

In Vivo Expression and Protein Extracts-- COS-7 cells were transfected using calcium phosphate coprecipitation (31) of 0.5-µg DNA vectors (adjusted to 14 µg per 9-cm Petri dish with pBluescript carrier DNA). The medium was changed after 16 h, and for zinc-induced expression of PRAM-1, 75 µM ZnSO4 was added to the medium. Thirty-six h after transfection, COS-7 cells were harvested, washed once in phosphate-buffered saline, and resuspended in lysis buffer (0.4 M KCl, 20 mM Tris-HCl, pH 7.9, 20% glycerol, 5 mM dithiothreitol, 0.2 mM phenylmethylsulfonyl fluoride, 1 mM Na3VO4, and a protease inhibitor mixture (Sigma)). ATRA-treated NB4 cells were washed once in phosphate-buffered saline and resuspended in lysis buffer. After two freeze-thaw cycles in liquid nitrogen, the resulting cell lysates were cleared by a 15-min 10,000 × g centrifugation at 4 °C.

Immunoprecipitation-- After one-step preclearing (30 min, 4 °C) with GammaBind G-Sepharose (Amersham Pharmacia Biotech), antibodies (1 µl of antiserum or 1 µl of ascites fluid) were added to the cell protein extract, in a binding buffer adjusted to 20 mM Tris-HCl, pH 7.5, 0.25 M NaCl, and 0.1% Nonidet P-40. After 90 min at 4 °C, 15 µl of GammaBind G-Sepharose suspension were added for an additional hour. Sepharose beads were then washed three times in 0.5 ml of the binding buffer. After 5 min of boiling in Laemmli buffer, samples were resolved by SDS-polyacrylamide gel electrophoresis (PAGE) and transferred onto polyvinylidene difluoride membranes (PerkinElmer Life Sciences). Background immunoreactivity was reduced by pre-incubating membranes with phosphate-buffered saline containing 5% nonfat dry milk and 0.1% Tween 20 for 1 h. Western analysis was carried out with antisera diluted 1:5000 in phosphate-buffered saline containing 0.1% Tween 20. Detection of antibody binding was achieved with horseradish peroxidase-conjugated secondary antibodies (Jackson Laboratories). Enzymatic activity was detected using the chemiluminescence reagent plus kit (PerkinElmer Life Sciences) and autoradiography.

    RESULTS
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
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DISCUSSION
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PRAM-1 mRNA Is Regulated during ATRA-induced Granulocytic Differentiation of NB4 Cells-- PRAM-1 mRNA expression was increased 4 h after exposure of NB4 cells to ATRA, with maximum expression at 96 h (Fig. 1A). Sequential treatment of NB4 cells with cycloheximide and ATRA indicated that ATRA-induced up-regulation of the PRAM-1 mRNA does not require de novo protein synthesis (Fig. 1A). As expected, ATRA did not affect growth and differentiation (Fig. 1B, a and b, respectively) of NB4.306, an ATRA-resistant NB4 subclone that has lost the capacity to encode an intact ATRA-binding PML-RARalpha fusion protein (23). In these cells, no induction of PRAM-1 mRNA was observed (Fig. 1B, c). In contrast, expression of PRAM-1 mRNA was strongly up-regulated in NB4 cells induced to growth arrest and differentiation by ATRA (Fig. 1B, a and b, respectively). These data strongly suggest that increased PRAM-1 mRNA expression correlates with the capacity of leukemia cells to undergo granulocytic differentiation when treated with ATRA.


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Fig. 1.   PRAM-1 is induced in ATRA-treated NB4 cells. A, time course in response to 5 × 10-7 M ATRA in NB4 cells. Where indicated, de novo protein synthesis was inhibited by pretreating cells for 30 min with 10 µg/ml cycloheximide (CHX) followed by an additional 8 h in the absence (0) or presence (8) of ATRA. B, PRAM-1 expression correlates with the capacity of NB4 cells to differentiate. NB4 and NB4.306 cells cultured with 10-6 M ATRA were harvested after 0, 24, and 48 h. The percent of viable (a) and nitro blue tetrazolium-positive (b) cells is shown, as well as the level of PRAM-1 mRNA expression (c). Northern blots were performed using 5 µg (A) or 3 µg (B) of total RNA. Top and bottom panels show signal obtained with PRAM-1 and GAPDH (to control for RNA quantities) probes. C, cDNA and deduced amino acid sequences of the human PRAM-1. Nucleotide residues are numbered in the 5' to 3' orientation, and amino acids in the reading frame are designated by the one-letter code. Kozak and poly(A) addition sequences are underlined, and the asterisk indicates the stop codon. The eight proline-rich repeats are underlined in bold. Proline residues clustered as either a type I or type II SH3 recognition motif are underlined with dotted lines. The SH3-like carboxyl-terminal domain is boxed. Tyrosine residues within motifs that bind SH2 domains are shaded.

PRAM-1 Has the Structural Features of a Novel Adaptor Protein-- A 2356-bp PRAM-1 cDNA was obtained from ATRA-treated NB4 cells (Fig. 1C). The sequence surrounding a 5' ATG codon is in agreement with the consensus initiation sequence (32). The 3' untranslated region ends with a ATAAA polyadenylation signal followed by a poly(A) tail (33). The complete open reading frame of PRAM-1 consists of 2154 bp translated into a predicted protein of 718 amino acids. Residues 70-165 comprise a series of eight proline-rich repeats with the consensus sequence KPP(P/Q)P(E/Q)(V/A/ F)TDLPK. Several proline residues are clustered as type I (RXPXXP) or type II (PXXPXR) SH3 recognition motifs (34). In the carboxyl-terminal region of PRAM-1, two tyrosine-based motifs have sequences conforming to the general motif preferentially selected by Group I SH2 domains (35). PRAM-1 shares homologies with the hematopoietic-specific adaptor molecule SLAP-130/fyb (21, 22), with a 57% similarity concentrated in the SH3-like domains in the extreme carboxyl termini of the two proteins. Both PRAM-1 and SLAP-130/fyb contain a central, proline-rich region. Together, these data suggest that PRAM-1 is a novel adaptor protein.

PRAM-1 mRNA Is Expressed and Regulated in Primary Hematopoietic Tissues-- PRAM-1 mRNA was mainly expressed in bone marrow and peripheral blood leukocytes (Fig. 2A), in freshly purified human granulocytes and monocytes, as well as, albeit to a much lesser extent, in lymphocytes (Fig. 2B). PRAM-1 mRNA was not detected in non-hematopoietic tissues, except in lung, which is known to contain a number of myelo-monocytic cells (data not shown). Purified CD34-positive human cord blood cells expressed low levels of the PRAM-1 mRNA (Fig. 2C, b, lane 1), which increased gradually during myeloid differentiation, with maximal expression at the promyelocytic stage (Fig. 2C, b, lane 6). Analysis of leukemia cell lines assigned to specific hematopoietic lineages supported the notion that PRAM-1 is mainly expressed in myeloid cells (data not shown). Together, these results indicate that PRAM-1 mRNA is expressed and regulated during normal myelopoiesis.


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Fig. 2.   Expression of PRAM-1 mRNA in primary hematopoietic tissues. A and B, autoradiograms of PRAM-1 mRNA expression in immune tissues and peripheral blood cells. Northern blots were obtained from CLONTECH (A) or were performed using 5 µg of total RNA from granulocytes, monocytes, and lymphocytes (B). In A and B, GAPDH was used as a probe for assessment of RNA quantities in each lane. PBL, peripheral blood leucocytes. C, PRAM-1 mRNA is up-regulated during myeloid differentiation of human hematopoietic stem/progenitor cells. a, morphological differentiation of CD34+ cells toward the myeloid lineage. b, Southern blot analysis (upper panels) and relative expression (lower panel) of reverse transcripton-PCR products from CD34+ cells differentiating toward the myeloid lineage. Expression of beta -actin mRNA was assessed as a control. Error bars indicate standard deviations from the results of three independent PCRs. This experiment was performed a second time with independent cell cultures, with similar results. A parallel PCR was conducted without addition of cDNA as a negative control (NC) or cDNA obtained from ATRA-treated NB4 cells as a positive control (PC).

PML-RARalpha Inhibits, and ATRA Subsequently Superinduces, Expression of PRAM-1 mRNA in U937 Cells-- In contrast to NB4 cells, PRAM-1 mRNA was not induced in NB4.306 cells, suggesting that an intact PML-RARalpha is required for ATRA to regulate PRAM-1 mRNA expression. To explore further the role of PML-RARalpha in the expression of PRAM-1 mRNA, we used cell lines generated by stable transfection into human U937 myeloid precursor cells of a zinc-inducible vector without an exogenous cDNA (U937-MT) or driving the PML-RARalpha cDNA (U937-PR9) (17). Zinc-induced expression of the PML-RARalpha protein in U937-PR9 cells resulted in an 8-fold decrease of PRAM-1 mRNA expression (Fig. 3A, lane 2 versus lane 1). Subsequent ATRA treatment of these cells resulted in a 60-fold increase of PRAM-1 mRNA expression at 24 h (Fig. 3A, lane 6 versus lane 2). No repression was observed in zinc-treated U937-MT cells (Fig. 3A, lane 8 versus lane 7), and a 3-fold increase was observed in these cells with ATRA treatment (Fig. 3A, lane 12 versus lane 7), as expected, because U937 cells express an active retinoic acid receptor (36). U937-PR9 and U937-MT cells were then left untreated or treated with increasing concentrations of ZnSO4 with or without ATRA (Fig. 3B). This dose-response experiment indicates that repression and ATRA inducibility of PRAM-1 correlates with the amount of the PML-RARalpha expressed. Together, these results suggest that PRAM-1 is a PML-RARalpha target gene.


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Fig. 3.   PRAM-1 mRNA expression is dysregulated by PML-RARalpha . A, PRAM-1 mRNA expression is down-regulated by ectopic expression of PML-RARalpha in U937 cells and markedly increased following ATRA treatment. Autoradiogram (upper panels) and relative expression (lower panel) of the PRAM-1 mRNA in U937-PR9 and U937-MT cells either untreated (-) or treated (+) with 100 µM ZnSO4 for 12 h, followed by exposure to 5 × 10-7 M ATRA for different times. B, autoradiogram (left panels) and relative expression (right panel) of PRAM-1 mRNA in U937-PR9 and U937-MT cells treated with increasing concentrations of ZnSO4. Cells were either untreated or treated with 5 × 10-7 M ATRA (-ATRA and +ATRA, respectively) for 12 h. The signal was quantified using densitometric analysis of phosphorimaging data. PRAM-1 mRNA quantities were adjusted for GAPDH expression. In A (lower panel) and B (right panel), mean values and standard errors from two independent experiments are shown. C, PRAM-1 mRNA is induced in ATRA-treated primary APL cells. Cells were purified from three untreated patients cultivated in the absence (-) or presence (+) of 10-7 M ATRA for 5 (APL#2) or 6 (APL#1 and APL#3) days. Northern blots were performed using 8 µg (A and B) or 2 µg (C) of total RNA. Hybridization with a GAPDH probe controlled for RNA quantities in each lane.

PRAM-1 mRNA was highly induced by in vitro treatment with ATRA of blasts freshly obtained from peripheral blood of newly diagnosed patients with APL (Fig. 3C) expressing the PML-RARalpha gene. This induction correlated with ATRA-induced differentiation of these cells, as assessed morphologically and by nitro blue tetrazolium reduction assay (data not shown).

PRAM-1 Is an Adaptor Molecule-- Using COS-7 cells transfected with a PRAM-1-expressing vector, anti-PRAM-1 polyclonal antibodies detected a specific protein migrating with an apparent molecular mass of 97 kDa (Fig. 4A, a). The discrepancy between the predicted molecular mass of 79 kDa and its migration on SDS-PAGE was probably due to numerous prolines and charged residues in PRAM-1, as also noted for the SLP-76 (37) and SLAP-130/fyb (21) adaptor proteins. In ATRA-treated NB4 cells, endogenous PRAM-1 migrated at the same rate as ectopically expressed PRAM-1 in COS-7 cells (Fig. 4A, a), and was tyrosine-phosphorylated upon pervanadate treatment (Fig. 4A, b). In kinetic studies, PRAM-1 protein expression was induced after 6 h of ATRA treatment and persisted through 6 days (Fig. 4B).


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Fig. 4.   PRAM-1 is an adaptor molecule. A, PRAM-1 protein is induced upon ATRA treatment in NB4 cells and is tyrosine-phosphorylated. a, COS-7 cells transfected with pMT-PRAM-1 were either untreated (-) or treated (Zn) with 75 µM ZnSO4 for 24 h. NB4 cells were either untreated (-) or treated (RA) with 5 × 10-7 M ATRA for 12 h. COS-7 cell lysates (10 µg) and protein extracts from 105 NB4 cells were separated by SDS-PAGE and immunoblotted for PRAM-1. b, NB4 cells were treated with 10-6 M ATRA for 72 h and either left unstimulated (-) or stimulated with pervanadate (PV) for 5 min. Cells were then lysed, subjected to immunoprecipitation with anti-PRAM-1 antiserum, and then assessed for phosphotyrosine (4G10) or PRAM-1. B, expression of PRAM-1, SKAP-HOM, and SLP-76 during ATRA-induced differentiation of NB4 cells. NB4 cells were treated with 5 × 10-7 M ATRA for different times. Protein extracts corresponding to 105 cells were analyzed by Western blot, using anti-PRAM-1, -SKAP-HOM, and -SLP-76 polyclonal antibodies. C, PRAM-1 associates with SKAP-HOM and SLP-76. a, vectors encoding F-PRAM-1, Flag-SLP-76, and Flag-SKAP-HOM were transfected (+) into COS-7 cells. 25-µg aliquots of each protein extract were immunoprecipitated (IP) with monoclonal anti-F antibodies. Immunoprecipitated proteins (right panels), as well as a 10-µg aliquot of the protein extracts (left panels) were separated by SDS-PAGE and analyzed for PRAM-1, SLP-76, and SKAP-HOM (Western blot, WB). b, protein extracts from ATRA-treated NB4 cells were immunoprecipitated (IP) with anti-PRAM-1 or anti-SKAP-HOM polyclonal antibodies or with control PRAM-1 pre-immune serum (control antibody, Control Ab). Immunoprecipitated proteins were separated by SDS-PAGE and transferred onto nitrocellulose. After Western blotting, membranes were hybridized with anti-PRAM-1 or anti-SKAP-HOM polyclonal antibodies. The arrowhead indicates the heavy chain of immunoglobulins (Ig (H)). c, ATRA-treated NB4 cells were either unstimulated (-) or stimulated (+) with pervanadate for 5 min. Lysates were subjected to immunoprecipitation with anti-SLP-76 or anti-PRAM-1 antisera or with the corresponding pre-immune serum. The resulting complexes were resolved by SDS-PAGE and analyzed for SLP-76 or PRAM-1. The asterisk indicates a nonspecific band. D, PRAM-1 associates with lyn in ATRA-treated NB4 cells. 120-µg aliquots of the ATRA-treated NB4 cell extracts were immunoprecipitated with anti-PRAM-1 polyclonal antibodies or with control PRAM-1 pre-immune serum (Control Ab). Immunoprecipitated proteins (right panels), as well as 40-µg aliquots of untreated or ATRA-treated protein extracts (left panels), were separated by SDS-PAGE and transferred onto polyvinylidene difluoride. Membranes were hybridized with anti-PRAM-1 or anti-lyn antibodies.

PRAM-1 shares sequence homologies with the adaptor protein SLAP-130/fyb, which can associate with SLP-76 (21, 22) and SKAP-HOM (also known as SKAP55-R) in T cells (29, 38). Upon finding that SLP-76 was expressed constitutively and that SKAP-HOM was induced by ATRA in NB4 cells (Fig. 4B), we investigated whether PRAM-1 associates with these proteins. First, we documented the association of SLP-76 and SKAP-HOM with PRAM-1 by coexpressing PRAM-1 tagged with the F domain of the human estrogen receptor (F-PRAM-1) with Flag-tagged SLP-76 or Flag-tagged SKAP-HOM in COS-7 cells. Fig. 4C, a shows that in these cells Flag-SLP-76 and F-PRAM-1, as well as Flag-SKAP-HOM and F-PRAM-1 proteins, were detected in anti-F immunoprecipitates. We next asked whether PRAM-1 can associate with SKAP-HOM and SLP-76 in leukemic cell lines. As shown in Fig. 4C, b, PRAM-1 and SKAP-HOM from ATRA-treated NB4 cell lysates were detected in SKAP-HOM and PRAM-1 immunoprecipitates, respectively. We also observed that PRAM-1 was detected in SLP-76 immunoprecipitates, and SLP-76 was found in PRAM-1 immunoprecipitates from lysates of NB4 cells treated with both ATRA and pervanadate (Fig. 4C, c). Together, these data indicate that the PRAM-1 adaptor protein can associate with SLP-76 and SKAP-HOM in ATRA-treated NB4 cells. Because PTK have been shown to be induced in RA-treated HL-60 cells (39), we investigated whether PRAM-1 and lyn can associate in ATRA-treated NB4 cells. As shown in Fig. 4D, both PRAM-1 and lyn from ATRA-treated NB4 cell lysate were detected in PRAM-1 immunoprecipitate. Altogether, our results strongly suggest that PRAM-1 is an adaptor protein interacting with proteins involved in an ATRA-signaling pathway.

    DISCUSSION
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

We identified a novel adaptor protein, PRAM-1, which is induced by ATRA in human leukemia promyelocytes and is expressed and regulated during normal myelopoiesis. That PML-RARalpha down-regulates expression of PRAM-1 mRNA in the absence of ligand indicates that PRAM-1 may be an oncogenic target of the fusion protein. Furthermore, superinduction of PRAM-1 by ATRA when PML-RARalpha is expressed suggests that this adaptor may be an important component of a signaling pathway through which ATRA induces differentiation in leukemia promyelocytes.

Adaptor proteins have achieved increasing prominence in recent years because of recognition of their roles in numerous cellular processes (40-42). Much evidence supports the hypothesis that these proteins exert their effects upon differentiation through assembly of cytoplasmic signaling complexes that are required to modulate transcription. PRAM-1 shares homologies with SLAP-130/fyb, an adaptor protein initially identified through associations with SLP-76 (22) and fyn (21). The SLAP-130 proline-rich region mediates binding to the SH3 domains of two related proteins, SKAP-HOM (38) and SKAP55 (43). Phosphorylated tyrosines amino-terminal to the SLAP-130 SH3-like motif mediate binding to SLP-76 (44, 45). Similar domains within PRAM-1 may mediate the association between PRAM-1 and SLP-76 or PRAM-1 and SKAP-HOM. Given the observations of shared structure and binding partners for PRAM-1 and SLAP-130, the two molecules may occupy a similar functional niche. Myeloid cells express SLAP-130 (21), and several observations suggest that it plays a role in myeloid signal transduction through Fc receptors (46) by coupling Fc receptor-stimulated protein tyrosine kinases to downstream signaling events. Furthermore, in murine bone marrow-derived macrophages, SLAP-130 is phosphorylated and inducibly associated with SLP-76 after exposure to antibody-coated sheep red blood cells.3 Our data showing that PRAM-1 is structurally similar to SLAP-130 and that it inducibly associates with SLP-76 thus reinforces the view that it may also regulate signaling through Fc receptors. SKAP-HOM, which can associate with PTK fyn (29), forms a complex with SLAP-130, which associates with the macrophage inhibitory receptor SHPS-1 (47). Our observation that PRAM-1 associates with SKAP-HOM raises the possibility that PRAM-1 might also participate in signaling through additional myeloid receptors. Furthermore, SKAP-HOM can associate with PTK lyn (48), which is induced and tyrosine-phosphorylated in RA-treated myeloid leukemia cells. Coordinate induction of PRAM-1, SKAP-HOM, and lyn protein expression by ATRA in NB4 cells, coupled with capacity of the two adaptors to associate together and with lyn, suggest that PRAM-1, SKAP-HOM, and lyn may be functionally linked in a common ATRA-dependent signaling pathway. The PTK lyn prevents apoptosis to promote RA-induced differentiation of HL-60 cells (39). Whether PRAM-1 is involved in this process remains to be determined.

Much attention has been given recently to cytosolic signalings in APL cell differentiation (11). PML-RARalpha confers marked resistance to hematopoietic growth factor starvation to hematopoietic stem/progenitor cells (10). Therefore, dysregulation of PML-RARalpha target genes might result in abnormal signaling, thereby freeing pre-leukemic cells from controls that normally induce the onset of differentiation. This, in association with other genetic dysregulations, may contribute to full leukemic transformation. It is also likely that treatment of APL cells by ATRA induces de novo up-regulation of the same genes that are dominantly repressed by PML-RARalpha and whose expression is required for reactivation of the differentiation program (16). To date, the myeloid transcription factor CCAAT/enhancer-binding protein epsilon  is the only example of such a gene (49). PRAM-1 is a first example of an adaptor molecule whose expression is inhibited and superinduced when PML-RARalpha is expressed alone and in the presence of ATRA, respectively. The evidence that PRAM-1 mRNA expression is inhibited by PML-RARalpha , together with the association of PRAM-1 with other RA-induced proteins including lyn, suggest that the fusion protein may indirectly dysregulate the organization of molecular complexes comprising scaffold proteins and therefore disrupt signaling events important for ATRA-induced differentiation.

    ACKNOWLEDGEMENTS

We thank Drs. P. G. Pelicci for generous gifts of U937-PR9 and U937-MT cell lines, C. Nervi for the NB4.306 cell line, M. Lanotte for NB4 cells, C. Chomienne and N. Balitrand for ATRA-treated APL cells, B. Schraven for the SKAP-HOM-expressing vector and anti-SKAP-HOM antibodies, and V. Witko-Sarsat for help in human blood cell purifications. We thank S. Axisa-Coon and F. C. Guibal for their interest in the work. Sequencing was conducted by C. Cruaud at the Center National de Séquençage (Evry, France) and by the Nucleic Acid/Protein Research Core Facility at the Children's Hospital of Philadelphia.

    FOOTNOTES

* This work was supported in part by INSERM and by grants from the Fondation de France, the Ligue Nationale Contre le Cancer, the Association Combattre La Leucémie, the Association pour la Recherche sur le Cancer, the Lady Tata Memorial Trust, and the National Institutes of Health.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.

The nucleotide sequence reported in this paper has been submitted to the EMBL/GenBankTM/EBI Data Bank with accession number AJ272324.

b  These authors contributed equally to this work.

c  A fellow of the Leukemia Research Foundation.

g  Supported by a Mentored Clinician Scientist Development Award from the National Institutes of Health.

j  These authors should be considered as equal last authors.

k  To whom correspondence should be addressed. Tel.: 33149284613; Fax: 33143406837; E-mail: cayre@st-antoine.inserm.fr.

Published, JBC Papers in Press, April 11, 2001, DOI 10.1074/jbc.M011683200

2 C. Moog-Lutz, unpublished results.

3 P. Myung and G. Koretzky, unpublished data.

    ABBREVIATIONS

The abbreviations used are: APL, acute promyelocytic leukemia; PML, promyelocytic leukemia; RA, retinoic acid; RARalpha , RA receptor alpha ; ATRA, all-trans retinoic acid; PTK, protein tyrosine kinase; SH, Src homology domain; bp, base pair(s); RACE, rapid amplification of cDNA ends; PCR, polymerase chain reaction; GAPDH, glyceraldehyde-3-phosphate dehydrogenase; PAGE, polyacrylamide gel electrophoresis.

    REFERENCES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
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