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Bleomycin Resistance in Mammalian Cells Expressing a Genetic Suppressor Element Derived from the SRPK1 Gene¹

CNRS UMR 8532, Institut Gustave Roussy, 94805 Villejuif, France [G. S., L. M.], and Laboratoire de Pharmacologie des Agents Anticancéreux, Institut Bergonié, 33076 Bordeaux Cedex, France [A. J-S.]

	ABSTRACT

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The genetic suppressor element (GSE) approach allows identification of genes essential for certaincell phenotypes. To identify genes controlling the cell response to cytotoxic agents, a normalized retroviral library of randomly fragmented cDNAs from the Chinese hamster cell line DC-3F was screened for GSEs conferring resistance to bleomycin. One of these GSEs, GSE^BLM, conferring an 2-fold bleomycin resistance in DC-3F cells, displayed 98% identity with an amino acid sequence located in the functional domain of human SRPK1. Using GSE^BLM as a probe, we cloned a cDNA with a nucleotide sequence that was 76.7% identical to that of human SRPK1, whereas the corresponding amino acid sequence was 92.6% identical to that of this enzyme. When GSE^BLM, inserted in the retroviral vector pLNCX, was transduced in HeLa cells, its expression resulted in a 5–10-fold bleomycin resistance, which was abolished when these cells were further transfected with SRPK1 cDNA. In our experimental conditions, DC-3F or HeLa cells expressing GSE^BLM did not show any detectable cross-resistance to other cytotoxic agents with various mechanisms of action. GSE^BLM, which is sense oriented in the vector, is likely to be translated in a peptide active as a dominant-negative inhibitor of SRPK1. SRPK1 is a protein serine kinase that regulates the activity of RS-proteins (arginine-serine-rich proteins), a group of nuclear factors controlling various physiological processes.

	INTRODUCTION

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BLMs,³ discovered by Umezawa et al. (1) as a group of antitumor antibiotics produced by Streptomyces verticillus, are presently used clinically in combination with other drugs for the treatment of various tumors, including head and neck cancers, Hodgkin’s disease, and germ cell tumors (2, 3, 4) . The major cause of BLM cytotoxicity is probably related to its ability to provoke DNA degradation. BLM (1) is a water-soluble glycopeptide that binds iron and oxygen in vivo to produce activated BLM, an Fe³⁺ hydroperoxide. When bound to DNA, with the metal binding domain located in the minor groove and the bithiazole group partially intercalated into the double helix, this intermediate induces the formation of single- and double-strand breaks at sequence-specific sites. The DNA double-strand breaks are considered as responsible for BLM toxicity (5, 6, 7) . However, various studies showed that BLM may also be responsible for other cellular damage, including RNA cleavage (8) and oxidative cell wall damage (9) , which might also contribute to its toxicity.

A few hundred molecules of BLM are enough to kill a cell (10) . However, its effectiveness is markedly restricted because BLM does not enter cells readily. In mammalian cells, BLM was shown to bind a M_r 250,000 cell surface protein, before internalization by endocytosis (11) , and cell sensitivity to BLM depends on the abundance of this protein (12) . Electroporation of cultured cells was shown to enhance its potency at least 1000-fold. Extension of this technique to the treatment of human tumors led to a novel antitumor approach, termed electrochemotherapy (13 , 14) , which is presently developing rapidly. Finally, activity of internalized BLM is also controlled by cell-dependent factors, such as DNA lesion repair pathways (15 , 16) and expression level of BLM hydrolase, a protease that inactivates BLM (17) . Despite a number of studies over more than 30 years, the mechanism of action of BLM remains unclear, most likely because of the structural complexity of the molecule and the variety of potential targets and effectors.

In fact, cell response to BLM, and to any other cytotoxic agent as well, depends on the balance between two groups of genes: genes which expression inhibits BLM activity and results in a resistance phenotype, and genes which expression is required for cell killing. To identify genes mediating cell sensitivity to BLM, we selected GSEs conferring resistance to this drug. GSEs are short cDNA fragments encoding peptides acting as dominant inhibitors of protein function or antisense RNAs inhibiting gene expression (18) . GSEs behave as dominant selectable markers for the phenotype associated with the repression of the gene from which they derived, thus allowing identification of this gene. For example, this strategy previously allowed the demonstration that kinesin heavy chain (19) and some members of the protein arginine methyltransferase family⁴ are involved in the control of cell response to various DNA-damaging agents.

In this study, we selected and characterized a GSE, GSE^BLM, conferring selective resistance to BLM in Chinese hamster and human cells by functional inhibition of SRPK1. SRPK1 is a protein serine kinase that regulates the activity of RS-proteins (arginine-serine-rich proteins), a group of nuclear factors controlling a variety of physiological processes including RNA processing and spliceosome assembly (20) .

	MATERIALS AND METHODS

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Cells and Culture Medium.
Human epitheloid carcinoma cells (HeLa) and Chinese hamster lung fibroblasts (DC-3F) were cultured as monolayers in standard conditions in DMEM and MEM (Life Technology, Cergy-Pontoise, France), respectively (21) . Medium was supplemented with 10% FCS and antibiotics.

Drugs.
BLM, cisplatin, and etoposide were purchased from Laboratoires Roger Bellon (Neuilly, France), Aventis (Montrouge, France), and Pharmachemie BV (Haarlem, the Netherlands), respectively. Staurosporine, camptothecin, and paraquat were from Sigma-Aldrich (La Verpillère, France).

Preparation of a Normalized cDNA Fragment Library.
A normalized library of random cDNA fragments of approximately 2.5 x 10⁷ clones, inserted in the ClaI site of the retroviral plasmid pLNCX (22) , was prepared from DC-3F cells as described previously (19) .

Library Transduction and Selection of GSEs Conferring BLM Resistance.
The library was packaged by transfecting 9 x 10⁷ BOSC 23 cells (1.5 x 10⁶/60 mm plate) with 80 µg of library DNA (23) . The viral suspension, collected 24, 36, and 48 h later, was used to infect DC-3F/cl23 cells (1 x 10⁶/plate, 10 100-mm plates), after treatment with DEAE dextran (20 µg/ml) for 20 min. DC-3F/cl23 cells are DC-3F cells made sensitive to retrovirus infection by transfection with the pJET plasmid, which carries an ecotropic retrovirus receptor gene (24) . Infection was repeated three times at 12-h intervals. Under these conditions, 80% of the cells were infected as determined by PCR amplification of proviral inserts from genomic DNA of isolated clones (see below). Genomic DNA was prepared using the QIAamp Blood Mini kit (Qiagen, Courtabeuf, France). Forty-eight h after the last infection, cells were replated and grown for 24 h.

One million cells were plated in 100-mm plates (five plates) and treated 24 h later with BLM (30 µM; 72 h). After drug exposure, surviving cells were rinsed three times with PBS and replated in five 100-mm dishes. Culture medium was renewed daily, and surviving clones were allowed to grow for 6–7 days. After trypsinization, cells were replated again in five 100-mm dishes and grown for 24 h, before a second BLM treatment in the same conditions as above. Twenty isolated clones were picked and grown first in 24-wells plates and then in 60-mm dishes. PCR amplification (see below) revealed that 17 of them contained at least one insert. After fractionation by electrophoresis in 1.2% agarose gel, 10 fragments were purified using the QIAquick Gel Extraction kit (Qiagen). Purified fragments were sequenced by Cybergen ESGS (Evry, France).

PCR Amplification of Proviral Inserts from Genomic DNA.
The following oligonucleotides were used as PCR primers: 5'-GCCCCAAGCTTTGTTAAC-AACGATGGATG-3', 5'-CTCCGCGGCCCC-AAGCTTTGTTTACATCGAT-3' (sense for pLNCX with inserts and empty vector, respectively), and 5'-ATGGCGTTACTTAAGCTAGCTTGCCAAACCTAC-3' (antisense). The sequence of the sense primer was designed to eliminate the ClaI site. Inserts were amplified from 50 ng of genomic DNA through 30 cycles of PCR (80 s at 58°C, 120 s at 72°C, 70 s at 94°C, and 10 min at 72°C).

Identification of GSEs Conferring Resistance to BLM.
PCR products, first digested by HindIII and ClaI, were then ligated in the corresponding sites of the pLN12 vector, a pLNCX vector in which the G418 resistance gene is replaced with the HR5 selection gene. HR5 selection is based on a point mutation of the Na⁺/H⁺ exchanger isoform 1 (NHE1), which confers resistance to lethal intracellular acidification in the presence of amiloride (25) . In pLN12, inserts were kept in the same orientation as in the original pLNCX. Each insert was individually tested for its ability to confer BLM resistance after retroviral transduction in DC-3F/cl23 cells. More than 70% of the cells surviving HR5 selection contained inserts detected by PCR amplification. BLM resistance was evaluated following two different protocols: treatment with 30 µM BLM for 72 h, or cell electropermeabilization by eight electric pulses of 1300 V/cm and 100 µs at the frequency of 1 Hz, in the presence of 5 nM BLM (26) . Surviving clones were stained with crystal violet either for determination of the absorbance at 600 nm (23) or individual clone counting. For all drug resistance studies, the number of plated cells was systematically controlled by measuring the cloning efficiency from 500 untreated cells plated in triplicate in 60-mm dishes.

cDNA Cloning.
These procedures have been described previously (27) .

Cross-Resistance Studies.
DC-3F or HeLa cells, stably transduced with pLN12-GSE^BLM, were plated at 8 x 10⁵ cells/plate in 100-mm plates. Twenty-four h later, the cells were treated with the different drugs at the indicated concentrations. After washing with PBS and trypsinization, the cells were returned to drug-free medium and allowed to form colonies for 8–10 days. Controls were cells infected with insert-free vector.

SRPK1 Overexpression.
The eukaryotic expression vector pCDNA3-SRPK1, containing the human SRPK1 cDNA, was kindly provided by Dr. Xiang-Dong Fu (University of California San Diego, San Diego, CA). After a first transfection with pLN12 or pLN12-GSE^BLM, HR5 resistant HeLa cells were again transfected with either pcDNA3 or pcDNA-SRPK1 using LipofectaminePLUS (Life Technology, Cergy-Pontoise, France). Transfected cells were selected in the presence of G418 (Prolabo, Gradignan, France) at 800 µg/ml, and BLM resistance was tested as above on the entire resistant population.

SRPK1 expression in transfected cells was determined by Western blot analysis, using an anti-SRPK1 monoclonal antibody (PharMingen, Le Pont de Claix, France). Preparation of cell extracts, protein fractionation by SDS-PAGE (50 µg/well), and immunoblotting conditions have been described previously (28) . Transfer to Millipore Immobilon-P membranes (Merck-Eurolab Polylabo, Strasbourg, France) was carried out as described by the manufacturer. Horseradish peroxidase-conjugated mouse antibody was used as secondary antibody (Amersham Pharmacia Biotech, Orsay, France). For control of gel loading, the membranes were also probed with anti--tubulin mouse monoclonal antibody (Sigma-Aldrich, Saint Quentin-Fallavier, France). After enhanced chemiluminescence detection, band intensities were quantified in volume using the variable mode imager Typhoon 8600 and the Image Quant software from Molecular Dynamics (Amersham Pharmacia Biotech, Orsay, France).

Expression of Bleomycin Hydrolase.
Cell extracts, protein fractionation by SDS-PAGE, and immunoblotting conditions were as described above. A polyclonal antibody against human bleomycin hydrolase, kindly provided by Dr. P. A. O’Farrell (Cold Spring Harbor Laboratory, Cold Spring Harbor, NY), was used as a primary antibody. Bound antibody was visualized with horseradish peroxidase-conjugated goat antirabbit IgG and enhanced chemiluminescence detection (Amersham-Pharmacia Biotech, Saclay, France). Recombinant bleomycin hydrolase, used as a control, was also kindly provided by Dr. P. A. O’Farrell.

	RESULTS

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Selection of GSEs Conferring BLM Resistance.
Fig. 1 shows a schematic representation of the GSE selection procedure. The plasmid library was transfected into packaging BOSC 23 cells, and the virus released in the supernatant medium was used to infect DC-3F/cl23 cells. Virus-infected cells were then submitted to BLM selection under conditions allowing the growth of 1 in 10,000 cells (30 µM; 72 h) The number of library-transduced cells surviving BLM treatment at this stage was approximately twice higher than that of the control (DC-3F cells transduced with insert-free pLNCX). BLM-surviving cells were then replated in an equal number of dishes and grown for 24 h, before a second BLM selection in the same conditions as above. At this stage, the number of surviving clones in the experiment was 3-fold higher than that in the control, indicating that the cell population was enriched for cells containing biologically active GSEs.

View larger version (54K): [in this window] [in a new window] [Download PPT slide]   Fig. 1. Selection of GSEs inducing BLM resistance. Top, scheme of selection. Bottom, crystal violet staining of typical plates containing BLM-selected DC-3F cells, infected either with insert-free pLNCX (control) or with GSE library carrying vectors.

View larger version (29K): [in this window] [in a new window] [Download PPT slide]   Fig. 2. Ethidium bromide staining of PCR products corresponding to the proviral inserts present in library-infected DC-3F cells after BLM selection (30 µM; 72 h). M, size markers; T+/T-, positive and negative PCR controls. *, the fragments isolated for further studies. GSEBLM corresponds to the upper band in Lane 2.

View larger version (100K): [in this window] [in a new window] [Download PPT slide]   Fig. 3. Induction of BLM resistance in electropermeabilized DC-3F cells by GSEBLM. Crystal violet staining of typical plates containing DC-3F cells infected with insert-free pLNCX or with GSEBLM carrying vectors is shown. Cells (1 x 106) were electropermeabilized in the presence of BLM (5 nM), plated in triplicate in 100-mm dishes, and grown for 6 days.

Search in sequence databases showed that GSE^BLM sequence shares a remarkable identity with a sequence located in the functional domain of the human SRPK1 (94% in nucleotides and 98% in amino acids). GSE^BLM was then used to probe a ZAPIIcDNA library made from DC-3F cells. Five clones, carrying inserts with sizes ranging from 2000 to 4200 bp, were selected. Sequence analysis showed that the longest cDNA nucleotide sequence had 76.7 and 89% identity to human and mouse SRPK1 nucleotide sequences, respectively. By comparison with the human sequence, an open reading frame of 4071 bp⁵ was identified in the Chinese hamster cDNA. The corresponding amino acid sequence is 92.6 and 89.7% homologous to the human and mouse SRPK1 sequences, respectively, but is missing the first three amino acid sequence (Met, Glu, and Arg).

Sequence analysis also showed that GSE^BLM is sense oriented and encodes a peptide extending from amino acids 94–153. To verify that GSE^BLM is indeed acting as a peptide, a modified GSE was PCR amplified using the following sense primer: 5'-GCCCCAAGCTTTGTTAACATCGATGGATGGATGGGTAGTTATC-3'. This primer contains a stop codon (underlined) preventing GSE translation. When the modified GSE, inserted between the ClaI and HindIII sites of pLN12, was transduced into HeLa cells, the HR5 selected cells did not show any detectable resistance to BLM (Fig. 4) . These results showed that GSE^BLM translation is required for induction of BLM resistance and that it is most likely active as a peptide inhibiting SRPK1 activity.

View larger version (32K): [in this window] [in a new window] [Download PPT slide]   Fig. 4. BLM resistance in HeLa cells expressing a mutated GSEBLM containing a stop codon. HeLa cells were infected with insert-free pLN12 (control) or with pLN12 containing either GSEBLM (GSEBLM) or the mutated GSEBLM (GSEBLM+STOP). HR5 selected cells were treated with BLM (30 µM; 24 h) in triplicate. The figure shows crystal violet staining of a representative experiment.

View larger version (36K): [in this window] [in a new window] [Download PPT slide]   Fig. 5. Restoration of drug sensitivity in cells overexpressing SRPK1. HeLa cells, first transduced with either insert-free pLN12 or pLN12-GSEBLM, were then transfected with pcDNA3 or pcDNA3-SRPK1. A, immunoblot analysis of SRPK1 expression in transfected cells. For gel loading control, the membrane was simultaneously probed with anti-SRPK1 and anti--tubulin antibodies. Because ECL detection of each antibody required different exposure times, the data are shown in separate pictures. Lanes 1, cells containing insert-free vectors; Lanes 2, cells containing pcDNA3-SRPK1; Lanes 3, cells containing pLN12-GSEBLM and insert-free pcDNA3; Lanes 4, cells containing pLN12-GSEBLM and pcDNA3-SRPK1. B, sensitivity to BLM. The number of surviving clones after treatment with BLM (30 µm for 72 h) was determined as described in "Materials and Methods."

View larger version (25K): [in this window] [in a new window] [Download PPT slide]   Fig. 6. Effect of GSEBLM expression on cell sensitivity to different drugs. Cells, infected with insert-free vector or with pLN12 expressing GSEBLM, were treated in triplicate with the different agents. Each experiment was repeated at least twice. Results are expressed as the ratio of the number of surviving clones from GSEBLM-expressing cells over the number of surviving clones from control cells. A, DC-3F cells were treated with BLM (30 µM; 72 h), BLM during electropermeabilization (5 nM), cisplatin (7.5 µg/ml; 3 h), etoposide (6 µM; 3 h), staurosporine (500 nM; 3 h), and ionizing radiation (500 rads). Bars, SD. B, HeLa cells were treated with BLM (30 µM; 24 h), camptothecin (1 µM; 16 h), paraquat (500 µM; 24 h), cisplatin (7 µg/ml), etoposide (40 µM), and staurosporine (5 µM) for 3 h. Bars, SD.

View larger version (26K): [in this window] [in a new window] [Download PPT slide]   Fig. 7. Expression of BLM hydrolase. Fifty µg (Lanes 2 and 4) or 25 µg (Lanes 3 and 5) of cell extract proteins were fractionated by SDS-PAGE, transferred to a nitrocellulose membrane, and probed with a polyclonal antibody raised against human BLM hydrolase. Lane 1, 100 ng of recombinant BLM hydrolase; Lanes 2 and 3, proteins from HeLa cells expressing GSEBLM; Lanes 4 and 5, proteins from HeLa cells infected with insert-free vector.

	DISCUSSION

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Identification of the SRPK1 gene as the gene from which GSE^BLM was derived is based on three arguments: presence in the human gene of a nucleotide sequence 94% identical to that of GSE^BLM; cloning of the SRPK1 cDNA by probing a Chinese hamster cDNA library with the GSE; and reversion of GSE^BLM-induced BLM resistance in cells transfected with SRPK1 cDNA. However, mammalian cells contain several SRPK enzymes. Alternative splicing of SRPK1 transcripts can give rise to two enzyme forms. Although both isoforms have the same substrate specificity and the same subcellular localization, they might perform different functions; SRPK1a differs from SRPK1 by insertion of 171 amino acids at its NH₂-terminal end and specifically interacts with scaffold attachment factor-B. Because the sequence corresponding to GSE^BLM is common to both proteins, this GSE is likely to inhibit both of them. Another enzyme, SRPK2, is highly related to SRPK1 in sequence, enzyme activity, and substrate specificity. These two kinases differ by a different expression in various human tissues and by the presence of a proline-rich sequence at the SRPK2 NH₂ terminus that may contribute to in vivo specific function and/or regulation. In their functional domains, SRPK1 and SRPK2 amino acid sequences are 77% identical. Although SRPK2 homology with GSE^BLM amino acid sequence is reduced to 81.3%, a possible effect of GSE^BLM on SRPK2 activity cannot be excluded.

SRPK family members represent an unusual class of constitutively active protein kinases and are characterized by the presence of a large spacer (250–300 residues), which divides the kinase domain into two halves, and a long NH₂-terminal tail (29) . GSE^BLM homologous sequence (amino acids 95 to 153) is located in the NH₂-terminal half of human SRPK1 kinase domain. This region is highly conserved in Sky1p, the only SRPK enzyme in Saccharomyces cerevisiae. The three-dimensional structure of the yeast protein was determined on crystals of a fully active truncated form of the protein, in which the NH₂-terminal tail and the spacer were deleted (30) . From these studies, we can deduce that the GSE^BLM corresponding region contains several structural elements, including helices C and C', which are essential to stabilize the active form of the enzyme through interaction with other domains of the protein. How GSE^BLM peptide can inhibit SRPK1 activity remains hypothetical. One possibility would be that this peptide would interact with the enzyme cofactor or substrate, thus preventing their binding to the enzyme. Alternatively, GSE^BLM peptide might inhibit peptide interactions within the enzyme molecule, such as the packing of the helix C against helix E mediated by helix C' and required for locking the activation loop in the active conformation (30) .

RS proteins (arginine-serine-rich proteins) are essential RNA processing factors and are characterized by the presence of at least one RNA recognition motif and a COOH-terminal domain rich in Arg-Ser (RS) dipeptide repeats (20) . RS domains are known to participate in protein-protein and protein-RNA interactions during spliceosome assembly and also to function as nuclear localization signals. SRPKs specifically phosphorylate most (if not all) Ser in the RS repeats and thus regulate the functions of RS proteins (31) . GSE^BLM expression only induced resistance to BLM, whereas it had no effect on the sensitivity of DC-3F and HeLa cells to a variety of other cytotoxic agents with different mechanisms of action. Inhibition of SRPK1 activity in GSE^BLM-expressing cells or increased expression of the enzyme in cells transfected with the SRPK1 cDNA did not change the cell growth rates. Therefore, GSE^BLM-induced BLM resistance did not result from a modification of cell growth properties, which would also be expected to have consequences on the sensitivity to other compounds. A selective resistance to BLM might result from an effect of SRPK1 inhibition on the activity and/or the expression of protein(s) specifically controlling BLM toxicity. Because GSE^BLM induces BLM resistance in permeabilized cells, this excludes any protein involved in the transport of the drug across cell membranes. Bleomycin hydrolase is a very unlikely substrate of SRPK1, because it does not contain any RS domain, and we have shown that its expression is not modified in GSE-expressing cells. Another possibility would be that expression and/or cellular localization of protein(s) involved in the repair of BLM-induced DNA lesions would be controlled by SRPK1. Inhibition of SRPK1 in GSE^BLM-expressing cells might then alter repair pathways of these lesions and thus induce cell resistance to this drug.

Very recently, it was reported that Sky1p mediates cisplatin toxicity in Saccharomyces cerevisiae (32) . This report also showed that down-regulation of SRPK1 in human ovarian carcinoma A2780 cells with antisense oligodeoxyribonucleotides resulted in a decreased sensitivity to cisplatin. The sensitivity of these cells to other drugs was not reported. It should be pointed out that our studies were carried out with different cell lines, and that GSE^BLM did not induce a down-regulation of SRPK1 but was rather acting as a dominant-negative inhibitor. Whether these differences explain the absence of resistance to cisplatin in our cell lines remains to be studied. Nevertheless, both studies support the conclusion that SRPK enzymes are involved in the control of cell sensitivity to anticancer agents. Another important point is that both studies show that alterations of SRPK1 activity are associated with low levels of drug resistance, which are generally believed to be more relevant to clinical situations than high resistance processes frequently analyzed in experimental models. Detection and characterization of such new mechanisms, controlling cell sensitivity to anticancer agents, may lead to a better understanding of the determinants of the clinical response to these agents.

	FOOTNOTES

 
The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked advertisement in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

¹ Supported in part by grants from the Ligue Nationale contre le Cancer (LNCC) Association pour la Recherche sur le Cancer (ARC), and Fondation pour la Recherche Médicale (FRM).

² To whom requests for reprints should be addressed, at Laboratoire de Pharmacologie des Agents Anticancéreux, Institut Bergonié, 229 Cours de l’Argonne, 33076 Bordeaux Cedex, France. Phone: 33-5-56-33-04-26; Fax: 33-5-56-33-04-21; E-mail: Jacquemin-a{at}bergonie.org

³ The abbreviations used are: BLM, bleomycin; GSE, genetic suppressor element.

⁴ C. Delaporte, L. Gros, S. Frey, J. Decesse, B. Robert de Saint-Vincent, J. Markovits, L. Cavarec, A. Dubart, A. V. Gudkov, and A. Jacquemin-Sablon. New drug sensitivity genes: protein arginine methyltransferase mediates cell sensitivity to DNA-damage, manuscript in preparation.

⁵ Sequence accession number to the Chinese hamster SRPK1 cDNA in GenBank is AF446079.

Received 1/14/02. Accepted 6/ 4/02.

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