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INTRODUCTION |
Cancer of the prostate is the most frequently diagnosed invasive
cancer and the second most common cause of cancer-related death in
males in North America (1, 2). Androgens play an important role in
stimulating prostatic epithelial cell proliferation and initial
treatment of patients with prostate cancer usually involves androgen
ablation. Despite this, androgen-insensitive tumors often emerge after
2-3 years (3). The molecular basis for progression to cancer of the
prostate is poorly understood, but there is increasing evidence that
alterations in growth factor signaling pathways may be involved in the
development of prostatic carcinomas. Epidermal growth factor
(EGF),1 insulin-like growth
factor 1 (IGF1), transforming growth factor 
, interleukin-6 (IL-6),
keratinocyte growth factor, and other fibroblast growth factors are all
expressed in advanced prostate cancer providing potential autocrine
growth factors for tumor cell growth (4-8). Furthermore, EGF, IGF1,
and keratinocyte growth factor can transactivate the androgen receptor
via nonsteroid transduction pathways, and alterations in expression of
fibroblast growth factor receptor 2IIIc, RET, Her2/neu, and ErbB1, -2, or -3 receptors have been detected in advanced prostate cancer (9-13). Activation of the mitogen-activated protein kinase (MAPK) pathways are
also thought to play an important role in prostate cancer development
with increased extracellular signal-regulated MAPK activation occurring
with increased Gleason score and tumor stage (8, 14). The prostate
cancer cell mitogen IL-6 also activates MAPK pathways and the androgen
receptor (15).
The MAPK pathways play crucial roles in the regulation of a diverse
array of responses including growth, differentiation, transformation,
stress responses, and apoptosis, but their role in the development of
prostate cancer remains to be determined (16-18). MAPK stimulation
occurs via activation of a MAPK kinase kinase (MAPKKK), which
phosphorylates a dual specificity MAPK kinase (MAPKK), which in turn
phosphorylates MAPK. The MAPKs currently consist of three related
protein kinase cascades named after the final enzyme in each series;
extracellular signal-regulated kinases (ERKs), Jun N-terminal kinases
(JNKs)/stress-activated protein kinases, and p38s. The ERK cascade
contains ERK1 and -2 (MAPKs), MEK1 and -2 (MAPKKs), and A-RAF, B-RAF,
and RAF-1 (MAPKKKs) and is predominantly involved in signaling cell
growth, proliferation and differentiation. In contrast to ERK
activation, pathways involved in the activation of JNK and p38 are less
clear. The JNK cascade includes JNKs 1, 2, and 3 (MAPKs) and MKKs 4 and
7 (MAPKKs), while the p38 cascade contains p38 and 
(MAPKs) and
MKKs 3 and 6 (MAPKKs) (18-21). The JNK and p38 pathways are
predominantly involved in the protective responses of cells to
pro-inflammatory cytokines (e.g. tumor necrosis factor-
and IL-1) and cellullar stresses (10, 16). A number of MAPKKK-like
proteins activate the JNK and p38 pathways and include MAP/ERK kinases
(MEKKs 1-4), MAPK upstream kinase, transforming growth factor
-activated kinase, tumor progression locus-2, and apoptosis
signal-regulated kinase (22-25). The large number of MAPKKKs is
thought to allow many different stimuli to input into the MAPK pathways
converging on a relatively limited number of MAPKK-like proteins.
Recent attention has focused on a family of serine-threonine kinases
whose catalytic domain has homology to the sterile 20 (STE20) kinase of
Saccharomyces cerevisiae involved in MAPK signaling of the
pheromone response in yeast (26). Mammalian STE20-like kinases appear
to act as MAPK kinase kinase kinases, and some members of this family
activate the JNK MAPK pathway. The STE20-like kinase family include
p21-activated kinases (PAKs), mixed lineage kinases (MLKs), mammalian
STE20-like kinases (MSTs), germinal center kinase (GCK), GCK-like
kinase (GLK), hematopoietic progenitor kinase (HPK), kinase homologous
to SPS1/STE20 (KHS), lymphocyte-oriented kinase (LOK), STE20 oxidant
stress response kinase (SOK), yeast SPS1/STE20-like kinase (YSK), and
NCK interacting kinase (NIK) (27-41). MLK2 can also stimulate the ERK
MAPK pathway, and PAKs not only activate the JNK and p38 MAPK pathways
but also regulate cytoskeletal organization stimulating disassembly of
actin stress fibers and membrane ruffling (34, 42-44).
We set out to obtain a profile of kinases expressed in surgically
removed prostate tumors to identify potential oncogenic signaling
pathways that might be involved in progression to prostate cancer. The
degenerate PCR screen of malignant prostate tissues identified 15 tyrosine or serine-threonine kinases and provides a basis for further
analysis of kinase signaling pathways and function in prostate cancer
development. The PCR screen for kinases also identified a novel member
of the STE20-like family of protein kinases which we have called
prostate-derived STE20-like kinase (PSK). PSK has a potential role as a
signal transduction molecule in prostatic carcinomas and may function
similarly to other STE20-like proteins discovered in mammalian tissues,
which occupy pivotal roles in coupling stimuli to downstream signaling
pathways. We have demonstrated that PSK specifically activates the JNK
MAPK pathway and induces loss of actin stress fibers, suggesting a role
for this new protein in regulating cellular stress responses and cell motility.
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EXPERIMENTAL PROCEDURES |
RNA Isolation and Reverse Transcription--
Total RNA was
isolated from surgically removed prostatic carcinoma tissues (Gleason
grades 6-8) using RNazol B (Biogenesis). RNA (5 µg) was
reverse-transcribed to cDNA using Superscript reverse transcriptase
(Life Technologies, Inc.) primed with oligo(dT)17. PCR was
performed using two degenerate primers
5'-CCTCGAGATCCA(T/C)(A/C)GNGA(T/C)(T/C)T-3' and
5'-GGAATTCCA(A/T)AGGACCA(G/C)AC(G/A)TC-3' to target conserved sequences
in subdomains VI and IX of the kinase catalytic domain (45, 46). PCR
conditions were 93 °C/90 s, 45 °C/2 min, and 72 °C/4 min for
30 cycles using 2 units of Taq polymerase (Promega) per
50-µl reaction. PCR products were digested with XhoI and
EcoRI and cloned into Lambda Zap ExpressTM arms according to
the manufacturer's instructions (Stratagene), and the DNA insert was
sequenced (T7 DNA polymerase sequencing kit, Amersham Pharmacia Biotech).
Cloning of PSK--
For 3' RACE (rapid amplification of cDNA
ends), RNA from a T-47D breast carcinoma cell line was reverse
transcribed using the primer
5'-GACTACGTTAGCATCTAGAATTCTCGAG(T)17-3'. Nested PCR was
carried out using two forward primers 5'-CTGCGTCCATCATGGCACCTG-3', followed by 5'-TTTGGATCCACTAGTGTCGA-3' and the reverse primer 5'-GACTACGTTAGCATCTAGAATTCTCGG-3' and a 534-bp product obtained and cloned into pGEM-T vector (Promega). The 534-bp 3'RACE product was
used to screen a Lambda Zap cDNA library prepared from T-47D carcinoma cells (Stratagene, kind gift from M. Crompton, ICR, London).
Filters (Amersham Pharmacia Biotech, HybondTM-N+) were
hybridized at 65 °C in a solution containing 5× SSPE, 5× Denhardt's solution, and 20 µg/ml salmon testis DNA (Sigma) for 48 h. Stringency of the final wash was 1× SSPE, 0.1% (w/v) SDS at 65 °C. CDNA clones were isolated from a screen of 1 × 106 phage clones and sequenced on both strands
(MWG-Biotech). PCR to confirm the presence of PSK in human genomic DNA
was carried out using a forward primer 5'-CCTGAACAAGAAGCAGACCCA-3' in
combination with a reverse primer 5'-CCAGAATCCTCTGCTGCTTGG-3'. PCR
conditions were 93 °C/45 s, 60 °C/60 s, and 68 °C/2 min for 35 cycles using 1 unit of Supertaq plus DNA polymerase (HT-Biotech) per
50-µl reaction.
Plasmid Construction--
For mammalian cell expression, the
open reading frame of PSK (758-4463 bp) was initially cloned into
EfPlink (kind gift from R. Marais, ICR, London) containing a 5' MYC
epitope tag. The 5' end of PSK was generated by PCR using a forward
primer 5'-AAGCTTGGATCCATGCCAGCTGGGGGCCGG-3', to introduce a
BamHI site next to the ATG start codon, with the reverse
primer 5'AAAGAATTCGCTGCAGGCGGCTGGAGA-3'. After digestion with
appropriate enzymes the BamHI 
1103 XbaI
fragment of PSK was ligated into EfPlink along with the 3' end of PSK
(XbaI 1104-4492 XbaI) and an annealed
oligonucleotide adaptor 5'-CTAGAGCATTGAGTAGATAGAATTCAAGCTTA-3' and
5'-CTAGTAAGCTTGAATTCTATCTACTCAATGCT-3' introduced at its
3' XbaI site. To improve protein expression in COS1 cells
upon transient transfection the open reading frame was subcloned into a
cytomegalovirus-based expression vector pRK5 containing a 5'
MYC-epitope tag. PSK (K57A) was prepared using the method of Kunkel
et al. (47). Briefly, PSK (BamHI 3504
BamHI) was subcloned into pBluescript II SK and used to
generate a mutated fragment using the oligonucleotide 5'-GAGGTGGTGGCCATCGCGAAGATGATGTCCTACAG-3'. The resultant PSK
(BamHI 3504 BamHI, K57A) fragment was ligated
back into EfPlink-PSK (BamHI 3504-4492
XbaI).
PSK (amino acids 1-349) and PSK (1-349, K57A) were prepared by
ligating the respective BamHI 1805 XhoI
blunt-ended fragments of PSK into EfPlink MYC-tag cut with
BamHI-EcoRI and containing an EcoRI
blunt end.
Northern Blotting--
A human multiple tissue Northern blot
(MTNTM, CLONTECH) was probed with an
XbaI 1104-1800 XhoI or BamHI
3504-4492 XbaI fragment of PSK using the method described
by the manufacturer.
Transient Cell Expression, Immunoblotting, Immunoprecipitation,
and Kinase Assays--
COS1 cells were grown in Dulbecco's modified
Eagle's medium supplemented with 10% FCS and antibiotics
(5%CO2, 37 °C). For transfection, cells (1.9 × 106/10 ml of medium) were seeded onto 100-mm Petri dishes
and grown for 16 h before the indicated plasmids (6 µg of each
plasmid with the total amount of DNA made equivalent using empty
vector) were co-transfected into COS1 cells for 5 h in the
presence of 30 µl of Lipofectin/4 ml of Opti-MEM I. (Life
Technologies, Inc.). Transfected cultures were transferred to 10 ml of
growth medium and incubated for 48 h.
For immunoblotting of whole cell lysates, cultures were lysed in 200 µl of gel sample buffer and 100 µg of each sample was separated by
10% or 15% SDS-PAGE before proteins were transferred to
nitrocellulose (Schleicher & Schuell). MYC-tagged PSK or p38 proteins
were detected using 9E10 anti-MYC tag antibody (Sigma), and FLAG-tagged
JNK or ERK2 were detected using anti-FLAG tag M2 antibody (Sigma).
Briefly, membranes were blocked with TBS (150 mM NaCl, 10 mM Tris, pH 7.4) containing 5% dried milk for 1 h at
room temperature; incubated in TBS-Tween 20 (0.5%) containing either a
1/500 dilution of 9E10 or 5 µg/ml M2 for 1 h (room temperature); and finally incubated in TBS-Tween 20 (0.5%) containing 1/2000 anti-mouse horseradish peroxidase-conjugated antibody (Transduction Laboratories) and 1% dried milk for 1 h (room temperature).
Membranes were processed using ECL according to the manufacturer's
instructions (Amersham Pharmacia Biotech).
For JNK and p38 kinase assays, cells were lysed 48 h after
transfection in 0.4 ml of lysis buffer A (1% (v/v) Triton X-100, 300 mM NaCl, 2.5 mM MgCl2, 40 mM Na4P2O7, 5 mM EGTA, pH 8.0, 2 µg/ml leupeptin, 2 µg/ml aprotinin,
50 mM NaF, 0.1 mM
Na3VO4, 3 mM phenylmethylsulfonyl
fluoride, 25 mM Hepes, pH 7.6). For ERK2 kinase assays or
myelin basic protein (MBP) phosphorylation assays, cells were lysed in
0.4 ml of buffer B (1% Nonidet P-40, 130 mM NaCl, 1 mM dithiothreitol, 2 µg/ml leupeptin, 2 µg/ml
aprotinin, 10 mM NaF, 0.1 mM
Na3VO4, 1 mM phenylmethylsulfonyl
fluoride, 20 mM Tris, pH 8.0). Cell lysates were extracted
for 10 min at 4 °C, and debris was removed by centrifugation
(12,000 × g for 10 min at 4 °C).
For immunoprecipitation, 400 µg of protein were taken and made up to
a final volume of 1 ml in binding buffer (50 mM NaCl, 2.5 mM MgCl2, 0.1 mM EDTA, pH 8.0, 0.05% (v/v) Triton X-100, 40 mM
Na4P2O7, 2 µg/ml leupeptin, 2 µg/ml aprotinin, 50 mM NaF, 0.1 mM
Na3VO4, 1 mM phenylmethylsulfonyl
fluoride, 20 mM Hepes, pH 7.6) for JNK or p38 kinase
assays, or to 0.5 ml in buffer B for ERK2 and MBP phosphorylation
assays. For JNK or ERK2 kinase assays, samples were incubated with 3 µg of anti-FLAG mouse monoclonal antibody for 1 h at 4 °C,
and for MBP phosphorylation or p38 kinase assays, 3 µg of
anti-MYC-tag 9E10 mouse monoclonal antibody was added for 1 h at
4 °C. 20 µl of protein G-Sepharose beads (Sigma; 1:1 in
appropriate binding buffer) were added to each sample for incubation
for another 1 h (4 °C), and beads were pelleted by centrifugation and washed two times in 0.5 ml of appropriate binding buffer.
For in vitro kinase assays, beads were washed in respective
kinase buffers. JNK and p38 kinase assays were carried out in 30 µl
of kinase buffer A (20 mM MgCl2, 2 mM dithiothreitol, 20 mM
p-nitrophenyl phosphate, 4 mM NaF, 0.1 mM Na3VO4, 20 mM Hepes, pH 7.6) containing 20 µM ATP, 5 µCi of
[
-32P]ATP (Amersham Pharmacia Biotech, 3000 Ci/mmol)
and either 3 µg of GST-c-Jun protein or 3 µg of GST-ATF2 protein,
and incubated for 20 min or 30 min, respectively, at 30 °C. ERK2 or
MBP kinase assays were carried out in 30 µl of kinase buffer B (20 mM MgCl2, 2 mM MnCl2,
30 mM Tris, pH 8.0) containing 0.25 mg/ml MBP, 10 µM ATP, and 1 µCi of [-32P]ATP for 30 min at 30 °C. Kinase assays were terminated in gel sample buffer,
heated to 100 °C for 5 min, and proteins separated by SDS-PAGE for
transfer to nitrocellulose. Samples were processed by immunoblotting
and analyzed by exposure to film or phosphorimaging (Fuji). Protein
normalization and protein expression were confirmed for each sample by
immunoblotting of cell lysates or immunoprecipitated material.
FLAG-tagged MKK3, MKK4, or MKK7 were transfected and immunoprecipitated
as described for FLAG-tagged JNK except that recombinant GST-p38 (MKK3)
or GST-JNK (MKK4 or -7) were used as substrate for in vitro
kinase assays.
Microinjection, Immunolocalization, and Actin
Detection--
Swiss 3T3 cells were grown in Dulbecco's modified
Eagle's medium containing 10% FCS. For microinjection, cells were
seeded at 3 × 104/well (15 mm diameter) on glass
coverslips (13 mm) and incubated for 2 days. Endotoxin-free plasmid DNA
(100 ng/µl, Qiagen) was microinjected into the nuclei of
approximately 100 cells (per coverslip), and, after 4 h, cultures
were washed with PBS containing 0.9 mM CaCl2
and 0.7 mM MgCl2, fixed for 20 min with 3.7%
formaldehyde in PBS, and permeabilized with 0.2% Triton X-100 in
PBS.
To localize MYC-tagged PSK and actin filaments, cells were incubated
with 1:500 anti-Myc tag antibody 9E10 (Santa Cruz Biotechnology) in
PBS, 0.1% bovine serum albumin followed by 1:400 FITC-conjugated goat
anti-mouse IgG (Jackson Immunoresearch) in PBS, 0.1% bovine serum
albumin together with 0.1 µg/ml TRITC-conjugated phalloidin (Sigma).
To localize PSK and vinculin, cells were incubated with 1:200 rabbit
anti-Myc tag antibody (Santa Cruz Biotechnology) and 1:50 mouse
anti-vinculin antibody (Sigma). Cells were imaged with a confocal laser
scanning microscope (LSM 510, Zeiss). Image files were collected as a
matrix of 1024 by 1024 pixels describing the average of 8 frames
scanned at 0.062 Hz, where FITC and TRITC were excited at 488 nm and
543 nm and visualized with bandpass filters of 540 ± 25 and
608 ± 32 nm, respectively.
Plasmids--
The following plasmids were kindly provided by
colleagues; pCMV-FLAG-JNK1 and pGEX-c-Jun (Dr. M. Karin, University of
California and Dr. J. Ham, Eisai London Research Laboratories);
pRK5-MYC-MLK2 (Dr. M. Terada, NCCRI, Tokyo); pCEF-HA-p38 (Dr. M. H. Cobb, University of Texas); and MKKs 3, 4, 7, GST-p38, and GST-JNK
(Dr. R. Davis, Howard Hughes Medical Institute). pEXV-MYC-ERK2 was
kindly provided by Dr. C. J.Marshall (Institute of Cancer
Research, London), and ERK2 was subcloned into pCMV-FLAG (Sigma).
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RESULTS |
Kinase Expression in Human Prostatic Carcinoma Tissues--
Total
RNA was prepared from three surgically removed prostate tumors (Gleason
grades 6-8) and used to obtain a profile of kinases expressed in
prostatic carcinoma tissues. RNA was reverse transcribed to cDNA
and amplified by PCR using degenerate oligonucleotides that correspond
to the highly conserved amino acid sequences present in subdomains V1
((I/V)HRDL) and 1X (DVWS(F/L)G) of the kinase catalytic domain (45,
46). This approach allowed us to amplify interconnecting sequences of
approximately 200 base pairs between the two subdomains that were
specific for each kinase. Sixty-six independent clones were sequenced.
Based on this analysis, the deduced amino acid sequences (GenBank and
EMBL data bases) identified 15 different tyrosine or serine-threonine
kinases including six known receptor kinases (PDGFBR, IGF1-R, VEGFR2,
MET, RYK and EPH-A1), six non-receptor kinases (ABL, JAK1, JAK2, TYK2,
PLK-1 and EMK), and three novel kinases (Fig.
1). Of the three tumors analyzed, one
(Gleason grade 6) was more informative. All of the known kinases identified in this screen were represented at least once in this tumor,
with IGF1-R being identified the most frequently (31% of clones
sequenced for this tumor). Interestingly, 79% of clones sequenced from
the other two tumors (Gleason grade 8) encoded PDGFBR, while IGF1-R was
sequenced twice and JAK1, ABL, and MET were each sequenced once. We
also detected three novel kinases. GenBank data base searches suggested
that clone 1 was most related to the STE20 family of serine-threonine
kinases with 52% homology to STE20 and clone 2 had most homology with
the Caenorhabditis elegans predicted protein C46C2.1 (87%)
and the Phycomyces blakesleeanus predicted protein PKPA
(60%) (48, 49). Clone 3 now appears to be the human homolog of mouse
PKL12 (50). We chose to focus on the novel kinase, which had
significant homology to members of the STE20 family of serine-threonine
kinases, because of the role that these proteins play in the regulation
of cell growth and survival. This new kinase is analyzed in detail
here.
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Fig. 1.
Identification of kinases expressed in three
prostatic carcinoma tissues. The identity of each protein kinase
is shown on the left of the alignment of the deduced amino
acid sequences encoded in PCR-amplified fragments. The number of
individual isolates sequenced is shown on the right.
Conserved amino acid sequences are shown in boldface and the
conserved subdomains described by Hanks et al. (45) are
indicated by Roman numerals. The novel clones are
marked (*).
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Cloning of cDNAs Encoding a Novel Member of the STE20
Kinases--
3' RACE was carried out using a modification of the
method of Frohman (51) to obtain more cDNA encoding the novel
STE20-related kinase. This approach generated a PCR fragment of 534 bp,
which was used to screen cDNA libraries leading to the isolation of two cDNA clones. One cDNA clone contained an insert of
approximately 5 kb and was sequenced on both strands, while the second
clone (approximately 3 kb) represented a C-terminally truncated version of the longer clone, lacking an in-frame stop codon.
A start codon AUG at position 758, which reflected a good match to the
consensus for efficient translation initiation (52), an in-frame stop
codon, and an open reading frame of 3705 bp encoding a predicted
protein of 1235 amino acids were identified (Fig. 2). The kinase domain was located at the
N terminus of the protein and contains all 11 subdomains. The first
kinase subdomain sequence (GHGSFG) is preceded by 34 amino acids and is
followed by a crucial lysine residue at amino acid 57, which is
required for ATP binding. The C-terminal domain contains several
proline-rich regions representing predicted SH3 domain binding regions
and a leucine-rich region. We have called this new protein PSK
(prostate-derived STE20-like kinase).
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Fig. 2.
Nucleotide and predicted amino acid sequences
of PSK. Indicated are the Kozak sequence (broken
line), start codon and stop codon (boldface),
along with the kinase domain (underlined). The
numbers to the left and right of the
sequence refer to nucleotide and amino acid positions in the predicted
protein, respectively.
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PSK Is Homologous to STE20-related Kinases--
A search of data
bases (GenBank and EMBL) revealed that PSK had significant sequence
homology over the kinase domain with members of the STE20 family of
kinases including TAO1 (90%), MST1 (45%), NIK (44%), HPK1
(43%), GCK (42%), and STE20 (40%) (Fig. 3A). The presence of an
N-terminal kinase domain and the stretch of 22 amino acids upstream of
the first of the kinase catalytic subdomains is similar to other
members of the STE20 family of kinases including MST1, NIK, GCK, HPK1,
GLK, KHS, and HGK. Furthermore, PSK contains the amino acid sequence
GTPY/FWMAPEV in subdomain VIII characteristic for the STE20 family and
there is also no evident putative Cdc42/Rac binding domain (CRIB). The
C-terminal domain of PSK has no significant homology with any STE20
family member.
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Fig. 3.
A, alignment of the catalytic domain of
PSK with those of other STE20 family members. The 11 catalytic
subdomains are indicated above the alignment (I-XI).
Identical amino acids are shown in black. B,
diagram illustrating regions of homology between PSK and TAO1 or
KIAA0881.
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The catalytic domain of PSK is most similar to the recently discovered
rat TAO1 (thousand and one amino
acids) protein kinase (53) with 90% identity over amino acids 22-278
(Fig. 3B). The C termini of PSK and TAO1 are 68% homologous
between amino acids 278 and 744 and 23% homologous between amino acids
745 and 1001 (Fig. 3B). PSK contains an additional stretch
of 15 glutamic acid residues (amino acids 378-392) that are not
present in TAO1, and PSK also contains an additional 234 amino acids at
the C terminus. A DNA sequence has recently been released encoding a
predicted amino acid sequence for a human protein KIAA0881 (accession
no. AB020688) (54) that also has homology to PSK and rat TAO1 (Fig.
3B). To confirm that PSK was distinct from TAO1 and
KIAA0881, human genomic DNA was taken and subjected to PCR using a
forward primer to nucleotides 2753-2774 of PSK, which are also present in KIAAO881, combined with a reverse primer that was specific for PSK
(nucleotides 3180-3200). The PCR reaction generated a product of
approximately 450 bp, which was cloned and sequenced and found to be
PSK (data not shown). Two expressed sequence tags representing a single
clone from human testis have recently been entered into the GenBank
data base (accession nos. AL048834 and AL048835) and encode 5' and 3'
regions of PSK (903-1353 and 4220-4836 bp). Furthermore, an
additional cDNA sequence encoding a potential rat homolog of PSK
has been submitted to the GenBank data base during review of this
manuscript (TAO2, accession no. AAD39480). This cDNA, however,
encodes a much shorter protein of 993 amino acids. Taken together, this
information indicates that PSK and TAO1 are distinct genes encoding
proteins with closely related kinase domains.
Expression of PSK--
Northern blotting analysis, using an
XbaI 1105-1800 XhoI DNA fragment of PSK to probe
mRNA from eight different tissues, detected a 5-kb transcript in
prostate. PSK was ubiquitiously expressed in all of the other tissues
examined, and the strongest expression was found in testis (Fig.
4). We also used a BamHI
3504-4492 XbaI DNA fragment representing the 3' end of PSK
to detect the same 5-kb transcript in prostate and testis (data not
shown).
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Fig. 4.
Northern blot analysis of PSK. A
Northern blot (MTNTM, CLONTECH) containing 2 µg
of poly(A)+ RNA from various human tissues was probed with
nucleotides 1103-1801 of PSK cDNA. Position of size markers is
indicated alongside, and equal loading of samples was confirmed using a
probe for -actin.
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PSK Is a Protein Kinase--
MYC-tagged PSK was transiently
transfected into COS1 cells and cell lysates were immunoblotted using
antibody against the MYC-epitope tag. Two proteins of 165 and 185 kDa
were specifically recognized in cells transfected with full-length PSK
but absent from cells transfected with vector alone, suggesting
possible post-translational processing or truncation of the protein
(Fig. 5). Previous studies on other
STE20-like kinases such as FLAG-tagged HGK have also revealed
expression of a doublet (55).
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Fig. 5.
Expression of PSK in COS1 cells. COS1
cells were transfected with either pRK5-MYC vector alone or various
MYC-tagged PSK constructs and the expressed protein detected from the
cell lysates by immunoblotting with anti-MYC 9E10 antibody.
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To determine whether PSK had kinase activity, MYC-tagged PSK was
transiently transfected into COS1 cells and an in vitro
immune complex kinase assay was carried out on immunoprecipitates.
Although there was some background kinase activity toward MBP from
cells transfected with vector alone, there was a marked increase in MBP
phosphorylation in cells transfected with either full-length PSK or
C-terminally truncated PSK (1-349), which retains the kinase catalytic
domain (Fig. 6A). To eliminate
the possibility that an associated kinase may be co-precipitating with
PSK, which may account for the kinase activity, we generated
kinase-defective mutants PSK (K57A) and PSK (1-349, K57A), which both
lack a crucial lysine residue in the second kinase subdomain required
for ATP binding. In contrast to our findings using wild type PSK,
immunoprecipitates from cells transfected with mutated PSK (K57A) or
mutated C-terminally truncated PSK (1-349, K57A) failed to increase
levels of MBP phosphorylation above those obtained with vector alone
(Fig. 6A). Additional phosphorylated proteins were also
observed in the immune complex assay, at 185 and 45 kDa, and ran with
the same mobility as full-length and truncated PSK, respectively,
consistent with autophosphorylation of these protein kinases (Fig.
6B). This interpretation is supported by the absence of
these phosphorylated proteins in cells transfected with
kinase-defective PSK (K57A) or PSK (1-349, K57A) (Fig. 6B). These observations demonstrate that PSK and truncated PSK (1-349) act
as functional kinases and that the kinase activity observed is
attributable to PSK. Furthermore, addition of IL-1, transforming growth
factor , or serum to serum-starved cells expressing PSK failed to
increase enzymatic activity of the immunoprecipitated protein toward
MBP, suggesting that PSK is constitutively activated under these
conditions (data not shown).
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Fig. 6.
PSK has in vitro kinase
activity. COS1 cells were transfected with either pRK5-MYC vector
alone, V12RAS, and MYC-tagged ERK2 or various MYC-tagged PSK
constructs. Proteins were immunoprecipitated with anti-MYC 9E10
antibody and immunoprecipitates subjected to an in vitro
kinase assay using MBP as the substrate. A, proteins were
transferred to nitrocellulose after 10% SDS-PAGE and expression of
MYC-tagged ERK2 or MYC-tagged PSK proteins was confirmed by immunoblot
analysis with 9E10 antibody. B, proteins were not
transferred to nitrocellulose after 15% SDS-PAGE in order to detect
autophosphorylated PSKs.
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PSK Activates the JNK MAPK Pathway--
To determine whether PSK
could activate MAPK pathways, MYC-tagged PSK was co-transfected
together with FLAG-tagged JNK into COS1 cells and immune complexes of
JNK were prepared from cell lysates for in vitro kinase
assays using recombinant c-Jun as a substrate. Fig.
7A shows that transfected wild
type PSK and also truncated PSK (1-349) stimulated phosphorylation of
c-Jun 17.5- and 11.1-fold, respectively, when compared with cells
transfected with JNK alone. In contrast, transfection of
kinase-defective PSK (K57A) or PSK (1-349, K57A) causes no significant
increase in c-Jun phosphorylation levels. Normalization of samples or
expression of each transfected protein was confirmed by immunoblotting
either immunoprecipitated FLAG-JNK or cell lysates (MYC-PSKs) (Fig.
7A).
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Fig. 7.
PSK activates the JNK MAPK pathway. COS1
cells were transfected with either pRK5MYC vector alone or various
MYC-tagged PSK constructs, control MYC-tagged V12RAS, or control
MYC-tagged MLK2 along with FLAG-tagged JNK1 or FLAG-tagged ERK2 or
MYC-tagged p38. A, FLAG-tagged JNK was immunoprecipitated
with the M2 antibody and immunoprecipitates subjected to an in
vitro kinase assay using GST-c-Jun as the substrate. -Fold
increases in c-Jun phosphorylation are shown when compared with cells
transfected with JNK alone. B, FLAG-tagged ERK2 was
immunoprecipitated with the M2 antibody and immunoprecipitates
subjected to an in vitro kinase assay using MBP as the
substrate. C, MYC-tagged p38 was immunoprecipitated with the
9E10 antibody and immunoprecipitates subjected to an in
vitro kinase assay using GST-ATF2 as the substrate. Normalization
of immunoprecipitated FLAG-JNK, FLAG-ERK2, or MYC-p38 and expression of
MYC-tagged PSK proteins was confirmed by immunoblot analysis. PSK
appears as a single band after 15% SDS-PAGE. D, COS1 cells
were transfected with either pRK5MYC vector alone or various MYC-tagged
PSK constructs along with FLAG-tagged MKK4 (a), MKK7
(b), or MKK3 (c). FLAG-tagged MKKs were
immunoprecipitated and subjected to an in vitro kinase assay
using GST-JNK or GST-p38 as substrate. MEKK3 and MLK2 were used as
positive controls for MKK3 and MKK4 or MKK7, respectively.
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We also looked at effects of transfected PSK or PSK (1-349) on the ERK
and p38 MAPK pathways. MYC-PSK was co-transfected with either
FLAG-tagged ERK2 or MYC-tagged p38 into COS1 cells. However, immune-complexes prepared from these cells failed to demonstrate any
significant effect of PSK or PSK (1-349) on ERK2 activity toward MBP
phosphorylation (Fig. 7B) or p38 activity toward ATF2 (Fig.
7C) compared with V12RAS (25.4-fold stimulation) or MLK2 (20.3-fold stimulation), respectively (Fig. 7, B and
C). These findings demonstrate that PSK specifically
activates the JNK MAPK pathway and has no detectable stimulatory effect
on ERK or p38 MAPK pathways.
PSK Activates MKK4 and MKK7--
To determine whether PSK could
regulate MAPKKs upstream of JNK MAPK, MYC-tagged PSK was co-transfected
together with FLAG-tagged MKK4 or FLAG-tagged MKK7 into COS1 cells, and
immune complexes of MKK4 or MKK7 were used for in vitro
kinase assays using recombinant GST-JNK as a substrate. Fig.
7D shows that transfected wild type PSK and truncated PSK
(1-349) stimulated both MKK4 and MKK7 phosphorylation of GST-JNK,
compared with cells transfected with kinase-dead PSK proteins. In
contrast, PSK was unable to stimulate activity of MKK3 toward p38 (Fig.
7D).
PSK Is Localized to a Vesicular Compartment--
To determine the
intracellular localization of PSK, expression vectors encoding PSK and
various mutants were microinjected into the nuclei of Swiss 3T3 cells,
and the localization of MYC epitope-tagged PSK determined 4 h
after microinjection. Wild-type PSK localized predominantly to vesicles
in the cytoplasm of the majority of injected cells (Fig.
8a), which in some cells had a
tubulovesicular morphology (Fig. 8c). The localization of
PSK was not detectably altered by serum starvation or serum
re-stimulation (Fig. 9a and
c), indicating that PSK constitutively associates with this
vesicular compartment. The localization of PSK was clearly different
from PAK1, which showed a uniform cytoplasmic distribution (Fig.
8i). Interestingly, the C-terminally truncated version of PSK (1-349) showed a diffuse cytoplasmic localization
(
C-t, Fig. 8e), suggesting that the C-terminal
region includes sequences that are required for targeting to the
vesicular compartment. Kinase-defective PSK (K57A) showed a variable
intracellular localization (KD; Fig. 8g). In
approximately 50% of cells, it appeared diffusely cytoplasmic, whereas
in the remainder of cells it showed a less homogeneous distribution
that nevertheless did not resemble that of wild-type PSK. This implies
that autophosphorylation of PSK and/or phosphorylation of a downstream
target are important for its localization. We have also analyzed
localization of PSK in transfected COS1 cells and observed a similar
requirement for the C terminus to localize PSK (data not shown).
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Fig. 8.
PSK localization and effects on the actin
cytoskeleton. Growing Swiss 3T3 cells were microinjected with
pRK5-MYC-PSK (wt) (a-d), pRK5-MYC-PSK(1-349)
(C-t) (e and f), pRK5-MYC-PSK
(K57A) (KD) (g and h), or
pRK5-MYC-PAK1 (L107F) (LF) (i and j).
After 4 h, cells were fixed and co-stained with mouse anti-MYC
epitope antibodies followed by FITC-labeled anti-mouse IgG to show PSK
or PAK1 localization (a, e, g, and
i) and with TRITC-phalloidin to show actin filaments
(b, f, h, and j); or with
rabbit anti-MYC epitope antibodies followed by TRITC-labeled
anti-rabbit IgG to show PSK localization (c) and mouse
anti-vinculin antibodies followed by FITC-labeled anti-mouse IgG to
show vinculin localization (d). Bar represents 20 µm.
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Fig. 9.
Effects of PSK on serum-starved and
serum-stimulated cells. Swiss 3T3 cells were starved for 16 h
and then microinjected with pRK5-MYC-PSK (wt). Cells were
incubated for 4 h and then fixed (a and b)
or stimulated with 10% FCS for 10 min and then fixed. Cells were
co-stained with mouse anti-MYC epitope antibodies, followed by
FITC-labeled anti-mouse IgG to show PSK (a and c)
and with TRITC-phalloidin to show actin filaments (b and
d). Bar represents 20 µm.
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PSK Induces Retraction and Actin Reorganization--
We observed
that cells expressing wild type PSK were clearly altered in morphology:
they were more rounded, had fewer processes, and had a smaller spread
area than surrounding uninjected cells or cells expressing
kinase-defective PSK. To determine whether this cell shape change was
reflected in altered actin cytoskeletal organization, we analyzed actin
filament distribution in growing Swiss 3T3 cells following
microinjection with expression vectors encoding wild-type PSK and
various mutants. A marked change in the distribution of actin filaments
was observed by 4 h after microinjection (Fig. 8b).
Stress fibers were disorganized, and instead of being arranged in
parallel bundles, were concentrated in shorter bundles at the periphery
of the cell. A similar effect on actin stress fiber organization was
observed both in growing Swiss 3T3 cells (Fig. 8b) and in
starved cells acutely restimulated with FCS (Fig. 9b). In
some cells, a significant decrease in the level of stress fibers was
observed, and lamellipodia were not observed on any PSK-expressing
cells (Figs. 8b and 9d, and data not shown).
These changes were observed in multiple experiments, and with PSK in
two different expression vectors, pRK5 and EfPlink. Staining for
vinculin, a component of focal adhesions normally found at the ends of
stress fibers (56), showed that vinculin-containing adhesions were
ro-organized in PSK-expressing cells, such that they were mostly
present as small complexes at the periphery of the cells (Fig.
8d), consistent with the reorganization of the actin
cytoskeleton. The PSK-mediated loss of processes was clear from the
vinculin localization, as control cells had vinculin-containing focal
adhesions at the end of processes.
The alteration in cell morphology and actin organization by PSK was
dependent on kinase activity, since the kinase-defective mutant PSK
(K57A) had no effect (Fig. 8h). In addition, the truncated form of PSK (1-349) did not effect actin organization (Fig.
8f). Taken together with the results on PSK localization,
this suggests that correct localization of PSK is important for its
effects on the actin cytoskeleton.
Expression of activated PAK kinases has been reported to induce loss of
stress fibers in various cell types (42-44), so we compared the effect
of PSK with that of an activated form of PAK1, PAK (L107F) (57). As
previously reported in REF52 fibroblasts (42), PAK (L107F) did not
induce detectable loss of stress fibers at early time points (4 h)
after microinjection of the expression construct, although a decrease
in stress fibers was observed at 24 h after injection (Fig.
8j). PAK1 (L107F)-expressing cells did not retract,
indicating that the mechanism whereby PAK1 alters actin cytoskeletal
organization is significantly different from that induced by PSK.
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DISCUSSION |
We have used reverse transcription-PCR to identify 15 tyrosine or
serine-threonine kinases expressed in surgically removed prostate
tumors. These include the receptor kinases IGF1-R, PDGFBR, VEGFR2,
EPH-A1, MET, and RYK; the non-receptor kinases JAK1, JAK2, TYK2, ABL,
EMK, and PLK; and three novel kinases. Many of these kinases have been
shown to have oncogenic potential, and their presence in prostate
tumors provides a basis for further analysis of signaling pathways
involved in prostate cancer development.
PCR conditions were designed for kinase detection rather than
quantitative analysis of kinase expression, but the most frequently sequenced clones using this approach were IGF1-R and PDGFBR. Others have shown that elevated levels of plasma IGF1 are associated with
increased risk of prostate cancer development and that IGF1 is able to
activate the ERK MAPK pathway in DU145 cells, and acts as a potent
mitogen for prostate cancer cells (8, 58). Moreover, an IGF1-R
autocrine loop supports androgen-independent growth of DU145 prostate
cancer cells and antisense to the IGF1-R suppresses growth and invasion
of prostate cancer cells (6, 59). The presence of IGF1-R in all three
of our screened prostatic carcinoma tissues supports the notion that
IGF1-R may play a functional role in prostate cancer development. We
also detected a number of other receptor kinases in our degenerate PCR
screen of prostatic carcinoma tissues including PDGFBR; PDGF acts as a
potent mitogen for prostate cells (60) and the oncogenic potential of
PDGFBRs has been well characterized in other cancers. VEGFR2 and the
HGF receptor c-MET also function to regulate cell growth, migration, and the actin cytoskeleton via autocrine and paracrine loops, and
increases in expression of both vascular EGF and c-MET proteins have
been reported in malignant prostate cells (61-63). The EPH-A1 receptor
has not yet been investigated in prostate; however, overexpression of
the EPH-A1 receptor has been reported in breast, lung, liver, and colon
carcinoma tissues (64).
Some of the non-receptor kinases detected function as
transduction molecules regulating MAPK pathways. c-ABL can regulate the
ERK, JNK, and p38 MAPK pathways and the BCR-ABL oncogene induces transformation by activating the STE20-like GCKR (GCK-related) kinase
and JNK MAPK pathway in CML cells (65-67). The Janus family of
tyrosine kinases (JAK1-3, TYK2), which are able to induce rapid stimulation of interferon-responsive genes through latent cytoplasmic transcription factors, known as signal transducers and activators of
transcription, have not yet been investigated in prostate but can
regulate the ERK MAPK cascade in other cell types (68).
A profile of kinases expressed in a prostate carcinoma xenograft
grown in mice has recently been published and detected some of the
kinases reported here, including PDGFBR, EPH-A1, ABL, JAK1, and TYK2
(12). MAPK upstream regulators such as MKK3, MKK4, and MKK5 were also
present in this malignant prostate xenograft. The different kinase
profiles reported by us and by Robinson et al. (12) are most
probably accounted for by the use of different degenerate primers and
our use of surgically removed prostatic carcinoma tissues rather than a
prostate cancer xenograft grown in mice. The number of kinases that we
have detected is by no means complete and could probably be increased
by using alternative degenerate primers and analyzing additional tumor tissues.
We were particularly interested in the three potentially novel kinases
that were detected in our screen. Of these, one is a protein with 65%
homology over its entire length to the C. elegans predicted
protein C46C2.1 (49); however, none of the cDNAs that we isolated
had an in-frame stop codon (data not shown) and although the predicted
amino acid sequence appeared to contain all 11 kinase subdomains, a
crucial lysine residue required for ATP binding was missing in the
second catalytic domain (C190K). The protein could be expressed in COS1
cells, but immunoprecipitated protein was unable to phosphorylate MBP,
even after a lysine residue had been introduced into the second
catalytic subdomain (data not shown). The sequence of this
kinase-defective protein (named KDP) has been submitted to the GenBank
data base. (Another of the novel kinases turned out to encode the human
homolog of the recently isolated murine protein kinase PKL12, a
serine-threonine kinase, which is ubiquitiously expressed but has
unknown function (50).)
The third novel kinase encodes a new member of the STE20 kinase family,
which we have named PSK. STE20 family members are known to be involved
in regulating cell growth, transformation, differentiation, stress
responses, cytoskeletal organization, cell motility, and apoptosis.
They can be classified into two subfamilies according to their
structure and regulation. The first group of enzymes includes the PAK
and MLK proteins which have a C-terminal kinase domain and an
N-terminal regulatory region containing a CRIB (69), while the second
group of proteins have an N-terminal kinase domain and a C-terminal
regulatory region that does not contain a CRIB. PSK is structurally
related to the second group, which includes GCK, GLK, HGK, HPK1, KHS,
MST1/2, NIK, and TAO1. Immune complexes of PSK phosphorylated MBP
in vitro, demonstrating that it has kinase activity, and
transfected PSK specifically stimulated the JNK MAPK pathway but not
ERK MAPK or p38 MAPK in COS1 cells. This is similar to the response
observed with GLK, HGK, HPK1, KHS, and NIK, which specifically
stimulate the JNK pathway through MKK4, with GCK, GLK and NIK acting
via MEKK1, HGK via TAK1, and HPK via MLK3 (28, 29, 37, 39, 41, 55, 70).
In the case of HPK and NIK, this activity has been attributed in part
to direct interaction with MLK3 and MEKK1, respectively, through
homologous regions in their non-catalytic C-terminal domains (39). PSK
has no homology in its C-terminal region with these kinases, but we
have shown that PSK activates MKK4 and MKK7, which regulate the JNK
pathway. The C-terminal region of PSK also contains proline-rich
motifs,which could potentially bind to SH3 domains, and some of
these sites could therefore be important in protein-protein interactions.
Among the STE20 family, PSK shows the closest homology to TAO1, with
90% amino acid identity within the kinase domain (53). Outside the
kinase domain, however, homology is substantially reduced. Despite the
similarity of their catalytic domains, the specificities of PSK and
TAO1 for MAPK pathways appear to differ in cells. Transfected TAO1
interacts with MKK3, apparently through its C-terminal non-catalytic
domain, and stimulates MKK3 but not MKK4 activity, which would normally
be expected to activate p38 but not JNK. C-terminally truncated TAO1
(1-416) can, however, stimulate MKK4 activity in vitro
(53), suggesting that specificity of MAPK pathway activation in cells
is mediated by selective interactions of the C-terminal domain. Indeed,
we observe that the C-terminal region is essential for localization of
PSK to a vesicular cytoplasmic compartment, and this may be important
for its function. Our finding that transfected PSK, unlike TAO1,
specifically activates JNK does not, however, appear to be solely due
to the different C termini of PSK and TAO1, since truncated PSK
(1-349) containing the N-terminal kinase domain was also able to
activate JNK, albeit less potently than full-length PSK. The inability
of Hutchison et al. (53) to co-express TAO1 with JNK or p38
in 293 cells makes further comparisons with PSK difficult at the
present time.
Of the STE20-like kinases, only PAKs have so far been shown to induce
changes in actin organization in mammalian cells. PAKs interact with
the GTPases Cdc42 and Rac, which regulate the formation of filopodia
and lamellipodia, respectively (56). Various mutated forms of PAKs can
induce loss of actin stress fibers and focal complexes, stimulate
formation of filopodia and lamellipodia, and/or block Cdc42 and Rac
effects on the cytoskeleton (42-44, 71). In contrast, MLK2 and MLK3
also interact with Cdc42 and Rac but do not regulate the actin
cytoskeleton (34, 40). The cell retraction, loss of processes, and
actin reorganization observed with PSK is significantly different from
the loss of stress fibers induced by activated PAK1. Stress fibers
consist of actin and non-muscle myosin II filaments, and increased MLC
phosphorylation normally correlates with an increase in the number
and/or contractility of stress fibers (72). Both MLC and MLC kinase
have been reported to be targets for PAKs (73-75). Expression of
activated PAK1, however, can lead to either an increase or decrease in
MLC phosphorylation depending on the system (44, 74). We have found
that immunoprecipitated PSK does not phosphorylate purified myosin
light chain kinase in vitro nor does transfected PSK alter
phosphorylation of MLC on serine 19 following analysis by
immunoblotting of COS1 cell lysates, whereas expression of activated
RhoA does induce increased MLC phosphorylation, as previously reported
(76) (data not shown). An alternative possibility for how PSK acts is
suggested by its localization to cytoplasmic vesicles. As its ability
to induce reorganization of stress fibers correlates with this
localization, it may play a role in trafficking of proteins involved in
actin organization or focal adhesion formation. Indeed, there is good evidence that some focal adhesion components, including paxillin, are
normally associated with intracellular vesicles and need to be
transported to the plasma membrane in order for focal adhesions and
associated stress fibers to form efficiently (77).
In conclusion, we have demonstrated for the first time that a
STE20-like kinase which lacks a CRIB, PSK, can not only selectively activate the JNK MAPK pathway but also affects actin cytoskeletal organization. By coordinating these two responses, PSK may play a role
in regulating cell migration.
,
TOP
ABSTRACT
INTRODUCTION
To whom correspondence should be addressed: Molecular Oncology
Laboratory, Rayne Inst., 123 Coldharbour Ln., London SE5 9NU, United
Kingdom. Fax: 44-0207-8485873; E-mail: jonathan.morris@ kcl.ac.uk.
