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Previous Article | Next Article 
Molecular and Cellular Biology, October 2000, p. 7726-7734, Vol. 20, No. 20
0270-7306/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Regulation of CDK7-Carboxyl-Terminal Domain Kinase Activity by
the Tumor Suppressor p16INK4A Contributes to Cell
Cycle Regulation
Eiji
Nishiwaki,1,
Saralinda L.
Turner,2
Susanna
Harju,1
Shiro
Miyazaki,1,
Masahide
Kashiwagi,1
James
Koh,2 and
Hiroaki
Serizawa1,*
Department of Biochemistry and Molecular
Biology, University of Kansas Medical Center, Kansas City, Kansas
66160-7421,1 and Department of
Pathology, University of Vermont College of Medicine, Burlington,
Vermont 05405-00682
Received 19 January 2000/Returned for modification 21 March
2000/Accepted 27 July 2000
 |
ABSTRACT |
The eukaryotic cell cycle is regulated by cyclin-dependent kinases
(CDKs). CDK4 and CDK6, which are activated by D-type cyclins during the
G1 phase of the cell cycle, are thought to be responsible for phosphorylation of the retinoblastoma gene product (pRb). The tumor suppressor p16INK4A inhibits phosphorylation of
pRb by CDK4 and CDK6 and can thereby block cell cycle progression
at the G1/S boundary. Phosphorylation of the
carboxyl-terminal domain (CTD) of the large subunit of RNA polymerase
II by general transcription factor TFIIH is believed to be an
important regulatory event in transcription. TFIIH contains a
CDK7 kinase subunit and phosphorylates the CTD. We have previously shown that p16INK4A inhibits phosphorylation of
the CTD by TFIIH. Here we report that the ability of
p16INK4A to inhibit CDK7-CTD kinase contributes
to the capacity to induce cell cycle arrest. These results
suggest that p16INK4A may regulate cell cycle
progression by inhibiting not only CDK4-pRb kinase activity but
also by modulating CDK7-CTD kinase activity. Regulation of
CDK7-CTD kinase activity by p16INK4A thus
may represent an alternative pathway for controlling cell cycle progression.
| |
INTRODUCTION |
Cyclin-dependent kinases (CDKs)
regulate cell cycle progression (references 13, 21,
and 28) and references therein). CDK4 and CDK6 are
activated by D-type cyclins and participate in controlling the
G1-to-S phase transition by phosphorylating the
retinoblastoma gene product (pRb). Phosphorylation of pRb induces
remodeling of transcriptional repressor complexes at pRb-regulated genes and causes the release of transcription factors such as E2F. Free
E2F can then activate the transcription of genes required for entering
S phase (36, 41).
p16INK4A is a tumor suppressor gene product which
binds CDK4 and inhibits CDK4-mediated phosphorylation of pRb
(27). Overexpression of p16INK4A can
block cell cycle progression through the G1-to-S phase
boundary in a pRB-dependent manner (16, 19). Many
p16INK4A mutants identified from human tumors
have been shown to have defects in this activity (15, 16, 19, 20,
22, 31). These data suggest that the CDK4-inhibitory activity of
p16INK4A is involved in regulating cell cycle
progression through the G1/S boundary.
Koh et al. have described an interesting phenotype associated with a
p16INK4A mutant, G101W, that was originally
identified in a familial melanoma kindred (14, 16). The
G101W mutant was defective in inhibiting CDK4, although overexpression
of the G101W mutant in an osteosarcoma cell line provoked cell cycle
arrest at G1. In this mutant, the CDK4-pRb
kinase-inhibitory activity of p16INK4A apparently
does not correlate with the ability to induce cell cycle arrest in
G1 when overexpressed. These results raise the possibility
that an additional biochemical activity of
p16INK4A might contribute to the ability to
arrest cell cycle progression.
p15INK4B, p18INK4C, and p19INK4D
are members of the p16INK4A gene family, and all
have significant homology in their primary structures (11, 12). Like p16INK4A, the other INK4 family
members can each bind and inhibit the activity of CDK4 and CDK6.
Despite these similarities among the INK4 family members, only
mutations in p16INK4A have been found to
correlate with human tumors (15, 16, 19, 20, 22, 31, 38,
39). These data suggest that the ability to inhibit pRb kinase
activity may not be the sole determinant of the tumor suppressor
activity of p16INK4A.
TFIIH is an essential factor for transcription by RNA
polymerase II (RNA pol II). TFIIH is composed of nine
subunits (2, 3, 40). CDK7, a kinase subunit of
TFIIH, phosphorylates the carboxyl-terminal domain (CTD) of
the largest subunit of RNA pol II in vitro (8, 23, 26, 29).
The CTD is highly phosphorylated in vivo (reference
5) and references therein). Genetic data for the
yeast Saccharomyces cerevisiae have suggested that
phosphorylation of the CTD by KIN28, the kinase subunit of yeast
TFIIH, is required for mRNA production and cell viability
(35). These data suggest that phosphorylation of the CTD by
TFIIH is required for transcription.
CyclinH, the obligate activating partner of CDK7, is also a subunit of
TFIIH. CDK7 and cyclinH form a TFIIH subcomplex
with MAT1, a component which stabilizes the association between cyclinH and CDK7 (7, 9, 32). Both TFIIH and the subcomplex
composed of CDK7, cyclinH, and MAT1 can phosphorylate the threonine
primary activation site of CDK2 and activate the histone H1 kinase
activity of this enzyme (references 26 and
30 and references therein). To reflect this
function, TFIIH and the cyclinH-CDK7-MAT1 subcomplex are
called CDK-activating kinase (CAK). Genetic data for
Drosophila have suggested that CAK activity by CDK7
regulates mitotic cell cycle progression (18).
We have recently reported that p16INK4A can
specifically inhibit TFIIH-CTD kinase activity but that
p16INK4A did not inhibit TFIIH-CDK2 kinase
activity (25). Recombinant p16INK4A inhibited phosphorylation of the CTD by
purified TFIIH or by recombinant CAK composed of CDK7,
cyclinH, and MAT1. We define this novel biochemical function as
CDK7-CTD kinase-inhibitory activity. Here we describe the cellular
phenotypes of p16INK4A mutants defective for the
ability to inhibit CDK7-CTD kinase, CDK4-pRb kinase, or both enzymes.
In a transient overexpression system, we have found that CDK7-CTD
kinase-inhibitory activity contributes to the ability of
p16INK4A to induce cell cycle arrest. These results
suggest that the CDK7-CTD kinase-inhibitory activity of
p16INK4A may constitute a link between the basal
transcription apparatus and regulation of cell cycle progression.
| |
MATERIALS AND METHODS |
Purification of recombinant CAK (rCAK).
Recombinant
baculoviruses containing cDNAs of CDK7, cyclinH, and MAT1 were
coinfected into Sf21 insect cells, and lysates from the infected cells
were prepared using nitrogen cavitation, as described by Serizawa
(25). The cell lysate containing ~13 mg of proteins was
dialyzed against buffer C (20 mM HEPES-NaOH [pH 7.4], 10% glycerol,
1 mM dithiothreitol [DTT]), until it reached a conductivity
equivalent to that of buffer C containing 50 mM KCl. The lysate was
centrifuged at 35,000 rpm for 30 min in a Beckman type 50.2Ti rotor,
and the resulting supernatant was loaded onto a DEAE-5PW column (7.5 by
75 mm) (Toso-Haas) preequilibrated with buffer C containing 80 mM KCl.
The column was washed using buffer C containing 80 to 1,000 mM KCl and
eluted at 1 ml/min using a 60-ml linear gradient from 80 to 1,000 mM
KCl in buffer C. One-milliliter fractions were collected. Active
fractions, which eluted at approximately 200 mM KCl, were pooled
(fraction I). Fraction I was dialyzed against buffer C until it reached a conductivity equivalent to that of buffer C containing 10 mM KCl. The
fraction was centrifuged at 35,000 rpm for 30 min in a Beckman type
80Ti rotor, and the resulting supernatant was loaded onto an SP-5PW
column (5 by 50 mm) (Toso-Haas) preequilibrated with buffer C
containing 80 mM KCl. The column was washed using buffer C containing
50 mM KCl, and the flowthrough fraction was collected and pooled. The
flowthrough fraction was centrifuged at 35,000 rpm for 30 min, and was
loaded onto a heparin-5PW column (5 by 50 mm) (Toso-Haas)
preequilibrated with buffer A (10 mM Tris-HCl [pH 7.9], 5 mM
MgCl2, 10% glycerol, 0.5 mM DTT) containing 50 mM KCl. The
column was washed using buffer A containing 50 mM KCl, and eluted at
0.3 ml/min using a 10-ml linear gradient from 50 to 300 mM KCl in
buffer C. Fractions (0.3 ml) were collected. Active fractions were
eluted at approximately 200 mM KCl.
Expression constructs of His-p15, His-chimera 1, His-chimera 2, His-R24P, His-L31R, and His-G101W.
The primary structures of
p16INK4A and p15INK4B used in this
work are shown in Fig. 3a. cDNAs encoding
p16INK4A and p15INK4B were obtained
from James Koh and David Beach, respectively, and were used as
templates for PCRs.
(i) His-p15.
A DNA fragment containing human
p15INK4B was amplified using PCR techniques. The fragment
was subcloned in the pQE9 vector (Qiagen) to produce human
p15INK4B containing six histidine residues at the amino terminus.
(ii) His-chimera 1.
To generate an expression construct of
His-chimera 1, shown in Fig. 3b, two DNA fragments encoding amino acid
residues 1 to 43 of p16INK4A and 46 to 138 of
p15INK4B were amplified using PCR techniques. These
fragments were subcloned in pQE9 (Qiagen). A silent mutation (AGT to
TCT) was introduced at codon 43, encoding a serine residue of
p16INK4A, to generate an EcoRI site in
the PCR primers, and this restriction site was used to subclone these
fragments in pQE9.
(iii) His-chimera 2.
To generate the expression construct of
His-chimera 2 shown in Fig. 3b, two DNA fragments encoding amino acid
residues 1 to 45 of p15INK4B and 44 to 156 of
p16INK4A were amplified using PCR techniques.
These fragments were subcloned in pQE9 (Qiagen). A silent mutation (GGT
to GGC) was introduced at codon 45, encoding a glycine residue of
p16INK4A, to generate an EagI site in
the PCR primers, and this restriction site was used to subclone these
fragments in pQE9.
(iv) His-R24P, His-L31R, and His-G101W.
cDNA constructs
containing p16INK4A mutants His-R24P, His-L31P,
and His-G101W were generated by PCR techniques using the
QuickChange site-directed mutagenesis kit (Stratagene) by
following the manufacturer's instructions. Codon 24 (CGG, arginine)
was changed to CCG (proline), (R24P), codon 31 (CTG, leucine)
was changed to CGT (arginine) (L31R), and codon 101 (GGG, glycine)
was changed to TGG (tryptophan) (G101W).
After generating these expression constructs using PCR techniques, DNA
sequences of the constructs were determined. The recombinant proteins
used in this study, including His-p16, contain six histidine residues
at the amino terminus.
Purification of His-p16, His-p15, His-chimera 1, and His-chimera
2.
Recombinant proteins His-p16, His-p15, His-chimera 1, His-chimera 2, His-R24P, His-L31R, and His-G101W were overexpressed in
Escherichia coli by IPTG
(isopropyl-
-D-thiogalactopyranoside) induction, and
lysates containing these proteins were prepared as described previously
(25). These proteins were purified using nickel-nitrilotriacetic acid columns (Qiagen) (25) and were extensively purified using phenyl-Sepharose columns (Pharmacia). Proteins were loaded on the columns in a buffer containing 1 M ammonium
sulfate and were eluted using stepwise buffer changes.
Phosphorylation of GST-CTD.
Except as indicated in the
figure legends, CTD phosphorylation reaction mixtures contained 10 µg
of glutathione S-transferase (GST)-CTD, ~0.01 pmol of
TFIIH, ~0.01 pmol of rCAK, and [
-32P]ATP
(ICN), as described previously (25). The reaction mixtures were incubated for 2 h at 28°C, and reactions were stopped by addition of an equal volume of sodium dodecyl sulfate (SDS) sample buffer containing 100 mM Tris-HCl, pH 6.8, 200 mM DTT, 4% SDS, 0.2%
bromophenol blue, and 20% (vol/vol) glycerol. Phosphorylated proteins
were analyzed by electrophoresis in SDS-10% polyacrylamide gels.
32P incorporated into GST-CTD was detected by autoradiograms.
Phosphorylation of pRb.
Except as indicated in the figure
legends, pRb phosphorylation reaction mixtures contained 50 mM
HEPES-NaOH (pH 7.9), 1 mM DTT, 0.1 mg of bovine serum albumin, 3.7%
glycerol, 10 µM ATP (2 µCi of [-32P]ATP), 10 mM
MgCl2, 2 µg of GST-pRb, and Sf21 cell lysates containing CDK4 and cyclinD. Reaction mixtures were incubated for 30 min at
28°C, and reactions were stopped by addition of an equal volume of
the SDS sample buffer. Phosphorylated proteins were analyzed by
electrophoresis in SDS-10% polyacrylamide gels. 32P
incorporated into GST-pRb was detected by autoradiograms.
CDK4-pRb kinase activity in Sf21 cell lysates and CDK4-pRb
kinase-inhibitory activities of p16INK4A mutants
and the wild type at 28°C were shown to be equivalent to those at
30°C (data not shown).
Western blotting analysis.
Western blotting experiments were
carried out as described previously (25). Antibodies against
CDK7, cyclinH, MAT1, p16INK4A, and
p15INK4B were obtained from Santa Cruz Biotechnology. These
molecules were detected by chemiluminescence using horseradish
peroxidase-conjugated secondary antibodies (Amersham).
Protein quantitation.
The recombinant proteins prepared from
E. coli lysates were quantified using the protein dye assay
(Bio-Rad) according to the manufacturer's instruction, with bovine
serum albumin as the standard. Protein quantitation of TFIIH
and rCAK was based on the A280 values of the
preparations (26).
Cell cycle analysis using flow cytometry.
Cell cycle
analysis was carried out essentially as described previously
(16). U2OS cells were cultured in Dulbecco's modified Eagle
medium containing 10% fetal bovine serum (FBS). Plasmids encoding a
membrane-bound derivative of EGFP (f-EGFP; Clontech), wild-type
p16INK4A, or the p16INK4A
mutants under the control of the cytomegalovirus promoter (pcDNA3.1 [Invitrogen]) were cotransfected using the Effectene transient transfection kit (Qiagen) in the presence of FBS by following the
manufacturer's instructions. After 36 h, the cells were harvested using trypsin. The harvested cells were washed once in culture media
containing FBS and once in phosphate-buffered saline (PBS) and then
were fixed in 75% ethanol overnight at 4°C. The fixed cells were
treated with RNase A and stained with propidium iodide (PI) using
standard conditions. The fixed and stained cells were then analyzed
using a Coulter EPICS XL analytical flow cytometer. Flow cytometry data
were generated from a minimum of 80,000 cells per sample. A gate was
set to select green fluorescent protein (GFP)-positive cells with a
signal intensity at least 20 times greater than that in the
untransfected cells. The PI signal was used as a measure of DNA
content. DNA histograms contain data from at least 1,000 GFP-positive
cells per sample, and cell cycle distribution data were calculated
using the WinList and ModFit analytical software packages (Verity Software).
Confocal microscopy.
HeLa cells plated onto glass coverslips
were washed once in PBS and then were fixed in a freshly prepared 4%
(wt/vol) paraformaldehyde-PBS solution for 20 min at room temperature.
The fixed cells were permeabilized by incubation in a 1% (vol/vol)
Triton X-100-PBS solution for 10 min at room temperature and then
washed twice with PBS. Before being stained, the cells were incubated
for 20 min at room temperature in a blocking buffer consisting of 20% (vol/vol) normal goat serum and 0.05% (vol/vol) Tween 20 in PBS. The
cells were washed once in PBS and then incubated with the primary
antibody in blocking buffer. The affinity-purified rabbit polyclonal
anti-CDK7 antibody (sc-529; Santa Cruz Biotechnology) was used at 4 µg/ml. For p16INK4A staining, a cocktail
consisting of an equal mixture of the protein G-purified monoclonal
antibodies JC2, JC4, JC6, and JC8 (1; J. Koh,
unpublished data) was used at a final concentration of 2 µg/ml in
blocking buffer. The coverslips were incubated in the primary antibody
solutions for 1 h at room temperature in a humidified chamber and
then were washed three times in PBS. CDK7 immunoreactivity was
visualized with an allophycocyanin 650-conjugated goat anti-rabbit secondary antibody (A-10931; Molecular Probes) used at a final concentration of 10 µg/ml in blocking buffer.
p16INK4A immunoreactivity was detected with an
ALEXA 488-conjugated goat anti-mouse secondary antibody (A-11029;
Molecular Probes) used at a final concentration of 10 µg/ml in
blocking buffer. Incubation in the secondary-antibody solutions was
conducted in a darkened humidified chamber for 1 h at room
temperature. The coverslips were then washed twice with PBS and once
with deionized water. Coverslips were mounted in a medium containing
the antiquenching agent n-propyl gallate.
Confocal microscopy analysis was conducted using a Bio-Rad MRC1024ES
instrument and Laser Scan software. Slides were scanned using a ×100
oil immersion phase objective with image zoom set at 2.00, sequential
488- and 650-nm laser excitation, and Kalman filtering to remove noise.
Phase images of the field were also recorded. Confocal images were
generated using the Laser Sharp software package. A small amount of
nonspecific binding was seen in the secondary-only control slide for
the allophycocyanin (red) images; this background signal was subtracted
out of the allophycocyanin images using the Laser Sharp threshold
setting. The adjusted allophycocyanin images were then merged with
their corresponding ALEXA (green) images. Pixels which contained both
red and green fluorescence above background appear in white on the
merged images. Pixel dimensions were 147 nm2, and the depth
of field was estimated at 1.5 µm.
| |
RESULTS |
Recombinant p16INK4A inhibits
phosphorylation of CTD by TFIIH and by
rCAK.
We previously demonstrated that recombinant
p16INK4A containing six histidine residues
(His-p16) inhibits phosphorylation of the CTD by highly
purified TFIIH (25). We sought to determine
whether His-p16 could inhibit phosphorylation of the
CTD by isolated rCAK composed of CDK7, cyclinH, and MAT1. Baculovirus
constructs containing cDNAs encoding these three molecules were
coinfected into Sf21 insect cells and were overexpressed therein.
The rCAK was purified to near homogeneity using conventional
high-performance liquid chromatography (HPLC) columns. Western
blots (Fig. 1a) show that CDK7, cyclinH,
and MAT1 coeluted in a heparin HPLC column. The CTD
phosphorylation activity in these column fractions
coeluted with the three proteins. The silver-stained gel of these
column fractions revealed proteins corresponding to CDK7, cyclinH, and MAT1; however, MAT1 was not stained by silver as strongly as CDK7 and
cyclinH. His-p16 was overexpressed in E. coli and was
purified to near homogeneity by nickel affinity and phenyl-Sepharose
columns (Fig. 1c). Phosphorylation of a fusion protein of GST and CTD (GST-CTD) by the purified rCAK was carried out in the presence of
increasing amounts of His-p16. The addition of His-p16 inhibited phosphorylation of GST-CTD by rCAK under conditions
where rCAK was limiting (Fig. 2a, lanes 7 to 9). In control experiments, similar inhibitory activities of His-p16
were detected in the phosphorylation of CTD by purified
TFIIH (Fig. 2a, lanes 1 to 3). These results suggest that
His-p16 inhibits phosphorylation of GST-CTD not only by
purified TFIIH but also by purified rCAK composed of CDK7,
cyclinH, and MAT1.
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FIG. 1.
Purified rCAK, TFIIH, recombinant His-p16, and
recombinant His-p15. (a) Purification of rCAK. The rCAK was
fractionated in a heparin-5PW column, as described in Materials and
Methods. The column fractions were analyzed by SDS-13.5%
polyacrylamide gel electrophoresis (PAGE) (silver stain), by
phosphorylation assays with GST-CTD, and by Western
blotting with antibodies against CDK7, cyclinH, and MAT1, as indicated.
(b) TFIIH purified from rat liver. This preparation of
TFIIH was previously shown (25). (c and d) His-p16
and His-p15 were purified as described in Materials and Methods. These
recombinant proteins were analyzed in an SDS-13.5% PAGE. Arrowheads,
His-p16 and His-p15 stained by Coomassie blue (CBB).
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FIG. 2.
His-p15 does not inhibit CDK7-CTD kinase under
conditions where His-p16 inhibited this kinase. (a) Phosphorylation of
GST-CTD by purified TFIIH and rCAK was carried out as
described in Materials and Methods. His-p16 and His-p15 (4 pmol each)
were added in the phosphorylation reactions shown in
lanes 2, 5, 8, and 11; 8 pmol of these recombinant proteins was added
in the phosphorylation reactions shown in lanes 3, 6, 9, and 12. The reactions shown in lanes 1, 4, 7, and 10 did not contain
His-p15 or His-p16. Arrowheads, GST-CTD phosphorylated
by purified TFIIH and rCAK. (b) Phosphorylation of GST-pRb in
insect cell lysates containing CDK4 and cyclinD was carried out as
described in Materials and Methods. His-p16 at 0.05, 0.1, and 0.5 pmol
was added in the phosphorylation reactions shown in
lanes 2 to 4, respectively. His-p15 at 0.05, 0.1, and 0.5 pmol was
added in the phosphorylation reactions shown in lanes 6 to 8, respectively. The reactions shown in lanes 1 and 5 had no His-p15
or His-p16. Arrowhead, phosphorylated GST-pRb.
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Recombinant p15INK4B does not inhibit
phosphorylation of CTD by TFIIH and
rCAK.
The CDK inhibitors p16INK4A and
p15INK4B have significantly similar primary structures
(12) (Fig. 3), and both are able to inhibit phosphorylation of pRb by CDK4 (12). We
examined whether p15INK4B could inhibit CTD
phosphorylation by TFIIH and rCAK. A
recombinant p15INK4B containing six histidine residues
(His-p15) was overexpressed in E. coli and was extensively
purified using nickel affinity and phenyl-Sepharose columns (Fig. 1d).
Phosphorylation of GST-CTD by purified TFIIH and by purified
rCAK was carried out in the presence of increasing amounts of His-p15.
In contrast to His-p16, purified His-p15 did not inhibit the
phosphorylation of GST-CTD (Fig. 2a, lanes 4 to 6 and
10 to 12). To confirm the CDK4-inhibitory activities of the His-p16 and
His-p15 preparations, phosphorylation of GST-pRb by
cyclinD-CDK4 complexes was assayed in the presence of these proteins.
GST-pRb was phosphorylated in lysates prepared from
insect cells coinfected by baculovirus constructs containing CDK4 and
cyclinD, but phosphorylation of GST-pRb in lysates
prepared from insect cells infected by a baculovirus construct
containing either CDK4 alone or cyclinD alone was undetectable (data
not shown). Addition of either His-p15 or His-p16 inhibited
phosphorylation of GST-pRb by cyclinD-cyclin D-CDK4
CDK4 kinase under conditions where CDK4 activity was limiting (Fig. 2).
These results suggest that the preparation of His-p15 used in GST-CTD
phosphorylation assays was as active as His-p16 in
inhibiting phosphorylation of GST-pRb by CDK4, although
it was unable to inhibit phosphorylation of GST-CTD by
TFIIH and rCAK. These results suggest that His-p15 does not
inhibit phosphorylation of GST-CTD by purified
TFIIH and rCAK.
Chimeras of p16INK4A and p15INK4B
inhibit phosphorylation of CTD by TFIIH and
rCAK.
The structural similarity of p16INK4A
and p15INK4B is concentrated in the middle regions of
these proteins, as shown in Fig. 3a. The amino-terminal region containing amino acid residues 1 through 43 of
p16INK4A, however, is quite divergent from the
amino-terminal region of p15INK4B. To test whether the
nonhomologous region of p16INK4A is involved in
CDK7-CTD kinase-inhibitory activity, we constructed recombinant
chimeric proteins of p16INK4A and
p15INK4B that exchanged these nonhomologous regions.
Expression constructs containing the chimeras depicted in Fig. 3b were
generated by PCR techniques. Chimera 1 has the nonhomologous region of
p16INK4A at the amino terminus and the homologous
region of p15INK4B at the carboxyl terminus. Chimera 2 has
the nonhomologous region of p15INK4B at the amino terminus
and the homologous region and the carboxyl-terminal 20 amino acid
residues of p16INK4A at the carboxyl
terminus. These recombinant chimeric proteins each contain six
histidine residues at their amino termini (His-chimera 1 and
His-chimera 2). The proteins were overexpressed in E. coli, and were purified to near homogeneity using nickel affinity and phenyl-Sepharose beads (Fig. 3c). The chimeric proteins were then tested for their ability to inhibit the CTD kinase activity of purified TFIIH and rCAK. Phosphorylation of GST-CTD by
purified TFIIH and rCAK was assayed in the presence of
increasing amounts of His-chimera 1 and His-chimera 2 under conditions
where wild-type His-p16 was able to fully inhibit this kinase activity.
His-chimera 1 inhibited phosphorylation of GST-CTD by
both purified TFIIH and rCAK, whereas His-chimera 2 did not
inhibit phosphorylation of GST-CTD by purified
TFIIH and rCAK (Fig. 4).
The intensities and profiles of His-chimera 1 and His-p16
inhibition of CDK7-CTD kinase were similar (Fig. 2a and 4a)
(25). In CTD phosphorylation reactions,
addition of 20 pmol or more of His-p16 or His-chimera 1 saturated the
inhibition of CDK7-CTD kinase, reducing CTD
phosphorylation by 60 to 70% (data not shown). These
results suggest that the nonhomologous region of
p16INK4A exchanged in these chimeric proteins is
involved in the CDK7-CTD kinase-inhibitory activity of
p16INK4A.
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FIG. 3.
Preparation of chimera 1 and chimera 2. (a) Amino acid
alignment of p16INK4A and p15INK4B
showing structural similarities. The amino acid alignment was carried
out using ClustalW, as described previously (34). Vertical
lines indicate amino acid identity, colons indicate conservative
substitutions, and single dots indicate nonconservative substitutions.
(b) Chimera 1 and chimera 2. (c) His-chimera 1 and His-chimera 2 were
expressed and purified as described in Materials and Methods. Purified
His-chimera 1 and His-chimera 2 were analyzed by SDS-13.5%
polyacrylamide gel electrophoresis and were stained using Coomassie
blue (CBB).
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FIG. 4.
His-chimera 1, but not His-chimera 2, inhibits CDK7-CTD
kinase. (a) Phosphorylation of GST-CTD by purified TFIIH and
rCAK was carried out as described in Materials and Methods. His-chimera
1 and His-chimera 2 (4 pmol each) were added in the kinase reactions
shown in lanes 2, 5, 8, and 11; 8 pmol of these recombinant proteins
was added in the kinase reactions shown in lanes 3, 6, 9, and 12. The
reactions shown in lanes 1, 4, 7, and 10 had no chimeric inhibitors.
Arrowheads, GST-CTD phosphorylated by purified
TFIIH and rCAK. (b) Phosphorylation of GST-pRb in insect cell
lysates containing CDK4 and cyclinD was carried out as described in
Materials and Methods. Purified His-chimera 1 at 0.05, 0.1, and 0.5 pmol was added in the phosphorylation reactions shown
in lanes 2 to 4, respectively. Purified His-chimera 2 at 0.05, 0.1, and
0.5 pmol was added in the phosphorylation reactions
shown in lanes 6 to 8, respectively. The reactions shown in lanes 1 and
5 had neither inhibitor. Arrowheads, phosphorylated
GST-pRb.
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To confirm that His-chimera 1 and His-chimera 2 retained the ability to
inhibit CDK4, phosphorylation of pRb by cyclinD-CDK4 complexes was carried out in the presence of these chimeric proteins under conditions where His-p16 and His-p15 showed full
inhibition. Addition of His-chimera 1 or His-chimera 2 inhibited
phosphorylation of pRb by CDK4 (Fig. 4). These
results suggest that the recombinant chimeras used here preserved their
CDK4-inhibitory activity and that the conserved regions of
p16INK4A and p15INK4B are responsible
for CDK4-pRb kinase-inhibitory activity.
Phenotypes of p16INK4A mutants in the
inhibitory activities for CDK7-CTD kinase and CDK4-pRb kinase.
To
examine whether the CDK7-CTD kinase-inhibitory activity of
p16INK4A could affect cell cycle progression, we
generated p16INK4A mutants using PCR techniques
and saturation mutagenesis and determined the phenotypes of these
mutants in the inhibition of CDK4-pRb kinase and CDK7-CTD kinase. The
fact that His-chimera 1 inhibits CDK7-CTD kinase suggests that there is
a distinct boundary separating regions involved in inhibiting CDK7-CTD
kinase and CDK4-pRb kinase and that the nonhomologous region is
involved in CDK7-CTD kinase-inhibitory activity. We focused on three
mutants with missense substitutions in regions involved in the
inhibition of CDK4-pRb kinase and CDK7-CTD kinase. These mutants
are R24P, L31R, and G101W. The R24P and G101W mutants were
identified from familial melanoma pedigrees (16, 31), and
the L31R mutant was generated by saturation mutagenesis. The R24P
and L31R mutations are located in the nonhomologous region and were
thus expected to result in defective inhibition of CDK7-CTD kinase.
Recombinant proteins of these mutants and the wild-type counterpart
were overexpressed in E. coli and were purified to near
homogeneity using nickel affinity and phenyl-Sepharose columns (Fig.
5a). These recombinant proteins are
called His-R24P, His-L31R, His-G101W, and His-p16. Phosphorylation of
GST-CTD was carried out using rCAK in the presence of increasing
amounts of His-R24P, His-L31R, His-G101W, or His-p16 under conditions
where rCAK was limiting. Addition of His-p16 and His-G101W inhibited phosphorylation of GST-CTD. However, addition of
His-R24P and His-L31R failed to inhibit rCAK activity in parallel
experiments (Fig. 5). The 50% inhibitory concentrations
(IC50) of His-R24P and His-L31R in the inhibition of
GST-CTD phosphorylation were significantly larger than
those of His-G101W and His-p16 (Table 1).
Similar results were obtained from experiments using purified TFIIH (data not shown). These results suggest that
His-R24P and His-L31R do not inhibit CTD
phosphorylation by CDK7 under conditions where
His-G101W and His-p16 efficiently inhibit this kinase activity.
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FIG. 5.
Inhibition of CDK4-pRb kinase and CDK7-CTD kinase by
His-p16, His-R24P, His-L31R, and His-G101W. (a) His-R24P, His-L31R,
His-G101W, and His-p16 purified from E. coli lysates were
stained by Coomassie blue in an SDS-13.5% polyacrylamide gel. Wt,
wild type. (b) Inhibition of CTD phosphorylation by
rCAK in the presence of His-p16 and His-G101W. Phosphorylation of
GST-CTD was carried out using rCAK, as described in the text. Four
(lanes 2, 6, 10, and 14), 8 (lanes 3, 7, 11, and 15), and 20 pmol
(lanes 4, 8, 12, and 16) of His-p16, His-R24P, His-L31R, and His-G101W
were added in the phosphorylation reactions. The
reactions in lanes 1, 5, 9, and 13 did not have these
p16INK4A proteins. Arrowheads, GST-CTD
phosphorylated by rCAK. (c) The inhibition of pRb
phosphorylation by CDK4 in the presence of His-p16 and
His-L31R. Phosphorylation of GST-pRb in insect cell lysates containing
CDK4 and cyclinD was carried out as described in Materials and Methods.
Phosphorylation reaction mixtures contained 0.05 (lanes 2, 6, 10, and
14), 0.1 (lanes 3, 7, 11, and 15), and 0.5 pmol (lanes 4, 8, 12, and
16) of His-p16, His-R24P, His-L31R, and His-G101W. The reactions shown
in lanes 1, 5, 9, and 13 contained no recombinant p16 proteins.
Arrowheads, phosphorylated GST-pRb.
|
|
Next, to determine the ability of the p16INK4A
mutants to inhibit pRb phosphorylation by CDK4,
phosphorylation of GST-pRb was carried out in the
presence of increasing amounts of His-R24P, His-L31R, His-G101W, and
His-p16 under conditions in which CDK4 is limiting. GST-pRb was
phosphorylated by lysates prepared from insect cells coinfected by baculovirus constructs containing CDK4 and cyclinD, but
no GST-pRb kinase activity was detectable in lysates prepared from
insect cells infected by a baculovirus construct containing either CDK4
or cyclinD alone (data not shown). Addition of His-p16 and His-L31R to
the lysates containing CDK4-cyclinD complexes inhibited
phosphorylation of GST-pRb; however, addition of G101W and R24P did not inhibit this kinase activity in parallel experiments (Fig. 5c). The IC50 of His-R24P and His-G101W were 10 times
greater than those of His-p16 and His-L31R (Table 1), and the
IC50 of His-G101W was equivalent to that reported by Yang
et al. (37). Clearly, His-R24P and His-G101W do not inhibit
pRb phosphorylation by CDK4 under conditions where
His-p16 and His-L31R efficiently inhibit CDK4 activity. These
biochemical data indicate that His-R24P is defective in the inhibition
of both CTD and pRb phosphorylation, that His-L31R is
defective in the inhibition of only the CDK7-CTD kinase, and that
His-G101W is defective in the inhibition of only the CDK4-pRb kinase.
Phenotypes of p16 mutants in inducing cell cycle arrest when
overexpressed.
To assay for the ability of the p16 mutants
to induce cell cycle arrest, expression constructs encoding
wild-type p16 and the mutants R24P, L31R, and G101W were
transiently transfected into the human osteosarcoma cell line U2OS. An
expression construct encoding GFP was cotransfected as a marker to
identify successfully transfected cells. Cells were harvested, and DNA
content as indicated by PI staining intensity was assayed by flow
cytometry, gating on GFP-positive cells in order to restrict analysis
to the transfected-cell population (16). Cell cycle
distribution was calculated by analyzing the histogram profiles using
the ModFit software package (Verity). Overexpression of mutants
L31R and G101W increased cell populations at
G0-G1 phase as well as the wild type (Fig.
6 and Table 1). The results from the
overexpression of the G101W mutant confirm previously published data
(16). The population of cells in the G0-G1 phase of the cell cycle did not
significantly change when an expression construct containing R24P was
transfected (Fig. 6 and Table 1). Western blots indicate that each of
these mutant proteins was overexpressed in transiently cotransfected
cells (Fig. 6). These results suggest that the L31R and G101W mutants are capable of inducing cell cycle arrest whereas the R24P mutant is
not.
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FIG. 6.
Cell cycle analysis of U2OS cells overexpressing
wild-type p16 and the mutants R24P, L31R, and G101W. (a) Expression
constructs containing wild-type p16 and mutants R24P, L31R, and G101W
were transiently cotransfected with a plasmid encoding GFP as a marker.
DNA content histograms of GFP-positive cells were generated by flow
cytometry as described in Materials and Methods. The cell cycle
distribution of the GFP-positive cells was calculated using the ModFit
flow cytometry software analysis package. (b) Vertical axis, percentage
of cells in the G0-G1 population as determined
by flow cytometry analysis. WT, wild type. (c) Just prior to fixation
and cell cycle analysis, approximately 20,000 transfected cells were
reserved and lysed using SDS sample buffer. The lysates were subjected
to an SDS-13.5% polyacrylamide gel, and proteins fractionated in the
gel were analyzed by Western blotting using an antibody against
p16INK4A. Arrowheads,
p16INK4A and an internal control protein.
|
|
Interaction of p16INK4A with CDK7 in
vivo.
Our previous data suggested that recombinant
p16INK4A can form a complex with purified
TFIIH and recombinant CDK7 in vitro (25). To
examine whether p16INK4A associates with CDK7 in
cells, we prepared crude cell lysates and assayed for
p16INK4A-CDK7 complexes by coimmunoprecipitation
(Fig. 7a). Crude lysates prepared from
HeLa cells were incubated with an antibody against CDK7, and the
immunocomplexes were precipitated using protein A-Sepharose beads.
Proteins in the supernatants and protein A-bound precipitates were
probed in parallel on Western blots using an antibody against
p16INK4A. As shown in Fig. 7a,
p16INK4A could be detected in CDK7
immunoprecipitates. The amount of p16INK4A
detected was estimated to represent less than 0.1% of the total p16INK4A in the lysates. When the synthetic
peptide used to generate the CDK7 antibody was added to the
antibody-lysate mixture before immunoprecipitation, the amount of
p16INK4A detected on the Western blots was
significantly less. Similar results were obtained from experiments
using calf thymus extracts (data not shown). These data suggest that
p16INK4A can exist in a complex with CDK7 in
lysates and that these complexes can be specifically recovered by
coimmunoprecipitation with an anti-CDK7 antibody.
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FIG. 7.
Interaction of CDK7 and p16INK4A
in vivo. (a) Coimmunoprecipitation of p16INK4A
and CDK7 from crude HeLa cell lysates. An antibody against CDK7 and an
excess amount of a synthetic peptide used to generate the anti-CDK7
antibody were added to crude HeLa cell lysates as indicated. Protein
A-Sepharose beads were added to recover the immunocomplexes. Following
centrifugation the supernatant (sup) was removed from the beads, which
were then extensively washed. The precipitates (ppt) and the
supernatant were resolved by SDS-polyacrylamide gel electrophoresis.
p16INK4A was detected on Western blots using an
antibody against p16INK4A. Arrowhead,
p16INK4A. (b) Confocal microscopy of HeLa cells
stained with anti-CDK7 plus allophycocyanin secondary antibody (red)
and anti-p16INK4A plus ALEXA 488 secondary
antibody (green). Pixels with both red and green fluorescence appear as
white on the merged image. Pixel dimensions were 147 nm2,
with an approximate depth of field of 1.5 µm.
|
|
To further confirm the interaction between CDK7 and
p16INK4A in cells, confocal microscopy analysis
was performed. The affinity-purified polyclonal rabbit anti-CDK7 was
detected with an allophycocyanin-conjugated antirabbit secondary
antibody, and the protein G-purified monoclonal anti-p16 antibody was
detected with an ALEXA 488-conjugated antimouse secondary antibody. As
shown in Fig. 7b, CDK7 and p16INK4A can be
detected in close proximity within the nuclei of the cells (each pixel
area is 147 nm2, and the depth of field is approximately
1.5 µm). p16INK4A but not CDK7 is also visible
in the cytoplasm of the cells. These results indicate that CDK7 and
p16INK4A are predominantly localized to the same
subcellular compartment and can be detected in close proximity to one
another in the nuclei of HeLa cells.
| |
DISCUSSION |
We have identified a region in the amino terminus of
p16INK4A required for inhibition of CDK7-CTD
kinase activity and have shown that the inhibitory activities of
p16INK4A to the CDK7-CTD kinase and CDK4-pRb
kinase reside in distinct structural domains. We have identified three
p16INK4A mutants that display different
phenotypes in inhibiting CDK7-CTD kinase and CDK4-pRB kinase and in
mediating cell cycle arrest. These mutants are R24P, L31R, and G101W,
and their phenotypes, as summarized in Table 1, are as follows: (i) the
R24P mutant fails to inhibit both CDK7 and CDK4 and does not induce
G1 arrest when overexpressed; (ii) the L31R and G101W
mutants are defective in inhibiting CDK7 and CDK4, respectively, but
both mutants can still induce G1 arrest. These results
suggest that the activities shown by p16INK4A for
the inhibition of both CDK4-pRb kinase and CDK7-CTD kinase may
contribute to the ability of p16INK4A to induce
G1 arrest when overexpressed. CDK7-CTD kinase activity may
therefore contribute to progression through the cell cycle at the
G1-to-S phase boundary.
Regions in p16INK4A involved in the
inhibition of CDK7-CTD kinase and CDK4-pRb kinase.
p16INK4A and p15INK4B have been shown
to inhibit phosphorylation of pRb by CDK4 and are
involved in regulating the G1-to-S phase transition (12, 16, 19, 27). Despite the facts that
p16INK4A and p15INK4B have
significant homology in their primary structures and that both inhibit
phosphorylation of pRb by CDK4 and CDK6, genetic studies suggest that only mutations of p16INK4A
closely correlate with human cancer (15, 16, 19, 20, 22, 31, 38,
39). These data suggest that p16INK4A has a
specific function in human oncogenesis. We have identified a new
biochemical activity associated with p16INK4A,
TFIIH-CTD kinase-inhibitory activity (25). The
present study focused on the structural similarity of
p16INK4A and p15INK4B and compared
the CDK-inhibitory activities of these molecules. p15INK4B
did not inhibit phosphorylation of GST-CTD by
TFIIH and rCAK under conditions where
p16INK4A could effectively inhibit these kinases
(Fig. 2). These results suggest that the CDK7-CTD
kinase-inhibitory activity of p16INK4A
may be specific and unique among the INK4 proteins and may correlate with its tumor suppressor function.
The region of highest homology between
p16INK4A and p15INK4B is located in
the middle portion of p16INK4A. The
amino-terminal regions of p16INK4A and
p15INK4B are not homologous (Fig. 3). Experiments using
recombinant chimeric proteins in which the nonhomologous regions of
p16INK4A and p15INK4B were exchanged
indicate that the amino-terminal region of
p16INK4A is involved in inhibiting
phosphorylation of CTD by CDK7, whereas the homologous
region is involved in inhibiting phosphorylation of pRb
by CDK4 (Fig. 4). These results suggest that there are distinct
boundaries separating the two different kinase-inhibitory activities in
p16INK4A.
X-ray crystal structure studies indicate that
p16INK4A is composed of four ankyrin repeats
(24). The ankyrin repeats in p16INK4A
are thought to form helix-turn-helix structures (33). The
first ankyrin repeat at the amino terminus of
p16INK4A overlaps with the region of nonhomology
between p15INK4B and p16INK4A (Fig.
3). The R24P and L31R mutations reside in this region, and both
proteins were shown to be defective in inhibiting CDK7-CTD kinase (Fig.
5). The helix-turn-helix structure of the first ankyrin repeat may
therefore be involved in inhibiting phosphorylation of
the CTD by CDK7, and the rest of the ankyrin repeats in
p16INK4A may be involved in inhibiting
phosphorylation of pRb by CDK4. The fourth ankyrin
repeat has been suggested to be involved in binding CDK4 and may be
important for inhibiting CDK4 (10). The R24P mutant was
defective in inhibiting CDK4-pRb kinase, although the mutation lies
outside the homologous region suggested to be involved in inhibition of
CDK4-pRb kinase based on experiments using chimeras of
p16INK4A and p15INK4B. It may be that
the mutation alters not only the structure of the nonhomologous
region but also the overall structure of p16INK4A,
including the homologous region. Such structural changes might result in the R24P mutant displaying defective inhibition of both CDK7-CTD kinase and CDK4-pRb kinase.
Whereas His-p16 inhibited CTD phosphorylation by CDK7
by approximately 60 to 70% (Fig. 2) (25), it resulted in
almost complete inhibition of pRb phosphorylation
by CDK4. The inhibition of CDK4-pRb kinase and the inhibition of
CDK7-CTD kinase by p16INK4A were measured under
different conditions. Furthermore, rCAK and TFIIH contain
MAT1, whereas CDK4 has no subunit equivalent to MAT1, precluding
direct comparison of their different inhibitory intensities. The
intensities of these inhibitory activities under physiological
conditions will be addressed in future studies. However, it is possible
that differential inhibition of CDK7-CTD kinase and CDK4-pRb kinase by
p16INK4A could contribute to modulation of cell
cycle regulation.
Phenotypes of p16INK4A mutants R24P, L31R,
and G101W.
It has been suggested that
p16INK4A plays an important role in a signaling
pathway regulating entry into S phase from the G1 phase of
the cell cycle (references 28, 36, and
41 and references therein). Current models have
proposed that transcription factors such as E2F form a complex with pRb
in quiescent cells, repressing transcription from specific target
genes. Phosphorylation of pRb by G1 CDKs causes the
dissociation of this complex, thus allowing activation of transcription
from genes required for entering S phase (36, 41).
p16INK4A inhibits pRb
phosphorylation by G1 CDKs and negatively
regulates cell cycle progression at the G1 phase. A wide
variety of p16INK4A mutations have been
identified from human tumors (15, 16, 19, 20, 22, 31, 38,
39), and it has been suggested that mutations of
p16INK4A closely correlate with human oncogenesis
(39). Many p16INK4A mutants derived
from human tumors have lost G1 CDK-pRb kinase-inhibitory activity. However, in several p16INK4A mutants,
the biochemical phenotypes with respect to G1 CDK-pRb kinase-inhibitory activity do not correlate with the ability to induce
G1 arrest when overexpressed (16, 38). For
example, the G101W mutant has a defect in inhibiting CDK4-pRb kinase;
however, it did not show a defect in inducing G1
arrest (16). The present study identifies a possible
correlation between the phenotypes of p16INK4A
mutants for CDK7-CTD kinase-inhibitory activity and for the induction of G1 arrest, suggesting that not only G1
CDK-pRb kinase-inhibitory activity but also CDK7-CTD
kinase-inhibitory activity might influence cell cycle regulation at the
G1-to-S phase boundary. Based on these results, we propose
that regulation of CDK7-CTD kinase activity may contribute to cell
cycle progression at the G1-to-S phase transition.
Genetic and biochemical studies suggest that
phosphorylation of RNA pol II CTD by
TFIIH regulates transcription in vivo and in vitro
(references 2 to 6, 17, 35, and
40 and references therein). A
hypophosphorylated form of RNA pol II
preferentially forms a preinitiation complex, and the CTD of RNA pol II
engaged in transcriptional elongation is highly
phosphorylated. Our previous study suggested that
p16INK4A can form a complex with TFIIH
and RNA pol II in vitro (25). Immunofluorescence
analysis of HeLa cells showed that p16INK4A is
concentrated predominantly in the nucleus and colocalizes with CDK7 in
double-labeling experiments (Fig. 7). It is possible that
p16INK4A can form a preinitiation complex on a
transcriptional promoter by interacting with TFIIH and RNA
pol II. p16INK4A might then directly regulate
transcription via the inhibition of CTD
phosphorylation. The present study suggests that the
CDK7-CTD kinase-inhibitory activity of p16INK4A
may represent a second mechanism for inducing cell cycle arrest. p16INK4A may not only regulate the cell cycle via
the inhibition of pRb phosphorylation but may also
regulate transcription via the inhibition of CTD
phosphorylation. Repression of transcription by
p16INK4A may contribute to the ability of this
inhibitor to regulate cell cycle progression.
| |
ACKNOWLEDGMENTS |
We are grateful to Hitoshi Matsushime for cDNA constructs
of CDK4, cyclinD, and GST-pRb, to David Morgan for baculovirus
constructs of CDK7, cyclinH, and MAT1, to David Beach for a cDNA
construct of p15INK4B, to Mary Patterson for helpful
discussions and reading the manuscript, and to Cristina Ward for
editing and scientific comments.
This work was supported by research grants from the American Cancer
Society and the American Heart Association, Heartland Affiliate, to
H.S., and by a research grant from the V Foundation to J.K. S.H. was a
Kansas Health Foundation Scholar.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Biochemistry and Molecular Biology, University of Kansas Medical
Center, 3901 Rainbow Blvd., Kansas City, KS 66160-7421. Phone: (913)
588-7033. Fax: (913) 588-7004. E-mail: hserizaw{at}kumc.edu.
Present address: Research and Development Division, Nippon Organon
K.K. 5-90, Miyakojima-ku, Osaka 534-0016, Japan.
Present address: Second Department of Medicine, Kurume University
School of Medicine, Kurume 830, Japan.
| |
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Molecular and Cellular Biology, October 2000, p. 7726-7734, Vol. 20, No. 20
0270-7306/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
