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Molecular and Cellular Biology, July 2000, p. 5310-5320, Vol. 20, No. 14
0270-7306/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Poly(A) Polymerase Phosphorylation Is Dependent on
Novel Interactions with Cyclins
Gareth L.
Bond,
Carol
Prives, and
James L.
Manley*
Department of Biological Sciences, Columbia
University, New York, New York 10027
Received 1 March 2000/Returned for modification 6 April
2000/Accepted 24 April 2000
 |
ABSTRACT |
We have previously shown that poly(A) polymerase (PAP) is
negatively regulated by cyclin B-cdc2 kinase hyperphosphorylation in
the M phase of the cell cycle. Here we show that cyclin B1 binds PAP directly, and we demonstrate further that this interaction is
mediated by a stretch of amino acids in PAP with homology to the cyclin
recognition motif (CRM), a sequence previously shown in several cell
cycle regulators to target specifically G1-phase-type cyclins. We find that PAP interacts with not only G1- but
also G2-type cyclins via the CRM and is a substrate for
phosphorylation by both types of cyclin-cdk pairs. PAP's CRM shows
novel, concentration-dependent effects when introduced as an 8-mer
peptide into binding and kinase assays. While higher concentrations of
PAP's CRM block PAP-cyclin binding and phosphorylation, lower
concentrations induce dramatic stimulation of both activities. Our data
not only support the notion that PAP is directly regulated by
cyclin-dependent kinases throughout the cell cycle but also introduce a
novel type of CRM that functionally interacts with both G1-
and G2-type cyclins in an unexpected way.
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INTRODUCTION |
Almost all eukaryotic mRNAs contain
a string of adenylate residues at their 3' ends. This structure, known
as the poly(A) tail, has been implicated in mRNA localization,
stability, and translation (reviewed in references 41,
52, and 59). The polyadenylation reaction
affects, and is affected by, other steps in mRNA synthesis, such as
transcription, splicing, and capping (e.g., references 11, 12,
29, 44, and 62). Therefore, polyadenylation could constitute a significant point of regulation utilized by the cell to control gene expression (reviewed in reference 4). A growing body of evidence suggests this to be
the case in early development (59), in cell differentiation
(e.g., references 19 and 56) and
in the M phase of the cell cycle (9).
mRNA 3'-end formation is achieved in a two-step reaction:
endonucleolytic cleavage of the pre-mRNA followed by synthesis of the
poly(A) tail. Components of the basal polyadenylation machinery, which
constitute a complex array of protein factors, work together to
catalyze and tightly couple these two reactions (reviewed in references
8, 34, and 58). Poly(A)
polymerase (PAP) is a single subunit enzyme responsible for adding the
adenylate residues onto the cleaved mRNA, and it is also required in
many cases for the cleavage reaction in vitro. Multiple additional,
multi-subunit proteins are involved in 3' end formation:
cleavage-polyadenylation specificity factor (CPSF), cleavage
stimulation factor (CstF), cleavage factors I and II, and RNA
polymerase II. CPSF is required for both steps of the reaction and is
responsible for recognizing the polyadenylation signal AAUAAA.
CPSF binds very efficiently AAUAAA when complexed with
CstF, which is itself required for efficient cleavage in vitro. CstF
also binds RNA specifically to the GU-rich element found in many
polyadenylation sites. The complexes most likely to be directly
involved in the endonucleolytic cleavage of the pre-mRNA are CFI and
CFII. The newest known essential component of 3' processing is RNA
polymerase II, specifically the C-terminal domain of its largest
subunit (CTD). The CTD was shown to be required for the cleavage
reaction in vitro (29), and interactions between the CTD and
CstF and CPSF have been observed (44).
Our laboratory and others have collected data supporting the regulation
of polyadenylation via control of PAP activity. The U1 snRNP A protein
(U1A) is able to repress PAP's polymerase activity via a direct
interaction between U1A bound to sequences in the U1A pre-mRNA 3'
untranslated region and the C terminus of PAP, thereby negatively
autoregulating its own synthesis (22-24). We and others
have been studying the effect of phosphorylation of PAP on its activity
in in vitro and in vivo assays (e.g., references 3,
9, and 64). All known vertebrate PAPs
contain a C-terminal Ser-Thr-rich domain with multiple cyclin-dependent
kinase (cdk) sites. These sites are phosphorylated in vitro and
in vivo by cyclin B-p34cdc2 (10). In M-phase cells,
where cyclin B-p34cdc2 is most active, PAP is hyperphosphorylated and
its activity is repressed (9). Chicken B cells expressing a
PAP with two consensus cdk sites mutated show growth defects compared
to cells expressing similar levels of the wild-type enzyme
(64).
Cyclin B-p34cdc2 is a member of the cdk family, with all members being
heterodimers containing a kinase subunit (the cdk) and a regulatory
subunit (the cyclin). These kinases are important players in regulating
the entry into and progression of the eukaryotic cell cycle (reviewed
in references 32 and 46). As such
their activities are tightly controlled to ensure a proper cell cycle. One of the most well-studied mechanisms of cdk regulation is the requirement of the cyclin binding to the catalytic subunit for its
activation (e.g., references 31, 33, and
40). Binding of the cyclin imparts upon the kinase a
structure conducive to catalysis (33).
In addition to influencing the structure of the catalytic subunit, the
cyclin also apparently imparts upon the cdk much of its substrate
specificity (e.g., references 14, 31, 35, 47, and
48). Initially through analysis of the crystal
structure of cyclin A-cdk2 complexed with the cdk-inhibitory protein
p27 (51), a motif in p27 was derived that was suggested to
be responsible for the interaction of the inhibitor with the cyclin.
This sequence, the cyclin recognition motif (CRM), is now known to be
shared by inhibitors (p21, p27, and p57) and substrates (e.g., E2F-1, p130, p107, and pRB) alike (1, 2, 6, 15, 38, 42, 43, 45, 49, 53,
65). The CRM's interaction with the cyclin relies on contact
with residues in a hydrophobic patch (50, 51, 54), which are
strongly conserved in cyclins A, B, D1, and E, although CRM-dependent
interactions have only been detected with the G1-specific
cyclins, A, D1, and E not with cyclin B1. A cyclin A
mutated in its hydrophobic patch was unable to interact with
CRM-containing proteins and lost its ability to drive cells out of
G1 (54), underlining the importance of
CRM-mediated interactions for the cdk in controlling the progression of
the cell cycle. When the CRM's interaction with the cyclin is
disrupted, decreased phosphorylation of the substrate is frequently
observed (1, 2, 38, 43, 54). Not all cdk substrates contain a CRM, and why some do and others do not is not known.
Here we further investigate PAP's regulation by cdks. We extend our
previous findings that PAP is a target for cdk phosphorylation by
showing that PAP binds directly to cyclins, both in vivo and in vitro.
PAP interacts with both G1- and G2-type cyclins
and is a substrate for phosphorylation by both types of cyclin-cdk pairs. Cyclin binding is mediated by a stretch of amino acids with
similarity to the consensus CRM. An 8-mer peptide spanning PAP's CRM
has novel concentration-dependent effects on binding and
phosphorylation of PAP by cdks. Unexpectedly, lower concentrations of
the 8-mer peptide actually stimulate PAP binding and phosphorylation by
cyclin B-cdc2. Higher concentrations abolish the PAP-cyclin interaction
and, in in vitro kinase reactions, specifically inhibit both PAP's and
pRB's phosphorylation by G2- as well as G1
cdks. With its ability to interact with both G1- and
G2-type cyclins, PAP's CRM allows for the possible
regulation of polyadenylation throughout the cell cycle, and the novel
mechanism by which it interacts with cyclins provides possible insight
into the mechanism of substrate targeting by cyclins.
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MATERIALS AND METHODS |
Coimmunoprecipitation.
Sf9 insect cells were infected with 1 PFU of PAP-expressing per cell and/or 3 PFU of cyclin
B1-expressing recombinant baculoviruses. After 40 h at
27°C, cells were harvested and lysed in 50 mM Tris (pH 8.0)-150 mM
NaCl-0.1% aprotinin-10 mM benzamidine-30 µg of leupeptin per
ml-1 mg of bacitracin per ml-10 mg of 
2-macroglobulin per ml-0.35
mM phenylmethylsulfonyl fluoride for 15 min on ice. Lysates were spun
at 37,000 × g for 15 min at 4°C, and supernatants were collected. Protein G-Sepharose beads (Pharmacia), anti-PAP polyclonal antisera, and supernatants were rocked for 3 h at
4°C. After an extensive washing with 50 mM Tris (pH 7.2)-200 mM
NaCl-0.1% NP-40, samples were subjected to sodium dodecyl
sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) in a 10%
polyacrylamide gel and Western blot analysis. Filters were probed with
a monoclonal cyclin B1 antibody (Santa Cruz).
Far-Western assays.
The modified far-Western assay was
carried out as previously described (37). One microgram of
protein was used for each strip. After renaturation and blocking, 100 ng of purified cyclin B1-cdc2 was incubated with the strips
for 12 h at 4°C. After extensive washing, strips were probed
with the anti-cyclin B1 monoclonal antibody.
GST binding assays.
Glutathione S-transferase
(GST)-cyclin fusion proteins were expressed in recombinant
baculovirus-infected cells. Infection and lysis were carried out as
described earlier (9). GST was expressed in
Escherichia coli (JM101), induced with 1 mM
isopropyl-
-D-thiogalactopyranoside (IPTG) at 37°C for
3 h. Proteins were affinity purified using glutathione-Sepharose
beads (Amersham Pharmacia Biotech AB). After an extensive washing with
NETN (20 mM Tris, pH 8.0; 100 mM NaCl; 0.5% NP-40; 1 mM EDTA),
proteins were eluted with 120 mM reduced glutathione (Sigma) and
dialyzed against 10 mM HEPES (pH 7.5)-5 mM NaCl-0.1 mM EDTA-1 mM
dithiothreitol (DTT)-25% glycerol. Two micrograms of each GST protein
was rebound to glutathione-Sepharose beads. Unbound proteins were
washed away, and in vitro-translated 35S-labeled PAPs (2 µl), purified bacterial PAP (100 ng), or purified hemagglutinin
(HA)-cdk2 (100 ng) were incubated with beads for 2 h at 24°C in
a total volume of 40 µl. For assays with peptides, 45 ng of purified
GST-B1 bound to glutathione-Sepharose beads, various
amounts of peptides, and 1 µl of in vitro-translated
35S-labeled PAP were incubated for 2 h at 24°C in a
total volume of 200 µl. In vitro-translated proteins were produced
using TNT rabbit reticulocyte lysate (Promega). Bovine PAP I (species
II in Fig. 2B) was produced from bovine PAP I cDNA subcloned into a
pET-14b plasmid containing a T7 promoter. The C-terminal truncated PAP
(amino acids [aa] 1 to 434) was in vitro transcribed and translated with the above-mentioned PAP I-pET14b plasmid linearized with DraIII. One N-terminal truncated PAP (309 to 689 aa) was
produced from a template constructed by blunt-end ligation of PAP
I-pET14b, cut with KpnI and NcoI. The second,
N-terminal truncated PAP (539 to 689 aa) was also produced from a
template constructed by blunt-end ligation of PAP I-pET14b but cut with
SpeI and NdeI.
Protein phosphorylation.
A 200-ng portion of purified pRB,
PAP or histone H1 was incubated with 80 ng of purified cdk for 20 min
at 30°C in kinase buffer (25 mM HEPES, pH 7.5; 5 mM
MgCl2; 100 mM ATP; 0.5 µCi of [
-32P]ATP;
0.1 mM DTT) in a total volume of 30 µl. Olomoucine (Calbiochem) and
roscovitine (Calbiochem) were added where indicated at the concentrations shown in the figure legends. Where indicated, peptides were added at the concentrations shown. Peptides were added to reaction
mixtures prior to substrates. The cyclin B1-cdc2
preparations used in the experiments shown in Fig. 7 and in Fig. 8B
varied slightly in their specific activities, resulting in small
differences in phosphorylation at lower concentrations.
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RESULTS |
PAP interacts both in vivo and in vitro with cyclin
B1.
We have been studying how PAP is regulated by
cyclin B-p34cdc2 phosphorylation, which involves multiple
cdk consensus (S/TPXK/R) and nonconsensus (S/TP) sites and the
inhibition of its catalytic activity upon hyperphosphorylation (9,
10). Given that some cdk substrates appear to be targeted by a
direct interaction with the cyclin subunit, it seemed that PAP, with
its multiple phosphorylation sites, would be a good candidate for such
an association. To investigate this possibility, we first sought to
test whether PAP can interact with a cyclin in vivo. To this end, Sf9
insect cells were coinfected with recombinant baculoviruses expressing
bovine PAP I and human cyclin B1. (PAP I and II arise from
alternatively spliced mRNAs [63]. They behave
indistinguishably in their interaction with cdk-cyclins and have been
used interchangeably in the experiments described here.) Total cell
extracts were prepared and subjected to immunoprecipitation with a
rabbit polyclonal anti-PAP antibody, and the immunocomplex was analyzed
by Western blotting using an anti-cyclin B1 monoclonal
antibody (see Materials and Methods). Figure
1A shows that cyclin B was present in the
anti-PAP immunocomplex (lane 1) and that this was dependent on
coexpression of PAP (lane 2). Lanes 3 and 4 show a Western blot with
anti-cyclin B1 antibodies of the lysates prior to
immunoprecipitation, which indicates that a significant fraction of the
cyclin was associated with PAP. We have been unable to
coimmunoprecipitate PAP I and cyclin B1 from uninfected
cells. However, this is, to our knowledge, consistent with all other
studies examining cyclin-substrate associations and suggests that the
interactions are relatively weak and/or transient.
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FIG. 1.
PAP binds cyclin B1 in vivo and in vitro.
(A) PAP associates with cyclin B1 in vivo.
Coimmunoprecipitation and Western blot analysis of Sf9 insect cell
extracts made from cells infected with recombinant baculoviruses
expressing either PAP plus cyclin B1 or cyclin
B1 alone. Lysates were immunoprecipitated with a polyclonal
antibody raised against PAP. The immunoprecipitates (lanes 1 and 2) and
10% of the cell extracts used (lanes 3 and 4) were subjected to
SDS-PAGE and subsequent Western blot analysis using a monoclonal
antibody against human cyclin B1. The position of cyclin
B1 is indicated. (B) PAP binds cyclin B1-cdc2
directly. Purified PAP II (1 µg; strips 1 and 2), purified p53 (1 µg; strip 3), and bacterial whole-cell extract expressing human
cyclin B1 (strip 4) were first immobilized on
nitrocellulose. Following renaturation by serial dilution with
guanidine-HCl, strips 1, 3, and 4 were incubated with purified cyclin
B1-cdc2 (100 ng). After washing, cyclin B1 was
detected by immunoreactivity to the anti-cyclin B1
antibody. An arrow on the left indicates the position of PAP II. An
arrow on the right indicates the position of cyclin B1.
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To characterize the PAP-cyclin B
1 interaction further,
baculovirus-produced and purified histidine-tagged PAP II and human
cyclin B
1-flu epitope-tagged p34
cdc2 proteins
were used in a modified far-Western protein-protein
interaction assay
(Fig.
1B). Purified PAP II (1 µg) was immobilized
on nitrocellulose
by Western blotting and renatured by serial
dilution with
guanidine-HCl, and strips were incubated with purified
cyclin
B
1-p34
cdc2 (100 ng). After extensive washing
(see Materials and Methods),
the presence of cyclin B
1
bound to PAP II was determined by its
immunoreactivity to the
anti-cyclin B
1 antibody (strip 1). The
absence of
cross-reactivity of PAP II with the anti-cyclin B
1 antibody
was established by incubating a strip of PAP II under
the above
conditions except for excluding incubation with cyclin
B
1
(strip 2). A strip containing p53 instead of PAP was used to
demonstrate the specificity of the interaction (strip 3). Strip
4 contained cyclin B
1. The results of this experiment
indicate
the existence of a direct interaction between PAP and cyclin
B
1-p34
cdc2.
PAP interacts with cyclin B1 via sequences N-terminal
of the Ser-Thr-rich regulatory region.
To address the role of
p34cdc2, if any, in the interaction of PAP with cyclin
B1 and to extend the above results to soluble proteins, a
GST pull-down assay was employed. A GST-B1 fusion protein
was purified from recombinant baculovirus-infected Sf9 cells, rebound to a glutathione-agarose matrix, and incubated with in vitro-translated 35S-labeled PAP I. After extensive washing and elution, the
elute was subjected to SDS-PAGE and the presence of PAP I was
determined by autoradiography. In Fig.
2A, PAP I was detected in the eluate of
the cyclin B1 matrix (lane 1) but not in that of a GST
control (lane 2), confirming the interaction of cyclin B1
with PAP.
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FIG. 2.
PAP binds cyclin B1 via residues N-terminal
of its Ser-Thr-rich regulatory region. GST-cyclin B1
pull-down assays were performed using purified GST or GST fusion
proteins bound to a glutathione matrix and in vitro-translated
35S-labeled PAPs (2 µl). (A) Autoradiogram of the eluates
of either GST-cyclin B1 (lane 1) or GST (lane 2)
glutathione matrices and 10% of the input PAP I (lane 3). An arrow on
the left indicates the position of PAP I. (B) Schematic representation
of PAP species used in the assay depicted in panel C and summary of
results. The black region indicates the Ser-Thr-rich region, and the
white bars indicate the sites for cdk phosphorylation. The bipartite
nuclear localization signal sequences are boxed in gray. A plus sign
indicates observed binding, two plus signs indicate strongest binding,
and a minus sign indicates no binding was observed. (C) Autoradiogram
of 35S-labeled PAPs bound to either GST-cyclin
B1 (lanes 1, 3, 5, and 7) or GST (lanes 2, 4, 6, and 8).
Lanes 9 to 12 are 10% of the input PAPs. The roman numerals indicate
the PAP species used as graphically represented in panel C.
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The same assay was next used to determine whether the Ser-Thr-rich C
terminus of PAP, which contains the seven known sites
for cyclin
B
1-p34
cdc2 phosphorylation (
10),
also contains the residues responsible
for associating with cyclin
B
1. (Although, perhaps arguing against
this, we have
observed no effect of the phosphorylation status
of PAP on the
enzyme's ability to bind cyclin B
1; results not
shown).
For this experiment, full-length in vitro-translated
[
35S]methionine-labeled PAP I was again incubated with
GST-cyclin
B
1 bound to glutathione agarose beads, but this
time alongside
of both N-terminal and C-terminal truncated PAPs (Fig.
2B). Both
the wild-type and N-terminal truncated species contain the
Ser-Thr-rich
region, the last comprising only this region (species II,
III,
and IV in panel B), but the C-terminal truncated PAP (species
I in
panel B) contains only residues N terminal of the regulatory
region. As
seen in Fig.
2C, lanes 1, 3, 5, and 7, only those species
with residues
N terminal to the regulatory region retained the
ability to bind cyclin
B
1, proving that the Ser-Thr-rich region
is neither
necessary nor sufficient for PAP's association with
cyclin
B
1, whereas sequences N terminal to this region, between
residues 309 and 434, are sufficient. Preliminary data (not shown)
suggest the possibility of a weak, secondary cyclin binding site
N-terminal of residue 309, although this has not been studied
further.
PAP contains a novel cyclin recognition motif.
Inspection of
the PAP sequence revealed that it contains a stretch of conserved amino
acids with similarity to the consensus CRM, situated just N terminal of
the Ser-Thr-rich regulatory region (Fig.
3). Although other CRM-containing cdk
substrates analyzed to date do not appear to interact with cyclin
B1, B-type cyclins do contain the residues in other cyclins
necessary to contact the CRM (2, 50, 54). The interaction
between PAP and GST-cyclin B1 is also resistant to high
salt concentrations (data not shown), which could suggest a hydrophobic
association, another trait of a CRM-mediated interaction (50,
54).
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FIG. 3.
PAP contains a CRM. A schematic representation of PAP is
shown at the top. The cyclin recognition motif is boxed and striped,
and the Ser-Thr-rich regulatory region is boxed in black, with white
bars representing the cdk sites and gray bars representing the nuclear
localization sequences. An alignment of CRMs with the highly conserved
arginine and leucine residues highlighted is shown below. The CRM
consensus contains the nearly invariant arginine and leucine residues
and, in lowercase, the residues found most frequently at the other
positions.
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To test the functional significance of the putative PAP CRM, a series
of experiments was carried out using a synthetic peptide
spanning these
eight residues of PAP (Fig.
3). These experiments
were based on studies
of the p21 family of cdk inhibitors and
of cdk substrates, including
the transcription factor E2F-1, the
retinoblastoma protein (pRB), and
the related protein p107 (
1,
2). We first took advantage of
the finding that phosphorylation
of pRB by cyclin A-cdk2, cyclin
E-cdk2, and cyclin D
1-cdk4 can
be inhibited by the addition
of increasing amounts of CRM-containing
peptides (from p21, E2F-1, or
pRB) to in vitro kinase assays and
tested whether PAP's potential
CRM-containing peptide could also
inhibit pRB phosphorylation.
Baculovirus-produced and purified
flu-tagged pRB and human cyclin
A-flu-tagged cdk2 were incubated
under kinase conditions in the
presence of [
-
32P]ATP and analyzed by SDS-PAGE and
subsequent autoradiography.
As seen in Fig.
4A, PAP's CRM effectively inhibited pRB
phosphorylation
by cyclin A-cdk2 (lanes 2 and 3). The fact that pRB but
not cyclin
A phosphorylation (which appears to be a CRM-independent
substrate
[
54]) was inhibited in the same reaction
mixture provided an
internal control for the specificity of the
inhibition. In order
to address the sequence specificity of this
effect, a peptide
with PAP's CRM scrambled was also tested, and it
showed no effect
on pRB phosphorylation (lanes 4 and 5). Similar
results were obtained
with cyclin E-cdk2 (data not shown). These
results suggest that
eight residues of PAP can act as a CRM,
functionally interacting
with cyclins A and E.
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FIG. 4.
PAP contains a functional CRM. Inhibition of cdk
phosphorylation of pRB by an 8-mer PAP-derived peptide. (A) Purified
pRB and cyclin A-cdk2 were incubated under kinase conditions in the
presence of [-32P]ATP and two concentrations (9 and 18 µM) of either an 8-mer PAP CRM-derived peptide (SKIRILVG) (lanes 2 and 3), an 8-mer peptide of scrambled sequence (LRSGIKVI)
(lanes 4 and 5), or no peptide (lane 1). Phosphorylated proteins were
resolved by SDS-PAGE and detected by autoradiography. Arrows on the
left indicate the positions of pRB and cyclin A. (B) Purified pRB and
cyclin B1-cdc2 were incubated under kinase conditions in
the presence of [-32P]ATP and the 8-mer PAP
CRM-derived peptide (18 µM) (lane 2), the 8-mer peptide of scrambled
sequence (18 µM) (lane 3), or no peptide (lane 1). Arrows on the left
indicate the positions of pRB and cyclin B1.
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Our data has shown that PAP interacts directly with cyclin
B
1. We therefore tested the ability of PAP's CRM to
interact functionally
with cyclin B
1 by testing the effects
of the 8-mer PAP peptide
in the pRB phosphorylation assay. Strikingly,
given the inactivity
of other CRM's on cyclin B
1-cdc2
phosphorylation (
2), PAP's
CRM also strongly and
specifically inhibited phosphorylation of
pRB by cyclin
B
1-cdc2 (Fig.
4B, compare lanes 1 and 3 with lane
2). As
observed above with cyclin A, cyclin B
1 autophosphorylation
was not affected. Together, these results suggest that PAP contains
a
novel CRM-like sequence capable of functionally interacting
with both
G
1 and G
2 cyclins.
PAP interacts with and is phosphorylated by cyclin
A-cdk2.
In order to determine whether the inhibition of cyclin
A-cdk2 phosphorylation by the PAP peptide reflected an interaction between cyclin A and PAP, we investigated the ability of full-length PAP to bind cyclin A. To this end, a GST binding assay similar to that
used in Fig. 2 was employed. In vitro-translated
[35S]methionine-labeled PAP I was incubated with
glutathione-agarose beads containing GST-cyclin B1,
GST-cyclin A, or GST alone. As seen on the autoradiogram depicted in
Fig. 5A, similar amounts of PAP I were
present in the eluates of both cyclin B1 (lane 1) and
cyclin A (lane 2) matrices but not in that of the GST control (lane 3),
providing evidence for an interaction between cyclin A and PAP. (Figure
5B shows a Coomassie blue-stained gel of the purified GST-cyclin fusion
proteins used.)
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FIG. 5.
PAP binds cyclin A and is phosphorylated by cyclin
A-cdk2. (A) Autoradiogram of in vitro-translated
35S-labeled PAP bound to GST-cyclin B1 (lane
1), GST-cyclin A (lane 2), or GST (lane 3) glutathione matrices and
10% of the input PAP I (lane 4). An arrow on the left indicates the
position of PAP. (B) Coomassie blue-stained SDS-PAGE of purified
GST-cyclin A (lane 2) and GST-cyclin B1 (lane 3) fusion
proteins used in the binding reactions. (C) Autoradiogram of
phosphorylated PAP after incubation with cyclin A-cdk2. Purified PAP
and cyclin A-cdk2 were incubated under kinase conditions in the
presence of [-32P]ATP (lane 1). Specific inhibitors of
cdks, olomoucine (14 and 70 µM) (lanes 2 and 3) and roscovitine (7 and 14 µM) (lanes 4 and 5), were added to establish the specificity
of the reaction. Phosphorylated proteins were resolved by SDS-PAGE and
detected by autoradiography. An arrow on the left indicates the
position of PAP.
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We next tested whether PAP could bind cyclin A, as well as serve as a
substrate for cyclin A-cdk2 phosphorylation. Phosphorylation
was
examined in an in vitro kinase assay using baculovirus-produced
and
purified human cyclin A-flu-tagged cdk2 and bacterium-produced
and
purified His-tagged PAP I. After incubation under kinase conditions
in
the presence of [
-
32P]ATP, the reaction mixture was
analyzed by SDS-PAGE and subsequent
autoradiography. As seen in Fig.
5C, lane 1,
32P was efficiently incorporated into PAP. The
specificity of cdk
phosphorylation was controlled for by the addition
of two specific
cdk inhibitors, olomoucine and roscovitine, into the
kinase reactions.
As seen in lanes 2 to 5, incorporation of
32P into PAP was inhibited by both compounds. Taken
together, these
results demonstrate that PAP can both bind cyclin A and
serve
as a substrate for phosphorylation by cyclin A-cdk2. This is
consistent
with the fact that PAP is phosphorylated throughout the cell
cycle,
not only in the M phase (
9).
Novel, concentration-dependent effects of PAP's CRM.
The data
presented above show that PAP can interact with both cyclin
B1 and cyclin A and, at least in the case of cyclin
B1, that these interactions are dependent on residues N
terminal of the Ser-Thr-rich PAP regulatory region which encompass the
PAP CRM. We next wished to examine the CRM dependence of PAP's
interactions with these cdks, and we therefore undertook a series of
binding and kinase assays using PAP as a substrate.
Figure
6A and B show autoradiograms of
GST pull-down assays using GST-cyclin B
1 and in
vitro-translated
35S-labeled PAP I. These experiments were
carried out like those
in Fig.
2 and
5, except that increasing amounts
of the 8-mer PAP
CRM peptide were added to the glutathione-GST-cyclin
B
1 matrix
prior to PAP I (see Materials and Methods).
Binding studies examining
other CRM-dependent interactions with cyclins
have demonstrated
that addition of increasing amounts of CRM-containing
peptides
disrupts binding of the CRM-containing protein and the cyclin
(e.g., references
1 and
2). Our
experiments with PAP's CRM
also illustrate a disruption of the
interaction between PAP and
cyclin B
1 (at peptide
concentrations of 36 and 72 µM; compare
lanes 4 and 5 with lanes 2 and 3 of Fig.
6A). Unexpectedly, however,
at lower concentrations of
peptide (9 and 18 µM), we observed
a dramatic stimulation of binding.
Lanes 2 and 3, compared to
lane 1, illustrate the striking enhancement
of PAP I's binding
to cyclin B
1: up to 50 to 100% bound
at the lower concentrations
of peptide (compare to lane 6, which
displays 100% of the amount
of PAP I used for each reaction). Figure
6B illustrates more thoroughly
the dose-dependent enhancement of PAP
I-GST-cyclin B
1 binding
by the CRM (2.25, 4.5, 9, and 18 µM; compare lane 1 with lanes
2 to 5). As a control for sequence
specificity, an 8-mer peptide
of scrambled CRM sequence was used (lanes
6 to 9). (Note that
these experiments were done with a low
concentration of GST-cyclin
B
1, which does not allow
significant PAP-cyclin B
1 interaction
without addition of
the lower concentrations of CRM peptide [Fig.
6A to C, lanes 1].)
These results together suggest a unique, CRM-dependent
interaction of
PAP with cyclin B
1.
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|
FIG. 6.
PAP's CRM both activates and represses PAP binding to
cyclin B1. The effect of the 8-mer PAP CRM-derived peptide
in GST-cyclin-PAP pull-down assays was tested. (A) GST-cyclin
B1 glutathione matrices were incubated with in
vitro-translated 35S-labeled PAP (1 µl) in the absence
(lane 1) or presence of increasing amounts of PAP's CRM peptide (9, 18, 36, and 72 µM; lanes 2, 3, 4, and 5, respectively). Samples were
washed, and bound proteins were analyzed by SDS-10% PAGE and
autoradiography. An arrow on the left indicates the position of PAP. A
total of 100% of the 35S-labeled PAP used in each reaction
is found in lane 6. (B) Concentration dependence of the PAP CRM
stimulatory effect. Lower concentrations of PAP's CRM peptide were
used in binding assays similar to those in panel A (2.25, 4.5, 9, and
18 µM; lanes 2, 3, 4, and 5, respectively), as well as identical
amounts of the 8-mer peptide of scrambled sequence (lanes 6, 7, 8, and
9). (C) CRM enhancement of PAP-cyclin B1 binding reflects a
direct interaction. GST-cyclin B1 glutathione matrices were
incubated with purified bacterial PAP in the presence of increasing
amounts (2, 8.6, and 17 µM) of either PAP's CRM (lanes 3, 4, and 5),
p21's CRM (lanes 6, 7, and 8), or no peptide (lane 1). Samples were
subjected to SDS-PAGE and subsequent Western blot analysis using a PAP
polyclonal antibody. (D) PAP's CRM can enhance cyclin-cdk association.
GST-cyclin D1 glutathione matrices were incubated with
purified HA-tagged cdk2 in the presence of increasing amounts (9 and 18 µM) of either PAP's CRM (lanes 3 and 4), a control peptide (lanes 5 and 6), or no peptide (lane 2). The presence of cdk2 in the eluates was
detected by Western blot analysis using a monoclonal antibody against
the HA epitope. Lane 1 contains the amount of HA-tagged cdk2 used.
|
|
To determine whether the CRM-mediated enhancement of the PAP-cyclin
association reflects a direct interaction between these
two molecules,
we changed the sources of PAP I. Bacterium-produced,
purified
His-tagged PAP I (100 ng) was incubated with the GST-cyclin
B
1 (1 µg) glutathione matrix in the presence of the lower
concentrations
of PAP's CRM-containing peptide that stimulated the
binding seen
in Fig.
6A. After extensive washing and elution, the
eluate was
subjected to SDS-PAGE and Western blotting with an anti-PAP
polyclonal
antibody. As seen in Fig.
6C, lanes 3 to 5, compared to lane
2,
addition of the peptide strongly stimulated the association of
PAP
with cyclin B
1 (2, 8.6, and 17 µM). Again, nearly 100%
of
the input PAP bound GST-cyclin B
1 at the highest
concentration.
As a control for specificity, an 8-mer peptide spanning
p21's
CRM was used. This peptide was chosen because it has been
previously
reported not to functionally associate with cyclin
B
1 (
2).
As seen in lanes 6 to 8, p21's CRM had
no effect on PAP-cyclin
B
1 binding. (The apparent absence
of PAP in lane 2 is due to the
exposure time of the blot, which was
designed to highlight the
dose-dependent stimulation of PAP-cyclin
binding by the peptide.)
Together, these results support a mechanism by
which the CRM peptide
directly stimulates the PAP-cyclin B
1
interaction at low peptide
concentrations but subsequently inhibits the
interaction at higher
peptide concentrations. (Note that the abrupt
switch from stimulation
to inhibition [e.g., Fig.
6A, lanes 3 and 4]
is highly reproducible.)
A possible explanation for these results is
discussed
below.
Although there have been no previous reports suggesting that a CRM
peptide could enhance cyclin-substrate interactions, Adams
et al.
(
2) reported that CRM peptides from p21 or E2F increased
cyclin-cdk association. To determine if PAP's CRM could also increase
cyclin-cdk association, we used a binding assay with GST-cyclin
D
1 and baculovirus-produced and purified human flu-tagged
cdk2.
Cyclin D
1's binding to cdk2 was assayed for because
of its documented
weak affinity (
39). Binding reactions were
performed as described
above, and the eluates were analyzed for the
presence of cdk2
by SDS-PAGE and subsequent Western blotting using an
anti-flu
antibody. As shown in Fig.
6C, the prior addition of PAP's
CRM
peptide (9 and 18 µM) into the binding reaction significantly
increased the presence of cdk2 in the eluate (compare lanes 2
to 4),
while addition of a control peptide was without significant
effect
(lanes 5 and 6). These results establish another similarity
between
PAP's CRM and other characterized CRMs, namely, the ability
to
stimulate the association of a cyclin and a cdk. Whether these
other
CRMs might also enhance cyclin-substrate binding, under
appropriate
conditions, is
unknown.
PAP phosphorylation is also first enhanced and then inhibited by
the CRM peptide.
We lastly wished to test the CRM dependence of
PAP phosphorylation, not only by cyclin B1-cdc2 but also by
a G1-specific cyclin-cdk, cyclin A-cdk2. We utilized kinase
assays similar to those shown in Fig. 4 but with bacterium-produced and
purified His-tagged PAP I instead of pRB. PAP I was first incubated
with baculovirus-produced and purified cyclin B1-flu-tagged
cdc2 under kinase conditions in the presence of
[-32P]ATP and analyzed by SDS-PAGE and subsequent
autoradiography. As seen in Fig. 7A, the
dramatic stimulation of PAP-cyclin B1 binding seen upon
addition of low concentrations of CRM is mirrored in a similar
stimulation of PAP I phosphorylation: prior addition of PAP's
CRM-containing peptide (4.3 to 8.7 µM) led to a dose-dependent increase of phosphorylation by cyclin B1-cdc2 (compare lane
1 with lanes 2 to 7), while addition of the scrambled sequence peptide had no significant effect (lanes 8 to 12). This CRM stimulation of
cyclin B1-cdc2 phosphorylation seems to be specific for
PAP, since parallel experiments using either the CRM-containing
substrate pRB (Fig. 7B) or the CRM-independent histone H1 (Fig. 7C)
showed either only inhibition or no effect, respectively. Consistent with the observed inhibition of cyclin B1-PAP binding,
addition of higher concentrations of PAP's CRM-containing peptide (5.8 to 22.5 µM) led to a dose-dependent inhibition of PAP phosphorylation by cyclin B1-cdc2, after an initial stimulation (Fig.
8A, compare lane 1 with lanes 2 to 5).
(Note that in lane 2 stimulation of PAP's phosphorylation upon
addition of 5.8 µM CRM was observed not only by incorporation of
32P but by the shift in mobility, as indicated by the
arrows to the left in Fig. 8A.)
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FIG. 7.
Phosphorylation of PAP by cyclin B1-cdc2 is
CRM enhanced. (A) Lower concentrations of CRM stimulate cyclin
B1-cdc2 phosphorylation of PAP. Purified PAP and cyclin
B1-cdc2 were incubated under kinase conditions in the
presence of [-32P]ATP and increasing concentrations
(4.3, 5.2, 6.1, 7, 7.8, and 8.7 µM) of either PAP's CRM (lanes 2 to
7) or an 8-mer peptide of scrambled sequence (lanes 8 to 12) or else
they were incubated with no peptide (lane 1). Phosphorylated proteins
were resolved by SDS-PAGE and detected by autoradiography. An arrow on
the left indicates the position of PAP. (B) Equivalent concentrations
of CRM have either no effect or an inhibitory effect on pRB's
phosphorylation by cyclin B1-cdc2. Kinase reactions were
carried out as described above. Lanes 2 to 7 contained increasing
amounts (4.3, 5.2, 6.1, 7, 7.8, and 8.7 µM) of PAP's CRM, and lanes
8 to 11 contained increasing amounts (4.3, 6.1, 7.8, and 8.7 µM) of
the scrambled sequence peptide. An arrow on the left indicates the
position of pRB. (C) No CRM peptide effect is observed on
phosphorylation of histone H1 by cyclin B1-cdc2. As above,
the same concentrations of either the CRM 8mer (lanes 2 to 7) or the
scrambled sequence 8-mer (lanes 8 to 12) were added to the kinase
assays. An arrow on the left indicates the position of histone H1.
|
|
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FIG. 8.
Phosphorylation of PAP by cdks is CRM dependent. (A)
Higher concentrations of CRM specifically inhibit cyclin
B1-cdc2 phosphorylation of PAP. Kinase reactions were
carried out as described in Fig. 7. Samples in lanes 1 to 5 contained
increasing amounts of CRM peptide (0, 5.8, 11.6, 17.3, and 22.5 µM).
Arrows to the left indicate the positions of PAP and cyclin
B1. (B) Phosphorylation of PAP by cyclin A-cdk2 is CRM
dependent. Inhibition of cdk activity toward PAP by either by PAP's
CRM or p21's CRM was tested. Purified PAP and cyclin A-cdk2 were
incubated under kinase conditions in the presence of
[-32P]ATP (lane 1). Kinase reactions contained 23 µM
concentrations of either PAP's CRM (lane 2), p21's CRM (lane 3), or
no peptide (lane 1). Arrows to the left indicate the positions of PAP
and cyclin A.
|
|
To test the CRM dependence of PAP phosphorylation by cyclin A-cdk2, a
concentration of the PAP (Fig.
8B, lane 2) or p21 (lane
3)
CRM-containing peptide that inhibited PAP phosphorylation by
cyclin
B
1-cdc2 (25 µM) was added to kinase reactions containing
PAP and baculovirus-produced and purified cyclin A-flu-tagged
cdk2. As
shown in Fig.
8B, lanes 1 and 2, PAP phosphorylation
was strongly
inhibited. In keeping with the known response of
cyclin A-cdk2 to p21,
the p21 CRM also strongly inhibited PAP
phosphorylation by this
cyclin-cdk pair (Fig.
8B, lane 3). These
results establish the
CRM-dependent nature of PAP phosphorylation
by both cyclin
B
1-cdc2 and cyclin A-cdk2 and provide further evidence
that
PAP's CRM is exceptional in its ability to interact with
cyclin
B
1.
| |
DISCUSSION |
One role of cyclin recognition motifs is to target CRM-containing
proteins for cdk phosphorylation (e.g., reference
54). The data in this report support a mechanism
whereby the complex phosphorylation status of PAP is, at least in part,
CRM mediated. We previously reported that PAP is phosphorylated on
multiple sites (9). In bovine PAP, these sites consist of
three consensus sites (T/SPXK/R) and at least four nonconsensus sites
(S/TP), and phosphorylation on all sites appears to be required for
inactivation of PAP activity. Complete phosphorylation of the
nonconsensus sites in vitro requires a 10-fold-higher concentration of
kinase than is required to phosphorylate the consensus sites
(10). By binding to an active cyclin B1-cdc2,
the CRM can help create a high local concentration of kinase, leading
to hyperphosphorylation and subsequent inactivation of PAP in late M
phase. The CRM also likely helps to maintain normal levels of PAP
phosphorylation throughout the cell cycle.
As mentioned in the introduction, polyadenylation seems to be regulated
not only during M phase but also as cells enter S phase. Cyclin
B1-p34cdc2 is most active in M phase of the
cell cycle, whereas cdk-cyclin pairs such as cyclin A-cdk2 and cyclin
E-cdk2 are more active during the transition into, and in, S phase
(e.g., references 32 and 46). If
the cell cycle machinery also regulates polyadenylation in S phase via
cdk phosphorylation, utilization of PAP's CRM likely contributes to
targeting the G1-phase cyclin-cdks. As the data above
illustrate, PAP's CRM functions to facilitate not only the association
of PAP with G1 and G2 cyclins but also the
phosphorylation by both types of cdks. This suggests the potential for
regulation of PAP and polyadenylation by cdks in the G1, S,
and G2 phases of the cell cycle, possibly contributing to
the well-documented increase of polyadenylation activity observed upon
entry into S phase (5, 7, 20, 28, 30). PAP is phosphorylated on only a subset of cdk sites throughout the cell cycle, and it is not
yet known how or if this affects activity.
Much of what we know about CRMs and how they interact with cyclins has
come from the crystal structure of a fragment of p27kip1
bound to a fragment of cyclin A-cdk2 (51). This structure
shows p27's CRM to be part of a rigid alpha-helical coil, tucked into a groove formed by cyclin A's cyclin box. The major contacts are with
residues conserved in the A-, B-, D-, and E-type cyclins (the so-called
MRAILVDW motif; reviewed in reference 50). While many examples of A-, E-, and D-type cyclins interacting with CRMs have
been reported (e.g., references 1, 2, 6, 15, 38, 42, 43, 45,
49, 53, and 65), there has been no
evidence of cyclin B-CRM interactions, and it has in fact been shown in one case that cyclin B does not bind to the E2F-1 CRM (2). Here we have provided evidence that B-type cyclins can indeed interact
with a CRM. Moreover, since the PAP CRM can interact with both B- and
G1-type cyclins, we suggest that PAP CRM typifies a novel,
universal CRM.
When comparing the core residues of multiple CRMs (Fig. 3), the
conservation of the +4 arginine and +6 leucine residues is striking.
These residues are responsible for multiple contacts with the cyclin,
based on the above-mentioned crystal structure (51). The
surrounding residues, however, do not form as obvious a pattern. When
comparing PAP's CRM to those listed in Fig. 3, it is apparent that the
PAP CRM contains more hydrophobic residues. The groove in cyclin A
shown to contact the CRM is part of a hydrophobic patch present in all
cyclins, containing the above-mentioned MRAILVDW motif (50, 51,
54). When several hydrophobic residues in cyclin A were mutated
to alanines, interactions with CRMs were disrupted (54). We
therefore propose that the greater hydrophobicity of PAP's CRM
contributes to its ability to interact with both G1- and
G2-type cyclins.
By studying the structure of the cyclin box, it has been proposed that
two CRMs can bind one cyclin molecule (50). In fact, multiple molecules of p21 and p57 (both CRM-containing proteins) have
been shown to complex with one cyclin-cdk heterodimer (27, 39,
61). The strong initial stimulation of PAP binding to cyclin
B1 by the CRM peptide can be explained as cooperative
binding of two CRM-containing molecules, whereby binding of the first (the CRM peptide alone) leads to enhanced binding of the second (PAP).
In the case of p21, multiple molecules binding to a cyclin-cdk complex
has been implicated in the ability of p21 to function as a cdk
inhibitor (25, 26, 61). In the case of PAP, we propose that
this property would provide for a rapid response mechanism to sense the
end of M phase.
M phase is characterized by the stimulation, rise, and subsequent loss
of cyclin B1-cdc2 kinase activity, which is mirrored in the
rise and fall of the cyclin B1 subunit (reviewed in
reference 36). As mentioned above, the inactivation
of PAP through hyperphosphorylation is restricted to the late M phase
(10). Cooperative binding of two PAP molecules to cyclin
B1, via their CRM's, whereby binding of the first strongly
stimulates binding of a second, could allow for rapid regulation by
hyperphosphorylation of PAP's activity in late M phase. PAP would be
extremely sensitive to a rise in cyclin B1-cdc2 levels,
allowing for maintenance of an active PAP in M phase until a threshold
level of cyclin B1-cdc2 is reached. A rapid association
with cyclin B1-cdc2 would then occur, driving subsequent
hyperphosphorylation and inactivation of PAP in late M phase. An
extension of this model is that the PAP-cyclin B1-cdc2 complex is activated for binding and phosphorylating other substrates containing a PAP-like CRM. A cooperative interaction, involving an
activated CRM-cyclin B1-cdc2 complex, also offers an
explanation for the observed precipitous inhibition of PAP binding at
elevated CRM peptide concentrations, such that the excess peptide is
efficiently bound to the second site, outcompeting the limiting
concentration of PAP.
As mentioned in the introduction, the most well-studied mechanism of
cdk regulation is cyclin-cdk binding. A number of mechanisms have been
shown to influence this interaction. For example, threonine phosphorylation of the cdk subunit has been shown in some cases to
stabilize cyclin-cdk binding (13). Cyclin H-cdk7 utilizes the assembly factor MAT-1 to promote an active cyclin-cdk complex (17, 57). Although MAT-1 does not contain a recognizable
CRM, it behaves in a manner similar to PAP's CRM. The C terminus of p27 can also serve as a stabilizing factor for the cyclin
B1-cdc2 interaction (18). Interestingly, in the
past few years data have been collected on the ability of
CRM-containing proteins to serve as assembly and stabilization factors
for the association of multiple cyclins and their respective cdks
(e.g., references 27, 39, 48, 60, and
61). In fact, Adams et al. (2) were able
to stimulate cyclin A's-cdk2 binding with the addition of just the CRM
from p21 (as well as from E2F-1), thus providing evidence that p21's
ability to function as a cyclin-cdk assembly factor lies in its CRM. As
to the mechanism, it was speculated that CRM binding to cyclin A
induces an allosteric change, thereby promoting complex assembly
(2). In this report we provide evidence that PAP's CRM can
also stimulate cyclin-cdk association, thereby supporting the
generality of this phenomena, and extending it to G2
cyclin-cdk complexes. We propose that CRM-containing proteins provide
another regulatory mechanism for cdk activity, ensuring cdk activity at
the proper substrates and subcellular localization to allow for proper
cell cycle progression.
Early studies of polyadenylation activity during the mammalian cell
cycle revealed an increase as cells entered S phase (5, 7, 20, 28,
30) and a decrease during M phase (16, 55). The
hyperphosphorylation and inactivation of PAP in M-phase cells (9,
10) coincides with the observed decrease in both polyadenylation and general gene expression during M phase (21). The data
presented here both provide a mechanistic underpinning for the
regulation of PAP by cyclin B-p34cdc2, in which the PAP CRM
plays an important, and complex, role in promoting phosphorylation, and
also opens up the possibility of regulation of polyadenylation during
other phases of the cell cycle, when cdks other than cyclin
B-p34cdc2 are active. Interestingly, all CRM-containing
proteins examined to date play active roles in regulating the cell
cycle. It is tempting to speculate that PAP also plays such a role and
that CRM-mediated phosphorylation of PAP helps modulate
polyadenylation, and hence gene expression, throughout the cell cycle.
| |
ACKNOWLEDGMENTS |
We thank B. Dynlacht for the bacluloviruses expressing the
GST-cyclins, W. Zhao for the vector expressing PAP I, D. F. Colgan for the baculovirus expressing PAP I, K. G. K. Murthy for the bacterial-purified PAP I, and E. Freulich for expert help with baculoviruses. We thank C. Cain, D. F. Colgan, E. Freulich, C. Gaiddon, F. Kleiman, K. G. K. Murthy, L. Ko, Y. Takagaki, and N. Baptiste for helpful discussions.
This work was supported by grants from the NIH to C.P. and J.L.M.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Biological Sciences, Columbia University, New York, NY 10027. Phone: (212) 854-4647. Fax: (212) 865-8246. E-mail:
jlm2{at}columbia.edu.
| |
REFERENCES |
| 1.
|
Adams, P. D.,
X. Li,
W. R. Sellers,
K. B. Baker,
X. Leng,
J. W. Harper,
Y. Taya, and W. G. Kaelin, Jr.
1999.
Retinoblastoma protein contains a C-terminal motif that targets it for phosphorylation by cyclin-cdk complexes.
Mol. Cell. Biol.
19:1068-1080[Abstract/Free Full Text].
|
| 2.
|
Adams, P. D.,
W. R. Sellers,
S. K. Sharma,
A. D. Wu,
C. M. Nalin, and W. G. Kaelin, Jr.
1996.
Identification of a cyclin-cdk2 recognition motif present in substrates and p21-like cyclin-dependent kinase inhibitors.
Mol. Cell. Biol.
16:6623-6633[Abstract].
|
| 3.
|
Ballantyne, S.,
A. Bilger,
J. Astrom,
A. Virtanen, and M. Wickens.
1995.
Poly(A) polymerases in the nucleus and cytoplasm of frog oocytes: dynamic changes during oocyte maturation and early development.
RNA
1:64-78[Abstract].
|
| 4.
|
Barabino, S. M., and W. Keller.
1999.
Last but not least: regulated poly(A) tail formation.
Cell
99:9-11[CrossRef][Medline].
|
| 5.
|
Benz, E. W., Jr.,
M. J. Getz,
D. J. Wells, and H. L. Moses.
1977.
Nuclear RNA polymerase activities and poly(A)-containing mRNA accumulation in cultured AKR mouse embryo cells stimulated to proliferate.
Exp. Cell Res.
108:157-165[Medline].
|
| 6.
|
Chen, I. T.,
M. Akamatsu,
M. L. Smith,
F. D. Lung,
D. Duba,
P. P. Roller,
A. J. Fornace, Jr., and P. M. O'Connor.
1996.
Characterization of p21Cip1/Waf1 peptide domains required for cyclin E/Cdk2 and PCNA interaction.
Oncogene
12:595-607[Medline].
|
| 7.
|
Coleman, M. S.,
J. J. Hutton, and F. J. Bollum.
1974.
Terminal riboadenylate transferase in human lymphocytes.
Nature
248:407-409[CrossRef][Medline].
|
| 8.
|
Colgan, D. F., and J. L. Manley.
1997.
Mechanism and regulation of mRNA polyadenylation.
Genes Dev.
11:2755-2766[Free Full Text].
|
| 9.
|
Colgan, D. F.,
K. G. Murthy,
C. Prives, and J. L. Manley.
1996.
Cell-cycle related regulation of poly(A) polymerase by phosphorylation.
Nature
384:282-285[CrossRef][Medline].
|
| 10.
|
Colgan, D. F.,
K. G. Murthy,
W. Zhao,
C. Prives, and J. L. Manley.
1998.
Inhibition of poly(A) polymerase requires p34cdc2/cyclin B phosphorylation of multiple consensus and non-consensus sites.
EMBO J.
17:1053-1062[CrossRef][Medline].
|
| 11.
|
Cooke, C., and J. C. Alwine.
1996.
The cap and the 3' splice site similarly affect polyadenylation efficiency.
Mol. Cell. Biol.
16:2579-2584[Abstract].
|
| 12.
|
Dantonel, J. C.,
K. G. Murthy,
J. L. Manley, and L. Tora.
1997.
Transcription factor TFIID recruits factor CPSF for formation of 3' end of mRNA.
Nature
389:399-402[CrossRef][Medline].
|
| 13.
|
Desai, D.,
H. C. Wessling,
R. P. Fisher, and D. O. Morgan.
1995.
Effects of phosphorylation by CAK on cyclin binding by CDC2 and CDK2.
Mol. Cell. Biol.
15:345-350[Abstract].
|
| 14.
|
Dynlacht, B. D.,
O. Flores,
J. A. Lees, and E. Harlow.
1994.
Differential regulation of E2F transactivation by cyclin/cdk2 complexes.
Genes Dev.
8:1772-1786[Abstract/Free Full Text].
|
| 15.
|
Dynlacht, B. D.,
K. Moberg,
J. A. Lees,
E. Harlow, and L. Zhu.
1997.
Specific regulation of E2F family members by cyclin-dependent kinases.
Mol. Cell. Biol.
17:3867-3875[Abstract].
|
| 16.
|
Fan, H., and S. Penman.
1970.
Regulation of protein synthesis in mammalian cells. II. Inhibition of protein synthesis at the level of initiation during mitosis.
J. Mol. Biol.
50:655-670[CrossRef][Medline].
|
| 17.
|
Fisher, R. P.,
P. Jin,
H. M. Chamberlin, and D. O. Morgan.
1995.
Alternative mechanisms of CAK assembly require an assembly factor or an activating kinase.
Cell
83:47-57[CrossRef][Medline].
|
| 18.
|
Font de Mora, J.,
A. Uren,
M. Heidaran, and E. Santos.
1997.
Biological activity of p27kip1 and its amino- and carboxy-terminal domains in G2/M transition of Xenopus oocytes.
Oncogene
15:2541-51[CrossRef][Medline].
|
| 19.
|
Foulkes, N. S.,
F. Schlotter,
P. Pevet, and P. Sassone-Corsi.
1993.
Pituitary hormone FSH directs the CREM functional switch during spermatogenesis.
Nature
362:264-267[CrossRef][Medline].
|
| 20.
|
Getz, M. J.,
P. K. Elder,
E. W. Benz, Jr.,
R. E. Stephens, and H. L. Moses.
1976.
Effect of cell proliferation on levels and diversity of poly(A)-containing mRNA.
Cell
7:255-265[CrossRef][Medline].
|
| 21.
|
Gottesfeld, J. M., and D. J. Forbes.
1997.
Mitotic repression of the transcriptional machinery.
Trends Biochem. Sci.
22:197-202[CrossRef][Medline].
|
| 22.
|
Gunderson, S. I.,
K. Beyer,
G. Martin,
W. Keller,
W. C. Boelens, and L. W. Mattaj.
1994.
The human U1A snRNP protein regulates polyadenylation via a direct interaction with poly(A) polymerase.
Cell
76:531-541[CrossRef][Medline].
|
| 23.
|
Gunderson, S. I.,
M. Polycarpou-Schwarz, and I. W. Mattaj.
1998.
U1 snRNP inhibits pre-mRNA polyadenylation through a direct interaction between U1 70K and poly(A) polymerase.
Mol. Cell
1:255-264[CrossRef][Medline].
|
| 24.
|
Gunderson, S. I.,
S. Vagner,
M. Polycarpou-Schwarz, and I. W. Mattaj.
1997.
Involvement of the carboxyl terminus of vertebrate poly(A) polymerase in U1A autoregulation and in the coupling of splicing and polyadenylation.
Genes Dev.
11:761-773[Abstract/Free Full Text].
|
| 25.
|
Harper, J. W., and S. J. Elledge.
1996.
Cdk inhibitors in development and cancer.
Curr. Opin. Genet. Dev.
6:56-64[CrossRef][Medline].
|
| 26.
|
Harper, J. W.,
S. J. Elledge,
K. Keyomarsi,
B. Dynlacht,
L. H. Tsai,
P. Zhang,
S. Dobrowolski,
C. Bai,
L. Connell-Crowley,
E. Swindell, et al.
1995.
Inhibition of cyclin-dependent kinases by p21.
Mol. Biol. Cell
6:387-400[Abstract].
|
| 27.
|
Harper, J. W.,
S. J. Elledge,
K. Keyomarsi,
B. Dynlacht,
L. H. Tsai,
P. Zhang,
S. Dobrowolski,
C. Bai,
L. Connell-Crowley,
E. Swindell,
M. P. Fox, and N. Wei.
1995.
Inhibition of cyclin-dependent kinases by p21.
Mol. Biol. Cell
6:387-400.
|
| 28.
|
Hauser, H.,
R. Knippers, and K. P. Schafer.
1978.
Increased rate of RNA-polyadenylation. An early response in concanavalin A activated lymphocytes.
Exp. Cell Res.
111:175-184[CrossRef][Medline].
|
| 29.
|
Hirose, Y., and J. L. Manley.
1998.
RNA polymerase II is an essential mRNA polyadenylation factor.
Nature
395:93-96[CrossRef][Medline].
|
| 30.
|
Hirsch, M., and S. Penman.
1974.
The messenger-like properties of the poly(A)+ RNA in mammalian mitochondria.
Cell
3:335-339[CrossRef][Medline].
|
| 31.
|
Horton, L. E., and D. J. Templeton.
1997.
The cyclin box and C-terminus of cyclins A and E specify CDK activation and substrate specificity.
Oncogene
14:491-498[CrossRef][Medline].
|
| 32.
|
Hunter, T., and J. Pines.
1994.
Cyclins and cancer. II. cyclin D and CDK inhibitors come of age.
Cell
79:573-582[CrossRef][Medline].
|
| 33.
|
Jeffrey, P. D.,
A. A. Russo,
K. Polyak,
E. Gibbs,
J. Hurwitz,
J. Massague, and N. P. Pavletich.
1995.
Mechanism of CDK activation revealed by the structure of a cyclin A-CDK2 complex.
Nature
376:313-320[CrossRef][Medline].
|
| 34.
|
Keller, W., and L. Minvielle-Sebastia.
1997.
A comparison of mammalian and yeast pre-mRNA 3'-end processing.
Curr. Opin. Cell Biol.
9:329-336[CrossRef][Medline].
|
| 35.
|
Kelly, B. L.,
K. G. Wolfe, and J. M. Roberts.
1998.
Identification of a substrate-targeting domain in cyclin E necessary for phosphorylation of the retinoblastoma protein.
Proc. Natl. Acad. Sci. USA
95:2535-2540[Abstract/Free Full Text].
|
| 36.
|
King, R. W.,
P. K. Jackson, and M. W. Kirschner.
1994.
Mitosis in transition.
Cell
79:563-571[CrossRef][Medline].
|
| 37.
|
Kohtz, J. D.,
S. F. Jamison,
C. L. Will,
P. Zuo,
R. Luhrmann,
M. A. Garcia-Blanco, and J. L. Manley.
1994.
Protein-protein interactions and 5'-splice-site recognition in mammalian mRNA precursors.
Nature
368:119-124[CrossRef][Medline].
|
| 38.
|
Krek, W.,
M. E. Ewen,
S. Shirodkar,
Z. Arany,
W. G. Kaelin, Jr., and D. M. Livingston.
1994.
Negative regulation of the growth-promoting transcription factor E2F-1 by a stably bound cyclin A-dependent protein kinase.
Cell
78:161-172[CrossRef][Medline].
|
| 39.
|
LaBaer, J.,
M. D. Garrett,
L. F. Stevenson,
J. M. Slingerland,
C. Sandhu,
H. S. Chou,
A. Fattaey, and E. Harlow.
1997.
New functional activities for the p21 family of CDK inhibitors.
Genes Dev.
11:847-862[Abstract/Free Full Text].
|
| 40.
|
Lees, E. M., and E. Harlow.
1993.
Sequences within the conserved cyclin box of human cyclin A are sufficient for binding to and activation of cdc2 kinase.
Mol. Cell. Biol.
13:1194-1201[Abstract/Free Full Text].
|
| 41.
|
Lewis, J. D.,
S. I. Gunderson, and I. W. Mattaj.
1995.
The influence of 5' and 3' end structures on pre-mRNA metabolism.
J. Cell Sci. Suppl.
19:13-19.
|
| 42.
|
Lin, J.,
C. Reichner,
X. Wu, and A. J. Levine.
1996.
Analysis of wild-type and mutant p21WAF-1 gene activities.
Mol. Cell. Biol.
16:1786-1793[Abstract].
|
| 43.
|
Ma, T.,
N. Zou,
B. Y. Lin,
L. T. Chow, and J. W. Harper.
1999.
Interaction between cyclin-dependent kinases and human papillomavirus replication-initiation protein E1 is required for efficient viral replication.
Proc. Natl. Acad. Sci. USA
96:382-387[Abstract/Free Full Text].
|
| 44.
|
McCracken, S.,
N. Fong,
K. Yankulov,
S. Ballantyne,
G. Pan,
J. Greenblatt,
S. D. Patterson,
M. Wickens, and D. L. Bentley.
1997.
The C-terminal domain of RNA polymerase II couples mRNA processing to transcription.
Nature
385:357-361[CrossRef][Medline].
|
| 45.
|
Morris, M. C., and G. Divita.
1999.
Characterization of the interactions between human cdc25C, cdks, cyclins and cdk-cyclin complexes.
J. Mol. Biol.
286:475-487[CrossRef][Medline].
|
| 46.
|
Nigg, E. A.
1995.
Cyclin-dependent protein kinases: key regulators of the eukaryotic cell cycle.
Bioessays
17:471-480[CrossRef][Medline].
|
| 47.
|
Pan, Z. Q.,
A. Amin, and J. Hurwitz.
1993.
Characterization of the in vitro reconstituted cyclin A or B1-dependent cdk2 and cdc2 kinase activities.
J. Biol. Chem.
268:20443-20451[Abstract/Free Full Text].
|
| 48.
|
Peeper, D. S.,
L. L. Parker,
M. E. Ewen,
M. Toebes,
F. L. Hall,
M. Xu,
A. Zantema,
A. J. van der Eb, and H. Piwnica-Worms.
1993.
A- and B-type cyclins differentially modulate substrate specificity of cyclin-cdk complexes.
EMBO J.
12:1947-1954[Medline].
|
| 49.
|
Petersen, B. O.,
J. Lukas,
S. r. CS,
J. Bartek, and K. Helin.
1999.
Phosphorylation of mammalian CDC6 by cyclin A/CDK2 regulates its subcellular localization.
EMBO J.
18:396-410[CrossRef][Medline].
|
| 50.
|
Pines, J.
1997.
Cyclin-dependent kinase inhibitors: the age of crystals.
Biochim. Biophys. Acta
1332:M39-M42[Medline].
|
| 51.
|
Russo, A. A.,
P. D. Jeffrey,
A. K. Patten,
J. Massague, and N. P. Pavletich.
1996.
Crystal structure of the p27Kip1 cyclin-dependent-kinase inhibitor bound to the cyclin A-Cdk2 complex.
Nature
382:325-331[CrossRef][Medline].
|
| 52.
|
Sachs, A. B.,
P. Sarnow, and M. W. Hentze.
1997.
Starting at the beginning, middle, and end: translation initiation in eukaryotes.
Cell
89:831-838[CrossRef][Medline].
|
| 53.
|
Saha, P.,
Q. Eichbaum,
E. D. Silberman,
B. J. Mayer, and A. Dutta.
1997.
p21CIP1 and Cdc25A: competition between an inhibitor and an activator of cyclin-dependent kinases.
Mol. Cell. Biol.
17:4338-4345[Abstract].
|
| 54.
|
Schulman, B. A.,
D. L. Lindstrom, and E. Harlow.
1998.
Substrate recruitment to cyclin-dependent kinase 2 by a multipurpose docking site on cyclin A.
Proc. Natl. Acad. Sci. USA
95:10453-10458[Abstract/Free Full Text].
|
| 55.
|
Steward, D. L.,
J. R. Shaeffer, and R. M. Humphrey.
1968.
Breakdown and assembly of polyribosomes in synchronized Chinese hamster cells.
Science
161:791-793[Abstract/Free Full Text].
|
| 56.
|
Takagaki, Y.,
R. L. Seipelt,
M. L. Peterson, and J. L. Manley.
1996.
The polyadenylation factor CstF-64 regulates alternative processing of IgM heavy chain pre-mRNA during B cell differentiation.
Cell
87:941-952[CrossRef][Medline].
|
| 57.
|
Tassan, J. P.,
M. Jaquenoud,
A. M. Fry,
S. Frutiger,
G. J. Hughes, and E. A. Nigg.
1995.
In vitro assembly of a functional human CDK7-cyclin H complex requires MAT1, a novel 36 kDa RING finger protein.
EMBO J.
14:5608-5617[Medline].
|
| 58.
|
Wahle, E., and U. Kuhn.
1997.
The mechanism of 3' cleavage and polyadenylation of eukaryotic pre-mRNA.
Prog. Nucleic Acid Res. Mol. Biol.
57:41-71[Medline].
|
| 59.
|
Wickens, M.,
P. Anderson, and R. J. Jackson.
1997.
Life and death in the cytoplasm: messages from the 3' end.
Curr. Opin. Genet. Dev.
7:220-232[CrossRef][Medline].
|
| 60.
|
Xiong, Y.,
G. J. Hannon,
H. Zhang,
D. Casso,
R. Kobayashi, and D. Beach.
1993.
p21 is a universal inhibitor of cyclin kinases.
Nature
366:701-704[CrossRef][Medline].
|
| 61.
|
Zhang, H.,
G. J. Hannon, and D. Beach.
1994.
p21-containing cyclin kinases exist in both active and inactive states.
Genes Dev.
8:1750-1758[Abstract/Free Full Text].
|
| 62.
|
Zhao, J.,
L. Hyman, and C. Moore.
1999.
Formation of mRNA 3' ends in eukaryotes: mechanism, regulation, and interrelationships with other steps in mRNA synthesis.
Microbiol. Mol. Biol. Rev.
63:405-445[Abstract/Free Full Text].
|
| 63.
|
Zhao, W., and J. L. Manley.
1996.
Complex alternative RNA processing generates an unexpected diversity of poly(A) polymerase isoforms.
Mol. Cell. Biol.
16:2378-2386[Abstract].
|
| 64.
|
Zhao, W., and J. L. Manley.
1998.
Deregulation of poly(A) polymerase interferes with cell growth.
Mol. Cell. Biol.
18:5010-5020[Abstract/Free Full Text].
|
| 65.
|
Zhu, L.,
E. Harlow, and B. D. Dynlacht.
1995.
p107 uses a p21CIP1-related domain to bind cyclin/cdk2 and regulate interactions with E2F.
Genes Dev.
9:1740-1752[Abstract/Free Full Text].
|
Molecular and Cellular Biology, July 2000, p. 5310-5320, Vol. 20, No. 14
0270-7306/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
