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Previous Article | Next Article 
Molecular and Cellular Biology, November 1999, p. 7511-7518, Vol. 19, No. 11
0270-7306/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
The Rpb4 Subunit of Fission Yeast
Schizosaccharomyces pombe RNA Polymerase II Is Essential for
Cell Viability and Similar in Structure to the Corresponding Subunits
of Higher Eukaryotes
Hitomi
Sakurai,1,2
Hiroshi
Mitsuzawa,1
Makoto
Kimura,1 and
Akira
Ishihama1,*
Department of Molecular Genetics, National
Institute of Genetics, Mishima, Shizuoka
411-8540,1 and Japan Science and
Technology Corporation, Kawaguchi, Saitama
332-0012,2 Japan
Received 26 July 1999/Accepted 16 August 1999
 |
ABSTRACT |
Both the gene and the cDNA encoding the Rpb4 subunit of RNA
polymerase II were cloned from the fission yeast
Schizosaccharomyces pombe. The cDNA sequence indicates that
Rpb4 consists of 135 amino acid residues with a molecular weight of
15,362. As in the case of the corresponding subunits from higher
eukaryotes such as humans and the plant Arabidopsis
thaliana, Rpb4 is smaller than RPB4 from the budding yeast
Saccharomyces cerevisiae and lacks several segments, which
are present in the S. cerevisiae RPB4 subunit, including
the highly charged sequence in the central portion. The RPB4 subunit of
S. cerevisiae is not essential for normal cell growth but
is required for cell viability under stress conditions. In contrast,
S. pombe Rpb4 was found to be essential even under normal
growth conditions. The fraction of RNA polymerase II containing RPB4 in
exponentially growing cells of S. cerevisiae is about 20%,
but S. pombe RNA polymerase II contains the stoichiometric amount of Rpb4 even at the exponential growth phase. In contrast to the
RPB4 homologues from higher eukaryotes, however, S. pombe Rpb4 formed stable hybrid heterodimers with S. cerevisiae
RPB7, suggesting that S. pombe Rpb4 is similar, in its
structure and essential role in cell viability, to the corresponding
subunits from higher eukaryotes. However, S. pombe Rpb4 is
closer in certain molecular functions to S. cerevisiae RPB4
than the eukaryotic RPB4 homologues.
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INTRODUCTION |
RNA polymerase II in eukaryotes is
composed of more than 10 different polypeptides (for example, see
reference 29). The genes coding for all 12 putative
subunits of RNA polymerase II have been isolated from the budding yeast
Saccharomyces cerevisiae (reviewed in references
26 and 27) and humans
(10). Sometime ago we reported that the purified RNA
polymerase II from the fission yeast Schizosaccharomyces
pombe contained at least 10 polypeptides, devoid of the components
corresponding to RPB4 and RPB9 of S. cerevisiae
(21, 24; for a recent review, see reference
8). Later we cloned the gene and the cDNA for Rpb9
by PCR using the sequence knowledge of subunit 9 from other organisms
(23). By Western blot analysis with antibodies against the
Rpb9 protein expressed in Escherichia coli, we found that
the purified S. pombe RNA polymerase II does indeed contain
Rpb9, which had not been detected in the gel pattern because of its
comigration with Rpb8 and Rpb11 (23).
Recently, the genes coding for subunit 4 were cloned from humans
(10) and the plant Arabidopsis thaliana
(15). Human cDNA for RPB4 was cloned by two-hybrid screening
of cDNA coding for a protein which interacts with human RPB7 (hRPB7)
(10), because S. cerevisiae RPB4 forms a binary
complex with RPB7 (6, 11). On the other hand, the gene for
the A. thaliana RPB15.9 (AtRPB15.9) subunit, which is a
homologue of S. cerevisiae RPB4, was cloned by
cross-hybridization using the homologous expressed sequence tag (EST)
clone of oilseed rape (Brassica napus) as the probe (15). Both hRPB4 and AtRPB15.9 are smaller than S. cerevisiae RPB4, lacking a segment corresponding to the central
portion of S. cerevisiae RPB4. As in the case of S. cerevisiae, subunits 4 and 7 from both human and the plant formed
a stable binary complex, but this subassembly seems to be associated
with the RNA polymerase II more tightly than that of S. cerevisiae (10, 15). We then reexamined whether the
purified RNA polymerase II from S. pombe contains Rpb4 or
not. Results herein described indicate that S. pombe
contains the gene for Rpb4 and that the Rpb4 protein is essential for
cell viability and more similar, in structure and function, to those of
higher eukaryotes than that of S. cerevisiae.
| |
MATERIALS AND METHODS |
Yeast strains, media, and transformation.
The S. pombe strains used in this study are JY741 (h
ade6-M216 ura4-D18 leu1) and JY746 (h+ ade6-M210
ura4-D18 leu1). Media YE, EMM, and ME were prepared as described
previously (17). 5-Fluoroorotic acid (Toronto Research Chemicals) was used at 1 mg/ml. S. pombe was transformed by
the lithium acetate method (18).
Cloning of the cDNA for rpb4.
Cloning of
rpb4 cDNA was performed by a combination of 3' RACE (rapid
amplification of the 3' end of cDNA) and 5' RACE (rapid amplification
of the 5' end of cDNA). 3' RACE was performed by the method described
previously (23), using a 3'-Full RACE core set (Takara
Shuzo, Kusatsu, Japan) and total mRNA as the template. Total mRNA was
isolated from S. pombe JY741 as described previously (22). For amplification of the 3'-proximal region of the
rpb4 cDNA, we designed a primer, primer 419, based on the
sequence of cosmid c337. Primer 419 corresponds to nucleotide positions 434 to 452 (nucleotide position 1 was set as the first nucleotide of
the rpb4 initiation codon) in the 3'-proximal exon (see
Table 1 for the primer sequence and Fig.
1A for the location of the primer sequence along the rpb4
gene). For 5' RACE, the oligo-capping method (22, 25) was
employed, using oligo-capped mRNA as the template and a pair of
primers, 5'-cap-specific primer, CAP20, and an rpb4-specific
3' primer, 421R, with the sequence within the last exon (Table 1 and
Fig. 1A). Nested PCR was performed using the first PCR products as the
template and a combination of the oligo-cap-specific primer and another
gene-specific primer, 420R (Table 1 and Fig. 1A). The complete
rpb4 cDNA was constructed after combination of the PCR
products from 3' and 5' RACEs, cloned into pGEM-T vector (Promega), and
sequenced.
Disruption of the rpb4 gene.
A 2.2-kb genomic
DNA segment including the rpb4 gene from positions 
953 to
+1201 (+1 is set at the first nucleotide of start codon) was PCR
amplified by using primers X426 and K429R (Table 1) and S. pombe genomic DNA as the template. After digestion with
XbaI-KpnI, the segment was ligated into pUC18
between XbaI and KpnI sites to construct
pUC-rpb4.
For disruption of the rpb4 gene, the entire vector sequence
flanked with the 5'- and 3'-terminal sequences of rpb4 (but
lacking the Rpb4-coding sequence) was PCR amplified with B424R and X427 as the primers (Table 1) and plasmid pUC-rpb4 as the
template, and the PCR product was ligated with a 1.8-kb
BamHI-XhoI ura4 fragment to construct
pUC-rpb4::ura4, in which the entire
coding sequence of rpb4 was replaced by the ura4
gene. A 2.8-kb rpb4::ura4 fragment was
PCR amplified with Vent DNA polymerase (New England Biolabs), using
primers 4-1 and 4-2 (Table 1) and
pUC-rpb4::ura4 as the template; the
resulting fragment was used to transform a diploid S. pombe
strain constructed by a cross between JY741 and JY746. Ura+
transformants were selected on an EMM medium plate containing leucine,
and screened on a plate containing 5-fluoroorotic acid for a stable
Ura+ phenotype. The disruption of one chromosomal copy of
the rpb4 gene was confirmed by PCR.
Expression and purification of Rpb4 and other Rpb proteins.
rpb4 cDNA including the complete coding sequence of Rpb4 was
amplified by PCR with a pair of primers, i.e., a 5' primer including an
NdeI site sequence (the translational start codon is
included in the NdeI sequence) and a 3' primer including a
XhoI site sequence. The PCR product was inserted into
pET-21b (Novagen) between NdeI and XhoI sites to
construct pET-Rpb4CH, the expression vector of Rpb4 with a
hexahistidine (His6) tag at the C terminus (Rpb4CH). Expression plasmids pET-Rpb4 (coding for Rpb4 without the
His6 tag), pET-Rpb8, pET-Rpb9, and pET-Rpb11 were also
derivatives of pET-21b containing rpb4, rpb8,
rpb9, and rpb11 cDNA, respectively. These cDNAs
were PCR amplified using specific sets of 5' and 3' primers, each
including the initiation codon (in the NdeI site) and the
termination codon, respectively.
The expression plasmids were transformed into E. coli
BL21(DE3). Rpb4CH was purified from induced-cell lysates by
Ni2+-agarose column chromatography.
Anti-Rpb protein antibodies and Western blotting.
Anti-Rpb4
antibodies were raised in rabbits immunized with the purified Rpb4CH.
Antibodies against other Rpb proteins were prepared as described
previously (7, 23).
For Western blotting, the purified RNA polymerase or the induced
E. coli cell lysates for the expression of Rpb proteins were separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE), and proteins were transferred to polyvinylidene difluoride membranes by electroblotting. Protein blots were probed with
anti-Rpb4CH, anti-Rpb7CH, anti-Rpb8CH, anti-Rpb9CH, and anti-Rpb11CH
antibodies (7, 23), followed by staining with anti-rabbit
immunoglobulin G antibodies conjugated with horseradish peroxidase
(Cappel). The peroxidase activity was visualized using an enhanced
chemiluminescence kit (Amersham), and analyzed with LAS-1000plus
lumino-image analyzer (Fuji Film).
Construction of double-expression plasmids of Rpb4 and
Rpb7CH.
For simultaneous expression of both subunits 4 (S. pombe Rpb4 [SpRpb4] and S. cerevisiae RPB4
[ScRPB4]) and 7 (S. pombe Rpb7 and S. cerevisiae RPB7) in all possible combinations, four kinds of the
double-expression plasmid, pET-Sp4/Sp7CH, pET-Sp4/Sc7CH, pET-Sc4/Sp7CH,
and pET-Sc4/Sc7CH, were constructed by using plasmid pET-21b (Novagen)
as a vector. First, cDNAs for S. pombe rpb4 and S. cerevisiae RPB4 were PCR amplified using 5' and 3' primers, each
including the initiation codon (in the NdeI site) and the termination codon, and integrated into pET-21b, while cDNAs for S. pombe rpb7 and S. cerevisiae RPB7 were PCR
amplified using 5' and 3' primers, each including the initiation
codon-NdeI site and the termination codon-XhoI
site. All these cDNAs were integrated into pET-21b as to synthesize
SpRpb4, ScRPB4, SpRpb7-His6, and ScRPB7-His6
proteins. The shorter SphI-BamHI fragment of
pET-Rpb4 or pET-RPB4 containing the subunit 4 cDNA and the larger
BglII-SphI fragment of pET-Rpb7CH or pET-RPB7CH
containing the subunit 7 cDNA sequence fused to the His6
sequence were ligated in all possible combinations to yield the four
kinds of double-expression plasmid. The double-expression plasmids were
transformed into E. coli BL21(DE3) for construction of the
simultaneous expression system of both subunits 4 and 7 in various
combinations (note that both subunit 4 and 7 cDNAs in a plasmid are
under independent control of the T7 promoter).
Isolation of complexes of Rpb4 or RPB4 and Rpb7 or RPB7.
The
transformed E. coli BL21(DE3) with double-expression
plasmids were grown in M9 medium containing 1% Bacto Tryptone, 4% glucose, and 100 µg of ampicillin per ml at 30°C. When the cells reached 80 U, as measured with a Klett-Summerson photometer,
isopropyl-
-D-thiogalactopyranoside (IPTG) was added to a
final concentration of 0.1 mM. After 3 h of incubation, the cells
were harvested by centrifugation and stored at 80°C.
For purification of expressed proteins, the cells were suspended in
buffer A (20 mM Tris-HCl [pH 8.0, 4°C], 0.1 M NaCl, 10% glycerol,
10 mM -mercaptoethanol [-ME], 0.5 mM phenylmethanesulfonyl fluoride [PMSF]) containing 0.3 mg of lysozyme per ml, incubated on
ice for 20 min, sonicated, and centrifuged at 15,000 × g for 20 min at 4°C. Polyethylenimine (pH 7.9) was added to the
supernatant to a final concentration of 0.1% (vol/vol) and mixed. The
mixture was incubated on ice for 30 min. After centrifugation at
15,000 × g for 20 min at 4°C and then at
150,000 × g for 1 h at 4°C, the resulting
supernatant was loaded onto a Ni2+-nitriloacetic acid
agarose (Qiagen) column equilibrated with buffer A. The column was
washed, in a stepwise fashion, with 20 times the column volume of
buffer B (20 mM Tris-HCl [pH 8.0, 4°C], 0.5 M NaCl, 10% glycerol,
10 mM -ME, 0.5 mM PMSF) and 10 times the column volume of buffer C
(20 mM Tris-HCl [pH 8.0, 4°C], 0.1 M NaCl, 10% glycerol, 10 mM
-ME, 0.5 mM PMSF, 20 mM imidazole) and then eluted with buffer D (20 mM Tris-HCl [pH 8.0, 4°C], 0.1 M NaCl, 10% glycerol, 10 mM -ME,
0.5 mM PMSF, 50 mM imidazole).
Gel filtration chromatography.
The complexes of Rpb4 or RPB4
and Rpb7 or RPB7 were loaded onto Superdex 75 PC 3.2/30 columns
(Pharmacia) at a flow rate of 40 µl/min in buffer E (20 mM Tris-HCl
[pH 8.0, 4°C], 0.3 M NaCl, 5% glycerol, 0.1 mM EDTA, 1 mM
dithiothreitol) at 4°C, using the Smart System (Pharmacia). Fractions
of 50 µl were collected and analyzed by SDS-PAGE.
Nucleotide sequence accession number.
The DNA sequence of
S. pombe rpb4 has been deposited into the DDBJ/GenBank/EMBL
database under accession no. AB019575.
| |
RESULTS |
Cloning of cDNA for Rpb4 and the rpb4 gene.
The
S. pombe Rpb4 subunit has not been identified by SDS-PAGE
analysis of the purified RNA polymerase II (21, 23).
Likewise, we failed to identify the S. pombe rpb4 gene by
PCR with primers which were synthesized by using the highly conserved
amino acid sequences among S. cerevisiae RPB4 and both mouse
and human ESTs (DNA database accession no. AA139434 and W87848,
respectively) (the region corresponding to amino acid residues 99 to
109 of S. pombe Rpb4 [Fig.
1B]). Recently, however, the RPB4
homologue genes were cloned both from humans and a plant (10,
15). We then reinitiated the search for the rpb4 gene
in S. pombe. After analysis of the newly publicized sequence
of S. pombe genome in PomBase (Sanger Center) using the
entire amino acid sequences of S. cerevisiae RPB4 (ScRPB4)
and hRPB4 as references, we found several sequence segments which are
similar to parts of ScRPB4 and hRPB4 in the cosmid c337 (the sequence
information of Rpb4 in the cosmid c337 was kindly provided by Pierre
Thuriaux and Olivier Gadal). Based on the comparison between the amino
acid sequences of ScRPB4 and hRPB4 proteins and the nucleotide sequence of S. pombe c337 cosmid, we predicted the presence of four
exons and three introns within the Rpb4-coding sequence (Fig. 1A).
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FIG. 1.
Structure of the rpb4 gene and the Rpb4
protein. (A) Nucleotide sequences were determined for both the
rpb4 gene and its cDNA. The amino acid sequence of Rpb4 was
predicted from the cDNA sequence. The Rpb4 open reading frame (large
black bars) is interrupted by three introns (small white bars).
Nucleotide 1 is defined as the first nucleotide of the initiation
codon, while amino acid 1 is defined as the initiation codon. The
positions and directions of primers used for PCR are shown by the
arrows. For primer sequences, see Table 1. (B) Comparison of the amino
acid sequences of RNA polymerase II subunit 4 in various organisms. The
amino acid sequence of S. pombe Rpb4 subunit (Sp) is
compared with the corresponding subunits from S. cerevisiae
(Sc), Homo sapiens (Hs), and A. thaliana (At).
The overall identity of the amino acid (aa) sequence of the S. pombe Rpb4 with those of other organisms is shown at the end of
each alignment. Amino acids that are identical or similar at least
between two species are outlined or shaded, respectively. Gaps
introduced to maximize alignment are indicated by dashes.
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To confirm our prediction, we tried to determine the rpb4
cDNA sequence using a combination of 3' RACE and 5' RACE. After 3' RACE
analysis of total S. pombe mRNA using primer 419 (Fig. 1A),
one DNA fragment about 400 bp long was amplified, which included the
sequence downstream from the last exon of rpb4 including the 3' untranslated region (Fig. 1A). On the other hand, the 5'-proximal region of rpb4 cDNA was PCR amplified by 5' RACE using a
5'-cap primer and one of the rpb4-specific primers 421R
(Table 1 and Fig. 1A). The major DNA product of about 550 bp in length,
obtained after the second PCR using primer 420R, contained the sequence upstream from the C-terminal proximal exon. The complete cDNA clone was
constructed by PCR using a set of primers, 5'-terminal 422 and
3'-terminal 423R (Table 1 and Fig. 1A). A 650-bp-long PCR product was
amplified. The sequence of this PCR product was completely identical to
the sequence obtained by the combination of 5' and 3' RACEs and the
sequence predicted from the c337 cosmid sequence.
To isolate the genomic clone of the rpb4 gene, PCR
amplification was performed with primers 422 and 423R (Table 1 and Fig. 1A) and with the genomic DNA as the template. The sequence
determination of PCR products revealed that the rpb4 gene
contains four exons and three introns. The exon-intron junction
sequences agree well with the known splice junction sequences in
S. pombe (21, 30).
Structure of the Rpb4 protein.
The Rpb4-coding sequence
consists of 408 nucleotides, which encodes a polypeptide of 135 amino
acid residues with a molecular weight of 15,362 (Fig. 1A). The
predicted amino acid sequence of S. pombe Rpb4 was compared
with those of the corresponding subunits from three organisms, i.e.,
human RPB4, A. thaliana RPB15.9, and S. cerevisiae RPB4 (Fig. 1B). S. pombe Rpb4 is similar in size to those of the human and plant RPB4 homologues (142 residues for
human and 138 residues for plant), but it was smaller than the S. cerevisiae RPB4 (221 residues) (Fig. 1B and Table 2). The overall
sequence identity of S. pombe Rpb4 with the corresponding subunits from humans, A. thaliana, and S. cerevisiae (including the extra sequences) is 36, 31, and 26%, respectively.
The S. cerevisiae RPB4 contains four segments of the extra
sequence, two N-terminal proximal segments (residues 7 to 14 and 36 to
43 on the S. cerevisiae sequence) and two segments (residues 72 to 98 and 108 to 138) in the central portion, which are not present
in the RPB4 homologue from other organisms (Fig. 1B). The highly
charged S. cerevisiae-specific sequence in the central portion is similar, in part, with the E. coli
70 subunit (28). As in the case of both human
and plant subunit 4, the S. pombe Rpb4 lacks these S. cerevisiae-specific sequences (Fig. 1B). Nevertheless, hRPB4 is
able to complement, albeit at a low efficiency, the altered phenotype
of S. cerevisiae rpb4 mutant (10). Together, the
results indicate that the S. cerevisiae RPB4-specific
sequences are not essential for the subunit 4 function in other
organisms and that the S. pombe Rpb4 is more similar, in its
structure, to the RPB4 homologues from higher eukaryotes.
Identification of Rpb4 in S. pombe RNA polymerase
II.
Previously, we failed to detect Rpb4 in our RNA polymerase II
preparations by microsequencing of proteolytic fragments of the
subunits separated by SDS-PAGE (21, 24). Since we identified the rpb4 gene sequence in the S. pombe genome, we
reexamined whether the rpb4 gene product was expressed in
S. pombe and assembled into the RNA polymerase II. For this
purpose, the rpb4 cDNA was expressed in E. coli
as a fusion with a sequence for His6 tag, and the putative
Rpb4 protein was purified by affinity chromatography. The purified
His6-tagged Rpb4 was used to raise polyclonal antibodies in
rabbits. As a test sample, the RNA polymerase II was purified from
growing cells of S. pombe by our standard procedure
(2).
When the crude enzyme preparation after MonoQ chromatography, which
contained more than 20 stained protein bands after SDS-PAGE, was
analyzed by Western blotting, we detected an immunostained band with
anti-Rpb4 antibodies, which migrated to the same position as Rpb8,
Rpb9, and Rpb11 (Fig. 2A). Comigration of
Rpb9 (113 amino acid residues) with Rpb8 (125 residues) and Rpb11 (123 residues) interfered with the detection of Rpb9 (23). Here,
it became clear that the failure to detect Rpb4 (135 residues) was also caused by the comigration of Rpb4 with these three subunits. To confirm
that the anti-Rpb4 antibodies used did not cross-react with other Rpb
proteins, all four Rpb proteins were independently expressed in
E. coli, the expressed cell lysates were fractionated by
SDS-PAGE, and the gel was subjected to Western blot analysis using the
anti-Rpb4 antibodies. As shown in Fig. 2B, no cross-reaction was
observed between the anti-Rpb4 antibodies and the Rpb8, Rpb9, and Rpb11
proteins.
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FIG. 2.
Identification of Rpb4 in purified S. pombe
RNA polymerase II. (A) RNA polymerase II was purified by the standard
procedure. The crude enzyme preparation after MonoQ chromatography was
separated by SDS-PAGE and subjected to Western blotting with
anti-Rpb7CH (lane 1), anti-Rpb8CH (lane 2), anti-Rpb9CH (lane 3),
anti-Rpb4CH (lane 4), and anti-Rpb11CH (lane 5) antibodies. (B) Cell
lysates of E. coli overexpressing the Rpb proteins (lanes 1 to 4, Rpb8, Rpb9, Rpb4, and Rpb11, respectively) were separated by
SDS-PAGE, and the gel was subjected to either immunostaining against
the anti-Rpb4 antibodies or protein staining with Coomassie brilliant
blue (CBB). (C) The MonoQ fraction of RNA polymerase II was further
purified by gel filtration chromatography on a Superose 6 column.
Aliquots from Superose 6 fractions (lanes 1 to 10) and an aliquot of
the Ni2+-affinity-purified RNA polymerase II from a
S. pombe strain expressing His6-tagged Rpb3
(lane 11) were separated by SDS-PAGE. The gel was subjected to Western
blotting with anti-Rpb4CH (top) and anti-GST-Rpb3 (bottom) antibodies.
(D) The purified RNA polymerase II (Pol II) (Superose 6 fraction) was
fractionated by SDS-PAGE (lane 4), and the gel was subjected to
quantitative immunoblot analysis using anti-Rpb7CH (top) and
anti-Rpb4CH antibodies (bottom). For quantitation, various amounts of
the purified Rpb4 and Rpb7CH were analyzed in parallel (10 [lane 1],
20 [lane 2], and 50 [lane 3] ng).
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Western blot analysis was also performed for an RNA polymerase II
preparation at a later step of purification, which was obtained after
Superose 6 gel filtration chromatography of the MonoQ fraction. The
Rpb4 protein showed the same elution pattern as both the Rpb3 protein
(Fig. 2C) and the RNA polymerase activity (data not shown). To confirm
these observations, we also tested two different preparations of the
RNA polymerase II obtained from different S. pombe strains and by different procedures. One enzyme preparation was purified by
glutathione-Sepharose column chromatography from a S. pombe strain carrying the gene coding for a glutathione
S-transferase (GST)-Rpb3 fusion in place of the wild-type
rpb3 gene (13). The other enzyme preparation was
obtained by Ni2+-affinity chromatography from a S. pombe strain in which the rpb3 gene was replaced by the
gene encoding Rpb3 fused with the His6 tag (12).
We detected the Rpb4 band for both of the RNA polymerase preparations
(see Fig. 2C, lane 11, for the RNA polymerase II containing
His6-tagged Rpb3) (the complete set of subunits including Rpb4 was also detected for the RNA polymerase preparation containing the GST-Rpb3 fusion [13]). Thus, we conclude that Rpb4
is indeed associated with the S. pombe RNA polymerase II.
Stoichiometry of the Rpb4 in RNA polymerase II.
The fraction
of S. cerevisiae RNA polymerase II containing RPB4 is only
about 20% in cells in the exponential growth phase but it gradually
increases in the postexponential phase (4, 14). In addition,
S. cerevisiae RPB4 is easily dissociated, together with
RPB7, from the RNA polymerase II at least under various in vitro
situations (5, 6, 20). On the other hand, in humans and
plants, subunits 4 and 7 are associated with RNA polymerase II more
tightly than in S. cerevisiae even in the exponential growth
phase (10, 15). We then tried to determine the stoichiometry of Rpb4 in the RNA polymerase from S. pombe. For this
purpose, a quantitative immunoblot analysis was performed with RNA
polymerase II, which was purified from exponentially growing cells
(5 × 107 cells/ml) by our standard procedure
(2). For quantification, we used Rpb7 as a reference,
because the stoichiometric amount of Rpb7 associates with the purified
S. pombe RNA polymerase II (24). The result,
shown in Fig. 2D, indicates that there is as much Rpb4 is as Rpb7.
Disruption of the rpb4 gene in S. pombe.
RPB4 of S. cerevisiae is not essential for cell growth but
is required for viability under certain stress conditions (4, 28). To determine whether Rpb4 is essential for cell viability of
S. pombe, we constructed a diploid strain carrying one
disrupted copy of rpb4 as described in Materials and
Methods. The rpb4/rpb4::ura4 cells were
sporulated and subjected to tetrad analysis. Of 23 tetrads dissected, 0 viable, 1 viable, and 2 viable spores were observed in 3, 4, and 16 tetrads, respectively, and no more than 2 viable spores were observed
(Fig. 3). Moreover, all the 36 viable spores were Ura, indicating that
rpb4::ura4 spores are not viable.
Microscopic observation revealed that
rpb4::ura4 spores germinated but ceased growth after a few divisions. These results demonstrate that the S. pombe rpb4 gene, unlike its S. cerevisiae
counterpart, is essential for cell growth.
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FIG. 3.
Tetrad analysis of an rpb4 heterozygous
diploid. Diploid cells carrying one disrupted copy of rpb4
were sporulated on ME medium at 27°C for 2 days, and tetrads were
dissected on YE medium containing adenine and uracil and allowed to
grow at 30°C for 3 days. Seven tetrads are shown; the four spores
from each tetrad are aligned vertically.
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Interaction between Rpb4 and Rpb7.
RPB4 and RPB7 from both
S. cerevisiae form a stable binary complex (6).
The RPB4 and RPB7 homologues from both humans and A. thaliana were also shown to form heterodimers (10, 15). In order to test whether S. pombe Rpb4 and Rpb7 form a
stable heterodimer, we expressed both Rpb4 and Rpb7CH in the same
E. coli cells and isolated an Rpb7CH complex(es) by
Ni2+-affinity chromatography. As shown in Fig.
4A, not only Rpb7CH but also Rpb4 bound
to the Ni2+-agarose resin, indicating that Rpb4 and Rpb7CH
formed a stable complex(es). To confirm the formation of Rpb4-Rpb7
complexes, the Ni2+-agarose fractions containing both Rpb4
and Rpb7CH were fractionated by gel filtration chromatography. As shown
in Fig. 4B, the Rpb4 and Rpb7CH subunits were coeluted at fractions
with an estimated molecular mass of 37 kDa. From the sizes of the two
proteins (Rpb4, 16 kDa; Rpb7CH, 22 kDa), we conclude that one molecule
each of the two subunits forms the heterodimer. The apparent difference in the staining intensities of the two proteins, Rpb4 and Rpb7, in the
equimolar heterodimeric complex is due to the strong binding of the
dye, Coomassie brilliant blue, to Rpb4.
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FIG. 4.
Formation of complexes of Rpb4 or RPB4 and Rpb7 or RPB7.
Two species of the RNA polymerase II subunit were coexpressed in
E. coli in the following four combinations: S. pombe Rpb4-S. pombe Rpb7CH, S. cerevisiae
RPB4-S. cerevisiae RPB7CH, S. cerevisiae
RPB4-S. pombe Rpb7CH, and S. pombe Rpb4-S.
cerevisiae RPB7CH, (which are shown as Sp4/Sp7H, Sc4/Sc7H,
Sc4/Sp7H, and Sp4/Sc7H over the lanes in panel A). (A) Crude cell
extracts were applied to a Ni2+-agarose column. Proteins
bound were eluted with an elution buffer containing imidazole. Aliquots
of the loading fraction, the flowthrough (FT) fraction, and the
column-bound fraction were analyzed by SDS-PAGE, and the gel was
stained with Coomassie brilliant blue. The migration positions of
molecular mass markers are shown on the left. The positions of Rpb4,
RPB4, Rpb7CH (Rpb7H), and RPB7CH (RPB7H) from S. pombe
(Sp) or S. cerevisiae (Sc) are indicated on the right (note
that the migration of S. pombe Rpb4 is faster than Rpb7).
(B) The Ni2+-agarose elution fractions containing the
binary complexes were subjected to gel filtration chromatography on a
Superdex 75 PC 3.2/30 column. Aliquots from the fractions were analyzed
by SDS-PAGE, and the gel was stained with Coomassie brilliant blue.
Fraction numbers are shown at the top, and the peak positions of
molecular marker proteins, fractionated on the same column, are
indicated at the bottom. The migration positions of Rpb4, RPB4, Rpb7CH,
and RPB7CH are indicated on the right.
|
|
Human RPB4 homologue does not interact with S. cerevisiae
RPB7 as detected by the yeast two-hybrid system but is able to rescue an S. cerevisiae rpb4 disruptant partially (10).
We then tested whether chimeric heterodimers are formed between
S. pombe and S. cerevisiae. Pairs of two subunits
in heterologous combinations, i.e., S. pombe Rpb4 plus
S. cerevisiae RPB7CH and S. cerevisiae RPB4 plus
S. pombe Rpb7CH were simultaneously expressed in E. coli. Expressed cell lysates were subjected to
Ni2+-affinity chromatography (Fig. 4A), and the
column-bound Rpb7CH or RPB7CH complexes were eluted and fractionated by
gel filtration chromatography (Fig. 4B). In both heterologous
combinations, the chimeric heterodimers, RPB4-Rpb7CH and Rpb4-RPB7CH,
were formed as in the case of homologous combinations,
RPB4-RPB7CH and Rpb4-Rpb7CH (Fig. 4B). The elution positions of
the heterodimers, except for the S. pombe Rpb4-S.
cerevisiae RPB7CH hybrid dimer, are close to those expected based
on the assumption that the dimers are composed of one molecule each of
the subunits in the dimer. The conformation of the Rpb4-RPB7CH hybrid
dimer may be different from those of other dimers. These observations
indicate that the extrasequence segments present only in the S. cerevisiae RPB4 are not essential for the dimerization with RPB7
and, moreover, that the S. pombe Rpb4 is closer, in its
structure and essential nature in cell viability, to the corresponding
subunits of higher eukaryotes, but closer in certain molecular
functions, to the S. cerevisiae RPB4 than the RPB4
homologues from higher eukaryotes.
| |
DISCUSSION |
Until recently, the subunit 4 (RPB4) of RNA polymerase II was
identified only in S. cerevisiae (29). The
stoichiometry of RPB4 in the S. cerevisiae RNA polymerase
II, however, changes, depending on the growth conditions. In growing
cells, the fraction of RNA polymerase II containing RPB4 is about 20%
(4, 14), but in the stationary phase, virtually all RNA
polymerase II molecules contain Rpb4 (4). In concert with
these observations, RPB4 is not essential for the viability of S. cerevisiae (28), and under optimal growth conditions at
moderate temperatures, the S. cerevisiae mutant lacking RPB4
can grow, albeit at lower rates than the wild-type counterpart
(4). The RPB4 mutant is, however, not viable
under various stress conditions such as upon exposure to heat shock
(4, 28) or under nutrient starvation at moderate temperatures (4). Overproduction of RPB4 results in almost twofold increase in the growth rate only when the cells were growing slowly (3). In agreement with these in vivo observations,
RPB4 is required for the RNA polymerase activity in vitro only at
extreme temperatures (19). The RNA polymerase II purified
from cells lacking the RPB4 gene is catalytically active in
RNA synthesis but is deficient in selective transcription initiation in
vitro from certain promoters (6). These observations
altogether indicate that in the case of S. cerevisiae, RPB4
is required for functional modulation of the RNA polymerase under
certain stress conditions.
The RNA polymerase II purified from an S. cerevisiae mutant
lacking the RPB4 gene lacks both RPB4 and RPB7
(14), suggesting that RPB7 interacts with RPB4 to associate
with the RNA polymerase. Both RPB4 and RPB7 can be dissociated as a
complex from the S. cerevisiae RNA polymerase II when the
enzyme is chromatographed on an anion-exchange resin in the presence of
1.2 to 2.0 M urea (6, 20) or when the enzyme is subjected to
native gel electrophoresis in the absence of protein denaturants
(5). The phenotype of the RPB4 mutant reflects the
involvement of the RPB4-RPB7 complex in the modulation of the activity
or specificity of RNA polymerase II. Unlike S. cerevisiae
RPB4 and RPB7, the corresponding subunits 4 and 7 are more stably
associated with animal and plant RNA polymerase II (10, 15).
Based on in vitro transcription experiments, RPB4 and RPB7 are known to
be dispensable for promoter-independent or nonspecific transcription
initiation and RNA chain elongation (6, 20). However, these
two subunits are required for promoter-dependent or -specific
initiation (6). Thus, RPB4 was once thought to be an
accessory protein with no essential role in the RNA polymerase II
functions. The association of RPB4 with the other RNA polymerase II
subunits may modulate its specificity as to increase the tolerance against various stresses.
Identification of Rpb4 in S. pombe, plants, and animals
categorizes the conserved nature of RNA polymerase II subunits in three
eukaryotic kingdoms, plants, animals, and fungi. Sequences of the
cloned subunits and ESTs suggest that plant, animal, and fission yeast
RNA polymerase II enzymes contain 12 subunits that are related to the
12 subunits originally identified in S. cerevisiae (10,
16) (Table 2). The sequence
comparison indicated that the S. pombe Rpb4 protein is
similar to the corresponding subunits from humans and plants in
structure in the following ways. (i) The size of subunit 4 from higher
eukaryotes and S. pombe is 60 to 65% of the size of
S. cerevisiae RPB4. (ii) The RPB4 homologues from higher
eukaryotes and S. pombe lack several segments of the sequence which are present in the S. cerevisiae RPB4,
including the highly charged 70-like sequence in the
central portion of RPB4 (28).
In concert with the structural difference, the RPB4 homologues from
higher eukaryotes and S. pombe are different from the S. cerevisiae RPB4 in function in the following ways. (i)
RPB4 is weakly associated with the S. cerevisiae RNA
polymerase II, while the RPB4 homologues are tightly associated with
the RNA polymerase II from S. pombe (this report) and higher
eukaryotes (10, 15). (ii) The stoichiometric amounts of RPB4
homologues are bound with the RNA polymerase II from S. pombe and higher eukaryotes, while the S. cerevisiae
RNA polymerase II fraction containing RPB4 is only about 20% of the
total RNA polymerase II from the growing cells. (iii) S. pombe Rpb4 is essential for cell growth as analyzed by gene
disruption (this report).
The RPB4 homologue from humans does not form stable complexes with the
S. cerevisiae RPB7, as evidenced by the yeast two-hybrid assay (10). In agreement with this observation, the human
RPB4 homologue is able to substitute only partially for the S. cerevisiae RPB4 as detected by the complementation assay
(10). In sharp contrast with the human RPB4 homologue,
however, the hybrid dimers are formed in heterologous combinations
between S. pombe Rpb4 and S. cerevisiae RPB7 and
between S. cerevisiae RPB4 and S. pombe Rpb7,
indicating that the S. pombe Rpb4 is closer in function to
the S. cerevisiae RPB4. This finding also imply that the
extrasequence segments present only in the S. cerevisiae
RPB4 (Fig. 1) are not involved in the RPB4-RPB7 dimerization. Instead,
an as-yet-unidentified structural element, which is present in both
S. pombe Rpb4 and S. cerevisiae RPB4 but absent
in the RPB4 homologues from higher eukaryotes, may be involved in the dimerization.
RPB4 is present in the S. cerevisiae cells in excess over
the RNA polymerase II during all growth phases, but its affinity to the
RNA polymerase II is weak in the exponential growth phase (19). The defective activity of the RPB4-depleted S. cerevisiae mutant cell extract at the nonoptimal temperature can
be rescued by the addition of RPB4 subunit from the heated
RPB1 mutant cell extract (19). However, this in
vitro complementation can be observed only when the RPB4 mutant extract
was prepared from the stationary-phase cells. Thus, it appears that the
S. cerevisiae RNA polymerase II is modified in the
stationary phase so as to recruit the RPB4 subunit. The RNA polymerase
II from animals, plants, and the fission yeast might be fixed at the
form which is capable of accepting subunit 4. The S. cerevisiae RNA polymerase II, saturated with RPB4, from cells
under stress conditions forms high-quality two-dimensional crystals
(1, 9). The S. pombe RNA polymerase II, which is
tightly associated with Rpb4 even under normal growth conditions, could
be a good tool for analysis of three-dimensional structure of the RNA
polymerase II.
| |
ACKNOWLEDGMENTS |
We thank Pierre Thuriaux and Olivier Gadal (CEA-Saclay) for the
c337 cosmid sequence, Richard Young (MIT) for the S. cerevisiae RPB4 and RPB7 clones, Susumu Ueda and Akira Iwata
(Nippon Institute for Biological Science) for preparation of
anti-Rpb4CH antibodies, and H. Suzuki for technical support.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Molecular Genetics, National Institute of Genetics, Mishima, Shizuoka 411-8540, Japan. Phone: 81-559-81-6741. Fax: 81-559-81-6746. E-mail: aishiham{at}lab.nig.ac.jp.
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Top
Abstract
Introduction
