(Received for publication, September 4, 1996)
From the Department of Biological Chemistry, School of Medicine,
University of California, Davis, California 95616 and the
Department of Biochemistry, School of Medicine, Case
Western Reserve University, Cleveland, Ohio 44106-5635
The largest of the mammalian translation
initiation factors, eIF3, consists of at least eight subunits ranging
in mass from 35 to 170 kDa. eIF3 binds to the 40 S ribosome in an early
step of translation initiation and promotes the binding of
methionyl-tRNAi and mRNA. We report the cloning and
characterization of human cDNAs encoding two of its subunits, p110
and p36. It was found that the second slowest band during
polyacrylamide gel electrophresis of eIF3 subunits in sodium dodecyl
sulfate contains two proteins: p110 and p116. Analysis of the cloned
cDNA encoding p110 indicates that its amino acid sequence is 31%
identical to that of the yeast protein, Nip1. The p116 cDNA was
cloned and characterized as a human homolog of yeast Prt1, as
described elsewhere (Méthot, N., Rom, E., Olsen, H., and
Sonenberg, N. (1997) J. Biol. Chem. 272, 1110-1116). p36
is a WD40 repeat protein, which is 46% identical to the p39 subunit of
yeast eIF3 and is identical to TRIP-1, a phosphorylation substrate of
the TGF- type II receptor. The p116, p110, and p36 subunits localize
on 40 S ribosomes in cells active in translation and
co-immunoprecipitate with affinity-purified antibodies against
the p170 subunit, showing that these proteins are integral components
of eIF3. Although p36 and p116 have homologous protein subunits in
yeast eIF3, the p110 homolog, Nip1, is not detected in yeast eIF3
preparations. The results indicate both conservation and diversity in
eIF3 between yeast and humans.
The initiation phase of eukaryotic protein synthesis is rate-limiting for most mRNAs and is frequently the site of translational control (1). The pathway of initiation involves dissociation of the 80 S ribosome into 40 S and 60 S ribosomal subunits, the binding of the initiator Met-tRNAi and mRNA to the 40 S ribosomal subunit, and subsequent junction of the 60 S ribosomal subunit to form an 80 S initiation complex. The reactions are promoted by at least 10 proteins called eukaryotic initiation factors (eIF),1 which have been purified and characterized biochemically (see Ref. 2 for a recent review). The largest of these, eIF3, is a complex of eight or more polypeptides and plays a central role in the initiation pathway. eIF3 binds to 40 S ribosomal subunits in the absence of other translational components and helps maintain 40 S and 60 S ribosomal subunits in a dissociated state. It interacts with the ternary complex of eIF2·GTP·Met-tRNAi and prevents its destabilization caused by RNA (3). eIF3 stabilizes Met-tRNAi binding on 40 S ribosomal subunits and is absolutely required for the binding of mRNA to 40 S and 80 S ribosomes when evaluated in vitro with purified translational components (4, 5). Furthermore, eIF3 associated with 40 S subunits may be directly involved in the initial stages of mRNA binding. The eIF4G subunit of the cap-binding complex, eIF4F, binds to eIF3 (6), as does eIF4B, a factor involved in RNA helicase activity (7).
A detailed understanding of the molecular events of initiation of protein synthesis benefits from a knowledge of the primary sequences of the initiation factors. Of the ~25 polypeptides comprising the initiation factors, cDNAs encoding all of them have been cloned and sequenced except for the subunits of eIF3 and the eIF6 polypeptide (reviewed in Ref. 2). Purified eIF3 has been characterized as a complex of eight nonidentical subunits, called p170, p115, p66, p47, p44, p40, p36, and p35 (4, 8, 9). The subunits co-purify during numerous fractionation procedures, although the p35 subunit appears to dissociate partially during nondenaturing gel electrophoresis (8). The p66 subunit is a strong RNA-binding protein (10), but the functions of the other subunits are not known.
Insight into the function of eIF3 comes from studies of the corresponding initiation factor in yeast. Yeast eIF3 has been purified on the basis of its stimulation of methionyl-puromycin synthesis in an assay composed of mammalian components that requires the formation of 80 S initiation complexes (11). The active yeast eIF3 preparation contains eight major polypeptides, called p135, p90, p62, p39, p33, p29, p21, and p16. That the yeast factor can replace mammalian eIF3 in the methionyl-puromycin synthesis assay indicates strong conservation of function.
The availability of purified yeast eIF3 led to the identification of genes encoding three of its subunits and characterization of their mutant forms has shed light on the function of the factor. p90, p62, and p16 are encoded by PRT1 (11), GCD10 (12), and SUI1 (13), respectively. A conditional lethal mutation in PRT1 was isolated (14), which shows a defect in Met-tRNAi binding to ribosomes (15). GCD10 was isolated as a gene whose mutations constitutively derepress the expression of GCN4 in rich medium (16). This gcd phenotype for p62 is consistent with the proposed role of eIF3 in stabilizing Met-tRNAi binding to 40 S subunits. Gcd10/p62 also is an RNA-binding protein and therefore might correspond to mammalian p66 (12). Mutant forms of SUI1 were identified from a genetic screen for proteins that affect initiator codon recognition and allow initiation at a UUG codon (17). SUI1 encodes p16, which implicates eIF3, along with eIF2, in initiation codon recognition. However, p16/Sui1 exists both in the eIF3 complex and as a free form (13). Since a mammalian homolog of Sui1 corresponds to the poorly characterized initiation factor eIF1 (18), which is not thought to be a component of mammalian eIF3, p16/Sui1 may perform more than one function in yeast. A fourth gene, TIF34, encoding the p39 subunit, has been cloned and characterized recently2 and appears to be required for the integrity of the entire eIF3 complex. Work is in progress to clone the remaining genes for yeast eIF3 subunits.
We report here the cloning and characterization of cDNAs encoding two of the human eIF3 subunits, namely p36 and p110. The eIF3-p36 subunit is homologous to the yeast p39 subunit. eIF3-p110 is one of two proteins found in the previously described p115 band and is related to the yeast protein, Nip1 (20). The other protein in the p115 band, eIF3-p116, is a homolog of yeast Prt1 (36). We discuss the conservation and divergence of eIF3 subunit structures between mammals and yeast.
eIF3 was prepared from human HeLa cells essentially as described previously (21), except that ion exchange chromatography employed FPLC (Pharmacia Biotech Inc.) Mono Q and Mono S columns. The polyclonal antiserum against rabbit reticulocyte eIF3 was prepared in a goat and was characterized previously (22).
Affinity Purification of AntibodiesHeLa eIF3 (100 µg)
was subjected to electrophoresis in a 7.5% polyacrylamide gel
containing SDS (23) and transferred to a nitrocellulose membrane
(AB084, Schleicher & Schuell). The membrane was stained with Ponceau S
to locate eIF3 proteins and then washed with water. After incubation at
room temperature for 3 h with 5 ml of Blotto (0.01 M
Tris-HCl, pH 7.4, 0.15 M NaCl, 0.075% Tween 20, 0.5%
dried milk) containing 200 µl of crude goat anti-eIF3 polyclonal
antiserum, the membrane was washed with TST (0.01 M Tris-HCl, pH 7.4, 0.15 M NaCl, 0.075% Tween 20), and
portions that contained eIF3 subunits were excised. Antibodies bound to the excised membrane pieces containing the p170 and p115 bands were
eluted with a low pH buffer (2 M glycine, 1 mM
EGTA, pH 2.5) for 30 min. The resulting affinity-purified anti-p170 and
anti-p115 antibodies were neutralized by addition of 1 M
Tris-HCl, pH 8.8, diluted with one volume of Blotto and stored frozen
at 80° C.
For affinity purification with recombinant eIF3-p116 (hPrt1), eIF3-p110 and eIF3-p36, 1-3 mg of Escherichia coli lysate expressing their respective cDNAs (see below) was fractionated by SDS-PAGE. The bands containing the recombinant proteins were excised and antibodies in the crude goat anti-eIF3 antiserum were affinity-purified as described above. In the case of the anti-p116 antibody, 50 µg of GST-p110 fusion protein immobilized on a nitrocellulose membrane chip was included in the incubation to remove anti-p110 antibodies whose high titer otherwise would seriously contaminate the anti-p116 antibody preparation.
Screening the Human HeLa cDNA LibraryAbout 1 × 105 bacteriophages from a human HeLa cDNA library in
gt11 (Clontech) were grown on a lawn of E. coli
Y1090/150-mm plate. Twenty plates were screened according to the method
described in Ref. 24 with affinity-purified anti-p115 antibody. Bound antibodies were detected by incubating the filters with rabbit anti-goat IgG antibodies conjugated with alkaline phosphatase (Sigma), followed by treatment with nitro blue
tetrazolium as recommended by the manufacturer. Putative positive
plaques were picked and rescreened until purified. Thirteen
immunopositive phages were obtained. The sizes of the inserts were
determined by the polymerase chain reaction (PCR) with
gt11 primers,
FW 5
-GGTGGCGACGACTCCTGGAGCCCG-3
and RV
5
-TTGACACCAGACCAACTGGTAATG-3
, which flank the EcoRI
cloning site, and restriction sites were mapped. Two phages containing
the longest related inserts (~3.0 kb), called 11a and 19a, were
selected and their DNAs were prepared as described (25). Since the
EcoRI sites in the phage DNAs were lost, the SplI sites
flanking the inserts were used instead, and 3.3-kb SplI fragments were
subcloned into the Asp718I site of pTZ19R (26). The resulting plasmids
are called pTZp110-11a and pTZp110-19a, respectively. The 5
ends of
the cDNA inserts were sequenced and clone 11a was found to be 68 bp
longer at the 5
end. For sequencing clone 11a on both strands,
deletions were constructed from pTZp110-11a with restriction enzymes
NdeI, BamHI and SphI, which cleave at
0.3, 1.7, and 1.8 kb from the 5
end, respectively, and with
PstI, which cleaves both at 2.0 and 2.6 kb, and the
remaining portions were sequenced with eight custom-made primers.
eIF3 (100 µg) purified from rabbit reticulocytes was applied to a standard SDS gel (15% acrylamide, 0.2% bisacrylamide), and individual subunits were resolved by electrophoresis at 30 milliamps for 3 h. The subunit bands were transferred to Immobilon-P (Millipore) in 10 mM sodium phosphate, pH 12, 10% methanol for a period of 1 h at 60 V. The membrane was stained with Coomassie Brilliant Blue R-250 to identify protein bands, then fully destained in 50% methanol, 10% acetic acid. The membrane was rinsed several times with distilled water, and individual bands containing the p36 subunit were excised. The excised strips were subjected to automated amino acid sequencing with an Applied Biosystems Inc. model 477A protein microsequencer with an on-line phenylthiohydantoin analyzer in the Molecular Biology Core Laboratory at Case Western Reserve University. Internal peptide sequences were obtained by trypsin digestion of the protein in the p36 band, high performance liquid chromatography purification, and sequencing essentially as described (27).
Sequences in the expressed sequence tag (EST) data base that match the
NH2-terminal amino acid sequence were sought in the National Center for Biomedical Information data base by using the GCG
BLAST program. One of the identified ESTs, clone obb04, was kindly
provided by Genethon, Evry, France. Clone obb04 from a human infant
brain cDNA library contains a 1.4-kb insert cloned into the
HindIII (5) and NotI (3
) sites of lafmid BA,
derived from pEMBL (28). Lafmid BA has an EcoRI site next to
the NotI site and the annealing sites for standard M13
primers in the regions flanking these cloning sites. For
dideoxynucleotide DNA sequencing, deletions in the insert were
constructed by digestion with BamHI or HindIII,
which cleave the insert at 0.4 and 0.7 kb from the 5
end,
respectively. The remaining portions of both strands were sequenced
with three custom-made primers.
Total RNA was isolated (29) from HeLa cells, which were grown exponentially to a density of 5 × 105 cells/ml in spinner flasks. Poly(A)+ RNA was isolated from total RNA, and Northern blotting was conducted as described previously (30) with radioactive probes derived from pTZp110-11a (PCR-amplified with the M13 forward and reverse primers) and obb04 (1.4-kb HindIII-EcoRI fragment). Hybridizing bands were visualized by autoradiography.
Overexpression of Recombinant p110 and p36 in Escherichia coliA 2.9-kb NdeI-EcoRI fragment of
pTZp110-11a (the EcoRI site is located 3 to the insert in
the multiple cloning site of pTZ19R), which lacks 314 bp including the
initiator AUG at the 5
end, was subcloned into the corresponding sites
of pT7-7 (31). The resulting plasmid, pT7p110(NdeI) was
introduced into E. coli strain DH5
carrying pGP1-2 and
expression was heat-induced as described (31). The size of the protein
product is shorter than the full-length p110 protein, since initiation
likely occurs at the internal AUG codon (Met-130, preceded by a good
Shine-Dalgarno sequence) because the AUG in the NdeI site is
out-of-frame. To construct pGEXp110 for expression of the GST-p110
fusion protein, the 5
-terminal half of the p110 coding region was
amplified from pTZp110-11a with primers
5
-CCCGAATTCCAT
TCGCGGTTTTTCACC-3
(tagged by
EcoRI and NdeI sites; the bases corresponding to
the initiator codon are underlined) and 5
-TGTTCCCGCATGGACTC-3
(base
pairs 2256-2240 in the sequence reported in GenBankTM: U46025[GenBank]). The
resulting 1.6-kb DNA fragment was digested with EcoRI and
BamHI, subcloned into pTZ19R to yield pTZp110N, and
sequenced. The 1.6-kb EcoRI-BamHI fragment of
pTZp110N was ligated to the 1.6-kb BamHI-EcoRI
fragment of pTZp110-11a, which contains the COOH-terminal half of the
p110 reading frame and to the EcoRI-digested
pGEX-2T[128/129] (32). A plasmid with the correct orientation was
identified and is called pGEXp110.
For expression of a p36-GST fusion protein, the 5 end of the p36
coding region was modified by PCR amplification of obb04 DNA with
primers 5
-CCCGAATTCCAT
AAGCCGATCCTACTG-3
(tagged by
EcoRI and NdeI sites; the bases corresponding to
the initiator codon are underlined) and the M13 reverse primer.
Amplified DNA was digested with EcoRI and subcloned into
pGEX-2T[128/129] to generate plasmid pGEXp36. E. coli
BL21(DE3) was transformed individually with plasmids pGEXp110 and
pGEXp36, and synthesis of the fusion proteins was induced with IPTG as
recommended by the manufacturer. The proteins were purified from
E. coli cell lysates by using glutathione-Sepharose 4B resin
(Pharmacia) as recommended by the manufacturer. In the case of p110,
cells were harvested early at 10 min after induction because the fusion
protein is unstable.
The
1.6-kb NdeI-BamHI fragment from pTZp110N was used
to replace the 1.4-kb NdeI-BamHI fragment of
pT7p110(NdeI) to generate plasmid pT7p110. Plasmid pTZp36
was constructed by subcloning the 1.4-kb
HindIII-EcoRI fragment of obb04 into pTZ19R.
pT7p110 and pTZp36 were transcribed and translated in vitro
with the T7 TnT-coupled reticulocyte lysate system (Promega) and
[35S]methionine. Reaction mixtures were incubated at
30 °C for 90 min, and an aliquot of the mixture was fractionated by
SDS-PAGE. Gels were stained, dried, and exposed to x-ray film at
80 °C for 16-32 h.
Two-dimensional gel analyses followed procedures described previously (33), with minor modifications. Briefly, 2 µg of HeLa eIF3 was subjected to isoelectric focusing in the first dimensional gel (4% acrylamide, 0.1% piperazine diacrylamide (Bio-Rad), 1.5% CHAPS (Boehringer Mannheim), 1.5% Nonidet P-40 (Pierce), 4% ampholytes, 9.8 M urea] at 3500 V-h with 25 mM histidine as the cathode buffer and 25 mM phosphoric acid as the anode buffer. The ampholytes were two-thirds pH 5-7 and one-third pH 3-10 (Serva). The second dimension employed a 7.5% polyacrylamide gel in SDS (23).
Polysome Profile AnalysesCOS-1 cells freshly fed with serum were lysed with buffer containing 20 mM HEPES-KOH, pH 7.5, 100 mM KCl, 10 mM magnesium chloride, 1 mM dithiothreitol, 0.25% Nonidet P-40, 1 µg/ml leupeptin, 2 µg/ml pepstatin, and 10 µg/ml cycloheximide with 10 strokes of a narrow gauge syringe. The lysate was clarified by centrifugation and an aliquot (10 A260 units) was layered on a 15-45% (w/v) sucrose gradient in detergent-free lysis buffer. After centrifugation at 4 °C in a Beckman SW60 rotor for 1 h at 50,000 rpm, 13 gradient fractions were collected by bottom puncture and upward displacement with an Isco gradient fractionator and scanned for absorbance at 254 nm with a UV monitor. Protein in the fractions was concentrated by trichloroacetic acid precipitation, and aliquots were analyzed by SDS-PAGE and immunoblotting.
Co-immunoprecipitationsHeLa eIF3 (0.5 µg) purified through the Mono Q column step was incubated on ice for 1 h with crude goat anti-eIF3 antiserum or affinity-purified anti-p170 antibodies in 50 µl of buffer A (30 mM HEPES-KOH, pH 7.6, 100 mM potassium acetate, 3 mM magnesium acetate, 1 mM dithiothreitol, 1 mM aminoethyl-benzenesulfonyl fluoride (AEBSF, Calbiochem)) containing 1 mg/ml bovine serum albumin. Anti-p170 antibody and crude anti-eIF3 antiserum were used in amounts that gave the same p170 band intensity upon Western blotting. As controls, an equal amount of the preimmune serum or no antiserum also were used. The immune complexes were incubated with Gamma Bind G Sepharose beads (Pharmacia) at 4 °C for 1 h with rocking, and the beads were washed three times with 100 µl of buffer A containing 0.1% Triton X-100, and once with 100 µl of 62.5 mM Tris-HCl, pH 6.8. Beads were resuspended in SDS sample buffer, and the eluted proteins were fractionated by SDS-PAGE (23). About 60% of the eIF3 was immunoprecipitated with anti-eIF3 antiserum under these conditions.
A goat
antiserum raised against rabbit eIF3 recognizes eight subunits in the
multiprotein complex (22). The strongest antigen gives rise to a broad
band or doublet at about 115 kDa when HeLa eIF3 is analyzed by SDS-PAGE
and immunoblotting (34) (see also Fig. 2A, lane
4). Antibodies recognizing the p115 protein(s) were affinity-purified and used to screen a gt11 expression library containing HeLa cDNAs as described under "Experimental
Procedures." Among the 2 × 106 plaques screened, 13 positives were identified and plaque-purified. Insert sizes were
determined by PCR analysis with primers that flank the cloning site in
the phage. The two largest inserts, called 11a and 19a, were subcloned
into pTZ19R and sequenced on both strands as described under
"Experimental Procedures." Clone 11a, called pTZp110, contains an
insert of 2945 bp, whereas clone 19a is somewhat shorter, with 2877 bp.
Clone 11a was named pTZp110 rather than pTZp115, because the p115 band
from which the antibodies were purified contains two proteins with
apparent masses of 116 and 110 kDa, as explained below.
The DNA sequence in pTZp110 contains an open reading frame of 2739 bp
that encodes a protein of 913 amino acid residues with a calculated
mass of 105,277 Da and a pI of 5.41. The sequence context surrounding
the first AUG, GCCAUGU, compares favorably to the consensus sequence
for moderately strong initiator AUGs (35); furthermore, the AUG is
preceded by an in-frame TGA termination codon in the 5-UTR. Thus, this
AUG very likely serves as the initiator codon, as discussed below. The
amino acid sequence derived from the open reading frame is shown in
Fig. 1 (labeled human p110); the DNA sequence is not
shown but is deposited in the GenBankTM data base with accession number
U46025[GenBank]. The 5
-UTR in the cDNA insert contains 49 bp, whereas the
3
-UTR has 89 bp and ends with a string of 48 A residues preceded by an
ACTAAA sequence, which may possibly serve as the polyadenylation
signal. Northern blot analysis of poly(A)+ RNA from HeLa
cells generates a single band of 3.0 kb (results not shown), suggesting
that pTZp110 contains a nearly full-length cDNA.
The sequence of the cDNA insert was compared with other known
sequences by searching the EST data base. The cDNA was found to
match identical or near-identical (>95%) partial DNA sequences in
ESTs from numerous human tissues, as shown in Table I.
The 72 matches found in all tissues represent about 0.02% of the total EST entries examined. Three independent human ESTs (H27714, H27960, and
D81864) overlap and match the 5-end of the insert in pTZp110, ruling
out the possibility that foreign DNA fused to the
NH2-terminal coding region of the 11a cDNA during
construction of the library. The frequency and wide distribution of
ESTs matching pTZp110 indicate that p110 is likely expressed in all
cells as a moderately abundant protein.
|
A COOH-terminal portion of the cDNA insert in pTZp110 carrying about 85% of the coding region was subcloned into a bacterial expression vector and introduced into E. coli as described under "Experimental Procedures." Shortly after heat induction, a 90-kDa protein was overexpressed but then disappeared at later times (data not shown). By lysing the cells at 10 min following induction, the 90-kDa protein was readily detectable upon SDS-PAGE and was used to affinity-purify antibodies from a crude goat anti-eIF3 antiserum. The resulting affinity-purified antibodies generate a single band with a mobility corresponding to a 110-kDa protein when either a HeLa lysate or purified human eIF3 is analyzed by Western blotting (Fig. 2A). Further evidence that pTZp110 encodes a subunit of eIF3 was obtained by in vitro transcription of the entire cDNA insert coupled with translation in a rabbit reticulocyte lysate as described under "Experimental Procedures." The resulting 35S-labeled proteins were subjected to analysis by SDS-PAGE and autoradiography as shown in Fig. 2B. A single major band of 110 kDa was detected. Since the size of the translation product and the protein detected in HeLa lysates by the affinity-purified antibodies is the same, this supports the view that the cDNA contains the entire coding region for a 110-kDa subunit of eIF3 (named eIF3-p110). Further evidence that the eIF3-p110 cDNA encodes a subunit of eIF3 is provided below.
eIF3-p110 Is Homologous to the Yeast Protein Nip1A search of EST sequences that are related to eIF3-p110 reveals homologs in rat, mouse, Caenorhabditis elegans, and Arabidopsis thaliana. The amino acid sequences derived from the rat and mouse ESTs (rat, H31971[GenBank], H34067[GenBank], H34777[GenBank], H34840[GenBank]; mouse, Z36299[GenBank]) show 97-100% identity to the corresponding regions of eIF3-p110, whereas those from C. elegans (D36264, D36431, D36784, D36806, D37362, and D37595) show 38-58% identity and from A. thaliana (T13976 and T88395), 48 and 60% identity. The eIF3-p110 sequence is 30.9% identical and 44.1% similar to the yeast Nip1 sequence ((20); see Fig. 1), but is not related to Prt1, which is reported to be the second largest subunit in the yeast eIF3 preparation (11) and therefore was presumed to be the homolog of the mammalian protein in the p115 band. No obvious peptide motif was found for either the mammalian or yeast proteins by the GCG MOTIFS program. However, it is noteworthy that the NH2-terminal third of both Nip1 and eIF3-p110 is hydrophilic and is also rich in serine, aspartate, and glutamate, as shown by bold letters in the sequence shown in Fig. 1. Nip1 was originally identified as a protein involved in nuclear import (20), but it may also play a role in the initiation phase of protein synthesis since a conditional mutant strain altered in NIP1 exhibits reduced polysomes and increased 80 S ribosomes when shifted to a nonpermissive temperature.4
eIF3-p116 Is the Human Homolog of Yeast Prt1While analyzing the components of HeLa eIF3, it was discovered that SDS-PAGE with a lower (7.5%) concentration of acrylamide than the usual 10% separates the p115 band into two components with apparent masses of 110 and 116 kDa (Fig. 2C, lane 1). Two components in the 115-kDa region of the gel were recognized earlier (22) but were thought to be due to limited proteolysis of the protein in the slower migrating band. The affinity-purified antibodies prepared against the recombinant p110 fragment described above recognize only the p110 band and not the p116 band (lane 2). During the course of this work, N. Méthot and N. Sonenberg (McGill University) identified human sequences in the data base of Human Genome Science Inc. that are homologous to yeast PRT1 and proceeded to clone a human cDNA encoding a Prt1 homolog (hPrt1). They constructed a fusion of GST DNA with the major part of the hPrt1 cDNA coding region and expressed a 120-kDa protein in E. coli (36). Using the E. coli lysate kindly provided by N. Méthot and N. Sonenberg, we affinity-purified antibodies from the goat anti-eIF3 antiserum that bound to the 120-kDa fusion protein. The affinity-purified antibodies recognize the 116-kDa band in eIF3 (Fig. 2C, lanes 3 and 4) and react most strongly with a ca. 116-kDa protein in HeLa lysates (lane 5). Because the titer of antibodies that recognize p116 is quite low, a high concentration of the affinity-purified antibody preparation is needed and cross-reaction with other proteins in the lysate is apparent. We conclude that both p110 (the homolog of Nip1) and p116 (hPrt1) are present in HeLa eIF3.
To further characterize and differentiate the p116 and p110 subunits of
eIF3, we conducted two-dimensional IEF/SDS-PAGE analyses of purified
eIF3. eIF3 proteins in the 115-kDa region of such gels are known to
focus into two spots or streaks at about pI = 5.2 and 6.5 (37,
34). When purified HeLa eIF3 was fractionated by the two-dimensional
gel system, followed by immunoblotting with antibodies
affinity-purified against recombinant p110 and p116, it was observed
that the anti-p110 antibodies recognize a spot with a pI of 5.8, whereas the anti-p116 antibodies recognize two streaky spots with pIs
of 4.8 to 5.0 (Fig. 3). Thus p116 is more acidic than
p110, consistent with their calculated pIs, and exhibits two
isoelectric variants that might be due to phosphorylation (see
"Discussion").
Cloning and Characterization of a cDNA Encoding eIF3-p36
The titer of antibodies against the p36 subunit in the
goat anti-eIF3 antiserum appears quite low (Fig. 2A,
lane 4). Rather than using antibodies to screen for p36
cDNA in an expression library, we relied on partial amino acid
sequencing of the p36 subunit from rabbit reticulocyte eIF3 to clone
the cDNA. NH2-terminal sequencing was carried out as
described under "Experimental Procedures," and a 20-residue
sequence was obtained: MKPILLQGHER(S/C)ITQIKYNR. ESTs that match the
sequence were sought by searching the data base, and 13 ESTs were found
that match perfectly. One of the longest of the ESTs, a 1444-bp
cDNA clone called obb04, encodes a 325-residue protein with a
calculated mass of 36,502 Da, which is essentially identical to the
apparent mass of p36 determined by SDS-PAGE. The obb04 cDNA was
kindly provided by Genethon (Evry, France) and was subcloned into
pTZ19R to generate pTZp36 as described under "Experimental
Procedures." The initiator codon is identified unambiguously by the
NH2-terminal sequence and lies in a favorable context,
namely GGGA. There are 17 nucleotides upstream of this
AUG, and an in-frame termination codon downstream at position 993-995.
The 975-bp coding region and termination codon is followed by a 3
-UTR
of 406 nucleotides and a string of 43 A residues. Two AAUAAA
polyadenylation signals are found beginning at positions 1366 and 1382. Northern blot hybridization of HeLa poly(A)+ RNA with the
obb04 probe generates a single band corresponding to an RNA of 1.6 kb
(results not shown), consistent with its encoding a 36-kDa protein.
To demonstrate that the cDNA in pTZp36 encodes the p36 subunit of
eIF3, antibodies specific for p36 were prepared as described under
"Experimental Procedures." Briefly, the coding region of the pTZp36
insert was subcloned into a derivative of pGEX-2T and the resulting
GST-p36 fusion protein was expressed in E. coli. Antibodies
in the goat anti-eIF3 antiserum were affinity-purified with the
recombinant GST-p36 protein band following SDS-PAGE of the E. coli lysate proteins. The affinity-purified antibodies recognize a
single major antigen in preparations of purified eIF3 and in HeLa cell
lysates which corresponds to a protein of 36-kDa (Fig. 2A,
lanes 5 and 6). Furthermore, when the cDNA in
pTZp36 is transcribed and translated in vitro in a
reticulocyte lysate, the only product is a 36-kDa protein that migrates
during SDS-PAGE with the same mobility as eIF3-p36 (Fig. 2B,
lane 2). Finally, two internal peptide sequences match the
cloned cDNA, as shown by the boxed sequences in Fig.
4. We conclude that pTZp36 encodes eIF3-p36.
The amino acid sequence of eIF3-p36 was analyzed further. The observation that the amino terminus is not blocked is consistent with the second amino acid being lysine. General rules for modification of the amino terminus of a protein indicate that there should be no addition of an acetyl or other blocking group and that the initiating methionine should be retained when lysine follows the methionine (Huang et al., 1987). The theoretical isoelectric point of the protein is 5.38, although two-dimensional IEF/SDS-PAGE analysis (Fig. 3) indicates a somewhat more acidic protein (pI = 5.2). A ProSite search of the sequence identifies the following possible sites for post-translational modification: a single N-glycosylation site, eight protein kinase C and four casein kinase II phosphorylation sites, five N-myristoylation sites, and an ATP/GTP-binding motif A site. From information currently in hand, it is likely that none of these ProSite-identified post-translational modification sequences is of biological importance.
Comparison of the eIF3-p36 sequence with other proteins in the data
base shows a match to the -transducin family WD repeat signature
(38). Five WD repeat elements, and another two more degenerate
elements, are identified (underlined in Fig. 4A)
and compared to the consensus sequence (Fig. 4B, where
conserved residues in the eIF3-p36 sequence are indicated in
bold). The WD repeat elements are likely to be important in
the folding of p36, and are discussed in greater detail below. A search
of the data base also identifies a large number of ESTs derived from
many different human tissues that match to the eIF3-p36 sequence (Table
I). This indicates that the p36 cDNA is expressed as a housekeeping gene, and the frequency of appearance of the ESTs suggests a moderately abundant protein. The p36 subunit also shares 45.8% identity and 58.8% similarity with a 39-kDa protein in yeast, which was recently identified as the p39 subunit of yeast eIF3.2 The
relatedness of the mammalian and yeast proteins extends throughout their entire length (Fig. 4A) and is apparent in their WD
repeat elements (Fig. 4B). Besides the human ESTs listed in
Table I, the p36 cDNA sequence is homologous with 12 ESTs from
A. thaliana (accession numbers H36544[GenBank], H76382[GenBank], T13850[GenBank], T34639[GenBank], T42527[GenBank], T43638[GenBank], T46040[GenBank], T75627[GenBank], Z27523[GenBank], Z29843[GenBank], Z46547[GenBank], and
Z46548[GenBank]) whose translation products show 36 to 71% identity to
eIF3-p36. In addition, one EST each from rice and Zea mays
(D23414 and T23353) exhibits 66% identity in the COOH-terminal region
of the proteins.
Although the eIF3 subunits co-purify and all bind to 40 S ribosomes (8), there is some uncertainty whether or not all are truly components of eIF3 as opposed to copurifying contaminants. Furthermore, the fact that many of the subunits are sensitive to partial proteolysis, especially the p170 subunit (34), complicates characterization of the protein complex. Having affinity-purified antibodies to recombinant eIF3 subunits provides an important tool for assessing whether or not a subunit is present in the complex. We have used antibodies that were affinity-purified against recombinant p116, p110, and p36 to examine the presence of these proteins following fractionation of cell lysates by sucrose gradient centrifugation, ion exchange chromatography, and immunoprecipitation.
Serum-fed COS cells were lysed in the presence of cycloheximide, and
the lysate was analyzed by sucrose gradient centrifugation (Fig.
5). The eIF3 complex was localized by Western blotting
of gradient fractions with anti-eIF3 antiserum (panel A).
eIF3 is found essentially throughout the gradient, but localizes most strongly on 40 S ribosomal subunits. Its presence in the heavier regions of the gradient may be due to eIF3 binding to 40 S ribosomal subunits in the process of initiating translation on polysomes. The
same gradient fractions were analyzed with antibodies affinity-purified against recombinant p116, p110, and p36. All three patterns
(panel B) are similar to that with the crude anti-eIF3
antiserum (panel A), although the weaker reactions in the
heavier region of the gradient seen in panel A are not
detectable in panel B, likely because the antibody titers
are lower. Thus, the fraction containing primarily 40 S ribosomal
subunits generates the most intense immunoreactive band in all three
cases. The finding that each of the three subunits is most concentrated
in the 40 S region of the gradient supports the view that each is
involved in translation, most likely as a part of eIF3.
Further support for p116, p110, and p36 being subunits of eIF3 comes
from co-fractionation by FPLC with a Mono S (Pharmacia) ion exchange
column. Each of the three affinity-purified antibodies reacts with its
cognate protein in the same region where the other eIF3 subunits elute
(results not shown). Finally, eIF3 complexes were immunoprecipitated
with anti-eIF3 antiserum and with antibodies affinity-purified against
the p170 subunit (Fig. 6). Four major immunoreactive
eIF3 subunit bands (p170, p115, p47, and p35) are detected by SDS-PAGE
and Western blotting with anti-eIF3 in the anti-eIF3 precipitate
(panel A, lane 2), but not when a preimmune serum
was used (lane 3). When the anti-p170 precipitate was
analyzed (lane 4), bands corresponding to p170, p115, and
p47 are detected, but not the p35 band. Apparently, p35 either readily
dissociates upon immunoprecipitation with anti-p170 antibodies or is
not a true component of eIF3. The same immunoprecipitates were then tested for the presence of p116, p110, and p36. Analysis by Western blotting with antibodies affinity-purified against recombinant p116,
p110, and p36 (panel B) each detects its respective cognate subunit in the anti-eIF3 and anti-p170 precipitates, but not in the
"precipitates" generated by preimmune or no antibodies. The results
demonstrate that the three subunits are present in complexes with p170.
Attempts to precipitate the eIF3 complex with affinity-purified anti-p110 antibodies were not successful (panel C,
lane 4). Because the antibody immunoprecipitates the
GST-p110 fusion protein and its partial degradation products
(lane 5), its failure to immunoprecipitate eIF3 implies that
the p110 epitopes are masked or altered when the subunit is
incorporated in the eIF3 complex.
We have cloned and characterized cDNAs encoding human eIF3-p110 and eIF3-p36. The following facts establish the authenticity of the coding regions. The calculated masses of the proteins encoded by the two cDNAs, 105.4 and 36.5 kDa, are consistent with their assigned masses measured by SDS-PAGE. Transcription in vitro of the cDNAs and subsequent translation of the transcripts in reticulocyte lysates result in radiolabeled protein products that migrate in SDS-PAGE at precisely the same positions as the corresponding subunits in highly purified eIF3 or in crude HeLa cell lysates (Fig. 2B). Antibodies from a crude goat antiserum made against purified rabbit eIF3 that were affinity-purified against recombinant p110 and p36 overexpressed in E. coli specifically recognize the corresponding proteins in purified eIF3 (Fig. 2A). Furthermore, for the eIF3-p36 cDNA, an NH2-terminal and two internal partial amino acid sequences obtained from the 36-kDa subunit of rabbit eIF3 match the deduced amino acid sequence.
The initiator AUG codon for each cDNA also has been identified unambiguously. For p110, a possible upstream AUG is ruled out by the presence of an in-frame UAG codon 18 nucleotides upstream of the initiator AUG. The sequence for the initiator AUG and NH2-terminal coding region was obtained and confirmed by analysis of three independent EST cDNAs. For p36, the NH2-terminal peptide sequence establishes the initiator AUG assignment.
During the characterization of purified eIF3 preparations, we noticed that the p115 band can be resolved by SDS-PAGE into two distinct bands of similar intensity when stained with Coomassie Blue (Fig. 2C). Protein in the faster migrating band is named the p110 subunit whose cDNA is cloned here. This band is recognized by the affinity-purified antibodies prepared with recombinant p110. Protein in the slower migrating band is named the p116 subunit (or hPrt1), which reacts with antibodies affinity-purified against a recombinant protein fragment expressed from a cDNA that is homologous to yeast PRT1 (kindly provided by N. Méthot and N. Sonenberg). The two eIF3 subunits also are resolved by IEF/SDS-PAGE according to their isoelectric points, with p110 being more basic (Fig. 3). Although two similar proteins were resolved previously by IEF/SDS-PAGE, the more acidic protein was labeled "p115" and the more basic protein was apparently incorrectly believed to be a partial degradation product of the p170 subunit (34).
A number of lines of evidence indicates that p116, p110, and p36 are integral parts of the eIF3 complex. All three proteins are found in the 40 S region of sucrose gradients following sedimentation analysis of HeLa cell lysates. Each co-elutes with the other eIF3 subunits during ion exchange chromatography and are found in highly purified eIF3 preparations. Affinity-purified antibodies specific for eIF3-p170 precipitate p116, p110, and p36, thereby demonstrating that these proteins are present in complexes that contain p170. However, the data collected to date do not prove that a single type of eIF3 complex exists with all four proteins present in the same complex. It remains possible that there are different eIF3 complexes where, for example, either p110 or p116 is present, but not both, even though the apparent stoichiometry of p170, p116, and p110 is 1:1:1 (see Fig. 2C, lane 1). Attempts to demonstrate the simultaneous presence of p116 and p110 by immunoprecipitation with affinity-purified anti-110 antibodies were not successful, as these antibodies do not precipitate any of the eIF3 subunits, although they precipitate recombinant p110 from an E. coli lysate (Fig. 6).
Mammalian and yeast eIF3 are functionally conserved, inasmuch as the yeast complex functions nearly as well as mammalian eIF3 in an in vitro assay for methionyl-puromycin synthesis constructed with purified ribosomes and initiation factors (11). It is therefore not surprising that the human p116 subunit is homologous with the yeast p90 subunit, also called Prt1. In addition, the human p36 subunit shares 46% sequence identity with yeast eIF3-p39, although the human cDNA does not produce an active protein in yeast.2 Although the human p110 subunit is homologous with a yeast protein called Nip1, Nip1 is not found in highly fractionated preparations of yeast eIF3.5 Either Nip1 dissociates from yeast eIF3 during fractionation, or the human and yeast eIF3 complexes differ in this respect. Another difference concerns the p16 (Sui1) subunit of yeast eIF3, which is homologous to mammalian eIF1, although eIF1 is not found in preparations of mammalian eIF3. It is surprising that the apparent subunit composition of eIF3 from mammals and yeast differs in these respects, given the strong conservation of most of the other initiation factors (2). Future efforts to obtain eIF3 complexes through tagging of individual subunit proteins, rather than by classical purification methods, may result in a better determination of the composition of eIF3 from yeast and mammalian cells.
It is noteworthy that eIF3-p36 and the homologous yeast subunit, p39,
are members of the WD repeat family of proteins, as this has
implications for their function in eIF3. The structures of prototypical
WD repeat proteins, the -subunit of G proteins, have been solved
(39, 40, 41). The last three
-strands of the COOH-terminal WD repeat
make a continuous
-sheet with the first
-strand of the
NH2-terminal repeat, giving the protein a circular
structure called a
propeller. eIF3-p36 contains at least five WD
repeat elements (Fig. 4B) and in principle should be capable
of forming a
propeller. WD repeat proteins are thought to interact
with other proteins. For example, G
has been
implicated in promoting the assembly of macromolecular effector complexes (42). One may speculate that the p36 subunit acts as a core
subunit to which other eIF3 subunits bind. In support of this notion,
the yeast p39 subunit of eIF3 appears to be essential for maintaining
the integrity of the complex, as depletion of p39 results in diminished
levels of all of the eIF3 subunits.2
The primary structure of eIF3-p36 is identical to a protein called
TRIP-1 (19). TRIP-1 cDNA transfection of mammalian cells does not
result in accumulation of the protein to levels much higher than those
found in untransfected cells, a result reminiscent of that with the
yeast homolog, eIF3-p39.2 TRIP-1 was identified in a yeast
two-hybrid selection as a protein that associates with the TGF- type
II receptor. The association was also demonstrated by
coimmunoprecipitation of the tagged proteins. Since TRIP-1 is
phosphorylated by the activated receptor, the results suggest that eIF3
is a phosphorylation target of the TGF-
type II receptor. However,
the antibodies that precipitate TRIP-1 or TGF-
type II do not
coprecipitate other proteins such as the other subunits of eIF3 (19).
It is therefore possible that the entire eIF3 complex does not
associate with the receptor. Alternatively, the presence of the tag on
TRIP-1 may have prevented the protein's assembly into eIF3 complexes.
A third possibility is that eIF3-p36 may play a functional role as a
free protein apart from eIF3, as appears to occur for the yeast eIF3
subunit, p16/Sui1 (13). Finally, it is possible that the eIF3 complex
is the true target of the TGF-
type II receptor, but its association
with eIF3 complexes is not sufficiently stable to persist during the
immunoprecipitations. Further work is required to better elucidate the
function of eIF3-p36 and its unexpected association with a membrane
receptor.
The nucleotide sequence(s) reported in this paper has been submitted to the GenBankTM/EMBL Data Bank with accession number(s) U46025[GenBank] and U39067[GenBank].
We thank Michael A. Blanar for the plasmid pGEX-2T[128/129], and Nathalie Méthot and Nahum Sonenberg for providing E. coli extracts that have expressed the p116 (hPrt1) protein and for conveying their results prior to publication. We also thank Susan MacMillan for purified eIF3, Elena Davydova for growing the COS-1 cells and performing the polysome gradients, and Chia-Lin Wei for preparing poly(A)+ RNA for the Northern blots.