(Received for publication, March 5, 1997, and in revised form, March 17, 1997)
From the Department of Biochemistry, University of Illinois, Urbana, Illinois 61801
RNA-binding proteins containing KH domains are
widely distributed. One KH domain protein of unknown function, vigilin
(also known as the high density lipoprotein-binding protein), contains 14 KH domains and is ubiquitous in vertebrate cells. We previously used
RNA gel mobility shift assays to describe an estrogen-inducible protein
which binds specifically to a segment of the 3-untranslated region
(3
-UTR) of vitellogenin mRNA, an area which has been implicated in
the estrogen-mediated stabilization of vitellogenin mRNA. Here we
show that the vitellogenin mRNA-binding protein (VitRNABP) is
vigilin. The VitRNABP was isolated as a 150-155-kDa protein on a
vitellogenin mRNA 3
-UTR affinity column. Peptide microsequencing revealed that the purified protein was vigilin, a conclusion confirmed in Western blot analysis with antibodies to vigilin. Direct
confirmation that vigilin is the VitRNABP was obtained from RNA gel
mobility shift assays which demonstrated that antibodies to chicken
vigilin supershifted the Xenopus VitRNABP band.
Xenopus liver vigilin mRNA and the VitRNABP exhibited
similar induction by estrogen, providing additional confirmation that
vigilin is the estrogen-inducible protein which binds to the 3
-UTR of
estrogen-stabilized vitellogenin mRNA. These data support a role
for vigilin in the hormonal control of mRNA metabolism.
Post-transcriptional events including nuclear RNA processing and
export, localization of RNA within the cell, degradation and
stabilization of RNAs, and mRNA translation are increasingly seen
as important cellular regulatory sites, whose alteration can contribute
to disease states. These processes are largely mediated by RNA-binding
proteins (1). One important and widely distributed class of RNA-binding
proteins contains K homology (KH)1 domains
(2). This class of proteins includes such biologically significant KH
domain-containing proteins as the FMR protein, which is involved in
Fragile X mental retardation (3), the Drosophila bicaudal C
protein which is important in development (4), and the
-poly(C)-binding protein which is found in the
-globin mRNA
ribonucleoprotein complex (5). One notable but little understood KH
domain protein is vigilin (also identified as the human high density
lipoprotein-binding protein, HDL-BP), a ubiquitous, highly conserved
protein with 14 KH domains (6, 7). Since vigilin has been found in all
cell lines and tissues examined (8), appears to be regulated by diverse
factors (7-11), and its 14 KH domains represent the largest number of
KH domains in any known protein (3, 12), it likely plays an important role in RNA metabolism. While vigilin has been used as a model protein
in solving the structure of a KH domain uncomplexed to RNA (12), its
RNA binding properties have been elusive, and its function(s) have
remained obscure.
We have been studying a protein which binds to a segment of the
3-untranslated region (3
-UTR) of the mRNA encoding the egg yolk
precursor protein, vitellogenin. In male Xenopus liver,
vitellogenin mRNA levels increase >10,000-fold following estrogen
administration (13, 14). The estrogen-mediated induction of
vitellogenin mRNA is brought about both by an increase in the rate
of vitellogenin gene transcription and by stabilization of cytoplasmic
vitellogenin mRNA (13, 14). Hepatic vitellogenin mRNA is
degraded with a half-life of 16 h in the absence of estrogen, and
500 h following addition of estrogen to the culture medium (14).
The estrogen-mediated stabilization of vitellogenin mRNA requires
association of the mRNA with ribosomes (15) and involves the 3
-UTR
of the mRNA (16). We identified a protein which binds specifically
to a segment of the 3
-UTR of vitellogenin mRNA in an
estrogen-inducible manner and named it the vitellogenin mRNA
3
-UTR-binding protein (VitRNABP) (17, 18). Here we describe the
isolation of the VitRNABP and demonstrate by several criteria that this
protein is Xenopus vigilin.
A protein mixture from salt-extracted polysomes from livers of estrogen-treated male Xenopus laevis was prepared as we have described (17). The pB1-15pA used in affinity chromatography was made by cloning the HindIII-DraI fragment of pB1-15 (17) into the HindIII-SmaI site of pSP64pA (Promega). B1-15pA RNA was made by in vitro transcription from the SP6 promoter of the pB1-15pA vector linearized with EcoRI yielding a 146-nucleotide RNA. Poly(U)-agarose beads (Pharmacia Biotech Inc.) were prepared by rinsing (i) once in 4 volumes of water, (ii) once in wash buffer (25 mM HEPES, pH 7.4, 10 mM EDTA, 1 mM EGTA, 0.05 M NaCl), and (iii) six times in binding buffer (25 mM HEPES, pH 7.4, 10 mM EDTA, 1 mM EGTA, 1 M LiCl). pB1-15pA RNA (approximately 4 µg of RNA/µl of beads) was added to the beads in 2 volumes of binding buffer and allowed to hybridize for 5-6 h at room temperature. The beads were kept in suspension by rotation. The beads were washed twice in hybridization buffer (HB) (6 mM Tris, pH 7.6, 6% glycerol, 1 mM EDTA, 0.01 mM EGTA, 0.25 mM magnesium acetate) with 50 mM NaCl and once in HB with 50 mM NaCl containing 1 µg/µl yeast tRNA, 1 µg/µl heparin, 0.3 unit/µl RNasin, and protease inhibitors (17). The beads were then incubated with the polysome extract in HB with tRNA, heparin, RNasin, and protease inhibitors with 200 µg of polysome extract per 20 µl of beads in a 300-µl total volume for 30 min at room temperature. The beads were then washed in buffer containing 200 mM KCl, 2.5 mM magnesium acetate, 10 mM Tris, pH 7.6, 10% glycerol, 0.1 mM EGTA, 1 mM EDTA, 1 mM dithiothreitol, and protease inhibitors. Proteins were eluted in the above buffer containing 500 mM KCl. Eluted proteins were resolved on a 7.5% SDS-PAGE gel (19) and visualized using a silver stain (20). For microsequencing, resolved proteins were transferred to a ProBlott membrane (Applied Biosystems) in 10 mM CAPS, pH 10, with 10% methanol at 50 V for 3 h and stained in Amido Black (21). The 150-kDa protein was cut from the membrane and sent to the Rockefeller University Technology Center (New York, NY) for digestion with endoproteinase Lys-C and internal sequencing (21).
For FPLC analysis, protein extracts were concentrated using Microcon 30 or 50 filters to about 0.25 original volume. Protein (1.2 mg) was loaded onto a Superdex 200 HR 10/30 column (Pharmacia) and resolved using a Pharmacia FPLC System at a flow rate of 0.5 ml/min at 4 °C. A total of 25 ml of buffer (10 mM Tris, pH 7.6, 200 mM KCl, 1 mM EDTA, 1 mM dithiothreitol, 5 µg/ml phenylmethylsulfonyl fluoride) was used to elute proteins in 0.5-ml fractions. Proteins eluting from the column were monitored at 280 nm. Fractions were assayed using the RNA gel mobility shift assay, and band intensities were determined using a PhosphorImager (Molecular Dynamics) or a densitometer.
RNA Isolation and Northern Blot AnalysisTotal RNA was isolated from livers of control or estrogen-treated X. laevis as described (22). RNA was resolved on a 0.75% formaldehyde-agarose gel, transferred to a Nytran membrane (Schleicher and Schuell) and hybridized to cDNA probes as described (23). cDNA was radiolabeled with [32P]dCTP by nick translation or random priming using standard methods (20). Ribosomal RNA band intensity was used to control for loading of samples. Intensities of labeled bands were determined using a PhosphorImager.
cDNA Library ScreeningOligonucleotides for PCR were
made to two conserved regions in the 5 portion of vigilin
corresponding to nucleotide numbers 213-243 and 315-340 in the
chicken vigilin sequence (GenBankTM accession number
X65292[GenBank]) (6). Xenopus liver RNA (10 µg) was PCR-amplified
using the above oligonucleotides (24), gel-purified, and radiolabeled
by nick translation. The labeled 128-nucleotide cDNA was used to
screen a X. laevis liver cDNA library (25). A positive
clone was identified, plaque-purified, and excised, and its 980 nucleotide insert was subcloned into pGEM3 (Promega). This clone is
referred to as pVIG10.
Gel mobility shift assays were performed as we have described (17) with the following modifications. Antiserum (42 µg) was added to the hybridization mixture in the absence of RNA probe for 45 min at 4 °C. RNA probe was then added, and the incubation was continued for an additional 45 min before gel analysis. Rabbit antibody to a segment of recombinant vigilin was a kind gift from Drs. S. Kügler and P. K. Müller (26). Rabbit anti-BSA was a gift from S. Miklasz. Western blot analysis was done as described previously (27), except that sodium azide was not added to buffers, SDS (0.1%) was added to the transfer buffer, and blots were transferred at 60 mA (14 V) overnight at 4 °C. Anti-vigilin antiserum was diluted 1:1500 and horseradish peroxidase-conjugated goat anti-rabbit second antibody (EY Laboratories) was used at a 1:2000 dilution. Bands were visualized with an ECL kit (Amersham).
We
described the VitRNABP as an estrogen-inducible protein which bound to
a segment of the vitellogenin mRNA 3-UTR in RNA gel mobility shift
assays and in UV cross-linking experiments (17). We used RNA affinity
chromatography to isolate the VitRNABP. A 94-nucleotide segment of the
vitellogenin mRNA 3
-UTR with a 30-nucleotide poly(A) tail, which
is efficiently bound by the VitRNABP, was immobilized on
poly(U)-agarose beads by hybridization. A salt extract of polysomes
prepared from the livers of 14-day estrogen-treated male X. laevis was incubated with the RNA affinity column, and control
extracts were incubated with the poly(U)-agarose. Bound proteins were
eluted in 500 mM salt and resolved on an SDS-PAGE gel. As
shown in Fig. 1A, a predominant protein band
of approximately 150-155 kDa, which appeared as a very closely spaced
doublet, was eluted from the agarose beads containing the vitellogenin mRNA segment (Fig. 1A, lane 2), but not from
control poly(U)-agarose beads (Fig. 1A, lane 3).
RNA binding activity and the presence of the 150-155-kDa band were
well correlated since the eluate from the B1-15pA RNA beads, but not
the eluate from the poly(U) beads, bound RNA in the RNA gel mobility
shift assay (data not shown).
We next determined whether the vitellogenin mRNA 3-UTR binding
activity was in the same 150-155-kDa molecular mass range as the
protein purified by the RNA affinity column. Since we have been unable
to reconstitute mRNA binding after denaturing the protein, we
size-fractionated a concentrated polysome extract under native
conditions. Proteins eluted from the FPLC sizing column were assayed
using the RNA gel mobility shift assay. As shown in Fig.
2, peak binding activity corresponded to a molecular mass range of 145-190 kDa, which was consistent with the 150-155-kDa protein being the VitRNABP.
Identification of the 150-155-kDa Band as Vigilin by Microsequencing and Western Blot Analysis
The 150-155-kDa protein was enriched by RNA affinity chromatography (Fig. 1A), size-fractionated on an SDS-polyacrylamide gel, transferred to a membrane, and submitted for microsequencing. Internal sequencing of one of the peptide fragments yielded the sequence; N(R/V)IRIEQDPQXVQQA. This sequence was used to search a protein sequence data base (Wisconsin Sequence Analysis Package of the Genetics Computer Group). Twelve out of fifteen amino acids were identical to those in chicken vigilin (amino acids 478-492) (6) and the human HDL-BP (amino acids 479-493) (7). Since vigilin and HDL-BP are the independently identified avian and human forms of the same protein, we subsequently refer to this protein as vigilin. To verify that the protein we purified as the VitRNABP was vigilin, a second peptide was sequenced. The sequence of this peptide, VI(S/T)QIR had a 5- out of 6-amino acid match with both the chicken and human sequences, confirming that the protein sequenced was vigilin.
To ensure that the isolated protein was Xenopus vigilin, a Western blot of the protein from the RNA affinity beads was probed with antibodies to a segment of recombinant chicken vigilin, expressed in Escherichia coli and affinity-purified (26). In Western blots using crude polysome extracts, the antibody reacts with a single protein (Fig. 1B, lane 1) which is the same size as the protein shown to be vigilin by microsequencing. The protein eluted from the B1-15pA affinity beads is also specifically recognized by the antibody (Fig. 1B, lane 2) and on shorter exposures can be seen to be a doublet (data not shown). Although this is a polyclonal antibody, in agreement with previous reports (26), we see no cross-reactivity with other proteins. Since the elution pattern was identical in both the SDS-PAGE gels and Western blots, we were confident that the isolated protein was indeed vigilin.
Antiserum to Chicken Vigilin Binds to the VitRNABPWhile
these data demonstrated that the protein purified by affinity
chromatography was vigilin, and that vigilin was approximately the same
size as the VitRNABP, it was still important to directly establish that
the protein bound to the vitellogenin mRNA 3-UTR in our gel
mobility shift assays was vigilin. If the VitRNABP was indeed
Xenopus vigilin, antibodies to vigilin added to the RNA gel
mobility shift assays should alter the mobility of the VitRNABP·RNA
complex. In an RNA gel mobility shift assay, the VitRNABP in a polysome
extract formed a specific complex with a radiolabeled probe containing
a segment of the vitellogenin mRNA 3
-UTR (Fig.
3A, lane 2). Addition of antibody
to vigilin supershifted this complex (Fig. 3A, lane
4). Since this is a polyclonal antibody, the number of antibody
molecules that can bind to each gel-shifted complex is variable, and
some tailing of the supershifted band is observed (Fig. 3A,
lane 4 and Fig. 3B, lane 2). This
supershift was specific for anti-vigilin, since it did not occur when a
control antibody to bovine serum albumin was used (Fig. 3A,
lane 6). Control experiments also showed that the antibodies
alone did not interact with the RNA probe (Fig. 3A,
lanes 3 and 5). By increasing the ratio of
anti-vigilin antibody to polysome extract, we were able to almost
completely supershift the VitRNABP·RNA complex (Fig. 3B),
indicating that vigilin is present in all of the complexes with the
vitellogenin mRNA 3
-UTR segment.
Vigilin mRNA Is Induced by Estrogen in Xenopus Liver
Since we had previously reported that the VitRNABP was
estrogen-inducible (17), we wanted to determine whether
Xenopus vigilin mRNA was also regulated by estrogen. We
therefore isolated and sequenced a 980-nucleotide Xenopus
vigilin cDNA clone (see "Experimental Procedures") with a high
homology to sequences at the 5-end of chicken and human vigilin. The
Xenopus vigilin cDNA showed a 74% and 76% nucleotide
identity with the chicken and human vigilin cDNAs, respectively,
and an 86% identity to amino acid sequences from both species.
To compare the regulation of Xenopus vigilin mRNA levels
and vitellogenin mRNA 3-UTR binding activity, three animals each were treated with vehicle or estrogen, total RNA was isolated from half
the liver, and whole cell protein extracts were prepared from the other
half. Consistent with our earlier work (17, 18), binding activity in
RNA gel shift assays from liver extracts from estrogen-induced
Xenopus liver was about 3-fold higher than in control
extracts (Fig. 4B). In agreement with the RNA
gel shift data, Northern blot analysis showed that a predominant
5.7-kilobase vigilin mRNA was induced 2-3-fold after estrogen
administration (Fig. 4, A and B).
Its broad distribution and the presence of 14 KH domains suggested
an important, but unidentified, role for vigilin in RNA metabolism. In
this work we show that vigilin is the estrogen-inducible protein we
previously demonstrated binds to a segment of the vitellogenin mRNA
3-UTR. This conclusion is supported by our findings that: vigilin is
retained on a vitellogenin mRNA 3
-UTR affinity column; in gel
shift assays, vigilin antiserum binds to the VitRNABP; the mRNA
binding activity and vigilin are approximately the same size; and both
are induced by estrogen. We now refer to the VitRNABP as vigilin.
Vigilin has been proposed to be an RNA-binding protein because of its
numerous KH domains (3) but to date had only been shown to bind tRNA
(28). Our work demonstrates for the first time that vigilin can bind to
an mRNA. We previously reported that the affinity for the
vitellogenin mRNA 3-UTR was orders of magnitude greater than that
for tRNA (17). Since vigilin is present in a wide variety of tissues
and cell types and is regulated by diverse factors, it almost certainly
binds to RNAs other than vitellogenin mRNA. The relative binding
affinity of vigilin for different RNA sequences may play a role in its
function in different tissues. The exact determinants of RNA binding
specificity remain to be determined and may involve specific KH domains
within vigilin and proteins which associate with vigilin. The nucleic acid binding properties of individual KH domains vary (29). The 14 KH
domains in vigilin may therefore interact on different RNA templates to
create different binding surfaces, allowing vigilin to bind to a
diverse array of RNAs. It is possible that other proteins may associate
with the vigilin·RNA complex and play a role in creating binding
specificity. Although other proteins which might play a role in RNA
binding are not yet identified, there are several minor proteins in the
vitellogenin mRNA affinity column eluent which may contribute to
this function.
The ability of vigilin to bind the vitellogenin mRNA 3-UTR
suggests that it may be involved in mRNA stabilization. Since the
3
-UTR of vitellogenin mRNA is critical for estrogen-mediated stabilization (16), and vigilin is the major protein which binds to
this region (17), we have proposed that vigilin is involved in the
stabilization of the message. Other KH domain-containing proteins have
been shown to be involved in RNA stabilization (5), and vigilin has
been reported to protect tRNA from RNase (28). Other functions have
been proposed for vigilin based on its intracellular distribution (26).
Additional studies will be required to determine the role of vigilin in
mRNA stabilization and any additional functions it may serve.
While a clear role for vigilin has not been established, its tight
regulation accentuates its importance in RNA metabolism. We have shown
that vigilin levels are increased by estrogen in liver (Fig. 4 and
Refs. 17 and 18) and by testosterone in muscle, and that it is
decreased by testosterone in testis (18). Our findings are consistent
with reports in several experimental models that vigilin can be
regulated by several factors and that increased levels of vigilin
correlate with increased protein production (8, 9, 11, 30). Vigilin has
been localized immunocytochemically to polysomes (8), and we have
extracted vigilin from liver polysomes indicating its association with
cytoplasmic RNA. In a situation such as the estrogen-induced liver in
Xenopus, where vitellogenin is 50% of the total cellular
mRNA (31), a substantial fraction of intracellular vigilin may be
bound to the relatively high affinity binding site in the vitellogenin
mRNA 3-UTR. Our findings are also in agreement with the ubiquitous
distribution of vigilin, since we have found vigilin in all
Xenopus tissues we have examined and in several cell lines
(18).
In conclusion, we have identified vigilin, a widely distributed protein
containing 14 RNA binding domains, as the estrogen-regulated protein
which binds to the 3-UTR of vitellogenin mRNA. Our data provide
the first evidence that vigilin can bind a specific mRNA and
suggest a role for vigilin in mRNA metabolism.
Protein sequence data were obtained at the Rockefeller University Protein/DNA Technology Center, which is supported in part by National Institutes of Health shared instrumentation grants and by funds provided by the U.S. Army and Navy for purchase of equipment. We thank S. Kügler and P. K. Müller for the gift of vigilin antiserum and D. Schoenberg for providing the Xenopus cDNA library. We would also like to thank J. Gerlt and members of his laboratory for assistance with the FPLC.