(Received for publication, October 25, 1996, and in revised form, March 10, 1997)
From the Laboratory of Molecular Embryology, NICHD, National Institutes of Health, Bethesda, Maryland 20892-5431
We examine the translational regulation of histone H4 mRNA when Xenopus laevis oocytes are induced to mature with progesterone. Histone H4 mRNA synthesized from plasmid templates microinjected into oocyte nuclei is translationally silenced (masked). This masked mRNA becomes translationally active only after oocyte maturation. In contrast, histone H4 mRNA injected into the oocyte cytoplasm is translationally active both before and after oocyte maturation. Thus, transcription in vivo is required to mask histone H4 mRNA and to allow subsequent translational regulation. Protein association with histone H4 mRNA synthesized in vivo was determined before and after oocyte maturation. UV cross-linking of radiolabeled RNA to protein and immunoprecipitation of cross-linked proteins reveals an increased association of the chaperone nucleoplasmin with ribonucleoprotein particles dependent on the oocyte maturation process. The Y-box protein FRGY2 inhibits translation of histone H4 mRNA in vitro. Nucleoplasmin is able to partially relieve this repression. We discuss the potential role of nuleoplasmin in the remodeling of repressive ribonucleoprotein particles containing maternal mRNA to facilitate translational activation.
The translational control of maternal mRNA is a major regulatory mechanism for gene expression during early Xenopus development (1-3). Maternal mRNA is packaged into ribonucleoprotein particles (mRNPs, informosomes)1 (4, 5). RNA-binding proteins, including those of the Y-box family of proteins, maintain mRNA in a translationally repressed or masked form (6-9). Removal of the Y-box proteins from mRNA in vitro facilitates translational activation (10, 11). Thus one potential translational regulatory mechanism might involve the removal of repressive Y-box proteins from maternal mRNA. In addition, true activation mechanisms exist that further facilitate translation of maternal mRNA. Most masked mRNAs that are in the oocyte have short poly(A) tails that are lengthened during oocyte maturation concomitant with translational activation (unmasking) (12-14). The poly(A) tail directly stimulates the initiation of translation (15). The exact molecular events that might regulate the translational activation of any masked maternal mRNA are not yet known. Multiple molecular mechanisms are likely to contribute to the translational regulation of any specific mRNA.
In this work we investigate the translational regulation of histone H4 mRNA during the maturation of Xenopus oocytes induced in vitro using progesterone (12, 13). We chose histone H4 mRNA because the endogenous message is abundant in Xenopus oocytes and the vast majority of H4 mRNA is masked (16). The rate of histone H4 synthesis increases 50-fold on oocyte maturation without an increase in histone H4 mRNA polyadenylation (17, 18). In fact histone H4 mRNA is polyadenylated in oocytes (16, 18), and the poly(A) tail is removed during the maturation process (18). Thus the unmasking of histone H4 mRNA most probably involves the mobilization of mRNA from stores present as masked ribonucleoprotein particles by removal of a repressor protein rather than activation via polyadenylation dependent mechanisms (18, 19).
We first reconstitute the regulated unmasking of histone H4 during oocyte maturation using mRNA synthesized from plasmid DNA templates microinjected into the oocyte nucleus. We next examine the proteins associated with H4 mRNA before and after oocyte maturation by UV cross-linking to radiolabeled mRNA. We purify the major protein whose association with H4 mRNA increases during oocyte maturation. This protein is nucleoplasmin, a well known chaperone stored in the Xenopus oocyte nucleus in large amounts (290 ng/oocyte) until oocytes mature and the nuclear envelope breaks down (20). Nucleoplasmin has the role of removing specialized arginine-rich protamines from Xenopus sperm chromatin (21). We propose that it has a comparable role in facilitating the removal of the arginine-rich Y-box proteins from maternal mRNA, thereby potentiating translation.
The SP6H4F construct has been
described elsewhere (22). The NH2-terminal FLAGged (IBI) H4
sequence was amplified from SP6H4F using the primers
5-ACCTTCCATGGCCTTAACCTCCGAATCCGTACAGAGTGCG-3
and
5
-AATTTGAATTCTAGAAAAGATGGACTACAAGGACGACGATGACAAGTCTGGAAGAGGCAAGAGGCAAGGGC-3
. This fragment was subcloned into the
XbaI/NcoI sites of the pCAT-Basic vector
(Promega), and the cytomegalovirus promoter (23) was subcloned into the
HindIII/XbaI sites to give CMV.H4F. All
constructions were confirmed by sequencing.
In vitro transcription
reactions were performed using SP6 RNA polymerase as described (24).
Templates were linearized with EcoRI downstream from a
poly(A) tract to give polyadenylated RNA. RNA synthesis was carried out
in the presence of a 10:1 cap analog to rGTP ratio to obtain 5 capped
transcripts (8). Transcribed RNA was phenol/chloroform extracted and
ethanol-precipitated.
Xenopus oocytes were prepared as described previously (25). Stage VI oocytes were sorted and used within 24 h of oocyte preparation. Oocytes were maintained at 18 °C in modified Barth's saline (26). To ensure accuracy in the nuclear versus cytoplasmic injection experiments, the injection volume was kept to 9.2 nl and cytoplasmic injections were performed into the vegetal pole. After injection, only oocytes with homogenous pigmentation and normal turgor were collected. Collected oocytes were homogenized in 0.25 M Tris-HCl (pH 7.5) (10 µl/oocyte) and aliquoted for protein and RNA analysis. A minimum of 30-40 oocytes were injected per item of data. All results were reproduced in at least three separate experiments. In vitro oocyte maturation was carried out in oocyte culture medium (26) using 1 µg/ml progesterone (Sigma). Oocyte maturation was determined by the appearance of a white spot at the animal pole indicative of germinal vesicle breakdown.
UV Cross-linkingLabeled in vitro transcribed
RNA was obtained by introducing 50 µCi of [32P]UTP or
[32P]GTP into the reaction. In vivo labeling
was obtained by injecting [32P]UTP or
[32P]GTP (1 µCi/oocyte) in the oocyte nucleus. After
the indicated time, oocytes (whole, nucleus, or cytoplasm) were
homogenized in 10 mM Tris-HCl (pH 7.7), 100 mM
KCl, 1 mM MgCl2, 0.1 mM
CaCl2, 50 mM sucrose (3 µl/oocyte). After
centrifugation for 10 min at 4 °C, protein extracts were exposed to
UV light for 10 min on ice; then RNase A was added (0.5 µg/µl) and
digestion was allowed for 1 h at 37 °C. Immunoprecipitation of
the cross-linked proteins used antibodies against nucleoplasmin
purified from serum using protein-A agarose (27). Using the fact that
nucleoplasmin is soluble at 80 °C (28), proteins extracted from
oocytes were heated for 10 min at 80 °C, then placed on ice for 10 min. The soluble proteins cross-linked to radiolabeled RNA were then
incubated with 15 µg of purified IgG containing nucleoplasmin
antibody and 50 µl of IgG Sorb (The Enzyme Center, Malden,
Massachusetts) in RIPA buffer (50 mM HEPES (pH 7.5), 2 M NaCl, 0.1% SDS, 1% Triton, 5 mM EDTA, 0.1%
bovine serum albumin) for 2 h at room temperature. Complexes were
washed five times with RIPA buffer, then three times with 50 mM HEPES (pH 7.5), 0.15 M NaCl, 5 mM EDTA, and then treated with RNase A as above. Proteins
were released by adding 25 µl of a solution of 1% SDS, 0.2 mM -mercaptoethanol and heating 10 min at 100 °C.
RNA was extracted from the homogenate by the
RNAzol method (Cinna Scientific). RNA was analyzed by primer extension
as described (29). Primer extension was performed using the primer
5-GGCTTGGTGATGCCCTGGATGTTATCC-3
which detects both exogenous and
endogenous histone H4 mRNA.
Batches of 15 oocytes were homogenized in 75 µl of protein homogenization buffer (70 mM KCl, 90 mM HEPES (pH 7.5), 1 mM dithiothreitol, 5% sucrose). This homogenate was centrifuged for 10 min at 4 °C and the supernatant removed. Radiolabeled H4 protein was resolved by SDS-polyacrylamide gel electrophoresis (PAGE). Before autoradiography, gels were treated for 30 min with Amplify (Amersham).
For detection of FLAG (IBI) epitope-tagged histone H4 protein by Western analysis, oocytes were homogenized in protein homogenization buffer and centrifuged for 10 min at 4 °C. An equal volume of 2 × SDS sample buffer was added to the supernatant, and the proteins were resolved by SDS-PAGE and transferred onto Hybond-ECL nitrocellulose membrane (Amersham). Affinity-purified anti-FLAG (IBI) monoclonal antibody was used in immunodetection.
Protein SequencingHeat-purified extract from in vitro matured oocytes (100 oocytes/sample) was resolved by SDS-PAGE, and transferred to a PVDF membrane. NH2-terminal sequencing of the appropriate protein was attempted, but the NH2 terminus was found to be blocked. In a repetition of this experiment the gel was stained with Coomassie Blue, and the appropriate protein band was cut out and electroeluted. The protein was precipitated with 80% trichloroacetic acid and the pellet washed with acetone, 0.2% HCl, then acetone alone. The pellet was resuspended in 10% cyanogen bromide in 70% formic acid, and cleaved overnight at 37 °C. After a 10-fold dilution with high performance liquid chromatography grade water, the mixture was lyophilized. The cleavage products were resuspended in 8 M urea, and an equivalent volume of SDS buffer added. Products were resolved on a 8-20% Tris glycine gradient gel (Novex) and transferred to a PVDF membrane in 3-(cyclohexylamino)-1-propanesulfonic acid buffer. The membrane was washed first with distilled water, then methanol, and then stained with Coomassie Blue. The cleavage products were sequenced.
Fractionation of Maternal Messenger Ribonucleoprotein ParticlesFractionation was performed as described (30). One hundred oocytes were homogenized in 180 µl of 1 × gradient buffer (0.3 M KCl, 2 mM MgCl2, 20 mM HEPES/KOH, pH 7.4, 0.1% diethyl pyrocarbonate, and 0.5% Nonidet P-40) and 20 units of RNasin was added. The extract was centrifuged at 12,000 × g at 4 °C for 10 min, and 200 µl of the soluble fraction was layered on top of 5 ml of a 20-60% Nycodenz step gradient in 1 × gradient buffer. The gradient was centrifuged at 150,000 × g for 20 h at 4 °C in a SW50.1 rotor (Beckman). The gradient was fractionated in 27 fractions (1-27 from top to bottom).
In Vitro TranslationNucleoplasmin purified from Xenopus egg extracts was a kind gift of Dr. Stefan Dimitrov (27). The capped histone H4 mRNA was synthesized by SP6 RNA polymerase transcription from EcoRI-linearized pSP H4F (22). RNA was heated at 65 °C for 10 min and quickly chilled on ice before use. In vitro translation was performed with the nuclease-treated rabbit reticulocyte lysate system (Promega). Histone H4 mRNA (0.13 µg) was incubated at 30 °C for 60 min in a 25-µl reaction mixture consisting of 15 µl of rabbit reticulocyte lysate, 50 µM each of amino acids including 87.5 µCi of [3H]lysine and 17.5 µCi of [3H]arginine, 20 units of RNasin (Promega), and Tail domain protein (FRGY2.D6, see Ref. 31). The mixture was then digested with 5 µg of RNase A at 30 °C for 5 min. Acid-soluble protein was prepared as described (8). The aliquots were subjected to electrophoresis in a 15% polyacrylamide gel containing 7 M urea and 5% acetic acid (32). The gel was fixed, treated with Amplify (Amersham Corp.), and dried. The translation products were detected by fluorography.
In earlier work we have described the translational
masking of histone H1 mRNA by quantitating protein synthesis per
mass of mRNA (8). Histone H1 mRNA synthesized in
vivo from a plasmid DNA molecule injected into the oocyte nucleus
was translated 50-100-fold less efficiently than the H1 mRNA
microinjected into the nucleus (8). Histone H1 mRNA is a bona fide
translationally masked mRNA in the oocyte (30, 33). We have also
examined whether the requirement for transcription in vivo
to establish efficient masking of mRNA was a general phenomenon
(14). Heterologous mRNAs such as those encoding chloramphenicol
acetyltransferase or luciferase are translationally active if they are
injected into the oocyte cytoplasm but are translationally masked if
they are synthesized in vivo (14). Endogenous H4 mRNA
(Fig. 1A, lanes 1-3) is not translationally
active (Fig. 1B, lane 1) as expected from earlier results
(19). To discriminate between endogenous and exogenous experimental H4
mRNA we modified the coding sequence to contain a FLAG (IBI)
epitope tag at the amino terminus (see "Materials and Methods"),
this additional nucleotide sequence enabled distinction between
endogenous and exogenous H4 mRNA using primer extension assays
(Fig. 1A, "Materials and Methods"). Note that the
histone H4 mRNA synthesized from the CMV.H4F expression vector
following injection into the Xenopus oocyte nucleus (Fig. 1A, lane 3, in vivo synthesized exogenous H4 mRNA) is
longer at the 5 end than the histone H4 mRNA synthesized in
vitro using SP6 RNA polymerase and the SP6 H4F expression vector
(Fig. 1A, lane 2, in vitro synthesized exogenous H4
mRNA). This additional sequence in the 5
-untranslated region has
no influence on the translational activity of the H4 mRNA, or the
translational activity of the H4 mRNA, or mRNA stability (see
Bouvet and Wolffe (8)).2
Microinjection of exogenous histone H4 mRNA synthesized in vitro into the oocyte cytoplasm (Fig. 1A, lane 2), or microinjection of a plasmid DNA molecule (H4 DNA CMV.H4F) into the oocyte nucleus directing the synthesis of exogenous H4 mRNA (Fig. 1A, lane 3) was followed by radiolabeling of newly synthesized protein in a 6-h period (Fig. 1B). Comparable levels of in vitro or in vivo synthesized exogenous H4 mRNA (Fig. 1A, compare lanes 2 and 3, Table I) show very different efficiencies for synthesis of epitope-tagged histone H4 protein (Fig. 1B, compare lanes 2 and 3; Table I). The in vitro synthesized exogenous H4 mRNA is translated into epitope-tagged H4 protein (Fig. 1B, lane 2, arrowhead) much more efficiently than the in vivo synthesized mRNA (Fig. 1B, lane 3). Note that the epitope-tagged histone H4 (indicated as H4 epitope-tagged, arrowhead) migrates as a larger protein than endogenous histone H4 (indicated by the asterisk). Thus like histone H1, chloramphenicol acetyltransferase, and luciferase mRNAs, the exogenous histone H4 mRNA is translationally active if injected into the oocyte cytoplasm, but is translationally repressed if synthesized from a plasmid template injected into the oocyte nucleus. Quantitation of relative translational efficiencies indicate a ~25-fold repression of in vivo synthesized versus in vitro synthesized H4 mRNA (Table I).
|
We have established conditions for the translational
masking of histone H4 mRNA following synthesis of the mRNA
in vivo (Fig. 1). We next examined whether this masked
mRNA would be released for translation on oocyte maturation and
hence come under the appropriate developmental control. We repeated the
experiment of injecting histone H4 mRNA into the cytoplasm or
synthesizing H4 mRNA in vivo, however, we added the
additional step of inducing oocyte maturation with progesterone (Fig.
2A). As a control we made use of our primer
extension assay to determine the level of the various histone H4
mRNAs at the end of our experiments (Fig. 2B).
Incubation in the presence of progesterone leads to a small decline in
the abundance of all the histone H4 mRNAs (Fig. 2B,
compare lanes 1 and 2). This result was confirmed
by Northern blotting (data not shown). We next examined the translation
of the exogenous H4 mRNA. In the absence of progesterone treatment, immunoblotting with antibodies specific for the FLAG epitope indicates that exogenous histone H4 mRNA synthesized in vitro and
injected into the cytoplasm is translated (Fig. 2C, lane 2),
whereas that synthesized in vivo is masked (Fig. 2C,
lane 4). Maturation of oocytes with progesterone has no effect on
the translation of histone H4 mRNA injected into the cytoplasm
(Fig. 2C, compare lanes 2 and 3), but
leads to the unmasking of histone H4 mRNA synthesized in
vivo (Fig. 2C, compare lanes 4 and
5). Thus histone H4 mRNA synthesized in vivo
from plasmid DNA templates comes under the appropriate developmental
control at oocyte maturation, whereas histone H4 mRNA microinjected
into oocyte cytoplasm does not. In earlier work (30), we made use of
density gradient centrifugation to show that masked maternal mRNA
is assembled exclusively into mRNPs, but that on release to the
translational machinery mRNA is distributed between mRNPs and
ribosomes. Histone H4 mRNA exhibits similar behavior. Histone H4
mRNA is exclusively in mRNPs prior to oocyte maturation (Fig.
2D, Pre) and redistributes between mRNPs and
ribosomes post-maturation (Fig. 2D, Post). Note that these
Northern blots of gradient fractions are only to compare the
distribution of H4 mRNA between various RNP fractions. Since there
is no transcription in Xenopus from oocyte maturation until the mid-blastula transition of Xenopus embryogenesis (34,
35) there is no increase in H4 mRNA abundance from levels in the
oocyte until after that time. We next examined the molecular mechanisms responsible for the release of H4 mRNA from storage
ribonucleoprotein particles to the ribosomes.
Nucleoplasmin Associates with Ribonucleoprotein Particles Containing Histone H4 mRNA following Oocyte Maturation
A
major event associated with oocyte maturation is the breakdown of the
nuclear envelope. This leads to a mixing of nuclear and cytoplasmic
components with important consequences for transcription (35) and
translation (36). We wished to explore whether oocyte maturation would
alter the distribution of proteins that could be cross-linked to
radiolabeled histone H4 mRNA. In earlier work we had documented the
association of proteins with radiolabeled mRNA synthesized in
vitro using this strategy (8, 37). The Y-box protein FRGY2
interacts with mRNA microinjected into the oocyte nucleus or
cytoplasm (8, 30, 31). The capacity for FRGY2 to bind to histone H4
mRNA is unchanged in this assay following oocyte maturation (Fig.
3A, compare lanes 1 with
2 and 3 with 4, FRGY2 is indicated
with an asterisk). The identity of FRGY2 was demonstrated by
immunoprecipitation experiments (Ref. 8; data not shown). This result
is consistent with the continued presence of histone H4 mRNA in
mRNPs after oocyte maturation (Fig. 2D). Several other
radiolabeled proteins appear, two have masses of ~250 and 30 kDa,
respectively (Fig. 3A). The identity of the ~250-kDa
protein is unknown. The properties of the 30-kDa protein suggest that
it is phosvitin; this is an egg yolk protein of ~30 kDa, that
contains 56% of the amino acids in the protein as potentially phosphorylated serines (38). This protein is readily radiolabeled following injection of any [32P]nucleotide triphosphate
into Xenopus oocytes, it is heat-stable (see Fig.
4), and is not extracted by phenol/chloroform
treatment.2 It is a highly radioactive contaminant of our
experiments. Our attention focussed on a protein of apparent molecular
mass of 34 kDa that associates with histone H4 mRNA after oocyte
maturation, but not before (Fig. 3A, arrowhead). We
substantially scaled up this analysis and resolved total protein after
heat purification (Fig. 3A, lane 5, see below) on SDS-PAGE
before transfer to PVDF membranes. Note that the radioactive 30-kDa
protein (Fig. 3A, lanes 1-4) is not visualized by Coomassie
Blue staining, suggesting that it is a minor contaminant of our
preparations in terms of protein mass. NH2-terminal
sequencing of the 34-kDa protein was attempted, but the NH2
terminus was found to be blocked. After repeat electrophoresis of the
extract, the gel was stained with Coomassie Blue and the appropriate
protein band was cut out and electroeluted. The protein was cleaved
with cyanogen bromide before resolution by SDS-PAGE and transfer to a
PVDF membrane (Fig. 3B). The cleavage products were analyzed
by NH2-terminal sequencing, Product 1 (Fig. 3B)
was blocked; however, Product 2 gave the sequence indicated (Fig.
3C). Sequence analysis revealed an identity with an internal
peptide sequence of Xenopus laevis nucleoplasmin (39). We
next proceeded to independently test the identity of the 34-kDa protein.
Nucleoplasmin is 200 amino acids in length and has a predicted molecular mass of 22,024 daltons (39), nevertheless the protein migrates as a 33-34 kDa protein on SDS-polyacrylamide gels (40). Anomalous electrophoretic mobility is due to polyglutamic acid tracts at the COOH terminus of nucleoplasmin (40). Nucleoplasmin is not precipitated by heating for 10 min at 80 °C and can be enriched by this procedure (20). FRGY2 also remains soluble under these conditions (41). The proteins cross-linked to histone H4 mRNA following oocyte maturation are not precipitated by heating at 10 min at 80 °C. These are FRGY2 (Fig. 3A, lane 5, asterisk) and the 34-kDa protein (arrowhead). We repeated this experiment using both H4 mRNA microinjected into the oocyte cytoplasm (Fig. 4A, lanes 1 and 2) and H4 mRNA synthesized in the nucleus from plasmid templates (Fig. 4A, lanes 3 and 4). In both instances an increase in cross-linking of a 34-kDa protein to mRNA was apparent on oocyte maturation (Fig. 4A, compare lanes 1 with 2 and 3 with 4). Subsequent immunoprecipitation (see Fig. 4C, later) suggests that the sharp band at 34 kDa in Fig. 4A, lane 4, is nucleoplasmin, but that the diffuse material in lane 3 is not nucleoplasmin. We next examined the heat stability of proteins cross-linked to H4 mRNA synthesized in vivo. Neither nuclear, cytoplasmic, nor total oocyte extracts showed strong cross-linking of the 34-kDa protein to H4 mRNA in the absence of oocyte maturation (Fig. 4B, lanes 1-3). However, strong cross-linking is apparent once the oocytes have matured (Fig. 4B, lane 4). This result indicates that the mixing of nuclear and cytoplasmic compartments on oocyte maturation is insufficient in isolation for changes in protein association with mRNA, since when these compartments are mixed in a total oocyte extract the cross-linking of the 34-kDa protein is insignificant compared with that in mature oocyte (Fig. 4B, compare lanes 3 and 4). The biochemical properties of several proteins change during oocyte maturation; for example, nucleoplasmin becomes heavily phosphorylated (21, 42). These biochemical changes are likely to make a major contribution to alterations in protein-RNA association. The heat enrichment of proteins cross-linked to histone H4 mRNA before and after oocyte maturation was repeated once again (Fig. 4C, compare lanes 1 and 2). These proteins were immunoprecipitated using polyclonal antibodies against nucleoplasmin (27). The radiolabeled 34-kDa protein is immunoprecipitated using these antibodies (Fig. 4C, lane 2), but is not precipitated by preimmune sera (Fig. 4C, lane 4). On the basis of peptide sequence (Fig. 3) and immunoreactivity (Fig. 4), we conclude that the heat-stable 34-kDa protein is nucleoplasmin.
Nucleoplasmin Potentiates the Translation of FRGY2-mRNA ComplexesThe major function of nucleoplasmin in the egg is to facilitate the decondensation of Xenopus sperm chromatin to allow the assembly of the paternal pronucleus (21, 43, 44). This involves the removal by nucleoplasmin of sperm-specific basic proteins (43). These proteins are arginine-rich (45), and their interaction with the acidic nucleoplasmin is enhanced by the hyperphosphorylation of nucleoplasmin that occurs on oocyte maturation (21, 42). The Y-box proteins that package maternal mRNA are also arginine-rich in their COOH-terminal Tail domains and have three 30-amino acid segments that are very similar to protamines in sequence (46-48). We next considered the possibility that nucleoplasmin might interact with the Y-box proteins and thereby facilitate translation of the mRNAs with which they are associated.
In earlier work we established in vitro conditions where the
binding of FRGY2 or the Tail domain of FRGY2 to mRNA led to
translational repression (31). We repeated these experiments with
histone H4 mRNA, adding sufficient excess of the Tail domain
containing the arginine-rich sequences to repress translation (Fig.
5A, lanes 1-3). We then titrated increasing
amounts of nucleoplasmin into the translation reaction (Fig. 5A,
lanes 3-6). Under these conditions nucleoplasmin provides a
modest stimulation of translation, quantitation indicates a 5% relief
of repression. The addition of nucleoplasmin alone to the translation
reaction in the presence of naked H4 mRNA was without effect on
translation efficiency (Fig. 5A, lanes 7-9).
These experiments (Fig. 5A) use 130 ng of H4 mRNA associated with 2,500 ng of Y-box protein. The addition of nucleoplasmin (3,000 ng) under these conditions provides a very limited relief of translational repression. The in vitro translation assay conditions constrain the amount of histone H4 mRNA required to obtain a strong translation signal; moreover, we can only concentrate nucleoplasmin to a limited extent before precipitation. However, in vivo in the oocyte there is 290 ng of nucleoplasmin and 21 ng of total mRNA associated with approximately 40 ng of Y-box proteins (30, 49); thus, the ratio of nucleoplasmin to Y-box protein is greater in the oocyte than in our in vitro reaction. If we reduce the excess of Y-box proteins in the in vitro translation reaction by 50%, we find that nucleoplasmin (3,000 ng) more effectively relieves translational repression (25% relief of repression, Fig. 5B, compare lanes 2 and 3). Our experimental system is limited by the concentration of purified nucleoplasmin; nevertheless, our results suggest that the ratio of Y-box protein to nucleoplasmin can influence the relief of translational repression. We suggest that nucleoplasmin can contribute to the partial relief of translational repression directed by the Tail domain of FRGY2.
Our results demonstrate that histone H4 mRNA synthesized from a plasmid DNA template in vivo comes under the appropriate developmental control of translation on oocyte maturation. The H4 mRNA synthesized in vivo is translationally silent prior to maturation and is released to the translational machinery after maturation (Fig. 2). Histone H4 mRNA microinjected into the oocyte cytoplasm does not come under this translational control. These results further emphasize the importance of in vivo transcription to establish translational silencing in the oocyte (5, 8). Although it is possible to activate translation on oocyte maturation in the oocyte using particular synthetic mRNAs injected into the oocyte cytoplasm (12, 13), the range of translational regulation that might be achieved is potentially greater if the same mRNA is synthesized in vivo (Fig. 2; Ref. 14). This amplification of responsiveness is due to the reduction in translational efficiency dependent on association of the mRNA with repressive proteins such as FRGY2. Earlier work has comprehensively excluded regulated increases in polyadenylation as exerting an activating function on histone H4 mRNA translation (18, 19). Thus other regulatory mechanisms must contribute to the unmasking of H4 mRNA.
In the immature oocyte nucleoplasmin stores histones H2A and H2B in the oocyte nucleus (20, 50). However, 290 ng of nucleoplasmin (molecular mass 22 kDa) is available to store 70 ng of histone H2A and H2B (which exist as a heterodimer of molecular mass 25 kDa) (20, 51). Thus it is likely that additional functions exist for nucleoplasmin. One of these functions is the unpackaging of the paternal genome within sperm chromatin following fertilization (21). This unpackaging is greatly facilitated by the hyperphosphorylation of nucleoplasmin that occurs on oocyte maturation (21, 42). Phosphorylated nucleoplasmin sequesters the arginine-rich sperm protamines allowing the paternal genome to be assembled into nucleosomes (43, 52). Our results suggest that a comparable function might exist for nucleoplasmin in facilitating the unpackaging of maternal mRNA.
Maternal mRNA is packaged by the Y-box protein FRGY2 (30, 41, 46). The COOH-terminal Tail domain of FRGY2 has marked sequence similarities with sperm-specific protamines (46, 47). Nucleoplasmin does not interact with naked histone H4 mRNA in vitro (data not shown), or efficiently with histone H4 mRNA in the nucleus (Fig. 4B), but it does interact with H4 mRNA following oocyte maturation as assayed by UV cross-linking (Figs. 3 and 4). These results imply that nucleoplasmin association is a regulated process dependent on protein-protein interactions with the mRNP. Earlier immunofluorescence studies had suggested that nucleoplasmin might associate with ribonucleoprotein particles on the lampbrush chromosomes of the oocyte (53). Thus some association of nucleoplasmin with nuclear ribonucleoprotein particles is likely to occur. We suggest that the affinity of nucleoplasmin for ribonucleoproteins will be increased following the hyperphosphorylation of nucleoplasmin during oocyte maturation (21, 42). The increased association of nucleoplasmin with masked maternal mRNPs following oocyte maturation may depend on interactions of the Tail domain with FRGY2. However, our experiments have so far failed to show a stable interaction between nucleoplasmin and FRGY2 in the absence of mRNA (data not shown). It is the interaction of hyperphosphorylated nucleoplasmin with sperm-specific protamines that leads nucleoplasmin to associate with sperm chromatin (21). A tethering of nucleoplasmin by the Tail domain might facilitate cross-linking to mRNA. It is also probable that nucleoplasmin association will destabilize the interaction of the translationally repressive Tail domain with mRNA (31). Nucleoplasmin can partially relieve the translational repression of H4 mRNA caused by the FRGY2 Tail domain in vitro (Fig. 5). Clearly other factors must contribute to translational regulation; however, nucleoplasmin or comparable chaperone activities are likely to have a role in unpackaging masked maternal mRNA following oocyte maturation.