(Received for publication, July 23, 1996, and in revised form, September 25, 1996)
From the Institut de Génétique et de Biologie Moléculaire et Cellulaire, CNRS/INSERM/ULP, BP 163, 67404 Illkirch Cedex, C.U. de Strasbourg, France and the § U 242 de l'Inserm, Hôpital des Enfants, Groupe Hospitalier de la Timone, 13385 Marseille, Cedex 5, France
Using antibody 2H9 from our heterogeneous nuclear
ribonucleoproteins (anti-hnRNP) monoclonal antibody library, we
previously showed in HeLa cells that a 35-37-kDa protein doublet
switches from the hnRNP complexes to the nuclear matrix following a
10-min heat shock at 45 °C (1 Lutz, Y., Jacob, M., and Fuchs, J. P. (1988) Exp. Cell Res. 175, 109-124). cDNA cloning and
sequencing revealed an hnRNP protein (2H9) which is a new member of the
hnRNP F, H/H family. Protein 2H9 displays two consensus sequence-type
RNA binding domains (CS-RBD) showing 80-90% homology with two of the
three CS-RBDs of hnRNP F and H/H
. Another common feature is the
presence of two glycine/tyrosine-rich auxiliary domains located at the C terminus and between the two CS-RBDs. At the functional level we show
that specific anti-2H9 peptide antibodies can directly inhibit an
in vitro splicing system. Moreover, the 2H9 protein doublet
is no more present in nuclear extracts from such briefly stressed
cells, which interestingly correlates with the inability of these
extracts to catalyze in vitro splicing reactions. Taken together, our data suggest that these proteins are involved in the
splicing process and also participate in early heat shock-induced splicing arrest by transiently leaving the hnRNP complexes. These 2H9
proteins, which are encoded by a single gene located on human chromosome 10, were also found to be associated with nuclear bodies in situ.
Most RNA polymerase II transcripts or pre-mRNAs undergo a series of post-translational processing events leading to mRNAs that are further exported to the cytoplasm. This results in the simultaneous presence within the nucleus of a large variety of pre-mRNAs, mRNAs, and intermediate reaction products, which are collectively termed heterogeneous nuclear RNAs (hnRNAs).1 As soon as they emerge from the transcription complex and throughout maturation, hnRNAs interact with hnRNP proteins (hnRNPs) and snRNPs; these assemblies, also called hnRNP complexes, serve as the substrate for RNA processing events, including splicing (2-5). Ultrastructural investigations in fact support the idea that the in situ form of these hnRNP complexes are the inter- and perichromatin fibrils (6-8). It is also thought that these complexes interact with the nuclear matrix which might be involved itself in splicing (9-14). Among the numerous hnRNP proteins (2, 15) several have been cloned and sequenced, but there is nevertheless only limited information available on their function, except for a few of them (2, 16). To investigate the structure and the function of the hnRNP proteins, we previously raised a monoclonal antibody library directed against hnRNP complexes purified from HeLa cells (1).
Among other aspects we used our anti-hnRNP monoclonal antibody library to investigate heat shock-induced splicing arrest. Indeed, splicing was previously shown to be transiently shut down following heat shock at the upper range of the stress response (17, 18). Since such a stress does not modify the general characteristics of hnRNP complexes (1, 19, 20), we assumed that splicing inhibition might be linked to changes at the level of a limited number of individual proteins. To check this hypothesis we screened our antibody library by indirect immunocytofluorescence on normal and heat-shocked HeLa cells, so as to detect possible differences either in signal intensity or distribution between both types of cells. As early as 10 min after the onset of a heat shock at 45 °C, we actually showed that the structure of hnRNP complexes is altered in a very subtle and reversible way. Indeed, among all antibodies from our library, only two of them revealed the kind of differences we were looking for. These antibodies named 2H9 (1) and 6D12 (20) recognize a 35-37- and a 72.5-74-kDa protein doublet, respectively. In our immunocytological assay using fixed cells, these antigens were only available to the antibodies in stressed cells, although Western blot analyses showed no quantitative variation in stressed versus normal cells. In stressed cells these antibodies revealed a bright nuclear signal present within the interchromatin space as numerous small dots. This signal persists for 2 h after cells were taken back at 37 °C and then gradually decreases and finally disappears after 6 h, which again corresponds to the situation in normal cells. By combining immunological and subcellular fractionation techniques, we could relate this observation to a rapid switch of both protein doublets from the hnRNP complexes to the nuclear matrix, a structure to which they bind very strongly (1, 20).
In this paper, we describe the cloning and the sequencing of the 2H9
cDNA that encodes the 35-37-kDa (or 2H9) proteins from HeLa cells.
The deduced amino acid sequence shows that they are genuine hnRNP
proteins that are related to the hnRNP F and H/H family. In order to
check in a direct way whether or not the 2H9 proteins are required for
pre-mRNA splicing, we tested the effect of anti-2H9 antibodies on
an in vitro cell-free system that faithfully splices E1A
transcripts of adenovirus 2 (21). Furthermore, since stressing HeLa
cells for 10 min at 45 °C causes nuclear extracts to be inactive in
in vitro splicing (22), such extracts were also analyzed and
compared with normal extracts, so as to find out whether there is a
correlation between the status of these 2H9 proteins in the cell-free
system and the fact that within the cell they transiently leave the
hnRNP complexes (1).
Monoclonal antibody 2H9 (IgG1), which is specific for the 2H9 proteins, was obtained as described previously (1), after immunizing Balb/c mice with hnRNP complexes purified from HeLa S3 cells. Both hybridoma culture supernatant and ascites fluids were used as monoclonal antibody sources.
For Western blotting analysis, proteins were resolved by SDS-PAGE and
electrophoretically transferred to nitrocellulose sheets, the blots
being further probed with 2H9 supernatant and 125I-labeled
anti-mouse Ig-F(ab)2 (1).
Peptidic maps were as described previously (20). Briefly, 2H9 proteins were immunoprecipitated from a nuclear extract, resolved by SDS-PAGE, and the 35- and 37-kDa bands cut out. Polypeptides were radioiodinated (Na125I) within the gel, using the chloramine-T method, and further hydrolyzed with trypsin or thermolysin. Peptides were resolved in two dimensions on cellulose-coated thin layer chromatography plates and visualized by autoradiography.
cDNA Libraries, cDNA Cloning, and SequencingcDNA cloning was by using a gt11- and a
gt10-cDNA library. The
gt11 library comprises random-primed
cDNAs cloned into the EcoRI site of the expression
vector; template RNA was a poly(A+) fraction isolated from
human MCF-7 cells. The
gt10 library we constructed according to
Sambrook et al. (23) contains oligo(dT)-primed cDNAs
cloned into the EcoRI site of the vector; template RNA was a
poly(A+) fraction isolated from HeLa S3-cell cytoplasm and
purified on poly(U)-Sepharose.
cDNA cloning was essentially performed by using standard techniques
described by Sambrook et al. (23). The random-primed gt11
library was immunoscreened for cDNA fragments encoding the epitope
recognized by monoclonal antibody 2H9. Such fragments were then used to
screen the oligo(dT)-primed
gt10 library, in an attempt to isolate
full-size cDNAs. For sequencing, cDNA was subcloned into
pBluescript SK+ and SK
. After generating a
series of partially overlapping deletion mutants, the nucleotide
sequence of each cDNA strand was determined according to the chain
termination method (24), using a single primer corresponding to a
vector sequence. In some cases primers corresponding to cDNA
sequences were used to obtain additional sequence information.
Purified cytoplasmic poly(A+) RNA was analyzed by electrophoresis on 1.2% agarose, 6% formaldehyde gels and transferred to nitrocellulose sheets by capillary blotting with 20 × SSC. Prehybridization and further hybridization with 32P-labeled probes were carried out according to Sambrook et al. (23).
In Vitro Expression and ImmunoprecipitationRecombinant pBluescript was linearized and
RNA transcribed in both directions with T3 and T7 RNA polymerase in the
presence of m7G(5)pppG. In vitro translation in
the presence of rabbit reticulocyte lysates (Amersham Corp.) and
[35S]methionine was performed according to the
manufacturer. Specific translation products were immunoprecipitated
with monoclonal antibody 2H9 previously coupled to CNBr-activated
Sepharose. Proteins were resolved on an SDS-10% polyacrylamide gel and
the labeled proteins visualized by fluorography.
The coding sequence of cDNA 2H9 was engineered
by polymerase chain reaction so as to add an NdeI site at
the 3 end and a BamHI site at the 5
end. This cDNA
fragment was then cloned either into a pET 3b expression vector
(Novagen) or into the same vector we modified by inserting a fragment
coding for an N-terminal His-tag. Recombinant protein expression was in
Escherichia coli BL21 following isopropyl-
-D-thiogalactopyranoside induction. For
recombinant antigen purification, bacteria from a 500-ml culture were
freeze-thawed, resuspended in 20 ml of 20 mM Tris-HCl, pH
7.9, 0.5 M NaCl in the presence of a mixture of protease
inhibitors, and the lysate further sonicated and centrifuged for 20 min
at 110,000 × g. The pellet containing the inclusions
was washed two times with buffer D and then dissolved in 2 ml of 6 M urea or guanidine HCl in buffer D, which yields
electrophoretically pure antigen. Renaturation was by step dialysis
against the same buffer containing 2 M (1.5 h) and 0.5 M (45 min) urea or guanidine HCl. Soluble recombinant protein from the supernatant was purified by immunoaffinity (antigen without His-tag) or by metal affinity chromatography (His-tagged antigen). Immunoaffinity was carried out on Sepharose-antibody columns,
the antigen being eluted with 3.5 M NaSCN or 4.5 M MgCl2 and further dialyzed against buffer D. His-tagged antigen was purified by chromatography on a Ni2+
chelation resin according to the manufacturer (Novagen); the antigen
was eluted with 0.4 M imidazole in 20 mM
Tris-HCl, pH 7.9, 0.5 M NaCl, and further dialyzed against
buffer D.
Potentially immunogenic amino acid stretches of the 2H9 protein sequence were determined from the hydrophilicity (25) and mobility (26) plots drawn from the predicted primary structure. Synthetic peptides with an additional Cys residue were prepared and further coupled to ovalbumin activated with m-maleimidobenzoyl-N-succinimide ester. For polyclonal antibodies, New Zealand rabbits were injected at 2-week intervals with 200 µg of peptide-ovalbumin. Sera were tested by immunoblotting for their ability to react with the 2H9 proteins, and antibodies were further immunopurified on a Sulfolink column (Pierce) coupled to the relevant peptide. For monoclonal anti-peptide antibodies, Balb/c mice were injected at 2-week intervals with 50 µg of peptide-ovalbumin, until specific humoral antibodies were detected. The mice were then given three 10-µg boosts over 3 days. On day 4, splenic cells were fused with X-63 myeloma cells; hybridoma cell lines were established as described previously (1). Monoclonal antibodies were purified from ascites liquids on ABx columns (J. T. Baker).
Cells and Heat Shock, Cytoplasmic and Nuclear ExtractsHeLa S3 cells were grown in Eagle's suspension medium supplemented with 10% newborn calf serum and antibiotics (penicillin, 100 IU/ml; streptomycin, 100 µg/ml). For heat treatment, cells were concentrated to 5 × 106 cells/ml and transferred to culture flasks, which were then immersed in a water bath for 10 min at 45 °C. Cytoplasmic S100 and nuclear extracts were prepared according to Dignam et al. (27) and dialyzed against buffer D for splicing assays.
Antibody Effect on In Vitro SplicingPlasmid Sp4 contains
the natural E1A sequence (nucleotides 533-1342) of adenovirus 2 between
the SmaI and Xba sites of the polylinker of
vector pSP65 (21). Capped E1A-precursor RNA was synthesized using
Sp6-RNA polymerase in the presence of m7G(5)pppG and
[
-32P]CTP, and further purified as described
previously (21).
Splicing reactions were carried out for 2 h at 30 °C in 25 µl of reaction mixtures containing 105 cpm of [32P]pre-mRNA (~4 ng), 10 µl of nuclear extract (6-8 mg of protein/ml) in the presence of 2.6 mM MgCl2, and 60 mM KCl as described previously (21). For studying the direct effect of antibody on splicing, the nuclear extract was preincubated at 0 °C for 30 min with either 10 µg of purified monoclonal antibody or 6 µg of purified polyclonal antibody. For control, the nuclear extract was preincubated with either an equal amount of the same antibody previously heat-denatured at 65 °C for 10 min or pretreated with 10 mM DTT at 30 °C for 30 min, or with nonrelevant antibody. After phenol extraction and purification, RNA was analyzed on 5.2% polyacrylamide gels in 8 M urea.
Double Immunocytofluorescence and Confocal MicroscopySchaffner HeLa cells (105 cells/ml) in Dulbecco's modified Eagle medium supplemented with 10% fetal calf serum and antibiotics (penicillin, 100 IU/ml; streptomycin 100 µg/ml) were grown on glass slides for 3 days, washed with PBS, and fixed for 4 min with 2% paraformaldehyde in PBS. When investigating the effect of heat shock, cell cultures were immersed in a water bath for 10 min at 45 °C prior to fixation. The cells were then permeabilized for 20 min with 0.1% Triton X-100, 0.05% NaN3 in PBS. After several washings with PBS/NaN3, they were incubated overnight with a mixture of 4A8 anti-H1 peptide monoclonal antibody (1 µg/ml) and rabbit anti-p80 coilin antibody (1:1000) in PBS. The cells were then washed with PBS/Triton/NaN3 and further incubated for 45 min with a mixture of Cy3-conjugated goat anti-mouse IgG (1:200) and fluorescein isothiocyanate-conjugated donkey anti-rabbit IgG (1:100, Jackson Immunoresearch Lab.) in PBS/Triton/NaN3. The cells were washed again and DNA counterstained with Hoechst 33258. The preparations were mounted in glycerol/PBS (4:1) containing 5% propylgallate as an anti-oxidant. Immunofluorescence images from 0.6-µm optical sections were obtained using a Leica confocal laser scanning microscope equipped with a PL APO 100/1.4 oil immersion lens and a krypton-argon laser. Excitation wavelengths of 488 and 568 nm were selected for fluorescein isothiocyanate and Cy3, respectively. Hoechst images were acquired using a Kappa video camera connected to the Leica digitizer. Pseudo-colored images of the signals were generated and further superimposed using an image processing program.
Gene Mapping by in Situ HybridizationIn situ
hybridization was carried out on chromosomes prepared from
phytohemagglutinin-stimulated human lymphocytes cultured for 72 h,
the last 7 h being in the presence of 5-bromodeoxyuridine (60 µg/ml). The recombinant Bluescript II SK plasmid
containing the 2H9 coding sequence was tritium labeled by nick
translation (1.5 × 108 dpm/µg) and hybridized to
metaphase spreads (100 ng/ml), as described previously (28). The slides
were coated with nuclear track emulsion (Kodak NTB2),
exposed for 18 days at 4 °C, and then developed. R-banding was
performed using the fluorochrome-photolysis-Giemsa method.
As described
before by Lutz et al. (1), the 2H9 proteins (35 and 37 kDa)
shown in Fig. 1 (left panel) share a series
of characteristics, including a common epitope recognized by monoclonal antibody 2H9. In order to rapidly assess to what extend these two
protein species are related, they were purified and further analyzed by
peptidic mapping. Following digestion with trypsin (Fig. 1,
A and B) or thermolysin (not shown), the two
protein species revealed similar maps, thus indicating a high degree of homology. cDNA cloning was therefore expected to lead at least to
very close coding sequences.
By immunoscreening the random-primed gt11 expression library with
antibody 2H9, we isolated one single positive plaque with a 330-bp
insert. Northern blot analysis on poly(A+) mRNA from
HeLa cells, using this 330-bp cDNA as a probe, revealed two
transcripts of 1.5 and 2.3 kb (Fig. 2). According to
their size, both of them might account for the 35- and the 37-kDa
proteins, which need a coding sequence at the most of 1000 to 1100 nucleotides. The 330-bp probe was then used to screen the
oligo(dT)-primed
gt10 cDNA library. Although numerous positive
plaques were obtained, only one of them contained an insert whose size
(1.7 kb) was consistent with that of the 2H9 proteins and which also
hybridized with both 1.5- and 2.3-kb mRNAs shown in Fig. 2.
In order to check whether this 1.7-kb cDNA really encodes one or
both of the 35- and 37-kDa proteins, in vitro translation experiments were carried out. Fig. 3 shows that
following immunoprecipitation with monoclonal antibody 2H9, a
35-37-kDa protein doublet is detected (B, lane 2), the two
bands being in the same proportion as in the control nuclear extract
(lane 3). These data show that the 1.7-kb cDNA
apparently contains the entire coding sequence for both 35- and 37-kDa
proteins. However, in terms of size our cDNA lies between the 1.5- and 2.3-kb mRNAs, thus suggesting that it is derived from the
larger transcript.
Nucleotide Sequence Analysis of the 1.7-kb cDNA
The
nucleotide sequence of the 1.7-kb cDNA is shown in Fig.
4. This sequence contains a single long translational
reading frame of 1038 bp, starting 303 bp from the 5-terminus, all
other possible frames being less than 200 bp long. The ATG codon at position 303 is flanked by nucleotides matching the translation start
consensus sequence (A/G)NNATGG (29). The open reading frame, which is
terminated by a TGA codon, is followed by 340 bp of 3
-untranslated
sequence which contains an AATAAA polyadenylation signal (position
1406) and a putative ATTTA instability sequence which is thought to be
involved in post-transcriptional regulation of gene expression (30).
However, although this cDNA contains the entire coding sequence, it
is missing the terminal part of the 3
-untranslated sequence. Indeed,
the polyadenylation signal is clearly not in the vicinity of the 3
end, which moreover is not terminated by a poly(A) sequence. Whether
this 1.7-kb cDNA is really an incomplete copy of the 2.3-kb
mRNA was investigated by Northern blotting. 32P-Labeled
cDNA probes corresponding to the 5
-untranslated sequence (Fig.
5, lane 1), to the coding region (not shown),
and to a region starting shortly after the stop codon and including the
entire downstream 3
sequence (lane 2), all hybridized with
both 1.5- and 2.3-kb mRNAs. In contrast, a probe spanning the
3
-terminal sequence located downstream from the polyadenylation site
only revealed the 2.3-kb mRNA (lane 3), thus showing
that the 1.7-kb cDNA is definitely derived from the 2.3-kb mRNA
but lacks the 3
-untranslated terminal part.
Analysis of the cDNA-deduced Amino Acid Sequence
The
predicted 2H9 primary sequence corresponds to a protein of 346 amino
acids (Fig. 4) with an expected molecular weight of 36,000, which
matches the experimental values (35 and 37 kDa). This protein sequence
reveals the presence of two consensus sequence RNA-binding domains,
CS-RBD I and CS-RBD II, of ~80 amino acids each. Data
base searches (Blitz EMBO) revealed high homologies between these
domains and two of the three CS-RBDs of hnRNP F (53 kDa) (31) and the
closely related hnRNP H/H (49 kDa) (32). The sequence alignment (Fig.
6A) reveals homologies of 89% between 2H9-RBD I and F-RBD II, 80% between 2H9-RBD I and H/H
-RBD II, and
85% between 2H9-RBD II and F- or H/H
-RBD III. It should be noted that
protein 2H9 does not have the F- or H/H
-RBD I counterpart; the
presence of several stop codons in the 5
-untranslated region of
cDNA 2H9, one of them being located nine codons upstream from the
initiation codon (Fig. 4), confirms that this RBD is really absent.
The primary sequence of protein 2H9 also reveals the presence of two
Gly-rich auxiliary domains (Fig. 4), one is located in the central
region between the two RBDs (amino acids 96-193; 32% of Gly) and the
other is in the C-terminal region (amino acids 273-346; 48% of Gly),
starting immediately after RBD II. Gly-rich internal and C-terminal
counterparts are also present in hnRNP F (18 and 21% of Gly) and in
hnRNP H/H (27 and 23% of Gly). In contrast to the RBDs, the Gly-rich
domains are less conserved (Fig. 6B); the internal domain of
protein 2H9 shows 50 and 34% homology with that of hnRNP H/H
and F,
respectively, whereas the C-terminal domain appears to be even less
conserved, showing a conspicuous 20-amino acid insert only present in
hnRNP H/H
. Further examination of the two glycine-rich auxiliary
domains reveals the presence in protein 2H9 of 17 Tyr residues among
which 15 are conserved in hnRNP F or H/H
either as Tyr or Phe. In the internal domain, two types of residues are well conserved too: the
charged residues (Arg, Lys, Asp, and Glu) and the proline residues
which are clustered within a element showing itself a high degree of
conservation (2H9 amino acids 101-117).
A comparison of the 2H9 Gly-rich domains with the C-terminal Gly-rich
domain of the basic hnRNP A1, A2, and B1 proteins (33, 34) shows
substantial sequence divergence, although the latter also display
numerous interspersed aromatic residues, which in hnRNP A1 are
essentially present within GNF/YGGS/GRG consensus repeats (35).
Although no such repeat is present in the 2H9, F, and H/H proteins,
one can, however, notice the presence in protein 2H9 of a short
GGXG repeat (Fig. 4, underlined), which interestingly is the central motif of the RGGXGGR repeat
present in the GAR domain of the Gly-rich region of human nucleolin and fibrillarin and yeast NSR1, which are all known to be involved in
pre-rRNA processing (36). This GGXG repeat is also present in the hnRNP A1, A2, and B1 but is not conserved in the hnRNP F and
H/H
proteins.
Additional data base searches for potential post-translational modifications showed that 2H9 sequence contains one possible glycosylation site on the Asn residue at position 307 and eight possible phosphorylation sites. However, we have not yet been able to show experimentally either of these modifications in HeLa cells.
2H9 Proteins and In Vitro SplicingIn previous studies we showed that in normal HeLa cells the 2H9 proteins are associated with hnRNP complexes (including pre-mRNPs) and are off these structures following a 10-min stress at 45 °C, thus suggesting that they might be involved in a mechanism that turns splicing on and off (1). To assess this hypothesis we first tested in a direct way whether these proteins are really involved in splicing. Therefore, we checked whether specific antibodies can directly inhibit an in vitro splicing system comprising an 854-nucleotide pre-mRNA synthesized from plasmid Sp4 which contains the natural adenoviral E1A sequence (21). In the salt conditions indicated under "Experimental Procedures," a single 114-nucleotide intron is excised from this pre-mRNA, giving rise to a 13 S mRNA, the final splicing product we will also refer to as E1:E2.
Preincubating a nuclear extract with monoclonal antibody 2H9 only led
to a weak but reproducible inhibition of splicing in vitro
when compared with nonrelated monoclonal antibody 5G4 (mAb-NR) from our
library (Fig. 7A, compare lanes 4 and 3). Since these data relied on a single antibody with
relatively low affinity, we raised both polyclonal and monoclonal
antibodies against synthetic peptides representing different regions of
the 2H9 primary sequence. The first antibodies we obtained were two
monoclonals (4A8 and 1C9) and one rabbit polyclonal antibody, all
directed against peptide H1 (amino acids 161-174) which is not
conserved in hnRNP F and H/H (see Fig. 6B). As the original
2H9 monoclonal antibody (1), the anti-peptide antibodies only recognize
the 2H9 proteins in a nuclear extract or in purified hnRNP complexes.
Preincubating a nuclear extract with any of the three previously
immunopurified anti-peptide antibodies severely inhibited the 13 S
mRNA accumulation. Fig. 7A shows the inhibition we
obtained when using anti-peptide H1 monoclonal antibody 4A8 (mAb H1,
lane 5) and anti-H1 polyclonal antibody (pAb-H1, lane
7). In comparison with control splicing, only small amounts of
13 S mRNA are detected. Moreover, exon 1 does not further
accumulate, which indicates that inhibition occurs during spliceosome
assembly. Using nonrelated monoclonal antibody 5G4 (mAb-NR, lane
3), nonrelated polyclonal IgGs (pAb-NR, lane 6), or
mAb-H1 denatured either by heat (65 °C for 10 min; Fig. 7B,
lane 10) (37, 38) or dissociated with DTT (10 mM at
30 °C for 30 min; Fig. 7B, lane 11) relieves splicing
inhibition, thus showing that the inhibition we observe is due to
specific antibody-antigen interactions. Additional splicing assays
carried out with rabbit
-globin pre-mRNA substrate containing
intron 1 led to similar splicing inhibition (not shown).
We further carried out specific depletion assays that were designed for further complementation. Experiments performed by using purified anti-peptide antibodies coupled to Sepharose-CNBr actually allowed removal of more than 90% of the 2H9 proteins from the nuclear extracts, as judged by Western blot analysis. However, such depleted extracts were still totally active in splicing in vitro (not shown) (see "Discussion").
The 2H9 Proteins Are Missing in Splicing Deficient Nuclear Extracts from Briefly Stressed CellsNuclear extracts from cells
heat-shocked for 1-2 h at 43.5 to 45 °C were earlier shown to be
inactive in splicing, which correlated with U-snRNP disruption (17). In
fact, hnRNP complexes are modified as early as 10 min following a heat
shock at 45 °C, since we previously found that 2H9 proteins and also
a 72.5-74-kDa protein doublet, we subsequently showed to be hnRNP M
proteins (22, 39), leave the hnRNP complexes and strongly bind to the
nuclear matrix (1, 20). Recently we have shown that nuclear extracts
prepared from cells stressed in these conditions are in fact already
splicing defective, but interestingly the U-snRNPs appear to be still
active (22). In order to find out what might explain this loss of
splicing activity, we compared the protein content of extracts from
normal and stressed cells first by SDS-PAGE analysis, which did not
reveal any significant difference (see also Fig.
8A, panel 1). We then screened by
Western blotting our anti-hnRNP monoclonal antibody library, which
includes anti-SR splicing factor 9G8 antibody (40), and in addition we
tested other antibodies like anti-hnRNP C (4F4) and anti-hnRNP U (3G6).
This latter analysis only revealed two differences, one of them being
that the hnRNP M proteins are clearly missing in extracts from stressed
cells (22).
The second difference is that the 2H9 proteins are also missing in nuclear extracts prepared from cells heat-shocked at 45 °C for 10 min (Fig. 8A, panel 2). In fact, this was not quite unexpected since we earlier showed that, within HeLa cells, this protein doublet behaves exactly as the hnRNP M proteins with respect to heat shock (1, 20). Since extracts from such stressed cells are totally inactive in splicing in vitro (Fig. 8B, lanes 1 and 2), we then tried to see whether splicing might be restored by complementation with the purified protein. Since the 2H9 proteins could not be efficiently immunopurified from normal nuclear extracts, we expressed the recombinant protein in E. coli (Fig. 8C). Whatever the recombinant protein we used, His-tagged or not, purified from the soluble fraction or from inclusions, complementation only led to a faint but nevertheless reproducible 13 S mRNA band (Fig. 8B, lane 4). Further complementation with both 2H9 and hnRNP M recombinant proteins together did not improve splicing efficiency (not shown). Complementing such an inactive nuclear extract with an S100 extract, which contains 2H9 proteins but no SR factors (40), significantly restores splicing (lane 3), thus showing that the SR factors in the extract from stressed cells are still active; it should be noted that the weaker 13 S mRNA band is due to the fact that in this assay we could only use half the amount of nuclear extract present in a standard assay.
The 2H9 Proteins Are Also Detected in Nuclear BodiesBy
indirect immunocytofluorescence we have previously shown that in normal
HeLa cells the 2H9 proteins are not available for the original 2H9
monoclonal antibody, whereas cells heat-shocked for 10 min at 45 °C
reveal a bright nuclear signal distributed as numerous small granules
as shown in Fig. 9D (inset) (1). Later on, when routinely supplementing cell culture medium with 10%
fetal calf serum instead of the newborn and fetal calf serum combination (7.5:2.5%) used previously, we still observed the previously described signal, but in both normal and stressed
interphasic cells we also detect a few brightly stained nuclear bodies,
which are often present as pairs, close to the nucleoli (Fig. 9,
A and D). These data were obtained with monoclonal
antibody 2H9, anti-peptide H1 monoclonal antibodies (1C9 and 4A8), as
well as with other monoclonal antibodies we obtained more recently and
which are directed against other peptides. These nuclear bodies are not nuclear speckles, known to contain several splicing factors, but their
size and shape rather point to coiled bodies, which were shown to
contain splicing factor U2AF (41, 42). Double immunocytofluorescence assays using an anti-peptide H1 monoclonal antibody (Fig. 9,
A and D) and a rabbit polyclonal anti-coilin antibody
to label coiled bodies (43, 44) (Fig. 9, B and
E), however, show that the nuclear bodies revealed with the
anti-H1 antibody are not coiled bodies (Fig. 9, C and
F).
Following these observations, we went back to the nuclear extracts in order to check whether any of their properties might also be serum-dependent. Therefore, we grew cells in 10% fetal calf serum and prepared nuclear extracts from normal and heat-shocked cells. In fact, when assayed for in vitro splicing capacity and for the presence of 2H9 proteins, as well as for hnRNP M proteins (22), these extracts did not reveal any difference with the extracts described above and which were prepared from cells grown in 10% newborn calf serum.
Southern Blot Analysis and Chromosomal MappingSouthern blot analysis was performed on human cellular DNA digested with either EcoRI (1 site in 2H9 cDNA) or TaqI (1 site) and further blotted on Highbond N+. Hybridization under normal stringency conditions, using as a probe 1.7-kb cDNA labeled with 32P by random priming (23), revealed two EcoRI bands and two Taq I bands. Cellular DNAs from different individuals from the CEPH (Centre d'Etude du Polymorphisme Humain) family panel all revealed this pattern, no polymorphism being observed (not shown).
In situ hybridization was performed on metaphasic human
lymphocytes as described before (28). Within the 100 cells examined, 154 silver grains were associated with chromosomes, and 32 of these
(21%) were located on chromosome 10; the grain distribution was
nonrandom since 24 out of 32 (75%) mapped to the q22 band of the long
arm of chromosome 10. These results allow us to map the 2H9
gene to the 10 q22 band of the human genome (Fig. 10). These results, along with the Southern blot data, suggest a single 2H9
locus in the human genome.
In the present work we investigate the structure and function of
the 2H9 proteins (35-37 kDa) we have previously shown to be involved
in minute and reversible alterations of hnRNP complexes triggered by a
10-min heat shock at 45 °C (1). The 1.7-kb cDNA we isolated
encodes genuine 2H9 proteins (Fig. 3). It further hybridizes with two
poly(A+) mRNAs of 1.5 and 2.3 kb (Fig. 2), which
probably differ by their 3-untranslated sequence, due to differential
use of two polyadenylation signals. Moreover, both 35- and 37-kDa
protein species are produced by the single mRNA transcribed from
the 1.7-kb cDNA. These data, together with those obtained by
Southern blotting and chromosomal mapping, point to the 2H9 proteins as
products from a single gene.
Since both 35- and 37-kDa protein species are synthesized in vitro from a single mRNA species, it is likely that one of the proteins derives from the other by post-translational modifications. Alternative use of the second but less favorable ATG codon (amino acid position 5) (29) might be another possibility, which in addition would explain the lesser proportion of the 35-kDa protein. Furthermore, the 35-kDa protein might also occur by proteolytic cleavage of the 37-kDa species, as several potential cleavage sites for trypsin-like (Arg) and chymotrypsin-like (Met, Trp, Tyr) proteases are present within the rather hydrophilic C terminus.
The predicted 2H9 primary sequence reveals that protein 2H9 is a new
member of a family of related but distinct hnRNP proteins that includes
hnRNP H/H (49 kDa) and hnRNP F (53 kDa) (31, 32). HnRNP H and H
,
which are homologous at 96%, share 75% identity with the hnRNP F,
including three highly conserved RBDs. As protein 2H9 is lacking the
upstream RBD and only shows 57 and 59% homology with the comparable
sequences in hnRNP F and H/H
, they clearly appear to be the most
divergent within that family. This actually correlates with the fact
that affinity chromatography of nucleoplasmic proteins on poly(rG)
selected hnRNP E, F, H, and M but apparently not the 2H9 proteins (31).
Indeed, although the 2H9 RBDs are highly conserved in hnRNP F and H,
differences appear for instance within loop 3 (Fig. 6A) and
its adjacent sequences (Fig. 6B), which might well confer a
somewhat different RNA sequence specificity to the 2H9 proteins. Such
structural similarities between the corresponding RBDs of hnRNP
proteins 2H9, F, H, and H
are likely to provide more flexibility in
modulating RNA binding, which for a growing number of hnRNP proteins
appears to underly an RNA annealing or chaperone activity designed to
bring RNA sequences in a position and a configuration within the
splicing complex so as to become available for splicing reactions
(45-47). Despite these structural relationships it should be noted
that these proteins have different chromosomal locations in the human
genome, mapping to locus 10q11.21/22 (hnRNP F), 5q35.3 (hnRNP H), Xq22
and/or 6q26 (hnRNP H
) (32), and 10q22 (2H9).
Another feature protein 2H9 shares with hnRNP F and H is the presence
of a Gly-rich auxiliary domain located between RBD I and II (2H9) or
RBD II and III (hnRNP F and H) and a second one in the C-terminal
region. Interestingly, aromatic amino acid residues (essentially Tyr)
interspersed along these two domains are mostly conserved, thus
suggesting a role in structure and function. Moreover, as hnRNP F and
H, protein 2H9 displays a sequence similar to a 30-40-amino acid
domain present in hnRNP A1 and A2 and which is known to localize hnRNP
A1 to the nucleus (48, 49). Interestingly, a simplified hnRNP A1/A2
consensus,
YX2FX2YX5FX7FX7-9Y
(X is often G and N), deduced from the domain defined by
Weighardt et al. (49), matches very well the hnRNP F/H and
2H9 consensus we determined as
YX2Y/FX2YX5-6YX6FX5Y;
in protein 2H9 this consensus is starting at position 147 (Fig.
6B). Numerous interspersed aromatic amino acids some of them
being in GGXG repeats is also one of the features of the
C-terminal Gly-rich domains of hnRNP A1, A2, and B1 proteins. By
analogy with the properties of the extensively studied hnRNP A1 domain
(35, 36, 46), one can assume that the 2H9 proteins might also have the
capacity to bind RNA unspecifically, which is thought to allow
migration along the RNA, until RBDs reach the specific high affinity
RNA sequences (36). Furthermore, we observed earlier that the 2H9
proteins can bind the major or basic hnRNP proteins (1), which is in line with studies showing that Gly-rich domains promote protein-protein interactions (35, 36, 50). Unlike hnRNP A1, A2, and B1 which contain a
single Gly-rich domain, the 2H9 proteins as well as hnRNP F and H/H
exhibit two of them which might confer these proteins increased
functional potentialities linked to both protein-RNA and
protein-protein contacts.
As to the function of the 2H9 proteins, we show that three anti-peptide
H1 antibodies (two monoclonals and one polyclonal) did inhibit in
vitro splicing of an adenovirus pre-mRNA, which points to
direct or indirect involvement of these proteins in splicing in
vitro. Unfortunately, splicing inhibition in vitro could not be confirmed by specific immunodepletion, although only low
amounts of 2H9 proteins were left in the extracts. In fact, this result
might well be explained by the extensive structural relationships
between protein 2H9 and hnRNP F and H/H, which are likely to allow
some interchangeability; indeed, 2H9-depleted nuclear extracts may
still contain hnRNP F and H/H
which are not recognized by the
anti-peptide H1 antibodies and might then functionally replace protein
2H9 in splicing assays in vitro. An additional clue in favor
of the involvement of the 2H9 proteins in splicing is provided by our
heat shock approach. Indeed, it turns out that such extracts can be
viewed as resulting from an in vivo depletion process since
they are splicing deficient, which interestingly correlates with the
absence of hnRNP M (22) and that of the 2H9 proteins too. This
correlation makes all the more sense since the absence of these two
protein families is in line with their behavior in vivo,
switching simultaneously from the hnRNP complexes to the nuclear
matrix, briefly upon the onset of a heat shock at 45 °C (1, 20).
However, attempts to restore the splicing capacity of nuclear extracts
from stressed cells were hardly conclusive, either due to the fact that
the recombinant 2H9 and hnRNP M proteins we used are not fully
representative of the native proteins, especially with regard to
conformation, post-translational modifications, and number of isoforms,
or because the process is really more complex in the sense that other
proteins, for instance the related hnRNP F and H/H
, are perhaps also
missing in the extract. So, taken together, our investigations provide a series of convergent data supporting the idea that hnRNP proteins 2H9
(this study) and hnRNP M (22) are directly or indirectly involved in
the splicing process and further participate in heat shock-induced
splicing arrest by leaving the hnRNP or splicing complexes.
With this novel hnRNP protein 2H9, which is closely related to hnRNP F
and H/H, and also linked to the basic hnRNP A1, A2, and B1, we further
emphasize the complex structural relationships occurring within the
hnRNP protein population and which most likely reflect a great
flexibility in regulating and tuning the splicing mechanisms. For
instance, there are now evidences that various hnRNP proteins can
influence 5
splice site selection in alternative splicing. HnRNP A1
does so by antagonizing the SF2/ASF and SC-35 splicing factors, which
has been shown in vitro (46, 51) and in vivo (52,
53). Interestingly, hnRNP F participates in the inclusion of
neuron-specific alternative exon N1 in mouse c-src mRNA
(54). Finally, it has also been shown that Drosophila hnRNP protein hrp48 and a 97-kDa RNA binding protein referred to as P element
somatic inhibitor are involved in the regulation of P element
pre-mRNA splicing (55). In this context of hnRNP-protein relationships, it is also worth mentioning that two monoclonal antibodies from our anti-hnRNP library recently allowed us to identify
two hnRNP-associated proteins showing a nuclear speckled distribution
similar to that of splicing factors and which share structural features
with the multifunctional adenoviral 72-kDa protein (56).
We finally showed that changing the cell culture conditions, in this case fetal calf serum concentration, is sufficient to partially modify the behavior of the 2H9 proteins. In fact, in addition to the previously observed nuclear distribution (1), we also detected their presence in nuclear bodies that do not colocalize with coilin and therefore are not coiled bodies according to the currently admitted criteria (43, 44). Actually, an increasing number of hnRNP-complex components are found to be also present in nuclear bodies, which comprise five different classes including the coiled bodies (57). Indeed, 2H9 proteins, along with hnRNP M (22), K (58), and L (59) proteins, are also present in yet undetermined nuclear bodies, whereas U-snRNPs and splicing factor U2AF also localize in coiled bodies (41, 42, 60). This further fits in a more recent concept of the splicing apparatus, which emphasizes the fact that some of its components are actually present in several nuclear compartments other than pre-mRNA processing sites (61-63). Whether upon increasing fetal calf serum concentration 2H9 proteins switch to these nuclear bodies or just become accessible to the antibody is not known yet. However, this aspect of the behavior of these proteins shows that they most likely also intervene in mechanisms enabling cells to physiologically adjust to various environmental changes, which might not necessarily correspond to what is usually referred to as stress situations.
The nucleotide sequence(s) reported in this paper has been submitted to the GenBankTM/EMBL Data Bank with accession number(s) L32610[GenBank].