(Received for publication, November 18, 1996)
From the Institut für Physiologische Chemie, Johannes-Gutenberg Universität, Duesbergweg 6, D-55099 Mainz Germany
Transcription of the gene encoding for the
nuclear autoantigen La resulted in La mRNA isoforms. A promoter
switching combined with an alternative splicing pathway replaced the
exon 1 with the exon 1. The exon 1
contained GC-rich regions and an
oligo(U) tail of 23 uridine residues. Moreover, it encoded for three
open reading frames upstream of the La protein reading frame. Despite this unusual structure, when exon 1
La mRNAs were expressed in transfected cells, both exon 1 and 1
La mRNAs were translated to
La protein, whereas the upstream open reading frames of the exon 1
were not translated. In addition to full-length exon 1
La mRNAs
5
-shortened exon 1
La mRNAs were detected. The exon 1
5
-starts
varied in dependence on the analyzed tissues. Like the full-length exon
1
La mRNA a 5
-shortened exon 1
construct starting downstream of
the oligo(U) tail but upstream of the open reading frames 2 and 3 was
also well translated when transfected in mouse cells. Thus all La
mRNA forms represent functional La mRNAs.
One of the target antigens of sera suffered from autoimmune
patients with rheumatoid diseases such as systemic lupus erythematosus or primary Sjögren's syndrome (pSS)1
is the nuclear autoantigen La (SS-B) (1). The La protein was described
to associate at least transiently with all primary RNA polymerase III
transcripts including precursor molecules of ribosomal 5 S RNA, tRNAs,
and some 4.5 S RNAs, as well as a portion of the uridine-rich small
nuclear RNAs U1 and U6 (2-5). Common to all primary RNA polymerase III
transcripts is their 3-terminal oligo(U) tail, which is transcribed
during the transcription termination step. These oligo(U) tails were
shown to be a binding site for the La protein (6). In addition to the
oligouridylated RNA polymerase III transcripts, an association of the
La protein with some nonoligouridylated RNAs has been reported
especially for some viral RNAs including the leader RNAs of the
vesicular stomatitis virus and rabies virus (7, 8).
The La protein is assumed to be involved in transcription termination of RNA polymerase III and internal initiation of translation of at least the poliovirus mRNA (9-12).
Most recently five La cDNAs were isolated when a cDNA library
made from peripheral blood lymphocytes (PBLs) of a patient with pSS was
screened with her own anti-La serum (13). In two of these five La
cDNAs the exon 1 was replaced with an alternative 5-end. Genomic
analysis revealed that these La cDNAs represented alternatively
spliced transcripts of the La gene. An additional promoter site was
identified in the intron between exons 1 and 2, which served as
initiation site for transcription of the alternative exon 1
.
The exon 1 La mRNA form had an unusual 5
terminus. It contained
GC-rich regions and an oligo(U) tail of 23 uridine residues and encoded
for three upstream open reading frames (ORF1 to 3). The ORF1 encoded
for a putative peptide of 5.4 kDa. It was interrupted from the La
protein reading frame by two stop codons. The ORF2 and ORF3 were not in
the reading frame of the La protein. Qualitative and quantitative
analysis of expression of the exon 1 and exon 1
La mRNAs showed
that both La mRNA forms represented finally processed abundant
cytoplasmic mRNAs. Exon 1 to exon 1
La mRNAs were expressed at
ratios between 1:1 and 1:5 (15, 16).
Due to the unusual structure of the exon 1 La mRNA it still
remained unclear whether the exon 1
La mRNA is a translatable mRNA and if so, which of the reading frames is used for
translation. This was of special interest because one of the exon 1
La
cDNAs contained a frameshift mutation in a recently detected hot
spot region in the exon 7 of the La gene (14). The frameshift mutation caused a premature stop codon in the La protein reading frame. Thus the
mutant exon 1
La mRNA could encode for a C-terminally truncated
mutant La peptide of 29 kDa.
Here we present evidence that exon 1 La mRNAs can be translated to
La protein, whereas the upstream ORFs are not used for translation.
The following materials were obtained:
BstEII, EcoO109, EcoRI,
KpnI, pGEX-2T, and T7-sequencing kit from Pharmacia Biotech Inc. (Freiburg, Germany); SalI, NheI, and
NcoI from MBI Fermentas (St. Leon-Rot, Germany);
QIAprep-spin kit and QIAEX were from Qiagen (Hilden, Germany); DMEM,
Opti-MEM medium, LipofectAMINE, and Taq polymerase from Life
Technologies, Inc. (Eggenstein, Germany); BglII,
Pfu polymerase, pBluescript SK() from Stratagene GmbH (Heidelberg, Germany); CDP-Star Tropix, pCI-neo, pCI, and pGEM-T vector
systems from Promega (Serva, Heidelberg, Germany); shrimp alkaline
phosphatase, BstXI, HindIII, Taq
buffer (10 ×), DNA molecular weight marker VI, blocking reagent from
Boehringer Mannheim (Mannheim, Germany); agarose and NuSieve-agarose
from Biozym (Hameln, Germany); anti-mouse IgG conjugated with
peroxidase developed in sheep ((Fab
)2 fragments) adsorbed
with human serum proteins, anti-human and anti-rabbit IgG-conjugated
with alkaline phosphatase, and isopropyl
-D-thiogalactopyranoside from Sigma; the ECL-Western
blotting detection reagents from Amersham-Buchler (Braunschweig,
Germany); 4-nitro blue tetrazolium chloride and
5-bromo-4-chloro-3-indolyl phosphate from Roth (Karlsruhe, Germany);
and polyvinylidene difluoride membrane (IPVH 000 10; pore size 0.45 µm) obtained from Millipore (Bedford, MA, U. S. A.).
The anti-La mAb SW5, which was found to be directed to the N-terminal domain of La protein (17), was originally described by Smith et al. (18). The hybridoma supernatant was kindly provided by Prof. vanVenrooij (University of Nijmegen, The Netherlands). As anti-La serum we used the serum of the patient (Ma) (12).
Polymerase Chain ReactionPCR was performed using a TC9600 Cycler (Perkin-Elmer, Überlingen, Germany). The 50-µl assay in 1 × Taq buffer contained 2 units Taq polymerase, 1.5 mM MgCl2, 5% (v/v) Me2So, 200 µM dNTP, 20 pmol of each primer, and 1 ng of DNA. Cycling was started by heating for 3 min to 95 °C. 40 cycles followed, each consisting of 15 s at 94 °C, 15 s at 57 °C, and 1 min at 72 °C. Then the temperature was held for 10 min at 72 °C and cooled down to 4 °C.
The PCR products were further analyzed by agarose gel electrophoresis. PCR fragments were visualized by ethidium bromide staining. Isolated PCR fragments were either directly sequenced or sequenced after subcloning into pGEM-T (13).
DNA Sequence AnalysisDNA was prepared using the QIAprep-spin kit and concentrated by ethanol precipitation to a final concentration of about 1 µg/µl in Tris-EDTA buffer (10 mM Tris, 1 mM EDTA, pH 8.3). DNA sequencing was performed as described previously (13).
5For an
analysis of the 5-ends of the La mRNAs we chose the 5
-rapid
amplification of cDNA ends system (5
-RACE) supplied by Life
Technologies, Inc. It includes a first strand cDNA synthesis and a
PCR amplification step. During reverse transcription 40 units of RNase
inhibitor were added to each 1-µg RNA sample. The RNA samples were
isolated from either (adult) liver (L) of the tumor patient, human
fetal spleen (20th week), PBLs of the patient with pSS, and PBLs of a
(adult) control person, and mouse LTA cells, which were untransfected
or transfected with the human either La gene or La exon 1 La cDNA
(19). Although the liver tissue of the tumor patient did not obviously
show metastasis, the tissue displayed an abundant expression of the
c-myc oncogene (data not shown).
The RNA was isolated as described earlier (13). The reactions and the
following 5-RACE steps were performed according to the instructions of
the supplier. For the first strand synthesis the primer P1 locating
within the exon 4 was used (P1, CACTGATTTCCATGAGTTCTGCCTTGG). This
primer was extracted with phenol/chloroform and diluted in diethyl
pyrocarbonate-treated bidistilled water. The first amplification was
performed using the Anchor primer of the supplier as upstream primer
and the primer P2 locating in the exon 3 (P2,
TGTCCCGTGGCAAATTGAAGTCGCC) as downstream primer. The cDNA synthesis
and the first amplification step is schematically summarized in Fig. 2
(S).
The cDNAs were further amplified using nested primer pairs. The
nested primer pairs consisted of the common downstream exon 2 primer P3
(P3, GATGACAGATTTTGGCCTCCAG) in combination with either the exon 1 specific upstream primer P4 (P4, GAGTCGTTGCTGTTGCTGTTTG) or the exon 1
specific upstream primer P5 (P5, TTCTAGTCTCACCGAAGGCTTGTG) (see also
Fig. 2 (A1). Alternatively the cDNAs were amplified using a combination of the universal amplification primer (UAP) of the
supplier with either the exon 1
specific downstream primer P6 (P6,
CTGAAACCTGATGTGAGCGATG) or the exon 1 specific downstream primer P7
(P7, CCACAGGCTCACAAACAGCAAC) as schematically summarized in Figs. 2
(B1) and 3 (S).
All exon 1 and 1 constructs were cloned in the two
transfection vectors pCI-neo and pCI according to the following
strategy. Cloning started from the La cDNA La23 in pBluescript
SK(
). The La insert in La23 started at the 5
-site with an oligo(dT)
tail and represented a 5
-shortened exon 1
La mRNA derivative.
Therefore, in a first step an exon 1
full-length La cDNA had to be
constructed. In parallel an exon 1 full-length La cDNA was
constructed. Because La23 started at the 5
terminus with 51 dT
residues, this irregular oligo(dT) tail was shortened to 5 dT residues
to obtain the 5
-shortened exon 1
construct. During cloning we learned
that La23 contained a frameshift mutation within the coding region
(Ref. 14; see also Fig. 6, ORF1 La(N)). Because all
constructs were derivatives of La23, in a further cloning step the
mutated reading frame was replaced with the correct reading frame,
which was obtained from the La cDNA La19.
For the first step of the cloning procedure 5-exon 1
and 5
-exon 1 fragments were required and prepared by PCR using the proofreading
Pfu polymerase. In the case of the exon 1
fragment, PCR was
performed using DNA of a genomic subclone as substrate. The subclone
was prepared from the charon phage Lambda 2.1 (19), which was a gift by
Prof. J. D. Keene (Duke University, Durham, NC). Restriction of Lambda
2.1 DNA with EcoRI resulted in a 4.4- and a 4.6-kilobase
fragment. The 4.6-kilobase EcoRI fragment was isolated and
subcloned into pBluescript SK(
). This subclone contained besides the
exons 1 and 2 the intron between exons 1 and 2 including the exon 1
.
PCR was performed using as upstream primer P8 (P8, CGCTTTGCGCGACTGCGCGTTTCC; the artificial
SpeI site is underlined) and as downstream primer P6. The
resulting exon 1
fragment started at the predicted 5
-start of exon 1
(13) and ended downstream of an EcoO109 site, which located
downstream of the oligo(dT) stretch in the La sequence. The exon 1
fragments were cleaved with SpeI and EcoO109 and
cloned into the respective sites of La23. For this purpose La23 was
linearized with SpeI, and the isolated DNA was partially
digested with EcoO109. Despite using Pfu
polymerase a series of clones had to be characterized, because the
vaste majority of clones had an incorrect length of dT residues in the
oligo(dT) tail ranging from 14 to 28 residues. Finally a single clone
was isolated with the correct length of 23 dT residues. The 5
-exon 1 fragment was obtained as follows. As substrate we used the La cDNA
M13-3, which was originally described by Chan et al. (20)
and which was a gift of Dr. E. K. L. Chan (Scripps Clinic, La Jolla,
CA). Upstream exon 1 primer served the primer P9 (P9,
CGCTTTCGGTCCCCATCTTCTTGG; the artificial
SpeI site is underlined). The downstream primer P1 located
in the exon 4 downstream of the KpnI site in the La
sequence. The exon 1 PCR fragments were cleaved with SpeI
and KpnI and cloned into the respective sites of La23. For
this purpose La23 was linearized with SpeI, and the isolated
linearized DNA was partially digested with KpnI. The exon 1 and 1
La inserts were isolated from the pBluescript SK(
) constructs
by cleavage with SpeI and XhoI and cloned into
pCI-neo and pCI, which were restricted with NheI and SalI. The exon 1
construct in pCI was termed as ORF1 La(N)
(see also Fig. 6, I).
In the case of the 5-shortened exon 1
construct, a PCR fragment was
prepared using as upstream primer P10 (P10,
CGCTTTTTTTACCTCCACCGCCTTC; the artificial
SpeI site is underlined) in combination with P1 as
downstream primer and La23 as substrate. The resulting fragment was
cleaved with SpeI and KpnI and cloned in the
respective sites of La23.
Finally the reading frame of the exon 1 and 1 constructs was corrected
as follows. La19 cDNA containing the correct La coding sequence was
restricted with BstEII, which cleaved in the exon 9 of the
La sequence, and BglII, which cleaved in the exon 5 of the
La sequence. The exon 1 and 1
pCI-neo and pCI constructs were
linearized with BstEII and after isolation of the linearized DNA partially digested with BglII. Then the
BglII-BstEII fragment of La19 was cloned in the
respective sites of the exon 1 and 1
pCI-neo or pCI construct. The
final constructs were sequenced.
The human Raji and XPTA cell lines were grown in RPMI 1640 medium containing 10% FCS in a humidified CO2 atmosphere. Mouse LTA and NIH 3T3 cells and human HeLa cells were grown in DMEM containing 10% FCS in a humidified CO2 atmosphere either in culture flasks for preparation of extracts or on coverslips for epifluorescence microscopy. The mouse cells were transfected transiently according to the following protocol. Transfection was performed in 6-well tissue culture plates (35 mm) containing coverslips. Cells were grown to confluency of 70-80% in 4 ml of DMEM containing 10% FCS. Prior to transfection the serum/medium was removed, and the cells were washed for 30 min with 2 ml of DMEM without FCS and antibiotics. In parallel 1.5 µg of plasmid DNA (see below) was dissolved in 100 µl of Opti-MEM medium and combined with 100 µl of DMEM (without antibiotics and FCS) containing 6 µl of LipofectAMINE. After removal of the 2 ml of DMEM, 0.8 ml of DMEM lacking FCS and antibiotics were added to the cells, and the DNA mixture followed. After an 5-h incubation 1 ml of DMEM containing 20% FCS and antibiotics was added. 20 h after the beginning of transfection the medium was replaced by 2 ml of DMEM containing 10% FCS and antibiotics. 44 h after transfection the cells were either harvested for preparation of total extracts or fixed with methanol/EGTA for immunofluorescence microscopy. In general we observed that even after optimization of the transfection conditions the expression level of the pCI-neo constructs was only 25% compared with the pCI constructs.
In addition to transiently transfected cells, permanently transfected LTA cell lines were used. These lines were kindly provided by Dr. K. Keech of the group of Prof. J. McCluskey and Prof. T. Gordon (Flinders Medical Center, Bedfort, South Australia). The cells were transfected with either the human La gene or the human exon 1 La cDNA (19). The permanently transfected LTA cells were grown in the presence of 0.02% geneticin.
For immunofluorescence microscopy the cells were fixed with methanol
containing 0.02% EGTA at 20 °C for 1 h. Indirect
immunofluorescence of cells with the anti-La mAb SW5 was performed by
incubating the fixed cells, which had been rehydrated for 5 min with
PBS, with cell culture supernatant of hybridomas secreting the anti-La mAb SW5 for at least 15 min. The cells were washed with PBS (5 min),
and the bound anti-La mAb was detected using Cy3-conjugated anti-mouse
antibody developed in goat. The incubation time for the secondary
antibody was 15 min. The staining occurred at room temperature and the
unbound secondary antibodies were removed by washing with PBS (twice, 5 min). The stained cells were mounted using PBS/glycerol (1:1 v/v).
Confocal laser scanning microscopy (cLSM) was performed using a Zeiss
LSM 10. The stained specimens were cut automatically into horizontal
sections (512 × 512 pixels/8 bit, objective lenses Plan-Neofluar
40 ×/1.3 oil). Evaluation of the stored stacks of the horizontal
optical sections was performed with the LSM 10 image processing unit.
Total extracts of transiently transfected cell lines were prepared by incubation with 350 µl of SDS-PAGE sample solution (95 °C). Total extracts from XPTA cells or permanently transfected LTA cells were harvested by adding 100 µl of hot cell lysis buffer (100 mM Na2HPO4, pH 8.3, 200 mM dithiothreitol, 1% SDS, 10% glycerol (v/v)) per cm2. Raji cells were harvested by centrifugation (250 × g, 10 min). The lysed cells were heated for 5 min to 95 °C and centrifuged at 14,000 × g for 5 min at 4 °C. 5-µl aliquots were mixed with SDS-PAGE sample solution and used for SDS-PAGE.
SDS-Polyacrylamide Gel Electrophoresis and ImmunoblottingSDS-PAGE and immunoblotting was performed as described (22, 23). After blocking and washing the blots were incubated with cell culture supernatant of hybridoma cells secreting the anti-La mAb SW5. Formed immune complexes were visualized using the enhanced chemiluminescence-Western blotting detection reagents. Then the anti-La SW5 immune complexes were eluted, and the blot was processed a second time using either the patient's anti-La antibody or the anti-ORF1 rabbit serum. The formed immune complexes were detected using anti-human or anti-rabbit antibodies conjugated with alkaline phosphatase and 5-bromo-4-chloro-3-indolyl phosphate/4-nitro blue tetrazolium chloride as substrate.
Preparation of ORF1 ConstructsTo obtain antibodies against
the ORF1, a fusion protein consisting of glutathione
S-transferase (GST) and a portion of ORF1 was constructed.
For this purpose an exon 1 fragment spanning nucleotides 171-260 (6)
was amplified by PCR using the upstream primer P11 (P11,
CCCGATGCGAGATCCTGG; the artificial BamHI site is underlined; A indicates a point
mutation introduced in the native BamHI site) and the
downstream primer P12 (P12, AAAGACGCAATGGGGATGAG; the
artificial BamHI site is underlined) subcloned into pGEM-T
and after restriction with BamHI inserted into the
BamHI site of pGEX-2T. To proof the specificity of the
anti-ORF1 serum and to look for or to rule out an expression of the
ORF1 further constructs were prepared. In a first step the complete
exon 1
was cloned in the transfection vector pCI. Because the
translation initiation site of the ORF1 in the exon 1
is not optimal
according to Kozak (24), a further construct was prepared in which the
translation initiation site was optimized according to the Kozak rules.
This construct was termed ORF1 Kozak construct. Finally, the ORF1 was
cloned downstream of a 3
-terminally truncated exon 1
-La mRNA.
This clone was termed as ORF1 La(N)-ORF1 (see also Fig. 6,
I).
The ORF1 in the pCI transfection vector was obtained as follows. The
pCI vector containing the full-length exon 1 La cDNA was cut with
SmaI. Then the cleaved DNA was partially digested with
BalI and religated. The resulting clone contained the 5
leader sequence of the exon 1
La mRNA (nucleotides 1-137), the complete ORF1 (starting at nucleotide 138 and ending at nucleotide 276 including the oligo(dT) tail). It ended at nucleotide 293 in the exon
1
.
The ORF1 Kozak construct was prepared as follows. The full-length exon
1 La cDNA served as substrate for PCR using as upstream primer the
primer P13 (P13,
TGCCACCATGGGGGATCCTGGGGTTC; the
artificial NheI site is underlined, the mutated optimized translational initiation site according to Kozak is given in italics). The primer P14 (P14, CGCTATGGGGATGAGG; the artificial
XbaI site is underlined) served the downstream primer. The
resulting fragment was subcloned in pGEM-T, isolated by cleavage with
NheI and XbaI, and cloned into the respective
sites of pCI. The resulting ORF1 construct contained the same portion
of the ORF1, which was also cloned in the GST-ORF1 construct.
The ORF1 La(N)-ORF1 construct was prepared as follows. The exon 1
full-length construct in pCI was cleaved with XbaI and dephosphorylated. The resulting deletion La mutant encoded for amino
acids 1-228 of La protein. The ORF1 insert was amplified from the
above mentioned ORF1 subcloned in pGEM-T using as upstream primer P15
(P15, TGTAAAACGACGGCCAGTG) and as downstream primer P16 (P16,
ATGAAATCGATTGCTAGCGCCACC; the SpeI site is
underlined). The resulting PCR fragment was cleaved with
SpeI and XbaI and cloned in the XbaI
site of the N-terminal truncated La deletion construct.
In a recent study Keech et al. (21) describe a mouse
LTA cell line transfected with the human La gene. This cell line
expressed human La protein in addition to the endogenous mouse La
protein. As shown in Fig. 1 a differentiation between
the human La protein and the endogenous mouse La protein in this mouse
LTA cell line was possible by two techniques, including
immunofluorescence microscopy (Fig. 1A) and
SDS-PAGE/immunoblotting (Fig. 1B). As shown in Fig. 1A (a) LTA cells transfected with the human La
gene were stained with the anti-La mAb SW5, whereas untransfected cells
were not stained (Fig. 1A, b and c).
After SDS-PAGE/immunoblotting, the anti-La mAb SW5 reacted with a
single protein band according to a molecular mass of 50 kDa from the
extract of the LTA cell line transfected with the human La gene (Fig.
1B, lane 2). The same band was also recognized by
the patient's anti-La antibody (Fig. 1B, lane
4). The anti-La mAb SW5 did not react with the total extract of
the untransfected LTA cells (Fig. 1B, lane 1). In
contrast, the patient's antibody reacted with a further protein band
according to a molecular mass of 45 kDa in the extract of both the
transfected (Fig. 1B, lane 4) and the
untransfected cells (Fig. 1B, lane 3). These data
allowed the following conclusions: (i) the human and the mouse La
protein can be separated by SDS-PAGE, (ii) the protein band with a
molecular mass of about 50 kDa represented the human La protein, (iii)
the protein band with a molecular mass of 45 kDa represented the
endogenous mouse La protein, (iv) the patient's anti-La antibody
reacted with both the human and the mouse La protein, and (v) the
anti-La mAb SW5 reacted only with the human but not with the endogenous
mouse La protein.
Consequently, transfection of mouse cells with a human exon 1 La
construct should allow the decision if the exon 1
La mRNA is a
translatable mRNA. Moreover, a mouse cell line transfected with an
exon 1
La construct but also the LTA cell line transfected with the
human La gene should be useful to look for translation products of the
upstream ORFs of the exon 1
La mRNA.
One prerequisite to use the LTA cell line transfected with the human La
gene for such a purpose was that the exon 1 La mRNA was made and
expressed similarly to human cells. Therefore, in a first step we
analyzed if the mouse LTA cells allowed the expression of the exon 1
La mRNA type from the human La gene.
For this purpose 5-RACE experiments were
performed as schematically summarized in Fig. 2
(S). The PCR products obtained after the first amplification
step were further amplified using a primer combination consisting
either of the common exon 2 downstream primer together with an exon 1 (Fig. 2, A1, PCR 2a) or exon 1
(Fig. 2,
A1, PCR 2b) specific upstream primer or of the
common UAP upstream primer in combination with an exon 1
specific
downstream primer (Fig. 2, B1, and also Fig.
3, S, B).
As shown in Fig. 2 (A2, lanes 1), both the exon
1 and exon 1 human La mRNA forms could be detected in the mouse
LTA cells transfected with the human La gene, whereas they were not
detectable in the untransfected cell line (Fig. 2, A2,
lanes 3). The human exon 1
La mRNAs were also not
detectable in a LTA cell line permanently transfected with the human
exon 1 La cDNA (Fig. 2, A2, exon 1
, lane 2), whereas the human exon 1 La mRNA was detectable
in this LTA cell line (Fig. 2, A2, exon 1,
lane 2). Finally, when the exon 1 and 1
bands were excised,
subcloned, and sequenced, the PCR products could be unequivocally
characterized as human exon 1 or exon 1
products.
Already during determination of the 5-start of the
exon 1
La mRNA type a series of 5
-shortened exon 1
La cDNAs
were isolated. The decision of the 5
-start of the exon 1
La mRNA
was made on the longest 5
-exon 1
La cDNA fragment obtained by the
5
-RACE technique. However, when the 5
-RACE products obtained for
mRNAs isolated from the LTA cells transfected with the human La
gene were separated on a NuSieve-agarose gel (Fig. 2, B2,
lane 1), several bands were obtained. Therefore, further
5
-RACE studies were performed, and the PCR products were
characterized. For this purpose exon 1 and exon 1
5
-RACE products
were prepared in parallel from different mRNA preparations
according to the procedure that is schematically summarized in Fig. 2
(S). After the first amplification (Fig. 2, S,
PCR(1)) the PCR products were further amplified as schematically summarized in Fig. 3 (S). The second
amplification was performed using the common UAP primer in combination
with either an exon 1 (Fig. 3, S, [A]) or an
exon 1
(Fig. 3, S, [B]) specific downstream
primer. The mRNA preparations used for the 5
-RACE experiments were
obtained from different human tissues including liver (Fig. 3,
A and B, lanes L), PBLs of a patient with pSS (Fig. 3, A and B, lanes
Pp) and a healthy donor (Fig. 3, A and
B, lanes Ph), and fetal spleen (Fig. 3, A and B, lanes FS).
As shown in Fig. 3 (A, lanes a-d), the exon 1 5-RACE products gave a single band when separated on an agarose gel.
The bands obtained from the mRNAs of the different tissues were
excised and subcloned, and a representative amount of clones were
sequenced. All exon 1 inserts started around the predicted 5
-start of
the exon 1 La mRNA as schematically summarized in Fig. 3
(A1). No difference was observed between the different
mRNA preparations. In contrast, when the exon 1
5
-RACE products
were separated on an agarose gel (Fig. 3B, lanes
a-d) up to at least five bands were obtained. Moreover, the exon
1
5
-RACE patterns differed between the liver tissue (Fig.
3B, lane d) and the patterns for the PBL
preparations (Fig. 3B, lanes b and c)
and the fetal spleen (Fig. 3B, lane a). Four
regions of the agarose gel as indicated by the bars in Fig.
3 (B, 1-4) were excised. The extracted DNAs were
subcloned, and representative amounts of clones were sequenced. The
results of these experiments were schematically summarized in Fig. 3
(B1, B2, B3, and B4). The
characterized exon 1
La cDNAs started either upstream of the ORF1
ATG at the predicted 5
-start of the exon 1
(Fig. 3, B1),
around the oligo(dT) stretch (Fig. 3, B2), downstream of the
ORF2 ATG but upstream of the ORF3 ATG (Fig. 3, B3), or
downstream of the ORF3 ATG (Fig. 3, B4).
In consequence, these data increased the complexity, and we had to look
for translational products not only of the exon 1 full-length La
mRNA but also of the 5
-shortened exon 1
La mRNAs.
In a
first step, full-length exon 1, full-length exon 1, and a 5
-shortened
exon 1
construct starting downstream of the oligo(U) tail but upstream
of the ORF2 AUG were prepared (see "Experimental Procedures") and
mouse LTA cells were transiently transfected. The transfected cell
lines were analyzed for expression of human La protein by cLSM (Fig.
4) and SDS-PAGE/immunoblotting (Fig. 5).
As shown in Fig. 4 (a-c) the anti-La mAb SW5 gave the same
nuclear staining pattern, which was also obtained for the LTA cell line
permanently transfected with the human La gene (see Fig. 1A,
a), on the LTA cells being transiently transfected with either the full-length human exon 1, full-length exon 1
, or the 5
-shortened exon 1
La pCI-neo construct. No staining was found on
cells transfected with a pCI-neo control lacking a La specific insert
(Fig. 4d). The staining intensities of the three constructs slightly differed. It appeared highest in the case of the 5
-shortened exon 1
derivative, followed by the exon 1 and the exon 1
full-length construct. Comparable results were obtained when instead of the pCI-neo
construct the corresponding pCI construct was used. In all cases the
pCI construct gave a higher protein expression than the pCI-neo
construct.
The results obtained with cLSM were confirmed by
SDS-PAGE/immunoblotting. As shown in Fig. 5 (lane 1) the
patient anti-La antibody reacted only with the endogenous mouse La
protein in LTA cells transiently transfected with the pCI-neo control
construct lacking a La insert. The endogenous mouse La protein was also detected in all the other extracts obtained from the transiently transfected LTA cells (Fig. 5, lanes 2-4). In addition to
the endogenous mouse La protein, the patient's anti-La antibody also detected the human La protein in the mouse LTA cells transfected with
full-length exon 1 (Fig. 5, lane 2), full-length exon 1 (Fig. 5, lane 3), and the 5
-shortened exon 1
(Fig. 5,
lane 4) pCI-neo construct. There was no obvious difference
between the molecular mass of La protein translated from the exon 1 or
the exon 1
La mRNAs.
From the epifluorescence and the SDS-PAGE/immunoblotting results, we
concluded that all La mRNA forms can be translated to the same La
protein. The shortening of the 5-end of the full-length exon 1
La
mRNA might increase the translational efficiency. None of the
upstream ORFs should be fused to La protein when translated from an
exon 1
La mRNA.
Finally,
we analyzed whether the ORF1 of the exon 1 is translated. For this
purpose a recombinant GST-ORF1 fusion protein was prepared and used for
immunization of a rabbit. After adsorption of the rabbit serum to GST,
the anti-serum did no more react with the GST-carrier protein but still
reacted with the recombinant GST-ORF1 fusion protein (data not shown).
No reactivity was detected in extracts of several human cell lines
including HeLa (see below), Raji, or XPTA cells and mouse cells
transfected with the human La gene or full-length exon 1
La mRNA
(data not shown).
To proof the specificity of the ORF1 serum and to look for a
translational product of the ORF1 further exon 1 La mRNA,
derivatives were constructed as schematically summarized in Fig.
6 (I). The ORF1 La(N) construct represented a
full-length exon 1
La cDNA in pCI but contained a frameshift
mutation in the exon 7. The frameshift mutation caused a premature stop
codon. Thus the mutant exon 1
La mRNA encoded a C-terminally
truncated La peptide of 29 kDa (14). Because the epitope recognized by
the anti-La mAb SW5 is located upstream of the frameshift mutation, it
still reacted with the truncated La protein (see below). The remaining
N-terminal La coding region contained a XbaI site upstream
of the premature stop codon. This site was used to fuse a second ORF1
sequence to the C terminus of the N-terminal La peptide. Thus the
resulting construct ORF1 La(N)-ORF1 (Fig. 6, I) contained a
first ORF1 locating upstream of but interrupted by two stop codons from
the La coding region and a second ORF1 fused to the C terminus of the
truncated N-terminal La peptide.
As shown in Fig. 6 (II, A, lane b) only the ORF1 La(N)-ORF1 La extract reacted with the anti-ORF1 serum. No reactivity was found for the ORF1 La(N) construct irrespective of whether the construct was transfected into human HeLa (Fig. 6, II, A, lane d) or mouse 3T3 (Fig. 6, II, A, lane f). Furthermore, no reactivity was found in the control HeLa and 3T3 cell extracts. The anti-ORF1 immune complexes were eluted from the blot. Then the same blot was processed a second time using the anti-La mAb SW5. As shown in Fig. 6 (II, B, lanes b, d, and h) the anti-La mAb SW5 reacted with the endogenous human La protein in all HeLa cell extracts. In the case of the transfected cell lines the anti-La mAb SW5 detected equal amounts of either the N-terminal truncated La peptide lacking the ORF1 (Fig. 6, II, B, lanes d and f) or the N-terminal La-ORF1 fusion peptide (Fig. 6, II, B, lane b). As expected the mobility of the N-terminal La-ORF1 fusion peptide was less than the mobility of the N-terminal truncated La peptide lacking the ORF1.
These data show that the ORF1 fused to the C terminus of the N-terminal
La peptide was efficiently made and detectable by the anti-ORF1 serum.
In contrast, the ORF1 encoded from the same exon 1 La mRNA but
upstream of the La protein reading frame was not made at an equivalent
amount or was very rapidly degraded. This interpretation was supported
by the results obtained with two further ORF1 constructs. One construct
contained only the complete exon 1
sequence cloned into pCI. In the
case of the other construct we tried to increase the probability of a
translation of the ORF1 reading frame by optimization of the
translation initiation site of the ORF1 (see "Experimental
Procedures"). However, in both cases no ORF1 translation product was
detected when these constructs were transfected into human HeLa or
mouse 3T3 cells (data not shown). All the results that were obtained by
SDS-PAGE/immunoblotting for all the ORF1 constructs were confirmed by
using enzyme-linked immunosorbent assay and indirect
immunofluorescence technique. In none of these studies was an ORF1
peptide detected (data not shown).
In summary, these results allow the following conclusions: (i) the ORF1
of an exon 1 La mRNA is not translated to either a separate ORF1
peptide or a ORF1 La fusion protein and (ii) the La protein reading
frame in an exon 1
La mRNA is efficiently translated.
Frequently sera of patients with pSS or systemic lupus erythematosus contain self-reacting antibodies directed to nuclear antigens. One of the targets of anti-nuclear antibodies is the nuclear autoantigen La/SS-B (1). The La protein was described as a housekeeping protein (19). It was proposed to be involved in transcription/termination of RNA polymerase III and in internal initiation of translation especially of (polio)virus mRNAs (9-12).
In a recent study we identified alternative La mRNAs (13). Both La
mRNA forms were characterized as abundant finally processed cytoplasmic mRNAs (see the Introduction). However, due to the unusual 5 terminus of the exon 1
La mRNA isoform its function still remained obscure. The exon 1
was GC-rich, contained an oligo(U)
tail of 23 uridine residues, and encoded for three ORFs locating
upstream of the La protein reading frame. mRNAs with GC-rich
5
-termini and/or upstream ORFs had also been described in the case of
other housekeeping proteins and also in the case of (proto)oncogenes,
growth factor receptors, and proteins involved in immune response and
inflammation (24). In most of these cases it was suggested that the
alternative mRNA forms may play a regulatory role. It was assumed
that the mRNA isoforms are either expressed in parallel to throttle
the protein production of critical protooncogene products or represent
nonfunctional mRNAs, which are alternatively expressed instead of
the functional gene product. Only in few cases were the upstream ORFs
used for translation.
Based on this background, we asked which if any of the reading frames
encoded by the exon 1 La mRNA can be translated into protein.
Looking to the upstream ORF1 to ORF3 it appeared likely that only the
ORF1 could be translated to a 5.4-kDa peptide, whereas the ORF2 and
ORF3 reading frames are (i) most likely too short and (ii) not in the
La protein frame. Thus, we looked for expression of a peptide from
either the ORF1 or the La protein reading frame of the exon 1
La
mRNA. To look for an expression of the ORF1 or the human La protein
reading frame a cell system and antibodies had to be established that
allowed a specific detection of the human La protein and an ORF1
peptide when made. During these studies we looked to find out whether
the selected mouse cell system was able to express the human La gene
similarly to a human cell. Thereby it became evident that the 5
-start
of the human exon 1
La mRNAs differed. However, similar results
had also been observed when analyzing mRNA preparations that were
obtained from a series of other human tissues. The observed 5
-start
variations might not be the result of a 5
-terminal nonspecific RNA
degradation because the exon 1 La mRNAs analyzed in parallel from
the same RNA preparations did not show 5
-terminal variations, and the
longest 5
-starts of exon 1
La mRNAs were found in human liver
tissue, which certainly contained the highest RNase concentration
during preparation of the mRNAs. It is also unlikely that the
distinct 5
-terminal start regions of the exon 1
La cDNAs are the
result of premature stops during reversed transcriptase due to
secondary structures in the exon 1
La mRNAs because the pattern of
a certain mRNA preparation could be repeated (data not shown).
Because exon 1
La mRNAs lacking the ORF1 could have different
properties if compared with the full-length exon 1
La mRNAs, we
included a 5
-shortened exon 1
La mRNA derivative in our
expression studies. The selected 5
-shortened exon 1
La mRNA form
started like the two exon 1
La cDNAs isolated from the patient's
cDNA library at the oligo(U) tail in the exon 1
.
The two independent techniques, immunofluorescence microscopy and
SDS-PAGE/immunoblotting, showed that the La protein reading frame in
full-length exon 1 and exon 1 and the 5
-shortened exon 1
La
mRNAs can be translated in transiently transfected cells, whereas
the ORF1 reading was not used. The translation of the full-length exon
1
product appeared to be less efficient if compared with the exon 1 mRNA, whereas the 5
-shortened exon 1
La mRNA appeared to be
more efficient despite the still existing two upstream ORFs 2 and 3. However, future studies using reporter gene constructs will be required
to determine the translational efficiency of the different La mRNA
forms.