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Mol Cell Biol, February 1998, p. 815-826, Vol. 18, No. 2
0270-7306/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
Regulation of the Stability of Heat-Stable Antigen
mRNA by Interplay between Two Novel cis Elements in the 3'
Untranslated Region
Qunmin
Zhou,
Yong
Guo, and
Yang
Liu*
Michael Heidelberger Division of Immunology,
Department of Pathology and Kaplan Comprehensive Cancer Center, New
York University Medical Center, New York, New York 10016
Received 15 September 1997/Returned for modification 28 October
1997/Accepted 31 October 1997
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ABSTRACT |
The heat-stable antigen (HSA) is a costimulatory molecule for
T-cell activation. Its expression is strictly regulated during lymphocyte development and differentiation. Recent studies using HSA-transgenic mice have demonstrated that this regulated expression is
critical for normal development of T and B lymphocytes. However, the
mechanisms that control the expression of HSA are largely unknown. HSA
mRNA is comprised of a 0.23-kb open reading frame and a 1.5-kb 3'
untranslated region (3'UTR). The function of the long 3'UTR has not
been addressed. Here we investigate the role of the 3'UTR of HSA mRNA.
We show that a 160-bp element, located in the region of nucleotides
1465 to 1625 in the 3'UTR of HSA mRNA, promotes RNA degradation and
that this effect is neutralized by a 43-bp fragment approximately 1 kb
upstream of the negative cis element. Both positive and
negative cis elements in the HSA mRNA are distinct from
other sequences that are known to modulate mRNA stability. These
results provide direct evidence that the interplay between two novel
cis elements in the 3'UTR of HSA mRNA determines cell
surface HSA expression by modulating its RNA stability.
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INTRODUCTION |
The heat-stable antigen (HSA) is a
glycosyl-phosphatidyl-inositol-anchored cell surface protein (1,
5, 34, 39). Recent studies from several groups revealed that HSA
plays a major role in regulating interaction between T and B
lymphocytes (12, 19, 28, 29), T-cell clonal expansion
(10, 18, 29), and induction of immunological memory
(30, 41). The expression of HSA is largely restricted to
cells of hematopoietic (1, 5, 34, 36) and neuronal (19,
36) origins. Among the hematopoietic cells, HSA is expressed on a
variety of cell types, including erythrocytes (39),
thymocytes (5), B cells (5, 19, 29, 36),
macrophages (8), and Langerhans cells (10).
The expression of HSA is strictly regulated during the development of T
and B lymphocytes (7, 27). In the T-cell lineage, HSA is
expressed at high levels on a subset of CD4
CD8 thymocytes and all CD4+ CD8+
immature thymocytes. The levels of HSA on CD4+ and
CD8+ single-positive thymocytes are inversely correlated
with their maturity (7). While HSA is not expressed on the
majority of peripheral T cells, it is rapidly induced during T-cell
activation (15). In the B-cell lineage, HSA is expressed at
high levels on pro- and pre-B cells and at intermediate levels on
peripheral B cells (27, 42), but it is absent on terminally
differentiated plasma cells (27). The strict control of HSA
expression suggests that it may also play an important role in
lymphocyte development and differentiation. This is supported by
findings that constitutive overexpression of HSA in lymphoid tissues
leads to defective development of T and B cells (13, 14).
However, the molecular basis for the regulated HSA expression has not
been elucidated, although it is known that the amounts of cell surface
HSA in different tissues and cell lines correlate with the steady-state
levels of cellular HSA mRNA (17, 20-22, 44).
mRNA levels are determined by the rate of de novo RNA synthesis as well
as the efficiency of posttranscriptional RNA processing, such as
polyadenylation, splicing, transport, and degradation of mRNA.
Accumulating data have suggested a major role of the 3' untranslated
region (3'UTR) in determining the stability of mRNA (3, 9, 16, 18,
26, 40). Many cytokine and oncogene mRNAs have long 3'UTRs and
are short-lived (2, 38), primarily due to active degradation
by mechanisms involving AU-rich cis elements, such as
multiple copies of AUUUA. Since HSA mRNA has a very short (0.23-kb)
open reading frame (ORF) and a relatively long (1.5-kb) 3'UTR, we
investigated whether HSA expression is controlled by its 3'UTR. Here we
report that the interplay of cis elements in the 3'UTR of
HSA mRNA determines cell surface HSA expression by modulating its mRNA
degradation.
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MATERIALS AND METHODS |
Plasmid construction.
All cDNA constructs described here
were cloned into the mammalian expression vector pCDM8 (Invitrogen, San
Diego, Calif.). HSA-Full contains a 1.8-kb fragment of full-length HSA
cDNA originally cloned from lipopolysaccharide-stimulated murine spleen
cells (28). HSA-DelA has a deletion of a 1,360-bp fragment
within the 3'UTR (nucleotides [nt] 440 to 1800). It was generated by digesting HSA-Full with EcoRI and NotI and
religating the remaining plasmid fragment with a 38-bp
EcoRI-NotI linker derived from pBluescript (Stratagene, San Diego, Calif.). HSA-DelB has a deletion of an 849-bp
fragment within the 3'UTR between nt 440 and 1289. It was generated by
digesting HSA-Full with EcoRI, removing an 849-bp EcoRI fragment, and religating the linear plasmid. HSA-pA-M
is a mutant of HSA-Full, with the polyadenylation signal (AATAAA) at positions 993 to 998 changed to AgcAAA by PCR-based
site-directed mutagenesis.
HSA-N1, -N2, -N3, -N4, -N5, -N6, and N7 consist of HSA nt 1 to 440 and
a portion of nt 1289 to 1800. They were generated by inserting PCR
fragments corresponding to different regions of the distal 3'UTR (nt
1289 to 1800) into HSA-DelA at EcoRI and NotI
sites.
B7-2 cDNA in the pCDM8 vector has been reported before (
43).
It contains the entire 969-bp coding region of a costimulatory
molecule, B7-2. B7-2-NE is composed of the B7-2 coding region
and part
of 3'UTR of HSA mRNA. It was generated by ligating a
0.51-kb distal
3'UTR fragment (nt 1289 to 1800) downstream of
the B7-2 ORF.
Nine constructs, H3, AccS, AccL, and P1 to 6, were produced to identify
the positive
cis elements. These constructs all contain
fragments spanning nt 1 to 440 and 1289 to 1800 of HSA-Full. Portions
of the fragment from nt 440 to 1289 were inserted between these
two
fragments. Inserts of various lengths were produced by either
restriction enzyme digestion or PCR.
The sequences and orientations of all these cDNA constructs were
confirmed by direct DNA sequencing. The primer sequences
used for the
study are available on request.
Cell culture and DNA transfection.
COS cells were cultured
in Dulbecco modified Eagle medium containing 5% fetal calf serum at
37°C and were used for transient transfection by the DEAE-dextran
method. Briefly, 106 COS cells were seeded in each
100-mm-diameter tissue plate. On the next day, COS cells were incubated
with 5 ml of transfection medium (500 µg of DEAE-dextran per ml, 0.1 µM chlorioquine, and 15 µg of plasmid DNA) for 2 to 3 h at
37°C. The cells were then shocked with 5 ml of 10% dimethyl
sulfoxide in phosphate-buffered saline (PBS) for 2 min, washed twice
with serum-free Dulbecco modified Eagle medium, and then cultured for 2 to 3 days. In some experiments, transfectants were split at 24 h
after transfection and treated with either actinomycin D (ActD) (5 µg/ml) (Sigma, St. Louis, Mo.) or cycloheximide (CHX) (50 µg/ml)
(Sigma) at 40 h after transfection.
Cell surface HSA expression determined by flow cytometry.
Three days after transfection, COS cells were detached from plates by
incubation with 5 mM EDTA-PBS solution. After being washed with PBS
once, COS cells (5 × 105 /sample) were incubated with
100 µl of anti-HSA monoclonal antibody (MAb) M1/69 hybridoma
supernatants (39) or the unrelated MAb GK1.5 as a control on
ice for 30 min. After three washes with staining buffer (PBS containing
1% fetal calf serum), cells were incubated with 100 µl of a 1:100
dilution of fluorescein isothiocyanate-conjugated mouse anti-rat
immunoglobulin G (Caltag, Mountain View, Calif.) for another 30 min.
After unbound conjugates were removed, cells were fixed in 200 µl of
1% paraformaldehyde-PBS solution and cell surface fluorescence was
measured with a FACScan (Becton Dickinson, Mountain View, Calif.).
Northern blot analysis.
Cytoplasmic and nuclear RNAs were
isolated as described previously (37). Total cellular RNA
was isolated by the guanidium isothiocyanate extraction method
(6). Poly(A)+ RNA was isolated with Oligotex
mRNA kits (Qiagen, Santa Clarita, Calif.) according to the
manufacturer's instructions. RNA (15 µg/sample) was separated on a
1.2% formaldehyde agarose gel by electrophoresis and transferred to
nitrocellulose membranes. The membranes were prehybridized at 42°C
for 4 to 10 h by incubation with prehybridization solution (50%
formide, 5× SSPE [1× SSPE is 0.18 M sodium chloride, 0.01 M sodium
phosphate, 1 mM EDTA; pH 7.7], 1 mM EDTA, 0.1% sodium dodecyl sulfate
[SDS], and 100 µg of denatured salmon sperm DNA per ml).
32P-labeled DNA probes were then added and incubated with
the membranes at 42°C overnight. At the end of hybridization,
membranes were washed once with 2× SSC (1× SSC is 0.15 M NaCl plus
0.015 M sodium citrate)-0.1% SDS at room temperature, twice with 2×
SSC-0.1% SDS at 42°C, and once with 0.2× SSC-0.1% SDS at 60°C,
with exchanges of the washing solution at intervals of 20 min. After
the final wash, membranes were rinsed with 2× SSC, and then exposed to
X-OMAT imaging films (Kodak, Rochester, N.Y.). In some experiments, the densities of the bands were quantified with a densitometer. The predicted sizes of mRNA were calculated based on the predicted transcription initiation site and the cleavage site for
polyadenylation: predicted size = size of 5' vector sequence (0.1 kb) + size of cDNA insert + size of 3' vector sequence (0.67 kb).
Nuclear run-on assay.
The nuclear run-on assay was performed
as described previously (11). The run-on products
(107 cpm/sample) were hybridized to nitrocellulose
membranes immobilized with DNA fragments corresponding to different
portions of HSA cDNA or control DNA.
HSA-transgenic mice.
The production of HSA-transgenic mice
has been reported previously (44). Briefly, HSA cDNA was
inserted into the p1017 cassette transgenic vector (kindly provided by
Roger Perlmutter, University of Washington, Seattle. The expression of
the HSA cDNA is controlled by a proximal lck promoter, and
the 3' processing is aided by a portion of human growth hormone gene.
Transgenic mice derived from founder A, which has approximately 40 copies of the HSA transgene, were used for the study. Total RNAs,
isolated from the spleens and thymuses of HSA transgenic mice, their
littermate controls, HSA-deficient mice (33), or C57BL/6j
mice, were analyzed by Northern blotting.
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RESULTS |
Positive and negative regulation of steady-state levels of HSA mRNA
by its 3'UTR.
To investigate whether the 3'UTR of HSA mRNA
contains cis elements that control HSA expression, we
generated two deletion mutants of HSA cDNA: HSA-DelA and HSA-DelB (Fig.
1a). HSA-DelA has a deletion of a
1,360-bp fragment spanning nt 440 to 1800, while HSA-DelB has a
deletion of an 849-bp fragment spanning nt 440 to 1289. These two
deletion mutants and the full-length HSA cDNA were cloned in the
expression vector pCDM8. Individual plasmids containing each of these
HSA cDNAs were cotransfected with the pCDM8 vector into COS cells by
the DEAE-dextran method.
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FIG. 1.
Positive and negative control of HSA expression by the
3'UTR of its mRNA. (a) Diagrams of the expression vector pCDM8 and HSA
cDNA constructs. The expression vector pCDM8 contains a 358-bp stuffer
fragment. The compositions of the full-length HSA cDNA (HSA-Full) and
its two deletion mutants, HSA-DelA and HSA-DelB, are also given. The
filled bars represent the 231 bp of HSA coding region (bp 73 to 303),
and the open bars depict either the 5'UTR (bp 1 to 72) or the 3'UTR (bp
304 to 1800). A polyadenylation signal (sequence AATAAA) is located at
positions 993 to 998. HSA-DelA has a 1,360-bp deletion within the 3'UTR
(bp 440 to 1800), whereas HSA-DelB has an 849-bp deletion within the
middle of the 3'UTR (bp 440 to 1289). CMV, cytomegalovirus; SV40,
simian virus 40. (b) The 3'UTR of HSA mRNA controls expression of cell
surface HSA as determined by flow cytometry. Histograms of HSA
expression are presented; the mean fluorescence values are indicated in
each panel. (c) The 3'UTR of HSA mRNA controls the steady-state levels
of HSA mRNA. COS cells were transfected with pCDM8 vector alone (Vec)
or vector plus either HSA-Full, HSA-DelA, or HSA-DelB. Total
cytoplasmic RNA was isolated, and the amount of HSA mRNA was measured
by Northern blotting with a 32P-labeled HSA cDNA fragment
spanning bp 38 to 440 (top). As a control for the transfection
efficiency, the same blot was hybridized with 32P-labeled
pCDM8 stuffer probe (middle). The amounts of RNA loaded are also shown
(bottom).
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We first examined the HSA protein expression by flow cytometry. As
shown in Fig.
1b, COS cells transfected with vector plus
HSA-Full, but
not those transfected with pCDM8 vector alone, expressed
HSA.
Interestingly, COS cells transfected with two deletion mutants
had
dramatically different levels of cell surface HSA: HSA-DelA
yielded
high levels of HSA, but HSA-DelB produced hardly detectable
HSA
protein. To determine if the cell surface HSA levels correlate
with
that of HSA mRNA, we performed Northern blot analyses with
the HSA
fragment from nt 38 to 440 as the probe (Fig.
1c, upper
panel).
Significant amounts of HSA mRNA were detected in COS cells
transfected
with HSA-Full but not in those transfected with vector
alone. The
highest levels of HSA mRNA were observed in HSA-DelA
transfectants,
while minimal amounts of HSA mRNA were detected
in HSA-DelB
transfectants. The differences are not due to transfection
efficiency,
because comparable levels of the cotransfected vector
RNA were detected
in all four transfectants (Fig.
1c, middle panel).
In addition, the
observed differences cannot be accounted for
by variations in RNA
loading (Fig.
1c, lower panel). These results
demonstrate that the
3'UTR determines the levels of steady-state
HSA mRNA, which in turn
determine the amounts of HSA protein expressed.
Since deletion of a
middle portion in the 3'UTR (nt 440 to 1289)
leads to a reduction in
HSA mRNA and protein expression, positive
cis elements may
exist in this region. Moreover, a further deletion
of the distal 3'UTR
(nt 1289 to 1800) results in the highest levels
of HSA expression; it
is likely that negative
cis-acting elements
are present in
the distal region.
The length of HSA mRNA detected does not correspond to that of HSA cDNA
inserts, as three inserts of different lengths, ranging
from 0.44 to
1.8 kb, give mRNAs of similar sizes, 1.1 to 1.2 kb.
This apparent
discrepancy can be explained by utilization of different
polyadenylation sites in different constructs. The HSA-Full insert
has
a functional polyadenylation signal (AATAAA) at positions
993 to 998, utilization of which would lead to an mRNA of about
1.1 kb,
as is the majority of HSA mRNA detected. In addition,
a less abundant
2.6-kb HSA mRNA was detected, which is expected
if the polyadenylation
site on the vector is utilized. Since the
HSA-DelA insert has no
polyadenylation signal, it has to utilize
the polyadenylation signal
from the vector, which is 0.67 kb downstream.
The mature HSA-DelA mRNA
should be 1.2 kb. In order to verify
this explanation, we mutated the
polyadenylation signal in the
3'UTR of HSA-Full. As shown in Fig.
2a, mutation of the polyadenylation
signal AATAAA to AgcAAA abrogated the
accumulation of the 1.1-kb
form of HSA mRNA and led to a preferential
accumulation of the
2.6-kb HSA mRNA. These results demonstrate that the
1.1-kb HSA
mRNA is due to utilization of the polyadenylation site in
inserted
HSA cDNA. In addition, since the 2.6-kb mRNA contains both
positive
and negative elements, it is likely that the function of the
positive
element dominates over that of the negative element. Moreover,
the majority of HSA mRNA in the HSA-Full-transfected cells contained
the putative positive but not the negative elements, yet its level
was
not higher than that in the COS cells transfected with HSA-DelA,
which
lacks both positive and negative
cis elements. It is
therefore
likely that the sole function of the positive
cis
element is to
neutralize the activity of the negative
cis element. The HSA-pA-M
and HSA-Full mRNAs were
translated with comparable efficiencies,
as similar levels of cell
surface HSA were detected (Fig.
2b).
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FIG. 2.
Mutation of a polyadenylation site in the HSA cDNA
alters the size of HSA mRNA but does not significantly affect the level
of HSA expression. The polyadenylation signal (AATAAA) at nt 993 to 998 in HSA cDNA was changed to AgcAAA in HSA-pA-M. COS cells were
transfected with either HSA-Full or HSA-pA-M. (a) Analyses of HSA mRNA
by Northern blotting with an HSA DNA fragment from nt 38 to 440 as a
probe. Note the essential elimination of the 1.1-kb band in the pA-M
transfectants. (b) Analysis of cell surface HSA expression by flow
cytometry. Histograms of HSA expression determined by staining with
anti-HSA MAb M1/69 are shown. The mean fluorescence values are
indicated in each panel.
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The 3'UTR of HSA mRNA does not affect the transcription rate.
To determine the transcription rates of HSA-Full and HSA-DelB inserts
in COS transfectants, we performed nuclear run-on assays with
immobilized DNA fragments from different regions of HSA cDNA or control
actin cDNA, to quantify nascent nuclear RNA. As shown in Fig.
3a, nascent RNA in HSA-Full-transfected
COS cells hybridized to cDNA fragments corresponding to nt 38 to 440 and 440 to 1289, while those in HSA-DelB transfectants hybridized to
HSA cDNA nt 38 to 440 but not HSA nt 440 to 1289, which is absent in
HSA-DelB. Further experiments using other regions of HSA cDNA as probes (Fig. 3b) revealed that the transcripts from HSA-DelB transfectants contain all the HSA sequences in the construct. After being normalized with control actin, the amounts of run-on products from both HSA-Full and HSA-DelB were almost identical. Thus, HSA-Full and HSA-DelB transfectants transcribed the HSA gene at comparable rates, and the
lack of functional HSA mRNA in the HSA-DelB transfectants must be due
to posttranscriptional mechanisms.
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FIG. 3.
Transcription rates of transfected HSA-Full and
HSA-DelB in COS cells as determined by nucler run-on assay. Nuclei were
isolated from COS cells transfected with either HSA-Full or HSA-DelB
and were incubated with reaction buffer at room temperature for 20 min.
Purified run-on products (107 cpm/sample) were hybridized
to nitrocellulose membranes that had been immobilized with HSA cDNA
fragments and a control actin DNA fragment. Results from two
independent experiments using different immobilized fragments are
presented in panels a and b.
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Stability of HSA mRNAs transcribed from HSA-full and HSA-DelB.
As a preliminary approach to determining the mechanisms responsible for
posttranscriptional regulation of HSA mRNA, we treated HSA cDNA
transfectants with either ActD, which inhibits transcription, or CHX,
which blocks both translating and RNA degradation, and then determined
the levels of steady-state HSA mRNA by Northern blotting (Fig.
4). As shown in Fig. 4, in the absence of
either treatment, a high level of HSA mRNA was detected in HSA-Full
transfectants but not in HSA-DelB transfectants. No significant
decrease of HSA mRNA was observed in HSA-Full transfectants after
4 h of incubation with ActD. This suggests that HSA mRNA in the
HSA-Full transfectants is stable. Incubation with CHX increased HSA
mRNA in HSA-Full transfectants by threefold, while the same treatment
increased HSA-DelB RNA by ninefold. The major species of HSA mRNA
detected in HSA-DelB transfectants were approximately 0.9 to 1.1 kb,
much shorter than the 1.7 kb predicted from the construct.
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FIG. 4.
Effects of CHX and ActD on the accumulation of
cytoplasmic HSA mRNA in COS transfectants. Aliquots of HSA-Full or
HSA-DelA transfectants were either left untreated (Nil) or treated with
ActD or CHX for 4 h. The amount of HSA mRNA was determined by
Northern blotting with the HSA cDNA probe (nt 38 to 440). The relative
amounts of the HSA mRNA were determined by densitometry. Numbers above
the bottom panels are the relative amounts of HSA mRNA after the drug
treatment. The amounts in untreated cells are defined as 1.0. ND, not
determined.
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The preferential increase in HSA-DelB RNA by CHX treatment suggests
that the RNA is less stable. To test this possibility
directly, we
incubated HSA-Full and HSA-DelA transfectants with
ActD for different
periods of time (0, 0.5, 1, 2, and 4 h) and
then measured HSA
mRNA. The amount of the predominant 1.1-kb HSA-Full
RNA and the sum of
two bands of 1.1- and 0.9-kb HSA-DelB mRNA
were used to determine the
decay kinetics of HSA mRNA. As shown
in Fig.
5, HSA mRNA in HSA-Full transfectants was
stable (half
life, >4 h), while HSA-DelB mRNA was rapidly degraded
(half-life,
0.5 h).
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FIG. 5.
Kinetics of HSA mRNA decay in COS cells transfected with
either the full-length HSA cDNA (HSA-Full) or its deletion mutant
(HSA-DelB). Aliquots of COS transfectants were incubated with ActD (5 µg/ml) for different periods starting at 40 h after
transfection. Cytoplasmic RNA was then isolated, and the amount of HSA
mRNA was determined by Northern blotting with the HSA fragment from nt
38 to 440. (a) Northern blot. The top panel is an autoradiograph of the
hybridization. Note that in HSA-DelB transfectants, there are two bands
of 1.1 and 0.9 kb, both of which are smaller than the predicted size of
mature HSA RNA derived from the construct (1.7 kb). The bottom is a
photograph of the nitrocellulose membrane after the transblot to
illustrate the amounts of RNA loaded. (b) Kinetics of RNA decay. The
amounts of HSA mRNA and total RNA loading in each lane were quantified
by densitometry. After normalization by the amount of RNA loading, the
relative amount of remaining HSA mRNA after ActD treatment was
calculated as the percentage of that detected in untreated COS
transfectants. The dominant 1.1-kb band in HSA-Full and the sum of 1.1- and 0.9-kb bands in HSA-DelB were used to calculate the decay
kinetics.
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Evidence for an endonucleic cleavage of the HSA-DelB RNA.
Since the HSA-DelB insert does not have a polyadenylation signal
sequence with a correct downstream cleavage sequence, the mRNA
transcript must use the signal and processing sequences from the vector
for efficient polyadenylation. The mRNA transcript is predicted to be
of 1.7 kb rather than the 0.9 and 1.1 kb protected by the CHX. To
confirm that the 1.7-kb HSA mRNA is transcribed from the HSA-DelB
construct, we prepared nuclear and cytoplasmic RNAs from the HSA-Full-
and HSA-DelB-transfected COS cells and analyzed the size of the HSA
RNA. As shown in Fig. 6a, nuclear RNA
derived from HSA-Full was comprised of 1.2- and 2.6-kb species, corresponding to alternative polyadenylation. Both species were present
in the cytoplasm, as predicted. HSA-DelB nuclear RNA was composed of
1.7- and >3-kb species. The 1.7-kb RNA is likely to be the full-length
transcript of HSA-DelB that utilized the vector polyadenylation signal.
The nature of the >3.0-kb species is not understood at present, but
such larger-than-expected RNA has been reported to be associated with
production of unstable mRNA (35). The 0.9- and 1.1-kb RNAs
were not found in the nuclear RNA. Interestingly, the cytoplasmic
HSA-DelB mRNA was selectively devoid of the 1.7-kb band while enriched
for the 0.9- and 1.1-kb bands. These results strongly suggest that the
1.7-kb RNA is the precursor for the 0.9- and 1.1-kb RNAs in the
cytoplasm.
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FIG. 6.
Evidence for endonucleic cleavage of the HSA-DelB mRNA.
(a) Distinct intracellular localization of the full-length and short
HSA-DelB products. COS cells transfected with pCDM8 vector plus either
HSA-Full or HSA-DelB were hypotonically lysed. After centrifugation,
cytoplasmic RNAs were isolated from the supernatants, while the nuclear
RNAs were prepared from the pellets from the same samples. After
separation on an agarose gel, the HSA RNAs were detected by using the
HSA(38-440) probe (top), while the mRNAs derived from the cotransfected
vector were determined by using a stuffer probe (bottom). (b) Most, if
not all, of the short, ORF-containing HSA-DelB RNA lacks a poly(A)
tail. Equal aliquots of cytoplasmic RNA were either left untreated
(cyto), or incubated with oligo(dT)-coated resin; after unbound RNAs
were removed, the poly(A)+ RNAs were eluted from the column
with soluble oligo(dT). The HSA RNAs were detected with the HSA(38-440)
probe. (c) Composition of HSA mRNA in COS cell transfectants determined
by Northern blotting with either HSA(38-440) (top) or HSA(1289-1625)
(middle) and simian virus 40 (SV40) sequence (bottom). Note that in the
HSA-DelB transfectant there is a preferential accumulation of the 3'
portion of the mRNA detected by distal 3'UTR and downstream vector
sequence.
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To determine if the HSA-DelB RNA observed in the cytoplasm is
polyadenylated, we divided the cytoplasmic RNA into two aliquots;
one
was left untreated, and the other was incubated with oligo(dT)-coated
resin to obtain poly(A)
+ RNA. As shown in Fig.
6b, all
major species of HSA-Full RNA were
recovered with high efficiency,
while the overwhelming majority
of the HSA-DelB RNA did not bind to the
oligo(dT) resin. It is
unclear at this stage whether the minute amount
of the HSA-DelB
RNA observed in the poly(A)
+ fraction is
due to incomplete removal of the poly(A)
fraction in the
experiment or due to existence of a small amount
of polyadenylated HSA
DelB RNA. These results demonstrate that
most, if not all, of the
HSA-DelB RNA lacks the poly(A) tail,
which explains the short
half-lives of these fragments. Moreover,
while the ORF-containing
HSA-DelB RNA was rapidly degraded, we
have detected, in separate
experiments, substantial amounts of
HSA-DelB RNA in the cytoplasm by
using the HSA (nt 1289 to 1625)
and downstream vector sequence as
probes (Fig.
6c). Taken together,
the results presented in this section
suggest that newly transcribed
1.7-kb RNA may be subject to rapid
endonucleic cleavage, perhaps
at multiple sites, to generate a spectrum
of 0.9- to 1.1-kb products;
the ORF-containing ones are devoid of
poly(A) and are rapidly
degraded, while the 3' fragments are
polyadenylated and accumulate
in a large quantity.
The distal 3'UTR (nt 1289 to 1800) of HSA mRNA promotes degradation
of heterologous mRNA.
To determine whether the distal 3'UTR
fragment alters the stability of heterologous mRNA, we linked this
fragment to the 3' end of the B7-2 ORF to produce B7-2-NE. Both B7-2
and B7-2-NE were transfected into COS cells. After drug treatment, RNAs
were isolated and the amounts of B7-2 mRNA were measured by Northern blotting. As shown in Fig. 7, in the
absence of any treatment, a strong 1.7-kb band was detected in B7-2
transfectants, while a weak 2.3-kb band, the predicted full-length
B7-2-NE mRNA, was observed in the B7-2-NE transfectants. ActD decreased
the levels of B7-2 and B7-2-NE mRNA, while CHX increased both levels.
Both drugs were more effective for B7-2-NE mRNA than for B7-2 mRNA. Moreover, CHX-treated B7-2-NE transfectants had an additional 1.4-kb
band, perhaps a truncated product of the 2.3-kb mRNA. These results
indicate that the 3'UTR of HSA mRNA promotes degradation of B7-2 mRNA.
It should be noted that the degradation of B7-2-NE mRNA is not as
efficient as that of HSA-DelB mRNA. In particular, we have observed a
significant protection of the intact B7-2-NE by CHX. Thus, the context
of the ORF modulates the efficiency of NE-mediated RNA degradation.
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FIG. 7.
The distal 3'UTR (nt 1289 to 1800) of HSA mRNA promotes
degradation of heterologous mRNA. Northern blot analysis for B7-2 mRNA
in COS cells transfected with either B7-2 or B7-2-NE is shown. The B7-2
insert is comprised of a 1.0-kb B7-2 cDNA ORF, while B7-2-NE is a
chimera cDNA consisting of the B7-2 ORF and part of the 3'UTR (nt 1289 to 1800) of HSA mRNA. The sizes of the predicted mature mRNAs are 1.8 kb for B7-2 and 2.3 kb for B7-2-NE. Aliquots of COS cells transfected
with B7-2 cDNA or B7-2-NE were left untreated (Nil) or treated with
ActD or CHX for 4 h. The total RNA was then isolated, and the
amount of B7-2 mRNA was determined by Northern blotting with a
32P-labeled B7-2 probe. The loading of RNA is shown in the
bottom panels. Numbers above the bottom panels are the relative amounts
of B7-2 mRNA after the drug treatment. The amounts in untreated cells
are defined as 1.0.
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|
Delineation of a negative cis-acting element in the
distal 3'UTR.
To further define the cis elements
responsible for the accelerated RNA degradation, we generated HSA-N1 to
-N4, each with a different deletion within the distal 3'UTR (nt 1289 to
1800) (Fig. 8a), and measured the RNA and
protein expression of the mutants in COS transfectants (Fig. 8b and c).
It was anticipated that deletions of negative cis-acting
elements would restore HSA expression. However, in three deletion
mutants, HSA-N1, -N2, and -N4, HSA expression was not restored as
judged by the amounts of HSA mRNA and protein. In addition, much like
the HSA-DelB mRNA, the majority of the HSA RNAs detected were either
smaller or larger than predicted. However, one construct, HSA-N3,
restored HSA expression to a level comparable to that in HSA-Full
transfectants. The major mRNA species in N3 transfectants was 1.5 kb,
the predicted size of mature N3 mRNA.
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FIG. 8.
Delineation of the negative cis elements
within the 3'UTR of HSA mRNA. (a) Diagram of constructs, the predicted
sizes of their mature RNAs, and relative expression of HSA protein. All
constructs are composed of HSA nt 1 to 440 plus a portion of the nt
1289 to 1800 fragment. Cell surface HSA protein expression as
determined by flow cytometry with anti-HSA MAb M1/69 is shown. The data
presented are relative amounts of cell surface HSA expression based on
the mean fluorescences from three independent experiments, with
standard deviations (SD). The expression of HSA-Full is defined as 100. (b and c) Northern blot analysis of HSA mRNA in COS transfectants. COS
cells were transfected with HSA-Full, HSA-DelB, or N1 to N6. The
amounts of HSA mRNA in the cytoplasm were determined by using
HSA(38-440) as a probe. The RNA loading is shown at the bottom. SV40,
simian virus 40.
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|
HSA-N3 has a 135-bp deletion from HSA-N4 in the region of nt 1465 to
1600, thus raising the possibility that this fragment
may be largely
responsible for the accelerated RNA degradation.
Furthermore, since
HSA-N2 and HSA-N4 share 30 bp, it is tempting
to suggest that this
30-bp fragment may be the negative
cis element.
We created
HSA-N5, -N6, and -N7 to test these possibilities. As
shown in Fig.
8c,
deletion of nt 1465 to 1625, as in the N5 construct,
restored HSA
expression as judged by a selective increase of a
1.6-kb HSA mRNA and
high levels of HSA protein. Thus, this region
is necessary for
efficient RNA degradation. Moreover, the lack
of mature HSA mRNA in
N6-transfected COS cells indicated that
the fragment from nt 1465 to
1625 is sufficient to abolish accumulation
of mature mRNA.
Interestingly, significant amounts of two small
HSA mRNAs were
detected, which suggests that the fragment from
nt 1465 to 1625 is only
sufficient to convey partial degradation
of HSA mRNA. The 30-bp
fragment shared by HSA-N2 and -N4 did not
promote RNA degradation and
has no effect on protein expression,
as in the case of the N7
construct. Taken together, the results
presented in this section
demonstrate that a 160-bp fragment in
the distal 3'UTR is both
necessary and sufficient to promote HSA
mRNA degradation.
A 43-bp element inhibits degradation of HSA mRNA.
In order to
delineate the positive cis element that neutralizes the
function of the negative cis element, we generated a large series of deletion mutants that contain the HSA sequence from nt 1 to
440 and nt 1290 to 1800 and overlapping fragments that cover all
sequence between nt 440 and 1289 (Fig.
9a). These constructs were transfected
into COS cells, and the cell surface HSA expression was determined by
flow cytometry with anti-HSA MAb M1/69. The data presented in Fig. 9a
show relative HSA expression, with that of HSA-Full defined as 100. Insertion into HSA-DelB of most fragments that contain a 43-bp
fragment, such as AccL, P4, P5, and P6, restored the cell surface HSA
expression to levels comparable to that of HSA-Full. These results
indicate that extension of the 43-bp fragment in the 3' end does not
increase the efficiency of the positive cis element. Further
experiments revealed that removing the sequence adjacent to either end
of the 43-bp fragment had no effect on the fragment (data not shown).
These results demonstrate that most, if not all, of the positive
activity within the nt 440 to 1289 region resides within a 43-bp
fragment between nt 440 and 482. The sequence of the 43-bp fragment is
shown at the bottom of Fig. 9a. Moreover, the H3 fragment was inserted
opposite to its natural orientation, which results in reversion of the
43-bp fragment. Since this fragment did not restore HSA expression, it
is likely that the function of the 43-bp fragment is orientation dependent.
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FIG. 9.
A 43-bp fragment is necessary and sufficient to
neutralize the effect of the negative cis element residing
within nt 1289 to 1800. (a) Diagram of the constructs and the relative
amounts of cell surface HSA expression. All constructs contain the HSA
nt 1 to 440 and 1289 to 1800 fragments. A portion of the putative
positive regulatory region was inserted between the two fragments.
Except for a reverse orientation of the H3 fragment, all fragments are
inserted in their natural orientation. Cell surface HSA protein
expression was determined by flow cytometry with anti-HSA MAb M1/69.
The data presented are relative HSA expression based on the mean
fluorescences of the samples, with standard deviations (SD), and are
summaries of two or three independent measurements for each group. The
expression of HSA-Full is defined as 100. The sequence of the minimal
cis element is shown at the bottom. (b) Steady-state HSA
mRNA levels in COS cells transfected with HSA-Full, DelB, AccS, P1, P2,
P3, and AccL. Total RNA was used for the study. HSA(38-440) was used as
the probe in the top panel. Bottom, the same blot was reprobed with a
glyceraldehyde-3-phosphate dehydrogenase (GAPDH) probe to quantify the
RNA loading. (c) As in panel b, except that HSA mRNAs in H3, P4, and P5
transfectants were determined. (d) A 43-bp oligonucleotide contains all
necessary signal for neutralization of the negative cis
element residing between nt 1289 and 1800. As in panels b and c, except
a photograph of the gel is used to illustrate RNA loading (bottom).
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|
We have analyzed the RNA accumulation in COS cells transfected with all
mutants listed in Fig.
9a. Total RNA was isolated,
and the HSA mRNA was
determined by Northern blotting. The results
for all of the mutants are
presented in Fig.
9b to d. Insertion
of AccL and P4 to -6 fragments,
but not P1 to -3 fragments, restored
the HSA mRNA levels to that of
HSA-Full. Two major species of
HSA mRNA, of 1.1 and 2.3 kb, were
observed in AccL transfectants,
most likely because AccL contains a
polyadenylation signal. The
sizes of P4 to -6 were as predicted. As
shown in Fig.
9d, a difference
of a 43-bp fragment between HSA-DelB and
P6 has a major effect
on the amount of HSA mRNA accumulated. These
results clearly demonstrate
that the 43-bp
cis element
promotes accumulation of HSA mRNA by
neutralizing the negative
cis element residing within the nt 1289
to 1800 region.
Preferential utilization of the second polyadenylation site in the
endogenous HSA gene.
We have shown that HSA mRNA that is
accumulated in the HSA-Full-transfected COS cells preferentially
utilizes the first polyadenylation site, which results in an absence of
the negative cis element identified in this study. Since the
HSA cDNA used in this study lacks the necessary downstream element for
polyadenylation (25), the preferential utilization of the
first poly(A) signal is most likely due to inactivation of the second
poly(A) site. In cell lines that express endogenous HSA, such as A20,
M12, and CRCS, the majority of HSA mRNA was 1.9 kb, presumbly due to
utilization of the second polyadenylation site (Fig.
10a). A small fraction of HSA mRNA was
1.1 kb and thus utilized the first poly(A) signal. To directly compare
the polyadenylation sites of the HSA cDNA and endogenous HSA gene, we
compared the sizes of transgenic HSA mRNA with those of the endogenous
HSA gene, we compared the sizes of transgenic HSA mRNA with those of
the endogenous HSA gene. The vector used for the HSA-transgenic mice
consists of a proximal lck promoter, full-length HSA cDNA,
and a portion of the human growth hormone gene for RNA processing. The
mice used for the current study were derived from founder A, which had
approximately 40 copies of the transgene (data not shown). Northern
blot analysis revealed that the HSA transgene is expressed at a higher
level in the thymus than in the spleen (Fig. 10b), which is consistent with the property of the vector. In the spleen, the transgene was
expressed at a level comparable to that of the endogenous HSA gene.
Most importantly, while the major species of the HSA RNA in littermate
control mice was 1.9 kb, the predominant species of the HSA derived
from the transgene was 1.1 kb. Moreover, the majority of the endogenous
HSA mRNA contain both positive and negative cis elements
identified in the study. The fact that the mRNA derived from HSA cDNA
in the transgenic mice cannot efficiently utilize the second
polyadenylation signal at its distal 3' end can be due to a lack of
downstream sequence. Alternatively, it is possible that there is a
limiting factor that inhibits the utilization of the first
polyadenylation signal in normal mice but that this putative inhibitor
is titrated out due to increased HSA expression in the transgenic mice.
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FIG. 10.
Preferential utilization of the distal 3'
polyadenylation site in the endogenous HSA gene. (a) Sizes of the HSA
mRNA in three B-cell lines, M12, A20, and CRCS, detected with the
HSA(38-440) probe. RNA loading was determined with a
glyceraldehyde-3-phosphate dehydrogenase (GAPDH) control (bottom). (b)
Comparison of HSA mRNAs in HSA-transgenic mice (TG), their
transgene-negative littermates (control) (WT), C57BL6/j mice (B6), and
HSA-deficient mice (KO). Total RNAs isolated from spleens (left panel)
and thymuses (right panel) were separated on an agarose gel and probed
with either HSA(38-440) or GAPDH.
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|
| |
DISCUSSION |
HSA cDNA consists of a short ORF (231 bp) and a long 3'UTR (1,497 bp). Partial deletion of the 3'UTR abolishes the mRNA accumulation in
the cytoplasm and, consequently, the cell surface expression of HSA.
Since further truncation of the 3'UTR restores HSA expression, we
conclude that the region between nt 1289 and 1800 contains a negative
cis element(s) that down-regulates the expression of HSA.
The addition of a fragment from nt 440 to 1289 neutralizes the negative
effect of the fragment from nt 1289 to 1800. These results indicate
that the 3'UTR of HSA mRNA plays an important role in controlling HSA
expression.
Several lines of evidence support the notion that these cis
elements regulate the stability of HSA mRNA. First, the transcription rate of the HSA mRNA is not altered by changing the composition of the
3'UTR. Second, the accumulation of cytoplasmic HSA mRNA is
significantly enhanced by treatment with CHX, a protein synthesis inhibitor that has been shown to increase RNA stability for a large
number of genes studied. Most importantly, the half-life of RNA derived
from HSA-DelB is at least eightfold shorter than that of RNA derived
from the full-length HSA cDNA.
Similar to most unstable RNAs, the fragment from nt 1289 to 1800 of HSA
mRNA contains multiple stretches of AU-rich elements, including one
AUUUA motif. However, deletion analysis reveals that this AUUUA motif
is neither necessary nor sufficient for promoting HSA mRNA degradation.
Deletions including this motif (as in the cases of HSA-N1 and HSA-N2)
do not restore expression of HSA. In contrast, HSA-N3, which retains
this motif, still expresses HSA at a high level. Such a lack of effect
of the AUUUA element on mRNA accumulation can be due to the fact that
it is not multimerized, as in the case of proto-oncogenes and cytokines
(2, 38). Alternatively, as suggested by recent studies, a
longer motif, UUAUUUAUU, may be needed for RNA
destabilization (24, 45).
Our deletion analyses have revealed that a 160-bp fragment is both
necessary and sufficient for rapid degradation of HSA mRNA. Deletion of
the element in HSA-N5 leads to accumulation of substantial amounts of
HSA mRNA and cell surface HSA, while addition of this fragment to
HSA-DelA abrogated accumulation of mature HSA mRNA and cell surface HSA
protein. Interestingly, this 160-bp fragment does not appear to contain
all the activities of the fragment from nt 1289 to 1800 in the HSA-DelB
construct. Thus, while HSA-N6 transfectants lack mature HSA mRNA, they
do accumulate short HSA mRNA. It is therefore likely that other
sequence within the nt 1289 to 1800 region may be responsible for rapid
degradation of the apparently truncated HSA RNA. With a few notable
exceptions (4, 23, 31, 32), RNA degradation in mammalian
cells proceeds rapidly after initiation, and the intermediate
degradation products are difficult to isolate. The substantial amount
of the short RNA accumulated in the HSA-N6-transfected COS cells and
CHX-treated HSA-DelB transfectants may facilitate the study of the
mechanism of RNA degradation.
An important aspect of the current study is the identification of a
43-bp fragment that can neutralize the negative cis element residing between nt 1289 and 1800. While multiple labile RNA contains negative cis elements (2, 24, 38, 45), the
existence of positive cis elements has been rarely reported
(3, 9). One such element has been reported for the
transferrin receptor mRNA (4, 23, 31, 32). However, no
obvious homology can be found between these two positive
cis-acting elements. It is therefore likely that the two
elements may act by different mechanisms. Moreover, in the published
studies (4, 23, 31, 32) the positive cis element
is adjacent to the negative cis element, whereas in the HSA
mRNA the positive and negative cis elements are about 1 kb
apart in the linear sequence. The positive cis element
described in this study does not have homology with other sequences
implicated in RNA regulation. It is therefore likely that it prevents
RNA degradation by a novel mechanism.
The coexistence of stabilizing and destabilizing cis-acting
elements within the 3'UTR, as described in this study, has been rarely
reported (18). However, mRNA for the transferrin receptor possesses both of these two types of cis elements (4,
23, 31, 32). Recent studies indicate that cellular factors that interact with these distinct elements can regulate the expression of
transferrin receptor mRNA in response to variation in iron concentration (23, 32). The presence of positive and
negative cis elements within the 3'UTR of HSA mRNA suggests
that the expression of HSA can be regulated by selectively activating
or silencing the putative trans elements that act on the
cis elements described in this paper. We show here that
deletion within the 3'UTR of HSA selectively inactivates either
positive or negative cis elements, which makes it possible
to test the hypothesis by using a transgenic approach.
While the primary focus of the current study is to delineate the
cis elements in the 3'UTR of the HSA mRNA that control its stability, several novel observations made in the study may have important implications for the mechanism of mammalian mRNA degradation, which has been difficult to study due to lack of degradation
intermediates. Several species of HSA-DelB of approximate 1.0 kb are
likely to be such intermediates. Thus, the full-length HSA-DelB
transcript is detected in the nuclei but not in the cytoplasm. In
contrast, the short pA ORF-containing fragments were
observed in the cytoplasm but not in the nuclei. Moreover, a large
amount of HSA-DelB RNA, which contains the 3'UTR plus downstream vector
sequence but not the ORF, is detected in the cytoplasm. These findings
lead us to propose a model for degradation of HSA-DelB RNA (Fig.
11a). First, the HSA transcript is
cleaved at multiple sites to generate a spectrum of small fragments of
approximately 1.0 kb. The 5' fragments, which contain the ORF but not
poly(A), are subject to a rapid, CHX-sensitive degradation, while the
3' fragments, which contain the poly(A) tail, accumulate in a large
amount. The relative speed and mechanism of the first endonucleic
cleavage can be modulated by the ORF. For instance HSA-DelB cleavage is
not prevented by CHX, while that for the B7-2-NE is CHX sensitive.
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FIG. 11.
(a) Mechanism of degradation of HSA-DelB mRNA. Newly
synthesized full-length RNA transcripts were endonucleically cleaved by
a CHX-independent mechanism. The 5' fragments that contain the HSA ORF
but lack a poly(A) tail are rapidly degraded by a CHX-sensitive
mechanism, while the 3' fragments that contain a poly(A) tail but not
the ORF accumulate. CMV, cytomegalovirus. NE, negative cis
element. (b) Implications of alternative polyadenylation on the
mechanisms of posttranscriptional regulation of HSA gene expression.
PE, positive cis element.
|
|
The HSA gene has two potential polyadenylation sites. Utilization of
the first will produce a shorter mRNA devoid of the negative cis element. Thus, alternative polyadenylation will produce
HSA mRNA subject to distinct posttranscriptional mechanisms (Fig. 11b).
Nevertheless, most cell types in animals utilize the second polyadenylation site, and the mRNAs are thus likely to be subject to
the posttranscriptional mechanism defined in the current study.
The expression of HSA is under stringent developmental control. In the
T-cell lineage, HSA is expressed among 50% of the CD4
CD8 and all CD4+ CD8+ thymocytes
(15). The level of HSA in T cells appears to correlate inversely with T-cell maturity (7). Hough et al.
(13) have recently demonstrated that transgenic mice that
constitutively express HSA at high levels have a very small thymus and
a selective defect in generating either CD4 or CD8 T cells. These
results indicate that down-regulation of HSA is a necessary step for
T-cell maturation in the thymus. Clearly, understanding of the strict regulation of HSA expression will provide insights into the mechanism of lymphocyte development and activation.
| |
ACKNOWLEDGMENTS |
Qunmin Zhou and Yong Guo contributed equally to the study.
We thank Peter Nielsen for HSA-deficient mice, Robert Schneider for
helpful discussion, and Mary Lee and Fran Hitchcock for critical
reading of the manuscript.
This study was supported by Public Health Service grant AI-32981 from
the National Institutes of Health and by the Searle Scholar Program.
Part of this study was performed when Y.G. was supported by NIH
training grant CA09161-18.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Pathology, New York University Medical Center, 550 First Ave., New
York, NY 10016. Phone: (212) 263-7838. Fax: (212) 263-8179. E-mail: liuy01{at}mcrcr6.med.nyu.edu.
| |
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Mol Cell Biol, February 1998, p. 815-826, Vol. 18, No. 2
0270-7306/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
