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Journal of Virology, January 1999, p. 352-361, Vol. 73, No. 1
0022-538X/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
Diminished Production of Human Immunodeficiency
Virus Type 1 in Astrocytes Results from Inefficient Translation of
gag, env, and nef mRNAs despite
Efficient Expression of Tat and Rev
Paul R.
Gorry,1,2
Jane L.
Howard,1
Melissa J.
Churchill,3,5
Jenny L.
Anderson,1,3
Anthony
Cunningham,4,5
Deborah
Adrian,4,5
Dale A.
McPhee,1,5 and
Damian F. J.
Purcell1,*
AIDS Cellular1 and
Molecular3Biology Units, Macfarlane
Burnet Centre for Medical Research, Fairfield 3078, and
Department of Medical Laboratory Science, RMIT
University, Melbourne 3001,2 Victoria,
Centre for Virus Research, Westmead Institutes of Health
Research, Westmead Hospital, University of Sydney, Westmead 2145,
New South Wales,4 and
National
Centre in HIV Virology Research, Fairfield 3078,
Victoria,5 Australia
Received 18 May 1998/Accepted 14 October 1998
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ABSTRACT |
Astrocytes infected with human immunodeficiency virus type 1 (HIV-1) produce only minimal quantities of virus. The molecular events
that limit acute-phase HIV-1 infection of astrocytes were examined
after inducing acute-phase replication by transfection with the pNL4-3
proviral plasmid. The levels of HIV-1 mRNA were similarly high in both
astrocytes and HeLa cells, but astrocytes produced approximately
50-fold less supernatant p24 than HeLa cells. We found that diminished
HIV-1 production in astrocytes resulted from inefficient translation of
gag, env, and nef mRNAs that were
efficiently transported to the cytoplasm. Tat- or Rev-dependent reporter constructs showed no defect in Tat or Rev function in astrocytes compared with HeLa cells. HIV-1 mRNAs were correctly spliced, but only Rev and Tat proteins were efficiently translated from
their native mRNAs. Pulse-chase labelling and immunoblot experiments
revealed no defect in protein processing, but levels of Gag, Env, or
Nef protein expressed were dramatically reduced in astrocytes compared
to HeLa cells. These results demonstrate that inefficient translation
of HIV-1 structural proteins underlies the restricted infection of
astrocytes. The efficient expression of functional Tat and Rev by
astrocytes may contribute to HIV-1 neuropathogenesis.
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INTRODUCTION |
Human immunodeficiency virus type 1 (HIV-1) infection of the central nervous system occurs early in the
course of HIV-1 disease. HIV-1 productively infects brain macrophages
and microglial cells (3, 7, 18, 24, 43). A subpopulation of
astrocytes is also consistently infected (3, 41, 43), but
astrocyte infection yields little progeny virus (6, 14, 21, 25, 36, 49, 50). However, nonproductively infected astrocytes may be
activated to produce virus that can be transferred to other susceptible
cells (6, 19, 50). Thus, infected astrocytes might serve as
a reservoir of HIV-1 in the brain and could be a sanctuary site for
HIV-1 that might thwart virus eradication by current therapeutic
regimens. Astrocytes are terminally differentiated in adult brain
tissue and are crucial for neuronal function and survival. Therefore,
elimination of HIV-1-infected astrocytes by therapeutic or
immunological means would be detrimental. A preferable approach would
permanently lock HIV-1 into a dormant state in astrocytes. However, to
achieve this, the precise mechanisms that initiate and maintain the
latent infection of astrocytes must be understood. Our present study
examined the initial events during acute-phase viral replication that
drive HIV-1 infection of astrocytes toward a dormant state.
Most previous studies on HIV-1 replication in astrocytes have focused
on the transcriptional control of stably integrated HIV-1 in long-term-
or latently infected cells. During this dormant phase that follows the
initial infection, restricted expression of virus results from
low-level basal long terminal repeat (LTR) activity which can be
modestly induced by cytokines or other chemical stimuli (13, 32,
40, 42). In contrast, during acute-phase virus replication in
astrocytes, low-level virus production appears to be controlled
posttranscriptionally, since high levels of HIV-1 mRNA are synthesized
after transfection with a proviral plasmid (19, 49). These
observations suggest that there may be two phases of entry into the
dormant state, one operating initially to suppress virion production
despite high-level RNA synthesis and another that eventually suppresses
RNA transcription. Transcriptional repression in long-term-infected
cells is not unique to astrocytes (10, 16, 17), but the
action of a novel central nervous system-derived molecule that promotes
TAR-independent transcription in the presence of Tat indicates that
unique transcriptional regulatory mechanisms may exist in astrocytes
(28, 45-47, 53).
Earlier studies using a persistently HIV-1-infected astrocyte cell
line, TH4-7-5, demonstrated that inefficient HIV-1 Rev function
prevented the nucleocytoplasmic export and subsequent expression of
gag and env RNAs bearing the Rev-responsive
element (RRE) (31). Here, we examined acute-phase HIV-1
replication in astrocytes following transfection of an infectious
molecular clone to examine whether an inactive Rev-RRE regulatory axis
leads to the restricted expression of virus during the initial
infection. We showed that astrocytes acutely infected by HIV-1 produce
high levels of viral mRNA, which is correctly spliced and efficiently translocated to the cytoplasm. Efficient RNA expression in astrocytes is associated with normal expression and function of Rev and Tat proteins. However, the major HIV-1 structural and Nef proteins are
expressed at low levels in astrocytes during the acute infection phase,
despite high levels of available mRNA and the efficient translation of
a coexpressed, non-HIV-1 reporter. We showed that diminished expression
of these proteins in astrocytes results from an HIV-1-specific
restriction in the translation of gag, env, and
nef mRNAs to proteins. This severely reduces the synthesis of progeny virions and initiates the nonproductive or latent infection. The efficient translation of Tat and Rev proteins by HIV-1-infected astrocytes may contribute to AIDS neuropathogenesis.
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MATERIALS AND METHODS |
Cell culture.
The astrocytoma cell line U251MG
(5) was obtained from J. Kort, Department of Medicine,
Albany Medical College, Albany, N.Y., and was maintained in Dulbecco's
modified Eagle medium (DMEM) supplemented with 10% (vol/vol) fetal
calf serum, penicillin (100 U/ml), streptomycin (100 µg/ml), and
glutamine (25 µg/ml) (DMEM-10). Primary fetal astrocytes (PFA),
obtained from fetal abortuses and judged to be >99% pure by
positivity to the astrocyte-specific marker glial fibrillary acidic
protein (GFAP), were cultured in DMEM-10 for up to 10 weeks
postisolation. HeLa cells (39) were also cultured in
DMEM-10.
Plasmids and cell transfection.
The HIV-1 proviral plasmids
pNL4-3 (1) and pNL4-3Tat
, which has two
premature stop codons introduced into the tat open reading
frame (23), were obtained from M. Martin (Laboratory of
Molecular Microbiology, National Institute of Allergy and Infectious Diseases, National Institutes of Health, Bethesda, Md.). pNL4-3Rev
contains an ACG point mutation at the initiating Met codon of the
rev gene and was prepared via site-directed mutagenesis by using the pALTER system (Promega, Madison, Wis.). The Rev reporter plasmid, pDM128, expresses the chloramphenicol acetyltransferase (CAT)
gene from an intron bearing the RRE in the presence of HIV-1 Rev
protein (22). pEGFP-N1 (Clontech, Palo Alto, Calif.)
produces green fluorescent protein (GFP) under the control of a
cytomegalovirus promoter. pLTR-EGFP, in which the
AseI-to-HindIII cytomegalovirus promoter
fragment of pEGFP-N1 is replaced with the
XhoI-to-HindIII 3'-LTR fragment from pNL4-3,
expresses high levels of GFP in the presence of HIV-1 Tat. pRSV-Rev
produces Rev protein under the direction of a Rous sarcoma virus
promoter (22). In pCMV-hGH, the GFP fragment of pEGFP-N1 was
replaced with the human growth hormone (hGH) gene. Unless indicated
otherwise, cells were cotransfected with 20 µg of proviral plasmid
plus 5 µg of GFP-expressing plasmid and 2 µg of pCMV-hGH plasmid by
the calcium phosphate method as previously described (19).
Antibodies.
BB10 (a gift from E. Dax, National HIV Reference
Laboratory, Fairfield, Victoria, Australia) is pooled human
HIV-1-immune serum that recognizes the major HIV-1 structural proteins
p24, p55, and gp120. Sheep anti-Nef15-27 (provided by A. Greenway) is an affinity-purified polyclonal antibody raised against a
peptide corresponding to amino acids 15 to 27 of HIV-1NL
Nef (20).
hGH and HIV-1 p24 assays.
HIV-1 p24 antigen production was
measured by enzyme immunoassay in accordance with the manufacturer's
instructions (Organon Teknika, Durham, N.C.). hGH production was
measured from 100 µl of culture supernatant by radioimmunoassay
(Nichols Institute Diagnostics, San Juan Capistrano, Calif.).
Analysis of HIV-1 mRNA.
Total cell RNA was extracted by
using TRIzol reagent in accordance with the manufacturer's protocol
(BRL Life Technologies, Gaithersburg, Md.). Cytoplasmic RNA extracts
were prepared from 106 transfected cells that were washed
three times in phosphate-buffered saline (PBS) and then hypotonically
swollen in 3 ml of a solution consisting of 10 mM KCl, 1.5 mM
MgCl2 and 10 mM HEPES (pH 7.9) for 10 min on ice. Cells
were lysed in 200 µl of ice-cold cytoplasmic extraction buffer (150 mM NaCl; 10 mM Tris-HCl, pH 8.0; 2 mM MgCl2; 0.5%
[vol/vol] Nonidet P-40 [NP-40]; 10 mM ribonucleoside complexes), and nondisruption of cell nuclei was confirmed by light microscopy. Cell lysates were vortexed for 10 s and centrifuged at 1,700 × g for 5 min to pellet intact nuclei. The supernatant was
collected and centrifuged again to remove any residual nuclei. One
hundred eighty microliters of supernatant was added to 1 ml of TRIzol reagent, the mixture was gently inverted, and RNA was purified as
above. Northern blot detection of the three major HIV-1 mRNA classes in
total-cell and cytoplasmic RNA extracts was performed with a 3' HIV-1
LTR region PCR product labelled with [
-32P]dCTP as
previously described (19).
First-strand cDNA was synthesized from total RNA extracts with avian
myeloblastosis virus reverse transcriptase, using a cDNA cycle kit and
an oligo(dT) primer (Invitrogen, Carlsbad, Calif.). PCR for spliced
HIV-1 mRNA species was performed by a method described previously
(34), with the following modifications: for PCR analysis of
cDNA from the 4.0-kb mRNA class, the oligonucleotide primers Odp.045
(5'-CTGAGCCTGGGAGCTCTCTG-3', positions 477 to 499 of
HIV-1NL) and Odp.084 (5'-TCATTGCCACTGTCTTCTGCTCT-3',
positions 6202 to 6225 of HIV-1NL) were used.
Amplification products were radiolabelled by performing a single round
of PCR, replacing dCTP with 10 µCi of [-32P]dCTP,
and then analyzed by electrophoresis on a 6% polyacrylamide-urea gel
and autoradiographed. Individual HIV-1 mRNA species were named according to the nomenclature of Purcell and Martin (34).
CAT assays.
Cells were trypsinized 72 h after
cotransfection, washed twice in PBS, resuspended in 120 µl of 250 mM
Tris-HCl (pH 7.8) with 0.5% (vol/vol) NP-40, and then subjected to
three rapid freeze-rapid thaw cycles to induce lysis. The tubes were
vortexed for 10 s between each freeze-thaw cycle. Lysates were
centrifuged at 15,300 × g for 5 min at 4°C,
supernatants were heat inactivated at 65°C for 10 min and then
centrifuged at 15,300 × g for 5 min at 4°C, and the
resultant supernatants were harvested for CAT assay. To control for
transfection efficiency, the amount of cell lysate assayed was adjusted
according to hGH production by dilution with 1 M Tris-HCl (pH 7.8), and
then 25 µl of this supernatant was added to 25 µl of 1 M Tris-HCl
(pH 7.8) and reacted with 10 µl of acetyl coenzyme A (Boehringer,
Mannheim, Germany; 3.5 mg/ml) and 5 µl of
D-threo[dichloracetyl-1,2-14C]chloramphenicol
(NEN, Boston, Mass.; 57 mCi/mmol) at 37°C for 6 to 24 h,
depending on the experiment. Incubation times were varied to measure
CAT activity in the linear range (<30% conversion). Reaction mixtures
were extracted with ethyl acetate and analyzed by thin-layer
chromatography. Acetylation by CAT protein was assessed by
autoradiography and quantified with a model FLA-2000 phosphorimager (Fuji, Tokyo, Japan).
Assessment of GFP fluorescence.
Cells transfected with
pEGFP-N1 or pLTR-EGFP were fixed in 1% (vol/vol) formaldehyde
(ultrapure electron microscopy grade; Polysciences, Warrington, Pa.)
and analyzed for the percentage and mean fluorescence of GFP-expressing
cells on a FACSCalibur flow cytometer (Becton Dickinson, San Jose,
Calif.) at 48 or 72 h posttransfection. To account for both the
number and intensity of fluorescent cells in experiments using the
pLTR-EGFP reporter, the amount of fluorescence was determined from the
fluorescence-activated cell sorter (FACS) profiles by multiplying the
percentage of positive cells by the mean channel fluorescence.
Immunoblotting.
At 72 h after transfection, cells
(106) were washed twice in PBS and resuspended in 200 µl
of ice-cold lysis buffer (0.5% [vol/vol] NP-40; 0.5% [wt/vol]
sodium deoxycholate; 50 mM NaCl; 25 mM Tris-HCl, pH 8.0; 10 mM EDTA; 5 mM benzamidine HCl; 10 mM phenylmethylsulfonyl fluoride) for 10 min,
and then cellular debris was removed by centrifugation at 15,300 × g for 10 min. Lysate concentrations were standardized for
transfection efficiency against hGH production, and 20 µl of lysate
was added to 5 µl of 5× sodium dodecyl sulfate (SDS) gel loading
buffer (10% [wt/vol] SDS; 500 mM dithiothreitol; 300 mM Tris-HCl, pH
6.8; 0.001% [wt/vol] bromophenol blue). Samples were boiled for 3 min and then electrophoresed on SDS-13% polyacrylamide gels, and
proteins were transferred to Hybond-C nitrocellulose membranes
(Amersham, Buckinghamshire, England). Nonspecific binding of membranes
was blocked with Tris-buffered saline containing 3% (wt/vol) casein
and 0.3% (vol/vol) Tween 20 for 16 h. After being washed four
times with Tris-buffered saline containing 0.3% (vol/vol) Tween 20, the membranes were probed with either polyclonal HIV-1 antiserum BB10
(1:5,000) or sheep anti-Nef15-27 (1:500). After being
subjected to four more washing steps as described above, the membrane
was incubated with a horseradish peroxidase-conjugated antibody to
human or sheep immunoglobulin G (1:5,000) for 1 h and then washed
seven times as described above, and immunoreactive proteins were
detected by enhanced chemiluminescence (ECL; Amersham).
Pulse-chase labelling and immunoprecipitation.
Cells were
transfected with 20 µg of pNL4-3 and 5 µg pEGFP-N1 and cultured
until 24 h before the peak of p24 production (48 h for HeLa cell
transfectants or 72 h for U251MG transfectants). Transfected (or
mock-transfected) cells (6 × 106) were washed twice
in PBS and starved in 6 ml of DMEM lacking methionine and cysteine
(ICN, Costa Mesa, Calif.) but containing 2% dialyzed fetal calf serum
for 30 min at 37°C. Cells were pulse-labelled for 1 h by adding
500 µCi of 35S-labelled methionine-cysteine (NEN) after
suspension in 600 µl of starvation medium. Labelled cells were washed
twice in PBS, resuspended in 6 ml of DMEM-10 medium, and divided into
six tubes (106 cells each). Cells were incubated at 37°C
and harvested at 0, 1, 2, 3, 4, and 6 h post-pulse-labelling.
Preparation of cell and virion lysates and immunoprecipitation of HIV-1
structural proteins with pooled HIV-1-immune serum were performed
as previously described (51). Immunoprecipitation for Rev
protein was performed with a sheep antiserum to glutathione
S-transferase-Rev (ICN) from lysates of 6 × 106 transfected HeLa or U251MG cells that were
radiolabelled with 500 µCi of 35S-labelled
methionine-cysteine for 16 h.
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RESULTS |
Inefficient expression of p24 antigen in PFA and U251MG astrocytoma
cells acutely replicating HIV-1.
In vitro infection of astrocytes
with cell-free HIV-1 is highly inefficient at initiating measurable
virus replication. To ensure sufficient synchronous expression of
HIV-1, we cotransfected either PFA or the U251MG astrocytoma cell line
with the pNL4-3 HIV-1 proviral plasmid, as well as with pEGFP-N1 to
monitor the transfection efficiency. When compared to control HeLa cell
transfections, the primary astrocytes and U251MG astrocytoma cells
synthesized 22- and 30-fold less p24 antigen, respectively, despite
comparable GFP expression (Fig. 1).
Hence, since HIV-1 production was similarly restricted in both primary
and transformed astrocytes during acute-phase viral replication, the
U251MG astrocytoma cell line was chosen to investigate the reduced
expression of virus.
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FIG. 1.
Restricted expression of HIV-1 p24 during acute-phase
viral replication in primary and transformed astrocytes compared with
HeLa cells. The expression of HIV-1 p24 or the GFP reporter is shown
from HeLa, U251MG astrocytoma, or PFA cells that were cotransfected
with the pNL4-3 proviral plasmid and pEGFP-N1. Cells and supernatant
were tested at their peak of expression, 48 h for HeLa cells and
72 h for both astrocytic cell types.
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Efficient transcription and nucleocytoplasmic transport of
Rev-dependent HIV-1 mRNAs in astrocytes.
To study the molecular
mechanisms restricting HIV-1 expression during an acute-phase
infection, we first assessed the HIV-1 mRNAs by Northern blot analysis.
HIV-1-transfected U251MG astrocytes and HeLa cells contained all three
HIV-1 mRNA classes (Fig. 2A). The
synthesis of 9-kb genomic and 4-kb env HIV-1 mRNAs was
comparable in transfected astrocytes and HeLa cells. The multiply
spliced 2-kb mRNA was expressed at even higher levels in astrocytes
than in HeLa cells and represented a greater proportion of the total HIV-1 mRNA, as previously reported (19, 25, 49). We
performed Northern blot experiments with astrocytes infected by
cell-free HIV-1 in vitro but could not detect HIV-1 RNA (data not
shown). Despite high levels of HIV-1 mRNA, the level of soluble p24
antigen detected in these transfected astrocytes (12 ng/ml) was
severely reduced compared to the level in HeLa cells (540 ng/ml) in
this experiment. We considered that restricted virus production in acutely infected astrocytes might result from a block in Rev-mediated nucleocytoplasmic transport of Rev-dependent mRNA as was previously shown for a persistently infected astrocyte cell line (31).
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FIG. 2.
Efficient transcription and nucleocytoplasmic transport
of HIV-1 mRNA in astrocytes. Northern blotting, using a 3' HIV-1 LTR
region probe designed to detect all HIV-1 mRNAs, was performed with
total cellular RNA from HeLa (lanes 1 and 2) and U251MG cells (lanes 3 and 4) transfected with pNL4-3 (lanes 2 and 4) or mock transfected
(lanes 1 and 3) (A) or with cytoplasmic (C) or total (T) RNA extracted
from HeLa (lanes 1 to 4) and U251MG (lanes 5 to 8) cells transfected
with pNL4-3 (lanes 3, 4, 7, and 8) or mock transfected (lanes 1, 2, 5, and 6) (B) or with cytoplasmic or total RNA extracted from HeLa (lanes
1 to 4) and U251MG (lanes 5 to 8) cells transfected with pNL4-3
Rev (lanes 3, 4, 7, and 8) or mock transfected (lanes 1, 2, 5, and 6) (C).
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Rev function in astrocytes transfected with pNL4-3 was first assessed
from the cytoplasmic accumulation of Rev-dependent HIV-1
mRNA. Northern
blot analyses comparing the relative ratios of
HIV-1 mRNAs in
total-cell and cytoplasmic extracts from transfected
astrocytes and
HeLa cells revealed no defect in the nucleocytoplasmic
transport of
Rev-dependent HIV-1 mRNAs in astrocytes (Fig.
2B).
By densitometry, it
was determined that astrocytes and HeLa cells
translocated similar
proportions of the 9-kb mRNA into the cytoplasm
(Table
1), indicating that this function of Rev
was not compromised
in astrocyte transfections. Aside from this
finding, densitometry
also showed that the multiply spliced 2-kb mRNA
accumulated in
the cytoplasmic fraction with a fivefold higher
efficiency in
astrocytes (Fig.
2B, lanes 7 and 8). Transfection of
astrocytes
and HeLa cells with a Rev-defective provirus control,
pNL4-3Rev
,
resulted in the 9- and 4-kb Rev-responsive mRNAs
being retained
almost exclusively in the nucleus, with efficient
cytoplasmic
accumulation of 2-kb mRNA (Fig.
2C and Table
1).
HIV-1 mRNA is correctly spliced in astrocytes.
Since adequate
levels of HIV-1 mRNA were available in transfected astrocytes for viral
protein production, the pattern of alternatively spliced mRNA was
assessed to determine whether the restriction in virus production
occurred due to incorrect processing. The multiply spliced 2-kb mRNA
species were examined by semiquantitative reverse transcription
(RT)-PCR (Fig. 3A). The full array of
multiply spliced mRNA species could be observed in both HeLa and U251MG astrocytoma cells transfected with the pNL4-3 proviral plasmid. A
reduced synthesis of Vpr1 (1/3E/7) mRNA (34) by U251MG
astrocytes was observed. Vpr expression is unlikely to account for the
observed differences in viral production, since pNL4-3 wild type and
Vpr mutants expressed similar levels of p24 and reverse transcriptase in HeLa cells. Similarly, cotransfection of Vpr expression constructs with pNL4-3 in U251MG astrocytes did not increase the level of p24 or
reverse transcriptase (data not shown). For the 4-kb species of mRNA,
the two cell types showed similar patterns of spliced RNA, with the
primary env transcript, Env1 (1/5E), predominating (Fig.
3B). Thus, RNA was spliced similarly in HeLa and U251MG astrocytoma
cells, and RNA splicing does not account for the differences in the
expression of HIV-1 particles from these two cell types.
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FIG. 3.
Astrocytes correctly splice HIV-1 mRNAs. RT-PCR analysis
of multiply spliced 2.0-kb (A) and singly spliced 4.0-kb (B) HIV-1
mRNAs from total-cell RNA extracted from HeLa (lane 1) or U251MG (lane
2) cells transfected with pNL4-3. cDNAs were amplified by PCR,
labelled, and analyzed on a 6% acrylamide-urea gel. Nonspecific
amplification was not observed in reactions lacking reverse
transcriptase (data not shown).
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Rev protein is expressed and functional in astrocytes.
The
pDM128 reporter plasmid requires Rev for the expression of CAT
(22). Cotransfection of pDM128 with a control Rev expression plasmid, pRSV-Rev, showed comparable Rev function in the U251MG astrocytoma and HeLa cell lines (Fig. 4).
Increased expression of Rev from pRSV-Rev in HeLa cells led to
dose-dependent CAT activity, indicating increasing Rev function (Fig.
4A and B). A very similar dose dependency was observed following
cotransfection of pRSV-Rev in the U251MG astrocytoma cells (Fig. 4C and
D). Rev-dependent regulation of pDM128 expression was not as stringent
in U251MG astrocytes as in HeLa cells, since low-level acetylation was
observed in astrocytes when pDM128 was transfected without Rev (Fig.
4C, lane 2). Thus, Rev protein functions efficiently in U251MG
astrocytes when expressed from a Rev expression plasmid.
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FIG. 4.
Rev-dependent expression of a CAT reporter in
astrocytes. Acetylation of chloramphenicol was measured in extracts of
HeLa (A and B) or U251MG (C and D) cells that were transfected with 5 µg of the Rev-dependent CAT reporter pDM128 alone (lane 2) or
together with increasing amounts of Rev from the pRSV-Rev expression
plasmid (0.05, 0.2, 2.0, or 5.0 µg [lanes 3, 4, 5, and 6, respectively]). Cells were cotransfected with 2 µg of pCMV-hGH to
control for transfection efficiency. Mock transfections received
pCMV-hGH alone (lane 1). CAT assays were performed on cell lysates that
were normalized for hGH production. Acetylation was quantitated by
phosphorimaging, with basal acetylation defined as CAT activity by
pDM128 without Rev (lane 2), and means and standard errors of the means
of the CAT activity for data from three experiments were determined
after subtracting basal acetylation (B and D).
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To measure Rev expression from the native
rev mRNA, the
pDM128 plasmid was cotransfected with increasing amounts of the pNL4-3
proviral plasmid or a Rev-defective control, pNL4-3Rev
. Again,
similar Rev activities were observed in U251MG astrocytoma and
HeLa
cells (Fig.
5). No CAT activity was
observed when the pNL4-3Rev
proviral plasmid was transfected into
HeLa cells (Fig.
5A), but
low-level acetylation similar to background
levels was observed
when that plasmid was transfected into U251MG
astrocytoma cells
(Fig.
5D). Despite finding similar Rev activities in
the two cell
types, p24 antigen was expressed in amounts up to 27-fold
higher
in HeLa cells (compare Fig.
5C and F). These results indicate
that expression of functional Rev protein from the native mRNA,
but not
p24, is equally efficient in U251MG astrocytes and HeLa
cells. Thus,
Rev function does not restrict the acute-phase replication
of HIV-1 in
astrocytes as demonstrated by the limited expression
of p24.
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FIG. 5.
Efficient expression of Rev from the native
rev mRNA in astrocytes. Acetylation of chloramphenicol was
measured in extracts of HeLa (A and B) or U251MG (D and E) cells that
were transfected with 5 µg of pDM128 without HIV-1 provirus (lane 2)
or together with increasing amounts of pNL4-3 (lanes 3, 5, 7, 9, and
11) or pNL4-3Rev (lanes 4, 6, 8, 10, and 12). Cells were transfected
with 2 µg of pCMV-hGH to control for transfection efficiency. Mock
transfections received pCMV-hGH alone (lane 1). CAT assays were
performed on cell lysates that were normalized for hGH production.
Acetylation was quantitated by phosphorimaging, with basal acetylation
defined as CAT activity by pDM128 without Rev (lane 2), and means and
standard errors of the means of the CAT activity for data from three
experiments were determined after subtracting basal acetylation (B and
E). Soluble p24 antigen was measured in culture supernatant samples
collected prior to cell harvesting and normalized for hGH production (C
and F).
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Efficient Tat expression and function in astrocytes.
The
Tat-dependent reporter plasmid pLTR-EGFP was used to measure Tat
function by fluorescence via flow cytometry. When Tat was expressed
from the pNL4-3 proviral plasmid, similar Tat activities were measured
in HeLa and U251MG cells (Fig. 6). Basal
LTR activity was obtained when a Tat-mutated proviral plasmid,
pNL4-3Tat, was used. Despite having similar Tat function, the
synthesis of p24 antigen was up to 23-fold higher in HeLa cell
supernatants that produced equivalent levels of hGH (compare Fig. 6B
and D). This shows that restricted virus production in U251MG cells was not due to inefficient Tat protein function. These results indicate that Tat protein is efficiently synthesized from its native mRNA in
U251MG astrocytes and is fully functional for transactivating transcription from the HIV-1 LTR.
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FIG. 6.
Efficient expression of Tat from the native
tat mRNA in astrocytes. The fluorescence of cells expressing
GFP was measured by flow cytometry of HeLa cells (A) or U251MG cells
(C) that were transfected with 5 µg of pLTR-EGFP together with
increasing amounts of pNL4-3 (0.05, 0.2, 2.0, 10.0, or 20.0 µg
[lanes 1, 3, 5, 7, and 9, respectively]) or pNL4-3Tat (0.05, 0.2, 2.0, 10.0, or 20.0 µg [lanes 2, 4, 6, 8, and 10, respectively]).
Transfections included 2 µg of pCMV-hGH to control for transfection
efficiency. Fluorescence (see Materials and Methods) was expressed as
the ratio of basal fluorescence obtained from transfections of
pLTR-EGFP without Tat and normalized for hGH production. Shown are mean
values and standard errors of the means of data from four experiments.
Soluble p24 antigen was measured in HeLa (B) or U251MG (D) culture
supernatant samples collected prior to cell harvesting and normalized
for hGH production.
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The restricted acute-phase infection of astrocytes results from a
specific downmodulation in the translation of HIV-1 structural and Nef
proteins.
The preceding experiments showed that astrocytes express
and process HIV-1 RNA in the same way as HeLa cells. We therefore measured the production of HIV-1 proteins after transfection with pNL4-3, using immunoblotting or pulse-chase labelling and
immunoprecipitation. Immunoblotting revealed very low-level synthesis
of HIV-1 proteins in pNL4-3-transfected astrocytes compared to HeLa
cells (Fig. 7A). Similarly, there were
fivefold lower levels of Nef in astrocytes than in HeLa cells (Fig.
7B), despite the existence of fivefold higher levels of nef
mRNA (Fig. 2A and 3A). The ratio of intracellular p24 (measured by
enzyme-linked immunosorbent assay of cell lysates) to hGH (measured
from transfected-cell supernatant) in astrocytes (0.073 ng/ng of hGH)
was 15-fold lower than that in HeLa cells (1.1 ng/ng of hGH). In
contrast, Rev was expressed with similar efficiencies by HeLa and
U251MG astrocytes, since equivalent amounts of Rev were
immunoprecipitated from the respective cell lysates after normalization
for trichloroacetic acid (TCA)-precipitable counts (Fig. 7C, compare
lanes 2 and 4).
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FIG. 7.
Low levels of HIV-1 structural and Nef protein
expression compared to Rev protein expression by astrocytes.
Immunoblotting or immunoprecipitation of viral antigens expressed in
U251MG (lanes 1 and 2) and HeLa (lanes 3 and 4) cells after
cotransfection with the HIV-1 proviral plasmid pNL4-3 and pCMV-hGH
(lanes 2 and 4) or pCMV-hGH transfection efficiency reporter alone
(lanes 1 and 3). Cell lysates were normalized for hGH production, and
viral proteins were detected with polyclonal HIV-immune serum (BB10;
1:5,000) (A) or anti-Nef15-27 (1:500) (B). (C) Rev protein
detected by immunoprecipitation with sheep antiserum to HIV-1 Rev
(1:500) from HeLa and U251MG cells labelled with
[35S]methionine-cysteine for 16 h, 48 and 72 h
after transfection, respectively.
|
|
To determine whether the reduced levels of HIV-1 structural proteins
expressed by astrocytes resulted from abnormal protein
processing or
from a specific block in translation of these mRNAs,
pulse-chase
labelling and immunoprecipitation were performed with
equal numbers of
U251MG and HeLa cells previously cotransfected
with pEGFP-N1 and pNL4-3
plasmids. Approximately 10% more U251MG
cells were transfected than
HeLa cells, but the two cell types
expressed GFP with equivalent mean
intensities (Fig.
8). Despite
a higher
overall level of expression of GFP by astrocytes, they
synthesized
25-fold less pulse-labelled HIV-1 protein than did
HeLa cells after
normalization for TCA-precipitable counts in
the respective cell
lysates (compare Fig.
9A and C). This
indicates
that astrocytes have a specific block in expression of HIV-1
structural
proteins. However, HIV-1 Gag and Env protein processing was
identical
in the two cell types, because the processing of Env
precursor
gp160 to gp120-SU and gp41-TM and that of Gag Pr55 to p24-CA
and
p17-MA were comparable at all chase time points in lysates from
both cell types (Fig.
9A and C) and their progeny virions (Fig.
9B and
D).
View larger version (29K):
[in this window]
[in a new window]
|
FIG. 8.
Efficient translation of a non-HIV-1 fluorescence
reporter by astrocytes. Flow cytometry profiles showing the
transfection-translation efficiency of GFP (light shading) by U251MG
astrocytes (A and C) and HeLa cells (B and D) transfected with 5 µg
of pEGFP-N1 alone (A and B) or together with 20 µg of the HIV-1
proviral plasmid pNL4-3 (C and D). FACS analysis was performed at the
peak of expression posttransfection (72 h for U251MG and 48 h for
HeLa cells). Mock transfections (dark shading) contained either no DNA
(A and B) or pNL4-3 alone (C and D). The region R1 shows the percentage
and the mean channel fluorescence (MCF) of cells expressing GFP above
the mock-transfection values.
|
|
View larger version (96K):
[in this window]
[in a new window]
|
FIG. 9.
Inefficient translation but correct processing of HIV-1
structural proteins by astrocytes. HeLa (A) and U251MG (C) cells were
pulse-labelled with [35S]methionine for 1 h at
48 h (HeLa) or 72 h (U251MG) after cotransfection with
pEGFP-N1 alone (mock) or together with 20 µg of HIV-1 proviral
plasmid pNL4-3 (pulse). Labelled cells were then incubated at 37°C
for 1, 2, 3, 4, and 6 h in complete medium, and HIV-1 proteins
were detected by immunoprecipitation from cell lysate volumes
(standardized by total TCA-precipitable 35S-labelled
proteins) with pooled HIV-1 immune serum (BB10). Virions pelleted from
the supernatant of HeLa (B) or U251MG (D) transfections were lysed and
subjected to immunoprecipitation for analysis of HIV-1 structural
proteins.
|
|
Thus, the restricted virus production from astrocytes acutely
replicating HIV-1 results from inefficient translation of structural
protein from high levels of correctly processed HIV-1
mRNA.
| |
DISCUSSION |
We examined the mechanisms restricting acute-phase HIV-1
production in astrocytes by using a transfection system to optimize expression during early viral replication. Despite normal
transcription, splicing, and transport of HIV-1 mRNA, immunoblot and
radioimmunoprecipitation experiments showed that the translation of a
subgroup of HIV-1 mRNAs is highly inefficient during acute-phase viral
replication in the U251MG astrocyte cell line. The cytoplasmic
gag, env, and nef RNAs were poor
substrates for protein expression, producing 25-fold less protein in
astrocytes than in HeLa cells. Pulse-chase labelling showed that
reduced accumulation of HIV-1 structural proteins during acute-phase
viral replication was due to their inefficient synthesis in the
astrocyte cell line and was not due to any abnormal processing or
targeted degradation of these proteins.
All HIV-1 mRNA classes were expressed at high levels in U251MG cells
(Fig. 2A) and were correctly spliced (Fig. 3) but yielded 50-fold lower
p24 levels than HeLa cells expressing comparable levels of HIV-1 mRNA.
Previous studies of a persistently HIV-1-infected astrocyte cell line,
TH4-7-5, demonstrated that in that model, restricted infection resulted
from an astrocyte-specific block in HIV-1 Rev function, causing
inefficient nucleocytoplasmic transport of unspliced and singly spliced
HIV-1 mRNA species (31). In our acute-phase replication
model, this mechanism did not account for the reduced expression of
virus because the Rev-dependent mRNA classes were readily detected in
cytoplasmic RNA extracts of astrocytes (Fig. 2B), showing that
Rev-dependent mRNAs were efficiently translocated to the cytoplasm.
Control transfections with a Rev-deficient proviral plasmid,
pNL4-3Rev, demonstrated almost complete nuclear retention of
Rev-dependent mRNA species in astrocytes (Fig. 2C), confirming that Rev
is required in U251MG astrocytes for cytoplasmic translocation of HIV-1
RNAs containing the RRE.
Further confirmation of competent Rev expression and function in
astrocytes was obtained biochemically by immunoprecipitation and
functionally by using a Rev-dependent CAT reporter plasmid. Rev
expressed from either the native rev RNA or a Rous sarcoma virus-Rev expression plasmid confirmed that Rev is translated and
functions with equivalent efficiency in U251MG astrocytes and HeLa
cells. An earlier study of the persistently infected TH4-7-5 cell line
that attributed the low production of virus to a defect in Rev function
used a Rev-dependent reporter that expressed Gag (31). Our
studies clearly show that translation of Gag protein is inefficient in
U251MG astrocytes and raise the possibility that the Gag reporter for
Rev function used in those studies might also be restricted for Gag
translation. Our use of the pDM128 Rev reporter that expresses CAT
protein might explain the differences in Rev function determined in our
study and in that of Neumann et al. (31). Thus, we conclude
that expression and function of Rev during acute-phase replication of
HIV-1 in U251MG astrocytes appear to be typical.
Latent HIV-1 infection of the T-cell line ACH2 and a promyelomonocytic
cell line, U1, results from mutations in Tat or its RNA binding site,
TAR, respectively (2, 8, 12). For astrocytes, several
studies have demonstrated efficient Tat transactivation of the HIV-1
LTR in the absence of TAR (42, 44-47), demonstrating a
unique transcriptional control mechanism in astrocytes. Our results
showed efficient expression of functional Tat from the native
tat mRNA, confirming earlier studies using other Tat
expression constructs. This suggests that the early events leading to
nonproductive HIV-1 infection of astrocytes involve suppressed
translation of HIV-1 structural proteins, as opposed to the
transcriptional repression that underpins the latent infection of T
cells and monocytes/macrophages. The suppressed translation of HIV-1
structural proteins in the face of efficient HIV-1 mRNA transcription
may explain the discrepancies in measurements of the numbers of
HIV-1-infected astrocytes in vivo. Measurements of HIV-1 structural
proteins may significantly underrepresent the distribution and
transcriptional activity of HIV-1-infected astrocytes in vivo compared
to RNA or DNA detection (3, 7, 18, 41, 43). Furthermore,
efficient expression of the neurotoxic Tat protein by astrocytes in
vivo may contribute to neuropathogenesis in AIDS patients (30,
37).
Our studies showed that Nef protein is expressed at fivefold lower
levels in U251MG cells than in HeLa cells, despite the fivefold higher
level of nef mRNA synthesis in the astrocytes. This reduced
Nef synthesis contrasts with the high levels measured in the TH4-7-5
cell line that was selected for Nef expression (6) and may
indicate that changes in the native nef mRNA alleviate the
inefficient translation. The high-level expression of Nef in postmortem
astrocytes from pediatric and adult AIDS patients (35, 38,
48) might demonstrate the existence of in vivo mechanisms that
overcome the inefficient translation of Nef, possibly modulated by
local cytokines. However, the suppressed translation of nef
mRNA observed in our study is in agreement with other reports showing
low-level Nef synthesis that could be relieved by coculture with
monocytes/macrophages (15) or tumor necrosis factor alpha stimulation (49).
The mechanism underlying the inefficient translation of the
gag, env, and nef mRNAs is unclear.
The strength of the Kozak signal surrounding the initiating AUG codon
does not correlate with the translation efficiency of these mRNAs,
because HIV-1NL tat, gag,
env, and nef mRNAs all have strong Kozak signals
whereas rev mRNA has a weak Kozak signal (26,
27). The translational control mechanism accounting for our
results must accommodate (i) the selective repression of HIV-1
structural protein synthesis over that of the other reporter proteins
used here (hGH and GFP), (ii) suppression mediated by 5' HIV-1
noncoding RNA proximal to TAR, and (iii) a relief of translational
suppression for tat and rev mRNAs that is
mediated by a short stretch of unique 5' noncoding RNA.
Several reports have shown that the translation of HIV-1 proteins may
be downmodulated by the alpha-interferon-inducible double-stranded RNA-activated protein kinase R (PKR) (4, 33). It is possible that astrocytes exhibit high-level constitutive expression of activated
PKR that might inhibit engagement of initiator tRNAMet at
the 7-methyl-Gppp cap structure at the 5' end of the RNA (reviewed by
Clemens [9]). However, PKR-mediated translational
control has not been reported to discriminate between mRNAs translated by typical ribosome scanning. The existence of polypyrimidine tracts
proximal to the initiating AUG of tat and rev
mRNAs (34) raises the possibility that the translation of
these mRNAs escapes a cap-dependent translational suppression imposed
on the other HIV-1 RNAs by direct interactions of the 40S ribosomal
subunit with polypyrimidine tract binding proteins, in a manner
resembling the activity of the internal ribosome entry sites of some
viruses, e.g., picornavirus (11).
The efficient expression of Tat protein in astrocytes raises the
possibility that this viral protein contributes to the translation control observed in these cells. Recently, the second coding exon of
HIV-1 Tat was shown to directly interact with a protein of the human
translation machinery, translation elongation factor 1 delta
(52). This interaction caused downmodulated translation of
CAT protein in vitro and of CD4 protein in transfected HeLa cells.
Interestingly, unlike CD4 cells, the translation of HIV-1 structural
proteins was not diminished in HeLA cells cotransfected with CD4 and
HIV-1 proviral plasmids (52). This discriminatory modulation
of translation in HeLa cells mediated by the second coding exon of Tat
raises the possibility that efficient expression of HIV-1 Tat in
astrocytes contributes to the observed downmodulated translation of
Gag, Env, and Nef. Another role for Tat might result from the reported
direct interaction of the first coding exon of Tat
(Tat1-72) with PKR causing an inhibition of
autophosphorylation and activation of PKR (29). In addition,
the second coding exon of Tat (Tat73-86) is itself a
substrate for phosphorylation by PKR (29). An accumulation
of Tat in astrocytes might result in interactions with PKR that
preferentially restrict translation of HIV-1 structural proteins.
Further experiments to examine the translational control mechanisms of
astrocytes that cause the diminished expression of HIV-1 are under way.
What is clear from our present results is that the translational
control mechanism of astrocytes discriminates between two subgroups of
HIV-1 mRNAs.
With regard to identifying the relevant differences between the HIV-1
mRNAs, it is of interest that the pDM128 reporter, which has the CAT
gene inserted at the translation initiation site for Env, efficiently
expresses CAT protein in astrocytes, whereas Env is inefficiently
expressed from the native env mRNA. The significant differences in the 5' untranslated regions (UTRs) of the pDM128 and the
native env mRNAs (22) provide insight into the
RNA elements that might increase the translation efficiency of the CAT
mRNA as well as rev and tat mRNA. The 5' end of
the pDM128 mRNA has up to 428 bases of the 5' UTR from simian virus 40 large T antigen joined to the bulge of the HIV-1 TAR region. The HIV-1
sequence extends to the end of the U5 region but excludes 102 bases
upstream of the major 5' splice site and includes noncoding mRNA 3' of the seventh codon of Tat. In pDM128, the start site for Rev has been
mutated and the CAT gene has been inserted at the Env initiation codon.
Thus, pDM128 includes up to 125 extra bases of the 5' UTRs from
rev and tat mRNAs that are not in the predominant
env mRNA. Thus, unique RNA elements from the rev
and tat mRNAs, such as the polypyrimidine tracts of the
splice acceptor sites for rev and env, are
included into the 5' UTR of pDM128. These RNA elements are spliced from
the native env and nef mRNAs and might confer a
more-efficient translation to some mRNAs in astrocytes. However, translation modulation by sequences in the Env coding frame cannot be excluded.
In the adult brain, astrocytes are unrenewable and crucial for
neurological function. The elimination of astrocytes latently infected
by HIV-1 may be neurologically detrimental. However, this dormant
infection provides a sanctuary for HIV-1 that may thwart viral
eradication and serve as a source for renewed systemic infection.
Inducing permanent viral dormancy may be a strategy to control HIV-1.
Our results show that the dormant infection of astrocytes originates
from a block in the translation of gag, env, and
nef mRNAs. Translation of the rev and
tat mRNAs was unaffected. Understanding the mechanisms
modulating the translation of HIV-1 structural proteins may identify
strategies to sustain the suppression of HIV-1 in viral sanctuaries
such as brain astrocytes.
| |
ACKNOWLEDGMENTS |
This work was supported by the National Health and Medical
Research Council (D.F.J.P., J.L.H., and J.L.A.; Reg Key 970558), the
National Centre for HIV Virology Research (D.A.M., M.J.C., A.C., and
D.A.), RMIT University (P.R.G.), and the Research Fund of the
Macfarlane Burnet Centre for Medical Research (P.R.G., J.L.H., M.J.C.,
J.L.A., D.A.M., and D.F.J.P.).
We thank J. Mills, A. Jaworowski, and D. Gabuzda for review of the
manuscript, G. Paukovics and A. Meikle (Flow Cytometry Unit, Macfarlane
Burnet Centre for Medical Research) for FACS analysis, and B. Rumble
(Department of Medical Laboratory Science, RMIT University) for advice
and support in this project.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Macfarlane
Burnet Centre for Medical Research, P.O. Box 254, Fairfield, Victoria
3078, Australia. Phone: 61-3-9282-2256. Fax: 61-3-9282-2100. E-mail: purcell{at}burnet.edu.au.
| |
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Journal of Virology, January 1999, p. 352-361, Vol. 73, No. 1
0022-538X/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
