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Previous Article | Next Article 
Journal of Virology, September 2000, p. 8343-8348, Vol. 74, No. 18
0022-538X/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Lack of Functional Receptors Is the Only Barrier That Prevents
Caprine Arthritis-Encephalitis Virus from Infecting Human
Cells
Laila
Mselli-Lakhal,1
Colette
Favier,1
Kevin
Leung,2
Francois
Guiguen,1
Delphine
Grezel,1
Pierre
Miossec,3
Jean-François
Mornex,1
Opendra
Narayan,2
Gilles
Querat,4 and
Yahia
Chebloune1,*
UMR INRA/ENVL/UCBL, Virologie Cellulaire, Moléculaire
et Maladies Emergentes, Ecole Vétérinaire de Lyon, Marcy
l'Etoile,1 Laboratoire d'Immunologie,
Faculté de Médicine Laennec, 69372 Lyon Cedex
08,3 and INSERM U372, Campus de Luminy,
BP 178, 13276 Marseille Cedex 09,4 France,
and Department of Microbiology, Marion Merrell Dow
Laboratory of Viral Pathogenesis, Kansas University Medical Center,
Kansas City, Kansas 66160-74242
Received 11 February 2000/Accepted 16 June 2000
 |
ABSTRACT |
Barriers to replication of viruses in potential host cells may
occur at several levels. Lack of suitable and functional receptors on
the host cell surface, thereby precluding entry of the virus, is a
frequent reason for noninfectivity, as long as no alternative way of
entry (e.g., pinocytosis, antibody-dependent adsorption) can be
exploited by the virus. Other barriers can intervene at later stages of
the virus life cycle, with restrictions on transcription of the viral
genome, incorrect translation and posttranslational processing of viral
proteins, inefficient viral assembly, and release or efficient early
induction of apoptosis in the infected cell. The data we present here
demonstrate that replication of caprine arthritis-encephalitis virus
(CAEV) is restricted in a variety of human cell lines and primary
tissue cultures. This barrier was efficiently overcome by transfection
of a novel infectious complete-proviral CAEV construct into the same
cells. The successful infection of human cells with a vesicular
stomatitis virus (VSV) G-pseudotyped Env-defective CAEV confirmed that
viral entry is the major obstacle to CAEV infection of human cells. The
fully efficient productive infection obtained with the
VSV-G-protein-pseudotyped infectious CAEV strengthened the evidence
that lack of viral entry is the only practical barrier to CAEV
replication in human cells. The virus thus produced retained its
original host cell specificity and acquired no propensity to propagate
further in human cultures.
| |
INTRODUCTION |
Lentiviruses, a genus of the family
Retroviridae, infect mammalian hosts from several orders,
including the primates (e.g., humans and several species of African
monkeys), carnivores (feline), and artiodactyls (bovine, small
ruminants, equine). They cause lifelong persistent infection, which may
be essentially symptomless or results in a variety of inflammatory,
degenerative, or immunosuppressive diseases in a variable proportion of
infected hosts. Their epidemiological, economic, and public health
impacts are considerable, and the insidious nature of the infection
raises concerns about possible spread of lentiviral infections to novel
host species. Lentiviruses have been considered to be highly
species-specific pathogens. However, the phylogenetic relationship
between them clearly indicates a common origin, so viral spread between
distantly related taxa must presumably occur, even if only rarely
(10, 15). In fact, several observations suggest possible
passage from species to species and even jumping to other genera and
families. It is clear now that human immunodeficiency virus type 1 (HIV-1) and HIV-2 in humans result from cross-species passages of
lentiviruses naturally infecting nonhuman primates. The source of HIV-2
in humans (Hominidae family) appears to have been sooty mangabeys
(Cercopithecidae family) harboring simian immunodeficiency virus smm
(SIVsmm) (4, 14), whereas the source of HIV-1
has recently been proved to be chimpanzees (10, 15).
Phylogenetic analyses also provided evidence that recombination events
have occurred between divergent viruses in vivo, indicating coinfection
with highly divergent viral strains can occur in HIV-infected humans
and SIV-infected primates (10, 17, 31). Caprine
arthritis-encephalitis virus (CAEV) and maedi-visna virus (MVV), the
small-ruminant lentivirus prototypes, are pathogens closely related to
HIV-1 and HIV-2. CAEV was isolated from goats and MVV was isolated from
sheep (6, 26, 32). CAEV infection of goats and MVV infection
of sheep are present worldwide and induce inflammatory disease mainly
in the joints, mammary glands, lungs, and central nervous system (8, 25, 33). Unlike primate lentiviruses, CAEV and MVV do
not induce immunodeficiency in infected sheep and goats and are not
tropic for CD4+ T lymphocytes (11, 25). In a
recent study, we demonstrated that CAEV replicates productively and
efficiently in milk epithelial cells, suggesting their implication in
virus transmission and pathogenesis (24). Several studies,
including ours, demonstrated the presence of viruses genetically
related to CAEV in sheep and the presence of viruses genetically
related to MVV in goats from naturally infected flocks. These data
suggested the absence of a barrier to CAEV and MVV cross-species
infection in domestic small ruminants (18, 19, 39). The
potential of these viruses to cross the species barrier and cause
infection in other animals and humans has not yet been studied. We
recently demonstrated that CAEV can cause productive persistent
infection in mouflon (wild sheep), following experimental infection
(13). Recent reports also suggested that some humans might
harbor CAEV, perhaps as a result of consumption of untreated goat milk
at an early age (A. Douvas, W. P. Cheevers, G. Ehresmann, D. T. Garcia, A. Levine, L. Xia, and J. Ju, Ninth Annu. Meet. Natl.
Cooperat. Vacc. Dev., AIDS Weekly Plus, 2 June 1997).
The purpose of the present study was to investigate the potential
of CAEV to infect human cells in vitro and the nature of any possible
barrier that could prevent its replication in human cells. We show
that, at the cellular level, the absence of suitable functional
receptors is the only practical restriction.
| |
MATERIALS AND METHODS |
Cells and viruses.
Goat synovial membrane (GSM) cells were
derived from a carpal synovial membrane explant from a goat embryo as
previously described (26) and were grown in Eagle's minimum
essential medium (MEM; Gibco BRL, Cergy Pontoise, France), supplemented
with 8% fetal bovine serum (FBS; Gibco-BRL). The large T-immortalized
goat embryo fibroblast cell line TIGEF (9) was obtained by
transfection of GSM cells with a replication origin-deleted simian
virus 40 plasmid (pMK16-SV40-ori-). Goat macrophages were derived from peripheral mononuclear cells from blood samples of CAEV-negative yearling goats as described previously (3).
Human epithelial cell lines TE671 (derived from a human
rhabdomyosarcoma [ATCC 184B5]), A431 (derived from a human epidermoid carcinoma [ATCC CRL-155]), HeLa (derived from human cervix carcinoma [ATCC CCL2]), and 293 (derived from transformed primary embryo kidney
cell [ATCC: CRL-1573]) were grown in Dulbecco's modified Eagle's
medium supplemented with 10% FBS. Human monocytic cell lines U937
(derived from a histiocytic lymphoma [ATCC CRL-1593]) and THP-1
(derived from the peripheral blood of a 1-year-old boy with monocytic
leukemia [ATCC TIB-201]) were cultured in nonadherent conditions in
RPMI 1640 medium supplemented with 10% FBS. Differentiation into
adherent macrophages was induced by addition of 20 ng of phorbol
12-myristate 13-acetate (PMA) (Sigma, Isle D'Abeau, France)/ml of
medium. Primary human macrophages were derived from blood samples of a
healthy HIV-negative donor. Peripheral blood mononuclear cells were
isolated by Ficoll-Hypaque gradient centrifugation and then were
cultured in macrophage differentiation medium with 20% human
serum in Teflon flasks as described previously (2) to induce the maturation of monocytes into macrophages. Differentiated macrophages were seeded into six-well plates for 4 to 24 h,
nonadherent cells were removed, and macrophage monolayers were grown in
macrophage differentiation medium. Primary human synovial cells were
obtained from an arthritic HIV-negative patient and were expanded
by culture in MEM supplemented with 10% FBS.
Plasmids.
The pTR-UF5 plasmid carrying the green fluorescent
protein (GFP) gene under the transcriptional control of the human
cytomegalovirus (CMV) early promoter/enhancer was obtained from
Clontech, Montigny Le-Brotonneux, France). The pHCMV-G plasmid
expressing the G glycoprotein of vesicular stomatitis virus (VSV) under
control of the same CMV promoter/enhancer was kindly provided by
J. Burns.
Construction of a plasmid containing the complete CAEV proviral
genome.
We generated a full-length infectious provirus molecular
clone of CAEV by using the recently described recombinant plasmids pK9Kb and pBS
(38). Double digestion of pK9Kb plasmid
DNA with SalI (Promega, Charbonnieres-Les-Bains, France) and
PflmI (New England Biolabs, Saint-Quentin Yvelines, France)
endonucleases under the conditions recommended by the supplier released
an 8.4-kb fragment corresponding to the complete CAEV-CO genome
lacking the 3' end of the env gene and the 3' long terminal
repeat (LTR). This fragment was separated by gel electrophoresis and
harvested by the freeze-and-squeeze method. Then, DNA was harvested
using the microcolumns (Millipore, Saint-Quentin Yvelines, France). This fragment was inserted into the pBS plasmid double digested with XhoI (Promega) and PflmI endonucleases under
the conditions recommended by the supplier. This reconstituted the
complete proviral CAEV-CO genome in one plasmid, which was found to
replicate well in transformed JM109 bacteria, with a lower
recombination rate than that of DH5
, particularly at a low growth
temperature (<30°C).
Production of CAEV-pBSCA virus stock.
GSM cells
(5 × 105) were transfected with 5 µg of pBSCA
plasmid DNA by using the Lipofectin method with Lipofectamine (Gibco BRL) as described previously (9). Medium was changed every 3 days, and the development of cytopathic effect (CPE) was monitored. When the monolayer reached 50% CPE, virus stock was harvested 8 to
16 h after replacement with fresh culture medium. Titer of the
virus stock was determined by infection of GSM cells with serial
dilutions and scoring CPE development as described previously (23,
29).
Infection of cell lines with CAEV-pBSCA virus.
Cells
were seeded at 5 × 104 cells/well in a six-well
plate, and 24 h later, they were inoculated with
CAEV-pBSCA at multiplicities of infection of 0.1, 1.0, and 10. At day 2, inoculated cells were rinsed two or three times with fresh
medium and then were cultured for three more days. Culture medium from
each well was harvested daily, clarified by filtration through a
0.45-µm-pore-size membrane, and stored at 
70°C for virus assay on
permissive GSM cells. Inoculated cells were cocultured with 5 × 104 GSM indicator cells and observed for development of
CPE. The presence of CAEV genome sequences was also investigated by
direct PCR or reverse transcription-PCR (RT-PCR).
PCR and RT-PCR analysis.
PCR analysis was performed on cell
lysates by using Gag and actin primers as previously described
(34). To increase the sensitivity of DNA amplification, two
rounds of PCR were performed. After the second round of amplification,
a fragment of 512 bp was expected. We used the human 
-actin gene as
an internal control for the integrity of the DNA lysates. After the
second round of amplification using the actin primers, a fragment of
390 bp was expected as previously described (34).
Total cellular RNA was isolated from cell monolayers by using the acid
guanidium thiocyanate method (5). RNA was reverse transcribed using Moloney murine leukemia virus reverse transcriptase and random hexamer primers as reported previously (23). PCR analysis was performed using the Gag primers GEX5 and GEX3 previously described (34).
Transfection of pBSCA into TE671 and THP-1 cell lines.
TIGEF and TE671 cells were transfected using the calcium phosphate
method (12). The cells were seeded at 5 × 105 cells/25-cm2 flask and then, 24 h
later, were transfected with 5 µg of pBSCA plasmid DNA. The cell
monolayers were washed with phosphate-buffered saline 16 to 18 h
later to remove the precipitate, and the medium was replaced. Culture
medium of transfected cells was harvested at different times after
transfection, clarified by filtration through a 0.45-µm-pore-size
membrane, and stored at 70°C for infectious virus assay.
THP-1 (5 × 106) cells were seeded into
25-cm2 flasks and then 24 h later were transfected by
the DEAE-dextran method (36). pBSCA DNA (10 µg) was
adsorbed onto DEAE-dextran (500 mg/ml), added to the cells, and
incubated for 1 h at 37°C. The cells were then incubated for 2.5 min in Tris-buffered saline, rinsed with medium lacking FBS, and then
incubated in regular growth medium. Aliquots of transfected cells were
cultured in medium containing 20 ng of PMA/ml 24 h
posttransfection. Culture in the presence of PMA induced
differentiation of about 30% of the THP-1 cells in culture. Medium was
harvested from transfected cells every 24 h, clarified, and stored
at 70°C for infectious virus assay.
The pTR-UF5 plasmid was used to control the efficiency of transfection.
Expression of GFP was evaluated by FACScan analysis 72 h after transfection.
Radioimmunoprecipitation of virus-specific proteins.
Radioimmunoprecipitation of viral proteins was performed as previously
described (3). Briefly, cells were seeded into six-well plates at 48 h posttransfection. The culture monolayers were
preincubated for 2 h in MEM lacking methionine and cysteine, and
then the proteins were radiolabeled for 16 to 18 h with 100 µCi
of [35S]methionine-cysteine (Promix; Amersham, Orsay,
France) in 1 ml of the same medium. Virus-specific proteins released
into the supernatant or accumulated inside the cells were
immunoprecipitated using the hyperimmune serum (G9615) from a goat
which had received several injections of a mixture of three different
CAEV and MVV-K1514 isolates. Clarified cell culture medium and cell
lysates were incubated overnight at 4°C in the presence of 10 µl of
G9615 serum and Sepharose protein A. Immunoprecipitated proteins were
then separated by sodium dodecyl sulfate-polyacrylamide gel
electrophoresis and specific virus proteins were visualized by standard autoradiography.
| |
RESULTS |
Construction of a full-length infectious CAEV molecular clone.
The proviral genome of CAEV-CO was initially cloned in two
fragments (28), and despite several attempts in many
laboratories, there was no success in obtaining an infectious molecular
clone that contains the complete proviral sequence of CAEV. To ensure a
homogeneous virus source for infection and transfection of the different cell lines used in this study, we first constructed an
infectious full-length proviral molecular clone of the CO strain of
CAEV. The pK9Kb plasmid, which lacks about 400 bp of the 3' end of the
CAEV genome (38), was digested with SalI and
PflmI to release an 8.4-kb CAEV genome lacking the 3'
end of the env gene and the 3' LTR. This fragment was
inserted between the XhoI and PflmI sites
of the pBS second plasmid, which contains the missing 3'
end of CAEV (Fig. 1). The resulting
complete-genome construct (pBSCA) was stable in JM109 bacteria
cultured at a temperature of <30°C to limit recombination, and no
deletion in the viral genome was detected after repeated rounds of
amplification. After transfection of pBSCA into GSM cells
(23) or goat TIGEF cells (9), infectious
cytopathic virus (CAEV-pBSCA) was released into the culture
medium with titers in the range of 106 50% tissue culture
infective doses (TCID50s)/ml at days 6 and 7.
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FIG. 1.
Construction of pBSCA and pBSCA E5 molecular
clones. pK9Kb plasmid DNA was double digested with SalI and
PflmI to release an 8.4-kb fragment corresponding to the
complete CAEV-CO genome lacking the 3' end of the env
gene and 3' LTR. This fragment was gel purified and then inserted into
the pBS plasmid DNA doubly digested with XhoI and
PflmI. The isolated molecular clone corresponds to a
reconstituted complete infectious proviral CAEV-CO genome
(pBSCA). pBSCAE5 was derived from the pBSCA plasmid by
deletion of an 0.4-kb BamHI fragment in the envelope-coding
sequence.
|
|
Lack of sensitivity of human cells to CAEV-pBSCA
infection.
Human cell lines of epithelial (HeLa, A431, TE671) or
monocyte/macrophage (THP-1, U937) origin, primary monocytes/macrophages from a healthy volunteer, and synovial cells from a rheumatic patient
were inoculated with CAEV-pBSCA at a multiplicity of infection of 0.1, 1, and 10. Induction of CPEs in pure cultures and in cocultures with the indicator GSM cells was examined by microscopic observation. Search for viral proteins in the lysate and culture medium of inoculated cells was performed by radioimmunoprecipitation assay. PCR
and RT-PCR techniques with CAEV-specific primers were used for
detection of viral genomes. The results of all these examinations were
consistently negative for all primary and continuous human cells we
tested. In contrast, the TIGEF cell line used as a positive control
produced easily detectable virus, viral proteins, and viral genomes.
Lysates of 107 human cells readily supported amplification
of the 393-bp actin gene fragment used as an internal control, but the
512-bp gag-specific fragment of the CAEV-pBSCA virus
genome was never observed (data not shown).
Transfection of human cells with CAEV-pBSCA DNA.
The
human epithelial cell lines TE671 and 293 were transfected with 5 µg
of CAEV-pBSCA plasmid DNA for 5 × 105 cells
by using the calcium phosphate method (12), and the THP-1 human monocyte/macrophage line was transfected with 10 µg of
CAEV-pBSCA plasmid DNA for 107 cells by using the
DEAE-dextran method (36). Transfection controls using the
pTR-UF5 plasmid expressing the GFP gene under the control of the CMV
promoter were carried out in the same conditions. Sixty-two percent of
TE671 cells, 78% of 293 cells, and 61% of TIGEF cells expressed the
GFP protein as detected by cytofluorometry 72 h postinfection.
Transfection of THP-1 cell lines resulted in only 2% of the
GFP-expressing cells.
The CAEV-pBSCA-transfected cells developed no visible CPE, but
following coculture with the indicator GSM cells, typical giant multinucleated cells developed (not shown). Viral proteins were detected in the lysate and culture medium of transfected but not nontransfected cells after metabolic radiolabeling with
[35S]methionine-cysteine and immunoprecipitation with a
polyvalent hyperimmune antiserum (G9615) from a goat multiply infected
with three different isolates of CAEV and with the K-1514 strain of maedi-visna virus. The protein profiles shown in Fig.
2 indicate that the major Gag proteins
and Env glycoproteins were correctly translated and processed. The
supernatant medium contained the p25 Gag protein and the gp135 Env
glycoprotein, suggesting that viral particles were released from the
transfected cells. Culture medium collected from TE671 or THP-1 human
cells, or from TIGEF positive control cells at 72 h after
transfection with CAEV-pBSCA plasmid DNA, was shown to contain
titers ranging from 103 to 104
TCID50s of infectious cytopathic CAEV per ml when tested on
GSM cells. The THP-1 cells required the PMA treatment to induce their differentiation to macrophages with consequent viral expression, as
already observed for HIV-1 productive infection in these cells.
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FIG. 2.
Radioimmunoprecipitation of viral proteins from
pBSCA-transfected human and goat cells by using a polyvalent
hyperimmune serum. pBSCA plasmid DNA containing the complete
proviral CAEV-CO genome was introduced by transfection into the
human 293 epithelial (lanes 1 and 2) and the goat TIGEF fibroblastic
(lanes 3 and 4) cell lines. The major CAEV p25 Gag protein and gp135
Env glycoproteins were detected in the pBSCA-transfected cells
(lanes 2 and 4) but not in the nontransfected cells (lanes 1 and 3).
These proteins were present both in the cell lysate (C) and in the
supernatant (SN) of the pBSCA-transfected cells. The
high-molecular-weight protein marker bandings are shown on the left.
|
|
To study comparatively the profile of CAEV production in human and
caprine transfected cells, viruses in the culture medium were harvested
daily and titrated in permissive GSM cells. The titers obtained were
used to derive kinetic curves that are shown in Fig.
3. Whereas TIGEF cells showed a
continual titer increase, reaching 106
TCID50s/ml by day 10, the supernatants from both
transfected human cell lines reached maximum titers of 103
to 104 TCID50s/ml at day 4, then progressively
decreased to 10 TCID50s/ml at day 10 posttransfection. This
might indicate that the virus produced remained unable to infect human
cells, thereby limiting the spread of infection, while the
increase in TIGEF cells resulted from subsequent infections of these
permissive cells. We confirmed that supernatants from the
pBSCA-transfected human cells collected at day 4 (at the highest
titer point) were unable to infect all tested human cell lines, as
demonstrated by the absence of specific viral sequences in the treated
cell's nucleic acids by PCR. However, the supernatant was still
infectious and replication competent in goat cells.
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FIG. 3.
Comparative kinetics of production of CAEV-pBSCA
virus from human (TE671 and THP-1) and goat (TIGEF) cells. pBSCA
plasmid DNA containing CAEV-CO genome was introduced by
transfection into human (TE671 and THP-1) and goat (TIGEF) cell lines.
Culture medium of transfected cells was harvested on days 2, 4, 6, 8, and 10 posttransfection, clarified by filtration through a
0.45-µm-pore-size membrane, and titrated for infectious virus in GSM
cells as described in Materials and Methods.
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Infection of human cells with VSV-G-protein-pseudotyped
CAEV.
First, an Env-defective mutant of pBSCA was generated by
deleting a 400-bp fragment in the SU part of the env gene
also causing a shift of the reading frame for the residual part of the
gene (pBSCAE5; Fig. 1). Following transfection into GSM cells,
this construct produced Gag proteins but no infectious progeny. It could be rescued by cotransfection with plasmid DNA expressing the
complete env and rev sequences. Recombination
events between these two plasmids generated replication-competent
viruses (data not shown).
Cotransfection of pBSCAE5 and pHCMV-G, a plasmid coding for
the G glycoprotein of VSV (1), into TIGEF cells led to
production of pseudotyped particles which were collected on day 4 and used to inoculate TE671 and THP-1 human cell lines. Cellular
proteins were metabolically labeled with
[35S]methionine-cysteine at day 5 postinfection and
CAEV-specific proteins were immunoprecipitated with the hyperimmune
G9615 serum (Fig. 4A). Uninfected THP-1
cells or those infected with transfection product from the
nonpseudotyped pBSCAE5 produced viral proteins neither in their
cell lysate nor in their supernatant medium (samples 1 and 2). The
cells infected with the pseudotyped particles produced abundant viral
Gag proteins (sample 3). As only about 120 amino acids were deleted in
the envelope glycoproteins, the band observed near the position
expected for gp135 probably corresponds to the truncated nonfunctional
Env glycoprotein.
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FIG. 4.
Radioimmunoprecipitation of CAEV-specific proteins
from human cell lines. (A) Immunoprecipitation of CAEV proteins from
THP-1 human cell line either uninfected (lanes 1), infected with the
supernatant from pBSCAE5-transfected cells (lanes 2), or
infected with supernatant from pBSCAE5 and pHCMV-G
cotransfected cells (lanes 3). (B) Immunoprecipitation of CAEV proteins
from the TE671 human cell line either uninfected (lanes 1), infected
with supernatant from pBSCA-transfected cells (lanes 2), or
infected with supernatant from pBSCA and pHCMV-G cotransfected
cells (lanes 3). CAEV viral proteins were detected both in the cell
lysate (C) and in the supernatant (SN) of the human cell lines infected
with VSV-G pseudotyped particles (A3 and B3). The
high-molecular-weight protein marker bandings are shown on the left.
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The results of these experiments indicated that an envelope-defective
CAEV can be complemented with VSV-G protein envelope and thereby
enabled to enter human cells and to direct the expression of viral
proteins. However, they could not indicate whether these infected cells
are capable of producing infectious particles since they lack a
functional envelope. We therefore repeated the experiment using the
replication-competent pBSCA and pHCMV-G to cotransfect the
TIGEF cells. The produced pseudotyped virus was used to inoculate the
human 293 and TE671 cells. Cellular proteins were metabolically labeled
with [35S]methionine-cysteine, and CAEV-specific
proteins were immunoprecipitated from cell lysates and supernatants
from cells infected with the pseudotyped virus, but not from those
infected with CAEV-pBSCA alone (Fig. 4B). Both Gag proteins and
Env glycoproteins were detected, and the virus-bearing supernatant was
infectious for susceptible goat cells with titers of up to
106 TCID50s/ml, although this virus was still
incapable of infecting human cells (not shown).
| |
DISCUSSION |
The ability of small-ruminant lentiviruses to cause cross-species
infection in human cells is subject to some controversy. There are
reports on morphological and cytopathic changes in human astrocytes
that have been inoculated with maedi-visna virus (20, 21);
however, no observation of nucleic acid or viral protein expression in
these cells was reported. Other recent observations (L. S. Tiley,
personal communication) have reported the ability of maedi-visna virus
to penetrate and replicate in some human cell lines. CAEV, on the other
hand, has not been shown to replicate in human cells, and our present
study shows that CAEV-pBSCA does not naturally infect a range
of human cell lines or cells derived from primary human tissues. In
addition, similar results were obtained with a French field isolate
(CAEV-3112), suggesting that the restriction is not a property of
CAEV-pBSCA (data not shown). The difference between the two
viruses might reside in their use of different presently unknown
receptors and/or co-receptors. We show in the present study that the
restriction of CAEV replication in human cells depends only on its
inability to penetrate the cell. Human cells do not form syncytia when
cocultivated with CAEV-infected goat cells (data not shown).
Interestingly, however, both transfection with infectious proviral DNA
and infection with CAEV pseudotyped with VSV-G protein envelope
resulted in efficient viral production and, in the relevant
circumstances, production of fully infectious virus. The resulting
virus retained the phenotypic character and biological properties of
the parental CAEV, in that it was still incapable of infecting human cells.
The lack of replication of CAEV in human cells contrasts with the
situation when similar cells are infected or transfected with feline
immunodeficiency virus (FIV). This virus can readily enter human cells,
and the FIV provirus is integrated into their genome (16,
27), but no virus is released into the supernatant medium of
these cells. In this particular case, the major restriction in the
process is the lack of active transcription of the provirus from the
FIV LTR in human cells (22, 35). When the provirus is
modified to be under transcriptional control of CMV promoter, abundant
virus is produced and released in the culture medium of human cells
(27). However, a further restriction concerning the proper
functioning of FIV Rev in human cells has been described (37). The CAEV genome appears to be correctly expressed in
human cells, and the titers (on caprine cells) of virus produced are comparable to those obtained from permissive goat cells. Furthermore, despite a low transfection efficacy of pBSCA into the THP-1
monocyte/macrophage human cell line (around 2%), these transfected
cells produced much more infectious virus than the TE671
rhabdomyosarcoma cells in which 62% of the cells were transfected.
This demonstrates that the preference for CAEV replication in the
monocyte/macrophage cell lineage is still maintained in the human
cellular context.
Production of CAEV particles pseudotyped with a polytropic functional
envelope, which can target human cells, restores the ability of the
virus to complete a full life cycle. Human cells infected with the
pseudotyped virus maintained virus production for at least 25 days
postinfection, suggesting stable integration of the provirus into the
host chromosome. These data clearly suggest that CAEV might be
considered as potentially able to cross the species barrier to human
cells by a single acquisition of novel receptor specificity or by the
cooperation of a helper virus. We also cannot exclude the possibility
of infection of human cells following cell-to-cell contact with
infected goat cells as we recently described for small-ruminant cells
resistant to infection by ovine field isolates (34).
These findings also provide important information for the development
of nonprimate lentiviral vectors for gene transfer. Indeed, to prevent
these vectors from neutralization by human serum, CAEV-based
vectors should be produced in human cell lines as described with murine
leukemia virus-based vectors (7). The data here
presented bring clear evidence that human cells can be used to derive
packaging cell lines for production of CAEV-based vectors.
| |
ACKNOWLEDGMENTS |
This work was supported by grants from INRA and DGER. We thank
Pasteur-Merieux-Connaught and the Fondation Merieux for grant support
of the salary of L. Mselli-Lakhal.
We thank Timothy Greenland for helpful discussion and proofreading of
the manuscript. We thank J. Burns for kindly providing the
pHCMV-G plasmid.
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FOOTNOTES |
*
Corresponding author. Mailing address: INRA Laboratoire
Associé de Recherches sur les Lentivirus des Petits Ruminants,
Ecole Vétérinaire de Lyon, BP 83, 69280 Marcy l'Etoile,
France. Phone: (33)-4 78 87 25 68. Fax: (33)-4 78 87 25 94. E-mail:
cheblou{at}univ-lyon1.fr.
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Journal of Virology, September 2000, p. 8343-8348, Vol. 74, No. 18
0022-538X/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
