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Journal of Virology, October 2000, p. 9797-9801, Vol. 74, No. 20
Department of Biochemistry and Molecular
Biology, Oregon Health Sciences University, Portland, Oregon 97201-3098
Received 2 March 2000/Accepted 24 July 2000
Chinese hamster ovary (CHO) cells are resistant to infections by
gibbon ape leukemia virus (GALV) and amphotropic murine leukemia virus
(A-MLV) unless they are pretreated with tunicamycin, an inhibitor of
N-linked glycosylation. These viruses use the related sodium-phosphate
symporters Pit1 and Pit2, respectively, as receptors in nonhamster
cells, and evidence has suggested that the corresponding transporters
of CHO cells may be masked by tunicamycin-sensitive secreted
inhibitors. Although the E36 line of Chinese hamster cells was reported
to secrete the putative Pit2 inhibitor and to be sensitive to the
inhibitory CHO factors, E36 cells are highly susceptible to both GALV
and A-MLV in the absence of tunicamycin. Moreover, expression of E36
Pit2 in CHO cells conferred tunicamycin-independent susceptibilities to
both viruses. Based on the latter results, it was suggested that E36
Pit2 must functionally differ from the endogenous Pit2 of CHO cells. To
test these ideas, we analyzed the receptor properties of CHO Pit1 and
Pit2 in CHO cells. Surprisingly, and counterintuitively, transfection
of a CHO Pit2 expression vector into CHO cells conferred strong
susceptibility to both GALV and A-MLV, and similar overexpression of
CHO Pit1 conferred susceptibility to GALV. Thus, CHO Pit2 is a
promiscuous functional receptor for both viruses, and CHO Pit1 is a
functional receptor for GALV. Similarly, we found that the natural
resistance of Mus dunni tail fibroblasts to subgroup C
feline leukemia viruses (FeLV-C) was eliminated simply by
overexpression of the endogenous FeLV-C receptor homologue. These
results demonstrate a novel and simple method to unmask latent
retroviral receptor activities that occur in some cells. Specifically,
resistances to retroviruses that are caused by subthreshold levels of
receptor expression or by stoichiometrically limited masking or
interference mechanisms can be efficiently overcome simply by
overexpressing the endogenous receptors in the same cells.
In most cells, gibbon ape leukemia
virus (GALV) and amphotropic murine leukemia virus (A-MLV) use the
related Na+-dependent phosphate symporters Pit1 and Pit2,
respectively, as receptors for infection (10, 17, 20, 37).
Both Pit1 and Pit2 are multiple-membrane-spanning proteins with five
presumptive extracellular loops (ECLs). Pit1 and Pit2 cDNAs from a
variety of species, including human, mouse, rat, and hamster, have been isolated and extensively characterized (3, 8, 17, 20, 27, 34, 35,
37). While all Pit2 proteins that have been analyzed mediate
A-MLV infections, with some mediating GALV infections as well (34,
35), not all Pit1 proteins are able to mediate GALV infections.
For example, the resistance of mouse cells to GALV infection, with the
exception of that described for the Japanese feral mouse M. m.
molossinus (34), is attributed to the inability of
mouse Pit1 to function as a GALV receptor (9, 27). Chimera studies of mouse Pit1 and human Pit1 have identified a 9-amino-acid sequence (region A) of Pit1 ECL 4 as critical for GALV receptor function (9, 27). Similarly, the resistances of many other cells to particular retroviruses are caused by mutations at key sites
in the receptors (1, 36). In other cases, however, cellular
resistances to entry of retroviruses are caused by endogenously inherited interfering envelope glycoproteins (16;
reviewed in reference 32) or possibly by other
receptor blocking mechanisms (18, 19).
Chinese hamster ovary (CHO) cells are resistant to GALV and A-MLV
unless they are pretreated with tunicamycin, an inhibitor of N-linked
glycosylation (18, 19). Previous studies have suggested that
cells from Chinese hamsters secrete unidentified tunicamycin-sensitive inhibitors that specifically block GALV and
A-MLV infections in hamster cells but do not block these infections in
nonhamster cells (18, 19). CHO cells are also resistant to
ecotropic MLVs unless tunicamycin is present (19). However, a variant of Friend ecotropic MLV that causes neural degeneration can
infect untreated CHO cells (15). Tunicamycin is also
required for infections of Mus dunni fibroblasts with
Moloney ecotropic MLV (6) and for human immunodeficiency
virus type 2 infections of some primate cell lines (30).
Thus, a tunicamycin requirement for retroviral infections occurs with
different viruses and cell lines and can, as was reported in one case
(15), be overcome by viral envelope glycoprotein mutants.
Surprisingly, E36 cells, which were also derived from a Chinese
hamster, are susceptible to both GALV and A-MLV in the absence of
tunicamycin (5), despite secreting Pit2 inhibitors that inhibit A-MLV infection of CHO cells (18). Moreover,
expression of E36 Pit2 in CHO cells confers tunicamycin-independent
susceptibility to both of these viruses (35). Therefore, it
was inferred that E36 Pit2 is a promiscuous receptor for both GALV and
A-MLV and that it must differ from the endogenous CHO Pit2 in its
sequence and in its tunicamycin dependency. Subsequently, Chaudry et.
al. (3) isolated a cDNA encoding CHO Pit2 and confirmed that
the encoded protein differs substantially from E36 Pit2, consistent with the hypothesis that these differences might be responsible for the
natural resistance of CHO cells to GALV and A-MLV. These workers also
isolated a cDNA encoding CHO Pit1. Based on sequences in the critical
ECL 4 region A, they inferred that CHO Pit1 was unlikely to be active
as a GALV receptor and they suggested that GALV infection of CHO cells
was probably mediated solely by CHO Pit2 (3). In this paper
we report the independent isolation of cDNAs for CHO Pit1 and Pit2 and
the surprising observation that both of the encoded transporters are
active tunicamycin-independent receptors when they are overexpressed
within CHO cells. This implies that the endogenous receptors are latent
and can be unmasked simply by overexpressing them in the cells from
which they were derived. Evidence supporting the generality of this
insight was obtained using mouse fibroblasts, which are naturally
resistant to subgroup C feline leukemia viruses (FeLV-C).
Overexpression of the FeLV-C receptor (FLVCR) homologue isolated from
M. dunni tail fibroblasts (MDTF) resulted in strong
susceptibility of these cells to FeLV-C.
Isolation of CHO Pit1 and Pit2 cDNAs.
We first endeavored to
clone Pit2 cDNA from CHO cells. This proved to be difficult. Initially,
we used a CHO cell 5'-stretch lambda gt10 cDNA library (Stratagene, La
Jolla, Calif.) with a 32P-labeled nick-translated
hybridization probe derived from full-length rat Pit2 cDNA. The
hybridizations were performed in stringent conditions at 42°C in a
solution containing 50% formamide, 1% sodium dodecyl sulfate, 1 M
sodium chloride, and 10% dextran sulfate. Of 12 positive phages that
were plaque purified and sequenced, all contained Pit1 rather than Pit2
sequences. Eventually, we succeeded in isolating a Pit2 cDNA clone by
PCR using primers that were complementary to the rat Pit2 coding region
(upstream primer, 5'-ATGGCCATGGATGAGTATTTGTGG-3'; downstream
primer, 5'-TCACACATATGGAAGGATCCCATAC-3'). The CHO Pit2 cDNA
was cloned into the vector pcDNA3.1 (Invitrogen, Carlsbad, Calif.) and
sequenced at the Microbiology and Molecular Immunology Core Facility on
a PE/ABD 377 DNA sequencer using dye terminator cycle chemistry
(Perkin-Elmer Applied Biosystems, Foster City, Calif.). The predicted
CHO Pit2 protein is 98% identical to the previously reported E36 Pit2
(comparison not shown). Interestingly, our CHO Pit2 sequence has a
closer identity to E36 Pit2 than the CHO Pit2 protein reported by
Chaudry et al. (3) and differs from the previously reported
sequence by 7 amino acids. Despite these differences, the presumptive
ECLs of these CHO Pit2 proteins are identical.
0022-538X/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Cellular and Species Resistance to Murine Amphotropic, Gibbon
Ape, and Feline Subgroup C Leukemia Viruses Is Strongly Influenced by
Receptor Expression Levels and by Receptor Masking Mechanisms
ABSTRACT
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References
CHO Pit2 is an efficient tunicamycin-independent receptor for both
GALV and A-MLV.
We analyzed the receptor function of CHO Pit1 and
Pit2 proteins by expressing them in CHO cells. We first ligated CHO
Pit2 cDNA and several Pit1 cDNAs into the retroviral expression vector pSFF and used ping-pong amplification to produce ecotropic host-range virions that encoded these proteins (13). CERD9 cells
(31), derived from CHO cells and expressing the mouse
receptor for ecotropic MLVs, were subsequently transduced with these
virions. As shown in Fig. 1, the
transduced cells expressed much higher levels of phosphate transport
activity than the control CHO and CERD9 cells that contained only the
endogenous phosphate transporters. This implies that the transduced
Pit1 and Pit2 proteins were expressed at relatively high levels in
these cells. Figure 1 also shows the phosphate transport activity of
CHO cells expressing E36 Pit2 (CHO/EAR cells) (35), which
were generated by infection of CHO cells with an amphotropic pseudotype
virus carrying the E36 Pit2 gene. CHO/EAR cells were generously donated
by M. Eiden and C. Wilson (National Institute of Mental Health,
Bethesda, Md.).
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-galactosidase-encoding (lacZ) virions pseudotyped with
GALV and A-MLV envelope glycoproteins. As shown by the representative results in Table 1, our clone of CHO
cells is resistant to GALV and A-MLV but becomes highly susceptible to
GALV after pretreatment with tunicamycin. Similarly, tunicamycin caused
a weak but somewhat variable susceptibility to A-MLV in the control CHO
and CERD9 cells. As determined by multiple independent experiments
involving tunicamycin, the control CHO and CERD9 cells were not
significantly or reproducibly different in their susceptibilities to
these infections (results not shown). In agreement with a previous
report (14), CHO cells expressing rat Pit2 (CE/rPit2)
(17) were highly susceptible to A-MLVs independently of
tunicamycin, suggesting that rat Pit2 is a specific receptor for
A-MLVs. Surprisingly, CHO cells expressing CHO Pit2 (CE/cPit2) were
also highly susceptible to both GALV and A-MLV in the absence of
tunicamycin. Table 1 also shows data from another experiment in which
we compared infections of CHO/EAR and CHO/cPit2 cells. CHO/cPit2 cells
were generated by transfection of CHO cells with a CHO Pit2 cDNA
expression vector. The results show that these cells had very similar
properties and confirmed a previous report that CHO/EAR cells are
susceptible to both GALV and A-MLV in the absence of tunicamycin
(35). Thus, the Pit2 proteins encoded by E36 and CHO cells
behave identically when assayed in CHO cells.
|
Mouse receptor for FeLV-C mediates infections when overexpressed in
mouse cells.
To ascertain the potential generality of the above
results for different viruses and cells, we analyzed murine MDTF, which are naturally resistant to FeLV-C infections and become susceptible to
the Moloney strain of ecotropic MLV only after treatment with tunicamycin (6). Parental MDTF were tested for
susceptibility to lacZ(FeLV-C) and lacZ(RD114) pseudotype viruses
before treatment with tunicamycin and after treatment with 250ng of
tunicamycin per ml. lacZ(FeLV-C) pseudotype virus was generated, as
previously described (28), by transfection of TELCeB6
packaging cells with an FBsalf retroviral expression vector containing
the cDNA encoding FeLV-C(Sarma) envelope. lacZ(RD114)
pseudotype virus was produced by TELCeB6/RDF-7 helper-free
packaging cells (4). The titers of infection were as follows
(values are in CFU per milliliter and are averages from three infection
experiments): lacZ(FeLV-C) without tunicamycin, <2; lacZ(FeLV-C) with
tunicamycin, 2; lacZ(RD114) without tunicamycin, 2.9 × 103; and lacZ(RD114) with tunicamycin, 1.0 × 105. As shown by the data given above, pretreatment of MDTF
cells with tunicamycin enhanced infections by RD114 feline endogenous retrovirus approximately 30-fold but did not enhance infections by
FeLV-C. These viruses use distinct cell surface receptors (22, 24,
26, 28). To further investigate the MDTF resistance to FeLV-C, we
isolated a receptor homologue, MDTF FLVCR (mdFLVCR), from these cells
by PCR using primers that were complimentary to the coding region
of human FLVCR (hFLVCR) cDNA that was previously isolated by our group
(28). The mdFLVCR cDNA was subcloned into the
pCDNA3.1V5His-Topo vector (Invitrogen). As shown in Fig.
2, the mdFLVCR protein contains 560 amino
acids and is 77% identical to hFLVCR. Interestingly, expression of the
mdFLVCR cDNA in MDTF cells conferred strong susceptibility to FeLV-C as
shown by the following. MDTF were transiently transfected with the
hASCT2, mdFLVCR, or hFLVCR expression constructs and then tested for
susceptibility to lacZ(FeLV-C) pseudotype virus. ASCT2 (type 2 neutral
amino acid transporter [11]) is the common name for
the receptor for RD114 (24, 26). The standard nomenclature
for the ASCT2 gene is SLC1A5 (OMIM database, The National
Center for Biotechnology Information, National Institutes of Health).
The titers of infection were as follows (values are in CFU per
milliliter and are averages from three infection experiments): for
MDTF/hASCT2, 0; for MDTF/hFLVCR, 2.5 × 103; and for
MDTF/mdFLVCR, 1.5 × 103. Thus, mdFLVCR functions as
an efficient receptor for FeLV-C when overexpressed in MDTF cells.
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Major implications. These results demonstrate that the resistances of untreated CHO cells to GALV and A-MLV infections and of MDTF to FeLV-C infections are not caused by inherent defects in the endogenous receptors for these viruses. Indeed, although CHO cells are only slightly susceptible to A-MLV infections even after treatment with tunicamycin, overexpression of CHO Pit2 causes substantial tunicamycin-independent susceptibility to both A-MLV and GALV (Table 1). This result is compatible with previous evidence that untreated E36 cells are highly susceptible to GALV and A-MLV infections in the absence of tunicamycin (5), suggesting that E36 cells may express larger amounts of Pit1 and Pit2 than CHO cells or lower concentrations of a masking factor(s) (18). Thus, the E36 and CHO Pit2 proteins function similarly in CHO cells as tunicamycin-independent mediators of GALV and A-MLV infections (Table 1). Similarly, although MDTF are completely resistant to FeLV-C, overexpression of the endogenous mdFLVCR protein in these cells results in strong susceptibility to this infection (see above).
We believe that the simplest explanation for these results that is compatible with previous evidence (18, 19) is that the Pit1 and Pit2 receptors within CHO cells and the FLVCR within MDTF are present in relatively low (subthreshold) quantities and may be additionally inhibited by stoichiometrically limited amounts of masking factors. According to this hypothesis, overexpression of the endogenous receptors would be expected to result in susceptibilities to infections. Previous studies have implied that receptors can be masked by endogenously inherited retrovirus-related envelope glycoproteins by interference mechanisms (reviewed in reference 32) or by other glycoproteins (18) and that these masking glycoproteins can be inactivated by tunicamycin treatment of the cells (18, 19, 25, 30). It is known that processing and folding of retroviral envelope glycoproteins requires N-linked glycosylation (2), which is blocked by tunicamycin. This masking model is clearly consistent with the fact that treatment of CHO cells with tunicamycin induces their susceptibility to GALV and A-MLV infections. However, it is notable that tunicamycin does not induce susceptibility of MDTF to FeLV-C (see above). This result would be compatible with the idea that the putative mask that blocks the mdFLVCR in MDTF might be insensitive to tunicamycin or that both mdFLVCR and its mask might be tunicamycin sensitive. According to the latter explanation, the mask in MDTF might be a retrovirus-related envelope glycoprotein that misfolds in the absence of N-linked glycosylation, but this would not result in tunicamycin-dependent susceptibility to infection because the FLVCR would become inactive in these conditions. This explanation would be compatible with evidence that many but not all glycoproteins misfold in the presence of tunicamycin (2, 12, 23) and that FLVCR contains three consensus sites for N-linked glycosylation (Fig. 2). Although additional studies will be required to test these interpretations, we believe that our results strongly suggest that receptor masking may be more widespread than previously suspected. In addition, the example of mdFLVCR clearly implies that such apparent masking cannot always be reversed by tunicamycin (see above). Finally, our results demonstrate a novel and simple method that may be generally useful for identifying masked or subthreshold quantities of retroviral receptors. In these cases, overexpressing the endogenous receptors within the same cells will result in strong viral susceptibilities.Nucleotide sequence accession numbers. The GenBank accession number for the CHO Pit2 cDNA is AF239675 and that for mdFLVCR cDNA is AF239767.
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ACKNOWLEDGMENTS |
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We are grateful to Yasuhiro Takeuchi (Wohl Virion Center, University College London, London, United Kingdom) for providing lacZ(GALV) and lacZ(A-MLV) producer cells, TELCeB6 packaging cells, and the FBsalf retroviral expression vector containing the RD114 envelope gene. We are also grateful to Brian J. Willet (Department of Veterinary Pathology, University of Glasgow, Glasgow, United Kingdom) for providing the FBsalf vector containing the FeLV-C(Sarma) envelope cDNA and to Maribeth Eiden and Carolyn Wilson (National Institute of Mental Health, Bethesda, Md.) for providing the CHO/EAR cells. We are grateful to our coworkers Susan Kozak, Mariana Marin, and Emily Platt for encouragement and helpful suggestions.
This work was supported by NIH grants CA25810 and CA83835 and by The Wellcome Trust.
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FOOTNOTES |
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* Corresponding author. Mailing address: Department of Biochemistry and Molecular Biology, Oregon Health Sciences University, 3181 SW Sam Jackson Park Rd., Mail Code L224, Portland, OR 97201-3098. Phone: (503) 494-2548. Fax: (503) 494-8393. E-mail: tailorc{at}ohsu.edu.
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Journal of Virology, October 2000, p. 9797-9801, Vol. 74, No. 20
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Copyright © 2000, American Society for Microbiology. All rights reserved.
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Kubo, Y., Yokoyama, M., Yoshii, H., Mitani, C., Tominaga, C., Tanaka, Y., Sato, H., Yamamoto, N.
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