Previous Article | Next Article 
Journal of Virology, January 2000, p. 139-145, Vol. 74, No. 1
HIV and Retrovirology Branch, Division of
AIDS, STD, and TB Laboratory Research, National Center for Infectious
Diseases, Centers for Disease Control and Prevention, Atlanta, Georgia
30333,1 and The Division of
Infectious Diseases, St. George's Hospital Medical School, London,
United Kingdom2
Received 18 June 1999/Accepted 13 September 1999
Antigens derived from host cells are detectable in the envelope of
human immunodeficiency virus type 1 (HIV-1) and result in a distinctive
viral phenotype reflecting that of the host cell. An immunomagnetic
capture assay targeting discriminatory host proteins was developed to
differentiate between HIV-1 derived from macrophages and lymphocytes.
HIV-1 propagated in macrophages or lymphocytes in vitro was selectively
captured by monoclonal antibodies directed against the virally
incorporated cell-type-specific host markers CD36 (macrophages) and
CD26 (lymphocytes). Furthermore, by targeting these markers, virus of
defined cellular origin was selectively captured from a mixed pool of
in vitro-propagated viruses. This technique was further refined in
order to determine the impact of opportunistic infection on HIV-1
expression from these cellular compartments in vivo. Analysis of
cell-free virus purified from plasma of patients with HIV-1 infection
suggested that in those with an opportunistic infection, viral
replication occurred in activated lymphocytes. Interestingly, there was
also significant replication in activated macrophages in those patients with untreated pulmonary tuberculosis. Thus, in addition to
lymphocytes, the macrophage cellular pool may serve as an important
source of cell-free HIV-1 in patients with opportunistic infections
that lead to marked macrophage activation. This novel viral capture technique may allow researchers to address a wide range of important questions regarding virus-host dynamics.
Both viral and cellular proteins are
incorporated into the human immunodeficiency virus type 1 (HIV-1)
envelope during viral maturation and release from host cells (1,
7, 18). Numerous cellular proteins have been identified in the
HIV-1 envelope (reviewed in reference 30), including
human lymphocyte antigen (HLA) classes I and II (22), CD44
(18), complement control proteins CD55 and CD59
(16), and the adhesion molecules LFA-1 and ICAM (10, 18). Although a number of such host-derived proteins retain functionality when incorporated into the viral envelope, the
involvement of many of these host molecules in AIDS pathogenesis is not
entirely clear. For example, CD44 in the HIV-1 envelope maintains
hyaluronate-binding activity similar to that of the cell surface CD44
(10). Antibody neutralization of adhesion molecules in the
viral envelope blocks HIV-1 infection, suggesting that these molecules
may function as docking proteins for the virus (6). HLA
class II molecules are detectable within the envelope of HIV-1 purified
from patient plasma (23) and have been shown to function in
superantigen presentation and to enhance viral infectivity in vitro
(4, 22). Furthermore, the complement-regulatory proteins
CD55 and CD59, which are incorporated in the HIV-1 envelope, block the formation of membrane attack complexes, suggesting a mechanism to evade
complement-mediated lysis similar to that employed by normal human
cells (24, 25, 28).
Incorporation of host proteins into the HIV-1 envelope leads to the
acquisition of an antigenic phenotype that reflects that of the host
cell (2), and we have previously demonstrated that this
aspect of viral maturation is conserved among diverse HIV-1 subtypes
(21). While many studies have focused on functionality of
virion-associated host proteins, we previously suggested that cell-type-specific antigens might serve as markers of the cellular origin of HIV-1 replication (21). Indeed, HIV-1 derived in
vitro from T cells and dendritic cells has recently been shown to
incorporate discriminatory host antigens into the viral envelope
(8). In this study, we describe an immunomagnetic viral
capture assay that is able to distinguish between lymphocyte-derived
and macrophage-derived viruses propagated in vitro based upon the
detection of defined host antigens in the HIV-1 envelope. Furthermore,
we demonstrate that this technique can be applied to clinical samples,
yielding insights into the impact of opportunistic infection on HIV-1
replication in these cellular pools. Further refinement of this
technique may provide a novel approach for addressing many issues
related to virus-host dynamics and AIDS pathogenesis.
Generation of in vitro HIV-1 stocks.
Stocks of
macrophage-derived HIV-1Ba-L (HIV-1Ba-L-M Capture and detection of in vitro HIV-1 stocks.
Murine
antibodies to human cellular antigens were selected based on the
T-lymphocyte and monocyte cell surface density, as described by the
Leukocyte Differentiation Antigen Database, and were obtained from
commercial sources. Sheep anti-mouse immunoglobulin G magnetic beads
(Dynal, Inc., Great Neck, N.Y.) were first conjugated with the murine
anti-human antibodies (0.5 µg of antibody per 2 × 107 beads) by rotation at 4°C for 1.5 h. Conjugated
beads were washed twice with standard phosphate-buffered saline
containing 2% fetal bovine serum (PBS-2% FBS). Viral stocks were
added at a concentration of 5 × 106 virions per 0.5 µg of capture antibody in PBS-2% FBS and rotated at 4°C for
1.5 h to allow virus immunocapture. Nonspecific viral binding was
assessed by adding virus to unconjugated or anti-CD19-conjugated magnetic beads (negative control). After viral capture, magnetic beads
were washed five times with PBS. Bound virions were lysed with 0.5%
NP-40 in PBS for 30 min at 4°C, and the amount of captured virus was
determined by using an HIV-1 p24 antigen enzyme immunoassay (Coulter).
Plasma interference with HIV-1 capture from serum samples.
To identify serum components potentially inhibitory to the capture of
HIV-1 from clinical samples, HIV-1Ba-L-M
0022-538X/0/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Cellular Compartments of Human Immunodeficiency Virus Type 1 Replication In Vivo: Determination by Presence of Virion-Associated
Host Proteins and Impact of Opportunistic Infection
ABSTRACT
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
INTRODUCTION
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
MATERIALS AND METHODS
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
)
were prepared by propagation of virus in purified normal human
monocytes and were commercially obtained (Advanced Biotechnologies,
Inc., Columbia, Md.). CD4+ T lymphocytes, purified (>95%
pure) by affinity column exclusion (R&D Systems, Inc., Minneapolis,
Minn.), were phytohemagglutinin activated and infected with either a
syncytium-inducing field strain (f/s.8) or HIV-1Ba-L to
generate two lymphocyte-derived stocks (HIV-1f/s.8 and
HIV-1Ba-L-CD4, respectively). All HIV-1 stocks were further
purified by standard sucrose density gradient centrifugation
(32). Banded viral stocks were quantified by HIV-1 p24
antigen enzyme immunoassay (Coulter/Immunotech, Inc., Westbrook,
Maine), and virion counts were estimated based on 100 pg of p24 antigen
being equivalent to 106 virus particles (3).
(5 × 106 virions) was first incubated with 10 µl of either PBS
or various characterized patient sera at room temperature for 1 h
prior to capture. Sera tested in this way were from uninfected healthy subjects, HIV-seropositive patients with an undetectable HIV-1 RNA load
(to assess the effect of anti-HIV antibodies), and HIV-seronegative patients with acute hepatitis A (to assess the effect of acute-phase proteins). The relative extent of capture of HIV-1Ba-L-M
incubated in PBS or the different sera was subsequently determined by
using anti-CD36, anti-HLA-DR, and anti-CD44 antibodies.
that had been preincubated with defined
inhibitory sera.
Patients. With consent, plasma samples were obtained from patients attending the Komfo Anokye Teaching Hospital, Kumasi, Ghana. Patients with untreated pulmonary tuberculosis (TB) and HIV-1 coinfection (TB/HIV.1 to TB/HIV.3) had radiographic evidence of pulmonary consolidation and two sputum smears positive by conventional Ziehl-Neelsen microscopy. Plasma samples from patients with HIV-1 infection but no opportunistic infection (HIV.1 to HIV.4) and from one patient with a microbiologically undefined opportunistic infection (OI.HIV.4) were also obtained. HIV-1 infection in patients with positive HIV-1-HIV-2 serology was confirmed by using the Multispot assay (Sanofi Diagnostics Pasteur S.A., Marnes la Coquette, France). Plasma HIV-1 load was quantified by the Amplicor HIV-1 Monitor Test (Roche Diagnostic Systems, Inc., Branchburg, N.J.). Patients were divided into two groups according to the presence or absence of opportunistic infection, and the two groups of patients were matched for CD4+ lymphocyte count (all <200 × 106/liter) and for plasma HIV-1 RNA load (range, 2.9 × 105 to 2.7 × 106 versus 1.7 × 105 to 1.7 × 106 copies/ml). No patients had received antiretroviral drug treatment.
HIV-1 capture from clinical samples. The standard capture protocol described above was optimized for analysis of virus purified from clinical samples as follows. A standardized input of 2 × 104 to 5 × 104 virions per capture was incubated with each of the conjugated beads for 4 h in the presence of PBS-5% normal human serum (NHS), and anti-interleukin-6 (anti-IL-6)-conjugated beads were used as the negative control. Bound virus was lysed and, in view of the input of virus per capture, HIV-1 was quantified by using the Amplicor HIV-1 Monitor Test (Roche Diagnostic Systems, Inc.) rather than by p24 antigen enzyme-linked immunosorbent assay (ELISA).
Markers of immune activation and acute-phase response.
Total
tumor necrosis factor alpha (TNF-
), tumor necrosis factor receptor
type 1 (TNF-R1, 55 kDa), and IL-6 were measured in patient plasma
samples by using Quantikine ELISAs (R&D Systems). C-reactive protein,
an acute-phase protein, and soluble serum CD14 (sCD14) were measured by
enzyme immunoassays by using the Virgo CRP 150 Kit (Hemagen
Diagnostics, Inc., Waltham, Mass.) and the sCD14 EASIA kit (Medgenix,
Fleurus, Belgium), respectively.
| |
RESULTS |
|---|
|
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
|
|---|
Characterization of host molecules incorporated in the HIV-1
envelope in vitro.
We examined whether HIV-1 propagated in
different primary cell types in vitro could be distinguished based on
incorporation of host-cell-specific antigens. A panel of antibodies
against various cell surface CD antigens that might distinguish between macrophage-derived (HIV-1Ba-L-M) and lymphocyte-derived
(HIV-1f/s.8) viral stocks was examined (Fig.
1). Among antibodies to
macrophage-specific markers, only anti-CD36 captured
HIV-1Ba-L-M to an appreciable extent. Anti-CD14 also
captured HIV-1Ba-L-M above the background level, but to
a much lesser extent than anti-CD36. Antibodies to other antigens
expressed at a high level by macrophages (CD32, CD64, CD88, and CD89)
did not capture virus. Anti-CD3, anti-CD25, and anti-CD26
antibodies all selectively captured the T-cell-derived virus
stock, HIV-1f/s.8. Both
HIV-1Ba-L-M and HIV-1f/s.8 were captured by
anti-HLA-A/B/C-, anti-HLA-DR-, and anti-CD44-conjugated beads.
Further experiments with antibodies to CD44, CD36, and CD26 determined
the efficiency of capture of both lymphocyte- and macrophage-derived
stocks in vitro (Table 1).
|
). T-cell-derived HIV-1f/s.8
(
) was
captured selectively by use of anti-CD3, anti-CD25, and anti-CD26.
Antibodies to antigens common to both T lymphocytes and macrophages
(HLA-A/B/C, HLA-DR, and CD44) captured both viral stocks. Data are
representative of three independent experiments with <20% variability
in the magnitude of capture.
|
Change in HIV-1 envelope phenotype after acute infection of
CD4+ T cells with macrophage-derived
HIV-1Ba-L.
To confirm the ability of anti-CD26 and
anti-CD36 antibodies to distinguish the cellular origin of HIV-1
replication, we examined phenotypic changes of the viral envelope after
propagation of the same virus stock (HIV-1Ba-L) through
either CD4+ T-cell or macrophage cultures (Fig.
2A). Virus propagated in macrophages
(HIV-1Ba-L-M) was captured by anti-CD36. In contrast, the same virus expanded in T-cell cultures (HIV-1Ba-L-CD4)
acquired a switch in envelope phenotype, resulting from the
incorporation of CD26 and the absence of CD36 (Fig. 2A). Both
HIV-1Ba-L-M and HIV-1Ba-L-CD4
incorporated HLA-DR in the envelope and were captured to similar
extents (data not shown).
|
stocks were mixed in various ratios. Capture
of virus with either anti-CD26 or anti-CD36 antibody was proportional
to the input of HIV-1Ba-L-CD4 and
HIV-1Ba-L-M, respectively (Fig. 2B), indicating that
viral capture by these antibodies was selective for the host cell of origin.
Inhibition of capture by serum components.
Initial attempts at
HIV-1 capture from patient serum samples revealed substantial
inhibition of capture. To delineate components within the HIV-infected
serum that were responsible for this inhibition, in vitro-derived
HIV-1Ba-L-M was captured after preincubation in PBS,
NHS, or sera containing anti-HIV antibodies or acute-phase proteins. In
comparison to PBS, NHS had no inhibitory effect on capture of
HIV-1Ba-L-M (Fig. 3).
However, HIV antibody-positive serum with an undetectable virus load
(HIV+) and serum from the patient with acute hepatitis A infection
(HEP.A) both inhibited anti-CD36 capture by >80%. The magnitude of
this inhibition was similar with anti-HLA-DR and anti-CD44 antibodies
(data not shown).
|
purified from NHS yielded >65% of the capturable virus (Fig. 3). More importantly, the algorithm substantially restored the capture of virus spiked into
the defined HIV+ and HEP.A inhibitory sera.
Capture of HIV-1 from patient plasma reflects activation of specific cellular compartments by opportunistic infections. We proceeded to analyze samples from HIV-infected patients who did or did not have an opportunistic infection in order to define the contributions of macrophage and lymphocyte cellular pools to the plasma viral load. Surprisingly, antibodies to the cell-type-specific antigens (CD26, CD36, and CD14) did not significantly capture HIV-1 from those patients who did not have an opportunistic infection (Fig. 4A). In contrast, however, virus from all four individuals with opportunistic infections was captured by the anti-CD26 antibody. Furthermore, antibodies to both macrophage-specific antigens (CD36 and CD14) captured virus from the three patients with active TB. Subsequent attempts to capture virus from three patients (TB/HIV.1, OI/HIV.4, and HIV.1) by using antibodies to other cell-type-specific antigens (CD3, CD45Ro, CD25, CD32, CD64, CD88, and CD89) did not demonstrate significant virus capture above background levels (data not shown). Anti-CD44 was used as the positive control antibody since it captured both lymphocyte- and macrophage-derived HIV-1 in vitro stocks (Fig. 1). Correspondingly, anti-CD44 antibody also successfully captured HIV-1 purified from the plasma of all eight patients (Fig. 4A).
|
0.5 log10 was taken as
significant, and the data are representative of three independent
experiments. HIV-1 from all samples was captured by anti-CD44 antibody,
serving as a positive control. Virus from all four patients with an
opportunistic infection was captured by antibody to the
lymphocyte-specific marker (CD26), but only virus from those with TB
was captured by antibodies to macrophage-specific markers (CD36 and
CD14). Antibodies to CD26, CD14, and CD36 did not capture HIV-1 from
patients with no opportunistic infection. (B) Plasma levels of
acute-phase and immune activation markers expressed as a percentage of
the maximum level of each seen in any patient. The maximum levels of
TNF-
|
, TNF-R1, IL-6,
and sCD14 confirmed a heightened state of systemic immune activation in
patients with opportunistic infections. Of note, markedly elevated
levels of the macrophage-derived cytokines (TNF- and IL-6) were
detected in the plasma of the three patients with active TB (TB/HIV.1
to TB/HIV.3) and this correlated with elevated plasma levels
of sCD14, a soluble marker of macrophage activation. Correspondingly, HIV-1 was captured from plasma of the patients with TB by using antibodies directed against the macrophage-specific markers, i.e., CD14 and CD36.
| |
DISCUSSION |
|---|
|
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
|
|---|
Using an immunomagnetic capture technique, we demonstrated the ability to distinguish between macrophage-derived and lymphocyte-derived HIV-1, based upon the detection of cell-type-specific host antigens incorporated in the viral envelope. We also demonstrated that the envelope of macrophage-derived HIV-1 changes when the virus is propagated in T lymphocytes and acquires a new phenotype, reflecting that of the new host cell (Fig. 2A). Furthermore, we were able to selectively capture HIV-1 from a mixed pool of macrophage-derived and lymphocyte-derived viruses (Fig. 2B). These key observations enabled us to develop an assay to detect cell-free virus derived from macrophage and lymphocyte compartments in vivo. Results from the analysis of patient plasma samples suggest that the pattern of HIV-1 capture reflects the replication of virus in specific cellular pools that have been activated as part of the host response to opportunistic infection.
In developing an assay to distinguish HIV-1 derived from T lymphocytes
or macrophages based on viral envelope phenotype, we restricted our
choice of host protein targets to those that were specifically
expressed at a high level on one cell type or the other. Selective
exclusion of different host proteins from the HIV-1 envelope
(18, 25; reviewed in reference 5)
may account for the failure to capture in vitro-propagated
HIV-1Ba-L-M with antibodies to a number of
macrophage markers known to be highly expressed by host cells (Fig. 1).
Only anti-CD36 and, to a much lesser extent, anti-CD14 antibodies
captured macrophage-derived HIV-1 stocks propagated in vitro. Although
the significance to HIV-1 pathogenesis of the presence of many host
molecules within the viral envelope is still largely speculative, CD36
functions as an adhesive receptor for defined cellular components
(29) and potentially could serve an accessory docking role
for HIV-1 attachment.
Among the markers to identify T-cell-derived HIV-1, antibodies against CD25 and CD26 captured HIV-1 with approximately equal efficiency, and antibody to CD3 captured virus to a lesser extent (Fig. 1). Since CD25 expression is not strictly specific to lymphocytes (26) and is substantially downregulated during progression of HIV-1 infection in vivo (11), we examined CD26 as the distinguishing T-lymphocyte marker in this assay. In support of this choice, we previously demonstrated that CD26 is readily detected in the viral envelope of lymphocyte-derived viruses representing diverse HIV-1 subtypes (21). The use of CD26 and CD36 as selective markers in this assay was further validated by demonstrating that a switch in envelope phenotype occurred when macrophage-derived HIV-1 was propagated in lymphocytes and also by demonstrating selective capture of macrophage- and lymphocyte-derived viruses from a mixed pool (Fig. 2).
Examination of the inhibitory effects of various patient sera on HIV-1 capture suggested that a combination of anti-HIV antibodies and acute-phase proteins was potentially responsible for the suppression of capture of virus from clinical plasma samples (Fig. 3). Steric hindrance and masking of host antigens within the viral envelope via specific or nonspecific protein coating could cause this inhibition. Salt treatment during the virus purification algorithm was an important step in dissociating these inhibitory proteins from the virion surface and permitted analysis of clinical material. In part, the purification algorithm used in this study may account for the greater success of capture of HIV-1 from plasma samples than has previously been reported (23).
Application of the capture assay to HIV-1 purified from plasma of patients resulted in capture of HIV-1 from all eight samples (Fig. 4A). Substantial capture of virus with anti-CD44 antibody suggested that CD44 is incorporated at a high level in the HIV-1 envelope. CD44 is expressed on many cell types, including both lymphocytes and macrophages, and is involved in lymphocyte homing (27). Since this molecule is functional when incorporated into the HIV-1 envelope (10), we speculate that the acquisition of this molecule by HIV-1 might assist in virus trafficking to lymphoid tissue.
The failure of antibodies to CD36, CD14, and CD26 to capture HIV-1 from the plasma of the patients with no opportunistic infection was surprising and contrasted with the successful capture of virus from those who did have opportunistic infections (Fig. 4A). This difference was even more striking since the opportunistic infections were associated with a marked acute-phase response (as indicated by increased levels of CRP [Fig. 4B]), which would have tended to inhibit capture of virus from these patients. It is likely that a threshold density of each of the host antigens in the viral envelope is required to enable successful antibody capture of HIV-1. Viral envelope antigen density may affect both the ability to capture HIV-1 and the efficiency of capture with different antibodies (Table 1). It is therefore notable that CD36, CD14, and CD26 are all inducibly expressed (13, 14, 20), and cellular upregulation of these antigens in the presence of marked systemic immune activation associated with opportunistic infection (Fig. 4A) could have resulted in the acquisition of higher antigen densities in the HIV-1 envelope. Indeed, elevated plasma concentrations of plasma immune markers confirmed a heightened state of systemic immune activation in patients with opportunistic infections (Fig. 4B). Levels of cellular activation may also be responsible for the differences in capture between in vitro-derived HIV-1 stocks and virus purified from patients HIV.1 to HIV.4 (Fig. 1 and 4A).
Both macrophages and lymphocytes are highly activated in the host
response to TB. The successful capture of HIV-1 purified from the
plasma of patients with active TB by using antibodies to CD26, CD36,
and CD14 (Fig. 4A) is consistent with viral replication occurring in
activated macrophage and lymphocyte pools in these patients.
Interestingly, anti-CD14 antibody captured HIV-1 purified from patients
with TB (Fig. 4A) to a greater extent than macrophage-derived in vitro
HIV-1 stocks (Fig. 1). This difference possibly reflects the
pivotal role of CD14 in the host response to TB. CD14 serves as the
receptor for the mycobacterial cell wall antigen lipoarabinomannan (20, 33), and CD14 expression is upregulated in patients
with mycobacterial disease (12, 15). The finding that the
highest plasma concentrations of soluble CD14 were observed in the
patients with TB (Fig. 4B) suggests that CD14 was indeed more
highly upregulated in those patients. Furthermore, the greatly elevated
plasma concentrations of macrophage-derived cytokines (TNF- and
IL-6) in the patients with TB also provide additional evidence of
marked activation of macrophages.
Previous studies have speculated that <1% of cell-free HIV-1 is derived from macrophages and that the vast majority of virus is of lymphocytic origin (19). However, our data demonstrate that under certain circumstances of generalized immune activation (i.e., active TB) macrophages contribute significantly to the plasma HIV-1 pool. Approximately 10% of the virus from patient TB/HIV.1 was found to be macrophage derived (Table 2), and in view of the modest efficiency of viral capture (Table 1), it is conceivable that substantially more than 10% of the plasma HIV-1 in this patient was, in fact, derived from this cellular pool. Thus, macrophages may contribute significantly to the increase in HIV-1 plasma load reported to occur in patients who develop active TB (9). Our results corroborate a previous report that macrophages within lymph nodes coinfected with Mycobacterium avium and HIV-1 have high levels of cell-associated replicating virus (17) and further support the theory that macrophages serve as an important source of HIV replication in those with opportunistic infections (31).
As the HIV-1 capture technique is refined, we may be able to target antigens incorporated in the viral envelope at lower concentrations. With enhanced sensitivity, this technique may enable us to address important questions regarding virus-host dynamics and increase our understanding of HIV-1 disease progression, transmission, and pathogenesis. For example, determining the ratio of virus derived from these cellular origins during the early viremic state and how that ratio changes during progression to AIDS might provide new insight into the disease process. Furthermore, if appropriate selective markers were identified, virus from specialized tissues such as neural or thymic tissue could be studied.
| |
ACKNOWLEDGMENTS |
|---|
Stephen D. Lawn is funded by the Wellcome Trust, London, United Kingdom. The Committee on Human Research, Publications, and Ethics of the School of Medical Sciences, Kumasi, Ghana, approved the collection of field samples by S.D.L. within the Department of Medicine.
Paul Sandstrom is acknowledged for giving advice regarding the salt-dissociation step of the HIV-1 purification algorithm.
| |
FOOTNOTES |
|---|
* Corresponding author. Mailing address: HARB/DASTLR/NCID/CDC, 1600 Clifton Rd., NE, MS-G19, Atlanta, GA 30333. Phone: (404) 639-1033. Fax: (404) 639-1174. E-mail: stb3{at}cdc.gov.
| |
REFERENCES |
|---|
|
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
|
|---|
| 1. |
Arthur, L. O.,
J. W. Bess, Jr.,
R. C. Sowder,
R. E. Benveniste,
D. L. Mann,
J. C. Chermann, and L. E. Henderson.
1992.
Cellular proteins bound to immunodeficiency viruses: implication for pathogenesis and vaccines.
Science
258:1935-1938 |
| 2. | Bastiani, L., S. Laal, M. Kim, and S. Zolla-Pazner. 1997. Host cell-dependent alterations in envelope components of human immunodeficiency virus type 1 virions. J. Virol. 71:3444-3450[Abstract]. |
| 3. | Bourinbaiar, A. S. 1994. The ratio of defective HIV-1 particles to replication-competent infectious virions. Acta Virol. 38:59-61[Medline]. |
| 4. |
Cantin, R.,
J.-F. Fortin,
G. Lamontagne, and M. Tremblay.
1997.
The acquisition of host-derived major histocompatibility complex class II glycoproteins by human immunodeficiency virus type 1 accelerates the process of virus entry and infection in human T-lymphoid cells.
Blood
90:1091-1100 |
| 5. | Dierich, M. P., I. Frank, A. Stoiber, M. Clivio, M. Spruth, and H. W. Katinger. 1996. The envelope of HIV. Immunol. Lett. 54:205-206[CrossRef][Medline]. |
| 6. | Fortin, J. F., R. Cantin, G. Lamontagne, and M. Tremblay. 1997. Host-derived ICAM-1 glycoproteins incorporated on human immunodeficiency virus type 1 are biologically active and enhance viral infectivity. J. Virol. 71:3588-3596[Abstract]. |
| 7. | Frank, I., H. Stoiber, S. Godar, H. Stockinger, F. Steindl, H. W. Katinger, and M. P. Dierich. 1996. Acquisition of host cell-surface-derived molecules by HIV-1. AIDS 10:1611-1620[Medline]. |
| 8. |
Frank, I.,
L. Kacani,
H. Stoiber,
H. Stüssel,
M. Spruth,
F. Steindl,
N. Romani, and M. P. Dierich.
1999.
Human immunodeficiency virus type 1 derived from cocultures of immature dendritic cells with autologous T cells carries T-cell-specific molecules on its surface and is highly infectious.
J. Virol.
73:3449-3454 |
| 9. | Goletti, D., D. Weissman, R. W. Jackson, N. M. H. Graham, D. Vlahov, R. S. Klein, S. S. Munsiff, L. Ortona, R. Cauda, and A. S. Fauci. 1996. Effect of Mycobacterium tuberculosis on HIV replication. Role of immune activation. J. Immunol. 157:1271-1278[Abstract]. |
| 10. | Guo, M. M. L., and J. E. K. Hildreth. 1995. HIV acquires functional adhesion receptors from host cells. AIDS Res. Hum. Retroviruses 11:1007-1013[Medline]. |
| 11. | Hofmann, B., P. Nishanian, J. L. Fahey, I. Esmail, A. L. Jackson, R. Detels, and W. Cumberland. 1991. Serum increases and lymphoid cell surface losses of IL-2 receptor CD25 in HIV infection: distinctive parameters of HIV-induced change. Clin. Immunol. Immunopathol. 61:212-224[Medline]. |
| 12. |
Hoheisel, G.,
L. Zheng,
H. Teschler,
I. Striz, and U. Costabel.
1995.
Increased soluble CD14 levels in BAL fluid in pulmonary tuberculosis.
Chest
108:1614-1616 |
| 13. |
Huh, H. Y.,
S. F. Pearce,
L. M. Yesner,
J. L. Schindler, and R. L. Silverstein.
1996.
Regulated expression of CD36 during monocyte-to-macrophage differentiation: potential role of CD36 in foam cell formation.
Blood
87:2020-2028 |
| 14. | Kahne, T., H. Kroning, U. Thiel, A. J. Ulmer, H. D. Flad, and S. Ansorge. 1996. Alterations in structure and cellular localization of DPIV/CD26 during T cell activation. Cell. Immunol. 170:63-70[CrossRef][Medline]. |
| 15. |
Lien, E.,
P. Aukrust,
A. Sundan,
F. Muller,
S. S. Froland, and T. Espevik.
1998.
Elevated levels of serum-soluble CD14 in human immunodeficiency virus type 1 infection: correlation to disease progression and clinical events.
Blood
92:2084-2092 |
| 16. | Montefiori, D. C., R. J. Cornell, J. T. Zhou, V. M. Hirsch, and P. R. Johnson. 1994. Complement control proteins, CD46, CD55, and CD59, as common surface constituents of human and simian immunodeficiency viruses and possible targets for vaccine protection. Virology 205:82-92[CrossRef][Medline]. |
| 17. |
Orenstein, J. M.,
C. Fox, and S. M. Wahl.
1997.
Macrophages as a source of HIV during opportunistic infections.
Science
276:1857-1861 |
| 18. | Orentas, R. J., and J. E. Hildreth. 1993. Association of host cell surface adhesion receptors and other membrane proteins with HIV and SIV. AIDS Res. Hum. Retroviruses 9:1157-1165[Medline]. |
| 19. | Perelson, A. S., A. Neumann, M. Markowitz, J. M. Leonard, and D. D. Ho. 1996. HIV-1 dynamics in vivo: virion clearance rate, infected cell life-span, and viral generation time. Science 271:1582-1586[Abstract]. |
| 20. | Pugin, J., I. D. Heumann, A. Tomasz, V. V. Kravchenko, Y. Akamatsu, M. Nishijima, M. P. Glauser, P. S. Tobias, and R. J. Ulevitch. 1994. CD14 is a pattern recognition receptor. Immunity 1:509-516[CrossRef][Medline]. |
| 21. | Roberts, B. D., and S. T. Butera. 1999. Host protein incorporation is conserved among diverse HIV-1 subtypes. AIDS 13:425-427[CrossRef][Medline]. |
| 22. | Rossio, J. L., J. Bess, L. E. Henderson, P. Cresswell, and L. O. Arthur. 1995. HLA class II on HIV particles is functional in superantigen presentation to human T-cells: implications for HIV pathogenesis. AIDS Res. Hum. Retroviruses 11:1433-1439[Medline]. |
| 23. | Saarloos, M.-N., B. L. Sullivan, M. A. Czerniewski, K. D. Parameswar, and G. T. Spear. 1997. Detection of HLA-DR associated with monocytotropic, primary, and plasma isolates of human immunodeficiency virus type 1. J. Virol. 71:1640-1643[Abstract]. |
| 24. |
Saifuddin, M.,
C. J. Parker,
M. E. Peeples,
M. K. Gorny,
S. Zolla-Pazner,
M. Ghassemi,
I. A. Rooney,
J. P. Aikinson, and G. T. Spear.
1995.
Role of virion-associated glycosylphosphatidylinositol-linked proteins CD55 and CD59 in complement resistance of cell line-derived and primary isolates of HIV-1.
J. Exp. Med.
182:501-509 |
| 25. | Saifuddin, M., T. Hedayati, J. P. Atkinson, M. H. Holguin, C. T. Parker, and G. T. Spear. 1997. Human immunodeficiency virus type 1 incorporates both glycosylphosphatidylinositol-anchored CD55 and CD59 and integral membrane CD46 at levels that protect from complement-mediated destruction. J. Gen. Virol. 78:1907-1911[Abstract]. |
| 26. | Scheibenbogen, C., U. Keilholz, M. Richter, R. Andreesen, and W. Huntstein. 1992. The interleukin-2 receptor in human monocytes and macrophages: regulation of expression and release of the alpha and beta chains (p55 and p75). Res. Immunol. 143:33-37[CrossRef][Medline]. |
| 27. | Stemenkovic, I., A. Aruffo, M. Amiot, and B. Seed. 1989. A lymphocyte molecule implicated in lymph node homing is a member of the cartilage link protein family. Cell 56:1057-1062[CrossRef][Medline]. |
| 28. | Sullivan, B. L., E. J. Knopoff, M. Saifuddin, D. M. Takefman, M. N. Saarloos, B. E. Sha, and G. T. Spear. 1996. Susceptibility of HIV-1 plasma virus to complement-mediated lysis. Evidence for a role in clearance of virus in vivo. J. Immunol. 157:1791-1798[Abstract]. |
| 29. |
Tandon, N. N.,
U. Kralisz, and G. A. Jamieson.
1989.
Identification of glycoprotein IV (CD36) as a primary receptor of platelet-collagen adhesion.
J. Biol. Chem.
264:7576-7583 |
| 30. | Tremblay, M. J., J.-F. Fortin, and R. Cantin. 1993. The acquisition of host-encoded proteins by nascent HIV-1. Immunol. Today 19:346-351. |
| 31. | Wahl, S. M., T. Green-Wild, G. Peng, H. Hale-Donze, and J. M. Orenstein. 1999. Coinfection with opportunistic pathogens promotes human immunodeficiency virus type 1 infection in macrophages. J. Infect. Dis. 179:S457-S460. |
| 32. |
Wiley, R. L.,
D. H. Smith,
L. A. Lasky,
T. S. Theodore,
P. L. Earl,
B. Moss,
D. J. Capon, and M. A. Martin.
1988.
In vitro mutagenesis identifies a region within the envelope gene of the human immunodeficiency virus that is critical for infectivity.
J. Virol.
62:139-147 |
| 33. |
Yu, W.,
E. Soprana,
G. Cosetino,
M. Volta,
H. S. Lichenstein,
G. Viale, and D. Vercelli.
1998.
Soluble CD14 confers responsiveness to both lipoarabinomannan and lipopolysaccharide in a novel HL-60 cell bioassay.
J. Immunol.
161:4244-4251 |
Journal of Virology, January 2000, p. 139-145, Vol. 74, No. 1
0022-538X/0/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
This article has been cited by other articles:
-
Wahl, S. M., Greenwell-Wild, T., Vazquez, N.
(2006). HIV accomplices and adversaries in macrophage infection. J. Leukoc. Biol.
80: 973-983
[Abstract] [Full Text] -
Chertova, E., Chertov, O., Coren, L. V., Roser, J. D., Trubey, C. M., Bess, J. W. Jr., Sowder, R. C. II, Barsov, E., Hood, B. L., Fisher, R. J., Nagashima, K., Conrads, T. P., Veenstra, T. D., Lifson, J. D., Ott, D. E.
(2006). Proteomic and biochemical analysis of purified human immunodeficiency virus type 1 produced from infected monocyte-derived macrophages.. J. Virol.
80: 9039-9052
[Abstract] [Full Text] -
Kolegraff, K., Bostik, P., Ansari, A. A.
(2006). Characterization and role of lentivirus-associated host proteins.. Exp. Biol. Med.
231: 252-263
[Abstract] [Full Text] -
Israel-Biet, D, Esvant, H, Laval, A M, Cadranel, J
(2004). Impairment of {beta} chemokine and cytokine production in patients with HIV related Pneumocystis jerovici pneumonia. Thorax
59: 247-251
[Abstract] [Full Text] -
Nguyen, D. G., Booth, A., Gould, S. J., Hildreth, J. E. K.
(2003). Evidence That HIV Budding in Primary Macrophages Occurs through the Exosome Release Pathway. J. Biol. Chem.
278: 52347-52354
[Abstract] [Full Text] -
Goodenow, M. M., Rose, S. L., Tuttle, D. L., Sleasman, J. W.
(2003). HIV-1 fitness and macrophages. J. Leukoc. Biol.
74: 657-666
[Abstract] [Full Text] -
Greenwell-Wild, T., Vazquez, N., Sim, D., Schito, M., Chatterjee, D., Orenstein, J. M., Wahl, S. M.
(2002). Mycobacterium avium Infection and Modulation of Human Macrophage Gene Expression. J. Immunol.
169: 6286-6297
[Abstract] [Full Text] -
Cantin, R., Martin, G., Tremblay, M. J.
(2001). A novel virus capture assay reveals a differential acquisition of host HLA-DR by clinical isolates of human immunodeficiency virus type 1 expanded in primary human cells depending on the nature of producing cells and the donor source. J. Gen. Virol.
82: 2979-2987
[Abstract] [Full Text] -
Lawn, S. D., Butera, S. T., Folks, T. M.
(2001). Contribution of Immune Activation to the Pathogenesis and Transmission of Human Immunodeficiency Virus Type 1 Infection. Clin. Microbiol. Rev.
14: 753-777
[Abstract] [Full Text] -
Esser, M. T., Graham, D. R., Coren, L. V., Trubey, C. M., Bess, J. W. Jr., Arthur, L. O., Ott, D. E., Lifson, J. D.
(2001). Differential Incorporation of CD45, CD80 (B7-1), CD86 (B7-2), and Major Histocompatibility Complex Class I and II Molecules into Human Immunodeficiency Virus Type 1 Virions and Microvesicles: Implications for Viral Pathogenesis and Immune Regulation. J. Virol.
75: 6173-6182
[Abstract] [Full Text] -
Esser, M. T., Bess, J. W. Jr., Suryanarayana, K., Chertova, E., Marti, D., Carrington, M., Arthur, L. O., Lifson, J. D.
(2001). Partial Activation and Induction of Apoptosis in CD4+ and CD8+ T Lymphocytes by Conformationally Authentic Noninfectious Human Immunodeficiency Virus Type 1. J. Virol.
75: 1152-1164
[Abstract] [Full Text] -
Lawn, S. D., Butera, S. T.
(2000). Incorporation of HLA-DR into the Envelope of Human Immunodeficiency Virus Type 1 In Vivo: Correlation with Stage of Disease and Presence of Opportunistic Infection. J. Virol.
74: 10256-10259
[Abstract] [Full Text] -
Zaitseva, M., Lee, S., Lapham, C., Taffs, R., King, L., Romantseva, T., Manischewitz, J., Golding, H.
(2000). Interferon gamma and interleukin 6 modulate the susceptibility of macrophages to human immunodeficiency virus type 1 infection. Blood
96: 3109-3117
[Abstract] [Full Text] -
Cunningham, A. L., Li, S, Juarez, J, Lynch, G, Alali, M., Naif, H.
(2000). The level of HIV infection of macrophages is determined by interaction of viral and host cell genotypes. J. Leukoc. Biol.
68: 311-317
[Abstract] [Full Text]
| |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
Copyright © 2009 by the American Society for Microbiology. For an alternate route to Journals.ASM.org, visit: http://intl-journals.asm.org | More Info»