Received 26 February 2001/Returned for modification 23 April
2001/Accepted 24 May 2001
 |
INTRODUCTION |
In general, proteinase inhibitors
are inhibitory for a single class of proteinases, often resulting in
mutual inactivation. On the other hand, proteinases may inactivate many
classes of inhibitors without being inactivated themselves and, in
the process, may produce bioactive fragments, e.g., complement
fragments. The proteinase inhibitor in serum exhibiting the
greatest concentration is 
1PI, and the proteinase
inhibitor encompassing the broadest spectrum is 2
macroglobulin (2M). Multiple molecular conformations of
active and inactive 1PI are known to exist and to be
receptor recognized. For example, active 1PI has been
found to react with surface-associated human leukocyte elastase
(HLE), and inactive 1PI has been found to react with the
well-characterized scavenger receptor,
2M receptor-low-density-lipoprotein receptor-related protein (2MR-LRP)
(2, 21). The highly conserved 2M uniquely
inhibits all four classes of proteinases and exhibits a
receptor-recognized conformation involved in signaling as well as an
2MR-LRP-recognized conformation (17). A
significant body of evidence suggests that receptor recognition of the
multiple forms of circulating proteinase inhibitors results in
activation of discrete cellular subsets of the mononuclear phagocyte
system (27).
Whereas 1PI covalently inhibits the catalytic site of
HLE, it has been shown that in certain situations the association of HLE with 2M in plasma is favored (6). When
proteinases are complexed with 2M, proteolysis of
low-molecular-weight peptides and cytokines can persist. The balance
between available HLE activity, the inhibitor 1PI, and
the substrate-restricting 2M represents a tightly
regulated mechanism for discrete targeting of proteolytic activity in
tissues. It has been shown that inter--trypsin inhibitor (II)
uniquely acts as a shuttle by transferring HLE to 1PI or 2M (25). It is the active site of II
which is identical with the principle HIV-neutralizing determinant in
the V3 loop, and it is this region of the V3 loop which has been shown
to reversibly inhibit proteinases (1). This suggests the
possibility that HIV envelope proteins themselves may disrupt the
homeostasis between proteinases and proteinase inhibitors.
The importance of maintaining a balance in proteinase inhibitor ratios
was dramatically demonstrated more than two decades ago. Ohlsson and
Laurell injected two volunteers intravenously with 1PI
or 2M less than half saturated with radiolabeled HLE or
trypsin (20). Rapid clearance of 2M
complexes and 1PI complexes was shown to be mediated by
the mononuclear phagocyte system and to be accompanied by transient
circulatory changes in some circumstances. Intravenous injection in
dogs resulted in shock and death whenever the concentration of active
proteinase exceeded that of 2M, even though circulating
1PI was less than half saturated with proteinase (19). The concept that HLE and 1PI might
impact HIV infectivity originated following the observations that gp120
exhibits a proteinase-inhibiting domain (1) and that CD4,
the T-lymphocyte antigen receptor, elastase, and 1PI are
functionally associated during antigen-specific lymphocyte activation
(8). Evidence that 1PI and cell surface HLE
participate during HIV infectivity (7) (C. L. Bristow, unpublished data) suggested the hypothesis that
1PI or 2M concentrations might be altered
during HIV disease.
| |
MATERIALS AND METHODS |
Serum specimens.
Sera from healthy volunteers were collected
after obtaining informed consent. Sera from HIV-infected patients were
excess specimens reserved from previous studies for which informed
consent had been obtained. HIV RNA in serum was quantitated by PCR
using the Amplicor HIV-1 Monitor Test (Roche Diagnostics, Branchburg, N.J.) by the Retrovirology Core Laboratory, University of North Carolina (UNC)
Chapel Hill, using procedures recommended by the manufacturer. Clinical category of disease progression at the time of
specimen collection was determined using 1993 Centers for Disease
Control and Prevention classification criteria. The clinical parameters
examined included HIV RNA, lymphocyte markers, demographic
characteristics, known infectious diseases, and antiretroviral therapy.
In this study, 44% category A1,A2, 57% category B1,B2, and 58% AIDS
patients had or were receiving azidothymidine therapy, and none were
receiving HIV-specific protease inhibitors. Characteristics not
presented herein were found not to contribute significantly to the
analysis. All measurements, chart extraction, and data analysis were
performed in a blinded fashion. Data were excluded from analysis if the
sera had not been maintained at 
80°C prior to analysis, the patient
charts could not be located, or the patient charts indicated no
evidence of HIV infection.
Quantitation of 2M and 1PI and
T-cell markers.
Methods for quantitating active 2M
and 1PI by determination of elastase inhibitory capacity
have been described elsewhere (6). Total
1PI was determined by enzyme-linked immunosorbent assay
(ELISA). Inactive 1PI was expressed as the difference
between total 1PI and active 1PI.
Measurements of CD4+, CD8+, and
CD3+ levels were performed by the Flow Cytometry
Laboratory, UNC Hospitals. Normal values were determined from 100 healthy donors (Janet Mantell and Cindy Evoy, unpublished results).
Data were not normally distributed, and all comparisons were made using
nonparametric methods. Medians among clinical categories were compared
by using Kruskal-Wallis one-way analysis of variance on ranks.
Comparison of medians between pairs of clinical categories was done by
using the Mann-Whitney rank sum test. Correlation was measured using
the Pearson product moment correlation.
Detection of anti-1PI immune complexes.
Detection of anti-1PI immune complexes was performed by
modification of the 1PI-specific ELISA (6).
Sera were heat inactivated for 30 min at 56°C.
Anti-1PI immune complexes were captured by diluting an
aliquot in 0.05 M Tris(hydroxymethyl)aminomethane-0.15 M NaCl (pH 7.8)
in wells of a microtiter plate precoated with the immunoglobulin
fraction of chicken anti-human 1PI (lot 18823680; O.E.M.
Concepts, Toms River, N.J.), followed by incubation for 120 min at
37°C. In parallel, to detect anti-1PI in serum by first dissociating the anti-1PI immune complexes, the
sera were acidified by diluting an equivalent aliquot in 0.05 M
glycine-HCl (pH 3.0). After incubation for 60 min at 37°C, acidified
sera were adjusted to pH 7.8, and complexes were allowed to reassociate for an additional 60 min at 37°C. Binding was detected by using horseradish peroxidase (HRP)-complexed rabbit anti-human immunoglobulin G (IgG; lot 091H4808; Sigma).
Anti-gp120 ELISA.
Immunorecognition of 1PI by
anti-gp120 was determined by ELISA (6). Wells of a
microtiter plate (Nunc) were precoated with various concentrations of
1PI (A6150; Sigma) or soluble CD4 (Biogen, Cambridge,
Mass.). Microtiter plates were incubated for 60 min at 20°C with
monoclonal anti-gp120 (1C1, lot 704-111; Repligen, Cambridge, Mass.) in
the presence or absence of 1 µg of competing recombinant gp120 (lot
1008-25; Repligen) per ml. Binding was detected with HRP-conjugated
protein A (Zymed, South San Francisco, Calif.). Immunorecognition of
1PI by HRP-conjugated monoclonal anti-gp120 (approximate
epitope V3 loop, 10 µg/ml; Research Diagnostics, Flanders, N.J.) was
performed for comparison.
Statistical analysis.
Normality was determined using the
Kolmogorov-Smirnov test. Values for CD4, CD8, 1PI, and
2M were not normally distributed, and all comparisons
were made using nonparametric methods. Medians among clinical
categories were compared by using Kruskal-Wallis one-way analysis of
variance on ranks. Comparison of medians between pairs of clinical
categories was done by using the Mann-Whitney rank sum test. Values for
anti-1PI and HIV-1 RNA were normally distributed, and
all comparisons were made by using one-way analysis of variance.
Comparison of means between pairs of clinical categories was done by
t test. Correlation was measured using Pearson product moment correlation, and linear regression was measured by computer-fit least-squares analysis.
| |
RESULTS |
1PI levels in clinical category of HIV disease.
The 1PI and 2M levels were quantitated in
the sera from 68 HIV-seropositive patients and 30 seronegative
volunteers (Table 1). None were being
treated with HIV-specific proteinase inhibitors at the time of blood
collection. In the normal subjects studied here, the mean value for
total 1PI was 36.0 ± 13.9 µM and ranged from 18 to 53 µM between the 5th and 95th percentiles (Fig.
1). The mean 2M
concentration in the present study was 3.36 ± 1.82 µM and
ranged from 1.26 to 5.57 µM between the 5th and 95th percentiles. Values for 1PI and 2M determined here are
consistent with previous studies (5, 12).
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FIG. 1.
1PI and 2M concentrations
in serum by clinical category of HIV disease. (A) Values were not
normally distributed. Category medians are represented by bars and are
statistically compared in Table 1. (B) HIV RNA was found to be
correlated with total 1PI in asymptomatic patients
(P < 0.04) but not in other clinical categories. HIV
RNA was not related to CD4 levels in any clinical category. (C) There
was no relationship between 2M and 1PI
concentrations in asymptomatic and symptomatic pre-AIDS patients;
however, in AIDS patients, 2M was correlated with both
active 1PI (r2 = 0.73, P < 6 × 10 6) and inactive
1PI (r2 = 0.45, P < 0.04). (D) Schematic representation of CD4
(.....), HIV RNA
(), active 1PI (----),
and total 1PI (----)
concentrations in this patient population.
|
|
The total concentration of 1PI in an individual serum
sample represents a unique mixture of active and inactive
1PI. In health, the active concentration has been found
to represent 90 to 100% of total 1PI concentration
(6). In the normal subjects studied here, the mean value
for active 1PI was 33.8 ± 12.5 µM and ranged
from 18 to 48 µM between the 5th and 95th percentiles. The mean value
for inactive 1PI was 2.3 ± 7.2 µM and ranged
from 0 to 11 µM between the 5th and 95th percentiles. Consistent with previous studies, population values were found not to be normally distributed, necessitating statistical comparisons using medians (5). Comparison of normally healthy subjects,
asymptomatic (clinical categories A1 and A2), symptomatic pre-AIDS
(clinical categories B1 and B2), and AIDS (clinical categories A3, B3,
and C1 to C3) categories of HIV disease revealed significant
differences in the concentrations of total (P < 3 × 107), active (P < 2 × 105), and inactive 1PI (P < 3 × 108) in serum but not of
2M (P < 0.3) (Fig. 1).
During the acute phase of inflammation, total 1PI can
increase as much as fourfold. As would be expected, total
1PI was significantly elevated in 100% of symptomatic
pre-AIDS patients but was not different from the normal level in the
asymptomatic HIV population. Values were considered elevated if they
exceeded the 95th percentile and deficient if they fell below the 5th
percentile of the normal range. Total 1PI was elevated
in 33% and deficient in 11% asymptomatic patients. Surprisingly,
total 1PI in AIDS was not significantly different from
normal. In this group, 42% were elevated and 22% were deficient.
Review of the spectrum of infections documented at the time of blood
collection revealed no significant trends (data not shown).
Unexpectedly, the concentration of active 1PI was found
to be deficient in 100% of asymptomatic, 44% of symptomatic pre-AIDS, and 56% of AIDS patients (Fig. 1). At concentrations of active 1PI of >20 µM, the odds were 11:1 that
CD4+ cell counts were <300 cells/µl (P = 0.01) in the HIV-seropositive population. As would be expected,
active 1PI was elevated in 29% of symptomatic pre-AIDS
patients and in 11% of AIDS patients.
In the asymptomatic category of disease, increased HIV RNA was found to
be correlated with increased total 1PI (P < 0.04) but not correlated with CD4+ levels. Further,
HIV RNA was neither correlated with CD4+ levels nor total
1PI in symptomatic and AIDS patients. Increased HIV RNA
was found to be correlated with decreased CD4+ levels when
all clinical categories were included in the analysis (P < 0.00005). These results support previous findings that decreased 1PI is associated with decreased HIV production.
Comparison of the sensitivities and specificities of
1PI, CD4, and HIV RNA measurements in determining the
clinical category of HIV disease in the patient population represented
here suggests that measuring 1PI could potentially
provide a significant improvement in defining clinical course (Table
2).
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TABLE 2.
Sensitivities and specificities of 1PI,
CD4, and HIV RNA as prognostic indicators for transition
between clinical categories in HIV diseasea
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|
Inactive 1PI was found to be elevated in 78% of
asymptomatic, in 86% of symptomatic pre-AIDS, and in 64% of AIDS
patients. The etiologic mechanisms of 1PI inactivation
might involve proteolytic inactivation, oxygenation, diminished
synthesis, and autoimmune reactivity. A state of dysregulated
proteolysis has been shown to exist in HIV disease (23),
and this results in generalized diminution in circulating competent
proteinase inhibitors.
Like 1PI, 2M can be inactivated by
proteinase interaction, as well as by oxygenation. In support of
uncontrolled proteolysis, among symptomatic pre-AIDS patients 40% were
elevated and 30% were deficient in active 2M
concentration. However, 80% of asymptomatic patients and 76% of AIDS
patients were within the normal limits for 2M, and this
reflects a disposition of controlled proteinase activity in these
clinical categories. The 2M concentrations in HIV
disease, including all clinical categories, were not significantly different from normal, and this suggests that deficient levels of
1PI could not be completely explained by dysregulated
proteolysis nor oxygenation. Significantly, in AIDS, but not in other
clinical categories of disease, 2M levels were
correlated with active 1PI (P < 6 × 106) and with inactive 1PI
(P < 0.04), suggesting that mechanisms other than
dysregulated proteolysis were involved in producing increased levels of
inactive 1PI in the asymptomatic category. Further, the
recovery in the circulating active 1PI concentration during the symptomatic stages of disease suggested that the synthesis of 1PI may not be impaired and that alternative
processes could be responsible for acquired deficiency. A previous
study has demonstrated no difference in 1PI synthesis
during AIDS in contrast to an increased synthesis of the acute-phase
C-reactive protein (11).
Anti-1PI in HIV disease.
Since autoantibodies
recognizing multiple cytokines and cellular proteins are known to occur
in HIV disease (14), the potential for an autoimmune
process in producing decreased active 1PI was examined.
Antibodies recognizing immobilized 1PI were not
discernible in serum from this patient population by traditional ELISA
(data not shown). However, it was found that
1PI-anti-1PI immune complexes were
detectable by capturing them with immobilized anti-1PI
and detecting them with anti-human IgG. Control sera from 17 normal subjects and 1 subject with inherited 1PI
deficiency were found to have background values of 11.2 ± 8.4 milliabsorbance at 405 nm (mA405)/min and to
range between 0.9 and 26.0. In contrast, 56% of asymptomatic, 57% of
symptomatic pre-AIDS, and 31% of AIDS patients exceeded the mean
control value by 2 standard deviations (Table
3). The high concentration of
1PI in serum suggested that the appearance of
anti-1PI would rapidly produce immune complexes,
precluding detection by this method. It was further considered that
immune complex formation might obscure 1PI epitopes, preventing capture using anti-1PI and resulting in
underestimation. We have previously shown in insulin-dependent diabetes
mellitus that insulin-anti-insulin immune complexes are
obscured in this manner (28). We determined that
acidification of serum allows dissociation of immune complexes and that
neutralization of acidified serum in the presence of competing
radiolabeled ligand allows the detection of insulin-anti-insulin
immune complexes. Using a modification of this approach, acidification
and neutralization of sera in the presence of immobilized competing
anti-1PI allowed detection of
1PI-anti-1PI immune complexes in an
additional 33% of asymptomatic patients, an additional 7% of
symptomatic pre-AIDS, and an additional 14% of AIDS patients.
Background values (mA405 per minute) in normal
control sera were not influenced by acidification and neutralization.
Overall, 89% of asymptomatic, 64% of symptomatic pre-AIDS, and 44%
of AIDS patients had detectable anti-1PI IgG, and this
decline in anti-1PI IgG is consistent with the decline
in specific antibody response during AIDS. An increased
anti-1PI level was correlated with decreased active 1PI in the asymptomatic category of HIV disease
(P < 0.05). Increased anti-1PI was
correlated with increased inactive 1PI in symptomatic (P < 0.03) and AIDS patients (P < 0.03), and this suggests that 1PI autoimmune
antibodies are responsible in part for acquired 1PI
deficiency. In patients with detectable anti-1PI IgG
immune complexes, the odds were 3.6:1 that active 1PI
would be deficient (P < 0.01). Further, in AIDS
patients, the mean reactivity (mA405 per minute)
was significantly lower than in the other clinical categories
(P < 0.002, Fig. 2), and
this result is consistent with the decline in detectable
anti-1PI. The correlation between 2M and
active and inactive 1PI in AIDS suggests that
infection-related dysregulated proteolysis also contributes to the
deficiency in 1PI detected.
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FIG. 2.
Autoantibodies reactive with 1PI in HIV
disease. (A) Autoantibodies reactive with 1PI were
detected by ELISA. Bars represent mA405 per
minute and are statistically compared in Table 3. The mean reactivity
was significantly lower in AIDS patients than in asymptomatic
(P < 0.0005) or symptomatic pre-AIDS (P < 0.02) patients. (B) A monoclonal antibody with specificity for
gp120 epitopes near the fusion domain also recognized
1PI ( ) but not CD4 ( ). Binding of anti-gp120 to
1PI was inhibited in the presence of 8 µM competing
gp120 ( ). A monoclonal antibody with specificity for gp120 epitopes
near the V3 loop failed to recognize 1PI ( ). (C)
Alignment of amino acid sequences for human 1PI and the
epitope recognized by anti-HIV gp120 near the fusion domain revealed
significant homology. Boxed residues are identical or conservatively
substituted. The immunizing peptide for monoclonal anti-gp120 antibody
is underlined. The hydrophobic 1PI pentapeptide is
depicted in boldface. The proteinase reactive site of
1PI is Met-358. HIV gp120 and gp41 are produced by
cleavage near Lys-517 and Arg-518 to reveal the fusion domain.
|
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Significantly, as is true for viral RNA, the actual
mA405 per minute values for circulating
anti-1PI IgG immune complexes, including all clinical
categories, were correlated with CD4+ cell counts
(P < 0.003) and CD8+ cell counts
(P < 0.03). The frequency of patients in each clinical category having circulating anti-1PI IgG immune
complexes was inversely related to CD4+ cell counts
(r2 = 0.999, P < 0.01) but
not with CD8+ cell counts (P < 0.2; data
not shown). These data suggest that in symptomatic pre-AIDS and AIDS,
lymphocyte population abnormalities may be responsible in part for the
decline in 1PI autoimmune antibodies.
Evidence that the V3 loop of gp120 contains a domain identical to the
active site of II and inhibits proteolytic activity in certain
circumstances (1) suggested that gp120 and
1PI might share antigenic epitopes. To determine the
potential for antigenic mimicry, immunoreactivity for
1PI by antibodies specific for gp120 was examined by
ELISA. Significant binding to 1PI was detected by
antibodies recognizing epitopes near the fusion domain but not epitopes
near the V3 loop. Binding of anti-gp120 to 1PI was
competitively inhibited by gp120, suggesting that molecular mimicry may
explain this epitope specificity. Comparative alignment of the carboxyl
terminus amino acid sequence of 1PI and the HIV peptide
sequence recognized by the immunoreactive monoclonal antibody revealed considerable homology. Significantly, these sequences are flanked by the hydrophobic chemotactic pentapeptide domain of
1PI (FXFXX, where X = V, L, I, or M) and the
hydrophobic the HIV fusion domain (FLGFL). This result suggests that in
the HIV-seropositive patient population, antibodies with specificity
for gp120 might also recognize 1PI potentially
diminishing the active 1PI concentration.
| |
DISCUSSION |
We unexpectedly found in this study that active 1PI
was deficient in all asymptomatic patients. On the other hand, total 1PI was elevated in all symptomatic pre-AIDS
HIV-positive patients. The strong association between
1PI and disease progression suggested 1PI
might be central to the pathophysiology of HIV disease. Combined with
CD4+ levels, determining the viral load (plasma viral RNA)
is integral to the recommended guidelines for the clinical management
of HIV disease. Discordant values for plasma viral RNA and
CD4+ cell counts occur in approximately 14% of patients
receiving antiretroviral therapy, and this complicates therapeutic
decisions. The prognostic value of 1PI concentration for
determining clinical category of HIV disease was equivalent to that of
CD4, and this finding supports recent evidence that this self antigen
acts as an entry cofactor.
More than 75 codominant alleles of human 1PI have been
identified that are correlated in mucosal secretions and serum
(16). In 1,084 plasma samples representing six species of
monkeys (Macaca irus, M. mulatta, M. cyclopis, M. nemestrina,
M. speciosa, and M. fuscata), five
codominant alleles have been identified (3). These genetic
differences might serve as a key to understanding the different
pathologic outcomes of HIV infection in humans and chimpanzees. Neither
antibodies to 1PI nor deficiency in 1PI were detected in macaques infected with simian/human immunodeficiency virus (SHIV) (data not shown), suggesting that different
pathophysiologic outcomes result during HIV disease in humans and SHIV
disease in macaques.
The primary source of circulating 1PI is thought
to be the liver. Synthesis and secretion of 1PI by
lymphocytes, mononuclear phagocytes, cornea, and intestinal Paneth
cells in response to interleukin-6, transforming growth factor
, granulocyte-macrophage colony-stimulating factor, HLE, and
lipopolysaccharide from gram-negative bacteria is under the regulation
of NF-
B (22). Convincing evidence from
1PI phenotype-mismatched patients undergoing bone marrow transplantation suggests that the mononuclear phagocyte system does not
contribute to the systemic pool (13). However, it can be
speculated that 1PI secreted by the mononuclear
phagocyte system might explain the low levels of 1PI in
patients homozygous for the PIzz phenotype who lack the
capacity for hepatocyte secretion of 1PI. It can
be further speculated that 1PI secreted by cells of the
mononuclear phagocyte system might primarily remain tissue associated,
creating a localized gradient.
The distribution of human 1PI phenotypes has been
reported to differ between ethnic groups and between groups
dichotomized by sexual preference (9). Testosterone can
induce a 20-fold increase in 1PI mRNA, and during
pregnancy 1PI increases by 100% and 2M
increases by 20% (10).
The detection of anti-1PI IgG in HIV-seropositive
patients suggests that autoimmune recognition of 1PI may
be one determinant in producing 1PI deficiency. This
result further suggests that in the presence of competing
anti-1PI immune complexes, the quantitation of total and
inactive 1PI by ELISA in these patients may have been
underestimated here. The binding of 1PI by monoclonal
anti-gp120 suggests humoral immunity to gp120 is one potential
mechanism for initiating an autoimmune response to 1PI.
Comparative alignment of the antibody-recognized gp120 peptide sequence
and the carboxyl-terminal amino acids of 1PI supports
antigenic mimicry. Further, because of the hydrophobic nature of the
1PI epitope recognized by anti-gp120, these results
suggest that neo-epitopes of 1PI may be exposed during
HIV disease. It has been suggested that viral proteins interactive with
host proteins can induce conformational changes and the exposure of
neo-epitopes, thereby initiating autoimmunity (26), and
this suggests a potential mechanism for the initiation of autoimmunity
to 1PI. Antibodies recognizing the V3 loop have been
shown to inhibit the activity of II (18), and this
suggests that the functional activity of II may also be diminished
in the HIV-seropositive population. Deficiency or overexpression of
II has not been described in any disease process (4);
however, the active derivative of II has been reported to localize
to affected tissue in Alzheimer-type dementia (29) and to
increase during bacterial infection (24). That morbidity
and mortality are documented to result from an imbalance in
1PI and 2M ratios (19, 20)
suggests that autoimmunity to 1PI may be cardinal to HIV-associated pathophysiology. The HIV-induced autoimmune recognition of 1PI raises an important concern regarding
vaccine development. It is not known at this time whether the
initiation of immunity to HIV by vaccination also may initiate
autoimmunity to 1PI. Of considerable interest is that
immune recognition of multiple HIV proteins can be detected in
HIV-exposed seronegative individuals; however, neither IgA nor IgG with
specificity for gp120 could be detected in these individuals
(15). The evidence from this continuing seronegative
population for the potential to coexist with HIV suggests, therefore,
that protection against AIDS in HIV-infected individuals might arise by
preventing autoimmunity to 1PI.
Results presented elsewhere suggest that 1PI deficiency,
a condition which exists in the asymptomatic category of HIV disease, may promote increased cellular sensitivity to HIV infectivity (8a). On
the other hand, the increasing concentrations of 1PI which occur during bacterial infection may promote increased viral load, conditions known to occur during the symptomatic category of HIV
disease. The correlation between HIV RNA and total 1PI in the asymptomatic category supports the hypothesis that changing concentrations of circulating 1PI in response to HIV
proteins and in response to attendant infections during HIV disease
directly impact HIV pathophysiology. Evidence that plasma
membrane-associated HLE has been previously shown to interact with
gp120 (17) and recent evidence that neither cell lines nor
peripheral blood cells infected in vitro produce detectable RT activity
in the absence of 1PI (8a) support the participation of
these proteins during HIV disease.
This research was supported by National Institutes of Health grants
DE-11190 and DE-08671, by UNC Center for AIDS Research grant HD-37260,
and by a grant from the University Research Council of UNCChapel Hill.
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Abstract
Introduction
