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Previous Article | Next Article 
Clinical and Diagnostic Laboratory Immunology, September 2000, p. 769-773, Vol. 7, No. 5
1071-412X/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Cytokine Gene Expression Occurs More Rapidly in
Stimulated Peripheral Blood Mononuclear Cells from Human
Immunodeficiency Virus-Infected Persons
Elizabeth Crabb
Breen,1,2,*
Matthew
McDonald,2
Jiang
Fan,2,
John
Boscardin,3 and
John
L.
Fahey2
Departments of Obstetrics and
Gynecology1 and Microbiology,
Immunology, and Molecular Genetics,2 School of
Medicine, and Department of Biostatistics, School of Public
Health,3 University of California, Los Angeles,
California
Received 1 May 2000/Accepted 30 May 2000
 |
ABSTRACT |
Evaluation of cytokine gene expression following in vitro
stimulation is one means of examining the dysregulation of the immune system in human immunodeficiency virus (HIV) infection. We have assessed differences in the immune status of non-HIV-infected (HIV
)
and HIV-infected (HIV+) individuals by evaluating the kinetics of the
expression of cytokine genes. We compared detailed time courses of
cytokine mRNA expression in HIV and HIV+ peripheral blood mononuclear
cells (PBMC) and found that there is a significant shift
(P < 0.01) for all cytokines examined (interleukin 2 [IL-2], IL-6, IL-10, gamma interferon, and tumor necrosis factor
alpha [TNF-
]) to an earlier time of mean peak mRNA expression by
HIV+ PBMC (between 4 and 8 h) compared to HIV PBMC (8 h) in
response to either phytohemagglutinin (PHA) or anti-CD3 stimulation.
Additional studies showed that although PHA-stimulated HIV+ PBMC showed
decreased median IL-2, IL-4, and TNF- mRNA levels, they typically
demonstrated more rapid kinetics (increased mean 4-h/24-h cytokine mRNA
ratios), with significant differences for IL-4 (P < 0.05) and TNF- (P < 0.005), compared to HIV
PBMC. The use of fresh or frozen cells gave comparable cytokine mRNA
data; however, the secretion of some cytokine proteins (IL-2 receptor,
IL-10, and TNF-) appeared to be reduced in HIV+ PBMC that had been
frozen and thawed. Our studies demonstrate that the kinetics of
cytokine gene expression can reveal additional dysregulation of the
immune system in HIV infection, suggesting that PBMC of HIV-infected
persons exist in an activated state in vivo that permits them to
express cytokine genes more rapidly than a normal PBMC.
| |
INTRODUCTION |
Infection with human
immunodeficiency virus (HIV) is associated with signs of both immune
deficiency and immune activation (9, 15, 16). The decline in
the number and function of CD4+ T cells is one of the
hallmarks of the infection. At the same time, there is ample evidence
of immune hyperactivity in HIV-infected (HIV+) individuals, as
indicated by numerous reports of increased levels in vivo, as well as
increased spontaneous in vitro production of immunoglobulins, certain
cytokines, and markers of immune activation (6, 9, 15, 16).
It has been suggested that decreases in the in vitro production of some
cytokines and increases in others may play a role in the progression of
HIV disease (3, 4); however, this has not been universally
observed (2, 7, 10, 14). There has been great interest,
therefore, in examining cytokine activity in and by cells from HIV+ and
non-HIV-infected (HIV) subjects. There are many studies that document
differences in the levels of cytokines secreted by and/or cytokine
genes expressed in peripheral blood mononuclear cells (PBMC) from HIV
and HIV+ subjects (reviewed in references 9 and
16). While not a direct measure of cytokine
production, semiquantitative determination of cytokine gene expression
by the measurement of cytokine mRNA is generally considered an
indicator of the potential of an individual's cells to ultimately
secrete cytokine proteins.
Many cytokine mRNA studies have focused on the quantitative nature of
the differences in cytokine gene expression, i.e., whether PBMC from
HIV+ individuals had increased or decreased levels of cytokine mRNA
compared to PBMC of HIV individuals under the same experimental
conditions in vitro. Such results are usually interpreted to suggest
that the PBMC of HIV+ persons have an increased or decreased potential
to express cytokine genes, which in turn may lead to differences in
actual cytokine production in vivo. We have been interested in
examining the kinetics of cytokine mRNA expression in response to in
vitro stimuli, which may reflect the preexisting in vivo immune status
of PBMC and their readiness to respond, rather than provide a
quantitative measure of their overall potential to express cytokine genes.
Recently, we examined the kinetics of cytokine mRNA expression in PBMC
from normal healthy subjects in response to various stimuli
(8). We have extended those studies to compare the kinetics
of cytokine mRNA expression in stimulated PBMC from HIV and HIV+
subjects, and we show that PBMC from HIV+ subjects express mRNAs for
several cytokines more rapidly than cells from HIV subjects. In
addition, we have examined the effects of using frozen HIV and HIV+
PBMC for evaluating cytokine responses following in vitro stimulation.
| |
MATERIALS AND METHODS |
The cytokines and cytokine receptor examined were interleukin 2 (IL-2), IL-2-receptor (IL-2R), interleukin 4 (IL-4), interleukin 6 (IL-6), interleukin 10 (IL-10), gamma interferon (IFN-
) and tumor
necrosis factor- (TNF-).
Heparinized whole blood was obtained from known HIV and HIV+
individuals. All HIV+ subjects were homosexual men currently enrolled
in the Multicenter AIDS Cohort Study (MACS) at UCLA (5, 11).
The two HIV+ individuals used for detailed kinetic analyses had
absolute CD4 T-cell counts of 168 and 312 cells/mm3; the
HIV+ group used for additional studies (n = 8) had a
mean absolute CD4 cell count of 376/mm3, with a range from
213 to 476/mm3. HIV subjects were healthy heterosexual
controls or HIV-seronegative participants in the MACS. PBMC were
purified from whole blood samples by density gradient centrifugation
over 60% Percoll gradients and cultured in complete RPMI 1640 medium
(100 U of penicillin per ml, 100 µg of streptomycin per ml, 0.3 mg of
glutamine per ml) with 10% human AB serum.
For kinetic studies, 106 PBMC in a total volume of 0.5 ml
were placed in 12- by 75-mm tubes, allowed to rest without stimulation for 1 h at 37°C, and then stimulated with phytohemagglutinin
(PHA) (Sigma) (5 µg/ml), or anti-CD3 monoclonal antibody (NEN
Research Products) (200 ng/ml), as previously described (8).
PBMC pellets were collected at the indicated times (up to 72 h)
poststimulation and stored at 70°C until RNA extraction. Culture
supernatants (SN) were also collected at 24 and 72 h
poststimulation and held at 20°C until assayed for cytokines or
cytokine receptor.
RNA extraction and semiquantitative reverse transcription-PCR (RT-PCR)
for cytokine gene expression were performed as previously described
(7, 8), utilizing the primers shown in Table
1. Briefly, RNA was obtained by
guanidinium isothiocyanate lysis and phenol-chloroform extraction, and
10 ng of total RNA was used for each RT-PCR. cDNA was synthesized using
oligo(dT) priming and Moloney murine leukemia virus reverse
transcriptase and then amplified using 0.2 µM 5' and 3'
oligonucleotide cytokine or beta-actin primers, 2.5 µmol of AmpliTaq
DNA polymerase (Perkin-Elmer Cetus), and a reaction mixture containing
10 mM Tris-HCl, 2.0 to 2.5 mM MgCl2, 0.2 mM deoxynucleoside
triphosphate (Perkin-Elmer Cetus), and 0.01 µM
[-32P]dATP. Reactions were amplified by 25 cycles
(beta-actin) or 35 cycles (cytokines) of denaturation at 95°C, with
annealing and extension at 60°C. PCR products were identified by
autoradiography following acrylamide gel electrophoresis, the
radioactive bands were cut from the dried gel, and activity was
determined by liquid scintillation counting. The activity obtained
(counts per minute) for each cytokine reaction product was normalized
to reflect total RNA content by using the activity obtained for
beta-actin in the same sample.
Concentrations of soluble IL-2R (Endogen), IL-4 (Genzyme), IL-10
(Immunotech), and TNF- (Innogenetics) in cell culture SN were
determined using commercially available enzyme-linked immunosorbent assay (ELISA) kits according to the manufacturer's protocol; IFN- (T Cell Diagnostics) was determined using a modified ELISA protocol (1).
For eight HIV and eight HIV+ subjects included in the kinetic studies
described above, parallel experiments were performed on aliquots of
PBMC from the same blood draw that were frozen in 10% serum-10%
dimethyl sulfoxide according to MACS protocols (12) and then
thawed, stimulated, and cultured as described above. PBMC pellets and
culture SN from frozen cells were collected at the same times, and
tested in the same RT-PCR assays and cytokine ELISAs as the samples
from fresh cells from the same subject.
The detailed kinetics of mRNA expression for each cytokine for each
subject was represented by calculating the percentage of maximum mRNA
expression obtained for a given cytokine at each time point over the
72-h time course. The mean percentage of maximum mRNA expression at
each time point for each cytokine was determined for HIV and HIV+
subjects and plotted as shown in Fig. 1 and 2. Statistical analysis of
the kinetic plots were performed by calculating the time axis centroid
for each plot, which represented the mean time of mRNA expression.
These mean times were then compared simultaneously for all six
cytokines and cytokine receptor between HIV and HIV+ subjects using a
mixed-effects linear model (13). Comparisons of mRNA values,
mRNA ratios, and data for fresh versus frozen cells were performed
using the nonparametric Wilcoxon rank sum test.
| |
RESULTS |
Peak cytokine mRNA expression occurs earlier in stimulated HIV+
PBMC than in HIV PBMC.
PBMC from HIV and HIV+ subjects were
stimulated with either PHA or anti-CD3 monoclonal antibody, and the
expression of mRNAs for the cytokines IL-2, IL-6, IL-10, IFN-, and
TNF- and the cytokine receptor IL-2R was determined at multiple time
points from 0 to 72 h poststimulation. The kinetics were expressed
by representing each cytokine mRNA value from a subject as a percentage of the maximum mRNA obtained for that cytokine over the time course; i.e., among all the values obtained from a single subject for a given
cytokine, the time point between 0 and 72 h that had the highest
absolute mRNA result was set equal to 100%, and the results at all
other time points for that particular cytokine were expressed as
percentages of the highest value.
When the mean percentages of maximum mRNA values were plotted over time
for HIV and HIV+ PBMC simulated with PHA (Fig.
1), HIV+ cells showed a clear shift
toward earlier peak mRNA expression for all five cytokines compared to
HIV cells. While HIV PBMC showed peak mRNA expression for most
cytokines at 8 h poststimulation (with IFN- as an exception at
24 h), HIV+ PBMC showed peak IL-2 and IL-6 mRNA expression at
2 h and peak IL-10, IFN-, and TNF- expression at 4 h.
Consistent with previous observations (8), the kinetics of
IL-2R mRNA expression differed from those of the cytokines, exhibiting
a more sustained time course that peaked at 72 h in both HIV+ and
HIV cells.
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FIG. 1.
Kinetics of cytokine mRNA expression following PHA
stimulation of PBMC. Each cytokine mRNA value from a subject was
represented as a percentage of the maximum mRNA obtained for that
cytokine over that subject's time course. (A) Mean percent maximum
mRNA expression for two HIV+ subjects. (B) Mean percent maximum mRNA
expression for two HIV subjects.
|
|
Plots of cytokine mRNA expression by HIV and HIV+ PBMC stimulated
with anti-CD3 antibody showed similar results (Fig.
2). HIV cells showed distinct peaks of
mRNA expression at 8 h for all five cytokines, while earlier times
of peak expression were seen in HIV+ cells. Although a mean IL-2 and
IL-6 mRNA values in HIV+ cells reached their maximum at 8 h, mRNA
levels for both of these cytokines were near maximal levels at 4 h, suggesting that the peak may have occurred between 4 and 8 h.
In the anti-CD3-stimulated cells, the shift toward earlier peak mRNA
expression in HIV+ cells was also seen for IL-2R, which clearly peaked
at 24 h, in comparison to 72 h in HIV cells.
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FIG. 2.
Kinetics of cytokine mRNA expression following
stimulation of PBMC with anti-CD3 monoclonal antibody. (A) Mean percent
maximum mRNA expression in the same HIV+ subjects as for Fig. 1A. (B)
Mean percent maximum mRNA expression in the same HIV subjects as for
Fig. 1B.
|
|
The shift toward earlier peak cytokine mRNA expression in HIV+ PBMC
seen in the plots was evaluated by calculating a weighted mean time of
mRNA expression for each cytokine time course for HIV and HIV+
subjects. This value, called a time axis centroid, takes into account
the overall shape of the kinetic curve rather than just the one time
point or mode that has the maximum mRNA expression. When the mean times
of mRNA expression for all cytokines and IL-2R following stimulation of
HIV and HIV+ PBMC with PHA were compared simultaneously, there was a
significant shift to an earlier mean time of mRNA expression in HIV+
cells (P < 0.01). When the same type of comparison was
made for anti-CD3-stimulated cells, HIV+ cells once again showed a
highly significant shift to an earlier mean time of expression
(P < 0.001). The increase in significance in the
anti-CD3 comparison was most likely due to the more obvious shift seen
in peak mRNA IL-2R expression. In both comparisons, the mean time of
mRNA expression in HIV+ PBMC was between 4 and 8 h, compared to
greater than or equal to 8 h in HIV PBMC. When the same types of
analyses were performed on cytokine data only (omitting IL-2R), a
statistically significant shift to earlier mean mRNA expression in HIV+
PBMC was still seen in both PHA- and anti-CD3-stimulated cells
(P < 0.01 and P < 0.001, respectively).
Stimulated PBMC from HIV+ subjects have decreased levels, but more
rapid kinetics, of expression of cytokine mRNAs than HIV PBMC.
In order to further explore the possibility of more rapid cytokine mRNA
expression in HIV+ PBMC, additional mRNA data were obtained from a
larger number of subjects. As it was not practical to attempt
larger-scale studies with multiple stimuli, time points, and cytokine
and cytokine receptor assays, a simpler experimental protocol was
utilized. Since PHA stimulation demonstrated a clear shift in mean peak
cytokine mRNAs in HIV+ PBMC to either 2 or 4 h poststimulation for
all of the cytokines examined initially, PHA was chosen as the
stimulus, with cell pellets collected at 4 and 24 h
poststimulation. Cytokine mRNA levels were determined for IL-2, IL-4,
TNF-, and IFN-, and median levels were compared between HIV and
HIV+ PBMC (Table 2). The relative
kinetics of cytokine mRNA expression were evaluated using the ratio of
4-h mRNA to 24-h mRNA (Table 3). A ratio
of >1 indicates more mRNA expression at 4 h than at 24 h,
and when comparing ratios, a higher ratio suggests an earlier peak of
mRNA expression.
When the median mRNA values obtained for each cytokine in PBMC from
HIV and HIV+ subjects were compared, our data were consistent with
other reports showing lower median IL-2, IL-4, and TNF- expression
and higher median IFN- expression in HIV+ cells than in cells from
HIV subjects (Table 2). However, the differences were not
statistically significant except in the case of TNF- mRNA at 24 h (P < 0.05). When the ratio of 4- to 24-h mRNA
expression for each cytokine was examined for evidence of a shift to
earlier expression in HIV+ cells, the mean ratio was higher in HIV+
than HIV cells for every cytokine, suggesting an earlier peak of mRNA expression (Table 3). Due to the relatively small sample size, however,
only the differences in ratios for IL-4 and TNF- were statistically
significant. Therefore, in spite of a reduced capacity to express most
kinds of cytokine mRNAs in response to stimulation, an evaluation of
relative kinetics suggests that cytokine mRNA responses in HIV+ PBMC
tend to occur more rapidly, with an earlier peak time of cytokine mRNA
response, than those in HIV PBMC.
Cytokine responses by HIV+ and HIV PBMC may differ in fresh and
frozen cells.
Cytokine mRNA expression was measured in parallel
cultures of PHA-stimulated fresh and "frozen" cells but showed no
statistically significant differences within either the HIV or HIV+
group (data not shown). Similarly, the relative kinetics of expression
(4-h/24-h ratio) for each cytokine showed no significant differences
between fresh and frozen cells in the HIV+ group, and only IL-2 ratios were slightly increased in fresh HIV PBMC compared to frozen HIV+
PBMC (P < 0.05) (data not shown).
The effect of freezing and thawing on cytokine production was also
evaluated with the same fresh and frozen PBMC cultures by measuring
cytokine or cytokine receptor concentrations in culture SN collected
72 h poststimulation. Soluble IL-2R, which is secreted in response
to IL-2 production, was measured as a surrogate for IL-2
(6). For each cytokine, mean levels in SN were compared between the HIV and HIV+ groups, first using the data obtained from
fresh cells and then again using the data from frozen cells (Fig.
3). There were no statistically
significant differences in mean SN cytokine levels between the HIV
and HIV+ groups (P > 0.05) when fresh cells were used.
However, when mean SN cytokine levels in the HIV and HIV+ groups were
compared using the data from cells that had been frozen and thawed
before culture, IL-2R, IL-10, and TNF- appeared to be significantly
decreased in the HIV+ group compared to the HIV group. While the
changes in IFN- were not statistically significant, it is
interesting that the HIV+ group had a higher mean IFN- level than
the HIV group in fresh cell SN but that the trend was reversed in
frozen SN, with the HIV group having the higher mean.
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FIG. 3.
Cytokine production following PHA stimulation in 72-h
culture supernatants. Open bars, mean cytokine concentrations in the
HIV group; filled bars, mean cytokine concentrations in the HIV+
group. The P values shown are for comparison of the HIV
versus HIV+ groups using data from either fresh or frozen PBMC.
|
|
| |
DISCUSSION |
Although the early descriptions of immune system changes in HIV
infection and AIDS focused on the immunodeficiency associated with the
loss of T-helper cells, there is now ample evidence of widespread
immune dysregulation in HIV+ persons, leading to a somewhat paradoxical
mix of both immune deficiency and immune hyperactivation. Studies of
changes in cytokines in HIV+ persons are an excellent example of this
paradox, as the circulating levels in serum of some cytokines, such as
IL-2, are decreased, while those of others, such as the inflammatory
cytokines IL-6 and TNF-, are increased in association with HIV
infection. While serum cytokine levels are a measure of in vivo
cytokine activity, they reflect the equilibrium that has been
established between cytokine production and uptake by cells expressing
cytokine receptors and/or clearance from the circulation. Many
investigators, therefore, have evaluated the ability of cells to
secrete cytokines in vitro in response to stimulation with mitogens, as
a means of determining changes in the potential or capacity of cells to
produce cytokines. Yet another approach is to examine cytokine
responses following in vitro stimulation at the level of cytokine gene
expression, by determining levels of cytokine-specific mRNA. This
approach examines the capacity of a cell to mount a cytokine response
at its most basic level and lends itself not only to addressing the
magnitude of a response but also to characterizing the time course over which the response occurs. We have been interested in examining the
kinetics of cytokine expression by PBMC following in vitro stimulation,
and we have previously described the cytokine mRNA kinetics seen in
healthy, HIV subjects in response to a number of mitogens commonly
employed in the immunology laboratory (8). In the work
reported here, we have extended those studies to compare the kinetics
of cytokine mRNA expression in HIV+ and HIV subjects, and we
demonstrate that although the magnitude of most cytokine mRNA responses
may be less than in PBMC from HIV+ subjects, these cells respond more
rapidly to in vitro stimulation.
In detailed time courses following stimulation with either PHA or
anti-CD3, two of the most commonly used laboratory mitogens, we
observed a clear shift in mean peak mRNA expression for all cytokines
examined to less than 8 h in HIV+ PBMC, compared to mean peaks at
8 or 24 h in HIV PBMC (Fig. 1 and 2). Evidence of a more rapid
response to stimulation by HIV+ PBMC was also seen when the relative
kinetics of PHA-stimulated PBMC were examined in a larger group of
subjects, where gene expression for IL-2, IL-4, TNF-, and IFN-
tended to occur more rapidly in the HIV+ group than in the HIV group
(Table 3). This was in spite of decreased levels of mRNA for all but
IFN- (Table 2). Therefore, even though cells from HIV+ persons
failed to express comparable levels of multiple cytokine-specific mRNAs
following stimulation, they appeared to be able to respond more quickly
to a stimulus. This observation suggests that cells within the HIV+
PBMC exist in a preactivated state in vivo that enables them to
initiate this process more quickly. These cells should be viewed,
therefore, as hyperresponsive to the initial cytokine-inducing signals
but unable to sustain comparable levels of cytokine mRNA expression and
production. The characterization of these cells as both hyperactive and
yet ultimately immunodeficient reflects the immune dysregulation that
characterizes HIV infection in the immune system as a whole. From the
perspective of the immunology laboratory, it is important to recognize
that the more rapid peak of cytokine gene expression seen in HIV+ cells
should be taken into account when designing studies comparing cytokine
mRNA responses between HIV and HIV+ subjects.
All of the HIV+ subjects in this work were participants in the MACS, a
study of the natural history of AIDS in which participants have been
providing blood samples every 3 to 6 months since the mid-1980s
(5, 11). While the kinetic studies described here were
performed on PBMC isolated from fresh blood samples, the MACS and other
cohort studies like it have repositories of frozen PBMC that provide
unique opportunities for study design. We were interested to see if
frozen and thawed PBMC would give results comparable to those obtained
with fresh cells in studies of cytokine responses following in vitro
stimulation, and so we performed parallel mRNA and cell culture SN
assays. While the use of fresh versus frozen cells did not alter the
comparisons of cytokine mRNA between the HIV and HIV+ groups, three
out of five cytokines examined (IL-2R, IL-10, and TNF-) showed
effects of freezing on cytokine protein production in culture SN. For
each of these cytokines, there was no statistically significant
difference between concentrations seen in SN from the HIV and HIV+
groups when fresh cells were used, but there was a significant decrease
in concentration for the HIV+ groups when frozen cells were used. This
suggests that HIV+ PBMC may be more sensitive to freezing than HIV
PBMC and that the use of frozen cells might bias the data when
comparing cytokine responses by HIV and HIV+ cells. These
observations indicate that although cryopreserved cells from the MACS
appear to be suitable for other laboratory studies (12), the
use of fresh cells may be preferable for evaluating cytokine responses in vitro.
| |
ACKNOWLEDGMENTS |
We gratefully acknowledge the men who participate in the MACS,
who have made this and many other studies possible. We also thank Thang
Nguyen and Najib Aziz for technical assistance and Pari Nishanian for
scientific input and manuscript review.
This work was supported by grants from the National Institutes of
Health (AI36086, AI35040, TW00003, and T32AI07388).
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Obstetrics & Gynecology, Box 951740, UCLA School of Medicine, Los
Angeles, CA 90095-1740. Phone: (310) 206-6846. Fax: (310) 206-5387. E-mail: ebreen{at}ucla.edu.
Present address: Department of Pediatrics, Medical College of
Wisconsin, Milwaukee, WI 53226.
| |
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Clinical and Diagnostic Laboratory Immunology, September 2000, p. 769-773, Vol. 7, No. 5
1071-412X/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
