Department of Allergy and Immunology, Walter
Reed Army Medical Center, Washington, D.C.,1
and
Department of Clinical Investigation, Fitzsimons Army
Medical Center, Aurora, Colorado2
Received 11 June 1997/Returned for modification 30 July
1997/Accepted 21 October 1997
The production of interleukin 2 (IL-2) gamma interferon, IL-4,
tumor necrosis factor alpha (TNF-
), TNF-
, IL-5, and IL-10 in
vitro by peripheral blood mononuclear cells cultured from healthy immunocompetent subjects after mitogen stimulation was determined. The
mitogens used were concanavalin A, phytohemagglutinin, pokeweed mitogen, and Staphylococcus aureus Cowen. The results
obtained provide a normal range for the production of these cytokines
under specified conditions in vitro.
 |
INTRODUCTION |
Cytokines are proteins which play an
integral role in the human immune response. The functions of these
proteins are diverse and include roles in normal T-cell-mediated
immunity, the inflammatory response, cancer, autoimmunity, and allergy
(2). Therefore, various pathologic conditions will be
accompanied by changes in cytokine levels. In order to develop a better
understanding of immune-mediated disorders, it becomes imperative to
measure cytokine production. Only recently has refined laboratory
technology provided the ability to measure serum cytokine levels.
However, these serum measurements are plagued with difficulties due to
soluble receptors, anticytokine antibodies, and receptor antagonists
(6, 15). The emphasis has since shifted to measuring in
vitro cytokine production in cell culture supernatants. This has been
accomplished by the use of various enzyme-linked immunosorbent assay
(ELISA) kits. Although the number of cytokines described is increasing, the normal cytokine production profile has not been established for
many of the cytokines. The purpose of this study was to evaluate cytokine production in vitro by peripheral blood mononuclear cells (PBMC) from healthy immunocompetent individuals after mitogen stimulation and to determine normal ranges. The cytokines measured include Th1-cell cytokines (gamma interferon [IFN-
] and tumor necrosis factor beta [TNF-]), Th2-cell cytokines (interleukin 4 [IL-4] and IL-5), macrophage/lymphocyte cytokines (TNF- and IL-10), and a cytokine produced by both Th1 and Th2 cells (IL-2) (2).
| |
MATERIALS AND METHODS |
Blood donors.
Blood samples were obtained from healthy
donors from the Allergy/Immunology Clinic (clinic personnel) and from
laboratory personnel at Fitzsimons Army Medical Center. Subjects aged
30 to 50 years were enrolled for the study. All subjects except three were active-duty military personnel and had had routine physical examinations that included yearly human immunodeficiency virus (HIV)
testing. None of the participants reported any history of acute or
chronic medical problems. These subjects were all in good health, and
any individuals with recent upper respiratory tract infections were
excluded. Males and females were represented in equal numbers.
Heparinized blood was obtained, and PBMC were isolated according to the
techniques described below. Informed consent was obtained from all
subjects.
Media and reagents.
All chemical reagents and media
components were obtained from Sigma Chemical Co., St. Louis, Mo.,
unless otherwise noted. The cell culture medium consisted of RPMI 1640 supplemented with 10% heat-inactivated fetal bovine serum, 10 mM HEPES
buffer, 2 mM L-glutamine, 50 µg of gentamicin/ml, 100 U
of penicillin/ml, 100 µg of streptomycin/ml, and 0.25 µg of
amphotericin B/ml. PBMC were isolated from whole blood by
centrifugation through Ficoll-Hypaque solution (Histopaque-1077 or
Accuspin-1077).
Cell culture.
PBMC isolated from whole blood were washed
twice in RPMI 1640 and resuspended in culture medium at a concentration
of 106/ml. Then, 0.5 ml of cell suspension was added to
wells of a 24-well tissue culture plate. Next, 0.5 ml of mitogens at a
2× final concentration in culture medium or 0.5 ml of additional
medium (for the cell control) was added to the wells, yielding a final
concentration of 5 × 105 cells/ml. The final
concentrations for concanavalin A (ConA), pokeweed mitogen (PWM),
phytohemagglutinin (PHA), and Staphylococcus aureus Cowen
(SAC) were 5, 5, 10, and 10 µg/ml, respectively. Plates were
incubated for 3 days (37°C, 95% air, 5% CO2, 100% humidity).
Cytokine assays.
Cell culture supernatants were harvested
and analyzed for cytokines by ELISA techniques with commercially
available kits (or were frozen for later analysis). IL-2, IL-4, IL-5,
and IL-10 kits were obtained from R & D Systems, Minneapolis, Minn.
TNF-, TNF-, and IFN- kits were obtained from Biosource
International, Camarillo, Calif. All cytokine assays were calibrated
against the World Health Organization international standards by the
kit manufacturer. The lower limits of detection for the individual
assays are as follows: IL-2, 20 pg/ml; IL-4, 0.2 pg/ml; IL-5, 5 pg/ml;
IL-10, 1 pg/ml; TNF-, 1 pg/ml; TNF-, 10 pg/ml; and IFN-, 10 pg/ml.
Data analysis.
The association between cytokine levels for
each mitogen was examined by using Spearman's correlation coefficient.
Given the large number of possible pairwise comparisons, only
correlations with P values less than 0.01 are presented to
reduce the probability of reporting spurious associations.
| |
RESULTS |
The range and median values for the production of each
cytokine by PBMC from a set of healthy subjects are given in Tables 1
to
7.
In general, the data show a wide range of values for each of the
mitogens used. Because of this wide range, the median rather than the
mean values are considered more indicative of the expected normal
values. The results for IFN- production are presented in Table 1 and
show a particularly wide range of values. The median values demonstrate
a clear mitogen stimulatory effect in the following order: PWM > PHA > SAC > ConA > cell control.
In contrast, IL-2 levels seen with all four mitogens were within a
somewhat narrower range (Table 2). PWM was much more effective in
generating IL-2 synthesis than the other mitogens and was the only
mitogen which stimulated IL-2 production at a median value above the
baseline (cell control) value.
The results for IL-4 production are given in Table 3. The range of
values obtained is also narrower than those for some of the other
cytokines. However, all of the mitogens stimulated production at median
values above the cell control value. The order of preferential stimulation was PWM > PHA > ConA > SAC.
The results of IL-5 production in stimulated cell cultures are shown in
Table 4 and again demonstrated a relatively narrow range of values. PWM
and PHA were the only mitogens capable of stimulating production at
median values above baseline, with PHA > PWM.
IL-10 production (Table 5) showed one of the wider ranges of values.
The preferential order of mitogen stimulation based on median values
was PWM > PHA > SAC > ConA > cell control.
The two forms of TNF have similar functions, and both showed a broad
range with all four mitogens (Tables 6 and 7). However, the
preferential order of mitogen stimulation based on median values was
different. For TNF-, this order was SAC > PWM > PHA > ConA > cell control, while for TNF- the order was PHA > PWM >> (much greater than) SAC 
ConA > cell control.
The association between cytokine levels for each mitogen and for all
individuals was assessed, and the significant results are shown in
Table 8. Stimulation with ConA
demonstrated direct correlations between IL-4 and TNF- and between
IL-10 and IFN-. A direct correlation was noted for PHA between IL-2
and IFN-. For PWM there was a direct correlation between IL-4 and
IL-5. SAC stimulation produced direct correlations between IL-2 and TNF- and between IFN- and TNF-. There were no inverse
correlations noted for any of the four mitogens.
| |
DISCUSSION |
This study determined normal ranges for IL-2, IL-4, IL-5, IL-10,
TNF-, TNF-, and IFN- levels. The increased levels of IL-2 noted secondary to PWM may have been due to dual stimulation of both T
and B lymphocytes. The B cells may have produced an amplification factor which then stimulated the T lymphocytes to increase IL-2 production. The seeming lack of IL-2 production by PBMC from the majority of donors in response to ConA and PHA (Table 2) may have been
due to the length of incubation of the cell cultures (3 days). If the
culture supernatants had been harvested after 24 h of incubation,
some IL-2 production by PBMC from a majority of donors may have been
observed. The absence of detectable IL-2 after 3 days may have been due
to upregulation of IL-2 receptors on activated lymphocytes, with
subsequent binding and uptake of this cytokine. IL-4 is classically
associated with allergic disease, as it is the immunoglobulin E switch
factor. The relatively low values of IL-4 observed may have been due to
the nonallergic state of the study participants or the absence of
aeroallergens during the study period (winter months in Denver, Colo.).
IL-5 is involved with eosinophil proliferation. Therefore, in a healthy
donor one would not expect the lymphocytes to be primed to produce
increased IL-5 levels. This would explain the narrow range noted for
IL-5 production. The high levels of TNF- obtained as a result of
stimulation with SAC may be due to preferential stimulation of
monocytes/macrophages with this mitogen and preferential production of
this cytokine by monocytes/macrophages.
This study also assessed whether a pattern existed between cytokine
levels for each individual for a given mitogen. The PHA and PWM results
were consistent with Th1 and Th2 profiles, respectively. For PHA, as
IL-2 levels increased or decreased IFN- levels increased or
decreased accordingly. For PWM, the same relationship existed between
IL-4 and IL-5. For SAC there was an association between TNF- and
IL-2, as well as one between TNF- and IFN-. These correlations
are of the Th1 variety. Stimulation with ConA showed that IL-10 levels
were directly related to IFN-, and this would not corroborate the
classic Th1-Th2 paradigm in which these two cytokines would be
inversely related. ConA stimulation also demonstrated a positive
relationship between TNF- and IL-4. Again, this may not fit the
classic Th1-Th2 differentiation model. However, recently there has been
further elucidation of the Th1-Th2 model for humans (2). The
majority of the literature has described cytokines such as IL-2 as
being produced by Th1 cells. However, this was originally described for
the murine model. The review by Borish and Rossenwasser demonstrates
that the breakdown of the Th1- and Th2-cell cytokines in humans is not
as clearly divided. For example, IL-2 is produced by both Th1 and Th2
lymphocytes. The cytokine associations noted in this study are very
interesting, and most appear to fit the Th1-Th2 paradigm. However, this
was not the primary objective of this study, and thus further
investigation is needed to delineate the direct and inverse
relationships between cytokines in humans.
The explanation of why each mitogen stimulates the cells to produce
different levels of cytokines is not clear, although the spectrum of
target cells for each mitogen is known to be somewhat different. ConA
is reported to stimulate cytotoxic T cells (14), suppressor
inducer T cells (12), or "virgin" T cells
(11). PWM, on the other hand, stimulates helper T cells and,
in association, B cells (11). SAC directly stimulates B
cells (13); however, T cells may possibly be stimulated
indirectly through cytokines elaborated by the stimulated B cells. As a
result this study not only highlights what cytokine levels one should
expect in culture but also shows that different levels are produced
depending on the mitogen used.
Cytokine levels vary not only in vitro secondary to different mitogens
but also in vivo in different clinical diseases. A study by Friberg et
al. showed varying cytokine levels in cancer patients who had received
biologic response modifiers (5). Al-Janadi et al.
(1) demonstrated greatly increased synthesis of IL-6 and
IFN- by ConA-stimulated PBMC from patients with systemic lupus
erythematosus (SLE) with nephrotic syndrome (NS) or SLE with
lymphadenopathy (LN), compared to that by ConA-stimulated PBMC from
healthy controls. However, ConA-stimulated PBMC from SLE patients with
thrombocytopenia (TP) showed significantly smaller increases in IL-6
production and no increase in IFN- synthesis relative to those from
healthy controls. In contrast, ConA-stimulated PBMC from SLE patients
with TP, but not from SLE patients with either NS or LN, produced
greatly increased amounts of TNF- compared to those from healthy
controls (1). Kobrynski et al. (8) found that
PBMC from chronic mucocutaneous candidiasis patients produced more
IL-4, but not IL-10, IL-2R, or IFN-, in response to PHA than PBMC
from controls. Additionally, there has been increasing use of in vitro
cytokine measurements to classify disease states according to the
Th1-Th2 cytokine paradigm. In a study of the effects of the
immunomodulatory drug thalidomide, McHugh et al. (10) found
that the drug effected an early switch from a Th1- to a Th2-type
cytokine profile. A switch from a Th1- to a Th2-type cytokine profile
has also been associated with disease progression in HIV-infected
patients (3, 4). In fact, pediatric HIV patients have been
found to produce more IL-4 and less IL-2 than healthy controls
(16). Moreover, in a comparative study of rapidly progressing (RP) and seroreverting (SR) vertically infected pediatric HIV patients, Lee et al. (9) found that the RP patients
produced less IL-2 and IFN- than the SR patients. In contrast, the
RP patients produced more IL-4 mRNA than did the SR patients. Finally, in a case study of a patient with a 
T lymphocytosis
(7), it was found that the production of all cytokines
tested, including both Th1- and Th2-cell cytokines, was severely
depressed.
The results presented above indicate that one needs to be very aware of
the culture conditions, the mitogens used, and the clinical state of
the patient when performing in vitro cytokine measurements. This is the
first study to provide reference ranges for cytokine production in
mitogen-stimulated cell cultures, while demonstrating variable cytokine
levels in response to different mitogens.
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Abstract
Introduction
Present address: Department of Chemistry, University of Hawaii at
Manoa, Honolulu, HI 96822.
