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1 Defence and Civil Institute of Environmental Medicine, Toronto, M3M 3B9; 3 Faculty of Physical Education and Health and 4 Department of Laboratory Medicine and Pathobiology, University of Toronto, Toronto, Ontario M5S 1A1 Canada; and 2 United States Army Research Institute of Environmental Medicine, Natick, Massachusetts 01760
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ABSTRACT |
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 TOP
 ABSTRACT
 INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES
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This study tested the
hypothesis that exercise elicits monocytic cytokine expression and that
prolonged cold exposure modulates such responses. Nine men (age,
24.6 ± 3.8 y; 
O2 peak, 56.8 ± 5.6 ml · kg
1 · min1) completed
7 days of exhausting exercise (aerobic, anaerobic, resistive) and
underwent three cold, wet exposures (CW). CW trials comprised 
6 h
(six 1-h rest-work cycles) exposure to cold (5°C, 20 km/h wind) and
wet (5 cm/h rain) conditions. Blood samples for the determination of
intracellular and serum cytokine levels and circulating hormone
concentrations were drawn at rest (0700), after exercise (~1130), and
after CW (~2000). Whole blood was incubated with (stimulated) or
without (spontaneous) lipopolysaccharide (LPS; 1 µg/ml) and stained
for CD14 monocyte surface antigens. Cell suspensions were stained for
intracellular cytokine expression and analyzed by flow cytometry. The
proportion of CD14+ monocytes exhibiting spontaneous and
stimulated intracellular expression of interleukin (IL)-1
, IL-6, and
tumor necrosis factor (TNF)-
increased after exercise, but these
cells produced less IL-1 and TNF- after CW when CW was preceded
by exhausting exercise. Serum cytokine concentrations followed
a parallel trend. These findings suggest that blood monocytes
contribute to exercise-induced cytokinemia and that cold exposure can
differentially modulate cytokine production, upregulating expression of
IL-6 and IL-1 receptor antagonist but downregulating IL-1 and
TNF-. The cold-induced changes in cytokine expression appear to be
linked to enhanced catecholamine secretion associated with cold exposure.
catecholamines; cortisol; flow cytometry; immune; interleukin; thermal stress
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INTRODUCTION |
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TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES
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CIRCULATING CYTOKINE CONCENTRATIONS are elevated in response to strenuous exercise and other forms of physical stress (43). Although valuable information has been gained from studies measuring soluble cytokine levels in serum or plasma, conventional bulk assay methods (e.g., immunoassays or mRNA analysis) are limited by their inability to detect cytokine production at the individual cell level (46). Moreover, certain cytokines have proven difficult to measure in the circulation due to their short half-life and rapid uptake/utilization (12). Consequently, identification of the precise cellular sources of exercise-induced cytokinemia remains unclear (56).
Blood monocytes are a first line of defense against invading pathogens
and a major source of immunoinflammatory mediators (56).
When activated by various noninfectious or infectious agents, such as
bacteria-derived lipopolysaccharide (LPS, endotoxin), monocytes
sequentially release a cascade of cytokines, including tumor necrosis
factor (TNF)-, followed by interleukin (IL)-1, IL-6, and IL-1
receptor antagonist (IL-1ra) (2, 56). Because strenuous
exercise can elicit both a pronounced monocytosis (23, 54)
and systemic endotoxemia (6), it may be hypothesized that
activated blood monocytes are a likely source of circulating cytokines
with physical stress (7, 51). Nevertheless, studies to
date have failed to directly confirm enhanced monocytic cytokine production with exercise (43) and the contribution of
monocytes to exercise-induced cytokine production remains speculative
(4, 7).
Although heat stress is known to accentuate exercise-associated immunomodulation, largely via augmented hormonal fluctuations (8, 45), relatively little is known regarding the physiological modulation of the human immune system by cold exposure, either at rest or during sustained exercise (50). Exposure to cold substantially augments hypothalamic-pituitary-adrenal (HPA) axis and sympathetic nervous system (SNS) activation, producing an enhanced secretion of cortisol and catecholamines, respectively (29, 34). Cold is known to affect leukocyte mobilization (9, 30) and can suppress lymphocyte functional activities (5, 13). Furthermore, limited evidence suggests that cold exposure may also initiate changes in cytokine expression associated with a nonspecific acute phase reaction (9, 19, 20). Because cytokines play a key role in the bidirectional communication between neuroendocrine and immune systems (22), it has been suggested that the interplay between hormones and cytokines during thermal stress may influence immune homeostasis in response to environmental challenge (19, 29). However, the impact of sustained cold exposure on in vivo cytokine expression in humans has not been fully explored.
To better understand the regulatory role played by cytokines released
during physical stress, the origin of cytokine production must be
established. The present study was conducted to examine the impact of
repeated bouts of strenuous, fatiguing exercise and prolonged exposures
to cold, wet (CW) conditions on spontaneous and LPS-stimulated
monocytic cytokine production. We hypothesized that strenuous exercise
would augment cytokine expression and that exposure to cold would
modify such responses. To test this, we used multiparameter flow
cytometry to measure intracellular cytokine expression, which in
conjunction with cell-surface marker analysis allows the frequency and
functional characteristics of discrete cytokine-producing cells to be
identified within heterogeneous whole blood cell populations
(41). Our specific aims were 1) to study the
effects of 7 consecutive days of strenuous exercise on resting and
exercise-induced changes in intracellular monocytic expression of
IL-1, IL-1ra, IL-6, and TNF-; 2) to determine if cold
stress is associated with alterations in circulating and/or intracellular profiles of these cytokines; 3) to assess the
relationship between circulating and intracellular cytokine expression;
and 4) to examine whether changes in these mediators are
associated with fluctuations in cortisol or catecholamine levels.
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METHODS |
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TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES
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Subjects.
Nine healthy [peak oxygen uptake
(O2 peak), 56.8 ± 5.6 (SD)
ml · kg1 · min1] men
[age, 24.6 ± 3.8 (SD) yr; body mass, 81.3 ± 11.1 kg; body fat, 15.5 ± 5.7%; height, 1.77 ± 0.08 m] volunteered to
participate in this study, which was approved by the institutional
Human Use Committee. Subjects were informed of all procedures and
possible risks associated with the study. After medical examination to exclude contraindications to exercise and/or cold exposure, each subject gave his written consent to participate in the experiment. Subjects were nonsmokers and were not taking prescription medications.
Preliminary testing.
The subjects' body composition,
O2 peak, and muscular strength were
assessed initially. Percent body fat was measured by dual-energy X-ray
absorbitometry (Model DPX-L, Lunar, Madison, WI).
O2 peak was determined by an
incremental treadmill test to exhaustion and open-circuit spirometry.
The one-repetition maximum of the upright row, chest press, latissimus
dorsi pull-down, and biceps curl was determined.
Experimental design.
This study took place in the summer and autumn months to minimize the
possible effect of developing cold habituation. Tests were conducted
over eight successive days. Subjects were tested in groups of three or
four and underwent a fatiguing exercise routine for 7 days (Fig.
1). Day 1 was comprised of
control measurements and CW exposure from ~1330-1930 without
prior exercise. On days 2-3 and 5-7,
subjects performed a 4.9-km run at their personal maximal speed.
Weightlifting involved one set of resistance exercises at 70% of
maximum to exhaustion on rowing, benchpress, latissimus pull-down, and
biceps curl movements. The mixed aerobic exercise comprised four sets
of 20-min exercise bouts at ~65%
O2 peak; activities, including
stair-stepping, rowing ergometry, treadmill walking, upright cycling,
and semirecumbent cycle ergometry. A 30-s Wingate test of anaerobic
capacity concluded each day of exercise. Hiking on days 4 and 8 consisted of a 9.7-km hike over varied terrain at
~6.4 km/h while carrying a 9.1-kg backpack. Exercise was performed
from 0900 to 1300 (days 2-3 and 5-7)
and from 0700 to 1100 (days 4 and 8). On
days 4 and 8, CW exposure was 2.5 h after
the end of fatiguing exercise. The CW exposure involved up to 6 h
intermittent treadmill walking (six cycles of 45 min walking, 10 min of
rest in simulated rain, and 5 min for transition between simulated rain
and walking). Subjects attempted to complete all six cycles. During the
simulated rain, subjects stood under a sprinkler delivering the
equivalent of 5.4 cm rain/h while exposed to a wind velocity of 4.1 km/h, and at this stage in each cycle, they were given 250 ml of a
commercial carbohydrate drink (Gatorade, Quaker Oats, Barrington, IL).
Treadmill walking was performed at 5 km/h, 0% grade, with a wind
velocity of 20 km/h and an average
O2 peak of 38.7 ± 1.4 and
39.5 ± 1.4 ml · kg1 · min1 on
days 1 and 8, respectively. The
environmental chamber temperature was set at 5°C throughout the CW.
Clothing consisted of a standard United States army battle dress
uniform [cotton shirt, cotton-nylon jacket, cotton-nylon pants,
cotton-nylon hat, socks, and leather boots, providing a thermal
insulation of approximately 1.1 clo [1 clo = 0.155°C/m2/W]). During the period of simulated
rain, this clothing was supplemented by a 100% nylon rain hat and
nylon gaiters. The CW was terminated if the subject's core temperature
dropped below 35°C, or if the subject requested to stop.
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Temperature measurements. A thermistor inserted 10 cm past the anal sphincter and an automated data-acquisition system measured the rectal temperature at 1-s intervals.
Blood sampling schedule. Peripheral blood samples, totaling 21 ml per determination, were drawn through an 18-gauge 5-cm intravenous catheter inserted into the left antecubital vein while the subjects sat quietly at rest (0700) 30 min after fatiguing exercise (~1130) and 30 min after CW (~2000) on days 1 and 8 (Fig. 1). We maintained catheter patency by flushing the device with heparinized saline (10 units/ml). Blood samples were collected into plastic syringes and transferred immediately to prechilled glass tubes containing specific anticoagulant for plasma or nonadditive tubes for serum.
Circulating cytokine assays.
Serum concentrations of IL-1, IL-1ra, IL-6, and TNF- were measured
according to the manufacturer's (Quantikine, R&D Systems, Minneapolis,
MN) instructions, using solid-phase sandwich ELISA kits with
sensitivities of 0.3, 22, 0.7, and 0.2 pg/ml, respectively. Optical
density, with wavelength correction, was read on an automated microplate photometer (EL340, BIO-TEK Instruments, Winooski, VT).
Antibodies and reagents.
Mouse anti-human monoclonal antibodies (mAbs), directly
conjugated with the fluorochromes fluorescein isothiocyanate (FITC) and
phycoerythrin (PE) against the cell-surface epitope CD14-FITC and Fast
Immune anti-human-cytokine mAbs specific for IL-1-PE, IL-1ra-PE,
IL-6-PE, TNF--PE, along with their respective isotype-matched (IgG1
and IgG2a) control mAbs, were obtained from Becton Dickinson Biosciences (San Jose, CA). FACS-brand lysing solution, permeabilizing solution, and CellWASH (optimized PBS containing 0.1% sodium azide) were also obtained from Becton Dickinson Biosciences. Paraformaldehyde, LPS, Escherichia coli 055:B5, and brefeldin A (BFA) were
purchased from Sigma (St. Louis, MO).
Cell preparation and culture. Heparin sodium-anticoagulated whole blood was immediately treated with 60 µl of BFA (at a final concentration of 10 µg/ml) to promote the accumulation of de novo synthesized cytokines within the Golgi apparatus of the synthesizing cell. Next, BFA-treated blood was aliquoted into 12 × 75-mm polystyrene Falcon tubes (Becton Dickinson Biosciences). One milliliter of blood was used for determination of unstimulated or spontaneous intracellular cytokine expression. Elicited cytokine expression was determined by stimulating a second 1-ml aliquot with a predetermined, optimal concentration (1 µg/ml) of LPS dissolved in sterile pyrogen-free PBS, for 4 h in a 5% CO2 humidified atmosphere at 37°C.
Two-color staining for intracellular cytokine production.
For phenotypic determination of CD14+ monocyte frequency,
100 µl aliquots of unstimulated and in vitro LPS-stimulated whole blood were incubated with saturating concentrations of anti-CD14-FITC surface stain for 15 min at room temperature in the dark. Immediately after incubation, cells were treated for 10 min with 2 ml of 1× FACS
lysing solution. After centrifugation (5 min, 500 × g), cell membranes were treated with 500 µl of 1× FACS
permeabilizing solution and incubated for 30 min with anti-cytokine-PE
antibodies against IL-1, IL-1ra, IL-6, and TNF-. After being
incubated and washed with 2 ml of CellWASH, the cell pellets were
resuspended in 300 µl of 2% paraformaldehyde before analysis on a
flow cytometer.
Flow cytometric acquisition and analysis.
Stained cell suspensions were acquired on a dual-laser EPICS XL flow
cytometer (Coulter Electronics, Hialeah, FL) calibrated for two-color
analysis. An electronic acquisition gate was set on CD14+
cells according to FITC emission and 90° side scatter light
scattering. Typically, 
5,000 CD14+
monocyte-gated events were acquired for analysis of the frequency of
intracellular cytokine staining. Analysis gates and quadrant markers
were set to define positive and negative populations for cytokine
production, according to the staining of isotype-matched negative
controls. Results were expressed as the percentage of cytokine-positive
monocytes in unstimulated and LPS-stimulated cultures. Absolute
monocyte counts were obtained by multiplying the corresponding
percentages of CD14+ cells derived from FACS analysis with
the total leukocyte counts derived from a hematology analyzer (Coulter
Electronics). All postexercise values were adjusted for changes in
blood volume according to the equations of Dill and Costill, using
hemoglobin and hematocrit values (16).
Hormonal analyses.
Specimens for catecholamine [epinephrine (Epi) and norepinephrine
(NE)] determination were stored briefly on ice in 4.5-ml tubes
containing EDTA and reduced glutathione (Amersham, Arlington Heights,
IL). The supernatant plasma was separated in a refrigerated centrifuge
for 15 min (4°C; 3,000 × g) and frozen at 
80°C
until assay. Unbound plasma catecholamine concentrations were
quantitated by gas chromatography-mass spectrometry. We
measured total serum concentrations of cortisol, using an IMMULITE
chemiluminescent immunoassay system (Diagnostic Products, Los Angeles,
CA). Postexercise hormone levels were corrected for changes in plasma volume.
Statistical analyses. Two-way repeated-measures (trial × time) ANOVA were used to evaluate differences. When significant F ratios were calculated, Neuman-Keuls post hoc analyses were made to isolate differences among treatment means. Separate stepwise multiple regression analyses were completed for cell counts and circulating and intracellular cytokines, and we compared each of the hormonal responses (independent variables) to each of the cellular subsets or cytokines (dependent variables). Data are presented as means ± SE, and the level of statistical significance was set at P < 0.05 for all analyses.
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RESULTS |
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TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES
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Thermal response. Cold exposure times averaged 5.2 ± 1.1 and 4.8 ± 1.3 h on days 1 and 8, respectively. Before entering the cold chamber on these days, the subjects had mean rectal temperatures (Tre) of 37.1 ± 0.25 and 37.2 ± 0.25°C, respectively. Tre declined significantly during cold exposure on each day (day 1, 36.89 ± 0.86; day 8, 36.9 ± 0.78°C). Tre was significantly higher in the second and third hours of cold exposure on day 8 compared with day 1, with no difference between trials for the last 3 h of exposure. Details of subject attrition, cold tolerance, and other thermoregulatory responses have been reported elsewhere (11).
Total leukocyte and monocyte counts.
Resting (0700) leukocyte (4.96 ± 1.65 × 109/l)
and monocyte (0.39 ± 0.13 × 109/l)
concentrations on day 1 were within reported normal ranges (Table 1), and values remained unchanged
on day 8, after 1 wk of exhausting exercise. Total leukocyte
[F(2,16) = 34.8, P = 0.0001] and monocyte [F(2,16) = 10, P = 0.002] counts showed significant main effects for
time. Significant trial × time interaction effects were also
detected for both cell subsets. Post hoc analyses showed elevated
leukocyte (6.82 ± 1.28 × 109/l) and monocyte
(0.54 ± 0.11 × 109/l) counts postexercise on
day 8 (1130) compared with day 1 and with resting
values (0700) within trials. After the 6-h CW (2000), leukocyte
(12.4 ± 3.97 × 109/l) and monocyte ( 0.72 ± 0.33 × 109/l) counts were significantly
elevated on both days 1 and 8, with no
differences between trials.
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Circulating cytokine concentrations.
Spontaneous serum cytokine concentrations were low in resting subjects
on day 1 (Fig. 2). TNF-
levels were below detection limits at 0700 on day 1, and
IL-1 remained undetectable throughout the study. There were no
significant differences between resting cytokine values on days 1 and 8. Significant main effects of time were found for
IL-1ra [F(2,14) = 31.7, P = 0.0001], IL-6 [F(2,14) = 32.3, P = 0.0001] and TNF-
[F(2,14) = 17.6, P = 0.001]. Circulating cytokine levels did not change when subjects were
at rest at 1130 on day 1. Exercise on day
8 (1130) led to significantly increased concentrations of IL-1ra
(804 ± 250 pg/ml), IL-6 (9.4 ± 2.1 pg/ml), and TNF-
(3.2 ± 0.7 pg/ml). Similarly, the CW on day 1 increased concentrations of all three cytokines (all
P < 0.0001). On day 8, the CW further
augmented IL-1ra (1 238 ± 414 pg/ml) and IL-6 (13.8 ± 6.2 pg/ml) concentrations but caused TNF- levels to return to baseline.
Significant interaction effects were obtained for IL-1ra
[F(4,28) = 3.7, P < 0.05], IL-6 [F(4,28) = 9.5, P < 0.05], and TNF-
[F(4,28) = 39.8, P = 0.001], with intertrial differences isolated to the 1130 and 2000 time
points.
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Intracellular cytokine expression.
Constitutive and induced intracellular IL-1, IL-1ra, IL-6, and
TNF- production by BFA-treated whole blood samples are shown in Fig.
3. The percentage of cytokine-positive
monocytes spontaneously exhibiting expression of all four cytokines by
unstimulated CD14+ monocytes was low in resting (0700)
subjects on day 1. Positive staining for IL-1 (2.8 ± 1.4%) and IL-1ra (4.7 ± 1.5%) was greater than for IL-6
(2.3 ± 0.8%) and TNF- (2.1 ± 1.3%). Significant main
effects across time were observed for IL-1
[F(2,12) = 37.8, P = 0.0001], IL-1ra [F(2,10) = 17.6, P = 0.001], IL-6 [F(2,8) = 11, P = 0.005], and TNF-
[F(2,8) = 8.5, P = 0.01]. Relative to unstimulated samples, 4 h of LPS stimulation
(1 µg/ml) increased the percentage of cytokine-producing monocytes
several thousandfold at all time points (P < 0.0001).
Neither stimulated (LPS+) nor unstimulated (LPS) cultures showed any
differences in cytokine expression at 1130 on day 1 relative
to initial values (0700). After the CW (2000) on day 1, the
percentages of IL-1ra (8.5 ± 2.8%), IL-6 (7.6 ± 1.8%),
and TNF- (3.3 ± 0.5%) among unstimulated CD14+
monocytes were significantly increased, but there was no change in
unstimulated intracellular IL-1 expression.
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levels (6.5 ± 1.3%) were significantly elevated relative to
day 1, but resting expression of the other three cytokines
was unchanged. Acute exercise increased the expression of all four
cytokines in unstimulated samples (Fig. 3). The CW further enhanced
IL-1ra expression (12 ± 3.7%); in contrast, cold exposure caused
a significant reduction in the expression of unstimulated IL-1
(1.1 ± 0.5%), and TNF- expression dropped below baseline by
the end of the CW on day 8. Both exercise and the CW
significantly increased the ex vivo capacity of LPS-stimulated whole
blood cultures to form IL-1 and IL-6, but exercise in the cold
suppressed TNF- (67.8 ± 6.6%) formation on day 8.
The intracellular expression of IL-1ra was consistently higher (90%)
than that of other cytokines in response to LPS challenge but was
unaltered by either acute exercise or the CW. In contrast to
unstimulated IL-6 expression, LPS-stimulated production of IL-6 was
increased slightly (70.3 ± 7.9%) at rest on day 8.
Circulating hormone concentrations.
Resting NE and Epi concentrations were comparable between trials (Fig.
4). However, there were significant main
effects for NE [F(2,16) = 49.8, P = 0.0001], Epi
[F(2,16) = 38.9, P = 0.0001], and cortisol [F(2,16) = 11.4, P = 0.001] over time. Post hoc analysis traced the
differences in catecholamines to significant elevations of both NE and
Epi after the CW on both days 1 and 8. Neither NE
nor Epi showed significant trial × time interaction effects. However, a significant interaction effect
[F(4,24) = 4.2, P = 0.04] was found for circulating cortisol. Peak cortisol values occurred in the early morning (0700) on both days 1 and
8, with values dropping significantly by 1130. Compared with
resting preexposure values on day 1, the CW conditions
stimulated cortisol secretion significantly on both days 1 and 8. No intertrial differences were found between 1130 and
2000 sample times. However, significantly elevated resting (0700)
cortisol levels were observed on day 8 compared with
day 1.
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Regression analyses.
Relationships among serum hormone concentrations, cell counts, and
intracellular and circulating cytokines derived by stepwise multiple
regression are presented in Table 2. The
proportion of total variance (R2) attributed to
changes in concentrations of Epi and NE ranged from 38-49% for
circulating cell counts and 34-40% for intracellular cytokine
expression. Intracellular IL-6 was the only cytokine whose expression
was significantly (R2 = 0.342, P = 0.02) related to serum cortisol levels.
Circulating IL-6 concentration was also positively associated
(R2 = 0.261, P = 0.04) with
NE, but changes in IL-1ra and TNF- levels were unrelated to any
hormone concentrations. Simple linear regression analyses identified
positive correlations between intracellular expression and circulating
concentrations of IL-1ra [r = 0.668, P = 0.002, 7 degrees of freedom (df)] and IL-6 (r = 0.504, P = 0.03, 7 df) postexercise. No relationship
was observed between intracellular and circulating TNF- levels, but
increases in intracellular IL-6 after exercise showed a strong positive
association with intracellular IL-1ra expression (r = 0.759, P = 0.0003, 7 df).
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DISCUSSION |
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TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES
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This report demonstrates that physical exercise triggers human
peripheral blood monocytes to express enhanced levels of IL-1, IL-1ra, IL-6, and TNF- and that upregulated intracellular expression of inflammation-associated cytokines mainly corresponds with their increased serum concentrations. We have also shown that prolonged exposure to cold, wet environmental conditions differentially modulates
cytokine expression. Furthermore, our findings provide evidence to
suggest that changes in sympathoadrenal activation are linked to
exertional and cold-induced modification of these cytokine production profiles.
Although numerous sources of cytokines have been identified in vitro,
relatively few studies involving exercise have attempted to identify
the origin of cytokines in vivo (4, 43). Previous research
has been limited mainly to bulk ELISA measurements of IL-6, TNF-,
IL-1, and more recently IL-1ra in the circulation (9, 25, 37,
39), culture supernatants (15, 18, 47), and urine
(52, 58). Unfortunately, such studies measure only integrated accumulation of secreted cytokines, reflecting the net
outcome of produced, absorbed, and degraded molecules within biological
fluids (12). Furthermore, this type of analysis gives no
indication of the cells responsible for cytokine production (46). Even sensitive RT-PCR methods provide no information
about the contribution of single cells to cytokine production in
heterogeneous cell populations, and cytokine mRNA transcription rates
do not necessarily reflect translation of the message into secreted
protein (21, 36, 38). By comparison, intracellular
cytokine detection by flow cytometry offers the advantages of providing
rapid and sensitive determination of the relative cytokine production
profiles of distinct cell subsets, avoiding many problems inherent to
soluble cytokine measurements, such as the release of natural cytokine inhibitors (33, 41).
The principal finding of this report was that flow cytometric
quantification of whole blood intracellular cytokine expression by
unstimulated CD14+ monocytes revealed significant
postexercise increases in the frequency of monocytes expressing each of
the four cytokines assayed. The greatest exercise-associated increases
were detected for intracellular expression of IL-6 and IL-1ra, followed
by IL-1 and TNF-. These findings provide the first direct
evidence that blood monocytes can be a source of circulating
inflammatory cytokine production with exercise. In accordance with our
results, previous human studies (28, 49) have indicated
that among circulating immunocytes, unstimulated CD14+
monocytes are the primary source of these inflammatory-associated cytokines in vivo. Such conclusions are strengthened by the close correlations observed between spontaneous intracellular expression of
IL-6 and IL-1ra and between intracellular expression and circulating concentrations of these cytokines. Furthermore, our ex vivo findings that exercise increased circulating IL-6 and TNF- levels by 273 and
83%, respectively, are consistent with the literature showing proportionally greater elevations of IL-6 than TNF- (25, 31, 39). Similarly, the marked elevation (113%) of circulating
IL-1ra observed postexercise is in agreement with prior exercise
studies (18, 37, 39). The fact that we observed
significant intracellular expression of IL-1 in the absence of a
circulating rise in this cytokine implies that, although local
monocytic IL-1 production is enhanced shortly after exercise, its
systemic accumulation may be prevented by rapid catabolism and/or
competition with circulating IL-1 antagonists (13, 20,
47). Supporting the importance of such localized cytokine
production, upregulated IL-1 and IL-6 expression has been found in
isolated skeletal muscle preparations after exercise (10, 40,
53). However, it remains unclear whether infiltrating monocytes
or active myofibrils themselves are the primary source of these
cytokines within muscle (27, 51).
Our study demonstrates that fatiguing exercise significantly enhances
LPS-stimulated intracellular expression of IL-6 and TNF--positive
monocytes. This observation supports earlier in vitro data showing that
exercise does not significantly impair cytokine synthesis in response
to LPS challenge (4, 15, 38, 58). In contrast,
LPS-stimulated production of IL-1ra was unchanged by our experimental
treatment, which probably reflects the excess capacity of monocytes to
produce IL-1ra even under basal conditions (17).
The modest elevation in CD14+ monocytes (~50%) that was detected postexercise is comparable to observations from other studies measuring cellular redistribution with similar exercise designs (7, 45). Typically, monocytes are deployed rapidly from the marginal pool into the circulation during the first minutes of strenuous exercise (23), but their numbers drop quickly on cessation of activity (7). Under the current protocol, prolonged cold exposure substantially magnified the extent of monocytosis (~100%), regardless of whether or not the subjects had performed prior fatiguing exercise. Such cold-enhanced recruitment of monocytes has been previously documented in humans (9, 30) and is presumably mediated by pronounced SNS activation accompanying prolonged cold stress. This activation may influence cell mobilization through indirect adjustments in hemodyamics or via direct receptor-mediated alterations in cellular adhesive properties, thereby affecting cell mobilization (19). In sum, these findings strengthen the hypothesis that strenuous exercise selectively mobilizes those monocytes with an enhanced functional capacity (23, 54).
Another important finding of this investigation is that when fatiguing
exercise preceded cold exposure, the spontaneous intracellular expression of IL-1 and TNF- was substantially reduced.
Furthermore, in vitro intracellular monocytic expression of
TNF- and its serum levels were also markedly suppressed
in response to LPS challenge after cold exposure. Such results are
consistent with results of a recent study (20)
demonstrating a blunted secretion of IL-1 and TNF- by monocytes
cultured at 32°C compared with levels at 37°C. By comparison, we
found unstimulated expression of IL-1ra and IL-6 to be enhanced after
cold exposure. This agrees with our previously reported finding that
short duration, moderate cold-air exposure (2 h, 5°C) in a climactic
chamber elicits significant plasma elevations of IL-6 in resting
subjects (9), consistent with a report of higher IL-6
levels in healthy volunteers after they swam in ice-cold water
(19). Others have found that short-term exposure to cold
air (1 h, 11°C) or cold water (1 h, 14°C) has no effect on systemic
IL-1 or IL-6 release (30, 35), although it does augment
circulating TNF- production (30). On the
other hand, studies of perioperative and accidental hypothermia have demonstrated that surface cooling to a core temperature of
34-30°C suppresses systemic IL-1 and IL-6 production after
surgery or traumatic injury, respectively (1, 5). By
contrast, a recent case study of two extreme hypothermia (core
temperature 28°C) victims reported greatly augmented circulating
IL-6 levels on admission to the hospital (1).
Thus it appears that different mechanisms of cytokine induction may be
operative in moderate vs. severe cold exposure.
The mechanism underlying the abovementioned differences in cytokine generation is not clear, but it can be argued that cold-associated modulation of cytokine production may be related to induction of systemic endotoxemia, provoked by alterations in central hemodynamics and stress hormone release associated with enhanced thermoregulatory demands. In support of this notion is the observation that moderate cold exposure leads to a sharp reduction in splanchnic blood flow and ischemia (24) that promotes translocation of LPS into the systemic circulation (26). Also, on rewarming, the potential for even greater endotoxemia exists due to transient splanchnic reperfusion (24). Moreover, cold exposure may further exacerbate such effects via enhanced sympathoadrenal activation (48) and/or by directly augmenting the biological activity of LPS (32). Based on this evidence, we hypothesize that under the current experimental conditions, cold exposure is likely to have facilitated endogenous cytokine release by LPS-activated circulating monocytes.
Although the present data support the view that circulating monocytes
can be a source of cytokines with exercise, they do not per se exclude
other immune and/or accessory cells as potential contributors to
overall cytokine production. In fact, our findings contradict previous
in vitro studies that failed to demonstrate exercise-induced changes in
the expression of monocytic mRNA and/or protein levels of IL-1,
IL-6, and TNF- (40, 47, 55). Such findings have led
some investigators (4, 37, 43) to speculate that
noncirculating cells, including vascular endothelium, hepatocytes, and/or fibroblasts, may be chiefly responsible for the enhanced secretion of these cytokines with exercise. Inconsistencies concerning the capacity of exercise to elicit monocytic cytokine production may
be, at least partially, attributable to methodological differences between studies. For example, compared with previous experiments, the
extremely fatiguing exercise regimen used in the current model may have
provided a stronger stimulus for monocyte activation and thereby
greater cytokine synthesis. In addition, the sensitivity of
intracellular flow cytometric techniques for enumerating
cytokine-producing cells is superior to earlier methodologies
(33). Finally, our use of whole blood, rather than
isolated mononuclear cells, more reliably simulates the complex in vivo
cellular and humoral milieu (14).
Data from the present study showing significant correlations between
circulating hormones and cytokine expression appear to support an
important role for reciprocal interactions between neuroendocrine and
immune systems (22) in the maintenance of homeostatic
balance between pro- and antiinflammatory cytokine responses
(17). For instance, IL-6 is induced along with other cytokines during the inflammatory cascade but does not mediate proinflammatory symptoms (46). Instead, IL-6 activates the
HPA axis and induces the upregulation of cortisol and IL-1ra that in
turn suppresses the synthesis of monocytic IL-1, TNF-, and IL-6
(17), thereby controlling the extent of local and systemic inflammatory responses. In this study, the positive correlation observed between circulating IL-6 levels and NE also agrees with previous findings that exercise- and cold-induced catecholamine secretion is closely related to systemic IL-6 release (9,
42). Likewise, the positive association of NE and Epi
concentrations with monocytic IL-6 and IL-1ra expression, but negative
association with IL-1 and TNF-, suggests that cytokine production
may be differentially regulated by circulating catecholamines during exercise and cold exposure.
In conclusion, flow cytometric detection of intracellular cytokines has
proven to be a useful tool to study cytokine expression at the single
cell level, thus improving our understanding of the cellular sources of
cytokines during physical stress. The present findings demonstrate that
blood monocytes are a source of IL-1, IL-1ra, IL-6, and TNF-
production after acute strenuous exercise. In addition, prolonged cold
exposure was shown to differentially modulate cytokine production,
upregulating the expression of IL-6 and IL-1ra but downregulating that
of IL-1 and TNF-. Secretion of sympathoadrenal hormones was
significantly associated with the changes in both circulating and
intracellular cytokine profiles. These findings suggest that multiple
interactions between cytokines and neuroendocrine hormones are likely
involved in the physiological response to exertional fatigue and cold
and may serve to limit the severity of the host inflammatory response.
Because the application of intracellular cytokine flow cytometry is a
novel approach to studying exercise and thermally mediated cytokine
modulation, future research is warranted to investigate the possible
contribution of additional immunocytes and/or immune accessory cells to
such responses.
Perspectives
The molecular signaling pathways involved in exercise- and/or thermal stress-induced cytokine alterations remain largely unknown. The current findings are consistent with studies indicating that adrenergic/noradrenergic mechanisms are intimately involved in the regulation of cytokine production under various forms of physical stress (3). Monocytes express both- and
-adrenergic receptors, and binding of Epi/NE can activate or inhibit
different signal transduction pathways (44). The
stimulation of 2-adrenoceptors during stress attenuates
excessive synthesis of proinflammatory cytokines (IL-1, TNF-) and
elevates antiinflammatory cytokines (IL-6, IL-1ra, IL-10) via increased
cAMP (44, 59). However, activation of
2-adrenoceptors is associated with reduced cAMP levels
and enhances proinflammatory cytokine synthesis (57). In
this context, the current observations showing that cold exposure elicited differential changes in IL-1 and TNF- suggest that -adrenergic mechanisms were able to prevail after cold stress on
day 1. In contrast, cold exposure on day 8 decreased monocytic TNF- and IL-1 but stimulated IL-1ra
expression, indicating that -adrenergic mechanisms may have
predominated when cold stress was preceded by fatiguing exercise.
Alternatively, it is conceivable that exhausting exercise for 7 days
may have altered monocytic adrenoceptor density (3),
thereby reducing the capacity for excessive synthesis of
proinflammatory cytokines but enhancing antiinflammatory cytokines
after cold exposure. Conclusive evidence for such cold-evoked,
SNS-associated modulation of cytokine expression must await future
studies that interdict specific steps in the signaling pathways leading
to cytokine induction.
| |
ACKNOWLEDGEMENTS |
|---|
The authors are grateful to D. Stulz, J. Balcius, J. Staab, M. Mayo, S. Petrongolo, and D. Saunders for their technical assistance and to M. Sawka for generous support of this research.
| |
FOOTNOTES |
|---|
Address for reprint requests and other correspondence: P. N. Shek, Biomedical Sciences Sect., Defence and Civil Inst. of Environmental Medicine, 1133 Sheppard Ave. W., Toronto, Ontario M3M 3B9, Canada (E-mail: pang.shek{at}dciem.dnd.ca).
The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
Received 11 October 2000; accepted in final form 27 February 2001.
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REFERENCES |
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TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
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; day 8, 
), after
exercise (day 8, 
), and after the cold-wet
(CW) exposure (day 1, 
; day 8,
). Values are means ± SD for n = 9 men. *Significant within-trial differences vs. resting (0700) values,
P < 0.05; 
significant intertrial differences
day 1 vs. 8 values, P < 0.05. Note: circulating IL-1
