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Influence of exercise and ethanol on cholinesterase activity and lipid peroxidation in blood and brain regions of rat
Reg.
ELSEVIER
NeumPsyc~pphnrmacd.
& Bti. Psyhiat. 1997, Vol. 2 1, pp. 059-670 Copyright 0 1997 Elsevier Sdence Inc. Printed in the USA. All rights reserved 0276-5646/97 $32.00 + .oO
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INFLUENCE OF EXERCISE AND ETHANOL ON CHOLINESTERASE ACTIVITY AND LIPID PEROXIDATION BLOOD AND B&UN REGIONS OF RAT
IN
KAZIM HUSAIN and SATU M. SOMANI Southern Illinois University School of Medicine Department of Pharmacology Springfield, IL, USA (Final form - January, 1997)
Abstract Husain, Kazim and Satu M. Somani: Influence of exercise and ethanol on cholinesterase activity and lipid peroxidation in blood and brain regions of rat. Prog. Neuro.-Psychopharmacol. & Biol. Psychiat. 1997,a: pp. 659-670. 0 1997 Elsevier Science Inc. 1. This study elucidates the interaction of acute exercise and single ethanol intake on cholinergic enzyme and its relationship to lipid peroxidation in the blood and brain regions of the rat. 2. Butyrylcholinesterase (BuChE) in plasma and acetylcholinesterase (AChE) in brain regions as well as lipid peroxidation (MDA) were assayed in 1) sedentary control rats; 2) after acute exercise (100% VO1,,,); 3) ethanol 20% (1.6 gm/kg, p.0.); 4) exercise and then ethanol 20% (1.6 gm/kg, p.0.). 3. Acute exercise significantly increased BuChE activity (155% of control) in plasma and decreased AChE activity (60% of control) in the corpus striatum with a significant increase in the striatal MDA level (254% of control). Ethanol significantly decreased AChE activity only in striatum (86% of control) with a significant increase in striatal MDA level (132% of control). 4. The combination of exercise and ethanol 20% (1.6gm/kg, p.0.) significantly increased BuChE activity (123% of control) in plasma, and decreased AChE activity (76% of control) in striatum with significant increase in striatal MDA level (147% of control). 5. Acute exercise, single ethanol 20% (1.6 grn/kg, p.o.) intake and the combination selectively inhibited striatal AChE, and the inhibition was correlated with increased lipid peroxidation indicating perturbation of motor function. The combination reduced the peripheral stress response caused by exhaustive exercise. Keywords: acetylcholinesterase. -2: cholinesterase
brain regions, butyrylcholinesterase,
acetylcholinesterase (AChE), acute exercise (ChE), ethanol (Et), malondialdehyde (MDA)
ethanol, exercise, lipid peroxidation
(AE),
butyrylcholinesterase
(BuChE),
Introduction Earlier studies reported that physical exercise enhances the inhibition of cholinergic by cholinesterase
inhibitor (physostigmine)
enzymes elicited
in cerebral and peripheral tissues of the rat (Dube et al, 1990;
Dube et al 1993; Somani et al, 1991). Exercise is known to cause oxidative stress on the nervous syste659
660
K. Husam and S.M. Somani
and increase the lipid peroxidation neuronal
membrane
permeability.
(Somani, 1994; Somani et al, 1996). which may lead to alteration in Similarly,
ethanol has also been reported to be stressful
(Tabakoff et al, 1978) and exerts an oxidative Nordmann.
1987).
Ethanol after ingestion
stress response
to mice
on the nervous system (Bondy,
is quickly absorbed
from the gastrointestinal
1992;
lumen into
circulation and can readily cross the blood brain barrier entering the areas of the brain (Ritchie, 1985). Due to high lipid solubility, ethanol also changes the permeability and fluidity of the synaptic membrane as well as the activities of membrane bound enzymes (Collins et al, 1984; Lasner et al. 1995; Sun and Smorajski. 1970).
Acetylcholinesterase
is a membrane bound enzyme with lipid dependence (Lasner et al. 1995: Ott, 1985).
and its distribution is different in specific brain regions (Appleyard et al. 1986: Husain and Vi.jayaraghavan, 1989; Somani et al, 1991); ethanol may likely influence the enzyme activity in a differential
pattern.
brain utilizes 20% of the oxygen consumed by the body, contains high levels ofperoxidizable low levels of antioxidants. hypothesis
It may actually be more vulnerable to peroxidative
is that acute exercise, single ethanol intake, and the combination
peroxidation
of neural membranes
damage.
The
lipids and
Therefore. the
are likely to influence lipid
and of the membrane bound acetylcholinesterase
enzyme in specific
brain regions. Each region of the brain has different responses to exercise (Somani et al. 199 1; Somani et al, 1995) or ethanol (Rawat. 1976; Somani et al. 1996) because each region has a separate level of peroxidizable
unsaturated lipids (Nordmann,
enzymes (Appleyard
1987; Somani et al., 1996: Uysal et al, 1989). cholinergic
et al, 1986; Somani et al, 1991). and cholinergic
innervation
(Arneric et al.. 1990:
Eckstein et al, 1988; Matin and Husain, 1985). Thus each brain region may receive a different amount of stress.
There is a paucity of information
concerning
the interaction
of exercise
cholinergic system. Only a few reports have demonstrated the influence ofethanol
and ethanol on the
on exercise performance
in human (Blomquist et al, 1970; Houmard et al. 1987; Kendrick et al. 1993: Side11 and Pless. 1971). Since exercise
and ethanol have been known to cause an oxidative
cholinergic system (Bondy, 1992: Hashem-Zadeh-Gargari
stress response
and interact with the
and Mandel. 1989; Somani et al, 199 1; Somani,
1994; Somani et al. 1995), it is essential to study the interactive effects of both on membrane-bound and lipid peroxidation
in brain regions of rat. Therefore, the specific aims of this study were:
determine whether acute exercise. single ethanol intake. and the combination influence
the cholinesterase
activity in the blood and sub-regions
correlation between cholinesterase rat.
AChE 1) to
of these two stressors would
of the brain; and 2) to establish
enzyme activity and lipid peroxidation
a
in specific brain regions of the
Exercise, ethanol/cholinesterase
661
Methods
Acetylthiocholine
iodide. butyrylthiocholine
iodide and 5’,5’ - dithiobisnitrobenzoic
acid were obtained
from the Sigma Chemical Co. (St. Louis, MO). Coomassie protein assay reagent was purchased from the Pierce Co. (Rockford, IL). _Animals Adult male Fisher-344 rats weighing 205-230 gm from Harlan Industries (Indianapolis, in this study. The rats were acclimatized for 5 days to the facility prior to starting
IN) were used
the experiments.
were fed ad libitum with Rodent Laboratory Chow (Ralston Purina Company, Indianapolis,
Rats
IN) and tap
water. Rats were randomly divided into four groups and treated as follows:
I.
Sedentarv Control (SC): of inclination minutes
Six rats were put on the treadmill belt at a speed of 2 m/min and 0”angle
in the Omnipacer
for equivalent
treadmill (Omnitech
handling.
Electronics,
Inc., Columbus,
OH) for five
They received equivalent volume of normal saline orally via
orogastric tube. II.
Acute Exercise (AE): Four rats were acutely exercised on the treadmill at 100% VOZmax.The speed of the belt and angle of inclination were increased gradually from 8.2 m/min to 30.3 m/min and from 0” to 12.5”, respectively,
as described earlier (Dube et al, 1990; Dube et al, 1993; Somani et
al, 1991). The oxygen consumption
and heat production
Oxyscan System (Omnitech Electronics,
III. Ethanol (Et):
in individual rats were recorded by the
Inc.).
Four rats were given ethanol 20% (v/v) at a dose of (1.6 gm/kg, p.o.) via orogastric
tube. IV. Acute Exercise and Ethanol (AE + Et): Six rats were exercised on the treadmill as described in group II and 5 min after exercise, animals were given ethanol as described in group III . Rats in all the groups were sacrificed 30 min post treatment by decapitation
between 9:00-l 1:OOa.m.
to minimize the Circadian cycle effects. Preparation of Tissue Extract: Blood was collected in heparinized vials and centrifuged at 1000 rpm for 10 min to separate the plasma. cerebellum, immersed
Heads were collected in ice water and brain regions - cerebral cortex,
medulla, corpus striatum and hypothalamus in liquid nitrogen and stored at -80°C.
were isolated.
Brain regions were immediately
Brain regions were homogenized
phosphate buffer (pH 7.0) containing 0.1 mM EDTA to give 5% homogenate
(“‘/J.
in cold 50 mM
K. Husain and S.M. Somani
662
Enzvme Assays Acetylcholinesterase
(EC 3.1.1.7): Its activity was determined
method of Ellman et al. (1961).
In a cuvette.
in brain regions according to modified
100 ul of tissue extract was added to 780 Pl of 0.1 M
phosphate buffer pH 8. One hundred ~1 of 0.01 M dithiobisnitrobenzoic
acid (in 0.1 M phosphate buffer
pH 7.0) was added to the cuvette. The reaction was started after the addition of 20 pl of acetylthiocholine as a substrate, and optical density was recorded at 4 I2 nm every 30 seconds up to 4 minutes using a Hitachi U-2000
spectrophotometer.
computerized
The
program.
hydrolyzed/min/mg
The change in optical density enzyme
activity
was
and enzyme
expressed
activity was calculated
as umoles
by
of acetylthiocholine
protein.
Butyrylcholinesterase
(,EC 3. I. I .8): Its activity was determined
in plasma by the modified method of
Ellman et al. (1961). In a cuvette containing 920 ul of 0.1 M phosphate buffer (pH 8), 10 ~1 of plasma and 50 u1 of 0.01 M dithiobisnitrobenzoic started with the addition.of
acid (in 0.1 M phosphate buffer pH 7) was added. The reaction was
20 ~1 of 0.075 M butyrylthiocholine
as substrate and optical density was
recorded at 4 I2 mn every 30 set up to 4 minutes. The change in optical density per minute and the enzyme activity was calculated by a computerized butyrylthiocholine
hydrolyzediminlmg
Linid Peroxidation
Assav
program.
The specific activity was expressed
as pmoles of
protein.
This assay is used to determine malondialdehyde
(MDA) level as described by Ohkawa et al. (1979).
Two hundred ul of tissue homogenate was added to 50 ~1 of8.1% sodium dodecyl sulfate (SDS), vortexed, and incubated for IO minutes at room temperature. 3.5) and 375 pl ofthiobarbituric
Three hundred seventy five pl of 20% acetic acid (pH
acid (0.6%) were added and placed in a boiling water bath for 60 min. The
samples were allowed to cool at room temperature, vortexed and centrifuged at 1000 RPM for 5 minutes.
then 1.25ml of butanol:
pyridine (15: 1) was added.
Five hundred u1 of the colored layer was measured
at 532 nm using 1.1.3.3-tetraethoxypropane as a standard.
Protein Assay Protein in plasma and tissue homogenate was determined by the method of Read and Northcole (1981) using bovine serum albumin as standard.
Data Analvsis Data were expressed as mean i S.E.M. and analyzed using one way analysis of variance (ANOVA) and group comparisons
by Tukey’s studentized
Range Test at significant level 0.05.
Exercise, ethanol/cholmesterase
663
Results The effect of acute exercise (AE), ethanol (Et) and the combination cholinesterase
activity
butyrylcholinesterase
of the rat is depicted
in Table
1.
of both (AE + Et) on plasma
AE significantly
increased
plasma
(BuChE) activity (155% of control) (F = 3 1.5, p
plasma BuChE activity.
The combination
of AE and Et significantly
increased plasma BuChE activity
(123% of control) (F = 15.4, pcO.05). Table 2 shows the effect of AE. Et and the combination (AE + Et) on AChE activity in brain regions of the rat. AE significantly
decreased
AChE activity in the corpus striatum (60% of control) (F = 25.8,
p
The combination
of AE and Et resulted in a significant decrease in AChE activity
in the corpus striatum (76% of control) (F = 21.5, p~O.001) whereas enzyme activity did not significantly change in other brain regions (Table 4).
Table 1 Effect of Acute Exercise (100% VOZmax)and Ethanol (1.6 gmkg, p.o.) Ingestion on Butyrylcholinesterase Activity in the Plasma of Rats.
Groups
Butyrylcholinesterase Activity * (Piasma)
Percent Increase
1. Sedentarv Control (n=6)
3.88 * 0.17
-___
2. Acute Exercise (n=4)
6.01 * 0.30a
55
3. Ethanol (n=4)
4.06 f 0.18
5
4.78 f 0.37b’C
23
4. Acute Exercise + Ethanol (n=S)
Data are mean + SEM; *b.tmoles butyrylthiocholine hydrolyzed/min/mg protein; a - significantly different from group 1 (p < 0.01); - significantly different from group 1 (p < 0.05); ’ - significantly different from group 2 (p < 0.05)
664
K. Husam and SM. Somani Table 2 Effect of Acute Exercise ( 100% VOrma,) and Ethanol (1.6 gm/kg, p.o.) Ingestion on Acetylcholinesterase Activity in Brain Regions of Rats, Brain Regions (acetylcholinesterase Cerebral Cortex
Groups
Corpus Striatum
Medulla
activity)*
Cerebellum
Hypothalamus
1. Sedentary Control (n=6)
18.20i I.55
68.83t 2.68
49.69+ 4.07
21.62+ 1.79
43.78* I.75
2. Acute Exercise (n=4)
15.12* 0.75 (-17%)
41.3I"i 3.21 (-40%)
38.41-t3 71 (-23%)
22.99+ 3.13 (+6Oa)
41.97 Ik1.50 (-4%)
3. Ethanol (n=4)
22.62+ 1.69 (+24%)
59.00bgd i 2.24 (-14%)
59.51'* 7.79 (+20%)
19.80+ 1.68 (-8%)
49.42i 3.48 (+13%)
4. Acute Exercise + Ethanol (n=5)
?3.01'+ 1.69 (+26%)
52.42"e'f+1.37 54.31f 7.12 (-2496) (+9%)
21.64i 1.23 (0%)
48.08t4.59 (+lo%)
Data are mean * sem; * bumoles Acetylthiocholine hydrolyzediminimg protein: ’ - significant (p i 0.01) ‘.; - significant (p < 0.02) compared to group 1; ’ - significant (p < 0.01) compared 1 - srgnn‘icant (p i 0.01) compared with group 2; e - significant (p < 0.02) compared with group 2; ’ - significant (p < 0.05) compared with group 3: g - significant (p < 0.05) compared with group 2; Values in parentheses indicate percent change (+) increase and (-) decrease ;;Tgy;pw;,hpup
The changes in lipid peroxidation (MDA) due to AE, Et, and AE + Et in plasma and brain regions of the rat is presented
in Table 3. No significant
exercise or the combination
ofAE
change in the plasma MDA level was observed after acute
and Et. However, the MDA level decreased slightly (79% of control)
in the plasma after Et treatment. AE significantly elevated MDA levels in corpus striatum (254% of control) (F = 46.87, p
(F = 13.5, p
increased the MDA level in the corpus Striatum (132% of control) (F = 15.2. p
MDA level did not significantly
alter in other brain regions.
increased the MDA level in the corpus striatum (153% significantly
of control)
of
The combination
of AE + Et significantly
control) (F = 34.5, pLO.02) while it did not
change in other brain regions (Table 4).
Discussion This is the first report delineating
the combined effect of acute exercise (physical stress) and ethanol
ingestion (chemical stress) on ChE activity in blood and brain regions of the rat and their relationship lipid peroxidation.
The data indicate that acute exercise alone significantly
to
increased BuChE activity in
plasma and decreased AChE activity in the corpus striatum without affecting other brain regions.
BuChE
Exercise,
is a nonspecific cholinesterase
ethanol/cholinesterase
which is synthesized
665
in the liver (Augustinsson
and Nachmansohn,
1949).
Physical exercise is a stress factor that is known to evoke a number of metabolic and enzymatic changes in the liver and muscle (Booth and Thompson.
1991; Davies et al, 1982). Thus, the increased plasma
BuChE activity may be a secondary effect of labilization of lysosomal membranes of liver cells and leakage of enzyme in the blood after exhaustive exercise.
The present findings are consistent with other reports
(Pawlowska et al. 1985; Ryhanen et al. 1988).
Table 3 Effect of Acute Exercise (AE), Ethanol (Et) and AE + Et on Lipid Peroxidation Brain Regions of the Rat.
(MDA) in Plasma and
Lipid Peroxidation (Malondialdehyde)’ Brain Regions Cerebral Cortex
corpus Striatum
Medulla
Cerebellum
Hypothalamus
Plasma
157.03*14.47
240.83*41.15
237.25128.24
130.4317.7
67.74+6.11
53.61&6.75
2. Acute Exercise (n=4)
206.61c*l 1.68 (+32%)
510.57p&38.68 (+I 54%)
329.55’+38.68 (+39%)
140.37*17.72 (+8%)
78.67i4.92 (+16%)
60.54h2.94 (+7%)
3. Ethanol (n=4)
202.04*50.68 (+29%)
316.80c’di20.10 (+32%)
304.40*3 1.64 (+28%)
137.25h8.70 (+5%)
77.12il3.71 (+14%)
42.6li6.06 (-2 I o/b)
4. Acute Exercise + Ethanol (n=5)
185.851t26.09 (+lS%)
367.74b’e*10.13 (+53%)
273.82+6.88 (+15%)
148.48*5.39 (+14%)
79.39i12.94 (C17%)
56.20+8.75 (+5%/o)
Groups I. Sedentary Control (n=6)
Data are mean f SEM; * - nmoles MDA/g tissue or ml of plasma; ’ - significant (p < 0.01) compared with groupl;bsignificant (p < 0.02) compared with group 1; ’ - significant (p < 0.05) compared with group 1; d - significant (p < 0.01) compared with group 2; e - significant (p < 0.02) compared with group 2; Values in parentheses indicate percent change (+) increase and (-) decrease
K. Husatn and SM. Somani
666
Table 4 Correlation of AChE Activity with Lipid Peroxidation
in Different Brain Regions of Rat
AChE Activity Brain Regions
AE
Et
Medulla
I
1
Cerebellum
I
I
Lipid Peroxidation AE+Et
(MDA)
AE
Et
tt
t
f
I
T
r
I
1
T
AE+Et
Cortex Striatum
I
t Hypothalamus 1 Tor 1 = increase or decrease is not significant;
T
1T or 1I = increase or decrease is significant
AE = Acute Exercise’ Et = Ethanol
Conversely, AChE activity decreased only in the corpus striatum, the region responsible motor functions, after acute exercise. regions of the brain which
Interestingly,
for controlling
the data show the pattern of AChE inhibition in sub-
is well correlated with a significant increase in lipid peroxidation.
possible that this could lead to changes in synaptic membrane fluidity and permeability.
It is quite
The differences
observed in the regional distribution of AChE are consistent with the known cholinergic innervation to the brain regions that have been previously examined (Appleyard et al. 1986; Eckstein et al, 1988; Husain and Vijayaraghavan.
1989; Matin and Husain, 1985). Under normal physiological
conditions,
tissue levels of
acetylcholine (ACh) are regulated by the net synthesis and degradation of ACh by choline acetyltransferase and AChE. respectively.
Following exhaustive exercise, striatal levels of ACh rise with AChE inhibition
due to increased lipid peroxidation. exercise showed regional selectivity, is involved acetylcholine
in controlling
specifically
motor activity
elicited by acute
for the corpus striatum (deeper area of the brain) which
(Benarroch
et al. 1986; Matin and Husain,1985),
rate (Matin and Husain. 1985; Somani et al., 1996). However, AChE and lipid
in various brain regions have been reported to be altered differently
conditions (Appleyard et al. 1990; Estevez et al, 1984; Tsakiris and Kondopaulos. The data indicate that ethanol significantly
to different
activity
in the cerebellum
stress
1993).
decreased AChE activity only in the corpus striatum while
it slightly increased enzyme activity in the cerebral cortex. medulla and hypothalamus enzyme
where
has potent actions (Matin and Husain. 1985). This region is also rich in AChE and has a
higher lipid peroxidation peroxidation
The changes in AChE activity and lipid peroxidation
indicating
differential
response
within sub-regions
without altering of the brain.
Interestingly. changes in AChE activity in specific brain regions correspond to increased lipid peroxidation. A single dose of ethanol is known to increase lipid peroxidation
in the brain (Bondy, 1992; Burmistrov et
al, 1992; Bykova and Zhukova, 199 1; Uysal et al, 1989), and affect the cholinergic
system (Arendt et al,
Exercise, ethanol/chohnesterase 1988; Hashemzadeh-Gargari
667
and Mandel, 1989; Soliman and Gabriel, 1985).
ACNE activity may be suggestive of an altered acetylcholine
The inhibition of striatal
level and thereby altered motor control with
ethanol intake. These behavioral and biochemical deficits have been known to be caused by ethanol intake (Lishman,
1990; Rawat,
1976).
determining the above deficits.
However,
and Flevora,
investigators.
1982).
and inhibit AChE activity in rat brain (Burmistrov
Thus, the present
data are consistent
In vitro studies have also revealed perturbation
membrane-bound
in
The low acute and chronic doses of ethanol (1 .O and 1.5 g/kg) have been
shown to increase lipid peroxidation Sytinskii
the dose and duration of ethanol intake is important
AChE activity
with the findings
of the synaptic membrane,
at 40-60 mM ethanol concentration
et al, 1992; of the other
and changes in
(Lasner et al, 1995; Sun and
Samorajski, 1970) with no significant change in soluble form of AChE activity indicating the involvement of the membrane membrane-bound a protein-lipid
in ethanol action.
Ethanol (200-600 mM) caused a greater level of inhibition
in
AChE enzyme than in soluble enzyme in vitro (Baker and Chen, 1989) indicating that
interaction is needed to maintain the conformation
inhibition of membrane-bound
of membrane-bound
AChE.
Thus, the
AChE with increased membrane lipid peroxidation due to ethanol ingestion
in rats. as observed in the present study, is consistent with the in vitro study. Ethanol consumption humans (Blomquist
has been reported to adversely influence the treadmill exercise performance
in
et al, 1970; Houmard et al, 1987; Kendrick et al, 1993; Side11 and Pless, 1971).
However. other studies did not support these findings (Bobo, 1972; Mazess et al, 1968), which may be due to differences in the intensity. duration, type of exercise and the dose of ethanol used in these studies. data show that the combination
of exercise and ethanol 20% (1.6 gmikg, p.o.) also selectively
striatal AChE activity and increased lipid peroxidation
indicating influence of the combination
Our
decreased on motor
activity. The sensitivity of this brain region to the combination of other stressors has also been reported in the rat (Pal et al, 1993). Thus, ethanol intake after acute exercise partially modified the striatal AChE activity and lipid peroxidation exercise-induced
which may also partially improve motor function.
Ethanol decreased
increases in plasma BuChE activity suggesting that ethanol reduces the stress response
of exhaustive exercise at peripheral site.
Conclusions Acute exercise, single ethanol (1.6 gm/kg, p.o.) intake and the combination selectively inhibited striatal AChE
activity
perturbation
and the inhibition
of motor activity.
was correlated The combination
with an increase decreased
in lipid peroxidation
plasma BuChE indicating
suppresses the peripheral stress response caused by exhaustive exercise.
indicating that ethanol
666
K. Husam and S.M. Somani References
APPLEYARD, M.E., GREEN, A.R. and SMITH, A.D. (1986). Acetylcholinesterase the rat brain following a convulsion. J. Neurochem. 6: 1749-756.
activity in regions of
APPLEYARD, M.E., TAYLOR. S.C., and LITTLE. H.J. (1990). Acetylcholinesterase activity in regions of mouse brain following acute and chronic treatment with a benzodiazepine inverse agonist. Br. J. Pharmacol. _l&l:599-605. ARENDT, T., ALLEN, Y.. SINDEN, J., SCHUGENS. M.M.. MARCHBANKS, R.M., LANTOS, P.L. and GRAY, J.A. (1988). Cholinergic-rich brain transplants reverse alcohol-induced memory deficits. Nature =:448-450. ARNERIC, S. P.. GIULIANO, R., ERNSBERGER, P., UNDERWOOD. M.D. and REIS. D.J. (1990). Synthesis. release and receptor binding of acetylcholine in the C, area of the rostra1 ventrolateral medulla; contribution sin regulation of arterial pressure. Brain Res. 511:98-l 12. AUGUSTINSSON, K.B., and NACHMANSOHN, D. (1949). Distinction between acetylcholine-esterase and other choline ester-splitting enzymes. Science m:98-99. BAKER, G.M. and CHEN, C.H. (1989). The effects of ethanol on the structural stability of acetylcholine receptor and the activity of various molecular forms of acetylcholinesterase. Biochem. Biophy. Acta. 992:333-340. BENARROCH, E.E.. GRANATA. A.R.. RUGGIERO, D.A., PARK, O.H.. and REIS, D.J. (1986). Neurons of C, area mediate cardiovascular response initiated from ventral medullary surface. Am. J. Physiol. m::R932-R945. BLOMQUIST. G., SALTIN, B., and MITCHELL, A.. (1970). Acute effects of ethanol ingestion on the response to submaximal and maximal exercise in man. Circulation a:463-470. BOB0 , W. (1972). Effects of alcohol upon maximum oxygen uptake, lung ventilation. Res. Q. 43:1-6.
and heart rate.
BONDY, S.C. (1992). Ethanol toxicity and oxidative stress. Toxicol. Lett. 63:23 l-241 BOOTH. F.W., and THOMPSON, D.B. (1991). Molecular and cellular adaptation of muscle in response to exercise: Perspective of various models. Physiol. Rev. 71:541-585. BURMISTROV, S.O., MASHEK, O.P. and KOTIN. A.M. (1992). Impact of acute alcohol intoxication on the antioxidative system and creatine kinase activity in the rat embryonic brain. Eksptl. Klin. Farmako. a:54-56. BYKOVA. L.P., and ZHUKAVA, T.P. (1991). Action of ethanol and limontar during neonatal development on lipid peroxidation and on the antioxidant protection system in the brain and liver tissue of neonatal rats. Byull. Eksp. Biol. Med. m:580-582. COLLINS, A.C.. SMOLEN, A., WAYMAN, A.L., and MARKS, M.J. ( 1984). Ethanol and temperature effects on five membrane bound enzymes. Alcohol. 1237-246. DAVIES, J.J.A., QINTANILLA, A.T.. BROOKS, G.A.. and PACKER, L. (1982) Free Radicals and tissue damage produced by exercise. Biochem. Biophys. Res. Commun. 107: 1198- 1205. DUBE, S.N., SOMANI, S.M., and COLLIVER, J.A. (1990). Interactive effects of physostigmine exercise on cholinesterase activity in RBC tissues of rat. Part-I. Arch. Int. Pharmacodyn.Ther.m:7182.
and
DUBE, S.N., SOMANI, S.M., and BABU. S.R. (I 993). Concurrent acute exercise alters central and peripheral responses to physostigmine. Pharmacol. Biochem. Behav. %:827-834.
Exercise. ethanol/choltnesterase ECKSTEIN, F.P.. BAUGHMAN. R.W., and QUINN, J. (1988) innervation in rat cerebral cortex. Neuroscience m:457-474.
669 An anatomical
study of cholinergic
ELLMAN. G.L., COURTNEY, D.K., ANDERS, V.J., and FEATHERSTONE, R.M. (1961). Rapid calorimetric determination of acetylcholinesterase activity. Biochem. Pharmacol. 28-95; 1961. ESTEVEZ, E.E., JERUSALINSKY, D., MEDINA, J.H., and ROBERTIS, E.D. (1984). Cholinergic muscarinic receptors in rat cerebral cortex, basal ganglia and cerebellum undergo rapid and reversible changes after acute stress. Neuroscience 11:1353-l 357. HASHEMZADEH-GARGARI, H. and MANDEL, P. (1989). Genetically-determined responses of central cholinergic markers: the effects of ethanol on inbred strains of mice. Neurotoxicology a:555-568. HOUMARD, J.A., LANGENFELD, M.E., WILEY, R.L. and SIEFERT. J. (1987). Effects of the acute ingestion of small amounts of alcohol upon 5-mile run times. J. Sports Med. n:2.53-257. HUSAIN. K., and VIJAYARAGHAVAN. R. (1989). DFP induced changes in acetylcholinesterase and glycogen level in certain brain regions of mice. Ind. J. Physiol. Pharmacol. 2:250-252.
activity
KENDRICK, Z.V., AFFRIME, M.B., and LOWENTHAL, D.T. (1993). Effect of ethanol on metabolic responses to treadmill running in well-trained men. J. Clin. Pharmacol. B:136-139. LASNER, M., ROTH, L.G., and CHEN, C.H. Structure-functional (1995). Structure-functional effects of a series of alcohols on acetylcholinesterase-associated membrane vesicles: Elucidation of factors contributing to the alcohol action. Arch. Biochem. Biophys. m:391-396. LISHMAN, W.A. (1990). Alcohol and the brain. Br. J. Psychiatr. l-5&635-644. MATIN, M.A. and HUSAIN, K. (1985). Striatal neurochemical changes and motor dysfunction in mipafox treated animals. Meth. Find. Clin. Exptl. Pharmacol. 2:79-81. MAZES& R., PICON-REATEGUL, E., and THOMAS, R. (1968). Effect of alcohol and altitude on man during rest and work. Aerospace Med. 3:403-406. NORDMANN,
R. (1987) Oxidative stress from alcohol in the brain. Alcohol. L:75-82.
OHKAWA, H., OHISHI, N., and YAGI, K. (1979). Assay for lipid peroxides in animals and tissues by thiobarbituric acid reaction. Anal. Biochem. 95:35 l-35. OTT, P. (1985). Membrane acetylcholinesterases: Purification, molecular properties and interactions with amphiphilic environments. Biochem. Biophys. Acta. 822:375-392. PAL, R., NATH, R., and GILL, D. (1993). Lipid peroxidation and antioxidant defense enzymes in various regions of adult rat brain after coexposure to cadmium and ethanol. Pharm. and Toxic. a:209-214. PAWLOWSKA, D., MONIUSZKO-JANKONIUK, and SOLTYS, M. (1985) Parathion methyl effect on the activity of hydrolytic enzymes after single physical exercise in rats. Pol. J. Pharmacol. Pharm. u:629-638. RAWAT, A.K. (1976). Neurobiol. B:123-172.
Neurochemical
consequences
of ethanol on the nervous system.
Int. Rev.
READ, S.M., and NORTHCOLE, D.H. (1981) Minimization of variation in the response to different protein of the Coomassie blue G dye-binding assay for protein. Anal. Biochem. fi:53-64. RITCHIE, J.M. (1985). The aliphatic alcohols, In: The Pharmacological Basis of Therapeutics, A.G. Gilman, L.S. Goodman, T.W. Rall, and F. Murad, (Eds), Ed. 7, pp 372-386, McMillan Publ. Co., New York. RYHANEN, R., KAJOVAARA, M., HARRI, M., KALISTE-KORHONEN, E.,and (1988). Physical exercise affects cholinesterases and organophosphate response. 19:815-820.
HANNINEN, 0. Gen. Pharmacol.
670
K. Husam and S.M. Somani
SIDELL, F., and PLESS, J. (1971). Ethyl alcohol blood levels and performance administration to man. Psychopharmacologia fi:246-26 1.
decrements
after oral
SOLIMAN, K.F.. and GABRIEL, N.N. (1985). Brain cholinergic involvement in the rapid development of tolerence to the hypothermic action of ethanol. Gen. Pharmacol. &5:137-140. SOMANI, S.M. ( 1994). Influence of exercise induced oxidative stress on the central nervous system. In: Exercise and Oxygen Toxicity. C.K. Sen. L. Packer. and 0. Hanninen, (Eds)., pp 462-477, Elsevier Science Publishers. SOMANI, S.M.. BABU. S.R., ARNERIC, S.P., and DUBE. S.N. (1991). Effect of cholinesterase inhibitor and exercise on choline acetyltransferase and acetylcholinesterase activities in rat brain regions. Pharmacol. Biochem. and Behav. 39:337-343. SOMANI, SM.. RYBAK, L.P.. and RAW, R.P. (1995). Effect of trained exercise on antioxidant system in rat brain regions. Pharmacol. Biochem. Behav. s:635-637. SOMANI, SM., HUSAIN. K., DIAZ-PHILLIPS, L.. LANZOTTI. D.J., KARETI. K.R., and TRAMMELL. G.L. (1996). Interaction of exercise and ethanol on antioxidant enzymes in brain regions of rat. Alcohol (In Press). SUN, A.Y., and SAMORAJSKI. T. (1970). Effects of ethanol on the activity of adenosine triphosphatase and acetylcholinesterase in synaptosomes isolated from guinea pig brain. J. Neurochem. 12: 1365-I 672. SYTINSKII, 1. A. and Flerova. N.I. (1982). Glutamyl transferase and acetylcholinesterase various areas of the rat brain in alcoholic intoxication. Ukrain. Biokhim. Z. 54:149-153. TABAKOFF, B., JAFFE, R.C. and RITZMAN, R.F. (1978). Corticosterone ethanol drinking and withdrawal. J. Pharm. Pharmacol. X:371-374.
concentrations
activity in
in mice during
TSAKIRIS, S., and KONTOPOULOS, A.N. (1993). Time changes in Na’. K’-ATPase, Mg”-ATPase, and acetylcholinesterase activities in the rat cerebrum and cerebellum caused by stress. Pharmacol. Biochem. Behav. a:339-342. UYSAL. M.. KUTALP. G.. ODZEMIRLER. G.. and AYKAC. G. (1989). Ethanol-induced changes in lipid peroxidation and glutathione content in rat brain. Drug Alcohol. Depend. a:227-230.
Inquiries and reprint requests should be addressed to:
Satu M. Somani, Ph.D. Professor of Pharmacology and Toxicology Southern Illinois University School of Medicine Department of Pharmacology P.O. Box 19230 Springfield, IL 62794- 1222 USA
ELSEVIER
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& Bti. Psyhiat. 1997, Vol. 2 1, pp. 059-670 Copyright 0 1997 Elsevier Sdence Inc. Printed in the USA. All rights reserved 0276-5646/97 $32.00 + .oO
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INFLUENCE OF EXERCISE AND ETHANOL ON CHOLINESTERASE ACTIVITY AND LIPID PEROXIDATION BLOOD AND B&UN REGIONS OF RAT
IN
KAZIM HUSAIN and SATU M. SOMANI Southern Illinois University School of Medicine Department of Pharmacology Springfield, IL, USA (Final form - January, 1997)
Abstract Husain, Kazim and Satu M. Somani: Influence of exercise and ethanol on cholinesterase activity and lipid peroxidation in blood and brain regions of rat. Prog. Neuro.-Psychopharmacol. & Biol. Psychiat. 1997,a: pp. 659-670. 0 1997 Elsevier Science Inc. 1. This study elucidates the interaction of acute exercise and single ethanol intake on cholinergic enzyme and its relationship to lipid peroxidation in the blood and brain regions of the rat. 2. Butyrylcholinesterase (BuChE) in plasma and acetylcholinesterase (AChE) in brain regions as well as lipid peroxidation (MDA) were assayed in 1) sedentary control rats; 2) after acute exercise (100% VO1,,,); 3) ethanol 20% (1.6 gm/kg, p.0.); 4) exercise and then ethanol 20% (1.6 gm/kg, p.0.). 3. Acute exercise significantly increased BuChE activity (155% of control) in plasma and decreased AChE activity (60% of control) in the corpus striatum with a significant increase in the striatal MDA level (254% of control). Ethanol significantly decreased AChE activity only in striatum (86% of control) with a significant increase in striatal MDA level (132% of control). 4. The combination of exercise and ethanol 20% (1.6gm/kg, p.0.) significantly increased BuChE activity (123% of control) in plasma, and decreased AChE activity (76% of control) in striatum with significant increase in striatal MDA level (147% of control). 5. Acute exercise, single ethanol 20% (1.6 grn/kg, p.o.) intake and the combination selectively inhibited striatal AChE, and the inhibition was correlated with increased lipid peroxidation indicating perturbation of motor function. The combination reduced the peripheral stress response caused by exhaustive exercise. Keywords: acetylcholinesterase. -2: cholinesterase
brain regions, butyrylcholinesterase,
acetylcholinesterase (AChE), acute exercise (ChE), ethanol (Et), malondialdehyde (MDA)
ethanol, exercise, lipid peroxidation
(AE),
butyrylcholinesterase
(BuChE),
Introduction Earlier studies reported that physical exercise enhances the inhibition of cholinergic by cholinesterase
inhibitor (physostigmine)
enzymes elicited
in cerebral and peripheral tissues of the rat (Dube et al, 1990;
Dube et al 1993; Somani et al, 1991). Exercise is known to cause oxidative stress on the nervous syste659
660
K. Husam and S.M. Somani
and increase the lipid peroxidation neuronal
membrane
permeability.
(Somani, 1994; Somani et al, 1996). which may lead to alteration in Similarly,
ethanol has also been reported to be stressful
(Tabakoff et al, 1978) and exerts an oxidative Nordmann.
1987).
Ethanol after ingestion
stress response
to mice
on the nervous system (Bondy,
is quickly absorbed
from the gastrointestinal
1992;
lumen into
circulation and can readily cross the blood brain barrier entering the areas of the brain (Ritchie, 1985). Due to high lipid solubility, ethanol also changes the permeability and fluidity of the synaptic membrane as well as the activities of membrane bound enzymes (Collins et al, 1984; Lasner et al. 1995; Sun and Smorajski. 1970).
Acetylcholinesterase
is a membrane bound enzyme with lipid dependence (Lasner et al. 1995: Ott, 1985).
and its distribution is different in specific brain regions (Appleyard et al. 1986: Husain and Vi.jayaraghavan, 1989; Somani et al, 1991); ethanol may likely influence the enzyme activity in a differential
pattern.
brain utilizes 20% of the oxygen consumed by the body, contains high levels ofperoxidizable low levels of antioxidants. hypothesis
It may actually be more vulnerable to peroxidative
is that acute exercise, single ethanol intake, and the combination
peroxidation
of neural membranes
damage.
The
lipids and
Therefore. the
are likely to influence lipid
and of the membrane bound acetylcholinesterase
enzyme in specific
brain regions. Each region of the brain has different responses to exercise (Somani et al. 199 1; Somani et al, 1995) or ethanol (Rawat. 1976; Somani et al. 1996) because each region has a separate level of peroxidizable
unsaturated lipids (Nordmann,
enzymes (Appleyard
1987; Somani et al., 1996: Uysal et al, 1989). cholinergic
et al, 1986; Somani et al, 1991). and cholinergic
innervation
(Arneric et al.. 1990:
Eckstein et al, 1988; Matin and Husain, 1985). Thus each brain region may receive a different amount of stress.
There is a paucity of information
concerning
the interaction
of exercise
cholinergic system. Only a few reports have demonstrated the influence ofethanol
and ethanol on the
on exercise performance
in human (Blomquist et al, 1970; Houmard et al. 1987; Kendrick et al. 1993: Side11 and Pless. 1971). Since exercise
and ethanol have been known to cause an oxidative
cholinergic system (Bondy, 1992: Hashem-Zadeh-Gargari
stress response
and interact with the
and Mandel. 1989; Somani et al, 199 1; Somani,
1994; Somani et al. 1995), it is essential to study the interactive effects of both on membrane-bound and lipid peroxidation
in brain regions of rat. Therefore, the specific aims of this study were:
determine whether acute exercise. single ethanol intake. and the combination influence
the cholinesterase
activity in the blood and sub-regions
correlation between cholinesterase rat.
AChE 1) to
of these two stressors would
of the brain; and 2) to establish
enzyme activity and lipid peroxidation
a
in specific brain regions of the
Exercise, ethanol/cholinesterase
661
Methods
Acetylthiocholine
iodide. butyrylthiocholine
iodide and 5’,5’ - dithiobisnitrobenzoic
acid were obtained
from the Sigma Chemical Co. (St. Louis, MO). Coomassie protein assay reagent was purchased from the Pierce Co. (Rockford, IL). _Animals Adult male Fisher-344 rats weighing 205-230 gm from Harlan Industries (Indianapolis, in this study. The rats were acclimatized for 5 days to the facility prior to starting
IN) were used
the experiments.
were fed ad libitum with Rodent Laboratory Chow (Ralston Purina Company, Indianapolis,
Rats
IN) and tap
water. Rats were randomly divided into four groups and treated as follows:
I.
Sedentarv Control (SC): of inclination minutes
Six rats were put on the treadmill belt at a speed of 2 m/min and 0”angle
in the Omnipacer
for equivalent
treadmill (Omnitech
handling.
Electronics,
Inc., Columbus,
OH) for five
They received equivalent volume of normal saline orally via
orogastric tube. II.
Acute Exercise (AE): Four rats were acutely exercised on the treadmill at 100% VOZmax.The speed of the belt and angle of inclination were increased gradually from 8.2 m/min to 30.3 m/min and from 0” to 12.5”, respectively,
as described earlier (Dube et al, 1990; Dube et al, 1993; Somani et
al, 1991). The oxygen consumption
and heat production
Oxyscan System (Omnitech Electronics,
III. Ethanol (Et):
in individual rats were recorded by the
Inc.).
Four rats were given ethanol 20% (v/v) at a dose of (1.6 gm/kg, p.o.) via orogastric
tube. IV. Acute Exercise and Ethanol (AE + Et): Six rats were exercised on the treadmill as described in group II and 5 min after exercise, animals were given ethanol as described in group III . Rats in all the groups were sacrificed 30 min post treatment by decapitation
between 9:00-l 1:OOa.m.
to minimize the Circadian cycle effects. Preparation of Tissue Extract: Blood was collected in heparinized vials and centrifuged at 1000 rpm for 10 min to separate the plasma. cerebellum, immersed
Heads were collected in ice water and brain regions - cerebral cortex,
medulla, corpus striatum and hypothalamus in liquid nitrogen and stored at -80°C.
were isolated.
Brain regions were immediately
Brain regions were homogenized
phosphate buffer (pH 7.0) containing 0.1 mM EDTA to give 5% homogenate
(“‘/J.
in cold 50 mM
K. Husain and S.M. Somani
662
Enzvme Assays Acetylcholinesterase
(EC 3.1.1.7): Its activity was determined
method of Ellman et al. (1961).
In a cuvette.
in brain regions according to modified
100 ul of tissue extract was added to 780 Pl of 0.1 M
phosphate buffer pH 8. One hundred ~1 of 0.01 M dithiobisnitrobenzoic
acid (in 0.1 M phosphate buffer
pH 7.0) was added to the cuvette. The reaction was started after the addition of 20 pl of acetylthiocholine as a substrate, and optical density was recorded at 4 I2 nm every 30 seconds up to 4 minutes using a Hitachi U-2000
spectrophotometer.
computerized
The
program.
hydrolyzed/min/mg
The change in optical density enzyme
activity
was
and enzyme
expressed
activity was calculated
as umoles
by
of acetylthiocholine
protein.
Butyrylcholinesterase
(,EC 3. I. I .8): Its activity was determined
in plasma by the modified method of
Ellman et al. (1961). In a cuvette containing 920 ul of 0.1 M phosphate buffer (pH 8), 10 ~1 of plasma and 50 u1 of 0.01 M dithiobisnitrobenzoic started with the addition.of
acid (in 0.1 M phosphate buffer pH 7) was added. The reaction was
20 ~1 of 0.075 M butyrylthiocholine
as substrate and optical density was
recorded at 4 I2 mn every 30 set up to 4 minutes. The change in optical density per minute and the enzyme activity was calculated by a computerized butyrylthiocholine
hydrolyzediminlmg
Linid Peroxidation
Assav
program.
The specific activity was expressed
as pmoles of
protein.
This assay is used to determine malondialdehyde
(MDA) level as described by Ohkawa et al. (1979).
Two hundred ul of tissue homogenate was added to 50 ~1 of8.1% sodium dodecyl sulfate (SDS), vortexed, and incubated for IO minutes at room temperature. 3.5) and 375 pl ofthiobarbituric
Three hundred seventy five pl of 20% acetic acid (pH
acid (0.6%) were added and placed in a boiling water bath for 60 min. The
samples were allowed to cool at room temperature, vortexed and centrifuged at 1000 RPM for 5 minutes.
then 1.25ml of butanol:
pyridine (15: 1) was added.
Five hundred u1 of the colored layer was measured
at 532 nm using 1.1.3.3-tetraethoxypropane as a standard.
Protein Assay Protein in plasma and tissue homogenate was determined by the method of Read and Northcole (1981) using bovine serum albumin as standard.
Data Analvsis Data were expressed as mean i S.E.M. and analyzed using one way analysis of variance (ANOVA) and group comparisons
by Tukey’s studentized
Range Test at significant level 0.05.
Exercise, ethanol/cholmesterase
663
Results The effect of acute exercise (AE), ethanol (Et) and the combination cholinesterase
activity
butyrylcholinesterase
of the rat is depicted
in Table
1.
of both (AE + Et) on plasma
AE significantly
increased
plasma
(BuChE) activity (155% of control) (F = 3 1.5, p
plasma BuChE activity.
The combination
of AE and Et significantly
increased plasma BuChE activity
(123% of control) (F = 15.4, pcO.05). Table 2 shows the effect of AE. Et and the combination (AE + Et) on AChE activity in brain regions of the rat. AE significantly
decreased
AChE activity in the corpus striatum (60% of control) (F = 25.8,
p
The combination
of AE and Et resulted in a significant decrease in AChE activity
in the corpus striatum (76% of control) (F = 21.5, p~O.001) whereas enzyme activity did not significantly change in other brain regions (Table 4).
Table 1 Effect of Acute Exercise (100% VOZmax)and Ethanol (1.6 gmkg, p.o.) Ingestion on Butyrylcholinesterase Activity in the Plasma of Rats.
Groups
Butyrylcholinesterase Activity * (Piasma)
Percent Increase
1. Sedentarv Control (n=6)
3.88 * 0.17
-___
2. Acute Exercise (n=4)
6.01 * 0.30a
55
3. Ethanol (n=4)
4.06 f 0.18
5
4.78 f 0.37b’C
23
4. Acute Exercise + Ethanol (n=S)
Data are mean + SEM; *b.tmoles butyrylthiocholine hydrolyzed/min/mg protein; a - significantly different from group 1 (p < 0.01); - significantly different from group 1 (p < 0.05); ’ - significantly different from group 2 (p < 0.05)
664
K. Husam and SM. Somani Table 2 Effect of Acute Exercise ( 100% VOrma,) and Ethanol (1.6 gm/kg, p.o.) Ingestion on Acetylcholinesterase Activity in Brain Regions of Rats, Brain Regions (acetylcholinesterase Cerebral Cortex
Groups
Corpus Striatum
Medulla
activity)*
Cerebellum
Hypothalamus
1. Sedentary Control (n=6)
18.20i I.55
68.83t 2.68
49.69+ 4.07
21.62+ 1.79
43.78* I.75
2. Acute Exercise (n=4)
15.12* 0.75 (-17%)
41.3I"i 3.21 (-40%)
38.41-t3 71 (-23%)
22.99+ 3.13 (+6Oa)
41.97 Ik1.50 (-4%)
3. Ethanol (n=4)
22.62+ 1.69 (+24%)
59.00bgd i 2.24 (-14%)
59.51'* 7.79 (+20%)
19.80+ 1.68 (-8%)
49.42i 3.48 (+13%)
4. Acute Exercise + Ethanol (n=5)
?3.01'+ 1.69 (+26%)
52.42"e'f+1.37 54.31f 7.12 (-2496) (+9%)
21.64i 1.23 (0%)
48.08t4.59 (+lo%)
Data are mean * sem; * bumoles Acetylthiocholine hydrolyzediminimg protein: ’ - significant (p i 0.01) ‘.; - significant (p < 0.02) compared to group 1; ’ - significant (p < 0.01) compared 1 - srgnn‘icant (p i 0.01) compared with group 2; e - significant (p < 0.02) compared with group 2; ’ - significant (p < 0.05) compared with group 3: g - significant (p < 0.05) compared with group 2; Values in parentheses indicate percent change (+) increase and (-) decrease ;;Tgy;pw;,hpup
The changes in lipid peroxidation (MDA) due to AE, Et, and AE + Et in plasma and brain regions of the rat is presented
in Table 3. No significant
exercise or the combination
ofAE
change in the plasma MDA level was observed after acute
and Et. However, the MDA level decreased slightly (79% of control)
in the plasma after Et treatment. AE significantly elevated MDA levels in corpus striatum (254% of control) (F = 46.87, p
(F = 13.5, p
increased the MDA level in the corpus Striatum (132% of control) (F = 15.2. p
MDA level did not significantly
alter in other brain regions.
increased the MDA level in the corpus striatum (153% significantly
of control)
of
The combination
of AE + Et significantly
control) (F = 34.5, pLO.02) while it did not
change in other brain regions (Table 4).
Discussion This is the first report delineating
the combined effect of acute exercise (physical stress) and ethanol
ingestion (chemical stress) on ChE activity in blood and brain regions of the rat and their relationship lipid peroxidation.
The data indicate that acute exercise alone significantly
to
increased BuChE activity in
plasma and decreased AChE activity in the corpus striatum without affecting other brain regions.
BuChE
Exercise,
is a nonspecific cholinesterase
ethanol/cholinesterase
which is synthesized
665
in the liver (Augustinsson
and Nachmansohn,
1949).
Physical exercise is a stress factor that is known to evoke a number of metabolic and enzymatic changes in the liver and muscle (Booth and Thompson.
1991; Davies et al, 1982). Thus, the increased plasma
BuChE activity may be a secondary effect of labilization of lysosomal membranes of liver cells and leakage of enzyme in the blood after exhaustive exercise.
The present findings are consistent with other reports
(Pawlowska et al. 1985; Ryhanen et al. 1988).
Table 3 Effect of Acute Exercise (AE), Ethanol (Et) and AE + Et on Lipid Peroxidation Brain Regions of the Rat.
(MDA) in Plasma and
Lipid Peroxidation (Malondialdehyde)’ Brain Regions Cerebral Cortex
corpus Striatum
Medulla
Cerebellum
Hypothalamus
Plasma
157.03*14.47
240.83*41.15
237.25128.24
130.4317.7
67.74+6.11
53.61&6.75
2. Acute Exercise (n=4)
206.61c*l 1.68 (+32%)
510.57p&38.68 (+I 54%)
329.55’+38.68 (+39%)
140.37*17.72 (+8%)
78.67i4.92 (+16%)
60.54h2.94 (+7%)
3. Ethanol (n=4)
202.04*50.68 (+29%)
316.80c’di20.10 (+32%)
304.40*3 1.64 (+28%)
137.25h8.70 (+5%)
77.12il3.71 (+14%)
42.6li6.06 (-2 I o/b)
4. Acute Exercise + Ethanol (n=5)
185.851t26.09 (+lS%)
367.74b’e*10.13 (+53%)
273.82+6.88 (+15%)
148.48*5.39 (+14%)
79.39i12.94 (C17%)
56.20+8.75 (+5%/o)
Groups I. Sedentary Control (n=6)
Data are mean f SEM; * - nmoles MDA/g tissue or ml of plasma; ’ - significant (p < 0.01) compared with groupl;bsignificant (p < 0.02) compared with group 1; ’ - significant (p < 0.05) compared with group 1; d - significant (p < 0.01) compared with group 2; e - significant (p < 0.02) compared with group 2; Values in parentheses indicate percent change (+) increase and (-) decrease
K. Husatn and SM. Somani
666
Table 4 Correlation of AChE Activity with Lipid Peroxidation
in Different Brain Regions of Rat
AChE Activity Brain Regions
AE
Et
Medulla
I
1
Cerebellum
I
I
Lipid Peroxidation AE+Et
(MDA)
AE
Et
tt
t
f
I
T
r
I
1
T
AE+Et
Cortex Striatum
I
t Hypothalamus 1 Tor 1 = increase or decrease is not significant;
T
1T or 1I = increase or decrease is significant
AE = Acute Exercise’ Et = Ethanol
Conversely, AChE activity decreased only in the corpus striatum, the region responsible motor functions, after acute exercise. regions of the brain which
Interestingly,
for controlling
the data show the pattern of AChE inhibition in sub-
is well correlated with a significant increase in lipid peroxidation.
possible that this could lead to changes in synaptic membrane fluidity and permeability.
It is quite
The differences
observed in the regional distribution of AChE are consistent with the known cholinergic innervation to the brain regions that have been previously examined (Appleyard et al. 1986; Eckstein et al, 1988; Husain and Vijayaraghavan.
1989; Matin and Husain, 1985). Under normal physiological
conditions,
tissue levels of
acetylcholine (ACh) are regulated by the net synthesis and degradation of ACh by choline acetyltransferase and AChE. respectively.
Following exhaustive exercise, striatal levels of ACh rise with AChE inhibition
due to increased lipid peroxidation. exercise showed regional selectivity, is involved acetylcholine
in controlling
specifically
motor activity
elicited by acute
for the corpus striatum (deeper area of the brain) which
(Benarroch
et al. 1986; Matin and Husain,1985),
rate (Matin and Husain. 1985; Somani et al., 1996). However, AChE and lipid
in various brain regions have been reported to be altered differently
conditions (Appleyard et al. 1990; Estevez et al, 1984; Tsakiris and Kondopaulos. The data indicate that ethanol significantly
to different
activity
in the cerebellum
stress
1993).
decreased AChE activity only in the corpus striatum while
it slightly increased enzyme activity in the cerebral cortex. medulla and hypothalamus enzyme
where
has potent actions (Matin and Husain. 1985). This region is also rich in AChE and has a
higher lipid peroxidation peroxidation
The changes in AChE activity and lipid peroxidation
indicating
differential
response
within sub-regions
without altering of the brain.
Interestingly. changes in AChE activity in specific brain regions correspond to increased lipid peroxidation. A single dose of ethanol is known to increase lipid peroxidation
in the brain (Bondy, 1992; Burmistrov et
al, 1992; Bykova and Zhukova, 199 1; Uysal et al, 1989), and affect the cholinergic
system (Arendt et al,
Exercise, ethanol/chohnesterase 1988; Hashemzadeh-Gargari
667
and Mandel, 1989; Soliman and Gabriel, 1985).
ACNE activity may be suggestive of an altered acetylcholine
The inhibition of striatal
level and thereby altered motor control with
ethanol intake. These behavioral and biochemical deficits have been known to be caused by ethanol intake (Lishman,
1990; Rawat,
1976).
determining the above deficits.
However,
and Flevora,
investigators.
1982).
and inhibit AChE activity in rat brain (Burmistrov
Thus, the present
data are consistent
In vitro studies have also revealed perturbation
membrane-bound
in
The low acute and chronic doses of ethanol (1 .O and 1.5 g/kg) have been
shown to increase lipid peroxidation Sytinskii
the dose and duration of ethanol intake is important
AChE activity
with the findings
of the synaptic membrane,
at 40-60 mM ethanol concentration
et al, 1992; of the other
and changes in
(Lasner et al, 1995; Sun and
Samorajski, 1970) with no significant change in soluble form of AChE activity indicating the involvement of the membrane membrane-bound a protein-lipid
in ethanol action.
Ethanol (200-600 mM) caused a greater level of inhibition
in
AChE enzyme than in soluble enzyme in vitro (Baker and Chen, 1989) indicating that
interaction is needed to maintain the conformation
inhibition of membrane-bound
of membrane-bound
AChE.
Thus, the
AChE with increased membrane lipid peroxidation due to ethanol ingestion
in rats. as observed in the present study, is consistent with the in vitro study. Ethanol consumption humans (Blomquist
has been reported to adversely influence the treadmill exercise performance
in
et al, 1970; Houmard et al, 1987; Kendrick et al, 1993; Side11 and Pless, 1971).
However. other studies did not support these findings (Bobo, 1972; Mazess et al, 1968), which may be due to differences in the intensity. duration, type of exercise and the dose of ethanol used in these studies. data show that the combination
of exercise and ethanol 20% (1.6 gmikg, p.o.) also selectively
striatal AChE activity and increased lipid peroxidation
indicating influence of the combination
Our
decreased on motor
activity. The sensitivity of this brain region to the combination of other stressors has also been reported in the rat (Pal et al, 1993). Thus, ethanol intake after acute exercise partially modified the striatal AChE activity and lipid peroxidation exercise-induced
which may also partially improve motor function.
Ethanol decreased
increases in plasma BuChE activity suggesting that ethanol reduces the stress response
of exhaustive exercise at peripheral site.
Conclusions Acute exercise, single ethanol (1.6 gm/kg, p.o.) intake and the combination selectively inhibited striatal AChE
activity
perturbation
and the inhibition
of motor activity.
was correlated The combination
with an increase decreased
in lipid peroxidation
plasma BuChE indicating
suppresses the peripheral stress response caused by exhaustive exercise.
indicating that ethanol
666
K. Husam and S.M. Somani References
APPLEYARD, M.E., GREEN, A.R. and SMITH, A.D. (1986). Acetylcholinesterase the rat brain following a convulsion. J. Neurochem. 6: 1749-756.
activity in regions of
APPLEYARD, M.E., TAYLOR. S.C., and LITTLE. H.J. (1990). Acetylcholinesterase activity in regions of mouse brain following acute and chronic treatment with a benzodiazepine inverse agonist. Br. J. Pharmacol. _l&l:599-605. ARENDT, T., ALLEN, Y.. SINDEN, J., SCHUGENS. M.M.. MARCHBANKS, R.M., LANTOS, P.L. and GRAY, J.A. (1988). Cholinergic-rich brain transplants reverse alcohol-induced memory deficits. Nature =:448-450. ARNERIC, S. P.. GIULIANO, R., ERNSBERGER, P., UNDERWOOD. M.D. and REIS. D.J. (1990). Synthesis. release and receptor binding of acetylcholine in the C, area of the rostra1 ventrolateral medulla; contribution sin regulation of arterial pressure. Brain Res. 511:98-l 12. AUGUSTINSSON, K.B., and NACHMANSOHN, D. (1949). Distinction between acetylcholine-esterase and other choline ester-splitting enzymes. Science m:98-99. BAKER, G.M. and CHEN, C.H. (1989). The effects of ethanol on the structural stability of acetylcholine receptor and the activity of various molecular forms of acetylcholinesterase. Biochem. Biophy. Acta. 992:333-340. BENARROCH, E.E.. GRANATA. A.R.. RUGGIERO, D.A., PARK, O.H.. and REIS, D.J. (1986). Neurons of C, area mediate cardiovascular response initiated from ventral medullary surface. Am. J. Physiol. m::R932-R945. BLOMQUIST. G., SALTIN, B., and MITCHELL, A.. (1970). Acute effects of ethanol ingestion on the response to submaximal and maximal exercise in man. Circulation a:463-470. BOB0 , W. (1972). Effects of alcohol upon maximum oxygen uptake, lung ventilation. Res. Q. 43:1-6.
and heart rate.
BONDY, S.C. (1992). Ethanol toxicity and oxidative stress. Toxicol. Lett. 63:23 l-241 BOOTH. F.W., and THOMPSON, D.B. (1991). Molecular and cellular adaptation of muscle in response to exercise: Perspective of various models. Physiol. Rev. 71:541-585. BURMISTROV, S.O., MASHEK, O.P. and KOTIN. A.M. (1992). Impact of acute alcohol intoxication on the antioxidative system and creatine kinase activity in the rat embryonic brain. Eksptl. Klin. Farmako. a:54-56. BYKOVA. L.P., and ZHUKAVA, T.P. (1991). Action of ethanol and limontar during neonatal development on lipid peroxidation and on the antioxidant protection system in the brain and liver tissue of neonatal rats. Byull. Eksp. Biol. Med. m:580-582. COLLINS, A.C.. SMOLEN, A., WAYMAN, A.L., and MARKS, M.J. ( 1984). Ethanol and temperature effects on five membrane bound enzymes. Alcohol. 1237-246. DAVIES, J.J.A., QINTANILLA, A.T.. BROOKS, G.A.. and PACKER, L. (1982) Free Radicals and tissue damage produced by exercise. Biochem. Biophys. Res. Commun. 107: 1198- 1205. DUBE, S.N., SOMANI, S.M., and COLLIVER, J.A. (1990). Interactive effects of physostigmine exercise on cholinesterase activity in RBC tissues of rat. Part-I. Arch. Int. Pharmacodyn.Ther.m:7182.
and
DUBE, S.N., SOMANI, S.M., and BABU. S.R. (I 993). Concurrent acute exercise alters central and peripheral responses to physostigmine. Pharmacol. Biochem. Behav. %:827-834.
Exercise. ethanol/choltnesterase ECKSTEIN, F.P.. BAUGHMAN. R.W., and QUINN, J. (1988) innervation in rat cerebral cortex. Neuroscience m:457-474.
669 An anatomical
study of cholinergic
ELLMAN. G.L., COURTNEY, D.K., ANDERS, V.J., and FEATHERSTONE, R.M. (1961). Rapid calorimetric determination of acetylcholinesterase activity. Biochem. Pharmacol. 28-95; 1961. ESTEVEZ, E.E., JERUSALINSKY, D., MEDINA, J.H., and ROBERTIS, E.D. (1984). Cholinergic muscarinic receptors in rat cerebral cortex, basal ganglia and cerebellum undergo rapid and reversible changes after acute stress. Neuroscience 11:1353-l 357. HASHEMZADEH-GARGARI, H. and MANDEL, P. (1989). Genetically-determined responses of central cholinergic markers: the effects of ethanol on inbred strains of mice. Neurotoxicology a:555-568. HOUMARD, J.A., LANGENFELD, M.E., WILEY, R.L. and SIEFERT. J. (1987). Effects of the acute ingestion of small amounts of alcohol upon 5-mile run times. J. Sports Med. n:2.53-257. HUSAIN. K., and VIJAYARAGHAVAN. R. (1989). DFP induced changes in acetylcholinesterase and glycogen level in certain brain regions of mice. Ind. J. Physiol. Pharmacol. 2:250-252.
activity
KENDRICK, Z.V., AFFRIME, M.B., and LOWENTHAL, D.T. (1993). Effect of ethanol on metabolic responses to treadmill running in well-trained men. J. Clin. Pharmacol. B:136-139. LASNER, M., ROTH, L.G., and CHEN, C.H. Structure-functional (1995). Structure-functional effects of a series of alcohols on acetylcholinesterase-associated membrane vesicles: Elucidation of factors contributing to the alcohol action. Arch. Biochem. Biophys. m:391-396. LISHMAN, W.A. (1990). Alcohol and the brain. Br. J. Psychiatr. l-5&635-644. MATIN, M.A. and HUSAIN, K. (1985). Striatal neurochemical changes and motor dysfunction in mipafox treated animals. Meth. Find. Clin. Exptl. Pharmacol. 2:79-81. MAZES& R., PICON-REATEGUL, E., and THOMAS, R. (1968). Effect of alcohol and altitude on man during rest and work. Aerospace Med. 3:403-406. NORDMANN,
R. (1987) Oxidative stress from alcohol in the brain. Alcohol. L:75-82.
OHKAWA, H., OHISHI, N., and YAGI, K. (1979). Assay for lipid peroxides in animals and tissues by thiobarbituric acid reaction. Anal. Biochem. 95:35 l-35. OTT, P. (1985). Membrane acetylcholinesterases: Purification, molecular properties and interactions with amphiphilic environments. Biochem. Biophys. Acta. 822:375-392. PAL, R., NATH, R., and GILL, D. (1993). Lipid peroxidation and antioxidant defense enzymes in various regions of adult rat brain after coexposure to cadmium and ethanol. Pharm. and Toxic. a:209-214. PAWLOWSKA, D., MONIUSZKO-JANKONIUK, and SOLTYS, M. (1985) Parathion methyl effect on the activity of hydrolytic enzymes after single physical exercise in rats. Pol. J. Pharmacol. Pharm. u:629-638. RAWAT, A.K. (1976). Neurobiol. B:123-172.
Neurochemical
consequences
of ethanol on the nervous system.
Int. Rev.
READ, S.M., and NORTHCOLE, D.H. (1981) Minimization of variation in the response to different protein of the Coomassie blue G dye-binding assay for protein. Anal. Biochem. fi:53-64. RITCHIE, J.M. (1985). The aliphatic alcohols, In: The Pharmacological Basis of Therapeutics, A.G. Gilman, L.S. Goodman, T.W. Rall, and F. Murad, (Eds), Ed. 7, pp 372-386, McMillan Publ. Co., New York. RYHANEN, R., KAJOVAARA, M., HARRI, M., KALISTE-KORHONEN, E.,and (1988). Physical exercise affects cholinesterases and organophosphate response. 19:815-820.
HANNINEN, 0. Gen. Pharmacol.
670
K. Husam and S.M. Somani
SIDELL, F., and PLESS, J. (1971). Ethyl alcohol blood levels and performance administration to man. Psychopharmacologia fi:246-26 1.
decrements
after oral
SOLIMAN, K.F.. and GABRIEL, N.N. (1985). Brain cholinergic involvement in the rapid development of tolerence to the hypothermic action of ethanol. Gen. Pharmacol. &5:137-140. SOMANI, S.M. ( 1994). Influence of exercise induced oxidative stress on the central nervous system. In: Exercise and Oxygen Toxicity. C.K. Sen. L. Packer. and 0. Hanninen, (Eds)., pp 462-477, Elsevier Science Publishers. SOMANI, S.M.. BABU. S.R., ARNERIC, S.P., and DUBE. S.N. (1991). Effect of cholinesterase inhibitor and exercise on choline acetyltransferase and acetylcholinesterase activities in rat brain regions. Pharmacol. Biochem. and Behav. 39:337-343. SOMANI, SM.. RYBAK, L.P.. and RAW, R.P. (1995). Effect of trained exercise on antioxidant system in rat brain regions. Pharmacol. Biochem. Behav. s:635-637. SOMANI, SM., HUSAIN. K., DIAZ-PHILLIPS, L.. LANZOTTI. D.J., KARETI. K.R., and TRAMMELL. G.L. (1996). Interaction of exercise and ethanol on antioxidant enzymes in brain regions of rat. Alcohol (In Press). SUN, A.Y., and SAMORAJSKI. T. (1970). Effects of ethanol on the activity of adenosine triphosphatase and acetylcholinesterase in synaptosomes isolated from guinea pig brain. J. Neurochem. 12: 1365-I 672. SYTINSKII, 1. A. and Flerova. N.I. (1982). Glutamyl transferase and acetylcholinesterase various areas of the rat brain in alcoholic intoxication. Ukrain. Biokhim. Z. 54:149-153. TABAKOFF, B., JAFFE, R.C. and RITZMAN, R.F. (1978). Corticosterone ethanol drinking and withdrawal. J. Pharm. Pharmacol. X:371-374.
concentrations
activity in
in mice during
TSAKIRIS, S., and KONTOPOULOS, A.N. (1993). Time changes in Na’. K’-ATPase, Mg”-ATPase, and acetylcholinesterase activities in the rat cerebrum and cerebellum caused by stress. Pharmacol. Biochem. Behav. a:339-342. UYSAL. M.. KUTALP. G.. ODZEMIRLER. G.. and AYKAC. G. (1989). Ethanol-induced changes in lipid peroxidation and glutathione content in rat brain. Drug Alcohol. Depend. a:227-230.
Inquiries and reprint requests should be addressed to:
Satu M. Somani, Ph.D. Professor of Pharmacology and Toxicology Southern Illinois University School of Medicine Department of Pharmacology P.O. Box 19230 Springfield, IL 62794- 1222 USA