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The Journal of Neuroscience, December 15, 2000, 20(24):8972-8979
Inhibition of Krebs Cycle Enzymes by Hydrogen Peroxide: A Key
Role of  -Ketoglutarate Dehydrogenase in Limiting NADH Production
under Oxidative Stress
Laszlo
Tretter and
Vera
Adam-Vizi
Department of Medical Biochemistry, Neurochemical Group, Semmelweis
University of Medicine, Budapest, H-1444, Hungary
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ABSTRACT |
In this study we addressed the function of the Krebs cycle to
determine which enzyme(s) limits the availability of reduced nicotinamide adenine dinucleotide (NADH) for the respiratory
chain under H2O2-induced oxidative stress, in
intact isolated nerve terminals. The enzyme that was most vulnerable to
inhibition by H2O2 proved to be aconitase,
being completely blocked at 50 µM H2O2.  -Ketoglutarate dehydrogenase
(-KGDH) was also inhibited but only at higher
H2O2 concentrations ( 100 µM),
and only partial inactivation was achieved. The rotenone-induced
increase in reduced nicotinamide adenine dinucleotide (phosphate)
[NAD(P)H] fluorescence reflecting the amount of NADH available
for the respiratory chain was also diminished by
H2O2, and the effect exerted at small
concentrations ( 50 µM) of the oxidant was
completely prevented by 1,3-bis(2-chloroethyl)-1-nitrosourea (BCNU), an inhibitor of glutathione reductase. BCNU-insensitive decline
by H2O2 in the rotenone-induced NAD(P)H
fluorescence correlated with inhibition of -ketoglutarate
dehydrogenase. Decrease in the glutamate content of nerve terminals was
induced by H2O2 at concentrations inhibiting
aconitase. It is concluded that (1) aconitase is the most sensitive
enzyme in the Krebs cycle to inhibition by
H2O2, (2) at small
H2O2 concentrations (50 µM)
when aconitase is inactivated, glutamate fuels the Krebs cycle and NADH
generation is unaltered, (3) at higher H2O2
concentrations (100 µM) inhibition of -ketoglutarate
dehydrogenase limits the amount of NADH available for the respiratory
chain, and (4) increased consumption of NADPH makes a
contribution to the H2O2-induced decrease in
the amount of reduced pyridine nucleotides. These results emphasize the
importance of -KGDH in impaired mitochondrial function under
oxidative stress, with implications for neurodegenerative diseases and
cell damage induced by ischemia/reperfusion.
Key words:
hydrogen peroxide; oxidative stress; mitochondria; Krebs
cycle; -ketoglutarate dehydrogenase; aconitase; NADH
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INTRODUCTION |
It has been recognized in recent
years that mitochondria play a crucial role in conditions involving
oxidative stress, e.g., in neurodegenerative diseases (Olanow, 1993 ;
Beal, 1996; Gibson et al., 1998a,b), excitotoxicity (Wang and Thayer,
1996; White and Reynolds, 1996), and ischemia/reperfusion (Phillis,
1994; Siesjö et al., 1995; Zhang and Lipton, 1999).
The respiratory chain is a rich source of reactive oxygen species
(Boveris et al., 1972; Loschen et al., 1974; Nohl et al., 1981; Cino
and Del Maestro, 1989; Dykens, 1994), but mitochondria could also be a
vulnerable target of oxidative stress (Hyslop et al., 1988; Zhang et
al., 1990). To understand the mechanisms by which reactive oxigen
species have a short or long term impact on the functional integrity of
cells, it is important to identify specific mitochondrial targets and
to characterize processes involved in the oxidative stress-induced
mitochondrial damage.
Hydrogen peroxide is a relatively mild means of inducing oxidative
stress, because components of the respiratory chain are only marginally
influenced (Zhang et al., 1990), and nonspecific peroxidation of
membrane lipids is not evoked by this oxidant (Tretter and Adam-Vizi,
1996). The relevance of
H2O2 for modeling oxidative
stress is emphasized by the fact that excessive production of
H2O2 is characteristic in
aging brain (Sohal et al., 1994; Auerbach and Segal, 1997) and has been
demonstrated in the striatum during reperfusion after an hypoxic insult
(Hyslop et al., 1995). In addition, generation of
H2O2 has also been
suggested to contribute to the neuronal damage observed in Parkinson's
disease (Schapira, 1994).
Previous studies suggested an impaired mitochondrial function evolving
in the early phase of an
H2O2-induced oxidative
stress, because there was a decline in the ATP level and ATP/ADP ratio in nerve terminals (Tretter et al., 1997) and a potentiated
glutamate-induced loss of mitochondrial membrane potential (  m) in
cultured cortical cells (Scanlon and Reynolds, 1998). Furthermore, we
found that H2O2 decreased
the activity of -ketoglutarate dehydrogenase (-KGDH) in nerve
terminals and suggested that m was reduced as a result of an
impaired respiratory capacity because of an insufficient amount of NADH
generated in the Krebs cycle (Chinopoulos et al., 1999).
The aim of the present work was to address specifically the function of
the Krebs cycle, and to identify the enzymes responsible for limiting
the availability of NADH to the respiratory chain during an acute
exposure to H2O2-mediated
oxidative stress. Studying oxidative stress-induced loss of functions
in in situ mitochondria in nerve terminals is relevant in
the light of the observation that over the progress of certain
neurodegenerative diseases, such as Alzheimer's disease, mitochondrial
damage appears to start at nerve terminals (Sumpter et al., 1986; see
also Blass and Gibson, 1991). In this preparation a limited capacity of
the respiratory chain in the early stage of an
H2O2-induced oxidative
stress appeared to be satisfactory under resting conditions, but when
combined with other insults (mitochondrial blockers,
[Na+]i load) it
resulted in a complete functional collapse (Chinopoulos et al.,
2000).
We demonstrate here that aconitase is the most sensitive enzyme to
H2O2 in the Krebs cycle;
however, inhibition of -KGDH by the oxidant limits the amount of
NADH available to the respiratory chain. During an acute exposure of
nerve terminals to H2O2,
glutamate serves as an alternative metabolite, thus NADH production in
the Krebs cycle is maintained. This study, by underlying the critical role of -KGDH in the impaired mitochondrial function under oxidative stress, may be relevant to neurodegeneration in which a reduced function of this enzyme appears to play a crucial role (Blass and
Gibson, 1991; Mizuno et al., 1994; Gibson et al., 1998a).
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MATERIALS AND METHODS |
Preparation of synaptosomes
Isolated nerve terminals (synaptosomes) were prepared from brain
cortex of guinea pigs as detailed elsewhere (Chinopoulos et al., 2000).
Synaptosomes suspended in 0.32 M sucrose (~20 mg/ml of
protein) were kept on ice, and aliquots were used for further manipulation. Incubations were carried our in standard medium containing (in mM): 140 NaCl, 3 KCl, 2 MgCl2, 2 CaCl2, 10 PIPES, pH 7.38, and 10 mM glucose at 37°C as described below.
Steady-state NAD(P)H quantification
Aliquots of synaptosomes were incubated in the standard medium
(0.5 mg/ml protein). The intrasynaptosomal NAD(P)H level was measured
fluorimetrically in the dual emission mode of a PTI Deltascan fluorescence spectrophotometer using 344 nm excitation wavelength with
emission at 460 and 550 nm (used as a reference) wavelengths. Changes
in NAD(P)H concentration were quantified using a calibration curve of
externally added NADH (1-3 nmol).
Determination of activities of TCA cycle enzymes
Synaptosomes were incubated in standard medium (0.5 mg/ml
protein) in the presence or absence of
H2O2, then aliquots were transferred into different media for enzyme assays.
Citrate synthase. Citrate synthase was measured as described
by Srere (1969). Aliquots of synaptosomes (50 µg protein) were added
to a medium containing 0.1 mM acetyl-CoA, 0.2 mM dithionitrobenzoic acid, 0.2% Triton X-100
(v/v), 100 mM Tris-HCl, pH 8.0. Changes in the
absorbance at 412 nm were monitored in a GBC UV/VIS 920 spectrophotometer. After a stable baseline signal was obtained, the
enzyme reaction was started with addition of 0.2 mM oxaloacetate.
Aconitase. Aconitase was assayed as described by Hausladen
and Fridovich (1996). Synaptosomal aliquots (100 µg protein) were transferred to a medium containing 50 mM
Tris-HCl, 0.6 mM MnCl2, 30 mM sodium citrate, 0.2% Triton X-100, 2 U/ml
isocitrate dehydrogenase (NADP+-dependent), and catalase (1 U/ml)
at 37°C, pH 7.4. The reaction was initiated by addition of 0.2 mM NADP+.
Fluorescence was monitored at 340 nm with a GBC UV/VIS 920 spectrophotometer. Results were calculated with
EmM = 6.22 for NADH.
-Ketoglutarate dehydrogenase.
-Ketoglutarate dehydrogenase was assayed essentially as described by
Lai and Cooper (1986). Aliquots (75 µg protein) were added to a
medium containing 0.2 mM thiamine pyrophosphate,
2 mM NAD+, 1 mM MgCl2, 0.4 mM ADP, 10 µM rotenone,
0.1% (v/v) Triton X-100, 50 mM potassium
phosphate buffer, pH 7.4, and 0.2 mM EGTA. The reaction was initiated by addition of 0.12 mM
HS-CoA and 1 mM -ketoglutarate.
Dithiothreitol was omitted from the assay medium to prevent a possible
reactivation of oxidative stress-sensitive SH groups of the enzyme.
NADH fluorescence was followed as described above.
Succinate dehydrogenase. This was assayed as described by
Tan et al. (1993). Synaptosomal protein (50 µg) was transferred to an
assay medium containing 60 µM
2,3-dimethoxy-5-methyl-6-decyl-1,4-benzo-quinone, 50 µM 2,6-dichlorophenolindophenol (terminal
electron acceptor), 2 µM rotenone, 5 mM KCN, 1 mM EGTA, 0.2%
Triton X-100 (v/v), 250 mM saccharose, and 50 mM potassium phosphate buffer, pH 7.6, at 37°C.
After preincubation for 5 min, the reaction was started by addition of
20 mM succinate. Absorbance changes were recorded at 600 nm in a GBC UV/VIS 920 recording spectrophotometer. Enzyme activities were calculated with EmM = 19.1 for 2,6-dichlorophenolindophenol.
Malate dehydrogenase. Malate dehydrogenase was
measured as described by Kitto (1969). Aliquots (20 µg protein) were
transferred into a medium containing 10 µM
rotenone, 0.2% Triton X-100, 0.15 mM NADH, and
100 mM potassium phosphate buffer, pH 7.4, at
37°C. The reaction was started by addition of 0.33 mM oxaloacetate. Absorbance was monitored as
described above.
Determination of NADP+ + NADPH pool
An assay described by Nisselbaum and Green (1969) was used for
NADP + NAD(P)H measurements. Synaptosomes (0.5 mg/ml) were preincubated
in standard medium for 10 min, then
H2O2 was added. Samples
were treated as described (Klingenberg, 1974). Protein samples (50 µg) were added to a medium containing 3.5 U/ml glucose 6-phosphate
dehydrogenase, 0.5 mM thiazolyl blue (MTT), 0.2 mM phenazine ethosulfate (PES), 50 mM Tris-HCl,
and 0.5 mM EDTA, pH 7.4. Changes in the absorbance were
followed at 570 nm in a GBC UV/VIS 920 double-beam spectrophotometer at
37°C. After a stable baseline was obtained, the reaction was started
by addition of 5 mM glucose-6-phosphate. External and
internal calibrations with known amounts of
NADP+ were used for quantification of results.
Determination of NAD+ + NADH pool
NAD+ + NADH content in synaptosomes
was measured as described (Bernofsky and Swan, 1973), using a sampling
method (Klingenberg, 1974). Samples from synaptosomes (20 µg protein)
were transferred to an assay medium containing 0.2 mg alcohol
dehydrogenase (Sigma A3263, Sigma, St. Louis, MO), 0.5 mM
MTT, 0.2 mM PES, 0.6 M ethanol, 50 mM Tris-HCl, and 0.5 mM EDTA, pH 7.8, and
absorbance was followed at 570 nm (30°C) in a GBC UV/VIS 920 spectrophotometer. External and internal calibrations with known
amounts of NAD+ were used for
quantification of results.
Assay for glutathione reductase activity
For glutathione reductase assay (Carlberg and Mannervik, 1985),
aliquots of synaptosomes (0.2 mg protein) were incubated in a medium
containing 0.2% Triton X-100, 0.1 mM NADPH, 100 mM potassum phosphate, and 1 mM EGTA, pH 7.4, at 37°C. After a stable baseline was obtained, reaction was started
by addition of 1 mM oxidized glutathion. NADPH
absorbance was measured as described above.
Determination of glutamate content of synaptosomes
The method described by Hinman and Blass (1981) was adapted to
measure the amount of glutamate. Aliquots (200 µl) of synaptosomes incubated in standard medium (0.5 mg/ml) were added to an assay medium
containing glutamic dehydrogenase (Sigma G7882) 7.5 U per assay, 1 mM NADP+, 1 mM
MgCl2, 0.6 mM
p-iodonitrotetrazolium violet, 6.5 µM phenazine methosulfate, 2 mM ADP, 0.1% Triton X-100, 0.2 mM EGTA, and 50 mM Tris-HCl
buffer, pH 7.8. Changes in the absorbance were followed at 500 nm
(30°C) in a GBC UV/VIS 920 spectrophotometer. Internal calibrations
with known amounts of glutamate were used for quantification of results.
Statistics
Statistical differences were evaluated with ANOVA (Sigmastat)
for multiple comparisons.
Materials
Standard laboratory chemicals were obtained from Sigma (St.
Louis, MO). Special peroxide- and carbonyl-free Triton X-100 (Sigma) was used throughout the experiments for disrupting synaptosomal membranes without further oxidative damage. BCNU was a gift from Laszlo
Kopper (Department of Pathology, Semmelweis University, Budapest).
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RESULTS |
Effect of H2O2 on the activity of enzymes
in the Krebs cycle
The activity of enzymes in the Krebs cycle was investigated in the
presence of H2O2, with a
particular focus on enzymes working with
NAD+ as a cofactor. Synthesis of citrate
is generally regarded as the "first" reaction of the cycle
catalyzed by citrate synthase, which proved to be insensitive to
H2O2 (Table
1). By contrast, aconitase, which has
been reported previously to be sensitive to inhibition by superoxide
anion (Patel et al., 1996; Gardner et al., 1997) and nitric oxide and
peroxynitrate (Andersson et al., 1998), was inhibited by
H2O2 in a
concentration-dependent manner (Fig. 1).
The activity of aconitase was significantly reduced to 75.5 ± 4.9% of control (n = 8, p < 0.05)
after 5 min incubation with 5 µM
H2O2, nearly completely
inhibited (to 13.6 ± 1.27% of control) by 25 µM
H2O2, and completely
inactivated by 50 µM
H2O2.
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Table 1.
The effect of H2O2 on the activity
of citrate synthase, succinate dehydrogenase, and malate dehydrogenase
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Figure 1.
Inhibition of aconitase by
H2O2. Nerve terminals were incubated in the
absence (control) or presence of different concentrations of
H2O2. Aconitase activity was measured after
incubation with H2O2 for 5 min. In the
control samples the activity of aconitase was
86.4±3.4 nmol · min 1 · mg1
protein taken as 100%. Enzyme activities are expressed as percentage
of control. Data are the average ± SEM of eight determinations
made in four independent experiments. *Significant compared with the
control, p < 0.05.
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Isocitrate is converted to -ketoglutarate by
NAD+-dependent isocitrate dehydrogenase,
which in our previous study was not inhibited by
H2O2 applied in 100 or 500 µM concentrations (Chinopoulos et al., 1999).
-Ketoglutarate dehydrogenase is the second dehydrogenase in the
cycle that generates NADH. As demonstrated in Figure
2a, the activity of -KGDH
was inhibited by H2O2 in
proportion to the concentration of the oxidant. Statistically
significant reduction of the enzyme was observed at 50 and 100 µM
H2O2 after incubation for
10 or 5 min, respectively, but at 500 µM,
incubation for 2.5 min was sufficient for the enzyme to be
significantly inhibited (Fig. 2b). It should be noted that
in comparison with the effects on aconitase, higher concentrations of
H2O2 were required for inhibiting -KGDH, and the enzyme was not completely inactivated even
at 500 µM
H2O2 present for 10 min
(38.3 ± 5.6% of control).
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Figure 2.
Inhibition of -ketoglutarate dehydrogenase by
H2O2. Nerve terminals were incubated in the
absence (control) or presence of different concentrations of
H2O2 for 5 or 10 min (a),
or with 100 and 500 µM
H2O2, respectively, for different
lengths of time (b). In control samples the
activity of -KGDH was 14.2 ± 1.2 nmol · min1 · mg1
taken as 100%. Data are the average ± SEM of eight
determinations made in three independent experiments. *Significant
compared with the control, p < 0.05.
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Succinate dehydrogenase present in rat liver mitochondria was reported
to be vulnerable to a strong lipid peroxidative insult induced by
ADP/Fe (Tretter et al., 1987), but in heart submitochondrial particles
H2O2 had no detectable
effect on the enzyme (Zhang et al., 1990). Table 1 shows that succinate
dehydrogenase in synaptosomes was sensitive to
H2O2. However, it is
important to note that 70.8 ± 3.7% of the enzyme activity was
still maintained after incubation with 500 µM
H2O2 for 10 min, whereas
the activity -KGDH was decreased to 38.2 ± 5.6% of control
under the same condition (Fig. 2b). These results show that
the extent of inhibition of this enzyme is smaller than that of
-KGDH at identical concentrations of the oxidant.
Malate dehydrogenase, which has a relatively high activity [see also
Yudkoff et al. (1994)] was insensitive to
H2O2-mediated oxidative
stress (Table 1).
These results indicate that three enzymes are inhibited in the Krebs
cycle during an acute exposure of nerve terminals to H2O2: (1) aconitase, which
is the most sensitive to the oxidant, (2) -KGDH, the only enzyme
inhibited by H2O2 that
contributes directly to the formation of NADH, and (3) succinate
dehydrogenase, which appears to be a less vulnerable target to
H2O2 than is -KGDH.
Changes in the NAD(P)H fluorescence caused by to
H2O2
To investigate whether
H2O2-mediated inhibition of
enzymes in the Krebs cycle, particularly that of -KGDH, could limit
the amount of NADH available for the respiratory chain, we monitored fluorescence changes at 344 nm in nerve terminals. Because fluorescence of both NADH and NADPH is measured by this method, in this paper the
fluorescence signals obtained are referred to as changes in the NAD(P)H level.
We have reported recently that oxidative stress induced by 100 or 500 µM H2O2
decreased the basal fluorescence signal, indicating a decrease in the
steady-state NAD(P)H level (Chinopoulos et al., 1999) (Fig.
3, inset, trace b).
Here the effect of H2O2 was
investigated further by recording changes in the NAD(P)H level induced
by rotenone, inhibitor of complex I (NADH/ubiquinone oxidoreductase) in
the respiratory chain. Addition of rotenone (2 µM) induced an abrupt increase in the
fluorescence of NAD(P)H (Fig. 3, inset, trace a,
NAD(P)H), this signal being proportional to the
amount of NADH available for the respiratory chain. We found that
monitoring the rotenone-induced fluorescence signal, rather than the
basal fluorescence, enabled us to obtain more consistent results and better resolution of the oxidant-induced changes in the NAD(P)H level.
Figure 3 (inset, trace b) shows a typical
experiment in which exposure to
H2O2 for 5 min reduced the
rotenone-induced fluorescence signal, indicating a decrease in the
NAD(P)H level. The effect of
H2O2 in both 100 and 500 µM concentrations (Fig. 3) was significant
after incubation for 2.5 min (72 ± 8.1% and 47 ± 4.9% of
control, respectively) and was maximal after 7.5 min (46.7 ± 1.5% and 31.8 ± 2.3% of control, respectively).
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Figure 3.
Decrease in the NAD(P)H level by
H2O2. Fluorescence of NAD(P)H was monitored in
synaptosomes (0.5 mg/ml protein) incubated in standard medium in the
presence or absence of H2O2. Five minutes after
application of H2O2, rotenone (2 µM) was added. To calculate NAD(P)H, the fluorescence
measured 10 sec before addition of rotenone was subtracted from that
obtained 100 sec after rotenone application. NAD(P)H representing
the effect of rotenone in the absence of H2O2
(inset, trace a) was taken as control
(100%). The rotenone-induced NAD(P)H signals obtained in the presence
of 100 or 500 µM H2O2 are shown
(% of control) as a function of time; 100%
represents 1.18 ± 0.04 nmol NAD(P)H, calibrated with added
amounts of NADPH. Results are mean ± SEM of five determinations
from three independent experiments. *Significant compared with the
control, p < 0.05.
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The decrease in NAD(P)H was proportional to the concentration of the
oxidant (Fig. 4, curve a).
After incubation with 500 µM
H2O2 for 5 min, the
rotenone-induced NAD(P)H signal decreased to 34 ± 0.4% as
compared with control, but the effect of
H2O2 at 15 µM was already significant (83 ± 3.6%).
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Figure 4.
Decrease in the NAD(P)H level by
H2O2 in the absence or presence of BCNU,
inhibitor of glutathione reductase. Synaptosomes (6 mg/ml) were
incubated in the presence (b) or absence
(a) of BCNU for 30 min at 37°C, then cooled to
0°C. Aliquots (1 mg protein) were incubated in standard medium (0.5 mg/ml), and NAD(P)H fluorescence was measured as described for Figure
3, in the presence of different concentrations of
H2O2 for 5 min. Results are expressed as
mean ± SEM of three independent experiments; 100% represents
1.17 ± 0.06 nmol NAD(P)H. Inset shows the activity
of glutathione reductase measured after incubation with different
concentrations of BCNU for 30 min. The activity of glutathione
reductase in control samples (100%) was 28 ± 0.56 nmol · min1 · mg1
protein. Data are mean ± SEM of five determinations,
p < 0.05.
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The effect of H2O2 on the NAD(P)H level in
glucose-free medium
H2O2 has been reported
to inhibit gliceraldehyde-3-phosphate-dehydrogenase (Hyslop et al.,
1988; Janero et al., 1993); thus we investigated whether a reduced NADH
production in the glycolysis could contribute to the results shown in
Figures 3 and 4. For this, the effect of
H2O2 on NAD(P)H was
investigated in the absence of glucose, using the experimental protocol
shown in Figure 3 (inset). In the absence of glucose,
glycolysis is unable to proceed; thus NADH is generated mainly in the
Krebs cycle from alternative substrates. Synaptosomes were preincubated
for 20 min in glucose-free standard medium in the presence of 5 mM 2-deoxyglucose (preventing glycolysis driven
by a possible glycogen store), and the rotenone-induced elevation in
the NAD(P)H fluorescence was investigated after pretreatment with
various concentrations of
H2O2 for 5 min. In Table
2 the results are compared with those
obtained in glucose-containing medium, and this shows that the effect
of H2O2 on the
rotenone-induced NAD(P)H signal was quantitatively similar under these
conditions. The presence or absence of 2-deoxyglucose made no
difference in the results (data not shown). These findings indicate
that nerve terminals are able to generate NADH in the absence of
glucose, and this NADH generation is sensitive to
H2O2-induced oxidative stress.
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Table 2.
Comparison of the effect of H2O2 on
the rotenone-induced NAD(P)H signal in the presence or absence of
glucose
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Pyridine nucleotide pool is unaltered by
H2O2
Given the observation that treatment of the
P388D1 cell line (Hyslop et al., 1988) and
cardiomyocytes (Janero et al., 1993) with
H2O2 caused a loss of
pyridine nucleotides, it was of interest to determine whether this
occurs in nerve terminals contributing to the
H2O2-induced decrease in
the rotenone-induced NAD(P)H fluorescence. Thus, we measured the total
NAD+/NADH and
NADP+/NADPH pool in the absence and
presence of 100 or 500 µM
H2O2. Table
3 shows that the total pyridine
nucleotide pool remained unchanged in the presence of
H2O2; the small decrease
observed in the NAD+/NADH content at 500 µM H2O2 was
statistically insignificant.
Inhibition of glutathione reductase partly prevents the
H2O2-induced decrease in the NAD(P)H signal
In addition to catalase, glutathione peroxidase plays an important
role in the brain in the elimination of
H2O2 (Desagher et al.,
1996; Dringen et al., 1999). Hence an increased consumption of NADPH by
glutathione reductase in the presence of
H2O2 could contribute to
the decrease in the rotenone-induced NAD(P)H signal. To test this
possibility, glutathione reductase was inhibited by BCNU, which
carbamoylates thiol groups of the enzyme (Becker and Schirmer, 1995),
and changes in the rotenone-induced NAD(P)H fluorescence caused by
H2O2 were investigated.
BCNU at 200 µM concentration was used in these
experiments, and it almost completely inhibited glutathione reductase
(86.7 ± 1.4% inhibition) (Fig. 4, inset) without
influencing the resting NAD(P)H level or the rotenone-induced NAD(P)H
signal (data not shown). At higher concentrations of BCNU, the control
and the rotenone-induced fluorescent signals were also decreased (data
not shown), probably reflecting an inhibition of other enzymes, most
notably lipoamide dehydrogenase (Ahmad and Frischer, 1985). In the
presence of BCNU, the effect of small concentrations of
H2O2 (5-50
µM) on the rotenone-induced NAD(P)H signal was
abolished (Fig. 4, curve b). The effect of
H2O2 at higher
concentrations was also reduced after pretreatment with BCNU; however,
the decrease in the rotenone-induced NAD(P)H signal remained
significant in the presence of both 100 µM
(21.2 ± 8.4%) and 500 µM
H2O2 (35.1 ± 4.2%)
(Fig. 4, trace b).
These experiments indicate that consumption of NADPH via the
glutathione reductase/peroxidase system accounts for the decreased rotenone-induced NAD(P)H signal in the presence of small concentrations of H2O2 (<50
µM) and also contributes to that observed at higher concentrations of the oxidant. Therefore, the decrease in the NAD(P)H
fluorescence induced by
H2O2 at 100 or 500 µM concentration, which was observed in the presence of
BCNU, could be taken primarily as a reflection of a decrease in the
NADH level, unrelated to consumption of NADPH caused by elimination of
the oxidant.
We also tried to block glutathione peroxidase by mercaptosuccinate, but
the activity of glutathione peroxidase was unaltered after incubation
with 10 mM mercaptosuccinate for 60 min at 37°C. This
shows that even the longest incubation period (~60 min) tolerated by
synaptosomes without disturbance in integrity was not sufficient for
the drug to gain access to the interior of nerve terminals.
Correlation between inhibition of -KGDH and decrease in NAD(P)H
level induced by H2O2
To establish which enzyme(s) could limit NADH production during
H2O2-induced oxidative
stress, the relationship between the decrease in the rotenone-induced
NAD(P)H signal and the activity of -KGDH and aconitase was analyzed.
Only data obtained in the presence of BCNU (Fig. 4, curve b)
were considered, because in these, fluorescence changes attributable to
an increased NADPH consumption by glutathione reductase are not
involved. Inhibition of succinate dehydrogenase was not considered,
because in nerve terminals, reactions in the TCA cycle between
succinate and oxaloacetate operate at a higher rate than does -KGDH
(Yudkoff et al., 1994); thus it is unlikely that succinate
dehydrogenase could limit the flux in the TCA cycle under conditions in
which -KGDH is substantially inhibited. A lack of correlation
between the activity of succinate dehydrogenase and the flux through
the cycle has been reported in rat heart (Cooney et al., 1981).
Aconitase is also not a rate-limiting enzyme, but because it is very
sensitive to H2O2 and at
higher oxidant concentrations (50-500 µM) is
inactivated completely, we studied the possible contribution of
aconitase to the limitation of NADH production in the TCA cycle. Figure
5 shows decreases in the rotenone-induced
NAD(P)H signal as a function of percentage inhibition of -KGDH and
aconitase, obtained in the presence of different concentrations of
H2O2 (10-500
µM). This Figure indicates a lack of
correlation between aconitase activity and NAD(P)H level; inhibition of
the enzyme by 86.5 ± 1.3% in the presence of 25 µM
H2O2 was not associated
with any alteration in the NAD(P)H signal, whereas a decrease in the
NAD(P)H level was seen at high concentrations of
H2O2 when aconitase was
completely inactivated (50-500 µM). By
contrast, inhibition of -KGDH in the presence of 50-500
µM
H2O2 appeared to correlate
with a decrease in the NAD(P)H level, suggesting that inhibition of
this enzyme could be a crucial factor in limiting the NADH production
in the Krebs cycle during oxidative stress induced by 100-500
µM
H2O2.
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Figure 5.
Relationship between inhibition of aconitase or
-KGDH and decrease in the rotenone-induced NAD(P)H fluorescence.
Decreases in the rotenone-induced NAD(P)H signal (data in Fig. 4,
curve b) are shown as a function of percentage
inhibition of aconitase (derived from Fig. 1) or -KGDH (from Fig.
2a) as measured after incubation with
H2O2 for 5 min. H2O2
concentrations (in micromoles) are indicated in
brackets. We have shown in separate control experiments
(data not shown) that BCNU at 200 µM concentration has no
effect on the activities of aconitase or -KGDH, nor does it
influence the effect of H2O2 on these enzymes.
Data are average of five [for NAD(P)H measurement] or eight (for
enzyme assays) determinations ± SEM.
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Decrease in the amount of glutamate by
H2O2
In nerve terminals it has been reported that in the absence of
glucose, the flux in the Krebs cycle is partially maintained (Yudkoff
et al., 1994; Erecinska et al., 1996), most likely resulting from a
supply of -ketoglutarate from glutamate by aspartate
aminotransferase (Yudkoff et al., 1994).
To determine whether glutamate could be used as a metabolite under
oxidative stress, we measured the glutamate content in synaptosomes.
The effect of H2O2 and of a
glucose-free condition were similar: both resulted in a decrease in the
total glutamate content (Table 4).
H2O2 at 50 and 500 µM concentrations decreased the glutamate level, and
after 20 min, 50% of the total glutamate content was lost. At lower
H2O2 concentrations, the
amount of glutamate was unchanged (5 µM) or only slightly
decreased (10 µM) (Table 4). Because
glutamate was measured in samples containing synaptosomes and the
medium in which the incubation was performed (see Materials and
Methods), the results obtained reflect a net loss in the amount of
glutamate and are unrelated to release of glutamate from nerve
terminals.
These results indicate that during exposure to
H2O2, glutamate in nerve
terminals could serve as an alternative metabolite when the normal flux
in the Krebs cycle is blocked because of inactivation of aconitase. In
this respect, the effect of a shortage in glucose supply and
H2O2-induced oxidative
stress appears to be similar.
| |
DISCUSSION |
To make a correct estimate of the
H2O2-induced changes in the
formation of NADH, it is crucial to establish the extent to which
changes in the fluorescence of NAD(P)H represent changes in the level
of NADH. The NAD-NADH/NADP-NADPH ratio in synaptosomes is
~10:1 (Table 3), in agreement with data for whole brain (Siesjö et al., 1995) and for different brain regions (Klaidman et al., 1995);
therefore, it is reasonable to assume that fluorescence of NADPH makes
only a small contribution to the total fluorescence monitored at 344 nm. In addition, in the present study the rotenone-induced increase in
the NAD(P)H fluorescence was studied and could be interpreted as an
indication primarily of the level of NADH available for the respiratory
chain. Although this reasoning is correct, the possibility should be
considered that a significant fraction of NADH could be used to
regenerate NADPH when an increased demand is imposed by
H2O2. This was indeed
indicated by the result that inhibition of glutathione reductase by
BCNU partly prevented the H2O2-induced decline in the
rotenone-induced NAD(P)H signal (Fig. 4). Thus an increased consumption
of NADPH in the glutathione peroxidase-reductase system to eliminate
H2O2 appears to drain part
of the NADH present in nerve terminals; i.e., some NADPH is regenerated
at the expense of NADH. We have not addressed the mechanisms by which
this could occur, but the conclusion is compatible with findings that
mitochondria from rat forebrain contain
NADP+-dependent isocitrate dehydrogenase,
malic enzyme, and nicotinamide nucleotide transhydrogenase, which
contribute to the regeneration of NADPH (Vogel et al.,
1999).
The BCNU-insensitive decrease in NAD(P)H signal induced by
H2O2 could be taken as a
reflection of changes in the NADH level that are unrelated to NADPH
consumption by glutathione reductase (Fig. 4, curve b).
Because rotenone was applied to prevent oxidation of NADH in the
respiratory chain, these changes could mirror primarily changes in the
formation of NADH. The present results show that generation of NADH
could be impaired by H2O2
only when present in >50 µM concentrations.
Decreases in the NAD(P)H fluorescence at lower concentrations of the
oxidant (10-50 µM) were completely prevented
by BCNU, which could be attributed to an increased utilization of NADPH
by glutathione reductase.
The question arises as to what could limit the formation of NADH during
H2O2-induced oxidative
stress. The result that omission of glucose (in the presence or absence
of 2-deoxyglucose) in the medium had essentially no effect on the
decrease in the NAD(P)H signal induced by
H2O2 suggests that
inhibition of glycolysis by the oxidant does not contribute to the
effect (Table 2). This shows that the inhibition of
glyceraldehyde-3-phosphate dehydrogenase reported previously (Hyslop et
al., 1988; Janero et al., 1993) makes no contribution to the decline in
NAD(P)H signal induced by
H2O2 in nerve terminals.
Because we also found that
H2O2 (50-500 µM) induced no alteration in the activity of pyruvate
dehydrogenase (data not shown), formation of NADH in the Krebs cycle
needs to be considered in interpreting the effect of
H2O2 on the
rotenone-induced NAD(P)H signal.
We demonstrate in this work that three enzymes in the Krebs cycle could
be inhibited by H2O2:
aconitase, -KGDH, and succinate dehydrogenase. The overall rate of
the Krebs cycle is considered to be determined by the activities of
citrate synthase, isocitrate dehydrogenase, and -KGDH (Cooney et
al., 1981; McCormack et al., 1990; Moreno-Sanchez et al., 1990).
However, Yudkoff et al. (1994) determined in an elaborate study the
flux through two segments of the Krebs cycle in nerve terminals that
between -ketoglutarate and oxaloacetate and that between
oxaloacetate and -ketoglutarateand established that the Krebs
cycle does not always function as a single unified entity. They also
suggested that the overall rate-controlling reaction of the cycle
involves either citrate synthase or pyruvate dehydrogenase (Yudkoff et
al., 1994). In our study, neither of these enzymes was found to be
influenced by H2O2. In this
portion of the cycle (between oxaloacetate and -ketoglutarate), only aconitase was vulnerable to inhibition by
H2O2 (Fig. 1), showing a
complete inactivation at 50 µM
H2O2 or higher.
In the segment between -ketoglutarate and oxaloacetate, -KGDH is
the slowest enzyme (14 ± 1.2 nmol · min1 · mg1
in this study) and is considered to have a flux-controlling function (Hansford, 1980; Yudkoff et al., 1994). We found that this enzyme is
inhibited by H2O2, and for
this, higher concentrations of
H2O2 are required than
those inhibiting aconitase; i.e., aconitase is a more vulnerable target
for H2O2 in the Krebs cycle
than is -KGDH. Aconitase was reported to be inactivated by
O2 (Gardner and
Fridovich, 1992; Gardner et al., 1995), and inhibition of aconitase has
been suggested to be a sensitive marker of intracellular superoxide
generation in mammalian cells (Gardner et al., 1995; Patel et al.,
1996). Our finding that aconitase is inhibited by H2O2, although
corroborating that this enzyme is a sensitive marker of oxidative
stress (Gardner and Fridovich, 1992; Gardner et al., 1995; Patel et
al., 1996), indicates that inhibition of aconitase does not permit the
identification of the type of reactive oxygen species involved in
oxidative stress.
Although aconitase is not considered to be a rate-controlling enzyme
and is not involved directly in NADH generation, when it is completely
inactivated the whole cycle could be blocked. We found, however, that
the rotenone-induced NAD(P)H fluorescence, i.e., NADH level available
for the respiratory chain, was not significantly changed even when
aconitase was inhibited by 100% with 50 µM
H2O2 (Fig. 5). In the
presence of inactivated aconitase, NAD(P)H fluorescence decreased only
when -KGDH was also inhibited (at higher
H2O2 concentrations). It
follows from this finding that in the complete absence of aconitase,
the NADH supply for the respiratory chain can be maintained; thus a
segment of the Krebs cycle must be functional.
It has been observed that in the absence of glucose the flux in the
segment between -ketoglutarate and oxaloacetate is accelerated, indicating that alternative substrate(s) entering at -ketoglutarate could operate this portion of the Krebs cycle (Yudkoff et al., 1994;
Erecinska et al., 1996). Our finding that in the absence of glucose the
NAD(P)H fluorescence was unchanged (Table 2) is consistent with this
suggestion. It has also been suggested (Yudkoff et al., 1994) that
glutamate, which is present at a level of 44 nmol/mg in nerve terminals
(Erecinska et al., 1988) and can be converted to -ketoglutarate, is
the most likely metabolite fueling the Krebs cycle in the absence of
glucose. We found that H2O2 significantly decreased the amount of glutamate present in nerve terminals, similarly to the glucose-free condition, but only at concentrations at which aconitase was inhibited to a large extent (Table 4). This indicates that a similar mechanism could operate under
glucose-free conditions and exposure to
H2O2, when aconitase is inhibited.
It can be concluded that glutamate is likely to be converted to
-ketoglutarate under
H2O2-induced oxidative
stress. In the early stage of an oxidative stress, this mechanism would
rescue a segment of the Krebs cycle when aconitase is already nearly completely inactivated (thus formation of -ketoglutarate from citrate is limited) but -KGDH is still functional. Only when -KGDH is inhibited at higher concentrations of the oxidant (>50 µM) is the production of NADH compromised (Fig. 5).
Because aspartate aminotransferase, but not glutamate dehydrogenase,
has a high activity in this preparation (Cheeseman and Clark, 1988;
Yudkoff et al., 1994), transamination could be the primary
mechanism by which glutamate is converted to -ketoglutarate. The
possible pathways operating in the presence of
H2O2 are outlined in Figure 6.
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Figure 6.
Reactions in the Krebs cycle influenced by low or
high concentrations of H2O2. In the presence of
low concentrations of H2O2,
(a) when aconitase is completely inactivated but
-KGDH is still functional, glutamate becomes a key metabolite
driving a segment of the Krebs cycle (thick arrows) and
NADH production is maintained. When -KGDH is also partially
inhibited (b) in the presence of higher
concentrations of H2O2 (100
µM), NADH generation becomes limited, resulting in an
impaired respiratory capacity.
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In summary, the conclusions of the present work are as follows. (1)
Aconitase is the most sensitive enzyme to
H2O2 in the Krebs cycle,
but inhibition of -KGDH plays a critical role in limiting the amount
of NADH during H2O2-induced
oxidative stress. (2) An increased conversion of NADH to NADPH to
supply reducing equivalents for the elimination of
H2O2 makes a contribution
to the decrease in NADH level. (3) In the early stage of an
H2O2-induced oxidative
stress, glutamate could be used as a metabolite to maintain NADH
production in a segment of the Krebs cycle.
This study highlights the significance of -KGDH in conditions
involving oxidative stress. Recently it has been reported that peroxinitrate in microglia (Park et al., 1999) and 4-hydroxy-2-nonenal (HNE), a product of lipid peroxidation, in isolated cardiac
mitochondria inhibited -KGDH and reduced NADH production initiated
by addition of -ketoglutarate (Humphries et al., 1998).
H2O2 is a relatively mild
insult, which in the early stage of the oxidative stress (<30 min) is
not associated with peroxidation of membrane lipids (Tretter and
Adam-Vizi, 1996), thus the formation of HNE.
-KGDH also exhibited a reperfusion-induced age-dependent
inactivation in mitochondria prepared from rat heart after exposure to
ischemia/reperfusion (Lucas and Szweda, 1999). This could be related to
an effect of H2O2 given
that during microdialysis, H2O2 at 0.1 mM
concentration is formed in the striatum during reperfusion after an
ischemic period (Hyslop et al., 1995). High concentrations of
H2O2 can also be reached in
aged brain (Sohal et al., 1994; Auerbach and Segal, 1997). The critical
role of inhibition of -KGDH by
H2O2 revealed in this study
could be important in the pathogenesis of late-onset neurodegenerative
diseases such as Parkinson's disease (Mizuno et al., 1994) and
Alzheimer's disease (Blass and Gibson, 1991; Gibson et al., 1998a),
during which the activity of -KGDH was found to be inhibited (for
review, see Gibson et al., 2000). The sensitivity of -KGDH in nerve
terminals could be particularly relevant to the suggestion that nerve
terminals are the primary site of mitochondrial damage in Alzheimer's
neurons (Sumpter et al., 1986; Blass and Gibson, 1991).
With a limited function of -KGDH, mitochondria in nerve terminals
are likely to be unable to meet the energy demand imposed by neuronal
activity, eventually leading to impaired function. This was indicated
in our previous finding that under an
H2O2-induced oxidative
stress, an increased energy demand induced a complete functional
collapse of nerve terminals (Chinopoulos et al., 2000).
| |
FOOTNOTES |
Received July 25, 2000; revised Sept. 7, 2000; accepted Sept. 18, 2000.
This work supported by grants from OR52AGO5 Tudomànyos
Kutatàsi Alap, EGES2SEGUGTI Tudomanyos Tanacs, Oktatasi
Miniszterium, and Magyar Tudomànyos Akademia to V.A.-V. We
are indebted to Katalin Takács and Katalin Zölde for
excellent technical assistance.
Correspondence should be addressed to Prof. Vera Adam-Vizi, Department
of Medical Biochemistry, Semmelweis University of Medicine, Budapest,
H-1444, P.O. Box 262, Hungary. E-mail:
AV{at}puskin.sote.hu.
| |
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TOP
ABSTRACT
INTRODUCTION
