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The inhibitory effect of extracts of cigarette tar on electron transport of mitochondria and submitochondrial particles
Free Radical Biology & Medicine, Vol. 12, pp. 365-372, 1992 Printed in the USA. All fights reserved.
0891-5849/92 $5.00 + .00 Copyright © 1992 Pergamon Press Ltd.
Original Contribution THE I N H I B I T O R Y
EFFECT OF EXTRACTS OF CIGARETTE TAR ELECTRON TRANSPORT OF MITOCHONDRIA AND SUBMITOCHONDRIAL PARTICLES
ON
WILLIAM A. PRYOR, NANCY C. ARBOUR, BRAD UPHAM, and DANIEL F. C H U R C H Biodynamics Institute, Louisiana State University, Baton Rouge, LA 70803, U.S.A. (Received 17 September 1991; Revised 30 December 1991 ; Accepted 2 January 1992)
Abstract--Acetonitrile extracts of cigarette tar inhibit state 3 and state 4 respiration of intact mitochondria. Exposure of respiring submitochondrial particles to acetonitrile extracts of cigarette tar results in a dose-dependent inhibition of oxygen consumption and reduced nicotinamide adenine dinucleotide (NADH) oxidation. This inhibition was not due to a solvent effect since acetonitrile alone did not alter oxygen consumption or NADH oxidation. Intact mitochondria are less sensitive to extracts of tar than submitochondrial particles. The NADH-ubiquinone (Q) reductase complex is more sensitive to inhibition by tar extract than the succinate-Q reductase and cytochrome complexes. Nicotine or catechol did not inhibit respiration of intact mitochondria. Treatment of submitochondrial particles with cigarette tar results in the formation of hydroxyl radicals, detected by electron spin resonance (ESR) spin trapping. The ESR signal attributable to the hydroxyl radical spin adduct requires the presence of NADH and is completely abolished by catalase and to a lesser extent superoxide dismutase (SOD). Catalase and SOD did not protect the mitochondrial respiratory chain from inhibition by tar extract, indicating that the radicals detected by ESR spin trapping are not responsible for the inhibition of the electron transport. We propose that tar causes at least two effects: ( l ) Tar components interact with the electron transport chain and inhibit electron flow, and (2) tar components interact with the electron transport chain, ultimately to form hydroxyl radicals. Keywords--Mitochondria, Cigarette tar, Electron transport, Autooxidation, Electron spin resonance, Spin trapping, Free radicals
mitochondria. Consistent with this hypothesis, exposure to cigarette tar has been shown to alter mitochondrial ultrastructure in cultured protozoa) ° Several studies have indicated that cigarette smoke inhibits mammalian mitochondrial function. 11:2 In one of the earliest reports, Kolberg x3 suggested that the depletion of oxygen by lung tissue homogenates was caused by cigarette-smoke-induced damage to mitochondrial membranes. Kyle et al. 14 demonstrated decreased phosphorylative efficiency in guinea pig lung mitochondria exposed to whole tobacco smoke in vivo. Several in vitro studies by Gairola et al. 15-17 showed that whole smoke alters respiration from pyridine-linked or ravin-linked substrates in intact mitochondria; depending on the protocol for the preparation of the tobacco smoke extract, either partial stimulation or inhibition of oxygen utilization by the mitochondria was observed. Attempts were made to localize the electron transport chain component(s) with which cigarette smoke interacted; spectroscopic measurement of the cytochromes in their reduced
INTRODUCTION
Over 4000 compounds, many of them highly toxic, have been identified in tobacco smoke.~-~ There is epidemiological evidence linking cigarette smoke with cancers of the larynx and lung, 4'5 and smoking has been suggested to be responsible for some or most of the deaths due to emphysema and chronic obstructive lung disease. 6,7Cigarette tar has been shown to possess redox properties that alter the activity of biologically important macromolecules. For example, Bilimoria et al. 8 have reported that tar accelerates the oxidation of ascorbate by a free-radical-generating reaction. Another study by these workers has shown that cigarette tar reduces cytochrome c,9 suggesting that tar might interact with and affect the electron transport chain of
Address correspondence to William A. Pryor and Daniel F. Church, Biodynamics Institute, Louisiana State University, Baton Rouge, LA 70803. 365
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W.A. PRYOR et al.
state indicated that multiple cytochrome constituents are involved in the interaction of whole cigarette smoke and intact mitochondria. ~6 In the present study, we report an investigation of the mechanisms involved in cigarette-tar-mediated inhibition of mitochondrial electron transport and compare the effects in mitochondria isolated from beef heart and liver. We have incubated acetonitrile extracts of cigarette tar with intact mitochondria and submitochondrial particles (SMP) and followed both oxygen consumption and reduced nicotinamide adenine dinucleotide (NADH) oxidation. We also performed electron spin resonance (ESR) spin-trapping studies to ascertain whether oxy radicals are involved in the interaction of cigarette tar with SMP. MATERIALS AND M E T H O D S
Materials Research cigarettes (1RI series) were obtained from the Tobacco & Health Research Institute, University of Kentucky (Lexington, Kentucky). The nitrone spin trap, 5,5-dimethyl-l-pyrroline-N-oxide (DMPO), was purchased from Sigma Chemical Co. (St. Louis, MO) and purified with activated charcoal as described by Buettner and Oberley. 18 All other chemicals were used as supplied. Deionized water was used to prepare reagents. Buffers were treated with Chelex-100 to remove any contaminating iron. All reagents were prepared in water, except rotenone and antimycin, which were dissolved in ethanol and methanol, respectively.
Preparation of beef heart submitochondrial particles Fresh bovine hearts were obtained from a local slaughterhouse and were kept at 4°C throughout the procedure. Beef heart was minced into 1 in 3 pieces, and 200 g of this tissue were homogenized using a Waring blender in 0.25 M sucrose, 0.01 M Tris, pH 7.8. The pH of the resulting homogenate was adjusted to 7.8 with 6 M KOH. Mitochondria were isolated from the homogenate as described by Smith. 19 The mitochondria were resuspended in 250 mM sucrose, 1 mM succinate, 2 mM ethylenediaminetetraacetic acid (EDTA), l0 mM Tris, pH 7.8. After a 1-week storage at -20°C, the mitochondria were thawed and recentrifuged. The pellets were then homogenized in 100 mM sodium phosphate, pH 7.8. Submitochondrial particles were prepared in phosphate buffer according to Davies et al. 2° The Bradford method of protein determination was performed on the fresh preparation using bovine serum albumin as a stan-
dard. 21 Aliquots of the submitochondrial suspension were stored up to three months at -80°C.
Preparation of rat liver mitochondria Sprague-Dawley rats were fasted overnight and sacrificed by decapitation. The liver was removed and macerated with scissors in a buffer containing 210 mM mannitol, 70 mM sucrose, 5 mM HEPES/pH 7.4, 1 mM [ethylenebis-(oxyethylenenitrilo)]tetraacetic acid (EGTA), 1 mM EDTA, and 0.15% lipidfree bovine serum albumin. The macerated tissue was homogenized using a Potter-Elvehjem homogenizer with a teflon pestle. The homogenate was centrifuged at 200 × g for 10 min at 4°C. The supernatant solution was centrifuged at 6000 × g for 10 min at 4°C. The pellet was resuspended in a buffer containing 210 mM mannitol, 70 mM sucrose, and 5 mM HEPES/ pH 7.4. All assays with mitochondria were conducted in the resuspension buffer plus 5 mM MgCI2 and 5 mM potassium phosphate. Liver submitochondrial particles were prepared the same way as beef heart submitochondrial particles.
Cigarette tar preparation Standard conditions of storing and smoking the cigarettes were employed,z2,23 Prior to use, the cigarettes were conditioned at room temperature by storage over a saturated solution of ammonium nitrate. The tar from three cigarettes was collected on a Cambridge filter by drawing a 35-mL puffof smoke, 2 s in duration, once a minute through the filter. The filter was then placed in 7.5 mL of a solvent and allowed to soak for 5 min, the extract filtered and kept on ice. The solvents tested include acetonitrile, dimethyl sulfoxide (DMSO), and ethanol. To quantify the amount of cigarette tar collected, the filter was weighed after smoking the cigarettes (wet weight) and then after drying the filter completely (dry weight). On average, a weight corresponding to 22 mg of wet tar per cigarette (66 mg total from three cigarettes) was collected on the Cambridge filter. Quantitative measurements indicated that acetonitrile extracts approximately 40 mg of the 66 mg total wet tar (i.e., it extracts 13 mg/ cigarette). The other solvents tested appear to have an efficiency for extracting tar components that is very similar (see Table 1). The weight of tar described in the table and figure legends is the dry weight. While it cannot be assumed that all three solvents extract the same components from tar with the same efficiency, the tar extracts of all three appear to affect submitochondrial particles respiration similarly (see Table 1). Acetonitrile was used for most of our experiments be-
Effect of cigarette tar on electron transport Table 1. Extraction o f Cigarette Tar Components by Various Solvents: Effect on Oxygen Consumption by Beef Heart Submitochondrial Particles a Reaction Mixture NADH NADH NADH NADH NADH
+ + + +
Acetonitrile Tar-Ethanol Extract Tar-DMSO Extract Tar-Acetonitrile Extract
Rate b 151.0 137.0 23.0 21.0 18.0
+ 7.0 _+ 6.0 _+ 2.0 _ 4.0 _+ 2.0
a All treatments contained 100 m M sodium phosphate/pH 7.4. Concentrations of N A D H and protein arc 1.3 m M and 0.3 mg protein/mL, respectively. 50 uL of acetonitrile or tar extract containing approximately 300, 270, and 280 ug o f dry tar in ethanol, DMSO, and acetonitrile, respectively, was added per reaction mixture. Values are the average of two determinations. b Rate = nanomoles o f O 2 consumed/per minute per milligram of protein.
cause of its volatility and the ease of evaporating it from the Cambridge filters.
Respiration measurement in submitochondrial particles Respiration by submitochondrial particles was measured polarographically at 25°C with a Clarketype electrode (Yellow Springs Inst. Company, Yellow Springs, CO). Mitochondria were incubated in air-saturated medium containing 100 mM sodium phosphate, pH 7.8, giving a final volume of 3 mL. Either 1.3 mM NADH or 13 mM sodium succinate was used to initiate oxygen consumption.
NADH oxidation Oxidation of NADH was measured by following the absorbance decrease at 340 nm, using an extinction coefficient of 6.23 mM -~ cm-'. Absorbance changes were measured with a Hewlett Packard 8415A Diode Array Spectrophotometer. The reaction mixture contained submitochondrial particles (0.7 mg of protein/mL) in 1.0 mL of the medium used in respiration studies. After a 5-min incubation, tar extract was added followed with the addition of NADH.
ESR spectroscopy Spectra were recorded on a Bruker 100D X-band spectrometer equipped with an Aspect 2000 data acquisition system. The reaction mixture containing submitochondrial particles (3 mg/mL protein), 10 mM NADH, and 50 mM DMPO in 100 mM sodium phosphate, pH 7.8, was allowed to incubate for 1 min at room temperature. Tar extract was then added and
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the sample mixed and purged with nitrogen. When included, scavengers were added prior to the addition of tar. The sample was transferred to a 17-mm quartz flat cell and degassed by vacuum before placing in the ESR cavity. Typically, three to five 200-s scans of each spectrum were recorded with a modulation frequency of 100 kHz, modulation amplitude 1.25 G, microwave power l0 mW, microwave frequency 7.4 kHz, and a scan rate of 30 G/min. RESULTS
Effects of extraction solvents Cigarette tar was collected on a Cambridge filter as described in "Materials and Methods," and several solvents were tested for their efficiency at extracting tar components from the filter. Table 1 presents a comparison of the rates of NADH-stimulated oxygen consumption by SMP from beef heart treated with ethanol, DMSO, and acetonitrile extracts of cigarette tar. The data (expressed as nanomoles of oxygen consumed per minute per milligram of protein) indicate that similar inhibited rates of respiration are observed for submitochondrial particles in the presence of tar extracts in any of these three solvents. The addition of acetonitrile to respiring SMP did not alter oxygen consumption; thus, the observed inhibition by tar extracts is not the result of a nonspecific effect of the solvent. Therefore, we adopted acetonitrile as a solvent for subsequent experiments because of its ease of evaporative removal. The effect of acetonitrile extracts of cigarette tar on NADH-stimulated respiration in rat liver SMP also inhibited respiration to the same extent (Tables 1 and 2), indicating that the source of the SMP made no difference. Exposure of rat liver submitochondrial particles to acetonitrile extracts of cigarette tar results in dose-dependent inhibition of both oxygen consumption and NADH oxidation, with maximal inhibition occurring at approximately 250 #g of tar per milligram of protein (Fig. 1). The rate of NADH oxidation was approximately twice the rate of oxygen consumption, in agreement with the predicted stoichiometry. When acetonitrile alone was incubated with submitochondrial particles, no effect on the rate of substrate oxidation was observed (data not shown). Similar results with beef heart submitochondrial particles were also found (data not shown). A comparison of the sensitivity of NADH-Q reductase, succinate-Q reductase, and the cytochromes to acetonitrile extracts of cigarette tar was investigated utilizing various inhibitors and electron donors. The addition of 180 ~tg of tar extract per milligram of protein to a submitochondrial preparation containing
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W . A . PRYOR et al. Table 2. Differential Sensitivity of Liver Submitochondrial Electron Transport Components to Cigarette Smoke Tar Extracts a Rate b Treatment
-Tar
NADH NADH+rot NADH+rot+succ NADH+rot+succ+antia NADH + rot + succ + anti a + asc/TMPD/CN c
107_+ 16_+ 67+ 15_+
Percent Inhibition
+Tar 9 4 8 5
19_+ 3 7+ 1 33_+ 6 5_+ 3
82 -51 --
212 + 32
119 _+ 30
40
a All treatments contained 3 mL of 100 m M sodium phosphate/pH 7.4. The concentrations o f N A D H , rotenone (rot), succinate (succ), antimycin a (anti a), ascorbate (asc), tetramethylphenylenediamine (TMPD), cyanide (CN), and tar were 333 #M, 25 ug/mL, 5 mM, 1.67 #M, 1 mM, 1 mM, 1.67 mM, and 186 #g/mg protein, respectively. The protein concentration was 153 #g/mL of liver SMP. Each rate value represents an average of three replications _+ 1 standard deviation. b Reaction rates are expressed as micromoles o f O 2 consumed per minute per milligram of protein. c The autooxidation o f ascorbate and T M P D was accounted for by subtracting the rate after the addition of KCN from the rate before the addition o f KCN.
159 #g of protein/mL inhibits NADH-dependent respiration by 82% (Table 2). Rotenone blocks electron flow to the NADH-Q reductase complex, and the addition of succinate bypasses this inhibition. The addition of tar extract to this rotenone/succinate system results in a 51% inhibition of the electron transport (Table 2). The addition of antimycin a (anti a) blocks electron flow to the succinate-Q reductase complex,
"2
and tetramethylphenylenediamine (TMPD)/ascorbate (asc) can be used to bypass this inhibition by donating electrons to the cytochromes. Both TMPD and ascorbate autooxidize, and the addition of potassium cyanide, which blocks mitochondrial electron flow to oxygen, was used to determine the residue rate of TMPD/ascorbate autooxidation. Addition of tar extract to this TMPD/ascorbate system inhibits respi-
225
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Fig. 1. Dose-dependent inhibition of both oxygen uptake and N A D H oxidation in submitochondrial particles exposed to cigarette tar extract. Liver submitochondrial particles were treated with increasing amounts o f tar extract; reactions were initiated by the addition of NADH. The total assay volume was 3 m L and contained 100 m M sodium phosphate/pH 7.4 and 333 #M NADH. The data are expressed as nanomoles of oxygen consumed per minute per milligram of submitochondrial particles protein or nanomoles N A D H oxidized per minute per milligram of protein. Values are the average of two determinations. Acetonitrile addition did not alter the rate o f N A D H oxidation: A control without acetonitrile gave 202 _+ 7 nmol NADH oxidized per minute per milligram o f protein, and the addition o f 20 #L aeetonitrile to this experiment resulted in 198 ___5 nmol N A D H oxidized per minute per milligram of protein.
Effect of cigarette tar on electron transport
0.0010 ~__... ~- " ~ . ~ - 0,0792 ~ #-~- .
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369
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Fig. 2. Difference spectra ofcytochromes in liver submitochondrial respiration exposed to acetonitrile extracts of tar. The assay media contained 1 mL of 100 m M sodium phosphate/pH 7.4 and 15 m M succinate. The spectra were recorded after the
depletion of oxygen.
ration by 44% (Table 2). A difference spectrum of the cytochromes is shown in Figure 2. The addition of tar extract to succinate-reduced cytochromes inhibited the cytochromes equally, showing no crossover points (Fig. 2).
Effects of tar extracts on respiration and coupling of intact mitochondria The effects of acetonitrile extracts of tar on the respiratory rate and the respiratory control ratio (RCR) of intact mitochondria from liver were also investigated (Table 3). Maximal inhibition of respiration by tar extract is approximately 40% of the control rate. This 40% inhibition is similar to the 50% inhibition of succinate-driven respiration ofsubmitochondrial particles treated with extracts of tar. Tar extract completely inhibits adenine 5'-diphosphate (ADP)-stimulated respiration, with a reduction of an RCR value of 3.5 to 0.7 with the addition of 19 ug tar/mg protein,
Table 3. The Effect of Tar Extract on Intact Coupled Liver Mitochondria a Tar Concentration (#g tar/mg protein) 0 19 47 95
Rate b 12.0 13.5 7.8 7.6
RCR c 3.5 0.7 ---
a All treatments contained 3 m L total volume of the assay buffer described in Materials and Methods. The concentrations of succinate and protein are 5 m M and 19.8 mg/mL, respectively. Each rate value represents an average of three replicates _ l standard deviation. b Rate = nanomoles of 02 consumed per minute per milligram of protein. c Respiratory control ratio.
indicating that intact liver mitochondria are very sensitive to inhibition by tar extract.
Effects of nicotine and catechol on intact mitochondria Acetonitrile extracts about 8.8 mg of tar from three cigarettes per milliliter of acetonitrile. Guerin 2z estimated that 9% of the mass of the particulate phase from 1R1 cigarettes is nicotine, giving an estimated concentration of 5 mM nicotine in our acetonitrile extracts. A 50 uL aliquot of the acetonitrile extract of tar was added to 3 mL of our assay media, which gives an estimated final concentration of 80 uM nicotine. Therefore, nicotine at a concentration of 168 tsM was considered sufficient to investigate the possibility that nicotine was the inhibitory substance in acetonitrile extracts of cigarette tar. Our experiments indicate that nicotine does not inhibit succinate-driven mitochondrial respiration, nor does nicotine affect the respiratory control ratios (Table 4). Phenolics are also a major component of cigarette smoke, accounting for 3%
Table 4. The Effects of Nicotine and Catechol on the Respiration of Intact Liver Mitochondria a Treatment
Rateb
RCRC
Succinate Succinate Succinate Succinate Succinate Succinate
5.3 _ 0.4 6.1 _+ 0.6 0 3.1 + 0.1 3.8 +_ 0.4 0
3.8 _+ 1.4 3.7 _+ 0.3 -3.9 _+ 0.7 3.8 _+ 0.7 --
+ Nicotine + Nicotine + KCN + Catechol + Catechol + KCN
a All treatments contained 3 mL total volume and the assay buffer, as described in Materials and Methods. The concentrations of succinate, nicotine (in acetonitrile), catechol, KCN, and protein were 5 raM, 168 tzM, 200 ~zM, 833 tzM, and 2.5 mg/mL, respectively. b Rate = nanomoles o f O 2 per minute per milligram of protein. c RCR = respiratory control ratio (333 #M ADP was used to
initiate state 3 respiration).
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W.A. PRYOR el al.
D
E
i
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20GAUSS Fig. 3. ESR spin trapping of cigarette-tar-mediated oxygen radical production in submitochondrial particles of beef heart. The following additions were made to the reaction mixtures described under Materials and Methods: (A) 500/~g of tar extract (in 100 ~zLacetonitrile); (B) tar extract plus 200 mM ethanol; (D) tar extract minus NADH; (E) tar plus 1 mg/mL catalase (20,000 units); (F) tar plus 0. l mg/mL SOD (450 units); and (G) tar plus NADH minus submitochondrial particles. In (C), the reaction mixture contained 0. l mM FeSO4, 0.2 mM EDTA, 2 mM H202,and 50 mM DMPO. Instrumental parameters were as follows: receiver gain 6.3 × l05, modulation amplitude 1.25, time constant 200 s, scan time 200 s, and sweep width 100 G.
of the wet weight, zz,z4 The addition of catechol, a dihydroxyaromatic that is present in cigarette tar, 24 did not affect succinate-driven respiration or alter RCR values (Table 4), suggesting that nicotine and catechol are not the components responsible for tar-extract inhibition of submitochondrial particle respiration.
ESR spin-trapping experiments Spin-trapping experiments have been performed using DMPO to determine whether radical species are generated following treatment of submitochondrial particles with acetonitrile extracts of cigarette tar. In the presence of tar extract, submitochondrial particles and NADH, a four-line spin adduct with hyperfine
splitting constants (hfsc) of aN =aH = 15.0 _+ 0.1 G is observed (Fig. 3A). These values are identical to those observed for the spin adduct produced from FeSO4, HzO2, and EDTA (Fig. 3C), suggesting that the hydroxyl spin adduct of DMPO is formed when submitochondrial particles are incubated with tar extract. 25'26This adduct is not observed under the same conditions when acetonitrile alone is added. The addition of ethanol to cigarette-tar-inhibited respiring submitochondrial particles results in inhibition of the four-line spin adduct and generation of new lines having hfsc of aN = 16.1 _+ 0.1, aH = 23.2 +_ 0.1 G; these lines are attributable to hydroxyethyl radical adducts (Fig. 3B) resulting from the oxidation of ethanol by the hydroxyl radical. The HO-DMPO spin adduct is
Effect of cigarette tar on electron transport Table 5. The Effect of Catalase and SOD on Tar-Inhibited Liver Submitochondrial Electron Transport a Treatment NADH NADH + Tar NADH + Tar + Catalase NADH + Tar + SOD
Rate b
Percent Inhibition
136 25 17 14
-82 87 90
a All treatments contained 3 mL of 100 mM sodium phosphate/ pH 7.4. The concentrations of NADH, catalase, SOD, tar and SMPs are 333 #M, 50 units/mL, 50 units/mL, 207 #g/mg protein, and 157 #g/mL, respectively. The data are an average of two replicates. b Rate = nanomoles of O2 per minute per milligram of protein.
observable in the absence of submitochondrial particles (Fig. 3G), but the intensity is reduced by a factor of about 2. We have previously shown that tar extracts can reduce 02 to superoxide and mediate oxy-radical generation by nonenzymatic pathways. 3,26 However, in the present system, cigarette tar extract does not induce radical formation in the absence of NADH (Fig. 3D). As additional evidence for oxy-radical formation, catalase is found to inhibit the ESR signal completely (Fig. 3E), whereas SOD produces only a slight inhibition (Fig. 3F). The addition ofcatalase and SOD to submitochondrial particles does not protect against inhibition of respiration by tar extract (Table 5), suggesting that the oxygen radicals detected by ESR spin trapping are not involved in the inhibition of mitochondrial electron transport by the tar extracts We observed. However, catalase inhibited oxygen consumption by 30%, suggesting that most of the residual oxygen consumption went to form hydrogen peroxide, and the hydroxyl spin adducts we detected may originate from this hydrogen peroxide. DISCUSSION
It has been previously reported by Gairola et al. ~s that whole cigarette smoke impairs mitochondrial function. However, the mechanism(s) involving the interaction between cigarette smoke and mitochondria are not clearly understood. Therefore, we have examined the effects of cigarette tar extracts on the various mitochondrial electron transport components and on oxy-radical production. Our results indicate that acetonitrile extracts of cigarette tar interact at multiple sites along the electron transport chain, although the NADH-Q reductase appears to be the most sensitive site to inhibition by tar extract. (At the levels we used, the addition ofacetonitrile alone to respiring mitochondrial or submitochondrial particles had no effect.) The detailed mecha-
371
nism of this tar-induced inhibition of electron transport is not known, particularly since cigarette smoke contains several thousand compounds, many of which are redox active. 8'9The possibility that the residual rate seen after the addition of tar extract is a bypass of the inhibition site is unlikely since the difference spectra data (Fig. 2) indicated no reduction of the cytochromes. The interaction of ascorbate with tar components in the TMPD/submitochondrial particle system could possibly result from bypassing the site of inhibition, masking the inhibitory effects of cigarette tar extract on this part of the electron transport. The 82% inhibition of whole-chain respiration (Table 2) is greater than that observed with rotenoneblocked succinate oxidation (Table 2) and ascorbateTMPT shunt (Table 2). This suggests that NADH-Q reductase is probably the most sensitive electron transport component to cigarette smoke. Nicotine and catechol, which are major components of cigarette smoke, did not inhibit the mitochondrial electron transport, indicating that these components are not responsible for the observed effects. The ESR signal for the hydroxyl radical spin adduct is completely abolished by catalase and to a lesser extent by SOD. However, these two protective enzymes do not protect the inhibition of electron transport in the mitochondrial respiratory chain by tar. Thus, we suggest that the hydroxyl radicals that are spin trapped are not responsible for the inhibitory effect of tar extract on submitochondrial respiration. Catalase inhibited oxygen consumption by 30% (relative to the 50% maximum possible effect), suggesting that most of the residual oxygen consumption went to form hydrogen peroxide, and the hydroxyl spin adducts we detected may originate from this hydrogen peroxide. These results could have significance in the etiology of smoking-induced diseases. Perturbation of mitochondrial electron transport by cigarette tar may affect the energy-producing machinery of mitochondria and contribute to the general cytotoxic effects of cigarette smoke. Acknowledgment--This research was supported in part by a grant from the NIH and a contract from the National Foundation for Cancer Research.
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anti a--antimycin a asc--ascorbate DMPO--5,5-dimethyl- 1-pyrroline-N-oxide ESR--electron spin resonance EGTA--[ethylenebis-(oxyethylenenitrilo)]tetraacetic acid hfsc--hyperfine splitting constant RCR--respiratory control ratio rot--rotenone SMP--submitochondrial particles SOD--superoxide dismutase TMPD--tetramethylphenylenediamine
0891-5849/92 $5.00 + .00 Copyright © 1992 Pergamon Press Ltd.
Original Contribution THE I N H I B I T O R Y
EFFECT OF EXTRACTS OF CIGARETTE TAR ELECTRON TRANSPORT OF MITOCHONDRIA AND SUBMITOCHONDRIAL PARTICLES
ON
WILLIAM A. PRYOR, NANCY C. ARBOUR, BRAD UPHAM, and DANIEL F. C H U R C H Biodynamics Institute, Louisiana State University, Baton Rouge, LA 70803, U.S.A. (Received 17 September 1991; Revised 30 December 1991 ; Accepted 2 January 1992)
Abstract--Acetonitrile extracts of cigarette tar inhibit state 3 and state 4 respiration of intact mitochondria. Exposure of respiring submitochondrial particles to acetonitrile extracts of cigarette tar results in a dose-dependent inhibition of oxygen consumption and reduced nicotinamide adenine dinucleotide (NADH) oxidation. This inhibition was not due to a solvent effect since acetonitrile alone did not alter oxygen consumption or NADH oxidation. Intact mitochondria are less sensitive to extracts of tar than submitochondrial particles. The NADH-ubiquinone (Q) reductase complex is more sensitive to inhibition by tar extract than the succinate-Q reductase and cytochrome complexes. Nicotine or catechol did not inhibit respiration of intact mitochondria. Treatment of submitochondrial particles with cigarette tar results in the formation of hydroxyl radicals, detected by electron spin resonance (ESR) spin trapping. The ESR signal attributable to the hydroxyl radical spin adduct requires the presence of NADH and is completely abolished by catalase and to a lesser extent superoxide dismutase (SOD). Catalase and SOD did not protect the mitochondrial respiratory chain from inhibition by tar extract, indicating that the radicals detected by ESR spin trapping are not responsible for the inhibition of the electron transport. We propose that tar causes at least two effects: ( l ) Tar components interact with the electron transport chain and inhibit electron flow, and (2) tar components interact with the electron transport chain, ultimately to form hydroxyl radicals. Keywords--Mitochondria, Cigarette tar, Electron transport, Autooxidation, Electron spin resonance, Spin trapping, Free radicals
mitochondria. Consistent with this hypothesis, exposure to cigarette tar has been shown to alter mitochondrial ultrastructure in cultured protozoa) ° Several studies have indicated that cigarette smoke inhibits mammalian mitochondrial function. 11:2 In one of the earliest reports, Kolberg x3 suggested that the depletion of oxygen by lung tissue homogenates was caused by cigarette-smoke-induced damage to mitochondrial membranes. Kyle et al. 14 demonstrated decreased phosphorylative efficiency in guinea pig lung mitochondria exposed to whole tobacco smoke in vivo. Several in vitro studies by Gairola et al. 15-17 showed that whole smoke alters respiration from pyridine-linked or ravin-linked substrates in intact mitochondria; depending on the protocol for the preparation of the tobacco smoke extract, either partial stimulation or inhibition of oxygen utilization by the mitochondria was observed. Attempts were made to localize the electron transport chain component(s) with which cigarette smoke interacted; spectroscopic measurement of the cytochromes in their reduced
INTRODUCTION
Over 4000 compounds, many of them highly toxic, have been identified in tobacco smoke.~-~ There is epidemiological evidence linking cigarette smoke with cancers of the larynx and lung, 4'5 and smoking has been suggested to be responsible for some or most of the deaths due to emphysema and chronic obstructive lung disease. 6,7Cigarette tar has been shown to possess redox properties that alter the activity of biologically important macromolecules. For example, Bilimoria et al. 8 have reported that tar accelerates the oxidation of ascorbate by a free-radical-generating reaction. Another study by these workers has shown that cigarette tar reduces cytochrome c,9 suggesting that tar might interact with and affect the electron transport chain of
Address correspondence to William A. Pryor and Daniel F. Church, Biodynamics Institute, Louisiana State University, Baton Rouge, LA 70803. 365
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W.A. PRYOR et al.
state indicated that multiple cytochrome constituents are involved in the interaction of whole cigarette smoke and intact mitochondria. ~6 In the present study, we report an investigation of the mechanisms involved in cigarette-tar-mediated inhibition of mitochondrial electron transport and compare the effects in mitochondria isolated from beef heart and liver. We have incubated acetonitrile extracts of cigarette tar with intact mitochondria and submitochondrial particles (SMP) and followed both oxygen consumption and reduced nicotinamide adenine dinucleotide (NADH) oxidation. We also performed electron spin resonance (ESR) spin-trapping studies to ascertain whether oxy radicals are involved in the interaction of cigarette tar with SMP. MATERIALS AND M E T H O D S
Materials Research cigarettes (1RI series) were obtained from the Tobacco & Health Research Institute, University of Kentucky (Lexington, Kentucky). The nitrone spin trap, 5,5-dimethyl-l-pyrroline-N-oxide (DMPO), was purchased from Sigma Chemical Co. (St. Louis, MO) and purified with activated charcoal as described by Buettner and Oberley. 18 All other chemicals were used as supplied. Deionized water was used to prepare reagents. Buffers were treated with Chelex-100 to remove any contaminating iron. All reagents were prepared in water, except rotenone and antimycin, which were dissolved in ethanol and methanol, respectively.
Preparation of beef heart submitochondrial particles Fresh bovine hearts were obtained from a local slaughterhouse and were kept at 4°C throughout the procedure. Beef heart was minced into 1 in 3 pieces, and 200 g of this tissue were homogenized using a Waring blender in 0.25 M sucrose, 0.01 M Tris, pH 7.8. The pH of the resulting homogenate was adjusted to 7.8 with 6 M KOH. Mitochondria were isolated from the homogenate as described by Smith. 19 The mitochondria were resuspended in 250 mM sucrose, 1 mM succinate, 2 mM ethylenediaminetetraacetic acid (EDTA), l0 mM Tris, pH 7.8. After a 1-week storage at -20°C, the mitochondria were thawed and recentrifuged. The pellets were then homogenized in 100 mM sodium phosphate, pH 7.8. Submitochondrial particles were prepared in phosphate buffer according to Davies et al. 2° The Bradford method of protein determination was performed on the fresh preparation using bovine serum albumin as a stan-
dard. 21 Aliquots of the submitochondrial suspension were stored up to three months at -80°C.
Preparation of rat liver mitochondria Sprague-Dawley rats were fasted overnight and sacrificed by decapitation. The liver was removed and macerated with scissors in a buffer containing 210 mM mannitol, 70 mM sucrose, 5 mM HEPES/pH 7.4, 1 mM [ethylenebis-(oxyethylenenitrilo)]tetraacetic acid (EGTA), 1 mM EDTA, and 0.15% lipidfree bovine serum albumin. The macerated tissue was homogenized using a Potter-Elvehjem homogenizer with a teflon pestle. The homogenate was centrifuged at 200 × g for 10 min at 4°C. The supernatant solution was centrifuged at 6000 × g for 10 min at 4°C. The pellet was resuspended in a buffer containing 210 mM mannitol, 70 mM sucrose, and 5 mM HEPES/ pH 7.4. All assays with mitochondria were conducted in the resuspension buffer plus 5 mM MgCI2 and 5 mM potassium phosphate. Liver submitochondrial particles were prepared the same way as beef heart submitochondrial particles.
Cigarette tar preparation Standard conditions of storing and smoking the cigarettes were employed,z2,23 Prior to use, the cigarettes were conditioned at room temperature by storage over a saturated solution of ammonium nitrate. The tar from three cigarettes was collected on a Cambridge filter by drawing a 35-mL puffof smoke, 2 s in duration, once a minute through the filter. The filter was then placed in 7.5 mL of a solvent and allowed to soak for 5 min, the extract filtered and kept on ice. The solvents tested include acetonitrile, dimethyl sulfoxide (DMSO), and ethanol. To quantify the amount of cigarette tar collected, the filter was weighed after smoking the cigarettes (wet weight) and then after drying the filter completely (dry weight). On average, a weight corresponding to 22 mg of wet tar per cigarette (66 mg total from three cigarettes) was collected on the Cambridge filter. Quantitative measurements indicated that acetonitrile extracts approximately 40 mg of the 66 mg total wet tar (i.e., it extracts 13 mg/ cigarette). The other solvents tested appear to have an efficiency for extracting tar components that is very similar (see Table 1). The weight of tar described in the table and figure legends is the dry weight. While it cannot be assumed that all three solvents extract the same components from tar with the same efficiency, the tar extracts of all three appear to affect submitochondrial particles respiration similarly (see Table 1). Acetonitrile was used for most of our experiments be-
Effect of cigarette tar on electron transport Table 1. Extraction o f Cigarette Tar Components by Various Solvents: Effect on Oxygen Consumption by Beef Heart Submitochondrial Particles a Reaction Mixture NADH NADH NADH NADH NADH
+ + + +
Acetonitrile Tar-Ethanol Extract Tar-DMSO Extract Tar-Acetonitrile Extract
Rate b 151.0 137.0 23.0 21.0 18.0
+ 7.0 _+ 6.0 _+ 2.0 _ 4.0 _+ 2.0
a All treatments contained 100 m M sodium phosphate/pH 7.4. Concentrations of N A D H and protein arc 1.3 m M and 0.3 mg protein/mL, respectively. 50 uL of acetonitrile or tar extract containing approximately 300, 270, and 280 ug o f dry tar in ethanol, DMSO, and acetonitrile, respectively, was added per reaction mixture. Values are the average of two determinations. b Rate = nanomoles o f O 2 consumed/per minute per milligram of protein.
cause of its volatility and the ease of evaporating it from the Cambridge filters.
Respiration measurement in submitochondrial particles Respiration by submitochondrial particles was measured polarographically at 25°C with a Clarketype electrode (Yellow Springs Inst. Company, Yellow Springs, CO). Mitochondria were incubated in air-saturated medium containing 100 mM sodium phosphate, pH 7.8, giving a final volume of 3 mL. Either 1.3 mM NADH or 13 mM sodium succinate was used to initiate oxygen consumption.
NADH oxidation Oxidation of NADH was measured by following the absorbance decrease at 340 nm, using an extinction coefficient of 6.23 mM -~ cm-'. Absorbance changes were measured with a Hewlett Packard 8415A Diode Array Spectrophotometer. The reaction mixture contained submitochondrial particles (0.7 mg of protein/mL) in 1.0 mL of the medium used in respiration studies. After a 5-min incubation, tar extract was added followed with the addition of NADH.
ESR spectroscopy Spectra were recorded on a Bruker 100D X-band spectrometer equipped with an Aspect 2000 data acquisition system. The reaction mixture containing submitochondrial particles (3 mg/mL protein), 10 mM NADH, and 50 mM DMPO in 100 mM sodium phosphate, pH 7.8, was allowed to incubate for 1 min at room temperature. Tar extract was then added and
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the sample mixed and purged with nitrogen. When included, scavengers were added prior to the addition of tar. The sample was transferred to a 17-mm quartz flat cell and degassed by vacuum before placing in the ESR cavity. Typically, three to five 200-s scans of each spectrum were recorded with a modulation frequency of 100 kHz, modulation amplitude 1.25 G, microwave power l0 mW, microwave frequency 7.4 kHz, and a scan rate of 30 G/min. RESULTS
Effects of extraction solvents Cigarette tar was collected on a Cambridge filter as described in "Materials and Methods," and several solvents were tested for their efficiency at extracting tar components from the filter. Table 1 presents a comparison of the rates of NADH-stimulated oxygen consumption by SMP from beef heart treated with ethanol, DMSO, and acetonitrile extracts of cigarette tar. The data (expressed as nanomoles of oxygen consumed per minute per milligram of protein) indicate that similar inhibited rates of respiration are observed for submitochondrial particles in the presence of tar extracts in any of these three solvents. The addition of acetonitrile to respiring SMP did not alter oxygen consumption; thus, the observed inhibition by tar extracts is not the result of a nonspecific effect of the solvent. Therefore, we adopted acetonitrile as a solvent for subsequent experiments because of its ease of evaporative removal. The effect of acetonitrile extracts of cigarette tar on NADH-stimulated respiration in rat liver SMP also inhibited respiration to the same extent (Tables 1 and 2), indicating that the source of the SMP made no difference. Exposure of rat liver submitochondrial particles to acetonitrile extracts of cigarette tar results in dose-dependent inhibition of both oxygen consumption and NADH oxidation, with maximal inhibition occurring at approximately 250 #g of tar per milligram of protein (Fig. 1). The rate of NADH oxidation was approximately twice the rate of oxygen consumption, in agreement with the predicted stoichiometry. When acetonitrile alone was incubated with submitochondrial particles, no effect on the rate of substrate oxidation was observed (data not shown). Similar results with beef heart submitochondrial particles were also found (data not shown). A comparison of the sensitivity of NADH-Q reductase, succinate-Q reductase, and the cytochromes to acetonitrile extracts of cigarette tar was investigated utilizing various inhibitors and electron donors. The addition of 180 ~tg of tar extract per milligram of protein to a submitochondrial preparation containing
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W . A . PRYOR et al. Table 2. Differential Sensitivity of Liver Submitochondrial Electron Transport Components to Cigarette Smoke Tar Extracts a Rate b Treatment
-Tar
NADH NADH+rot NADH+rot+succ NADH+rot+succ+antia NADH + rot + succ + anti a + asc/TMPD/CN c
107_+ 16_+ 67+ 15_+
Percent Inhibition
+Tar 9 4 8 5
19_+ 3 7+ 1 33_+ 6 5_+ 3
82 -51 --
212 + 32
119 _+ 30
40
a All treatments contained 3 mL of 100 m M sodium phosphate/pH 7.4. The concentrations o f N A D H , rotenone (rot), succinate (succ), antimycin a (anti a), ascorbate (asc), tetramethylphenylenediamine (TMPD), cyanide (CN), and tar were 333 #M, 25 ug/mL, 5 mM, 1.67 #M, 1 mM, 1 mM, 1.67 mM, and 186 #g/mg protein, respectively. The protein concentration was 153 #g/mL of liver SMP. Each rate value represents an average of three replications _+ 1 standard deviation. b Reaction rates are expressed as micromoles o f O 2 consumed per minute per milligram of protein. c The autooxidation o f ascorbate and T M P D was accounted for by subtracting the rate after the addition of KCN from the rate before the addition o f KCN.
159 #g of protein/mL inhibits NADH-dependent respiration by 82% (Table 2). Rotenone blocks electron flow to the NADH-Q reductase complex, and the addition of succinate bypasses this inhibition. The addition of tar extract to this rotenone/succinate system results in a 51% inhibition of the electron transport (Table 2). The addition of antimycin a (anti a) blocks electron flow to the succinate-Q reductase complex,
"2
and tetramethylphenylenediamine (TMPD)/ascorbate (asc) can be used to bypass this inhibition by donating electrons to the cytochromes. Both TMPD and ascorbate autooxidize, and the addition of potassium cyanide, which blocks mitochondrial electron flow to oxygen, was used to determine the residue rate of TMPD/ascorbate autooxidation. Addition of tar extract to this TMPD/ascorbate system inhibits respi-
225
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Fig. 1. Dose-dependent inhibition of both oxygen uptake and N A D H oxidation in submitochondrial particles exposed to cigarette tar extract. Liver submitochondrial particles were treated with increasing amounts o f tar extract; reactions were initiated by the addition of NADH. The total assay volume was 3 m L and contained 100 m M sodium phosphate/pH 7.4 and 333 #M NADH. The data are expressed as nanomoles of oxygen consumed per minute per milligram of submitochondrial particles protein or nanomoles N A D H oxidized per minute per milligram of protein. Values are the average of two determinations. Acetonitrile addition did not alter the rate o f N A D H oxidation: A control without acetonitrile gave 202 _+ 7 nmol NADH oxidized per minute per milligram o f protein, and the addition o f 20 #L aeetonitrile to this experiment resulted in 198 ___5 nmol N A D H oxidized per minute per milligram of protein.
Effect of cigarette tar on electron transport
0.0010 ~__... ~- " ~ . ~ - 0,0792 ~ #-~- .
.
369
+ 100 F.I Tor . . .
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Fig. 2. Difference spectra ofcytochromes in liver submitochondrial respiration exposed to acetonitrile extracts of tar. The assay media contained 1 mL of 100 m M sodium phosphate/pH 7.4 and 15 m M succinate. The spectra were recorded after the
depletion of oxygen.
ration by 44% (Table 2). A difference spectrum of the cytochromes is shown in Figure 2. The addition of tar extract to succinate-reduced cytochromes inhibited the cytochromes equally, showing no crossover points (Fig. 2).
Effects of tar extracts on respiration and coupling of intact mitochondria The effects of acetonitrile extracts of tar on the respiratory rate and the respiratory control ratio (RCR) of intact mitochondria from liver were also investigated (Table 3). Maximal inhibition of respiration by tar extract is approximately 40% of the control rate. This 40% inhibition is similar to the 50% inhibition of succinate-driven respiration ofsubmitochondrial particles treated with extracts of tar. Tar extract completely inhibits adenine 5'-diphosphate (ADP)-stimulated respiration, with a reduction of an RCR value of 3.5 to 0.7 with the addition of 19 ug tar/mg protein,
Table 3. The Effect of Tar Extract on Intact Coupled Liver Mitochondria a Tar Concentration (#g tar/mg protein) 0 19 47 95
Rate b 12.0 13.5 7.8 7.6
RCR c 3.5 0.7 ---
a All treatments contained 3 m L total volume of the assay buffer described in Materials and Methods. The concentrations of succinate and protein are 5 m M and 19.8 mg/mL, respectively. Each rate value represents an average of three replicates _ l standard deviation. b Rate = nanomoles of 02 consumed per minute per milligram of protein. c Respiratory control ratio.
indicating that intact liver mitochondria are very sensitive to inhibition by tar extract.
Effects of nicotine and catechol on intact mitochondria Acetonitrile extracts about 8.8 mg of tar from three cigarettes per milliliter of acetonitrile. Guerin 2z estimated that 9% of the mass of the particulate phase from 1R1 cigarettes is nicotine, giving an estimated concentration of 5 mM nicotine in our acetonitrile extracts. A 50 uL aliquot of the acetonitrile extract of tar was added to 3 mL of our assay media, which gives an estimated final concentration of 80 uM nicotine. Therefore, nicotine at a concentration of 168 tsM was considered sufficient to investigate the possibility that nicotine was the inhibitory substance in acetonitrile extracts of cigarette tar. Our experiments indicate that nicotine does not inhibit succinate-driven mitochondrial respiration, nor does nicotine affect the respiratory control ratios (Table 4). Phenolics are also a major component of cigarette smoke, accounting for 3%
Table 4. The Effects of Nicotine and Catechol on the Respiration of Intact Liver Mitochondria a Treatment
Rateb
RCRC
Succinate Succinate Succinate Succinate Succinate Succinate
5.3 _ 0.4 6.1 _+ 0.6 0 3.1 + 0.1 3.8 +_ 0.4 0
3.8 _+ 1.4 3.7 _+ 0.3 -3.9 _+ 0.7 3.8 _+ 0.7 --
+ Nicotine + Nicotine + KCN + Catechol + Catechol + KCN
a All treatments contained 3 mL total volume and the assay buffer, as described in Materials and Methods. The concentrations of succinate, nicotine (in acetonitrile), catechol, KCN, and protein were 5 raM, 168 tzM, 200 ~zM, 833 tzM, and 2.5 mg/mL, respectively. b Rate = nanomoles o f O 2 per minute per milligram of protein. c RCR = respiratory control ratio (333 #M ADP was used to
initiate state 3 respiration).
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W.A. PRYOR el al.
D
E
i
I
20GAUSS Fig. 3. ESR spin trapping of cigarette-tar-mediated oxygen radical production in submitochondrial particles of beef heart. The following additions were made to the reaction mixtures described under Materials and Methods: (A) 500/~g of tar extract (in 100 ~zLacetonitrile); (B) tar extract plus 200 mM ethanol; (D) tar extract minus NADH; (E) tar plus 1 mg/mL catalase (20,000 units); (F) tar plus 0. l mg/mL SOD (450 units); and (G) tar plus NADH minus submitochondrial particles. In (C), the reaction mixture contained 0. l mM FeSO4, 0.2 mM EDTA, 2 mM H202,and 50 mM DMPO. Instrumental parameters were as follows: receiver gain 6.3 × l05, modulation amplitude 1.25, time constant 200 s, scan time 200 s, and sweep width 100 G.
of the wet weight, zz,z4 The addition of catechol, a dihydroxyaromatic that is present in cigarette tar, 24 did not affect succinate-driven respiration or alter RCR values (Table 4), suggesting that nicotine and catechol are not the components responsible for tar-extract inhibition of submitochondrial particle respiration.
ESR spin-trapping experiments Spin-trapping experiments have been performed using DMPO to determine whether radical species are generated following treatment of submitochondrial particles with acetonitrile extracts of cigarette tar. In the presence of tar extract, submitochondrial particles and NADH, a four-line spin adduct with hyperfine
splitting constants (hfsc) of aN =aH = 15.0 _+ 0.1 G is observed (Fig. 3A). These values are identical to those observed for the spin adduct produced from FeSO4, HzO2, and EDTA (Fig. 3C), suggesting that the hydroxyl spin adduct of DMPO is formed when submitochondrial particles are incubated with tar extract. 25'26This adduct is not observed under the same conditions when acetonitrile alone is added. The addition of ethanol to cigarette-tar-inhibited respiring submitochondrial particles results in inhibition of the four-line spin adduct and generation of new lines having hfsc of aN = 16.1 _+ 0.1, aH = 23.2 +_ 0.1 G; these lines are attributable to hydroxyethyl radical adducts (Fig. 3B) resulting from the oxidation of ethanol by the hydroxyl radical. The HO-DMPO spin adduct is
Effect of cigarette tar on electron transport Table 5. The Effect of Catalase and SOD on Tar-Inhibited Liver Submitochondrial Electron Transport a Treatment NADH NADH + Tar NADH + Tar + Catalase NADH + Tar + SOD
Rate b
Percent Inhibition
136 25 17 14
-82 87 90
a All treatments contained 3 mL of 100 mM sodium phosphate/ pH 7.4. The concentrations of NADH, catalase, SOD, tar and SMPs are 333 #M, 50 units/mL, 50 units/mL, 207 #g/mg protein, and 157 #g/mL, respectively. The data are an average of two replicates. b Rate = nanomoles of O2 per minute per milligram of protein.
observable in the absence of submitochondrial particles (Fig. 3G), but the intensity is reduced by a factor of about 2. We have previously shown that tar extracts can reduce 02 to superoxide and mediate oxy-radical generation by nonenzymatic pathways. 3,26 However, in the present system, cigarette tar extract does not induce radical formation in the absence of NADH (Fig. 3D). As additional evidence for oxy-radical formation, catalase is found to inhibit the ESR signal completely (Fig. 3E), whereas SOD produces only a slight inhibition (Fig. 3F). The addition ofcatalase and SOD to submitochondrial particles does not protect against inhibition of respiration by tar extract (Table 5), suggesting that the oxygen radicals detected by ESR spin trapping are not involved in the inhibition of mitochondrial electron transport by the tar extracts We observed. However, catalase inhibited oxygen consumption by 30%, suggesting that most of the residual oxygen consumption went to form hydrogen peroxide, and the hydroxyl spin adducts we detected may originate from this hydrogen peroxide. DISCUSSION
It has been previously reported by Gairola et al. ~s that whole cigarette smoke impairs mitochondrial function. However, the mechanism(s) involving the interaction between cigarette smoke and mitochondria are not clearly understood. Therefore, we have examined the effects of cigarette tar extracts on the various mitochondrial electron transport components and on oxy-radical production. Our results indicate that acetonitrile extracts of cigarette tar interact at multiple sites along the electron transport chain, although the NADH-Q reductase appears to be the most sensitive site to inhibition by tar extract. (At the levels we used, the addition ofacetonitrile alone to respiring mitochondrial or submitochondrial particles had no effect.) The detailed mecha-
371
nism of this tar-induced inhibition of electron transport is not known, particularly since cigarette smoke contains several thousand compounds, many of which are redox active. 8'9The possibility that the residual rate seen after the addition of tar extract is a bypass of the inhibition site is unlikely since the difference spectra data (Fig. 2) indicated no reduction of the cytochromes. The interaction of ascorbate with tar components in the TMPD/submitochondrial particle system could possibly result from bypassing the site of inhibition, masking the inhibitory effects of cigarette tar extract on this part of the electron transport. The 82% inhibition of whole-chain respiration (Table 2) is greater than that observed with rotenoneblocked succinate oxidation (Table 2) and ascorbateTMPT shunt (Table 2). This suggests that NADH-Q reductase is probably the most sensitive electron transport component to cigarette smoke. Nicotine and catechol, which are major components of cigarette smoke, did not inhibit the mitochondrial electron transport, indicating that these components are not responsible for the observed effects. The ESR signal for the hydroxyl radical spin adduct is completely abolished by catalase and to a lesser extent by SOD. However, these two protective enzymes do not protect the inhibition of electron transport in the mitochondrial respiratory chain by tar. Thus, we suggest that the hydroxyl radicals that are spin trapped are not responsible for the inhibitory effect of tar extract on submitochondrial respiration. Catalase inhibited oxygen consumption by 30% (relative to the 50% maximum possible effect), suggesting that most of the residual oxygen consumption went to form hydrogen peroxide, and the hydroxyl spin adducts we detected may originate from this hydrogen peroxide. These results could have significance in the etiology of smoking-induced diseases. Perturbation of mitochondrial electron transport by cigarette tar may affect the energy-producing machinery of mitochondria and contribute to the general cytotoxic effects of cigarette smoke. Acknowledgment--This research was supported in part by a grant from the NIH and a contract from the National Foundation for Cancer Research.
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anti a--antimycin a asc--ascorbate DMPO--5,5-dimethyl- 1-pyrroline-N-oxide ESR--electron spin resonance EGTA--[ethylenebis-(oxyethylenenitrilo)]tetraacetic acid hfsc--hyperfine splitting constant RCR--respiratory control ratio rot--rotenone SMP--submitochondrial particles SOD--superoxide dismutase TMPD--tetramethylphenylenediamine