COMMUNICATION:
The Content of Intracellular Mitochondrial DNA Is Decreased by 1-Methyl-4-phenylpyridinium Ion (MPP+)*

(Received for publication, December 27, 1996, and in revised form, February 12, 1997)

Kenichi Miyako , Yoichiro Kai , Takashi Irie , Koichiro Takeshige and Dongchon Kang Dagger

From the Department of Biochemistry, Kyushu University School of Medicine, Fukuoka 812-82, Japan

ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS AND DISCUSSION
FOOTNOTES
ACKNOWLEDGEMENTS
REFERENCES


ABSTRACT

1-Methyl-4-phenylpyridinium ion (MPP+), an oxidative metabolite of 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP), is considered to be directly responsible for MPTP-induced Parkinson's disease-like symptoms by inhibiting NADH-ubiquinone oxidoreductase (complex I) in the mitochondrial respiratory chain. Here we demonstrate that 25 µM MPP+ decreases the content of mitochondrial DNA to about one-third in HeLa S3 cells. On the contrary, 0.1 µM rotenone, which inhibits complex I to the same extent as 25 µM MPP+ in the cells, increases the content of mitochondrial DNA about 2-fold. Hence, the effect of MPP+ on mitochondrial DNA is not mediated by the inhibition of complex I. To examine the replication state of mitochondrial DNA, we measured the amount of nascent strands of mitochondrial DNA. The amount is decreased by MPP+ but increased by rotenone, suggesting that the replication of mitochondrial DNA is inhibited by MPP+. Because the proper amount of mitochondrial DNA is essential to maintain components of the respiratory chain, the decrease of mitochondrial DNA may play a role in the progression of MPTP-induced Parkinson's disease-like symptoms caused by the mitochondrial respiratory failure.


INTRODUCTION

Parkinson's disease is a common neurodegenerative disease with motor abnormalities resulting from the selective dopaminergic cell death in the substantia nigra pars compacta. Since 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP)1 was found to cause Parkinson's disease in human, it is widely used to produce an experimental model of Parkinson's disease in primates, rats, and mice (1-3). Animals that receive MPTP show a marked reduction in the number of dopaminergic cells in the substantia nigra pars compacta. MPTP is oxidized to 1-methyl-4-phenylpyridinium ion (MPP+). MPP+ is selectively accumulated in the dopaminergic cells via dopamine transporter and causes the dopaminergic cell death. MPP+, like rotenone, is an inhibitor of NADH-ubiquinone oxidoreductase (complex I) in the mitochondrial respiratory chain (4-6). The inhibition of complex I not only leads to the decline of the mitochondrial ATP production, but also causes the generation of superoxide radical (Obardot 2) and induces lipid peroxidation reaction (7-9). It has been demonstrated that MPP+ stimulates the production of Obardot 2 and initiates lipid peroxidation reaction in isolated bovine heart submitochondrial particles (10). The oxygen radicals as well as intracellular ATP depletion are implicated in the MPP+-induced cell death. Consistent with this assumption, transgenic mice overexpressing the copper/zinc-type superoxide dismutase (11) and mutant mice lacking neuronal nitric-oxide synthase (12) are both resistant to MPTP-induced dopamine neurotoxicity. Thus, MPP+ apparently functions as an agent of oxidative stress to mitochondria in vivo.

Thirteen subunits of the respiratory chain are coded by mitochondrial DNA, all of which are essential to the respiratory electron transport system. The integrity of mitochondrial genome must be maintained for the normal respiratory function. Mitochondria have the machinery for preventing the mutations caused by oxidative damages (13, 14). The adequate amount of transcripts from the genome is critical for maintaining mitochondrial function in addition to preventing mutations. Particularly on the level of transcripts from the mitochondrial genome, we should take the copy number of DNA into account as well as the efficiency of the initiation of transcription from each genome, since mitochondrial DNA exists in multicopies. The decline of the copy number of mitochondrial DNA should lead to the decrease in the transcript level. The replication of mitochondrial DNA must be regulated precisely for maintaining the copy number. The replication of mitochondrial DNA is tightly coupled to transcription (15). The initiation of transcription of mitochondrial DNA is mainly regulated in the D-loop region where the cis-acting elements are almost exclusively located. The D-loop region is considered to be more susceptible to oxidative stress than the other regions (16). Hence, we expected that oxidative damages to mitochondrial DNA could alter the degree of the initiation of transcription and replication.

Despite the essential role of mitochondrial DNA in respiration, the effects of MPP+ on mitochondrial DNA have not been adequately investigated. Considering the possibility that MPP+ may affect the integrity of mitochondrial DNA through oxidative damage, we examined the in vivo effect of MPP+ on the mitochondrial genome. Here, we demonstrate that MPP+ decreases the content of mitochondrial DNA without apparent degradation of the DNA, and the decrease is likely due to the selective inhibition of the replication of mitochondrial DNA.


EXPERIMENTAL PROCEDURES

Materials

BamHI, XbaI, PvuII, and T4 DNA ligase were purchased from Takara (Seta, Japan). RNase A and rotenone were from Sigma. Vent DNA polymerase was from New England Biolabs (Beverly, MA). MPP+ was from Research Biochemicals International (Natick, MA). EDTA was from Dojindo (Kumamoto, Japan). Other reagents were of analytical grade.

Cell Culture

HeLa S3 cells were cultured in Dulbecco's modified Eagle's medium containing 10% fetal calf serum, 105 units/liter penicillin G, and 100 mg/liter streptomycin. The cell number was determined photometrically using WST-1 cell counting kit (Dojindo).

Southern Blot

The cells cultured in the indicated conditions were harvested and the total DNA was extracted with DNAzol reagent (Life Technologies, Inc.) according to the manufacturer's instructions. The extracted DNA was digested with RNase A and PvuII, phenol-extracted, ethanol-precipitated, and solubilized in 0.1 × TE (1 mM Tris-HCl, pH 7.5, and 0.1 mM EDTA). The concentration of DNA was determined by measuring A260. After 0.5 µg of DNA was electrophoresed in 0.6% agarose gel and transferred onto nylon membrane (Hybond-N+, Amersham Corp., Buckinghamshire, United Kingdom), the mitochondrial gene and 18 S rRNA gene were probed with 0.8-kbp XbaI fragment of mitochondrial DNA (nt 7441-8286) and 1.5-kbp XbaI fragment of 18 S rRNA gene (nt 435-1951), respectively. Each probe was labeled with [alpha -32P]dCTP using a Megaprime DNA labeling kit (Amersham). The signals were detected and quantified with an image scanner STORM (Molecular Dynamics, Sunnyvale, CA).

Ligation-mediated PCR

Ligation-mediated PCR (LMPCR) of the mitochondrial D-loop region was performed as reported previously (17)2 and imaged with FluorImagerSI (Molecular Dynamics). Primers 1 and 2 were 5'-tttcgtctggggggtatgc-3' and 5'-cacgcgatagcattgcgagacgctg-3', respectively. Primer 2 was fluorescein labeled at the 5' end.

Lactate Production

The production of lactate was estimated by the increase of lactate in the culture medium. Lactate was measured as described previously (19).


RESULTS AND DISCUSSION

Effects of MPP+ on Cell Growth and DNA Content

Effect of MPP+ on cell viability varies in cell lines depending on the extent to which mitochondrial respiration contributes to the production of ATP in the cells. We first examined the effect of MPP+ on the growth of HeLa S3 cells. MPP+ dose-dependently inhibited the growth. The growth was inhibited by about 30% at 25 µM MPP+ (Fig. 1A). The intensity of 16-kbp band of mitochondrial DNA decreased to about one-third at 25 µM MPP+ in 3 days (Fig. 1B). The growth was fairly maintained at 25 µM MPP+ (Fig. 1A). Only the cells attached to the flask were used for analysis. The viability of cells was greater than 99% as determined by the trypan blue dye exclusion test, indicating that the decrease of mitochondrial DNA is not an event related to cell death. To confirm that the 16-kbp band is mitochondrial DNA, we probed mitochondrial DNA in BamHI-digested DNA with a 1.9-kbp fragment of mitochondrial DNA (nt 2573-4431) and obtained the same results (results not shown). The intensity of the 12-kbp band of 18 S rRNA gene as an internal standard for nuclear genome was constant, indicating that adjusting the total DNA works well for estimating the content of mitochondrial DNA per cell (Fig. 1B). From the fact that we did not observe the increase of smear bands under the 16-kbp band, the decrease of mitochondrial DNA was apparently not due to its degradation.


Fig. 1. Effects of MPP+ on cell growth and mitochondrial DNA. A, HeLa S3 cells were plated at 1 × 104 cells/ml. After 24 h, the medium was exchanged by the medium containing the indicated concentrations of MPP+. The cell number was estimated photometrically as described under "Experimental Procedures." B, after incubation with the indicated concentration of MPP+ for 3 days, the content of mitochondrial DNA (Mt DNA) in 0.5 µg of the PvuII-digested total DNA was estimated by Southern blot using the 0.8-kbp XbaI fragment of mitochondrial DNA (nt 7441-8286) as a probe. The 18 S rRNA gene was also detected simultaneously as an internal standard for the nuclear gene.
[View Larger Version of this Image (27K GIF file)]


Effects of Rotenone on Cell Growth and DNA Content

To determine whether the decrease of mitochondrial DNA by MPP+ is mediated by the inhibition of complex I, we examined the effects of rotenone on cell growth and the content of mitochondrial DNA. MPP+ is considered to bind to the rotenone-binding site in complex I, thereby inhibiting complex I (6). Rotenone inhibited the growth of HeLa S3 cells dose-dependently (Fig. 2A). Just like 25 µM MPP+, 0.1 µM rotenone inhibited the growth by approximately 30%.


Fig. 2. Effects of rotenone on cell growth and mitochondrial DNA. A, the cell growth was measured as in Fig. 1A except for using rotenone. Rotenone was solubilized in ethanol and finally diluted 1000-fold. B, after the incubation with the indicated concentration of rotenone for 3 days, the total DNA was extracted and digested with BamHI. The content of mitochondrial DNA (Mt DNA) in 0.5 µg of the total DNA was determined using the 1.9-kbp fragment of mitochondrial DNA (nt 2573-4431) as a probe. C, the experiments were performed as in Fig. 1B.
[View Larger Version of this Image (23K GIF file)]


To examine to what extent 0.1 µM rotenone and 25 µM MPP+ inhibits complex I in the HeLa cells, we measured the production of lactate by the cells treated with each reagent, because the inhibition of complex I decreases the content of intracellular ATP, resulting in the compensating enhancement of the glycolytic activity. As shown in Table I, both reagents enhanced the production of lactate to a similar extent, suggesting that the two reagents inhibit complex I similarly in vivo.

Table I.

Lactate production

HeLa S3 cells were cultured with MPP+ or rotenone at the indicated concentrations for 72 h. The content of lactate in the medium was measured. The difference in the content of lactate before and after culture was calculated and represents the production of lactate by the cells. The values are a mean of two independent experiments. Each value in parentheses represents the relative increase of the lactate production.


 Delta Lactate

µmol/105 cells
MPP+
  0 µM 2.8  (1)
  25 µM 7.4  (2.6)
Rotenonea
  0 µM 3.3  (1)
  0.1 µM 8.6  (2.6)

a 0.1% ethanol is contained in the culture medium.

In contrast to 25 µM MPP+, the intensity of mitochondrial DNA band increased approximately 2-fold at 0.1 µM rotenone concentration, when the mitochondrial DNA was detected in the BamHI-digested total DNA with the 1.9-kbp fragment of mitochondrial DNA (nt 2573-4431) (Fig. 2B). To confirm the increase in mitochondrial DNA content, we probed mitochondrial DNA and 18 S rRNA gene simultaneously in the PvuII-digested total DNA. We obtained essentially the same results as in the BamHI-digested total DNA (Fig. 2C). These results show that the inhibition of complex I alone does not decrease the content of mitochondrial DNA.

Effect on the Content of Nascent Strand of Mitochondrial DNA

Apparently the decrease of mitochondrial DNA was not accompanied with the degradation (Fig. 1A). This prompted us to examine the replication of mitochondrial DNA. We developed the ligation-mediated PCR method to estimate the content of the nascent strands of mitochondrial DNA.2 We specifically amplified the strands with the free 5' end, i.e. nascent strands of mitochondrial DNA from the cells treated with or without MPP+. To assess the number of the nascent strand per mitochondria, we adjusted the amount of mitochondrial DNA in between MPP+-treated and MPP+-untreated cells in the LMPCR analysis based on the quantification of mitochondrial DNA by Southern blot. MPP+ weakened signals of free 5' ends (Fig. 3), which indicates that the number of nascent strand per mitochondrial DNA decreased. On the other hand, rotenone augmented the signals (Fig. 3). These results suggest that MPP+ inhibits the replication of mitochondrial DNA, while rotenone enhances it.


Fig. 3. Detection of the nascent strands by LMPCR. The total DNA prepared from the cells and treated with 25 µM MPP+, 0.1 µM rotenone, or nothing was analyzed by LMPCR. For adjusting the content of mitochondrial DNA, 0.5, 0.15, 0.1, and 0.2 µg of the total DNA were used in lanes for MPP+, control for MPP+, rotenone, and control for rotenone, respectively. DNA was chemically cleaved at adenine and guanine for lane AG and at cytosine and thymine for lane CT according to the method by Maxam and Gilbert (23). The major sites with free 5' ends are indicated with arrows and numbered according to Anderson et al. (18).
[View Larger Version of this Image (43K GIF file)]


Although rotenone has not been reported to increase the intracellular content of mitochondrial DNA or enhance the replication to date, it is plausible that the content of mitochondrial DNA compensatingly increases when the respiratory function declines due to the inhibition of complex I as shown here. We noted that the content of mitochondrial DNA in the cells treated with 50 µM MPP+ was slightly more than that found in the cells with 25 µM MPP+ reproducibly (Fig. 1B). This increase of mitochondrial DNA may result from the fact that the mitochondrial DNA-decreasing effect of MPP+ was partially compensated by the mitochondrial DNA-increasing effect caused by the inhibition of complex I. Taken together with the results in Fig. 2, the decrease of mitochondrial DNA by MPP+ may be independent of the inhibition of complex I.

The toxic effects of MPP+ have been analyzed in the context of the intracellular ATP depletion and the production of oxygen radicals caused by the inhibition of complex I (3). The cytotoxicity of MPP+ analogs is not necessarily correlated to their inhibitory activities on complex I (19). Thus, it is uncertain whether the inhibition of complex I can explain all of the MPP+-induced cytotoxicity. The reduction of the copy number of mitochondrial DNA should result in the decrease of the transcripts. The decrease of transcripts in turn should lead to the decrease in the translation products. For example, an antiviral drug zidovudine is reported to inhibit the replication of mitochondrial DNA and cause mitochondrial myopathy resulting from the depletion of mitochondrial DNA (20-22). It is also reported that patients with a type of mitochondrial disease suffer a severe depletion of mitochondrial DNA (22). The decrease of mitochondrial DNA could be another factor related to the deterioration of the mitochondrial respiratory function in Parkinson's disease. It may be of interest to investigate the relationship between the mitochondrial DNA-decreasing effect and the progression of Parkinson's disease-like symptoms by using MPP+ analogs.

MPP+ decreases the content of mitochondrial DNA in other cell lines, including a neuron-derived cell line,3 indicating that the effect on mitochondrial DNA observed here is a general phenomenon. Because rotenone rather increased the content of mitochondrial DNA, the decrease in mitochondrial DNA by MPP+ is not due to the Obardot 2-induced oxidative damage caused by the inhibition of complex I. MPP+ is likely to have two independent effects on mitochondria, the inhibition of complex I and the decrease of mitochondrial DNA content. It is intriguing to determine whether the structural part on MPP+ responsible for each effect is separated. If there is an MPP+ analog which decreases the content of mitochondrial DNA but does not inhibit complex I, the analog may be extremely useful for studying the mechanism for the MPP+-induced decrease of mitochondrial DNA content.

Although the mechanism by which MPP+ decreases mitochondrial DNA is not clear at the present time, the decrease of the nascent H strand suggests that the replication is inhibited. The inhibition of the replication by zidovudine is due to the delay of the elongation of nascent strand. The delay of the elongation of nascent H strand may accumulate the replication intermediates, which would decrease the nascent H strands per cell, but rather increase the nascent H strands per mitochondrial DNA. Hence, it is likely that the initiation of the replication is suppressed if the inhibition of the replication by MPP+ is the case. The elucidation of the mechanism should provide a new insight into the regulation of the intracellular content of mitochondrial DNA.


FOOTNOTES

*   This work was supported in part by Grant-in aid for Scientific Research on Priority Areas (08280104) from the Ministry of Education, Science, Sports, and Culture of Japan.The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
Dagger    To whom correspondence should be addressed. Present address: Dept. of Clinical Chemistry and Laboratory Medicine, Kyushu University Faculty of Medicine, 3-1-1 Maidashi, Higashi-ku, Fukuoka 812-82, Japan. Fax: 81-92-642-5772.
1   The abbreviations used are: MPTP, 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine; MPP+, 1-methyl-4-phenylpyridinium ion; PCR, polymerase chain reaction; LMPCR, ligation-mediated PCR; Obardot 2, superoxide radical; kbp, kilobase pair(s); nt, nucleotide(s).
2   D. Kang, K. Miyako, Y. Kai, T. Irie, and K. Takeshige, submitted for publication.
3   K. Miyako, Y. Kai, T. Irie, K. Takeshige, and D. Kang, unpublished data.

ACKNOWLEDGEMENTS

We extend special thanks to Drs. Sumimoto and Nakabeppu (Kyushu University) and Prof. Sekiguchi (Fukuoka Dental College) for critical discussion and useful comments. We sincerely thank Prof. Narayanan (New York Medical College) and Prof. Hamasaki (Kyushu University) for the critical reading of the manuscript.


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